Merge vk-gl-cts/vulkan-cts-1.1.4 into vk-gl-cts/vulkan-cts-1.1.5

[platform/upstream/VK-GL-CTS.git] / external / vulkancts / modules / vulkan / descriptor_indexing / vktDescriptorSetsIndexingTests.cpp

/*------------------------------------------------------------------------
* Vulkan Conformance Tests
* ------------------------
*
* Copyright (c) 2019 The Khronos Group 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 Vulkan Decriptor Indexing Tests
*//*--------------------------------------------------------------------*/

#include <algorithm>
#include <iostream>
#include <iterator>
#include <functional>
#include <sstream>
#include <utility>
#include <vector>

#include "vktDescriptorSetsIndexingTests.hpp"

#include "vkBuilderUtil.hpp"
#include "vkCmdUtil.hpp"
#include "vkDefs.hpp"
#include "vkObjUtil.hpp"
#include "vkPlatform.hpp"
#include "vkPrograms.hpp"
#include "vkQueryUtil.hpp"
#include "vkTypeUtil.hpp"

#include "tcuTestLog.hpp"
#include "tcuResource.hpp"
#include "tcuImageCompare.hpp"
#include "tcuCommandLine.hpp"
#include "tcuStringTemplate.hpp"
#include "tcuSurface.hpp"
#include "tcuVectorUtil.hpp"

#include "deRandom.hpp"
#include "deMath.h"
#include "deStringUtil.hpp"

namespace vkt
{
namespace DescriptorIndexing
{
namespace
{
using namespace vk;
using tcu::UVec2;
using tcu::Vec4;
using tcu::TestStatus;
using tcu::PixelBufferAccess;
using tcu::Texture2D;

#define RESOLUTION_width        64
#define RESOLUTION_height       64
static const VkExtent3D RESOLUTION = { RESOLUTION_width, RESOLUTION_height, 1 };

#define MAX_DESCRIPTORS         4200
#define FUZZY_COMPARE           DE_FALSE
#define CMP_THRESHOLD           0.02f

#define BINDING_Undefined                               0
#define BINDING_UniformBuffer                   1
#define BINDING_StorageBuffer                   2
#define BINDING_UniformTexelBuffer              3
#define BINDING_StorageTexelBuffer              4
#define BINDING_Sampler                                 5
#define BINDING_SampledImage                    6
#define BINDING_CombinedImageSampler    7
#define BINDING_UniformBufferDynamic    8
#define BINDING_StorageBufferDynamic    9
#define BINDING_InputAttachment                 10
#define BINDING_StorageImage                    11
#define BINDING_DescriptorEnumerator    12

static const VkExtent3D                 smallImageExtent                                = { 4, 4, 1 };
static const VkExtent3D                 bigImageExtent                                  = { 32, 32, 1 };
static const VkDescriptorType   VK_DESCRIPTOR_TYPE_UNDEFINED = VK_DESCRIPTOR_TYPE_INLINE_UNIFORM_BLOCK_EXT;

template<deUint32 BindingNumber>
struct Binding
{
        static const deUint32   binding = BindingNumber;
};

struct BindingUniformBuffer : Binding<BINDING_UniformBuffer>
{
        typedef struct
        {
                tcu::Vec4 c;
        } Data;
};

struct BindingStorageBuffer : Binding<BINDING_StorageBuffer>
{
        typedef struct
        {
                tcu::Vec4 cnew;
                tcu::Vec4 cold;
        } Data;
};

struct TestCaseParams
{
        VkDescriptorType        descriptorType;         // used only to distinguish test class instance
        VkShaderStageFlags      stageFlags;                     // used only to build a proper program
        VkExtent3D                      frameResolution;        // target frame buffer resolution
        bool                            updateAfterBind;        // whether a test will use update after bind feature
        bool                            calculateInLoop;        // perform calculation in a loop
        bool                            usesMipMaps;            // this makes a sense and affects in image test cases only
        deBool                          fuzzyComparison;        // if true then a test will use fuzzy comparison, otherwise float threshold
        float                           thresholdValue;         // a threshold that will be used for both, float and fuzzy comparisons
};

struct TestParams
{
        VkShaderStageFlags      stageFlags;
        VkDescriptorType        descriptorType;
        deUint32                        descriptorBinding;
        VkDescriptorType        additionalDescriptorType;
        deUint32                        additionalDescriptorBinding;
        bool                            copyBuffersToImages;
        bool                            allowVertexStoring;
        VkExtent3D                      frameResolution;
        bool                            updateAfterBind;
        bool                            calculateInLoop;
        bool                            usesMipMaps;
        deBool                          fuzzyComparison;
        float                           thresholdValue;

        TestParams                      (VkShaderStageFlags             stageFlags_,
                                                VkDescriptorType                descriptorType_,
                                                deUint32                                descriptorBinding_,
                                                VkDescriptorType                additionalDescriptorType_,
                                                deUint32                                additionalDescriptorBinding_,
                                                bool                                    copyBuffersToImages_,
                                                bool                                    allowVertexStoring_,
                                                const TestCaseParams&   caseParams)
                : stageFlags                                                    (stageFlags_)
                , descriptorType                                                (descriptorType_)
                , descriptorBinding                                             (descriptorBinding_)
                , additionalDescriptorType                              (additionalDescriptorType_)
                , additionalDescriptorBinding                   (additionalDescriptorBinding_)
                , copyBuffersToImages                                   (copyBuffersToImages_)
                , allowVertexStoring                                    (allowVertexStoring_)
                , frameResolution                                               (caseParams.frameResolution)
                , updateAfterBind                                               (caseParams.updateAfterBind)
                , calculateInLoop                                               (caseParams.calculateInLoop)
                , usesMipMaps                                                   (caseParams.usesMipMaps)
                , fuzzyComparison                                               (caseParams.fuzzyComparison ? true : false)
                , thresholdValue                                                (caseParams.thresholdValue)
        {
        }
};

struct DescriptorEnumerator
{
        ut::BufferHandleAllocSp                                                 buffer;
        ut::BufferViewSp                                                                bufferView;
        VkDeviceSize                                                                    bufferSize;

        Move<VkDescriptorSetLayout>                                             descriptorSetLayout;
        Move<VkDescriptorPool>                                                  descriptorPool;
        Move<VkDescriptorSet>                                                   descriptorSet;

        void init(const vkt::Context& context, deUint32 vertexCount, deUint32 availableDescriptorCount);
        void update(const vkt::Context& context);
};

struct IterateCommonVariables
{
        // An amount of descriptors of a given type available on the platform
        deUint32                                                                                availableDescriptorCount;
        // An amount of valid descriptors that have connected a buffers to them
        deUint32                                                                                validDescriptorCount;
        // As the name suggests, sometimes it is used as invocationCount
        deUint32                                                                                vertexCount;
        VkRect2D                                                                                renderArea;
        VkDeviceSize                                                                    dataAlignment;
        deUint32                                                                                lowerBound;
        deUint32                                                                                upperBound;

        DescriptorEnumerator                                                    descriptorEnumerator;

        ut::BufferHandleAllocSp                                                 vertexAttributesBuffer;
        ut::BufferHandleAllocSp                                                 descriptorsBuffer;
        std::vector<VkDescriptorBufferInfo>                             descriptorsBufferInfos;
        std::vector<ut::BufferViewSp>                                   descriptorsBufferViews;
        std::vector<ut::ImageViewSp>                                    descriptorImageViews;
        std::vector<ut::SamplerSp>                                              descriptorSamplers;
        std::vector<ut::ImageHandleAllocSp>                             descriptorsImages;
        ut::FrameBufferSp                                                               frameBuffer;

        Move<VkDescriptorSetLayout>                                             descriptorSetLayout;
        Move<VkDescriptorPool>                                                  descriptorPool;
        Move<VkDescriptorSet>                                                   descriptorSet;
        Move<VkPipelineLayout>                                                  pipelineLayout;
        Move<VkRenderPass>                                                              renderPass;
        Move<VkPipeline>                                                                pipeline;
        Move<VkCommandBuffer>                                                   commandBuffer;
};

class CommonDescriptorInstance : public TestInstance
{
public:
                                                                CommonDescriptorInstance                (Context&                                                                       context,
                                                                                                                                const TestParams&                                                       testParams);

        deUint32                                        computeAvailableDescriptorCount (VkDescriptorType                                                       descriptorType) const;

        Move<VkDescriptorSetLayout>     createDescriptorSetLayout               (deUint32&                                                                      descriptorCount) const;

        Move<VkDescriptorPool>          createDescriptorPool                    (deUint32                                                                       descriptorCount) const;

        Move<VkDescriptorSet>           createDescriptorSet                             (VkDescriptorPool                                                       dsPool,
                                                                                                                                 VkDescriptorSetLayout                                          dsLayout) const;

        struct attributes
        {
                typedef tcu::Vec4       vec4;
                typedef tcu::Vec2       vec2;
                typedef tcu::IVec4      ivec4;
                vec4                    position;
                vec2                    normalpos;
                ivec4                   index;
                attributes& operator()(const vec4& pos)
                {
                        position = pos;

                        normalpos.x() = (pos.x() + 1.0f) / 2.0f;
                        normalpos.y() = (pos.y() + 1.0f) / 2.0f;

                        return *this;
                }
        };
        void                                            createVertexAttributeBuffer             (ut::BufferHandleAllocSp&                                       buffer,
                                                                                                                                 deUint32                                                                       availableDescriptorCount) const;

        static std::string                      substBinding                                    (deUint32                                                                       binding,
                                                                                                                                 const char*                                                            str,
                                                                                                                                 deUint32                                                                       count = 0,
                                                                                                                                 const char*                                                            name = DE_NULL);

        static const char*                      getVertexShaderProlog                   (void);

        static const char*                      getFragmentShaderProlog                 (void);

        static const char*                      getShaderEpilog                                 (void);

        static bool                                     performWritesInVertex                   (VkDescriptorType                                                       descriptorType);

        static bool                                     performWritesInVertex                   (VkDescriptorType                                                       descriptorType,
                                                                                                                                 const Context&                                         context);
        static std::string                      getShaderSource                                 (VkShaderStageFlagBits                                          shaderType,
                                                                                                                                 const TestCaseParams&                                          testCaseParams,
                                                                                                                                 bool                                                                           allowVertexStoring);

        static std::string                      getColorAccess                                  (VkDescriptorType                                                       descriptorType,
                                                                                                                                 const char*                                                            indexVariableName,
                                                                                                                                 bool                                                                           usesMipMaps);

        static std::string                      getFragmentReturnSource                 (const std::string&                                                     colorAccess);

        static std::string                      getFragmentLoopSource                   (const std::string&                                                     colorAccess1,
                                                                                                                                 const std::string&                                                     colorAccess2);

        virtual Move<VkRenderPass>      createRenderPass                                (const IterateCommonVariables&                          variables);

        struct push_constant
        {
                deInt32 lowerBound;
                deInt32 upperBound;
        };
        VkPushConstantRange                     makePushConstantRange                   (void) const;

        Move<VkPipelineLayout>          createPipelineLayout                    (const std::vector<VkDescriptorSetLayout>&      descriptorSetLayouts) const;

        // Creates graphics or compute pipeline and appropriate shaders' modules according the testCaseParams.stageFlags
        // In the case of compute pipeline renderPass parameter is ignored.
        // Viewport will be created with a width and a height taken from testCaseParam.fragResolution.
        Move<VkPipeline>                        createPipeline                                  (VkPipelineLayout                                                       pipelineLayout,
                                                                                                                                 VkRenderPass                                                           renderPass);

        virtual void                            createFramebuffer                               (ut::FrameBufferSp&                                                     frameBuffer,
                                                                                                                                 VkRenderPass                                                           renderPass,
                                                                                                                                 const IterateCommonVariables&                          variables);

        // Creates one big stagging buffer cutted out on chunks that can accomodate an element of elementSize size
        VkDeviceSize                            createBuffers                                   (std::vector<VkDescriptorBufferInfo>&           bufferInfos,
                                                                                                                                 ut::BufferHandleAllocSp&                                       buffer,
                                                                                                                                 deUint32                                                                       elementCount,
                                                                                                                                 deUint32                                                                       elementSize,
                                                                                                                                 VkDeviceSize                                                           alignment,
                                                                                                                                 VkBufferUsageFlags                                                     bufferUsage);

        // Creates and binds an imagesCount of images with given parameters.
        // Additionally creates stagging buffer for their data and PixelBufferAccess for particular images.
        VkDeviceSize                            createImages                                    (std::vector<ut::ImageHandleAllocSp>&           images,
                                                                                                                                 std::vector<VkDescriptorBufferInfo>&           bufferInfos,
                                                                                                                                 ut::BufferHandleAllocSp&                                       buffer,
                                                                                                                                 VkBufferUsageFlags                                                     bufferUsage,
                                                                                                                                 const VkExtent3D&                                                      imageExtent,
                                                                                                                                 VkFormat                                                                       imageFormat,
                                                                                                                                 VkImageLayout                                                          imageLayout,
                                                                                                                                 deUint32                                                                       imageCount,
                                                                                                                                 bool                                                                           withMipMaps = false);

        void                                            createBuffersViews                              (std::vector<ut::BufferViewSp>&                         views,
                                                                                                                                 const std::vector<VkDescriptorBufferInfo>&     bufferInfos,
                                                                                                                                 VkFormat                                                                       format);

        void                                            createImagesViews                               (std::vector<ut::ImageViewSp>&                          views,
                                                                                                                                 const std::vector<ut::ImageHandleAllocSp>&     images,
                                                                                                                                 VkFormat                                                                       format);

        virtual void                            copyBuffersToImages                             (IterateCommonVariables&                                        variables);

        virtual void                            copyImagesToBuffers                             (IterateCommonVariables&                                        variables);

        PixelBufferAccess                       getPixelAccess                                  (deUint32                                                                       imageIndex,
                                                                                                                                 const VkExtent3D&                                                      imageExtent,
                                                                                                                                 VkFormat                                                                       imageFormat,
                                                                                                                                 const std::vector<VkDescriptorBufferInfo>&     bufferInfos,
                                                                                                                                 const ut::BufferHandleAllocSp&                         buffer,
                                                                                                                                 deUint32                                                                       mipLevel = 0u) const;

        virtual void                            createAndPopulateDescriptors    (IterateCommonVariables&                                        variables) = 0;

        virtual void                            updateDescriptors                               (IterateCommonVariables&                                        variables);

        virtual void                            iterateCollectResults                   (ut::UpdatablePixelBufferAccessPtr&                     result,
                                                                                                                                 const IterateCommonVariables&                          variables,
                                                                                                                                 bool                                                                           fromTest);

        void                                            iterateCommandSetup                             (IterateCommonVariables&                                        variables);

        void                                            iterateCommandBegin                             (IterateCommonVariables&                                        variables,
                                                                                                                                bool                                                                            firstPass = true);

        void                                            iterateCommandEnd                               (IterateCommonVariables&                                        variables,
                                                                                                                                ut::UpdatablePixelBufferAccessPtr&      programResult,
                                                                                                                                ut::UpdatablePixelBufferAccessPtr&      referenceResult,
                                                                                                                                 bool                                                                           collectBeforeSubmit = true);

        bool                                            iterateVerifyResults                    (IterateCommonVariables&                                        variables,
                                                                                                                                         ut::UpdatablePixelBufferAccessPtr      programResult,
                                                                                                                                         ut::UpdatablePixelBufferAccessPtr      referenceResult);

        Move<VkCommandBuffer>           createCmdBuffer                                 (void);

        void                                            commandBindPipeline                             (VkCommandBuffer                                                        commandBuffer,
                                                                                                                                 VkPipeline                                                                     pipeline);

        void                                            commandBindVertexAttributes             (VkCommandBuffer                                                        commandBuffer,
                                                                                                                                 const ut::BufferHandleAllocSp&                         vertexAttributesBuffer);

        void                                            commandBindDescriptorSets               (VkCommandBuffer                                                        commandBuffer,
                                                                                                                                 VkPipelineLayout                                                       pipelineLayout,
                                                                                                                                 VkDescriptorSet                                                        descriptorSet,
                                                                                                                                 deUint32                                                                       descriptorSetIndex);

        void                                            commandReadFrameBuffer                  (ut::BufferHandleAllocSp&                                       content,
                                                                                                                                 VkCommandBuffer                                                        commandBuffer,
                                                                                                                                 const ut::FrameBufferSp&                                       frameBuffer);
        ut::UpdatablePixelBufferAccessPtr
                                                                commandReadFrameBuffer                  (VkCommandBuffer                                                        commandBuffer,
                                                                                                                                 const ut::FrameBufferSp&                                       frameBuffer);

        Move<VkFence>                           commandSubmit                                   (VkCommandBuffer                                                        commandBuffer);

        virtual bool                            verifyVertexWriteResults                (IterateCommonVariables&                                        variables);

protected:
        virtual tcu::TestStatus         iterate                                                 (void);

protected:
        const VkDevice                          m_vkd;
        const DeviceInterface&          m_vki;
        Allocator&                                      m_allocator;
        const VkQueue                           m_queue;
        const deUint32                          m_queueFamilyIndex;
        const Move<VkCommandPool>       m_commandPool;
        const VkFormat                          m_colorFormat;
        const TestParams                        m_testParams;
        static const tcu::Vec4          m_clearColor;
        const std::vector<float>        m_colorScheme;
        const deUint32                          m_schemeSize;

private:

        Move<VkPipeline>                        createGraphicsPipeline                  (VkPipelineLayout                                                       pipelineLayout,
                                                                                                                                 VkRenderPass                                                           renderPass);

        Move<VkPipeline>                        createComputePipeline                   (VkPipelineLayout                                                       pipelineLayout);

        int                                                     constructShaderModules                  (void);

        static std::vector<float>       createColorScheme();

        Move<VkShaderModule>            m_vertexModule;
        Move<VkShaderModule>            m_fragmentModule;
        Move<VkShaderModule>            m_computeModule;
};
const tcu::Vec4 CommonDescriptorInstance::m_clearColor = tcu::Vec4(0.0f, 0.0f, 0.0f, 1.0f);

void DescriptorEnumerator::init (const vkt::Context& context, deUint32 vertexCount, deUint32 availableDescriptorCount)
{
        const VkDevice                                  device = context.getDevice();
        const DeviceInterface&                  deviceInterface = context.getDeviceInterface();

        const VkFormat                                  imageFormat = VK_FORMAT_R32G32B32A32_SINT;
        typedef ut::mapVkFormat2Type<imageFormat>::type pixelType;
        const VkDeviceSize                              dataSize = vertexCount * sizeof(pixelType);
        const std::vector<deUint32>             primes = ut::generatePrimes(availableDescriptorCount);
        const deUint32                                  primeCount = static_cast<deUint32>(primes.size());

        std::vector<pixelType>  data(vertexCount);
        // e.g. 2,3,5,7,11,13,2,3,5,7,...
        for (deUint32 idx = 0; idx < vertexCount; ++idx)
        {
                data[idx].x() = static_cast<pixelType::Element>(primes[idx % primeCount]);
                data[idx].y() = static_cast<pixelType::Element>(idx);
        }

        bufferSize = ut::createBufferAndBind(buffer, context, VK_BUFFER_USAGE_UNIFORM_TEXEL_BUFFER_BIT, dataSize);
        deMemcpy(buffer->alloc->getHostPtr(), data.data(), static_cast<size_t>(dataSize));

        const VkBufferViewCreateInfo bufferViewCreateInfo =
        {
                VK_STRUCTURE_TYPE_BUFFER_VIEW_CREATE_INFO,              // sType
                DE_NULL,                                                                                // pNext
                0u,                                                                                             // flags
                *(buffer.get()->buffer),                                                // buffer
                imageFormat,                                                                    // format
                0u,                                                                                             // offset
                bufferSize,                                                                             // range
        };

        bufferView = ut::BufferViewSp(new Move<VkBufferView>(vk::createBufferView(deviceInterface, device, &bufferViewCreateInfo)));

        const VkDescriptorSetLayoutBinding      binding =
        {
                BINDING_DescriptorEnumerator,                                   // binding
                VK_DESCRIPTOR_TYPE_UNIFORM_TEXEL_BUFFER,                // descriptorType
                1u,                                                                                             // descriptorCount
                VK_SHADER_STAGE_ALL,                                                    // stageFlags
                DE_NULL,                                                                                // pImmutableSamplers
        };

        const VkDescriptorSetLayoutCreateInfo   layoutCreateInfo =
        {
                VK_STRUCTURE_TYPE_DESCRIPTOR_SET_LAYOUT_CREATE_INFO,
                DE_NULL,                                                                                // pNext
                0u,                                                                                             // flags
                1u,                                                                                             // bindingCount
                &binding,                                                                               // pBindings
        };

        descriptorSetLayout = vk::createDescriptorSetLayout(deviceInterface, device, &layoutCreateInfo);
        descriptorPool = DescriptorPoolBuilder().addType(binding.descriptorType)
                .build(deviceInterface, device, VK_DESCRIPTOR_POOL_CREATE_FREE_DESCRIPTOR_SET_BIT, 1u);

        const VkDescriptorSetAllocateInfo       dsAllocInfo =
        {
                VK_STRUCTURE_TYPE_DESCRIPTOR_SET_ALLOCATE_INFO, // sType
                DE_NULL,                                                                                // pNext
                *descriptorPool,                                                                // descriptorPool
                1u,                                                                                             // descriptorSetCount
                &(*descriptorSetLayout)                                                 // pSetLayouts
        };

        descriptorSet = vk::allocateDescriptorSet(deviceInterface, device, &dsAllocInfo);
}

void DescriptorEnumerator::update (const vkt::Context& context)
{
        const VkDescriptorBufferInfo bufferInfo =
        {
                *(buffer.get()->buffer),                                        // buffer
                0u,                                                                                     // offset
                bufferSize,                                                                     // range
        };

        const VkWriteDescriptorSet writeInfo =
        {
                VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET,
                DE_NULL,                                                                        // pNext
                *descriptorSet,                                                         // dstSet
                BINDING_DescriptorEnumerator,                           // dstBinding
                0u,                                                                                     // dstArrayElement
                1u,                                                                                     // descriptorCount
                VK_DESCRIPTOR_TYPE_UNIFORM_TEXEL_BUFFER,        // descriptorType
                DE_NULL,                                                                        // pImageInfo
                &bufferInfo,                                                            // pBufferInfo
                &(**bufferView),                                                        // pTexelBufferView
        };

        context.getDeviceInterface().updateDescriptorSets(context.getDevice(), 1u, &writeInfo, 0u, DE_NULL);
}

CommonDescriptorInstance::CommonDescriptorInstance                                      (Context&                                                               context,
                                                                                                                                        const TestParams&                                               testParams)
        : TestInstance          (context)
        , m_vkd                         (context.getDevice())
        , m_vki                         (context.getDeviceInterface())
        , m_allocator           (context.getDefaultAllocator())
        , m_queue                       (context.getUniversalQueue())
        , m_queueFamilyIndex(context.getUniversalQueueFamilyIndex())
        , m_commandPool         (vk::createCommandPool(m_vki, m_vkd, (VK_COMMAND_POOL_CREATE_TRANSIENT_BIT | VK_COMMAND_POOL_CREATE_RESET_COMMAND_BUFFER_BIT), m_queueFamilyIndex))
        , m_colorFormat         (VK_FORMAT_R32G32B32A32_SFLOAT)
        , m_testParams          (testParams)
        , m_colorScheme         (createColorScheme())
        , m_schemeSize          (static_cast<deUint32>(m_colorScheme.size()))
{
}

deUint32 CommonDescriptorInstance::computeAvailableDescriptorCount      (VkDescriptorType                                               descriptorType) const
{
        DE_UNREF(descriptorType);
        const deUint32 vertexCount = m_testParams.frameResolution.width * m_testParams.frameResolution.height;
        const deUint32 availableDescriptorsOnDevice = ut::DeviceProperties(m_context).computeMaxPerStageDescriptorCount(m_testParams.descriptorType, m_testParams.updateAfterBind);
        return deMinu32(deMinu32(vertexCount, availableDescriptorsOnDevice), MAX_DESCRIPTORS);
}

Move<VkDescriptorSetLayout>     CommonDescriptorInstance::createDescriptorSetLayout (deUint32&                                  descriptorCount) const
{
        descriptorCount = computeAvailableDescriptorCount(m_testParams.descriptorType);

        bool optional = (m_testParams.additionalDescriptorBinding != BINDING_Undefined) && (m_testParams.additionalDescriptorType != VK_DESCRIPTOR_TYPE_UNDEFINED);

        const VkDescriptorSetLayoutBinding      bindings[] =
        {
                {
                        m_testParams.descriptorBinding,                         // binding
                        m_testParams.descriptorType,                            // descriptorType
                        descriptorCount,                                                        // descriptorCount
                        m_testParams.stageFlags,                                        // stageFlags
                        DE_NULL,                                                                        // pImmutableSamplers
                },
                {
                        m_testParams.additionalDescriptorBinding,       // binding
                        m_testParams.additionalDescriptorType,          // descriptorType
                        1,                                                                                      // descriptorCount
                        m_testParams.stageFlags,                                        // stageFlags
                        DE_NULL,                                                                        // pImmutableSamplers
                }
        };

        const VkDescriptorBindingFlagsEXT       bindingFlagUpdateAfterBind =
                m_testParams.updateAfterBind ? VK_DESCRIPTOR_BINDING_UPDATE_AFTER_BIND_BIT_EXT : 0;

        const VkDescriptorBindingFlagsEXT bindingFlagsExt[] =
        {
                VK_DESCRIPTOR_BINDING_PARTIALLY_BOUND_BIT_EXT | bindingFlagUpdateAfterBind,
                VK_DESCRIPTOR_BINDING_PARTIALLY_BOUND_BIT_EXT | bindingFlagUpdateAfterBind
        };

        const VkDescriptorSetLayoutBindingFlagsCreateInfoEXT    bindingCreateInfoExt =
        {
                VK_STRUCTURE_TYPE_DESCRIPTOR_SET_LAYOUT_BINDING_FLAGS_CREATE_INFO_EXT,
                DE_NULL,
                optional ? 2u : 1u,     // bindingCount
                bindingFlagsExt,        // pBindingFlags
        };

        const VkDescriptorSetLayoutCreateFlags  layoutCreateFlags =
                m_testParams.updateAfterBind ? VK_DESCRIPTOR_SET_LAYOUT_CREATE_UPDATE_AFTER_BIND_POOL_BIT_EXT : 0;

        const VkDescriptorSetLayoutCreateInfo   layoutCreateInfo =
        {
                VK_STRUCTURE_TYPE_DESCRIPTOR_SET_LAYOUT_CREATE_INFO,
                &bindingCreateInfoExt,  // pNext
                layoutCreateFlags,              // flags
                optional ? 2u : 1u,             // bindingCount
                bindings,                               // pBindings
        };

        return vk::createDescriptorSetLayout(m_vki, m_vkd, &layoutCreateInfo);
}

Move<VkDescriptorPool>  CommonDescriptorInstance::createDescriptorPool (deUint32                                                        descriptorCount) const
{
        const VkDescriptorPoolCreateFlags pcf = m_testParams.updateAfterBind ? VK_DESCRIPTOR_POOL_CREATE_UPDATE_AFTER_BIND_BIT_EXT : 0;

        DescriptorPoolBuilder builder;

        builder.addType(m_testParams.descriptorType, descriptorCount);

        if (m_testParams.additionalDescriptorType != VK_DESCRIPTOR_TYPE_UNDEFINED && m_testParams.additionalDescriptorBinding != BINDING_Undefined)
        {
                builder.addType(m_testParams.additionalDescriptorType, 1);
        }

        return builder.build(m_vki, m_vkd, (VK_DESCRIPTOR_POOL_CREATE_FREE_DESCRIPTOR_SET_BIT | pcf), 1u);
}

Move<VkDescriptorSet> CommonDescriptorInstance::createDescriptorSet     (VkDescriptorPool                                               dsPool,
                                                                                                                                         VkDescriptorSetLayout                                  dsLayout) const
{
        const VkDescriptorSetAllocateInfo       dsAllocInfo =
        {
                VK_STRUCTURE_TYPE_DESCRIPTOR_SET_ALLOCATE_INFO,         // sType;
                DE_NULL,                                                                                        // pNext;
                dsPool,                                                                                         // descriptorPool;
                1u,                                                                                                     // descriptorSetCount
                &dsLayout                                                                                       // pSetLayouts
        };

        return vk::allocateDescriptorSet(m_vki, m_vkd, &dsAllocInfo);
}

void CommonDescriptorInstance::createVertexAttributeBuffer                      (ut::BufferHandleAllocSp&                               buffer,
                                                                                                                                         deUint32                                                               availableDescriptorCount) const
{
        float                                           xSize                   = 0.0f;
        float                                           ySize                   = 0.0f;

        const deUint32                          invocationCount = m_testParams.frameResolution.width * m_testParams.frameResolution.height;
        const std::vector<Vec4>         vertices                = ut::createVertices(m_testParams.frameResolution.width, m_testParams.frameResolution.height, xSize, ySize);
        const std::vector<deUint32>     primes                  = ut::generatePrimes(availableDescriptorCount);
        const deUint32                          primeCount              = static_cast<deUint32>(primes.size());

        std::vector<attributes> data(vertices.size());
        std::transform(vertices.begin(), vertices.end(), data.begin(), attributes());

        for (deUint32 invIdx = 0; invIdx < invocationCount; ++invIdx)
        {
                // r: 2,3,5,7,11,13,2,3,5,7,...
                data[invIdx].index.x() = primes[invIdx % primeCount];

                // b: x index in texel coordinate
                data[invIdx].index.z() = invIdx % m_testParams.frameResolution.width;

                //a: y index in texel coordinate
                data[invIdx].index.w() = invIdx / m_testParams.frameResolution.width;
        }

        // g: 0,0,2,3,0,5,0,7,0,0,0,11,0,13,...
        for (deUint32 primeIdx = 0; primeIdx < primeCount; ++primeIdx)
        {
                const deUint32 prime = primes[primeIdx];
                DE_ASSERT(prime < invocationCount);
                data[prime].index.y() = prime;
        }

        const VkDeviceSize              dataSize = data.size() * sizeof(attributes);

        VkDeviceSize                    deviceSize = ut::createBufferAndBind(buffer, m_context, VK_BUFFER_USAGE_VERTEX_BUFFER_BIT, dataSize);

        deMemcpy(buffer->alloc->getHostPtr(), data.data(), static_cast<size_t>(deviceSize));

        vk::flushAlloc(m_vki, m_vkd, *buffer->alloc);
}

std::string CommonDescriptorInstance::substBinding                                      (deUint32                                                               binding,
                                                                                                                                         const char*                                                    str,
                                                                                                                                         deUint32                                                               count,
                                                                                                                                         const char*                                                    name)
{
        std::map<std::string, std::string> vars;
        vars["?"]       = de::toString(binding);
        vars["*"]       = (0 == count)          ? ""            : de::toString(count);
        vars["VAR"]     = (DE_NULL == name)     ? "data"        : name;
        return tcu::StringTemplate(str).specialize(vars);
}

const char* CommonDescriptorInstance::getVertexShaderProlog                     (void)
{
        return
                "layout(location = 0) in  vec4  in_position;    \n"
                "layout(location = 1) in  vec2  in_normalpos;   \n"
                "layout(location = 2) in  ivec4 index;                  \n"
                "layout(location = 0) out vec4  position;       \n"
                "layout(location = 1) out vec2  normalpos;      \n"
                "layout(location = 2) out int   vIndex;         \n"
                "layout(location = 3) out int   rIndex;         \n"
                "layout(location = 4) out int   gIndex;         \n"
                "layout(location = 5) out int   bIndex;         \n"
                "layout(location = 6) out int   aIndex;         \n"
                "void main()                                                    \n"
                "{                                                                              \n"
                "    gl_PointSize = 0.2f;                               \n"
                "    position = in_position;                    \n"
                "    normalpos = in_normalpos;                  \n"
                "    gl_Position = position;                    \n"
                "    vIndex = gl_VertexIndex;                   \n"
                "    rIndex = index.x;                                  \n"
                "    gIndex = index.y;                                  \n"
                "    bIndex = index.z;                                  \n"
                "    aIndex = index.w;                                  \n";
}

const char* CommonDescriptorInstance::getFragmentShaderProlog           (void)
{
        return
                "layout(location = 0) out vec4     FragColor;   \n"
                "layout(location = 0) in flat vec4 position;    \n"
                "layout(location = 1) in flat vec2 normalpos;   \n"
                "layout(location = 2) in flat int  vIndex;              \n"
                "layout(location = 3) in flat int  rIndex;              \n"
                "layout(location = 4) in flat int  gIndex;              \n"
                "layout(location = 5) in flat int  bIndex;              \n"
                "layout(location = 6) in flat int  aIndex;              \n"
                "void main()                                                                    \n"
                "{                                                                                              \n";
}

const char* CommonDescriptorInstance::getShaderEpilog                           (void)
{
        return "}                                                                                       \n";
}

int     CommonDescriptorInstance::constructShaderModules                                (void)
{
        int                                                             result  = 0;
        tcu::TestLog&                                   log             = m_context.getTestContext().getLog();

        if (m_testParams.stageFlags & VK_SHADER_STAGE_COMPUTE_BIT)
        {
                ++result;
                const std::string name = ut::buildShaderName(VK_SHADER_STAGE_COMPUTE_BIT, m_testParams.descriptorType, m_testParams.updateAfterBind, m_testParams.calculateInLoop, false);
                m_computeModule = vk::createShaderModule(m_vki, m_vkd, m_context.getBinaryCollection().get(name), (VkShaderModuleCreateFlags)0);
        }
        if (m_testParams.stageFlags & VK_SHADER_STAGE_FRAGMENT_BIT)
        {
                ++result;
                const std::string name = ut::buildShaderName(VK_SHADER_STAGE_FRAGMENT_BIT, m_testParams.descriptorType, m_testParams.updateAfterBind, m_testParams.calculateInLoop, m_testParams.allowVertexStoring);
                m_fragmentModule = vk::createShaderModule(m_vki, m_vkd, m_context.getBinaryCollection().get(name), (VkShaderModuleCreateFlags)0);
                log << tcu::TestLog::Message << "Finally used fragment shader: " << name << '\n' << tcu::TestLog::EndMessage;
        }
        if (m_testParams.stageFlags & VK_SHADER_STAGE_VERTEX_BIT)
        {
                ++result;
                const std::string name = ut::buildShaderName(VK_SHADER_STAGE_VERTEX_BIT, m_testParams.descriptorType, m_testParams.updateAfterBind, m_testParams.calculateInLoop, m_testParams.allowVertexStoring);
                m_vertexModule = vk::createShaderModule(m_vki, m_vkd, m_context.getBinaryCollection().get(name), (VkShaderModuleCreateFlags)0);
                log << tcu::TestLog::Message << "Finally used vertex shader: " << name << '\n' << tcu::TestLog::EndMessage;
        }

        DE_ASSERT(result > 0);

        return result;
}

Move<VkRenderPass> CommonDescriptorInstance::createRenderPass           (const IterateCommonVariables&                  variables)
{
        DE_UNREF(variables);
        if ((m_testParams.stageFlags & VK_SHADER_STAGE_VERTEX_BIT) || (m_testParams.stageFlags & VK_SHADER_STAGE_FRAGMENT_BIT))
        {
                // Use VK_ATTACHMENT_LOAD_OP_LOAD to make the utility function select initialLayout = VK_IMAGE_LAYOUT_COLOR_ATTACHMENT_OPTIMAL
                return vk::makeRenderPass(m_vki, m_vkd, m_colorFormat, VK_FORMAT_UNDEFINED, VK_ATTACHMENT_LOAD_OP_LOAD);
        }
        return Move<VkRenderPass>();
}

VkPushConstantRange CommonDescriptorInstance::makePushConstantRange     (void) const
{
        const VkPushConstantRange pcr =
        {
                m_testParams.stageFlags,                                                        // stageFlags
                0u,                                                                                                     // offset
                static_cast<deUint32>(sizeof(push_constant))            // size
        };
        return pcr;
}

Move<VkPipelineLayout> CommonDescriptorInstance::createPipelineLayout (const std::vector<VkDescriptorSetLayout>&        descriptorSetLayouts) const
{
        const VkPushConstantRange pcr = makePushConstantRange();

        const VkPipelineLayoutCreateInfo createInfo =
        {
                VK_STRUCTURE_TYPE_PIPELINE_LAYOUT_CREATE_INFO,          // sType
                DE_NULL,                                                                                        // pNext
                (VkPipelineLayoutCreateFlags)0,                                         // flags
                static_cast<deUint32>(descriptorSetLayouts.size()),     // setLayoutCount
                descriptorSetLayouts.data(),                                            // pSetLayouts;
                m_testParams.calculateInLoop ? 1u : 0u,                         // pushConstantRangeCount
                m_testParams.calculateInLoop ? &pcr : DE_NULL,          // pPushConstantRanges
        };

        return vk::createPipelineLayout(m_vki, m_vkd, &createInfo);
}

void CommonDescriptorInstance::createFramebuffer                                        (ut::FrameBufferSp&                                                     frameBuffer,
                                                                                                                                         VkRenderPass                                                           renderPass,
                                                                                                                                         const IterateCommonVariables&                          variables)
{
        DE_UNREF(variables);
        ut::createFrameBuffer(frameBuffer, m_context, m_testParams.frameResolution, m_colorFormat, renderPass);
}

Move<VkPipeline> CommonDescriptorInstance::createPipeline                       (VkPipelineLayout                                                       pipelineLayout,
                                                                                                                                         VkRenderPass                                                           renderPass)
{       DE_ASSERT(VK_SHADER_STAGE_ALL != m_testParams.stageFlags);

        constructShaderModules();

        return (m_testParams.stageFlags & VK_SHADER_STAGE_COMPUTE_BIT)
                ? createComputePipeline(pipelineLayout)
                : createGraphicsPipeline(pipelineLayout, renderPass);
}

Move<VkPipeline> CommonDescriptorInstance::createComputePipeline        (VkPipelineLayout                                                       pipelineLayout)
{
        const VkPipelineShaderStageCreateInfo   shaderStaegCreateInfo =
        {
                VK_STRUCTURE_TYPE_PIPELINE_SHADER_STAGE_CREATE_INFO,
                DE_NULL,                                                                // pNext
                (VkPipelineShaderStageCreateFlags)0,    // flags
                VK_SHADER_STAGE_COMPUTE_BIT,                    // stage
                *m_computeModule,                                               // module
                "main",                                                                 // pName
                (VkSpecializationInfo*)DE_NULL                  // pSpecializationInfo
        };

        const VkComputePipelineCreateInfo               pipelineCreateInfo =
        {
                VK_STRUCTURE_TYPE_COMPUTE_PIPELINE_CREATE_INFO,
                DE_NULL,                                                                // pNext
                0u,                                                                             // flags
                shaderStaegCreateInfo,                                  // stage
                pipelineLayout,                                                 // layout
                (VkPipeline)0,                                                  // basePipelineHandle
                0u,                                                                             // basePipelineIndex
        };
        return vk::createComputePipeline(m_vki, m_vkd, (VkPipelineCache)0u, &pipelineCreateInfo);
}

Move<VkPipeline> CommonDescriptorInstance::createGraphicsPipeline       (VkPipelineLayout                                                       pipelineLayout,
                                                                                                                                         VkRenderPass                                                           renderPass)
{
        const VkVertexInputBindingDescription                   bindingDescriptions[] =
        {
                {
                        0u,                                                                                                     // binding
                        sizeof(attributes),                                                                     // stride
                        VK_VERTEX_INPUT_RATE_VERTEX,                                            // inputRate
                },
        };

        const VkVertexInputAttributeDescription                 attributeDescriptions[] =
        {
                {
                        0u,                                                                                                     // location
                        0u,                                                                                                     // binding
                        ut::mapType2vkFormat<attributes::vec4>::value,          // format
                        0u                                                                                                      // offset
                },                                                                                                              // @in_position
                {
                        1u,                                                                                                     // location
                        0u,                                                                                                     // binding
                        ut::mapType2vkFormat<attributes::vec2>::value,          // format
                        static_cast<deUint32>(sizeof(attributes::vec4))         // offset
                },                                                                                                              // @normalpos
                {
                        2u,                                                                                                     // location
                        0u,                                                                                                     // binding
                        ut::mapType2vkFormat<attributes::ivec4>::value,         // format
                        static_cast<deUint32>(sizeof(attributes::vec2)
                                                                + sizeof(attributes::vec4))             // offset
                },                                                                                                              // @index
        };

        const VkPipelineVertexInputStateCreateInfo              vertexInputStateCreateInfo      =
        {
                VK_STRUCTURE_TYPE_PIPELINE_VERTEX_INPUT_STATE_CREATE_INFO,
                DE_NULL,
                (VkPipelineVertexInputStateCreateFlags)0,       // flags
                DE_LENGTH_OF_ARRAY(bindingDescriptions),        // vertexBindingDescriptionCount
                bindingDescriptions,                                            // pVertexBindingDescriptions
                DE_LENGTH_OF_ARRAY(attributeDescriptions),      // vertexAttributeDescriptionCount
                attributeDescriptions                                           // pVertexAttributeDescriptions
        };

        const   VkDynamicState                                                  dynamicStates[]                         =
        {
                VK_DYNAMIC_STATE_SCISSOR
        };

        const VkPipelineDynamicStateCreateInfo                  dynamicStateCreateInfo =
        {
                VK_STRUCTURE_TYPE_PIPELINE_DYNAMIC_STATE_CREATE_INFO,  // sType
                DE_NULL,                                                                                           // pNext
                0u,                                                                                                        // flags
                DE_LENGTH_OF_ARRAY(dynamicStates),                                         // dynamicStateCount
                dynamicStates                                                                              // pDynamicStates
        };

        const std::vector<VkViewport>   viewports       (1, makeViewport(m_testParams.frameResolution.width, m_testParams.frameResolution.height));
        const std::vector<VkRect2D>             scissors        (1, makeRect2D(0u, 0u));

        DE_ASSERT(m_vertexModule && m_fragmentModule);

        return vk::makeGraphicsPipeline(
                m_vki,                                                                                  // vk
                m_vkd,                                                                                  // device
                pipelineLayout,                                                                 // pipelineLayout
                *m_vertexModule,                                                                // vertexShaderModule
                DE_NULL,                                                                                // tessellationControlModule
                DE_NULL,                                                                                // tessellationEvalModule
                DE_NULL,                                                                                // geometryShaderModule
                *m_fragmentModule,                                                              // fragmentShaderModule
                renderPass,                                                                             // renderPass
                viewports,                                                                              // viewports
                scissors,                                                                               // scissors
                VK_PRIMITIVE_TOPOLOGY_POINT_LIST,                               // topology
                0U,                                                                                             // subpass
                0U,                                                                                             // patchControlPoints
                &vertexInputStateCreateInfo,                                    // vertexInputStateCreateInfo
                nullptr,                                                                                // rasterizationStateCreateInfo
                nullptr,                                                                                // multisampleStateCreateInfo
                nullptr,                                                                                // depthStencilStateCreateInfo
                nullptr,                                                                                // colorBlendStateCreateInfo
                &dynamicStateCreateInfo);                                               // dynamicStateCreateInfo
}

VkDeviceSize CommonDescriptorInstance::createBuffers                            (std::vector<VkDescriptorBufferInfo>&           bufferInfos,
                                                                                                                                         ut::BufferHandleAllocSp&                                       buffer,
                                                                                                                                         deUint32                                                                       elementCount,
                                                                                                                                         deUint32                                                                       elementSize,
                                                                                                                                         VkDeviceSize                                                           alignment,
                                                                                                                                         VkBufferUsageFlags                                                     bufferUsage)
{
        const VkDeviceSize      roundedSize = deAlign64(elementSize, alignment);
        VkDeviceSize            bufferSize      = ut::createBufferAndBind(buffer, m_context, bufferUsage, (roundedSize * elementCount));

        for (deUint32 elementIdx = 0; elementIdx < elementCount; ++elementIdx)
        {
                const VkDescriptorBufferInfo bufferInfo =
                {
                        *buffer.get()->buffer,          //buffer;
                        elementIdx * roundedSize,       //offset;
                        elementSize,                            // range;

                };
                bufferInfos.push_back(bufferInfo);
        }

        return bufferSize;
}

VkDeviceSize CommonDescriptorInstance::createImages                                     (std::vector<ut::ImageHandleAllocSp>&           images,
                                                                                                                                         std::vector<VkDescriptorBufferInfo>&           bufferInfos,
                                                                                                                                         ut::BufferHandleAllocSp&                                       buffer,
                                                                                                                                         VkBufferUsageFlags                                                     bufferUsage,
                                                                                                                                         const VkExtent3D&                                                      imageExtent,
                                                                                                                                         VkFormat                                                                       imageFormat,
                                                                                                                                         VkImageLayout                                                          imageLayout,
                                                                                                                                         deUint32                                                                       imageCount,
                                                                                                                                         bool                                                                           withMipMaps)

{
        const deUint32          imageSize       = ut::computeImageSize(imageExtent, imageFormat, withMipMaps);

        const VkDeviceSize      bufferSize      = createBuffers(bufferInfos, buffer, imageCount, imageSize, sizeof(tcu::Vec4), bufferUsage);

        for (deUint32 imageIdx = 0; imageIdx < imageCount; ++imageIdx)
        {
                ut::ImageHandleAllocSp image;
                ut::createImageAndBind(image, m_context, imageFormat, imageExtent, imageLayout, withMipMaps);
                images.push_back(image);
        }

        return bufferSize;
}

void CommonDescriptorInstance::createBuffersViews                                       (std::vector<ut::BufferViewSp>&                         views,
                                                                                                                                         const std::vector<VkDescriptorBufferInfo>&     bufferInfos,
                                                                                                                                         VkFormat                                                                       format)
{
        const deUint32 infoCount = static_cast<deUint32>(bufferInfos.size());
        for (deUint32 infoIdx = 0; infoIdx < infoCount; ++infoIdx)
        {
                const VkDescriptorBufferInfo&   bufferInfo = bufferInfos[infoIdx];
                const VkBufferViewCreateInfo    bufferViewInfo =
                {
                        VK_STRUCTURE_TYPE_BUFFER_VIEW_CREATE_INFO,      // sType
                        DE_NULL,                                                                        // pNext
                        (VkBufferViewCreateFlags)0,                                     // flags
                        bufferInfo.buffer,                                                      // buffer
                        format,                                                                         // format
                        bufferInfo.offset,                                                      // offset
                        bufferInfo.range                                                        // range;
                };
                views.push_back(ut::BufferViewSp(new Move<VkBufferView>(vk::createBufferView(m_vki, m_vkd, &bufferViewInfo))));
        }
}

void CommonDescriptorInstance::createImagesViews                                        (std::vector<ut::ImageViewSp>&                          views,
                                                                                                                                         const std::vector<ut::ImageHandleAllocSp>&     images,
                                                                                                                                         VkFormat                                                                       format)
{
        const deUint32 imageCount = static_cast<deUint32>(images.size());
        for (deUint32 imageIdx = 0; imageIdx < imageCount; ++imageIdx)
        {
                const VkImageViewCreateInfo createInfo =
                {
                        VK_STRUCTURE_TYPE_IMAGE_VIEW_CREATE_INFO,       // sType
                        DE_NULL,                                                                        // pNext
                        (VkImageViewCreateFlags)0,                                      // flags
                        *images[imageIdx]->image,                                       // image
                        VK_IMAGE_VIEW_TYPE_2D,                                          // viewType
                        format,                                                                         // format
                        vk::makeComponentMappingRGBA(),                         // components
                        {
                                VK_IMAGE_ASPECT_COLOR_BIT,                              // aspectMask
                                (deUint32)0,                                                    // baseMipLevel
                                images[imageIdx]->levels,                               // mipLevels
                                (deUint32)0,                                                    // baseArrayLayer
                                (deUint32)1u,                                                   // arraySize
                        },
                };
                views.push_back(ut::ImageViewSp(new Move<VkImageView>(vk::createImageView(m_vki, m_vkd, &createInfo))));
        }
}

void CommonDescriptorInstance::copyBuffersToImages                                      (IterateCommonVariables&                                        variables)
{
        const deUint32 infoCount = static_cast<deUint32>(variables.descriptorsBufferInfos.size());
        DE_ASSERT(variables.descriptorsImages.size() == infoCount);
        const VkPipelineStageFlagBits dstStageMask = (m_testParams.stageFlags & VK_SHADER_STAGE_COMPUTE_BIT)
                ? VK_PIPELINE_STAGE_COMPUTE_SHADER_BIT
                : VK_PIPELINE_STAGE_VERTEX_INPUT_BIT;
        for (deUint32 infoIdx = 0; infoIdx < infoCount; ++infoIdx)
        {
                ut::recordCopyBufferToImage(
                        *variables.commandBuffer,                                               // commandBuffer
                        m_vki,                                                                                  // interface
                        VK_PIPELINE_STAGE_TOP_OF_PIPE_BIT,                              // srcStageMask
                        dstStageMask,                                                                   // dstStageMask
                        variables.descriptorsBufferInfos[infoIdx],              // bufferInfo
                        *(variables.descriptorsImages[infoIdx]->image), // image
                        variables.descriptorsImages[infoIdx]->extent,   // imageExtent
                        variables.descriptorsImages[infoIdx]->format,   // imageFormat
                        VK_IMAGE_LAYOUT_UNDEFINED,                                              // oldImageLayout
                        VK_IMAGE_LAYOUT_GENERAL,                                                // newImageLayout
                        variables.descriptorsImages[infoIdx]->levels);  // mipLevelCount
        }
}

void CommonDescriptorInstance::copyImagesToBuffers                                      (IterateCommonVariables&                                        variables)
{
        const deUint32 infoCount = static_cast<deUint32>(variables.descriptorsBufferInfos.size());
        DE_ASSERT(variables.descriptorsImages.size() == infoCount);
        const VkPipelineStageFlagBits srcStageMask = (m_testParams.stageFlags & VK_SHADER_STAGE_COMPUTE_BIT)
                ? VK_PIPELINE_STAGE_COMPUTE_SHADER_BIT
                : VK_PIPELINE_STAGE_COLOR_ATTACHMENT_OUTPUT_BIT;

        for (deUint32 infoIdx = 0; infoIdx < infoCount; ++infoIdx)
        {
                ut::recordCopyImageToBuffer(
                        *variables.commandBuffer,                                               // commandBuffer
                        m_vki,                                                                                  // interface
                        srcStageMask,                                                                   // srcStageMask
                        VK_PIPELINE_STAGE_HOST_BIT,                                             // dstStageMask
                        *(variables.descriptorsImages[infoIdx]->image), // image
                        variables.descriptorsImages[infoIdx]->extent,   // imageExtent
                        variables.descriptorsImages[infoIdx]->format,   // imageFormat
                        VK_IMAGE_LAYOUT_GENERAL,                                                // oldImageLayout
                        VK_IMAGE_LAYOUT_GENERAL,                                                // newImageLayout
                        variables.descriptorsBufferInfos[infoIdx]);             // bufferInfo
        }
}

PixelBufferAccess CommonDescriptorInstance::getPixelAccess                      (deUint32                                                                       imageIndex,
                                                                                                                                         const VkExtent3D&                                                      imageExtent,
                                                                                                                                         VkFormat                                                                       imageFormat,
                                                                                                                                         const std::vector<VkDescriptorBufferInfo>&     bufferInfos,
                                                                                                                                         const ut::BufferHandleAllocSp&                         buffer,
                                                                                                                                         deUint32                                                                       mipLevel) const
{
        DE_ASSERT(bufferInfos[imageIndex].buffer == *buffer.get()->buffer);
        DE_ASSERT(ut::computeImageSize(imageExtent, imageFormat, true, (mipLevel ? ut::maxDeUint32 : 0)) <= bufferInfos[imageIndex].range);
        DE_ASSERT(imageExtent.width             >> mipLevel);
        DE_ASSERT(imageExtent.height    >> mipLevel);

        deUint32 mipOffset = 0;

        for (deUint32 level = 0; mipLevel && level < mipLevel; ++level)
        {
                mipOffset += ut::computeImageSize(imageExtent, imageFormat, true, level);
        }

        unsigned char* hostPtr  = static_cast<unsigned char*>(buffer->alloc->getHostPtr());
        unsigned char* data = hostPtr + bufferInfos[imageIndex].offset + mipOffset;
        return tcu::PixelBufferAccess(vk::mapVkFormat(imageFormat), (imageExtent.width >> mipLevel), (imageExtent.height >> mipLevel), imageExtent.depth, data);
}

void CommonDescriptorInstance::updateDescriptors                                        (IterateCommonVariables&                                        variables)
{
        const std::vector<deUint32>     primes = ut::generatePrimes(variables.availableDescriptorCount);
        const deUint32                          primeCount = static_cast<deUint32>(primes.size());

        for (deUint32 primeIdx = 0; primeIdx < primeCount; ++primeIdx)
        {
                const VkDescriptorBufferInfo*   pBufferInfo                     = DE_NULL;
                const VkDescriptorImageInfo*    pImageInfo                      = DE_NULL;
                const VkBufferView*                             pTexelBufferView        = DE_NULL;

                VkDescriptorImageInfo           imageInfo =
                {
                        static_cast<VkSampler>(0),
                        static_cast<VkImageView>(0),
                        VK_IMAGE_LAYOUT_GENERAL
                };

                switch (m_testParams.descriptorType)
                {
                case VK_DESCRIPTOR_TYPE_STORAGE_BUFFER:
                case VK_DESCRIPTOR_TYPE_STORAGE_BUFFER_DYNAMIC:
                case VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER:
                case VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER_DYNAMIC:
                case VK_DESCRIPTOR_TYPE_STORAGE_TEXEL_BUFFER:
                case VK_DESCRIPTOR_TYPE_UNIFORM_TEXEL_BUFFER:
                        {
                                pBufferInfo = &variables.descriptorsBufferInfos[primeIdx];
                                switch (m_testParams.descriptorType)
                                {
                                case VK_DESCRIPTOR_TYPE_STORAGE_TEXEL_BUFFER:
                                case VK_DESCRIPTOR_TYPE_UNIFORM_TEXEL_BUFFER:
                                        pTexelBufferView = &(**variables.descriptorsBufferViews[primeIdx]);
                                        break;
                                default:
                                        break;
                                }
                        }
                        break;

                case VK_DESCRIPTOR_TYPE_SAMPLER:
                        imageInfo.sampler = **variables.descriptorSamplers[primeIdx];
                        pImageInfo = &imageInfo;
                        break;

                case VK_DESCRIPTOR_TYPE_SAMPLED_IMAGE:
                case VK_DESCRIPTOR_TYPE_STORAGE_IMAGE:
                case VK_DESCRIPTOR_TYPE_INPUT_ATTACHMENT:
                        imageInfo.imageView = **variables.descriptorImageViews[primeIdx];
                        pImageInfo = &imageInfo;
                        break;

                default:        break;
                }

                const VkWriteDescriptorSet writeInfo =
                {
                        VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET,                 // sType
                        DE_NULL,                                                                                // pNext
                        *variables.descriptorSet,                                               // descriptorSet
                        m_testParams.descriptorBinding,                                 // descriptorBinding;
                        primes[primeIdx],                                                               // elementIndex
                        1u,                                                                                             // descriptorCount
                        m_testParams.descriptorType,                                    // descriptorType
                        pImageInfo,                                                                             // pImageInfo
                        pBufferInfo,                                                                    // pBufferInfo
                        pTexelBufferView                                                                // pTexelBufferView
                };

                m_vki.updateDescriptorSets(m_vkd, 1u, &writeInfo, 0u, DE_NULL);
        }
}

void CommonDescriptorInstance::iterateCommandSetup                                      (IterateCommonVariables&                                        variables)
{
        variables.dataAlignment                         = 0;

        variables.renderArea.offset.x           = 0;
        variables.renderArea.offset.y           = 0;
        variables.renderArea.extent.width       = m_testParams.frameResolution.width;
        variables.renderArea.extent.height      = m_testParams.frameResolution.height;

        variables.vertexCount                           = m_testParams.frameResolution.width * m_testParams.frameResolution.height;

        variables.lowerBound                            = 0;
        variables.upperBound                            = variables.vertexCount;

        variables.descriptorSetLayout           = createDescriptorSetLayout(variables.availableDescriptorCount);
        variables.validDescriptorCount          = ut::computePrimeCount(variables.availableDescriptorCount);
        variables.descriptorPool                        = createDescriptorPool(variables.availableDescriptorCount);
        variables.descriptorSet                         = createDescriptorSet(*variables.descriptorPool, *variables.descriptorSetLayout);

        std::vector<VkDescriptorSetLayout>      descriptorSetLayouts;
        descriptorSetLayouts.push_back(*variables.descriptorSetLayout);
        if (m_testParams.calculateInLoop)
        {
                variables.descriptorEnumerator.init(m_context, variables.vertexCount, variables.availableDescriptorCount);
                descriptorSetLayouts.push_back(*variables.descriptorEnumerator.descriptorSetLayout);
        }

        variables.pipelineLayout                        = createPipelineLayout(descriptorSetLayouts);

        createAndPopulateDescriptors            (variables);

        variables.renderPass                            = createRenderPass(variables);
        variables.pipeline                                      = createPipeline(*variables.pipelineLayout, *variables.renderPass);

        variables.commandBuffer                         = createCmdBuffer();

        if ((m_testParams.stageFlags & VK_SHADER_STAGE_VERTEX_BIT) || (m_testParams.stageFlags & VK_SHADER_STAGE_FRAGMENT_BIT))
        {
                createVertexAttributeBuffer             (variables.vertexAttributesBuffer, variables.availableDescriptorCount);
                createFramebuffer                               (variables.frameBuffer, *variables.renderPass, variables);
        }

        if (m_testParams.calculateInLoop)
        {
                variables.descriptorEnumerator.update(m_context);
        }

        if (!m_testParams.updateAfterBind)
        {
                updateDescriptors                               (variables);
        }

}

void CommonDescriptorInstance::iterateCommandBegin                                      (IterateCommonVariables&                                        variables,      bool firstPass)
{
        vk::beginCommandBuffer                          (m_vki, *variables.commandBuffer);

        // Clear color attachment, and transition it to VK_IMAGE_LAYOUT_COLOR_ATTACHMENT_OPTIMAL
        if ((m_testParams.stageFlags & VK_SHADER_STAGE_VERTEX_BIT) || (m_testParams.stageFlags & VK_SHADER_STAGE_FRAGMENT_BIT))
        {
                const VkImageMemoryBarrier preImageBarrier =
                {
                        VK_STRUCTURE_TYPE_IMAGE_MEMORY_BARRIER,                         // VkStructureType              sType
                        DE_NULL,                                                                                        // const void*                  pNext
                        0u,                                                                                                     // VkAccessFlags                srcAccessMask
                        VK_ACCESS_TRANSFER_WRITE_BIT,                                           // VkAccessFlags                dstAccessMask
                        VK_IMAGE_LAYOUT_UNDEFINED,                                                      // VkImageLayout                oldLayout
                        VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL,                           // VkImageLayout                newLayout
                        VK_QUEUE_FAMILY_IGNORED,                                                        // uint32_t                             srcQueueFamilyIndex
                        VK_QUEUE_FAMILY_IGNORED,                                                        // uint32_t                             dstQueueFamilyIndex
                        *variables.frameBuffer->image->image,                           // VkImage                              image
                        {
                                VK_IMAGE_ASPECT_COLOR_BIT,                              // VkImageAspectFlags   aspectMask
                                0u,                                                                             // uint32_t                             baseMipLevel
                                VK_REMAINING_MIP_LEVELS,                                // uint32_t                             mipLevels,
                                0u,                                                                             // uint32_t                             baseArray
                                VK_REMAINING_ARRAY_LAYERS,                              // uint32_t                             arraySize
                        }
                };

                m_vki.cmdPipelineBarrier(*variables.commandBuffer, VK_PIPELINE_STAGE_BOTTOM_OF_PIPE_BIT, VK_PIPELINE_STAGE_TRANSFER_BIT,
                                                                (VkDependencyFlags)0,
                                                                0, (const VkMemoryBarrier*)DE_NULL,
                                                                0, (const VkBufferMemoryBarrier*)DE_NULL,
                                                                1, &preImageBarrier);

                const VkClearColorValue clearColorValue         = makeClearValueColor(m_clearColor).color;

                if (firstPass)
                        m_vki.cmdClearColorImage(*variables.commandBuffer, *variables.frameBuffer->image->image, VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL, &clearColorValue, 1, &preImageBarrier.subresourceRange);

                const VkImageMemoryBarrier postImageBarrier =
                {
                        VK_STRUCTURE_TYPE_IMAGE_MEMORY_BARRIER,                         // VkStructureType              sType
                        DE_NULL,                                                                                        // const void*                  pNext
                        VK_ACCESS_TRANSFER_WRITE_BIT,                                           // VkAccessFlags                srcAccessMask
                        VK_ACCESS_COLOR_ATTACHMENT_WRITE_BIT,                           // VkAccessFlags                dstAccessMask
                        VK_IMAGE_LAYOUT_TRANSFER_DST_OPTIMAL,                           // VkImageLayout                oldLayout
                        VK_IMAGE_LAYOUT_COLOR_ATTACHMENT_OPTIMAL,                       // VkImageLayout                newLayout
                        VK_QUEUE_FAMILY_IGNORED,                                                        // uint32_t                             srcQueueFamilyIndex
                        VK_QUEUE_FAMILY_IGNORED,                                                        // uint32_t                             dstQueueFamilyIndex
                        *variables.frameBuffer->image->image,                           // VkImage                              image
                        {
                                VK_IMAGE_ASPECT_COLOR_BIT,                              // VkImageAspectFlags   aspectMask
                                0u,                                                                             // uint32_t                             baseMipLevel
                                VK_REMAINING_MIP_LEVELS,                                // uint32_t                             mipLevels,
                                0u,                                                                             // uint32_t                             baseArray
                                VK_REMAINING_ARRAY_LAYERS,                              // uint32_t                             arraySize
                        }
                };

                m_vki.cmdPipelineBarrier(*variables.commandBuffer, VK_PIPELINE_STAGE_TRANSFER_BIT, VK_PIPELINE_STAGE_COLOR_ATTACHMENT_OUTPUT_BIT,
                                                                (VkDependencyFlags)0,
                                                                0, (const VkMemoryBarrier*)DE_NULL,
                                                                0, (const VkBufferMemoryBarrier*)DE_NULL,
                                                                1, &postImageBarrier);

        }

        if (m_testParams.calculateInLoop)
        {
                deRandom rnd;
                deRandom_init(&rnd, static_cast<deUint32>(m_testParams.descriptorType));
                const deUint32 quarter = variables.vertexCount / 4;

                variables.lowerBound                    = deRandom_getUint32(&rnd) % quarter;
                variables.upperBound                    = (deRandom_getUint32(&rnd) % quarter) + (3 * quarter);

                const push_constant pc =
                {
                        static_cast<deInt32>(variables.lowerBound),
                        static_cast<deInt32>(variables.upperBound)
                };

                m_vki.cmdPushConstants(*variables.commandBuffer, *variables.pipelineLayout, m_testParams.stageFlags, 0u, static_cast<deUint32>(sizeof(pc)), &pc);
        }

        if ((m_testParams.stageFlags & VK_SHADER_STAGE_VERTEX_BIT) || (m_testParams.stageFlags & VK_SHADER_STAGE_FRAGMENT_BIT))
        {
                commandBindVertexAttributes             (*variables.commandBuffer, variables.vertexAttributesBuffer);
        }

        if (m_testParams.calculateInLoop)
        {
                commandBindDescriptorSets(*variables.commandBuffer, *variables.pipelineLayout, *variables.descriptorEnumerator.descriptorSet, 1);
        }

        if (!ut::isDynamicDescriptor(m_testParams.descriptorType))
        {
                commandBindDescriptorSets               (*variables.commandBuffer, *variables.pipelineLayout, *variables.descriptorSet, 0);
        }

        commandBindPipeline                                     (*variables.commandBuffer, *variables.pipeline);
}

tcu::TestStatus CommonDescriptorInstance::iterate                                       (void)
{
        IterateCommonVariables  v;
        ut::UpdatablePixelBufferAccessPtr       programResult;
        ut::UpdatablePixelBufferAccessPtr       referenceResult;

        bool firstPass = true;

        iterateCommandSetup             (v);

        v.renderArea.extent.width       = m_testParams.frameResolution.width/4;
        v.renderArea.extent.height      = m_testParams.frameResolution.height/4;

        for (int x = 0; x < 4; x++)
                for (int y= 0; y < 4; y++)
                {
                        iterateCommandBegin             (v, firstPass);

                        if (true == firstPass && true == m_testParams.copyBuffersToImages)
                        {
                                copyBuffersToImages     (v);
                        }

                        firstPass = false;

                        if (true == m_testParams.updateAfterBind)
                        {
                                updateDescriptors       (v);
                        }

                        v.renderArea.offset.x           = x * m_testParams.frameResolution.width/4;
                        v.renderArea.offset.y           = y * m_testParams.frameResolution.height/4;

                        vk::VkRect2D scissor = makeRect2D(v.renderArea.offset.x, v.renderArea.offset.y, v.renderArea.extent.width, v.renderArea.extent.height);
                        m_vki.cmdSetScissor(*v.commandBuffer, 0u, 1u, &scissor);

                        vk::beginRenderPass             (m_vki, *v.commandBuffer, *v.renderPass, *v.frameBuffer->buffer, v.renderArea, m_clearColor);
                        m_vki.cmdDraw                   (*v.commandBuffer, v.vertexCount, 1u, 0u, 0u);
                        vk::endRenderPass               (m_vki, *v.commandBuffer);

                        iterateCommandEnd(v, programResult, referenceResult);
                }

        return ( iterateVerifyResults(v, programResult, referenceResult) ? tcu::TestStatus::pass : tcu::TestStatus::fail)("");
}

std::vector<float> CommonDescriptorInstance::createColorScheme          (void)
{
        std::vector<float> cs;
        int divider = 2;
        for (int i = 0; i < 10; ++i)
        {
                cs.push_back(1.0f / float(divider));
                divider *= 2;
        }
        return cs;
}

void CommonDescriptorInstance::iterateCommandEnd                                        (IterateCommonVariables&                                        variables,
                                                                                                                                         ut::UpdatablePixelBufferAccessPtr&     programResult,
                                                                                                                                         ut::UpdatablePixelBufferAccessPtr&     referenceResult,
                                                                                                                                         bool                                                                           collectBeforeSubmit)
{
        if (collectBeforeSubmit)
        {
                iterateCollectResults(programResult, variables, true);
                iterateCollectResults(referenceResult, variables, false);
        }

        VK_CHECK(m_vki.endCommandBuffer(*variables.commandBuffer));
        Move<VkFence> fence = commandSubmit(*variables.commandBuffer);
        m_vki.waitForFences(m_vkd, 1, &(*fence), DE_TRUE, ~0ull);

        if (false == collectBeforeSubmit)
        {
                iterateCollectResults(programResult, variables, true);
                iterateCollectResults(referenceResult, variables, false);
        }
}

bool CommonDescriptorInstance::iterateVerifyResults                     (IterateCommonVariables&                                        variables,
                                                                                                                                         ut::UpdatablePixelBufferAccessPtr      programResult,
                                                                                                                                         ut::UpdatablePixelBufferAccessPtr      referenceResult)
{
        bool result = false;
        if (m_testParams.fuzzyComparison)
        {
                result = tcu::fuzzyCompare(m_context.getTestContext().getLog(),
                        "Fuzzy Compare", "Comparison result", *referenceResult.get(), *programResult.get(), 0.02f, tcu::COMPARE_LOG_EVERYTHING);
        }
        else
        {
                result = tcu::floatThresholdCompare(m_context.getTestContext().getLog(),
                        "Float Threshold Compare", "Comparison result", *referenceResult.get(), *programResult.get(), tcu::Vec4(0.02f, 0.02f, 0.02f, 0.02f), tcu::COMPARE_LOG_EVERYTHING);
        }

        if (m_testParams.allowVertexStoring)
        {
                result = verifyVertexWriteResults(variables);
        }

        return result;
}

void CommonDescriptorInstance::iterateCollectResults                            (ut::UpdatablePixelBufferAccessPtr&                     result,
                                                                                                                                         const IterateCommonVariables&                          variables,
                                                                                                                                         bool                                                                           fromTest)
{
        if (fromTest)
        {
                result = commandReadFrameBuffer(*variables.commandBuffer, variables.frameBuffer);
        }
        else
        {
                result = ut::UpdatablePixelBufferAccessPtr(new ut::PixelBufferAccessAllocation(vk::mapVkFormat(m_colorFormat), m_testParams.frameResolution));

                for (deUint32 y = 0, pixelNum = 0; y < m_testParams.frameResolution.height; ++y)
                {
                        for (deUint32 x = 0; x < m_testParams.frameResolution.width; ++x, ++pixelNum)
                        {
                                const float component = m_colorScheme[(pixelNum % variables.validDescriptorCount) % m_schemeSize];
                                result->setPixel(tcu::Vec4(component, component, component, 1.0f), x, y);
                        }
                }
        }
}

Move<VkCommandBuffer> CommonDescriptorInstance::createCmdBuffer         (void)
{
        return vk::allocateCommandBuffer(m_vki, m_vkd, *m_commandPool, VK_COMMAND_BUFFER_LEVEL_PRIMARY);
}

Move<VkFence> CommonDescriptorInstance::commandSubmit                           (VkCommandBuffer                                                        cmd)
{
        Move<VkFence>   fence(vk::createFence(m_vki, m_vkd));

        const VkSubmitInfo      submitInfo =
        {
                VK_STRUCTURE_TYPE_SUBMIT_INFO,                                          // sType
                DE_NULL,                                                                                        // pNext
                0u,                                                                                                     // waitSemaphoreCount
                static_cast<VkSemaphore*>(DE_NULL),                                     // pWaitSemaphores
                static_cast<const VkPipelineStageFlags*>(DE_NULL),      // pWaitDstStageMask
                1u,                                                                                                     // commandBufferCount
                &cmd,                                                                                           // pCommandBuffers
                0u,                                                                                                     // signalSemaphoreCount
                static_cast<VkSemaphore*>(DE_NULL)                                      // pSignalSemaphores
        };

        VK_CHECK(m_vki.queueSubmit(m_queue, 1u, &submitInfo, *fence));

        return fence;
}

bool CommonDescriptorInstance::verifyVertexWriteResults(IterateCommonVariables&                                 variables)
{
        DE_UNREF(variables);
        return true;
}

void CommonDescriptorInstance::commandBindPipeline                                      (VkCommandBuffer                                                        commandBuffer,
                                                                                                                                         VkPipeline                                                                     pipeline)
{
        const VkPipelineBindPoint pipelineBindingPoint = (m_testParams.stageFlags & VK_SHADER_STAGE_COMPUTE_BIT) ? VK_PIPELINE_BIND_POINT_COMPUTE : VK_PIPELINE_BIND_POINT_GRAPHICS;
        m_vki.cmdBindPipeline(commandBuffer, pipelineBindingPoint, pipeline);
}

void CommonDescriptorInstance::commandBindVertexAttributes                      (VkCommandBuffer                                                        commandBuffer,
                                                                                                                                         const ut::BufferHandleAllocSp&                         vertexAttributesBuffer)
{
        const VkDeviceSize      offsets[] = { 0u };
        const VkBuffer          buffers[] = { *vertexAttributesBuffer->buffer };
        m_vki.cmdBindVertexBuffers(commandBuffer, 0u, 1u, buffers, offsets);
}

void CommonDescriptorInstance::commandBindDescriptorSets                        (VkCommandBuffer                                                        commandBuffer,
                                                                                                                                         VkPipelineLayout                                                       pipelineLayout,
                                                                                                                                         VkDescriptorSet                                                        descriptorSet,
                                                                                                                                         deUint32                                                                       descriptorSetIndex)
{
        const VkPipelineBindPoint pipelineBindingPoint = (m_testParams.stageFlags & VK_SHADER_STAGE_COMPUTE_BIT) ? VK_PIPELINE_BIND_POINT_COMPUTE : VK_PIPELINE_BIND_POINT_GRAPHICS;
        m_vki.cmdBindDescriptorSets(commandBuffer, pipelineBindingPoint, pipelineLayout, descriptorSetIndex, 1u, &descriptorSet, 0u, static_cast<deUint32*>(DE_NULL));
}

ut::UpdatablePixelBufferAccessPtr
CommonDescriptorInstance::commandReadFrameBuffer                                        (VkCommandBuffer                                                        commandBuffer,
                                                                                                                                         const ut::FrameBufferSp&                                       frameBuffer)
{
        ut::BufferHandleAllocSp frameBufferContent;
        commandReadFrameBuffer(frameBufferContent, commandBuffer, frameBuffer);
        return ut::UpdatablePixelBufferAccessPtr(new ut::PixelBufferAccessBuffer(
                m_vkd, m_vki, vk::mapVkFormat(m_colorFormat), m_testParams.frameResolution,
                de::SharedPtr< Move<VkBuffer> >(new Move<VkBuffer>(frameBufferContent->buffer)),
                de::SharedPtr< de::MovePtr<Allocation> >(new de::MovePtr<Allocation>(frameBufferContent->alloc))));
}

void CommonDescriptorInstance::commandReadFrameBuffer                           (ut::BufferHandleAllocSp&                                       content,
                                                                                                                                         VkCommandBuffer                                                        commandBuffer,
                                                                                                                                         const ut::FrameBufferSp&                                       frameBuffer)
{
        Move<VkBuffer>                  buffer;
        de::MovePtr<Allocation> allocation;

        const VkDeviceSize bufferSize = ut::computeImageSize(frameBuffer->image);

        // create a buffer and an host allocation for it
        {
                const VkBufferCreateInfo bufferCreateInfo =
                {
                        VK_STRUCTURE_TYPE_BUFFER_CREATE_INFO,           // sType
                        DE_NULL,                                                                        // pNext
                        0u,                                                                                     // flags
                        bufferSize,                                                                     // size
                        VK_BUFFER_USAGE_TRANSFER_DST_BIT,                       // usage
                        VK_SHARING_MODE_EXCLUSIVE,                                      // sharingMode
                        1u,                                                                                     // queueFamilyIndexCoun
                        &m_queueFamilyIndex                                                     // pQueueFamilyIndices
                };

                buffer = vk::createBuffer(m_vki, m_vkd, &bufferCreateInfo);
                const VkMemoryRequirements      memRequirements(vk::getBufferMemoryRequirements(m_vki, m_vkd, *buffer));
                allocation = m_allocator.allocate(memRequirements, MemoryRequirement::HostVisible);

                VK_CHECK(m_vki.bindBufferMemory(m_vkd, *buffer, allocation->getMemory(), allocation->getOffset()));
        }

        const VkImage& image = *frameBuffer->image->image;

        VkImageSubresourceRange         subresourceRange =
        {
                VK_IMAGE_ASPECT_COLOR_BIT,                                      // aspectMask
                0u,                                                                                     // baseMipLevel
                1u,                                                                                     // levelCount
                0u,                                                                                     // baseArrayLayer
                1u                                                                                      // layerCount
        };

        const VkImageMemoryBarrier      barrierBefore =
        {
                VK_STRUCTURE_TYPE_IMAGE_MEMORY_BARRIER,         // sType;
                DE_NULL,                                                                        // pNext;
                VK_ACCESS_COLOR_ATTACHMENT_WRITE_BIT,           // srcAccessMask;
                VK_ACCESS_TRANSFER_READ_BIT,                            // dstAccessMask;
                VK_IMAGE_LAYOUT_COLOR_ATTACHMENT_OPTIMAL,       // oldLayout
                VK_IMAGE_LAYOUT_TRANSFER_SRC_OPTIMAL,           // newLayout;
                VK_QUEUE_FAMILY_IGNORED,                                        // srcQueueFamilyIndex;
                VK_QUEUE_FAMILY_IGNORED,                                        // dstQueueFamilyIndex;
                image,                                                                          // image;
                subresourceRange                                                        // subresourceRange;
        };

        const VkBufferImageCopy         copyRegion =
        {
                0u,                                                                                     // bufferOffset
                frameBuffer->image->extent.width,                               // bufferRowLength
                frameBuffer->image->extent.height,                      // bufferImageHeight
                {                                                                                       // VkImageSubresourceLayers
                        VK_IMAGE_ASPECT_COLOR_BIT,                              // aspect
                        0u,                                                                             // mipLevel
                        0u,                                                                             // baseArrayLayer
                        1u,                                                                             // layerCount
                },
                { 0, 0, 0 },                                                            // imageOffset
                frameBuffer->image->extent                                      // imageExtent
        };

        const VkBufferMemoryBarrier     bufferBarrier =
        {
                VK_STRUCTURE_TYPE_BUFFER_MEMORY_BARRIER,        // sType;
                DE_NULL,                                                                        // pNext;
                VK_ACCESS_TRANSFER_WRITE_BIT,                           // srcAccessMask;
                VK_ACCESS_HOST_READ_BIT,                                        // dstAccessMask;
                VK_QUEUE_FAMILY_IGNORED,                                        // srcQueueFamilyIndex;
                VK_QUEUE_FAMILY_IGNORED,                                        // dstQueueFamilyIndex;
                *buffer,                                                                        // buffer;
                0u,                                                                                     // offset;
                bufferSize                                                                      // size;
        };

        const VkImageMemoryBarrier      barrierAfter =
        {
                VK_STRUCTURE_TYPE_IMAGE_MEMORY_BARRIER,                 // sType;
                DE_NULL,                                                                                // pNext;
                VK_ACCESS_TRANSFER_READ_BIT,                                    // srcAccessMask;
                VK_ACCESS_COLOR_ATTACHMENT_WRITE_BIT,                   // dstAccessMask;
                VK_IMAGE_LAYOUT_TRANSFER_SRC_OPTIMAL,                   // oldLayout;
                VK_IMAGE_LAYOUT_COLOR_ATTACHMENT_OPTIMAL,               // newLayout;
                VK_QUEUE_FAMILY_IGNORED,                                                // srcQueueFamilyIndex;
                VK_QUEUE_FAMILY_IGNORED,                                                // dstQueueFamilyIndex;
                image,                                                                                  // image
                subresourceRange                                                                // subresourceRange
        };


        m_vki.cmdPipelineBarrier(commandBuffer,                                                                                         // commandBuffer
                VK_PIPELINE_STAGE_COLOR_ATTACHMENT_OUTPUT_BIT, VK_PIPELINE_STAGE_TRANSFER_BIT,  // srcStageMask, dstStageMask
                (VkDependencyFlags)0,                                                                                                                   // dependencyFlags
                0u, DE_NULL,                                                                                                                                    // memoryBarrierCount, pMemoryBarriers
                0u, DE_NULL,                                                                                                                                    // bufferBarrierCount, pBufferBarriers
                1u, &barrierBefore);                                                                                                                            // imageBarrierCount, pImageBarriers

        m_vki.cmdCopyImageToBuffer(commandBuffer, image, VK_IMAGE_LAYOUT_TRANSFER_SRC_OPTIMAL, *buffer, 1u, &copyRegion);

        m_vki.cmdPipelineBarrier(commandBuffer,
                VK_PIPELINE_STAGE_TRANSFER_BIT, VK_PIPELINE_STAGE_HOST_BIT | VK_PIPELINE_STAGE_ALL_GRAPHICS_BIT,
                (VkDependencyFlags)0,
                0u, DE_NULL,
                1u, &bufferBarrier,
                1u, &barrierAfter);

        content = ut::BufferHandleAllocSp(new ut::BufferHandleAlloc(buffer, allocation));
}

std::string CommonDescriptorInstance::getColorAccess                            (VkDescriptorType                                                       descriptorType,
                                                                                                                                         const char*                                                            indexVariableName,
                                                                                                                                         bool                                                                           usesMipMaps)
{
        std::string text;
        std::map<std::string, std::string> vars;
        vars["INDEX"] = indexVariableName;

        switch (descriptorType)
        {
        case VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER:
        case VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER_DYNAMIC:
                text = "data[nonuniformEXT(${INDEX})].c";
                break;
        case VK_DESCRIPTOR_TYPE_STORAGE_BUFFER:
        case VK_DESCRIPTOR_TYPE_STORAGE_BUFFER_DYNAMIC:
                text = "data[nonuniformEXT(${INDEX})].cold";
                break;
        case VK_DESCRIPTOR_TYPE_INPUT_ATTACHMENT:
                text = "subpassLoad(data[nonuniformEXT(${INDEX})]).rgba";
                break;
        case VK_DESCRIPTOR_TYPE_UNIFORM_TEXEL_BUFFER:
                text = "texelFetch(data[nonuniformEXT(${INDEX})], 0)";
                break;
        case VK_DESCRIPTOR_TYPE_STORAGE_TEXEL_BUFFER:
                text = "imageLoad(data[nonuniformEXT(${INDEX})], 0)";
                break;
        case VK_DESCRIPTOR_TYPE_SAMPLER:
                text = usesMipMaps
                        ? "textureLod(sampler2D(tex[0], data[nonuniformEXT(${INDEX})]), normalpos, 1)"
                        : "texture(   sampler2D(tex[0], data[nonuniformEXT(${INDEX})]), normalpos   )";
                break;
        case VK_DESCRIPTOR_TYPE_SAMPLED_IMAGE:
                text = usesMipMaps
                        ? "textureLod( sampler2D(data[nonuniformEXT(${INDEX})], samp[0]), vec2(0,0), textureQueryLevels(sampler2D(data[nonuniformEXT(${INDEX})], samp[0]))-1)"
                        : "texture(    sampler2D(data[nonuniformEXT(${INDEX})], samp[0]), vec2(0,0)   )";
                break;
        case VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER:
                text = usesMipMaps
                        ? "textureLod( data[nonuniformEXT(${INDEX})], uvec2(0,0), textureQueryLevels(data[nonuniformEXT(${INDEX})])-1)"
                        : "texture(    data[nonuniformEXT(${INDEX})], uvec2(0,0)   )";
                break;
        default:
                TCU_THROW(InternalError, "Not implemented descriptor type");
        }

        return tcu::StringTemplate(text).specialize(vars);
}

std::string CommonDescriptorInstance::getFragmentReturnSource           (const std::string&                                                     colorAccess)
{
        return "  FragColor = " + colorAccess + ";\n";
}

std::string CommonDescriptorInstance::getFragmentLoopSource                     (const std::string&                                                     colorAccess1,
                                                                                                                                         const std::string&                                                     colorAccess2)
{
        std::map < std::string, std::string > vars;
        vars["COLOR_ACCESS_1"] = colorAccess1;
        vars["COLOR_ACCESS_2"] = colorAccess2;

        const char* s =
                "  vec4 sumClr1 = vec4(0,0,0,0);                \n"
                "  vec4 sumClr2 = vec4(0,0,0,0);                \n"
                "  for (int i = pc.lowerBound; i < pc.upperBound; ++i)  \n"
                "  {\n"
                "    int loopIdx = texelFetch(iter, i).x;                               \n"
                "    sumClr1 += ${COLOR_ACCESS_2} + ${COLOR_ACCESS_1};  \n"
                "    sumClr2 += ${COLOR_ACCESS_2};                                              \n"
                "  }\n"
                "  FragColor = vec4(((sumClr1 - sumClr2) / float(pc.upperBound - pc.lowerBound)).rgb, 1);       \n";

        return tcu::StringTemplate(s).specialize(vars);
}

bool CommonDescriptorInstance::performWritesInVertex                            (VkDescriptorType                                                       descriptorType)
{
        bool result = false;

        switch (descriptorType)
        {
        case VK_DESCRIPTOR_TYPE_STORAGE_BUFFER:
        case VK_DESCRIPTOR_TYPE_STORAGE_BUFFER_DYNAMIC:
        case VK_DESCRIPTOR_TYPE_STORAGE_TEXEL_BUFFER:
                result = true;
                break;
        default:
                result = false;
                break;
        }

        return result;
}

bool CommonDescriptorInstance::performWritesInVertex                            (VkDescriptorType                                                       descriptorType,
                                                                                                                                        const Context&                                                          context)
{
        bool result = false;

        ut::DeviceProperties                    dp              (context);
        const VkPhysicalDeviceFeatures& feats   = dp.physicalDeviceFeatures();

        if (feats.vertexPipelineStoresAndAtomics != DE_FALSE)
        {
                result = CommonDescriptorInstance::performWritesInVertex(descriptorType);
        }

        return result;
}

std::string CommonDescriptorInstance::getShaderSource                           (VkShaderStageFlagBits                                          shaderType,
                                                                                                                                         const TestCaseParams&                                          testCaseParams,
                                                                                                                                         bool                                                                           allowVertexStoring)
{
        std::stringstream       s;

        s << glu::getGLSLVersionDeclaration(glu::GLSL_VERSION_450) << '\n';
        s << "#extension GL_EXT_nonuniform_qualifier : require  \n";

        if (testCaseParams.calculateInLoop)
        {
                s << "layout(push_constant)     uniform Block { int lowerBound, upperBound; } pc;\n";
                s << substBinding(BINDING_DescriptorEnumerator,
                        "layout(set=1,binding=${?}) uniform isamplerBuffer iter;        \n");
        }

        switch (testCaseParams.descriptorType)
        {
                case VK_DESCRIPTOR_TYPE_STORAGE_BUFFER:
                        s << substBinding(BINDING_StorageBuffer,
                                "layout(set=0,binding=${?}) buffer Data { vec4 cnew, cold; } data[]; \n");
                        break;
                case VK_DESCRIPTOR_TYPE_STORAGE_BUFFER_DYNAMIC:
                        s << substBinding(BINDING_StorageBufferDynamic,
                                "layout(set=0,binding=${?}) buffer Data { vec4 cnew, cold; } data[]; \n");
                        break;
                case VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER:
                        s << substBinding(BINDING_UniformBuffer,
                                "layout(set=0,binding=${?}) uniform Data { vec4 c; } data[]; \n");
                        break;
                case VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER_DYNAMIC:
                        s << substBinding(BINDING_UniformBufferDynamic,
                                "layout(set=0,binding=${?}) uniform Data { vec4 c; } data[]; \n");
                        break;
                case VK_DESCRIPTOR_TYPE_STORAGE_TEXEL_BUFFER:
                        s << substBinding(BINDING_StorageTexelBuffer,
                                "layout(set=0,binding=${?},rgba32f) uniform imageBuffer data[];\n");
                        break;
                case VK_DESCRIPTOR_TYPE_UNIFORM_TEXEL_BUFFER:
                        s << "#extension GL_EXT_texture_buffer : require        \n";
                        s << substBinding(BINDING_UniformTexelBuffer,
                                "layout(set=0,binding=${?}) uniform samplerBuffer data[];\n");
                        break;
                case VK_DESCRIPTOR_TYPE_INPUT_ATTACHMENT:
                        // Left for the consistent of code.
                        // Header is set one swicth below
                        break;
                case VK_DESCRIPTOR_TYPE_SAMPLER:
                        s << "#extension GL_EXT_texture_buffer : require        \n";
                        s << substBinding(BINDING_SampledImage,
                                "layout(set=0,binding=${?}) uniform texture2D ${VAR}[${*}];\n", 1, "tex");
                        s << substBinding(BINDING_Sampler,
                                "layout(set=0,binding=${?}) uniform sampler ${VAR}[${*}];\n");
                        break;
                case VK_DESCRIPTOR_TYPE_SAMPLED_IMAGE:
                        s << "#extension GL_EXT_texture_buffer : require        \n";
                        s << substBinding(BINDING_Sampler,
                                "layout(set=0,binding=${?}) uniform sampler ${VAR}[${*}];\n", 1, "samp");
                        s << substBinding(BINDING_SampledImage,
                                "layout(set=0,binding=${?}) uniform texture2D ${VAR}[${*}];\n");
                        break;
                case VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER:
                        s << "#extension GL_EXT_texture_buffer : require        \n";
                        s << substBinding(BINDING_CombinedImageSampler,
                                "layout(set=0,binding=${?}) uniform sampler2D data[];\n");
                        break;
                case VK_DESCRIPTOR_TYPE_STORAGE_IMAGE:
                        s << "layout(local_size_x=1,local_size_y=1,local_size_z=1) in;  \n";
                        s << substBinding(BINDING_StorageImage + 1,
                                "layout(r32ui,set=0,binding=${?}) uniform uimage2D idxs;        \n");
                        s << substBinding(BINDING_StorageImage,
                                "layout(r32ui,set=0,binding=${?}) uniform uimage2D data[];      \n");
                        break;
                default:
                        TCU_THROW(InternalError, "Not implemented descriptor type");
        }

        switch (shaderType)
        {
                case VK_SHADER_STAGE_VERTEX_BIT:        s << getVertexShaderProlog();   break;
                case VK_SHADER_STAGE_FRAGMENT_BIT:
                        {
                                if (testCaseParams.descriptorType == VK_DESCRIPTOR_TYPE_INPUT_ATTACHMENT)
                                {
                                        s << substBinding(BINDING_InputAttachment,
                                                "layout(input_attachment_index=1,set=0,binding=${?}) uniform subpassInput data[];       \n");
                                }
                                s << getFragmentShaderProlog();
                        }
                        break;
                case VK_SHADER_STAGE_COMPUTE_BIT:
                        break;
                default:
                        TCU_THROW(InternalError, "Not implemented shader stage");
        }

        switch (shaderType)
        {
                case VK_SHADER_STAGE_VERTEX_BIT:
                {
                        switch (testCaseParams.descriptorType)
                        {
                        case VK_DESCRIPTOR_TYPE_STORAGE_BUFFER:
                        case VK_DESCRIPTOR_TYPE_STORAGE_BUFFER_DYNAMIC:
                                if (allowVertexStoring)
                                        s << "  if (gIndex != 0) data[nonuniformEXT(gIndex)].cnew = data[nonuniformEXT(rIndex)].cold;   \n";
                                break;
                        case VK_DESCRIPTOR_TYPE_STORAGE_TEXEL_BUFFER:
                                if (allowVertexStoring)
                                        s << "  if (gIndex != 0) imageStore(data[nonuniformEXT(gIndex)], 1, imageLoad(data[nonuniformEXT(rIndex)], 0)); \n";
                                break;
                        case VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER:
                        case VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER_DYNAMIC:
                        case VK_DESCRIPTOR_TYPE_UNIFORM_TEXEL_BUFFER:
                        case VK_DESCRIPTOR_TYPE_INPUT_ATTACHMENT:
                        case VK_DESCRIPTOR_TYPE_SAMPLER:
                        case VK_DESCRIPTOR_TYPE_SAMPLED_IMAGE:
                        case VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER:
                                break;

                        default:
                                TCU_THROW(InternalError, "Not implemented descriptor type");
                        }
                }
                break;

                case VK_SHADER_STAGE_FRAGMENT_BIT:
                {
                        switch (testCaseParams.descriptorType)
                        {
                        case VK_DESCRIPTOR_TYPE_STORAGE_BUFFER:
                        case VK_DESCRIPTOR_TYPE_STORAGE_BUFFER_DYNAMIC:
                        case VK_DESCRIPTOR_TYPE_STORAGE_TEXEL_BUFFER:
                                {
                                        if (testCaseParams.calculateInLoop)
                                                s << getFragmentLoopSource(
                                                        getColorAccess(testCaseParams.descriptorType, "rIndex", false),
                                                        getColorAccess(testCaseParams.descriptorType, "loopIdx", false));
                                        else
                                                s << getFragmentReturnSource(getColorAccess(testCaseParams.descriptorType, "rIndex", false));
                                }
                                break;
                        case VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER:
                        case VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER_DYNAMIC:
                        case VK_DESCRIPTOR_TYPE_INPUT_ATTACHMENT:
                        case VK_DESCRIPTOR_TYPE_UNIFORM_TEXEL_BUFFER:
                        case VK_DESCRIPTOR_TYPE_SAMPLER:
                        case VK_DESCRIPTOR_TYPE_SAMPLED_IMAGE:
                        case VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER:
                                if (testCaseParams.calculateInLoop)
                                        s << getFragmentLoopSource(
                                                getColorAccess(testCaseParams.descriptorType, "rIndex", testCaseParams.usesMipMaps),
                                                getColorAccess(testCaseParams.descriptorType, "loopIdx", testCaseParams.usesMipMaps));
                                else
                                        s << getFragmentReturnSource(getColorAccess(testCaseParams.descriptorType, "rIndex", testCaseParams.usesMipMaps));
                                break;
                        default:        TCU_THROW(InternalError, "Not implemented descriptor type");
                        }
                }
                break;

                case VK_SHADER_STAGE_COMPUTE_BIT: // VK_DESCRIPTOR_TYPE_STORAGE_IMAGE
                        s << "void main(void)\n{\n";
                        if (testCaseParams.calculateInLoop)
                                s << "  for (int i = pc.lowerBound; i < pc.upperBound; ++i)     \n"
                                        "    imageAtomicAdd(data[nonuniformEXT(texelFetch(iter, i).x)], ivec2(0, 0), 1);                        \n";
                        else
                                s << "  uvec4 c = imageLoad(idxs, ivec2(gl_WorkGroupID.x, gl_WorkGroupID.y));   \n"
                                        "  imageAtomicAdd( data[nonuniformEXT(c.r)], ivec2(0, 0), 1);                                                           \n";
                        break;

                default:        TCU_THROW(InternalError, "Not implemented shader stage");
        }

        s << getShaderEpilog();

        return s.str();
}

class StorageBufferInstance : virtual public CommonDescriptorInstance
{
public:
                                                                StorageBufferInstance                           (Context&                                                                       context,
                                                                                                                                         const TestCaseParams&                                          testCaseParams);
protected:
        virtual void                            createAndPopulateDescriptors            (IterateCommonVariables&                                        variables);

        virtual bool                            verifyVertexWriteResults                        (IterateCommonVariables&                                        variables);
};

StorageBufferInstance::StorageBufferInstance                                            (Context&                                                                       context,
                                                                                                                                         const TestCaseParams&                                          testCaseParams)
        : CommonDescriptorInstance(context,
                TestParams(VK_SHADER_STAGE_ALL_GRAPHICS,
                        VK_DESCRIPTOR_TYPE_STORAGE_BUFFER,
                        BINDING_StorageBuffer,
                        VK_DESCRIPTOR_TYPE_UNDEFINED,
                        BINDING_Undefined,
                        false,
                        performWritesInVertex(testCaseParams.descriptorType, context),
                        testCaseParams))
{
}

void StorageBufferInstance::createAndPopulateDescriptors                        (IterateCommonVariables&                                        variables)
{
        BindingStorageBuffer::Data      data;

        bool                                            vertexStores = false;
        {
                ut::DeviceProperties dp(m_context);
                vertexStores = dp.physicalDeviceFeatures().vertexPipelineStoresAndAtomics != DE_FALSE;
        }
        const deUint32                          alignment       = static_cast<deUint32>(ut::DeviceProperties(m_context).physicalDeviceProperties().limits.minStorageBufferOffsetAlignment);
        createBuffers(variables.descriptorsBufferInfos, variables.descriptorsBuffer, variables.validDescriptorCount, sizeof(data), alignment, VK_BUFFER_USAGE_STORAGE_BUFFER_BIT);

        unsigned char*                          buffer          = static_cast<unsigned char*>(variables.descriptorsBuffer->alloc->getHostPtr());
        for (deUint32 infoIdx = 0; infoIdx < variables.validDescriptorCount; ++infoIdx)
        {
                const float                             component       = m_colorScheme[infoIdx % m_schemeSize];
                const tcu::Vec4                 color           (component, component, component, 1.0f);
                VkDescriptorBufferInfo& info            = variables.descriptorsBufferInfos[infoIdx];
                data.cnew                                                       = vertexStores ? m_clearColor : color;
                data.cold                                                       = color;

                deMemcpy(buffer + info.offset, &data, sizeof(data));
        }
        vk::flushAlloc(m_vki, m_vkd, *variables.descriptorsBuffer->alloc);

        variables.dataAlignment = deAlign64(sizeof(data), alignment);
}

bool StorageBufferInstance::verifyVertexWriteResults                            (IterateCommonVariables&                                        variables)
{
        const tcu::Vec4                         threshold               (0.002f, 0.002f, 0.002f, 0.002f);
        const std::vector<deUint32>     primes                  = ut::generatePrimes(variables.availableDescriptorCount);

        unsigned char*                          buffer = static_cast<unsigned char*>(variables.descriptorsBuffer->alloc->getHostPtr());
        BindingStorageBuffer::Data      data;
        for (deUint32 primeIdx = 0; primeIdx < variables.validDescriptorCount; ++primeIdx)
        {
                const deUint32                  prime           = primes[primeIdx];
                const float                             component       = m_colorScheme[(prime % variables.validDescriptorCount) % m_schemeSize];
                const tcu::Vec4                 referenceValue(component, component, component, 1.0f);

                VkDescriptorBufferInfo& info = variables.descriptorsBufferInfos[primeIdx];
                deMemcpy(&data, buffer + info.offset, sizeof(data));
                const tcu::Vec4                 realValue = data.cnew;

                const tcu::Vec4                 diff = tcu::absDiff(referenceValue, realValue);
                if (!tcu::boolAll(tcu::lessThanEqual(diff, threshold)))
                        return false;
        }
        return true;
}

class UniformBufferInstance : virtual public CommonDescriptorInstance
{
public:
                                                                UniformBufferInstance                           (Context&                                                                       context,
                                                                                                                                         const TestCaseParams&                                          testCaseParams);
protected:
        virtual void                            createAndPopulateDescriptors            (IterateCommonVariables&                                        variables);
};

UniformBufferInstance::UniformBufferInstance                                            (Context&                                                                       context,
                                                                                                                                         const TestCaseParams&                                          testCaseParams)
        : CommonDescriptorInstance(context,
                TestParams(VK_SHADER_STAGE_ALL_GRAPHICS,
                        VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER,
                        BINDING_UniformBuffer,
                        VK_DESCRIPTOR_TYPE_UNDEFINED,
                        BINDING_Undefined,
                        false,
                        performWritesInVertex(testCaseParams.descriptorType, context),
                        testCaseParams))
{
}

void UniformBufferInstance::createAndPopulateDescriptors                        (IterateCommonVariables&                                        variables)
{
        BindingUniformBuffer::Data data;

        const deUint32                          alignment       = static_cast<deUint32>(ut::DeviceProperties(m_context).physicalDeviceProperties().limits.minUniformBufferOffsetAlignment);
        createBuffers(variables.descriptorsBufferInfos, variables.descriptorsBuffer, variables.validDescriptorCount, sizeof(data), alignment, VK_BUFFER_USAGE_UNIFORM_BUFFER_BIT);

        unsigned char*                          buffer          = static_cast<unsigned char*>(variables.descriptorsBuffer->alloc->getHostPtr());
        for (deUint32 infoIdx = 0; infoIdx < variables.validDescriptorCount; ++infoIdx)
        {
                const float                             component       = m_colorScheme[infoIdx % m_schemeSize];
                VkDescriptorBufferInfo& info            = variables.descriptorsBufferInfos[infoIdx];
                data.c                                                          = tcu::Vec4(component, component, component, 1.0f);
                deMemcpy(buffer + info.offset, &data, sizeof(data));
        }
        vk::flushAlloc(m_vki, m_vkd, *variables.descriptorsBuffer->alloc);

        variables.dataAlignment = deAlign64(sizeof(data), alignment);
}

class StorageTexelInstance : public CommonDescriptorInstance
{
public:
                                                                StorageTexelInstance                            (Context&                                                                       context,
                                                                                                                                         const TestCaseParams&                                          testCaseParams);
private:
        virtual void                            createAndPopulateDescriptors            (IterateCommonVariables&                                        variables);

        virtual bool                            verifyVertexWriteResults                        (IterateCommonVariables&                                        variables);
};

StorageTexelInstance::StorageTexelInstance                                                      (Context&                                                                       context,
                                                                                                                                         const TestCaseParams&                                          testCaseParams)
        : CommonDescriptorInstance(context,
                TestParams(VK_SHADER_STAGE_ALL_GRAPHICS,
                        VK_DESCRIPTOR_TYPE_STORAGE_TEXEL_BUFFER,
                        BINDING_StorageTexelBuffer,
                        VK_DESCRIPTOR_TYPE_UNDEFINED,
                        BINDING_Undefined,
                        false,
                        performWritesInVertex(testCaseParams.descriptorType, context),
                        testCaseParams))
{
}

void StorageTexelInstance::createAndPopulateDescriptors                 (IterateCommonVariables&                                        variables)
{
        const VkExtent3D                        imageExtent                     = { 4, 4, 1 };
        const deUint32                          imageSize                       = ut::computeImageSize(imageExtent, m_colorFormat);

        createBuffers(variables.descriptorsBufferInfos, variables.descriptorsBuffer, variables.validDescriptorCount, imageSize, sizeof(tcu::Vec4), VK_BUFFER_USAGE_STORAGE_TEXEL_BUFFER_BIT);
        createBuffersViews(variables.descriptorsBufferViews, variables.descriptorsBufferInfos, m_colorFormat);

        for (deUint32 imageIdx = 0; imageIdx < variables.validDescriptorCount; ++imageIdx)
        {
                const float                             component                       = m_colorScheme[imageIdx % m_schemeSize];
                const PixelBufferAccess pa                                      = getPixelAccess(imageIdx, imageExtent, m_colorFormat, variables.descriptorsBufferInfos, variables.descriptorsBuffer);

                tcu::clear(pa, m_clearColor);
                pa.setPixel(tcu::Vec4(component, component, component, 1.0f), 0, 0);
        }
        vk::flushAlloc(m_vki, m_vkd, *variables.descriptorsBuffer->alloc);
}

bool StorageTexelInstance::verifyVertexWriteResults(IterateCommonVariables&                                     variables)
{
        const VkExtent3D                        imageExtent             = { 4, 4, 1 };
        const tcu::Vec4                         threshold               (0.002f, 0.002f, 0.002f, 0.002f);
        const std::vector<deUint32>     primes                  = ut::generatePrimes(variables.availableDescriptorCount);

        for (deUint32 primeIdx = 0; primeIdx < variables.validDescriptorCount; ++primeIdx)
        {
                const deUint32                  prime           = primes[primeIdx];
                const float                             component       = m_colorScheme[( prime % variables.validDescriptorCount ) % m_schemeSize];
                const tcu::Vec4                 referenceValue(component, component, component, 1.0f);

                const PixelBufferAccess pa                      = getPixelAccess(primeIdx, imageExtent, m_colorFormat, variables.descriptorsBufferInfos, variables.descriptorsBuffer);
                const tcu::Vec4                 realValue       = pa.getPixel(1, 0);

                const tcu::Vec4                 diff            = tcu::absDiff(referenceValue, realValue);
                if (!tcu::boolAll(tcu::lessThanEqual(diff, threshold)))
                        return false;
        }
        return true;
}

class UniformTexelInstance : public CommonDescriptorInstance
{
public:
                                                                UniformTexelInstance                            (Context&                                                                       context,
                                                                                                                                         const TestCaseParams&                                          testCaseParams);
private:
        virtual void                            createAndPopulateDescriptors            (IterateCommonVariables&                                        variables);
};

UniformTexelInstance::UniformTexelInstance                                                      (Context&                                                                       context,
                                                                                                                                         const TestCaseParams&                                          testCaseParams)
        : CommonDescriptorInstance(context,
                TestParams(VK_SHADER_STAGE_ALL_GRAPHICS,
                        VK_DESCRIPTOR_TYPE_UNIFORM_TEXEL_BUFFER,
                        BINDING_UniformTexelBuffer,
                        VK_DESCRIPTOR_TYPE_UNDEFINED,
                        BINDING_Undefined,
                        false,
                        performWritesInVertex(testCaseParams.descriptorType, context),
                        testCaseParams))
{
}

void UniformTexelInstance::createAndPopulateDescriptors                         (IterateCommonVariables&                                        variables)
{
        const VkExtent3D                        imageExtent     = { 4, 4, 1 };
        const deUint32                          imageSize       = ut::computeImageSize(imageExtent, m_colorFormat);

        createBuffers(variables.descriptorsBufferInfos, variables.descriptorsBuffer, variables.validDescriptorCount, imageSize, sizeof(tcu::Vec4), VK_BUFFER_USAGE_UNIFORM_TEXEL_BUFFER_BIT);
        createBuffersViews(variables.descriptorsBufferViews, variables.descriptorsBufferInfos, m_colorFormat);

        for (deUint32 imageIdx = 0; imageIdx < variables.validDescriptorCount; ++imageIdx)
        {
                const float                             component       = m_colorScheme[imageIdx % m_schemeSize];
                const PixelBufferAccess pa                      = getPixelAccess(imageIdx, imageExtent, m_colorFormat, variables.descriptorsBufferInfos, variables.descriptorsBuffer);

                tcu::clear(pa, tcu::Vec4(component, component, component, 1.0f));
        }
        vk::flushAlloc(m_vki, m_vkd, *variables.descriptorsBuffer->alloc);
}

class DynamicBuffersInstance : virtual public CommonDescriptorInstance
{
public:
        DynamicBuffersInstance                                                                                  (Context&                                                                       context,
                                                                                                                                         const TestParams&                                                      testParams)
                : CommonDescriptorInstance(context, testParams) {}

protected:
        virtual tcu::TestStatus         iterate                                                         (void);
        virtual void                            updateDescriptors                                       (IterateCommonVariables&                                        variables);
};

void DynamicBuffersInstance::updateDescriptors                                          (IterateCommonVariables&                                        variables)
{
        DE_ASSERT(variables.dataAlignment);

        VkDescriptorBufferInfo  bufferInfo =
        {
                *variables.descriptorsBuffer.get()->buffer,
                0,      // always 0, it will be taken from pDynamicOffsets
                variables.dataAlignment
        };

        VkWriteDescriptorSet updateInfo =
        {
                VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET,                 // sType
                DE_NULL,                                                                                // pNext
                *variables.descriptorSet,                                               // descriptorSet
                m_testParams.descriptorBinding,                                 // descriptorBinding;
                0,      // to be set in below loop                                      // dstArrayElement
                1u,                                                                                             // descriptorCount
                m_testParams.descriptorType,                                    // descriptorType
                DE_NULL,                                                                                // pImageInfo
                &bufferInfo,                                                                    // pBufferInfo
                DE_NULL                                                                                 // pTexelBufferView
        };

        deUint32 descIdx = 0;
        const std::vector<deUint32> primes = ut::generatePrimes(variables.availableDescriptorCount);
        for (deUint32 validIdx = 0; validIdx < variables.validDescriptorCount; ++validIdx)
        {
                for (; descIdx < primes[validIdx]; ++descIdx)
                {
                        updateInfo.dstArrayElement                      = descIdx;
                        m_vki.updateDescriptorSets      (m_vkd, 1u, &updateInfo, 0u, DE_NULL);
                }

                updateInfo.dstArrayElement                              = primes[validIdx];
                m_vki.updateDescriptorSets              (m_vkd, 1u, &updateInfo, 0u, DE_NULL);

                ++descIdx;
        }
        for (; descIdx < variables.availableDescriptorCount; ++descIdx)
        {
                updateInfo.dstArrayElement = descIdx;
                m_vki.updateDescriptorSets(m_vkd, 1u, &updateInfo, 0u, DE_NULL);
        }
}

tcu::TestStatus DynamicBuffersInstance::iterate                                         (void)
{
        IterateCommonVariables  v;
        iterateCommandSetup             (v);

        ut::UpdatablePixelBufferAccessPtr       programResult;
        ut::UpdatablePixelBufferAccessPtr       referenceResult;
        bool firstPass = true;

        DE_ASSERT(v.dataAlignment);

        std::vector<deUint32> dynamicOffsets;

        deUint32 descIdx = 0;
        const std::vector<deUint32> primes = ut::generatePrimes(v.availableDescriptorCount);
        for (deUint32 validIdx = 0; validIdx < v.validDescriptorCount; ++validIdx)
        {
                for (; descIdx < primes[validIdx]; ++descIdx)
                {
                        dynamicOffsets.push_back(0);
                }

                dynamicOffsets.push_back(static_cast<deUint32>(validIdx * v.dataAlignment));

                ++descIdx;
        }
        for (; descIdx < v.availableDescriptorCount; ++descIdx)
        {
                dynamicOffsets.push_back(0);
        }

        // Unfortunatelly not lees and not more, only exactly
        DE_ASSERT(dynamicOffsets.size() == v.availableDescriptorCount);

        const VkDescriptorSet   descriptorSets[] = { *v.descriptorSet };

        v.renderArea.extent.width       = m_testParams.frameResolution.width/4;
        v.renderArea.extent.height      = m_testParams.frameResolution.height/4;

        for (int x = 0; x < 4; x++)
                for (int y= 0; y < 4; y++)
                {

                        v.renderArea.offset.x           = x * m_testParams.frameResolution.width/4;
                        v.renderArea.offset.y           = y * m_testParams.frameResolution.height/4;

                        iterateCommandBegin             (v, firstPass);
                        firstPass = false;

        m_vki.cmdBindDescriptorSets(
                *v.commandBuffer,                                               // commandBuffer
                VK_PIPELINE_BIND_POINT_GRAPHICS,                // pipelineBindPoint
                *v.pipelineLayout,                                              // layout
                0u,                                                                             // firstSet
                DE_LENGTH_OF_ARRAY(descriptorSets),             // descriptorSetCount
                descriptorSets,                                                 // pDescriptorSets
                v.availableDescriptorCount,                             // dynamicOffsetCount
                dynamicOffsets.data());                                 // pDynamicOffsets

                        vk::VkRect2D scissor = makeRect2D(v.renderArea.offset.x, v.renderArea.offset.y, v.renderArea.extent.width, v.renderArea.extent.height);
        m_vki.cmdSetScissor(*v.commandBuffer, 0u, 1u, &scissor);

        vk::beginRenderPass     (m_vki, *v.commandBuffer, *v.renderPass, *v.frameBuffer->buffer, v.renderArea, m_clearColor);
                        m_vki.cmdDraw                   (*v.commandBuffer, v.vertexCount, 1u, 0u, 0u);
        vk::endRenderPass       (m_vki, *v.commandBuffer);

                        iterateCommandEnd(v, programResult, referenceResult);
                }

        return (iterateVerifyResults(v, programResult, referenceResult) ? tcu::TestStatus::pass : tcu::TestStatus::fail)("");
}

class DynamicStorageBufferInstance : public DynamicBuffersInstance, public StorageBufferInstance
{
public:
        DynamicStorageBufferInstance                                                                    (Context&                                       context,
                                                                                                                                         const TestCaseParams&          testCaseParams);
        tcu::TestStatus         iterate                                                                         (void);
        void                            createAndPopulateDescriptors                            (IterateCommonVariables&        variables);
        void                            updateDescriptors                                                       (IterateCommonVariables&        variables);
        bool                            verifyVertexWriteResults                                        (IterateCommonVariables&        variables);
};

DynamicStorageBufferInstance::DynamicStorageBufferInstance                      (Context&                                       context,
                                                                                                                                         const TestCaseParams&          testCaseParams)
        : CommonDescriptorInstance(context,
                TestParams(VK_SHADER_STAGE_ALL_GRAPHICS,
                        VK_DESCRIPTOR_TYPE_STORAGE_BUFFER_DYNAMIC,
                        BINDING_StorageBufferDynamic,
                        VK_DESCRIPTOR_TYPE_UNDEFINED,
                        BINDING_Undefined,
                        false,
                        performWritesInVertex(testCaseParams.descriptorType, context),
                        testCaseParams)),
                        DynamicBuffersInstance(context, m_testParams), StorageBufferInstance(context, testCaseParams)
{
}

tcu::TestStatus DynamicStorageBufferInstance::iterate(void)
{
        return DynamicBuffersInstance::iterate();
}

void DynamicStorageBufferInstance::createAndPopulateDescriptors(IterateCommonVariables&                 variables)
{
        StorageBufferInstance::createAndPopulateDescriptors(variables);
}

void DynamicStorageBufferInstance::updateDescriptors(IterateCommonVariables&                                    variables)
{
        DynamicBuffersInstance::updateDescriptors(variables);
}

bool DynamicStorageBufferInstance::verifyVertexWriteResults(IterateCommonVariables&                             variables)
{
        return StorageBufferInstance::verifyVertexWriteResults(variables);
}

class DynamicUniformBufferInstance : public DynamicBuffersInstance, public UniformBufferInstance
{
public:
        DynamicUniformBufferInstance                                                                    (Context&                                       context,
                                                                                                                                         const TestCaseParams&          testCaseParams);
        tcu::TestStatus         iterate(void);
        void                            createAndPopulateDescriptors(IterateCommonVariables&                                    variables);
        void                            updateDescriptors(IterateCommonVariables&                                                               variables);
};

DynamicUniformBufferInstance::DynamicUniformBufferInstance                      (Context&                                       context,
                                                                                                                                         const TestCaseParams&          testCaseParams)
        : CommonDescriptorInstance(context,
                TestParams(VK_SHADER_STAGE_ALL_GRAPHICS,
                        VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER_DYNAMIC,
                        BINDING_UniformBufferDynamic,
                        VK_DESCRIPTOR_TYPE_UNDEFINED,
                        BINDING_Undefined,
                        false,
                        performWritesInVertex(testCaseParams.descriptorType, context),
                        testCaseParams)),
                        DynamicBuffersInstance(context, m_testParams), UniformBufferInstance(context, testCaseParams)
{
}

tcu::TestStatus DynamicUniformBufferInstance::iterate(void)
{
        return DynamicBuffersInstance::iterate();
}

void DynamicUniformBufferInstance::createAndPopulateDescriptors(IterateCommonVariables&                 variables)
{
        UniformBufferInstance::createAndPopulateDescriptors(variables);
}

void DynamicUniformBufferInstance::updateDescriptors(IterateCommonVariables&                                    variables)
{
        DynamicBuffersInstance::updateDescriptors(variables);
}

class InputAttachmentInstance : public CommonDescriptorInstance
{
public:
                                                                InputAttachmentInstance                         (Context&                                                                       context,
                                                                                                                                        const TestCaseParams&                                           testCaseParams);
private:
        virtual Move<VkRenderPass>      createRenderPass                                        (const IterateCommonVariables&                          variables);
        virtual void                            createFramebuffer                                       (ut::FrameBufferSp&                                                     frameBuffer,
                                                                                                                                         VkRenderPass                                                           renderPass,
                                                                                                                                         const IterateCommonVariables&                          variables);
        virtual void                            createAndPopulateDescriptors            (IterateCommonVariables&                                        variables);
};

InputAttachmentInstance::InputAttachmentInstance                                        (Context&                                                                       context,
                                                                                                                                         const TestCaseParams&                                          testCaseParams)
        : CommonDescriptorInstance(context,
                TestParams(VK_SHADER_STAGE_ALL_GRAPHICS,
                        VK_DESCRIPTOR_TYPE_INPUT_ATTACHMENT,
                        BINDING_InputAttachment,
                        VK_DESCRIPTOR_TYPE_UNDEFINED,
                        BINDING_Undefined,
                        true,
                        performWritesInVertex(testCaseParams.descriptorType, context),
                        testCaseParams))
{
}

void InputAttachmentInstance::createAndPopulateDescriptors                      (IterateCommonVariables&                                        variables)
{
        createImages(variables.descriptorsImages, variables.descriptorsBufferInfos, variables.descriptorsBuffer,
                VK_BUFFER_USAGE_TRANSFER_SRC_BIT, m_testParams.frameResolution, m_colorFormat, VK_IMAGE_LAYOUT_UNDEFINED, variables.validDescriptorCount);
        createImagesViews(variables.descriptorImageViews, variables.descriptorsImages, m_colorFormat);

        for (deUint32 descriptorIdx = 0; descriptorIdx < variables.validDescriptorCount; ++descriptorIdx)
        {
                const float                                             component       = m_colorScheme[descriptorIdx % m_schemeSize];
                const tcu::PixelBufferAccess    pa                      = getPixelAccess(descriptorIdx, m_testParams.frameResolution, m_colorFormat, variables.descriptorsBufferInfos, variables.descriptorsBuffer);
                tcu::clear(pa, tcu::Vec4(component, component, component, 1.0f));
        }
        vk::flushAlloc(m_vki, m_vkd, *variables.descriptorsBuffer->alloc);
}

Move<VkRenderPass> InputAttachmentInstance::createRenderPass            (const IterateCommonVariables&                          variables)
{
        std::vector<VkAttachmentDescription>    attachmentDescriptions;
        std::vector<VkAttachmentReference>              inputAttachmentRefs;

        const VkAttachmentDescription   colorAttachmentDescription =
        {
                (VkAttachmentDescriptionFlags)0,                        // VkAttachmentDescriptionFlags         flags;
                m_colorFormat,                                                          // VkFormat                                                     format;
                VK_SAMPLE_COUNT_1_BIT,                                          // VkSampleCountFlagBits                        samples;
                VK_ATTACHMENT_LOAD_OP_CLEAR,                            // VkAttachmentLoadOp                           loadOp;
                VK_ATTACHMENT_STORE_OP_STORE,                           // VkAttachmentStoreOp                          storeOp;
                VK_ATTACHMENT_LOAD_OP_DONT_CARE,                        // VkAttachmentLoadOp                           stencilLoadOp;
                VK_ATTACHMENT_STORE_OP_DONT_CARE,                       // VkAttachmentStoreOp                          stencilStoreOp;
                VK_IMAGE_LAYOUT_COLOR_ATTACHMENT_OPTIMAL,       // VkImageLayout                                        initialLayout;
                VK_IMAGE_LAYOUT_COLOR_ATTACHMENT_OPTIMAL,       // VkImageLayout                                        finalLayout;
        };
        const VkAttachmentReference             colorAttachmentRef =
        {
                0u,                                                                                             // deUint32                                                     attachment;
                VK_IMAGE_LAYOUT_COLOR_ATTACHMENT_OPTIMAL                // VkImageLayout                                        layout;
        };
        attachmentDescriptions.push_back(colorAttachmentDescription);

        // build input atachments
        {
                const std::vector<deUint32>     primes = ut::generatePrimes(variables.availableDescriptorCount);
                const deUint32 inputCount = static_cast<deUint32>(variables.descriptorImageViews.size());
                for (deUint32 inputIdx = 0; inputIdx < inputCount; ++inputIdx)
                {
                        // primes holds the indices of input attachments for shader binding 10 which has input_attachment_index=1
                        deUint32 nextInputAttachmentIndex = primes[inputIdx] + 1;

                        // Fill up the subpass description's input attachments with unused attachments forming gaps to the next referenced attachment
                        for (deUint32 unusedIdx = static_cast<deUint32>(inputAttachmentRefs.size()); unusedIdx < nextInputAttachmentIndex; ++unusedIdx)
                        {
                                const VkAttachmentReference             inputAttachmentRef =
                                {
                                        VK_ATTACHMENT_UNUSED,                                           // deUint32                                                     attachment;
                                        VK_IMAGE_LAYOUT_GENERAL                                         // VkImageLayout                                        layout;
                                };

                                inputAttachmentRefs.push_back(inputAttachmentRef);
                        }

                        const VkAttachmentDescription   inputAttachmentDescription =
                        {
                                VK_ATTACHMENT_DESCRIPTION_MAY_ALIAS_BIT,                // VkAttachmentDescriptionFlags         flags;
                                variables.descriptorsImages[inputIdx]->format,  // VkFormat                                                     format;
                                VK_SAMPLE_COUNT_1_BIT,                                                  // VkSampleCountFlagBits                        samples;
                                VK_ATTACHMENT_LOAD_OP_LOAD,                                             // VkAttachmentLoadOp                           loadOp;
                                VK_ATTACHMENT_STORE_OP_STORE,                                   // VkAttachmentStoreOp                          storeOp;
                                VK_ATTACHMENT_LOAD_OP_DONT_CARE,                                // VkAttachmentLoadOp                           stencilLoadOp;
                                VK_ATTACHMENT_STORE_OP_DONT_CARE,                               // VkAttachmentStoreOp                          stencilStoreOp;
                                VK_IMAGE_LAYOUT_GENERAL,                                                // VkImageLayout                                        initialLayout;
                                VK_IMAGE_LAYOUT_GENERAL                                                 // VkImageLayout                                        finalLayout;
                        };

                        const VkAttachmentReference             inputAttachmentRef =
                        {
                                inputIdx + 1,                                                           // deUint32                                                     attachment;
                                VK_IMAGE_LAYOUT_GENERAL                                         // VkImageLayout                                        layout;
                        };

                        inputAttachmentRefs.push_back(inputAttachmentRef);
                        attachmentDescriptions.push_back(inputAttachmentDescription);
                }
        }

        const VkSubpassDescription              subpassDescription =
        {
                (VkSubpassDescriptionFlags)0,                                           // VkSubpassDescriptionFlags            flags;
                VK_PIPELINE_BIND_POINT_GRAPHICS,                                        // VkPipelineBindPoint                          pipelineBindPoint;
                static_cast<deUint32>(inputAttachmentRefs.size()),      // deUint32                                                     inputAttachmentCount;
                inputAttachmentRefs.data(),                                                     // const VkAttachmentReference*         pInputAttachments;
                1u,                                                                                                     // deUint32                                                     colorAttachmentCount;
                &colorAttachmentRef,                                                            // const VkAttachmentReference*         pColorAttachments;
                DE_NULL,                                                                                        // const VkAttachmentReference*         pResolveAttachments;
                DE_NULL,                                                                                        // const VkAttachmentReference*         pDepthStencilAttachment;
                0u,                                                                                                     // deUint32                                                     preserveAttachmentCount;
                DE_NULL                                                                                         // const deUint32*                                      pPreserveAttachments;
        };

        const VkRenderPassCreateInfo    renderPassInfo =
        {
                VK_STRUCTURE_TYPE_RENDER_PASS_CREATE_INFO,                              // VkStructureType                                      sType;
                DE_NULL,                                                                                                // const void*                                          pNext;
                (VkRenderPassCreateFlags)0,                                                             // VkRenderPassCreateFlags                      flags;
                static_cast<deUint32>(attachmentDescriptions.size()),   // deUint32                                                     attachmentCount;
                attachmentDescriptions.data(),                                                  // const VkAttachmentDescription*       pAttachments;
                1u,                                                                                                             // deUint32                                                     subpassCount;
                &subpassDescription,                                                                    // const VkSubpassDescription*          pSubpasses;
                0u,                                                                                                             // deUint32                                                     dependencyCount;
                DE_NULL                                                                                                 // const VkSubpassDependency*           pDependencies;
        };

        return vk::createRenderPass(m_vki, m_vkd, &renderPassInfo);
}

void InputAttachmentInstance::createFramebuffer                                         (ut::FrameBufferSp&                                                     frameBuffer,
                                                                                                                                         VkRenderPass                                                           renderPass,
                                                                                                                                         const IterateCommonVariables&                          variables)
{
        std::vector<VkImageView>                        inputAttachments;
        const deUint32 viewCount = static_cast<deUint32>(variables.descriptorImageViews.size());
        inputAttachments.resize(viewCount);
        for (deUint32 viewIdx = 0; viewIdx < viewCount; ++viewIdx)
        {
                inputAttachments[viewIdx] = **variables.descriptorImageViews[viewIdx];
        }
        ut::createFrameBuffer(frameBuffer, m_context, m_testParams.frameResolution, m_colorFormat, renderPass, viewCount, inputAttachments.data());
}

class SamplerInstance : public CommonDescriptorInstance
{
public:
                                                                SamplerInstance                                         (Context&                                                                       context,
                                                                                                                                         const TestCaseParams&                                          testCaseParams);
private:
        virtual void                            createAndPopulateDescriptors            (IterateCommonVariables&                                        variables);
        virtual void                            updateDescriptors                                       (IterateCommonVariables&                                        variables);
};

SamplerInstance::SamplerInstance                                                                        (Context&                                                                       context,
                                                                                                                                         const TestCaseParams&                                          testCaseParams)
        : CommonDescriptorInstance(context,
                TestParams(VK_SHADER_STAGE_ALL_GRAPHICS,
                        VK_DESCRIPTOR_TYPE_SAMPLER,
                        BINDING_Sampler,
                        VK_DESCRIPTOR_TYPE_SAMPLED_IMAGE,
                        BINDING_SampledImage,
                        true,
                        performWritesInVertex(testCaseParams.descriptorType, context),
                        testCaseParams))
{
}

void SamplerInstance::updateDescriptors                                                         (IterateCommonVariables&                                        variables)
{
        DE_ASSERT(variables.descriptorsImages.size()            == 1);
        DE_ASSERT(variables.descriptorImageViews.size()         == 1);
        DE_ASSERT(variables.descriptorsBufferInfos.size()       == 1);
        DE_ASSERT(m_testParams.additionalDescriptorType         == VK_DESCRIPTOR_TYPE_SAMPLED_IMAGE);
        DE_ASSERT(variables.descriptorSamplers.size()           == variables.validDescriptorCount);

        // update an image
        {
                const VkDescriptorImageInfo imageInfo =
                {
                        static_cast<VkSampler>(0),
                        **variables.descriptorImageViews[0],
                        VK_IMAGE_LAYOUT_GENERAL
                };

                const VkWriteDescriptorSet writeInfo =
                {
                        VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET,                 // sType
                        DE_NULL,                                                                                // pNext
                        *variables.descriptorSet,                                               // descriptorSet
                        BINDING_SampledImage,                                                   // descriptorBinding;
                        0,                                                                                              // elementIndex
                        1u,                                                                                             // descriptorCount
                        VK_DESCRIPTOR_TYPE_SAMPLED_IMAGE,                               // descriptorType
                        &imageInfo,                                                                             // pImageInfo
                        DE_NULL,                                                                                // pBufferInfo
                        DE_NULL                                                                                 // pTexelBufferView
                };

                m_vki.updateDescriptorSets(m_vkd, 1u, &writeInfo, 0u, DE_NULL);
        }

        // update samplers
        CommonDescriptorInstance::updateDescriptors(variables);
}

void SamplerInstance::createAndPopulateDescriptors                                      (IterateCommonVariables&                                        variables)
{
        DE_ASSERT(variables.descriptorsImages.size()            == 0);
        DE_ASSERT(variables.descriptorImageViews.size()         == 0);
        DE_ASSERT(variables.descriptorsBufferInfos.size()       == 0);
        DE_ASSERT(variables.descriptorSamplers.size()           == 0);

        // create and populate an image
        {
                VkExtent3D imageExtent = m_testParams.frameResolution;
                if (m_testParams.usesMipMaps)
                {
                        imageExtent.width *= 2;
                        imageExtent.height *= 2;
                };

                createImages(variables.descriptorsImages, variables.descriptorsBufferInfos, variables.descriptorsBuffer,
                        VK_BUFFER_USAGE_TRANSFER_SRC_BIT, imageExtent, m_colorFormat, VK_IMAGE_LAYOUT_UNDEFINED, 1, m_testParams.usesMipMaps);
                createImagesViews(variables.descriptorImageViews, variables.descriptorsImages, m_colorFormat);

                PixelBufferAccess pa = getPixelAccess(0, imageExtent, m_colorFormat, variables.descriptorsBufferInfos, variables.descriptorsBuffer, m_testParams.usesMipMaps ? 1 : 0);

                for (deUint32 y = 0, pixelNum = 0; y < m_testParams.frameResolution.height; ++y)
                {
                        for (deUint32 x = 0; x < m_testParams.frameResolution.width; ++x, ++pixelNum)
                        {
                                const float             component       = m_colorScheme[(pixelNum % variables.validDescriptorCount) % m_schemeSize];
                                pa.setPixel(tcu::Vec4(component, component, component, 1.0f), x, y);
                        }
                }

                vk::flushAlloc(m_vki, m_vkd, *variables.descriptorsBuffer->alloc);
        }

        const tcu::Sampler sampler(
                tcu::Sampler::CLAMP_TO_BORDER,                                                                                                                  // wrapS
                tcu::Sampler::CLAMP_TO_BORDER,                                                                                                                  // wrapT
                tcu::Sampler::CLAMP_TO_BORDER,                                                                                                                  // wrapR
                m_testParams.usesMipMaps ? tcu::Sampler::LINEAR_MIPMAP_NEAREST : tcu::Sampler::NEAREST, // minFilter
                m_testParams.usesMipMaps ? tcu::Sampler::LINEAR_MIPMAP_NEAREST : tcu::Sampler::NEAREST, // magFilter
                0.0f,                                                                                                                                                                   // lodTreshold
                true);                                                                                                                                                                  // normalizeCoords
        const VkSamplerCreateInfo createInfo = vk::mapSampler(sampler, vk::mapVkFormat(m_colorFormat));
        variables.descriptorSamplers.resize(variables.validDescriptorCount);

        for (deUint32 samplerIdx = 0; samplerIdx < variables.validDescriptorCount; ++samplerIdx)
        {
                variables.descriptorSamplers[samplerIdx] = ut::SamplerSp(new Move<VkSampler>(vk::createSampler(m_vki, m_vkd, &createInfo)));
        }
}

class SampledImageInstance : public CommonDescriptorInstance
{
public:
                                                                SampledImageInstance                            (Context&                                                                       context,
                                                                                                                                         const TestCaseParams&                                          testCaseParams);
private:
        virtual void                            createAndPopulateDescriptors            (IterateCommonVariables&                                        variables);
        virtual void                            updateDescriptors                                       (IterateCommonVariables&                                        variables);
};

SampledImageInstance::SampledImageInstance                                                      (Context&                                                                       context,
                                                                                                                                         const TestCaseParams&                                          testCaseParams)
        : CommonDescriptorInstance(context,
                TestParams(VK_SHADER_STAGE_ALL_GRAPHICS,
                        VK_DESCRIPTOR_TYPE_SAMPLED_IMAGE,
                        BINDING_SampledImage,
                        VK_DESCRIPTOR_TYPE_SAMPLER,
                        BINDING_Sampler,
                        true,
                        performWritesInVertex(testCaseParams.descriptorType, context),
                        testCaseParams))
{
}

void SampledImageInstance::updateDescriptors                                            (IterateCommonVariables&                                        variables)
{
        DE_ASSERT(variables.descriptorSamplers.size()           == 1);
        DE_ASSERT(variables.descriptorsImages.size()            == variables.validDescriptorCount);
        DE_ASSERT(variables.descriptorImageViews.size()         == variables.validDescriptorCount);
        DE_ASSERT(variables.descriptorsBufferInfos.size()       == variables.validDescriptorCount);

        // update a sampler
        {
                const VkDescriptorImageInfo samplerInfo =
                {
                        **variables.descriptorSamplers[0],
                        static_cast<VkImageView>(0),
                        static_cast<VkImageLayout>(0)
                };

                const VkWriteDescriptorSet writeInfo =
                {
                        VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET,                 // sType
                        DE_NULL,                                                                                // pNext
                        *variables.descriptorSet,                                               // descriptorSet
                        BINDING_Sampler,                                                                // descriptorBinding;
                        0,                                                                                              // elementIndex
                        1u,                                                                                             // descriptorCount
                        VK_DESCRIPTOR_TYPE_SAMPLER,                                             // descriptorType
                        &samplerInfo,                                                                   // pImageInfo
                        DE_NULL,                                                                                // pBufferInfo
                        DE_NULL                                                                                 // pTexelBufferView
                };

                m_vki.updateDescriptorSets(m_vkd, 1u, &writeInfo, 0u, DE_NULL);
        }

        // update images
        CommonDescriptorInstance::updateDescriptors(variables);
}

void SampledImageInstance::createAndPopulateDescriptors                         (IterateCommonVariables&                                        variables)
{
        DE_ASSERT(variables.descriptorSamplers.size()           == 0);
        DE_ASSERT(variables.descriptorsImages.size()            == 0);
        DE_ASSERT(variables.descriptorImageViews.size()         == 0);
        DE_ASSERT(variables.descriptorsBufferInfos.size()       == 0);

        // create an only one sampler for all images
        {
                const tcu::Sampler sampler(
                        tcu::Sampler::CLAMP_TO_BORDER,                                                                                                                          // wrapS
                        tcu::Sampler::CLAMP_TO_BORDER,                                                                                                                          // wrapT
                        tcu::Sampler::CLAMP_TO_BORDER,                                                                                                                          // wrapR
                        m_testParams.usesMipMaps ? tcu::Sampler::NEAREST_MIPMAP_NEAREST : tcu::Sampler::NEAREST,        // minFilter
                        m_testParams.usesMipMaps ? tcu::Sampler::NEAREST_MIPMAP_NEAREST : tcu::Sampler::NEAREST,        // magFilter
                        0.0f,                                                                                                                                                                           // lodTreshold
                        true);                                                                                                                                                                          // normalizeCoords
                const VkSamplerCreateInfo createInfo = vk::mapSampler(sampler, vk::mapVkFormat(m_colorFormat));
                variables.descriptorSamplers.push_back(ut::SamplerSp(new Move<VkSampler>(vk::createSampler(m_vki, m_vkd, &createInfo))));
        }

        const VkExtent3D&                       imageExtent = m_testParams.usesMipMaps ? bigImageExtent : smallImageExtent;

        createImages(variables.descriptorsImages, variables.descriptorsBufferInfos, variables.descriptorsBuffer,
                VK_BUFFER_USAGE_TRANSFER_SRC_BIT, imageExtent, m_colorFormat, VK_IMAGE_LAYOUT_UNDEFINED, variables.validDescriptorCount, m_testParams.usesMipMaps);
        createImagesViews(variables.descriptorImageViews, variables.descriptorsImages, m_colorFormat);

        PixelBufferAccess                       pixelAccess;
        for (deUint32 imageIdx = 0; imageIdx < variables.validDescriptorCount; ++imageIdx)
        {
                const float                             component       = m_colorScheme[imageIdx % m_schemeSize];

                if (m_testParams.usesMipMaps)
                {
                        const deUint32 mipCount = ut::computeMipMapCount(imageExtent);
                        DE_ASSERT(mipCount >= 2);
                        for (deUint32 mipIdx = 0; mipIdx < mipCount; ++mipIdx)
                        {
                                pixelAccess = getPixelAccess(imageIdx, imageExtent, m_colorFormat, variables.descriptorsBufferInfos, variables.descriptorsBuffer, mipIdx);
                                tcu::clear(pixelAccess, m_clearColor);
                        }

                        pixelAccess = getPixelAccess(imageIdx, imageExtent, m_colorFormat, variables.descriptorsBufferInfos, variables.descriptorsBuffer, mipCount-1);
                        pixelAccess.setPixel(tcu::Vec4(component, component, component, 1.0f), 0, 0);
                }
                else
                {
                        pixelAccess = getPixelAccess(imageIdx, imageExtent, m_colorFormat, variables.descriptorsBufferInfos, variables.descriptorsBuffer, 0);
                        pixelAccess.setPixel(tcu::Vec4(component, component, component, 1.0f), 0, 0);
                }
        }
        vk::flushAlloc(m_vki, m_vkd, *variables.descriptorsBuffer->alloc);
}

class CombinedImageInstance : public CommonDescriptorInstance
{
public:
                                                                CombinedImageInstance                           (Context&                                                                       context,
                                                                                                                                         const TestCaseParams&                                          testCaseParams);
private:
        virtual void                            createAndPopulateDescriptors            (IterateCommonVariables&                                        variables);
        virtual void                            updateDescriptors                                       (IterateCommonVariables&                                        variables);
};

CombinedImageInstance::CombinedImageInstance                                            (Context&                                                                       context,
                                                                                                                                         const TestCaseParams&                                          testCaseParams)
        : CommonDescriptorInstance(context,
                TestParams(VK_SHADER_STAGE_ALL_GRAPHICS,
                        testCaseParams.descriptorType,
                        BINDING_CombinedImageSampler,
                        VK_DESCRIPTOR_TYPE_UNDEFINED,
                        BINDING_Undefined,
                        true,
                        performWritesInVertex(testCaseParams.descriptorType),
                        testCaseParams))
{
}

void CombinedImageInstance::updateDescriptors                                           (IterateCommonVariables&                                        variables)
{
        const std::vector<deUint32>     primes = ut::generatePrimes(variables.availableDescriptorCount);
        const deUint32                          primeCount = static_cast<deUint32>(primes.size());

        DE_ASSERT(variables.descriptorSamplers.size()           == 1);
        DE_ASSERT(variables.descriptorsImages.size()            == primeCount);
        DE_ASSERT(variables.descriptorImageViews.size()         == primeCount);
        DE_ASSERT(variables.descriptorsBufferInfos.size()       == primeCount);

        for (deUint32 primeIdx = 0; primeIdx < primeCount; ++primeIdx)
        {
                const VkDescriptorImageInfo imageInfo =
                {
                        **variables.descriptorSamplers[0],
                        **variables.descriptorImageViews[primeIdx],
                        VK_IMAGE_LAYOUT_GENERAL
                };

                const VkWriteDescriptorSet writeInfo =
                {
                        VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET,                 // sType
                        DE_NULL,                                                                                // pNext
                        *variables.descriptorSet,                                               // descriptorSet
                        BINDING_CombinedImageSampler,                                   // descriptorBinding;
                        primes[primeIdx],                                                               // elementIndex
                        1u,                                                                                             // descriptorCount
                        m_testParams.descriptorType,                                    // descriptorType
                        &imageInfo,                                                                             // pImageInfo
                        DE_NULL,                                                                                // pBufferInfo
                        DE_NULL                                                                                 // pTexelBufferView
                };

                m_vki.updateDescriptorSets(m_vkd, 1u, &writeInfo, 0u, DE_NULL);
        }
}

void CombinedImageInstance::createAndPopulateDescriptors                        (IterateCommonVariables&                                        variables)
{
        DE_ASSERT(variables.descriptorSamplers.size()           == 0);
        DE_ASSERT(variables.descriptorsImages.size()            == 0);
        DE_ASSERT(variables.descriptorImageViews.size()         == 0);
        DE_ASSERT(variables.descriptorsBufferInfos.size()       == 0);
        DE_ASSERT(variables.descriptorSamplers.size()           == 0);

        const tcu::Sampler sampler(
                tcu::Sampler::CLAMP_TO_BORDER,                                                                                                                          // wrapS
                tcu::Sampler::CLAMP_TO_BORDER,                                                                                                                          // wrapT
                tcu::Sampler::CLAMP_TO_BORDER,                                                                                                                          // wrapR
                m_testParams.usesMipMaps ? tcu::Sampler::NEAREST_MIPMAP_NEAREST : tcu::Sampler::NEAREST,        // minFilter
                m_testParams.usesMipMaps ? tcu::Sampler::NEAREST_MIPMAP_NEAREST : tcu::Sampler::NEAREST,        // magFilter
                0.0f,                                                                                                                                                                           // lodTreshold
                true);                                                                                                                                                                          // normalizeCoords
        const VkSamplerCreateInfo       createInfo = vk::mapSampler(sampler, vk::mapVkFormat(m_colorFormat));
        variables.descriptorSamplers.push_back(ut::SamplerSp(new Move<VkSampler>(vk::createSampler(m_vki, m_vkd, &createInfo))));

        const VkExtent3D&                       imageExtent = m_testParams.usesMipMaps ? bigImageExtent : smallImageExtent;
        createImages(variables.descriptorsImages, variables.descriptorsBufferInfos, variables.descriptorsBuffer, VK_BUFFER_USAGE_TRANSFER_SRC_BIT,
                imageExtent, m_colorFormat, VK_IMAGE_LAYOUT_UNDEFINED, variables.validDescriptorCount, m_testParams.usesMipMaps);
        createImagesViews(variables.descriptorImageViews, variables.descriptorsImages, m_colorFormat);

        PixelBufferAccess                       pixelAccess;
        for (deUint32 imageIdx = 0; imageIdx < variables.validDescriptorCount; ++imageIdx)
        {
                const float                             component = m_colorScheme[imageIdx % m_schemeSize];

                if (m_testParams.usesMipMaps)
                {
                        const deUint32  mipCount = ut::computeMipMapCount(imageExtent);
                        DE_ASSERT(mipCount >= 2);
                        for (deUint32 mipIdx = 0; mipIdx < mipCount; ++mipIdx)
                        {
                                pixelAccess = getPixelAccess(imageIdx, imageExtent, m_colorFormat, variables.descriptorsBufferInfos, variables.descriptorsBuffer, mipIdx);
                                tcu::clear(pixelAccess, m_clearColor);
                        }

                        pixelAccess = getPixelAccess(imageIdx, imageExtent, m_colorFormat, variables.descriptorsBufferInfos, variables.descriptorsBuffer, mipCount-1);
                        pixelAccess.setPixel(tcu::Vec4(component, component, component, 1.0f), 0, 0);
                }
                else
                {
                        pixelAccess = getPixelAccess(imageIdx, imageExtent, m_colorFormat, variables.descriptorsBufferInfos, variables.descriptorsBuffer, 0);
                        pixelAccess.setPixel(tcu::Vec4(component, component, component, 1.0f), 0, 0);
                }
        }

        vk::flushAlloc(m_vki, m_vkd, *variables.descriptorsBuffer->alloc);
}

class StorageImageInstance : public CommonDescriptorInstance
{
public:
                                                                StorageImageInstance                            (Context&                                                                       context,
                                                                                                                                         const TestCaseParams&                                          testCaseParams);
private:
        virtual tcu::TestStatus         iterate                                                         (void);
        virtual void                            createAndPopulateDescriptors            (IterateCommonVariables&                                        variables);
        virtual void                            updateDescriptors                                       (IterateCommonVariables&                                        variables);
        virtual void                            iterateCollectResults                           (ut::UpdatablePixelBufferAccessPtr&                     result,
                                                                                                                                         const IterateCommonVariables&                          variables,
                                                                                                                                         bool                                                                           fromTest);
        ut::BufferHandleAllocSp         m_buffer;
        const deUint32                          m_fillColor;
        typedef deUint32                        m_imageFormat_t;
};

StorageImageInstance::StorageImageInstance                                                      (Context&                                                                       context,
                                                                                                                                         const TestCaseParams&                                          testCaseParams)
        : CommonDescriptorInstance(context,
                TestParams      (VK_SHADER_STAGE_COMPUTE_BIT,
                                        VK_DESCRIPTOR_TYPE_STORAGE_IMAGE,
                                        BINDING_StorageImage,
                                        VK_DESCRIPTOR_TYPE_STORAGE_IMAGE,
                                        (BINDING_StorageImage + 1),
                                        true,
                                        performWritesInVertex(testCaseParams.descriptorType, context),
                                        testCaseParams))
        , m_buffer              ()
        , m_fillColor   (10)
{
}

void StorageImageInstance::updateDescriptors                                            (IterateCommonVariables&                                        variables)
{
        // update image at last index
        {
                VkDescriptorImageInfo           imageInfo =
                {
                        static_cast<VkSampler>(0),
                        **variables.descriptorImageViews[variables.validDescriptorCount],
                        VK_IMAGE_LAYOUT_GENERAL
                };

                const VkWriteDescriptorSet writeInfo =
                {
                        VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET,         // sType
                        DE_NULL,                                                                        // pNext
                        *variables.descriptorSet,                                       // descriptorSet
                        m_testParams.additionalDescriptorBinding,       // descriptorBinding;
                        0,                                                                                      // elementIndex
                        1u,                                                                                     // descriptorCount
                        m_testParams.additionalDescriptorType,          // descriptorType
                        &imageInfo,                                                                     // pImageInfo
                        DE_NULL,                                                                        // pBufferInfo
                        DE_NULL                                                                         // pTexelBufferView
                };

                m_vki.updateDescriptorSets(m_vkd, 1u, &writeInfo, 0u, DE_NULL);
        }

        // update rest images
        CommonDescriptorInstance::updateDescriptors(variables);
}

void StorageImageInstance::createAndPopulateDescriptors                         (IterateCommonVariables&                                        variables)
{
        const VkFormat                          imageFormat = ut::mapType2vkFormat<m_imageFormat_t>::value;
        const VkBufferUsageFlags        bufferUsage = VK_BUFFER_USAGE_STORAGE_BUFFER_BIT | VK_BUFFER_USAGE_TRANSFER_SRC_BIT | VK_BUFFER_USAGE_TRANSFER_DST_BIT;

        // create descriptor buffer, images and views
        {
                const VkExtent3D                        imageExtent = { 4, 4, 1 };

                createImages(variables.descriptorsImages, variables.descriptorsBufferInfos, variables.descriptorsBuffer,
                        bufferUsage, imageExtent, imageFormat, VK_IMAGE_LAYOUT_UNDEFINED, variables.validDescriptorCount);

                for (deUint32 imageIdx = 0; imageIdx < variables.validDescriptorCount; ++imageIdx)
                {
                        const PixelBufferAccess pa = getPixelAccess(imageIdx, imageExtent, imageFormat, variables.descriptorsBufferInfos, variables.descriptorsBuffer);
                        tcu::clear(pa, tcu::UVec4(m_fillColor));
                }
                vk::flushAlloc(m_vki, m_vkd, *variables.descriptorsBuffer->alloc);
        }

        // create additional image that will be used as index container
        {
                createImages(variables.descriptorsImages, variables.descriptorsBufferInfos, m_buffer,
                        bufferUsage, m_testParams.frameResolution, imageFormat, VK_IMAGE_LAYOUT_UNDEFINED, 1);

                // populate buffer
                const std::vector<deUint32>     primes = ut::generatePrimes(variables.availableDescriptorCount);
                const PixelBufferAccess pa = getPixelAccess(variables.validDescriptorCount, m_testParams.frameResolution, imageFormat, variables.descriptorsBufferInfos, m_buffer);
                for (deUint32 y = 0, pixel = 0; y < m_testParams.frameResolution.height; ++y)
                {
                        for (deUint32 x = 0; x < m_testParams.frameResolution.width; ++x, ++pixel)
                        {
                                const deUint32 component = primes[pixel % variables.validDescriptorCount];
                                pa.setPixel(tcu::UVec4(component), x, y);
                        }
                }

                // save changes
                vk::flushAlloc(m_vki, m_vkd, *m_buffer->alloc);
        }

        // create views for all previously created images
        createImagesViews(variables.descriptorImageViews, variables.descriptorsImages, imageFormat);
}

tcu::TestStatus StorageImageInstance::iterate                                           (void)
{
        IterateCommonVariables  v;
        iterateCommandSetup             (v);
        iterateCommandBegin             (v);

        ut::UpdatablePixelBufferAccessPtr       programResult;
        ut::UpdatablePixelBufferAccessPtr       referenceResult;

        if (m_testParams.updateAfterBind)
        {
                updateDescriptors       (v);
        }

        copyBuffersToImages             (v);

        m_vki.cmdDispatch               (*v.commandBuffer,
                                                        m_testParams.calculateInLoop ? 1 : v.renderArea.extent.width,
                                                        m_testParams.calculateInLoop ? 1 : v.renderArea.extent.height,
                                                        1);

        copyImagesToBuffers             (v);

        iterateCommandEnd(v, programResult, referenceResult, false);

        return ( iterateVerifyResults(v, programResult, referenceResult) ? tcu::TestStatus::pass : tcu::TestStatus::fail)("");
}

void StorageImageInstance::iterateCollectResults                                        (ut::UpdatablePixelBufferAccessPtr&                     result,
                                                                                                                                         const IterateCommonVariables&                          variables,
                                                                                                                                         bool                                                                           fromTest)
{
        result = ut::UpdatablePixelBufferAccessPtr(new ut::PixelBufferAccessAllocation(
                vk::mapVkFormat(ut::mapType2vkFormat<m_imageFormat_t>::value), m_testParams.frameResolution));
        const PixelBufferAccess& dst = *result.get();

        if (fromTest)
        {
                vk::invalidateAlloc(m_vki, m_vkd, *variables.descriptorsBuffer->alloc);
                for (deUint32 y = 0, pixelNum = 0; y < m_testParams.frameResolution.height; ++y)
                {
                        for (deUint32 x = 0; x < m_testParams.frameResolution.width; ++x, ++pixelNum)
                        {
                                const deUint32 imageIdx = pixelNum % variables.validDescriptorCount;
                                const PixelBufferAccess src = getPixelAccess(imageIdx,
                                        variables.descriptorsImages[imageIdx]->extent, variables.descriptorsImages[imageIdx]->format,
                                        variables.descriptorsBufferInfos, variables.descriptorsBuffer);
                                dst.setPixel(tcu::Vector<m_imageFormat_t, 4>(src.getPixelT<m_imageFormat_t>(0, 0).x()), x, y);
                        }
                }
        }
        else
        {
                std::vector<m_imageFormat_t> inc(variables.validDescriptorCount, m_fillColor);

                for (deUint32 invIdx = variables.lowerBound; invIdx < variables.upperBound; ++invIdx)
                {
                        ++inc[invIdx % variables.validDescriptorCount];
                }

                for (deUint32 invIdx = 0; invIdx < variables.vertexCount; ++invIdx)
                {
                        const deUint32 row = invIdx / m_testParams.frameResolution.width;
                        const deUint32 col = invIdx % m_testParams.frameResolution.width;
                        const m_imageFormat_t color = inc[invIdx % variables.validDescriptorCount];
                        dst.setPixel(tcu::Vector<m_imageFormat_t, 4>(color), col, row);
                }
        }
}

class DescriptorIndexingTestCase : public TestCase
{
        const TestCaseParams m_testCaseParams;
public:
        DescriptorIndexingTestCase (tcu::TestContext &context, const char *name, const char *description, const TestCaseParams& testCaseParams)
                : TestCase(context, name, description)
                , m_testCaseParams(testCaseParams)
        {
        }

        vkt::TestInstance* createInstance (vkt::Context& context) const // override
        {
                switch (m_testCaseParams.descriptorType)
                {
                case VK_DESCRIPTOR_TYPE_STORAGE_BUFFER:
                        return new StorageBufferInstance                (context, m_testCaseParams);
                case VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER:
                        return new UniformBufferInstance                (context, m_testCaseParams);
                case VK_DESCRIPTOR_TYPE_STORAGE_TEXEL_BUFFER:
                        return new StorageTexelInstance                 (context, m_testCaseParams);
                case VK_DESCRIPTOR_TYPE_UNIFORM_TEXEL_BUFFER:
                        return new UniformTexelInstance                 (context, m_testCaseParams);
                case VK_DESCRIPTOR_TYPE_STORAGE_BUFFER_DYNAMIC:
                        return new DynamicStorageBufferInstance (context, m_testCaseParams);
                case VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER_DYNAMIC:
                        return new DynamicUniformBufferInstance (context, m_testCaseParams);
                case VK_DESCRIPTOR_TYPE_INPUT_ATTACHMENT:
                        return new InputAttachmentInstance              (context, m_testCaseParams);
                case VK_DESCRIPTOR_TYPE_SAMPLER:
                        return new SamplerInstance                              (context, m_testCaseParams);
                case VK_DESCRIPTOR_TYPE_SAMPLED_IMAGE:
                        return new SampledImageInstance                 (context, m_testCaseParams);
                case VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER:
                        return new CombinedImageInstance                (context, m_testCaseParams);
                case VK_DESCRIPTOR_TYPE_STORAGE_IMAGE:
                        return new StorageImageInstance                 (context, m_testCaseParams);
                default:
                        TCU_THROW(InternalError, "Unknown Descriptor Type");
                }
                return DE_NULL;
        }

        virtual void checkSupport (vkt::Context& context) const
        {
                context.requireDeviceExtension("VK_EXT_descriptor_indexing");

                const vk::VkPhysicalDeviceDescriptorIndexingFeaturesEXT& feats = context.getDescriptorIndexingFeatures();

                switch (m_testCaseParams.descriptorType)
                {
                case VK_DESCRIPTOR_TYPE_STORAGE_BUFFER:
                        if (!(feats.shaderStorageBufferArrayNonUniformIndexing))
                                TCU_THROW(NotSupportedError, "Non-uniform indexing over storage buffer descriptor arrays is not supported.");

                        if (m_testCaseParams.updateAfterBind && !feats.descriptorBindingStorageBufferUpdateAfterBind)
                                TCU_THROW(NotSupportedError, "Update after bind for storage buffer descriptors is not supported.");
                        break;
                case VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER:
                        if (!(feats.shaderUniformBufferArrayNonUniformIndexing))
                                TCU_THROW(NotSupportedError, "Non-uniform indexing for uniform buffer descriptor arrays is not supported.");

                        if (m_testCaseParams.updateAfterBind && !feats.descriptorBindingUniformBufferUpdateAfterBind)
                                TCU_THROW(NotSupportedError, "Update after bind for uniform buffer descriptors is not supported.");
                        break;
                case VK_DESCRIPTOR_TYPE_STORAGE_TEXEL_BUFFER:
                        if (!(feats.shaderStorageTexelBufferArrayNonUniformIndexing))
                                TCU_THROW(NotSupportedError, "Non-uniform indexing for storage texel buffer descriptor arrays is not supported.");

                        if (m_testCaseParams.updateAfterBind && !feats.descriptorBindingStorageTexelBufferUpdateAfterBind)
                                TCU_THROW(NotSupportedError, "Update after bind for storage texel buffer descriptors is not supported.");
                        break;
                case VK_DESCRIPTOR_TYPE_UNIFORM_TEXEL_BUFFER:
                        if (!(feats.shaderUniformTexelBufferArrayNonUniformIndexing))
                                TCU_THROW(NotSupportedError, "Non-uniform indexing for uniform texel buffer descriptor arrays is not supported.");

                        if (m_testCaseParams.updateAfterBind && !feats.descriptorBindingUniformTexelBufferUpdateAfterBind)
                                TCU_THROW(NotSupportedError, "Update after bind for uniform texel buffer descriptors is not supported.");
                        break;
                case VK_DESCRIPTOR_TYPE_STORAGE_BUFFER_DYNAMIC:
                        if (!(feats.shaderStorageBufferArrayNonUniformIndexing))
                                TCU_THROW(NotSupportedError, "Non-uniform indexing over storage buffer dynamic descriptor arrays is not supported.");

                        if (m_testCaseParams.updateAfterBind)
                                TCU_THROW(NotSupportedError, "Update after bind for storage buffer dynamic descriptors is not supported.");
                        break;
                case VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER_DYNAMIC:
                        if (!(feats.shaderUniformBufferArrayNonUniformIndexing))
                                TCU_THROW(NotSupportedError, "Non-uniform indexing over uniform buffer dynamic descriptor arrays is not supported.");

                        if (m_testCaseParams.updateAfterBind)
                                TCU_THROW(NotSupportedError, "Update after bind for uniform buffer dynamic descriptors is not supported.");
                        break;
                case VK_DESCRIPTOR_TYPE_INPUT_ATTACHMENT:
                        if (!(feats.shaderInputAttachmentArrayNonUniformIndexing))
                                TCU_THROW(NotSupportedError, "Non-uniform indexing over input attachment descriptor arrays is not supported.");

                        if (m_testCaseParams.updateAfterBind)
                                TCU_THROW(NotSupportedError, "Update after bind for input attachment descriptors is not supported.");
                        break;
                case VK_DESCRIPTOR_TYPE_SAMPLER:
                        if (!(feats.shaderSampledImageArrayNonUniformIndexing))
                                TCU_THROW(NotSupportedError, "Non-uniform indexing over sampler descriptor arrays is not supported.");

                        if (m_testCaseParams.updateAfterBind && !feats.descriptorBindingSampledImageUpdateAfterBind)
                                TCU_THROW(NotSupportedError, "Update after bind for sampler descriptors is not supported.");
                        break;
                case VK_DESCRIPTOR_TYPE_SAMPLED_IMAGE:
                        if (!(feats.shaderSampledImageArrayNonUniformIndexing))
                                TCU_THROW(NotSupportedError, "Non-uniform indexing over sampled image descriptor arrays is not supported.");

                        if (m_testCaseParams.updateAfterBind && !feats.descriptorBindingSampledImageUpdateAfterBind)
                                TCU_THROW(NotSupportedError, "Update after bind for sampled image descriptors is not supported.");
                        break;
                case VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER:
                        if (!(feats.shaderSampledImageArrayNonUniformIndexing))
                                TCU_THROW(NotSupportedError, "Non-uniform indexing over combined image sampler descriptor arrays is not supported.");

                        if (m_testCaseParams.updateAfterBind && !feats.descriptorBindingSampledImageUpdateAfterBind)
                                TCU_THROW(NotSupportedError, "Update after bind for combined image sampler descriptors is not supported.");
                        break;
                case VK_DESCRIPTOR_TYPE_STORAGE_IMAGE:
                        if (!(feats.shaderStorageImageArrayNonUniformIndexing))
                                TCU_THROW(NotSupportedError, "Non-uniform indexing over storage image descriptor arrays is not supported.");

                        if (m_testCaseParams.updateAfterBind && !feats.descriptorBindingStorageImageUpdateAfterBind)
                                TCU_THROW(NotSupportedError, "Update after bind for storage image descriptors is not supported.");
                        break;
                default:
                        DE_FATAL("Unknown Descriptor Type");
                        break;
                }
        }

        virtual void initPrograms (SourceCollections& programCollection) const
        {
                std::string(*genShaderSource)(VkShaderStageFlagBits, const TestCaseParams&, bool) = &CommonDescriptorInstance::getShaderSource;

                if (VK_SHADER_STAGE_VERTEX_BIT & m_testCaseParams.stageFlags)
                {
                        programCollection.glslSources.add(
                                ut::buildShaderName(VK_SHADER_STAGE_VERTEX_BIT, m_testCaseParams.descriptorType, m_testCaseParams.updateAfterBind, m_testCaseParams.calculateInLoop, false))
                                << glu::VertexSource((*genShaderSource)(VK_SHADER_STAGE_VERTEX_BIT, m_testCaseParams, false));

                        if (CommonDescriptorInstance::performWritesInVertex(m_testCaseParams.descriptorType))
                        {
                                programCollection.glslSources.add(
                                        ut::buildShaderName(VK_SHADER_STAGE_VERTEX_BIT, m_testCaseParams.descriptorType, m_testCaseParams.updateAfterBind, m_testCaseParams.calculateInLoop, true))
                                        << glu::VertexSource((*genShaderSource)(VK_SHADER_STAGE_VERTEX_BIT, m_testCaseParams, true));
                        }
                }
                if (VK_SHADER_STAGE_FRAGMENT_BIT & m_testCaseParams.stageFlags)
                {
                        programCollection.glslSources.add(
                                ut::buildShaderName(VK_SHADER_STAGE_FRAGMENT_BIT, m_testCaseParams.descriptorType, m_testCaseParams.updateAfterBind, m_testCaseParams.calculateInLoop, false))
                                << glu::FragmentSource((*genShaderSource)(VK_SHADER_STAGE_FRAGMENT_BIT, m_testCaseParams, false));

                        if (CommonDescriptorInstance::performWritesInVertex(m_testCaseParams.descriptorType))
                        {
                                programCollection.glslSources.add(
                                        ut::buildShaderName(VK_SHADER_STAGE_FRAGMENT_BIT, m_testCaseParams.descriptorType, m_testCaseParams.updateAfterBind, m_testCaseParams.calculateInLoop, true))
                                        << glu::FragmentSource((*genShaderSource)(VK_SHADER_STAGE_FRAGMENT_BIT, m_testCaseParams, true));
                        }
                }
                if (VK_SHADER_STAGE_COMPUTE_BIT & m_testCaseParams.stageFlags)
                {
                        programCollection.glslSources.add(
                                ut::buildShaderName(VK_SHADER_STAGE_COMPUTE_BIT, m_testCaseParams.descriptorType, m_testCaseParams.updateAfterBind, m_testCaseParams.calculateInLoop, false))
                                << glu::ComputeSource((*genShaderSource)(VK_SHADER_STAGE_COMPUTE_BIT, m_testCaseParams, false));
                }
        }
};

} // - unnamed namespace

void descriptorIndexingDescriptorSetsCreateTests (tcu::TestCaseGroup* group)
{
        struct TestCaseInfo
        {
                const char*             name;
                const char*             description;
                TestCaseParams  params;
        };

        tcu::TestContext&                               context(group->getTestContext());

        TestCaseInfo casesAfterBindAndLoop[] =
        {
                {
                        "storage_buffer", "Regular Storage Buffer Descriptors",
                        {
                                VK_DESCRIPTOR_TYPE_STORAGE_BUFFER,
                                (VK_SHADER_STAGE_VERTEX_BIT | VK_SHADER_STAGE_FRAGMENT_BIT),
                                RESOLUTION,
                                false,  // updateAfterBind
                                false,  // calculateInLoop
                                false,  // useMipMaps
                                FUZZY_COMPARE, CMP_THRESHOLD
                        }
                },
                {
                        "storage_texel_buffer", "Storage Texel Buffer Descriptors",
                        {
                                VK_DESCRIPTOR_TYPE_STORAGE_TEXEL_BUFFER,
                                (VK_SHADER_STAGE_VERTEX_BIT | VK_SHADER_STAGE_FRAGMENT_BIT),
                                RESOLUTION,
                                false,  // updateAfterBind
                                false,  // calculateInLoop
                                false,  // useMipMaps
                                FUZZY_COMPARE, CMP_THRESHOLD
                        }
                },
                {
                        "uniform_texel_buffer", "Uniform Texel Buffer Descriptors",
                        {
                                VK_DESCRIPTOR_TYPE_UNIFORM_TEXEL_BUFFER,
                                (VK_SHADER_STAGE_VERTEX_BIT | VK_SHADER_STAGE_FRAGMENT_BIT),
                                RESOLUTION,
                                false,  // updateAfterBind,
                                false,  // calculateInLoop
                                false,  // usesMipMaps
                                FUZZY_COMPARE, CMP_THRESHOLD
                        }
                },
                {
                        "storage_image", "Storage Image Descriptors",
                        {
                                VK_DESCRIPTOR_TYPE_STORAGE_IMAGE,
                                VK_SHADER_STAGE_COMPUTE_BIT,
                                RESOLUTION,
                                false,  // updateAfterBind
                                false,  // calculateInLoop
                                false,  // useMipMaps
                                FUZZY_COMPARE, CMP_THRESHOLD
                        }
                },
        };

        for (int updateAfterBind = 0; updateAfterBind < 2; ++updateAfterBind)
        {
                for (int calculateInLoop = 0; calculateInLoop < 2; ++calculateInLoop)
                {
                        for (deUint32 caseIdx = 0; caseIdx < DE_LENGTH_OF_ARRAY(casesAfterBindAndLoop); ++caseIdx)
                        {
                                TestCaseInfo&   info                    (casesAfterBindAndLoop[caseIdx]);
                                std::string             caseName                (info.name);
                                std::string             caseDescription (info.description);
                                TestCaseParams  params                  (info.params);

                                caseName                                += (updateAfterBind     ? "_after_bind" : "");
                                caseName                                += (calculateInLoop     ? "_in_loop"    : "");

                                caseDescription                 += (updateAfterBind     ? " After Bind" : "");
                                caseDescription                 += (calculateInLoop ? " In Loop"        : "");

                                params.updateAfterBind  = updateAfterBind       ? true                  : false;
                                params.calculateInLoop  = calculateInLoop       ? true                  : false;

                                group->addChild(new DescriptorIndexingTestCase(context, caseName.c_str(), caseDescription.c_str(), params));
                        }
                }
        }

        TestCaseInfo casesAfterBindAndLoopAndLOD[] =
        {
                {
                        "sampler", "Sampler Descriptors",
                        {
                                VK_DESCRIPTOR_TYPE_SAMPLER,
                                (VK_SHADER_STAGE_VERTEX_BIT | VK_SHADER_STAGE_FRAGMENT_BIT),
                                RESOLUTION,
                                false,  // updateAfterBind
                                false,  // calculateInLoop
                                false,  // usesMipMaps
                                FUZZY_COMPARE, CMP_THRESHOLD
                        }
                },
                {
                        "sampled_image", "Sampled Image Descriptors",
                        {
                                VK_DESCRIPTOR_TYPE_SAMPLED_IMAGE,
                                (VK_SHADER_STAGE_VERTEX_BIT | VK_SHADER_STAGE_FRAGMENT_BIT),
                                RESOLUTION,
                                false,  // updateAfterBind
                                false,  // calculateInLoop
                                false,  // usesMipMaps
                                FUZZY_COMPARE, CMP_THRESHOLD
                        }
                },
                {
                        "combined_image_sampler", "Combined Image Sampler Descriptors",
                        {
                                VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER,
                                (VK_SHADER_STAGE_VERTEX_BIT | VK_SHADER_STAGE_FRAGMENT_BIT),
                                RESOLUTION,
                                false,  // updateAfterBind
                                false,  // calculateInLoop
                                false,  // usesMipMaps
                                FUZZY_COMPARE, CMP_THRESHOLD
                        }
                },
        };

        for (int updateAfterBind = 0; updateAfterBind < 2; ++updateAfterBind)
        {
                for (int calculateInLoop = 0; calculateInLoop < 2; ++calculateInLoop)
                {
                        for (int usesMipMaps = 0; usesMipMaps < 2; ++usesMipMaps)
                        {
                                for (deUint32 caseIdx = 0; caseIdx < DE_LENGTH_OF_ARRAY(casesAfterBindAndLoopAndLOD); ++caseIdx)
                                {
                                        TestCaseInfo&   info                    (casesAfterBindAndLoopAndLOD[caseIdx]);
                                        std::string             caseName                (info.name);
                                        std::string             caseDescription (info.description);
                                        TestCaseParams  params                  (info.params);

                                        caseName                                += (updateAfterBind     ? "_after_bind" : "");
                                        caseName                                += (calculateInLoop ? "_in_loop"        : "");
                                        caseName                                += (usesMipMaps         ? "_with_lod"   : "");

                                        caseDescription                 += (updateAfterBind     ? " After Bind" : "");
                                        caseDescription                 += (calculateInLoop     ? " In Loop"    : "");
                                        caseDescription                 += (usesMipMaps         ? " Use LOD"    : "");

                                        params.updateAfterBind  = updateAfterBind       ? true                  : false;
                                        params.calculateInLoop  = calculateInLoop       ? true                  : false;
                                        params.usesMipMaps              = usesMipMaps           ? true                  : false;

                                        group->addChild(new DescriptorIndexingTestCase(context, caseName.c_str(), caseDescription.c_str(), params));
                                }
                        }
                }
        }

        TestCaseInfo casesNonAfterBindAndLoop[] =
        {
                {
                        "uniform_buffer", "Regular Uniform Buffer Descriptors",
                        {
                                VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER,
                                (VK_SHADER_STAGE_VERTEX_BIT | VK_SHADER_STAGE_FRAGMENT_BIT),
                                RESOLUTION,
                                false,  // updateAfterBind
                                false,  // calculateInLoop
                                false,  // usesMipMaps
                                FUZZY_COMPARE, CMP_THRESHOLD
                        }
                },
                {
                        "storage_buffer_dynamic", "Dynamic Storage Buffer Descriptors",
                        {
                                VK_DESCRIPTOR_TYPE_STORAGE_BUFFER_DYNAMIC,
                                (VK_SHADER_STAGE_VERTEX_BIT | VK_SHADER_STAGE_FRAGMENT_BIT),
                                RESOLUTION,
                                false,  // updateAfterBind
                                false,  // calculateInLoop
                                false,  // useMipMaps
                                FUZZY_COMPARE, CMP_THRESHOLD
                        }
                },
                {
                        "uniform_buffer_dynamic", "Dynamic Uniform Buffer Descriptors",
                        {
                                VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER_DYNAMIC,
                                (VK_SHADER_STAGE_VERTEX_BIT | VK_SHADER_STAGE_FRAGMENT_BIT),
                                RESOLUTION,
                                false,  // updateAfterBind
                                false,  // calculateInLoop
                                false,  // useMipMaps
                                FUZZY_COMPARE, CMP_THRESHOLD
                        }
                },
                {
                        "input_attachment", "Input Attachment Descriptors",
                        {
                                VK_DESCRIPTOR_TYPE_INPUT_ATTACHMENT,
                                (VK_SHADER_STAGE_VERTEX_BIT | VK_SHADER_STAGE_FRAGMENT_BIT),
                                RESOLUTION,
                                false,  // updateAfterBind
                                false,  // calculateInLoop
                                false,  // useMipMaps
                                FUZZY_COMPARE, CMP_THRESHOLD
                        }
                },
        };

        for (int calculateInLoop = 0; calculateInLoop < 2; ++calculateInLoop)
        {
                for (deUint32 caseIdx = 0; caseIdx < DE_LENGTH_OF_ARRAY(casesNonAfterBindAndLoop); ++caseIdx)
                {
                        TestCaseInfo&   info(casesNonAfterBindAndLoop[caseIdx]);
                        std::string             caseName(info.name);
                        std::string             caseDescription(info.description);
                        TestCaseParams  params(info.params);

                        caseName                                += (calculateInLoop     ? "_in_loop"    : "");

                        caseDescription                 += (calculateInLoop ? " In Loop"        : "");

                        params.calculateInLoop  = calculateInLoop       ? true                  : false;

                        group->addChild(new DescriptorIndexingTestCase(context, caseName.c_str(), caseDescription.c_str(), params));
                }
        }
}

} // - DescriptorIndexing
} // - vkt