kc3-lang/angle/src/libANGLE/renderer/vulkan/ProgramVk.cpp

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• Hash : a741abb9
  Author :
  Date : 2020-02-21T16:37:37
  

  Vulkan: Rename CommandGraphResource to Resource.
  
  Also renames the h and cpp files to ResourceVk (to keep distinct from
  other resource.h/cpp files) and renames 'onResourceAccess' to 'retain'.
  Cleans up a few remaining mentions of the command graph in comments.
  
  Bug: angleproject:4029
  Change-Id: Ifc8e880c8cea3fc48a4aec4730191c88aa35a076
  Reviewed-on: https://chromium-review.googlesource.com/c/angle/angle/+/2065920
  Commit-Queue: Jamie Madill <jmadill@chromium.org>
  Reviewed-by: Tim Van Patten <timvp@google.com>
  

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• src/libANGLE/renderer/vulkan/ProgramVk.cpp

• //
  // Copyright 2016 The ANGLE Project Authors. All rights reserved.
  // Use of this source code is governed by a BSD-style license that can be
  // found in the LICENSE file.
  //
  // ProgramVk.cpp:
  //    Implements the class methods for ProgramVk.
  //
  
  #include "libANGLE/renderer/vulkan/ProgramVk.h"
  
  #include "common/debug.h"
  #include "common/utilities.h"
  #include "libANGLE/Context.h"
  #include "libANGLE/ProgramLinkedResources.h"
  #include "libANGLE/renderer/glslang_wrapper_utils.h"
  #include "libANGLE/renderer/renderer_utils.h"
  #include "libANGLE/renderer/vulkan/BufferVk.h"
  #include "libANGLE/renderer/vulkan/GlslangWrapperVk.h"
  #include "libANGLE/renderer/vulkan/TextureVk.h"
  
  namespace rx
  {
  
  namespace
  {
  // This size is picked according to the required maxUniformBufferRange in the Vulkan spec.
  constexpr size_t kUniformBlockDynamicBufferMinSize = 16384u;
  
  // Identical to Std140 encoder in all aspects, except it ignores opaque uniform types.
  class VulkanDefaultBlockEncoder : public sh::Std140BlockEncoder
  {
    public:
      void advanceOffset(GLenum type,
                         const std::vector<unsigned int> &arraySizes,
                         bool isRowMajorMatrix,
                         int arrayStride,
                         int matrixStride) override
      {
          if (gl::IsOpaqueType(type))
          {
              return;
          }
  
          sh::Std140BlockEncoder::advanceOffset(type, arraySizes, isRowMajorMatrix, arrayStride,
                                                matrixStride);
      }
  };
  
  void InitDefaultUniformBlock(const std::vector<sh::ShaderVariable> &uniforms,
                               sh::BlockLayoutMap *blockLayoutMapOut,
                               size_t *blockSizeOut)
  {
      if (uniforms.empty())
      {
          *blockSizeOut = 0;
          return;
      }
  
      VulkanDefaultBlockEncoder blockEncoder;
      sh::GetActiveUniformBlockInfo(uniforms, "", &blockEncoder, blockLayoutMapOut);
  
      size_t blockSize = blockEncoder.getCurrentOffset();
  
      // TODO(jmadill): I think we still need a valid block for the pipeline even if zero sized.
      if (blockSize == 0)
      {
          *blockSizeOut = 0;
          return;
      }
  
      *blockSizeOut = blockSize;
      return;
  }
  
  template <typename T>
  void UpdateDefaultUniformBlock(GLsizei count,
                                 uint32_t arrayIndex,
                                 int componentCount,
                                 const T *v,
                                 const sh::BlockMemberInfo &layoutInfo,
                                 angle::MemoryBuffer *uniformData)
  {
      const int elementSize = sizeof(T) * componentCount;
  
      uint8_t *dst = uniformData->data() + layoutInfo.offset;
      if (layoutInfo.arrayStride == 0 || layoutInfo.arrayStride == elementSize)
      {
          uint32_t arrayOffset = arrayIndex * layoutInfo.arrayStride;
          uint8_t *writePtr    = dst + arrayOffset;
          ASSERT(writePtr + (elementSize * count) <= uniformData->data() + uniformData->size());
          memcpy(writePtr, v, elementSize * count);
      }
      else
      {
          // Have to respect the arrayStride between each element of the array.
          int maxIndex = arrayIndex + count;
          for (int writeIndex = arrayIndex, readIndex = 0; writeIndex < maxIndex;
               writeIndex++, readIndex++)
          {
              const int arrayOffset = writeIndex * layoutInfo.arrayStride;
              uint8_t *writePtr     = dst + arrayOffset;
              const T *readPtr      = v + (readIndex * componentCount);
              ASSERT(writePtr + elementSize <= uniformData->data() + uniformData->size());
              memcpy(writePtr, readPtr, elementSize);
          }
      }
  }
  
  template <typename T>
  void ReadFromDefaultUniformBlock(int componentCount,
                                   uint32_t arrayIndex,
                                   T *dst,
                                   const sh::BlockMemberInfo &layoutInfo,
                                   const angle::MemoryBuffer *uniformData)
  {
      ASSERT(layoutInfo.offset != -1);
  
      const int elementSize = sizeof(T) * componentCount;
      const uint8_t *source = uniformData->data() + layoutInfo.offset;
  
      if (layoutInfo.arrayStride == 0 || layoutInfo.arrayStride == elementSize)
      {
          const uint8_t *readPtr = source + arrayIndex * layoutInfo.arrayStride;
          memcpy(dst, readPtr, elementSize);
      }
      else
      {
          // Have to respect the arrayStride between each element of the array.
          const int arrayOffset  = arrayIndex * layoutInfo.arrayStride;
          const uint8_t *readPtr = source + arrayOffset;
          memcpy(dst, readPtr, elementSize);
      }
  }
  
  angle::Result SyncDefaultUniformBlock(ContextVk *contextVk,
                                        vk::DynamicBuffer *dynamicBuffer,
                                        const angle::MemoryBuffer &bufferData,
                                        uint32_t *outOffset,
                                        bool *outBufferModified)
  {
      dynamicBuffer->releaseInFlightBuffers(contextVk);
  
      ASSERT(!bufferData.empty());
      uint8_t *data       = nullptr;
      VkBuffer *outBuffer = nullptr;
      VkDeviceSize offset = 0;
      ANGLE_TRY(dynamicBuffer->allocate(contextVk, bufferData.size(), &data, outBuffer, &offset,
                                        outBufferModified));
      *outOffset = static_cast<uint32_t>(offset);
      memcpy(data, bufferData.data(), bufferData.size());
      ANGLE_TRY(dynamicBuffer->flush(contextVk));
      return angle::Result::Continue;
  }
  
  uint32_t GetInterfaceBlockArraySize(const std::vector<gl::InterfaceBlock> &blocks,
                                      uint32_t bufferIndex)
  {
      const gl::InterfaceBlock &block = blocks[bufferIndex];
  
      if (!block.isArray)
      {
          return 1;
      }
  
      ASSERT(block.arrayElement == 0);
  
      // Search consecutively until all array indices of this block are visited.
      uint32_t arraySize;
      for (arraySize = 1; bufferIndex + arraySize < blocks.size(); ++arraySize)
      {
          const gl::InterfaceBlock &nextBlock = blocks[bufferIndex + arraySize];
  
          if (nextBlock.arrayElement != arraySize)
          {
              break;
          }
  
          // It's unexpected for an array to start at a non-zero array size, so we can always rely on
          // the sequential `arrayElement`s to belong to the same block.
          ASSERT(nextBlock.name == block.name);
          ASSERT(nextBlock.isArray);
      }
  
      return arraySize;
  }
  
  void AddInterfaceBlockDescriptorSetDesc(const std::vector<gl::InterfaceBlock> &blocks,
                                          uint32_t bindingStart,
                                          VkDescriptorType descType,
                                          vk::DescriptorSetLayoutDesc *descOut)
  {
      uint32_t bindingIndex = 0;
      for (uint32_t bufferIndex = 0; bufferIndex < blocks.size();)
      {
          const uint32_t arraySize = GetInterfaceBlockArraySize(blocks, bufferIndex);
          VkShaderStageFlags activeStages =
              gl_vk::GetShaderStageFlags(blocks[bufferIndex].activeShaders());
  
          descOut->update(bindingStart + bindingIndex, descType, arraySize, activeStages);
  
          bufferIndex += arraySize;
          ++bindingIndex;
      }
  }
  
  void AddAtomicCounterBufferDescriptorSetDesc(
      const std::vector<gl::AtomicCounterBuffer> &atomicCounterBuffers,
      uint32_t bindingStart,
      vk::DescriptorSetLayoutDesc *descOut)
  {
      if (atomicCounterBuffers.empty())
      {
          return;
      }
  
      VkShaderStageFlags activeStages = 0;
      for (const gl::AtomicCounterBuffer &buffer : atomicCounterBuffers)
      {
          activeStages |= gl_vk::GetShaderStageFlags(buffer.activeShaders());
      }
  
      // A single storage buffer array is used for all stages for simplicity.
      descOut->update(bindingStart, VK_DESCRIPTOR_TYPE_STORAGE_BUFFER,
                      gl::IMPLEMENTATION_MAX_ATOMIC_COUNTER_BUFFERS, activeStages);
  }
  
  void AddImageDescriptorSetDesc(const gl::ProgramState &programState,
                                 uint32_t bindingStart,
                                 vk::DescriptorSetLayoutDesc *descOut)
  {
      const std::vector<gl::ImageBinding> &imageBindings = programState.getImageBindings();
      const std::vector<gl::LinkedUniform> &uniforms     = programState.getUniforms();
  
      for (uint32_t imageIndex = 0; imageIndex < imageBindings.size(); ++imageIndex)
      {
          const gl::ImageBinding &imageBinding = imageBindings[imageIndex];
  
          uint32_t uniformIndex = programState.getUniformIndexFromImageIndex(imageIndex);
          const gl::LinkedUniform &imageUniform = uniforms[uniformIndex];
  
          // The front-end always binds array image units sequentially.
          uint32_t arraySize = static_cast<uint32_t>(imageBinding.boundImageUnits.size());
          VkShaderStageFlags activeStages = gl_vk::GetShaderStageFlags(imageUniform.activeShaders());
  
          uint32_t bindingIndex = bindingStart + imageIndex;
          descOut->update(bindingIndex, VK_DESCRIPTOR_TYPE_STORAGE_IMAGE, arraySize, activeStages);
      }
  }
  
  void AddTextureDescriptorSetDesc(const gl::ProgramState &programState,
                                   bool useOldRewriteStructSamplers,
                                   vk::DescriptorSetLayoutDesc *descOut)
  {
      uint32_t bindingIndex                                  = 0;
      const std::vector<gl::SamplerBinding> &samplerBindings = programState.getSamplerBindings();
      const std::vector<gl::LinkedUniform> &uniforms         = programState.getUniforms();
  
      for (uint32_t textureIndex = 0; textureIndex < samplerBindings.size(); ++textureIndex)
      {
          const gl::SamplerBinding &samplerBinding = samplerBindings[textureIndex];
  
          uint32_t uniformIndex = programState.getUniformIndexFromSamplerIndex(textureIndex);
          const gl::LinkedUniform &samplerUniform = uniforms[uniformIndex];
  
          // The front-end always binds array sampler units sequentially.
          uint32_t arraySize = static_cast<uint32_t>(samplerBinding.boundTextureUnits.size());
          VkShaderStageFlags activeStages =
              gl_vk::GetShaderStageFlags(samplerUniform.activeShaders());
  
          if (!useOldRewriteStructSamplers)
          {
              // 2D arrays are split into multiple 1D arrays when generating
              // LinkedUniforms. Since they are flattened into one array, ignore the
              // nonzero elements and expand the array to the total array size.
              if (gl::SamplerNameContainsNonZeroArrayElement(samplerUniform.name))
              {
                  continue;
              }
  
              for (unsigned int outerArraySize : samplerUniform.outerArraySizes)
              {
                  arraySize *= outerArraySize;
              }
          }
  
          descOut->update(bindingIndex++, VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER, arraySize,
                          activeStages);
      }
  }
  
  void WriteBufferDescriptorSetBinding(const gl::OffsetBindingPointer<gl::Buffer> &bufferBinding,
                                       VkDeviceSize maxSize,
                                       VkDescriptorSet descSet,
                                       VkDescriptorType descType,
                                       uint32_t bindingIndex,
                                       uint32_t arrayElement,
                                       VkDeviceSize requiredOffsetAlignment,
                                       VkDescriptorBufferInfo *bufferInfoOut,
                                       VkWriteDescriptorSet *writeInfoOut)
  {
      gl::Buffer *buffer = bufferBinding.get();
      ASSERT(buffer != nullptr);
  
      // Make sure there's no possible under/overflow with binding size.
      static_assert(sizeof(VkDeviceSize) >= sizeof(bufferBinding.getSize()),
                    "VkDeviceSize too small");
      ASSERT(bufferBinding.getSize() >= 0);
  
      BufferVk *bufferVk             = vk::GetImpl(buffer);
      VkDeviceSize offset            = bufferBinding.getOffset();
      VkDeviceSize size              = bufferBinding.getSize();
      vk::BufferHelper &bufferHelper = bufferVk->getBuffer();
  
      // If size is 0, we can't always use VK_WHOLE_SIZE (or bufferHelper.getSize()), as the
      // backing buffer may be larger than max*BufferRange.  In that case, we use the minimum of
      // the backing buffer size (what's left after offset) and the buffer size as defined by the
      // shader.  That latter is only valid for UBOs, as SSBOs may have variable length arrays.
      size = size > 0 ? size : (bufferHelper.getSize() - offset);
      if (maxSize > 0)
      {
          size = std::min(size, maxSize);
      }
  
      // If requiredOffsetAlignment is 0, the buffer offset is guaranteed to have the necessary
      // alignment through other means (the backend specifying the alignment through a GLES limit that
      // the frontend then enforces).  If it's not 0, we need to bind the buffer at an offset that's
      // aligned.  The difference in offsets is communicated to the shader via driver uniforms.
      if (requiredOffsetAlignment)
      {
          VkDeviceSize alignedOffset = (offset / requiredOffsetAlignment) * requiredOffsetAlignment;
          VkDeviceSize offsetDiff    = offset - alignedOffset;
  
          offset = alignedOffset;
          size += offsetDiff;
      }
  
      bufferInfoOut->buffer = bufferHelper.getBuffer().getHandle();
      bufferInfoOut->offset = offset;
      bufferInfoOut->range  = size;
  
      writeInfoOut->sType            = VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET;
      writeInfoOut->pNext            = nullptr;
      writeInfoOut->dstSet           = descSet;
      writeInfoOut->dstBinding       = bindingIndex;
      writeInfoOut->dstArrayElement  = arrayElement;
      writeInfoOut->descriptorCount  = 1;
      writeInfoOut->descriptorType   = descType;
      writeInfoOut->pImageInfo       = nullptr;
      writeInfoOut->pBufferInfo      = bufferInfoOut;
      writeInfoOut->pTexelBufferView = nullptr;
      ASSERT(writeInfoOut->pBufferInfo[0].buffer != VK_NULL_HANDLE);
  }
  
  class Std140BlockLayoutEncoderFactory : public gl::CustomBlockLayoutEncoderFactory
  {
    public:
      sh::BlockLayoutEncoder *makeEncoder() override { return new sh::Std140BlockEncoder(); }
  };
  }  // anonymous namespace
  
  // ProgramVk::ShaderInfo implementation.
  ProgramVk::ShaderInfo::ShaderInfo() {}
  
  ProgramVk::ShaderInfo::~ShaderInfo() = default;
  
  angle::Result ProgramVk::ShaderInfo::initShaders(
      ContextVk *contextVk,
      const gl::ShaderMap<std::string> &shaderSources,
      const ShaderInterfaceVariableInfoMap &variableInfoMap)
  {
      ASSERT(!valid());
  
      ANGLE_TRY(GlslangWrapperVk::GetShaderCode(contextVk, contextVk->getCaps(), shaderSources,
                                                variableInfoMap, &mSpirvBlobs));
  
      mIsInitialized = true;
      return angle::Result::Continue;
  }
  
  void ProgramVk::ShaderInfo::release(ContextVk *contextVk)
  {
      for (SpirvBlob &spirvBlob : mSpirvBlobs)
      {
          spirvBlob.clear();
      }
      mIsInitialized = false;
  }
  
  void ProgramVk::ShaderInfo::load(gl::BinaryInputStream *stream)
  {
      // Read in shader codes for all shader types
      for (const gl::ShaderType shaderType : gl::AllShaderTypes())
      {
          SpirvBlob *spirvBlob = &mSpirvBlobs[shaderType];
  
          // Read the SPIR-V
          stream->readIntVector<uint32_t>(spirvBlob);
      }
  
      mIsInitialized = true;
  }
  
  void ProgramVk::ShaderInfo::save(gl::BinaryOutputStream *stream)
  {
      ASSERT(valid());
  
      // Write out shader codes for all shader types
      for (const gl::ShaderType shaderType : gl::AllShaderTypes())
      {
          const SpirvBlob &spirvBlob = mSpirvBlobs[shaderType];
  
          // Write the SPIR-V
          stream->writeIntVector(spirvBlob);
      }
  }
  
  // ProgramVk::ProgramInfo implementation.
  ProgramVk::ProgramInfo::ProgramInfo() {}
  
  ProgramVk::ProgramInfo::~ProgramInfo() = default;
  
  angle::Result ProgramVk::ProgramInfo::initProgram(ContextVk *contextVk,
                                                    const ShaderInfo &shaderInfo,
                                                    bool enableLineRasterEmulation)
  {
      const gl::ShaderMap<SpirvBlob> &spirvBlobs = shaderInfo.getSpirvBlobs();
  
      for (const gl::ShaderType shaderType : gl::AllShaderTypes())
      {
          const SpirvBlob &spirvBlob = spirvBlobs[shaderType];
  
          if (!spirvBlob.empty())
          {
              ANGLE_TRY(vk::InitShaderAndSerial(contextVk, &mShaders[shaderType].get(),
                                                spirvBlob.data(),
                                                spirvBlob.size() * sizeof(uint32_t)));
  
              mProgramHelper.setShader(shaderType, &mShaders[shaderType]);
          }
      }
  
      if (enableLineRasterEmulation)
      {
          mProgramHelper.enableSpecializationConstant(
              sh::vk::SpecializationConstantId::LineRasterEmulation);
      }
  
      return angle::Result::Continue;
  }
  
  void ProgramVk::ProgramInfo::release(ContextVk *contextVk)
  {
      mProgramHelper.release(contextVk);
  
      for (vk::RefCounted<vk::ShaderAndSerial> &shader : mShaders)
      {
          shader.get().destroy(contextVk->getDevice());
      }
  }
  
  // ProgramVk implementation.
  ProgramVk::DefaultUniformBlock::DefaultUniformBlock() {}
  
  ProgramVk::DefaultUniformBlock::~DefaultUniformBlock() = default;
  
  ProgramVk::ProgramVk(const gl::ProgramState &state)
      : ProgramImpl(state),
        mDynamicBufferOffsets{},
        mStorageBlockBindingsOffset(0),
        mAtomicCounterBufferBindingsOffset(0),
        mImageBindingsOffset(0)
  {}
  
  ProgramVk::~ProgramVk() = default;
  
  void ProgramVk::destroy(const gl::Context *context)
  {
      ContextVk *contextVk = vk::GetImpl(context);
      reset(contextVk);
  }
  
  void ProgramVk::reset(ContextVk *contextVk)
  {
      for (auto &descriptorSetLayout : mDescriptorSetLayouts)
      {
          descriptorSetLayout.reset();
      }
      mPipelineLayout.reset();
  
      RendererVk *renderer = contextVk->getRenderer();
  
      for (auto &uniformBlock : mDefaultUniformBlocks)
      {
          uniformBlock.storage.release(renderer);
      }
  
      mShaderInfo.release(contextVk);
      mDefaultProgramInfo.release(contextVk);
      mLineRasterProgramInfo.release(contextVk);
  
      mEmptyBuffer.release(renderer);
  
      mDescriptorSets.clear();
      mEmptyDescriptorSets.fill(VK_NULL_HANDLE);
  
      for (vk::RefCountedDescriptorPoolBinding &binding : mDescriptorPoolBindings)
      {
          binding.reset();
      }
  
      for (vk::DynamicDescriptorPool &descriptorPool : mDynamicDescriptorPools)
      {
          descriptorPool.release(contextVk);
      }
  
      mTextureDescriptorsCache.clear();
      mDescriptorBuffersCache.clear();
  }
  
  std::unique_ptr<rx::LinkEvent> ProgramVk::load(const gl::Context *context,
                                                 gl::BinaryInputStream *stream,
                                                 gl::InfoLog &infoLog)
  {
      ContextVk *contextVk = vk::GetImpl(context);
      gl::ShaderMap<size_t> requiredBufferSize;
      requiredBufferSize.fill(0);
  
      reset(contextVk);
  
      mShaderInfo.load(stream);
  
      // Deserializes the uniformLayout data of mDefaultUniformBlocks
      for (gl::ShaderType shaderType : gl::AllShaderTypes())
      {
          const size_t uniformCount = stream->readInt<size_t>();
          for (unsigned int uniformIndex = 0; uniformIndex < uniformCount; ++uniformIndex)
          {
              sh::BlockMemberInfo blockInfo;
              gl::LoadBlockMemberInfo(stream, &blockInfo);
              mDefaultUniformBlocks[shaderType].uniformLayout.push_back(blockInfo);
          }
      }
  
      // Deserializes required uniform block memory sizes
      for (gl::ShaderType shaderType : gl::AllShaderTypes())
      {
          requiredBufferSize[shaderType] = stream->readInt<size_t>();
      }
  
      // Initialize and resize the mDefaultUniformBlocks' memory
      angle::Result status = resizeUniformBlockMemory(contextVk, requiredBufferSize);
      if (status != angle::Result::Continue)
      {
          return std::make_unique<LinkEventDone>(status);
      }
  
      return std::make_unique<LinkEventDone>(linkImpl(context, infoLog));
  }
  
  void ProgramVk::save(const gl::Context *context, gl::BinaryOutputStream *stream)
  {
      mShaderInfo.save(stream);
  
      // Serializes the uniformLayout data of mDefaultUniformBlocks
      for (gl::ShaderType shaderType : gl::AllShaderTypes())
      {
          const size_t uniformCount = mDefaultUniformBlocks[shaderType].uniformLayout.size();
          stream->writeInt<size_t>(uniformCount);
          for (unsigned int uniformIndex = 0; uniformIndex < uniformCount; ++uniformIndex)
          {
              sh::BlockMemberInfo &blockInfo =
                  mDefaultUniformBlocks[shaderType].uniformLayout[uniformIndex];
              gl::WriteBlockMemberInfo(stream, blockInfo);
          }
      }
  
      // Serializes required uniform block memory sizes
      for (gl::ShaderType shaderType : gl::AllShaderTypes())
      {
          stream->writeInt(mDefaultUniformBlocks[shaderType].uniformData.size());
      }
  }
  
  void ProgramVk::setBinaryRetrievableHint(bool retrievable)
  {
      UNIMPLEMENTED();
  }
  
  void ProgramVk::setSeparable(bool separable)
  {
      // Nohting to do here yet.
  }
  
  std::unique_ptr<LinkEvent> ProgramVk::link(const gl::Context *context,
                                             const gl::ProgramLinkedResources &resources,
                                             gl::InfoLog &infoLog)
  {
      ContextVk *contextVk = vk::GetImpl(context);
      // Link resources before calling GetShaderSource to make sure they are ready for the set/binding
      // assignment done in that function.
      linkResources(resources);
  
      reset(contextVk);
  
      // Gather variable info and transform sources.
      gl::ShaderMap<std::string> shaderSources;
      ShaderInterfaceVariableInfoMap variableInfoMap;
      GlslangWrapperVk::GetShaderSource(contextVk->getRenderer()->getFeatures(), mState, resources,
                                        &shaderSources, &variableInfoMap);
  
      // Compile the shaders.
      angle::Result status = mShaderInfo.initShaders(contextVk, shaderSources, variableInfoMap);
      if (status != angle::Result::Continue)
      {
          return std::make_unique<LinkEventDone>(status);
      }
  
      status = initDefaultUniformBlocks(context);
      if (status != angle::Result::Continue)
      {
          return std::make_unique<LinkEventDone>(status);
      }
  
      // TODO(jie.a.chen@intel.com): Parallelize linking.
      // http://crbug.com/849576
      return std::make_unique<LinkEventDone>(linkImpl(context, infoLog));
  }
  
  angle::Result ProgramVk::linkImpl(const gl::Context *glContext, gl::InfoLog &infoLog)
  {
      const gl::State &glState                 = glContext->getState();
      ContextVk *contextVk                     = vk::GetImpl(glContext);
      RendererVk *renderer                     = contextVk->getRenderer();
      gl::TransformFeedback *transformFeedback = glState.getCurrentTransformFeedback();
  
      updateBindingOffsets();
  
      // Store a reference to the pipeline and descriptor set layouts. This will create them if they
      // don't already exist in the cache.
  
      // Default uniforms and transform feedback:
      vk::DescriptorSetLayoutDesc uniformsAndXfbSetDesc;
      uint32_t uniformBindingIndex = 0;
      for (const gl::ShaderType shaderType : mState.getLinkedShaderStages())
      {
          uniformsAndXfbSetDesc.update(uniformBindingIndex++,
                                       VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER_DYNAMIC, 1,
                                       gl_vk::kShaderStageMap[shaderType]);
      }
      if (mState.hasLinkedShaderStage(gl::ShaderType::Vertex) && transformFeedback &&
          !mState.getLinkedTransformFeedbackVaryings().empty())
      {
          TransformFeedbackVk *transformFeedbackVk = vk::GetImpl(transformFeedback);
          transformFeedbackVk->updateDescriptorSetLayout(contextVk, mState, &uniformsAndXfbSetDesc);
      }
  
      ANGLE_TRY(renderer->getDescriptorSetLayout(
          contextVk, uniformsAndXfbSetDesc,
          &mDescriptorSetLayouts[kUniformsAndXfbDescriptorSetIndex]));
  
      // Uniform and storage buffers, atomic counter buffers and images:
      vk::DescriptorSetLayoutDesc resourcesSetDesc;
  
      AddInterfaceBlockDescriptorSetDesc(mState.getUniformBlocks(), getUniformBlockBindingsOffset(),
                                         VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER, &resourcesSetDesc);
      AddInterfaceBlockDescriptorSetDesc(mState.getShaderStorageBlocks(),
                                         getStorageBlockBindingsOffset(),
                                         VK_DESCRIPTOR_TYPE_STORAGE_BUFFER, &resourcesSetDesc);
      AddAtomicCounterBufferDescriptorSetDesc(mState.getAtomicCounterBuffers(),
                                              getAtomicCounterBufferBindingsOffset(),
                                              &resourcesSetDesc);
      AddImageDescriptorSetDesc(mState, getImageBindingsOffset(), &resourcesSetDesc);
  
      ANGLE_TRY(renderer->getDescriptorSetLayout(
          contextVk, resourcesSetDesc, &mDescriptorSetLayouts[kShaderResourceDescriptorSetIndex]));
  
      // Textures:
      vk::DescriptorSetLayoutDesc texturesSetDesc;
  
      AddTextureDescriptorSetDesc(mState, contextVk->useOldRewriteStructSamplers(), &texturesSetDesc);
  
      ANGLE_TRY(renderer->getDescriptorSetLayout(contextVk, texturesSetDesc,
                                                 &mDescriptorSetLayouts[kTextureDescriptorSetIndex]));
  
      // Driver uniforms:
      VkShaderStageFlags driverUniformsStages =
          mState.isCompute() ? VK_SHADER_STAGE_COMPUTE_BIT : VK_SHADER_STAGE_ALL_GRAPHICS;
      vk::DescriptorSetLayoutDesc driverUniformsSetDesc =
          contextVk->getDriverUniformsDescriptorSetDesc(driverUniformsStages);
      ANGLE_TRY(renderer->getDescriptorSetLayout(
          contextVk, driverUniformsSetDesc,
          &mDescriptorSetLayouts[kDriverUniformsDescriptorSetIndex]));
  
      // Create pipeline layout with these 4 descriptor sets.
      vk::PipelineLayoutDesc pipelineLayoutDesc;
      pipelineLayoutDesc.updateDescriptorSetLayout(kUniformsAndXfbDescriptorSetIndex,
                                                   uniformsAndXfbSetDesc);
      pipelineLayoutDesc.updateDescriptorSetLayout(kShaderResourceDescriptorSetIndex,
                                                   resourcesSetDesc);
      pipelineLayoutDesc.updateDescriptorSetLayout(kTextureDescriptorSetIndex, texturesSetDesc);
      pipelineLayoutDesc.updateDescriptorSetLayout(kDriverUniformsDescriptorSetIndex,
                                                   driverUniformsSetDesc);
  
      ANGLE_TRY(renderer->getPipelineLayout(contextVk, pipelineLayoutDesc, mDescriptorSetLayouts,
                                            &mPipelineLayout));
  
      // Initialize descriptor pools.
      std::array<VkDescriptorPoolSize, 2> uniformAndXfbSetSize = {
          {{VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER_DYNAMIC,
            static_cast<uint32_t>(mState.getLinkedShaderStageCount())},
           {VK_DESCRIPTOR_TYPE_STORAGE_BUFFER, gl::IMPLEMENTATION_MAX_TRANSFORM_FEEDBACK_BUFFERS}}};
  
      uint32_t uniformBlockCount = static_cast<uint32_t>(mState.getUniformBlocks().size());
      uint32_t storageBlockCount = static_cast<uint32_t>(mState.getShaderStorageBlocks().size());
      uint32_t atomicCounterBufferCount =
          static_cast<uint32_t>(mState.getAtomicCounterBuffers().size());
      uint32_t imageCount   = static_cast<uint32_t>(mState.getImageBindings().size());
      uint32_t textureCount = static_cast<uint32_t>(mState.getSamplerBindings().size());
  
      if (renderer->getFeatures().bindEmptyForUnusedDescriptorSets.enabled)
      {
          // For this workaround, we have to create an empty descriptor set for each descriptor set
          // index, so make sure their pools are initialized.
          uniformBlockCount = std::max(uniformBlockCount, 1u);
          textureCount      = std::max(textureCount, 1u);
      }
  
      constexpr size_t kResourceTypesInResourcesSet = 3;
      angle::FixedVector<VkDescriptorPoolSize, kResourceTypesInResourcesSet> resourceSetSize;
      if (uniformBlockCount > 0)
      {
          resourceSetSize.emplace_back(VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER, uniformBlockCount);
      }
      if (storageBlockCount > 0 || atomicCounterBufferCount > 0)
      {
          // Note that we always use an array of IMPLEMENTATION_MAX_ATOMIC_COUNTER_BUFFERS storage
          // buffers for emulating atomic counters, so if there are any atomic counter buffers, we
          // need to allocate IMPLEMENTATION_MAX_ATOMIC_COUNTER_BUFFERS descriptors.
          const uint32_t atomicCounterStorageBufferCount =
              atomicCounterBufferCount > 0 ? gl::IMPLEMENTATION_MAX_ATOMIC_COUNTER_BUFFERS : 0;
          const uint32_t storageBufferDescCount = storageBlockCount + atomicCounterStorageBufferCount;
          resourceSetSize.emplace_back(VK_DESCRIPTOR_TYPE_STORAGE_BUFFER, storageBufferDescCount);
      }
      if (imageCount > 0)
      {
          resourceSetSize.emplace_back(VK_DESCRIPTOR_TYPE_STORAGE_IMAGE, imageCount);
      }
  
      VkDescriptorPoolSize textureSetSize = {VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER, textureCount};
  
      ANGLE_TRY(mDynamicDescriptorPools[kUniformsAndXfbDescriptorSetIndex].init(
          contextVk, uniformAndXfbSetSize.data(), uniformAndXfbSetSize.size()));
      if (resourceSetSize.size() > 0)
      {
          ANGLE_TRY(mDynamicDescriptorPools[kShaderResourceDescriptorSetIndex].init(
              contextVk, resourceSetSize.data(), static_cast<uint32_t>(resourceSetSize.size())));
      }
      if (textureCount > 0)
      {
          ANGLE_TRY(mDynamicDescriptorPools[kTextureDescriptorSetIndex].init(contextVk,
                                                                             &textureSetSize, 1));
      }
  
      mDynamicBufferOffsets.resize(mState.getLinkedShaderStageCount());
  
      // Initialize an "empty" buffer for use with default uniform blocks where there are no uniforms,
      // or atomic counter buffer array indices that are unused.
      constexpr VkBufferUsageFlags kEmptyBufferUsage =
          VK_BUFFER_USAGE_UNIFORM_BUFFER_BIT | VK_BUFFER_USAGE_STORAGE_BUFFER_BIT;
  
      VkBufferCreateInfo emptyBufferInfo    = {};
      emptyBufferInfo.sType                 = VK_STRUCTURE_TYPE_BUFFER_CREATE_INFO;
      emptyBufferInfo.flags                 = 0;
      emptyBufferInfo.size                  = 4;
      emptyBufferInfo.usage                 = kEmptyBufferUsage;
      emptyBufferInfo.sharingMode           = VK_SHARING_MODE_EXCLUSIVE;
      emptyBufferInfo.queueFamilyIndexCount = 0;
      emptyBufferInfo.pQueueFamilyIndices   = nullptr;
  
      constexpr VkMemoryPropertyFlags kMemoryType = VK_MEMORY_PROPERTY_DEVICE_LOCAL_BIT;
      return mEmptyBuffer.init(contextVk, emptyBufferInfo, kMemoryType);
  }
  
  void ProgramVk::updateBindingOffsets()
  {
      mStorageBlockBindingsOffset = static_cast<uint32_t>(mState.getUniqueUniformBlockCount());
  
      mAtomicCounterBufferBindingsOffset =
          static_cast<uint32_t>(mStorageBlockBindingsOffset + mState.getUniqueStorageBlockCount());
  
      uint32_t atomicCounterBindingCount = mState.getAtomicCounterBuffers().empty() ? 0 : 1;
      mImageBindingsOffset = mAtomicCounterBufferBindingsOffset + atomicCounterBindingCount;
  }
  
  void ProgramVk::linkResources(const gl::ProgramLinkedResources &resources)
  {
      Std140BlockLayoutEncoderFactory std140EncoderFactory;
      gl::ProgramLinkedResourcesLinker linker(&std140EncoderFactory);
  
      linker.linkResources(mState, resources);
  }
  
  angle::Result ProgramVk::initDefaultUniformBlocks(const gl::Context *glContext)
  {
      ContextVk *contextVk = vk::GetImpl(glContext);
  
      // Process vertex and fragment uniforms into std140 packing.
      gl::ShaderMap<sh::BlockLayoutMap> layoutMap;
      gl::ShaderMap<size_t> requiredBufferSize;
      requiredBufferSize.fill(0);
  
      generateUniformLayoutMapping(layoutMap, requiredBufferSize);
      initDefaultUniformLayoutMapping(layoutMap);
  
      // All uniform initializations are complete, now resize the buffers accordingly and return
      return resizeUniformBlockMemory(contextVk, requiredBufferSize);
  }
  
  void ProgramVk::generateUniformLayoutMapping(gl::ShaderMap<sh::BlockLayoutMap> &layoutMap,
                                               gl::ShaderMap<size_t> &requiredBufferSize)
  {
      for (const gl::ShaderType shaderType : mState.getLinkedShaderStages())
      {
          gl::Shader *shader = mState.getAttachedShader(shaderType);
  
          if (shader)
          {
              const std::vector<sh::ShaderVariable> &uniforms = shader->getUniforms();
              InitDefaultUniformBlock(uniforms, &layoutMap[shaderType],
                                      &requiredBufferSize[shaderType]);
          }
      }
  }
  
  void ProgramVk::initDefaultUniformLayoutMapping(gl::ShaderMap<sh::BlockLayoutMap> &layoutMap)
  {
      // Init the default block layout info.
      const auto &uniforms = mState.getUniforms();
      for (const gl::VariableLocation &location : mState.getUniformLocations())
      {
          gl::ShaderMap<sh::BlockMemberInfo> layoutInfo;
  
          if (location.used() && !location.ignored)
          {
              const auto &uniform = uniforms[location.index];
              if (uniform.isInDefaultBlock() && !uniform.isSampler() && !uniform.isImage())
              {
                  std::string uniformName = uniform.name;
                  if (uniform.isArray())
                  {
                      // Gets the uniform name without the [0] at the end.
                      uniformName = gl::StripLastArrayIndex(uniformName);
                      ASSERT(uniformName.size() != uniform.name.size());
                  }
  
                  bool found = false;
  
                  for (const gl::ShaderType shaderType : mState.getLinkedShaderStages())
                  {
                      auto it = layoutMap[shaderType].find(uniformName);
                      if (it != layoutMap[shaderType].end())
                      {
                          found                  = true;
                          layoutInfo[shaderType] = it->second;
                      }
                  }
  
                  ASSERT(found);
              }
          }
  
          for (const gl::ShaderType shaderType : mState.getLinkedShaderStages())
          {
              mDefaultUniformBlocks[shaderType].uniformLayout.push_back(layoutInfo[shaderType]);
          }
      }
  }
  
  angle::Result ProgramVk::resizeUniformBlockMemory(ContextVk *contextVk,
                                                    gl::ShaderMap<size_t> &requiredBufferSize)
  {
      RendererVk *renderer = contextVk->getRenderer();
      for (const gl::ShaderType shaderType : mState.getLinkedShaderStages())
      {
          if (requiredBufferSize[shaderType] > 0)
          {
              if (!mDefaultUniformBlocks[shaderType].uniformData.resize(
                      requiredBufferSize[shaderType]))
              {
                  ANGLE_VK_CHECK(contextVk, false, VK_ERROR_OUT_OF_HOST_MEMORY);
              }
              size_t minAlignment = static_cast<size_t>(
                  renderer->getPhysicalDeviceProperties().limits.minUniformBufferOffsetAlignment);
  
              mDefaultUniformBlocks[shaderType].storage.init(
                  renderer, VK_BUFFER_USAGE_UNIFORM_BUFFER_BIT | VK_BUFFER_USAGE_TRANSFER_SRC_BIT,
                  minAlignment, kUniformBlockDynamicBufferMinSize, true);
  
              // Initialize uniform buffer memory to zero by default.
              mDefaultUniformBlocks[shaderType].uniformData.fill(0);
              mDefaultUniformBlocksDirty.set(shaderType);
          }
      }
  
      return angle::Result::Continue;
  }
  
  GLboolean ProgramVk::validate(const gl::Caps &caps, gl::InfoLog *infoLog)
  {
      // No-op. The spec is very vague about the behavior of validation.
      return GL_TRUE;
  }
  
  template <typename T>
  void ProgramVk::setUniformImpl(GLint location, GLsizei count, const T *v, GLenum entryPointType)
  {
      const gl::VariableLocation &locationInfo = mState.getUniformLocations()[location];
      const gl::LinkedUniform &linkedUniform   = mState.getUniforms()[locationInfo.index];
  
      ASSERT(!linkedUniform.isSampler());
  
      if (linkedUniform.typeInfo->type == entryPointType)
      {
          for (const gl::ShaderType shaderType : mState.getLinkedShaderStages())
          {
              DefaultUniformBlock &uniformBlock     = mDefaultUniformBlocks[shaderType];
              const sh::BlockMemberInfo &layoutInfo = uniformBlock.uniformLayout[location];
  
              // Assume an offset of -1 means the block is unused.
              if (layoutInfo.offset == -1)
              {
                  continue;
              }
  
              const GLint componentCount = linkedUniform.typeInfo->componentCount;
              UpdateDefaultUniformBlock(count, locationInfo.arrayIndex, componentCount, v, layoutInfo,
                                        &uniformBlock.uniformData);
              mDefaultUniformBlocksDirty.set(shaderType);
          }
      }
      else
      {
          for (const gl::ShaderType shaderType : mState.getLinkedShaderStages())
          {
              DefaultUniformBlock &uniformBlock     = mDefaultUniformBlocks[shaderType];
              const sh::BlockMemberInfo &layoutInfo = uniformBlock.uniformLayout[location];
  
              // Assume an offset of -1 means the block is unused.
              if (layoutInfo.offset == -1)
              {
                  continue;
              }
  
              const GLint componentCount = linkedUniform.typeInfo->componentCount;
  
              ASSERT(linkedUniform.typeInfo->type == gl::VariableBoolVectorType(entryPointType));
  
              GLint initialArrayOffset =
                  locationInfo.arrayIndex * layoutInfo.arrayStride + layoutInfo.offset;
              for (GLint i = 0; i < count; i++)
              {
                  GLint elementOffset = i * layoutInfo.arrayStride + initialArrayOffset;
                  GLint *dest =
                      reinterpret_cast<GLint *>(uniformBlock.uniformData.data() + elementOffset);
                  const T *source = v + i * componentCount;
  
                  for (int c = 0; c < componentCount; c++)
                  {
                      dest[c] = (source[c] == static_cast<T>(0)) ? GL_FALSE : GL_TRUE;
                  }
              }
  
              mDefaultUniformBlocksDirty.set(shaderType);
          }
      }
  }
  
  template <typename T>
  void ProgramVk::getUniformImpl(GLint location, T *v, GLenum entryPointType) const
  {
      const gl::VariableLocation &locationInfo = mState.getUniformLocations()[location];
      const gl::LinkedUniform &linkedUniform   = mState.getUniforms()[locationInfo.index];
  
      ASSERT(!linkedUniform.isSampler() && !linkedUniform.isImage());
  
      const gl::ShaderType shaderType = linkedUniform.getFirstShaderTypeWhereActive();
      ASSERT(shaderType != gl::ShaderType::InvalidEnum);
  
      const DefaultUniformBlock &uniformBlock = mDefaultUniformBlocks[shaderType];
      const sh::BlockMemberInfo &layoutInfo   = uniformBlock.uniformLayout[location];
  
      ASSERT(linkedUniform.typeInfo->componentType == entryPointType ||
             linkedUniform.typeInfo->componentType == gl::VariableBoolVectorType(entryPointType));
  
      if (gl::IsMatrixType(linkedUniform.type))
      {
          const uint8_t *ptrToElement = uniformBlock.uniformData.data() + layoutInfo.offset +
                                        (locationInfo.arrayIndex * layoutInfo.arrayStride);
          GetMatrixUniform(linkedUniform.type, v, reinterpret_cast<const T *>(ptrToElement), false);
      }
      else
      {
          ReadFromDefaultUniformBlock(linkedUniform.typeInfo->componentCount, locationInfo.arrayIndex,
                                      v, layoutInfo, &uniformBlock.uniformData);
      }
  }
  
  void ProgramVk::setUniform1fv(GLint location, GLsizei count, const GLfloat *v)
  {
      setUniformImpl(location, count, v, GL_FLOAT);
  }
  
  void ProgramVk::setUniform2fv(GLint location, GLsizei count, const GLfloat *v)
  {
      setUniformImpl(location, count, v, GL_FLOAT_VEC2);
  }
  
  void ProgramVk::setUniform3fv(GLint location, GLsizei count, const GLfloat *v)
  {
      setUniformImpl(location, count, v, GL_FLOAT_VEC3);
  }
  
  void ProgramVk::setUniform4fv(GLint location, GLsizei count, const GLfloat *v)
  {
      setUniformImpl(location, count, v, GL_FLOAT_VEC4);
  }
  
  void ProgramVk::setUniform1iv(GLint location, GLsizei count, const GLint *v)
  {
      const gl::VariableLocation &locationInfo = mState.getUniformLocations()[location];
      const gl::LinkedUniform &linkedUniform   = mState.getUniforms()[locationInfo.index];
      if (linkedUniform.isSampler())
      {
          // We could potentially cache some indexing here. For now this is a no-op since the mapping
          // is handled entirely in ContextVk.
          return;
      }
  
      setUniformImpl(location, count, v, GL_INT);
  }
  
  void ProgramVk::setUniform2iv(GLint location, GLsizei count, const GLint *v)
  {
      setUniformImpl(location, count, v, GL_INT_VEC2);
  }
  
  void ProgramVk::setUniform3iv(GLint location, GLsizei count, const GLint *v)
  {
      setUniformImpl(location, count, v, GL_INT_VEC3);
  }
  
  void ProgramVk::setUniform4iv(GLint location, GLsizei count, const GLint *v)
  {
      setUniformImpl(location, count, v, GL_INT_VEC4);
  }
  
  void ProgramVk::setUniform1uiv(GLint location, GLsizei count, const GLuint *v)
  {
      setUniformImpl(location, count, v, GL_UNSIGNED_INT);
  }
  
  void ProgramVk::setUniform2uiv(GLint location, GLsizei count, const GLuint *v)
  {
      setUniformImpl(location, count, v, GL_UNSIGNED_INT_VEC2);
  }
  
  void ProgramVk::setUniform3uiv(GLint location, GLsizei count, const GLuint *v)
  {
      setUniformImpl(location, count, v, GL_UNSIGNED_INT_VEC3);
  }
  
  void ProgramVk::setUniform4uiv(GLint location, GLsizei count, const GLuint *v)
  {
      setUniformImpl(location, count, v, GL_UNSIGNED_INT_VEC4);
  }
  
  template <int cols, int rows>
  void ProgramVk::setUniformMatrixfv(GLint location,
                                     GLsizei count,
                                     GLboolean transpose,
                                     const GLfloat *value)
  {
      const gl::VariableLocation &locationInfo = mState.getUniformLocations()[location];
      const gl::LinkedUniform &linkedUniform   = mState.getUniforms()[locationInfo.index];
  
      for (const gl::ShaderType shaderType : mState.getLinkedShaderStages())
      {
          DefaultUniformBlock &uniformBlock     = mDefaultUniformBlocks[shaderType];
          const sh::BlockMemberInfo &layoutInfo = uniformBlock.uniformLayout[location];
  
          // Assume an offset of -1 means the block is unused.
          if (layoutInfo.offset == -1)
          {
              continue;
          }
  
          SetFloatUniformMatrixGLSL<cols, rows>::Run(
              locationInfo.arrayIndex, linkedUniform.getArraySizeProduct(), count, transpose, value,
              uniformBlock.uniformData.data() + layoutInfo.offset);
  
          mDefaultUniformBlocksDirty.set(shaderType);
      }
  }
  
  void ProgramVk::setUniformMatrix2fv(GLint location,
                                      GLsizei count,
                                      GLboolean transpose,
                                      const GLfloat *value)
  {
      setUniformMatrixfv<2, 2>(location, count, transpose, value);
  }
  
  void ProgramVk::setUniformMatrix3fv(GLint location,
                                      GLsizei count,
                                      GLboolean transpose,
                                      const GLfloat *value)
  {
      setUniformMatrixfv<3, 3>(location, count, transpose, value);
  }
  
  void ProgramVk::setUniformMatrix4fv(GLint location,
                                      GLsizei count,
                                      GLboolean transpose,
                                      const GLfloat *value)
  {
      setUniformMatrixfv<4, 4>(location, count, transpose, value);
  }
  
  void ProgramVk::setUniformMatrix2x3fv(GLint location,
                                        GLsizei count,
                                        GLboolean transpose,
                                        const GLfloat *value)
  {
      setUniformMatrixfv<2, 3>(location, count, transpose, value);
  }
  
  void ProgramVk::setUniformMatrix3x2fv(GLint location,
                                        GLsizei count,
                                        GLboolean transpose,
                                        const GLfloat *value)
  {
      setUniformMatrixfv<3, 2>(location, count, transpose, value);
  }
  
  void ProgramVk::setUniformMatrix2x4fv(GLint location,
                                        GLsizei count,
                                        GLboolean transpose,
                                        const GLfloat *value)
  {
      setUniformMatrixfv<2, 4>(location, count, transpose, value);
  }
  
  void ProgramVk::setUniformMatrix4x2fv(GLint location,
                                        GLsizei count,
                                        GLboolean transpose,
                                        const GLfloat *value)
  {
      setUniformMatrixfv<4, 2>(location, count, transpose, value);
  }
  
  void ProgramVk::setUniformMatrix3x4fv(GLint location,
                                        GLsizei count,
                                        GLboolean transpose,
                                        const GLfloat *value)
  {
      setUniformMatrixfv<3, 4>(location, count, transpose, value);
  }
  
  void ProgramVk::setUniformMatrix4x3fv(GLint location,
                                        GLsizei count,
                                        GLboolean transpose,
                                        const GLfloat *value)
  {
      setUniformMatrixfv<4, 3>(location, count, transpose, value);
  }
  
  void ProgramVk::setPathFragmentInputGen(const std::string &inputName,
                                          GLenum genMode,
                                          GLint components,
                                          const GLfloat *coeffs)
  {
      UNIMPLEMENTED();
  }
  
  angle::Result ProgramVk::allocateDescriptorSet(ContextVk *contextVk, uint32_t descriptorSetIndex)
  {
      bool ignoreNewPoolAllocated;
      return allocateDescriptorSetAndGetInfo(contextVk, descriptorSetIndex, &ignoreNewPoolAllocated);
  }
  
  angle::Result ProgramVk::allocateDescriptorSetAndGetInfo(ContextVk *contextVk,
                                                           uint32_t descriptorSetIndex,
                                                           bool *newPoolAllocatedOut)
  {
      vk::DynamicDescriptorPool &dynamicDescriptorPool = mDynamicDescriptorPools[descriptorSetIndex];
  
      uint32_t potentialNewCount = descriptorSetIndex + 1;
      if (potentialNewCount > mDescriptorSets.size())
      {
          mDescriptorSets.resize(potentialNewCount, VK_NULL_HANDLE);
      }
  
      const vk::DescriptorSetLayout &descriptorSetLayout =
          mDescriptorSetLayouts[descriptorSetIndex].get();
      ANGLE_TRY(dynamicDescriptorPool.allocateSetsAndGetInfo(
          contextVk, descriptorSetLayout.ptr(), 1, &mDescriptorPoolBindings[descriptorSetIndex],
          &mDescriptorSets[descriptorSetIndex], newPoolAllocatedOut));
      mEmptyDescriptorSets[descriptorSetIndex] = VK_NULL_HANDLE;
  
      return angle::Result::Continue;
  }
  
  void ProgramVk::getUniformfv(const gl::Context *context, GLint location, GLfloat *params) const
  {
      getUniformImpl(location, params, GL_FLOAT);
  }
  
  void ProgramVk::getUniformiv(const gl::Context *context, GLint location, GLint *params) const
  {
      getUniformImpl(location, params, GL_INT);
  }
  
  void ProgramVk::getUniformuiv(const gl::Context *context, GLint location, GLuint *params) const
  {
      getUniformImpl(location, params, GL_UNSIGNED_INT);
  }
  
  angle::Result ProgramVk::updateUniforms(ContextVk *contextVk)
  {
      ASSERT(dirtyUniforms());
  
      bool anyNewBufferAllocated = false;
      uint32_t offsetIndex       = 0;
  
      // Update buffer memory by immediate mapping. This immediate update only works once.
      for (gl::ShaderType shaderType : mState.getLinkedShaderStages())
      {
          DefaultUniformBlock &uniformBlock = mDefaultUniformBlocks[shaderType];
  
          if (mDefaultUniformBlocksDirty[shaderType])
          {
              bool bufferModified = false;
              ANGLE_TRY(
                  SyncDefaultUniformBlock(contextVk, &uniformBlock.storage, uniformBlock.uniformData,
                                          &mDynamicBufferOffsets[offsetIndex], &bufferModified));
              mDefaultUniformBlocksDirty.reset(shaderType);
  
              if (bufferModified)
              {
                  anyNewBufferAllocated = true;
              }
          }
  
          ++offsetIndex;
      }
  
      if (anyNewBufferAllocated)
      {
          // We need to reinitialize the descriptor sets if we newly allocated buffers since we can't
          // modify the descriptor sets once initialized.
          ANGLE_TRY(allocateDescriptorSet(contextVk, kUniformsAndXfbDescriptorSetIndex));
          updateDefaultUniformsDescriptorSet(contextVk);
          updateTransformFeedbackDescriptorSetImpl(contextVk);
      }
  
      return angle::Result::Continue;
  }
  
  void ProgramVk::updateDefaultUniformsDescriptorSet(ContextVk *contextVk)
  {
      uint32_t shaderStageCount = static_cast<uint32_t>(mState.getLinkedShaderStageCount());
  
      gl::ShaderVector<VkDescriptorBufferInfo> descriptorBufferInfo(shaderStageCount);
      gl::ShaderVector<VkWriteDescriptorSet> writeDescriptorInfo(shaderStageCount);
  
      uint32_t bindingIndex = 0;
  
      mDescriptorBuffersCache.clear();
  
      // Write default uniforms for each shader type.
      for (const gl::ShaderType shaderType : mState.getLinkedShaderStages())
      {
          DefaultUniformBlock &uniformBlock  = mDefaultUniformBlocks[shaderType];
          VkDescriptorBufferInfo &bufferInfo = descriptorBufferInfo[bindingIndex];
          VkWriteDescriptorSet &writeInfo    = writeDescriptorInfo[bindingIndex];
  
          if (!uniformBlock.uniformData.empty())
          {
              vk::BufferHelper *bufferHelper = uniformBlock.storage.getCurrentBuffer();
              bufferInfo.buffer              = bufferHelper->getBuffer().getHandle();
              mDescriptorBuffersCache.emplace_back(bufferHelper);
          }
          else
          {
              mEmptyBuffer.retain(&contextVk->getResourceUseList());
              bufferInfo.buffer = mEmptyBuffer.getBuffer().getHandle();
              mDescriptorBuffersCache.emplace_back(&mEmptyBuffer);
          }
  
          bufferInfo.offset = 0;
          bufferInfo.range  = VK_WHOLE_SIZE;
  
          writeInfo.sType            = VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET;
          writeInfo.pNext            = nullptr;
          writeInfo.dstSet           = mDescriptorSets[kUniformsAndXfbDescriptorSetIndex];
          writeInfo.dstBinding       = bindingIndex;
          writeInfo.dstArrayElement  = 0;
          writeInfo.descriptorCount  = 1;
          writeInfo.descriptorType   = VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER_DYNAMIC;
          writeInfo.pImageInfo       = nullptr;
          writeInfo.pBufferInfo      = &bufferInfo;
          writeInfo.pTexelBufferView = nullptr;
  
          ++bindingIndex;
      }
  
      VkDevice device = contextVk->getDevice();
  
      ASSERT(bindingIndex == shaderStageCount);
      ASSERT(shaderStageCount <= kReservedDefaultUniformBindingCount);
  
      vkUpdateDescriptorSets(device, shaderStageCount, writeDescriptorInfo.data(), 0, nullptr);
  }
  
  void ProgramVk::updateBuffersDescriptorSet(ContextVk *contextVk,
                                             vk::ResourceUseList *resourceUseList,
                                             CommandBufferHelper *commandBufferHelper,
                                             vk::Resource *recorder,
                                             const std::vector<gl::InterfaceBlock> &blocks,
                                             VkDescriptorType descriptorType)
  {
      if (blocks.empty())
      {
          return;
      }
  
      VkDescriptorSet descriptorSet = mDescriptorSets[kShaderResourceDescriptorSetIndex];
  
      ASSERT(descriptorType == VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER ||
             descriptorType == VK_DESCRIPTOR_TYPE_STORAGE_BUFFER);
      const bool isStorageBuffer = descriptorType == VK_DESCRIPTOR_TYPE_STORAGE_BUFFER;
      const uint32_t bindingStart =
          isStorageBuffer ? getStorageBlockBindingsOffset() : getUniformBlockBindingsOffset();
  
      static_assert(
          gl::IMPLEMENTATION_MAX_SHADER_STORAGE_BUFFER_BINDINGS >=
              gl::IMPLEMENTATION_MAX_UNIFORM_BUFFER_BINDINGS,
          "The descriptor arrays here would have inadequate size for uniform buffer objects");
  
      gl::StorageBuffersArray<VkDescriptorBufferInfo> descriptorBufferInfo;
      gl::StorageBuffersArray<VkWriteDescriptorSet> writeDescriptorInfo;
      uint32_t writeCount = 0;
      // The binding is incremented every time arrayElement 0 is encountered, which means there will
      // be an increment right at the start.  Start from -1 to get 0 as the first binding.
      int32_t currentBinding = -1;
  
      // Write uniform or storage buffers.
      const gl::State &glState = contextVk->getState();
      for (uint32_t bufferIndex = 0; bufferIndex < blocks.size(); ++bufferIndex)
      {
          const gl::InterfaceBlock &block = blocks[bufferIndex];
          const gl::OffsetBindingPointer<gl::Buffer> &bufferBinding =
              isStorageBuffer ? glState.getIndexedShaderStorageBuffer(block.binding)
                              : glState.getIndexedUniformBuffer(block.binding);
  
          if (!block.isArray || block.arrayElement == 0)
          {
              // Array indices of the same buffer binding are placed sequentially in `blocks`.
              // Thus, the block binding is updated only when array index 0 is encountered.
              ++currentBinding;
          }
  
          if (bufferBinding.get() == nullptr)
          {
              continue;
          }
  
          uint32_t binding          = bindingStart + currentBinding;
          uint32_t arrayElement     = block.isArray ? block.arrayElement : 0;
          VkDeviceSize maxBlockSize = isStorageBuffer ? 0 : block.dataSize;
  
          VkDescriptorBufferInfo &bufferInfo = descriptorBufferInfo[writeCount];
          VkWriteDescriptorSet &writeInfo    = writeDescriptorInfo[writeCount];
  
          WriteBufferDescriptorSetBinding(bufferBinding, maxBlockSize, descriptorSet, descriptorType,
                                          binding, arrayElement, 0, &bufferInfo, &writeInfo);
  
          BufferVk *bufferVk             = vk::GetImpl(bufferBinding.get());
          vk::BufferHelper &bufferHelper = bufferVk->getBuffer();
  
          if (isStorageBuffer)
          {
              // We set the SHADER_READ_BIT to be conservative.
              VkAccessFlags accessFlags = VK_ACCESS_SHADER_READ_BIT | VK_ACCESS_SHADER_WRITE_BIT;
              commandBufferHelper->bufferWrite(resourceUseList, accessFlags, &bufferHelper);
          }
          else
          {
              commandBufferHelper->bufferRead(resourceUseList, VK_ACCESS_UNIFORM_READ_BIT,
                                              &bufferHelper);
          }
  
          ++writeCount;
      }
  
      VkDevice device = contextVk->getDevice();
  
      vkUpdateDescriptorSets(device, writeCount, writeDescriptorInfo.data(), 0, nullptr);
  }
  
  void ProgramVk::updateAtomicCounterBuffersDescriptorSet(ContextVk *contextVk,
                                                          vk::ResourceUseList *resourceUseList,
                                                          CommandBufferHelper *commandBufferHelper,
                                                          vk::Resource *recorder)
  {
      const gl::State &glState = contextVk->getState();
      const std::vector<gl::AtomicCounterBuffer> &atomicCounterBuffers =
          mState.getAtomicCounterBuffers();
  
      if (atomicCounterBuffers.empty())
      {
          return;
      }
  
      VkDescriptorSet descriptorSet = mDescriptorSets[kShaderResourceDescriptorSetIndex];
  
      const uint32_t bindingStart = getAtomicCounterBufferBindingsOffset();
  
      gl::AtomicCounterBuffersArray<VkDescriptorBufferInfo> descriptorBufferInfo;
      gl::AtomicCounterBuffersArray<VkWriteDescriptorSet> writeDescriptorInfo;
      gl::AtomicCounterBufferMask writtenBindings;
  
      RendererVk *rendererVk = contextVk->getRenderer();
      const VkDeviceSize requiredOffsetAlignment =
          rendererVk->getPhysicalDeviceProperties().limits.minStorageBufferOffsetAlignment;
  
      // Write atomic counter buffers.
      for (uint32_t bufferIndex = 0; bufferIndex < atomicCounterBuffers.size(); ++bufferIndex)
      {
          const gl::AtomicCounterBuffer &atomicCounterBuffer = atomicCounterBuffers[bufferIndex];
          uint32_t binding                                   = atomicCounterBuffer.binding;
          const gl::OffsetBindingPointer<gl::Buffer> &bufferBinding =
              glState.getIndexedAtomicCounterBuffer(binding);
  
          if (bufferBinding.get() == nullptr)
          {
              continue;
          }
  
          VkDescriptorBufferInfo &bufferInfo = descriptorBufferInfo[binding];
          VkWriteDescriptorSet &writeInfo    = writeDescriptorInfo[binding];
  
          WriteBufferDescriptorSetBinding(bufferBinding, 0, descriptorSet,
                                          VK_DESCRIPTOR_TYPE_STORAGE_BUFFER, bindingStart, binding,
                                          requiredOffsetAlignment, &bufferInfo, &writeInfo);
  
          BufferVk *bufferVk             = vk::GetImpl(bufferBinding.get());
          vk::BufferHelper &bufferHelper = bufferVk->getBuffer();
  
          // We set SHADER_READ_BIT to be conservative.
          commandBufferHelper->bufferWrite(
              resourceUseList, VK_ACCESS_SHADER_READ_BIT | VK_ACCESS_SHADER_WRITE_BIT, &bufferHelper);
  
          writtenBindings.set(binding);
      }
  
      // Bind the empty buffer to every array slot that's unused.
      mEmptyBuffer.retain(&contextVk->getResourceUseList());
      for (size_t binding : ~writtenBindings)
      {
          VkDescriptorBufferInfo &bufferInfo = descriptorBufferInfo[binding];
          VkWriteDescriptorSet &writeInfo    = writeDescriptorInfo[binding];
  
          bufferInfo.buffer = mEmptyBuffer.getBuffer().getHandle();
          bufferInfo.offset = 0;
          bufferInfo.range  = VK_WHOLE_SIZE;
  
          writeInfo.sType            = VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET;
          writeInfo.pNext            = nullptr;
          writeInfo.dstSet           = descriptorSet;
          writeInfo.dstBinding       = bindingStart;
          writeInfo.dstArrayElement  = static_cast<uint32_t>(binding);
          writeInfo.descriptorCount  = 1;
          writeInfo.descriptorType   = VK_DESCRIPTOR_TYPE_STORAGE_BUFFER;
          writeInfo.pImageInfo       = nullptr;
          writeInfo.pBufferInfo      = &bufferInfo;
          writeInfo.pTexelBufferView = nullptr;
      }
  
      VkDevice device = contextVk->getDevice();
  
      vkUpdateDescriptorSets(device, gl::IMPLEMENTATION_MAX_ATOMIC_COUNTER_BUFFERS,
                             writeDescriptorInfo.data(), 0, nullptr);
  }
  
  angle::Result ProgramVk::updateImagesDescriptorSet(ContextVk *contextVk, vk::Resource *recorder)
  {
      const gl::State &glState                           = contextVk->getState();
      const std::vector<gl::ImageBinding> &imageBindings = mState.getImageBindings();
  
      if (imageBindings.empty())
      {
          return angle::Result::Continue;
      }
  
      VkDescriptorSet descriptorSet = mDescriptorSets[kShaderResourceDescriptorSetIndex];
  
      const gl::ActiveTextureArray<TextureVk *> &activeImages = contextVk->getActiveImages();
  
      const uint32_t bindingStart = getImageBindingsOffset();
  
      gl::ImagesArray<VkDescriptorImageInfo> descriptorImageInfo;
      gl::ImagesArray<VkWriteDescriptorSet> writeDescriptorInfo;
      uint32_t writeCount = 0;
  
      // Write images.
      for (uint32_t imageIndex = 0; imageIndex < imageBindings.size(); ++imageIndex)
      {
          const gl::ImageBinding &imageBinding = imageBindings[imageIndex];
  
          ASSERT(!imageBinding.unreferenced);
  
          for (uint32_t arrayElement = 0; arrayElement < imageBinding.boundImageUnits.size();
               ++arrayElement)
          {
              GLuint imageUnit             = imageBinding.boundImageUnits[arrayElement];
              const gl::ImageUnit &binding = glState.getImageUnit(imageUnit);
              TextureVk *textureVk         = activeImages[imageUnit];
  
              vk::ImageHelper *image         = &textureVk->getImage();
              const vk::ImageView *imageView = nullptr;
  
              ANGLE_TRY(textureVk->getStorageImageView(contextVk, (binding.layered == GL_TRUE),
                                                       binding.level, binding.layer, &imageView));
  
              // Note: binding.access is unused because it is implied by the shader.
  
              // TODO(syoussefi): Support image data reinterpretation by using binding.format.
              // http://anglebug.com/3563
  
              VkDescriptorImageInfo &imageInfo = descriptorImageInfo[writeCount];
              VkWriteDescriptorSet &writeInfo  = writeDescriptorInfo[writeCount];
  
              imageInfo.sampler     = VK_NULL_HANDLE;
              imageInfo.imageView   = imageView->getHandle();
              imageInfo.imageLayout = image->getCurrentLayout();
  
              writeInfo.sType            = VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET;
              writeInfo.pNext            = nullptr;
              writeInfo.dstSet           = descriptorSet;
              writeInfo.dstBinding       = bindingStart + imageIndex;
              writeInfo.dstArrayElement  = arrayElement;
              writeInfo.descriptorCount  = 1;
              writeInfo.descriptorType   = VK_DESCRIPTOR_TYPE_STORAGE_IMAGE;
              writeInfo.pImageInfo       = &imageInfo;
              writeInfo.pBufferInfo      = nullptr;
              writeInfo.pTexelBufferView = nullptr;
  
              ++writeCount;
          }
      }
  
      VkDevice device = contextVk->getDevice();
  
      vkUpdateDescriptorSets(device, writeCount, writeDescriptorInfo.data(), 0, nullptr);
  
      return angle::Result::Continue;
  }
  
  angle::Result ProgramVk::updateShaderResourcesDescriptorSet(
      ContextVk *contextVk,
      vk::ResourceUseList *resourceUseList,
      CommandBufferHelper *commandBufferHelper,
      vk::Resource *recorder)
  {
      ANGLE_TRY(allocateDescriptorSet(contextVk, kShaderResourceDescriptorSetIndex));
  
      updateBuffersDescriptorSet(contextVk, resourceUseList, commandBufferHelper, recorder,
                                 mState.getUniformBlocks(), VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER);
      updateBuffersDescriptorSet(contextVk, resourceUseList, commandBufferHelper, recorder,
                                 mState.getShaderStorageBlocks(), VK_DESCRIPTOR_TYPE_STORAGE_BUFFER);
      updateAtomicCounterBuffersDescriptorSet(contextVk, resourceUseList, commandBufferHelper,
                                              recorder);
      return updateImagesDescriptorSet(contextVk, recorder);
  }
  
  angle::Result ProgramVk::updateTransformFeedbackDescriptorSet(ContextVk *contextVk,
                                                                vk::FramebufferHelper *framebuffer)
  {
      ASSERT(hasTransformFeedbackOutput());
  
      ANGLE_TRY(allocateDescriptorSet(contextVk, kUniformsAndXfbDescriptorSetIndex));
  
      updateDefaultUniformsDescriptorSet(contextVk);
      updateTransformFeedbackDescriptorSetImpl(contextVk);
  
      return angle::Result::Continue;
  }
  
  void ProgramVk::updateTransformFeedbackDescriptorSetImpl(ContextVk *contextVk)
  {
      const gl::State &glState                 = contextVk->getState();
      gl::TransformFeedback *transformFeedback = glState.getCurrentTransformFeedback();
  
      if (!hasTransformFeedbackOutput())
      {
          // If xfb has no output there is no need to update descriptor set.
          return;
      }
      if (!glState.isTransformFeedbackActive())
      {
          // We set empty Buffer to xfb descriptor set because xfb descriptor set
          // requires valid buffer bindings, even if they are empty buffer,
          // otherwise Vulkan validation layer generates errors.
          if (transformFeedback)
          {
              TransformFeedbackVk *transformFeedbackVk = vk::GetImpl(transformFeedback);
              transformFeedbackVk->initDescriptorSet(
                  contextVk, mState.getTransformFeedbackBufferCount(), &mEmptyBuffer,
                  mDescriptorSets[kUniformsAndXfbDescriptorSetIndex]);
          }
          return;
      }
  
      TransformFeedbackVk *transformFeedbackVk = vk::GetImpl(glState.getCurrentTransformFeedback());
      transformFeedbackVk->updateDescriptorSet(contextVk, mState,
                                               mDescriptorSets[kUniformsAndXfbDescriptorSetIndex]);
  }
  
  angle::Result ProgramVk::updateTexturesDescriptorSet(ContextVk *contextVk)
  {
      const vk::TextureDescriptorDesc &texturesDesc = contextVk->getActiveTexturesDesc();
  
      auto iter = mTextureDescriptorsCache.find(texturesDesc);
      if (iter != mTextureDescriptorsCache.end())
      {
          mDescriptorSets[kTextureDescriptorSetIndex] = iter->second;
          return angle::Result::Continue;
      }
  
      ASSERT(hasTextures());
      bool newPoolAllocated;
      ANGLE_TRY(
          allocateDescriptorSetAndGetInfo(contextVk, kTextureDescriptorSetIndex, &newPoolAllocated));
  
      // Clear descriptor set cache. It may no longer be valid.
      if (newPoolAllocated)
      {
          mTextureDescriptorsCache.clear();
      }
  
      VkDescriptorSet descriptorSet = mDescriptorSets[kTextureDescriptorSetIndex];
  
      gl::ActiveTextureArray<VkDescriptorImageInfo> descriptorImageInfo;
      gl::ActiveTextureArray<VkWriteDescriptorSet> writeDescriptorInfo;
      uint32_t writeCount = 0;
  
      const gl::ActiveTextureArray<vk::TextureUnit> &activeTextures = contextVk->getActiveTextures();
  
      bool emulateSeamfulCubeMapSampling = contextVk->emulateSeamfulCubeMapSampling();
      bool useOldRewriteStructSamplers   = contextVk->useOldRewriteStructSamplers();
  
      std::unordered_map<std::string, uint32_t> mappedSamplerNameToBindingIndex;
      std::unordered_map<std::string, uint32_t> mappedSamplerNameToArrayOffset;
  
      uint32_t currentBindingIndex = 0;
  
      for (uint32_t textureIndex = 0; textureIndex < mState.getSamplerBindings().size();
           ++textureIndex)
      {
          const gl::SamplerBinding &samplerBinding = mState.getSamplerBindings()[textureIndex];
  
          ASSERT(!samplerBinding.unreferenced);
  
          uint32_t uniformIndex = mState.getUniformIndexFromSamplerIndex(textureIndex);
          const gl::LinkedUniform &samplerUniform = mState.getUniforms()[uniformIndex];
          std::string mappedSamplerName           = GlslangGetMappedSamplerName(samplerUniform.name);
  
          if (useOldRewriteStructSamplers ||
              mappedSamplerNameToBindingIndex.emplace(mappedSamplerName, currentBindingIndex).second)
          {
              currentBindingIndex++;
          }
  
          uint32_t bindingIndex = textureIndex;
          uint32_t arrayOffset  = 0;
          uint32_t arraySize    = static_cast<uint32_t>(samplerBinding.boundTextureUnits.size());
  
          if (!useOldRewriteStructSamplers)
          {
              bindingIndex = mappedSamplerNameToBindingIndex[mappedSamplerName];
              arrayOffset  = mappedSamplerNameToArrayOffset[mappedSamplerName];
              // Front-end generates array elements in order, so we can just increment
              // the offset each time we process a nested array.
              mappedSamplerNameToArrayOffset[mappedSamplerName] += arraySize;
          }
  
          for (uint32_t arrayElement = 0; arrayElement < arraySize; ++arrayElement)
          {
              GLuint textureUnit   = samplerBinding.boundTextureUnits[arrayElement];
              TextureVk *textureVk = activeTextures[textureUnit].texture;
              SamplerVk *samplerVk = activeTextures[textureUnit].sampler;
  
              vk::ImageHelper &image = textureVk->getImage();
  
              VkDescriptorImageInfo &imageInfo = descriptorImageInfo[writeCount];
  
              // Use bound sampler object if one present, otherwise use texture's sampler
              const vk::Sampler &sampler =
                  (samplerVk != nullptr) ? samplerVk->getSampler() : textureVk->getSampler();
  
              imageInfo.sampler     = sampler.getHandle();
              imageInfo.imageLayout = image.getCurrentLayout();
  
              if (emulateSeamfulCubeMapSampling)
              {
                  // If emulating seamful cubemapping, use the fetch image view.  This is basically
                  // the same image view as read, except it's a 2DArray view for cube maps.
                  imageInfo.imageView =
                      textureVk->getFetchImageViewAndRecordUse(contextVk).getHandle();
              }
              else
              {
                  imageInfo.imageView =
                      textureVk->getReadImageViewAndRecordUse(contextVk).getHandle();
              }
  
              VkWriteDescriptorSet &writeInfo = writeDescriptorInfo[writeCount];
  
              writeInfo.sType            = VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET;
              writeInfo.pNext            = nullptr;
              writeInfo.dstSet           = descriptorSet;
              writeInfo.dstBinding       = bindingIndex;
              writeInfo.dstArrayElement  = arrayOffset + arrayElement;
              writeInfo.descriptorCount  = 1;
              writeInfo.descriptorType   = VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER;
              writeInfo.pImageInfo       = &imageInfo;
              writeInfo.pBufferInfo      = nullptr;
              writeInfo.pTexelBufferView = nullptr;
  
              ++writeCount;
          }
      }
  
      VkDevice device = contextVk->getDevice();
  
      ASSERT(writeCount > 0);
  
      vkUpdateDescriptorSets(device, writeCount, writeDescriptorInfo.data(), 0, nullptr);
  
      mTextureDescriptorsCache.emplace(texturesDesc, descriptorSet);
  
      return angle::Result::Continue;
  }
  
  void ProgramVk::setDefaultUniformBlocksMinSizeForTesting(size_t minSize)
  {
      for (DefaultUniformBlock &block : mDefaultUniformBlocks)
      {
          block.storage.setMinimumSizeForTesting(minSize);
      }
  }
  
  angle::Result ProgramVk::updateDescriptorSets(ContextVk *contextVk,
                                                vk::CommandBuffer *commandBuffer)
  {
      // Can probably use better dirty bits here.
  
      if (mDescriptorSets.empty())
          return angle::Result::Continue;
  
      // Find the maximum non-null descriptor set.  This is used in conjunction with a driver
      // workaround to bind empty descriptor sets only for gaps in between 0 and max and avoid
      // binding unnecessary empty descriptor sets for the sets beyond max.
      const size_t descriptorSetStart = kUniformsAndXfbDescriptorSetIndex;
      size_t descriptorSetRange       = 0;
      for (size_t descriptorSetIndex = descriptorSetStart;
           descriptorSetIndex < mDescriptorSets.size(); ++descriptorSetIndex)
      {
          if (mDescriptorSets[descriptorSetIndex] != VK_NULL_HANDLE)
          {
              descriptorSetRange = descriptorSetIndex + 1;
          }
      }
  
      const VkPipelineBindPoint pipelineBindPoint =
          mState.isCompute() ? VK_PIPELINE_BIND_POINT_COMPUTE : VK_PIPELINE_BIND_POINT_GRAPHICS;
  
      for (uint32_t descriptorSetIndex = descriptorSetStart; descriptorSetIndex < descriptorSetRange;
           ++descriptorSetIndex)
      {
          VkDescriptorSet descSet = mDescriptorSets[descriptorSetIndex];
          if (descSet == VK_NULL_HANDLE)
          {
              if (!contextVk->getRenderer()->getFeatures().bindEmptyForUnusedDescriptorSets.enabled)
              {
                  continue;
              }
  
              // Workaround a driver bug where missing (though unused) descriptor sets indices cause
              // later sets to misbehave.
              if (mEmptyDescriptorSets[descriptorSetIndex] == VK_NULL_HANDLE)
              {
                  const vk::DescriptorSetLayout &descriptorSetLayout =
                      mDescriptorSetLayouts[descriptorSetIndex].get();
  
                  ANGLE_TRY(mDynamicDescriptorPools[descriptorSetIndex].allocateSets(
                      contextVk, descriptorSetLayout.ptr(), 1,
                      &mDescriptorPoolBindings[descriptorSetIndex],
                      &mEmptyDescriptorSets[descriptorSetIndex]));
              }
              descSet = mEmptyDescriptorSets[descriptorSetIndex];
          }
  
          // Default uniforms are encompassed in a block per shader stage, and they are assigned
          // through dynamic uniform buffers (requiring dynamic offsets).  No other descriptor
          // requires a dynamic offset.
          const uint32_t uniformBlockOffsetCount =
              descriptorSetIndex == kUniformsAndXfbDescriptorSetIndex
                  ? static_cast<uint32_t>(mDynamicBufferOffsets.size())
                  : 0;
  
          commandBuffer->bindDescriptorSets(mPipelineLayout.get(), pipelineBindPoint,
                                            descriptorSetIndex, 1, &descSet, uniformBlockOffsetCount,
                                            mDynamicBufferOffsets.data());
      }
  
      for (vk::BufferHelper *buffer : mDescriptorBuffersCache)
      {
          buffer->retain(&contextVk->getResourceUseList());
      }
  
      return angle::Result::Continue;
  }
  }  // namespace rx
  

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