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

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• Hash : dbc605ce
  Author :
  Date : 2019-01-04T16:39:14
  

  Vulkan: Optimize VBO state changes.
  
  Also has some minor optimizations for the front-end.
  
  12% improvement on the Vulkan VBO change test.
  
  Bug: angleproject:3014
  Change-Id: I38e1a8194edfc14bfe57424be348cb9688e928f4
  Reviewed-on: https://chromium-review.googlesource.com/c/1369286
  Reviewed-by: Shahbaz Youssefi <syoussefi@chromium.org>
  Commit-Queue: Jamie Madill <jmadill@chromium.org>
  

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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 "libANGLE/Context.h"
  #include "libANGLE/renderer/renderer_utils.h"
  #include "libANGLE/renderer/vulkan/ContextVk.h"
  #include "libANGLE/renderer/vulkan/GlslangWrapper.h"
  #include "libANGLE/renderer/vulkan/RendererVk.h"
  #include "libANGLE/renderer/vulkan/TextureVk.h"
  
  namespace rx
  {
  
  namespace
  {
  
  constexpr size_t kUniformBlockDynamicBufferMinSize = 256 * 128;
  
  void InitDefaultUniformBlock(const std::vector<sh::Uniform> &uniforms,
                               gl::Shader *shader,
                               sh::BlockLayoutMap *blockLayoutMapOut,
                               size_t *blockSizeOut)
  {
      if (uniforms.empty())
      {
          *blockSizeOut = 0;
          return;
      }
  
      sh::Std140BlockEncoder blockEncoder;
      sh::GetUniformBlockInfo(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->releaseRetainedBuffers(contextVk->getRenderer());
  
      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;
  }
  }  // anonymous namespace
  
  // ProgramVk::ShaderInfo implementation.
  ProgramVk::ShaderInfo::ShaderInfo() {}
  
  ProgramVk::ShaderInfo::~ShaderInfo() = default;
  
  angle::Result ProgramVk::ShaderInfo::initShaders(ContextVk *contextVk,
                                                   const std::string &vertexSource,
                                                   const std::string &fragmentSource,
                                                   bool enableLineRasterEmulation)
  {
      ASSERT(!valid());
  
      std::vector<uint32_t> vertexCode;
      std::vector<uint32_t> fragmentCode;
      ANGLE_TRY(GlslangWrapper::GetShaderCode(contextVk, contextVk->getCaps(),
                                              enableLineRasterEmulation, vertexSource, fragmentSource,
                                              &vertexCode, &fragmentCode));
  
      ANGLE_TRY(vk::InitShaderAndSerial(contextVk, &mShaders[gl::ShaderType::Vertex].get(),
                                        vertexCode.data(), vertexCode.size() * sizeof(uint32_t)));
      ANGLE_TRY(vk::InitShaderAndSerial(contextVk, &mShaders[gl::ShaderType::Fragment].get(),
                                        fragmentCode.data(), fragmentCode.size() * sizeof(uint32_t)));
  
      mProgramHelper.setShader(gl::ShaderType::Vertex, &mShaders[gl::ShaderType::Vertex]);
      mProgramHelper.setShader(gl::ShaderType::Fragment, &mShaders[gl::ShaderType::Fragment]);
  
      return angle::Result::Continue;
  }
  
  void ProgramVk::ShaderInfo::release(RendererVk *renderer)
  {
      mProgramHelper.release(renderer);
  
      for (vk::RefCounted<vk::ShaderAndSerial> &shader : mShaders)
      {
          shader.get().destroy(renderer->getDevice());
      }
  }
  
  // ProgramVk implementation.
  ProgramVk::DefaultUniformBlock::DefaultUniformBlock()
      : storage(VK_BUFFER_USAGE_UNIFORM_BUFFER_BIT | VK_BUFFER_USAGE_TRANSFER_SRC_BIT,
                kUniformBlockDynamicBufferMinSize,
                true)
  {}
  
  ProgramVk::DefaultUniformBlock::~DefaultUniformBlock() = default;
  
  ProgramVk::ProgramVk(const gl::ProgramState &state) : ProgramImpl(state), mUniformBlocksOffsets{}
  {
      mUsedDescriptorSetRange.invalidate();
  }
  
  ProgramVk::~ProgramVk() = default;
  
  void ProgramVk::destroy(const gl::Context *context)
  {
      ContextVk *contextVk = vk::GetImpl(context);
      reset(contextVk->getRenderer());
  }
  
  void ProgramVk::reset(RendererVk *renderer)
  {
      for (auto &descriptorSetLayout : mDescriptorSetLayouts)
      {
          descriptorSetLayout.reset();
      }
      mPipelineLayout.reset();
  
      for (auto &uniformBlock : mDefaultUniformBlocks)
      {
          uniformBlock.storage.release(renderer);
      }
  
      mDefaultShaderInfo.release(renderer);
      mLineRasterShaderInfo.release(renderer);
  
      mEmptyUniformBlockStorage.release(renderer);
  
      mDescriptorSets.clear();
      mUsedDescriptorSetRange.invalidate();
  
      for (vk::SharedDescriptorPoolBinding &binding : mDescriptorPoolBindings)
      {
          binding.reset();
      }
  }
  
  angle::Result ProgramVk::load(const gl::Context *context,
                                gl::InfoLog &infoLog,
                                gl::BinaryInputStream *stream)
  {
      UNIMPLEMENTED();
      return angle::Result::Stop;
  }
  
  void ProgramVk::save(const gl::Context *context, gl::BinaryOutputStream *stream)
  {
      UNIMPLEMENTED();
  }
  
  void ProgramVk::setBinaryRetrievableHint(bool retrievable)
  {
      UNIMPLEMENTED();
  }
  
  void ProgramVk::setSeparable(bool separable)
  {
      UNIMPLEMENTED();
  }
  
  std::unique_ptr<LinkEvent> ProgramVk::link(const gl::Context *context,
                                             const gl::ProgramLinkedResources &resources,
                                             gl::InfoLog &infoLog)
  {
      // TODO(jie.a.chen@intel.com): Parallelize linking.
      // http://crbug.com/849576
      return std::make_unique<LinkEventDone>(linkImpl(context, resources, infoLog));
  }
  
  angle::Result ProgramVk::linkImpl(const gl::Context *glContext,
                                    const gl::ProgramLinkedResources &resources,
                                    gl::InfoLog &infoLog)
  {
      ContextVk *contextVk = vk::GetImpl(glContext);
      RendererVk *renderer = contextVk->getRenderer();
  
      reset(renderer);
  
      GlslangWrapper::GetShaderSource(mState, resources, &mVertexSource, &mFragmentSource);
  
      ANGLE_TRY(initDefaultUniformBlocks(glContext));
  
      if (!mState.getSamplerUniformRange().empty())
      {
          // Ensure the descriptor set range includes the textures at position 1.
          mUsedDescriptorSetRange.extend(kTextureDescriptorSetIndex);
      }
  
      // Store a reference to the pipeline and descriptor set layouts. This will create them if they
      // don't already exist in the cache.
      vk::DescriptorSetLayoutDesc uniformsSetDesc;
      uniformsSetDesc.update(kVertexUniformsBindingIndex, VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER_DYNAMIC,
                             1);
      uniformsSetDesc.update(kFragmentUniformsBindingIndex, VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER_DYNAMIC,
                             1);
  
      ANGLE_TRY(renderer->getDescriptorSetLayout(
          contextVk, uniformsSetDesc, &mDescriptorSetLayouts[kUniformsDescriptorSetIndex]));
  
      vk::DescriptorSetLayoutDesc texturesSetDesc;
  
      for (uint32_t textureIndex = 0; textureIndex < mState.getSamplerBindings().size();
           ++textureIndex)
      {
          const gl::SamplerBinding &samplerBinding = mState.getSamplerBindings()[textureIndex];
  
          // The front-end always binds array sampler units sequentially.
          const uint32_t count = static_cast<uint32_t>(samplerBinding.boundTextureUnits.size());
          texturesSetDesc.update(textureIndex, VK_DESCRIPTOR_TYPE_COMBINED_IMAGE_SAMPLER, count);
      }
  
      ANGLE_TRY(renderer->getDescriptorSetLayout(contextVk, texturesSetDesc,
                                                 &mDescriptorSetLayouts[kTextureDescriptorSetIndex]));
  
      vk::DescriptorSetLayoutDesc driverUniformsSetDesc;
      driverUniformsSetDesc.update(0, VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER, 1);
      ANGLE_TRY(renderer->getDescriptorSetLayout(
          contextVk, driverUniformsSetDesc,
          &mDescriptorSetLayouts[kDriverUniformsDescriptorSetIndex]));
  
      vk::PipelineLayoutDesc pipelineLayoutDesc;
      pipelineLayoutDesc.updateDescriptorSetLayout(kUniformsDescriptorSetIndex, uniformsSetDesc);
      pipelineLayoutDesc.updateDescriptorSetLayout(kTextureDescriptorSetIndex, texturesSetDesc);
      pipelineLayoutDesc.updateDescriptorSetLayout(kDriverUniformsDescriptorSetIndex,
                                                   driverUniformsSetDesc);
  
      ANGLE_TRY(renderer->getPipelineLayout(contextVk, pipelineLayoutDesc, mDescriptorSetLayouts,
                                            &mPipelineLayout));
  
      if (!mState.getUniforms().empty())
      {
          const gl::RangeUI &samplerRange = mState.getSamplerUniformRange();
  
          if (mState.getUniforms().size() > samplerRange.length())
          {
              // Ensure the descriptor set range includes the uniform buffers at position 0.
              mUsedDescriptorSetRange.extend(kUniformsDescriptorSetIndex);
          }
  
          if (!samplerRange.empty())
          {
              // Ensure the descriptor set range includes the textures at position 1.
              mUsedDescriptorSetRange.extend(kTextureDescriptorSetIndex);
          }
      }
  
      return angle::Result::Continue;
  }
  
  angle::Result ProgramVk::initDefaultUniformBlocks(const gl::Context *glContext)
  {
      ContextVk *contextVk = vk::GetImpl(glContext);
      RendererVk *renderer = contextVk->getRenderer();
  
      // Process vertex and fragment uniforms into std140 packing.
      gl::ShaderMap<sh::BlockLayoutMap> layoutMap;
      gl::ShaderMap<size_t> requiredBufferSize;
      requiredBufferSize.fill(0);
  
      for (gl::ShaderType shaderType : gl::AllGLES2ShaderTypes())
      {
          gl::Shader *shader                       = mState.getAttachedShader(shaderType);
          const std::vector<sh::Uniform> &uniforms = shader->getUniforms();
          InitDefaultUniformBlock(uniforms, shader, &layoutMap[shaderType],
                                  &requiredBufferSize[shaderType]);
      }
  
      // 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.isSampler())
              {
                  std::string uniformName = uniform.name;
                  if (uniform.isArray())
                  {
                      // Gets the uniform name without the [0] at the end.
                      uniformName = gl::ParseResourceName(uniformName, nullptr);
                  }
  
                  bool found = false;
  
                  for (gl::ShaderType shaderType : gl::AllGLES2ShaderTypes())
                  {
                      auto it = layoutMap[shaderType].find(uniformName);
                      if (it != layoutMap[shaderType].end())
                      {
                          found                  = true;
                          layoutInfo[shaderType] = it->second;
                      }
                  }
  
                  ASSERT(found);
              }
          }
  
          for (gl::ShaderType shaderType : gl::AllGLES2ShaderTypes())
          {
              mDefaultUniformBlocks[shaderType].uniformLayout.push_back(layoutInfo[shaderType]);
          }
      }
  
      for (gl::ShaderType shaderType : gl::AllGLES2ShaderTypes())
      {
          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(minAlignment, renderer);
  
              // Initialize uniform buffer memory to zero by default.
              mDefaultUniformBlocks[shaderType].uniformData.fill(0);
              mDefaultUniformBlocksDirty.set(shaderType);
          }
      }
  
      if (mDefaultUniformBlocksDirty.any())
      {
          // Initialize the "empty" uniform block if necessary.
          if (!mDefaultUniformBlocksDirty.all())
          {
              VkBufferCreateInfo uniformBufferInfo    = {};
              uniformBufferInfo.sType                 = VK_STRUCTURE_TYPE_BUFFER_CREATE_INFO;
              uniformBufferInfo.flags                 = 0;
              uniformBufferInfo.size                  = 1;
              uniformBufferInfo.usage                 = VK_BUFFER_USAGE_UNIFORM_BUFFER_BIT;
              uniformBufferInfo.sharingMode           = VK_SHARING_MODE_EXCLUSIVE;
              uniformBufferInfo.queueFamilyIndexCount = 0;
              uniformBufferInfo.pQueueFamilyIndices   = nullptr;
  
              // Assume host visible/coherent memory available.
              VkMemoryPropertyFlags flags =
                  (VK_MEMORY_PROPERTY_HOST_VISIBLE_BIT | VK_MEMORY_PROPERTY_HOST_COHERENT_BIT);
              ANGLE_TRY(mEmptyUniformBlockStorage.init(contextVk, uniformBufferInfo, flags));
          }
      }
  
      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];
  
      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;
      }
  
      if (linkedUniform.typeInfo->type == entryPointType)
      {
          for (gl::ShaderType shaderType : gl::AllGLES2ShaderTypes())
          {
              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 (gl::ShaderType shaderType : gl::AllGLES2ShaderTypes())
          {
              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());
  
      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)
  {
      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)
  {
      UNIMPLEMENTED();
  }
  
  void ProgramVk::setUniform2uiv(GLint location, GLsizei count, const GLuint *v)
  {
      UNIMPLEMENTED();
  }
  
  void ProgramVk::setUniform3uiv(GLint location, GLsizei count, const GLuint *v)
  {
      UNIMPLEMENTED();
  }
  
  void ProgramVk::setUniform4uiv(GLint location, GLsizei count, const GLuint *v)
  {
      UNIMPLEMENTED();
  }
  
  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 (gl::ShaderType shaderType : gl::AllGLES2ShaderTypes())
      {
          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;
          }
  
          bool updated = SetFloatUniformMatrix<cols, rows>(
              locationInfo.arrayIndex, linkedUniform.getArraySizeProduct(), count, transpose, value,
              uniformBlock.uniformData.data() + layoutInfo.offset);
  
          // If the uniformsDirty flag was true, we don't want to flip it to false here if the
          // setter did not update any data. We still want the uniform to be included when we'll
          // update the descriptor sets.
          if (updated)
          {
              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)
  {
      // Write out to a new a descriptor set.
      vk::DynamicDescriptorPool *dynamicDescriptorPool =
          contextVk->getDynamicDescriptorPool(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->allocateSets(contextVk, descriptorSetLayout.ptr(), 1,
                                                    &mDescriptorPoolBindings[descriptorSetIndex],
                                                    &mDescriptorSets[descriptorSetIndex]));
      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
  {
      UNIMPLEMENTED();
  }
  
  angle::Result ProgramVk::updateUniforms(ContextVk *contextVk)
  {
      ASSERT(dirtyUniforms());
  
      // Update buffer memory by immediate mapping. This immediate update only works once.
      bool anyNewBufferAllocated = false;
      for (gl::ShaderType shaderType : gl::AllGLES2ShaderTypes())
      {
          DefaultUniformBlock &uniformBlock = mDefaultUniformBlocks[shaderType];
  
          if (mDefaultUniformBlocksDirty[shaderType])
          {
              bool bufferModified = false;
              ANGLE_TRY(SyncDefaultUniformBlock(contextVk, &uniformBlock.storage,
                                                uniformBlock.uniformData,
                                                &mUniformBlocksOffsets[shaderType], &bufferModified));
              mDefaultUniformBlocksDirty.reset(shaderType);
  
              if (bufferModified)
              {
                  anyNewBufferAllocated = true;
              }
          }
      }
  
      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, kUniformsDescriptorSetIndex));
          ANGLE_TRY(updateDefaultUniformsDescriptorSet(contextVk));
      }
  
      return angle::Result::Continue;
  }
  
  angle::Result ProgramVk::updateDefaultUniformsDescriptorSet(ContextVk *contextVk)
  {
      gl::ShaderMap<VkDescriptorBufferInfo> descriptorBufferInfo;
      gl::ShaderMap<VkWriteDescriptorSet> writeDescriptorInfo;
  
      for (gl::ShaderType shaderType : gl::AllGLES2ShaderTypes())
      {
          DefaultUniformBlock &uniformBlock  = mDefaultUniformBlocks[shaderType];
          VkDescriptorBufferInfo &bufferInfo = descriptorBufferInfo[shaderType];
          VkWriteDescriptorSet &writeInfo    = writeDescriptorInfo[shaderType];
  
          if (!uniformBlock.uniformData.empty())
          {
              bufferInfo.buffer = uniformBlock.storage.getCurrentBuffer()->getBuffer().getHandle();
          }
          else
          {
              bufferInfo.buffer = mEmptyUniformBlockStorage.getBuffer().getHandle();
          }
  
          bufferInfo.offset = 0;
          bufferInfo.range  = VK_WHOLE_SIZE;
  
          writeInfo.sType            = VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET;
          writeInfo.pNext            = nullptr;
          writeInfo.dstSet           = mDescriptorSets[0];
          writeInfo.dstBinding       = static_cast<uint32_t>(shaderType);
          writeInfo.dstArrayElement  = 0;
          writeInfo.descriptorCount  = 1;
          writeInfo.descriptorType   = VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER_DYNAMIC;
          writeInfo.pImageInfo       = nullptr;
          writeInfo.pBufferInfo      = &bufferInfo;
          writeInfo.pTexelBufferView = nullptr;
      }
  
      VkDevice device = contextVk->getDevice();
  
      vkUpdateDescriptorSets(device, 2, writeDescriptorInfo.data(), 0, nullptr);
  
      return angle::Result::Continue;
  }
  
  angle::Result ProgramVk::updateTexturesDescriptorSet(ContextVk *contextVk,
                                                       vk::FramebufferHelper *framebuffer)
  {
      ASSERT(hasTextures());
      ANGLE_TRY(allocateDescriptorSet(contextVk, kTextureDescriptorSetIndex));
  
      ASSERT(mUsedDescriptorSetRange.contains(1));
      VkDescriptorSet descriptorSet = mDescriptorSets[kTextureDescriptorSetIndex];
  
      gl::ActiveTextureArray<VkDescriptorImageInfo> descriptorImageInfo;
      gl::ActiveTextureArray<VkWriteDescriptorSet> writeDescriptorInfo;
      uint32_t writeCount = 0;
  
      const gl::ActiveTextureArray<TextureVk *> &activeTextures = contextVk->getActiveTextures();
  
      for (uint32_t textureIndex = 0; textureIndex < mState.getSamplerBindings().size();
           ++textureIndex)
      {
          const gl::SamplerBinding &samplerBinding = mState.getSamplerBindings()[textureIndex];
  
          ASSERT(!samplerBinding.unreferenced);
  
          for (uint32_t arrayElement = 0; arrayElement < samplerBinding.boundTextureUnits.size();
               ++arrayElement)
          {
              GLuint textureUnit   = samplerBinding.boundTextureUnits[arrayElement];
              TextureVk *textureVk = activeTextures[textureUnit];
  
              // Ensure any writes to the textures are flushed before we read from them.
              ANGLE_TRY(textureVk->ensureImageInitialized(contextVk));
              vk::ImageHelper &image = textureVk->getImage();
  
              // Ensure the image is in read-only layout
              if (image.getCurrentLayout() != VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL)
              {
                  vk::CommandBuffer *srcLayoutChange;
                  ANGLE_TRY(image.recordCommands(contextVk, &srcLayoutChange));
  
                  image.changeLayoutWithStages(
                      VK_IMAGE_ASPECT_COLOR_BIT, VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL,
                      VK_PIPELINE_STAGE_ALL_COMMANDS_BIT, VK_PIPELINE_STAGE_FRAGMENT_SHADER_BIT,
                      srcLayoutChange);
              }
  
              image.addReadDependency(framebuffer);
  
              VkDescriptorImageInfo &imageInfo = descriptorImageInfo[writeCount];
  
              imageInfo.sampler     = textureVk->getSampler().getHandle();
              imageInfo.imageView   = textureVk->getReadImageView().getHandle();
              imageInfo.imageLayout = image.getCurrentLayout();
  
              VkWriteDescriptorSet &writeInfo = writeDescriptorInfo[writeCount];
  
              writeInfo.sType            = VK_STRUCTURE_TYPE_WRITE_DESCRIPTOR_SET;
              writeInfo.pNext            = nullptr;
              writeInfo.dstSet           = descriptorSet;
              writeInfo.dstBinding       = textureIndex;
              writeInfo.dstArrayElement  = 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);
  
      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 (mUsedDescriptorSetRange.empty())
          return angle::Result::Continue;
  
      ASSERT(!mDescriptorSets.empty());
  
      unsigned int low = mUsedDescriptorSetRange.low();
  
      // No uniforms descriptor set means no need to specify dynamic buffer offsets.
      if (mUsedDescriptorSetRange.contains(kUniformsDescriptorSetIndex))
      {
          constexpr uint32_t kShaderTypeMin = static_cast<uint32_t>(gl::kGLES2ShaderTypeMin);
          constexpr uint32_t kShaderTypeMax = static_cast<uint32_t>(gl::kGLES2ShaderTypeMax);
          commandBuffer->bindDescriptorSets(
              VK_PIPELINE_BIND_POINT_GRAPHICS, mPipelineLayout.get(), low,
              mUsedDescriptorSetRange.length(), &mDescriptorSets[low],
              kShaderTypeMax - kShaderTypeMin + 1, mUniformBlocksOffsets.data() + kShaderTypeMin);
      }
      else
      {
          commandBuffer->bindDescriptorSets(VK_PIPELINE_BIND_POINT_GRAPHICS, mPipelineLayout.get(),
                                            low, mUsedDescriptorSetRange.length(),
                                            &mDescriptorSets[low], 0, nullptr);
      }
  
      return angle::Result::Continue;
  }
  }  // namespace rx
  

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