kc3-lang/angle/src/libGLESv2/renderer/d3d/d3d11/InputLayoutCache.cpp

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• Hash : b543afff
  Author :
  Date : 2014-09-30T14:52:54
  

  Update Program, ProgramBinary and HLSLCompiler to use Error objects.
  
  BUG=angle:520
  
  Change-Id: Ibbe8c95780fecfb68f4558e99e3a761107da6aee
  Reviewed-on: https://chromium-review.googlesource.com/220790
  Reviewed-by: Shannon Woods <shannonwoods@chromium.org>
  Tested-by: Geoff Lang <geofflang@chromium.org>
  

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• src/libGLESv2/renderer/d3d/d3d11/InputLayoutCache.cpp

• //
  // Copyright (c) 2012 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.
  //
  
  // InputLayoutCache.cpp: Defines InputLayoutCache, a class that builds and caches
  // D3D11 input layouts.
  
  #include "libGLESv2/renderer/d3d/d3d11/InputLayoutCache.h"
  #include "libGLESv2/renderer/d3d/d3d11/VertexBuffer11.h"
  #include "libGLESv2/renderer/d3d/d3d11/Buffer11.h"
  #include "libGLESv2/renderer/d3d/d3d11/ShaderExecutable11.h"
  #include "libGLESv2/renderer/d3d/d3d11/formatutils11.h"
  #include "libGLESv2/renderer/d3d/ProgramD3D.h"
  #include "libGLESv2/renderer/d3d/VertexDataManager.h"
  #include "libGLESv2/ProgramBinary.h"
  #include "libGLESv2/VertexAttribute.h"
  
  #include "third_party/murmurhash/MurmurHash3.h"
  
  namespace rx
  {
  
  static void GetInputLayout(const TranslatedAttribute translatedAttributes[gl::MAX_VERTEX_ATTRIBS],
                             gl::VertexFormat inputLayout[gl::MAX_VERTEX_ATTRIBS])
  {
      for (unsigned int attributeIndex = 0; attributeIndex < gl::MAX_VERTEX_ATTRIBS; attributeIndex++)
      {
          const TranslatedAttribute &translatedAttribute = translatedAttributes[attributeIndex];
  
          if (translatedAttributes[attributeIndex].active)
          {
              inputLayout[attributeIndex] = gl::VertexFormat(*translatedAttribute.attribute,
                                                             translatedAttribute.currentValueType);
          }
      }
  }
  
  const unsigned int InputLayoutCache::kMaxInputLayouts = 1024;
  
  InputLayoutCache::InputLayoutCache() : mInputLayoutMap(kMaxInputLayouts, hashInputLayout, compareInputLayouts)
  {
      mCounter = 0;
      mDevice = NULL;
      mDeviceContext = NULL;
      mCurrentIL = NULL;
      for (unsigned int i = 0; i < gl::MAX_VERTEX_ATTRIBS; i++)
      {
          mCurrentBuffers[i] = NULL;
          mCurrentVertexStrides[i] = -1;
          mCurrentVertexOffsets[i] = -1;
      }
  }
  
  InputLayoutCache::~InputLayoutCache()
  {
      clear();
  }
  
  void InputLayoutCache::initialize(ID3D11Device *device, ID3D11DeviceContext *context)
  {
      clear();
      mDevice = device;
      mDeviceContext = context;
  }
  
  void InputLayoutCache::clear()
  {
      for (InputLayoutMap::iterator i = mInputLayoutMap.begin(); i != mInputLayoutMap.end(); i++)
      {
          SafeRelease(i->second.inputLayout);
      }
      mInputLayoutMap.clear();
      markDirty();
  }
  
  void InputLayoutCache::markDirty()
  {
      mCurrentIL = NULL;
      for (unsigned int i = 0; i < gl::MAX_VERTEX_ATTRIBS; i++)
      {
          mCurrentBuffers[i] = NULL;
          mCurrentVertexStrides[i] = -1;
          mCurrentVertexOffsets[i] = -1;
      }
  }
  
  gl::Error InputLayoutCache::applyVertexBuffers(TranslatedAttribute attributes[gl::MAX_VERTEX_ATTRIBS],
                                                 gl::ProgramBinary *programBinary)
  {
      int sortedSemanticIndices[gl::MAX_VERTEX_ATTRIBS];
      programBinary->sortAttributesByLayout(attributes, sortedSemanticIndices);
  
      if (!mDevice || !mDeviceContext)
      {
          return gl::Error(GL_OUT_OF_MEMORY, "Internal input layout cache is not initialized.");
      }
  
      InputLayoutKey ilKey = { 0 };
  
      static const char* semanticName = "TEXCOORD";
  
      for (unsigned int i = 0; i < gl::MAX_VERTEX_ATTRIBS; i++)
      {
          if (attributes[i].active)
          {
              D3D11_INPUT_CLASSIFICATION inputClass = attributes[i].divisor > 0 ? D3D11_INPUT_PER_INSTANCE_DATA : D3D11_INPUT_PER_VERTEX_DATA;
  
              gl::VertexFormat vertexFormat(*attributes[i].attribute, attributes[i].currentValueType);
              const d3d11::VertexFormat &vertexFormatInfo = d3d11::GetVertexFormatInfo(vertexFormat);
  
              // Record the type of the associated vertex shader vector in our key
              // This will prevent mismatched vertex shaders from using the same input layout
              GLint attributeSize;
              programBinary->getActiveAttribute(ilKey.elementCount, 0, NULL, &attributeSize, &ilKey.elements[ilKey.elementCount].glslElementType, NULL);
  
              ilKey.elements[ilKey.elementCount].desc.SemanticName = semanticName;
              ilKey.elements[ilKey.elementCount].desc.SemanticIndex = sortedSemanticIndices[i];
              ilKey.elements[ilKey.elementCount].desc.Format = vertexFormatInfo.nativeFormat;
              ilKey.elements[ilKey.elementCount].desc.InputSlot = i;
              ilKey.elements[ilKey.elementCount].desc.AlignedByteOffset = 0;
              ilKey.elements[ilKey.elementCount].desc.InputSlotClass = inputClass;
              ilKey.elements[ilKey.elementCount].desc.InstanceDataStepRate = attributes[i].divisor;
              ilKey.elementCount++;
          }
      }
  
      ID3D11InputLayout *inputLayout = NULL;
  
      InputLayoutMap::iterator keyIter = mInputLayoutMap.find(ilKey);
      if (keyIter != mInputLayoutMap.end())
      {
          inputLayout = keyIter->second.inputLayout;
          keyIter->second.lastUsedTime = mCounter++;
      }
      else
      {
          gl::VertexFormat shaderInputLayout[gl::MAX_VERTEX_ATTRIBS];
          GetInputLayout(attributes, shaderInputLayout);
          ProgramD3D *programD3D = ProgramD3D::makeProgramD3D(programBinary->getImplementation());
  
          ShaderExecutable *shader = NULL;
          gl::Error error = programD3D->getVertexExecutableForInputLayout(shaderInputLayout, &shader);
          if (error.isError())
          {
              return error;
          }
  
          ShaderExecutable *shader11 = ShaderExecutable11::makeShaderExecutable11(shader);
  
          D3D11_INPUT_ELEMENT_DESC descs[gl::MAX_VERTEX_ATTRIBS];
          for (unsigned int j = 0; j < ilKey.elementCount; ++j)
          {
              descs[j] = ilKey.elements[j].desc;
          }
  
          HRESULT result = mDevice->CreateInputLayout(descs, ilKey.elementCount, shader11->getFunction(), shader11->getLength(), &inputLayout);
          if (FAILED(result))
          {
              return gl::Error(GL_OUT_OF_MEMORY, "Failed to create internal input layout, HRESULT: 0x%08x", result);
          }
  
          if (mInputLayoutMap.size() >= kMaxInputLayouts)
          {
              TRACE("Overflowed the limit of %u input layouts, removing the least recently used "
                    "to make room.", kMaxInputLayouts);
  
              InputLayoutMap::iterator leastRecentlyUsed = mInputLayoutMap.begin();
              for (InputLayoutMap::iterator i = mInputLayoutMap.begin(); i != mInputLayoutMap.end(); i++)
              {
                  if (i->second.lastUsedTime < leastRecentlyUsed->second.lastUsedTime)
                  {
                      leastRecentlyUsed = i;
                  }
              }
              SafeRelease(leastRecentlyUsed->second.inputLayout);
              mInputLayoutMap.erase(leastRecentlyUsed);
          }
  
          InputLayoutCounterPair inputCounterPair;
          inputCounterPair.inputLayout = inputLayout;
          inputCounterPair.lastUsedTime = mCounter++;
  
          mInputLayoutMap.insert(std::make_pair(ilKey, inputCounterPair));
      }
  
      if (inputLayout != mCurrentIL)
      {
          mDeviceContext->IASetInputLayout(inputLayout);
          mCurrentIL = inputLayout;
      }
  
      bool dirtyBuffers = false;
      size_t minDiff = gl::MAX_VERTEX_ATTRIBS;
      size_t maxDiff = 0;
      for (unsigned int i = 0; i < gl::MAX_VERTEX_ATTRIBS; i++)
      {
          ID3D11Buffer *buffer = NULL;
  
          if (attributes[i].active)
          {
              VertexBuffer11 *vertexBuffer = VertexBuffer11::makeVertexBuffer11(attributes[i].vertexBuffer);
              Buffer11 *bufferStorage = attributes[i].storage ? Buffer11::makeBuffer11(attributes[i].storage) : NULL;
  
              buffer = bufferStorage ? bufferStorage->getBuffer(BUFFER_USAGE_VERTEX_OR_TRANSFORM_FEEDBACK)
                                     : vertexBuffer->getBuffer();
          }
  
          UINT vertexStride = attributes[i].stride;
          UINT vertexOffset = attributes[i].offset;
  
          if (buffer != mCurrentBuffers[i] || vertexStride != mCurrentVertexStrides[i] ||
              vertexOffset != mCurrentVertexOffsets[i])
          {
              dirtyBuffers = true;
              minDiff = std::min(minDiff, static_cast<size_t>(i));
              maxDiff = std::max(maxDiff, static_cast<size_t>(i));
  
              mCurrentBuffers[i] = buffer;
              mCurrentVertexStrides[i] = vertexStride;
              mCurrentVertexOffsets[i] = vertexOffset;
          }
      }
  
      if (dirtyBuffers)
      {
          ASSERT(minDiff <= maxDiff && maxDiff < gl::MAX_VERTEX_ATTRIBS);
          mDeviceContext->IASetVertexBuffers(minDiff, maxDiff - minDiff + 1, mCurrentBuffers + minDiff,
                                             mCurrentVertexStrides + minDiff, mCurrentVertexOffsets + minDiff);
      }
  
      return gl::Error(GL_NO_ERROR);
  }
  
  std::size_t InputLayoutCache::hashInputLayout(const InputLayoutKey &inputLayout)
  {
      static const unsigned int seed = 0xDEADBEEF;
  
      std::size_t hash = 0;
      MurmurHash3_x86_32(inputLayout.begin(), inputLayout.end() - inputLayout.begin(), seed, &hash);
      return hash;
  }
  
  bool InputLayoutCache::compareInputLayouts(const InputLayoutKey &a, const InputLayoutKey &b)
  {
      if (a.elementCount != b.elementCount)
      {
          return false;
      }
  
      return std::equal(a.begin(), a.end(), b.begin());
  }
  
  }
  

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