kc3-lang/angle/src/libANGLE/angletypes.cpp

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• Hash : 779a25a8
  Author :
  Date : 2020-04-27T02:11:58
  

  D3D11: Migrate to the new blend state tracking
  
  Migrate D3D ClearParameters struct to the new color mask storage
  
  Bug: angleproject:4394
  Change-Id: Ibeb64e4bbb2758b9c8271fc3c59d2d675850b0a8
  Reviewed-on: https://chromium-review.googlesource.com/c/angle/angle/+/2165886
  Commit-Queue: Kenneth Russell <kbr@chromium.org>
  Reviewed-by: Geoff Lang <geofflang@chromium.org>
  

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• src/libANGLE/angletypes.cpp

• //
  // Copyright 2013 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.
  //
  
  // angletypes.h : Defines a variety of structures and enum types that are used throughout libGLESv2
  
  #include "libANGLE/angletypes.h"
  #include "libANGLE/Program.h"
  #include "libANGLE/State.h"
  #include "libANGLE/VertexArray.h"
  #include "libANGLE/VertexAttribute.h"
  
  namespace gl
  {
  RasterizerState::RasterizerState()
  {
      memset(this, 0, sizeof(RasterizerState));
  
      rasterizerDiscard   = false;
      cullFace            = false;
      cullMode            = CullFaceMode::Back;
      frontFace           = GL_CCW;
      polygonOffsetFill   = false;
      polygonOffsetFactor = 0.0f;
      polygonOffsetUnits  = 0.0f;
      pointDrawMode       = false;
      multiSample         = false;
      dither              = true;
  }
  
  RasterizerState::RasterizerState(const RasterizerState &other)
  {
      memcpy(this, &other, sizeof(RasterizerState));
  }
  
  bool operator==(const RasterizerState &a, const RasterizerState &b)
  {
      return memcmp(&a, &b, sizeof(RasterizerState)) == 0;
  }
  
  bool operator!=(const RasterizerState &a, const RasterizerState &b)
  {
      return !(a == b);
  }
  
  BlendState::BlendState()
  {
      memset(this, 0, sizeof(BlendState));
  
      blend              = false;
      sourceBlendRGB     = GL_ONE;
      sourceBlendAlpha   = GL_ONE;
      destBlendRGB       = GL_ZERO;
      destBlendAlpha     = GL_ZERO;
      blendEquationRGB   = GL_FUNC_ADD;
      blendEquationAlpha = GL_FUNC_ADD;
      colorMaskRed       = true;
      colorMaskGreen     = true;
      colorMaskBlue      = true;
      colorMaskAlpha     = true;
  }
  
  BlendState::BlendState(const BlendState &other)
  {
      memcpy(this, &other, sizeof(BlendState));
  }
  
  bool operator==(const BlendState &a, const BlendState &b)
  {
      return memcmp(&a, &b, sizeof(BlendState)) == 0;
  }
  
  bool operator!=(const BlendState &a, const BlendState &b)
  {
      return !(a == b);
  }
  
  DepthStencilState::DepthStencilState()
  {
      memset(this, 0, sizeof(DepthStencilState));
  
      depthTest                = false;
      depthFunc                = GL_LESS;
      depthMask                = true;
      stencilTest              = false;
      stencilFunc              = GL_ALWAYS;
      stencilMask              = static_cast<GLuint>(-1);
      stencilWritemask         = static_cast<GLuint>(-1);
      stencilBackFunc          = GL_ALWAYS;
      stencilBackMask          = static_cast<GLuint>(-1);
      stencilBackWritemask     = static_cast<GLuint>(-1);
      stencilFail              = GL_KEEP;
      stencilPassDepthFail     = GL_KEEP;
      stencilPassDepthPass     = GL_KEEP;
      stencilBackFail          = GL_KEEP;
      stencilBackPassDepthFail = GL_KEEP;
      stencilBackPassDepthPass = GL_KEEP;
  }
  
  DepthStencilState::DepthStencilState(const DepthStencilState &other)
  {
      memcpy(this, &other, sizeof(DepthStencilState));
  }
  
  bool operator==(const DepthStencilState &a, const DepthStencilState &b)
  {
      return memcmp(&a, &b, sizeof(DepthStencilState)) == 0;
  }
  
  bool operator!=(const DepthStencilState &a, const DepthStencilState &b)
  {
      return !(a == b);
  }
  
  SamplerState::SamplerState()
  {
      memset(this, 0, sizeof(SamplerState));
  
      setMinFilter(GL_NEAREST_MIPMAP_LINEAR);
      setMagFilter(GL_LINEAR);
      setWrapS(GL_REPEAT);
      setWrapT(GL_REPEAT);
      setWrapR(GL_REPEAT);
      setMaxAnisotropy(1.0f);
      setMinLod(-1000.0f);
      setMaxLod(1000.0f);
      setCompareMode(GL_NONE);
      setCompareFunc(GL_LEQUAL);
      setSRGBDecode(GL_DECODE_EXT);
  }
  
  SamplerState::SamplerState(const SamplerState &other) = default;
  
  // static
  SamplerState SamplerState::CreateDefaultForTarget(TextureType type)
  {
      SamplerState state;
  
      // According to OES_EGL_image_external and ARB_texture_rectangle: For external textures, the
      // default min filter is GL_LINEAR and the default s and t wrap modes are GL_CLAMP_TO_EDGE.
      if (type == TextureType::External || type == TextureType::Rectangle)
      {
          state.mMinFilter = GL_LINEAR;
          state.mWrapS     = GL_CLAMP_TO_EDGE;
          state.mWrapT     = GL_CLAMP_TO_EDGE;
      }
  
      return state;
  }
  
  void SamplerState::setMinFilter(GLenum minFilter)
  {
      mMinFilter                    = minFilter;
      mCompleteness.typed.minFilter = static_cast<uint8_t>(FromGLenum<FilterMode>(minFilter));
  }
  
  void SamplerState::setMagFilter(GLenum magFilter)
  {
      mMagFilter                    = magFilter;
      mCompleteness.typed.magFilter = static_cast<uint8_t>(FromGLenum<FilterMode>(magFilter));
  }
  
  void SamplerState::setWrapS(GLenum wrapS)
  {
      mWrapS                    = wrapS;
      mCompleteness.typed.wrapS = static_cast<uint8_t>(FromGLenum<WrapMode>(wrapS));
  }
  
  void SamplerState::setWrapT(GLenum wrapT)
  {
      mWrapT = wrapT;
      updateWrapTCompareMode();
  }
  
  void SamplerState::setWrapR(GLenum wrapR)
  {
      mWrapR = wrapR;
  }
  
  void SamplerState::setMaxAnisotropy(float maxAnisotropy)
  {
      mMaxAnisotropy = maxAnisotropy;
  }
  
  void SamplerState::setMinLod(GLfloat minLod)
  {
      mMinLod = minLod;
  }
  
  void SamplerState::setMaxLod(GLfloat maxLod)
  {
      mMaxLod = maxLod;
  }
  
  void SamplerState::setCompareMode(GLenum compareMode)
  {
      mCompareMode = compareMode;
      updateWrapTCompareMode();
  }
  
  void SamplerState::setCompareFunc(GLenum compareFunc)
  {
      mCompareFunc = compareFunc;
  }
  
  void SamplerState::setSRGBDecode(GLenum sRGBDecode)
  {
      mSRGBDecode = sRGBDecode;
  }
  
  void SamplerState::setBorderColor(const ColorGeneric &color)
  {
      mBorderColor = color;
  }
  
  void SamplerState::updateWrapTCompareMode()
  {
      uint8_t wrap    = static_cast<uint8_t>(FromGLenum<WrapMode>(mWrapT));
      uint8_t compare = static_cast<uint8_t>(mCompareMode == GL_NONE ? 0x10 : 0x00);
      mCompleteness.typed.wrapTCompareMode = wrap | compare;
  }
  
  ImageUnit::ImageUnit()
      : texture(), level(0), layered(false), layer(0), access(GL_READ_ONLY), format(GL_R32UI)
  {}
  
  ImageUnit::ImageUnit(const ImageUnit &other) = default;
  
  ImageUnit::~ImageUnit() = default;
  
  BlendStateExt::BlendStateExt(const size_t drawBuffers)
      : mMaxFactorMask(FactorStorage::GetMask(drawBuffers)),
        mSrcColor(FactorStorage::GetReplicatedValue(BlendFactorType::One, mMaxFactorMask)),
        mDstColor(FactorStorage::GetReplicatedValue(BlendFactorType::Zero, mMaxFactorMask)),
        mSrcAlpha(FactorStorage::GetReplicatedValue(BlendFactorType::One, mMaxFactorMask)),
        mDstAlpha(FactorStorage::GetReplicatedValue(BlendFactorType::Zero, mMaxFactorMask)),
        mMaxEquationMask(EquationStorage::GetMask(drawBuffers)),
        mEquationColor(EquationStorage::GetReplicatedValue(BlendEquationType::Add, mMaxEquationMask)),
        mEquationAlpha(EquationStorage::GetReplicatedValue(BlendEquationType::Add, mMaxEquationMask)),
        mMaxColorMask(ColorMaskStorage::GetMask(drawBuffers)),
        mColorMask(ColorMaskStorage::GetReplicatedValue(PackColorMask(true, true, true, true),
                                                        mMaxColorMask)),
        mMaxEnabledMask(0xFF >> (8 - drawBuffers)),
        mEnabledMask(),
        mMaxDrawBuffers(drawBuffers)
  {}
  
  BlendStateExt &BlendStateExt::operator=(const BlendStateExt &other)
  {
      memcpy(this, &other, sizeof(BlendStateExt));
      return *this;
  }
  
  void BlendStateExt::setEnabled(const bool enabled)
  {
      mEnabledMask = enabled ? mMaxEnabledMask : DrawBufferMask::Zero();
  }
  
  void BlendStateExt::setEnabledIndexed(const size_t index, const bool enabled)
  {
      ASSERT(index < mMaxDrawBuffers);
      mEnabledMask.set(index, enabled);
  }
  
  BlendStateExt::ColorMaskStorage::Type BlendStateExt::expandColorMaskValue(const bool red,
                                                                            const bool green,
                                                                            const bool blue,
                                                                            const bool alpha) const
  {
      return BlendStateExt::ColorMaskStorage::GetReplicatedValue(
          PackColorMask(red, green, blue, alpha), mMaxColorMask);
  }
  
  BlendStateExt::ColorMaskStorage::Type BlendStateExt::expandColorMaskIndexed(
      const size_t index) const
  {
      return ColorMaskStorage::GetReplicatedValue(
          ColorMaskStorage::GetValueIndexed(index, mColorMask), mMaxColorMask);
  }
  
  void BlendStateExt::setColorMask(const bool red,
                                   const bool green,
                                   const bool blue,
                                   const bool alpha)
  {
      mColorMask = expandColorMaskValue(red, green, blue, alpha);
  }
  
  void BlendStateExt::setColorMaskIndexed(const size_t index, const uint8_t value)
  {
      ASSERT(index < mMaxDrawBuffers);
      ASSERT(value <= 0xF);
      ColorMaskStorage::SetValueIndexed(index, value, &mColorMask);
  }
  
  void BlendStateExt::setColorMaskIndexed(const size_t index,
                                          const bool red,
                                          const bool green,
                                          const bool blue,
                                          const bool alpha)
  {
      ASSERT(index < mMaxDrawBuffers);
      ColorMaskStorage::SetValueIndexed(index, PackColorMask(red, green, blue, alpha), &mColorMask);
  }
  
  uint8_t BlendStateExt::getColorMaskIndexed(const size_t index) const
  {
      ASSERT(index < mMaxDrawBuffers);
      return ColorMaskStorage::GetValueIndexed(index, mColorMask);
  }
  
  void BlendStateExt::getColorMaskIndexed(const size_t index,
                                          bool *red,
                                          bool *green,
                                          bool *blue,
                                          bool *alpha) const
  {
      ASSERT(index < mMaxDrawBuffers);
      UnpackColorMask(ColorMaskStorage::GetValueIndexed(index, mColorMask), red, green, blue, alpha);
  }
  
  DrawBufferMask BlendStateExt::compareColorMask(ColorMaskStorage::Type other) const
  {
      return ColorMaskStorage::GetDiffMask(mColorMask, other);
  }
  
  BlendStateExt::EquationStorage::Type BlendStateExt::expandEquationValue(const GLenum mode) const
  {
      return EquationStorage::GetReplicatedValue(FromGLenum<BlendEquationType>(mode),
                                                 mMaxEquationMask);
  }
  
  BlendStateExt::EquationStorage::Type BlendStateExt::expandEquationColorIndexed(
      const size_t index) const
  {
      return EquationStorage::GetReplicatedValue(
          EquationStorage::GetValueIndexed(index, mEquationColor), mMaxEquationMask);
  }
  
  BlendStateExt::EquationStorage::Type BlendStateExt::expandEquationAlphaIndexed(
      const size_t index) const
  {
      return EquationStorage::GetReplicatedValue(
          EquationStorage::GetValueIndexed(index, mEquationAlpha), mMaxEquationMask);
  }
  
  void BlendStateExt::setEquations(const GLenum modeColor, const GLenum modeAlpha)
  {
      mEquationColor = expandEquationValue(modeColor);
      mEquationAlpha = expandEquationValue(modeAlpha);
  }
  
  void BlendStateExt::setEquationsIndexed(const size_t index,
                                          const GLenum modeColor,
                                          const GLenum modeAlpha)
  {
      ASSERT(index < mMaxDrawBuffers);
      EquationStorage::SetValueIndexed(index, FromGLenum<BlendEquationType>(modeColor),
                                       &mEquationColor);
      EquationStorage::SetValueIndexed(index, FromGLenum<BlendEquationType>(modeAlpha),
                                       &mEquationAlpha);
  }
  
  void BlendStateExt::setEquationsIndexed(const size_t index,
                                          const size_t sourceIndex,
                                          const BlendStateExt &source)
  {
      ASSERT(index < mMaxDrawBuffers);
      ASSERT(sourceIndex < source.mMaxDrawBuffers);
      EquationStorage::SetValueIndexed(
          index, EquationStorage::GetValueIndexed(sourceIndex, source.mEquationColor),
          &mEquationColor);
      EquationStorage::SetValueIndexed(
          index, EquationStorage::GetValueIndexed(sourceIndex, source.mEquationAlpha),
          &mEquationAlpha);
  }
  
  GLenum BlendStateExt::getEquationColorIndexed(size_t index) const
  {
      ASSERT(index < mMaxDrawBuffers);
      return ToGLenum(EquationStorage::GetValueIndexed(index, mEquationColor));
  }
  
  GLenum BlendStateExt::getEquationAlphaIndexed(size_t index) const
  {
      ASSERT(index < mMaxDrawBuffers);
      return ToGLenum(EquationStorage::GetValueIndexed(index, mEquationAlpha));
  }
  
  DrawBufferMask BlendStateExt::compareEquations(const EquationStorage::Type color,
                                                 const EquationStorage::Type alpha) const
  {
      return EquationStorage::GetDiffMask(mEquationColor, color) |
             EquationStorage::GetDiffMask(mEquationAlpha, alpha);
  }
  
  BlendStateExt::FactorStorage::Type BlendStateExt::expandFactorValue(const GLenum func) const
  {
      return FactorStorage::GetReplicatedValue(FromGLenum<BlendFactorType>(func), mMaxFactorMask);
  }
  
  BlendStateExt::FactorStorage::Type BlendStateExt::expandSrcColorIndexed(const size_t index) const
  {
      ASSERT(index < mMaxDrawBuffers);
      return FactorStorage::GetReplicatedValue(FactorStorage::GetValueIndexed(index, mSrcColor),
                                               mMaxFactorMask);
  }
  
  BlendStateExt::FactorStorage::Type BlendStateExt::expandDstColorIndexed(const size_t index) const
  {
      ASSERT(index < mMaxDrawBuffers);
      return FactorStorage::GetReplicatedValue(FactorStorage::GetValueIndexed(index, mDstColor),
                                               mMaxFactorMask);
  }
  
  BlendStateExt::FactorStorage::Type BlendStateExt::expandSrcAlphaIndexed(const size_t index) const
  {
      ASSERT(index < mMaxDrawBuffers);
      return FactorStorage::GetReplicatedValue(FactorStorage::GetValueIndexed(index, mSrcAlpha),
                                               mMaxFactorMask);
  }
  
  BlendStateExt::FactorStorage::Type BlendStateExt::expandDstAlphaIndexed(const size_t index) const
  {
      ASSERT(index < mMaxDrawBuffers);
      return FactorStorage::GetReplicatedValue(FactorStorage::GetValueIndexed(index, mDstAlpha),
                                               mMaxFactorMask);
  }
  
  void BlendStateExt::setFactors(const GLenum srcColor,
                                 const GLenum dstColor,
                                 const GLenum srcAlpha,
                                 const GLenum dstAlpha)
  {
      mSrcColor = expandFactorValue(srcColor);
      mDstColor = expandFactorValue(dstColor);
      mSrcAlpha = expandFactorValue(srcAlpha);
      mDstAlpha = expandFactorValue(dstAlpha);
  }
  
  void BlendStateExt::setFactorsIndexed(const size_t index,
                                        const GLenum srcColor,
                                        const GLenum dstColor,
                                        const GLenum srcAlpha,
                                        const GLenum dstAlpha)
  {
      ASSERT(index < mMaxDrawBuffers);
      FactorStorage::SetValueIndexed(index, FromGLenum<BlendFactorType>(srcColor), &mSrcColor);
      FactorStorage::SetValueIndexed(index, FromGLenum<BlendFactorType>(dstColor), &mDstColor);
      FactorStorage::SetValueIndexed(index, FromGLenum<BlendFactorType>(srcAlpha), &mSrcAlpha);
      FactorStorage::SetValueIndexed(index, FromGLenum<BlendFactorType>(dstAlpha), &mDstAlpha);
  }
  
  void BlendStateExt::setFactorsIndexed(const size_t index,
                                        const size_t sourceIndex,
                                        const BlendStateExt &source)
  {
      ASSERT(index < mMaxDrawBuffers);
      ASSERT(sourceIndex < source.mMaxDrawBuffers);
      FactorStorage::SetValueIndexed(
          index, FactorStorage::GetValueIndexed(sourceIndex, source.mSrcColor), &mSrcColor);
      FactorStorage::SetValueIndexed(
          index, FactorStorage::GetValueIndexed(sourceIndex, source.mDstColor), &mDstColor);
      FactorStorage::SetValueIndexed(
          index, FactorStorage::GetValueIndexed(sourceIndex, source.mSrcAlpha), &mSrcAlpha);
      FactorStorage::SetValueIndexed(
          index, FactorStorage::GetValueIndexed(sourceIndex, source.mDstAlpha), &mDstAlpha);
  }
  
  GLenum BlendStateExt::getSrcColorIndexed(size_t index) const
  {
      ASSERT(index < mMaxDrawBuffers);
      return ToGLenum(FactorStorage::GetValueIndexed(index, mSrcColor));
  }
  
  GLenum BlendStateExt::getDstColorIndexed(size_t index) const
  {
      ASSERT(index < mMaxDrawBuffers);
      return ToGLenum(FactorStorage::GetValueIndexed(index, mDstColor));
  }
  
  GLenum BlendStateExt::getSrcAlphaIndexed(size_t index) const
  {
      ASSERT(index < mMaxDrawBuffers);
      return ToGLenum(FactorStorage::GetValueIndexed(index, mSrcAlpha));
  }
  
  GLenum BlendStateExt::getDstAlphaIndexed(size_t index) const
  {
      ASSERT(index < mMaxDrawBuffers);
      return ToGLenum(FactorStorage::GetValueIndexed(index, mDstAlpha));
  }
  
  DrawBufferMask BlendStateExt::compareFactors(const FactorStorage::Type srcColor,
                                               const FactorStorage::Type dstColor,
                                               const FactorStorage::Type srcAlpha,
                                               const FactorStorage::Type dstAlpha) const
  {
      return FactorStorage::GetDiffMask(mSrcColor, srcColor) |
             FactorStorage::GetDiffMask(mDstColor, dstColor) |
             FactorStorage::GetDiffMask(mSrcAlpha, srcAlpha) |
             FactorStorage::GetDiffMask(mDstAlpha, dstAlpha);
  }
  
  static void MinMax(int a, int b, int *minimum, int *maximum)
  {
      if (a < b)
      {
          *minimum = a;
          *maximum = b;
      }
      else
      {
          *minimum = b;
          *maximum = a;
      }
  }
  
  Rectangle Rectangle::flip(bool flipX, bool flipY) const
  {
      Rectangle flipped = *this;
      if (flipX)
      {
          flipped.x     = flipped.x + flipped.width;
          flipped.width = -flipped.width;
      }
      if (flipY)
      {
          flipped.y      = flipped.y + flipped.height;
          flipped.height = -flipped.height;
      }
      return flipped;
  }
  
  Rectangle Rectangle::removeReversal() const
  {
      return flip(isReversedX(), isReversedY());
  }
  
  bool Rectangle::encloses(const gl::Rectangle &inside) const
  {
      return x0() <= inside.x0() && y0() <= inside.y0() && x1() >= inside.x1() && y1() >= inside.y1();
  }
  
  bool ClipRectangle(const Rectangle &source, const Rectangle &clip, Rectangle *intersection)
  {
      int minSourceX, maxSourceX, minSourceY, maxSourceY;
      MinMax(source.x, source.x + source.width, &minSourceX, &maxSourceX);
      MinMax(source.y, source.y + source.height, &minSourceY, &maxSourceY);
  
      int minClipX, maxClipX, minClipY, maxClipY;
      MinMax(clip.x, clip.x + clip.width, &minClipX, &maxClipX);
      MinMax(clip.y, clip.y + clip.height, &minClipY, &maxClipY);
  
      if (minSourceX >= maxClipX || maxSourceX <= minClipX || minSourceY >= maxClipY ||
          maxSourceY <= minClipY)
      {
          return false;
      }
      if (intersection)
      {
          intersection->x      = std::max(minSourceX, minClipX);
          intersection->y      = std::max(minSourceY, minClipY);
          intersection->width  = std::min(maxSourceX, maxClipX) - std::max(minSourceX, minClipX);
          intersection->height = std::min(maxSourceY, maxClipY) - std::max(minSourceY, minClipY);
      }
      return true;
  }
  
  bool Box::operator==(const Box &other) const
  {
      return (x == other.x && y == other.y && z == other.z && width == other.width &&
              height == other.height && depth == other.depth);
  }
  
  bool Box::operator!=(const Box &other) const
  {
      return !(*this == other);
  }
  
  Rectangle Box::toRect() const
  {
      ASSERT(z == 0 && depth == 1);
      return Rectangle(x, y, width, height);
  }
  
  bool operator==(const Offset &a, const Offset &b)
  {
      return a.x == b.x && a.y == b.y && a.z == b.z;
  }
  
  bool operator!=(const Offset &a, const Offset &b)
  {
      return !(a == b);
  }
  
  bool operator==(const Extents &lhs, const Extents &rhs)
  {
      return lhs.width == rhs.width && lhs.height == rhs.height && lhs.depth == rhs.depth;
  }
  
  bool operator!=(const Extents &lhs, const Extents &rhs)
  {
      return !(lhs == rhs);
  }
  
  bool ValidateComponentTypeMasks(unsigned long outputTypes,
                                  unsigned long inputTypes,
                                  unsigned long outputMask,
                                  unsigned long inputMask)
  {
      static_assert(IMPLEMENTATION_MAX_DRAW_BUFFERS <= kMaxComponentTypeMaskIndex,
                    "Output/input masks should fit into 16 bits - 1 bit per draw buffer. The "
                    "corresponding type masks should fit into 32 bits - 2 bits per draw buffer.");
      static_assert(MAX_VERTEX_ATTRIBS <= kMaxComponentTypeMaskIndex,
                    "Output/input masks should fit into 16 bits - 1 bit per attrib. The "
                    "corresponding type masks should fit into 32 bits - 2 bits per attrib.");
  
      // For performance reasons, draw buffer and attribute type validation is done using bit masks.
      // We store two bits representing the type split, with the low bit in the lower 16 bits of the
      // variable, and the high bit in the upper 16 bits of the variable. This is done so we can AND
      // with the elswewhere used DrawBufferMask or AttributeMask.
  
      // OR the masks with themselves, shifted 16 bits. This is to match our split type bits.
      outputMask |= (outputMask << kMaxComponentTypeMaskIndex);
      inputMask |= (inputMask << kMaxComponentTypeMaskIndex);
  
      // To validate:
      // 1. Remove any indexes that are not enabled in the input (& inputMask)
      // 2. Remove any indexes that exist in output, but not in input (& outputMask)
      // 3. Use == to verify equality
      return (outputTypes & inputMask) == ((inputTypes & outputMask) & inputMask);
  }
  
  GLsizeiptr GetBoundBufferAvailableSize(const OffsetBindingPointer<Buffer> &binding)
  {
      Buffer *buffer = binding.get();
      if (buffer)
      {
          if (binding.getSize() == 0)
              return static_cast<GLsizeiptr>(buffer->getSize());
          angle::CheckedNumeric<GLintptr> offset       = binding.getOffset();
          angle::CheckedNumeric<GLsizeiptr> size       = binding.getSize();
          angle::CheckedNumeric<GLsizeiptr> bufferSize = buffer->getSize();
          auto end                                     = offset + size;
          auto clampedSize                             = size;
          auto difference                              = end - bufferSize;
          if (!difference.IsValid())
          {
              return 0;
          }
          if (difference.ValueOrDie() > 0)
          {
              clampedSize = size - difference;
          }
          return clampedSize.ValueOrDefault(0);
      }
      else
      {
          return 0;
      }
  }
  
  }  // namespace gl
  

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