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

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• Hash : 3515113e
  Author :
  Date : 2024-06-24T15:10:28
  

  CL/Vulkan: Remove redundant state in CLImageVk
  
  Much of the image state can be queried from the front-end object.
  Removing all the redundant state from CLImageVk.
  
  Bug: angleproject:378103913
  Change-Id: I7783674da891d1af768375e5d8efd1937c4a4177
  Signed-off-by: Gowtham Tammana <g.tammana@samsung.com>
  Reviewed-on: https://chromium-review.googlesource.com/c/angle/angle/+/6004687
  Reviewed-by: Shahbaz Youssefi <syoussefi@chromium.org>
  Reviewed-by: Geoff Lang <geofflang@chromium.org>
  

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

• //
  // Copyright 2021 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.
  //
  // CLMemoryVk.cpp: Implements the class methods for CLMemoryVk.
  
  #include "libANGLE/renderer/vulkan/CLMemoryVk.h"
  #include "libANGLE/renderer/vulkan/CLContextVk.h"
  #include "libANGLE/renderer/vulkan/vk_cl_utils.h"
  #include "libANGLE/renderer/vulkan/vk_renderer.h"
  #include "libANGLE/renderer/vulkan/vk_utils.h"
  
  #include "libANGLE/renderer/CLMemoryImpl.h"
  #include "libANGLE/renderer/Format.h"
  #include "libANGLE/renderer/FormatID_autogen.h"
  
  #include "libANGLE/CLBuffer.h"
  #include "libANGLE/CLContext.h"
  #include "libANGLE/CLImage.h"
  #include "libANGLE/CLMemory.h"
  #include "libANGLE/Error.h"
  #include "libANGLE/cl_utils.h"
  
  #include "CL/cl_half.h"
  
  namespace rx
  {
  namespace
  {
  cl_int NormalizeFloatValue(float value, float maximum)
  {
      if (value < 0)
      {
          return 0;
      }
      if (value > 1.f)
      {
          return static_cast<cl_int>(maximum);
      }
      float valueToRound = (value * maximum);
  
      if (fabsf(valueToRound) < 0x1.0p23f)
      {
          constexpr float magic[2] = {0x1.0p23f, -0x1.0p23f};
          float magicVal           = magic[valueToRound < 0.0f];
          valueToRound += magicVal;
          valueToRound -= magicVal;
      }
  
      return static_cast<cl_int>(valueToRound);
  }
  
  angle::FormatID CLImageFormatToAngleFormat(cl_image_format format)
  {
      switch (format.image_channel_order)
      {
          case CL_R:
          case CL_LUMINANCE:
          case CL_INTENSITY:
              return angle::Format::CLRFormatToID(format.image_channel_data_type);
          case CL_RG:
              return angle::Format::CLRGFormatToID(format.image_channel_data_type);
          case CL_RGB:
              return angle::Format::CLRGBFormatToID(format.image_channel_data_type);
          case CL_RGBA:
              return angle::Format::CLRGBAFormatToID(format.image_channel_data_type);
          case CL_BGRA:
              return angle::Format::CLBGRAFormatToID(format.image_channel_data_type);
          case CL_sRGBA:
              return angle::Format::CLsRGBAFormatToID(format.image_channel_data_type);
          case CL_DEPTH:
              return angle::Format::CLDEPTHFormatToID(format.image_channel_data_type);
          case CL_DEPTH_STENCIL:
              return angle::Format::CLDEPTHSTENCILFormatToID(format.image_channel_data_type);
          default:
              return angle::FormatID::NONE;
      }
  }
  
  }  // namespace
  
  CLMemoryVk::CLMemoryVk(const cl::Memory &memory)
      : CLMemoryImpl(memory),
        mContext(&memory.getContext().getImpl<CLContextVk>()),
        mRenderer(mContext->getRenderer()),
        mMappedMemory(nullptr),
        mMapCount(0),
        mParent(nullptr)
  {}
  
  CLMemoryVk::~CLMemoryVk()
  {
      mContext->mAssociatedObjects->mMemories.erase(mMemory.getNative());
  }
  
  VkBufferUsageFlags CLMemoryVk::getVkUsageFlags()
  {
      return cl_vk::GetBufferUsageFlags(mMemory.getFlags());
  }
  
  VkMemoryPropertyFlags CLMemoryVk::getVkMemPropertyFlags()
  {
      return cl_vk::GetMemoryPropertyFlags(mMemory.getFlags());
  }
  
  angle::Result CLMemoryVk::map(uint8_t *&ptrOut, size_t offset)
  {
      if (!isMapped())
      {
          ANGLE_TRY(mapImpl());
      }
      ptrOut = mMappedMemory + offset;
      return angle::Result::Continue;
  }
  
  angle::Result CLMemoryVk::copyTo(void *dst, size_t srcOffset, size_t size)
  {
      uint8_t *src = nullptr;
      ANGLE_TRY(map(src, srcOffset));
      std::memcpy(dst, src, size);
      unmap();
      return angle::Result::Continue;
  }
  
  angle::Result CLMemoryVk::copyTo(CLMemoryVk *dst, size_t srcOffset, size_t dstOffset, size_t size)
  {
      uint8_t *dstPtr = nullptr;
      ANGLE_TRY(dst->map(dstPtr, dstOffset));
      ANGLE_TRY(copyTo(dstPtr, srcOffset, size));
      dst->unmap();
      return angle::Result::Continue;
  }
  
  angle::Result CLMemoryVk::copyFrom(const void *src, size_t srcOffset, size_t size)
  {
      uint8_t *dst = nullptr;
      ANGLE_TRY(map(dst, srcOffset));
      std::memcpy(dst, src, size);
      unmap();
      return angle::Result::Continue;
  }
  
  // Create a sub-buffer from the given buffer object
  angle::Result CLMemoryVk::createSubBuffer(const cl::Buffer &buffer,
                                            cl::MemFlags flags,
                                            size_t size,
                                            CLMemoryImpl::Ptr *subBufferOut)
  {
      ASSERT(buffer.isSubBuffer());
  
      CLBufferVk *bufferVk = new CLBufferVk(buffer);
      if (!bufferVk)
      {
          ANGLE_CL_RETURN_ERROR(CL_OUT_OF_HOST_MEMORY);
      }
      ANGLE_TRY(bufferVk->create(nullptr));
      *subBufferOut = CLMemoryImpl::Ptr(bufferVk);
  
      return angle::Result::Continue;
  }
  
  CLBufferVk::CLBufferVk(const cl::Buffer &buffer) : CLMemoryVk(buffer)
  {
      if (buffer.isSubBuffer())
      {
          mParent = &buffer.getParent()->getImpl<CLBufferVk>();
      }
      mDefaultBufferCreateInfo             = {};
      mDefaultBufferCreateInfo.sType       = VK_STRUCTURE_TYPE_BUFFER_CREATE_INFO;
      mDefaultBufferCreateInfo.size        = buffer.getSize();
      mDefaultBufferCreateInfo.usage       = getVkUsageFlags();
      mDefaultBufferCreateInfo.sharingMode = VK_SHARING_MODE_EXCLUSIVE;
  }
  
  CLBufferVk::~CLBufferVk()
  {
      if (isMapped())
      {
          unmap();
      }
      mBuffer.destroy(mRenderer);
  }
  
  vk::BufferHelper &CLBufferVk::getBuffer()
  {
      if (isSubBuffer())
      {
          return getParent()->getBuffer();
      }
      return mBuffer;
  }
  
  angle::Result CLBufferVk::create(void *hostPtr)
  {
      if (!isSubBuffer())
      {
          VkBufferCreateInfo createInfo  = mDefaultBufferCreateInfo;
          createInfo.size                = getSize();
          VkMemoryPropertyFlags memFlags = getVkMemPropertyFlags();
          if (IsError(mBuffer.init(mContext, createInfo, memFlags)))
          {
              ANGLE_CL_RETURN_ERROR(CL_OUT_OF_RESOURCES);
          }
          if (mMemory.getFlags().intersects(CL_MEM_USE_HOST_PTR | CL_MEM_COPY_HOST_PTR))
          {
              ASSERT(hostPtr);
              ANGLE_CL_IMPL_TRY_ERROR(setDataImpl(static_cast<uint8_t *>(hostPtr), getSize(), 0),
                                      CL_OUT_OF_RESOURCES);
          }
      }
      return angle::Result::Continue;
  }
  
  angle::Result CLBufferVk::mapImpl()
  {
      ASSERT(!isMapped());
  
      if (isSubBuffer())
      {
          ANGLE_TRY(mParent->map(mMappedMemory, getOffset()));
          return angle::Result::Continue;
      }
      ANGLE_TRY(mBuffer.map(mContext, &mMappedMemory));
      return angle::Result::Continue;
  }
  
  void CLBufferVk::unmapImpl()
  {
      if (!isSubBuffer())
      {
          mBuffer.unmap(mRenderer);
      }
      mMappedMemory = nullptr;
  }
  
  angle::Result CLBufferVk::setDataImpl(const uint8_t *data, size_t size, size_t offset)
  {
      // buffer cannot be in use state
      ASSERT(mBuffer.valid());
      ASSERT(!isCurrentlyInUse());
      ASSERT(size + offset <= getSize());
      ASSERT(data != nullptr);
  
      // Assuming host visible buffers for now
      // TODO: http://anglebug.com/42267019
      if (!mBuffer.isHostVisible())
      {
          UNIMPLEMENTED();
          ANGLE_CL_RETURN_ERROR(CL_OUT_OF_RESOURCES);
      }
  
      uint8_t *mapPointer = nullptr;
      ANGLE_TRY(mBuffer.mapWithOffset(mContext, &mapPointer, offset));
      ASSERT(mapPointer != nullptr);
  
      std::memcpy(mapPointer, data, size);
      mBuffer.unmap(mRenderer);
  
      return angle::Result::Continue;
  }
  
  bool CLBufferVk::isCurrentlyInUse() const
  {
      return !mRenderer->hasResourceUseFinished(mBuffer.getResourceUse());
  }
  
  VkImageUsageFlags CLImageVk::getVkImageUsageFlags()
  {
      VkImageUsageFlags usageFlags =
          VK_IMAGE_USAGE_TRANSFER_SRC_BIT | VK_IMAGE_USAGE_TRANSFER_DST_BIT;
  
      if (mMemory.getFlags().intersects(CL_MEM_WRITE_ONLY))
      {
          usageFlags |= VK_IMAGE_USAGE_STORAGE_BIT;
      }
      else if (mMemory.getFlags().intersects(CL_MEM_READ_ONLY))
      {
          usageFlags |= VK_IMAGE_USAGE_SAMPLED_BIT;
      }
      else
      {
          usageFlags |= VK_IMAGE_USAGE_SAMPLED_BIT | VK_IMAGE_USAGE_STORAGE_BIT;
      }
  
      return usageFlags;
  }
  
  VkImageType CLImageVk::getVkImageType(const cl::ImageDescriptor &desc)
  {
      VkImageType imageType = VK_IMAGE_TYPE_MAX_ENUM;
  
      switch (desc.type)
      {
          case cl::MemObjectType::Image1D_Buffer:
          case cl::MemObjectType::Image1D:
          case cl::MemObjectType::Image1D_Array:
              return VK_IMAGE_TYPE_1D;
          case cl::MemObjectType::Image2D:
          case cl::MemObjectType::Image2D_Array:
              return VK_IMAGE_TYPE_2D;
          case cl::MemObjectType::Image3D:
              return VK_IMAGE_TYPE_3D;
          default:
              UNREACHABLE();
      }
  
      return imageType;
  }
  
  angle::Result CLImageVk::createStagingBuffer(size_t size)
  {
      const VkBufferCreateInfo createInfo = {VK_STRUCTURE_TYPE_BUFFER_CREATE_INFO,
                                             nullptr,
                                             0,
                                             size,
                                             getVkUsageFlags(),
                                             VK_SHARING_MODE_EXCLUSIVE,
                                             0,
                                             nullptr};
      if (IsError(mStagingBuffer.init(mContext, createInfo, getVkMemPropertyFlags())))
      {
          ANGLE_CL_RETURN_ERROR(CL_OUT_OF_RESOURCES);
      }
  
      mStagingBufferInitialized = true;
      return angle::Result::Continue;
  }
  
  angle::Result CLImageVk::copyStagingFrom(void *ptr, size_t offset, size_t size)
  {
      uint8_t *ptrOut;
      uint8_t *ptrIn = static_cast<uint8_t *>(ptr);
      ANGLE_TRY(getStagingBuffer().map(mContext, &ptrOut));
      std::memcpy(ptrOut, ptrIn + offset, size);
      ANGLE_TRY(getStagingBuffer().flush(mRenderer));
      getStagingBuffer().unmap(mContext->getRenderer());
      return angle::Result::Continue;
  }
  
  angle::Result CLImageVk::copyStagingTo(void *ptr, size_t offset, size_t size)
  {
      uint8_t *ptrOut;
      ANGLE_TRY(getStagingBuffer().map(mContext, &ptrOut));
      ANGLE_TRY(getStagingBuffer().invalidate(mRenderer));
      std::memcpy(ptr, ptrOut + offset, size);
      getStagingBuffer().unmap(mContext->getRenderer());
      return angle::Result::Continue;
  }
  
  angle::Result CLImageVk::copyStagingToFromWithPitch(void *hostPtr,
                                                      const cl::Coordinate &region,
                                                      const size_t rowPitch,
                                                      const size_t slicePitch,
                                                      StagingBufferCopyDirection copyStagingTo)
  {
      uint8_t *ptrInBase  = nullptr;
      uint8_t *ptrOutBase = nullptr;
      cl::BufferBox stagingBufferBox{
          {},
          {static_cast<int>(region.x), static_cast<int>(region.y), static_cast<int>(region.z)},
          0,
          0,
          getElementSize()};
  
      if (copyStagingTo == StagingBufferCopyDirection::ToHost)
      {
          ptrOutBase = static_cast<uint8_t *>(hostPtr);
          ANGLE_TRY(getStagingBuffer().map(mContext, &ptrInBase));
      }
      else
      {
          ptrInBase = static_cast<uint8_t *>(hostPtr);
          ANGLE_TRY(getStagingBuffer().map(mContext, &ptrOutBase));
      }
      for (size_t slice = 0; slice < region.z; slice++)
      {
          for (size_t row = 0; row < region.y; row++)
          {
              size_t stagingBufferOffset = stagingBufferBox.getRowOffset(slice, row);
              size_t hostPtrOffset       = (slice * slicePitch + row * rowPitch);
              uint8_t *dst               = (copyStagingTo == StagingBufferCopyDirection::ToHost)
                                               ? ptrOutBase + hostPtrOffset
                                               : ptrOutBase + stagingBufferOffset;
              uint8_t *src               = (copyStagingTo == StagingBufferCopyDirection::ToHost)
                                               ? ptrInBase + stagingBufferOffset
                                               : ptrInBase + hostPtrOffset;
              memcpy(dst, src, region.x * getElementSize());
          }
      }
      getStagingBuffer().unmap(mContext->getRenderer());
      return angle::Result::Continue;
  }
  
  CLImageVk::CLImageVk(const cl::Image &image)
      : CLMemoryVk(image),
        mExtent(cl_vk::GetExtentFromDescriptor(image.getDescriptor())),
        mAngleFormat(CLImageFormatToAngleFormat(image.getFormat())),
        mStagingBufferInitialized(false),
        mImageViewType(cl_vk::GetImageViewType(image.getDescriptor().type))
  {}
  
  CLImageVk::~CLImageVk()
  {
      if (isMapped())
      {
          unmap();
      }
  
      mImage.destroy(mRenderer);
      mImageView.destroy(mContext->getDevice());
      if (isStagingBufferInitialized())
      {
          mStagingBuffer.destroy(mRenderer);
      }
  }
  
  angle::Result CLImageVk::create(void *hostPtr)
  {
      ANGLE_CL_IMPL_TRY_ERROR(mImage.initStaging(mContext, false, mRenderer->getMemoryProperties(),
                                                 getVkImageType(getDescriptor()), mExtent,
                                                 mAngleFormat, mAngleFormat, VK_SAMPLE_COUNT_1_BIT,
                                                 getVkImageUsageFlags(), 1, (uint32_t)getArraySize()),
                              CL_OUT_OF_RESOURCES);
  
      if (mMemory.getFlags().intersects(CL_MEM_USE_HOST_PTR | CL_MEM_COPY_HOST_PTR))
      {
          ASSERT(hostPtr);
          ANGLE_CL_IMPL_TRY_ERROR(createStagingBuffer(getSize()), CL_OUT_OF_RESOURCES);
          if (getDescriptor().rowPitch == 0 && getDescriptor().slicePitch == 0)
          {
              ANGLE_CL_IMPL_TRY_ERROR(copyStagingFrom(hostPtr, 0, getSize()), CL_OUT_OF_RESOURCES);
          }
          else
          {
              ANGLE_TRY(copyStagingToFromWithPitch(
                  hostPtr, {mExtent.width, mExtent.height, mExtent.depth}, getDescriptor().rowPitch,
                  getDescriptor().slicePitch, StagingBufferCopyDirection::ToStagingBuffer));
          }
          VkBufferImageCopy copyRegion{};
          copyRegion.bufferOffset      = 0;
          copyRegion.bufferRowLength   = 0;
          copyRegion.bufferImageHeight = 0;
          copyRegion.imageExtent = getExtentForCopy({mExtent.width, mExtent.height, mExtent.depth});
          copyRegion.imageOffset = getOffsetForCopy({0, 0, 0});
          copyRegion.imageSubresource =
              getSubresourceLayersForCopy({0, 0, 0}, {mExtent.width, mExtent.height, mExtent.depth},
                                          getDescriptor().type, ImageCopyWith::Buffer);
  
          ANGLE_CL_IMPL_TRY_ERROR(mImage.copyToBufferOneOff(mContext, &mStagingBuffer, copyRegion),
                                  CL_OUT_OF_RESOURCES);
      }
  
      ANGLE_TRY(initImageViewImpl());
      return angle::Result::Continue;
  }
  
  angle::Result CLImageVk::initImageViewImpl()
  {
      VkImageViewCreateInfo viewInfo = {};
      viewInfo.sType                 = VK_STRUCTURE_TYPE_IMAGE_VIEW_CREATE_INFO;
      viewInfo.flags                 = 0;
      viewInfo.image                 = getImage().getImage().getHandle();
      viewInfo.format                = getImage().getActualVkFormat();
      viewInfo.viewType              = mImageViewType;
  
      viewInfo.subresourceRange.aspectMask = VK_IMAGE_ASPECT_COLOR_BIT;
      // We don't support mip map levels and should have been validated
      ASSERT(getDescriptor().numMipLevels == 0);
      viewInfo.subresourceRange.baseMipLevel   = getDescriptor().numMipLevels;
      viewInfo.subresourceRange.levelCount     = 1;
      viewInfo.subresourceRange.baseArrayLayer = 0;
      viewInfo.subresourceRange.layerCount     = static_cast<uint32_t>(getArraySize());
  
      // no swizzle support for now
      viewInfo.components.r = VK_COMPONENT_SWIZZLE_IDENTITY;
      viewInfo.components.g = VK_COMPONENT_SWIZZLE_IDENTITY;
      viewInfo.components.b = VK_COMPONENT_SWIZZLE_IDENTITY;
      viewInfo.components.a = VK_COMPONENT_SWIZZLE_IDENTITY;
  
      VkImageViewUsageCreateInfo imageViewUsageCreateInfo = {};
      imageViewUsageCreateInfo.sType = VK_STRUCTURE_TYPE_IMAGE_VIEW_USAGE_CREATE_INFO;
      imageViewUsageCreateInfo.usage = getVkImageUsageFlags();
  
      viewInfo.pNext = &imageViewUsageCreateInfo;
  
      ANGLE_VK_TRY(mContext, mImageView.init(mContext->getDevice(), viewInfo));
      return angle::Result::Continue;
  }
  
  bool CLImageVk::isCurrentlyInUse() const
  {
      return !mRenderer->hasResourceUseFinished(mImage.getResourceUse());
  }
  
  bool CLImageVk::containsHostMemExtension()
  {
      const vk::ExtensionNameList &enabledDeviceExtensions = mRenderer->getEnabledDeviceExtensions();
      return std::find(enabledDeviceExtensions.begin(), enabledDeviceExtensions.end(),
                       "VK_EXT_external_memory_host") != enabledDeviceExtensions.end();
  }
  
  void CLImageVk::packPixels(const void *fillColor, PixelColor *packedColor)
  {
      size_t channelCount = cl::GetChannelCount(getFormat().image_channel_order);
  
      switch (getFormat().image_channel_data_type)
      {
          case CL_UNORM_INT8:
          {
              float *srcVector = static_cast<float *>(const_cast<void *>(fillColor));
              if (getFormat().image_channel_order == CL_BGRA)
              {
                  packedColor->u8[0] =
                      static_cast<unsigned char>(NormalizeFloatValue(srcVector[2], 255.f));
                  packedColor->u8[1] =
                      static_cast<unsigned char>(NormalizeFloatValue(srcVector[1], 255.f));
                  packedColor->u8[2] =
                      static_cast<unsigned char>(NormalizeFloatValue(srcVector[0], 255.f));
                  packedColor->u8[3] =
                      static_cast<unsigned char>(NormalizeFloatValue(srcVector[3], 255.f));
              }
              else
              {
                  for (unsigned int i = 0; i < channelCount; i++)
                      packedColor->u8[i] =
                          static_cast<unsigned char>(NormalizeFloatValue(srcVector[i], 255.f));
              }
              break;
          }
          case CL_SIGNED_INT8:
          {
              int *srcVector = static_cast<int *>(const_cast<void *>(fillColor));
              for (unsigned int i = 0; i < channelCount; i++)
                  packedColor->s8[i] = static_cast<char>(std::clamp(srcVector[i], -128, 127));
              break;
          }
          case CL_UNSIGNED_INT8:
          {
              unsigned int *srcVector = static_cast<unsigned int *>(const_cast<void *>(fillColor));
              for (unsigned int i = 0; i < channelCount; i++)
                  packedColor->u8[i] = static_cast<unsigned char>(
                      std::clamp(static_cast<unsigned int>(srcVector[i]),
                                 static_cast<unsigned int>(0), static_cast<unsigned int>(255)));
              break;
          }
          case CL_UNORM_INT16:
          {
              float *srcVector = static_cast<float *>(const_cast<void *>(fillColor));
              for (unsigned int i = 0; i < channelCount; i++)
                  packedColor->u16[i] =
                      static_cast<unsigned short>(NormalizeFloatValue(srcVector[i], 65535.f));
              break;
          }
          case CL_SIGNED_INT16:
          {
              int *srcVector = static_cast<int *>(const_cast<void *>(fillColor));
              for (unsigned int i = 0; i < channelCount; i++)
                  packedColor->s16[i] = static_cast<short>(std::clamp(srcVector[i], -32768, 32767));
              break;
          }
          case CL_UNSIGNED_INT16:
          {
              unsigned int *srcVector = static_cast<unsigned int *>(const_cast<void *>(fillColor));
              for (unsigned int i = 0; i < channelCount; i++)
                  packedColor->u16[i] = static_cast<unsigned short>(
                      std::clamp(static_cast<unsigned int>(srcVector[i]),
                                 static_cast<unsigned int>(0), static_cast<unsigned int>(65535)));
              break;
          }
          case CL_HALF_FLOAT:
          {
              float *srcVector = static_cast<float *>(const_cast<void *>(fillColor));
              for (unsigned int i = 0; i < channelCount; i++)
                  packedColor->fp16[i] = cl_half_from_float(srcVector[i], CL_HALF_RTE);
              break;
          }
          case CL_SIGNED_INT32:
          {
              int *srcVector = static_cast<int *>(const_cast<void *>(fillColor));
              for (unsigned int i = 0; i < channelCount; i++)
                  packedColor->s32[i] = static_cast<int>(srcVector[i]);
              break;
          }
          case CL_UNSIGNED_INT32:
          {
              unsigned int *srcVector = static_cast<unsigned int *>(const_cast<void *>(fillColor));
              for (unsigned int i = 0; i < channelCount; i++)
                  packedColor->u32[i] = static_cast<unsigned int>(srcVector[i]);
              break;
          }
          case CL_FLOAT:
          {
              float *srcVector = static_cast<float *>(const_cast<void *>(fillColor));
              for (unsigned int i = 0; i < channelCount; i++)
                  packedColor->fp32[i] = srcVector[i];
              break;
          }
          default:
              UNIMPLEMENTED();
              break;
      }
  }
  
  void CLImageVk::fillImageWithColor(const cl::MemOffsets &origin,
                                     const cl::Coordinate &region,
                                     uint8_t *imagePtr,
                                     PixelColor *packedColor)
  {
      size_t elementSize = getElementSize();
      cl::BufferBox stagingBufferBox{
          {},
          {static_cast<int>(mExtent.width), static_cast<int>(mExtent.height),
           static_cast<int>(mExtent.depth)},
          0,
          0,
          elementSize};
      uint8_t *ptrBase = imagePtr + (origin.z * stagingBufferBox.getSlicePitch()) +
                         (origin.y * stagingBufferBox.getRowPitch()) + (origin.x * elementSize);
      for (size_t slice = 0; slice < region.z; slice++)
      {
          for (size_t row = 0; row < region.y; row++)
          {
              size_t stagingBufferOffset = stagingBufferBox.getRowOffset(slice, row);
              uint8_t *pixelPtr          = ptrBase + stagingBufferOffset;
              for (size_t x = 0; x < region.x; x++)
              {
                  memcpy(pixelPtr, packedColor, elementSize);
                  pixelPtr += elementSize;
              }
          }
      }
  }
  
  VkExtent3D CLImageVk::getExtentForCopy(const cl::Coordinate &region)
  {
      VkExtent3D extent = {};
      extent.width      = static_cast<uint32_t>(region.x);
      extent.height     = static_cast<uint32_t>(region.y);
      extent.depth      = static_cast<uint32_t>(region.z);
      switch (getDescriptor().type)
      {
          case cl::MemObjectType::Image1D_Array:
  
              extent.height = 1;
              extent.depth  = 1;
              break;
          case cl::MemObjectType::Image2D_Array:
              extent.depth = 1;
              break;
          default:
              break;
      }
      return extent;
  }
  
  VkOffset3D CLImageVk::getOffsetForCopy(const cl::MemOffsets &origin)
  {
      VkOffset3D offset = {};
      offset.x          = static_cast<int32_t>(origin.x);
      offset.y          = static_cast<int32_t>(origin.y);
      offset.z          = static_cast<int32_t>(origin.z);
      switch (getDescriptor().type)
      {
          case cl::MemObjectType::Image1D_Array:
              offset.y = 0;
              offset.z = 0;
              break;
          case cl::MemObjectType::Image2D_Array:
              offset.z = 0;
              break;
          default:
              break;
      }
      return offset;
  }
  
  VkImageSubresourceLayers CLImageVk::getSubresourceLayersForCopy(const cl::MemOffsets &origin,
                                                                  const cl::Coordinate &region,
                                                                  cl::MemObjectType copyToType,
                                                                  ImageCopyWith imageCopy)
  {
      VkImageSubresourceLayers subresource = {};
      subresource.aspectMask               = VK_IMAGE_ASPECT_COLOR_BIT;
      subresource.mipLevel                 = 0;
      switch (getDescriptor().type)
      {
          case cl::MemObjectType::Image1D_Array:
              subresource.baseArrayLayer = static_cast<uint32_t>(origin.y);
              if (imageCopy == ImageCopyWith::Image)
              {
                  subresource.layerCount = static_cast<uint32_t>(region.y);
              }
              else
              {
                  subresource.layerCount = static_cast<uint32_t>(getArraySize());
              }
              break;
          case cl::MemObjectType::Image2D_Array:
              subresource.baseArrayLayer = static_cast<uint32_t>(origin.z);
              if (copyToType == cl::MemObjectType::Image2D ||
                  copyToType == cl::MemObjectType::Image3D)
              {
                  subresource.layerCount = 1;
              }
              else if (imageCopy == ImageCopyWith::Image)
              {
                  subresource.layerCount = static_cast<uint32_t>(region.z);
              }
              else
              {
                  subresource.layerCount = static_cast<uint32_t>(getArraySize());
              }
              break;
          default:
              subresource.baseArrayLayer = 0;
              subresource.layerCount     = 1;
              break;
      }
      return subresource;
  }
  
  angle::Result CLImageVk::mapImpl()
  {
      ASSERT(!isMapped());
  
      ASSERT(isStagingBufferInitialized());
      ANGLE_TRY(getStagingBuffer().map(mContext, &mMappedMemory));
  
      return angle::Result::Continue;
  }
  void CLImageVk::unmapImpl()
  {
      getStagingBuffer().unmap(mContext->getRenderer());
      mMappedMemory = nullptr;
  }
  
  size_t CLImageVk::getRowPitch() const
  {
      return getFrontendObject().getRowSize();
  }
  
  size_t CLImageVk::getSlicePitch() const
  {
      return getFrontendObject().getSliceSize();
  }
  
  }  // namespace rx
  

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