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

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• Hash : a1be7e61
  Author :
  Date : 2024-11-26T14:39:18
  

  Implement EGL_EXT_surface_compression
  
  This patch adds implementation of EGL_EXT_surface_compression to
  ANGLE, including new API eglQuerySupportedCompressionRatesEXT and
  adding EGL_SURFACE_COMPRESSION_EXT in EGLQuerySurface and
  EGLCreateWindowSurface/EGLCreatePlatformWindowSurface.
  Angle end2end test is added to verify the extension.
  
  Bug: angleproject:375496226
  Change-Id: I06926930d94485a378fc831d552cf55fe7938a57
  Reviewed-on: https://chromium-review.googlesource.com/c/angle/angle/+/6073355
  Commit-Queue: Shahbaz Youssefi <syoussefi@chromium.org>
  Reviewed-by: Charlie Lao <cclao@google.com>
  Reviewed-by: Shahbaz Youssefi <syoussefi@chromium.org>
  

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• src/libANGLE/renderer/vulkan/DisplayVk.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.
  //
  // DisplayVk.cpp:
  //    Implements the class methods for DisplayVk.
  //
  
  #include "libANGLE/renderer/vulkan/DisplayVk.h"
  
  #include "common/debug.h"
  #include "common/system_utils.h"
  #include "libANGLE/BlobCache.h"
  #include "libANGLE/Context.h"
  #include "libANGLE/Display.h"
  #include "libANGLE/renderer/vulkan/BufferVk.h"
  #include "libANGLE/renderer/vulkan/ContextVk.h"
  #include "libANGLE/renderer/vulkan/DeviceVk.h"
  #include "libANGLE/renderer/vulkan/ImageVk.h"
  #include "libANGLE/renderer/vulkan/ShareGroupVk.h"
  #include "libANGLE/renderer/vulkan/SurfaceVk.h"
  #include "libANGLE/renderer/vulkan/SyncVk.h"
  #include "libANGLE/renderer/vulkan/TextureVk.h"
  #include "libANGLE/renderer/vulkan/VkImageImageSiblingVk.h"
  #include "libANGLE/renderer/vulkan/vk_helpers.h"
  #include "libANGLE/renderer/vulkan/vk_renderer.h"
  
  namespace rx
  {
  
  namespace
  {
  // Query surface format and colorspace support.
  void GetSupportedFormatColorspaces(VkPhysicalDevice physicalDevice,
                                     const angle::FeaturesVk &featuresVk,
                                     VkSurfaceKHR surface,
                                     std::vector<VkSurfaceFormat2KHR> *surfaceFormatsOut)
  {
      ASSERT(surfaceFormatsOut);
      surfaceFormatsOut->clear();
  
      constexpr VkSurfaceFormat2KHR kSurfaceFormat2Initializer = {
          VK_STRUCTURE_TYPE_SURFACE_FORMAT_2_KHR,
          nullptr,
          {VK_FORMAT_UNDEFINED, VK_COLOR_SPACE_SRGB_NONLINEAR_KHR}};
  
      if (featuresVk.supportsSurfaceCapabilities2Extension.enabled)
      {
          VkPhysicalDeviceSurfaceInfo2KHR surfaceInfo2 = {};
          surfaceInfo2.sType          = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_SURFACE_INFO_2_KHR;
          surfaceInfo2.surface        = surface;
          uint32_t surfaceFormatCount = 0;
  
          // Query the count first
          VkResult result = vkGetPhysicalDeviceSurfaceFormats2KHR(physicalDevice, &surfaceInfo2,
                                                                  &surfaceFormatCount, nullptr);
          ASSERT(result == VK_SUCCESS);
          ASSERT(surfaceFormatCount > 0);
  
          // Query the VkSurfaceFormat2KHR list
          std::vector<VkSurfaceFormat2KHR> surfaceFormats2(surfaceFormatCount,
                                                           kSurfaceFormat2Initializer);
          result = vkGetPhysicalDeviceSurfaceFormats2KHR(physicalDevice, &surfaceInfo2,
                                                         &surfaceFormatCount, surfaceFormats2.data());
          ASSERT(result == VK_SUCCESS);
  
          *surfaceFormatsOut = std::move(surfaceFormats2);
      }
      else
      {
          uint32_t surfaceFormatCount = 0;
          // Query the count first
          VkResult result = vkGetPhysicalDeviceSurfaceFormatsKHR(physicalDevice, surface,
                                                                 &surfaceFormatCount, nullptr);
          ASSERT(result == VK_SUCCESS);
  
          // Query the VkSurfaceFormatKHR list
          std::vector<VkSurfaceFormatKHR> surfaceFormats(surfaceFormatCount);
          result = vkGetPhysicalDeviceSurfaceFormatsKHR(physicalDevice, surface, &surfaceFormatCount,
                                                        surfaceFormats.data());
          ASSERT(result == VK_SUCCESS);
  
          // Copy over data from std::vector<VkSurfaceFormatKHR> to std::vector<VkSurfaceFormat2KHR>
          std::vector<VkSurfaceFormat2KHR> surfaceFormats2(surfaceFormatCount,
                                                           kSurfaceFormat2Initializer);
          for (size_t index = 0; index < surfaceFormatCount; index++)
          {
              surfaceFormats2[index].surfaceFormat.format = surfaceFormats[index].format;
          }
  
          *surfaceFormatsOut = std::move(surfaceFormats2);
      }
  }
  
  vk::UseDebugLayers ShouldLoadDebugLayers(const egl::AttributeMap &attribs)
  {
      EGLAttrib debugSetting =
          attribs.get(EGL_PLATFORM_ANGLE_DEBUG_LAYERS_ENABLED_ANGLE, EGL_DONT_CARE);
  
  #if defined(ANGLE_ENABLE_VULKAN_VALIDATION_LAYERS_BY_DEFAULT)
      const bool yes = ShouldUseDebugLayers(attribs);
  #else
      const bool yes = debugSetting == EGL_TRUE;
  #endif  // defined(ANGLE_ENABLE_VULKAN_VALIDATION_LAYERS_BY_DEFAULT)
  
      const bool ifAvailable = debugSetting == EGL_DONT_CARE;
  
      return yes && ifAvailable ? vk::UseDebugLayers::YesIfAvailable
             : yes              ? vk::UseDebugLayers::Yes
                                : vk::UseDebugLayers::No;
  }
  
  angle::vk::ICD ChooseICDFromAttribs(const egl::AttributeMap &attribs)
  {
  #if !defined(ANGLE_PLATFORM_ANDROID)
      // Mock ICD does not currently run on Android
      EGLAttrib deviceType = attribs.get(EGL_PLATFORM_ANGLE_DEVICE_TYPE_ANGLE,
                                         EGL_PLATFORM_ANGLE_DEVICE_TYPE_HARDWARE_ANGLE);
  
      switch (deviceType)
      {
          case EGL_PLATFORM_ANGLE_DEVICE_TYPE_HARDWARE_ANGLE:
              break;
          case EGL_PLATFORM_ANGLE_DEVICE_TYPE_NULL_ANGLE:
              return angle::vk::ICD::Mock;
          case EGL_PLATFORM_ANGLE_DEVICE_TYPE_SWIFTSHADER_ANGLE:
              return angle::vk::ICD::SwiftShader;
          default:
              UNREACHABLE();
              break;
      }
  #endif  // !defined(ANGLE_PLATFORM_ANDROID)
  
      return angle::vk::ICD::Default;
  }
  
  void InstallDebugAnnotator(egl::Display *display, vk::Renderer *renderer)
  {
      bool installedAnnotator = false;
  
      // Ensure the appropriate global DebugAnnotator is used
      ASSERT(renderer);
      renderer->setGlobalDebugAnnotator(&installedAnnotator);
  
      if (!installedAnnotator)
      {
          std::unique_lock<angle::SimpleMutex> lock(gl::GetDebugMutex());
          display->setGlobalDebugAnnotator();
      }
  }
  }  // namespace
  
  DisplayVk::DisplayVk(const egl::DisplayState &state)
      : DisplayImpl(state),
        vk::Context(new vk::Renderer()),
        mScratchBuffer(1000u),
        mSupportedColorspaceFormatsMap{}
  {}
  
  DisplayVk::~DisplayVk()
  {
      delete mRenderer;
  }
  
  egl::Error DisplayVk::initialize(egl::Display *display)
  {
      ASSERT(mRenderer != nullptr && display != nullptr);
      const egl::AttributeMap &attribs = display->getAttributeMap();
  
      const vk::UseDebugLayers useDebugLayers = ShouldLoadDebugLayers(attribs);
      const angle::vk::ICD desiredICD         = ChooseICDFromAttribs(attribs);
      const uint32_t preferredVendorId =
          static_cast<uint32_t>(attribs.get(EGL_PLATFORM_ANGLE_DEVICE_ID_HIGH_ANGLE, 0));
      const uint32_t preferredDeviceId =
          static_cast<uint32_t>(attribs.get(EGL_PLATFORM_ANGLE_DEVICE_ID_LOW_ANGLE, 0));
  
      angle::Result result = mRenderer->initialize(
          this, this, desiredICD, preferredVendorId, preferredDeviceId, useDebugLayers,
          getWSIExtension(), getWSILayer(), getWindowSystem(), mState.featureOverrides);
      ANGLE_TRY(angle::ToEGL(result, EGL_NOT_INITIALIZED));
  
      mDeviceQueueIndex = mRenderer->getDeviceQueueIndex(egl::ContextPriority::Medium);
  
      InstallDebugAnnotator(display, mRenderer);
  
      // Query and cache supported surface format and colorspace for later use.
      initSupportedSurfaceFormatColorspaces();
      return egl::NoError();
  }
  
  void DisplayVk::terminate()
  {
      mRenderer->reloadVolkIfNeeded();
  
      ASSERT(mRenderer);
      mRenderer->onDestroy(this);
  }
  
  egl::Error DisplayVk::makeCurrent(egl::Display *display,
                                    egl::Surface * /*drawSurface*/,
                                    egl::Surface * /*readSurface*/,
                                    gl::Context * /*context*/)
  {
      InstallDebugAnnotator(display, mRenderer);
      return egl::NoError();
  }
  
  bool DisplayVk::testDeviceLost()
  {
      return mRenderer->isDeviceLost();
  }
  
  egl::Error DisplayVk::restoreLostDevice(const egl::Display *display)
  {
      // A vulkan device cannot be restored, the entire renderer would have to be re-created along
      // with any other EGL objects that reference it.
      return egl::EglBadDisplay();
  }
  
  std::string DisplayVk::getRendererDescription()
  {
      if (mRenderer)
      {
          return mRenderer->getRendererDescription();
      }
      return std::string();
  }
  
  std::string DisplayVk::getVendorString()
  {
      if (mRenderer)
      {
          return mRenderer->getVendorString();
      }
      return std::string();
  }
  
  std::string DisplayVk::getVersionString(bool includeFullVersion)
  {
      if (mRenderer)
      {
          return mRenderer->getVersionString(includeFullVersion);
      }
      return std::string();
  }
  
  DeviceImpl *DisplayVk::createDevice()
  {
      return new DeviceVk();
  }
  
  egl::Error DisplayVk::waitClient(const gl::Context *context)
  {
      ANGLE_TRACE_EVENT0("gpu.angle", "DisplayVk::waitClient");
      ContextVk *contextVk = vk::GetImpl(context);
      return angle::ToEGL(contextVk->finishImpl(RenderPassClosureReason::EGLWaitClient),
                          EGL_BAD_ACCESS);
  }
  
  egl::Error DisplayVk::waitNative(const gl::Context *context, EGLint engine)
  {
      ANGLE_TRACE_EVENT0("gpu.angle", "DisplayVk::waitNative");
      return angle::ResultToEGL(waitNativeImpl());
  }
  
  angle::Result DisplayVk::waitNativeImpl()
  {
      return angle::Result::Continue;
  }
  
  SurfaceImpl *DisplayVk::createWindowSurface(const egl::SurfaceState &state,
                                              EGLNativeWindowType window,
                                              const egl::AttributeMap &attribs)
  {
      return createWindowSurfaceVk(state, window);
  }
  
  SurfaceImpl *DisplayVk::createPbufferSurface(const egl::SurfaceState &state,
                                               const egl::AttributeMap &attribs)
  {
      ASSERT(mRenderer);
      return new OffscreenSurfaceVk(state, mRenderer);
  }
  
  SurfaceImpl *DisplayVk::createPbufferFromClientBuffer(const egl::SurfaceState &state,
                                                        EGLenum buftype,
                                                        EGLClientBuffer clientBuffer,
                                                        const egl::AttributeMap &attribs)
  {
      UNIMPLEMENTED();
      return static_cast<SurfaceImpl *>(0);
  }
  
  SurfaceImpl *DisplayVk::createPixmapSurface(const egl::SurfaceState &state,
                                              NativePixmapType nativePixmap,
                                              const egl::AttributeMap &attribs)
  {
      UNIMPLEMENTED();
      return static_cast<SurfaceImpl *>(0);
  }
  
  ImageImpl *DisplayVk::createImage(const egl::ImageState &state,
                                    const gl::Context *context,
                                    EGLenum target,
                                    const egl::AttributeMap &attribs)
  {
      return new ImageVk(state, context);
  }
  
  ShareGroupImpl *DisplayVk::createShareGroup(const egl::ShareGroupState &state)
  {
      return new ShareGroupVk(state, mRenderer);
  }
  
  bool DisplayVk::isConfigFormatSupported(VkFormat format) const
  {
      // Requires VK_GOOGLE_surfaceless_query extension to be supported.
      ASSERT(mRenderer->getFeatures().supportsSurfacelessQueryExtension.enabled);
  
      // A format is considered supported if it is supported in atleast 1 colorspace.
      using ColorspaceFormatSetItem =
          const std::pair<const VkColorSpaceKHR, std::unordered_set<VkFormat>>;
      for (ColorspaceFormatSetItem &colorspaceFormatSetItem : mSupportedColorspaceFormatsMap)
      {
          if (colorspaceFormatSetItem.second.count(format) > 0)
          {
              return true;
          }
      }
  
      return false;
  }
  
  bool DisplayVk::isSurfaceFormatColorspacePairSupported(VkSurfaceKHR surface,
                                                         VkFormat format,
                                                         VkColorSpaceKHR colorspace) const
  {
      if (mSupportedColorspaceFormatsMap.size() > 0)
      {
          return mSupportedColorspaceFormatsMap.count(colorspace) > 0 &&
                 mSupportedColorspaceFormatsMap.at(colorspace).count(format) > 0;
      }
      else
      {
          const angle::FeaturesVk &featuresVk = mRenderer->getFeatures();
          std::vector<VkSurfaceFormat2KHR> surfaceFormats;
          GetSupportedFormatColorspaces(mRenderer->getPhysicalDevice(), featuresVk, surface,
                                        &surfaceFormats);
  
          if (!featuresVk.supportsSurfaceCapabilities2Extension.enabled)
          {
              if (surfaceFormats.size() == 1u &&
                  surfaceFormats[0].surfaceFormat.format == VK_FORMAT_UNDEFINED)
              {
                  return true;
              }
          }
  
          for (const VkSurfaceFormat2KHR &surfaceFormat : surfaceFormats)
          {
              if (surfaceFormat.surfaceFormat.format == format &&
                  surfaceFormat.surfaceFormat.colorSpace == colorspace)
              {
                  return true;
              }
          }
      }
  
      return false;
  }
  
  bool DisplayVk::isColorspaceSupported(VkColorSpaceKHR colorspace) const
  {
      return mSupportedColorspaceFormatsMap.count(colorspace) > 0;
  }
  
  void DisplayVk::initSupportedSurfaceFormatColorspaces()
  {
      const angle::FeaturesVk &featuresVk = mRenderer->getFeatures();
      if (featuresVk.supportsSurfacelessQueryExtension.enabled &&
          featuresVk.supportsSurfaceCapabilities2Extension.enabled)
      {
          // Use the VK_GOOGLE_surfaceless_query extension to query supported surface formats and
          // colorspaces by using a VK_NULL_HANDLE for the VkSurfaceKHR handle.
          std::vector<VkSurfaceFormat2KHR> surfaceFormats;
          GetSupportedFormatColorspaces(mRenderer->getPhysicalDevice(), featuresVk, VK_NULL_HANDLE,
                                        &surfaceFormats);
          for (const VkSurfaceFormat2KHR &surfaceFormat : surfaceFormats)
          {
              // Cache supported VkFormat and VkColorSpaceKHR for later use
              VkFormat format            = surfaceFormat.surfaceFormat.format;
              VkColorSpaceKHR colorspace = surfaceFormat.surfaceFormat.colorSpace;
  
              ASSERT(format != VK_FORMAT_UNDEFINED);
  
              mSupportedColorspaceFormatsMap[colorspace].insert(format);
          }
  
          ASSERT(mSupportedColorspaceFormatsMap.size() > 0);
      }
      else
      {
          mSupportedColorspaceFormatsMap.clear();
      }
  }
  
  ContextImpl *DisplayVk::createContext(const gl::State &state,
                                        gl::ErrorSet *errorSet,
                                        const egl::Config *configuration,
                                        const gl::Context *shareContext,
                                        const egl::AttributeMap &attribs)
  {
      return new ContextVk(state, errorSet, mRenderer);
  }
  
  StreamProducerImpl *DisplayVk::createStreamProducerD3DTexture(
      egl::Stream::ConsumerType consumerType,
      const egl::AttributeMap &attribs)
  {
      UNIMPLEMENTED();
      return static_cast<StreamProducerImpl *>(0);
  }
  
  EGLSyncImpl *DisplayVk::createSync()
  {
      return new EGLSyncVk();
  }
  
  gl::Version DisplayVk::getMaxSupportedESVersion() const
  {
      return mRenderer->getMaxSupportedESVersion();
  }
  
  gl::Version DisplayVk::getMaxConformantESVersion() const
  {
      return mRenderer->getMaxConformantESVersion();
  }
  
  egl::Error DisplayVk::validateImageClientBuffer(const gl::Context *context,
                                                  EGLenum target,
                                                  EGLClientBuffer clientBuffer,
                                                  const egl::AttributeMap &attribs) const
  {
      switch (target)
      {
          case EGL_VULKAN_IMAGE_ANGLE:
          {
              VkImage *vkImage = reinterpret_cast<VkImage *>(clientBuffer);
              if (!vkImage || *vkImage == VK_NULL_HANDLE)
              {
                  return egl::EglBadParameter() << "clientBuffer is invalid.";
              }
  
              GLenum internalFormat =
                  static_cast<GLenum>(attribs.get(EGL_TEXTURE_INTERNAL_FORMAT_ANGLE, GL_NONE));
              switch (internalFormat)
              {
                  case GL_RGBA:
                  case GL_BGRA_EXT:
                  case GL_RGB:
                  case GL_RED_EXT:
                  case GL_RG_EXT:
                  case GL_RGB10_A2_EXT:
                  case GL_R16_EXT:
                  case GL_RG16_EXT:
                  case GL_NONE:
                      break;
                  default:
                      return egl::EglBadParameter() << "Invalid EGLImage texture internal format: 0x"
                                                    << std::hex << internalFormat;
              }
  
              uint64_t hi = static_cast<uint64_t>(attribs.get(EGL_VULKAN_IMAGE_CREATE_INFO_HI_ANGLE));
              uint64_t lo = static_cast<uint64_t>(attribs.get(EGL_VULKAN_IMAGE_CREATE_INFO_LO_ANGLE));
              uint64_t info = ((hi & 0xffffffff) << 32) | (lo & 0xffffffff);
              if (reinterpret_cast<const VkImageCreateInfo *>(info)->sType !=
                  VK_STRUCTURE_TYPE_IMAGE_CREATE_INFO)
              {
                  return egl::EglBadParameter()
                         << "EGL_VULKAN_IMAGE_CREATE_INFO_HI_ANGLE and "
                            "EGL_VULKAN_IMAGE_CREATE_INFO_LO_ANGLE are not pointing to a "
                            "valid VkImageCreateInfo structure.";
              }
  
              return egl::NoError();
          }
          default:
              return DisplayImpl::validateImageClientBuffer(context, target, clientBuffer, attribs);
      }
  }
  
  ExternalImageSiblingImpl *DisplayVk::createExternalImageSibling(const gl::Context *context,
                                                                  EGLenum target,
                                                                  EGLClientBuffer buffer,
                                                                  const egl::AttributeMap &attribs)
  {
      switch (target)
      {
          case EGL_VULKAN_IMAGE_ANGLE:
              return new VkImageImageSiblingVk(buffer, attribs);
          default:
              return DisplayImpl::createExternalImageSibling(context, target, buffer, attribs);
      }
  }
  
  void DisplayVk::generateExtensions(egl::DisplayExtensions *outExtensions) const
  {
      outExtensions->createContextRobustness  = getRenderer()->getNativeExtensions().robustnessAny();
      outExtensions->surfaceOrientation       = true;
      outExtensions->displayTextureShareGroup = true;
      outExtensions->displaySemaphoreShareGroup        = true;
      outExtensions->robustResourceInitializationANGLE = true;
  
      // The Vulkan implementation will always say that EGL_KHR_swap_buffers_with_damage is supported.
      // When the Vulkan driver supports VK_KHR_incremental_present, it will use it.  Otherwise, it
      // will ignore the hint and do a regular swap.
      outExtensions->swapBuffersWithDamage = true;
  
      outExtensions->fenceSync            = true;
      outExtensions->waitSync             = true;
      outExtensions->globalFenceSyncANGLE = true;
  
      outExtensions->image                 = true;
      outExtensions->imageBase             = true;
      outExtensions->imagePixmap           = false;  // ANGLE does not support pixmaps
      outExtensions->glTexture2DImage      = true;
      outExtensions->glTextureCubemapImage = true;
      outExtensions->glTexture3DImage      = getFeatures().supportsSampler2dViewOf3d.enabled;
      outExtensions->glRenderbufferImage = true;
      outExtensions->imageNativeBuffer     = getFeatures().supportsAndroidHardwareBuffer.enabled;
      outExtensions->surfacelessContext = true;
      outExtensions->glColorspace       = true;
      outExtensions->imageGlColorspace =
          outExtensions->glColorspace && getFeatures().supportsImageFormatList.enabled;
  
  #if defined(ANGLE_PLATFORM_ANDROID)
      outExtensions->getNativeClientBufferANDROID = true;
      outExtensions->framebufferTargetANDROID     = true;
  
      // Only expose EGL_ANDROID_front_buffer_auto_refresh on Android and when Vulkan supports
      // VK_EXT_swapchain_maintenance1 (supportsSwapchainMaintenance1 feature), since we know that
      // VK_PRESENT_MODE_SHARED_DEMAND_REFRESH_KHR and VK_PRESENT_MODE_SHARED_CONTINUOUS_REFRESH_KHR
      // are compatible on Android (does not require swapchain recreation).
      outExtensions->frontBufferAutoRefreshANDROID =
          getFeatures().supportsSwapchainMaintenance1.enabled;
  #endif  // defined(ANGLE_PLATFORM_ANDROID)
  
      // EGL_EXT_image_dma_buf_import is only exposed if EGL_EXT_image_dma_buf_import_modifiers can
      // also be exposed.  The Vulkan extensions that support these EGL extensions are not split in
      // the same way; both Vulkan extensions are needed for EGL_EXT_image_dma_buf_import, and with
      // both Vulkan extensions, EGL_EXT_image_dma_buf_import_modifiers is also supportable.
      outExtensions->imageDmaBufImportEXT =
          getFeatures().supportsExternalMemoryDmaBufAndModifiers.enabled;
      outExtensions->imageDmaBufImportModifiersEXT = outExtensions->imageDmaBufImportEXT;
  
      // Disable context priority when non-zero memory init is enabled. This enforces a queue order.
      outExtensions->contextPriority = !getFeatures().allocateNonZeroMemory.enabled;
      outExtensions->noConfigContext = true;
  
  #if defined(ANGLE_PLATFORM_ANDROID) || defined(ANGLE_PLATFORM_LINUX)
      outExtensions->nativeFenceSyncANDROID = getFeatures().supportsAndroidNativeFenceSync.enabled;
  #endif  // defined(ANGLE_PLATFORM_ANDROID) || defined(ANGLE_PLATFORM_LINUX)
  
  #if defined(ANGLE_PLATFORM_GGP)
      outExtensions->ggpStreamDescriptor = true;
      outExtensions->swapWithFrameToken  = getFeatures().supportsGGPFrameToken.enabled;
  #endif  // defined(ANGLE_PLATFORM_GGP)
  
      outExtensions->bufferAgeEXT = true;
  
      outExtensions->protectedContentEXT = (getFeatures().supportsProtectedMemory.enabled &&
                                            getFeatures().supportsSurfaceProtectedSwapchains.enabled);
  
      outExtensions->createSurfaceSwapIntervalANGLE = true;
  
      outExtensions->mutableRenderBufferKHR =
          getFeatures().supportsSharedPresentableImageExtension.enabled;
  
      outExtensions->vulkanImageANGLE = true;
  
      outExtensions->lockSurface3KHR = getFeatures().supportsLockSurfaceExtension.enabled;
  
      outExtensions->partialUpdateKHR = true;
  
      outExtensions->timestampSurfaceAttributeANGLE =
          getFeatures().supportsTimestampSurfaceAttribute.enabled;
  
      outExtensions->eglColorspaceAttributePassthroughANGLE =
          outExtensions->glColorspace && getFeatures().eglColorspaceAttributePassthrough.enabled;
  
      // If EGL_KHR_gl_colorspace extension is supported check if other colorspace extensions
      // can be supported as well.
      if (outExtensions->glColorspace)
      {
          if (isColorspaceSupported(VK_COLOR_SPACE_DISPLAY_P3_NONLINEAR_EXT))
          {
              outExtensions->glColorspaceDisplayP3            = true;
              outExtensions->glColorspaceDisplayP3Passthrough = true;
          }
  
          outExtensions->glColorspaceDisplayP3Linear =
              isColorspaceSupported(VK_COLOR_SPACE_DISPLAY_P3_LINEAR_EXT);
          outExtensions->glColorspaceScrgb =
              isColorspaceSupported(VK_COLOR_SPACE_EXTENDED_SRGB_NONLINEAR_EXT);
          outExtensions->glColorspaceScrgbLinear =
              isColorspaceSupported(VK_COLOR_SPACE_EXTENDED_SRGB_LINEAR_EXT);
          outExtensions->glColorspaceBt2020Linear =
              isColorspaceSupported(VK_COLOR_SPACE_BT2020_LINEAR_EXT);
          outExtensions->glColorspaceBt2020Pq =
              isColorspaceSupported(VK_COLOR_SPACE_HDR10_ST2084_EXT);
          outExtensions->glColorspaceBt2020Hlg = isColorspaceSupported(VK_COLOR_SPACE_HDR10_HLG_EXT);
      }
  
      outExtensions->surfaceCompressionEXT =
          getFeatures().supportsImageCompressionControlSwapchain.enabled;
  }
  
  void DisplayVk::generateCaps(egl::Caps *outCaps) const
  {
      outCaps->textureNPOT = true;
      outCaps->stencil8    = getRenderer()->getNativeExtensions().textureStencil8OES;
  }
  
  const char *DisplayVk::getWSILayer() const
  {
      return nullptr;
  }
  
  void DisplayVk::handleError(VkResult result,
                              const char *file,
                              const char *function,
                              unsigned int line)
  {
      ASSERT(result != VK_SUCCESS);
  
      std::stringstream errorStream;
      errorStream << "Internal Vulkan error (" << result << "): " << VulkanResultString(result)
                  << ", in " << file << ", " << function << ":" << line << ".";
      std::string errorString = errorStream.str();
  
      if (result == VK_ERROR_DEVICE_LOST)
      {
          WARN() << errorString;
          mRenderer->notifyDeviceLost();
      }
  
      // Note: the errorCode will be set later in angle::ToEGL where it's available.
      *egl::Display::GetCurrentThreadErrorScratchSpace() = egl::Error(0, 0, std::move(errorString));
  }
  
  void DisplayVk::initializeFrontendFeatures(angle::FrontendFeatures *features) const
  {
      mRenderer->initializeFrontendFeatures(features);
  }
  
  void DisplayVk::populateFeatureList(angle::FeatureList *features)
  {
      mRenderer->getFeatures().populateFeatureList(features);
  }
  
  // vk::GlobalOps
  void DisplayVk::putBlob(const angle::BlobCacheKey &key, const angle::MemoryBuffer &value)
  {
      getBlobCache()->putApplication(nullptr, key, value);
  }
  
  bool DisplayVk::getBlob(const angle::BlobCacheKey &key, angle::BlobCacheValue *valueOut)
  {
      return getBlobCache()->get(nullptr, &mScratchBuffer, key, valueOut);
  }
  
  std::shared_ptr<angle::WaitableEvent> DisplayVk::postMultiThreadWorkerTask(
      const std::shared_ptr<angle::Closure> &task)
  {
      return mState.multiThreadPool->postWorkerTask(task);
  }
  
  void DisplayVk::notifyDeviceLost()
  {
      mState.notifyDeviceLost();
  }
  
  egl::Error DisplayVk::querySupportedCompressionRates(const egl::Config *configuration,
                                                       const egl::AttributeMap &attributes,
                                                       EGLint *rates,
                                                       EGLint rate_size,
                                                       EGLint *num_rates) const
  {
      ASSERT(mRenderer->getFeatures().supportsImageCompressionControl.enabled);
      ASSERT(mRenderer->getFeatures().supportsImageCompressionControlSwapchain.enabled);
  
      if (rate_size == 0 || rates == nullptr)
      {
          *num_rates = 0;
          return egl::NoError();
      }
  
      const vk::Format &format = mRenderer->getFormat(configuration->renderTargetFormat);
  
      VkImageCompressionControlEXT compressionInfo = {};
      compressionInfo.sType                        = VK_STRUCTURE_TYPE_IMAGE_COMPRESSION_CONTROL_EXT;
      compressionInfo.flags                        = VK_IMAGE_COMPRESSION_FIXED_RATE_DEFAULT_EXT;
      compressionInfo.compressionControlPlaneCount = 1;
  
      VkPhysicalDeviceImageFormatInfo2 imageFormatInfo = {};
      imageFormatInfo.sType = VK_STRUCTURE_TYPE_PHYSICAL_DEVICE_IMAGE_FORMAT_INFO_2;
      imageFormatInfo.pNext = &compressionInfo;
      imageFormatInfo.format =
          vk::GetVkFormatFromFormatID(mRenderer, format.getActualRenderableImageFormatID());
      imageFormatInfo.type   = VK_IMAGE_TYPE_2D;
      imageFormatInfo.tiling = VK_IMAGE_TILING_OPTIMAL;
      imageFormatInfo.usage  = VK_IMAGE_USAGE_TRANSFER_SRC_BIT | VK_IMAGE_USAGE_TRANSFER_DST_BIT |
                              VK_IMAGE_USAGE_SAMPLED_BIT | VK_IMAGE_USAGE_COLOR_ATTACHMENT_BIT |
                              VK_IMAGE_USAGE_INPUT_ATTACHMENT_BIT;
  
      VkImageCompressionPropertiesEXT compressionProperties = {};
      compressionProperties.sType = VK_STRUCTURE_TYPE_IMAGE_COMPRESSION_PROPERTIES_EXT;
  
      VkImageFormatProperties2 imageFormatProperties2 = {};
      imageFormatProperties2.sType                    = VK_STRUCTURE_TYPE_IMAGE_FORMAT_PROPERTIES_2;
      imageFormatProperties2.pNext                    = &compressionProperties;
  
      VkResult result = vkGetPhysicalDeviceImageFormatProperties2(
          mRenderer->getPhysicalDevice(), &imageFormatInfo, &imageFormatProperties2);
  
      if (result == VK_ERROR_FORMAT_NOT_SUPPORTED)
      {
          *num_rates = 0;
          return egl::NoError();
      }
      else if (result == VK_ERROR_OUT_OF_HOST_MEMORY || result == VK_ERROR_OUT_OF_DEVICE_MEMORY)
      {
          return egl::EglBadAlloc();
      }
      else if (result != VK_SUCCESS)
      {
          return egl::EglBadAccess();
      }
  
      std::vector<EGLint> eglFixedRates = vk_gl::ConvertCompressionFlagsToEGLFixedRate(
          compressionProperties.imageCompressionFixedRateFlags, static_cast<size_t>(rate_size));
      std::copy(eglFixedRates.begin(), eglFixedRates.end(), rates);
      *num_rates = static_cast<EGLint>(eglFixedRates.size());
  
      return egl::NoError();
  }
  
  }  // namespace rx
  

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