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

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• Hash : 0ab41fa5
  Author :
  Date : 2018-03-14T11:03:30
  

  Add an EGL extension to disable GL extensions by default.
  
  BUG=angleproject:2404
  
  Change-Id: I2667ddc92d5c9ef6e0ef115f2fdf0c3d3643d945
  Reviewed-on: https://chromium-review.googlesource.com/962702
  Reviewed-by: Frank Henigman <fjhenigman@chromium.org>
  Commit-Queue: Geoff Lang <geofflang@chromium.org>
  

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• src/libANGLE/Display.cpp

• //
  // Copyright (c) 2002-2014 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.
  //
  
  // Display.cpp: Implements the egl::Display class, representing the abstract
  // display on which graphics are drawn. Implements EGLDisplay.
  // [EGL 1.4] section 2.1.2 page 3.
  
  #include "libANGLE/Display.h"
  
  #include <algorithm>
  #include <iterator>
  #include <map>
  #include <sstream>
  #include <vector>
  
  #include <platform/Platform.h>
  #include <EGL/eglext.h>
  
  #include "common/debug.h"
  #include "common/mathutil.h"
  #include "common/platform.h"
  #include "common/utilities.h"
  #include "libANGLE/Context.h"
  #include "libANGLE/Device.h"
  #include "libANGLE/Image.h"
  #include "libANGLE/ResourceManager.h"
  #include "libANGLE/Stream.h"
  #include "libANGLE/Surface.h"
  #include "libANGLE/histogram_macros.h"
  #include "libANGLE/renderer/DeviceImpl.h"
  #include "libANGLE/renderer/DisplayImpl.h"
  #include "libANGLE/renderer/ImageImpl.h"
  #include "third_party/trace_event/trace_event.h"
  
  #if defined(ANGLE_ENABLE_D3D9) || defined(ANGLE_ENABLE_D3D11)
  #   include "libANGLE/renderer/d3d/DisplayD3D.h"
  #endif
  
  #if defined(ANGLE_ENABLE_OPENGL)
  #   if defined(ANGLE_PLATFORM_WINDOWS)
  #       include "libANGLE/renderer/gl/wgl/DisplayWGL.h"
  #   elif defined(ANGLE_USE_X11)
  #       include "libANGLE/renderer/gl/glx/DisplayGLX.h"
  #   elif defined(ANGLE_PLATFORM_APPLE)
  #       include "libANGLE/renderer/gl/cgl/DisplayCGL.h"
  #   elif defined(ANGLE_USE_OZONE)
  #       include "libANGLE/renderer/gl/egl/ozone/DisplayOzone.h"
  #   elif defined(ANGLE_PLATFORM_ANDROID)
  #       include "libANGLE/renderer/gl/egl/android/DisplayAndroid.h"
  #   else
  #       error Unsupported OpenGL platform.
  #   endif
  #endif
  
  #if defined(ANGLE_ENABLE_NULL)
  #include "libANGLE/renderer/null/DisplayNULL.h"
  #endif  // defined(ANGLE_ENABLE_NULL)
  
  #if defined(ANGLE_ENABLE_VULKAN)
  #if defined(ANGLE_PLATFORM_WINDOWS)
  #include "libANGLE/renderer/vulkan/win32/DisplayVkWin32.h"
  #elif defined(ANGLE_PLATFORM_LINUX)
  #include "libANGLE/renderer/vulkan/xcb/DisplayVkXcb.h"
  #elif defined(ANGLE_PLATFORM_ANDROID)
  #include "libANGLE/renderer/vulkan/android/DisplayVkAndroid.h"
  #else
  #error Unsupported Vulkan platform.
  #endif
  #endif  // defined(ANGLE_ENABLE_VULKAN)
  
  namespace egl
  {
  
  namespace
  {
  
  typedef std::map<EGLNativeWindowType, Surface*> WindowSurfaceMap;
  // Get a map of all EGL window surfaces to validate that no window has more than one EGL surface
  // associated with it.
  static WindowSurfaceMap *GetWindowSurfaces()
  {
      static WindowSurfaceMap windowSurfaces;
      return &windowSurfaces;
  }
  
  typedef std::map<EGLNativeDisplayType, Display *> ANGLEPlatformDisplayMap;
  static ANGLEPlatformDisplayMap *GetANGLEPlatformDisplayMap()
  {
      static ANGLEPlatformDisplayMap displays;
      return &displays;
  }
  
  typedef std::map<Device *, Display *> DevicePlatformDisplayMap;
  static DevicePlatformDisplayMap *GetDevicePlatformDisplayMap()
  {
      static DevicePlatformDisplayMap displays;
      return &displays;
  }
  
  rx::DisplayImpl *CreateDisplayFromDevice(Device *eglDevice, const DisplayState &state)
  {
      rx::DisplayImpl *impl = nullptr;
  
      switch (eglDevice->getType())
      {
  #if defined(ANGLE_ENABLE_D3D11)
          case EGL_D3D11_DEVICE_ANGLE:
              impl = new rx::DisplayD3D(state);
              break;
  #endif
  #if defined(ANGLE_ENABLE_D3D9)
          case EGL_D3D9_DEVICE_ANGLE:
              // Currently the only way to get EGLDeviceEXT representing a D3D9 device
              // is to retrieve one from an already-existing EGLDisplay.
              // When eglGetPlatformDisplayEXT is called with a D3D9 EGLDeviceEXT,
              // the already-existing display should be returned.
              // Therefore this codepath to create a new display from the device
              // should never be hit.
              UNREACHABLE();
              break;
  #endif
          default:
              UNREACHABLE();
              break;
      }
  
      ASSERT(impl != nullptr);
      return impl;
  }
  
  rx::DisplayImpl *CreateDisplayFromAttribs(const AttributeMap &attribMap, const DisplayState &state)
  {
      rx::DisplayImpl *impl = nullptr;
      EGLAttrib displayType =
          attribMap.get(EGL_PLATFORM_ANGLE_TYPE_ANGLE, EGL_PLATFORM_ANGLE_TYPE_DEFAULT_ANGLE);
      switch (displayType)
      {
          case EGL_PLATFORM_ANGLE_TYPE_DEFAULT_ANGLE:
  #if defined(ANGLE_ENABLE_D3D9) || defined(ANGLE_ENABLE_D3D11)
              // Default to D3D displays
              impl = new rx::DisplayD3D(state);
  #elif defined(ANGLE_USE_X11)
              impl = new rx::DisplayGLX(state);
  #elif defined(ANGLE_PLATFORM_APPLE)
              impl = new rx::DisplayCGL(state);
  #elif defined(ANGLE_USE_OZONE)
              impl = new rx::DisplayOzone(state);
  #elif defined(ANGLE_PLATFORM_ANDROID)
              impl = new rx::DisplayAndroid(state);
  #else
              // No display available
              UNREACHABLE();
  #endif
              break;
  
          case EGL_PLATFORM_ANGLE_TYPE_D3D9_ANGLE:
          case EGL_PLATFORM_ANGLE_TYPE_D3D11_ANGLE:
  #if defined(ANGLE_ENABLE_D3D9) || defined(ANGLE_ENABLE_D3D11)
              impl = new rx::DisplayD3D(state);
  #else
              // A D3D display was requested on a platform that doesn't support it
              UNREACHABLE();
  #endif
              break;
  
          case EGL_PLATFORM_ANGLE_TYPE_OPENGL_ANGLE:
  #if defined(ANGLE_ENABLE_OPENGL)
  #if defined(ANGLE_PLATFORM_WINDOWS)
              impl = new rx::DisplayWGL(state);
  #elif defined(ANGLE_USE_X11)
              impl = new rx::DisplayGLX(state);
  #elif defined(ANGLE_PLATFORM_APPLE)
              impl = new rx::DisplayCGL(state);
  #elif defined(ANGLE_USE_OZONE)
              // This might work but has never been tried, so disallow for now.
              impl = nullptr;
  #elif defined(ANGLE_PLATFORM_ANDROID)
              // No GL support on this platform, fail display creation.
              impl = nullptr;
  #else
  #error Unsupported OpenGL platform.
  #endif
  #else
              // No display available
              UNREACHABLE();
  #endif  // defined(ANGLE_ENABLE_OPENGL)
              break;
  
          case EGL_PLATFORM_ANGLE_TYPE_OPENGLES_ANGLE:
  #if defined(ANGLE_ENABLE_OPENGL)
  #if defined(ANGLE_PLATFORM_WINDOWS)
              impl = new rx::DisplayWGL(state);
  #elif defined(ANGLE_USE_X11)
              impl = new rx::DisplayGLX(state);
  #elif defined(ANGLE_USE_OZONE)
              impl = new rx::DisplayOzone(state);
  #elif defined(ANGLE_PLATFORM_ANDROID)
              impl = new rx::DisplayAndroid(state);
  #else
              // No GLES support on this platform, fail display creation.
              impl = nullptr;
  #endif
  #endif  // defined(ANGLE_ENABLE_OPENGL)
              break;
  
          case EGL_PLATFORM_ANGLE_TYPE_VULKAN_ANGLE:
  #if defined(ANGLE_ENABLE_VULKAN)
  #if defined(ANGLE_PLATFORM_WINDOWS)
              impl = new rx::DisplayVkWin32(state);
  #elif defined(ANGLE_PLATFORM_LINUX)
              impl = new rx::DisplayVkXcb(state);
  #elif defined(ANGLE_PLATFORM_ANDROID)
              impl = new rx::DisplayVkAndroid(state);
  #else
  #error Unsupported Vulkan platform.
  #endif
  #else
              // No display available
              UNREACHABLE();
  #endif  // defined(ANGLE_ENABLE_VULKAN)
              break;
  
          case EGL_PLATFORM_ANGLE_TYPE_NULL_ANGLE:
  #if defined(ANGLE_ENABLE_NULL)
              impl = new rx::DisplayNULL(state);
  #else
              // No display available
              UNREACHABLE();
  #endif  // defined(ANGLE_ENABLE_NULL)
              break;
  
          default:
              UNREACHABLE();
              break;
      }
  
      return impl;
  }
  
  void Display_logError(angle::PlatformMethods *platform, const char *errorMessage)
  {
      gl::Trace(gl::LOG_ERR, errorMessage);
  }
  
  void Display_logWarning(angle::PlatformMethods *platform, const char *warningMessage)
  {
      gl::Trace(gl::LOG_WARN, warningMessage);
  }
  
  void Display_logInfo(angle::PlatformMethods *platform, const char *infoMessage)
  {
      // Uncomment to get info spam
      // gl::Trace(gl::LOG_WARN, infoMessage);
  }
  
  void ANGLESetDefaultDisplayPlatform(angle::EGLDisplayType display)
  {
      angle::PlatformMethods *platformMethods = ANGLEPlatformCurrent();
      if (platformMethods->logError != angle::DefaultLogError)
      {
          // Don't reset pre-set Platform to Default
          return;
      }
  
      ANGLEResetDisplayPlatform(display);
      platformMethods->logError   = Display_logError;
      platformMethods->logWarning = Display_logWarning;
      platformMethods->logInfo    = Display_logInfo;
  }
  
  }  // anonymous namespace
  
  DisplayState::DisplayState()
  {
  }
  
  DisplayState::~DisplayState()
  {
  }
  
  // static
  Display *Display::GetDisplayFromNativeDisplay(EGLNativeDisplayType nativeDisplay,
                                                const AttributeMap &attribMap)
  {
      Display *display = nullptr;
  
      ANGLEPlatformDisplayMap *displays = GetANGLEPlatformDisplayMap();
      const auto &iter                  = displays->find(nativeDisplay);
      if (iter != displays->end())
      {
          display = iter->second;
      }
  
      if (display == nullptr)
      {
          // Validate the native display
          if (!Display::isValidNativeDisplay(nativeDisplay))
          {
              return nullptr;
          }
  
          display = new Display(EGL_PLATFORM_ANGLE_ANGLE, nativeDisplay, nullptr);
          displays->insert(std::make_pair(nativeDisplay, display));
      }
  
      // Apply new attributes if the display is not initialized yet.
      if (!display->isInitialized())
      {
          rx::DisplayImpl *impl = CreateDisplayFromAttribs(attribMap, display->getState());
          if (impl == nullptr)
          {
              // No valid display implementation for these attributes
              return nullptr;
          }
  
          display->setAttributes(impl, attribMap);
      }
  
      return display;
  }
  
  // static
  Display *Display::GetDisplayFromDevice(Device *device, const AttributeMap &attribMap)
  {
      Display *display = nullptr;
  
      ASSERT(Device::IsValidDevice(device));
  
      ANGLEPlatformDisplayMap *anglePlatformDisplays   = GetANGLEPlatformDisplayMap();
      DevicePlatformDisplayMap *devicePlatformDisplays = GetDevicePlatformDisplayMap();
  
      // First see if this eglDevice is in use by a Display created using ANGLE platform
      for (auto &displayMapEntry : *anglePlatformDisplays)
      {
          egl::Display *iterDisplay = displayMapEntry.second;
          if (iterDisplay->getDevice() == device)
          {
              display = iterDisplay;
          }
      }
  
      if (display == nullptr)
      {
          // See if the eglDevice is in use by a Display created using the DEVICE platform
          const auto &iter = devicePlatformDisplays->find(device);
          if (iter != devicePlatformDisplays->end())
          {
              display = iter->second;
          }
      }
  
      if (display == nullptr)
      {
          // Otherwise create a new Display
          display = new Display(EGL_PLATFORM_DEVICE_EXT, 0, device);
          devicePlatformDisplays->insert(std::make_pair(device, display));
      }
  
      // Apply new attributes if the display is not initialized yet.
      if (!display->isInitialized())
      {
          rx::DisplayImpl *impl = CreateDisplayFromDevice(device, display->getState());
          display->setAttributes(impl, attribMap);
      }
  
      return display;
  }
  
  Display::Display(EGLenum platform, EGLNativeDisplayType displayId, Device *eglDevice)
      : mImplementation(nullptr),
        mDisplayId(displayId),
        mAttributeMap(),
        mConfigSet(),
        mContextSet(),
        mStreamSet(),
        mInitialized(false),
        mDeviceLost(false),
        mCaps(),
        mDisplayExtensions(),
        mDisplayExtensionString(),
        mVendorString(),
        mDevice(eglDevice),
        mPlatform(platform),
        mTextureManager(nullptr),
        mMemoryProgramCache(gl::kDefaultMaxProgramCacheMemoryBytes),
        mGlobalTextureShareGroupUsers(0),
        mProxyContext(this)
  {
  }
  
  Display::~Display()
  {
      // TODO(jmadill): When is this called?
      // terminate();
  
      if (mPlatform == EGL_PLATFORM_ANGLE_ANGLE)
      {
          ANGLEPlatformDisplayMap *displays      = GetANGLEPlatformDisplayMap();
          ANGLEPlatformDisplayMap::iterator iter = displays->find(mDisplayId);
          if (iter != displays->end())
          {
              displays->erase(iter);
          }
      }
      else if (mPlatform == EGL_PLATFORM_DEVICE_EXT)
      {
          DevicePlatformDisplayMap *displays      = GetDevicePlatformDisplayMap();
          DevicePlatformDisplayMap::iterator iter = displays->find(mDevice);
          if (iter != displays->end())
          {
              displays->erase(iter);
          }
      }
      else
      {
          UNREACHABLE();
      }
  
      mProxyContext.reset(nullptr);
  
      SafeDelete(mDevice);
      SafeDelete(mImplementation);
  }
  
  void Display::setAttributes(rx::DisplayImpl *impl, const AttributeMap &attribMap)
  {
      ASSERT(!mInitialized);
  
      ASSERT(impl != nullptr);
      SafeDelete(mImplementation);
      mImplementation = impl;
  
      mAttributeMap = attribMap;
  }
  
  Error Display::initialize()
  {
      // TODO(jmadill): Store Platform in Display and init here.
      const angle::PlatformMethods *platformMethods =
          reinterpret_cast<const angle::PlatformMethods *>(
              mAttributeMap.get(EGL_PLATFORM_ANGLE_PLATFORM_METHODS_ANGLEX, 0));
      if (platformMethods != nullptr)
      {
          *ANGLEPlatformCurrent() = *platformMethods;
      }
      else
      {
          ANGLESetDefaultDisplayPlatform(this);
      }
  
      gl::InitializeDebugAnnotations(&mAnnotator);
  
      SCOPED_ANGLE_HISTOGRAM_TIMER("GPU.ANGLE.DisplayInitializeMS");
      TRACE_EVENT0("gpu.angle", "egl::Display::initialize");
  
      ASSERT(mImplementation != nullptr);
  
      if (isInitialized())
      {
          return NoError();
      }
  
      Error error = mImplementation->initialize(this);
      if (error.isError())
      {
          // Log extended error message here
          ERR() << "ANGLE Display::initialize error " << error.getID() << ": " << error.getMessage();
          return error;
      }
  
      mCaps = mImplementation->getCaps();
  
      mConfigSet = mImplementation->generateConfigs();
      if (mConfigSet.size() == 0)
      {
          mImplementation->terminate();
          return EglNotInitialized();
      }
  
      // OpenGL ES1 is implemented in the frontend, explicitly add ES1 support to all configs
      for (auto &config : mConfigSet)
      {
          // TODO(geofflang): Enable the conformant bit once we pass enough tests
          // config.second.conformant |= EGL_OPENGL_ES_BIT;
  
          config.second.renderableType |= EGL_OPENGL_ES_BIT;
      }
  
      initDisplayExtensions();
      initVendorString();
  
      // Populate the Display's EGLDeviceEXT if the Display wasn't created using one
      if (mPlatform != EGL_PLATFORM_DEVICE_EXT)
      {
          if (mDisplayExtensions.deviceQuery)
          {
              std::unique_ptr<rx::DeviceImpl> impl(mImplementation->createDevice());
              ASSERT(impl != nullptr);
              ANGLE_TRY(impl->initialize());
              mDevice = new Device(this, impl.release());
          }
          else
          {
              mDevice = nullptr;
          }
      }
      else
      {
          // For EGL_PLATFORM_DEVICE_EXT, mDevice should always be populated using
          // an external device
          ASSERT(mDevice != nullptr);
      }
  
      mProxyContext.reset(nullptr);
      gl::Context *proxyContext = new gl::Context(mImplementation, nullptr, nullptr, nullptr, nullptr,
                                                  egl::AttributeMap(), mDisplayExtensions);
      mProxyContext.reset(proxyContext);
  
      mInitialized = true;
  
      return NoError();
  }
  
  Error Display::terminate()
  {
      ANGLE_TRY(makeCurrent(nullptr, nullptr, nullptr));
  
      mMemoryProgramCache.clear();
  
      mProxyContext.reset(nullptr);
  
      while (!mContextSet.empty())
      {
          ANGLE_TRY(destroyContext(*mContextSet.begin()));
      }
  
      // The global texture manager should be deleted with the last context that uses it.
      ASSERT(mGlobalTextureShareGroupUsers == 0 && mTextureManager == nullptr);
  
      while (!mImageSet.empty())
      {
          destroyImage(*mImageSet.begin());
      }
  
      while (!mStreamSet.empty())
      {
          destroyStream(*mStreamSet.begin());
      }
  
      while (!mState.surfaceSet.empty())
      {
          ANGLE_TRY(destroySurface(*mState.surfaceSet.begin()));
      }
  
      mConfigSet.clear();
  
      if (mDevice != nullptr && mDevice->getOwningDisplay() != nullptr)
      {
          // Don't delete the device if it was created externally using eglCreateDeviceANGLE
          // We also shouldn't set it to null in case eglInitialize() is called again later
          SafeDelete(mDevice);
      }
  
      mImplementation->terminate();
  
      mDeviceLost = false;
  
      mInitialized = false;
  
      gl::UninitializeDebugAnnotations();
  
      // TODO(jmadill): Store Platform in Display and deinit here.
      ANGLEResetDisplayPlatform(this);
  
      return NoError();
  }
  
  std::vector<const Config*> Display::getConfigs(const egl::AttributeMap &attribs) const
  {
      return mConfigSet.filter(attribs);
  }
  
  Error Display::createWindowSurface(const Config *configuration,
                                     EGLNativeWindowType window,
                                     const AttributeMap &attribs,
                                     Surface **outSurface)
  {
      if (mImplementation->testDeviceLost())
      {
          ANGLE_TRY(restoreLostDevice());
      }
  
      SurfacePointer surface(new WindowSurface(mImplementation, configuration, window, attribs),
                             this);
      ANGLE_TRY(surface->initialize(this));
  
      ASSERT(outSurface != nullptr);
      *outSurface = surface.release();
      mState.surfaceSet.insert(*outSurface);
  
      WindowSurfaceMap *windowSurfaces = GetWindowSurfaces();
      ASSERT(windowSurfaces && windowSurfaces->find(window) == windowSurfaces->end());
      windowSurfaces->insert(std::make_pair(window, *outSurface));
  
      return NoError();
  }
  
  Error Display::createPbufferSurface(const Config *configuration,
                                      const AttributeMap &attribs,
                                      Surface **outSurface)
  {
      ASSERT(isInitialized());
  
      if (mImplementation->testDeviceLost())
      {
          ANGLE_TRY(restoreLostDevice());
      }
  
      SurfacePointer surface(new PbufferSurface(mImplementation, configuration, attribs), this);
      ANGLE_TRY(surface->initialize(this));
  
      ASSERT(outSurface != nullptr);
      *outSurface = surface.release();
      mState.surfaceSet.insert(*outSurface);
  
      return NoError();
  }
  
  Error Display::createPbufferFromClientBuffer(const Config *configuration,
                                               EGLenum buftype,
                                               EGLClientBuffer clientBuffer,
                                               const AttributeMap &attribs,
                                               Surface **outSurface)
  {
      ASSERT(isInitialized());
  
      if (mImplementation->testDeviceLost())
      {
          ANGLE_TRY(restoreLostDevice());
      }
  
      SurfacePointer surface(
          new PbufferSurface(mImplementation, configuration, buftype, clientBuffer, attribs), this);
      ANGLE_TRY(surface->initialize(this));
  
      ASSERT(outSurface != nullptr);
      *outSurface = surface.release();
      mState.surfaceSet.insert(*outSurface);
  
      return NoError();
  }
  
  Error Display::createPixmapSurface(const Config *configuration,
                                     NativePixmapType nativePixmap,
                                     const AttributeMap &attribs,
                                     Surface **outSurface)
  {
      ASSERT(isInitialized());
  
      if (mImplementation->testDeviceLost())
      {
          ANGLE_TRY(restoreLostDevice());
      }
  
      SurfacePointer surface(new PixmapSurface(mImplementation, configuration, nativePixmap, attribs),
                             this);
      ANGLE_TRY(surface->initialize(this));
  
      ASSERT(outSurface != nullptr);
      *outSurface = surface.release();
      mState.surfaceSet.insert(*outSurface);
  
      return NoError();
  }
  
  Error Display::createImage(const gl::Context *context,
                             EGLenum target,
                             EGLClientBuffer buffer,
                             const AttributeMap &attribs,
                             Image **outImage)
  {
      ASSERT(isInitialized());
  
      if (mImplementation->testDeviceLost())
      {
          ANGLE_TRY(restoreLostDevice());
      }
  
      egl::ImageSibling *sibling = nullptr;
      if (IsTextureTarget(target))
      {
          sibling = context->getTexture(egl_gl::EGLClientBufferToGLObjectHandle(buffer));
      }
      else if (IsRenderbufferTarget(target))
      {
          sibling = context->getRenderbuffer(egl_gl::EGLClientBufferToGLObjectHandle(buffer));
      }
      else
      {
          UNREACHABLE();
      }
      ASSERT(sibling != nullptr);
  
      angle::UniqueObjectPointer<Image, gl::Context> imagePtr(
          new Image(mImplementation, target, sibling, attribs), context);
      ANGLE_TRY(imagePtr->initialize());
  
      Image *image = imagePtr.release();
  
      ASSERT(outImage != nullptr);
      *outImage = image;
  
      // Add this image to the list of all images and hold a ref to it.
      image->addRef();
      mImageSet.insert(image);
  
      return NoError();
  }
  
  Error Display::createStream(const AttributeMap &attribs, Stream **outStream)
  {
      ASSERT(isInitialized());
  
      Stream *stream = new Stream(this, attribs);
  
      ASSERT(stream != nullptr);
      mStreamSet.insert(stream);
  
      ASSERT(outStream != nullptr);
      *outStream = stream;
  
      return NoError();
  }
  
  Error Display::createContext(const Config *configuration,
                               gl::Context *shareContext,
                               const AttributeMap &attribs,
                               gl::Context **outContext)
  {
      ASSERT(isInitialized());
  
      if (mImplementation->testDeviceLost())
      {
          ANGLE_TRY(restoreLostDevice());
      }
  
      // This display texture sharing will allow the first context to create the texture share group.
      bool usingDisplayTextureShareGroup =
          attribs.get(EGL_DISPLAY_TEXTURE_SHARE_GROUP_ANGLE, EGL_FALSE) == EGL_TRUE;
      gl::TextureManager *shareTextures = nullptr;
  
      if (usingDisplayTextureShareGroup)
      {
          ASSERT((mTextureManager == nullptr) == (mGlobalTextureShareGroupUsers == 0));
          if (mTextureManager == nullptr)
          {
              mTextureManager = new gl::TextureManager();
          }
  
          mGlobalTextureShareGroupUsers++;
          shareTextures = mTextureManager;
      }
  
      gl::MemoryProgramCache *cachePointer = &mMemoryProgramCache;
  
      // Check context creation attributes to see if we should enable the cache.
      if (mAttributeMap.get(EGL_CONTEXT_PROGRAM_BINARY_CACHE_ENABLED_ANGLE, EGL_TRUE) == EGL_FALSE)
      {
          cachePointer = nullptr;
      }
  
      // A program cache size of zero indicates it should be disabled.
      if (mMemoryProgramCache.maxSize() == 0)
      {
          cachePointer = nullptr;
      }
  
      gl::Context *context =
          new gl::Context(mImplementation, configuration, shareContext, shareTextures, cachePointer,
                          attribs, mDisplayExtensions);
  
      ASSERT(context != nullptr);
      mContextSet.insert(context);
  
      ASSERT(outContext != nullptr);
      *outContext = context;
      return NoError();
  }
  
  Error Display::makeCurrent(egl::Surface *drawSurface,
                             egl::Surface *readSurface,
                             gl::Context *context)
  {
      ANGLE_TRY(mImplementation->makeCurrent(drawSurface, readSurface, context));
  
      if (context != nullptr)
      {
          ASSERT(readSurface == drawSurface);
          ANGLE_TRY(context->makeCurrent(this, drawSurface));
      }
  
      return NoError();
  }
  
  Error Display::restoreLostDevice()
  {
      for (ContextSet::iterator ctx = mContextSet.begin(); ctx != mContextSet.end(); ctx++)
      {
          if ((*ctx)->isResetNotificationEnabled())
          {
              // If reset notifications have been requested, application must delete all contexts first
              return EglContextLost();
          }
      }
  
      return mImplementation->restoreLostDevice(this);
  }
  
  Error Display::destroySurface(Surface *surface)
  {
      if (surface->getType() == EGL_WINDOW_BIT)
      {
          WindowSurfaceMap *windowSurfaces = GetWindowSurfaces();
          ASSERT(windowSurfaces);
  
          bool surfaceRemoved = false;
          for (WindowSurfaceMap::iterator iter = windowSurfaces->begin(); iter != windowSurfaces->end(); iter++)
          {
              if (iter->second == surface)
              {
                  windowSurfaces->erase(iter);
                  surfaceRemoved = true;
                  break;
              }
          }
  
          ASSERT(surfaceRemoved);
      }
  
      mState.surfaceSet.erase(surface);
      ANGLE_TRY(surface->onDestroy(this));
      return NoError();
  }
  
  void Display::destroyImage(egl::Image *image)
  {
      auto iter = mImageSet.find(image);
      ASSERT(iter != mImageSet.end());
      (*iter)->release(mProxyContext.get());
      mImageSet.erase(iter);
  }
  
  void Display::destroyStream(egl::Stream *stream)
  {
      mStreamSet.erase(stream);
      SafeDelete(stream);
  }
  
  Error Display::destroyContext(gl::Context *context)
  {
      if (context->usingDisplayTextureShareGroup())
      {
          ASSERT(mGlobalTextureShareGroupUsers >= 1 && mTextureManager != nullptr);
          if (mGlobalTextureShareGroupUsers == 1)
          {
              // If this is the last context using the global share group, destroy the global texture
              // manager so that the textures can be destroyed while a context still exists
              mTextureManager->release(context);
              mTextureManager = nullptr;
          }
          mGlobalTextureShareGroupUsers--;
      }
  
      ANGLE_TRY(context->onDestroy(this));
      mContextSet.erase(context);
      SafeDelete(context);
      return NoError();
  }
  
  bool Display::isDeviceLost() const
  {
      ASSERT(isInitialized());
      return mDeviceLost;
  }
  
  bool Display::testDeviceLost()
  {
      ASSERT(isInitialized());
  
      if (!mDeviceLost && mImplementation->testDeviceLost())
      {
          notifyDeviceLost();
      }
  
      return mDeviceLost;
  }
  
  void Display::notifyDeviceLost()
  {
      if (mDeviceLost)
      {
          return;
      }
  
      for (ContextSet::iterator context = mContextSet.begin(); context != mContextSet.end(); context++)
      {
          (*context)->markContextLost();
      }
  
      mDeviceLost = true;
  }
  
  Error Display::waitClient(const gl::Context *context) const
  {
      return mImplementation->waitClient(context);
  }
  
  Error Display::waitNative(const gl::Context *context, EGLint engine) const
  {
      return mImplementation->waitNative(context, engine);
  }
  
  const Caps &Display::getCaps() const
  {
      return mCaps;
  }
  
  bool Display::isInitialized() const
  {
      return mInitialized;
  }
  
  bool Display::isValidConfig(const Config *config) const
  {
      return mConfigSet.contains(config);
  }
  
  bool Display::isValidContext(const gl::Context *context) const
  {
      return mContextSet.find(const_cast<gl::Context *>(context)) != mContextSet.end();
  }
  
  bool Display::isValidSurface(const Surface *surface) const
  {
      return mState.surfaceSet.find(const_cast<Surface *>(surface)) != mState.surfaceSet.end();
  }
  
  bool Display::isValidImage(const Image *image) const
  {
      return mImageSet.find(const_cast<Image *>(image)) != mImageSet.end();
  }
  
  bool Display::isValidStream(const Stream *stream) const
  {
      return mStreamSet.find(const_cast<Stream *>(stream)) != mStreamSet.end();
  }
  
  bool Display::hasExistingWindowSurface(EGLNativeWindowType window)
  {
      WindowSurfaceMap *windowSurfaces = GetWindowSurfaces();
      ASSERT(windowSurfaces);
  
      return windowSurfaces->find(window) != windowSurfaces->end();
  }
  
  static ClientExtensions GenerateClientExtensions()
  {
      ClientExtensions extensions;
  
      extensions.clientExtensions = true;
      extensions.platformBase = true;
      extensions.platformANGLE = true;
  
  #if defined(ANGLE_ENABLE_D3D9) || defined(ANGLE_ENABLE_D3D11)
      extensions.platformANGLED3D = true;
      extensions.platformDevice   = true;
  #endif
  
  #if defined(ANGLE_ENABLE_OPENGL)
      extensions.platformANGLEOpenGL = true;
  #endif
  
  #if defined(ANGLE_ENABLE_NULL)
      extensions.platformANGLENULL = true;
  #endif
  
  #if defined(ANGLE_ENABLE_D3D11)
      extensions.deviceCreation      = true;
      extensions.deviceCreationD3D11 = true;
      extensions.experimentalPresentPath = true;
  #endif
  
  #if defined(ANGLE_ENABLE_VULKAN)
      extensions.platformANGLEVulkan = true;
  #endif
  
  #if defined(ANGLE_USE_X11)
      extensions.x11Visual = true;
  #endif
  
      extensions.clientGetAllProcAddresses = true;
  
      return extensions;
  }
  
  template <typename T>
  static std::string GenerateExtensionsString(const T &extensions)
  {
      std::vector<std::string> extensionsVector = extensions.getStrings();
  
      std::ostringstream stream;
      std::copy(extensionsVector.begin(), extensionsVector.end(), std::ostream_iterator<std::string>(stream, " "));
      return stream.str();
  }
  
  // static
  const ClientExtensions &Display::GetClientExtensions()
  {
      static const ClientExtensions clientExtensions = GenerateClientExtensions();
      return clientExtensions;
  }
  
  // static
  const std::string &Display::GetClientExtensionString()
  {
      static const std::string clientExtensionsString =
          GenerateExtensionsString(GetClientExtensions());
      return clientExtensionsString;
  }
  
  void Display::initDisplayExtensions()
  {
      mDisplayExtensions = mImplementation->getExtensions();
  
      // Some extensions are always available because they are implemented in the EGL layer.
      mDisplayExtensions.createContext        = true;
      mDisplayExtensions.createContextNoError = true;
      mDisplayExtensions.createContextWebGLCompatibility = true;
      mDisplayExtensions.createContextBindGeneratesResource = true;
      mDisplayExtensions.createContextClientArrays          = true;
      mDisplayExtensions.pixelFormatFloat                   = true;
  
      // Force EGL_KHR_get_all_proc_addresses on.
      mDisplayExtensions.getAllProcAddresses = true;
  
      // Enable program cache control since it is not back-end dependent.
      mDisplayExtensions.programCacheControl = true;
  
      // Request extension is implemented in the ANGLE frontend
      mDisplayExtensions.createContextExtensionsEnabled = true;
  
      mDisplayExtensionString = GenerateExtensionsString(mDisplayExtensions);
  }
  
  bool Display::isValidNativeWindow(EGLNativeWindowType window) const
  {
      return mImplementation->isValidNativeWindow(window);
  }
  
  Error Display::validateClientBuffer(const Config *configuration,
                                      EGLenum buftype,
                                      EGLClientBuffer clientBuffer,
                                      const AttributeMap &attribs)
  {
      return mImplementation->validateClientBuffer(configuration, buftype, clientBuffer, attribs);
  }
  
  bool Display::isValidDisplay(const egl::Display *display)
  {
      const ANGLEPlatformDisplayMap *anglePlatformDisplayMap = GetANGLEPlatformDisplayMap();
      for (const auto &displayPair : *anglePlatformDisplayMap)
      {
          if (displayPair.second == display)
          {
              return true;
          }
      }
  
      const DevicePlatformDisplayMap *devicePlatformDisplayMap = GetDevicePlatformDisplayMap();
      for (const auto &displayPair : *devicePlatformDisplayMap)
      {
          if (displayPair.second == display)
          {
              return true;
          }
      }
  
      return false;
  }
  
  bool Display::isValidNativeDisplay(EGLNativeDisplayType display)
  {
      // TODO(jmadill): handle this properly
      if (display == EGL_DEFAULT_DISPLAY)
      {
          return true;
      }
  
  #if defined(ANGLE_PLATFORM_WINDOWS) && !defined(ANGLE_ENABLE_WINDOWS_STORE)
      if (display == EGL_SOFTWARE_DISPLAY_ANGLE ||
          display == EGL_D3D11_ELSE_D3D9_DISPLAY_ANGLE ||
          display == EGL_D3D11_ONLY_DISPLAY_ANGLE)
      {
          return true;
      }
      return (WindowFromDC(display) != nullptr);
  #else
      return true;
  #endif
  }
  
  void Display::initVendorString()
  {
      mVendorString = mImplementation->getVendorString();
  }
  
  const DisplayExtensions &Display::getExtensions() const
  {
      return mDisplayExtensions;
  }
  
  const std::string &Display::getExtensionString() const
  {
      return mDisplayExtensionString;
  }
  
  const std::string &Display::getVendorString() const
  {
      return mVendorString;
  }
  
  Device *Display::getDevice() const
  {
      return mDevice;
  }
  
  gl::Version Display::getMaxSupportedESVersion() const
  {
      return mImplementation->getMaxSupportedESVersion();
  }
  
  EGLint Display::programCacheGetAttrib(EGLenum attrib) const
  {
      switch (attrib)
      {
          case EGL_PROGRAM_CACHE_KEY_LENGTH_ANGLE:
              return static_cast<EGLint>(gl::kProgramHashLength);
  
          case EGL_PROGRAM_CACHE_SIZE_ANGLE:
              return static_cast<EGLint>(mMemoryProgramCache.entryCount());
  
          default:
              UNREACHABLE();
              return 0;
      }
  }
  
  Error Display::programCacheQuery(EGLint index,
                                   void *key,
                                   EGLint *keysize,
                                   void *binary,
                                   EGLint *binarysize)
  {
      ASSERT(index >= 0 && index < static_cast<EGLint>(mMemoryProgramCache.entryCount()));
  
      const angle::MemoryBuffer *programBinary = nullptr;
      gl::ProgramHash programHash;
      // TODO(jmadill): Make this thread-safe.
      bool result =
          mMemoryProgramCache.getAt(static_cast<size_t>(index), &programHash, &programBinary);
      if (!result)
      {
          return EglBadAccess() << "Program binary not accessible.";
      }
  
      ASSERT(keysize && binarysize);
  
      if (key)
      {
          ASSERT(*keysize == static_cast<EGLint>(gl::kProgramHashLength));
          memcpy(key, programHash.data(), gl::kProgramHashLength);
      }
  
      if (binary)
      {
          // Note: we check the size here instead of in the validation code, since we need to
          // access the cache as atomically as possible. It's possible that the cache contents
          // could change between the validation size check and the retrieval.
          if (programBinary->size() > static_cast<size_t>(*binarysize))
          {
              return EglBadAccess() << "Program binary too large or changed during access.";
          }
  
          memcpy(binary, programBinary->data(), programBinary->size());
      }
  
      *binarysize = static_cast<EGLint>(programBinary->size());
      *keysize    = static_cast<EGLint>(gl::kProgramHashLength);
  
      return NoError();
  }
  
  Error Display::programCachePopulate(const void *key,
                                      EGLint keysize,
                                      const void *binary,
                                      EGLint binarysize)
  {
      ASSERT(keysize == static_cast<EGLint>(gl::kProgramHashLength));
  
      gl::ProgramHash programHash;
      memcpy(programHash.data(), key, gl::kProgramHashLength);
  
      mMemoryProgramCache.putBinary(programHash, reinterpret_cast<const uint8_t *>(binary),
                                    static_cast<size_t>(binarysize));
      return NoError();
  }
  
  EGLint Display::programCacheResize(EGLint limit, EGLenum mode)
  {
      switch (mode)
      {
          case EGL_PROGRAM_CACHE_RESIZE_ANGLE:
          {
              size_t initialSize = mMemoryProgramCache.size();
              mMemoryProgramCache.resize(static_cast<size_t>(limit));
              return static_cast<EGLint>(initialSize);
          }
  
          case EGL_PROGRAM_CACHE_TRIM_ANGLE:
              return static_cast<EGLint>(mMemoryProgramCache.trim(static_cast<size_t>(limit)));
  
          default:
              UNREACHABLE();
              return 0;
      }
  }
  
  }  // namespace egl
  

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