Adding upstream version 115.7.0esr.upstream/115.7.0esrupstream

Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>

1 files changed, 1922 insertions, 0 deletions

diff --git a/gfx/webrender_bindings/DCLayerTree.cpp b/gfx/webrender_bindings/DCLayerTree.cpp
new file mode 100644
index 0000000000..0ededcb042
--- /dev/null
+++ b/gfx/webrender_bindings/DCLayerTree.cpp
@@ -0,0 +1,1922 @@
+/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
+/* vim: set ts=8 sts=2 et sw=2 tw=80: */
+/* This Source Code Form is subject to the terms of the Mozilla Public
+ * License, v. 2.0. If a copy of the MPL was not distributed with this
+ * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
+
+#include "DCLayerTree.h"
+
+// -
+
+#include "mozilla/gfx/AllOfDcomp.h"
+#include <d3d11.h>
+#include <d3d11_1.h>
+#include <dxgi1_2.h>
+
+// -
+
+#include "gfxWindowsPlatform.h"
+#include "GLContext.h"
+#include "GLContextEGL.h"
+#include "mozilla/gfx/DeviceManagerDx.h"
+#include "mozilla/gfx/Logging.h"
+#include "mozilla/gfx/gfxVars.h"
+#include "mozilla/gfx/GPUParent.h"
+#include "mozilla/gfx/Matrix.h"
+#include "mozilla/StaticPrefs_gfx.h"
+#include "mozilla/webrender/RenderD3D11TextureHost.h"
+#include "mozilla/webrender/RenderDcompSurfaceTextureHost.h"
+#include "mozilla/webrender/RenderTextureHost.h"
+#include "mozilla/webrender/RenderThread.h"
+#include "mozilla/WindowsVersion.h"
+#include "mozilla/Telemetry.h"
+#include "nsPrintfCString.h"
+#include "WinUtils.h"
+
+// -
+
+#if defined(__MINGW32__)  // 64 defines both 32 and 64
+// We need to fake some things, while we wait on updates to mingw's dcomp.h
+// header. Just enough that we can successfully fail to work there.
+#  define MOZ_MINGW_DCOMP_H_INCOMPLETE
+struct IDCompositionColorMatrixEffect : public IDCompositionFilterEffect {};
+struct IDCompositionTableTransferEffect : public IDCompositionFilterEffect {};
+#endif  // defined(__MINGW32__)
+
+namespace mozilla {
+namespace wr {
+
+extern LazyLogModule gRenderThreadLog;
+#define LOG(...) MOZ_LOG(gRenderThreadLog, LogLevel::Debug, (__VA_ARGS__))
+
+#define LOG_H(msg, ...)                   \
+  MOZ_LOG(gDcompSurface, LogLevel::Debug, \
+          ("DCSurfaceHandle=%p, " msg, this, ##__VA_ARGS__))
+
+UniquePtr<GpuOverlayInfo> DCLayerTree::sGpuOverlayInfo;
+
+/* static */
+UniquePtr<DCLayerTree> DCLayerTree::Create(gl::GLContext* aGL,
+                                           EGLConfig aEGLConfig,
+                                           ID3D11Device* aDevice,
+                                           ID3D11DeviceContext* aCtx,
+                                           HWND aHwnd, nsACString& aError) {
+  RefPtr<IDCompositionDevice2> dCompDevice =
+      gfx::DeviceManagerDx::Get()->GetDirectCompositionDevice();
+  if (!dCompDevice) {
+    aError.Assign("DCLayerTree(no device)"_ns);
+    return nullptr;
+  }
+
+  auto layerTree =
+      MakeUnique<DCLayerTree>(aGL, aEGLConfig, aDevice, aCtx, dCompDevice);
+  if (!layerTree->Initialize(aHwnd, aError)) {
+    return nullptr;
+  }
+
+  return layerTree;
+}
+
+void DCLayerTree::Shutdown() { DCLayerTree::sGpuOverlayInfo = nullptr; }
+
+DCLayerTree::DCLayerTree(gl::GLContext* aGL, EGLConfig aEGLConfig,
+                         ID3D11Device* aDevice, ID3D11DeviceContext* aCtx,
+                         IDCompositionDevice2* aCompositionDevice)
+    : mGL(aGL),
+      mEGLConfig(aEGLConfig),
+      mDevice(aDevice),
+      mCtx(aCtx),
+      mCompositionDevice(aCompositionDevice),
+      mDebugCounter(false),
+      mDebugVisualRedrawRegions(false),
+      mEGLImage(EGL_NO_IMAGE),
+      mColorRBO(0),
+      mPendingCommit(false) {
+  LOG("DCLayerTree::DCLayerTree()");
+}
+
+DCLayerTree::~DCLayerTree() {
+  LOG("DCLayerTree::~DCLayerTree()");
+
+  ReleaseNativeCompositorResources();
+}
+
+void DCLayerTree::ReleaseNativeCompositorResources() {
+  const auto gl = GetGLContext();
+
+  DestroyEGLSurface();
+
+  // Delete any cached FBO objects
+  for (auto it = mFrameBuffers.begin(); it != mFrameBuffers.end(); ++it) {
+    gl->fDeleteRenderbuffers(1, &it->depthRboId);
+    gl->fDeleteFramebuffers(1, &it->fboId);
+  }
+}
+
+bool DCLayerTree::Initialize(HWND aHwnd, nsACString& aError) {
+  HRESULT hr;
+
+  RefPtr<IDCompositionDesktopDevice> desktopDevice;
+  hr = mCompositionDevice->QueryInterface(
+      (IDCompositionDesktopDevice**)getter_AddRefs(desktopDevice));
+  if (FAILED(hr)) {
+    aError.Assign(nsPrintfCString(
+        "DCLayerTree(get IDCompositionDesktopDevice failed %lx)", hr));
+    return false;
+  }
+
+  hr = desktopDevice->CreateTargetForHwnd(aHwnd, TRUE,
+                                          getter_AddRefs(mCompositionTarget));
+  if (FAILED(hr)) {
+    aError.Assign(nsPrintfCString(
+        "DCLayerTree(create DCompositionTarget failed %lx)", hr));
+    return false;
+  }
+
+  hr = mCompositionDevice->CreateVisual(getter_AddRefs(mRootVisual));
+  if (FAILED(hr)) {
+    aError.Assign(nsPrintfCString(
+        "DCLayerTree(create root DCompositionVisual failed %lx)", hr));
+    return false;
+  }
+
+  hr =
+      mCompositionDevice->CreateVisual(getter_AddRefs(mDefaultSwapChainVisual));
+  if (FAILED(hr)) {
+    aError.Assign(nsPrintfCString(
+        "DCLayerTree(create swap chain DCompositionVisual failed %lx)", hr));
+    return false;
+  }
+
+  if (gfx::gfxVars::UseWebRenderDCompVideoOverlayWin()) {
+    if (!InitializeVideoOverlaySupport()) {
+      RenderThread::Get()->HandleWebRenderError(WebRenderError::VIDEO_OVERLAY);
+    }
+  }
+  if (!sGpuOverlayInfo) {
+    // Set default if sGpuOverlayInfo was not set.
+    sGpuOverlayInfo = MakeUnique<GpuOverlayInfo>();
+  }
+
+  // Initialize SwapChainInfo
+  SupportsSwapChainTearing();
+
+  mCompositionTarget->SetRoot(mRootVisual);
+  // Set interporation mode to nearest, to ensure 1:1 sampling.
+  // By default, a visual inherits the interpolation mode of the parent visual.
+  // If no visuals set the interpolation mode, the default for the entire visual
+  // tree is nearest neighbor interpolation.
+  mRootVisual->SetBitmapInterpolationMode(
+      DCOMPOSITION_BITMAP_INTERPOLATION_MODE_NEAREST_NEIGHBOR);
+  return true;
+}
+
+bool FlagsSupportsOverlays(UINT flags) {
+  return (flags & (DXGI_OVERLAY_SUPPORT_FLAG_DIRECT |
+                   DXGI_OVERLAY_SUPPORT_FLAG_SCALING));
+}
+
+// A warpper of IDXGIOutput4::CheckOverlayColorSpaceSupport()
+bool CheckOverlayColorSpaceSupport(DXGI_FORMAT aDxgiFormat,
+                                   DXGI_COLOR_SPACE_TYPE aDxgiColorSpace,
+                                   RefPtr<IDXGIOutput> aOutput,
+                                   RefPtr<ID3D11Device> aD3d11Device) {
+  UINT colorSpaceSupportFlags = 0;
+  RefPtr<IDXGIOutput4> output4;
+
+  if (FAILED(aOutput->QueryInterface(__uuidof(IDXGIOutput4),
+                                     getter_AddRefs(output4)))) {
+    return false;
+  }
+
+  if (FAILED(output4->CheckOverlayColorSpaceSupport(
+          aDxgiFormat, aDxgiColorSpace, aD3d11Device,
+          &colorSpaceSupportFlags))) {
+    return false;
+  }
+
+  return (colorSpaceSupportFlags &
+          DXGI_OVERLAY_COLOR_SPACE_SUPPORT_FLAG_PRESENT);
+}
+
+bool DCLayerTree::InitializeVideoOverlaySupport() {
+  MOZ_ASSERT(IsWin10AnniversaryUpdateOrLater());
+
+  HRESULT hr;
+
+  hr = mDevice->QueryInterface(
+      (ID3D11VideoDevice**)getter_AddRefs(mVideoDevice));
+  if (FAILED(hr)) {
+    gfxCriticalNote << "Failed to get D3D11VideoDevice: " << gfx::hexa(hr);
+    return false;
+  }
+
+  hr =
+      mCtx->QueryInterface((ID3D11VideoContext**)getter_AddRefs(mVideoContext));
+  if (FAILED(hr)) {
+    gfxCriticalNote << "Failed to get D3D11VideoContext: " << gfx::hexa(hr);
+    return false;
+  }
+
+  if (sGpuOverlayInfo) {
+    return true;
+  }
+
+  UniquePtr<GpuOverlayInfo> info = MakeUnique<GpuOverlayInfo>();
+
+  RefPtr<IDXGIDevice> dxgiDevice;
+  RefPtr<IDXGIAdapter> adapter;
+  mDevice->QueryInterface((IDXGIDevice**)getter_AddRefs(dxgiDevice));
+  dxgiDevice->GetAdapter(getter_AddRefs(adapter));
+
+  unsigned int i = 0;
+  while (true) {
+    RefPtr<IDXGIOutput> output;
+    if (FAILED(adapter->EnumOutputs(i++, getter_AddRefs(output)))) {
+      break;
+    }
+    RefPtr<IDXGIOutput3> output3;
+    if (FAILED(output->QueryInterface(__uuidof(IDXGIOutput3),
+                                      getter_AddRefs(output3)))) {
+      break;
+    }
+
+    output3->CheckOverlaySupport(DXGI_FORMAT_NV12, mDevice,
+                                 &info->mNv12OverlaySupportFlags);
+    output3->CheckOverlaySupport(DXGI_FORMAT_YUY2, mDevice,
+                                 &info->mYuy2OverlaySupportFlags);
+    output3->CheckOverlaySupport(DXGI_FORMAT_B8G8R8A8_UNORM, mDevice,
+                                 &info->mBgra8OverlaySupportFlags);
+    output3->CheckOverlaySupport(DXGI_FORMAT_R10G10B10A2_UNORM, mDevice,
+                                 &info->mRgb10a2OverlaySupportFlags);
+
+    if (FlagsSupportsOverlays(info->mNv12OverlaySupportFlags)) {
+      // NV12 format is preferred if it's supported.
+      info->mOverlayFormatUsed = DXGI_FORMAT_NV12;
+      info->mSupportsHardwareOverlays = true;
+    }
+
+    if (!info->mSupportsHardwareOverlays &&
+        FlagsSupportsOverlays(info->mYuy2OverlaySupportFlags)) {
+      // If NV12 isn't supported, fallback to YUY2 if it's supported.
+      info->mOverlayFormatUsed = DXGI_FORMAT_YUY2;
+      info->mSupportsHardwareOverlays = true;
+    }
+
+    // RGB10A2 overlay is used for displaying HDR content. In Intel's
+    // platform, RGB10A2 overlay is enabled only when
+    // DXGI_COLOR_SPACE_RGB_FULL_G2084_NONE_P2020 is supported.
+    if (FlagsSupportsOverlays(info->mRgb10a2OverlaySupportFlags)) {
+      if (!CheckOverlayColorSpaceSupport(
+              DXGI_FORMAT_R10G10B10A2_UNORM,
+              DXGI_COLOR_SPACE_RGB_FULL_G2084_NONE_P2020, output, mDevice))
+        info->mRgb10a2OverlaySupportFlags = 0;
+    }
+
+    // Early out after the first output that reports overlay support. All
+    // outputs are expected to report the same overlay support according to
+    // Microsoft's WDDM documentation:
+    // https://docs.microsoft.com/en-us/windows-hardware/drivers/display/multiplane-overlay-hardware-requirements
+    if (info->mSupportsHardwareOverlays) {
+      break;
+    }
+  }
+
+  if (!StaticPrefs::gfx_webrender_dcomp_video_yuv_overlay_win_AtStartup()) {
+    info->mOverlayFormatUsed = DXGI_FORMAT_B8G8R8A8_UNORM;
+    info->mSupportsHardwareOverlays = false;
+  }
+
+  info->mSupportsOverlays = info->mSupportsHardwareOverlays;
+
+  sGpuOverlayInfo = std::move(info);
+
+  if (auto* gpuParent = gfx::GPUParent::GetSingleton()) {
+    gpuParent->NotifyOverlayInfo(GetOverlayInfo());
+  }
+
+  return true;
+}
+
+DCSurface* DCLayerTree::GetSurface(wr::NativeSurfaceId aId) const {
+  auto surface_it = mDCSurfaces.find(aId);
+  MOZ_RELEASE_ASSERT(surface_it != mDCSurfaces.end());
+  return surface_it->second.get();
+}
+
+void DCLayerTree::SetDefaultSwapChain(IDXGISwapChain1* aSwapChain) {
+  LOG("DCLayerTree::SetDefaultSwapChain()");
+
+  mRootVisual->AddVisual(mDefaultSwapChainVisual, TRUE, nullptr);
+  mDefaultSwapChainVisual->SetContent(aSwapChain);
+  // Default SwapChain's visual does not need linear interporation.
+  mDefaultSwapChainVisual->SetBitmapInterpolationMode(
+      DCOMPOSITION_BITMAP_INTERPOLATION_MODE_NEAREST_NEIGHBOR);
+  mPendingCommit = true;
+}
+
+void DCLayerTree::MaybeUpdateDebug() {
+  bool updated = false;
+  updated |= MaybeUpdateDebugCounter();
+  updated |= MaybeUpdateDebugVisualRedrawRegions();
+  if (updated) {
+    mPendingCommit = true;
+  }
+}
+
+void DCLayerTree::MaybeCommit() {
+  if (!mPendingCommit) {
+    return;
+  }
+  mCompositionDevice->Commit();
+}
+
+void DCLayerTree::WaitForCommitCompletion() {
+  mCompositionDevice->WaitForCommitCompletion();
+}
+
+void DCLayerTree::DisableNativeCompositor() {
+  MOZ_ASSERT(mCurrentSurface.isNothing());
+  MOZ_ASSERT(mCurrentLayers.empty());
+
+  ReleaseNativeCompositorResources();
+  mPrevLayers.clear();
+  mRootVisual->RemoveAllVisuals();
+}
+
+bool DCLayerTree::MaybeUpdateDebugCounter() {
+  bool debugCounter = StaticPrefs::gfx_webrender_debug_dcomp_counter();
+  if (mDebugCounter == debugCounter) {
+    return false;
+  }
+
+  RefPtr<IDCompositionDeviceDebug> debugDevice;
+  HRESULT hr = mCompositionDevice->QueryInterface(
+      (IDCompositionDeviceDebug**)getter_AddRefs(debugDevice));
+  if (FAILED(hr)) {
+    return false;
+  }
+
+  if (debugCounter) {
+    debugDevice->EnableDebugCounters();
+  } else {
+    debugDevice->DisableDebugCounters();
+  }
+
+  mDebugCounter = debugCounter;
+  return true;
+}
+
+bool DCLayerTree::MaybeUpdateDebugVisualRedrawRegions() {
+  bool debugVisualRedrawRegions =
+      StaticPrefs::gfx_webrender_debug_dcomp_redraw_regions();
+  if (mDebugVisualRedrawRegions == debugVisualRedrawRegions) {
+    return false;
+  }
+
+  RefPtr<IDCompositionVisualDebug> visualDebug;
+  HRESULT hr = mRootVisual->QueryInterface(
+      (IDCompositionVisualDebug**)getter_AddRefs(visualDebug));
+  if (FAILED(hr)) {
+    return false;
+  }
+
+  if (debugVisualRedrawRegions) {
+    visualDebug->EnableRedrawRegions();
+  } else {
+    visualDebug->DisableRedrawRegions();
+  }
+
+  mDebugVisualRedrawRegions = debugVisualRedrawRegions;
+  return true;
+}
+
+void DCLayerTree::CompositorBeginFrame() { mCurrentFrame++; }
+
+void DCLayerTree::CompositorEndFrame() {
+  auto start = TimeStamp::Now();
+  // Check if the visual tree of surfaces is the same as last frame.
+  bool same = mPrevLayers == mCurrentLayers;
+
+  if (!same) {
+    // If not, we need to rebuild the visual tree. Note that addition or
+    // removal of tiles no longer needs to rebuild the main visual tree
+    // here, since they are added as children of the surface visual.
+    mRootVisual->RemoveAllVisuals();
+  }
+
+  for (auto it = mCurrentLayers.begin(); it != mCurrentLayers.end(); ++it) {
+    auto surface_it = mDCSurfaces.find(*it);
+    MOZ_RELEASE_ASSERT(surface_it != mDCSurfaces.end());
+    const auto surface = surface_it->second.get();
+    // Ensure surface is trimmed to updated tile valid rects
+    surface->UpdateAllocatedRect();
+    if (!same) {
+      // Add surfaces in z-order they were added to the scene.
+      const auto visual = surface->GetVisual();
+      mRootVisual->AddVisual(visual, false, nullptr);
+    }
+  }
+
+  mPrevLayers.swap(mCurrentLayers);
+  mCurrentLayers.clear();
+
+  mCompositionDevice->Commit();
+
+  auto end = TimeStamp::Now();
+  mozilla::Telemetry::Accumulate(mozilla::Telemetry::COMPOSITE_SWAP_TIME,
+                                 (end - start).ToMilliseconds() * 10.);
+
+  // Remove any framebuffers that haven't been
+  // used in the last 60 frames.
+  //
+  // This should use nsTArray::RemoveElementsBy once
+  // CachedFrameBuffer is able to properly destroy
+  // itself in the destructor.
+  const auto gl = GetGLContext();
+  for (uint32_t i = 0, len = mFrameBuffers.Length(); i < len; ++i) {
+    auto& fb = mFrameBuffers[i];
+    if ((mCurrentFrame - fb.lastFrameUsed) > 60) {
+      gl->fDeleteRenderbuffers(1, &fb.depthRboId);
+      gl->fDeleteFramebuffers(1, &fb.fboId);
+      mFrameBuffers.UnorderedRemoveElementAt(i);
+      --i;  // Examine the element again, if necessary.
+      --len;
+    }
+  }
+}
+
+void DCLayerTree::Bind(wr::NativeTileId aId, wr::DeviceIntPoint* aOffset,
+                       uint32_t* aFboId, wr::DeviceIntRect aDirtyRect,
+                       wr::DeviceIntRect aValidRect) {
+  auto surface = GetSurface(aId.surface_id);
+  auto tile = surface->GetTile(aId.x, aId.y);
+  wr::DeviceIntPoint targetOffset{0, 0};
+
+  // If tile owns an IDCompositionSurface we use it, otherwise we're using an
+  // IDCompositionVirtualSurface owned by the DCSurface.
+  RefPtr<IDCompositionSurface> compositionSurface;
+  if (surface->mIsVirtualSurface) {
+    gfx::IntRect validRect(aValidRect.min.x, aValidRect.min.y,
+                           aValidRect.width(), aValidRect.height());
+    if (!tile->mValidRect.IsEqualEdges(validRect)) {
+      tile->mValidRect = validRect;
+      surface->DirtyAllocatedRect();
+    }
+    wr::DeviceIntSize tileSize = surface->GetTileSize();
+    compositionSurface = surface->GetCompositionSurface();
+    wr::DeviceIntPoint virtualOffset = surface->GetVirtualOffset();
+    targetOffset.x = virtualOffset.x + tileSize.width * aId.x;
+    targetOffset.y = virtualOffset.y + tileSize.height * aId.y;
+  } else {
+    compositionSurface = tile->Bind(aValidRect);
+  }
+
+  if (tile->mNeedsFullDraw) {
+    // dcomp requires that the first BeginDraw on a non-virtual surface is the
+    // full size of the pixel buffer.
+    auto tileSize = surface->GetTileSize();
+    aDirtyRect.min.x = 0;
+    aDirtyRect.min.y = 0;
+    aDirtyRect.max.x = tileSize.width;
+    aDirtyRect.max.y = tileSize.height;
+    tile->mNeedsFullDraw = false;
+  }
+
+  *aFboId = CreateEGLSurfaceForCompositionSurface(
+      aDirtyRect, aOffset, compositionSurface, targetOffset);
+  mCurrentSurface = Some(compositionSurface);
+}
+
+void DCLayerTree::Unbind() {
+  if (mCurrentSurface.isNothing()) {
+    return;
+  }
+
+  RefPtr<IDCompositionSurface> surface = mCurrentSurface.ref();
+  surface->EndDraw();
+
+  DestroyEGLSurface();
+  mCurrentSurface = Nothing();
+}
+
+void DCLayerTree::CreateSurface(wr::NativeSurfaceId aId,
+                                wr::DeviceIntPoint aVirtualOffset,
+                                wr::DeviceIntSize aTileSize, bool aIsOpaque) {
+  auto it = mDCSurfaces.find(aId);
+  MOZ_RELEASE_ASSERT(it == mDCSurfaces.end());
+  if (it != mDCSurfaces.end()) {
+    // DCSurface already exists.
+    return;
+  }
+
+  // Tile size needs to be positive.
+  if (aTileSize.width <= 0 || aTileSize.height <= 0) {
+    gfxCriticalNote << "TileSize is not positive aId: " << wr::AsUint64(aId)
+                    << " aTileSize(" << aTileSize.width << ","
+                    << aTileSize.height << ")";
+  }
+
+  bool isVirtualSurface =
+      StaticPrefs::gfx_webrender_dcomp_use_virtual_surfaces_AtStartup();
+  auto surface = MakeUnique<DCSurface>(aTileSize, aVirtualOffset,
+                                       isVirtualSurface, aIsOpaque, this);
+  if (!surface->Initialize()) {
+    gfxCriticalNote << "Failed to initialize DCSurface: " << wr::AsUint64(aId);
+    return;
+  }
+
+  mDCSurfaces[aId] = std::move(surface);
+}
+
+void DCLayerTree::CreateExternalSurface(wr::NativeSurfaceId aId,
+                                        bool aIsOpaque) {
+  auto it = mDCSurfaces.find(aId);
+  MOZ_RELEASE_ASSERT(it == mDCSurfaces.end());
+
+  auto surface = MakeUnique<DCExternalSurfaceWrapper>(aIsOpaque, this);
+  if (!surface->Initialize()) {
+    gfxCriticalNote << "Failed to initialize DCExternalSurfaceWrapper: "
+                    << wr::AsUint64(aId);
+    return;
+  }
+
+  mDCSurfaces[aId] = std::move(surface);
+}
+
+void DCLayerTree::DestroySurface(NativeSurfaceId aId) {
+  auto surface_it = mDCSurfaces.find(aId);
+  MOZ_RELEASE_ASSERT(surface_it != mDCSurfaces.end());
+  auto surface = surface_it->second.get();
+
+  mRootVisual->RemoveVisual(surface->GetVisual());
+  mDCSurfaces.erase(surface_it);
+}
+
+void DCLayerTree::CreateTile(wr::NativeSurfaceId aId, int32_t aX, int32_t aY) {
+  auto surface = GetSurface(aId);
+  surface->CreateTile(aX, aY);
+}
+
+void DCLayerTree::DestroyTile(wr::NativeSurfaceId aId, int32_t aX, int32_t aY) {
+  auto surface = GetSurface(aId);
+  surface->DestroyTile(aX, aY);
+}
+
+void DCLayerTree::AttachExternalImage(wr::NativeSurfaceId aId,
+                                      wr::ExternalImageId aExternalImage) {
+  auto surface_it = mDCSurfaces.find(aId);
+  MOZ_RELEASE_ASSERT(surface_it != mDCSurfaces.end());
+  surface_it->second->AttachExternalImage(aExternalImage);
+}
+
+void DCExternalSurfaceWrapper::AttachExternalImage(
+    wr::ExternalImageId aExternalImage) {
+  if (auto* surface = EnsureSurfaceForExternalImage(aExternalImage)) {
+    surface->AttachExternalImage(aExternalImage);
+  }
+}
+
+template <class ToT>
+struct QI {
+  template <class FromT>
+  [[nodiscard]] static inline RefPtr<ToT> From(FromT* const from) {
+    RefPtr<ToT> to;
+    (void)from->QueryInterface(static_cast<ToT**>(getter_AddRefs(to)));
+    return to;
+  }
+};
+
+DCSurface* DCExternalSurfaceWrapper::EnsureSurfaceForExternalImage(
+    wr::ExternalImageId aExternalImage) {
+  if (mSurface) {
+    return mSurface.get();
+  }
+
+  // Create a new surface based on the texture type.
+  RenderTextureHost* texture =
+      RenderThread::Get()->GetRenderTexture(aExternalImage);
+  if (texture && texture->AsRenderDXGITextureHost()) {
+    mSurface.reset(new DCSurfaceVideo(mIsOpaque, mDCLayerTree));
+    if (!mSurface->Initialize()) {
+      gfxCriticalNote << "Failed to initialize DCSurfaceVideo: "
+                      << wr::AsUint64(aExternalImage);
+      mSurface = nullptr;
+    }
+  } else if (texture && texture->AsRenderDcompSurfaceTextureHost()) {
+    mSurface.reset(new DCSurfaceHandle(mIsOpaque, mDCLayerTree));
+    if (!mSurface->Initialize()) {
+      gfxCriticalNote << "Failed to initialize DCSurfaceHandle: "
+                      << wr::AsUint64(aExternalImage);
+      mSurface = nullptr;
+    }
+  }
+  if (!mSurface) {
+    gfxCriticalNote << "Failed to create a surface for external image: "
+                    << gfx::hexa(texture);
+    return nullptr;
+  }
+
+  // Add surface's visual which will contain video data to our root visual.
+  const auto surfaceVisual = mSurface->GetVisual();
+  mVisual->AddVisual(surfaceVisual, true, nullptr);
+
+  // -
+  // Apply color management.
+
+  [&]() {
+    const auto cmsMode = GfxColorManagementMode();
+    if (cmsMode == CMSMode::Off) return;
+
+    const auto dcomp = mDCLayerTree->GetCompositionDevice();
+    const auto dcomp3 = QI<IDCompositionDevice3>::From(dcomp);
+    if (!dcomp3) {
+      NS_WARNING(
+          "No IDCompositionDevice3, cannot use dcomp for color management.");
+      return;
+    }
+
+    // -
+
+    const auto cspace = [&]() {
+      const auto rangedCspace = texture->GetYUVColorSpace();
+      const auto info = FromYUVRangedColorSpace(rangedCspace);
+      auto ret = ToColorSpace2(info.space);
+      if (ret == gfx::ColorSpace2::Display && cmsMode == CMSMode::All) {
+        ret = gfx::ColorSpace2::SRGB;
+      }
+      return ret;
+    }();
+
+    const bool rec709GammaAsSrgb =
+        StaticPrefs::gfx_color_management_rec709_gamma_as_srgb();
+    const bool rec2020GammaAsRec709 =
+        StaticPrefs::gfx_color_management_rec2020_gamma_as_rec709();
+
+    auto cspaceDesc = color::ColorspaceDesc{};
+    switch (cspace) {
+      case gfx::ColorSpace2::Display:
+        return;  // No color management needed!
+      case gfx::ColorSpace2::SRGB:
+        cspaceDesc.chrom = color::Chromaticities::Srgb();
+        cspaceDesc.tf = color::PiecewiseGammaDesc::Srgb();
+        break;
+
+      case gfx::ColorSpace2::DISPLAY_P3:
+        cspaceDesc.chrom = color::Chromaticities::DisplayP3();
+        cspaceDesc.tf = color::PiecewiseGammaDesc::DisplayP3();
+        break;
+
+      case gfx::ColorSpace2::BT601_525:
+        cspaceDesc.chrom = color::Chromaticities::Rec601_525_Ntsc();
+        if (rec709GammaAsSrgb) {
+          cspaceDesc.tf = color::PiecewiseGammaDesc::Srgb();
+        } else {
+          cspaceDesc.tf = color::PiecewiseGammaDesc::Rec709();
+        }
+        break;
+
+      case gfx::ColorSpace2::BT709:
+        cspaceDesc.chrom = color::Chromaticities::Rec709();
+        if (rec709GammaAsSrgb) {
+          cspaceDesc.tf = color::PiecewiseGammaDesc::Srgb();
+        } else {
+          cspaceDesc.tf = color::PiecewiseGammaDesc::Rec709();
+        }
+        break;
+
+      case gfx::ColorSpace2::BT2020:
+        cspaceDesc.chrom = color::Chromaticities::Rec2020();
+        if (rec2020GammaAsRec709 && rec709GammaAsSrgb) {
+          cspaceDesc.tf = color::PiecewiseGammaDesc::Srgb();
+        } else if (rec2020GammaAsRec709) {
+          cspaceDesc.tf = color::PiecewiseGammaDesc::Rec709();
+        } else {
+          // Just Rec709 with slightly more precision.
+          cspaceDesc.tf = color::PiecewiseGammaDesc::Rec2020_12bit();
+        }
+        break;
+    }
+
+    const auto cprofileIn = color::ColorProfileDesc::From(cspaceDesc);
+    auto cprofileOut = mDCLayerTree->OutputColorProfile();
+    bool pretendSrgb = true;
+    if (pretendSrgb) {
+      cprofileOut = color::ColorProfileDesc::From({
+          color::Chromaticities::Srgb(),
+          color::PiecewiseGammaDesc::Srgb(),
+      });
+    }
+    const auto conversion = color::ColorProfileConversionDesc::From({
+        .src = cprofileIn,
+        .dst = cprofileOut,
+    });
+
+    // -
+
+    auto chain = ColorManagementChain::From(*dcomp3, conversion);
+    mCManageChain = Some(chain);
+
+    surfaceVisual->SetEffect(mCManageChain->last.get());
+  }();
+
+  return mSurface.get();
+}
+
+void DCExternalSurfaceWrapper::PresentExternalSurface(gfx::Matrix& aTransform) {
+  MOZ_ASSERT(mSurface);
+  if (auto* surface = mSurface->AsDCSurfaceVideo()) {
+    if (surface->CalculateSwapChainSize(aTransform)) {
+      surface->PresentVideo();
+    }
+  } else if (auto* surface = mSurface->AsDCSurfaceHandle()) {
+    surface->PresentSurfaceHandle();
+  }
+}
+
+template <typename T>
+static inline D2D1_RECT_F D2DRect(const T& aRect) {
+  return D2D1::RectF(aRect.X(), aRect.Y(), aRect.XMost(), aRect.YMost());
+}
+
+static inline D2D1_MATRIX_3X2_F D2DMatrix(const gfx::Matrix& aTransform) {
+  return D2D1::Matrix3x2F(aTransform._11, aTransform._12, aTransform._21,
+                          aTransform._22, aTransform._31, aTransform._32);
+}
+
+void DCLayerTree::AddSurface(wr::NativeSurfaceId aId,
+                             const wr::CompositorSurfaceTransform& aTransform,
+                             wr::DeviceIntRect aClipRect,
+                             wr::ImageRendering aImageRendering) {
+  auto it = mDCSurfaces.find(aId);
+  MOZ_RELEASE_ASSERT(it != mDCSurfaces.end());
+  const auto surface = it->second.get();
+  const auto visual = surface->GetVisual();
+
+  wr::DeviceIntPoint virtualOffset = surface->GetVirtualOffset();
+
+  float sx = aTransform.scale.x;
+  float sy = aTransform.scale.y;
+  float tx = aTransform.offset.x;
+  float ty = aTransform.offset.y;
+  gfx::Matrix transform(sx, 0.0, 0.0, sy, tx, ty);
+
+  surface->PresentExternalSurface(transform);
+
+  transform.PreTranslate(-virtualOffset.x, -virtualOffset.y);
+
+  // The DirectComposition API applies clipping *before* any
+  // transforms/offset, whereas we want the clip applied after. Right now, we
+  // only support rectilinear transforms, and then we transform our clip into
+  // pre-transform coordinate space for it to be applied there.
+  // DirectComposition does have an option for pre-transform clipping, if you
+  // create an explicit IDCompositionEffectGroup object and set a 3D transform
+  // on that. I suspect that will perform worse though, so we should only do
+  // that for complex transforms (which are never provided right now).
+  MOZ_ASSERT(transform.IsRectilinear());
+  gfx::Rect clip = transform.Inverse().TransformBounds(gfx::Rect(
+      aClipRect.min.x, aClipRect.min.y, aClipRect.width(), aClipRect.height()));
+  // Set the clip rect - converting from world space to the pre-offset space
+  // that DC requires for rectangle clips.
+  visual->SetClip(D2DRect(clip));
+
+  // TODO: The input matrix is a 4x4, but we only support a 3x2 at
+  // the D3D API level (unless we QI to IDCompositionVisual3, which might
+  // not be available?).
+  // Should we assert here, or restrict at the WR API level.
+  visual->SetTransform(D2DMatrix(transform));
+
+  if (aImageRendering == wr::ImageRendering::Auto) {
+    visual->SetBitmapInterpolationMode(
+        DCOMPOSITION_BITMAP_INTERPOLATION_MODE_LINEAR);
+  } else {
+    visual->SetBitmapInterpolationMode(
+        DCOMPOSITION_BITMAP_INTERPOLATION_MODE_NEAREST_NEIGHBOR);
+  }
+
+  mCurrentLayers.push_back(aId);
+}
+
+GLuint DCLayerTree::GetOrCreateFbo(int aWidth, int aHeight) {
+  const auto gl = GetGLContext();
+  GLuint fboId = 0;
+
+  // Check if we have a cached FBO with matching dimensions
+  for (auto it = mFrameBuffers.begin(); it != mFrameBuffers.end(); ++it) {
+    if (it->width == aWidth && it->height == aHeight) {
+      fboId = it->fboId;
+      it->lastFrameUsed = mCurrentFrame;
+      break;
+    }
+  }
+
+  // If not, create a new FBO with attached depth buffer
+  if (fboId == 0) {
+    // Create the depth buffer
+    GLuint depthRboId;
+    gl->fGenRenderbuffers(1, &depthRboId);
+    gl->fBindRenderbuffer(LOCAL_GL_RENDERBUFFER, depthRboId);
+    gl->fRenderbufferStorage(LOCAL_GL_RENDERBUFFER, LOCAL_GL_DEPTH_COMPONENT24,
+                             aWidth, aHeight);
+
+    // Create the framebuffer and attach the depth buffer to it
+    gl->fGenFramebuffers(1, &fboId);
+    gl->fBindFramebuffer(LOCAL_GL_DRAW_FRAMEBUFFER, fboId);
+    gl->fFramebufferRenderbuffer(LOCAL_GL_DRAW_FRAMEBUFFER,
+                                 LOCAL_GL_DEPTH_ATTACHMENT,
+                                 LOCAL_GL_RENDERBUFFER, depthRboId);
+
+    // Store this in the cache for future calls.
+    // TODO(gw): Maybe we should periodically scan this list and remove old
+    // entries that
+    //           haven't been used for some time?
+    DCLayerTree::CachedFrameBuffer frame_buffer_info;
+    frame_buffer_info.width = aWidth;
+    frame_buffer_info.height = aHeight;
+    frame_buffer_info.fboId = fboId;
+    frame_buffer_info.depthRboId = depthRboId;
+    frame_buffer_info.lastFrameUsed = mCurrentFrame;
+    mFrameBuffers.AppendElement(frame_buffer_info);
+  }
+
+  return fboId;
+}
+
+bool DCLayerTree::EnsureVideoProcessor(const gfx::IntSize& aInputSize,
+                                       const gfx::IntSize& aOutputSize) {
+  HRESULT hr;
+
+  if (!mVideoDevice || !mVideoContext) {
+    return false;
+  }
+
+  if (mVideoProcessor && (aInputSize <= mVideoInputSize) &&
+      (aOutputSize <= mVideoOutputSize)) {
+    return true;
+  }
+
+  mVideoProcessor = nullptr;
+  mVideoProcessorEnumerator = nullptr;
+
+  D3D11_VIDEO_PROCESSOR_CONTENT_DESC desc = {};
+  desc.InputFrameFormat = D3D11_VIDEO_FRAME_FORMAT_PROGRESSIVE;
+  desc.InputFrameRate.Numerator = 60;
+  desc.InputFrameRate.Denominator = 1;
+  desc.InputWidth = aInputSize.width;
+  desc.InputHeight = aInputSize.height;
+  desc.OutputFrameRate.Numerator = 60;
+  desc.OutputFrameRate.Denominator = 1;
+  desc.OutputWidth = aOutputSize.width;
+  desc.OutputHeight = aOutputSize.height;
+  desc.Usage = D3D11_VIDEO_USAGE_PLAYBACK_NORMAL;
+
+  hr = mVideoDevice->CreateVideoProcessorEnumerator(
+      &desc, getter_AddRefs(mVideoProcessorEnumerator));
+  if (FAILED(hr)) {
+    gfxCriticalNote << "Failed to create VideoProcessorEnumerator: "
+                    << gfx::hexa(hr);
+    return false;
+  }
+
+  hr = mVideoDevice->CreateVideoProcessor(mVideoProcessorEnumerator, 0,
+                                          getter_AddRefs(mVideoProcessor));
+  if (FAILED(hr)) {
+    mVideoProcessor = nullptr;
+    mVideoProcessorEnumerator = nullptr;
+    gfxCriticalNote << "Failed to create VideoProcessor: " << gfx::hexa(hr);
+    return false;
+  }
+
+  // Reduce power cosumption
+  // By default, the driver might perform certain processing tasks
+  // automatically
+  mVideoContext->VideoProcessorSetStreamAutoProcessingMode(mVideoProcessor, 0,
+                                                           FALSE);
+
+  mVideoInputSize = aInputSize;
+  mVideoOutputSize = aOutputSize;
+
+  return true;
+}
+
+bool DCLayerTree::SupportsHardwareOverlays() {
+  return sGpuOverlayInfo->mSupportsHardwareOverlays;
+}
+
+bool DCLayerTree::SupportsSwapChainTearing() {
+  RefPtr<ID3D11Device> device = mDevice;
+  static const bool supported = [device] {
+    RefPtr<IDXGIDevice> dxgiDevice;
+    RefPtr<IDXGIAdapter> adapter;
+    device->QueryInterface((IDXGIDevice**)getter_AddRefs(dxgiDevice));
+    dxgiDevice->GetAdapter(getter_AddRefs(adapter));
+
+    RefPtr<IDXGIFactory5> dxgiFactory;
+    HRESULT hr = adapter->GetParent(
+        IID_PPV_ARGS((IDXGIFactory5**)getter_AddRefs(dxgiFactory)));
+    if (FAILED(hr)) {
+      return false;
+    }
+
+    BOOL presentAllowTearing = FALSE;
+    hr = dxgiFactory->CheckFeatureSupport(DXGI_FEATURE_PRESENT_ALLOW_TEARING,
+                                          &presentAllowTearing,
+                                          sizeof(presentAllowTearing));
+    if (FAILED(hr)) {
+      return false;
+    }
+
+    if (auto* gpuParent = gfx::GPUParent::GetSingleton()) {
+      gpuParent->NotifySwapChainInfo(
+          layers::SwapChainInfo(!!presentAllowTearing));
+    } else if (XRE_IsParentProcess()) {
+      MOZ_ASSERT_UNREACHABLE("unexpected to be called");
+    }
+    return !!presentAllowTearing;
+  }();
+  return supported;
+}
+
+DXGI_FORMAT DCLayerTree::GetOverlayFormatForSDR() {
+  return sGpuOverlayInfo->mOverlayFormatUsed;
+}
+
+static layers::OverlaySupportType FlagsToOverlaySupportType(
+    UINT aFlags, bool aSoftwareOverlaySupported) {
+  if (aFlags & DXGI_OVERLAY_SUPPORT_FLAG_SCALING) {
+    return layers::OverlaySupportType::Scaling;
+  }
+  if (aFlags & DXGI_OVERLAY_SUPPORT_FLAG_DIRECT) {
+    return layers::OverlaySupportType::Direct;
+  }
+  if (aSoftwareOverlaySupported) {
+    return layers::OverlaySupportType::Software;
+  }
+  return layers::OverlaySupportType::None;
+}
+
+layers::OverlayInfo DCLayerTree::GetOverlayInfo() {
+  layers::OverlayInfo info;
+
+  info.mSupportsOverlays = sGpuOverlayInfo->mSupportsHardwareOverlays;
+  info.mNv12Overlay =
+      FlagsToOverlaySupportType(sGpuOverlayInfo->mNv12OverlaySupportFlags,
+                                /* aSoftwareOverlaySupported */ false);
+  info.mYuy2Overlay =
+      FlagsToOverlaySupportType(sGpuOverlayInfo->mYuy2OverlaySupportFlags,
+                                /* aSoftwareOverlaySupported */ false);
+  info.mBgra8Overlay =
+      FlagsToOverlaySupportType(sGpuOverlayInfo->mBgra8OverlaySupportFlags,
+                                /* aSoftwareOverlaySupported */ true);
+  info.mRgb10a2Overlay =
+      FlagsToOverlaySupportType(sGpuOverlayInfo->mRgb10a2OverlaySupportFlags,
+                                /* aSoftwareOverlaySupported */ false);
+
+  return info;
+}
+
+DCSurface::DCSurface(wr::DeviceIntSize aTileSize,
+                     wr::DeviceIntPoint aVirtualOffset, bool aIsVirtualSurface,
+                     bool aIsOpaque, DCLayerTree* aDCLayerTree)
+    : mIsVirtualSurface(aIsVirtualSurface),
+      mDCLayerTree(aDCLayerTree),
+      mTileSize(aTileSize),
+      mIsOpaque(aIsOpaque),
+      mAllocatedRectDirty(true),
+      mVirtualOffset(aVirtualOffset) {}
+
+DCSurface::~DCSurface() {}
+
+bool DCSurface::Initialize() {
+  // Create a visual for tiles to attach to, whether virtual or not.
+  HRESULT hr;
+  const auto dCompDevice = mDCLayerTree->GetCompositionDevice();
+  hr = dCompDevice->CreateVisual(getter_AddRefs(mVisual));
+  if (FAILED(hr)) {
+    gfxCriticalNote << "Failed to create DCompositionVisual: " << gfx::hexa(hr);
+    return false;
+  }
+
+  // If virtual surface is enabled, create and attach to visual, in this case
+  // the tiles won't own visuals or surfaces.
+  if (mIsVirtualSurface) {
+    DXGI_ALPHA_MODE alpha_mode =
+        mIsOpaque ? DXGI_ALPHA_MODE_IGNORE : DXGI_ALPHA_MODE_PREMULTIPLIED;
+
+    hr = dCompDevice->CreateVirtualSurface(
+        VIRTUAL_SURFACE_SIZE, VIRTUAL_SURFACE_SIZE, DXGI_FORMAT_R8G8B8A8_UNORM,
+        alpha_mode, getter_AddRefs(mVirtualSurface));
+    MOZ_ASSERT(SUCCEEDED(hr));
+
+    // Bind the surface memory to this visual
+    hr = mVisual->SetContent(mVirtualSurface);
+    MOZ_ASSERT(SUCCEEDED(hr));
+  }
+
+  return true;
+}
+
+void DCSurface::CreateTile(int32_t aX, int32_t aY) {
+  TileKey key(aX, aY);
+  MOZ_RELEASE_ASSERT(mDCTiles.find(key) == mDCTiles.end());
+
+  auto tile = MakeUnique<DCTile>(mDCLayerTree);
+  if (!tile->Initialize(aX, aY, mTileSize, mIsVirtualSurface, mIsOpaque,
+                        mVisual)) {
+    gfxCriticalNote << "Failed to initialize DCTile: " << aX << aY;
+    return;
+  }
+
+  if (mIsVirtualSurface) {
+    mAllocatedRectDirty = true;
+  } else {
+    mVisual->AddVisual(tile->GetVisual(), false, nullptr);
+  }
+
+  mDCTiles[key] = std::move(tile);
+}
+
+void DCSurface::DestroyTile(int32_t aX, int32_t aY) {
+  TileKey key(aX, aY);
+  if (mIsVirtualSurface) {
+    mAllocatedRectDirty = true;
+  } else {
+    auto tile = GetTile(aX, aY);
+    mVisual->RemoveVisual(tile->GetVisual());
+  }
+  mDCTiles.erase(key);
+}
+
+void DCSurface::DirtyAllocatedRect() { mAllocatedRectDirty = true; }
+
+void DCSurface::UpdateAllocatedRect() {
+  if (mAllocatedRectDirty) {
+    if (mVirtualSurface) {
+      // The virtual surface may have holes in it (for example, an empty tile
+      // that has no primitives). Instead of trimming to a single bounding
+      // rect, supply the rect of each valid tile to handle this case.
+      std::vector<RECT> validRects;
+
+      for (auto it = mDCTiles.begin(); it != mDCTiles.end(); ++it) {
+        auto tile = GetTile(it->first.mX, it->first.mY);
+        RECT rect;
+
+        rect.left = (LONG)(mVirtualOffset.x + it->first.mX * mTileSize.width +
+                           tile->mValidRect.x);
+        rect.top = (LONG)(mVirtualOffset.y + it->first.mY * mTileSize.height +
+                          tile->mValidRect.y);
+        rect.right = rect.left + tile->mValidRect.width;
+        rect.bottom = rect.top + tile->mValidRect.height;
+
+        validRects.push_back(rect);
+      }
+
+      mVirtualSurface->Trim(validRects.data(), validRects.size());
+    }
+    // When not using a virtual surface, we still want to reset this
+    mAllocatedRectDirty = false;
+  }
+}
+
+DCTile* DCSurface::GetTile(int32_t aX, int32_t aY) const {
+  TileKey key(aX, aY);
+  auto tile_it = mDCTiles.find(key);
+  MOZ_RELEASE_ASSERT(tile_it != mDCTiles.end());
+  return tile_it->second.get();
+}
+
+DCSurfaceVideo::DCSurfaceVideo(bool aIsOpaque, DCLayerTree* aDCLayerTree)
+    : DCSurface(wr::DeviceIntSize{}, wr::DeviceIntPoint{}, false, aIsOpaque,
+                aDCLayerTree) {}
+
+DCSurfaceVideo::~DCSurfaceVideo() {
+  ReleaseDecodeSwapChainResources();
+  MOZ_ASSERT(!mSwapChainSurfaceHandle);
+}
+
+bool IsYUVSwapChainFormat(DXGI_FORMAT aFormat) {
+  if (aFormat == DXGI_FORMAT_NV12 || aFormat == DXGI_FORMAT_YUY2) {
+    return true;
+  }
+  return false;
+}
+
+void DCSurfaceVideo::AttachExternalImage(wr::ExternalImageId aExternalImage) {
+  RenderTextureHost* texture =
+      RenderThread::Get()->GetRenderTexture(aExternalImage);
+  MOZ_RELEASE_ASSERT(texture);
+
+  if (mPrevTexture == texture) {
+    return;
+  }
+
+  // XXX if software decoded video frame format is nv12, it could be used as
+  // video overlay.
+  if (!texture || !texture->AsRenderDXGITextureHost() ||
+      texture->GetFormat() != gfx::SurfaceFormat::NV12) {
+    gfxCriticalNote << "Unsupported RenderTexture for overlay: "
+                    << gfx::hexa(texture);
+    return;
+  }
+
+  mRenderTextureHost = texture;
+}
+
+bool DCSurfaceVideo::CalculateSwapChainSize(gfx::Matrix& aTransform) {
+  if (!mRenderTextureHost) {
+    MOZ_ASSERT_UNREACHABLE("unexpected to be called");
+    return false;
+  }
+
+  mVideoSize = mRenderTextureHost->AsRenderDXGITextureHost()->GetSize(0);
+
+  // When RenderTextureHost, swapChainSize or VideoSwapChain are updated,
+  // DCSurfaceVideo::PresentVideo() needs to be called.
+  bool needsToPresent = mPrevTexture != mRenderTextureHost;
+  gfx::IntSize swapChainSize = mVideoSize;
+  gfx::Matrix transform = aTransform;
+
+  // When video is rendered to axis aligned integer rectangle, video scaling
+  // could be done by VideoProcessor
+  bool scaleVideoAtVideoProcessor = false;
+  if (StaticPrefs::gfx_webrender_dcomp_video_vp_scaling_win_AtStartup() &&
+      aTransform.PreservesAxisAlignedRectangles()) {
+    gfx::Size scaledSize = gfx::Size(mVideoSize) * aTransform.ScaleFactors();
+    gfx::IntSize size(int32_t(std::round(scaledSize.width)),
+                      int32_t(std::round(scaledSize.height)));
+    if (gfx::FuzzyEqual(scaledSize.width, size.width, 0.1f) &&
+        gfx::FuzzyEqual(scaledSize.height, size.height, 0.1f)) {
+      scaleVideoAtVideoProcessor = true;
+      swapChainSize = size;
+    }
+  }
+
+  if (scaleVideoAtVideoProcessor) {
+    // 4:2:2 subsampled formats like YUY2 must have an even width, and 4:2:0
+    // subsampled formats like NV12 must have an even width and height.
+    if (swapChainSize.width % 2 == 1) {
+      swapChainSize.width += 1;
+    }
+    if (swapChainSize.height % 2 == 1) {
+      swapChainSize.height += 1;
+    }
+    transform = gfx::Matrix::Translation(aTransform.GetTranslation());
+  }
+
+  if (!mVideoSwapChain || mSwapChainSize != swapChainSize) {
+    needsToPresent = true;
+    ReleaseDecodeSwapChainResources();
+    // Update mSwapChainSize before creating SwapChain
+    mSwapChainSize = swapChainSize;
+
+    auto swapChainFormat = GetSwapChainFormat();
+    bool useYUVSwapChain = IsYUVSwapChainFormat(swapChainFormat);
+    if (useYUVSwapChain) {
+      // Tries to create YUV SwapChain
+      CreateVideoSwapChain();
+      if (!mVideoSwapChain) {
+        mFailedYuvSwapChain = true;
+        ReleaseDecodeSwapChainResources();
+
+        gfxCriticalNote << "Fallback to RGB SwapChain";
+      }
+    }
+    // Tries to create RGB SwapChain
+    if (!mVideoSwapChain) {
+      CreateVideoSwapChain();
+    }
+  }
+
+  aTransform = transform;
+
+  return needsToPresent;
+}
+
+void DCSurfaceVideo::PresentVideo() {
+  if (!mRenderTextureHost) {
+    return;
+  }
+
+  if (!mVideoSwapChain) {
+    gfxCriticalNote << "Failed to create VideoSwapChain";
+    RenderThread::Get()->NotifyWebRenderError(
+        wr::WebRenderError::VIDEO_OVERLAY);
+    return;
+  }
+
+  mVisual->SetContent(mVideoSwapChain);
+
+  if (!CallVideoProcessorBlt()) {
+    auto swapChainFormat = GetSwapChainFormat();
+    bool useYUVSwapChain = IsYUVSwapChainFormat(swapChainFormat);
+    if (useYUVSwapChain) {
+      mFailedYuvSwapChain = true;
+      ReleaseDecodeSwapChainResources();
+      return;
+    }
+    RenderThread::Get()->NotifyWebRenderError(
+        wr::WebRenderError::VIDEO_OVERLAY);
+    return;
+  }
+
+  auto start = TimeStamp::Now();
+  HRESULT hr = mVideoSwapChain->Present(0, 0);
+  auto end = TimeStamp::Now();
+
+  if (FAILED(hr) && hr != DXGI_STATUS_OCCLUDED) {
+    gfxCriticalNoteOnce << "video Present failed: " << gfx::hexa(hr);
+  }
+
+  mPrevTexture = mRenderTextureHost;
+
+  // Disable video overlay if mVideoSwapChain->Present() is too slow. It drops
+  // fps.
+
+  if (!StaticPrefs::gfx_webrender_dcomp_video_check_slow_present()) {
+    return;
+  }
+
+  const auto maxWaitDurationMs = 2.0;
+  const auto maxSlowPresentCount = 5;
+  const auto duration = (end - start).ToMilliseconds();
+
+  if (duration > maxWaitDurationMs) {
+    mSlowPresentCount++;
+  } else {
+    mSlowPresentCount = 0;
+  }
+
+  if (mSlowPresentCount > maxSlowPresentCount) {
+    gfxCriticalNoteOnce << "Video swapchain present is slow";
+    RenderThread::Get()->HandleWebRenderError(WebRenderError::VIDEO_OVERLAY);
+  }
+}
+
+DXGI_FORMAT DCSurfaceVideo::GetSwapChainFormat() {
+  if (mFailedYuvSwapChain || !mDCLayerTree->SupportsHardwareOverlays()) {
+    return DXGI_FORMAT_B8G8R8A8_UNORM;
+  }
+  return mDCLayerTree->GetOverlayFormatForSDR();
+}
+
+bool DCSurfaceVideo::CreateVideoSwapChain() {
+  MOZ_ASSERT(mRenderTextureHost);
+
+  const auto device = mDCLayerTree->GetDevice();
+
+  RefPtr<IDXGIDevice> dxgiDevice;
+  device->QueryInterface((IDXGIDevice**)getter_AddRefs(dxgiDevice));
+
+  RefPtr<IDXGIFactoryMedia> dxgiFactoryMedia;
+  {
+    RefPtr<IDXGIAdapter> adapter;
+    dxgiDevice->GetAdapter(getter_AddRefs(adapter));
+    adapter->GetParent(
+        IID_PPV_ARGS((IDXGIFactoryMedia**)getter_AddRefs(dxgiFactoryMedia)));
+  }
+
+  mSwapChainSurfaceHandle = gfx::DeviceManagerDx::CreateDCompSurfaceHandle();
+  if (!mSwapChainSurfaceHandle) {
+    gfxCriticalNote << "Failed to create DCompSurfaceHandle";
+    return false;
+  }
+
+  auto swapChainFormat = GetSwapChainFormat();
+
+  DXGI_SWAP_CHAIN_DESC1 desc = {};
+  desc.Width = mSwapChainSize.width;
+  desc.Height = mSwapChainSize.height;
+  desc.Format = swapChainFormat;
+  desc.Stereo = FALSE;
+  desc.SampleDesc.Count = 1;
+  desc.BufferCount = 2;
+  desc.BufferUsage = DXGI_USAGE_RENDER_TARGET_OUTPUT;
+  desc.Scaling = DXGI_SCALING_STRETCH;
+  desc.SwapEffect = DXGI_SWAP_EFFECT_FLIP_SEQUENTIAL;
+  desc.Flags = DXGI_SWAP_CHAIN_FLAG_FULLSCREEN_VIDEO;
+  if (IsYUVSwapChainFormat(swapChainFormat)) {
+    desc.Flags |= DXGI_SWAP_CHAIN_FLAG_YUV_VIDEO;
+  }
+  desc.AlphaMode = DXGI_ALPHA_MODE_IGNORE;
+
+  HRESULT hr;
+  hr = dxgiFactoryMedia->CreateSwapChainForCompositionSurfaceHandle(
+      device, mSwapChainSurfaceHandle, &desc, nullptr,
+      getter_AddRefs(mVideoSwapChain));
+
+  if (FAILED(hr)) {
+    gfxCriticalNote << "Failed to create video SwapChain: " << gfx::hexa(hr)
+                    << " " << mSwapChainSize;
+    return false;
+  }
+
+  mSwapChainFormat = swapChainFormat;
+  return true;
+}
+
+// TODO: Replace with YUVRangedColorSpace
+static Maybe<DXGI_COLOR_SPACE_TYPE> GetSourceDXGIColorSpace(
+    const gfx::YUVColorSpace aYUVColorSpace,
+    const gfx::ColorRange aColorRange) {
+  if (aYUVColorSpace == gfx::YUVColorSpace::BT601) {
+    if (aColorRange == gfx::ColorRange::FULL) {
+      return Some(DXGI_COLOR_SPACE_YCBCR_FULL_G22_LEFT_P601);
+    } else {
+      return Some(DXGI_COLOR_SPACE_YCBCR_STUDIO_G22_LEFT_P601);
+    }
+  } else if (aYUVColorSpace == gfx::YUVColorSpace::BT709) {
+    if (aColorRange == gfx::ColorRange::FULL) {
+      return Some(DXGI_COLOR_SPACE_YCBCR_FULL_G22_LEFT_P709);
+    } else {
+      return Some(DXGI_COLOR_SPACE_YCBCR_STUDIO_G22_LEFT_P709);
+    }
+  } else if (aYUVColorSpace == gfx::YUVColorSpace::BT2020) {
+    if (aColorRange == gfx::ColorRange::FULL) {
+      // XXX Add SMPTEST2084 handling. HDR content is not handled yet by
+      // video overlay.
+      return Some(DXGI_COLOR_SPACE_YCBCR_FULL_G22_LEFT_P2020);
+    } else {
+      return Some(DXGI_COLOR_SPACE_YCBCR_STUDIO_G22_LEFT_P2020);
+    }
+  }
+
+  return Nothing();
+}
+
+static Maybe<DXGI_COLOR_SPACE_TYPE> GetSourceDXGIColorSpace(
+    const gfx::YUVRangedColorSpace aYUVColorSpace) {
+  const auto info = FromYUVRangedColorSpace(aYUVColorSpace);
+  return GetSourceDXGIColorSpace(info.space, info.range);
+}
+
+static void SetNvidiaVideoSuperRes(ID3D11VideoContext* videoContext,
+                                   ID3D11VideoProcessor* videoProcessor,
+                                   bool enabled) {
+  LOG("SetNvidiaVideoSuperRes() enabled=%d", enabled);
+
+  // Undocumented NVIDIA driver constants
+  constexpr GUID nvGUID = {0xD43CE1B3,
+                           0x1F4B,
+                           0x48AC,
+                           {0xBA, 0xEE, 0xC3, 0xC2, 0x53, 0x75, 0xE6, 0xF7}};
+
+  constexpr UINT nvExtensionVersion = 0x1;
+  constexpr UINT nvExtensionMethodSuperResolution = 0x2;
+  struct {
+    UINT version;
+    UINT method;
+    UINT enable;
+  } streamExtensionInfo = {nvExtensionVersion, nvExtensionMethodSuperResolution,
+                           enabled ? 0 : 1u};
+
+  HRESULT hr;
+  hr = videoContext->VideoProcessorSetStreamExtension(
+      videoProcessor, 0, &nvGUID, sizeof(streamExtensionInfo),
+      &streamExtensionInfo);
+
+  // Ignore errors as could be unsupported
+  if (FAILED(hr)) {
+    LOG("SetNvidiaVideoSuperRes() error: %lx", hr);
+    return;
+  }
+}
+
+static UINT GetVendorId(ID3D11VideoDevice* const videoDevice) {
+  RefPtr<IDXGIDevice> dxgiDevice;
+  RefPtr<IDXGIAdapter> adapter;
+  videoDevice->QueryInterface((IDXGIDevice**)getter_AddRefs(dxgiDevice));
+  dxgiDevice->GetAdapter(getter_AddRefs(adapter));
+
+  DXGI_ADAPTER_DESC adapterDesc;
+  adapter->GetDesc(&adapterDesc);
+
+  return adapterDesc.VendorId;
+}
+
+bool DCSurfaceVideo::CallVideoProcessorBlt() {
+  MOZ_ASSERT(mRenderTextureHost);
+
+  HRESULT hr;
+  const auto videoDevice = mDCLayerTree->GetVideoDevice();
+  const auto videoContext = mDCLayerTree->GetVideoContext();
+  const auto texture = mRenderTextureHost->AsRenderDXGITextureHost();
+
+  Maybe<DXGI_COLOR_SPACE_TYPE> sourceColorSpace =
+      GetSourceDXGIColorSpace(texture->GetYUVColorSpace());
+  if (sourceColorSpace.isNothing()) {
+    gfxCriticalNote << "Unsupported color space";
+    return false;
+  }
+
+  RefPtr<ID3D11Texture2D> texture2D = texture->GetD3D11Texture2DWithGL();
+  if (!texture2D) {
+    gfxCriticalNote << "Failed to get D3D11Texture2D";
+    return false;
+  }
+
+  if (!mVideoSwapChain) {
+    return false;
+  }
+
+  if (!mDCLayerTree->EnsureVideoProcessor(mVideoSize, mSwapChainSize)) {
+    gfxCriticalNote << "EnsureVideoProcessor Failed";
+    return false;
+  }
+
+  RefPtr<IDXGISwapChain3> swapChain3;
+  mVideoSwapChain->QueryInterface(
+      (IDXGISwapChain3**)getter_AddRefs(swapChain3));
+  if (!swapChain3) {
+    gfxCriticalNote << "Failed to get IDXGISwapChain3";
+    return false;
+  }
+
+  RefPtr<ID3D11VideoContext1> videoContext1;
+  videoContext->QueryInterface(
+      (ID3D11VideoContext1**)getter_AddRefs(videoContext1));
+  if (!videoContext1) {
+    gfxCriticalNote << "Failed to get ID3D11VideoContext1";
+    return false;
+  }
+
+  const auto videoProcessor = mDCLayerTree->GetVideoProcessor();
+  const auto videoProcessorEnumerator =
+      mDCLayerTree->GetVideoProcessorEnumerator();
+
+  DXGI_COLOR_SPACE_TYPE inputColorSpace = sourceColorSpace.ref();
+  videoContext1->VideoProcessorSetStreamColorSpace1(videoProcessor, 0,
+                                                    inputColorSpace);
+
+  DXGI_COLOR_SPACE_TYPE outputColorSpace =
+      IsYUVSwapChainFormat(mSwapChainFormat)
+          ? inputColorSpace
+          : DXGI_COLOR_SPACE_RGB_FULL_G22_NONE_P709;
+  hr = swapChain3->SetColorSpace1(outputColorSpace);
+  if (FAILED(hr)) {
+    gfxCriticalNoteOnce << "SetColorSpace1 failed: " << gfx::hexa(hr);
+    RenderThread::Get()->NotifyWebRenderError(
+        wr::WebRenderError::VIDEO_OVERLAY);
+    return false;
+  }
+  videoContext1->VideoProcessorSetOutputColorSpace1(videoProcessor,
+                                                    outputColorSpace);
+
+  D3D11_VIDEO_PROCESSOR_INPUT_VIEW_DESC inputDesc = {};
+  inputDesc.ViewDimension = D3D11_VPIV_DIMENSION_TEXTURE2D;
+  inputDesc.Texture2D.ArraySlice = texture->ArrayIndex();
+
+  RefPtr<ID3D11VideoProcessorInputView> inputView;
+  hr = videoDevice->CreateVideoProcessorInputView(
+      texture2D, videoProcessorEnumerator, &inputDesc,
+      getter_AddRefs(inputView));
+  if (FAILED(hr)) {
+    gfxCriticalNote << "ID3D11VideoProcessorInputView creation failed: "
+                    << gfx::hexa(hr);
+    return false;
+  }
+
+  D3D11_VIDEO_PROCESSOR_STREAM stream = {};
+  stream.Enable = true;
+  stream.OutputIndex = 0;
+  stream.InputFrameOrField = 0;
+  stream.PastFrames = 0;
+  stream.FutureFrames = 0;
+  stream.pInputSurface = inputView.get();
+
+  RECT destRect;
+  destRect.left = 0;
+  destRect.top = 0;
+  destRect.right = mSwapChainSize.width;
+  destRect.bottom = mSwapChainSize.height;
+
+  videoContext->VideoProcessorSetOutputTargetRect(videoProcessor, TRUE,
+                                                  &destRect);
+  videoContext->VideoProcessorSetStreamDestRect(videoProcessor, 0, TRUE,
+                                                &destRect);
+  RECT sourceRect;
+  sourceRect.left = 0;
+  sourceRect.top = 0;
+  sourceRect.right = mVideoSize.width;
+  sourceRect.bottom = mVideoSize.height;
+  videoContext->VideoProcessorSetStreamSourceRect(videoProcessor, 0, TRUE,
+                                                  &sourceRect);
+
+  if (!mOutputView) {
+    RefPtr<ID3D11Texture2D> backBuf;
+    mVideoSwapChain->GetBuffer(0, __uuidof(ID3D11Texture2D),
+                               (void**)getter_AddRefs(backBuf));
+
+    D3D11_VIDEO_PROCESSOR_OUTPUT_VIEW_DESC outputDesc = {};
+    outputDesc.ViewDimension = D3D11_VPOV_DIMENSION_TEXTURE2D;
+    outputDesc.Texture2D.MipSlice = 0;
+
+    hr = videoDevice->CreateVideoProcessorOutputView(
+        backBuf, videoProcessorEnumerator, &outputDesc,
+        getter_AddRefs(mOutputView));
+    if (FAILED(hr)) {
+      gfxCriticalNote << "ID3D11VideoProcessorOutputView creation failed: "
+                      << gfx::hexa(hr);
+      return false;
+    }
+  }
+
+  const UINT vendorId = GetVendorId(videoDevice);
+  if (vendorId == 0x10DE &&
+      StaticPrefs::gfx_webrender_super_resolution_nvidia_AtStartup()) {
+    SetNvidiaVideoSuperRes(videoContext, videoProcessor, true);
+  }
+
+  hr = videoContext->VideoProcessorBlt(videoProcessor, mOutputView, 0, 1,
+                                       &stream);
+  if (FAILED(hr)) {
+    gfxCriticalNote << "VideoProcessorBlt failed: " << gfx::hexa(hr);
+    return false;
+  }
+
+  return true;
+}
+
+void DCSurfaceVideo::ReleaseDecodeSwapChainResources() {
+  mOutputView = nullptr;
+  mVideoSwapChain = nullptr;
+  mDecodeSwapChain = nullptr;
+  mDecodeResource = nullptr;
+  if (mSwapChainSurfaceHandle) {
+    ::CloseHandle(mSwapChainSurfaceHandle);
+    mSwapChainSurfaceHandle = 0;
+  }
+}
+
+DCSurfaceHandle::DCSurfaceHandle(bool aIsOpaque, DCLayerTree* aDCLayerTree)
+    : DCSurface(wr::DeviceIntSize{}, wr::DeviceIntPoint{}, false, aIsOpaque,
+                aDCLayerTree) {}
+
+void DCSurfaceHandle::AttachExternalImage(wr::ExternalImageId aExternalImage) {
+  RenderTextureHost* texture =
+      RenderThread::Get()->GetRenderTexture(aExternalImage);
+  RenderDcompSurfaceTextureHost* renderTexture =
+      texture ? texture->AsRenderDcompSurfaceTextureHost() : nullptr;
+  if (!renderTexture) {
+    gfxCriticalNote << "Unsupported RenderTexture for DCSurfaceHandle: "
+                    << gfx::hexa(texture);
+    return;
+  }
+
+  const auto handle = renderTexture->GetDcompSurfaceHandle();
+  if (GetSurfaceHandle() == handle) {
+    return;
+  }
+
+  LOG_H("AttachExternalImage, ext-image=%" PRIu64 ", texture=%p, handle=%p",
+        wr::AsUint64(aExternalImage), renderTexture, handle);
+  mDcompTextureHost = renderTexture;
+}
+
+HANDLE DCSurfaceHandle::GetSurfaceHandle() const {
+  if (mDcompTextureHost) {
+    return mDcompTextureHost->GetDcompSurfaceHandle();
+  }
+  return nullptr;
+}
+
+IDCompositionSurface* DCSurfaceHandle::EnsureSurface() {
+  if (auto* surface = mDcompTextureHost->GetSurface()) {
+    return surface;
+  }
+
+  // Texture host hasn't created the surface yet, ask it to create a new one.
+  RefPtr<IDCompositionDevice> device;
+  HRESULT hr = mDCLayerTree->GetCompositionDevice()->QueryInterface(
+      (IDCompositionDevice**)getter_AddRefs(device));
+  if (FAILED(hr)) {
+    gfxCriticalNote
+        << "Failed to convert IDCompositionDevice2 to IDCompositionDevice: "
+        << gfx::hexa(hr);
+    return nullptr;
+  }
+
+  return mDcompTextureHost->CreateSurfaceFromDevice(device);
+}
+
+void DCSurfaceHandle::PresentSurfaceHandle() {
+  LOG_H("PresentSurfaceHandle");
+  if (IDCompositionSurface* surface = EnsureSurface()) {
+    LOG_H("Set surface %p to visual", surface);
+    mVisual->SetContent(surface);
+  } else {
+    mVisual->SetContent(nullptr);
+  }
+}
+
+DCTile::DCTile(DCLayerTree* aDCLayerTree) : mDCLayerTree(aDCLayerTree) {}
+
+DCTile::~DCTile() {}
+
+bool DCTile::Initialize(int aX, int aY, wr::DeviceIntSize aSize,
+                        bool aIsVirtualSurface, bool aIsOpaque,
+                        RefPtr<IDCompositionVisual2> mSurfaceVisual) {
+  if (aSize.width <= 0 || aSize.height <= 0) {
+    return false;
+  }
+
+  mSize = aSize;
+  mIsOpaque = aIsOpaque;
+  mIsVirtualSurface = aIsVirtualSurface;
+  mNeedsFullDraw = !aIsVirtualSurface;
+
+  if (aIsVirtualSurface) {
+    // Initially, the entire tile is considered valid, unless it is set by
+    // the SetTileProperties method.
+    mValidRect.x = 0;
+    mValidRect.y = 0;
+    mValidRect.width = aSize.width;
+    mValidRect.height = aSize.height;
+  } else {
+    HRESULT hr;
+    const auto dCompDevice = mDCLayerTree->GetCompositionDevice();
+    // Create the visual and put it in the tree under the surface visual
+    hr = dCompDevice->CreateVisual(getter_AddRefs(mVisual));
+    if (FAILED(hr)) {
+      gfxCriticalNote << "Failed to CreateVisual for DCTile: " << gfx::hexa(hr);
+      return false;
+    }
+    mSurfaceVisual->AddVisual(mVisual, false, nullptr);
+    // Position the tile relative to the surface visual
+    mVisual->SetOffsetX(aX * aSize.width);
+    mVisual->SetOffsetY(aY * aSize.height);
+    // Clip the visual so it doesn't show anything until we update it
+    D2D_RECT_F clip = {0, 0, 0, 0};
+    mVisual->SetClip(clip);
+    // Create the underlying pixel buffer.
+    mCompositionSurface = CreateCompositionSurface(aSize, aIsOpaque);
+    if (!mCompositionSurface) {
+      return false;
+    }
+    hr = mVisual->SetContent(mCompositionSurface);
+    if (FAILED(hr)) {
+      gfxCriticalNote << "Failed to SetContent for DCTile: " << gfx::hexa(hr);
+      return false;
+    }
+  }
+
+  return true;
+}
+
+RefPtr<IDCompositionSurface> DCTile::CreateCompositionSurface(
+    wr::DeviceIntSize aSize, bool aIsOpaque) {
+  HRESULT hr;
+  const auto dCompDevice = mDCLayerTree->GetCompositionDevice();
+  const auto alphaMode =
+      aIsOpaque ? DXGI_ALPHA_MODE_IGNORE : DXGI_ALPHA_MODE_PREMULTIPLIED;
+  RefPtr<IDCompositionSurface> compositionSurface;
+
+  hr = dCompDevice->CreateSurface(aSize.width, aSize.height,
+                                  DXGI_FORMAT_R8G8B8A8_UNORM, alphaMode,
+                                  getter_AddRefs(compositionSurface));
+  if (FAILED(hr)) {
+    gfxCriticalNote << "Failed to CreateSurface for DCTile: " << gfx::hexa(hr);
+    return nullptr;
+  }
+  return compositionSurface;
+}
+
+RefPtr<IDCompositionSurface> DCTile::Bind(wr::DeviceIntRect aValidRect) {
+  if (mVisual != nullptr) {
+    // Tile owns a visual, set the size of the visual to match the portion we
+    // want to be visible.
+    D2D_RECT_F clip_rect;
+    clip_rect.left = aValidRect.min.x;
+    clip_rect.top = aValidRect.min.y;
+    clip_rect.right = aValidRect.max.x;
+    clip_rect.bottom = aValidRect.max.y;
+    mVisual->SetClip(clip_rect);
+  }
+  return mCompositionSurface;
+}
+
+GLuint DCLayerTree::CreateEGLSurfaceForCompositionSurface(
+    wr::DeviceIntRect aDirtyRect, wr::DeviceIntPoint* aOffset,
+    RefPtr<IDCompositionSurface> aCompositionSurface,
+    wr::DeviceIntPoint aSurfaceOffset) {
+  MOZ_ASSERT(aCompositionSurface.get());
+
+  HRESULT hr;
+  const auto gl = GetGLContext();
+  RefPtr<ID3D11Texture2D> backBuf;
+  POINT offset;
+
+  RECT update_rect;
+  update_rect.left = aSurfaceOffset.x + aDirtyRect.min.x;
+  update_rect.top = aSurfaceOffset.y + aDirtyRect.min.y;
+  update_rect.right = aSurfaceOffset.x + aDirtyRect.max.x;
+  update_rect.bottom = aSurfaceOffset.y + aDirtyRect.max.y;
+  hr = aCompositionSurface->BeginDraw(&update_rect, __uuidof(ID3D11Texture2D),
+                                      (void**)getter_AddRefs(backBuf), &offset);
+
+  if (FAILED(hr)) {
+    LayoutDeviceIntRect rect = widget::WinUtils::ToIntRect(update_rect);
+
+    gfxCriticalNote << "DCompositionSurface::BeginDraw failed: "
+                    << gfx::hexa(hr) << " " << rect;
+    RenderThread::Get()->HandleWebRenderError(WebRenderError::BEGIN_DRAW);
+    return false;
+  }
+
+  // DC includes the origin of the dirty / update rect in the draw offset,
+  // undo that here since WR expects it to be an absolute offset.
+  offset.x -= aDirtyRect.min.x;
+  offset.y -= aDirtyRect.min.y;
+
+  D3D11_TEXTURE2D_DESC desc;
+  backBuf->GetDesc(&desc);
+
+  const auto& gle = gl::GLContextEGL::Cast(gl);
+  const auto& egl = gle->mEgl;
+
+  const auto buffer = reinterpret_cast<EGLClientBuffer>(backBuf.get());
+
+  // Construct an EGLImage wrapper around the D3D texture for ANGLE.
+  const EGLint attribs[] = {LOCAL_EGL_NONE};
+  mEGLImage = egl->fCreateImage(EGL_NO_CONTEXT, LOCAL_EGL_D3D11_TEXTURE_ANGLE,
+                                buffer, attribs);
+
+  // Get the current FBO and RBO id, so we can restore them later
+  GLint currentFboId, currentRboId;
+  gl->fGetIntegerv(LOCAL_GL_DRAW_FRAMEBUFFER_BINDING, &currentFboId);
+  gl->fGetIntegerv(LOCAL_GL_RENDERBUFFER_BINDING, &currentRboId);
+
+  // Create a render buffer object that is backed by the EGL image.
+  gl->fGenRenderbuffers(1, &mColorRBO);
+  gl->fBindRenderbuffer(LOCAL_GL_RENDERBUFFER, mColorRBO);
+  gl->fEGLImageTargetRenderbufferStorage(LOCAL_GL_RENDERBUFFER, mEGLImage);
+
+  // Get or create an FBO for the specified dimensions
+  GLuint fboId = GetOrCreateFbo(desc.Width, desc.Height);
+
+  // Attach the new renderbuffer to the FBO
+  gl->fBindFramebuffer(LOCAL_GL_DRAW_FRAMEBUFFER, fboId);
+  gl->fFramebufferRenderbuffer(LOCAL_GL_DRAW_FRAMEBUFFER,
+                               LOCAL_GL_COLOR_ATTACHMENT0,
+                               LOCAL_GL_RENDERBUFFER, mColorRBO);
+
+  // Restore previous FBO and RBO bindings
+  gl->fBindFramebuffer(LOCAL_GL_DRAW_FRAMEBUFFER, currentFboId);
+  gl->fBindRenderbuffer(LOCAL_GL_RENDERBUFFER, currentRboId);
+
+  aOffset->x = offset.x;
+  aOffset->y = offset.y;
+
+  return fboId;
+}
+
+void DCLayerTree::DestroyEGLSurface() {
+  const auto gl = GetGLContext();
+
+  if (mColorRBO) {
+    gl->fDeleteRenderbuffers(1, &mColorRBO);
+    mColorRBO = 0;
+  }
+
+  if (mEGLImage) {
+    const auto& gle = gl::GLContextEGL::Cast(gl);
+    const auto& egl = gle->mEgl;
+    egl->fDestroyImage(mEGLImage);
+    mEGLImage = EGL_NO_IMAGE;
+  }
+}
+
+// -
+
+color::ColorProfileDesc DCLayerTree::QueryOutputColorProfile() {
+  // GPU process can't simply init gfxPlatform, (and we don't need most of it)
+  // but we do need gfxPlatform::GetCMSOutputProfile().
+  // So we steal what we need through the window:
+  const auto outputProfileData =
+      gfxWindowsPlatform::GetPlatformCMSOutputProfileData_Impl();
+
+  const auto qcmsProfile = qcms_profile_from_memory(
+      outputProfileData.Elements(), outputProfileData.Length());
+  const auto release = MakeScopeExit([&]() {
+    if (qcmsProfile) {
+      qcms_profile_release(qcmsProfile);
+    }
+  });
+
+  const bool print = gfxEnv::MOZ_GL_SPEW();
+
+  const auto ret = [&]() {
+    if (qcmsProfile) {
+      return color::ColorProfileDesc::From(*qcmsProfile);
+    }
+    if (print) {
+      printf_stderr(
+          "Missing or failed to load display color profile, defaulting to "
+          "sRGB.\n");
+    }
+    const auto MISSING_PROFILE_DEFAULT_SPACE = color::ColorspaceDesc{
+        color::Chromaticities::Srgb(),
+        color::PiecewiseGammaDesc::Srgb(),
+    };
+    return color::ColorProfileDesc::From(MISSING_PROFILE_DEFAULT_SPACE);
+  }();
+
+  if (print) {
+    const auto gammaGuess = color::GuessGamma(ret.linearFromTf.r);
+    printf_stderr(
+        "Display profile:\n"
+        "  Approx Gamma: %f\n"
+        "  XYZ-D65 Red  : %f, %f, %f\n"
+        "  XYZ-D65 Green: %f, %f, %f\n"
+        "  XYZ-D65 Blue : %f, %f, %f\n",
+        gammaGuess, ret.xyzd65FromLinearRgb.at(0, 0),
+        ret.xyzd65FromLinearRgb.at(0, 1), ret.xyzd65FromLinearRgb.at(0, 2),
+
+        ret.xyzd65FromLinearRgb.at(1, 0), ret.xyzd65FromLinearRgb.at(1, 1),
+        ret.xyzd65FromLinearRgb.at(1, 2),
+
+        ret.xyzd65FromLinearRgb.at(2, 0), ret.xyzd65FromLinearRgb.at(2, 1),
+        ret.xyzd65FromLinearRgb.at(2, 2));
+  }
+
+  return ret;
+}
+
+inline D2D1_MATRIX_5X4_F to_D2D1_MATRIX_5X4_F(const color::mat4& m) {
+  return D2D1_MATRIX_5X4_F{{{
+      m.rows[0][0],
+      m.rows[1][0],
+      m.rows[2][0],
+      m.rows[3][0],
+      m.rows[0][1],
+      m.rows[1][1],
+      m.rows[2][1],
+      m.rows[3][1],
+      m.rows[0][2],
+      m.rows[1][2],
+      m.rows[2][2],
+      m.rows[3][2],
+      m.rows[0][3],
+      m.rows[1][3],
+      m.rows[2][3],
+      m.rows[3][3],
+      0,
+      0,
+      0,
+      0,
+  }}};
+}
+
+ColorManagementChain ColorManagementChain::From(
+    IDCompositionDevice3& dcomp,
+    const color::ColorProfileConversionDesc& conv) {
+  auto ret = ColorManagementChain{};
+
+#if !defined(MOZ_MINGW_DCOMP_H_INCOMPLETE)
+
+  const auto Append = [&](const RefPtr<IDCompositionFilterEffect>& afterLast) {
+    if (ret.last) {
+      afterLast->SetInput(0, ret.last, 0);
+    }
+    ret.last = afterLast;
+  };
+
+  const auto MaybeAppendColorMatrix = [&](const color::mat4& m) {
+    RefPtr<IDCompositionColorMatrixEffect> e;
+    if (approx(m, color::mat4::Identity())) return e;
+    dcomp.CreateColorMatrixEffect(getter_AddRefs(e));
+    MOZ_ASSERT(e);
+    if (!e) return e;
+    e->SetMatrix(to_D2D1_MATRIX_5X4_F(m));
+    Append(e);
+    return e;
+  };
+  const auto MaybeAppendTableTransfer = [&](const color::RgbTransferTables& t) {
+    RefPtr<IDCompositionTableTransferEffect> e;
+    if (!t.r.size() && !t.g.size() && !t.b.size()) return e;
+    dcomp.CreateTableTransferEffect(getter_AddRefs(e));
+    MOZ_ASSERT(e);
+    if (!e) return e;
+    e->SetRedTable(t.r.data(), t.r.size());
+    e->SetGreenTable(t.g.data(), t.g.size());
+    e->SetBlueTable(t.b.data(), t.b.size());
+    Append(e);
+    return e;
+  };
+
+  ret.srcRgbFromSrcYuv = MaybeAppendColorMatrix(conv.srcRgbFromSrcYuv);
+  ret.srcLinearFromSrcTf = MaybeAppendTableTransfer(conv.srcLinearFromSrcTf);
+  ret.dstLinearFromSrcLinear =
+      MaybeAppendColorMatrix(color::mat4(conv.dstLinearFromSrcLinear));
+  ret.dstTfFromDstLinear = MaybeAppendTableTransfer(conv.dstTfFromDstLinear);
+
+#endif  // !defined(MOZ_MINGW_DCOMP_H_INCOMPLETE)
+
+  return ret;
+}
+
+ColorManagementChain::~ColorManagementChain() = default;
+
+}  // namespace wr
+}  // namespace mozilla
+
+#undef LOG_H