示例#1
0
Mat3
SubRectMat3(const gfx::IntRect& subrect, const gfx::IntSize& size)
{
    return SubRectMat3(float(subrect.X()) / size.width,
                       float(subrect.Y()) / size.height,
                       float(subrect.Width()) / size.width,
                       float(subrect.Height()) / size.height);
}
示例#2
0
TemporaryRef<CompositingRenderTarget>
CompositorD3D11::CreateRenderTargetFromSource(const gfx::IntRect &aRect,
                                              const CompositingRenderTarget* aSource,
                                              const gfx::IntPoint &aSourcePoint)
{
  MOZ_ASSERT(aRect.width != 0 && aRect.height != 0);

  if (aRect.width * aRect.height == 0) {
    return nullptr;
  }

  CD3D11_TEXTURE2D_DESC desc(DXGI_FORMAT_B8G8R8A8_UNORM,
                             aRect.width, aRect.height, 1, 1,
                             D3D11_BIND_SHADER_RESOURCE | D3D11_BIND_RENDER_TARGET);

  RefPtr<ID3D11Texture2D> texture;
  HRESULT hr = mDevice->CreateTexture2D(&desc, nullptr, byRef(texture));
  NS_ASSERTION(texture, "Could not create texture");
  if (Failed(hr) || !texture) {
    return nullptr;
  }

  if (aSource) {
    const CompositingRenderTargetD3D11* sourceD3D11 =
      static_cast<const CompositingRenderTargetD3D11*>(aSource);

    D3D11_BOX srcBox;
    srcBox.left = aSourcePoint.x;
    srcBox.top = aSourcePoint.y;
    srcBox.front = 0;
    srcBox.right = aSourcePoint.x + aRect.width;
    srcBox.bottom = aSourcePoint.y + aRect.height;
    srcBox.back = 1;

    const IntSize& srcSize = sourceD3D11->GetSize();
    MOZ_ASSERT(srcSize.width >= 0 && srcSize.height >= 0,
               "render targets should have nonnegative sizes");
    if (srcBox.left >= 0 &&
        srcBox.top >= 0 &&
        srcBox.left < srcBox.right &&
        srcBox.top < srcBox.bottom &&
        srcBox.right <= static_cast<uint32_t>(srcSize.width) &&
        srcBox.bottom <= static_cast<uint32_t>(srcSize.height)) {
      mContext->CopySubresourceRegion(texture, 0,
                                      0, 0, 0,
                                      sourceD3D11->GetD3D11Texture(), 0,
                                      &srcBox);
    } else {
      NS_WARNING("Could not copy render target - source rect out of bounds");
    }
  }

  RefPtr<CompositingRenderTargetD3D11> rt =
    new CompositingRenderTargetD3D11(texture, aRect.TopLeft());
  rt->SetSize(aRect.Size());

  return rt;
}
TemporaryRef<CompositingRenderTarget>
CompositorD3D9::CreateRenderTargetFromSource(const gfx::IntRect &aRect,
                                             const CompositingRenderTarget *aSource)
{
  RefPtr<IDirect3DTexture9> texture;
  HRESULT hr = device()->CreateTexture(aRect.width, aRect.height, 1,
                                       D3DUSAGE_RENDERTARGET, D3DFMT_A8R8G8B8,
                                       D3DPOOL_DEFAULT, byRef(texture),
                                       NULL);
  if (FAILED(hr)) {
    ReportFailure(NS_LITERAL_CSTRING("CompositorD3D9::CreateRenderTargetFromSource: Failed to create texture"),
                  hr);
    return nullptr;
  }

  if (aSource) {
    nsRefPtr<IDirect3DSurface9> sourceSurface =
      static_cast<const CompositingRenderTargetD3D9*>(aSource)->GetD3D9Surface();

    nsRefPtr<IDirect3DSurface9> destSurface;
    hr = texture->GetSurfaceLevel(0, getter_AddRefs(destSurface));
    if (FAILED(hr)) {
      NS_WARNING("Failed to get texture surface level for dest.");
    }

    if (sourceSurface && destSurface) {
      RECT sourceRect;
      sourceRect.left = aRect.x;
      sourceRect.right = aRect.XMost();
      sourceRect.top = aRect.y;
      sourceRect.bottom = aRect.YMost();
      RECT destRect;
      destRect.left = 0;
      destRect.right = aRect.width;
      destRect.top = 0;
      destRect.bottom = aRect.height;

      // copy the source to the dest
      hr = device()->StretchRect(sourceSurface,
                                 &sourceRect,
                                 destSurface,
                                 &destRect,
                                 D3DTEXF_NONE);
      if (FAILED(hr)) {
        ReportFailure(NS_LITERAL_CSTRING("CompositorD3D9::CreateRenderTargetFromSource: Failed to update texture"),
                      hr);
      }
    }
  }

  RefPtr<CompositingRenderTargetD3D9> rt =
    new CompositingRenderTargetD3D9(texture,
                                    INIT_MODE_NONE,
                                    IntSize(aRect.width, aRect.height));

  return rt;
}
示例#4
0
CompositingRenderTargetD3D9::CompositingRenderTargetD3D9(IDirect3DSurface9* aSurface,
                                                         SurfaceInitMode aInit,
                                                         const gfx::IntRect& aRect)
  : CompositingRenderTarget(aRect.TopLeft())
  , mSurface(aSurface)
  , mInitMode(aInit)
  , mInitialized(false)
{
  MOZ_COUNT_CTOR(CompositingRenderTargetD3D9);
  MOZ_ASSERT(mSurface);
  TextureSourceD3D9::SetSize(aRect.Size());
}
示例#5
0
Mat3
SubRectMat3(const gfx::IntRect& bigSubrect, const gfx::IntSize& smallSize,
            const gfx::IntSize& divisors)
{
    const float x = float(bigSubrect.X()) / divisors.width;
    const float y = float(bigSubrect.Y()) / divisors.height;
    const float w = float(bigSubrect.Width()) / divisors.width;
    const float h = float(bigSubrect.Height()) / divisors.height;
    return SubRectMat3(x / smallSize.width,
                       y / smallSize.height,
                       w / smallSize.width,
                       h / smallSize.height);
}
示例#6
0
CompositingRenderTargetD3D9::CompositingRenderTargetD3D9(IDirect3DTexture9* aTexture,
                                                         SurfaceInitMode aInit,
                                                         const gfx::IntRect& aRect)
  : CompositingRenderTarget(aRect.TopLeft())
  , mInitMode(aInit)
  , mInitialized(false)
{
  MOZ_COUNT_CTOR(CompositingRenderTargetD3D9);
  MOZ_ASSERT(aTexture);

  mTexture = aTexture;
  HRESULT hr = mTexture->GetSurfaceLevel(0, getter_AddRefs(mSurface));
  NS_ASSERTION(mSurface, "Couldn't create surface for texture");
  TextureSourceD3D9::SetSize(aRect.Size());
}
示例#7
0
static void CalculatePluginClip(const gfx::IntRect& aBounds,
                                const nsTArray<gfx::IntRect>& aPluginClipRects,
                                const nsIntPoint& aContentOffset,
                                const nsIntRegion& aParentLayerVisibleRegion,
                                nsTArray<gfx::IntRect>& aResult,
                                gfx::IntRect& aVisibleBounds,
                                bool& aPluginIsVisible)
{
  aPluginIsVisible = true;
  // aBounds (content origin)
  nsIntRegion contentVisibleRegion(aBounds);
  // aPluginClipRects (plugin widget origin)
  for (uint32_t idx = 0; idx < aPluginClipRects.Length(); idx++) {
    gfx::IntRect rect = aPluginClipRects[idx];
    // shift to content origin
    rect.MoveBy(aBounds.x, aBounds.y);
    contentVisibleRegion.AndWith(rect);
  }
  // apply layers clip (window origin)
  nsIntRegion region = aParentLayerVisibleRegion;
  region.MoveBy(-aContentOffset.x, -aContentOffset.y);
  contentVisibleRegion.AndWith(region);
  if (contentVisibleRegion.IsEmpty()) {
    aPluginIsVisible = false;
    return;
  }
  // shift to plugin widget origin
  contentVisibleRegion.MoveBy(-aBounds.x, -aBounds.y);
  nsIntRegionRectIterator iter(contentVisibleRegion);
  for (const gfx::IntRect* rgnRect = iter.Next(); rgnRect; rgnRect = iter.Next()) {
    aResult.AppendElement(*rgnRect);
    aVisibleBounds.UnionRect(aVisibleBounds, *rgnRect);
  }
}
示例#8
0
TemporaryRef<CompositingRenderTarget>
CompositorD3D11::CreateRenderTargetFromSource(const gfx::IntRect &aRect,
                                              const CompositingRenderTarget* aSource)
{
  CD3D11_TEXTURE2D_DESC desc(DXGI_FORMAT_B8G8R8A8_UNORM,
                             aRect.width, aRect.height, 1, 1,
                             D3D11_BIND_SHADER_RESOURCE | D3D11_BIND_RENDER_TARGET);

  RefPtr<ID3D11Texture2D> texture;
  mDevice->CreateTexture2D(&desc, nullptr, byRef(texture));
  NS_ASSERTION(texture, "Could not create texture");
  if (!texture) {
    return nullptr;
  }

  if (aSource) {
    const CompositingRenderTargetD3D11* sourceD3D11 =
      static_cast<const CompositingRenderTargetD3D11*>(aSource);

    D3D11_BOX srcBox;
    srcBox.left = aRect.x;
    srcBox.top = aRect.y;
    srcBox.front = 0;
    srcBox.right = aRect.XMost();
    srcBox.bottom = aRect.YMost();
    srcBox.back = 0;

    const IntSize& srcSize = sourceD3D11->GetSize();
    if (srcBox.right <= srcSize.width &&
        srcBox.bottom <= srcSize.height) {
      mContext->CopySubresourceRegion(texture, 0,
                                      0, 0, 0,
                                      sourceD3D11->GetD3D11Texture(), 0,
                                      &srcBox);
    } else {
      NS_WARNING("Could not copy render target - source rect out of bounds");
    }
  }

  RefPtr<CompositingRenderTargetD3D11> rt =
    new CompositingRenderTargetD3D11(texture);
  rt->SetSize(IntSize(aRect.width, aRect.height));

  return rt;
}
示例#9
0
gfx::IntRect
ComputeBackdropCopyRect(const gfx::Rect& aRect,
                        const gfx::IntRect& aClipRect,
                        const gfx::Matrix4x4& aTransform,
                        const gfx::IntRect& aRenderTargetRect,
                        gfx::Matrix4x4* aOutTransform,
                        gfx::Rect* aOutLayerQuad)
{
  // Compute the clip.
  IntPoint rtOffset = aRenderTargetRect.TopLeft();
  IntSize rtSize = aRenderTargetRect.Size();

  gfx::IntRect renderBounds(0, 0, rtSize.width, rtSize.height);
  renderBounds.IntersectRect(renderBounds, aClipRect);
  renderBounds.MoveBy(rtOffset);

  // Apply the layer transform.
  RectDouble dest = aTransform.TransformAndClipBounds(
    RectDouble(aRect.x, aRect.y, aRect.width, aRect.height),
    RectDouble(renderBounds.x, renderBounds.y, renderBounds.width, renderBounds.height));
  dest -= rtOffset;

  // Ensure we don't round out to -1, which trips up Direct3D.
  dest.IntersectRect(dest, RectDouble(0, 0, rtSize.width, rtSize.height));

  if (aOutLayerQuad) {
    *aOutLayerQuad = Rect(dest.x, dest.y, dest.width, dest.height);
  }

  // Round out to integer.
  IntRect result;
  dest.RoundOut();
  dest.ToIntRect(&result);

  // Create a transform from adjusted clip space to render target space,
  // translate it for the backdrop rect, then transform it into the backdrop's
  // uv-space.
  Matrix4x4 transform;
  transform.PostScale(rtSize.width, rtSize.height, 1.0);
  transform.PostTranslate(-result.x, -result.y, 0.0);
  transform.PostScale(1 / float(result.width), 1 / float(result.height), 1.0);
  *aOutTransform = transform;
  return result;
}
bool
BasicContainerLayer::ChildrenPartitionVisibleRegion(const gfx::IntRect& aInRect)
{
  Matrix transform;
  if (!GetEffectiveTransform().CanDraw2D(&transform) ||
      ThebesMatrix(transform).HasNonIntegerTranslation())
    return false;

  nsIntPoint offset(int32_t(transform._31), int32_t(transform._32));
  gfx::IntRect rect = aInRect.Intersect(GetEffectiveVisibleRegion().GetBounds() + offset);
  nsIntRegion covered;

  for (Layer* l = mFirstChild; l; l = l->GetNextSibling()) {
    if (ToData(l)->IsHidden())
      continue;

    Matrix childTransform;
    if (!l->GetEffectiveTransform().CanDraw2D(&childTransform) ||
        ThebesMatrix(childTransform).HasNonIntegerTranslation() ||
        l->GetEffectiveOpacity() != 1.0)
      return false;
    nsIntRegion childRegion = l->GetEffectiveVisibleRegion();
    childRegion.MoveBy(int32_t(childTransform._31), int32_t(childTransform._32));
    childRegion.And(childRegion, rect);
    if (l->GetClipRect()) {
      childRegion.And(childRegion, ParentLayerIntRect::ToUntyped(*l->GetClipRect()) + offset);
    }
    nsIntRegion intersection;
    intersection.And(covered, childRegion);
    if (!intersection.IsEmpty())
      return false;
    covered.Or(covered, childRegion);
  }

  return covered.Contains(rect);
}
示例#11
0
TemporaryRef<CompositingRenderTarget>
CompositorD3D11::CreateRenderTarget(const gfx::IntRect& aRect,
                                    SurfaceInitMode aInit)
{
  MOZ_ASSERT(aRect.width != 0 && aRect.height != 0);

  if (aRect.width * aRect.height == 0) {
    return nullptr;
  }

  CD3D11_TEXTURE2D_DESC desc(DXGI_FORMAT_B8G8R8A8_UNORM, aRect.width, aRect.height, 1, 1,
                             D3D11_BIND_SHADER_RESOURCE | D3D11_BIND_RENDER_TARGET);

  RefPtr<ID3D11Texture2D> texture;
  HRESULT hr = mDevice->CreateTexture2D(&desc, nullptr, byRef(texture));
  if (Failed(hr) || !texture) {
    return nullptr;
  }

  RefPtr<CompositingRenderTargetD3D11> rt = new CompositingRenderTargetD3D11(texture, aRect.TopLeft());
  rt->SetSize(IntSize(aRect.width, aRect.height));

  if (aInit == INIT_MODE_CLEAR) {
    FLOAT clear[] = { 0, 0, 0, 0 };
    mContext->ClearRenderTargetView(rt->mRTView, clear);
  }

  return rt;
}
void
DecomposeIntoNoRepeatTriangles(const gfx::IntRect& aTexCoordRect,
                               const gfx::IntSize& aTexSize,
                               RectTriangles& aRects,
                               bool aFlipY /* = false */)
{
    // normalize this
    gfx::IntRect tcr(aTexCoordRect);
    while (tcr.x >= aTexSize.width)
        tcr.x -= aTexSize.width;
    while (tcr.y >= aTexSize.height)
        tcr.y -= aTexSize.height;

    // Compute top left and bottom right tex coordinates
    GLfloat tl[2] =
        { GLfloat(tcr.x) / GLfloat(aTexSize.width),
          GLfloat(tcr.y) / GLfloat(aTexSize.height) };
    GLfloat br[2] =
        { GLfloat(tcr.XMost()) / GLfloat(aTexSize.width),
          GLfloat(tcr.YMost()) / GLfloat(aTexSize.height) };

    // then check if we wrap in either the x or y axis; if we do,
    // then also use fmod to figure out the "true" non-wrapping
    // texture coordinates.

    bool xwrap = false, ywrap = false;
    if (tcr.x < 0 || tcr.x > aTexSize.width ||
        tcr.XMost() < 0 || tcr.XMost() > aTexSize.width)
    {
        xwrap = true;
        tl[0] = WrapTexCoord(tl[0]);
        br[0] = WrapTexCoord(br[0]);
    }

    if (tcr.y < 0 || tcr.y > aTexSize.height ||
        tcr.YMost() < 0 || tcr.YMost() > aTexSize.height)
    {
        ywrap = true;
        tl[1] = WrapTexCoord(tl[1]);
        br[1] = WrapTexCoord(br[1]);
    }

    NS_ASSERTION(tl[0] >= 0.0f && tl[0] <= 1.0f &&
                 tl[1] >= 0.0f && tl[1] <= 1.0f &&
                 br[0] >= 0.0f && br[0] <= 1.0f &&
                 br[1] >= 0.0f && br[1] <= 1.0f,
                 "Somehow generated invalid texture coordinates");

    // If xwrap is false, the texture will be sampled from tl[0]
    // .. br[0].  If xwrap is true, then it will be split into tl[0]
    // .. 1.0, and 0.0 .. br[0].  Same for the Y axis.  The
    // destination rectangle is also split appropriately, according
    // to the calculated xmid/ymid values.

    // There isn't a 1:1 mapping between tex coords and destination coords;
    // when computing midpoints, we have to take that into account.  We
    // need to map the texture coords, which are (in the wrap case):
    // |tl->1| and |0->br| to the |0->1| range of the vertex coords.  So
    // we have the length (1-tl)+(br) that needs to map into 0->1.
    // These are only valid if there is wrap involved, they won't be used
    // otherwise.
    GLfloat xlen = (1.0f - tl[0]) + br[0];
    GLfloat ylen = (1.0f - tl[1]) + br[1];

    NS_ASSERTION(!xwrap || xlen > 0.0f, "xlen isn't > 0, what's going on?");
    NS_ASSERTION(!ywrap || ylen > 0.0f, "ylen isn't > 0, what's going on?");
    NS_ASSERTION(aTexCoordRect.Width() <= aTexSize.width &&
                 aTexCoordRect.Height() <= aTexSize.height, "tex coord rect would cause tiling!");

    if (!xwrap && !ywrap) {
        aRects.addRect(0.0f, 0.0f,
                       1.0f, 1.0f,
                       tl[0], tl[1],
                       br[0], br[1],
                       aFlipY);
    } else if (!xwrap && ywrap) {
        GLfloat ymid = (1.0f - tl[1]) / ylen;
        aRects.addRect(0.0f, 0.0f,
                       1.0f, ymid,
                       tl[0], tl[1],
                       br[0], 1.0f,
                       aFlipY);
        aRects.addRect(0.0f, ymid,
                       1.0f, 1.0f,
                       tl[0], 0.0f,
                       br[0], br[1],
                       aFlipY);
    } else if (xwrap && !ywrap) {
        GLfloat xmid = (1.0f - tl[0]) / xlen;
        aRects.addRect(0.0f, 0.0f,
                       xmid, 1.0f,
                       tl[0], tl[1],
                       1.0f, br[1],
                       aFlipY);
        aRects.addRect(xmid, 0.0f,
                       1.0f, 1.0f,
                       0.0f, tl[1],
                       br[0], br[1],
                       aFlipY);
    } else {
        GLfloat xmid = (1.0f - tl[0]) / xlen;
        GLfloat ymid = (1.0f - tl[1]) / ylen;
        aRects.addRect(0.0f, 0.0f,
                       xmid, ymid,
                       tl[0], tl[1],
                       1.0f, 1.0f,
                       aFlipY);
        aRects.addRect(xmid, 0.0f,
                       1.0f, ymid,
                       0.0f, tl[1],
                       br[0], 1.0f,
                       aFlipY);
        aRects.addRect(0.0f, ymid,
                       xmid, 1.0f,
                       tl[0], 0.0f,
                       1.0f, br[1],
                       aFlipY);
        aRects.addRect(xmid, ymid,
                       1.0f, 1.0f,
                       0.0f, 0.0f,
                       br[0], br[1],
                       aFlipY);
    }
}
already_AddRefed<gfx::DrawTarget>
PersistentBufferProviderShared::BorrowDrawTarget(const gfx::IntRect& aPersistedRect)
{
  if (!mFwd->GetTextureForwarder()->IPCOpen()) {
    return nullptr;
  }

  MOZ_ASSERT(!mSnapshot);

  if (IsActivityTracked()) {
    mFwd->GetActiveResourceTracker().MarkUsed(this);
  } else {
    mFwd->GetActiveResourceTracker().AddObject(this);
  }

  if (mDrawTarget) {
    RefPtr<gfx::DrawTarget> dt(mDrawTarget);
    return dt.forget();
  }

  mFront = Nothing();

  auto previousBackBuffer = mBack;

  TextureClient* tex = GetTexture(mBack);

  // First try to reuse the current back buffer. If we can do that it means
  // we can skip copying its content to the new back buffer.
  if (tex && tex->IsReadLocked()) {
    // The back buffer is currently used by the compositor, we can't draw
    // into it.
    tex = nullptr;
  }

  if (!tex) {
    // Try to grab an already allocated texture if any is available.
    for (uint32_t i = 0; i < mTextures.length(); ++i) {
      if (!mTextures[i]->IsReadLocked()) {
        mBack = Some(i);
        tex = mTextures[i];
        break;
      }
    }
  }

  if (!tex) {
    // We have to allocate a new texture.
    if (mTextures.length() >= 4) {
      // We should never need to buffer that many textures, something's wrong.
      MOZ_ASSERT(false);
      // In theory we throttle the main thread when the compositor can't keep up,
      // so we shoud never get in a situation where we sent 4 textures to the
      // compositor and the latter as not released any of them.
      // This seems to happen, however, in some edge cases such as just after a
      // device reset (cf. Bug 1291163).
      // It would be pretty bad to keep piling textures up at this point so we
      // call NotifyInactive to remove some of our textures.
      NotifyInactive();
      // Give up now. The caller can fall-back to a non-shared buffer provider.
      return nullptr;
    }

    RefPtr<TextureClient> newTexture = TextureClient::CreateForDrawing(
      mFwd, mFormat, mSize,
      BackendSelector::Canvas,
      TextureFlags::DEFAULT,
      TextureAllocationFlags::ALLOC_DEFAULT
    );

    MOZ_ASSERT(newTexture);
    if (newTexture) {
      if (mTextures.append(newTexture)) {
        tex = newTexture;
        mBack = Some<uint32_t>(mTextures.length() - 1);
      }
    }
  }

  if (!tex || !tex->Lock(OpenMode::OPEN_READ_WRITE)) {
    return nullptr;
  }

  if (mBack != previousBackBuffer && !aPersistedRect.IsEmpty()) {
    TextureClient* previous = GetTexture(previousBackBuffer);
    if (previous && previous->Lock(OpenMode::OPEN_READ)) {
      DebugOnly<bool> success = previous->CopyToTextureClient(tex, &aPersistedRect, nullptr);
      MOZ_ASSERT(success);

      previous->Unlock();
    }
  }

  mDrawTarget = tex->BorrowDrawTarget();

  RefPtr<gfx::DrawTarget> dt(mDrawTarget);
  return dt.forget();
}
示例#14
0
void
CompositorD3D9::FinishMixBlend(const gfx::IntRect& aBackdropRect,
                               const gfx::Rect& aBackdropDest,
                               const gfx::Matrix4x4& aBackdropTransform,
                               RefPtr<IDirect3DTexture9> aBackdrop,
                               gfx::CompositionOp aBlendMode)
{
  HRESULT hr;

  RefPtr<IDirect3DTexture9> source =
    CreateTexture(aBackdropRect, mCurrentRT, aBackdropRect.TopLeft());
  if (!source) {
    return;
  }

  // Slow path - do everything in software. Unfortunately this requires
  // a lot of copying, since we have to readback the source and backdrop,
  // then upload the blended result, then blit it back.

  IDirect3DDevice9* d3d9Device = device();

  // Query geometry/format of the two surfaces.
  D3DSURFACE_DESC backdropDesc, sourceDesc;
  if (FAILED(aBackdrop->GetLevelDesc(0, &backdropDesc)) ||
      FAILED(source->GetLevelDesc(0, &sourceDesc)))
  {
    gfxCriticalNote << "Failed to query mix-blend texture descriptor";
    return;
  }

  MOZ_ASSERT(backdropDesc.Format == D3DFMT_A8R8G8B8);
  MOZ_ASSERT(sourceDesc.Format == D3DFMT_A8R8G8B8);

  // Acquire a temporary data surface for the backdrop texture.
  RefPtr<IDirect3DSurface9> backdropSurface = GetSurfaceOfTexture(aBackdrop);
  if (!backdropSurface) {
    return;
  }
  RefPtr<IDirect3DSurface9> tmpBackdrop =
    CreateDataSurfaceForTexture(d3d9Device, backdropSurface, backdropDesc);
  if (!tmpBackdrop) {
    return;
  }

  // New scope for locks and temporary surfaces.
  {
    // Acquire a temporary data surface for the source texture.
    RefPtr<IDirect3DSurface9> sourceSurface = GetSurfaceOfTexture(source);
    if (!sourceSurface) {
      return;
    }
    RefPtr<IDirect3DSurface9> tmpSource =
      CreateDataSurfaceForTexture(d3d9Device, sourceSurface, sourceDesc);
    if (!tmpSource) {
      return;
    }

    // Perform the readback and blend in software.
    AutoSurfaceLock backdropLock(tmpBackdrop);
    AutoSurfaceLock sourceLock(tmpSource, D3DLOCK_READONLY);
    if (!backdropLock.Okay() || !sourceLock.Okay()) {
      return;
    }

    RefPtr<DataSourceSurface> source = Factory::CreateWrappingDataSourceSurface(
      sourceLock.Bits(), sourceLock.Pitch(),
      gfx::IntSize(sourceDesc.Width, sourceDesc.Height),
      SurfaceFormat::B8G8R8A8);

    RefPtr<DrawTarget> dest = Factory::CreateDrawTargetForData(
      BackendType::CAIRO,
      backdropLock.Bits(),
      gfx::IntSize(backdropDesc.Width, backdropDesc.Height),
      backdropLock.Pitch(),
      SurfaceFormat::B8G8R8A8);

    // The backdrop rect is rounded out - account for any difference between
    // it and the actual destination.
    gfx::Rect destRect(
      aBackdropDest.x - aBackdropRect.x,
      aBackdropDest.y - aBackdropRect.y,
      aBackdropDest.width,
      aBackdropDest.height);

    dest->DrawSurface(
      source, destRect, destRect,
      gfx::DrawSurfaceOptions(),
      gfx::DrawOptions(1.0f, aBlendMode));
  }

  // Upload the new blended surface to the backdrop texture.
  d3d9Device->UpdateSurface(tmpBackdrop, nullptr, backdropSurface, nullptr);

  // Finally, drop in the new backdrop. We don't need to do another
  // DrawPrimitive() since the software blend will have included the
  // final OP_OVER step for us.
  RECT destRect = {
    aBackdropRect.x, aBackdropRect.y,
    aBackdropRect.XMost(), aBackdropRect.YMost()
  };
  hr = d3d9Device->StretchRect(backdropSurface,
                               nullptr,
                               mCurrentRT->GetD3D9Surface(),
                               &destRect,
                               D3DTEXF_NONE);
  if (FAILED(hr)) {
    gfxCriticalNote << "StretcRect with mix-blend failed " << hexa(hr);
  }
}
void
GLBlitTextureImageHelper::BlitTextureImage(TextureImage *aSrc, const gfx::IntRect& aSrcRect,
                                           TextureImage *aDst, const gfx::IntRect& aDstRect)
{
    GLContext *gl = mCompositor->gl();

    if (!aSrc || !aDst || aSrcRect.IsEmpty() || aDstRect.IsEmpty())
        return;

    int savedFb = 0;
    gl->fGetIntegerv(LOCAL_GL_FRAMEBUFFER_BINDING, &savedFb);

    ScopedGLState scopedScissorTestState(gl, LOCAL_GL_SCISSOR_TEST, false);
    ScopedGLState scopedBlendState(gl, LOCAL_GL_BLEND, false);

    // 2.0 means scale up by two
    float blitScaleX = float(aDstRect.width) / float(aSrcRect.width);
    float blitScaleY = float(aDstRect.height) / float(aSrcRect.height);

    // We start iterating over all destination tiles
    aDst->BeginBigImageIteration();
    do {
        // calculate portion of the tile that is going to be painted to
        gfx::IntRect dstSubRect;
        gfx::IntRect dstTextureRect = aDst->GetTileRect();
        dstSubRect.IntersectRect(aDstRect, dstTextureRect);

        // this tile is not part of the destination rectangle aDstRect
        if (dstSubRect.IsEmpty())
            continue;

        // (*) transform the rect of this tile into the rectangle defined by aSrcRect...
        gfx::IntRect dstInSrcRect(dstSubRect);
        dstInSrcRect.MoveBy(-aDstRect.TopLeft());
        // ...which might be of different size, hence scale accordingly
        dstInSrcRect.ScaleRoundOut(1.0f / blitScaleX, 1.0f / blitScaleY);
        dstInSrcRect.MoveBy(aSrcRect.TopLeft());

        SetBlitFramebufferForDestTexture(aDst->GetTextureID());
        UseBlitProgram();

        aSrc->BeginBigImageIteration();
        // now iterate over all tiles in the source Image...
        do {
            // calculate portion of the source tile that is in the source rect
            gfx::IntRect srcSubRect;
            gfx::IntRect srcTextureRect = aSrc->GetTileRect();
            srcSubRect.IntersectRect(aSrcRect, srcTextureRect);

            // this tile is not part of the source rect
            if (srcSubRect.IsEmpty()) {
                continue;
            }
            // calculate intersection of source rect with destination rect
            srcSubRect.IntersectRect(srcSubRect, dstInSrcRect);
            // this tile does not overlap the current destination tile
            if (srcSubRect.IsEmpty()) {
                continue;
            }
            // We now have the intersection of
            //     the current source tile
            // and the desired source rectangle
            // and the destination tile
            // and the desired destination rectange
            // in destination space.
            // We need to transform this back into destination space, inverting the transform from (*)
            gfx::IntRect srcSubInDstRect(srcSubRect);
            srcSubInDstRect.MoveBy(-aSrcRect.TopLeft());
            srcSubInDstRect.ScaleRoundOut(blitScaleX, blitScaleY);
            srcSubInDstRect.MoveBy(aDstRect.TopLeft());

            // we transform these rectangles to be relative to the current src and dst tiles, respectively
            gfx::IntSize srcSize = srcTextureRect.Size();
            gfx::IntSize dstSize = dstTextureRect.Size();
            srcSubRect.MoveBy(-srcTextureRect.x, -srcTextureRect.y);
            srcSubInDstRect.MoveBy(-dstTextureRect.x, -dstTextureRect.y);

            float dx0 = 2.0f * float(srcSubInDstRect.x) / float(dstSize.width) - 1.0f;
            float dy0 = 2.0f * float(srcSubInDstRect.y) / float(dstSize.height) - 1.0f;
            float dx1 = 2.0f * float(srcSubInDstRect.x + srcSubInDstRect.width) / float(dstSize.width) - 1.0f;
            float dy1 = 2.0f * float(srcSubInDstRect.y + srcSubInDstRect.height) / float(dstSize.height) - 1.0f;
            ScopedViewportRect autoViewportRect(gl, 0, 0, dstSize.width, dstSize.height);

            RectTriangles rects;

            gfx::IntSize realTexSize = srcSize;
            if (!CanUploadNonPowerOfTwo(gl)) {
                realTexSize = gfx::IntSize(RoundUpPow2(srcSize.width),
                                           RoundUpPow2(srcSize.height));
            }

            if (aSrc->GetWrapMode() == LOCAL_GL_REPEAT) {
                rects.addRect(/* dest rectangle */
                        dx0, dy0, dx1, dy1,
                        /* tex coords */
                        srcSubRect.x / float(realTexSize.width),
                        srcSubRect.y / float(realTexSize.height),
                        srcSubRect.XMost() / float(realTexSize.width),
                        srcSubRect.YMost() / float(realTexSize.height));
            } else {
                DecomposeIntoNoRepeatTriangles(srcSubRect, realTexSize, rects);

                // now put the coords into the d[xy]0 .. d[xy]1 coordinate space
                // from the 0..1 that it comes out of decompose
                InfallibleTArray<RectTriangles::coord>& coords = rects.vertCoords();

                for (unsigned int i = 0; i < coords.Length(); ++i) {
                    coords[i].x = (coords[i].x * (dx1 - dx0)) + dx0;
                    coords[i].y = (coords[i].y * (dy1 - dy0)) + dy0;
                }
            }

            ScopedBindTextureUnit autoTexUnit(gl, LOCAL_GL_TEXTURE0);
            ScopedBindTexture autoTex(gl, aSrc->GetTextureID());
            ScopedVertexAttribPointer autoAttrib0(gl, 0, 2, LOCAL_GL_FLOAT, LOCAL_GL_FALSE, 0, 0, rects.vertCoords().Elements());
            ScopedVertexAttribPointer autoAttrib1(gl, 1, 2, LOCAL_GL_FLOAT, LOCAL_GL_FALSE, 0, 0, rects.texCoords().Elements());

            gl->fDrawArrays(LOCAL_GL_TRIANGLES, 0, rects.elements());

        } while (aSrc->NextTile());
    } while (aDst->NextTile());

    // unbind the previous texture from the framebuffer
    SetBlitFramebufferForDestTexture(0);

    gl->fBindFramebuffer(LOCAL_GL_FRAMEBUFFER, savedFb);
}