void
UseTileTexture(CompositableTextureHostRef& aTexture,
CompositableTextureSourceRef& aTextureSource,
const IntRect& aUpdateRect,
Compositor* aCompositor)
{
MOZ_ASSERT(aTexture);
if (!aTexture) {
return;
}
if (aCompositor) {
aTexture->SetCompositor(aCompositor);
}
if (!aUpdateRect.IsEmpty()) {
#ifdef MOZ_GFX_OPTIMIZE_MOBILE
aTexture->Updated(nullptr);
#else
// We possibly upload the entire texture contents here. This is a purposeful
// decision, as sub-image upload can often be slow and/or unreliable, but
// we may want to reevaluate this in the future.
// For !HasInternalBuffer() textures, this is likely a no-op.
nsIntRegion region = aUpdateRect;
aTexture->Updated(®ion);
#endif
}
aTexture->PrepareTextureSource(aTextureSource);
}
TiledLayerBufferComposite::TiledLayerBufferComposite(ISurfaceAllocator* aAllocator,
const SurfaceDescriptorTiles& aDescriptor,
const nsIntRegion& aOldPaintedRegion,
Compositor* aCompositor)
{
mIsValid = true;
mHasDoubleBufferedTiles = false;
mValidRegion = aDescriptor.validRegion();
mPaintedRegion = aDescriptor.paintedRegion();
mRetainedWidth = aDescriptor.retainedWidth();
mRetainedHeight = aDescriptor.retainedHeight();
mResolution = aDescriptor.resolution();
mFrameResolution = CSSToParentLayerScale(aDescriptor.frameResolution());
if (mResolution == 0 || IsNaN(mResolution)) {
// There are divisions by mResolution so this protects the compositor process
// against malicious content processes and fuzzing.
mIsValid = false;
return;
}
// Combine any valid content that wasn't already uploaded
nsIntRegion oldPaintedRegion(aOldPaintedRegion);
oldPaintedRegion.And(oldPaintedRegion, mValidRegion);
mPaintedRegion.Or(mPaintedRegion, oldPaintedRegion);
bool isSameProcess = aAllocator->IsSameProcess();
const InfallibleTArray<TileDescriptor>& tiles = aDescriptor.tiles();
for(size_t i = 0; i < tiles.Length(); i++) {
CompositableTextureHostRef texture;
CompositableTextureHostRef textureOnWhite;
const TileDescriptor& tileDesc = tiles[i];
switch (tileDesc.type()) {
case TileDescriptor::TTexturedTileDescriptor : {
texture = TextureHost::AsTextureHost(tileDesc.get_TexturedTileDescriptor().textureParent());
MaybeTexture onWhite = tileDesc.get_TexturedTileDescriptor().textureOnWhite();
if (onWhite.type() == MaybeTexture::TPTextureParent) {
textureOnWhite = TextureHost::AsTextureHost(onWhite.get_PTextureParent());
}
const TileLock& ipcLock = tileDesc.get_TexturedTileDescriptor().sharedLock();
nsRefPtr<gfxSharedReadLock> sharedLock;
if (ipcLock.type() == TileLock::TShmemSection) {
sharedLock = gfxShmSharedReadLock::Open(aAllocator, ipcLock.get_ShmemSection());
} else {
if (!isSameProcess) {
// Trying to use a memory based lock instead of a shmem based one in
// the cross-process case is a bad security violation.
NS_ERROR("A client process may be trying to peek at the host's address space!");
// This tells the TiledContentHost that deserialization failed so that
// it can propagate the error.
mIsValid = false;
mRetainedTiles.Clear();
return;
}
sharedLock = reinterpret_cast<gfxMemorySharedReadLock*>(ipcLock.get_uintptr_t());
if (sharedLock) {
// The corresponding AddRef is in TiledClient::GetTileDescriptor
sharedLock.get()->Release();
}
}
CompositableTextureSourceRef textureSource;
CompositableTextureSourceRef textureSourceOnWhite;
if (texture) {
texture->SetCompositor(aCompositor);
texture->PrepareTextureSource(textureSource);
}
if (textureOnWhite) {
textureOnWhite->SetCompositor(aCompositor);
textureOnWhite->PrepareTextureSource(textureSourceOnWhite);
}
mRetainedTiles.AppendElement(TileHost(sharedLock,
texture.get(),
textureOnWhite.get(),
textureSource.get(),
textureSourceOnWhite.get()));
break;
}
default:
NS_WARNING("Unrecognised tile descriptor type");
// Fall through
case TileDescriptor::TPlaceholderTileDescriptor :
mRetainedTiles.AppendElement(GetPlaceholderTile());
break;
}
if (texture && !texture->HasInternalBuffer()) {
mHasDoubleBufferedTiles = true;
}
}
}
