gecko-dev/gfx/layers/composite/TiledContentHost.cpp

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/* -*- Mode: C++; tab-width: 20; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* 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 "TiledContentHost.h"
#include "PaintedLayerComposite.h" // for PaintedLayerComposite
#include "mozilla/gfx/BaseSize.h" // for BaseSize
#include "mozilla/gfx/Matrix.h" // for Matrix4x4
#include "mozilla/layers/Compositor.h" // for Compositor
#include "mozilla/layers/Effects.h" // for TexturedEffect, Effect, etc
#include "mozilla/layers/LayerMetricsWrapper.h" // for LayerMetricsWrapper
#include "mozilla/layers/TextureHostOGL.h" // for TextureHostOGL
#include "nsAString.h"
#include "nsDebug.h" // for NS_WARNING
#include "nsPoint.h" // for IntPoint
#include "nsPrintfCString.h" // for nsPrintfCString
#include "nsRect.h" // for IntRect
#include "nsSize.h" // for nsIntSize
#include "mozilla/layers/TiledContentClient.h"
class gfxReusableSurfaceWrapper;
namespace mozilla {
using namespace gfx;
namespace layers {
class Layer;
TiledLayerBufferComposite::TiledLayerBufferComposite()
: mFrameResolution()
, mHasDoubleBufferedTiles(false)
, mIsValid(false)
{}
/* static */ void
TiledLayerBufferComposite::RecycleCallback(TextureHost* textureHost, void* aClosure)
{
textureHost->CompositorRecycle();
}
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 = CSSToParentLayerScale2D(aDescriptor.frameXResolution(),
aDescriptor.frameYResolution());
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;
}
}
}
void
TiledLayerBufferComposite::ReadUnlock()
{
if (!IsValid()) {
return;
}
for (size_t i = 0; i < mRetainedTiles.Length(); i++) {
mRetainedTiles[i].ReadUnlock();
}
}
void
TiledLayerBufferComposite::ReleaseTextureHosts()
{
if (!IsValid()) {
return;
}
for (size_t i = 0; i < mRetainedTiles.Length(); i++) {
mRetainedTiles[i].mTextureHost = nullptr;
mRetainedTiles[i].mTextureHostOnWhite = nullptr;
mRetainedTiles[i].mTextureSource = nullptr;
mRetainedTiles[i].mTextureSourceOnWhite = nullptr;
}
}
void
TiledLayerBufferComposite::Upload()
{
if(!IsValid()) {
return;
}
// The TextureClients were created with the TextureFlags::IMMEDIATE_UPLOAD flag,
// so calling Update on all the texture hosts will perform the texture upload.
Update(mValidRegion, mPaintedRegion);
ClearPaintedRegion();
}
TileHost
TiledLayerBufferComposite::ValidateTile(TileHost aTile,
const IntPoint& aTileOrigin,
const nsIntRegion& aDirtyRect)
{
if (aTile.IsPlaceholderTile()) {
NS_WARNING("Placeholder tile encountered in painted region");
return aTile;
}
#ifdef GFX_TILEDLAYER_PREF_WARNINGS
printf_stderr("Upload tile %i, %i\n", aTileOrigin.x, aTileOrigin.y);
long start = PR_IntervalNow();
#endif
MOZ_ASSERT(aTile.mTextureHost->GetFlags() & TextureFlags::IMMEDIATE_UPLOAD);
#ifdef MOZ_GFX_OPTIMIZE_MOBILE
MOZ_ASSERT(!aTile.mTextureHostOnWhite);
// 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.
aTile.mTextureHost->Updated(nullptr);
#else
nsIntRegion tileUpdated = aDirtyRect.MovedBy(-aTileOrigin);
aTile.mTextureHost->Updated(&tileUpdated);
if (aTile.mTextureHostOnWhite) {
aTile.mTextureHostOnWhite->Updated(&tileUpdated);
}
#endif
#ifdef GFX_TILEDLAYER_PREF_WARNINGS
if (PR_IntervalNow() - start > 1) {
printf_stderr("Tile Time to upload %i\n", PR_IntervalNow() - start);
}
#endif
return aTile;
}
void
TiledLayerBufferComposite::SetCompositor(Compositor* aCompositor)
{
MOZ_ASSERT(aCompositor);
if (!IsValid()) {
return;
}
for (size_t i = 0; i < mRetainedTiles.Length(); i++) {
if (mRetainedTiles[i].IsPlaceholderTile()) continue;
mRetainedTiles[i].mTextureHost->SetCompositor(aCompositor);
if (mRetainedTiles[i].mTextureHostOnWhite) {
mRetainedTiles[i].mTextureHostOnWhite->SetCompositor(aCompositor);
}
}
}
TiledContentHost::TiledContentHost(const TextureInfo& aTextureInfo)
: ContentHost(aTextureInfo)
, mTiledBuffer(TiledLayerBufferComposite())
, mLowPrecisionTiledBuffer(TiledLayerBufferComposite())
, mOldTiledBuffer(TiledLayerBufferComposite())
, mOldLowPrecisionTiledBuffer(TiledLayerBufferComposite())
, mPendingUpload(false)
, mPendingLowPrecisionUpload(false)
{
MOZ_COUNT_CTOR(TiledContentHost);
}
TiledContentHost::~TiledContentHost()
{
MOZ_COUNT_DTOR(TiledContentHost);
// Unlock any buffers that may still be locked. If we have a pending upload,
// we will need to unlock the buffer that was about to be uploaded.
// If a buffer that was being composited had double-buffered tiles, we will
// need to unlock that buffer too.
if (mPendingUpload) {
mTiledBuffer.ReadUnlock();
if (mOldTiledBuffer.HasDoubleBufferedTiles()) {
mOldTiledBuffer.ReadUnlock();
}
} else if (mTiledBuffer.HasDoubleBufferedTiles()) {
mTiledBuffer.ReadUnlock();
}
if (mPendingLowPrecisionUpload) {
mLowPrecisionTiledBuffer.ReadUnlock();
if (mOldLowPrecisionTiledBuffer.HasDoubleBufferedTiles()) {
mOldLowPrecisionTiledBuffer.ReadUnlock();
}
} else if (mLowPrecisionTiledBuffer.HasDoubleBufferedTiles()) {
mLowPrecisionTiledBuffer.ReadUnlock();
}
}
void
TiledContentHost::Attach(Layer* aLayer,
Compositor* aCompositor,
AttachFlags aFlags /* = NO_FLAGS */)
{
CompositableHost::Attach(aLayer, aCompositor, aFlags);
}
void
TiledContentHost::Detach(Layer* aLayer,
AttachFlags aFlags /* = NO_FLAGS */)
{
if (!mKeepAttached || aLayer == mLayer || aFlags & FORCE_DETACH) {
// Unlock any buffers that may still be locked. If we have a pending upload,
// we will need to unlock the buffer that was about to be uploaded.
// If a buffer that was being composited had double-buffered tiles, we will
// need to unlock that buffer too.
if (mPendingUpload) {
mTiledBuffer.ReadUnlock();
if (mOldTiledBuffer.HasDoubleBufferedTiles()) {
mOldTiledBuffer.ReadUnlock();
}
} else if (mTiledBuffer.HasDoubleBufferedTiles()) {
mTiledBuffer.ReadUnlock();
}
if (mPendingLowPrecisionUpload) {
mLowPrecisionTiledBuffer.ReadUnlock();
if (mOldLowPrecisionTiledBuffer.HasDoubleBufferedTiles()) {
mOldLowPrecisionTiledBuffer.ReadUnlock();
}
} else if (mLowPrecisionTiledBuffer.HasDoubleBufferedTiles()) {
mLowPrecisionTiledBuffer.ReadUnlock();
}
mTiledBuffer = TiledLayerBufferComposite();
mLowPrecisionTiledBuffer = TiledLayerBufferComposite();
mOldTiledBuffer = TiledLayerBufferComposite();
mOldLowPrecisionTiledBuffer = TiledLayerBufferComposite();
}
CompositableHost::Detach(aLayer,aFlags);
}
bool
TiledContentHost::UseTiledLayerBuffer(ISurfaceAllocator* aAllocator,
const SurfaceDescriptorTiles& aTiledDescriptor)
{
if (aTiledDescriptor.resolution() < 1) {
if (mPendingLowPrecisionUpload) {
mLowPrecisionTiledBuffer.ReadUnlock();
} else {
mPendingLowPrecisionUpload = true;
// If the old buffer has double-buffered tiles, hang onto it so we can
// unlock it after we've composited the new buffer.
// We only need to hang onto the locks, but not the textures.
// Releasing the textures here can help prevent a memory spike in the
// situation that the client starts rendering new content before we get
// to composite the new buffer.
if (mLowPrecisionTiledBuffer.HasDoubleBufferedTiles()) {
mOldLowPrecisionTiledBuffer = mLowPrecisionTiledBuffer;
mOldLowPrecisionTiledBuffer.ReleaseTextureHosts();
}
}
mLowPrecisionTiledBuffer =
TiledLayerBufferComposite(aAllocator,
aTiledDescriptor,
mLowPrecisionTiledBuffer.GetPaintedRegion(),
mCompositor);
if (!mLowPrecisionTiledBuffer.IsValid()) {
// Something bad happened. Stop here, return false (kills the child process),
// and do as little work as possible on the received data as it appears
// to be corrupted.
mPendingLowPrecisionUpload = false;
mPendingUpload = false;
return false;
}
} else {
if (mPendingUpload) {
mTiledBuffer.ReadUnlock();
} else {
mPendingUpload = true;
if (mTiledBuffer.HasDoubleBufferedTiles()) {
mOldTiledBuffer = mTiledBuffer;
mOldTiledBuffer.ReleaseTextureHosts();
}
}
mTiledBuffer = TiledLayerBufferComposite(aAllocator,
aTiledDescriptor,
mTiledBuffer.GetPaintedRegion(),
mCompositor);
if (!mTiledBuffer.IsValid()) {
// Something bad happened. Stop here, return false (kills the child process),
// and do as little work as possible on the received data as it appears
// to be corrupted.
mPendingLowPrecisionUpload = false;
mPendingUpload = false;
return false;
}
}
return true;
}
void
TiledContentHost::Composite(EffectChain& aEffectChain,
float aOpacity,
const gfx::Matrix4x4& aTransform,
const gfx::Filter& aFilter,
const gfx::Rect& aClipRect,
const nsIntRegion* aVisibleRegion /* = nullptr */)
{
MOZ_ASSERT(mCompositor);
if (mPendingUpload) {
mTiledBuffer.SetCompositor(mCompositor);
mTiledBuffer.Upload();
// For a single-buffered tiled buffer, Upload will upload the shared memory
// surface to texture memory and we no longer need to read from them.
if (!mTiledBuffer.HasDoubleBufferedTiles()) {
mTiledBuffer.ReadUnlock();
}
}
if (mPendingLowPrecisionUpload) {
mLowPrecisionTiledBuffer.SetCompositor(mCompositor);
mLowPrecisionTiledBuffer.Upload();
if (!mLowPrecisionTiledBuffer.HasDoubleBufferedTiles()) {
mLowPrecisionTiledBuffer.ReadUnlock();
}
}
// Reduce the opacity of the low-precision buffer to make it a
// little more subtle and less jarring. In particular, text
// rendered at low-resolution and scaled tends to look pretty
// heavy and this helps mitigate that. When we reduce the opacity
// we also make sure to draw the background color behind the
// reduced-opacity tile so that content underneath doesn't show
// through.
// However, in cases where the background is transparent, or the layer
// already has some opacity, we want to skip this behaviour. Otherwise
// we end up changing the expected overall transparency of the content,
// and it just looks wrong.
gfxRGBA backgroundColor(0);
if (aOpacity == 1.0f && gfxPrefs::LowPrecisionOpacity() < 1.0f) {
// Background colors are only stored on scrollable layers. Grab
// the one from the nearest scrollable ancestor layer.
for (LayerMetricsWrapper ancestor(GetLayer(), LayerMetricsWrapper::StartAt::BOTTOM); ancestor; ancestor = ancestor.GetParent()) {
if (ancestor.Metrics().IsScrollable()) {
backgroundColor = ancestor.Metrics().GetBackgroundColor();
break;
}
}
}
float lowPrecisionOpacityReduction =
(aOpacity == 1.0f && backgroundColor.a == 1.0f)
? gfxPrefs::LowPrecisionOpacity() : 1.0f;
nsIntRegion tmpRegion;
const nsIntRegion* renderRegion = aVisibleRegion;
#ifndef MOZ_IGNORE_PAINT_WILL_RESAMPLE
if (PaintWillResample()) {
// If we're resampling, then the texture image will contain exactly the
// entire visible region's bounds, and we should draw it all in one quad
// to avoid unexpected aliasing.
tmpRegion = aVisibleRegion->GetBounds();
renderRegion = &tmpRegion;
}
#endif
// Render the low and high precision buffers.
RenderLayerBuffer(mLowPrecisionTiledBuffer,
lowPrecisionOpacityReduction < 1.0f ? &backgroundColor : nullptr,
aEffectChain, lowPrecisionOpacityReduction * aOpacity,
aFilter, aClipRect, *renderRegion, aTransform);
RenderLayerBuffer(mTiledBuffer, nullptr, aEffectChain, aOpacity, aFilter,
aClipRect, *renderRegion, aTransform);
// Now release the old buffer if it had double-buffered tiles, as we can
// guarantee that they're no longer on the screen (and so any locks that may
// have been held have been released).
if (mPendingUpload && mOldTiledBuffer.HasDoubleBufferedTiles()) {
mOldTiledBuffer.ReadUnlock();
mOldTiledBuffer = TiledLayerBufferComposite();
}
if (mPendingLowPrecisionUpload && mOldLowPrecisionTiledBuffer.HasDoubleBufferedTiles()) {
mOldLowPrecisionTiledBuffer.ReadUnlock();
mOldLowPrecisionTiledBuffer = TiledLayerBufferComposite();
}
mPendingUpload = mPendingLowPrecisionUpload = false;
}
void
TiledContentHost::RenderTile(const TileHost& aTile,
const gfxRGBA* aBackgroundColor,
EffectChain& aEffectChain,
float aOpacity,
const gfx::Matrix4x4& aTransform,
const gfx::Filter& aFilter,
const gfx::Rect& aClipRect,
const nsIntRegion& aScreenRegion,
const IntPoint& aTextureOffset,
const nsIntSize& aTextureBounds)
{
if (aTile.IsPlaceholderTile()) {
// This shouldn't ever happen, but let's fail semi-gracefully. No need
// to warn, the texture update would have already caught this.
return;
}
if (aBackgroundColor) {
aEffectChain.mPrimaryEffect = new EffectSolidColor(ToColor(*aBackgroundColor));
nsIntRegionRectIterator it(aScreenRegion);
for (const IntRect* rect = it.Next(); rect != nullptr; rect = it.Next()) {
Rect graphicsRect(rect->x, rect->y, rect->width, rect->height);
mCompositor->DrawQuad(graphicsRect, aClipRect, aEffectChain, 1.0, aTransform);
}
}
AutoLockTextureHost autoLock(aTile.mTextureHost);
AutoLockTextureHost autoLockOnWhite(aTile.mTextureHostOnWhite);
if (autoLock.Failed() ||
autoLockOnWhite.Failed()) {
NS_WARNING("Failed to lock tile");
return;
}
if (!aTile.mTextureHost->BindTextureSource(aTile.mTextureSource)) {
return;
}
if (aTile.mTextureHostOnWhite && !aTile.mTextureHostOnWhite->BindTextureSource(aTile.mTextureSourceOnWhite)) {
return;
}
RefPtr<TexturedEffect> effect = CreateTexturedEffect(aTile.mTextureSource, aTile.mTextureSourceOnWhite, aFilter, true);
if (!effect) {
return;
}
aEffectChain.mPrimaryEffect = effect;
nsIntRegionRectIterator it(aScreenRegion);
for (const IntRect* rect = it.Next(); rect != nullptr; rect = it.Next()) {
Rect graphicsRect(rect->x, rect->y, rect->width, rect->height);
Rect textureRect(rect->x - aTextureOffset.x, rect->y - aTextureOffset.y,
rect->width, rect->height);
effect->mTextureCoords = Rect(textureRect.x / aTextureBounds.width,
textureRect.y / aTextureBounds.height,
textureRect.width / aTextureBounds.width,
textureRect.height / aTextureBounds.height);
mCompositor->DrawQuad(graphicsRect, aClipRect, aEffectChain, aOpacity, aTransform);
}
DiagnosticFlags flags = DiagnosticFlags::CONTENT | DiagnosticFlags::TILE;
if (aTile.mTextureHostOnWhite) {
flags |= DiagnosticFlags::COMPONENT_ALPHA;
}
mCompositor->DrawDiagnostics(flags,
aScreenRegion, aClipRect, aTransform, mFlashCounter);
}
void
TiledContentHost::RenderLayerBuffer(TiledLayerBufferComposite& aLayerBuffer,
const gfxRGBA* aBackgroundColor,
EffectChain& aEffectChain,
float aOpacity,
const gfx::Filter& aFilter,
const gfx::Rect& aClipRect,
nsIntRegion aVisibleRegion,
gfx::Matrix4x4 aTransform)
{
if (!mCompositor) {
NS_WARNING("Can't render tiled content host - no compositor");
return;
}
float resolution = aLayerBuffer.GetResolution();
gfx::Size layerScale(1, 1);
// We assume that the current frame resolution is the one used in our high
// precision layer buffer. Compensate for a changing frame resolution when
// rendering the low precision buffer.
if (aLayerBuffer.GetFrameResolution() != mTiledBuffer.GetFrameResolution()) {
const CSSToParentLayerScale2D& layerResolution = aLayerBuffer.GetFrameResolution();
const CSSToParentLayerScale2D& localResolution = mTiledBuffer.GetFrameResolution();
layerScale.width = layerResolution.xScale / localResolution.xScale;
layerScale.height = layerResolution.yScale / localResolution.yScale;
aVisibleRegion.ScaleRoundOut(layerScale.width, layerScale.height);
}
// If we're drawing the low precision buffer, make sure the high precision
// buffer is masked out to avoid overdraw and rendering artifacts with
// non-opaque layers.
nsIntRegion maskRegion;
if (resolution != mTiledBuffer.GetResolution()) {
maskRegion = mTiledBuffer.GetValidRegion();
// XXX This should be ScaleRoundIn, but there is no such function on
// nsIntRegion.
maskRegion.ScaleRoundOut(layerScale.width, layerScale.height);
}
// Make sure the resolution and difference in frame resolution are accounted
// for in the layer transform.
aTransform.PreScale(1/(resolution * layerScale.width),
1/(resolution * layerScale.height), 1);
DiagnosticFlags componentAlphaDiagnostic = DiagnosticFlags::NO_DIAGNOSTIC;
uint32_t rowCount = 0;
uint32_t tileX = 0;
IntRect visibleRect = aVisibleRegion.GetBounds();
gfx::IntSize scaledTileSize = aLayerBuffer.GetScaledTileSize();
for (int32_t x = visibleRect.x; x < visibleRect.x + visibleRect.width;) {
rowCount++;
int32_t tileStartX = aLayerBuffer.GetTileStart(x, scaledTileSize.width);
int32_t w = scaledTileSize.width - tileStartX;
if (x + w > visibleRect.x + visibleRect.width) {
w = visibleRect.x + visibleRect.width - x;
}
int tileY = 0;
for (int32_t y = visibleRect.y; y < visibleRect.y + visibleRect.height;) {
int32_t tileStartY = aLayerBuffer.GetTileStart(y, scaledTileSize.height);
int32_t h = scaledTileSize.height - tileStartY;
if (y + h > visibleRect.y + visibleRect.height) {
h = visibleRect.y + visibleRect.height - y;
}
TileHost tileTexture = aLayerBuffer.
GetTile(IntPoint(aLayerBuffer.RoundDownToTileEdge(x, scaledTileSize.width),
aLayerBuffer.RoundDownToTileEdge(y, scaledTileSize.height)));
if (tileTexture != aLayerBuffer.GetPlaceholderTile()) {
nsIntRegion tileDrawRegion;
tileDrawRegion.And(IntRect(x, y, w, h), aLayerBuffer.GetValidRegion());
tileDrawRegion.And(tileDrawRegion, aVisibleRegion);
tileDrawRegion.Sub(tileDrawRegion, maskRegion);
if (!tileDrawRegion.IsEmpty()) {
tileDrawRegion.ScaleRoundOut(resolution, resolution);
IntPoint tileOffset((x - tileStartX) * resolution,
(y - tileStartY) * resolution);
gfx::IntSize tileSize = aLayerBuffer.GetTileSize();
RenderTile(tileTexture, aBackgroundColor, aEffectChain, aOpacity, aTransform,
aFilter, aClipRect, tileDrawRegion, tileOffset,
nsIntSize(tileSize.width, tileSize.height));
if (tileTexture.mTextureHostOnWhite) {
componentAlphaDiagnostic = DiagnosticFlags::COMPONENT_ALPHA;
}
}
}
tileY++;
y += h;
}
tileX++;
x += w;
}
gfx::Rect rect(visibleRect.x, visibleRect.y,
visibleRect.width, visibleRect.height);
GetCompositor()->DrawDiagnostics(DiagnosticFlags::CONTENT | componentAlphaDiagnostic,
rect, aClipRect, aTransform, mFlashCounter);
}
void
TiledContentHost::PrintInfo(std::stringstream& aStream, const char* aPrefix)
{
aStream << aPrefix;
aStream << nsPrintfCString("TiledContentHost (0x%p)", this).get();
if (gfxPrefs::LayersDumpTexture() || profiler_feature_active("layersdump")) {
nsAutoCString pfx(aPrefix);
pfx += " ";
Dump(aStream, pfx.get(), false);
}
}
void
TiledContentHost::Dump(std::stringstream& aStream,
const char* aPrefix,
bool aDumpHtml)
{
mTiledBuffer.Dump(aStream, aPrefix, aDumpHtml);
}
} // namespace
} // namespace