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android / platform / external / webkit / b627d5bd0e9b9a4d02131ef694467bfb62b9fb7f / . / Source / WebCore / rendering / RenderLayerCompositor.cpp
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/*
* Copyright (C) 2009, 2010 Apple Inc. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE COMPUTER, INC. OR
* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
* OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "config.h"
#if USE(ACCELERATED_COMPOSITING)
#include "RenderLayerCompositor.h"
#include "AnimationController.h"
#include "CanvasRenderingContext.h"
#include "CSSPropertyNames.h"
#include "Chrome.h"
#include "ChromeClient.h"
#include "Frame.h"
#include "FrameView.h"
#include "GraphicsLayer.h"
#include "HTMLCanvasElement.h"
#include "HTMLIFrameElement.h"
#include "HTMLNames.h"
#include "HitTestResult.h"
#include "NodeList.h"
#include "Page.h"
#include "RenderApplet.h"
#include "RenderEmbeddedObject.h"
#include "RenderFullScreen.h"
#include "RenderIFrame.h"
#include "RenderLayerBacking.h"
#include "RenderReplica.h"
#include "RenderVideo.h"
#include "RenderView.h"
#include "Settings.h"
#if ENABLE(PLUGIN_PROXY_FOR_VIDEO)
#include "HTMLMediaElement.h"
#endif
#if PROFILE_LAYER_REBUILD
#include <wtf/CurrentTime.h>
#endif
#ifndef NDEBUG
#include "RenderTreeAsText.h"
#endif
#if ENABLE(3D_RENDERING)
// This symbol is used to determine from a script whether 3D rendering is enabled (via 'nm').
bool WebCoreHas3DRendering = true;
#endif
namespace WebCore {
using namespace HTMLNames;
struct CompositingState {
CompositingState(RenderLayer* compAncestor)
: m_compositingAncestor(compAncestor)
, m_subtreeIsCompositing(false)
#if ENABLE(COMPOSITED_FIXED_ELEMENTS)
, m_fixedSibling(false)
, m_hasFixedElement(false)
#endif
#if ENABLE(ANDROID_OVERFLOW_SCROLL)
, m_hasScrollableElement(false)
#endif
#ifndef NDEBUG
, m_depth(0)
#endif
{
}
RenderLayer* m_compositingAncestor;
bool m_subtreeIsCompositing;
#if ENABLE(COMPOSITED_FIXED_ELEMENTS)
bool m_fixedSibling;
bool m_hasFixedElement;
#endif
#if ENABLE(ANDROID_OVERFLOW_SCROLL)
bool m_hasScrollableElement;
#endif
#ifndef NDEBUG
int m_depth;
#endif
};
RenderLayerCompositor::RenderLayerCompositor(RenderView* renderView)
: m_renderView(renderView)
, m_rootPlatformLayer(0)
, m_updateCompositingLayersTimer(this, &RenderLayerCompositor::updateCompositingLayersTimerFired)
, m_hasAcceleratedCompositing(true)
, m_compositingTriggers(static_cast<ChromeClient::CompositingTriggerFlags>(ChromeClient::AllTriggers))
, m_showDebugBorders(false)
, m_showRepaintCounter(false)
, m_compositingConsultsOverlap(true)
, m_compositingDependsOnGeometry(false)
, m_compositing(false)
, m_compositingLayersNeedRebuild(false)
, m_flushingLayers(false)
, m_forceCompositingMode(false)
, m_rootLayerAttachment(RootLayerUnattached)
#if PROFILE_LAYER_REBUILD
, m_rootLayerUpdateCount(0)
#endif // PROFILE_LAYER_REBUILD
{
Settings* settings = m_renderView->document()->settings();
// Even when forcing compositing mode, ignore child frames, or this will trigger
// layer creation from the enclosing RenderIFrame.
ASSERT(m_renderView->document()->frame());
if (settings && settings->forceCompositingMode() && settings->acceleratedCompositingEnabled()
&& !m_renderView->document()->frame()->tree()->parent()) {
m_forceCompositingMode = true;
enableCompositingMode();
}
}
RenderLayerCompositor::~RenderLayerCompositor()
{
ASSERT(m_rootLayerAttachment == RootLayerUnattached);
}
void RenderLayerCompositor::enableCompositingMode(bool enable /* = true */)
{
if (enable != m_compositing) {
m_compositing = enable;
if (m_compositing) {
ensureRootPlatformLayer();
notifyIFramesOfCompositingChange();
} else
destroyRootPlatformLayer();
}
}
void RenderLayerCompositor::cacheAcceleratedCompositingFlags()
{
bool hasAcceleratedCompositing = false;
bool showDebugBorders = false;
bool showRepaintCounter = false;
if (Settings* settings = m_renderView->document()->settings()) {
hasAcceleratedCompositing = settings->acceleratedCompositingEnabled();
showDebugBorders = settings->showDebugBorders();
showRepaintCounter = settings->showRepaintCounter();
}
// We allow the chrome to override the settings, in case the page is rendered
// on a chrome that doesn't allow accelerated compositing.
if (hasAcceleratedCompositing) {
Frame* frame = m_renderView->frameView()->frame();
Page* page = frame ? frame->page() : 0;
if (page) {
ChromeClient* chromeClient = page->chrome()->client();
m_compositingTriggers = chromeClient->allowedCompositingTriggers();
hasAcceleratedCompositing = m_compositingTriggers;
}
}
if (hasAcceleratedCompositing != m_hasAcceleratedCompositing || showDebugBorders != m_showDebugBorders || showRepaintCounter != m_showRepaintCounter)
setCompositingLayersNeedRebuild();
m_hasAcceleratedCompositing = hasAcceleratedCompositing;
m_showDebugBorders = showDebugBorders;
m_showRepaintCounter = showRepaintCounter;
}
bool RenderLayerCompositor::canRender3DTransforms() const
{
return hasAcceleratedCompositing() && (m_compositingTriggers & ChromeClient::ThreeDTransformTrigger);
}
void RenderLayerCompositor::setCompositingLayersNeedRebuild(bool needRebuild)
{
if (inCompositingMode())
m_compositingLayersNeedRebuild = needRebuild;
}
void RenderLayerCompositor::scheduleLayerFlush()
{
Frame* frame = m_renderView->frameView()->frame();
Page* page = frame ? frame->page() : 0;
if (!page)
return;
page->chrome()->client()->scheduleCompositingLayerSync();
}
void RenderLayerCompositor::flushPendingLayerChanges()
{
ASSERT(!m_flushingLayers);
m_flushingLayers = true;
// FIXME: FrameView::syncCompositingStateRecursive() calls this for each
// frame, so when compositing layers are connected between frames, we'll
// end up syncing subframe's layers multiple times.
// https://bugs.webkit.org/show_bug.cgi?id=52489
if (GraphicsLayer* rootLayer = rootPlatformLayer())
rootLayer->syncCompositingState();
ASSERT(m_flushingLayers);
m_flushingLayers = false;
}
RenderLayerCompositor* RenderLayerCompositor::enclosingCompositorFlushingLayers() const
{
if (!m_renderView->frameView())
return 0;
for (Frame* frame = m_renderView->frameView()->frame(); frame; frame = frame->tree()->parent()) {
RenderLayerCompositor* compositor = frame->contentRenderer() ? frame->contentRenderer()->compositor() : 0;
if (compositor->isFlushingLayers())
return compositor;
}
return 0;
}
void RenderLayerCompositor::scheduleCompositingLayerUpdate()
{
if (!m_updateCompositingLayersTimer.isActive())
m_updateCompositingLayersTimer.startOneShot(0);
}
bool RenderLayerCompositor::compositingLayerUpdatePending() const
{
return m_updateCompositingLayersTimer.isActive();
}
void RenderLayerCompositor::updateCompositingLayersTimerFired(Timer<RenderLayerCompositor>*)
{
updateCompositingLayers();
}
void RenderLayerCompositor::updateCompositingLayers(CompositingUpdateType updateType, RenderLayer* updateRoot)
{
m_updateCompositingLayersTimer.stop();
if (!m_compositingDependsOnGeometry && !m_compositing)
return;
bool checkForHierarchyUpdate = m_compositingDependsOnGeometry;
bool needGeometryUpdate = false;
switch (updateType) {
case CompositingUpdateAfterLayoutOrStyleChange:
case CompositingUpdateOnPaitingOrHitTest:
checkForHierarchyUpdate = true;
break;
case CompositingUpdateOnScroll:
if (m_compositingConsultsOverlap)
checkForHierarchyUpdate = true; // Overlap can change with scrolling, so need to check for hierarchy updates.
needGeometryUpdate = true;
break;
}
if (!checkForHierarchyUpdate && !needGeometryUpdate)
return;
bool needHierarchyUpdate = m_compositingLayersNeedRebuild;
if (!updateRoot || m_compositingConsultsOverlap) {
// Only clear the flag if we're updating the entire hierarchy.
m_compositingLayersNeedRebuild = false;
updateRoot = rootRenderLayer();
}
#if PROFILE_LAYER_REBUILD
++m_rootLayerUpdateCount;
double startTime = WTF::currentTime();
#endif
if (checkForHierarchyUpdate) {
// Go through the layers in presentation order, so that we can compute which RenderLayers need compositing layers.
// FIXME: we could maybe do this and the hierarchy udpate in one pass, but the parenting logic would be more complex.
CompositingState compState(updateRoot);
bool layersChanged = false;
#if ENABLE(COMPOSITED_FIXED_ELEMENTS)
compState.m_hasFixedElement = false;
#endif
#if ENABLE(ANDROID_OVERFLOW_SCROLL)
compState.m_hasScrollableElement = false;
#endif
if (m_compositingConsultsOverlap) {
OverlapMap overlapTestRequestMap;
computeCompositingRequirements(updateRoot, &overlapTestRequestMap, compState, layersChanged);
} else
computeCompositingRequirements(updateRoot, 0, compState, layersChanged);
needHierarchyUpdate |= layersChanged;
}
if (needHierarchyUpdate) {
// Update the hierarchy of the compositing layers.
CompositingState compState(updateRoot);
Vector<GraphicsLayer*> childList;
rebuildCompositingLayerTree(updateRoot, compState, childList);
// Host the document layer in the RenderView's root layer.
if (updateRoot == rootRenderLayer()) {
if (childList.isEmpty())
destroyRootPlatformLayer();
else
m_rootPlatformLayer->setChildren(childList);
}
} else if (needGeometryUpdate) {
// We just need to do a geometry update. This is only used for position:fixed scrolling;
// most of the time, geometry is updated via RenderLayer::styleChanged().
updateLayerTreeGeometry(updateRoot);
}
#if PROFILE_LAYER_REBUILD
double endTime = WTF::currentTime();
if (updateRoot == rootRenderLayer())
fprintf(stderr, "Update %d: computeCompositingRequirements for the world took %fms\n",
m_rootLayerUpdateCount, 1000.0 * (endTime - startTime));
#endif
ASSERT(updateRoot || !m_compositingLayersNeedRebuild);
if (!hasAcceleratedCompositing())
enableCompositingMode(false);
}
bool RenderLayerCompositor::updateBacking(RenderLayer* layer, CompositingChangeRepaint shouldRepaint)
{
bool layerChanged = false;
if (needsToBeComposited(layer)) {
enableCompositingMode();
// 3D transforms turn off the testing of overlap.
if (requiresCompositingForTransform(layer->renderer()))
setCompositingConsultsOverlap(false);
#if ENABLE(ANDROID_OVERFLOW_SCROLL)
// If we are a child of a scrollable layer, ignore the overlap from the
// scrollable layer as it can cause child layers to become composited
// siblings and will not scroll with the main content layer.
if (layer->hasOverflowParent())
setCompositingConsultsOverlap(false);
#endif
if (!layer->backing()) {
// If we need to repaint, do so before making backing
if (shouldRepaint == CompositingChangeRepaintNow)
repaintOnCompositingChange(layer);
layer->ensureBacking();
#if PLATFORM(MAC) && USE(CA)
if (m_renderView->document()->settings()->acceleratedDrawingEnabled())
layer->backing()->graphicsLayer()->setAcceleratesDrawing(true);
else if (layer->renderer()->isCanvas()) {
HTMLCanvasElement* canvas = static_cast<HTMLCanvasElement*>(layer->renderer()->node());
if (canvas->renderingContext() && canvas->renderingContext()->isAccelerated())
layer->backing()->graphicsLayer()->setAcceleratesDrawing(true);
}
#endif
layerChanged = true;
}
} else {
if (layer->backing()) {
// If we're removing backing on a reflection, clear the source GraphicsLayer's pointer to
// its replica GraphicsLayer. In practice this should never happen because reflectee and reflection
// are both either composited, or not composited.
if (layer->isReflection()) {
RenderLayer* sourceLayer = toRenderBoxModelObject(layer->renderer()->parent())->layer();
if (RenderLayerBacking* backing = sourceLayer->backing()) {
ASSERT(backing->graphicsLayer()->replicaLayer() == layer->backing()->graphicsLayer());
backing->graphicsLayer()->setReplicatedByLayer(0);
}
}
layer->clearBacking();
layerChanged = true;
// The layer's cached repaints rects are relative to the repaint container, so change when
// compositing changes; we need to update them here.
layer->computeRepaintRects();
// If we need to repaint, do so now that we've removed the backing
if (shouldRepaint == CompositingChangeRepaintNow)
repaintOnCompositingChange(layer);
}
}
#if ENABLE(VIDEO)
if (layerChanged && layer->renderer()->isVideo()) {
// If it's a video, give the media player a chance to hook up to the layer.
RenderVideo* video = toRenderVideo(layer->renderer());
video->acceleratedRenderingStateChanged();
}
#endif
if (layerChanged && layer->renderer()->isRenderPart()) {
RenderLayerCompositor* innerCompositor = frameContentsCompositor(toRenderPart(layer->renderer()));
if (innerCompositor && innerCompositor->inCompositingMode())
innerCompositor->updateRootLayerAttachment();
}
return layerChanged;
}
bool RenderLayerCompositor::updateLayerCompositingState(RenderLayer* layer, CompositingChangeRepaint shouldRepaint)
{
bool layerChanged = updateBacking(layer, shouldRepaint);
// See if we need content or clipping layers. Methods called here should assume
// that the compositing state of descendant layers has not been updated yet.
if (layer->backing() && layer->backing()->updateGraphicsLayerConfiguration())
layerChanged = true;
return layerChanged;
}
void RenderLayerCompositor::repaintOnCompositingChange(RenderLayer* layer)
{
// If the renderer is not attached yet, no need to repaint.
if (layer->renderer() != m_renderView && !layer->renderer()->parent())
return;
RenderBoxModelObject* repaintContainer = layer->renderer()->containerForRepaint();
if (!repaintContainer)
repaintContainer = m_renderView;
layer->repaintIncludingNonCompositingDescendants(repaintContainer);
if (repaintContainer == m_renderView) {
// The contents of this layer may be moving between the window
// and a GraphicsLayer, so we need to make sure the window system
// synchronizes those changes on the screen.
m_renderView->frameView()->setNeedsOneShotDrawingSynchronization();
}
}
// The bounds of the GraphicsLayer created for a compositing layer is the union of the bounds of all the descendant
// RenderLayers that are rendered by the composited RenderLayer.
IntRect RenderLayerCompositor::calculateCompositedBounds(const RenderLayer* layer, const RenderLayer* ancestorLayer)
{
if (!canBeComposited(layer))
return IntRect();
IntRect boundingBoxRect = layer->localBoundingBox();
if (layer->renderer()->isRoot()) {
// If the root layer becomes composited (e.g. because some descendant with negative z-index is composited),
// then it has to be big enough to cover the viewport in order to display the background. This is akin
// to the code in RenderBox::paintRootBoxFillLayers().
if (m_renderView->frameView()) {
int rw = m_renderView->frameView()->contentsWidth();
int rh = m_renderView->frameView()->contentsHeight();
boundingBoxRect.setWidth(max(boundingBoxRect.width(), rw - boundingBoxRect.x()));
boundingBoxRect.setHeight(max(boundingBoxRect.height(), rh - boundingBoxRect.y()));
}
}
IntRect unionBounds = boundingBoxRect;
if (layer->renderer()->hasOverflowClip() || layer->renderer()->hasMask()) {
int ancestorRelX = 0, ancestorRelY = 0;
layer->convertToLayerCoords(ancestorLayer, ancestorRelX, ancestorRelY);
boundingBoxRect.move(ancestorRelX, ancestorRelY);
return boundingBoxRect;
}
if (RenderLayer* reflection = layer->reflectionLayer()) {
if (!reflection->isComposited()) {
IntRect childUnionBounds = calculateCompositedBounds(reflection, layer);
unionBounds.unite(childUnionBounds);
}
}
ASSERT(layer->isStackingContext() || (!layer->m_posZOrderList || layer->m_posZOrderList->size() == 0));
if (Vector<RenderLayer*>* negZOrderList = layer->negZOrderList()) {
size_t listSize = negZOrderList->size();
for (size_t i = 0; i < listSize; ++i) {
RenderLayer* curLayer = negZOrderList->at(i);
if (!curLayer->isComposited()) {
IntRect childUnionBounds = calculateCompositedBounds(curLayer, layer);
unionBounds.unite(childUnionBounds);
}
}
}
if (Vector<RenderLayer*>* posZOrderList = layer->posZOrderList()) {
size_t listSize = posZOrderList->size();
for (size_t i = 0; i < listSize; ++i) {
RenderLayer* curLayer = posZOrderList->at(i);
if (!curLayer->isComposited()) {
IntRect childUnionBounds = calculateCompositedBounds(curLayer, layer);
unionBounds.unite(childUnionBounds);
}
}
}
if (Vector<RenderLayer*>* normalFlowList = layer->normalFlowList()) {
size_t listSize = normalFlowList->size();
for (size_t i = 0; i < listSize; ++i) {
RenderLayer* curLayer = normalFlowList->at(i);
if (!curLayer->isComposited()) {
IntRect curAbsBounds = calculateCompositedBounds(curLayer, layer);
unionBounds.unite(curAbsBounds);
}
}
}
if (layer->paintsWithTransform(PaintBehaviorNormal)) {
TransformationMatrix* affineTrans = layer->transform();
boundingBoxRect = affineTrans->mapRect(boundingBoxRect);
unionBounds = affineTrans->mapRect(unionBounds);
}
int ancestorRelX = 0, ancestorRelY = 0;
layer->convertToLayerCoords(ancestorLayer, ancestorRelX, ancestorRelY);
unionBounds.move(ancestorRelX, ancestorRelY);
return unionBounds;
}
void RenderLayerCompositor::layerWasAdded(RenderLayer* /*parent*/, RenderLayer* /*child*/)
{
setCompositingLayersNeedRebuild();
}
void RenderLayerCompositor::layerWillBeRemoved(RenderLayer* parent, RenderLayer* child)
{
if (!child->isComposited() || parent->renderer()->documentBeingDestroyed())
return;
setCompositingParent(child, 0);
RenderLayer* compLayer = parent->enclosingCompositingLayer();
if (compLayer) {
ASSERT(compLayer->backing());
IntRect compBounds = child->backing()->compositedBounds();
int offsetX = 0, offsetY = 0;
child->convertToLayerCoords(compLayer, offsetX, offsetY);
compBounds.move(offsetX, offsetY);
compLayer->setBackingNeedsRepaintInRect(compBounds);
// The contents of this layer may be moving from a GraphicsLayer to the window,
// so we need to make sure the window system synchronizes those changes on the screen.
m_renderView->frameView()->setNeedsOneShotDrawingSynchronization();
}
setCompositingLayersNeedRebuild();
}
RenderLayer* RenderLayerCompositor::enclosingNonStackingClippingLayer(const RenderLayer* layer) const
{
for (RenderLayer* curr = layer->parent(); curr != 0; curr = curr->parent()) {
if (curr->isStackingContext())
return 0;
if (curr->renderer()->hasOverflowClip() || curr->renderer()->hasClip())
return curr;
}
return 0;
}
void RenderLayerCompositor::addToOverlapMap(OverlapMap& overlapMap, RenderLayer* layer, IntRect& layerBounds, bool& boundsComputed)
{
if (layer->isRootLayer())
return;
if (!boundsComputed) {
layerBounds = layer->renderer()->localToAbsoluteQuad(FloatRect(layer->localBoundingBox())).enclosingBoundingBox();
// Empty rects never intersect, but we need them to for the purposes of overlap testing.
if (layerBounds.isEmpty())
layerBounds.setSize(IntSize(1, 1));
boundsComputed = true;
}
overlapMap.add(layer, layerBounds);
}
bool RenderLayerCompositor::overlapsCompositedLayers(OverlapMap& overlapMap, const IntRect& layerBounds)
{
RenderLayerCompositor::OverlapMap::const_iterator end = overlapMap.end();
for (RenderLayerCompositor::OverlapMap::const_iterator it = overlapMap.begin(); it != end; ++it) {
const IntRect& bounds = it->second;
if (layerBounds.intersects(bounds)) {
return true;
}
}
return false;
}
#if ENABLE(COMPOSITED_FIXED_ELEMENTS)
// to properly support z-index with composited fixed elements, we need to turn
// layers following a fixed layer into compositing mode; but if a layer is fully
// contained into a previous layer already composited (that is not the fixed
// layer), we don't need to composite it. This saves up quite a bit on the
// number of layers we have to composite.
//
bool RenderLayerCompositor::checkForFixedLayers(Vector<RenderLayer*>* list, bool stopAtFixedLayer)
{
int listSize = list->size();
int haveFixedLayer = -1;
bool fixedSibling = false;
for (int j = 0; j < listSize; ++j) {
RenderLayer* currentLayer = list->at(j);
if (currentLayer->isFixed() && needsToBeComposited(currentLayer)) {
haveFixedLayer = j;
fixedSibling = true;
}
IntRect currentLayerBounds = currentLayer->renderer()->localToAbsoluteQuad(
FloatRect(currentLayer->localBoundingBox())).enclosingBoundingBox();
if ((currentLayerBounds.width() <= 1
|| currentLayerBounds.height() <= 1)
&& haveFixedLayer == j) {
haveFixedLayer = -1;
fixedSibling = false;
}
if (haveFixedLayer != -1 && haveFixedLayer != j) {
bool needComposite = true;
int stop = 0;
if (stopAtFixedLayer)
stop = haveFixedLayer + 1;
for (int k = j - 1; k >= stop; --k) {
RenderLayer* aLayer = list->at(k);
if (aLayer && aLayer->renderer()) {
IntRect bounds = aLayer->renderer()->localToAbsoluteQuad(
FloatRect(aLayer->localBoundingBox())).enclosingBoundingBox();
if (bounds.contains(currentLayerBounds)
&& needsToBeComposited(aLayer) && aLayer->isStackingContext()) {
needComposite = false;
break;
}
}
}
currentLayer->setShouldComposite(needComposite);
}
}
return fixedSibling;
}
#endif
// Recurse through the layers in z-index and overflow order (which is equivalent to painting order)
// For the z-order children of a compositing layer:
// If a child layers has a compositing layer, then all subsequent layers must
// be compositing in order to render above that layer.
//
// If a child in the negative z-order list is compositing, then the layer itself
// must be compositing so that its contents render over that child.
// This implies that its positive z-index children must also be compositing.
//
void RenderLayerCompositor::computeCompositingRequirements(RenderLayer* layer, OverlapMap* overlapMap, struct CompositingState& compositingState, bool& layersChanged)
{
layer->updateLayerPosition();
layer->updateZOrderLists();
layer->updateNormalFlowList();
// Clear the flag
layer->setHasCompositingDescendant(false);
bool mustOverlapCompositedLayers = compositingState.m_subtreeIsCompositing;
bool haveComputedBounds = false;
IntRect absBounds;
if (overlapMap && !overlapMap->isEmpty()) {
// If we're testing for overlap, we only need to composite if we overlap something that is already composited.
absBounds = layer->renderer()->localToAbsoluteQuad(FloatRect(layer->localBoundingBox())).enclosingBoundingBox();
// Empty rects never intersect, but we need them to for the purposes of overlap testing.
if (absBounds.isEmpty())
absBounds.setSize(IntSize(1, 1));
haveComputedBounds = true;
mustOverlapCompositedLayers = overlapsCompositedLayers(*overlapMap, absBounds);
}
#if ENABLE(COMPOSITED_FIXED_ELEMENTS)
if (compositingState.m_fixedSibling)
layer->setMustOverlapCompositedLayers(layer->shouldComposite());
else
layer->setMustOverlapCompositedLayers(mustOverlapCompositedLayers);
#else
layer->setMustOverlapCompositedLayers(mustOverlapCompositedLayers);
#endif
// The children of this layer don't need to composite, unless there is
// a compositing layer among them, so start by inheriting the compositing
// ancestor with m_subtreeIsCompositing set to false.
CompositingState childState(compositingState.m_compositingAncestor);
#ifndef NDEBUG
++childState.m_depth;
#endif
bool willBeComposited = needsToBeComposited(layer);
#if ENABLE(ANDROID_OVERFLOW_SCROLL)
// tell the parent it has scrollable descendants.
if (layer->hasOverflowScroll())
compositingState.m_hasScrollableElement = true;
#endif
#if ENABLE(COMPOSITED_FIXED_ELEMENTS)
if (layer->isFixed())
compositingState.m_hasFixedElement = true;
#endif
if (willBeComposited) {
// Tell the parent it has compositing descendants.
compositingState.m_subtreeIsCompositing = true;
// This layer now acts as the ancestor for kids.
childState.m_compositingAncestor = layer;
if (overlapMap)
addToOverlapMap(*overlapMap, layer, absBounds, haveComputedBounds);
}
#if ENABLE(VIDEO)
// Video is special. It's a replaced element with a content layer, but has shadow content
// for the controller that must render in front. Without this, the controls fail to show
// when the video element is a stacking context (e.g. due to opacity or transform).
if (willBeComposited && layer->renderer()->isVideo())
childState.m_subtreeIsCompositing = true;
#endif
if (layer->isStackingContext()) {
ASSERT(!layer->m_zOrderListsDirty);
if (Vector<RenderLayer*>* negZOrderList = layer->negZOrderList()) {
size_t listSize = negZOrderList->size();
#if ENABLE(COMPOSITED_FIXED_ELEMENTS)
childState.m_fixedSibling = compositingState.m_fixedSibling;
if (checkForFixedLayers(negZOrderList, false))
childState.m_fixedSibling = true;
#endif
for (size_t i = 0; i < listSize; ++i) {
RenderLayer* curLayer = negZOrderList->at(i);
computeCompositingRequirements(curLayer, overlapMap, childState, layersChanged);
// If we have to make a layer for this child, make one now so we can have a contents layer
// (since we need to ensure that the -ve z-order child renders underneath our contents).
#ifdef ANDROID
// Normally we try to reduce the number of layers by not promoting all fixed
// or scrollable elements to their own compositing layer. But in the case that
// we have such an element in the negative z-order, we must make it a layer
// otherwise the content will be painted at a higher z-index. This breaks pages
// that set a large image with a z-index of -1 to implement a background image,
// for example.
bool childRequiresCompositing = childState.m_hasFixedElement || childState.m_hasScrollableElement;
if (!willBeComposited && (childState.m_subtreeIsCompositing || childRequiresCompositing)) {
#else
if (!willBeComposited && childState.m_subtreeIsCompositing) {
#endif
// make layer compositing
layer->setMustOverlapCompositedLayers(true);
childState.m_compositingAncestor = layer;
if (overlapMap)
addToOverlapMap(*overlapMap, layer, absBounds, haveComputedBounds);
willBeComposited = true;
}
}
}
}
ASSERT(!layer->m_normalFlowListDirty);
if (Vector<RenderLayer*>* normalFlowList = layer->normalFlowList()) {
size_t listSize = normalFlowList->size();
#if ENABLE(COMPOSITED_FIXED_ELEMENTS)
childState.m_fixedSibling = compositingState.m_fixedSibling;
if (checkForFixedLayers(normalFlowList, true))
childState.m_fixedSibling = true;
#endif
for (size_t i = 0; i < listSize; ++i) {
RenderLayer* curLayer = normalFlowList->at(i);
computeCompositingRequirements(curLayer, overlapMap, childState, layersChanged);
}
}
if (layer->isStackingContext()) {
if (Vector<RenderLayer*>* posZOrderList = layer->posZOrderList()) {
size_t listSize = posZOrderList->size();
#if ENABLE(COMPOSITED_FIXED_ELEMENTS)
childState.m_fixedSibling = compositingState.m_fixedSibling;
if (checkForFixedLayers(posZOrderList, true))
childState.m_fixedSibling = true;
#endif
for (size_t i = 0; i < listSize; ++i) {
RenderLayer* curLayer = posZOrderList->at(i);
computeCompositingRequirements(curLayer, overlapMap, childState, layersChanged);
}
}
}
// If we just entered compositing mode, the root will have become composited (as long as accelerated compositing is enabled).
if (layer->isRootLayer()) {
if (inCompositingMode() && m_hasAcceleratedCompositing)
willBeComposited = true;
}
ASSERT(willBeComposited == needsToBeComposited(layer));
// If we have a software transform, and we have layers under us, we need to also
// be composited. Also, if we have opacity < 1, then we need to be a layer so that
// the child layers are opaque, then rendered with opacity on this layer.
if (!willBeComposited && canBeComposited(layer) && childState.m_subtreeIsCompositing && requiresCompositingWhenDescendantsAreCompositing(layer->renderer())) {
layer->setMustOverlapCompositedLayers(true);
if (overlapMap)
addToOverlapMap(*overlapMap, layer, absBounds, haveComputedBounds);
willBeComposited = true;
}
ASSERT(willBeComposited == needsToBeComposited(layer));
if (layer->reflectionLayer())
layer->reflectionLayer()->setMustOverlapCompositedLayers(willBeComposited);
// Subsequent layers in the parent stacking context also need to composite.
if (childState.m_subtreeIsCompositing)
compositingState.m_subtreeIsCompositing = true;
#if ENABLE(COMPOSITED_FIXED_ELEMENTS)
if (childState.m_hasFixedElement)
compositingState.m_hasFixedElement = true;
#endif
#if ENABLE(ANDROID_OVERFLOW_SCROLL)
if (childState.m_hasScrollableElement)
compositingState.m_hasScrollableElement = true;
#endif
// Set the flag to say that this SC has compositing children.
layer->setHasCompositingDescendant(childState.m_subtreeIsCompositing);
// setHasCompositingDescendant() may have changed the answer to needsToBeComposited() when clipping,
// so test that again.
if (!willBeComposited && canBeComposited(layer) && clipsCompositingDescendants(layer)) {
if (overlapMap)
addToOverlapMap(*overlapMap, layer, absBounds, haveComputedBounds);
willBeComposited = true;
}
// If we're back at the root, and no other layers need to be composited, and the root layer itself doesn't need
// to be composited, then we can drop out of compositing mode altogether.
#if ENABLE(ANDROID_OVERFLOW_SCROLL)
// We also need to check that we don't have a scrollable layer, as this
// would not have set the m_subtreeIsCompositing flag
if (layer->isRootLayer() && !childState.m_subtreeIsCompositing && !childState.m_hasScrollableElement && !childState.m_hasFixedElement && !requiresCompositingLayer(layer) && !m_forceCompositingMode) {
#else
if (layer->isRootLayer() && !childState.m_subtreeIsCompositing && !requiresCompositingLayer(layer) && !m_forceCompositingMode) {
#endif
enableCompositingMode(false);
willBeComposited = false;
}
// If the layer is going into compositing mode, repaint its old location.
ASSERT(willBeComposited == needsToBeComposited(layer));
if (!layer->isComposited() && willBeComposited)
repaintOnCompositingChange(layer);
// Update backing now, so that we can use isComposited() reliably during tree traversal in rebuildCompositingLayerTree().
if (updateBacking(layer, CompositingChangeRepaintNow))
layersChanged = true;
if (layer->reflectionLayer() && updateLayerCompositingState(layer->reflectionLayer(), CompositingChangeRepaintNow))
layersChanged = true;
}
void RenderLayerCompositor::setCompositingParent(RenderLayer* childLayer, RenderLayer* parentLayer)
{
ASSERT(!parentLayer || childLayer->ancestorCompositingLayer() == parentLayer);
ASSERT(childLayer->isComposited());
// It's possible to be called with a parent that isn't yet composited when we're doing
// partial updates as required by painting or hit testing. Just bail in that case;
// we'll do a full layer update soon.
if (!parentLayer || !parentLayer->isComposited())
return;
if (parentLayer) {
GraphicsLayer* hostingLayer = parentLayer->backing()->parentForSublayers();
GraphicsLayer* hostedLayer = childLayer->backing()->childForSuperlayers();
hostingLayer->addChild(hostedLayer);
} else
childLayer->backing()->childForSuperlayers()->removeFromParent();
}
void RenderLayerCompositor::removeCompositedChildren(RenderLayer* layer)
{
ASSERT(layer->isComposited());
GraphicsLayer* hostingLayer = layer->backing()->parentForSublayers();
hostingLayer->removeAllChildren();
}
#if ENABLE(VIDEO)
bool RenderLayerCompositor::canAccelerateVideoRendering(RenderVideo* o) const
{
if (!m_hasAcceleratedCompositing)
return false;
return o->supportsAcceleratedRendering();
}
#endif
void RenderLayerCompositor::rebuildCompositingLayerTree(RenderLayer* layer, const CompositingState& compositingState, Vector<GraphicsLayer*>& childLayersOfEnclosingLayer)
{
// Make the layer compositing if necessary, and set up clipping and content layers.
// Note that we can only do work here that is independent of whether the descendant layers
// have been processed. computeCompositingRequirements() will already have done the repaint if necessary.
RenderLayerBacking* layerBacking = layer->backing();
if (layerBacking) {
// The compositing state of all our children has been updated already, so now
// we can compute and cache the composited bounds for this layer.
layerBacking->updateCompositedBounds();
if (RenderLayer* reflection = layer->reflectionLayer()) {
if (reflection->backing())
reflection->backing()->updateCompositedBounds();
}
layerBacking->updateGraphicsLayerConfiguration();
layerBacking->updateGraphicsLayerGeometry();
if (!layer->parent())
updateRootLayerPosition();
}
// If this layer has backing, then we are collecting its children, otherwise appending
// to the compositing child list of an enclosing layer.
Vector<GraphicsLayer*> layerChildren;
Vector<GraphicsLayer*>& childList = layerBacking ? layerChildren : childLayersOfEnclosingLayer;
CompositingState childState = compositingState;
if (layer->isComposited())
childState.m_compositingAncestor = layer;
#ifndef NDEBUG
++childState.m_depth;
#endif
// The children of this stacking context don't need to composite, unless there is
// a compositing layer among them, so start by assuming false.
childState.m_subtreeIsCompositing = false;
if (layer->isStackingContext()) {
ASSERT(!layer->m_zOrderListsDirty);
if (Vector<RenderLayer*>* negZOrderList = layer->negZOrderList()) {
size_t listSize = negZOrderList->size();
for (size_t i = 0; i < listSize; ++i) {
RenderLayer* curLayer = negZOrderList->at(i);
rebuildCompositingLayerTree(curLayer, childState, childList);
}
}
// If a negative z-order child is compositing, we get a foreground layer which needs to get parented.
if (layerBacking && layerBacking->foregroundLayer())
childList.append(layerBacking->foregroundLayer());
}
ASSERT(!layer->m_normalFlowListDirty);
if (Vector<RenderLayer*>* normalFlowList = layer->normalFlowList()) {
size_t listSize = normalFlowList->size();
for (size_t i = 0; i < listSize; ++i) {
RenderLayer* curLayer = normalFlowList->at(i);
rebuildCompositingLayerTree(curLayer, childState, childList);
}
}
if (layer->isStackingContext()) {
if (Vector<RenderLayer*>* posZOrderList = layer->posZOrderList()) {
size_t listSize = posZOrderList->size();
for (size_t i = 0; i < listSize; ++i) {
RenderLayer* curLayer = posZOrderList->at(i);
rebuildCompositingLayerTree(curLayer, childState, childList);
}
}
}
if (layerBacking) {
bool parented = false;
if (layer->renderer()->isRenderPart())
parented = parentFrameContentLayers(toRenderPart(layer->renderer()));
// If the layer has a clipping layer the overflow controls layers will be siblings of the clipping layer.
// Otherwise, the overflow control layers are normal children.
if (!layerBacking->hasClippingLayer()) {
if (GraphicsLayer* overflowControlLayer = layerBacking->layerForHorizontalScrollbar()) {
overflowControlLayer->removeFromParent();
layerChildren.append(overflowControlLayer);
}
if (GraphicsLayer* overflowControlLayer = layerBacking->layerForVerticalScrollbar()) {
overflowControlLayer->removeFromParent();
layerChildren.append(overflowControlLayer);
}
if (GraphicsLayer* overflowControlLayer = layerBacking->layerForScrollCorner()) {
overflowControlLayer->removeFromParent();
layerChildren.append(overflowControlLayer);
}
}
if (!parented)
layerBacking->parentForSublayers()->setChildren(layerChildren);
#if ENABLE(FULLSCREEN_API)
// For the sake of clients of the full screen renderer, don't reparent
// the full screen layer out from under them if they're in the middle of
// animating.
if (layer->renderer()->isRenderFullScreen() && toRenderFullScreen(layer->renderer())->isAnimating())
return;
#endif
childLayersOfEnclosingLayer.append(layerBacking->childForSuperlayers());
}
}
void RenderLayerCompositor::frameViewDidChangeLocation(const IntPoint& contentsOffset)
{
if (m_overflowControlsHostLayer)
m_overflowControlsHostLayer->setPosition(contentsOffset);
}
void RenderLayerCompositor::frameViewDidChangeSize()
{
if (m_clipLayer) {
FrameView* frameView = m_renderView->frameView();
m_clipLayer->setSize(frameView->visibleContentRect(false /* exclude scrollbars */).size());
IntPoint scrollPosition = frameView->scrollPosition();
m_scrollLayer->setPosition(FloatPoint(-scrollPosition.x(), -scrollPosition.y()));
updateOverflowControlsLayers();
}
}
void RenderLayerCompositor::frameViewDidScroll(const IntPoint& scrollPosition)
{
if (m_scrollLayer)
m_scrollLayer->setPosition(FloatPoint(-scrollPosition.x(), -scrollPosition.y()));
}
String RenderLayerCompositor::layerTreeAsText(bool showDebugInfo)
{
if (compositingLayerUpdatePending())
updateCompositingLayers();
if (!m_rootPlatformLayer)
return String();
// We skip dumping the scroll and clip layers to keep layerTreeAsText output
// similar between platforms.
return m_rootPlatformLayer->layerTreeAsText(showDebugInfo ? LayerTreeAsTextDebug : LayerTreeAsTextBehaviorNormal);
}
RenderLayerCompositor* RenderLayerCompositor::frameContentsCompositor(RenderPart* renderer)
{
if (!renderer->node()->isFrameOwnerElement())
return 0;
HTMLFrameOwnerElement* element = static_cast<HTMLFrameOwnerElement*>(renderer->node());
if (Document* contentDocument = element->contentDocument()) {
if (RenderView* view = contentDocument->renderView())
return view->compositor();
}
return 0;
}
bool RenderLayerCompositor::parentFrameContentLayers(RenderPart* renderer)
{
RenderLayerCompositor* innerCompositor = frameContentsCompositor(renderer);
if (!innerCompositor || !innerCompositor->inCompositingMode() || innerCompositor->rootLayerAttachment() != RootLayerAttachedViaEnclosingFrame)
return false;
RenderLayer* layer = renderer->layer();
if (!layer->isComposited())
return false;
RenderLayerBacking* backing = layer->backing();
GraphicsLayer* hostingLayer = backing->parentForSublayers();
GraphicsLayer* rootLayer = innerCompositor->rootPlatformLayer();
if (hostingLayer->children().size() != 1 || hostingLayer->children()[0] != rootLayer) {
hostingLayer->removeAllChildren();
hostingLayer->addChild(rootLayer);
}
return true;
}
// This just updates layer geometry without changing the hierarchy.
void RenderLayerCompositor::updateLayerTreeGeometry(RenderLayer* layer)
{
if (RenderLayerBacking* layerBacking = layer->backing()) {
// The compositing state of all our children has been updated already, so now
// we can compute and cache the composited bounds for this layer.
layerBacking->updateCompositedBounds();
if (RenderLayer* reflection = layer->reflectionLayer()) {
if (reflection->backing())
reflection->backing()->updateCompositedBounds();
}
layerBacking->updateGraphicsLayerConfiguration();
layerBacking->updateGraphicsLayerGeometry();
if (!layer->parent())
updateRootLayerPosition();
}
if (layer->isStackingContext()) {
ASSERT(!layer->m_zOrderListsDirty);
if (Vector<RenderLayer*>* negZOrderList = layer->negZOrderList()) {
size_t listSize = negZOrderList->size();
for (size_t i = 0; i < listSize; ++i)
updateLayerTreeGeometry(negZOrderList->at(i));
}
}
ASSERT(!layer->m_normalFlowListDirty);
if (Vector<RenderLayer*>* normalFlowList = layer->normalFlowList()) {
size_t listSize = normalFlowList->size();
for (size_t i = 0; i < listSize; ++i)
updateLayerTreeGeometry(normalFlowList->at(i));
}
if (layer->isStackingContext()) {
if (Vector<RenderLayer*>* posZOrderList = layer->posZOrderList()) {
size_t listSize = posZOrderList->size();
for (size_t i = 0; i < listSize; ++i)
updateLayerTreeGeometry(posZOrderList->at(i));
}
}
}
// Recurs down the RenderLayer tree until its finds the compositing descendants of compositingAncestor and updates their geometry.
void RenderLayerCompositor::updateCompositingDescendantGeometry(RenderLayer* compositingAncestor, RenderLayer* layer, RenderLayerBacking::UpdateDepth updateDepth)
{
if (layer != compositingAncestor) {
if (RenderLayerBacking* layerBacking = layer->backing()) {
layerBacking->updateCompositedBounds();
if (RenderLayer* reflection = layer->reflectionLayer()) {
if (reflection->backing())
reflection->backing()->updateCompositedBounds();
}
layerBacking->updateGraphicsLayerGeometry();
if (updateDepth == RenderLayerBacking::CompositingChildren)
return;
}
}
if (layer->reflectionLayer())
updateCompositingDescendantGeometry(compositingAncestor, layer->reflectionLayer(), updateDepth);
if (!layer->hasCompositingDescendant())
return;
if (layer->isStackingContext()) {
if (Vector<RenderLayer*>* negZOrderList = layer->negZOrderList()) {
size_t listSize = negZOrderList->size();
for (size_t i = 0; i < listSize; ++i)
updateCompositingDescendantGeometry(compositingAncestor, negZOrderList->at(i), updateDepth);
}
}
if (Vector<RenderLayer*>* normalFlowList = layer->normalFlowList()) {
size_t listSize = normalFlowList->size();
for (size_t i = 0; i < listSize; ++i)
updateCompositingDescendantGeometry(compositingAncestor, normalFlowList->at(i), updateDepth);
}
if (layer->isStackingContext()) {
if (Vector<RenderLayer*>* posZOrderList = layer->posZOrderList()) {
size_t listSize = posZOrderList->size();
for (size_t i = 0; i < listSize; ++i)
updateCompositingDescendantGeometry(compositingAncestor, posZOrderList->at(i), updateDepth);
}
}
}
void RenderLayerCompositor::repaintCompositedLayersAbsoluteRect(const IntRect& absRect)
{
recursiveRepaintLayerRect(rootRenderLayer(), absRect);
}
void RenderLayerCompositor::recursiveRepaintLayerRect(RenderLayer* layer, const IntRect& rect)
{
// FIXME: This method does not work correctly with transforms.
if (layer->isComposited())
layer->setBackingNeedsRepaintInRect(rect);
if (layer->hasCompositingDescendant()) {
if (Vector<RenderLayer*>* negZOrderList = layer->negZOrderList()) {
size_t listSize = negZOrderList->size();
for (size_t i = 0; i < listSize; ++i) {
RenderLayer* curLayer = negZOrderList->at(i);
int x = 0;
int y = 0;
curLayer->convertToLayerCoords(layer, x, y);
IntRect childRect(rect);
childRect.move(-x, -y);
recursiveRepaintLayerRect(curLayer, childRect);
}
}
if (Vector<RenderLayer*>* posZOrderList = layer->posZOrderList()) {
size_t listSize = posZOrderList->size();
for (size_t i = 0; i < listSize; ++i) {
RenderLayer* curLayer = posZOrderList->at(i);
int x = 0;
int y = 0;
curLayer->convertToLayerCoords(layer, x, y);
IntRect childRect(rect);
childRect.move(-x, -y);
recursiveRepaintLayerRect(curLayer, childRect);
}
}
}
if (Vector<RenderLayer*>* normalFlowList = layer->normalFlowList()) {
size_t listSize = normalFlowList->size();
for (size_t i = 0; i < listSize; ++i) {
RenderLayer* curLayer = normalFlowList->at(i);
int x = 0;
int y = 0;
curLayer->convertToLayerCoords(layer, x, y);
IntRect childRect(rect);
childRect.move(-x, -y);
recursiveRepaintLayerRect(curLayer, childRect);
}
}
}
RenderLayer* RenderLayerCompositor::rootRenderLayer() const
{
return m_renderView->layer();
}
GraphicsLayer* RenderLayerCompositor::rootPlatformLayer() const
{
if (m_overflowControlsHostLayer)
return m_overflowControlsHostLayer.get();
return m_rootPlatformLayer.get();
}
void RenderLayerCompositor::didMoveOnscreen()
{
if (!inCompositingMode() || m_rootLayerAttachment != RootLayerUnattached)
return;
RootLayerAttachment attachment = shouldPropagateCompositingToEnclosingFrame() ? RootLayerAttachedViaEnclosingFrame : RootLayerAttachedViaChromeClient;
attachRootPlatformLayer(attachment);
}
void RenderLayerCompositor::willMoveOffscreen()
{
if (!inCompositingMode() || m_rootLayerAttachment == RootLayerUnattached)
return;
detachRootPlatformLayer();
}
void RenderLayerCompositor::updateRootLayerPosition()
{
if (m_rootPlatformLayer) {
m_rootPlatformLayer->setSize(FloatSize(m_renderView->docWidth(), m_renderView->docHeight()));
m_rootPlatformLayer->setPosition(FloatPoint(m_renderView->docLeft(), m_renderView->docTop()));
}
if (m_clipLayer) {
FrameView* frameView = m_renderView->frameView();
m_clipLayer->setSize(frameView->visibleContentRect(false /* exclude scrollbars */).size());
}
}
void RenderLayerCompositor::didStartAcceleratedAnimation(CSSPropertyID property)
{
// If an accelerated animation or transition runs, we have to turn off overlap checking because
// we don't do layout for every frame, but we have to ensure that the layering is
// correct between the animating object and other objects on the page.
if (property == CSSPropertyWebkitTransform)
setCompositingConsultsOverlap(false);
}
bool RenderLayerCompositor::has3DContent() const
{
return layerHas3DContent(rootRenderLayer());
}
bool RenderLayerCompositor::allowsIndependentlyCompositedFrames(const FrameView* view)
{
#if PLATFORM(MAC)
// frames are only independently composited in Mac pre-WebKit2.
return view->platformWidget();
#endif
return false;
}
bool RenderLayerCompositor::shouldPropagateCompositingToEnclosingFrame() const
{
#if PLATFORM(ANDROID)
if (enclosingFrameElement() && !allowsIndependentlyCompositedFrames(m_renderView->frameView()))
return true;
#endif
// Parent document content needs to be able to render on top of a composited frame, so correct behavior
// is to have the parent document become composited too. However, this can cause problems on platforms that
// use native views for frames (like Mac), so disable that behavior on those platforms for now.
HTMLFrameOwnerElement* ownerElement = enclosingFrameElement();
RenderObject* renderer = ownerElement ? ownerElement->renderer() : 0;
// If we are the top-level frame, don't propagate.
if (!ownerElement)
return false;
if (!allowsIndependentlyCompositedFrames(m_renderView->frameView()))
return true;
if (!renderer || !renderer->isRenderPart())
return false;
// On Mac, only propagate compositing if the frame is overlapped in the parent
// document, or the parent is already compositing, or the main frame is scaled.
Frame* frame = m_renderView->frameView()->frame();
Page* page = frame ? frame->page() : 0;
if (page->mainFrame()->pageScaleFactor() != 1)
return true;
RenderPart* frameRenderer = toRenderPart(renderer);
if (frameRenderer->widget()) {
ASSERT(frameRenderer->widget()->isFrameView());
FrameView* view = static_cast<FrameView*>(frameRenderer->widget());
if (view->isOverlappedIncludingAncestors() || view->hasCompositingAncestor())
return true;
}
return false;
}
HTMLFrameOwnerElement* RenderLayerCompositor::enclosingFrameElement() const
{
if (HTMLFrameOwnerElement* ownerElement = m_renderView->document()->ownerElement())
return (ownerElement->hasTagName(iframeTag) || ownerElement->hasTagName(frameTag) || ownerElement->hasTagName(objectTag)) ? ownerElement : 0;
return 0;
}
bool RenderLayerCompositor::needsToBeComposited(const RenderLayer* layer) const
{
if (!canBeComposited(layer))
return false;
// The root layer always has a compositing layer, but it may not have backing.
return requiresCompositingLayer(layer) || layer->mustOverlapCompositedLayers() || (inCompositingMode() && layer->isRootLayer());
}
#if PLATFORM(ANDROID)
bool RenderLayerCompositor::requiresCompositingForAndroidLayers(const RenderLayer* layer) const
{
#if ENABLE(ANDROID_OVERFLOW_SCROLL)
if (layer->hasOverflowScroll())
return true;
if (layer->isRootLayer() && m_renderView->frameView()->hasOverflowScroll())
return true;
#endif
#if ENABLE(COMPOSITED_FIXED_ELEMENTS)
// Enable composited layers (for fixed elements)
if (layer->isFixed())
return true;
#endif
return false;
}
#endif
// Note: this specifies whether the RL needs a compositing layer for intrinsic reasons.
// Use needsToBeComposited() to determine if a RL actually needs a compositing layer.
// static
bool RenderLayerCompositor::requiresCompositingLayer(const RenderLayer* layer) const
{
RenderObject* renderer = layer->renderer();
// The compositing state of a reflection should match that of its reflected layer.
if (layer->isReflection()) {
renderer = renderer->parent(); // The RenderReplica's parent is the object being reflected.
layer = toRenderBoxModelObject(renderer)->layer();
}
return requiresCompositingForTransform(renderer)
#if PLATFORM(ANDROID)
|| requiresCompositingForAndroidLayers(layer)
#endif
|| requiresCompositingForVideo(renderer)
|| requiresCompositingForCanvas(renderer)
|| requiresCompositingForPlugin(renderer)
|| requiresCompositingForFrame(renderer)
|| (canRender3DTransforms() && renderer->style()->backfaceVisibility() == BackfaceVisibilityHidden)
|| clipsCompositingDescendants(layer)
|| requiresCompositingForAnimation(renderer)
|| requiresCompositingForFullScreen(renderer);
}
bool RenderLayerCompositor::canBeComposited(const RenderLayer* layer) const
{
return m_hasAcceleratedCompositing && layer->isSelfPaintingLayer();
}
// Return true if the given layer has some ancestor in the RenderLayer hierarchy that clips,
// up to the enclosing compositing ancestor. This is required because compositing layers are parented
// according to the z-order hierarchy, yet clipping goes down the renderer hierarchy.
// Thus, a RenderLayer can be clipped by a RenderLayer that is an ancestor in the renderer hierarchy,
// but a sibling in the z-order hierarchy.
bool RenderLayerCompositor::clippedByAncestor(RenderLayer* layer) const
{
if (!layer->isComposited() || !layer->parent())
return false;
RenderLayer* compositingAncestor = layer->ancestorCompositingLayer();
if (!compositingAncestor)
return false;
// If the compositingAncestor clips, that will be taken care of by clipsCompositingDescendants(),
// so we only care about clipping between its first child that is our ancestor (the computeClipRoot),
// and layer.
RenderLayer* computeClipRoot = 0;
RenderLayer* curr = layer;
while (curr) {
RenderLayer* next = curr->parent();
if (next == compositingAncestor) {
computeClipRoot = curr;
break;
}
curr = next;
}
if (!computeClipRoot || computeClipRoot == layer)
return false;
IntRect backgroundRect = layer->backgroundClipRect(computeClipRoot, true);
return backgroundRect != PaintInfo::infiniteRect();
}
// Return true if the given layer is a stacking context and has compositing child
// layers that it needs to clip. In this case we insert a clipping GraphicsLayer
// into the hierarchy between this layer and its children in the z-order hierarchy.
bool RenderLayerCompositor::clipsCompositingDescendants(const RenderLayer* layer) const
{
#if ENABLE(ANDROID_OVERFLOW_SCROLL)
if (layer->hasOverflowScroll())
return false;
#endif
return layer->hasCompositingDescendant() &&
(layer->renderer()->hasOverflowClip() || layer->renderer()->hasClip());
}
bool RenderLayerCompositor::requiresCompositingForTransform(RenderObject* renderer) const
{
if (!(m_compositingTriggers & ChromeClient::ThreeDTransformTrigger))
return false;
RenderStyle* style = renderer->style();
// Note that we ask the renderer if it has a transform, because the style may have transforms,
// but the renderer may be an inline that doesn't suppport them.
return renderer->hasTransform() && (style->transform().has3DOperation() || style->transformStyle3D() == TransformStyle3DPreserve3D || style->hasPerspective());
}
bool RenderLayerCompositor::requiresCompositingForVideo(RenderObject* renderer) const
{
if (!(m_compositingTriggers & ChromeClient::VideoTrigger))
return false;
#if ENABLE(VIDEO)
if (renderer->isVideo()) {
RenderVideo* video = toRenderVideo(renderer);
return video->shouldDisplayVideo() && canAccelerateVideoRendering(video);
}
#if ENABLE(PLUGIN_PROXY_FOR_VIDEO)
else if (renderer->isRenderPart()) {
if (!m_hasAcceleratedCompositing)
return false;
Node* node = renderer->node();
if (!node || (!node->hasTagName(HTMLNames::videoTag) && !node->hasTagName(HTMLNames::audioTag)))
return false;
HTMLMediaElement* mediaElement = static_cast<HTMLMediaElement*>(node);
return mediaElement->player() ? mediaElement->player()->supportsAcceleratedRendering() : false;
}
#endif // ENABLE(PLUGIN_PROXY_FOR_VIDEO)
#else
UNUSED_PARAM(renderer);
#endif
return false;
}
bool RenderLayerCompositor::requiresCompositingForCanvas(RenderObject* renderer) const
{
if (!(m_compositingTriggers & ChromeClient::CanvasTrigger))
return false;
if (renderer->isCanvas()) {
HTMLCanvasElement* canvas = static_cast<HTMLCanvasElement*>(renderer->node());
return canvas->renderingContext() && canvas->renderingContext()->isAccelerated();
}
return false;
}
bool RenderLayerCompositor::requiresCompositingForPlugin(RenderObject* renderer) const
{
if (!(m_compositingTriggers & ChromeClient::PluginTrigger))
return false;
bool composite = (renderer->isEmbeddedObject() && toRenderEmbeddedObject(renderer)->allowsAcceleratedCompositing())
|| (renderer->isApplet() && toRenderApplet(renderer)->allowsAcceleratedCompositing());
if (!composite)
return false;
m_compositingDependsOnGeometry = true;
RenderWidget* pluginRenderer = toRenderWidget(renderer);
// If we can't reliably know the size of the plugin yet, don't change compositing state.
if (pluginRenderer->needsLayout())
return pluginRenderer->hasLayer() && pluginRenderer->layer()->isComposited();
// Don't go into compositing mode if height or width are zero, or size is 1x1.
IntRect contentBox = pluginRenderer->contentBoxRect();
#if PLATFORM(ANDROID)
// allow all plugins including 1x1 to be composited, so that they are drawn,
// and acquire an ANativeWindow on the UI thread
return contentBox.height() * contentBox.width() > 0;
#else
return contentBox.height() * contentBox.width() > 1;
#endif
}
bool RenderLayerCompositor::requiresCompositingForFrame(RenderObject* renderer) const
{
if (!renderer->isRenderPart())
return false;
RenderPart* frameRenderer = toRenderPart(renderer);
if (!frameRenderer->requiresAcceleratedCompositing())
return false;
m_compositingDependsOnGeometry = true;
RenderLayerCompositor* innerCompositor = frameContentsCompositor(frameRenderer);
if (!innerCompositor || !innerCompositor->shouldPropagateCompositingToEnclosingFrame())
return false;
// If we can't reliably know the size of the iframe yet, don't change compositing state.
if (renderer->needsLayout())
return frameRenderer->hasLayer() && frameRenderer->layer()->isComposited();
// Don't go into compositing mode if height or width are zero.
IntRect contentBox = frameRenderer->contentBoxRect();
return contentBox.height() * contentBox.width() > 0;
}
bool RenderLayerCompositor::requiresCompositingForAnimation(RenderObject* renderer) const
{
if (!(m_compositingTriggers & ChromeClient::AnimationTrigger))
return false;
if (AnimationController* animController = renderer->animation()) {
#if PLATFORM(ANDROID)
// android renders an opacity animation much faster if it's composited
return (animController->isRunningAnimationOnRenderer(renderer, CSSPropertyOpacity))
#else
return (animController->isRunningAnimationOnRenderer(renderer, CSSPropertyOpacity) && inCompositingMode())
#endif
|| animController->isRunningAnimationOnRenderer(renderer, CSSPropertyWebkitTransform);
}
return false;
}
bool RenderLayerCompositor::requiresCompositingWhenDescendantsAreCompositing(RenderObject* renderer) const
{
return renderer->hasTransform() || renderer->isTransparent() || renderer->hasMask() || renderer->hasReflection();
}
bool RenderLayerCompositor::requiresCompositingForFullScreen(RenderObject* renderer) const
{
#if ENABLE(FULLSCREEN_API)
return renderer->isRenderFullScreen() && toRenderFullScreen(renderer)->isAnimating();
#else
UNUSED_PARAM(renderer);
return false;
#endif
}
// If an element has negative z-index children, those children render in front of the
// layer background, so we need an extra 'contents' layer for the foreground of the layer
// object.
bool RenderLayerCompositor::needsContentsCompositingLayer(const RenderLayer* layer) const
{
return (layer->m_negZOrderList && layer->m_negZOrderList->size() > 0);
}
bool RenderLayerCompositor::requiresScrollLayer(RootLayerAttachment attachment) const
{
// We need to handle our own scrolling if we're:
return !m_renderView->frameView()->platformWidget() // viewless (i.e. non-Mac, or Mac in WebKit2)
|| attachment == RootLayerAttachedViaEnclosingFrame; // a composited frame on Mac
}
static void paintScrollbar(Scrollbar* scrollbar, GraphicsContext& context, const IntRect& clip)
{
if (!scrollbar)
return;
context.save();
const IntRect& scrollbarRect = scrollbar->frameRect();
context.translate(-scrollbarRect.x(), -scrollbarRect.y());
IntRect transformedClip = clip;
transformedClip.move(scrollbarRect.x(), scrollbarRect.y());
scrollbar->paint(&context, transformedClip);
context.restore();
}
void RenderLayerCompositor::paintContents(const GraphicsLayer* graphicsLayer, GraphicsContext& context, GraphicsLayerPaintingPhase, const IntRect& clip)
{
if (graphicsLayer == layerForHorizontalScrollbar())
paintScrollbar(m_renderView->frameView()->horizontalScrollbar(), context, clip);
else if (graphicsLayer == layerForVerticalScrollbar())
paintScrollbar(m_renderView->frameView()->verticalScrollbar(), context, clip);
else if (graphicsLayer == layerForScrollCorner()) {
const IntRect& scrollCorner = m_renderView->frameView()->scrollCornerRect();
context.save();
context.translate(-scrollCorner.x(), -scrollCorner.y());
IntRect transformedClip = clip;
transformedClip.move(scrollCorner.x(), scrollCorner.y());
m_renderView->frameView()->paintScrollCorner(&context, transformedClip);
context.restore();
}
}
static bool shouldCompositeOverflowControls(ScrollView* view)
{
if (view->platformWidget())
return false;
#if !PLATFORM(CHROMIUM)
if (!view->hasOverlayScrollbars())
return false;
#endif
return true;
}
bool RenderLayerCompositor::requiresHorizontalScrollbarLayer() const
{
ScrollView* view = m_renderView->frameView();
return shouldCompositeOverflowControls(view) && view->horizontalScrollbar();
}
bool RenderLayerCompositor::requiresVerticalScrollbarLayer() const
{
ScrollView* view = m_renderView->frameView();
return shouldCompositeOverflowControls(view) && view->verticalScrollbar();
}
bool RenderLayerCompositor::requiresScrollCornerLayer() const
{
ScrollView* view = m_renderView->frameView();
return shouldCompositeOverflowControls(view) && view->isScrollCornerVisible();
}
void RenderLayerCompositor::updateOverflowControlsLayers()
{
bool layersChanged = false;
if (requiresHorizontalScrollbarLayer()) {
m_layerForHorizontalScrollbar = GraphicsLayer::create(this);
#ifndef NDEBUG
m_layerForHorizontalScrollbar->setName("horizontal scrollbar");
#endif
m_overflowControlsHostLayer->addChild(m_layerForHorizontalScrollbar.get());
layersChanged = true;
} else if (m_layerForHorizontalScrollbar) {
m_layerForHorizontalScrollbar->removeFromParent();
m_layerForHorizontalScrollbar = 0;
layersChanged = true;
}
if (requiresVerticalScrollbarLayer()) {
m_layerForVerticalScrollbar = GraphicsLayer::create(this);
#ifndef NDEBUG
m_layerForVerticalScrollbar->setName("vertical scrollbar");
#endif
m_overflowControlsHostLayer->addChild(m_layerForVerticalScrollbar.get());
layersChanged = true;
} else if (m_layerForVerticalScrollbar) {
m_layerForVerticalScrollbar->removeFromParent();
m_layerForVerticalScrollbar = 0;
layersChanged = true;
}
if (requiresScrollCornerLayer()) {
m_layerForScrollCorner = GraphicsLayer::create(this);
#ifndef NDEBUG
m_layerForScrollCorner->setName("scroll corner");
#endif
m_overflowControlsHostLayer->addChild(m_layerForScrollCorner.get());
layersChanged = true;
} else if (m_layerForScrollCorner) {
m_layerForScrollCorner->removeFromParent();
m_layerForScrollCorner = 0;
layersChanged = true;
}
if (layersChanged)
m_renderView->frameView()->positionScrollbarLayers();
}
void RenderLayerCompositor::ensureRootPlatformLayer()
{
RootLayerAttachment expectedAttachment = shouldPropagateCompositingToEnclosingFrame() ? RootLayerAttachedViaEnclosingFrame : RootLayerAttachedViaChromeClient;
if (expectedAttachment == m_rootLayerAttachment)
return;
if (!m_rootPlatformLayer) {
m_rootPlatformLayer = GraphicsLayer::create(0);
#ifndef NDEBUG
m_rootPlatformLayer->setName("Root platform");
#endif
m_rootPlatformLayer->setSize(FloatSize(m_renderView->maxXLayoutOverflow(), m_renderView->maxYLayoutOverflow()));
m_rootPlatformLayer->setPosition(FloatPoint());
// Need to clip to prevent transformed content showing outside this frame
m_rootPlatformLayer->setMasksToBounds(true);
}
if (requiresScrollLayer(expectedAttachment)) {
if (!m_overflowControlsHostLayer) {
ASSERT(!m_scrollLayer);
ASSERT(!m_clipLayer);
// Create a layer to host the clipping layer and the overflow controls layers.
m_overflowControlsHostLayer = GraphicsLayer::create(0);
#ifndef NDEBUG
m_overflowControlsHostLayer->setName("overflow controls host");
#endif
// Create a clipping layer if this is an iframe
m_clipLayer = GraphicsLayer::create(this);
#ifndef NDEBUG
m_clipLayer->setName("iframe Clipping");
#endif
m_clipLayer->setMasksToBounds(true);
m_scrollLayer = GraphicsLayer::create(this);
#ifndef NDEBUG
m_scrollLayer->setName("iframe scrolling");
#endif
// Hook them up
m_overflowControlsHostLayer->addChild(m_clipLayer.get());
m_clipLayer->addChild(m_scrollLayer.get());
m_scrollLayer->addChild(m_rootPlatformLayer.get());
frameViewDidChangeSize();
frameViewDidScroll(m_renderView->frameView()->scrollPosition());
}
} else {
if (m_overflowControlsHostLayer) {
m_overflowControlsHostLayer = 0;
m_clipLayer = 0;
m_scrollLayer = 0;
}
}
// Check to see if we have to change the attachment
if (m_rootLayerAttachment != RootLayerUnattached)
detachRootPlatformLayer();
attachRootPlatformLayer(expectedAttachment);
}
void RenderLayerCompositor::destroyRootPlatformLayer()
{
if (!m_rootPlatformLayer)
return;
detachRootPlatformLayer();
if (m_layerForHorizontalScrollbar) {
m_layerForHorizontalScrollbar->removeFromParent();
m_layerForHorizontalScrollbar = 0;
if (Scrollbar* horizontalScrollbar = m_renderView->frameView()->verticalScrollbar())
m_renderView->frameView()->invalidateScrollbar(horizontalScrollbar, IntRect(IntPoint(0, 0), horizontalScrollbar->frameRect().size()));
}
if (m_layerForVerticalScrollbar) {
m_layerForVerticalScrollbar->removeFromParent();
m_layerForVerticalScrollbar = 0;
if (Scrollbar* verticalScrollbar = m_renderView->frameView()->verticalScrollbar())
m_renderView->frameView()->invalidateScrollbar(verticalScrollbar, IntRect(IntPoint(0, 0), verticalScrollbar->frameRect().size()));
}
if (m_layerForScrollCorner) {
m_layerForScrollCorner = 0;
m_renderView->frameView()->invalidateScrollCorner();
}
if (m_overflowControlsHostLayer) {
m_overflowControlsHostLayer = 0;
m_clipLayer = 0;
m_scrollLayer = 0;
}
ASSERT(!m_scrollLayer);
m_rootPlatformLayer = 0;
}
void RenderLayerCompositor::attachRootPlatformLayer(RootLayerAttachment attachment)
{
if (!m_rootPlatformLayer)
return;
switch (attachment) {
case RootLayerUnattached:
ASSERT_NOT_REACHED();
break;
case RootLayerAttachedViaChromeClient: {
Frame* frame = m_renderView->frameView()->frame();
Page* page = frame ? frame->page() : 0;
if (!page)
return;
page->chrome()->client()->attachRootGraphicsLayer(frame, rootPlatformLayer());
break;
}
case RootLayerAttachedViaEnclosingFrame: {
// The layer will get hooked up via RenderLayerBacking::updateGraphicsLayerConfiguration()
// for the frame's renderer in the parent document.
scheduleNeedsStyleRecalc(m_renderView->document()->ownerElement());
break;
}
}
m_rootLayerAttachment = attachment;
rootLayerAttachmentChanged();
}
void RenderLayerCompositor::detachRootPlatformLayer()
{
if (!m_rootPlatformLayer || m_rootLayerAttachment == RootLayerUnattached)
return;
switch (m_rootLayerAttachment) {
case RootLayerAttachedViaEnclosingFrame: {
// The layer will get unhooked up via RenderLayerBacking::updateGraphicsLayerConfiguration()
// for the frame's renderer in the parent document.
if (m_overflowControlsHostLayer)
m_overflowControlsHostLayer->removeFromParent();
else
m_rootPlatformLayer->removeFromParent();
if (HTMLFrameOwnerElement* ownerElement = m_renderView->document()->ownerElement())
scheduleNeedsStyleRecalc(ownerElement);
break;
}
case RootLayerAttachedViaChromeClient: {
Frame* frame = m_renderView->frameView()->frame();
Page* page = frame ? frame->page() : 0;
if (!page)
return;
page->chrome()->client()->attachRootGraphicsLayer(frame, 0);
}
break;
case RootLayerUnattached:
break;
}
m_rootLayerAttachment = RootLayerUnattached;
rootLayerAttachmentChanged();
}
void RenderLayerCompositor::updateRootLayerAttachment()
{
ensureRootPlatformLayer();
}
void RenderLayerCompositor::rootLayerAttachmentChanged()
{
// The attachment can affect whether the RenderView layer's paintingGoesToWindow() behavior,
// so call updateGraphicsLayerGeometry() to udpate that.
RenderLayer* layer = m_renderView->layer();
if (RenderLayerBacking* backing = layer ? layer->backing() : 0)
backing->updateDrawsContent();
}
static void needsStyleRecalcCallback(Node* node)
{
node->setNeedsStyleRecalc(SyntheticStyleChange);
}
void RenderLayerCompositor::scheduleNeedsStyleRecalc(Element* element)
{
if (ContainerNode::postAttachCallbacksAreSuspended())
ContainerNode::queuePostAttachCallback(needsStyleRecalcCallback, element);
else
element->setNeedsStyleRecalc(SyntheticStyleChange);
}
// IFrames are special, because we hook compositing layers together across iframe boundaries
// when both parent and iframe content are composited. So when this frame becomes composited, we have
// to use a synthetic style change to get the iframes into RenderLayers in order to allow them to composite.
void RenderLayerCompositor::notifyIFramesOfCompositingChange()
{
Frame* frame = m_renderView->frameView() ? m_renderView->frameView()->frame() : 0;
if (!frame)
return;
for (Frame* child = frame->tree()->firstChild(); child; child = child->tree()->traverseNext(frame)) {
if (child->document() && child->document()->ownerElement())
scheduleNeedsStyleRecalc(child->document()->ownerElement());
}
// Compositing also affects the answer to RenderIFrame::requiresAcceleratedCompositing(), so
// we need to schedule a style recalc in our parent document.
if (HTMLFrameOwnerElement* ownerElement = m_renderView->document()->ownerElement())
scheduleNeedsStyleRecalc(ownerElement);
}
bool RenderLayerCompositor::layerHas3DContent(const RenderLayer* layer) const
{
const RenderStyle* style = layer->renderer()->style();
if (style &&
(style->transformStyle3D() == TransformStyle3DPreserve3D ||
style->hasPerspective() ||
style->transform().has3DOperation()))
return true;
if (layer->isStackingContext()) {
if (Vector<RenderLayer*>* negZOrderList = layer->negZOrderList()) {
size_t listSize = negZOrderList->size();
for (size_t i = 0; i < listSize; ++i) {
RenderLayer* curLayer = negZOrderList->at(i);
if (layerHas3DContent(curLayer))
return true;
}
}
if (Vector<RenderLayer*>* posZOrderList = layer->posZOrderList()) {
size_t listSize = posZOrderList->size();
for (size_t i = 0; i < listSize; ++i) {
RenderLayer* curLayer = posZOrderList->at(i);
if (layerHas3DContent(curLayer))
return true;
}
}
}
if (Vector<RenderLayer*>* normalFlowList = layer->normalFlowList()) {
size_t listSize = normalFlowList->size();
for (size_t i = 0; i < listSize; ++i) {
RenderLayer* curLayer = normalFlowList->at(i);
if (layerHas3DContent(curLayer))
return true;
}
}
return false;
}
void RenderLayerCompositor::updateContentsScale(float scale, RenderLayer* layer)
{
if (!layer)
layer = rootRenderLayer();
layer->updateContentsScale(scale);
if (layer->isStackingContext()) {
if (Vector<RenderLayer*>* negZOrderList = layer->negZOrderList()) {
size_t listSize = negZOrderList->size();
for (size_t i = 0; i < listSize; ++i)
updateContentsScale(scale, negZOrderList->at(i));
}
if (Vector<RenderLayer*>* posZOrderList = layer->posZOrderList()) {
size_t listSize = posZOrderList->size();
for (size_t i = 0; i < listSize; ++i)
updateContentsScale(scale, posZOrderList->at(i));
}
}
if (Vector<RenderLayer*>* normalFlowList = layer->normalFlowList()) {
size_t listSize = normalFlowList->size();
for (size_t i = 0; i < listSize; ++i)
updateContentsScale(scale, normalFlowList->at(i));
}
}
} // namespace WebCore
#endif // USE(ACCELERATED_COMPOSITING)