| /* |
| * Copyright (C) 1999 Lars Knoll (knoll@kde.org) |
| * (C) 1999 Antti Koivisto (koivisto@kde.org) |
| * (C) 2005 Allan Sandfeld Jensen (kde@carewolf.com) |
| * (C) 2005, 2006 Samuel Weinig (sam.weinig@gmail.com) |
| * Copyright (C) 2005, 2006, 2007, 2008, 2009, 2013 Apple Inc. All rights reserved. |
| * Copyright (C) 2010 Google Inc. All rights reserved. |
| * |
| * This library is free software; you can redistribute it and/or |
| * modify it under the terms of the GNU Library General Public |
| * License as published by the Free Software Foundation; either |
| * version 2 of the License, or (at your option) any later version. |
| * |
| * This library is distributed in the hope that it will be useful, |
| * but WITHOUT ANY WARRANTY; without even the implied warranty of |
| * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU |
| * Library General Public License for more details. |
| * |
| * You should have received a copy of the GNU Library General Public License |
| * along with this library; see the file COPYING.LIB. If not, write to |
| * the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, |
| * Boston, MA 02110-1301, USA. |
| * |
| */ |
| |
| #include "config.h" |
| #include "RenderBoxModelObject.h" |
| |
| #include "BitmapImage.h" |
| #include "BorderEdge.h" |
| #include "CachedImage.h" |
| #include "FloatRoundedRect.h" |
| #include "Frame.h" |
| #include "FrameView.h" |
| #include "GeometryUtilities.h" |
| #include "GraphicsContext.h" |
| #include "HTMLFrameOwnerElement.h" |
| #include "HTMLFrameSetElement.h" |
| #include "HTMLImageElement.h" |
| #include "HTMLNames.h" |
| #include "ImageBuffer.h" |
| #include "ImageQualityController.h" |
| #include "Path.h" |
| #include "RenderBlock.h" |
| #include "RenderFlexibleBox.h" |
| #include "RenderFragmentContainer.h" |
| #include "RenderInline.h" |
| #include "RenderLayer.h" |
| #include "RenderLayerBacking.h" |
| #include "RenderLayerCompositor.h" |
| #include "RenderMultiColumnFlow.h" |
| #include "RenderTable.h" |
| #include "RenderTableRow.h" |
| #include "RenderText.h" |
| #include "RenderTextFragment.h" |
| #include "RenderTreeBuilder.h" |
| #include "RenderView.h" |
| #include "ScrollingConstraints.h" |
| #include "Settings.h" |
| #include "TransformState.h" |
| #include <wtf/IsoMallocInlines.h> |
| #include <wtf/NeverDestroyed.h> |
| #if !ASSERT_DISABLED |
| #include <wtf/SetForScope.h> |
| #endif |
| |
| #if PLATFORM(IOS) |
| #include "RuntimeApplicationChecks.h" |
| #endif |
| |
| namespace WebCore { |
| |
| using namespace HTMLNames; |
| |
| WTF_MAKE_ISO_ALLOCATED_IMPL(RenderBoxModelObject); |
| |
| // The HashMap for storing continuation pointers. |
| // An inline can be split with blocks occuring in between the inline content. |
| // When this occurs we need a pointer to the next object. We can basically be |
| // split into a sequence of inlines and blocks. The continuation will either be |
| // an anonymous block (that houses other blocks) or it will be an inline flow. |
| // <b><i><p>Hello</p></i></b>. In this example the <i> will have a block as |
| // its continuation but the <b> will just have an inline as its continuation. |
| RenderBoxModelObject::ContinuationChainNode::ContinuationChainNode(RenderBoxModelObject& renderer) |
| : renderer(makeWeakPtr(renderer)) |
| { |
| } |
| |
| RenderBoxModelObject::ContinuationChainNode::~ContinuationChainNode() |
| { |
| if (next) { |
| ASSERT(previous); |
| ASSERT(next->previous == this); |
| next->previous = previous; |
| } |
| if (previous) { |
| ASSERT(previous->next == this); |
| previous->next = next; |
| } |
| } |
| |
| void RenderBoxModelObject::ContinuationChainNode::insertAfter(ContinuationChainNode& after) |
| { |
| ASSERT(!previous); |
| ASSERT(!next); |
| if ((next = after.next)) { |
| ASSERT(next->previous == &after); |
| next->previous = this; |
| } |
| previous = &after; |
| after.next = this; |
| } |
| |
| using ContinuationChainNodeMap = HashMap<const RenderBoxModelObject*, std::unique_ptr<RenderBoxModelObject::ContinuationChainNode>>; |
| |
| static ContinuationChainNodeMap& continuationChainNodeMap() |
| { |
| static NeverDestroyed<ContinuationChainNodeMap> map; |
| return map; |
| } |
| |
| using FirstLetterRemainingTextMap = HashMap<const RenderBoxModelObject*, WeakPtr<RenderTextFragment>>; |
| |
| static FirstLetterRemainingTextMap& firstLetterRemainingTextMap() |
| { |
| static NeverDestroyed<FirstLetterRemainingTextMap> map; |
| return map; |
| } |
| |
| void RenderBoxModelObject::setSelectionState(SelectionState state) |
| { |
| if (state == SelectionInside && selectionState() != SelectionNone) |
| return; |
| |
| if ((state == SelectionStart && selectionState() == SelectionEnd) |
| || (state == SelectionEnd && selectionState() == SelectionStart)) |
| RenderLayerModelObject::setSelectionState(SelectionBoth); |
| else |
| RenderLayerModelObject::setSelectionState(state); |
| |
| // FIXME: We should consider whether it is OK propagating to ancestor RenderInlines. |
| // This is a workaround for http://webkit.org/b/32123 |
| // The containing block can be null in case of an orphaned tree. |
| RenderBlock* containingBlock = this->containingBlock(); |
| if (containingBlock && !containingBlock->isRenderView()) |
| containingBlock->setSelectionState(state); |
| } |
| |
| void RenderBoxModelObject::contentChanged(ContentChangeType changeType) |
| { |
| if (!hasLayer()) |
| return; |
| |
| layer()->contentChanged(changeType); |
| } |
| |
| bool RenderBoxModelObject::hasAcceleratedCompositing() const |
| { |
| return view().compositor().hasAcceleratedCompositing(); |
| } |
| |
| bool RenderBoxModelObject::startTransition(double timeOffset, CSSPropertyID propertyId, const RenderStyle* fromStyle, const RenderStyle* toStyle) |
| { |
| ASSERT(hasLayer()); |
| ASSERT(isComposited()); |
| return layer()->backing()->startTransition(timeOffset, propertyId, fromStyle, toStyle); |
| } |
| |
| void RenderBoxModelObject::transitionPaused(double timeOffset, CSSPropertyID propertyId) |
| { |
| ASSERT(hasLayer()); |
| ASSERT(isComposited()); |
| layer()->backing()->transitionPaused(timeOffset, propertyId); |
| } |
| |
| void RenderBoxModelObject::transitionFinished(CSSPropertyID propertyId) |
| { |
| ASSERT(hasLayer()); |
| ASSERT(isComposited()); |
| layer()->backing()->transitionFinished(propertyId); |
| } |
| |
| bool RenderBoxModelObject::startAnimation(double timeOffset, const Animation* animation, const KeyframeList& keyframes) |
| { |
| ASSERT(hasLayer()); |
| ASSERT(isComposited()); |
| return layer()->backing()->startAnimation(timeOffset, animation, keyframes); |
| } |
| |
| void RenderBoxModelObject::animationPaused(double timeOffset, const String& name) |
| { |
| ASSERT(hasLayer()); |
| ASSERT(isComposited()); |
| layer()->backing()->animationPaused(timeOffset, name); |
| } |
| |
| void RenderBoxModelObject::animationSeeked(double timeOffset, const String& name) |
| { |
| ASSERT(hasLayer()); |
| ASSERT(isComposited()); |
| layer()->backing()->animationSeeked(timeOffset, name); |
| } |
| |
| void RenderBoxModelObject::animationFinished(const String& name) |
| { |
| ASSERT(hasLayer()); |
| ASSERT(isComposited()); |
| layer()->backing()->animationFinished(name); |
| } |
| |
| void RenderBoxModelObject::suspendAnimations(MonotonicTime time) |
| { |
| ASSERT(hasLayer()); |
| ASSERT(isComposited()); |
| layer()->backing()->suspendAnimations(time); |
| } |
| |
| RenderBoxModelObject::RenderBoxModelObject(Element& element, RenderStyle&& style, BaseTypeFlags baseTypeFlags) |
| : RenderLayerModelObject(element, WTFMove(style), baseTypeFlags | RenderBoxModelObjectFlag) |
| { |
| } |
| |
| RenderBoxModelObject::RenderBoxModelObject(Document& document, RenderStyle&& style, BaseTypeFlags baseTypeFlags) |
| : RenderLayerModelObject(document, WTFMove(style), baseTypeFlags | RenderBoxModelObjectFlag) |
| { |
| } |
| |
| RenderBoxModelObject::~RenderBoxModelObject() |
| { |
| // Do not add any code here. Add it to willBeDestroyed() instead. |
| ASSERT(!continuation()); |
| } |
| |
| void RenderBoxModelObject::willBeDestroyed() |
| { |
| if (hasContinuationChainNode()) |
| removeFromContinuationChain(); |
| |
| if (isFirstLetter()) |
| clearFirstLetterRemainingText(); |
| |
| if (!renderTreeBeingDestroyed()) |
| view().imageQualityController().rendererWillBeDestroyed(*this); |
| |
| RenderLayerModelObject::willBeDestroyed(); |
| } |
| |
| bool RenderBoxModelObject::hasVisibleBoxDecorationStyle() const |
| { |
| return hasBackground() || style().hasVisibleBorderDecoration() || style().hasAppearance() || style().boxShadow(); |
| } |
| |
| void RenderBoxModelObject::updateFromStyle() |
| { |
| RenderLayerModelObject::updateFromStyle(); |
| |
| // Set the appropriate bits for a box model object. Since all bits are cleared in styleWillChange, |
| // we only check for bits that could possibly be set to true. |
| const RenderStyle& styleToUse = style(); |
| setHasVisibleBoxDecorations(hasVisibleBoxDecorationStyle()); |
| setInline(styleToUse.isDisplayInlineType()); |
| setPositionState(styleToUse.position()); |
| setHorizontalWritingMode(styleToUse.isHorizontalWritingMode()); |
| if (styleToUse.isFlippedBlocksWritingMode()) |
| view().frameView().setHasFlippedBlockRenderers(true); |
| } |
| |
| static LayoutSize accumulateInFlowPositionOffsets(const RenderObject* child) |
| { |
| if (!child->isAnonymousBlock() || !child->isInFlowPositioned()) |
| return LayoutSize(); |
| LayoutSize offset; |
| for (RenderElement* parent = downcast<RenderBlock>(*child).inlineContinuation(); is<RenderInline>(parent); parent = parent->parent()) { |
| if (parent->isInFlowPositioned()) |
| offset += downcast<RenderInline>(*parent).offsetForInFlowPosition(); |
| } |
| return offset; |
| } |
| |
| static inline bool isOutOfFlowPositionedWithImplicitHeight(const RenderBoxModelObject& child) |
| { |
| return child.isOutOfFlowPositioned() && !child.style().logicalTop().isAuto() && !child.style().logicalBottom().isAuto(); |
| } |
| |
| RenderBlock* RenderBoxModelObject::containingBlockForAutoHeightDetection(Length logicalHeight) const |
| { |
| // For percentage heights: The percentage is calculated with respect to the |
| // height of the generated box's containing block. If the height of the |
| // containing block is not specified explicitly (i.e., it depends on content |
| // height), and this element is not absolutely positioned, the used height is |
| // calculated as if 'auto' was specified. |
| if (!logicalHeight.isPercentOrCalculated() || isOutOfFlowPositioned()) |
| return nullptr; |
| |
| // Anonymous block boxes are ignored when resolving percentage values that |
| // would refer to it: the closest non-anonymous ancestor box is used instead. |
| auto* cb = containingBlock(); |
| while (cb && cb->isAnonymous() && !is<RenderView>(cb)) |
| cb = cb->containingBlock(); |
| if (!cb) |
| return nullptr; |
| |
| // Matching RenderBox::percentageLogicalHeightIsResolvable() by |
| // ignoring table cell's attribute value, where it says that table cells |
| // violate what the CSS spec says to do with heights. Basically we don't care |
| // if the cell specified a height or not. |
| if (cb->isTableCell()) |
| return nullptr; |
| |
| // Match RenderBox::availableLogicalHeightUsing by special casing the layout |
| // view. The available height is taken from the frame. |
| if (cb->isRenderView()) |
| return nullptr; |
| |
| if (isOutOfFlowPositionedWithImplicitHeight(*cb)) |
| return nullptr; |
| |
| return cb; |
| } |
| |
| bool RenderBoxModelObject::hasAutoHeightOrContainingBlockWithAutoHeight() const |
| { |
| const auto* thisBox = isBox() ? downcast<RenderBox>(this) : nullptr; |
| Length logicalHeightLength = style().logicalHeight(); |
| auto* cb = containingBlockForAutoHeightDetection(logicalHeightLength); |
| |
| if (logicalHeightLength.isPercentOrCalculated() && cb && isBox()) |
| cb->addPercentHeightDescendant(*const_cast<RenderBox*>(downcast<RenderBox>(this))); |
| |
| if (thisBox && thisBox->isFlexItem()) { |
| auto& flexBox = downcast<RenderFlexibleBox>(*parent()); |
| if (flexBox.childLogicalHeightForPercentageResolution(*thisBox)) |
| return false; |
| } |
| |
| if (thisBox && thisBox->isGridItem() && thisBox->hasOverrideContainingBlockLogicalHeight()) |
| return false; |
| |
| if (logicalHeightLength.isAuto() && !isOutOfFlowPositionedWithImplicitHeight(*this)) |
| return true; |
| |
| if (document().inQuirksMode()) |
| return false; |
| |
| if (cb) |
| return !cb->hasDefiniteLogicalHeight(); |
| |
| return false; |
| } |
| |
| DecodingMode RenderBoxModelObject::decodingModeForImageDraw(const Image& image, const PaintInfo& paintInfo) const |
| { |
| if (!is<BitmapImage>(image)) |
| return DecodingMode::Synchronous; |
| |
| const BitmapImage& bitmapImage = downcast<BitmapImage>(image); |
| if (bitmapImage.canAnimate()) { |
| // The DecodingMode for the current frame has to be Synchronous. The DecodingMode |
| // for the next frame will be calculated in BitmapImage::internalStartAnimation(). |
| return DecodingMode::Synchronous; |
| } |
| |
| // Large image case. |
| #if PLATFORM(IOS) |
| if (IOSApplication::isIBooksStorytime()) |
| return DecodingMode::Synchronous; |
| #endif |
| if (is<HTMLImageElement>(element())) { |
| auto decodingMode = downcast<HTMLImageElement>(*element()).decodingMode(); |
| if (decodingMode != DecodingMode::Auto) |
| return decodingMode; |
| } |
| if (bitmapImage.isLargeImageAsyncDecodingEnabledForTesting()) |
| return DecodingMode::Asynchronous; |
| if (document().isImageDocument()) |
| return DecodingMode::Synchronous; |
| if (paintInfo.paintBehavior & PaintBehaviorSnapshotting) |
| return DecodingMode::Synchronous; |
| if (!settings().largeImageAsyncDecodingEnabled()) |
| return DecodingMode::Synchronous; |
| if (!bitmapImage.canUseAsyncDecodingForLargeImages()) |
| return DecodingMode::Synchronous; |
| if (paintInfo.paintBehavior & PaintBehaviorTileFirstPaint) |
| return DecodingMode::Asynchronous; |
| // FIXME: isVisibleInViewport() is not cheap. Find a way to make this condition faster. |
| if (!isVisibleInViewport()) |
| return DecodingMode::Asynchronous; |
| return DecodingMode::Synchronous; |
| } |
| |
| LayoutSize RenderBoxModelObject::relativePositionOffset() const |
| { |
| // This function has been optimized to avoid calls to containingBlock() in the common case |
| // where all values are either auto or fixed. |
| |
| LayoutSize offset = accumulateInFlowPositionOffsets(this); |
| |
| // Objects that shrink to avoid floats normally use available line width when computing containing block width. However |
| // in the case of relative positioning using percentages, we can't do this. The offset should always be resolved using the |
| // available width of the containing block. Therefore we don't use containingBlockLogicalWidthForContent() here, but instead explicitly |
| // call availableWidth on our containing block. |
| if (!style().left().isAuto()) { |
| if (!style().right().isAuto() && !containingBlock()->style().isLeftToRightDirection()) |
| offset.setWidth(-valueForLength(style().right(), !style().right().isFixed() ? containingBlock()->availableWidth() : LayoutUnit())); |
| else |
| offset.expand(valueForLength(style().left(), !style().left().isFixed() ? containingBlock()->availableWidth() : LayoutUnit()), 0); |
| } else if (!style().right().isAuto()) { |
| offset.expand(-valueForLength(style().right(), !style().right().isFixed() ? containingBlock()->availableWidth() : LayoutUnit()), 0); |
| } |
| |
| // If the containing block of a relatively positioned element does not |
| // specify a height, a percentage top or bottom offset should be resolved as |
| // auto. An exception to this is if the containing block has the WinIE quirk |
| // where <html> and <body> assume the size of the viewport. In this case, |
| // calculate the percent offset based on this height. |
| // See <https://bugs.webkit.org/show_bug.cgi?id=26396>. |
| if (!style().top().isAuto() |
| && (!style().top().isPercentOrCalculated() |
| || !containingBlock()->hasAutoHeightOrContainingBlockWithAutoHeight() |
| || containingBlock()->stretchesToViewport())) |
| offset.expand(0, valueForLength(style().top(), !style().top().isFixed() ? containingBlock()->availableHeight() : LayoutUnit())); |
| |
| else if (!style().bottom().isAuto() |
| && (!style().bottom().isPercentOrCalculated() |
| || !containingBlock()->hasAutoHeightOrContainingBlockWithAutoHeight() |
| || containingBlock()->stretchesToViewport())) |
| offset.expand(0, -valueForLength(style().bottom(), !style().bottom().isFixed() ? containingBlock()->availableHeight() : LayoutUnit())); |
| |
| return offset; |
| } |
| |
| LayoutPoint RenderBoxModelObject::adjustedPositionRelativeToOffsetParent(const LayoutPoint& startPoint) const |
| { |
| // If the element is the HTML body element or doesn't have a parent |
| // return 0 and stop this algorithm. |
| if (isBody() || !parent()) |
| return LayoutPoint(); |
| |
| LayoutPoint referencePoint = startPoint; |
| |
| // If the offsetParent of the element is null, or is the HTML body element, |
| // return the distance between the canvas origin and the left border edge |
| // of the element and stop this algorithm. |
| if (const RenderBoxModelObject* offsetParent = this->offsetParent()) { |
| if (is<RenderBox>(*offsetParent) && !offsetParent->isBody() && !is<RenderTable>(*offsetParent)) |
| referencePoint.move(-downcast<RenderBox>(*offsetParent).borderLeft(), -downcast<RenderBox>(*offsetParent).borderTop()); |
| if (!isOutOfFlowPositioned() || enclosingFragmentedFlow()) { |
| if (isRelativelyPositioned()) |
| referencePoint.move(relativePositionOffset()); |
| else if (isStickilyPositioned()) |
| referencePoint.move(stickyPositionOffset()); |
| |
| // CSS regions specification says that region flows should return the body element as their offsetParent. |
| // Since we will bypass the body’s renderer anyway, just end the loop if we encounter a region flow (named flow thread). |
| // See http://dev.w3.org/csswg/css-regions/#cssomview-offset-attributes |
| auto* ancestor = parent(); |
| while (ancestor != offsetParent) { |
| // FIXME: What are we supposed to do inside SVG content? |
| |
| if (is<RenderMultiColumnFlow>(*ancestor)) { |
| // We need to apply a translation based off what region we are inside. |
| RenderFragmentContainer* fragment = downcast<RenderMultiColumnFlow>(*ancestor).physicalTranslationFromFlowToFragment(referencePoint); |
| if (fragment) |
| referencePoint.moveBy(fragment->topLeftLocation()); |
| } else if (!isOutOfFlowPositioned()) { |
| if (is<RenderBox>(*ancestor) && !is<RenderTableRow>(*ancestor)) |
| referencePoint.moveBy(downcast<RenderBox>(*ancestor).topLeftLocation()); |
| } |
| |
| ancestor = ancestor->parent(); |
| } |
| |
| if (is<RenderBox>(*offsetParent) && offsetParent->isBody() && !offsetParent->isPositioned()) |
| referencePoint.moveBy(downcast<RenderBox>(*offsetParent).topLeftLocation()); |
| } |
| } |
| |
| return referencePoint; |
| } |
| |
| void RenderBoxModelObject::computeStickyPositionConstraints(StickyPositionViewportConstraints& constraints, const FloatRect& constrainingRect) const |
| { |
| constraints.setConstrainingRectAtLastLayout(constrainingRect); |
| |
| RenderBlock* containingBlock = this->containingBlock(); |
| RenderLayer* enclosingClippingLayer = layer()->enclosingOverflowClipLayer(ExcludeSelf); |
| RenderBox& enclosingClippingBox = enclosingClippingLayer ? downcast<RenderBox>(enclosingClippingLayer->renderer()) : view(); |
| |
| LayoutRect containerContentRect; |
| if (!enclosingClippingLayer || (containingBlock != &enclosingClippingBox)) |
| containerContentRect = containingBlock->contentBoxRect(); |
| else { |
| containerContentRect = containingBlock->layoutOverflowRect(); |
| LayoutPoint containerLocation = containerContentRect.location() + LayoutPoint(containingBlock->borderLeft() + containingBlock->paddingLeft(), |
| containingBlock->borderTop() + containingBlock->paddingTop()); |
| containerContentRect.setLocation(containerLocation); |
| } |
| |
| LayoutUnit maxWidth = containingBlock->availableLogicalWidth(); |
| |
| // Sticky positioned element ignore any override logical width on the containing block (as they don't call |
| // containingBlockLogicalWidthForContent). It's unclear whether this is totally fine. |
| LayoutBoxExtent minMargin(minimumValueForLength(style().marginTop(), maxWidth), |
| minimumValueForLength(style().marginRight(), maxWidth), |
| minimumValueForLength(style().marginBottom(), maxWidth), |
| minimumValueForLength(style().marginLeft(), maxWidth)); |
| |
| // Compute the container-relative area within which the sticky element is allowed to move. |
| containerContentRect.contract(minMargin); |
| |
| // Finally compute container rect relative to the scrolling ancestor. |
| FloatRect containerRectRelativeToScrollingAncestor = containingBlock->localToContainerQuad(FloatRect(containerContentRect), &enclosingClippingBox).boundingBox(); |
| if (enclosingClippingLayer) { |
| FloatPoint containerLocationRelativeToScrollingAncestor = containerRectRelativeToScrollingAncestor.location() - |
| FloatSize(enclosingClippingBox.borderLeft() + enclosingClippingBox.paddingLeft(), |
| enclosingClippingBox.borderTop() + enclosingClippingBox.paddingTop()); |
| if (&enclosingClippingBox != containingBlock) |
| containerLocationRelativeToScrollingAncestor += enclosingClippingLayer->scrollOffset(); |
| containerRectRelativeToScrollingAncestor.setLocation(containerLocationRelativeToScrollingAncestor); |
| } |
| constraints.setContainingBlockRect(containerRectRelativeToScrollingAncestor); |
| |
| // Now compute the sticky box rect, also relative to the scrolling ancestor. |
| LayoutRect stickyBoxRect = frameRectForStickyPositioning(); |
| LayoutRect flippedStickyBoxRect = stickyBoxRect; |
| containingBlock->flipForWritingMode(flippedStickyBoxRect); |
| FloatRect stickyBoxRelativeToScrollingAnecstor = flippedStickyBoxRect; |
| |
| // FIXME: sucks to call localToContainerQuad again, but we can't just offset from the previously computed rect if there are transforms. |
| // Map to the view to avoid including page scale factor. |
| FloatPoint stickyLocationRelativeToScrollingAncestor = flippedStickyBoxRect.location() + containingBlock->localToContainerQuad(FloatRect(FloatPoint(), containingBlock->size()), &enclosingClippingBox).boundingBox().location(); |
| if (enclosingClippingLayer) { |
| stickyLocationRelativeToScrollingAncestor -= FloatSize(enclosingClippingBox.borderLeft() + enclosingClippingBox.paddingLeft(), |
| enclosingClippingBox.borderTop() + enclosingClippingBox.paddingTop()); |
| if (&enclosingClippingBox != containingBlock) |
| stickyLocationRelativeToScrollingAncestor += enclosingClippingLayer->scrollOffset(); |
| } |
| // FIXME: For now, assume that |this| is not transformed. |
| stickyBoxRelativeToScrollingAnecstor.setLocation(stickyLocationRelativeToScrollingAncestor); |
| constraints.setStickyBoxRect(stickyBoxRelativeToScrollingAnecstor); |
| |
| if (!style().left().isAuto()) { |
| constraints.setLeftOffset(valueForLength(style().left(), constrainingRect.width())); |
| constraints.addAnchorEdge(ViewportConstraints::AnchorEdgeLeft); |
| } |
| |
| if (!style().right().isAuto()) { |
| constraints.setRightOffset(valueForLength(style().right(), constrainingRect.width())); |
| constraints.addAnchorEdge(ViewportConstraints::AnchorEdgeRight); |
| } |
| |
| if (!style().top().isAuto()) { |
| constraints.setTopOffset(valueForLength(style().top(), constrainingRect.height())); |
| constraints.addAnchorEdge(ViewportConstraints::AnchorEdgeTop); |
| } |
| |
| if (!style().bottom().isAuto()) { |
| constraints.setBottomOffset(valueForLength(style().bottom(), constrainingRect.height())); |
| constraints.addAnchorEdge(ViewportConstraints::AnchorEdgeBottom); |
| } |
| } |
| |
| FloatRect RenderBoxModelObject::constrainingRectForStickyPosition() const |
| { |
| RenderLayer* enclosingClippingLayer = layer()->enclosingOverflowClipLayer(ExcludeSelf); |
| if (enclosingClippingLayer) { |
| RenderBox& enclosingClippingBox = downcast<RenderBox>(enclosingClippingLayer->renderer()); |
| LayoutRect clipRect = enclosingClippingBox.overflowClipRect(LayoutPoint(), nullptr); // FIXME: make this work in regions. |
| clipRect.contract(LayoutSize(enclosingClippingBox.paddingLeft() + enclosingClippingBox.paddingRight(), |
| enclosingClippingBox.paddingTop() + enclosingClippingBox.paddingBottom())); |
| |
| FloatRect constrainingRect = enclosingClippingBox.localToContainerQuad(FloatRect(clipRect), &view()).boundingBox(); |
| |
| FloatPoint scrollOffset = FloatPoint() + enclosingClippingLayer->scrollOffset(); |
| |
| float scrollbarOffset = 0; |
| if (enclosingClippingBox.hasLayer() && enclosingClippingBox.shouldPlaceBlockDirectionScrollbarOnLeft()) |
| scrollbarOffset = enclosingClippingBox.layer()->verticalScrollbarWidth(IgnoreOverlayScrollbarSize); |
| |
| constrainingRect.setLocation(FloatPoint(scrollOffset.x() + scrollbarOffset, scrollOffset.y())); |
| return constrainingRect; |
| } |
| |
| return view().frameView().rectForFixedPositionLayout(); |
| } |
| |
| LayoutSize RenderBoxModelObject::stickyPositionOffset() const |
| { |
| ASSERT(hasLayer()); |
| |
| FloatRect constrainingRect = constrainingRectForStickyPosition(); |
| StickyPositionViewportConstraints constraints; |
| computeStickyPositionConstraints(constraints, constrainingRect); |
| |
| // The sticky offset is physical, so we can just return the delta computed in absolute coords (though it may be wrong with transforms). |
| return LayoutSize(constraints.computeStickyOffset(constrainingRect)); |
| } |
| |
| LayoutSize RenderBoxModelObject::offsetForInFlowPosition() const |
| { |
| if (isRelativelyPositioned()) |
| return relativePositionOffset(); |
| |
| if (isStickilyPositioned()) |
| return stickyPositionOffset(); |
| |
| return LayoutSize(); |
| } |
| |
| LayoutUnit RenderBoxModelObject::offsetLeft() const |
| { |
| // Note that RenderInline and RenderBox override this to pass a different |
| // startPoint to adjustedPositionRelativeToOffsetParent. |
| return adjustedPositionRelativeToOffsetParent(LayoutPoint()).x(); |
| } |
| |
| LayoutUnit RenderBoxModelObject::offsetTop() const |
| { |
| // Note that RenderInline and RenderBox override this to pass a different |
| // startPoint to adjustedPositionRelativeToOffsetParent. |
| return adjustedPositionRelativeToOffsetParent(LayoutPoint()).y(); |
| } |
| |
| LayoutUnit RenderBoxModelObject::computedCSSPadding(const Length& padding) const |
| { |
| LayoutUnit w = 0; |
| if (padding.isPercentOrCalculated()) |
| w = containingBlockLogicalWidthForContent(); |
| return minimumValueForLength(padding, w); |
| } |
| |
| RoundedRect RenderBoxModelObject::getBackgroundRoundedRect(const LayoutRect& borderRect, InlineFlowBox* box, LayoutUnit inlineBoxWidth, LayoutUnit inlineBoxHeight, |
| bool includeLogicalLeftEdge, bool includeLogicalRightEdge) const |
| { |
| RoundedRect border = style().getRoundedBorderFor(borderRect, includeLogicalLeftEdge, includeLogicalRightEdge); |
| if (box && (box->nextLineBox() || box->prevLineBox())) { |
| RoundedRect segmentBorder = style().getRoundedBorderFor(LayoutRect(0, 0, inlineBoxWidth, inlineBoxHeight), includeLogicalLeftEdge, includeLogicalRightEdge); |
| border.setRadii(segmentBorder.radii()); |
| } |
| return border; |
| } |
| |
| void RenderBoxModelObject::clipRoundedInnerRect(GraphicsContext& context, const FloatRect& rect, const FloatRoundedRect& clipRect) |
| { |
| if (clipRect.isRenderable()) |
| context.clipRoundedRect(clipRect); |
| else { |
| // We create a rounded rect for each of the corners and clip it, while making sure we clip opposing corners together. |
| if (!clipRect.radii().topLeft().isEmpty() || !clipRect.radii().bottomRight().isEmpty()) { |
| FloatRect topCorner(clipRect.rect().x(), clipRect.rect().y(), rect.maxX() - clipRect.rect().x(), rect.maxY() - clipRect.rect().y()); |
| FloatRoundedRect::Radii topCornerRadii; |
| topCornerRadii.setTopLeft(clipRect.radii().topLeft()); |
| context.clipRoundedRect(FloatRoundedRect(topCorner, topCornerRadii)); |
| |
| FloatRect bottomCorner(rect.x(), rect.y(), clipRect.rect().maxX() - rect.x(), clipRect.rect().maxY() - rect.y()); |
| FloatRoundedRect::Radii bottomCornerRadii; |
| bottomCornerRadii.setBottomRight(clipRect.radii().bottomRight()); |
| context.clipRoundedRect(FloatRoundedRect(bottomCorner, bottomCornerRadii)); |
| } |
| |
| if (!clipRect.radii().topRight().isEmpty() || !clipRect.radii().bottomLeft().isEmpty()) { |
| FloatRect topCorner(rect.x(), clipRect.rect().y(), clipRect.rect().maxX() - rect.x(), rect.maxY() - clipRect.rect().y()); |
| FloatRoundedRect::Radii topCornerRadii; |
| topCornerRadii.setTopRight(clipRect.radii().topRight()); |
| context.clipRoundedRect(FloatRoundedRect(topCorner, topCornerRadii)); |
| |
| FloatRect bottomCorner(clipRect.rect().x(), rect.y(), rect.maxX() - clipRect.rect().x(), clipRect.rect().maxY() - rect.y()); |
| FloatRoundedRect::Radii bottomCornerRadii; |
| bottomCornerRadii.setBottomLeft(clipRect.radii().bottomLeft()); |
| context.clipRoundedRect(FloatRoundedRect(bottomCorner, bottomCornerRadii)); |
| } |
| } |
| } |
| |
| static LayoutRect shrinkRectByOneDevicePixel(const GraphicsContext& context, const LayoutRect& rect, float devicePixelRatio) |
| { |
| LayoutRect shrunkRect = rect; |
| AffineTransform transform = context.getCTM(); |
| shrunkRect.inflateX(-ceilToDevicePixel(LayoutUnit::fromPixel(1) / transform.xScale(), devicePixelRatio)); |
| shrunkRect.inflateY(-ceilToDevicePixel(LayoutUnit::fromPixel(1) / transform.yScale(), devicePixelRatio)); |
| return shrunkRect; |
| } |
| |
| LayoutRect RenderBoxModelObject::borderInnerRectAdjustedForBleedAvoidance(const GraphicsContext& context, const LayoutRect& rect, BackgroundBleedAvoidance bleedAvoidance) const |
| { |
| if (bleedAvoidance != BackgroundBleedBackgroundOverBorder) |
| return rect; |
| |
| // We shrink the rectangle by one device pixel on each side to make it fully overlap the anti-aliased background border |
| return shrinkRectByOneDevicePixel(context, rect, document().deviceScaleFactor()); |
| } |
| |
| RoundedRect RenderBoxModelObject::backgroundRoundedRectAdjustedForBleedAvoidance(const GraphicsContext& context, const LayoutRect& borderRect, BackgroundBleedAvoidance bleedAvoidance, InlineFlowBox* box, const LayoutSize& boxSize, bool includeLogicalLeftEdge, bool includeLogicalRightEdge) const |
| { |
| if (bleedAvoidance == BackgroundBleedShrinkBackground) { |
| // We shrink the rectangle by one device pixel on each side because the bleed is one pixel maximum. |
| return getBackgroundRoundedRect(shrinkRectByOneDevicePixel(context, borderRect, document().deviceScaleFactor()), box, boxSize.width(), boxSize.height(), |
| includeLogicalLeftEdge, includeLogicalRightEdge); |
| } |
| if (bleedAvoidance == BackgroundBleedBackgroundOverBorder) |
| return style().getRoundedInnerBorderFor(borderRect, includeLogicalLeftEdge, includeLogicalRightEdge); |
| |
| return getBackgroundRoundedRect(borderRect, box, boxSize.width(), boxSize.height(), includeLogicalLeftEdge, includeLogicalRightEdge); |
| } |
| |
| static void applyBoxShadowForBackground(GraphicsContext& context, const RenderStyle* style) |
| { |
| const ShadowData* boxShadow = style->boxShadow(); |
| while (boxShadow->style() != Normal) |
| boxShadow = boxShadow->next(); |
| |
| FloatSize shadowOffset(boxShadow->x(), boxShadow->y()); |
| if (!boxShadow->isWebkitBoxShadow()) |
| context.setShadow(shadowOffset, boxShadow->radius(), boxShadow->color()); |
| else |
| context.setLegacyShadow(shadowOffset, boxShadow->radius(), boxShadow->color()); |
| } |
| |
| InterpolationQuality RenderBoxModelObject::chooseInterpolationQuality(GraphicsContext& context, Image& image, const void* layer, const LayoutSize& size) |
| { |
| return view().imageQualityController().chooseInterpolationQuality(context, this, image, layer, size); |
| } |
| |
| void RenderBoxModelObject::paintMaskForTextFillBox(ImageBuffer* maskImage, const IntRect& maskRect, InlineFlowBox* box, const LayoutRect& scrolledPaintRect) |
| { |
| GraphicsContext& maskImageContext = maskImage->context(); |
| maskImageContext.translate(-maskRect.location()); |
| |
| // Now add the text to the clip. We do this by painting using a special paint phase that signals to |
| // InlineTextBoxes that they should just add their contents to the clip. |
| PaintInfo info(maskImageContext, maskRect, PaintPhaseTextClip, PaintBehaviorForceBlackText); |
| if (box) { |
| const RootInlineBox& rootBox = box->root(); |
| box->paint(info, LayoutPoint(scrolledPaintRect.x() - box->x(), scrolledPaintRect.y() - box->y()), rootBox.lineTop(), rootBox.lineBottom()); |
| } else { |
| LayoutSize localOffset = is<RenderBox>(*this) ? downcast<RenderBox>(*this).locationOffset() : LayoutSize(); |
| paint(info, scrolledPaintRect.location() - localOffset); |
| } |
| } |
| |
| void RenderBoxModelObject::paintFillLayerExtended(const PaintInfo& paintInfo, const Color& color, const FillLayer& bgLayer, const LayoutRect& rect, |
| BackgroundBleedAvoidance bleedAvoidance, InlineFlowBox* box, const LayoutSize& boxSize, CompositeOperator op, RenderElement* backgroundObject, BaseBackgroundColorUsage baseBgColorUsage) |
| { |
| GraphicsContext& context = paintInfo.context(); |
| if (context.paintingDisabled() || rect.isEmpty()) |
| return; |
| |
| bool includeLeftEdge = box ? box->includeLogicalLeftEdge() : true; |
| bool includeRightEdge = box ? box->includeLogicalRightEdge() : true; |
| |
| bool hasRoundedBorder = style().hasBorderRadius() && (includeLeftEdge || includeRightEdge); |
| bool clippedWithLocalScrolling = hasOverflowClip() && bgLayer.attachment() == LocalBackgroundAttachment; |
| bool isBorderFill = bgLayer.clip() == BorderFillBox; |
| bool isRoot = this->isDocumentElementRenderer(); |
| |
| Color bgColor = color; |
| StyleImage* bgImage = bgLayer.image(); |
| bool shouldPaintBackgroundImage = bgImage && bgImage->canRender(this, style().effectiveZoom()); |
| |
| bool forceBackgroundToWhite = false; |
| if (document().printing()) { |
| if (style().printColorAdjust() == PrintColorAdjustEconomy) |
| forceBackgroundToWhite = true; |
| if (settings().shouldPrintBackgrounds()) |
| forceBackgroundToWhite = false; |
| } |
| |
| // When printing backgrounds is disabled or using economy mode, |
| // change existing background colors and images to a solid white background. |
| // If there's no bg color or image, leave it untouched to avoid affecting transparency. |
| // We don't try to avoid loading the background images, because this style flag is only set |
| // when printing, and at that point we've already loaded the background images anyway. (To avoid |
| // loading the background images we'd have to do this check when applying styles rather than |
| // while rendering.) |
| if (forceBackgroundToWhite) { |
| // Note that we can't reuse this variable below because the bgColor might be changed |
| bool shouldPaintBackgroundColor = !bgLayer.next() && bgColor.isVisible(); |
| if (shouldPaintBackgroundImage || shouldPaintBackgroundColor) { |
| bgColor = Color::white; |
| shouldPaintBackgroundImage = false; |
| } |
| } |
| |
| bool baseBgColorOnly = (baseBgColorUsage == BaseBackgroundColorOnly); |
| if (baseBgColorOnly && (!isRoot || bgLayer.next() || bgColor.isOpaque())) |
| return; |
| |
| bool colorVisible = bgColor.isVisible(); |
| float deviceScaleFactor = document().deviceScaleFactor(); |
| FloatRect pixelSnappedRect = snapRectToDevicePixels(rect, deviceScaleFactor); |
| |
| // Fast path for drawing simple color backgrounds. |
| if (!isRoot && !clippedWithLocalScrolling && !shouldPaintBackgroundImage && isBorderFill && !bgLayer.next()) { |
| if (!colorVisible) |
| return; |
| |
| bool boxShadowShouldBeAppliedToBackground = this->boxShadowShouldBeAppliedToBackground(rect.location(), bleedAvoidance, box); |
| GraphicsContextStateSaver shadowStateSaver(context, boxShadowShouldBeAppliedToBackground); |
| if (boxShadowShouldBeAppliedToBackground) |
| applyBoxShadowForBackground(context, &style()); |
| |
| if (hasRoundedBorder && bleedAvoidance != BackgroundBleedUseTransparencyLayer) { |
| FloatRoundedRect pixelSnappedBorder = backgroundRoundedRectAdjustedForBleedAvoidance(context, rect, bleedAvoidance, box, boxSize, |
| includeLeftEdge, includeRightEdge).pixelSnappedRoundedRectForPainting(deviceScaleFactor); |
| if (pixelSnappedBorder.isRenderable()) |
| context.fillRoundedRect(pixelSnappedBorder, bgColor); |
| else { |
| context.save(); |
| clipRoundedInnerRect(context, pixelSnappedRect, pixelSnappedBorder); |
| context.fillRect(pixelSnappedBorder.rect(), bgColor); |
| context.restore(); |
| } |
| } else |
| context.fillRect(pixelSnappedRect, bgColor); |
| |
| return; |
| } |
| |
| // BorderFillBox radius clipping is taken care of by BackgroundBleedUseTransparencyLayer |
| bool clipToBorderRadius = hasRoundedBorder && !(isBorderFill && bleedAvoidance == BackgroundBleedUseTransparencyLayer); |
| GraphicsContextStateSaver clipToBorderStateSaver(context, clipToBorderRadius); |
| if (clipToBorderRadius) { |
| RoundedRect border = isBorderFill ? backgroundRoundedRectAdjustedForBleedAvoidance(context, rect, bleedAvoidance, box, boxSize, includeLeftEdge, includeRightEdge) : getBackgroundRoundedRect(rect, box, boxSize.width(), boxSize.height(), includeLeftEdge, includeRightEdge); |
| |
| // Clip to the padding or content boxes as necessary. |
| if (bgLayer.clip() == ContentFillBox) { |
| border = style().getRoundedInnerBorderFor(border.rect(), |
| paddingTop() + borderTop(), paddingBottom() + borderBottom(), paddingLeft() + borderLeft(), paddingRight() + borderRight(), includeLeftEdge, includeRightEdge); |
| } else if (bgLayer.clip() == PaddingFillBox) |
| border = style().getRoundedInnerBorderFor(border.rect(), includeLeftEdge, includeRightEdge); |
| |
| clipRoundedInnerRect(context, pixelSnappedRect, border.pixelSnappedRoundedRectForPainting(deviceScaleFactor)); |
| } |
| |
| LayoutUnit bLeft = includeLeftEdge ? borderLeft() : LayoutUnit::fromPixel(0); |
| LayoutUnit bRight = includeRightEdge ? borderRight() : LayoutUnit::fromPixel(0); |
| LayoutUnit pLeft = includeLeftEdge ? paddingLeft() : LayoutUnit(); |
| LayoutUnit pRight = includeRightEdge ? paddingRight() : LayoutUnit(); |
| |
| GraphicsContextStateSaver clipWithScrollingStateSaver(context, clippedWithLocalScrolling); |
| LayoutRect scrolledPaintRect = rect; |
| if (clippedWithLocalScrolling) { |
| // Clip to the overflow area. |
| auto& thisBox = downcast<RenderBox>(*this); |
| context.clip(thisBox.overflowClipRect(rect.location())); |
| |
| // Adjust the paint rect to reflect a scrolled content box with borders at the ends. |
| scrolledPaintRect.moveBy(-thisBox.scrollPosition()); |
| scrolledPaintRect.setWidth(bLeft + layer()->scrollWidth() + bRight); |
| scrolledPaintRect.setHeight(borderTop() + layer()->scrollHeight() + borderBottom()); |
| } |
| |
| GraphicsContextStateSaver backgroundClipStateSaver(context, false); |
| std::unique_ptr<ImageBuffer> maskImage; |
| IntRect maskRect; |
| |
| if (bgLayer.clip() == PaddingFillBox || bgLayer.clip() == ContentFillBox) { |
| // Clip to the padding or content boxes as necessary. |
| if (!clipToBorderRadius) { |
| bool includePadding = bgLayer.clip() == ContentFillBox; |
| LayoutRect clipRect = LayoutRect(scrolledPaintRect.x() + bLeft + (includePadding ? pLeft : LayoutUnit()), |
| scrolledPaintRect.y() + borderTop() + (includePadding ? paddingTop() : LayoutUnit()), |
| scrolledPaintRect.width() - bLeft - bRight - (includePadding ? pLeft + pRight : LayoutUnit()), |
| scrolledPaintRect.height() - borderTop() - borderBottom() - (includePadding ? paddingTop() + paddingBottom() : LayoutUnit())); |
| backgroundClipStateSaver.save(); |
| context.clip(clipRect); |
| } |
| } else if (bgLayer.clip() == TextFillBox) { |
| // We have to draw our text into a mask that can then be used to clip background drawing. |
| // First figure out how big the mask has to be. It should be no bigger than what we need |
| // to actually render, so we should intersect the dirty rect with the border box of the background. |
| maskRect = snappedIntRect(rect); |
| maskRect.intersect(snappedIntRect(paintInfo.rect)); |
| |
| // Now create the mask. |
| maskImage = ImageBuffer::createCompatibleBuffer(maskRect.size(), ColorSpaceSRGB, context); |
| if (!maskImage) |
| return; |
| paintMaskForTextFillBox(maskImage.get(), maskRect, box, scrolledPaintRect); |
| |
| // The mask has been created. Now we just need to clip to it. |
| backgroundClipStateSaver.save(); |
| context.clip(maskRect); |
| context.beginTransparencyLayer(1); |
| } |
| |
| // Only fill with a base color (e.g., white) if we're the root document, since iframes/frames with |
| // no background in the child document should show the parent's background. |
| bool isOpaqueRoot = false; |
| if (isRoot) { |
| isOpaqueRoot = true; |
| if (!bgLayer.next() && !bgColor.isOpaque()) { |
| HTMLFrameOwnerElement* ownerElement = document().ownerElement(); |
| if (ownerElement) { |
| if (!ownerElement->hasTagName(frameTag)) { |
| // Locate the <body> element using the DOM. This is easier than trying |
| // to crawl around a render tree with potential :before/:after content and |
| // anonymous blocks created by inline <body> tags etc. We can locate the <body> |
| // render object very easily via the DOM. |
| if (HTMLElement* body = document().bodyOrFrameset()) { |
| // Can't scroll a frameset document anyway. |
| isOpaqueRoot = is<HTMLFrameSetElement>(*body); |
| } else { |
| // SVG documents and XML documents with SVG root nodes are transparent. |
| isOpaqueRoot = !document().hasSVGRootNode(); |
| } |
| } |
| } else |
| isOpaqueRoot = !view().frameView().isTransparent(); |
| } |
| view().frameView().setContentIsOpaque(isOpaqueRoot); |
| } |
| |
| // Paint the color first underneath all images, culled if background image occludes it. |
| // FIXME: In the bgLayer.hasFiniteBounds() case, we could improve the culling test |
| // by verifying whether the background image covers the entire layout rect. |
| if (!bgLayer.next()) { |
| LayoutRect backgroundRect(scrolledPaintRect); |
| bool boxShadowShouldBeAppliedToBackground = this->boxShadowShouldBeAppliedToBackground(rect.location(), bleedAvoidance, box); |
| if (boxShadowShouldBeAppliedToBackground || !shouldPaintBackgroundImage || !bgLayer.hasOpaqueImage(*this) || !bgLayer.hasRepeatXY()) { |
| if (!boxShadowShouldBeAppliedToBackground) |
| backgroundRect.intersect(paintInfo.rect); |
| |
| // If we have an alpha and we are painting the root element, blend with the base background color. |
| Color baseColor; |
| bool shouldClearBackground = false; |
| if ((baseBgColorUsage != BaseBackgroundColorSkip) && isOpaqueRoot) { |
| baseColor = view().frameView().baseBackgroundColor(); |
| if (!baseColor.isVisible()) |
| shouldClearBackground = true; |
| } |
| |
| GraphicsContextStateSaver shadowStateSaver(context, boxShadowShouldBeAppliedToBackground); |
| if (boxShadowShouldBeAppliedToBackground) |
| applyBoxShadowForBackground(context, &style()); |
| |
| FloatRect backgroundRectForPainting = snapRectToDevicePixels(backgroundRect, deviceScaleFactor); |
| if (baseColor.isVisible()) { |
| if (!baseBgColorOnly && bgColor.isVisible()) |
| baseColor = baseColor.blend(bgColor); |
| context.fillRect(backgroundRectForPainting, baseColor, CompositeCopy); |
| } else if (!baseBgColorOnly && bgColor.isVisible()) { |
| auto operation = shouldClearBackground ? CompositeCopy : context.compositeOperation(); |
| context.fillRect(backgroundRectForPainting, bgColor, operation); |
| } else if (shouldClearBackground) |
| context.clearRect(backgroundRectForPainting); |
| } |
| } |
| |
| // no progressive loading of the background image |
| if (!baseBgColorOnly && shouldPaintBackgroundImage) { |
| auto geometry = calculateBackgroundImageGeometry(paintInfo.paintContainer, bgLayer, rect.location(), scrolledPaintRect, backgroundObject); |
| geometry.clip(LayoutRect(pixelSnappedRect)); |
| RefPtr<Image> image; |
| if (!geometry.destRect().isEmpty() && (image = bgImage->image(backgroundObject ? backgroundObject : this, geometry.tileSize()))) { |
| auto compositeOp = op == CompositeSourceOver ? bgLayer.composite() : op; |
| context.setDrawLuminanceMask(bgLayer.maskSourceType() == MaskLuminance); |
| |
| if (is<BitmapImage>(image)) |
| downcast<BitmapImage>(*image).updateFromSettings(settings()); |
| |
| auto interpolation = chooseInterpolationQuality(context, *image, &bgLayer, geometry.tileSize()); |
| auto decodingMode = decodingModeForImageDraw(*image, paintInfo); |
| auto drawResult = context.drawTiledImage(*image, geometry.destRect(), toLayoutPoint(geometry.relativePhase()), geometry.tileSize(), geometry.spaceSize(), ImagePaintingOptions(compositeOp, bgLayer.blendMode(), decodingMode, ImageOrientationDescription(), interpolation)); |
| if (drawResult == ImageDrawResult::DidRequestDecoding) { |
| ASSERT(bgImage->isCachedImage()); |
| bgImage->cachedImage()->addPendingImageDrawingClient(*this); |
| } |
| } |
| } |
| |
| if (maskImage && bgLayer.clip() == TextFillBox) { |
| context.drawConsumingImageBuffer(WTFMove(maskImage), maskRect, CompositeDestinationIn); |
| context.endTransparencyLayer(); |
| } |
| } |
| |
| static inline LayoutUnit resolveWidthForRatio(LayoutUnit height, const LayoutSize& intrinsicRatio) |
| { |
| return height * intrinsicRatio.width() / intrinsicRatio.height(); |
| } |
| |
| static inline LayoutUnit resolveHeightForRatio(LayoutUnit width, const LayoutSize& intrinsicRatio) |
| { |
| return width * intrinsicRatio.height() / intrinsicRatio.width(); |
| } |
| |
| static inline LayoutSize resolveAgainstIntrinsicWidthOrHeightAndRatio(const LayoutSize& size, const LayoutSize& intrinsicRatio, LayoutUnit useWidth, LayoutUnit useHeight) |
| { |
| if (intrinsicRatio.isEmpty()) { |
| if (useWidth) |
| return LayoutSize(useWidth, size.height()); |
| return LayoutSize(size.width(), useHeight); |
| } |
| |
| if (useWidth) |
| return LayoutSize(useWidth, resolveHeightForRatio(useWidth, intrinsicRatio)); |
| return LayoutSize(resolveWidthForRatio(useHeight, intrinsicRatio), useHeight); |
| } |
| |
| static inline LayoutSize resolveAgainstIntrinsicRatio(const LayoutSize& size, const LayoutSize& intrinsicRatio) |
| { |
| // Two possible solutions: (size.width(), solutionHeight) or (solutionWidth, size.height()) |
| // "... must be assumed to be the largest dimensions..." = easiest answer: the rect with the largest surface area. |
| |
| LayoutUnit solutionWidth = resolveWidthForRatio(size.height(), intrinsicRatio); |
| LayoutUnit solutionHeight = resolveHeightForRatio(size.width(), intrinsicRatio); |
| if (solutionWidth <= size.width()) { |
| if (solutionHeight <= size.height()) { |
| // If both solutions fit, choose the one covering the larger area. |
| LayoutUnit areaOne = solutionWidth * size.height(); |
| LayoutUnit areaTwo = size.width() * solutionHeight; |
| if (areaOne < areaTwo) |
| return LayoutSize(size.width(), solutionHeight); |
| return LayoutSize(solutionWidth, size.height()); |
| } |
| |
| // Only the first solution fits. |
| return LayoutSize(solutionWidth, size.height()); |
| } |
| |
| // Only the second solution fits, assert that. |
| ASSERT(solutionHeight <= size.height()); |
| return LayoutSize(size.width(), solutionHeight); |
| } |
| |
| LayoutSize RenderBoxModelObject::calculateImageIntrinsicDimensions(StyleImage* image, const LayoutSize& positioningAreaSize, ScaleByEffectiveZoomOrNot shouldScaleOrNot) const |
| { |
| // A generated image without a fixed size, will always return the container size as intrinsic size. |
| if (image->isGeneratedImage() && image->usesImageContainerSize()) |
| return LayoutSize(positioningAreaSize.width(), positioningAreaSize.height()); |
| |
| Length intrinsicWidth; |
| Length intrinsicHeight; |
| FloatSize intrinsicRatio; |
| image->computeIntrinsicDimensions(this, intrinsicWidth, intrinsicHeight, intrinsicRatio); |
| |
| ASSERT(!intrinsicWidth.isPercentOrCalculated()); |
| ASSERT(!intrinsicHeight.isPercentOrCalculated()); |
| |
| LayoutSize resolvedSize(intrinsicWidth.value(), intrinsicHeight.value()); |
| LayoutSize minimumSize(resolvedSize.width() > 0 ? 1 : 0, resolvedSize.height() > 0 ? 1 : 0); |
| |
| if (shouldScaleOrNot == ScaleByEffectiveZoom) |
| resolvedSize.scale(style().effectiveZoom()); |
| resolvedSize.clampToMinimumSize(minimumSize); |
| |
| if (!resolvedSize.isEmpty()) |
| return resolvedSize; |
| |
| // If the image has one of either an intrinsic width or an intrinsic height: |
| // * and an intrinsic aspect ratio, then the missing dimension is calculated from the given dimension and the ratio. |
| // * and no intrinsic aspect ratio, then the missing dimension is assumed to be the size of the rectangle that |
| // establishes the coordinate system for the 'background-position' property. |
| if (resolvedSize.width() > 0 || resolvedSize.height() > 0) |
| return resolveAgainstIntrinsicWidthOrHeightAndRatio(positioningAreaSize, LayoutSize(intrinsicRatio), resolvedSize.width(), resolvedSize.height()); |
| |
| // If the image has no intrinsic dimensions and has an intrinsic ratio the dimensions must be assumed to be the |
| // largest dimensions at that ratio such that neither dimension exceeds the dimensions of the rectangle that |
| // establishes the coordinate system for the 'background-position' property. |
| if (!intrinsicRatio.isEmpty()) |
| return resolveAgainstIntrinsicRatio(positioningAreaSize, LayoutSize(intrinsicRatio)); |
| |
| // If the image has no intrinsic ratio either, then the dimensions must be assumed to be the rectangle that |
| // establishes the coordinate system for the 'background-position' property. |
| return positioningAreaSize; |
| } |
| |
| LayoutSize RenderBoxModelObject::calculateFillTileSize(const FillLayer& fillLayer, const LayoutSize& positioningAreaSize) const |
| { |
| StyleImage* image = fillLayer.image(); |
| EFillSizeType type = fillLayer.size().type; |
| |
| LayoutSize imageIntrinsicSize; |
| if (image) { |
| imageIntrinsicSize = calculateImageIntrinsicDimensions(image, positioningAreaSize, ScaleByEffectiveZoom); |
| imageIntrinsicSize.scale(1 / image->imageScaleFactor(), 1 / image->imageScaleFactor()); |
| } else |
| imageIntrinsicSize = positioningAreaSize; |
| |
| switch (type) { |
| case SizeLength: { |
| LayoutSize tileSize = positioningAreaSize; |
| |
| Length layerWidth = fillLayer.size().size.width; |
| Length layerHeight = fillLayer.size().size.height; |
| |
| if (layerWidth.isFixed()) |
| tileSize.setWidth(layerWidth.value()); |
| else if (layerWidth.isPercentOrCalculated()) |
| tileSize.setWidth(valueForLength(layerWidth, positioningAreaSize.width())); |
| |
| if (layerHeight.isFixed()) |
| tileSize.setHeight(layerHeight.value()); |
| else if (layerHeight.isPercentOrCalculated()) |
| tileSize.setHeight(valueForLength(layerHeight, positioningAreaSize.height())); |
| |
| // If one of the values is auto we have to use the appropriate |
| // scale to maintain our aspect ratio. |
| if (layerWidth.isAuto() && !layerHeight.isAuto()) { |
| if (imageIntrinsicSize.height()) |
| tileSize.setWidth(imageIntrinsicSize.width() * tileSize.height() / imageIntrinsicSize.height()); |
| } else if (!layerWidth.isAuto() && layerHeight.isAuto()) { |
| if (imageIntrinsicSize.width()) |
| tileSize.setHeight(imageIntrinsicSize.height() * tileSize.width() / imageIntrinsicSize.width()); |
| } else if (layerWidth.isAuto() && layerHeight.isAuto()) { |
| // If both width and height are auto, use the image's intrinsic size. |
| tileSize = imageIntrinsicSize; |
| } |
| |
| tileSize.clampNegativeToZero(); |
| return tileSize; |
| } |
| case SizeNone: { |
| // If both values are ‘auto’ then the intrinsic width and/or height of the image should be used, if any. |
| if (!imageIntrinsicSize.isEmpty()) |
| return imageIntrinsicSize; |
| |
| // If the image has neither an intrinsic width nor an intrinsic height, its size is determined as for ‘contain’. |
| type = Contain; |
| } |
| FALLTHROUGH; |
| case Contain: |
| case Cover: { |
| // Scale computation needs higher precision than what LayoutUnit can offer. |
| FloatSize localImageIntrinsicSize = imageIntrinsicSize; |
| FloatSize localPositioningAreaSize = positioningAreaSize; |
| |
| float horizontalScaleFactor = localImageIntrinsicSize.width() ? (localPositioningAreaSize.width() / localImageIntrinsicSize.width()) : 1; |
| float verticalScaleFactor = localImageIntrinsicSize.height() ? (localPositioningAreaSize.height() / localImageIntrinsicSize.height()) : 1; |
| float scaleFactor = type == Contain ? std::min(horizontalScaleFactor, verticalScaleFactor) : std::max(horizontalScaleFactor, verticalScaleFactor); |
| float deviceScaleFactor = document().deviceScaleFactor(); |
| return LayoutSize(std::max<LayoutUnit>(1 / deviceScaleFactor, localImageIntrinsicSize.width() * scaleFactor), |
| std::max<LayoutUnit>(1 / deviceScaleFactor, localImageIntrinsicSize.height() * scaleFactor)); |
| } |
| } |
| |
| ASSERT_NOT_REACHED(); |
| return LayoutSize(); |
| } |
| |
| static void pixelSnapBackgroundImageGeometryForPainting(LayoutRect& destinationRect, LayoutSize& tileSize, LayoutSize& phase, LayoutSize& space, float scaleFactor) |
| { |
| tileSize = LayoutSize(snapRectToDevicePixels(LayoutRect(destinationRect.location(), tileSize), scaleFactor).size()); |
| phase = LayoutSize(snapRectToDevicePixels(LayoutRect(destinationRect.location(), phase), scaleFactor).size()); |
| space = LayoutSize(snapRectToDevicePixels(LayoutRect(LayoutPoint(), space), scaleFactor).size()); |
| destinationRect = LayoutRect(snapRectToDevicePixels(destinationRect, scaleFactor)); |
| } |
| |
| bool RenderBoxModelObject::fixedBackgroundPaintsInLocalCoordinates() const |
| { |
| if (!isDocumentElementRenderer()) |
| return false; |
| |
| if (view().frameView().paintBehavior() & PaintBehaviorFlattenCompositingLayers) |
| return false; |
| |
| RenderLayer* rootLayer = view().layer(); |
| if (!rootLayer || !rootLayer->isComposited()) |
| return false; |
| |
| return rootLayer->backing()->backgroundLayerPaintsFixedRootBackground(); |
| } |
| |
| static inline LayoutUnit getSpace(LayoutUnit areaSize, LayoutUnit tileSize) |
| { |
| int numberOfTiles = areaSize / tileSize; |
| LayoutUnit space = -1; |
| |
| if (numberOfTiles > 1) |
| space = (areaSize - numberOfTiles * tileSize) / (numberOfTiles - 1); |
| |
| return space; |
| } |
| |
| static LayoutUnit resolveEdgeRelativeLength(const Length& length, Edge edge, LayoutUnit availableSpace, const LayoutSize& areaSize, const LayoutSize& tileSize) |
| { |
| LayoutUnit result = minimumValueForLength(length, availableSpace); |
| |
| if (edge == Edge::Right) |
| return areaSize.width() - tileSize.width() - result; |
| |
| if (edge == Edge::Bottom) |
| return areaSize.height() - tileSize.height() - result; |
| |
| return result; |
| } |
| |
| BackgroundImageGeometry RenderBoxModelObject::calculateBackgroundImageGeometry(const RenderLayerModelObject* paintContainer, const FillLayer& fillLayer, const LayoutPoint& paintOffset, |
| const LayoutRect& borderBoxRect, RenderElement* backgroundObject) const |
| { |
| LayoutUnit left = 0; |
| LayoutUnit top = 0; |
| LayoutSize positioningAreaSize; |
| // Determine the background positioning area and set destination rect to the background painting area. |
| // Destination rect will be adjusted later if the background is non-repeating. |
| // FIXME: transforms spec says that fixed backgrounds behave like scroll inside transforms. https://bugs.webkit.org/show_bug.cgi?id=15679 |
| LayoutRect destinationRect(borderBoxRect); |
| bool fixedAttachment = fillLayer.attachment() == FixedBackgroundAttachment; |
| float deviceScaleFactor = document().deviceScaleFactor(); |
| if (!fixedAttachment) { |
| LayoutUnit right = 0; |
| LayoutUnit bottom = 0; |
| // Scroll and Local. |
| if (fillLayer.origin() != BorderFillBox) { |
| left = borderLeft(); |
| right = borderRight(); |
| top = borderTop(); |
| bottom = borderBottom(); |
| if (fillLayer.origin() == ContentFillBox) { |
| left += paddingLeft(); |
| right += paddingRight(); |
| top += paddingTop(); |
| bottom += paddingBottom(); |
| } |
| } |
| |
| // The background of the box generated by the root element covers the entire canvas including |
| // its margins. Since those were added in already, we have to factor them out when computing |
| // the background positioning area. |
| if (isDocumentElementRenderer()) { |
| positioningAreaSize = downcast<RenderBox>(*this).size() - LayoutSize(left + right, top + bottom); |
| positioningAreaSize = LayoutSize(snapSizeToDevicePixel(positioningAreaSize, LayoutPoint(), deviceScaleFactor)); |
| if (view().frameView().hasExtendedBackgroundRectForPainting()) { |
| LayoutRect extendedBackgroundRect = view().frameView().extendedBackgroundRectForPainting(); |
| left += (marginLeft() - extendedBackgroundRect.x()); |
| top += (marginTop() - extendedBackgroundRect.y()); |
| } |
| } else { |
| positioningAreaSize = borderBoxRect.size() - LayoutSize(left + right, top + bottom); |
| positioningAreaSize = LayoutSize(snapRectToDevicePixels(LayoutRect(paintOffset, positioningAreaSize), deviceScaleFactor).size()); |
| } |
| } else { |
| LayoutRect viewportRect; |
| float topContentInset = 0; |
| if (settings().fixedBackgroundsPaintRelativeToDocument()) |
| viewportRect = view().unscaledDocumentRect(); |
| else { |
| FrameView& frameView = view().frameView(); |
| bool useFixedLayout = frameView.useFixedLayout() && !frameView.fixedLayoutSize().isEmpty(); |
| |
| if (useFixedLayout) { |
| // Use the fixedLayoutSize() when useFixedLayout() because the rendering will scale |
| // down the frameView to to fit in the current viewport. |
| viewportRect.setSize(frameView.fixedLayoutSize()); |
| } else |
| viewportRect.setSize(frameView.sizeForVisibleContent()); |
| |
| if (fixedBackgroundPaintsInLocalCoordinates()) { |
| if (!useFixedLayout) { |
| // Shifting location up by topContentInset is needed for layout tests which expect |
| // layout to be shifted down when calling window.internals.setTopContentInset(). |
| topContentInset = frameView.topContentInset(ScrollView::TopContentInsetType::WebCoreOrPlatformContentInset); |
| viewportRect.setLocation(LayoutPoint(0, -topContentInset)); |
| } |
| } else if (useFixedLayout || frameView.frameScaleFactor() != 1) { |
| // scrollPositionForFixedPosition() is adjusted for page scale and it does not include |
| // topContentInset so do not add it to the calculation below. |
| viewportRect.setLocation(frameView.scrollPositionForFixedPosition()); |
| } else { |
| // documentScrollPositionRelativeToViewOrigin() includes -topContentInset in its height |
| // so we need to account for that in calculating the phase size |
| topContentInset = frameView.topContentInset(ScrollView::TopContentInsetType::WebCoreOrPlatformContentInset); |
| viewportRect.setLocation(frameView.documentScrollPositionRelativeToViewOrigin()); |
| } |
| |
| top += topContentInset; |
| } |
| |
| if (paintContainer) |
| viewportRect.moveBy(LayoutPoint(-paintContainer->localToAbsolute(FloatPoint()))); |
| |
| destinationRect = viewportRect; |
| positioningAreaSize = destinationRect.size(); |
| positioningAreaSize.setHeight(positioningAreaSize.height() - topContentInset); |
| positioningAreaSize = LayoutSize(snapRectToDevicePixels(LayoutRect(destinationRect.location(), positioningAreaSize), deviceScaleFactor).size()); |
| } |
| |
| auto clientForBackgroundImage = backgroundObject ? backgroundObject : this; |
| LayoutSize tileSize = calculateFillTileSize(fillLayer, positioningAreaSize); |
| if (StyleImage* layerImage = fillLayer.image()) |
| layerImage->setContainerContextForRenderer(*clientForBackgroundImage, tileSize, style().effectiveZoom()); |
| |
| EFillRepeat backgroundRepeatX = fillLayer.repeatX(); |
| EFillRepeat backgroundRepeatY = fillLayer.repeatY(); |
| LayoutUnit availableWidth = positioningAreaSize.width() - tileSize.width(); |
| LayoutUnit availableHeight = positioningAreaSize.height() - tileSize.height(); |
| |
| LayoutSize spaceSize; |
| LayoutSize phase; |
| LayoutSize noRepeat; |
| LayoutUnit computedXPosition = resolveEdgeRelativeLength(fillLayer.xPosition(), fillLayer.backgroundXOrigin(), availableWidth, positioningAreaSize, tileSize); |
| if (backgroundRepeatX == RoundFill && positioningAreaSize.width() > 0 && tileSize.width() > 0) { |
| int numTiles = std::max(1, roundToInt(positioningAreaSize.width() / tileSize.width())); |
| if (fillLayer.size().size.height.isAuto() && backgroundRepeatY != RoundFill) |
| tileSize.setHeight(tileSize.height() * positioningAreaSize.width() / (numTiles * tileSize.width())); |
| |
| tileSize.setWidth(positioningAreaSize.width() / numTiles); |
| phase.setWidth(tileSize.width() ? tileSize.width() - fmodf((computedXPosition + left), tileSize.width()) : 0); |
| } |
| |
| LayoutUnit computedYPosition = resolveEdgeRelativeLength(fillLayer.yPosition(), fillLayer.backgroundYOrigin(), availableHeight, positioningAreaSize, tileSize); |
| if (backgroundRepeatY == RoundFill && positioningAreaSize.height() > 0 && tileSize.height() > 0) { |
| int numTiles = std::max(1, roundToInt(positioningAreaSize.height() / tileSize.height())); |
| if (fillLayer.size().size.width.isAuto() && backgroundRepeatX != RoundFill) |
| tileSize.setWidth(tileSize.width() * positioningAreaSize.height() / (numTiles * tileSize.height())); |
| |
| tileSize.setHeight(positioningAreaSize.height() / numTiles); |
| phase.setHeight(tileSize.height() ? tileSize.height() - fmodf((computedYPosition + top), tileSize.height()) : 0); |
| } |
| |
| if (backgroundRepeatX == RepeatFill) { |
| phase.setWidth(tileSize.width() ? tileSize.width() - fmodf(computedXPosition + left, tileSize.width()) : 0); |
| spaceSize.setWidth(0); |
| } else if (backgroundRepeatX == SpaceFill && tileSize.width() > 0) { |
| LayoutUnit space = getSpace(positioningAreaSize.width(), tileSize.width()); |
| if (space >= 0) { |
| LayoutUnit actualWidth = tileSize.width() + space; |
| computedXPosition = minimumValueForLength(Length(), availableWidth); |
| spaceSize.setWidth(space); |
| spaceSize.setHeight(0); |
| phase.setWidth(actualWidth ? actualWidth - fmodf((computedXPosition + left), actualWidth) : 0); |
| } else |
| backgroundRepeatX = NoRepeatFill; |
| } |
| |
| if (backgroundRepeatX == NoRepeatFill) { |
| LayoutUnit xOffset = left + computedXPosition; |
| if (xOffset > 0) |
| destinationRect.move(xOffset, 0); |
| xOffset = std::min<LayoutUnit>(xOffset, 0); |
| phase.setWidth(-xOffset); |
| destinationRect.setWidth(tileSize.width() + xOffset); |
| spaceSize.setWidth(0); |
| } |
| |
| if (backgroundRepeatY == RepeatFill) { |
| phase.setHeight(tileSize.height() ? tileSize.height() - fmodf(computedYPosition + top, tileSize.height()) : 0); |
| spaceSize.setHeight(0); |
| } else if (backgroundRepeatY == SpaceFill && tileSize.height() > 0) { |
| LayoutUnit space = getSpace(positioningAreaSize.height(), tileSize.height()); |
| |
| if (space >= 0) { |
| LayoutUnit actualHeight = tileSize.height() + space; |
| computedYPosition = minimumValueForLength(Length(), availableHeight); |
| spaceSize.setHeight(space); |
| phase.setHeight(actualHeight ? actualHeight - fmodf((computedYPosition + top), actualHeight) : 0); |
| } else |
| backgroundRepeatY = NoRepeatFill; |
| } |
| if (backgroundRepeatY == NoRepeatFill) { |
| LayoutUnit yOffset = top + computedYPosition; |
| if (yOffset > 0) |
| destinationRect.move(0, yOffset); |
| yOffset = std::min<LayoutUnit>(yOffset, 0); |
| phase.setHeight(-yOffset); |
| destinationRect.setHeight(tileSize.height() + yOffset); |
| spaceSize.setHeight(0); |
| } |
| |
| if (fixedAttachment) { |
| LayoutPoint attachmentPoint = borderBoxRect.location(); |
| phase.expand(std::max<LayoutUnit>(attachmentPoint.x() - destinationRect.x(), 0), std::max<LayoutUnit>(attachmentPoint.y() - destinationRect.y(), 0)); |
| } |
| |
| destinationRect.intersect(borderBoxRect); |
| pixelSnapBackgroundImageGeometryForPainting(destinationRect, tileSize, phase, spaceSize, deviceScaleFactor); |
| return BackgroundImageGeometry(destinationRect, tileSize, phase, spaceSize, fixedAttachment); |
| } |
| |
| void RenderBoxModelObject::getGeometryForBackgroundImage(const RenderLayerModelObject* paintContainer, const LayoutPoint& paintOffset, FloatRect& destRect, FloatSize& phase, FloatSize& tileSize) const |
| { |
| LayoutRect paintRect(destRect); |
| auto geometry = calculateBackgroundImageGeometry(paintContainer, style().backgroundLayers(), paintOffset, paintRect); |
| phase = geometry.phase(); |
| tileSize = geometry.tileSize(); |
| destRect = geometry.destRect(); |
| } |
| |
| bool RenderBoxModelObject::paintNinePieceImage(GraphicsContext& graphicsContext, const LayoutRect& rect, const RenderStyle& style, |
| const NinePieceImage& ninePieceImage, CompositeOperator op) |
| { |
| StyleImage* styleImage = ninePieceImage.image(); |
| if (!styleImage) |
| return false; |
| |
| if (!styleImage->isLoaded()) |
| return true; // Never paint a nine-piece image incrementally, but don't paint the fallback borders either. |
| |
| if (!styleImage->canRender(this, style.effectiveZoom())) |
| return false; |
| |
| // FIXME: border-image is broken with full page zooming when tiling has to happen, since the tiling function |
| // doesn't have any understanding of the zoom that is in effect on the tile. |
| float deviceScaleFactor = document().deviceScaleFactor(); |
| |
| LayoutRect rectWithOutsets = rect; |
| rectWithOutsets.expand(style.imageOutsets(ninePieceImage)); |
| LayoutRect destination = LayoutRect(snapRectToDevicePixels(rectWithOutsets, deviceScaleFactor)); |
| |
| LayoutSize source = calculateImageIntrinsicDimensions(styleImage, destination.size(), DoNotScaleByEffectiveZoom); |
| |
| // If both values are ‘auto’ then the intrinsic width and/or height of the image should be used, if any. |
| styleImage->setContainerContextForRenderer(*this, source, style.effectiveZoom()); |
| |
| ninePieceImage.paint(graphicsContext, this, style, destination, source, deviceScaleFactor, op); |
| return true; |
| } |
| |
| static bool allCornersClippedOut(const RoundedRect& border, const LayoutRect& clipRect) |
| { |
| LayoutRect boundingRect = border.rect(); |
| if (clipRect.contains(boundingRect)) |
| return false; |
| |
| RoundedRect::Radii radii = border.radii(); |
| |
| LayoutRect topLeftRect(boundingRect.location(), radii.topLeft()); |
| if (clipRect.intersects(topLeftRect)) |
| return false; |
| |
| LayoutRect topRightRect(boundingRect.location(), radii.topRight()); |
| topRightRect.setX(boundingRect.maxX() - topRightRect.width()); |
| if (clipRect.intersects(topRightRect)) |
| return false; |
| |
| LayoutRect bottomLeftRect(boundingRect.location(), radii.bottomLeft()); |
| bottomLeftRect.setY(boundingRect.maxY() - bottomLeftRect.height()); |
| if (clipRect.intersects(bottomLeftRect)) |
| return false; |
| |
| LayoutRect bottomRightRect(boundingRect.location(), radii.bottomRight()); |
| bottomRightRect.setX(boundingRect.maxX() - bottomRightRect.width()); |
| bottomRightRect.setY(boundingRect.maxY() - bottomRightRect.height()); |
| if (clipRect.intersects(bottomRightRect)) |
| return false; |
| |
| return true; |
| } |
| |
| static bool borderWillArcInnerEdge(const LayoutSize& firstRadius, const FloatSize& secondRadius) |
| { |
| return !firstRadius.isZero() || !secondRadius.isZero(); |
| } |
| |
| inline bool styleRequiresClipPolygon(EBorderStyle style) |
| { |
| return style == DOTTED || style == DASHED; // These are drawn with a stroke, so we have to clip to get corner miters. |
| } |
| |
| static bool borderStyleFillsBorderArea(EBorderStyle style) |
| { |
| return !(style == DOTTED || style == DASHED || style == DOUBLE); |
| } |
| |
| static bool borderStyleHasInnerDetail(EBorderStyle style) |
| { |
| return style == GROOVE || style == RIDGE || style == DOUBLE; |
| } |
| |
| static bool borderStyleIsDottedOrDashed(EBorderStyle style) |
| { |
| return style == DOTTED || style == DASHED; |
| } |
| |
| // OUTSET darkens the bottom and right (and maybe lightens the top and left) |
| // INSET darkens the top and left (and maybe lightens the bottom and right) |
| static inline bool borderStyleHasUnmatchedColorsAtCorner(EBorderStyle style, BoxSide side, BoxSide adjacentSide) |
| { |
| // These styles match at the top/left and bottom/right. |
| if (style == INSET || style == GROOVE || style == RIDGE || style == OUTSET) { |
| const BorderEdgeFlags topRightFlags = edgeFlagForSide(BSTop) | edgeFlagForSide(BSRight); |
| const BorderEdgeFlags bottomLeftFlags = edgeFlagForSide(BSBottom) | edgeFlagForSide(BSLeft); |
| |
| BorderEdgeFlags flags = edgeFlagForSide(side) | edgeFlagForSide(adjacentSide); |
| return flags == topRightFlags || flags == bottomLeftFlags; |
| } |
| return false; |
| } |
| |
| static inline bool colorsMatchAtCorner(BoxSide side, BoxSide adjacentSide, const BorderEdge edges[]) |
| { |
| if (edges[side].shouldRender() != edges[adjacentSide].shouldRender()) |
| return false; |
| |
| if (!edgesShareColor(edges[side], edges[adjacentSide])) |
| return false; |
| |
| return !borderStyleHasUnmatchedColorsAtCorner(edges[side].style(), side, adjacentSide); |
| } |
| |
| |
| static inline bool colorNeedsAntiAliasAtCorner(BoxSide side, BoxSide adjacentSide, const BorderEdge edges[]) |
| { |
| if (edges[side].color().isOpaque()) |
| return false; |
| |
| if (edges[side].shouldRender() != edges[adjacentSide].shouldRender()) |
| return false; |
| |
| if (!edgesShareColor(edges[side], edges[adjacentSide])) |
| return true; |
| |
| return borderStyleHasUnmatchedColorsAtCorner(edges[side].style(), side, adjacentSide); |
| } |
| |
| // This assumes that we draw in order: top, bottom, left, right. |
| static inline bool willBeOverdrawn(BoxSide side, BoxSide adjacentSide, const BorderEdge edges[]) |
| { |
| switch (side) { |
| case BSTop: |
| case BSBottom: |
| if (edges[adjacentSide].presentButInvisible()) |
| return false; |
| |
| if (!edgesShareColor(edges[side], edges[adjacentSide]) && !edges[adjacentSide].color().isOpaque()) |
| return false; |
| |
| if (!borderStyleFillsBorderArea(edges[adjacentSide].style())) |
| return false; |
| |
| return true; |
| |
| case BSLeft: |
| case BSRight: |
| // These draw last, so are never overdrawn. |
| return false; |
| } |
| return false; |
| } |
| |
| static inline bool borderStylesRequireMitre(BoxSide side, BoxSide adjacentSide, EBorderStyle style, EBorderStyle adjacentStyle) |
| { |
| if (style == DOUBLE || adjacentStyle == DOUBLE || adjacentStyle == GROOVE || adjacentStyle == RIDGE) |
| return true; |
| |
| if (borderStyleIsDottedOrDashed(style) != borderStyleIsDottedOrDashed(adjacentStyle)) |
| return true; |
| |
| if (style != adjacentStyle) |
| return true; |
| |
| return borderStyleHasUnmatchedColorsAtCorner(style, side, adjacentSide); |
| } |
| |
| static bool joinRequiresMitre(BoxSide side, BoxSide adjacentSide, const BorderEdge edges[], bool allowOverdraw) |
| { |
| if ((edges[side].isTransparent() && edges[adjacentSide].isTransparent()) || !edges[adjacentSide].isPresent()) |
| return false; |
| |
| if (allowOverdraw && willBeOverdrawn(side, adjacentSide, edges)) |
| return false; |
| |
| if (!edgesShareColor(edges[side], edges[adjacentSide])) |
| return true; |
| |
| if (borderStylesRequireMitre(side, adjacentSide, edges[side].style(), edges[adjacentSide].style())) |
| return true; |
| |
| return false; |
| } |
| |
| static RoundedRect calculateAdjustedInnerBorder(const RoundedRect&innerBorder, BoxSide side) |
| { |
| // Expand the inner border as necessary to make it a rounded rect (i.e. radii contained within each edge). |
| // This function relies on the fact we only get radii not contained within each edge if one of the radii |
| // for an edge is zero, so we can shift the arc towards the zero radius corner. |
| RoundedRect::Radii newRadii = innerBorder.radii(); |
| LayoutRect newRect = innerBorder.rect(); |
| |
| float overshoot; |
| float maxRadii; |
| |
| switch (side) { |
| case BSTop: |
| overshoot = newRadii.topLeft().width() + newRadii.topRight().width() - newRect.width(); |
| if (overshoot > 0) { |
| ASSERT(!(newRadii.topLeft().width() && newRadii.topRight().width())); |
| newRect.setWidth(newRect.width() + overshoot); |
| if (!newRadii.topLeft().width()) |
| newRect.move(-overshoot, 0); |
| } |
| newRadii.setBottomLeft(IntSize(0, 0)); |
| newRadii.setBottomRight(IntSize(0, 0)); |
| maxRadii = std::max(newRadii.topLeft().height(), newRadii.topRight().height()); |
| if (maxRadii > newRect.height()) |
| newRect.setHeight(maxRadii); |
| break; |
| |
| case BSBottom: |
| overshoot = newRadii.bottomLeft().width() + newRadii.bottomRight().width() - newRect.width(); |
| if (overshoot > 0) { |
| ASSERT(!(newRadii.bottomLeft().width() && newRadii.bottomRight().width())); |
| newRect.setWidth(newRect.width() + overshoot); |
| if (!newRadii.bottomLeft().width()) |
| newRect.move(-overshoot, 0); |
| } |
| newRadii.setTopLeft(IntSize(0, 0)); |
| newRadii.setTopRight(IntSize(0, 0)); |
| maxRadii = std::max(newRadii.bottomLeft().height(), newRadii.bottomRight().height()); |
| if (maxRadii > newRect.height()) { |
| newRect.move(0, newRect.height() - maxRadii); |
| newRect.setHeight(maxRadii); |
| } |
| break; |
| |
| case BSLeft: |
| overshoot = newRadii.topLeft().height() + newRadii.bottomLeft().height() - newRect.height(); |
| if (overshoot > 0) { |
| ASSERT(!(newRadii.topLeft().height() && newRadii.bottomLeft().height())); |
| newRect.setHeight(newRect.height() + overshoot); |
| if (!newRadii.topLeft().height()) |
| newRect.move(0, -overshoot); |
| } |
| newRadii.setTopRight(IntSize(0, 0)); |
| newRadii.setBottomRight(IntSize(0, 0)); |
| maxRadii = std::max(newRadii.topLeft().width(), newRadii.bottomLeft().width()); |
| if (maxRadii > newRect.width()) |
| newRect.setWidth(maxRadii); |
| break; |
| |
| case BSRight: |
| overshoot = newRadii.topRight().height() + newRadii.bottomRight().height() - newRect.height(); |
| if (overshoot > 0) { |
| ASSERT(!(newRadii.topRight().height() && newRadii.bottomRight().height())); |
| newRect.setHeight(newRect.height() + overshoot); |
| if (!newRadii.topRight().height()) |
| newRect.move(0, -overshoot); |
| } |
| newRadii.setTopLeft(IntSize(0, 0)); |
| newRadii.setBottomLeft(IntSize(0, 0)); |
| maxRadii = std::max(newRadii.topRight().width(), newRadii.bottomRight().width()); |
| if (maxRadii > newRect.width()) { |
| newRect.move(newRect.width() - maxRadii, 0); |
| newRect.setWidth(maxRadii); |
| } |
| break; |
| } |
| |
| return RoundedRect(newRect, newRadii); |
| } |
| |
| void RenderBoxModelObject::paintOneBorderSide(GraphicsContext& graphicsContext, const RenderStyle& style, const RoundedRect& outerBorder, const RoundedRect& innerBorder, |
| const LayoutRect& sideRect, BoxSide side, BoxSide adjacentSide1, BoxSide adjacentSide2, const BorderEdge edges[], const Path* path, |
| BackgroundBleedAvoidance bleedAvoidance, bool includeLogicalLeftEdge, bool includeLogicalRightEdge, bool antialias, const Color* overrideColor) |
| { |
| const BorderEdge& edgeToRender = edges[side]; |
| ASSERT(edgeToRender.widthForPainting()); |
| const BorderEdge& adjacentEdge1 = edges[adjacentSide1]; |
| const BorderEdge& adjacentEdge2 = edges[adjacentSide2]; |
| |
| bool mitreAdjacentSide1 = joinRequiresMitre(side, adjacentSide1, edges, !antialias); |
| bool mitreAdjacentSide2 = joinRequiresMitre(side, adjacentSide2, edges, !antialias); |
| |
| bool adjacentSide1StylesMatch = colorsMatchAtCorner(side, adjacentSide1, edges); |
| bool adjacentSide2StylesMatch = colorsMatchAtCorner(side, adjacentSide2, edges); |
| |
| const Color& colorToPaint = overrideColor ? *overrideColor : edgeToRender.color(); |
| |
| if (path) { |
| GraphicsContextStateSaver stateSaver(graphicsContext); |
| |
| clipBorderSidePolygon(graphicsContext, outerBorder, innerBorder, side, adjacentSide1StylesMatch, adjacentSide2StylesMatch); |
| |
| if (!innerBorder.isRenderable()) |
| graphicsContext.clipOutRoundedRect(FloatRoundedRect(calculateAdjustedInnerBorder(innerBorder, side))); |
| |
| float thickness = std::max(std::max(edgeToRender.widthForPainting(), adjacentEdge1.widthForPainting()), adjacentEdge2.widthForPainting()); |
| drawBoxSideFromPath(graphicsContext, outerBorder.rect(), *path, edges, edgeToRender.widthForPainting(), thickness, side, style, |
| colorToPaint, edgeToRender.style(), bleedAvoidance, includeLogicalLeftEdge, includeLogicalRightEdge); |
| } else { |
| bool clipForStyle = styleRequiresClipPolygon(edgeToRender.style()) && (mitreAdjacentSide1 || mitreAdjacentSide2); |
| bool clipAdjacentSide1 = colorNeedsAntiAliasAtCorner(side, adjacentSide1, edges) && mitreAdjacentSide1; |
| bool clipAdjacentSide2 = colorNeedsAntiAliasAtCorner(side, adjacentSide2, edges) && mitreAdjacentSide2; |
| bool shouldClip = clipForStyle || clipAdjacentSide1 || clipAdjacentSide2; |
| |
| GraphicsContextStateSaver clipStateSaver(graphicsContext, shouldClip); |
| if (shouldClip) { |
| bool aliasAdjacentSide1 = clipAdjacentSide1 || (clipForStyle && mitreAdjacentSide1); |
| bool aliasAdjacentSide2 = clipAdjacentSide2 || (clipForStyle && mitreAdjacentSide2); |
| clipBorderSidePolygon(graphicsContext, outerBorder, innerBorder, side, !aliasAdjacentSide1, !aliasAdjacentSide2); |
| // Since we clipped, no need to draw with a mitre. |
| mitreAdjacentSide1 = false; |
| mitreAdjacentSide2 = false; |
| } |
| drawLineForBoxSide(graphicsContext, sideRect, side, colorToPaint, edgeToRender.style(), mitreAdjacentSide1 ? adjacentEdge1.widthForPainting() : 0, mitreAdjacentSide2 ? adjacentEdge2.widthForPainting() : 0, antialias); |
| } |
| } |
| |
| static LayoutRect calculateSideRect(const RoundedRect& outerBorder, const BorderEdge edges[], int side) |
| { |
| LayoutRect sideRect = outerBorder.rect(); |
| float width = edges[side].widthForPainting(); |
| |
| if (side == BSTop) |
| sideRect.setHeight(width); |
| else if (side == BSBottom) |
| sideRect.shiftYEdgeTo(sideRect.maxY() - width); |
| else if (side == BSLeft) |
| sideRect.setWidth(width); |
| else |
| sideRect.shiftXEdgeTo(sideRect.maxX() - width); |
| |
| return sideRect; |
| } |
| |
| void RenderBoxModelObject::paintBorderSides(GraphicsContext& graphicsContext, const RenderStyle& style, const RoundedRect& outerBorder, const RoundedRect& innerBorder, |
| const IntPoint& innerBorderAdjustment, const BorderEdge edges[], BorderEdgeFlags edgeSet, BackgroundBleedAvoidance bleedAvoidance, |
| bool includeLogicalLeftEdge, bool includeLogicalRightEdge, bool antialias, const Color* overrideColor) |
| { |
| bool renderRadii = outerBorder.isRounded(); |
| |
| Path roundedPath; |
| if (renderRadii) |
| roundedPath.addRoundedRect(outerBorder); |
| |
| // The inner border adjustment for bleed avoidance mode BackgroundBleedBackgroundOverBorder |
| // is only applied to sideRect, which is okay since BackgroundBleedBackgroundOverBorder |
| // is only to be used for solid borders and the shape of the border painted by drawBoxSideFromPath |
| // only depends on sideRect when painting solid borders. |
| |
| if (edges[BSTop].shouldRender() && includesEdge(edgeSet, BSTop)) { |
| LayoutRect sideRect = outerBorder.rect(); |
| sideRect.setHeight(edges[BSTop].widthForPainting() + innerBorderAdjustment.y()); |
| |
| bool usePath = renderRadii && (borderStyleHasInnerDetail(edges[BSTop].style()) || borderWillArcInnerEdge(innerBorder.radii().topLeft(), innerBorder.radii().topRight())); |
| paintOneBorderSide(graphicsContext, style, outerBorder, innerBorder, sideRect, BSTop, BSLeft, BSRight, edges, usePath ? &roundedPath : nullptr, bleedAvoidance, includeLogicalLeftEdge, includeLogicalRightEdge, antialias, overrideColor); |
| } |
| |
| if (edges[BSBottom].shouldRender() && includesEdge(edgeSet, BSBottom)) { |
| LayoutRect sideRect = outerBorder.rect(); |
| sideRect.shiftYEdgeTo(sideRect.maxY() - edges[BSBottom].widthForPainting() - innerBorderAdjustment.y()); |
| |
| bool usePath = renderRadii && (borderStyleHasInnerDetail(edges[BSBottom].style()) || borderWillArcInnerEdge(innerBorder.radii().bottomLeft(), innerBorder.radii().bottomRight())); |
| paintOneBorderSide(graphicsContext, style, outerBorder, innerBorder, sideRect, BSBottom, BSLeft, BSRight, edges, usePath ? &roundedPath : nullptr, bleedAvoidance, includeLogicalLeftEdge, includeLogicalRightEdge, antialias, overrideColor); |
| } |
| |
| if (edges[BSLeft].shouldRender() && includesEdge(edgeSet, BSLeft)) { |
| LayoutRect sideRect = outerBorder.rect(); |
| sideRect.setWidth(edges[BSLeft].widthForPainting() + innerBorderAdjustment.x()); |
| |
| bool usePath = renderRadii && (borderStyleHasInnerDetail(edges[BSLeft].style()) || borderWillArcInnerEdge(innerBorder.radii().bottomLeft(), innerBorder.radii().topLeft())); |
| paintOneBorderSide(graphicsContext, style, outerBorder, innerBorder, sideRect, BSLeft, BSTop, BSBottom, edges, usePath ? &roundedPath : nullptr, bleedAvoidance, includeLogicalLeftEdge, includeLogicalRightEdge, antialias, overrideColor); |
| } |
| |
| if (edges[BSRight].shouldRender() && includesEdge(edgeSet, BSRight)) { |
| LayoutRect sideRect = outerBorder.rect(); |
| sideRect.shiftXEdgeTo(sideRect.maxX() - edges[BSRight].widthForPainting() - innerBorderAdjustment.x()); |
| |
| bool usePath = renderRadii && (borderStyleHasInnerDetail(edges[BSRight].style()) || borderWillArcInnerEdge(innerBorder.radii().bottomRight(), innerBorder.radii().topRight())); |
| paintOneBorderSide(graphicsContext, style, outerBorder, innerBorder, sideRect, BSRight, BSTop, BSBottom, edges, usePath ? &roundedPath : nullptr, bleedAvoidance, includeLogicalLeftEdge, includeLogicalRightEdge, antialias, overrideColor); |
| } |
| } |
| |
| void RenderBoxModelObject::paintTranslucentBorderSides(GraphicsContext& graphicsContext, const RenderStyle& style, const RoundedRect& outerBorder, const RoundedRect& innerBorder, const IntPoint& innerBorderAdjustment, |
| const BorderEdge edges[], BorderEdgeFlags edgesToDraw, BackgroundBleedAvoidance bleedAvoidance, bool includeLogicalLeftEdge, bool includeLogicalRightEdge, bool antialias) |
| { |
| // willBeOverdrawn assumes that we draw in order: top, bottom, left, right. |
| // This is different from BoxSide enum order. |
| static const BoxSide paintOrder[] = { BSTop, BSBottom, BSLeft, BSRight }; |
| |
| while (edgesToDraw) { |
| // Find undrawn edges sharing a color. |
| Color commonColor; |
| |
| BorderEdgeFlags commonColorEdgeSet = 0; |
| for (size_t i = 0; i < sizeof(paintOrder) / sizeof(paintOrder[0]); ++i) { |
| BoxSide currSide = paintOrder[i]; |
| if (!includesEdge(edgesToDraw, currSide)) |
| continue; |
| |
| bool includeEdge; |
| if (!commonColorEdgeSet) { |
| commonColor = edges[currSide].color(); |
| includeEdge = true; |
| } else |
| includeEdge = edges[currSide].color() == commonColor; |
| |
| if (includeEdge) |
| commonColorEdgeSet |= edgeFlagForSide(currSide); |
| } |
| |
| bool useTransparencyLayer = includesAdjacentEdges(commonColorEdgeSet) && !commonColor.isOpaque(); |
| if (useTransparencyLayer) { |
| graphicsContext.beginTransparencyLayer(commonColor.alphaAsFloat()); |
| commonColor = commonColor.opaqueColor(); |
| } |
| |
| paintBorderSides(graphicsContext, style, outerBorder, innerBorder, innerBorderAdjustment, edges, commonColorEdgeSet, bleedAvoidance, includeLogicalLeftEdge, includeLogicalRightEdge, antialias, &commonColor); |
| |
| if (useTransparencyLayer) |
| graphicsContext.endTransparencyLayer(); |
| |
| edgesToDraw &= ~commonColorEdgeSet; |
| } |
| } |
| |
| void RenderBoxModelObject::paintBorder(const PaintInfo& info, const LayoutRect& rect, const RenderStyle& style, |
| BackgroundBleedAvoidance bleedAvoidance, bool includeLogicalLeftEdge, bool includeLogicalRightEdge) |
| { |
| GraphicsContext& graphicsContext = info.context(); |
| |
| if (graphicsContext.paintingDisabled()) |
| return; |
| |
| if (rect.isEmpty()) |
| return; |
| |
| auto rectToClipOut = paintRectToClipOutFromBorder(rect); |
| bool appliedClipAlready = !rectToClipOut.isEmpty(); |
| GraphicsContextStateSaver stateSave(graphicsContext, appliedClipAlready); |
| if (!rectToClipOut.isEmpty()) |
| graphicsContext.clipOut(snapRectToDevicePixels(rectToClipOut, document().deviceScaleFactor())); |
| |
| // border-image is not affected by border-radius. |
| if (paintNinePieceImage(graphicsContext, rect, style, style.borderImage())) |
| return; |
| |
| BorderEdge edges[4]; |
| BorderEdge::getBorderEdgeInfo(edges, style, document().deviceScaleFactor(), includeLogicalLeftEdge, includeLogicalRightEdge); |
| RoundedRect outerBorder = style.getRoundedBorderFor(rect, includeLogicalLeftEdge, includeLogicalRightEdge); |
| RoundedRect innerBorder = style.getRoundedInnerBorderFor(borderInnerRectAdjustedForBleedAvoidance(graphicsContext, rect, bleedAvoidance), includeLogicalLeftEdge, includeLogicalRightEdge); |
| |
| // If no borders intersects with the dirty area, we can skip the border painting. |
| if (innerBorder.contains(info.rect)) |
| return; |
| |
| bool haveAlphaColor = false; |
| bool haveAllSolidEdges = true; |
| bool haveAllDoubleEdges = true; |
| int numEdgesVisible = 4; |
| bool allEdgesShareColor = true; |
| int firstVisibleEdge = -1; |
| BorderEdgeFlags edgesToDraw = 0; |
| |
| for (int i = BSTop; i <= BSLeft; ++i) { |
| const BorderEdge& currEdge = edges[i]; |
| |
| if (edges[i].shouldRender()) |
| edgesToDraw |= edgeFlagForSide(static_cast<BoxSide>(i)); |
| |
| if (currEdge.presentButInvisible()) { |
| --numEdgesVisible; |
| allEdgesShareColor = false; |
| continue; |
| } |
| |
| if (!currEdge.widthForPainting()) { |
| --numEdgesVisible; |
| continue; |
| } |
| |
| if (firstVisibleEdge == -1) |
| firstVisibleEdge = i; |
| else if (currEdge.color() != edges[firstVisibleEdge].color()) |
| allEdgesShareColor = false; |
| |
| if (!currEdge.color().isOpaque()) |
| haveAlphaColor = true; |
| |
| if (currEdge.style() != SOLID) |
| haveAllSolidEdges = false; |
| |
| if (currEdge.style() != DOUBLE) |
| haveAllDoubleEdges = false; |
| } |
| |
| // If no corner intersects the clip region, we can pretend outerBorder is |
| // rectangular to improve performance. |
| if (haveAllSolidEdges && outerBorder.isRounded() && allCornersClippedOut(outerBorder, info.rect)) |
| outerBorder.setRadii(RoundedRect::Radii()); |
| |
| float deviceScaleFactor = document().deviceScaleFactor(); |
| // isRenderable() check avoids issue described in https://bugs.webkit.org/show_bug.cgi?id=38787 |
| if ((haveAllSolidEdges || haveAllDoubleEdges) && allEdgesShareColor && innerBorder.isRenderable()) { |
| // Fast path for drawing all solid edges and all unrounded double edges |
| if (numEdgesVisible == 4 && (outerBorder.isRounded() || haveAlphaColor) |
| && (haveAllSolidEdges || (!outerBorder.isRounded() && !innerBorder.isRounded()))) { |
| Path path; |
| |
| FloatRoundedRect pixelSnappedOuterBorder = outerBorder.pixelSnappedRoundedRectForPainting(deviceScaleFactor); |
| if (pixelSnappedOuterBorder.isRounded() && bleedAvoidance != BackgroundBleedUseTransparencyLayer) |
| path.addRoundedRect(pixelSnappedOuterBorder); |
| else |
| path.addRect(pixelSnappedOuterBorder.rect()); |
| |
| if (haveAllDoubleEdges) { |
| LayoutRect innerThirdRect = outerBorder.rect(); |
| LayoutRect outerThirdRect = outerBorder.rect(); |
| for (int side = BSTop; side <= BSLeft; ++side) { |
| LayoutUnit outerWidth; |
| LayoutUnit innerWidth; |
| edges[side].getDoubleBorderStripeWidths(outerWidth, innerWidth); |
| |
| if (side == BSTop) { |
| innerThirdRect.shiftYEdgeTo(innerThirdRect.y() + innerWidth); |
| outerThirdRect.shiftYEdgeTo(outerThirdRect.y() + outerWidth); |
| } else if (side == BSBottom) { |
| innerThirdRect.setHeight(innerThirdRect.height() - innerWidth); |
| outerThirdRect.setHeight(outerThirdRect.height() - outerWidth); |
| } else if (side == BSLeft) { |
| innerThirdRect.shiftXEdgeTo(innerThirdRect.x() + innerWidth); |
| outerThirdRect.shiftXEdgeTo(outerThirdRect.x() + outerWidth); |
| } else { |
| innerThirdRect.setWidth(innerThirdRect.width() - innerWidth); |
| outerThirdRect.setWidth(outerThirdRect.width() - outerWidth); |
| } |
| } |
| |
| FloatRoundedRect pixelSnappedOuterThird = outerBorder.pixelSnappedRoundedRectForPainting(deviceScaleFactor); |
| pixelSnappedOuterThird.setRect(snapRectToDevicePixels(outerThirdRect, deviceScaleFactor)); |
| |
| if (pixelSnappedOuterThird.isRounded() && bleedAvoidance != BackgroundBleedUseTransparencyLayer) |
| path.addRoundedRect(pixelSnappedOuterThird); |
| else |
| path.addRect(pixelSnappedOuterThird.rect()); |
| |
| FloatRoundedRect pixelSnappedInnerThird = innerBorder.pixelSnappedRoundedRectForPainting(deviceScaleFactor); |
| pixelSnappedInnerThird.setRect(snapRectToDevicePixels(innerThirdRect, deviceScaleFactor)); |
| if (pixelSnappedInnerThird.isRounded() && bleedAvoidance != BackgroundBleedUseTransparencyLayer) |
| path.addRoundedRect(pixelSnappedInnerThird); |
| else |
| path.addRect(pixelSnappedInnerThird.rect()); |
| } |
| |
| FloatRoundedRect pixelSnappedInnerBorder = innerBorder.pixelSnappedRoundedRectForPainting(deviceScaleFactor); |
| if (pixelSnappedInnerBorder.isRounded()) |
| path.addRoundedRect(pixelSnappedInnerBorder); |
| else |
| path.addRect(pixelSnappedInnerBorder.rect()); |
| |
| graphicsContext.setFillRule(RULE_EVENODD); |
| graphicsContext.setFillColor(edges[firstVisibleEdge].color()); |
| graphicsContext.fillPath(path); |
| return; |
| } |
| // Avoid creating transparent layers |
| if (haveAllSolidEdges && numEdgesVisible != 4 && !outerBorder.isRounded() && haveAlphaColor) { |
| Path path; |
| |
| for (int i = BSTop; i <= BSLeft; ++i) { |
| const BorderEdge& currEdge = edges[i]; |
| if (currEdge.shouldRender()) { |
| LayoutRect sideRect = calculateSideRect(outerBorder, edges, i); |
| path.addRect(sideRect); |
| } |
| } |
| |
| graphicsContext.setFillRule(RULE_NONZERO); |
| graphicsContext.setFillColor(edges[firstVisibleEdge].color()); |
| graphicsContext.fillPath(path); |
| return; |
| } |
| } |
| |
| bool clipToOuterBorder = outerBorder.isRounded(); |
| GraphicsContextStateSaver stateSaver(graphicsContext, clipToOuterBorder && !appliedClipAlready); |
| if (clipToOuterBorder) { |
| // Clip to the inner and outer radii rects. |
| if (bleedAvoidance != BackgroundBleedUseTransparencyLayer) |
| graphicsContext.clipRoundedRect(outerBorder.pixelSnappedRoundedRectForPainting(deviceScaleFactor)); |
| // isRenderable() check avoids issue described in https://bugs.webkit.org/show_bug.cgi?id=38787 |
| // The inside will be clipped out later (in clipBorderSideForComplexInnerPath) |
| if (innerBorder.isRenderable()) |
| graphicsContext.clipOutRoundedRect(innerBorder.pixelSnappedRoundedRectForPainting(deviceScaleFactor)); |
| } |
| |
| // If only one edge visible antialiasing doesn't create seams |
| bool antialias = shouldAntialiasLines(graphicsContext) || numEdgesVisible == 1; |
| RoundedRect unadjustedInnerBorder = (bleedAvoidance == BackgroundBleedBackgroundOverBorder) ? style.getRoundedInnerBorderFor(rect, includeLogicalLeftEdge, includeLogicalRightEdge) : innerBorder; |
| IntPoint innerBorderAdjustment(innerBorder.rect().x() - unadjustedInnerBorder.rect().x(), innerBorder.rect().y() - unadjustedInnerBorder.rect().y()); |
| if (haveAlphaColor) |
| paintTranslucentBorderSides(graphicsContext, style, outerBorder, unadjustedInnerBorder, innerBorderAdjustment, edges, edgesToDraw, bleedAvoidance, includeLogicalLeftEdge, includeLogicalRightEdge, antialias); |
| else |
| paintBorderSides(graphicsContext, style, outerBorder, unadjustedInnerBorder, innerBorderAdjustment, edges, edgesToDraw, bleedAvoidance, includeLogicalLeftEdge, includeLogicalRightEdge, antialias); |
| } |
| |
| void RenderBoxModelObject::drawBoxSideFromPath(GraphicsContext& graphicsContext, const LayoutRect& borderRect, const Path& borderPath, const BorderEdge edges[], |
| float thickness, float drawThickness, BoxSide side, const RenderStyle& style, Color color, EBorderStyle borderStyle, BackgroundBleedAvoidance bleedAvoidance, |
| bool includeLogicalLeftEdge, bool includeLogicalRightEdge) |
| { |
| if (thickness <= 0) |
| return; |
| |
| if (borderStyle == DOUBLE && thickness < 3) |
| borderStyle = SOLID; |
| |
| switch (borderStyle) { |
| case BNONE: |
| case BHIDDEN: |
| return; |
| case DOTTED: |
| case DASHED: { |
| graphicsContext.setStrokeColor(color); |
| |
| // The stroke is doubled here because the provided path is the |
| // outside edge of the border so half the stroke is clipped off. |
| // The extra multiplier is so that the clipping mask can antialias |
| // the edges to prevent jaggies. |
| graphicsContext.setStrokeThickness(drawThickness * 2 * 1.1f); |
| graphicsContext.setStrokeStyle(borderStyle == DASHED ? DashedStroke : DottedStroke); |
| |
| // If the number of dashes that fit in the path is odd and non-integral then we |
| // will have an awkwardly-sized dash at the end of the path. To try to avoid that |
| // here, we simply make the whitespace dashes ever so slightly bigger. |
| // FIXME: This could be even better if we tried to manipulate the dash offset |
| // and possibly the gapLength to get the corners dash-symmetrical. |
| float dashLength = thickness * ((borderStyle == DASHED) ? 3.0f : 1.0f); |
| float gapLength = dashLength; |
| float numberOfDashes = borderPath.length() / dashLength; |
| // Don't try to show dashes if we have less than 2 dashes + 2 gaps. |
| // FIXME: should do this test per side. |
| if (numberOfDashes >= 4) { |
| bool evenNumberOfFullDashes = !((int)numberOfDashes % 2); |
| bool integralNumberOfDashes = !(numberOfDashes - (int)numberOfDashes); |
| if (!evenNumberOfFullDashes && !integralNumberOfDashes) { |
| float numberOfGaps = numberOfDashes / 2; |
| gapLength += (dashLength / numberOfGaps); |
| } |
| |
| DashArray lineDash; |
| lineDash.append(dashLength); |
| lineDash.append(gapLength); |
| graphicsContext.setLineDash(lineDash, dashLength); |
| } |
| |
| // FIXME: stroking the border path causes issues with tight corners: |
| // https://bugs.webkit.org/show_bug.cgi?id=58711 |
| // Also, to get the best appearance we should stroke a path between the two borders. |
| graphicsContext.strokePath(borderPath); |
| return; |
| } |
| case DOUBLE: { |
| // Get the inner border rects for both the outer border line and the inner border line |
| LayoutUnit outerBorderTopWidth; |
| LayoutUnit innerBorderTopWidth; |
| edges[BSTop].getDoubleBorderStripeWidths(outerBorderTopWidth, innerBorderTopWidth); |
| |
| LayoutUnit outerBorderRightWidth; |
| LayoutUnit innerBorderRightWidth; |
| edges[BSRight].getDoubleBorderStripeWidths(outerBorderRightWidth, innerBorderRightWidth); |
| |
| LayoutUnit outerBorderBottomWidth; |
| LayoutUnit innerBorderBottomWidth; |
| edges[BSBottom].getDoubleBorderStripeWidths(outerBorderBottomWidth, innerBorderBottomWidth); |
| |
| LayoutUnit outerBorderLeftWidth; |
| LayoutUnit innerBorderLeftWidth; |
| edges[BSLeft].getDoubleBorderStripeWidths(outerBorderLeftWidth, innerBorderLeftWidth); |
| |
| // Draw inner border line |
| { |
| GraphicsContextStateSaver stateSaver(graphicsContext); |
| RoundedRect innerClip = style.getRoundedInnerBorderFor(borderRect, |
| innerBorderTopWidth, innerBorderBottomWidth, innerBorderLeftWidth, innerBorderRightWidth, |
| includeLogicalLeftEdge, includeLogicalRightEdge); |
| |
| graphicsContext.clipRoundedRect(FloatRoundedRect(innerClip)); |
| drawBoxSideFromPath(graphicsContext, borderRect, borderPath, edges, thickness, drawThickness, side, style, color, SOLID, bleedAvoidance, includeLogicalLeftEdge, includeLogicalRightEdge); |
| } |
| |
| // Draw outer border line |
| { |
| GraphicsContextStateSaver stateSaver(graphicsContext); |
| LayoutRect outerRect = borderRect; |
| if (bleedAvoidance == BackgroundBleedUseTransparencyLayer) { |
| outerRect.inflate(1); |
| ++outerBorderTopWidth; |
| ++outerBorderBottomWidth; |
| ++outerBorderLeftWidth; |
| ++outerBorderRightWidth; |
| } |
| |
| RoundedRect outerClip = style.getRoundedInnerBorderFor(outerRect, |
| outerBorderTopWidth, outerBorderBottomWidth, outerBorderLeftWidth, outerBorderRightWidth, |
| includeLogicalLeftEdge, includeLogicalRightEdge); |
| graphicsContext.clipOutRoundedRect(FloatRoundedRect(outerClip)); |
| drawBoxSideFromPath(graphicsContext, borderRect, borderPath, edges, thickness, drawThickness, side, style, color, SOLID, bleedAvoidance, includeLogicalLeftEdge, includeLogicalRightEdge); |
| } |
| return; |
| } |
| case RIDGE: |
| case GROOVE: |
| { |
| EBorderStyle s1; |
| EBorderStyle s2; |
| if (borderStyle == GROOVE) { |
| s1 = INSET; |
| s2 = OUTSET; |
| } else { |
| s1 = OUTSET; |
| s2 = INSET; |
| } |
| |
| // Paint full border |
| drawBoxSideFromPath(graphicsContext, borderRect, borderPath, edges, thickness, drawThickness, side, style, color, s1, bleedAvoidance, includeLogicalLeftEdge, includeLogicalRightEdge); |
| |
| // Paint inner only |
| GraphicsContextStateSaver stateSaver(graphicsContext); |
| LayoutUnit topWidth = edges[BSTop].widthForPainting() / 2; |
| LayoutUnit bottomWidth = edges[BSBottom].widthForPainting() / 2; |
| LayoutUnit leftWidth = edges[BSLeft].widthForPainting() / 2; |
| LayoutUnit rightWidth = edges[BSRight].widthForPainting() / 2; |
| |
| RoundedRect clipRect = style.getRoundedInnerBorderFor(borderRect, |
| topWidth, bottomWidth, leftWidth, rightWidth, |
| includeLogicalLeftEdge, includeLogicalRightEdge); |
| |
| graphicsContext.clipRoundedRect(FloatRoundedRect(clipRect)); |
| drawBoxSideFromPath(graphicsContext, borderRect, borderPath, edges, thickness, drawThickness, side, style, color, s2, bleedAvoidance, includeLogicalLeftEdge, includeLogicalRightEdge); |
| return; |
| } |
| case INSET: |
| case OUTSET: |
| calculateBorderStyleColor(borderStyle, side, color); |
| break; |
| default: |
| break; |
| } |
| |
| graphicsContext.setStrokeStyle(NoStroke); |
| graphicsContext.setFillColor(color); |
| graphicsContext.drawRect(snapRectToDevicePixels(borderRect, document().deviceScaleFactor())); |
| } |
| |
| void RenderBoxModelObject::clipBorderSidePolygon(GraphicsContext& graphicsContext, const RoundedRect& outerBorder, const RoundedRect& innerBorder, |
| BoxSide side, bool firstEdgeMatches, bool secondEdgeMatches) |
| { |
| float deviceScaleFactor = document().deviceScaleFactor(); |
| const FloatRect& outerRect = snapRectToDevicePixels(outerBorder.rect(), deviceScaleFactor); |
| const FloatRect& innerRect = snapRectToDevicePixels(innerBorder.rect(), deviceScaleFactor); |
| |
| // For each side, create a quad that encompasses all parts of that side that may draw, |
| // including areas inside the innerBorder. |
| // |
| // 0----------------3 |
| // 0 \ / 0 |
| // |\ 1----------- 2 /| |
| // | 1 1 | |
| // | | | | |
| // | | | | |
| // | 2 2 | |
| // |/ 1------------2 \| |
| // 3 / \ 3 |
| // 0----------------3 |
| // |
| Vector<FloatPoint> quad; |
| quad.reserveInitialCapacity(4); |
| switch (side) { |
| case BSTop: |
| quad.uncheckedAppend(outerRect.minXMinYCorner()); |
| quad.uncheckedAppend(innerRect.minXMinYCorner()); |
| quad.uncheckedAppend(innerRect.maxXMinYCorner()); |
| quad.uncheckedAppend(outerRect.maxXMinYCorner()); |
| |
| if (!innerBorder.radii().topLeft().isZero()) |
| findIntersection(outerRect.minXMinYCorner(), innerRect.minXMinYCorner(), innerRect.minXMaxYCorner(), innerRect.maxXMinYCorner(), quad[1]); |
| |
| if (!innerBorder.radii().topRight().isZero()) |
| findIntersection(outerRect.maxXMinYCorner(), innerRect.maxXMinYCorner(), innerRect.minXMinYCorner(), innerRect.maxXMaxYCorner(), quad[2]); |
| break; |
| |
| case BSLeft: |
| quad.uncheckedAppend(outerRect.minXMinYCorner()); |
| quad.uncheckedAppend(innerRect.minXMinYCorner()); |
| quad.uncheckedAppend(innerRect.minXMaxYCorner()); |
| quad.uncheckedAppend(outerRect.minXMaxYCorner()); |
| |
| if (!innerBorder.radii().topLeft().isZero()) |
| findIntersection(outerRect.minXMinYCorner(), innerRect.minXMinYCorner(), innerRect.minXMaxYCorner(), innerRect.maxXMinYCorner(), quad[1]); |
| |
| if (!innerBorder.radii().bottomLeft().isZero()) |
| findIntersection(outerRect.minXMaxYCorner(), innerRect.minXMaxYCorner(), innerRect.minXMinYCorner(), innerRect.maxXMaxYCorner(), quad[2]); |
| break; |
| |
| case BSBottom: |
| quad.uncheckedAppend(outerRect.minXMaxYCorner()); |
| quad.uncheckedAppend(innerRect.minXMaxYCorner()); |
| quad.uncheckedAppend(innerRect.maxXMaxYCorner()); |
| quad.uncheckedAppend(outerRect.maxXMaxYCorner()); |
| |
| if (!innerBorder.radii().bottomLeft().isZero()) |
| findIntersection(outerRect.minXMaxYCorner(), innerRect.minXMaxYCorner(), innerRect.minXMinYCorner(), innerRect.maxXMaxYCorner(), quad[1]); |
| |
| if (!innerBorder.radii().bottomRight().isZero()) |
| findIntersection(outerRect.maxXMaxYCorner(), innerRect.maxXMaxYCorner(), innerRect.maxXMinYCorner(), innerRect.minXMaxYCorner(), quad[2]); |
| break; |
| |
| case BSRight: |
| quad.uncheckedAppend(outerRect.maxXMinYCorner()); |
| quad.uncheckedAppend(innerRect.maxXMinYCorner()); |
| quad.uncheckedAppend(innerRect.maxXMaxYCorner()); |
| quad.uncheckedAppend(outerRect.maxXMaxYCorner()); |
| |
| if (!innerBorder.radii().topRight().isZero()) |
| findIntersection(outerRect.maxXMinYCorner(), innerRect.maxXMinYCorner(), innerRect.minXMinYCorner(), innerRect.maxXMaxYCorner(), quad[1]); |
| |
| if (!innerBorder.radii().bottomRight().isZero()) |
| findIntersection(outerRect.maxXMaxYCorner(), innerRect.maxXMaxYCorner(), innerRect.maxXMinYCorner(), innerRect.minXMaxYCorner(), quad[2]); |
| break; |
| } |
| |
| // If the border matches both of its adjacent sides, don't anti-alias the clip, and |
| // if neither side matches, anti-alias the clip. |
| if (firstEdgeMatches == secondEdgeMatches) { |
| bool wasAntialiased = graphicsContext.shouldAntialias(); |
| graphicsContext.setShouldAntialias(!firstEdgeMatches); |
| graphicsContext.clipPath(Path::polygonPathFromPoints(quad), RULE_NONZERO); |
| graphicsContext.setShouldAntialias(wasAntialiased); |
| return; |
| } |
| |
| // Square off the end which shouldn't be affected by antialiasing, and clip. |
| Vector<FloatPoint> firstQuad = { |
| quad[0], |
| quad[1], |
| quad[2], |
| side == BSTop || side == BSBottom ? FloatPoint(quad[3].x(), quad[2].y()) : FloatPoint(quad[2].x(), quad[3].y()), |
| quad[3] |
| }; |
| bool wasAntialiased = graphicsContext.shouldAntialias(); |
| graphicsContext.setShouldAntialias(!firstEdgeMatches); |
| graphicsContext.clipPath(Path::polygonPathFromPoints(firstQuad), RULE_NONZERO); |
| |
| Vector<FloatPoint> secondQuad = { |
| quad[0], |
| side == BSTop || side == BSBottom ? FloatPoint(quad[0].x(), quad[1].y()) : FloatPoint(quad[1].x(), quad[0].y()), |
| quad[1], |
| quad[2], |
| quad[3] |
| }; |
| // Antialiasing affects the second side. |
| graphicsContext.setShouldAntialias(!secondEdgeMatches); |
| graphicsContext.clipPath(Path::polygonPathFromPoints(secondQuad), RULE_NONZERO); |
| |
| graphicsContext.setShouldAntialias(wasAntialiased); |
| } |
| |
| bool RenderBoxModelObject::borderObscuresBackgroundEdge(const FloatSize& contextScale) const |
| { |
| BorderEdge edges[4]; |
| BorderEdge::getBorderEdgeInfo(edges, style(), document().deviceScaleFactor()); |
| |
| for (int i = BSTop; i <= BSLeft; ++i) { |
| const BorderEdge& currEdge = edges[i]; |
| // FIXME: for vertical text |
| float axisScale = (i == BSTop || i == BSBottom) ? contextScale.height() : contextScale.width(); |
| if (!currEdge.obscuresBackgroundEdge(axisScale)) |
| return false; |
| } |
| |
| return true; |
| } |
| |
| bool RenderBoxModelObject::borderObscuresBackground() const |
| { |
| if (!style().hasBorder()) |
| return false; |
| |
| // Bail if we have any border-image for now. We could look at the image alpha to improve this. |
| if (style().borderImage().image()) |
| return false; |
| |
| BorderEdge edges[4]; |
| BorderEdge::getBorderEdgeInfo(edges, style(), document().deviceScaleFactor()); |
| |
| for (int i = BSTop; i <= BSLeft; ++i) { |
| const BorderEdge& currEdge = edges[i]; |
| if (!currEdge.obscuresBackground()) |
| return false; |
| } |
| |
| return true; |
| } |
| |
| bool RenderBoxModelObject::boxShadowShouldBeAppliedToBackground(const LayoutPoint&, BackgroundBleedAvoidance bleedAvoidance, InlineFlowBox* inlineFlowBox) const |
| { |
| if (bleedAvoidance != BackgroundBleedNone) |
| return false; |
| |
| if (style().hasAppearance()) |
| return false; |
| |
| bool hasOneNormalBoxShadow = false; |
| for (const ShadowData* currentShadow = style().boxShadow(); currentShadow; currentShadow = currentShadow->next()) { |
| if (currentShadow->style() != Normal) |
| continue; |
| |
| if (hasOneNormalBoxShadow) |
| return false; |
| hasOneNormalBoxShadow = true; |
| |
| if (currentShadow->spread()) |
| return false; |
| } |
| |
| if (!hasOneNormalBoxShadow) |
| return false; |
| |
| Color backgroundColor = style().visitedDependentColor(CSSPropertyBackgroundColor); |
| if (!backgroundColor.isOpaque()) |
| return false; |
| |
| auto* lastBackgroundLayer = &style().backgroundLayers(); |
| while (auto* next = lastBackgroundLayer->next()) |
| lastBackgroundLayer = next; |
| |
| if (lastBackgroundLayer->clip() != BorderFillBox) |
| return false; |
| |
| if (lastBackgroundLayer->image() && style().hasBorderRadius()) |
| return false; |
| |
| if (inlineFlowBox && !inlineFlowBox->boxShadowCanBeAppliedToBackground(*lastBackgroundLayer)) |
| return false; |
| |
| if (hasOverflowClip() && lastBackgroundLayer->attachment() == LocalBackgroundAttachment) |
| return false; |
| |
| return true; |
| } |
| |
| static inline LayoutRect areaCastingShadowInHole(const LayoutRect& holeRect, int shadowExtent, int shadowSpread, const IntSize& shadowOffset) |
| { |
| LayoutRect bounds(holeRect); |
| |
| bounds.inflate(shadowExtent); |
| |
| if (shadowSpread < 0) |
| bounds.inflate(-shadowSpread); |
| |
| LayoutRect offsetBounds = bounds; |
| offsetBounds.move(-shadowOffset); |
| return unionRect(bounds, offsetBounds); |
| } |
| |
| void RenderBoxModelObject::paintBoxShadow(const PaintInfo& info, const LayoutRect& paintRect, const RenderStyle& style, ShadowStyle shadowStyle, bool includeLogicalLeftEdge, bool includeLogicalRightEdge) |
| { |
| // FIXME: Deal with border-image. Would be great to use border-image as a mask. |
| GraphicsContext& context = info.context(); |
| if (context.paintingDisabled() || !style.boxShadow()) |
| return; |
| |
| RoundedRect border = (shadowStyle == Inset) ? style.getRoundedInnerBorderFor(paintRect, includeLogicalLeftEdge, includeLogicalRightEdge) |
| : style.getRoundedBorderFor(paintRect, includeLogicalLeftEdge, includeLogicalRightEdge); |
| |
| bool hasBorderRadius = style.hasBorderRadius(); |
| bool isHorizontal = style.isHorizontalWritingMode(); |
| float deviceScaleFactor = document().deviceScaleFactor(); |
| |
| bool hasOpaqueBackground = style.visitedDependentColor(CSSPropertyBackgroundColor).isOpaque(); |
| for (const ShadowData* shadow = style.boxShadow(); shadow; shadow = shadow->next()) { |
| if (shadow->style() != shadowStyle) |
| continue; |
| |
| // FIXME: Add subpixel support for the shadow values. Soon after the shadow offset becomes fractional, |
| // all the early snappings here need to be pushed to the actual painting operations. |
| IntSize shadowOffset(shadow->x(), shadow->y()); |
| int shadowRadius = shadow->radius(); |
| int shadowPaintingExtent = shadow->paintingExtent(); |
| int shadowSpread = shadow->spread(); |
| |
| if (shadowOffset.isZero() && !shadowRadius && !shadowSpread) |
| continue; |
| |
| const Color& shadowColor = shadow->color(); |
| |
| if (shadow->style() == Normal) { |
| RoundedRect fillRect = border; |
| fillRect.inflate(shadowSpread); |
| if (fillRect.isEmpty()) |
| continue; |
| |
| FloatRect pixelSnappedShadowRect = snapRectToDevicePixels(border.rect(), deviceScaleFactor); |
| pixelSnappedShadowRect.inflate(shadowPaintingExtent + shadowSpread); |
| pixelSnappedShadowRect.move(shadowOffset); |
| |
| GraphicsContextStateSaver stateSaver(context); |
| context.clip(pixelSnappedShadowRect); |
| |
| // Move the fill just outside the clip, adding 1 pixel separation so that the fill does not |
| // bleed in (due to antialiasing) if the context is transformed. |
| IntSize extraOffset(roundToInt(paintRect.width()) + std::max(0, shadowOffset.width()) + shadowPaintingExtent + 2 * shadowSpread + 1, 0); |
| shadowOffset -= extraOffset; |
| fillRect.move(extraOffset); |
| |
| if (shadow->isWebkitBoxShadow()) |
| context.setLegacyShadow(shadowOffset, shadowRadius, shadowColor); |
| else |
| context.setShadow(shadowOffset, shadowRadius, shadowColor); |
| |
| FloatRoundedRect rectToClipOut = border.pixelSnappedRoundedRectForPainting(deviceScaleFactor); |
| FloatRoundedRect pixelSnappedFillRect = fillRect.pixelSnappedRoundedRectForPainting(deviceScaleFactor); |
| if (hasBorderRadius) { |
| // If the box is opaque, it is unnecessary to clip it out. However, doing so saves time |
| // when painting the shadow. On the other hand, it introduces subpixel gaps along the |
| // corners. Those are avoided by insetting the clipping path by one pixel. |
| if (hasOpaqueBackground) |
| rectToClipOut.inflateWithRadii(LayoutUnit::fromPixel(-1)); |
| |
| if (!rectToClipOut.isEmpty()) |
| context.clipOutRoundedRect(rectToClipOut); |
| |
| RoundedRect influenceRect(LayoutRect(pixelSnappedShadowRect), border.radii()); |
| influenceRect.expandRadii(2 * shadowPaintingExtent + shadowSpread); |
| |
| if (allCornersClippedOut(influenceRect, info.rect)) |
| context.fillRect(pixelSnappedFillRect.rect(), Color::black); |
| else { |
| pixelSnappedFillRect.expandRadii(shadowSpread); |
| if (!pixelSnappedFillRect.isRenderable()) |
| pixelSnappedFillRect.adjustRadii(); |
| context.fillRoundedRect(pixelSnappedFillRect, Color::black); |
| } |
| } else { |
| // If the box is opaque, it is unnecessary to clip it out. However, doing so saves time |
| // when painting the shadow. On the other hand, it introduces subpixel gaps along the |
| // edges if they are not pixel-aligned. Those are avoided by insetting the clipping path |
| // by one pixel. |
| if (hasOpaqueBackground) { |
| // FIXME: The function to decide on the policy based on the transform should be a named function. |
| // FIXME: It's not clear if this check is right. What about integral scale factors? |
| AffineTransform transform = context.getCTM(); |
| if (transform.a() != 1 || (transform.d() != 1 && transform.d() != -1) || transform.b() || transform.c()) |
| rectToClipOut.inflate(LayoutUnit::fromPixel(-1).toFloat()); |
| } |
| |
| if (!rectToClipOut.isEmpty()) |
| context.clipOut(rectToClipOut.rect()); |
| context.fillRect(pixelSnappedFillRect.rect(), Color::black); |
| } |
| } else { |
| // Inset shadow. |
| FloatRoundedRect pixelSnappedBorderRect = border.pixelSnappedRoundedRectForPainting(deviceScaleFactor); |
| FloatRect pixelSnappedHoleRect = pixelSnappedBorderRect.rect(); |
| pixelSnappedHoleRect.inflate(-shadowSpread); |
| |
| if (pixelSnappedHoleRect.isEmpty()) { |
| if (hasBorderRadius) |
| context.fillRoundedRect(pixelSnappedBorderRect, shadowColor); |
| else |
| context.fillRect(pixelSnappedBorderRect.rect(), shadowColor); |
| continue; |
| } |
| |
| if (!includeLogicalLeftEdge) { |
| if (isHorizontal) { |
| pixelSnappedHoleRect.move(-std::max(shadowOffset.width(), 0) - shadowPaintingExtent, 0); |
| pixelSnappedHoleRect.setWidth(pixelSnappedHoleRect.width() + std::max(shadowOffset.width(), 0) + shadowPaintingExtent); |
| } else { |
| pixelSnappedHoleRect.move(0, -std::max(shadowOffset.height(), 0) - shadowPaintingExtent); |
| pixelSnappedHoleRect.setHeight(pixelSnappedHoleRect.height() + std::max(shadowOffset.height(), 0) + shadowPaintingExtent); |
| } |
| } |
| if (!includeLogicalRightEdge) { |
| if (isHorizontal) |
| pixelSnappedHoleRect.setWidth(pixelSnappedHoleRect.width() - std::min(shadowOffset.width(), 0) + shadowPaintingExtent); |
| else |
| pixelSnappedHoleRect.setHeight(pixelSnappedHoleRect.height() - std::min(shadowOffset.height(), 0) + shadowPaintingExtent); |
| } |
| |
| Color fillColor(shadowColor.red(), shadowColor.green(), shadowColor.blue(), 255); |
| |
| FloatRect pixelSnappedOuterRect = snapRectToDevicePixels(areaCastingShadowInHole(LayoutRect(pixelSnappedBorderRect.rect()), shadowPaintingExtent, shadowSpread, shadowOffset), deviceScaleFactor); |
| FloatRoundedRect pixelSnappedRoundedHole = FloatRoundedRect(pixelSnappedHoleRect, pixelSnappedBorderRect.radii()); |
| |
| GraphicsContextStateSaver stateSaver(context); |
| if (hasBorderRadius) { |
| context.clipRoundedRect(pixelSnappedBorderRect); |
| pixelSnappedRoundedHole.shrinkRadii(shadowSpread); |
| } else |
| context.clip(pixelSnappedBorderRect.rect()); |
| |
| IntSize extraOffset(2 * roundToInt(paintRect.width()) + std::max(0, shadowOffset.width()) + shadowPaintingExtent - 2 * shadowSpread + 1, 0); |
| context.translate(extraOffset); |
| shadowOffset -= extraOffset; |
| |
| if (shadow->isWebkitBoxShadow()) |
| context.setLegacyShadow(shadowOffset, shadowRadius, shadowColor); |
| else |
| context.setShadow(shadowOffset, shadowRadius, shadowColor); |
| |
| context.fillRectWithRoundedHole(pixelSnappedOuterRect, pixelSnappedRoundedHole, fillColor); |
| } |
| } |
| } |
| |
| LayoutUnit RenderBoxModelObject::containingBlockLogicalWidthForContent() const |
| { |
| if (auto* containingBlock = this->containingBlock()) |
| return containingBlock->availableLogicalWidth(); |
| return { }; |
| } |
| |
| RenderBoxModelObject* RenderBoxModelObject::continuation() const |
| { |
| if (!hasContinuationChainNode()) |
| return nullptr; |
| |
| auto& continuationChainNode = *continuationChainNodeMap().get(this); |
| if (!continuationChainNode.next) |
| return nullptr; |
| return continuationChainNode.next->renderer.get(); |
| } |
| |
| RenderInline* RenderBoxModelObject::inlineContinuation() const |
| { |
| if (!hasContinuationChainNode()) |
| return nullptr; |
| |
| for (auto* next = continuationChainNodeMap().get(this)->next; next; next = next->next) { |
| if (is<RenderInline>(*next->renderer)) |
| return downcast<RenderInline>(next->renderer.get()); |
| } |
| return nullptr; |
| } |
| |
| RenderBoxModelObject::ContinuationChainNode* RenderBoxModelObject::continuationChainNode() const |
| { |
| return continuationChainNodeMap().get(this); |
| } |
| |
| void RenderBoxModelObject::insertIntoContinuationChainAfter(RenderBoxModelObject& afterRenderer) |
| { |
| ASSERT(isContinuation()); |
| ASSERT(!continuationChainNodeMap().contains(this)); |
| |
| auto& after = afterRenderer.ensureContinuationChainNode(); |
| ensureContinuationChainNode().insertAfter(after); |
| } |
| |
| void RenderBoxModelObject::removeFromContinuationChain() |
| { |
| ASSERT(hasContinuationChainNode()); |
| ASSERT(continuationChainNodeMap().contains(this)); |
| setHasContinuationChainNode(false); |
| continuationChainNodeMap().remove(this); |
| } |
| |
| auto RenderBoxModelObject::ensureContinuationChainNode() -> ContinuationChainNode& |
| { |
| setHasContinuationChainNode(true); |
| return *continuationChainNodeMap().ensure(this, [&] { |
| return std::make_unique<ContinuationChainNode>(*this); |
| }).iterator->value; |
| } |
| |
| RenderTextFragment* RenderBoxModelObject::firstLetterRemainingText() const |
| { |
| if (!isFirstLetter()) |
| return nullptr; |
| return firstLetterRemainingTextMap().get(this).get(); |
| } |
| |
| void RenderBoxModelObject::setFirstLetterRemainingText(RenderTextFragment& remainingText) |
| { |
| ASSERT(isFirstLetter()); |
| firstLetterRemainingTextMap().set(this, makeWeakPtr(remainingText)); |
| } |
| |
| void RenderBoxModelObject::clearFirstLetterRemainingText() |
| { |
| ASSERT(isFirstLetter()); |
| firstLetterRemainingTextMap().remove(this); |
| } |
| |
| LayoutRect RenderBoxModelObject::localCaretRectForEmptyElement(LayoutUnit width, LayoutUnit textIndentOffset) |
| { |
| ASSERT(!firstChild()); |
| |
| // FIXME: This does not take into account either :first-line or :first-letter |
| // However, as soon as some content is entered, the line boxes will be |
| // constructed and this kludge is not called any more. So only the caret size |
| // of an empty :first-line'd block is wrong. I think we can live with that. |
| const RenderStyle& currentStyle = firstLineStyle(); |
| LayoutUnit height = lineHeight(true, currentStyle.isHorizontalWritingMode() ? HorizontalLine : VerticalLine); |
| |
| enum CaretAlignment { alignLeft, alignRight, alignCenter }; |
| |
| CaretAlignment alignment = alignLeft; |
| |
| switch (currentStyle.textAlign()) { |
| case LEFT: |
| case WEBKIT_LEFT: |
| break; |
| case CENTER: |
| case WEBKIT_CENTER: |
| alignment = alignCenter; |
| break; |
| case RIGHT: |
| case WEBKIT_RIGHT: |
| alignment = alignRight; |
| break; |
| case JUSTIFY: |
| case TASTART: |
| if (!currentStyle.isLeftToRightDirection()) |
| alignment = alignRight; |
| break; |
| case TAEND: |
| if (currentStyle.isLeftToRightDirection()) |
| alignment = alignRight; |
| break; |
| } |
| |
| LayoutUnit x = borderLeft() + paddingLeft(); |
| LayoutUnit maxX = width - borderRight() - paddingRight(); |
| |
| switch (alignment) { |
| case alignLeft: |
| if (currentStyle.isLeftToRightDirection()) |
| x += textIndentOffset; |
| break; |
| case alignCenter: |
| x = (x + maxX) / 2; |
| if (currentStyle.isLeftToRightDirection()) |
| x += textIndentOffset / 2; |
| else |
| x -= textIndentOffset / 2; |
| break; |
| case alignRight: |
| x = maxX - caretWidth; |
| if (!currentStyle.isLeftToRightDirection()) |
| x -= textIndentOffset; |
| break; |
| } |
| x = std::min(x, std::max<LayoutUnit>(maxX - caretWidth, 0)); |
| |
| LayoutUnit y = paddingTop() + borderTop(); |
| |
| return currentStyle.isHorizontalWritingMode() ? LayoutRect(x, y, caretWidth, height) : LayoutRect(y, x, height, caretWidth); |
| } |
| |
| bool RenderBoxModelObject::shouldAntialiasLines(GraphicsContext& context) |
| { |
| // FIXME: We may want to not antialias when scaled by an integral value, |
| // and we may want to antialias when translated by a non-integral value. |
| return !context.getCTM().isIdentityOrTranslationOrFlipped(); |
| } |
| |
| void RenderBoxModelObject::mapAbsoluteToLocalPoint(MapCoordinatesFlags mode, TransformState& transformState) const |
| { |
| RenderElement* container = this->container(); |
| if (!container) |
| return; |
| |
| // FIXME: This code is wrong for named flow threads since it only works for content in the first region. |
| // We also don't want to run it for multicolumn flow threads, since we can use our knowledge of column |
| // geometry to actually get a better result. |
| // The point inside a box that's inside a region has its coordinates relative to the region, |
| // not the FragmentedFlow that is its container in the RenderObject tree. |
| if (is<RenderBox>(*this) && container->isOutOfFlowRenderFragmentedFlow()) { |
| RenderFragmentContainer* startFragment = nullptr; |
| RenderFragmentContainer* endFragment = nullptr; |
| if (downcast<RenderFragmentedFlow>(*container).getFragmentRangeForBox(downcast<RenderBox>(this), startFragment, endFragment)) |
| container = startFragment; |
| } |
| |
| container->mapAbsoluteToLocalPoint(mode, transformState); |
| |
| LayoutSize containerOffset = offsetFromContainer(*container, LayoutPoint()); |
| |
| bool preserve3D = mode & UseTransforms && (container->style().preserves3D() || style().preserves3D()); |
| if (mode & UseTransforms && shouldUseTransformFromContainer(container)) { |
| TransformationMatrix t; |
| getTransformFromContainer(container, containerOffset, t); |
| transformState.applyTransform(t, preserve3D ? TransformState::AccumulateTransform : TransformState::FlattenTransform); |
| } else |
| transformState.move(containerOffset.width(), containerOffset.height(), preserve3D ? TransformState::AccumulateTransform : TransformState::FlattenTransform); |
| } |
| |
| } // namespace WebCore |