Source/WebCore/rendering/RenderMultiColumnFlow.cpp - WebKit - Git at Google

 /*
  * Copyright (C) 2012 Apple Inc.  All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions
  * are met:
  * 1. Redistributions of source code must retain the above copyright
  *    notice, this list of conditions and the following disclaimer.
  * 2. Redistributions in binary form must reproduce the above copyright
  *    notice, this list of conditions and the following disclaimer in the
  *    documentation and/or other materials provided with the distribution.
  *
  * THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
  * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL APPLE INC. OR
  * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
  * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
  * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
  * PROFITS; OR BUSINESS IN..0TERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
  * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
  * OF THIS SOFTWARE, EVEN IF  ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  */

 #include "config.h"
 #include "RenderMultiColumnFlow.h"

 #include "HitTestResult.h"
 #include "RenderIterator.h"
 #include "RenderLayoutState.h"
 #include "RenderMultiColumnSet.h"
 #include "RenderMultiColumnSpannerPlaceholder.h"
 #include "RenderTreeBuilder.h"
 #include "RenderView.h"
 #include "TransformState.h"
 #include <wtf/IsoMallocInlines.h>

 namespace WebCore {

 WTF_MAKE_ISO_ALLOCATED_IMPL(RenderMultiColumnFlow);

 RenderMultiColumnFlow::RenderMultiColumnFlow(Document& document, RenderStyle&& style)
     : RenderFragmentedFlow(document, WTFMove(style))
     , m_spannerMap(makeUnique<SpannerMap>())
     , m_lastSetWorkedOn(nullptr)
     , m_columnCount(1)
     , m_columnWidth(0)
     , m_columnHeightAvailable(0)
     , m_inLayout(false)
     , m_inBalancingPass(false)
     , m_needsHeightsRecalculation(false)
     , m_progressionIsInline(false)
     , m_progressionIsReversed(false)
 {
     setFragmentedFlowState(InsideInFragmentedFlow);
 }

 RenderMultiColumnFlow::~RenderMultiColumnFlow() = default;

 const char* RenderMultiColumnFlow::renderName() const
 {
     return "RenderMultiColumnFlowThread";
 }

 RenderMultiColumnSet* RenderMultiColumnFlow::firstMultiColumnSet() const
 {
     for (RenderObject* sibling = nextSibling(); sibling; sibling = sibling->nextSibling()) {
         if (is<RenderMultiColumnSet>(*sibling))
             return downcast<RenderMultiColumnSet>(sibling);
     }
     return nullptr;
 }

 RenderMultiColumnSet* RenderMultiColumnFlow::lastMultiColumnSet() const
 {
     for (RenderObject* sibling = multiColumnBlockFlow()->lastChild(); sibling; sibling = sibling->previousSibling()) {
         if (is<RenderMultiColumnSet>(*sibling))
             return downcast<RenderMultiColumnSet>(sibling);
     }
     return nullptr;
 }

 RenderBox* RenderMultiColumnFlow::firstColumnSetOrSpanner() const
 {
     if (RenderObject* sibling = nextSibling()) {
         ASSERT(is<RenderBox>(*sibling));
         ASSERT(is<RenderMultiColumnSet>(*sibling) || findColumnSpannerPlaceholder(downcast<RenderBox>(sibling)));
         return downcast<RenderBox>(sibling);
     }
     return nullptr;
 }

 RenderBox* RenderMultiColumnFlow::nextColumnSetOrSpannerSiblingOf(const RenderBox* child)
 {
     return child ? child->nextSiblingBox() : nullptr;
 }

 RenderBox* RenderMultiColumnFlow::previousColumnSetOrSpannerSiblingOf(const RenderBox* child)
 {
     if (!child)
         return nullptr;
     if (auto* sibling = child->previousSiblingBox()) {
         if (!is<RenderFragmentedFlow>(*sibling))
             return sibling;
     }
     return nullptr;
 }

 RenderMultiColumnSpannerPlaceholder* RenderMultiColumnFlow::findColumnSpannerPlaceholder(RenderBox* spanner) const
 {
     return m_spannerMap->get(spanner).get();
 }

 void RenderMultiColumnFlow::layout()
 {
     ASSERT(!m_inLayout);
     m_inLayout = true;
     m_lastSetWorkedOn = nullptr;
     if (RenderBox* first = firstColumnSetOrSpanner()) {
         if (is<RenderMultiColumnSet>(*first)) {
             m_lastSetWorkedOn = downcast<RenderMultiColumnSet>(first);
             m_lastSetWorkedOn->beginFlow(this);
         }
     }
     RenderFragmentedFlow::layout();
     if (RenderMultiColumnSet* lastSet = lastMultiColumnSet()) {
         if (!nextColumnSetOrSpannerSiblingOf(lastSet))
             lastSet->endFlow(this, logicalHeight());
         lastSet->expandToEncompassFragmentedFlowContentsIfNeeded();
     }
     m_inLayout = false;
     m_lastSetWorkedOn = nullptr;
 }

 void RenderMultiColumnFlow::addFragmentToThread(RenderFragmentContainer* RenderFragmentContainer)
 {
     auto* columnSet = downcast<RenderMultiColumnSet>(RenderFragmentContainer);
     if (RenderMultiColumnSet* nextSet = columnSet->nextSiblingMultiColumnSet()) {
         RenderFragmentContainerList::iterator it = m_fragmentList.find(nextSet);
         ASSERT(it != m_fragmentList.end());
         m_fragmentList.insertBefore(it, columnSet);
     } else
         m_fragmentList.add(columnSet);
     RenderFragmentContainer->setIsValid(true);
 }

 void RenderMultiColumnFlow::willBeRemovedFromTree()
 {
     // Detach all column sets from the flow thread. Cannot destroy them at this point, since they
     // are siblings of this object, and there may be pointers to this object's sibling somewhere
     // further up on the call stack.
     for (RenderMultiColumnSet* columnSet = firstMultiColumnSet(); columnSet; columnSet = columnSet->nextSiblingMultiColumnSet())
         columnSet->detachFragment();
     RenderFragmentedFlow::willBeRemovedFromTree();
 }

 void RenderMultiColumnFlow::fragmentedFlowDescendantBoxLaidOut(RenderBox* descendant)
 {
     if (!is<RenderMultiColumnSpannerPlaceholder>(*descendant))
         return;
     auto& placeholder = downcast<RenderMultiColumnSpannerPlaceholder>(*descendant);
     RenderBlock* container = placeholder.containingBlock();

     for (RenderBox* prev = previousColumnSetOrSpannerSiblingOf(placeholder.spanner()); prev; prev = previousColumnSetOrSpannerSiblingOf(prev)) {
         if (is<RenderMultiColumnSet>(*prev)) {
             downcast<RenderMultiColumnSet>(*prev).endFlow(container, placeholder.logicalTop());
             break;
         }
     }

     for (RenderBox* next = nextColumnSetOrSpannerSiblingOf(placeholder.spanner()); next; next = nextColumnSetOrSpannerSiblingOf(next)) {
         if (is<RenderMultiColumnSet>(*next)) {
             m_lastSetWorkedOn = downcast<RenderMultiColumnSet>(next);
             m_lastSetWorkedOn->beginFlow(container);
             break;
         }
     }
 }

 RenderBox::LogicalExtentComputedValues RenderMultiColumnFlow::computeLogicalHeight(LayoutUnit logicalHeight, LayoutUnit logicalTop) const
 {
     // We simply remain at our intrinsic height.
     return { logicalHeight, logicalTop, ComputedMarginValues() };
 }

 LayoutUnit RenderMultiColumnFlow::initialLogicalWidth() const
 {
     return columnWidth();
 }

 void RenderMultiColumnFlow::setPageBreak(const RenderBlock* block, LayoutUnit offset, LayoutUnit spaceShortage)
 {
     if (auto* multicolSet = downcast<RenderMultiColumnSet>(fragmentAtBlockOffset(block, offset)))
         multicolSet->recordSpaceShortage(spaceShortage);
 }

 void RenderMultiColumnFlow::updateMinimumPageHeight(const RenderBlock* block, LayoutUnit offset, LayoutUnit minHeight)
 {
     if (auto* multicolSet = downcast<RenderMultiColumnSet>(fragmentAtBlockOffset(block, offset)))
         multicolSet->updateMinimumColumnHeight(minHeight);
 }

 RenderFragmentContainer* RenderMultiColumnFlow::fragmentAtBlockOffset(const RenderBox* box, LayoutUnit offset, bool extendLastFragment) const
 {
     if (!m_inLayout)
         return RenderFragmentedFlow::fragmentAtBlockOffset(box, offset, extendLastFragment);

     // Layout in progress. We are calculating the set heights as we speak, so the fragment range
     // information is not up-to-date.

     RenderMultiColumnSet* columnSet = m_lastSetWorkedOn ? m_lastSetWorkedOn : firstMultiColumnSet();
     if (!columnSet) {
         // If there's no set, bail. This multicol is empty or only consists of spanners. There
         // are no fragments.
         return nullptr;
     }
     // The last set worked on is a good guess. But if we're not within the bounds, search for the
     // right one.
     if (offset < columnSet->logicalTopInFragmentedFlow()) {
         do {
             if (RenderMultiColumnSet* prev = columnSet->previousSiblingMultiColumnSet())
                 columnSet = prev;
             else
                 break;
         } while (offset < columnSet->logicalTopInFragmentedFlow());
     } else {
         while (offset >= columnSet->logicalBottomInFragmentedFlow()) {
             RenderMultiColumnSet* next = columnSet->nextSiblingMultiColumnSet();
             if (!next || !next->hasBeenFlowed())
                 break;
             columnSet = next;
         }
     }
     return columnSet;
 }

 void RenderMultiColumnFlow::setFragmentRangeForBox(const RenderBox& box, RenderFragmentContainer* startFragment, RenderFragmentContainer* endFragment)
 {
     // Some column sets may have zero height, which means that two or more sets may start at the
     // exact same flow thread position, which means that some parts of the code may believe that a
     // given box lives in sets that it doesn't really live in. Make some adjustments here and
     // include such sets if they are adjacent to the start and/or end fragments.
     for (RenderMultiColumnSet* columnSet = downcast<RenderMultiColumnSet>(*startFragment).previousSiblingMultiColumnSet(); columnSet; columnSet = columnSet->previousSiblingMultiColumnSet()) {
         if (columnSet->logicalHeightInFragmentedFlow())
             break;
         startFragment = columnSet;
     }
     for (RenderMultiColumnSet* columnSet = downcast<RenderMultiColumnSet>(*startFragment).nextSiblingMultiColumnSet(); columnSet; columnSet = columnSet->nextSiblingMultiColumnSet()) {
         if (columnSet->logicalHeightInFragmentedFlow())
             break;
         endFragment = columnSet;
     }

     RenderFragmentedFlow::setFragmentRangeForBox(box, startFragment, endFragment);
 }

 bool RenderMultiColumnFlow::addForcedFragmentBreak(const RenderBlock* block, LayoutUnit offset, RenderBox* /*breakChild*/, bool /*isBefore*/, LayoutUnit* offsetBreakAdjustment)
 {
     if (auto* multicolSet = downcast<RenderMultiColumnSet>(fragmentAtBlockOffset(block, offset))) {
         multicolSet->addForcedBreak(offset);
         if (offsetBreakAdjustment)
             *offsetBreakAdjustment = pageLogicalHeightForOffset(offset) ? pageRemainingLogicalHeightForOffset(offset, IncludePageBoundary) : 0_lu;
         return true;
     }
     return false;
 }

 LayoutSize RenderMultiColumnFlow::offsetFromContainer(RenderElement& enclosingContainer, const LayoutPoint& physicalPoint, bool* offsetDependsOnPoint) const
 {
     ASSERT(&enclosingContainer == container());

     if (offsetDependsOnPoint)
         *offsetDependsOnPoint = true;

     LayoutPoint translatedPhysicalPoint(physicalPoint);
     if (RenderFragmentContainer* fragment = physicalTranslationFromFlowToFragment(translatedPhysicalPoint))
         translatedPhysicalPoint.moveBy(fragment->topLeftLocation());

     LayoutSize offset(translatedPhysicalPoint.x(), translatedPhysicalPoint.y());
     if (is<RenderBox>(enclosingContainer))
         offset -= toLayoutSize(downcast<RenderBox>(enclosingContainer).scrollPosition());
     return offset;
 }

 void RenderMultiColumnFlow::mapAbsoluteToLocalPoint(MapCoordinatesFlags mode, TransformState& transformState) const
 {
     // First get the transform state's point into the block flow thread's physical coordinate space.
     parent()->mapAbsoluteToLocalPoint(mode, transformState);
     LayoutPoint transformPoint(transformState.mappedPoint());

     // Now walk through each fragment.
     const RenderMultiColumnSet* candidateColumnSet = nullptr;
     LayoutPoint candidatePoint;
     LayoutSize candidateContainerOffset;

     for (const auto& columnSet : childrenOfType<RenderMultiColumnSet>(*parent())) {
         candidateContainerOffset = columnSet.offsetFromContainer(*parent(), LayoutPoint());

         candidatePoint = transformPoint - candidateContainerOffset;
         candidateColumnSet = &columnSet;

         // We really have no clue what to do with overflow. We'll just use the closest fragment to the point in that case.
         LayoutUnit pointOffset = isHorizontalWritingMode() ? candidatePoint.y() : candidatePoint.x();
         LayoutUnit fragmentOffset = isHorizontalWritingMode() ? columnSet.topLeftLocation().y() : columnSet.topLeftLocation().x();
         if (pointOffset < fragmentOffset + columnSet.logicalHeight())
             break;
     }

     // Once we have a good guess as to which fragment we hit tested through (and yes, this was just a heuristic, but it's
     // the best we could do), then we can map from the fragment into the flow thread.
     LayoutSize translationOffset = physicalTranslationFromFragmentToFlow(candidateColumnSet, candidatePoint) + candidateContainerOffset;
     bool preserve3D = mode & UseTransforms && (parent()->style().preserves3D() || style().preserves3D());
     if (mode & UseTransforms && shouldUseTransformFromContainer(parent())) {
         TransformationMatrix t;
         getTransformFromContainer(parent(), translationOffset, t);
         transformState.applyTransform(t, preserve3D ? TransformState::AccumulateTransform : TransformState::FlattenTransform);
     } else
         transformState.move(translationOffset.width(), translationOffset.height(), preserve3D ? TransformState::AccumulateTransform : TransformState::FlattenTransform);
 }

 LayoutSize RenderMultiColumnFlow::physicalTranslationFromFragmentToFlow(const RenderMultiColumnSet* columnSet, const LayoutPoint& physicalPoint) const
 {
     LayoutPoint logicalPoint = columnSet->flipForWritingMode(physicalPoint);
     LayoutPoint translatedPoint = columnSet->translateFragmentPointToFragmentedFlow(logicalPoint);
     LayoutPoint physicalTranslatedPoint = columnSet->flipForWritingMode(translatedPoint);
     return physicalPoint - physicalTranslatedPoint;
 }

 RenderFragmentContainer* RenderMultiColumnFlow::mapFromFlowToFragment(TransformState& transformState) const
 {
     if (!hasValidFragmentInfo())
         return nullptr;

     // Get back into our local flow thread space.
     LayoutRect boxRect = transformState.mappedQuad().enclosingBoundingBox();
     flipForWritingMode(boxRect);

     // FIXME: We need to refactor RenderObject::absoluteQuads to be able to split the quads across fragments,
     // for now we just take the center of the mapped enclosing box and map it to a column.
     LayoutPoint centerPoint = boxRect.center();
     LayoutUnit centerLogicalOffset = isHorizontalWritingMode() ? centerPoint.y() : centerPoint.x();
     RenderFragmentContainer* RenderFragmentContainer = fragmentAtBlockOffset(this, centerLogicalOffset, true);
     if (!RenderFragmentContainer)
         return nullptr;
     transformState.move(physicalTranslationOffsetFromFlowToFragment(RenderFragmentContainer, centerLogicalOffset));
     return RenderFragmentContainer;
 }

 LayoutSize RenderMultiColumnFlow::physicalTranslationOffsetFromFlowToFragment(const RenderFragmentContainer* RenderFragmentContainer, const LayoutUnit logicalOffset) const
 {
     // Now that we know which multicolumn set we hit, we need to get the appropriate translation offset for the column.
     const auto* columnSet = downcast<RenderMultiColumnSet>(RenderFragmentContainer);
     LayoutPoint translationOffset = columnSet->columnTranslationForOffset(logicalOffset);

     // Now we know how we want the rect to be translated into the fragment. At this point we're converting
     // back to physical coordinates.
     if (style().isFlippedBlocksWritingMode()) {
         LayoutRect portionRect(columnSet->fragmentedFlowPortionRect());
         LayoutRect columnRect = columnSet->columnRectAt(0);
         LayoutUnit physicalDeltaFromPortionBottom = logicalHeight() - columnSet->logicalBottomInFragmentedFlow();
         if (isHorizontalWritingMode())
             columnRect.setHeight(portionRect.height());
         else
             columnRect.setWidth(portionRect.width());
         columnSet->flipForWritingMode(columnRect);
         if (isHorizontalWritingMode())
             translationOffset.move(0_lu, columnRect.y() - portionRect.y() - physicalDeltaFromPortionBottom);
         else
             translationOffset.move(columnRect.x() - portionRect.x() - physicalDeltaFromPortionBottom, 0_lu);
     }

     return LayoutSize(translationOffset.x(), translationOffset.y());
 }

 RenderFragmentContainer* RenderMultiColumnFlow::physicalTranslationFromFlowToFragment(LayoutPoint& physicalPoint) const
 {
     if (!hasValidFragmentInfo())
         return nullptr;

     // Put the physical point into the flow thread's coordinate space.
     LayoutPoint logicalPoint = flipForWritingMode(physicalPoint);

     // Now get the fragment that we are in.
     LayoutUnit logicalOffset = isHorizontalWritingMode() ? logicalPoint.y() : logicalPoint.x();
     RenderFragmentContainer* RenderFragmentContainer = fragmentAtBlockOffset(this, logicalOffset, true);
     if (!RenderFragmentContainer)
         return nullptr;

     // Translate to the coordinate space of the fragment.
     LayoutSize translationOffset = physicalTranslationOffsetFromFlowToFragment(RenderFragmentContainer, logicalOffset);

     // Now shift the physical point into the fragment's coordinate space.
     physicalPoint += translationOffset;

     return RenderFragmentContainer;
 }

 bool RenderMultiColumnFlow::isPageLogicalHeightKnown() const
 {
     if (RenderMultiColumnSet* columnSet = lastMultiColumnSet())
         return columnSet->columnHeightComputed();
     return false;
 }

 bool RenderMultiColumnFlow::nodeAtPoint(const HitTestRequest& request, HitTestResult& result, const HitTestLocation& locationInContainer, const LayoutPoint& accumulatedOffset, HitTestAction hitTestAction)
 {
     // You cannot be inside an in-flow RenderFragmentedFlow without a corresponding DOM node. It's better to
     // just let the ancestor figure out where we are instead.
     if (hitTestAction == HitTestBlockBackground)
         return false;
     bool inside = RenderFragmentedFlow::nodeAtPoint(request, result, locationInContainer, accumulatedOffset, hitTestAction);
     if (inside && !result.innerNode())
         return false;
     return inside;
 }

 bool RenderMultiColumnFlow::shouldCheckColumnBreaks() const
 {
     if (!parent()->isRenderView())
         return true;
     return view().frameView().pagination().behavesLikeColumns;
 }

 }
	/*
	* Copyright (C) 2012 Apple Inc. All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions
	* are met:
	* 1. Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* 2. Redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in the
	* documentation and/or other materials provided with the distribution.
	*
	* THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
	* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
	* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR
	* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
	* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
	* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
	* PROFITS; OR BUSINESS IN..0TERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
	* OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/

	#include "config.h"
	#include "RenderMultiColumnFlow.h"

	#include "HitTestResult.h"
	#include "RenderIterator.h"
	#include "RenderLayoutState.h"
	#include "RenderMultiColumnSet.h"
	#include "RenderMultiColumnSpannerPlaceholder.h"
	#include "RenderTreeBuilder.h"
	#include "RenderView.h"
	#include "TransformState.h"
	#include <wtf/IsoMallocInlines.h>

	namespace WebCore {

	WTF_MAKE_ISO_ALLOCATED_IMPL(RenderMultiColumnFlow);

	RenderMultiColumnFlow::RenderMultiColumnFlow(Document& document, RenderStyle&& style)
	: RenderFragmentedFlow(document, WTFMove(style))
	, m_spannerMap(makeUnique<SpannerMap>())
	, m_lastSetWorkedOn(nullptr)
	, m_columnCount(1)
	, m_columnWidth(0)
	, m_columnHeightAvailable(0)
	, m_inLayout(false)
	, m_inBalancingPass(false)
	, m_needsHeightsRecalculation(false)
	, m_progressionIsInline(false)
	, m_progressionIsReversed(false)
	{
	setFragmentedFlowState(InsideInFragmentedFlow);
	}

	RenderMultiColumnFlow::~RenderMultiColumnFlow() = default;

	const char* RenderMultiColumnFlow::renderName() const
	{
	return "RenderMultiColumnFlowThread";
	}

	RenderMultiColumnSet* RenderMultiColumnFlow::firstMultiColumnSet() const
	{
	for (RenderObject* sibling = nextSibling(); sibling; sibling = sibling->nextSibling()) {
	if (is<RenderMultiColumnSet>(*sibling))
	return downcast<RenderMultiColumnSet>(sibling);
	}
	return nullptr;
	}

	RenderMultiColumnSet* RenderMultiColumnFlow::lastMultiColumnSet() const
	{
	for (RenderObject* sibling = multiColumnBlockFlow()->lastChild(); sibling; sibling = sibling->previousSibling()) {
	if (is<RenderMultiColumnSet>(*sibling))
	return downcast<RenderMultiColumnSet>(sibling);
	}
	return nullptr;
	}

	RenderBox* RenderMultiColumnFlow::firstColumnSetOrSpanner() const
	{
	if (RenderObject* sibling = nextSibling()) {
	ASSERT(is<RenderBox>(*sibling));
	ASSERT(is<RenderMultiColumnSet>(*sibling) \|\| findColumnSpannerPlaceholder(downcast<RenderBox>(sibling)));
	return downcast<RenderBox>(sibling);
	}
	return nullptr;
	}

	RenderBox* RenderMultiColumnFlow::nextColumnSetOrSpannerSiblingOf(const RenderBox* child)
	{
	return child ? child->nextSiblingBox() : nullptr;
	}

	RenderBox* RenderMultiColumnFlow::previousColumnSetOrSpannerSiblingOf(const RenderBox* child)
	{
	if (!child)
	return nullptr;
	if (auto* sibling = child->previousSiblingBox()) {
	if (!is<RenderFragmentedFlow>(*sibling))
	return sibling;
	}
	return nullptr;
	}

	RenderMultiColumnSpannerPlaceholder* RenderMultiColumnFlow::findColumnSpannerPlaceholder(RenderBox* spanner) const
	{
	return m_spannerMap->get(spanner).get();
	}

	void RenderMultiColumnFlow::layout()
	{
	ASSERT(!m_inLayout);
	m_inLayout = true;
	m_lastSetWorkedOn = nullptr;
	if (RenderBox* first = firstColumnSetOrSpanner()) {
	if (is<RenderMultiColumnSet>(*first)) {
	m_lastSetWorkedOn = downcast<RenderMultiColumnSet>(first);
	m_lastSetWorkedOn->beginFlow(this);
	}
	}
	RenderFragmentedFlow::layout();
	if (RenderMultiColumnSet* lastSet = lastMultiColumnSet()) {
	if (!nextColumnSetOrSpannerSiblingOf(lastSet))
	lastSet->endFlow(this, logicalHeight());
	lastSet->expandToEncompassFragmentedFlowContentsIfNeeded();
	}
	m_inLayout = false;
	m_lastSetWorkedOn = nullptr;
	}

	void RenderMultiColumnFlow::addFragmentToThread(RenderFragmentContainer* RenderFragmentContainer)
	{
	auto* columnSet = downcast<RenderMultiColumnSet>(RenderFragmentContainer);
	if (RenderMultiColumnSet* nextSet = columnSet->nextSiblingMultiColumnSet()) {
	RenderFragmentContainerList::iterator it = m_fragmentList.find(nextSet);
	ASSERT(it != m_fragmentList.end());
	m_fragmentList.insertBefore(it, columnSet);
	} else
	m_fragmentList.add(columnSet);
	RenderFragmentContainer->setIsValid(true);
	}

	void RenderMultiColumnFlow::willBeRemovedFromTree()
	{
	// Detach all column sets from the flow thread. Cannot destroy them at this point, since they
	// are siblings of this object, and there may be pointers to this object's sibling somewhere
	// further up on the call stack.
	for (RenderMultiColumnSet* columnSet = firstMultiColumnSet(); columnSet; columnSet = columnSet->nextSiblingMultiColumnSet())
	columnSet->detachFragment();
	RenderFragmentedFlow::willBeRemovedFromTree();
	}

	void RenderMultiColumnFlow::fragmentedFlowDescendantBoxLaidOut(RenderBox* descendant)
	{
	if (!is<RenderMultiColumnSpannerPlaceholder>(*descendant))
	return;
	auto& placeholder = downcast<RenderMultiColumnSpannerPlaceholder>(*descendant);
	RenderBlock* container = placeholder.containingBlock();

	for (RenderBox* prev = previousColumnSetOrSpannerSiblingOf(placeholder.spanner()); prev; prev = previousColumnSetOrSpannerSiblingOf(prev)) {
	if (is<RenderMultiColumnSet>(*prev)) {
	downcast<RenderMultiColumnSet>(*prev).endFlow(container, placeholder.logicalTop());
	break;
	}
	}

	for (RenderBox* next = nextColumnSetOrSpannerSiblingOf(placeholder.spanner()); next; next = nextColumnSetOrSpannerSiblingOf(next)) {
	if (is<RenderMultiColumnSet>(*next)) {
	m_lastSetWorkedOn = downcast<RenderMultiColumnSet>(next);
	m_lastSetWorkedOn->beginFlow(container);
	break;
	}
	}
	}

	RenderBox::LogicalExtentComputedValues RenderMultiColumnFlow::computeLogicalHeight(LayoutUnit logicalHeight, LayoutUnit logicalTop) const
	{
	// We simply remain at our intrinsic height.
	return { logicalHeight, logicalTop, ComputedMarginValues() };
	}

	LayoutUnit RenderMultiColumnFlow::initialLogicalWidth() const
	{
	return columnWidth();
	}

	void RenderMultiColumnFlow::setPageBreak(const RenderBlock* block, LayoutUnit offset, LayoutUnit spaceShortage)
	{
	if (auto* multicolSet = downcast<RenderMultiColumnSet>(fragmentAtBlockOffset(block, offset)))
	multicolSet->recordSpaceShortage(spaceShortage);
	}

	void RenderMultiColumnFlow::updateMinimumPageHeight(const RenderBlock* block, LayoutUnit offset, LayoutUnit minHeight)
	{
	if (auto* multicolSet = downcast<RenderMultiColumnSet>(fragmentAtBlockOffset(block, offset)))
	multicolSet->updateMinimumColumnHeight(minHeight);
	}

	RenderFragmentContainer* RenderMultiColumnFlow::fragmentAtBlockOffset(const RenderBox* box, LayoutUnit offset, bool extendLastFragment) const
	{
	if (!m_inLayout)
	return RenderFragmentedFlow::fragmentAtBlockOffset(box, offset, extendLastFragment);

	// Layout in progress. We are calculating the set heights as we speak, so the fragment range
	// information is not up-to-date.

	RenderMultiColumnSet* columnSet = m_lastSetWorkedOn ? m_lastSetWorkedOn : firstMultiColumnSet();
	if (!columnSet) {
	// If there's no set, bail. This multicol is empty or only consists of spanners. There
	// are no fragments.
	return nullptr;
	}
	// The last set worked on is a good guess. But if we're not within the bounds, search for the
	// right one.
	if (offset < columnSet->logicalTopInFragmentedFlow()) {
	do {
	if (RenderMultiColumnSet* prev = columnSet->previousSiblingMultiColumnSet())
	columnSet = prev;
	else
	break;
	} while (offset < columnSet->logicalTopInFragmentedFlow());
	} else {
	while (offset >= columnSet->logicalBottomInFragmentedFlow()) {
	RenderMultiColumnSet* next = columnSet->nextSiblingMultiColumnSet();
	if (!next \|\| !next->hasBeenFlowed())
	break;
	columnSet = next;
	}
	}
	return columnSet;
	}

	void RenderMultiColumnFlow::setFragmentRangeForBox(const RenderBox& box, RenderFragmentContainer* startFragment, RenderFragmentContainer* endFragment)
	{
	// Some column sets may have zero height, which means that two or more sets may start at the
	// exact same flow thread position, which means that some parts of the code may believe that a
	// given box lives in sets that it doesn't really live in. Make some adjustments here and
	// include such sets if they are adjacent to the start and/or end fragments.
	for (RenderMultiColumnSet* columnSet = downcast<RenderMultiColumnSet>(*startFragment).previousSiblingMultiColumnSet(); columnSet; columnSet = columnSet->previousSiblingMultiColumnSet()) {
	if (columnSet->logicalHeightInFragmentedFlow())
	break;
	startFragment = columnSet;
	}
	for (RenderMultiColumnSet* columnSet = downcast<RenderMultiColumnSet>(*startFragment).nextSiblingMultiColumnSet(); columnSet; columnSet = columnSet->nextSiblingMultiColumnSet()) {
	if (columnSet->logicalHeightInFragmentedFlow())
	break;
	endFragment = columnSet;
	}

	RenderFragmentedFlow::setFragmentRangeForBox(box, startFragment, endFragment);
	}

	bool RenderMultiColumnFlow::addForcedFragmentBreak(const RenderBlock* block, LayoutUnit offset, RenderBox* /breakChild/, bool /isBefore/, LayoutUnit* offsetBreakAdjustment)
	{
	if (auto* multicolSet = downcast<RenderMultiColumnSet>(fragmentAtBlockOffset(block, offset))) {
	multicolSet->addForcedBreak(offset);
	if (offsetBreakAdjustment)
	*offsetBreakAdjustment = pageLogicalHeightForOffset(offset) ? pageRemainingLogicalHeightForOffset(offset, IncludePageBoundary) : 0_lu;
	return true;
	}
	return false;
	}

	LayoutSize RenderMultiColumnFlow::offsetFromContainer(RenderElement& enclosingContainer, const LayoutPoint& physicalPoint, bool* offsetDependsOnPoint) const
	{
	ASSERT(&enclosingContainer == container());

	if (offsetDependsOnPoint)
	*offsetDependsOnPoint = true;

	LayoutPoint translatedPhysicalPoint(physicalPoint);
	if (RenderFragmentContainer* fragment = physicalTranslationFromFlowToFragment(translatedPhysicalPoint))
	translatedPhysicalPoint.moveBy(fragment->topLeftLocation());

	LayoutSize offset(translatedPhysicalPoint.x(), translatedPhysicalPoint.y());
	if (is<RenderBox>(enclosingContainer))
	offset -= toLayoutSize(downcast<RenderBox>(enclosingContainer).scrollPosition());
	return offset;
	}

	void RenderMultiColumnFlow::mapAbsoluteToLocalPoint(MapCoordinatesFlags mode, TransformState& transformState) const
	{
	// First get the transform state's point into the block flow thread's physical coordinate space.
	parent()->mapAbsoluteToLocalPoint(mode, transformState);
	LayoutPoint transformPoint(transformState.mappedPoint());

	// Now walk through each fragment.
	const RenderMultiColumnSet* candidateColumnSet = nullptr;
	LayoutPoint candidatePoint;
	LayoutSize candidateContainerOffset;

	for (const auto& columnSet : childrenOfType<RenderMultiColumnSet>(*parent())) {
	candidateContainerOffset = columnSet.offsetFromContainer(*parent(), LayoutPoint());

	candidatePoint = transformPoint - candidateContainerOffset;
	candidateColumnSet = &columnSet;

	// We really have no clue what to do with overflow. We'll just use the closest fragment to the point in that case.
	LayoutUnit pointOffset = isHorizontalWritingMode() ? candidatePoint.y() : candidatePoint.x();
	LayoutUnit fragmentOffset = isHorizontalWritingMode() ? columnSet.topLeftLocation().y() : columnSet.topLeftLocation().x();
	if (pointOffset < fragmentOffset + columnSet.logicalHeight())
	break;
	}

	// Once we have a good guess as to which fragment we hit tested through (and yes, this was just a heuristic, but it's
	// the best we could do), then we can map from the fragment into the flow thread.
	LayoutSize translationOffset = physicalTranslationFromFragmentToFlow(candidateColumnSet, candidatePoint) + candidateContainerOffset;
	bool preserve3D = mode & UseTransforms && (parent()->style().preserves3D() \|\| style().preserves3D());
	if (mode & UseTransforms && shouldUseTransformFromContainer(parent())) {
	TransformationMatrix t;
	getTransformFromContainer(parent(), translationOffset, t);
	transformState.applyTransform(t, preserve3D ? TransformState::AccumulateTransform : TransformState::FlattenTransform);
	} else
	transformState.move(translationOffset.width(), translationOffset.height(), preserve3D ? TransformState::AccumulateTransform : TransformState::FlattenTransform);
	}

	LayoutSize RenderMultiColumnFlow::physicalTranslationFromFragmentToFlow(const RenderMultiColumnSet* columnSet, const LayoutPoint& physicalPoint) const
	{
	LayoutPoint logicalPoint = columnSet->flipForWritingMode(physicalPoint);
	LayoutPoint translatedPoint = columnSet->translateFragmentPointToFragmentedFlow(logicalPoint);
	LayoutPoint physicalTranslatedPoint = columnSet->flipForWritingMode(translatedPoint);
	return physicalPoint - physicalTranslatedPoint;
	}

	RenderFragmentContainer* RenderMultiColumnFlow::mapFromFlowToFragment(TransformState& transformState) const
	{
	if (!hasValidFragmentInfo())
	return nullptr;

	// Get back into our local flow thread space.
	LayoutRect boxRect = transformState.mappedQuad().enclosingBoundingBox();
	flipForWritingMode(boxRect);

	// FIXME: We need to refactor RenderObject::absoluteQuads to be able to split the quads across fragments,
	// for now we just take the center of the mapped enclosing box and map it to a column.
	LayoutPoint centerPoint = boxRect.center();
	LayoutUnit centerLogicalOffset = isHorizontalWritingMode() ? centerPoint.y() : centerPoint.x();
	RenderFragmentContainer* RenderFragmentContainer = fragmentAtBlockOffset(this, centerLogicalOffset, true);
	if (!RenderFragmentContainer)
	return nullptr;
	transformState.move(physicalTranslationOffsetFromFlowToFragment(RenderFragmentContainer, centerLogicalOffset));
	return RenderFragmentContainer;
	}

	LayoutSize RenderMultiColumnFlow::physicalTranslationOffsetFromFlowToFragment(const RenderFragmentContainer* RenderFragmentContainer, const LayoutUnit logicalOffset) const
	{
	// Now that we know which multicolumn set we hit, we need to get the appropriate translation offset for the column.
	const auto* columnSet = downcast<RenderMultiColumnSet>(RenderFragmentContainer);
	LayoutPoint translationOffset = columnSet->columnTranslationForOffset(logicalOffset);

	// Now we know how we want the rect to be translated into the fragment. At this point we're converting
	// back to physical coordinates.
	if (style().isFlippedBlocksWritingMode()) {
	LayoutRect portionRect(columnSet->fragmentedFlowPortionRect());
	LayoutRect columnRect = columnSet->columnRectAt(0);
	LayoutUnit physicalDeltaFromPortionBottom = logicalHeight() - columnSet->logicalBottomInFragmentedFlow();
	if (isHorizontalWritingMode())
	columnRect.setHeight(portionRect.height());
	else
	columnRect.setWidth(portionRect.width());
	columnSet->flipForWritingMode(columnRect);
	if (isHorizontalWritingMode())
	translationOffset.move(0_lu, columnRect.y() - portionRect.y() - physicalDeltaFromPortionBottom);
	else
	translationOffset.move(columnRect.x() - portionRect.x() - physicalDeltaFromPortionBottom, 0_lu);
	}

	return LayoutSize(translationOffset.x(), translationOffset.y());
	}

	RenderFragmentContainer* RenderMultiColumnFlow::physicalTranslationFromFlowToFragment(LayoutPoint& physicalPoint) const
	{
	if (!hasValidFragmentInfo())
	return nullptr;

	// Put the physical point into the flow thread's coordinate space.
	LayoutPoint logicalPoint = flipForWritingMode(physicalPoint);

	// Now get the fragment that we are in.
	LayoutUnit logicalOffset = isHorizontalWritingMode() ? logicalPoint.y() : logicalPoint.x();
	RenderFragmentContainer* RenderFragmentContainer = fragmentAtBlockOffset(this, logicalOffset, true);
	if (!RenderFragmentContainer)
	return nullptr;

	// Translate to the coordinate space of the fragment.
	LayoutSize translationOffset = physicalTranslationOffsetFromFlowToFragment(RenderFragmentContainer, logicalOffset);

	// Now shift the physical point into the fragment's coordinate space.
	physicalPoint += translationOffset;

	return RenderFragmentContainer;
	}

	bool RenderMultiColumnFlow::isPageLogicalHeightKnown() const
	{
	if (RenderMultiColumnSet* columnSet = lastMultiColumnSet())
	return columnSet->columnHeightComputed();
	return false;
	}

	bool RenderMultiColumnFlow::nodeAtPoint(const HitTestRequest& request, HitTestResult& result, const HitTestLocation& locationInContainer, const LayoutPoint& accumulatedOffset, HitTestAction hitTestAction)
	{
	// You cannot be inside an in-flow RenderFragmentedFlow without a corresponding DOM node. It's better to
	// just let the ancestor figure out where we are instead.
	if (hitTestAction == HitTestBlockBackground)
	return false;
	bool inside = RenderFragmentedFlow::nodeAtPoint(request, result, locationInContainer, accumulatedOffset, hitTestAction);
	if (inside && !result.innerNode())
	return false;
	return inside;
	}

	bool RenderMultiColumnFlow::shouldCheckColumnBreaks() const
	{
	if (!parent()->isRenderView())
	return true;
	return view().frameView().pagination().behavesLikeColumns;
	}

	}