Source/WebCore/rendering/RenderFlowThread.h - WebKit - Git at Google

 /*
  * Copyright (C) 2011 Adobe Systems Incorporated. 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 THE COPYRIGHT HOLDER "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 THE COPYRIGHT HOLDER BE
  * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY,
  * OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
  * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
  * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR
  * TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF
  * THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
  * SUCH DAMAGE.
  */

 #ifndef RenderFlowThread_h
 #define RenderFlowThread_h


 #include "RenderBlockFlow.h"
 #include <wtf/HashCountedSet.h>
 #include <wtf/ListHashSet.h>
 #include <wtf/PassRefPtr.h>

 namespace WebCore {

 struct LayerFragment;
 typedef Vector<LayerFragment, 1> LayerFragments;
 class RenderFlowThread;
 class RenderNamedFlowFragment;
 class RenderStyle;
 class RenderRegion;

 typedef ListHashSet<RenderRegion*> RenderRegionList;
 typedef Vector<RenderLayer*> RenderLayerList;
 #if USE(ACCELERATED_COMPOSITING)
 typedef HashMap<RenderNamedFlowFragment*, RenderLayerList> RegionToLayerListMap;
 typedef HashMap<RenderLayer*, RenderNamedFlowFragment*> LayerToRegionMap;
 #endif

 // RenderFlowThread is used to collect all the render objects that participate in a
 // flow thread. It will also help in doing the layout. However, it will not render
 // directly to screen. Instead, RenderRegion objects will redirect their paint
 // and nodeAtPoint methods to this object. Each RenderRegion will actually be a viewPort
 // of the RenderFlowThread.

 class RenderFlowThread: public RenderBlockFlow {
 public:
     RenderFlowThread(Document&, PassRef<RenderStyle>);
     virtual ~RenderFlowThread() { };

     virtual bool isRenderFlowThread() const OVERRIDE FINAL { return true; }

     virtual void layout() OVERRIDE FINAL;

     // Always create a RenderLayer for the RenderFlowThread so that we
     // can easily avoid drawing the children directly.
     virtual bool requiresLayer() const OVERRIDE FINAL { return true; }

     virtual void removeFlowChildInfo(RenderObject*);
 #ifndef NDEBUG
     bool hasChildInfo(RenderObject* child) const { return child && child->isBox() && m_regionRangeMap.contains(toRenderBox(child)); }
 #endif

     virtual void addRegionToThread(RenderRegion*);
     virtual void removeRegionFromThread(RenderRegion*);
     const RenderRegionList& renderRegionList() const { return m_regionList; }

     virtual void updateLogicalWidth() OVERRIDE FINAL;
     virtual void computeLogicalHeight(LayoutUnit logicalHeight, LayoutUnit logicalTop, LogicalExtentComputedValues&) const OVERRIDE;

     virtual bool nodeAtPoint(const HitTestRequest&, HitTestResult&, const HitTestLocation& locationInContainer, const LayoutPoint& accumulatedOffset, HitTestAction) OVERRIDE;

     bool hasRegions() const { return m_regionList.size(); }
     virtual void regionChangedWritingMode(RenderRegion*) { }

     void validateRegions();
     void invalidateRegions();
     bool hasValidRegionInfo() const { return !m_regionsInvalidated && !m_regionList.isEmpty(); }

     static PassRef<RenderStyle> createFlowThreadStyle(RenderStyle* parentStyle);

     virtual void styleDidChange(StyleDifference, const RenderStyle* oldStyle) OVERRIDE;

     void repaintRectangleInRegions(const LayoutRect&, bool immediate) const;

     LayoutPoint adjustedPositionRelativeToOffsetParent(const RenderBoxModelObject&, const LayoutPoint&);

     LayoutUnit pageLogicalTopForOffset(LayoutUnit);
     LayoutUnit pageLogicalWidthForOffset(LayoutUnit);
     LayoutUnit pageLogicalHeightForOffset(LayoutUnit);
     LayoutUnit pageRemainingLogicalHeightForOffset(LayoutUnit, PageBoundaryRule = IncludePageBoundary);

     virtual void setPageBreak(const RenderBlock*, LayoutUnit /*offset*/, LayoutUnit /*spaceShortage*/) { }
     virtual void updateMinimumPageHeight(const RenderBlock*, LayoutUnit /*offset*/, LayoutUnit /*minHeight*/) { }

     enum RegionAutoGenerationPolicy {
         AllowRegionAutoGeneration,
         DisallowRegionAutoGeneration,
     };

     RenderRegion* regionAtBlockOffset(const RenderBox*, LayoutUnit, bool extendLastRegion = false, RegionAutoGenerationPolicy = AllowRegionAutoGeneration);

     bool regionsHaveUniformLogicalWidth() const { return m_regionsHaveUniformLogicalWidth; }
     bool regionsHaveUniformLogicalHeight() const { return m_regionsHaveUniformLogicalHeight; }

     RenderRegion* mapFromFlowToRegion(TransformState&) const;

     void removeRenderBoxRegionInfo(RenderBox*);
     void logicalWidthChangedInRegionsForBlock(const RenderBlock*, bool&);

     LayoutUnit contentLogicalWidthOfFirstRegion() const;
     LayoutUnit contentLogicalHeightOfFirstRegion() const;
     LayoutUnit contentLogicalLeftOfFirstRegion() const;

     RenderRegion* firstRegion() const;
     RenderRegion* lastRegion() const;

     bool previousRegionCountChanged() const { return m_previousRegionCount != m_regionList.size(); };
     void updatePreviousRegionCount() { m_previousRegionCount = m_regionList.size(); };

     void setRegionRangeForBox(const RenderBox*, RenderRegion*, RenderRegion*);
     void getRegionRangeForBox(const RenderBox*, RenderRegion*& startRegion, RenderRegion*& endRegion) const;

     // Check if the object is in region and the region is part of this flow thread.
     bool objectInFlowRegion(const RenderObject*, const RenderRegion*) const;

     // Check if the object should be painted in this region and if the region is part of this flow thread.
     bool objectShouldPaintInFlowRegion(const RenderObject*, const RenderRegion*) const;

     void markAutoLogicalHeightRegionsForLayout();
     void markRegionsForOverflowLayoutIfNeeded();

     bool addForcedRegionBreak(const RenderBlock*, LayoutUnit, RenderBox* breakChild, bool isBefore, LayoutUnit* offsetBreakAdjustment = 0);
     void applyBreakAfterContent(LayoutUnit);

     bool pageLogicalSizeChanged() const { return m_pageLogicalSizeChanged; }

     bool hasAutoLogicalHeightRegions() const { ASSERT(isAutoLogicalHeightRegionsCountConsistent()); return m_autoLogicalHeightRegionsCount; }
     void incrementAutoLogicalHeightRegions();
     void decrementAutoLogicalHeightRegions();

 #ifndef NDEBUG
     bool isAutoLogicalHeightRegionsCountConsistent() const;
 #endif

     void collectLayerFragments(LayerFragments&, const LayoutRect& layerBoundingBox, const LayoutRect& dirtyRect);
     LayoutRect fragmentsBoundingBox(const LayoutRect& layerBoundingBox);

     // A flow thread goes through different states during layout.
     enum LayoutPhase {
         LayoutPhaseMeasureContent = 0, // The initial phase, used to measure content for the auto-height regions.
         LayoutPhaseConstrained, // In this phase the regions are laid out using the sizes computed in the normal phase.
         LayoutPhaseOverflow, // In this phase the layout overflow is propagated from the content to the regions.
         LayoutPhaseFinal // In case scrollbars have resized the regions, content is laid out one last time to respect the change.
     };
     bool inMeasureContentLayoutPhase() const { return m_layoutPhase == LayoutPhaseMeasureContent; }
     bool inConstrainedLayoutPhase() const { return m_layoutPhase == LayoutPhaseConstrained; }
     bool inOverflowLayoutPhase() const { return m_layoutPhase == LayoutPhaseOverflow; }
     bool inFinalLayoutPhase() const { return m_layoutPhase == LayoutPhaseFinal; }
     void setLayoutPhase(LayoutPhase phase) { m_layoutPhase = phase; }

     bool needsTwoPhasesLayout() const { return m_needsTwoPhasesLayout; }
     void clearNeedsTwoPhasesLayout() { m_needsTwoPhasesLayout = false; }

 #if USE(ACCELERATED_COMPOSITING)
     // Whether any of the regions has a compositing descendant.
     bool hasCompositingRegionDescendant() const;

     void setNeedsLayerToRegionMappingsUpdate() { m_layersToRegionMappingsDirty = true; }
     void updateAllLayerToRegionMappingsIfNeeded()
     {
         if (m_layersToRegionMappingsDirty)
             updateAllLayerToRegionMappings();
     }

     const RenderLayerList* getLayerListForRegion(RenderNamedFlowFragment*);

     RenderNamedFlowFragment* regionForCompositedLayer(RenderLayer&); // By means of getRegionRangeForBox or regionAtBlockOffset.
     RenderNamedFlowFragment* cachedRegionForCompositedLayer(RenderLayer&);

 #endif
     virtual bool collectsGraphicsLayersUnderRegions() const;

     void pushFlowThreadLayoutState(const RenderObject&);
     void popFlowThreadLayoutState();
     LayoutUnit offsetFromLogicalTopOfFirstRegion(const RenderBlock*) const;
     void clearRenderBoxRegionInfoAndCustomStyle(const RenderBox*, const RenderRegion*, const RenderRegion*, const RenderRegion*, const RenderRegion*);

     void addRegionsVisualEffectOverflow(const RenderBox*);
     void addRegionsVisualOverflowFromTheme(const RenderBlock*);
     void addRegionsOverflowFromChild(const RenderBox*, const RenderBox*, const LayoutSize&);
     void addRegionsLayoutOverflow(const RenderBox*, const LayoutRect&);
     void addRegionsVisualOverflow(const RenderBox*, const LayoutRect&);
     void clearRegionsOverflow(const RenderBox*);

     LayoutRect mapFromFlowThreadToLocal(const RenderBox*, const LayoutRect&) const;
     LayoutRect mapFromLocalToFlowThread(const RenderBox*, const LayoutRect&) const;

     LayoutRect decorationsClipRectForBoxInRegion(const RenderBox&, RenderRegion&) const;

     void flipForWritingModeLocalCoordinates(LayoutRect&) const;

     // Used to estimate the maximum height of the flow thread.
     static LayoutUnit maxLogicalHeight() { return LayoutUnit::max() / 2; }

     bool regionInRange(const RenderRegion* targetRegion, const RenderRegion* startRegion, const RenderRegion* endRegion) const;

 protected:
     virtual const char* renderName() const = 0;

     // Overridden by columns/pages to set up an initial logical width of the page width even when
     // no regions have been generated yet.
     virtual LayoutUnit initialLogicalWidth() const { return 0; };

     virtual void mapLocalToContainer(const RenderLayerModelObject* repaintContainer, TransformState&, MapCoordinatesFlags = ApplyContainerFlip, bool* wasFixed = 0) const OVERRIDE;

     void updateRegionsFlowThreadPortionRect(const RenderRegion* = 0);
     bool shouldRepaint(const LayoutRect&) const;

     LayoutRect computeRegionClippingRect(const LayoutPoint&, const LayoutRect&, const LayoutRect&) const;

 #if USE(ACCELERATED_COMPOSITING)
     bool updateAllLayerToRegionMappings();

     // Triggers a layers' update if a layer has moved from a region to another since the last update.
     void updateLayerToRegionMappings(RenderLayer&, LayerToRegionMap&, RegionToLayerListMap&, bool& needsLayerUpdate);
     RenderNamedFlowFragment* regionForCompositedLayer(RenderLayer*);
     bool updateLayerToRegionMappings();
     void updateRegionForRenderLayer(RenderLayer*, LayerToRegionMap&, RegionToLayerListMap&, bool& needsLayerUpdate);
 #endif

     void setDispatchRegionLayoutUpdateEvent(bool value) { m_dispatchRegionLayoutUpdateEvent = value; }
     bool shouldDispatchRegionLayoutUpdateEvent() { return m_dispatchRegionLayoutUpdateEvent; }

     void setDispatchRegionOversetChangeEvent(bool value) { m_dispatchRegionOversetChangeEvent = value; }
     bool shouldDispatchRegionOversetChangeEvent() const { return m_dispatchRegionOversetChangeEvent; }

     // Override if the flow thread implementation supports dispatching events when the flow layout is updated (e.g. for named flows)
     virtual void dispatchRegionLayoutUpdateEvent() { m_dispatchRegionLayoutUpdateEvent = false; }
     virtual void dispatchRegionOversetChangeEvent() { m_dispatchRegionOversetChangeEvent = false; }

     void initializeRegionsComputedAutoHeight(RenderRegion* = 0);

     virtual void autoGenerateRegionsToBlockOffset(LayoutUnit) { };

     inline bool hasCachedOffsetFromLogicalTopOfFirstRegion(const RenderBox*) const;
     inline LayoutUnit cachedOffsetFromLogicalTopOfFirstRegion(const RenderBox*) const;
     inline void setOffsetFromLogicalTopOfFirstRegion(const RenderBox*, LayoutUnit);
     inline void clearOffsetFromLogicalTopOfFirstRegion(const RenderBox*);

     inline const RenderBox* currentActiveRenderBox() const;

     RenderRegionList m_regionList;
     unsigned short m_previousRegionCount;

     class RenderRegionRange {
     public:
         RenderRegionRange()
         {
             setRange(0, 0);
         }

         RenderRegionRange(RenderRegion* start, RenderRegion* end)
         {
             setRange(start, end);
         }

         void setRange(RenderRegion* start, RenderRegion* end)
         {
             m_startRegion = start;
             m_endRegion = end;
             m_rangeInvalidated = true;
         }

         RenderRegion* startRegion() const { return m_startRegion; }
         RenderRegion* endRegion() const { return m_endRegion; }
         bool rangeInvalidated() const { return m_rangeInvalidated; }
         void clearRangeInvalidated() { m_rangeInvalidated = false; }

     private:
         RenderRegion* m_startRegion;
         RenderRegion* m_endRegion;
         bool m_rangeInvalidated;
     };

     typedef PODInterval<LayoutUnit, RenderRegion*> RegionInterval;
     typedef PODIntervalTree<LayoutUnit, RenderRegion*> RegionIntervalTree;

     class RegionSearchAdapter {
     public:
         RegionSearchAdapter(LayoutUnit offset)
             : m_offset(offset)
             , m_result(0)
         {
         }

         const LayoutUnit& lowValue() const { return m_offset; }
         const LayoutUnit& highValue() const { return m_offset; }
         void collectIfNeeded(const RegionInterval&);

         RenderRegion* result() const { return m_result; }

     private:
         LayoutUnit m_offset;
         RenderRegion* m_result;
     };

 #if USE(ACCELERATED_COMPOSITING)
     // To easily find the region where a layer should be painted.
     OwnPtr<LayerToRegionMap> m_layerToRegionMap;

     // To easily find the list of layers that paint in a region.
     OwnPtr<RegionToLayerListMap> m_regionToLayerListMap;
 #endif

     // Map a box to the list of regions in which the box is rendered.
     typedef HashMap<const RenderBox*, RenderRegionRange> RenderRegionRangeMap;
     RenderRegionRangeMap m_regionRangeMap;

     // Map a box with a region break to the auto height region affected by that break.
     typedef HashMap<RenderBox*, RenderRegion*> RenderBoxToRegionMap;
     RenderBoxToRegionMap m_breakBeforeToRegionMap;
     RenderBoxToRegionMap m_breakAfterToRegionMap;

     typedef ListHashSet<const RenderObject*> RenderObjectStack;
     RenderObjectStack m_activeObjectsStack;

     typedef HashMap<const RenderBox*, LayoutUnit> RenderBoxToOffsetMap;
     RenderBoxToOffsetMap m_boxesToOffsetMap;

     unsigned m_autoLogicalHeightRegionsCount;

     RegionIntervalTree m_regionIntervalTree;

     bool m_regionsInvalidated : 1;
     bool m_regionsHaveUniformLogicalWidth : 1;
     bool m_regionsHaveUniformLogicalHeight : 1;
     bool m_dispatchRegionLayoutUpdateEvent : 1;
     bool m_dispatchRegionOversetChangeEvent : 1;
     bool m_pageLogicalSizeChanged : 1;
     unsigned m_layoutPhase : 2;
     bool m_needsTwoPhasesLayout : 1;
     bool m_layersToRegionMappingsDirty : 1;
 };

 RENDER_OBJECT_TYPE_CASTS(RenderFlowThread, isRenderFlowThread())

 class CurrentRenderFlowThreadMaintainer {
     WTF_MAKE_NONCOPYABLE(CurrentRenderFlowThreadMaintainer);
 public:
     CurrentRenderFlowThreadMaintainer(RenderFlowThread*);
     ~CurrentRenderFlowThreadMaintainer();
 private:
     RenderFlowThread* m_renderFlowThread;
     RenderFlowThread* m_previousRenderFlowThread;
 };

 // This structure is used by PODIntervalTree for debugging.
 #ifndef NDEBUG
 template <> struct ValueToString<RenderRegion*> {
     static String string(const RenderRegion* value) { return String::format("%p", value); }
 };
 #endif

 } // namespace WebCore

 #endif // RenderFlowThread_h
	/*
	* Copyright (C) 2011 Adobe Systems Incorporated. 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 THE COPYRIGHT HOLDER "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 THE COPYRIGHT HOLDER BE
	* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY,
	* OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
	* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
	* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR
	* TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF
	* THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
	* SUCH DAMAGE.
	*/

	#ifndef RenderFlowThread_h
	#define RenderFlowThread_h


	#include "RenderBlockFlow.h"
	#include <wtf/HashCountedSet.h>
	#include <wtf/ListHashSet.h>
	#include <wtf/PassRefPtr.h>

	namespace WebCore {

	struct LayerFragment;
	typedef Vector<LayerFragment, 1> LayerFragments;
	class RenderFlowThread;
	class RenderNamedFlowFragment;
	class RenderStyle;
	class RenderRegion;

	typedef ListHashSet<RenderRegion*> RenderRegionList;
	typedef Vector<RenderLayer*> RenderLayerList;
	#if USE(ACCELERATED_COMPOSITING)
	typedef HashMap<RenderNamedFlowFragment*, RenderLayerList> RegionToLayerListMap;
	typedef HashMap<RenderLayer, RenderNamedFlowFragment> LayerToRegionMap;
	#endif

	// RenderFlowThread is used to collect all the render objects that participate in a
	// flow thread. It will also help in doing the layout. However, it will not render
	// directly to screen. Instead, RenderRegion objects will redirect their paint
	// and nodeAtPoint methods to this object. Each RenderRegion will actually be a viewPort
	// of the RenderFlowThread.

	class RenderFlowThread: public RenderBlockFlow {
	public:
	RenderFlowThread(Document&, PassRef<RenderStyle>);
	virtual ~RenderFlowThread() { };

	virtual bool isRenderFlowThread() const OVERRIDE FINAL { return true; }

	virtual void layout() OVERRIDE FINAL;

	// Always create a RenderLayer for the RenderFlowThread so that we
	// can easily avoid drawing the children directly.
	virtual bool requiresLayer() const OVERRIDE FINAL { return true; }

	virtual void removeFlowChildInfo(RenderObject*);
	#ifndef NDEBUG
	bool hasChildInfo(RenderObject* child) const { return child && child->isBox() && m_regionRangeMap.contains(toRenderBox(child)); }
	#endif

	virtual void addRegionToThread(RenderRegion*);
	virtual void removeRegionFromThread(RenderRegion*);
	const RenderRegionList& renderRegionList() const { return m_regionList; }

	virtual void updateLogicalWidth() OVERRIDE FINAL;
	virtual void computeLogicalHeight(LayoutUnit logicalHeight, LayoutUnit logicalTop, LogicalExtentComputedValues&) const OVERRIDE;

	virtual bool nodeAtPoint(const HitTestRequest&, HitTestResult&, const HitTestLocation& locationInContainer, const LayoutPoint& accumulatedOffset, HitTestAction) OVERRIDE;

	bool hasRegions() const { return m_regionList.size(); }
	virtual void regionChangedWritingMode(RenderRegion*) { }

	void validateRegions();
	void invalidateRegions();
	bool hasValidRegionInfo() const { return !m_regionsInvalidated && !m_regionList.isEmpty(); }

	static PassRef<RenderStyle> createFlowThreadStyle(RenderStyle* parentStyle);

	virtual void styleDidChange(StyleDifference, const RenderStyle* oldStyle) OVERRIDE;

	void repaintRectangleInRegions(const LayoutRect&, bool immediate) const;

	LayoutPoint adjustedPositionRelativeToOffsetParent(const RenderBoxModelObject&, const LayoutPoint&);

	LayoutUnit pageLogicalTopForOffset(LayoutUnit);
	LayoutUnit pageLogicalWidthForOffset(LayoutUnit);
	LayoutUnit pageLogicalHeightForOffset(LayoutUnit);
	LayoutUnit pageRemainingLogicalHeightForOffset(LayoutUnit, PageBoundaryRule = IncludePageBoundary);

	virtual void setPageBreak(const RenderBlock, LayoutUnit /offset/, LayoutUnit /spaceShortage*/) { }
	virtual void updateMinimumPageHeight(const RenderBlock, LayoutUnit /offset/, LayoutUnit /minHeight*/) { }

	enum RegionAutoGenerationPolicy {
	AllowRegionAutoGeneration,
	DisallowRegionAutoGeneration,
	};

	RenderRegion* regionAtBlockOffset(const RenderBox*, LayoutUnit, bool extendLastRegion = false, RegionAutoGenerationPolicy = AllowRegionAutoGeneration);

	bool regionsHaveUniformLogicalWidth() const { return m_regionsHaveUniformLogicalWidth; }
	bool regionsHaveUniformLogicalHeight() const { return m_regionsHaveUniformLogicalHeight; }

	RenderRegion* mapFromFlowToRegion(TransformState&) const;

	void removeRenderBoxRegionInfo(RenderBox*);
	void logicalWidthChangedInRegionsForBlock(const RenderBlock*, bool&);

	LayoutUnit contentLogicalWidthOfFirstRegion() const;
	LayoutUnit contentLogicalHeightOfFirstRegion() const;
	LayoutUnit contentLogicalLeftOfFirstRegion() const;

	RenderRegion* firstRegion() const;
	RenderRegion* lastRegion() const;

	bool previousRegionCountChanged() const { return m_previousRegionCount != m_regionList.size(); };
	void updatePreviousRegionCount() { m_previousRegionCount = m_regionList.size(); };

	void setRegionRangeForBox(const RenderBox, RenderRegion, RenderRegion*);
	void getRegionRangeForBox(const RenderBox, RenderRegion& startRegion, RenderRegion*& endRegion) const;

	// Check if the object is in region and the region is part of this flow thread.
	bool objectInFlowRegion(const RenderObject, const RenderRegion) const;

	// Check if the object should be painted in this region and if the region is part of this flow thread.
	bool objectShouldPaintInFlowRegion(const RenderObject, const RenderRegion) const;

	void markAutoLogicalHeightRegionsForLayout();
	void markRegionsForOverflowLayoutIfNeeded();

	bool addForcedRegionBreak(const RenderBlock, LayoutUnit, RenderBox breakChild, bool isBefore, LayoutUnit* offsetBreakAdjustment = 0);
	void applyBreakAfterContent(LayoutUnit);

	bool pageLogicalSizeChanged() const { return m_pageLogicalSizeChanged; }

	bool hasAutoLogicalHeightRegions() const { ASSERT(isAutoLogicalHeightRegionsCountConsistent()); return m_autoLogicalHeightRegionsCount; }
	void incrementAutoLogicalHeightRegions();
	void decrementAutoLogicalHeightRegions();

	#ifndef NDEBUG
	bool isAutoLogicalHeightRegionsCountConsistent() const;
	#endif

	void collectLayerFragments(LayerFragments&, const LayoutRect& layerBoundingBox, const LayoutRect& dirtyRect);
	LayoutRect fragmentsBoundingBox(const LayoutRect& layerBoundingBox);

	// A flow thread goes through different states during layout.
	enum LayoutPhase {
	LayoutPhaseMeasureContent = 0, // The initial phase, used to measure content for the auto-height regions.
	LayoutPhaseConstrained, // In this phase the regions are laid out using the sizes computed in the normal phase.
	LayoutPhaseOverflow, // In this phase the layout overflow is propagated from the content to the regions.
	LayoutPhaseFinal // In case scrollbars have resized the regions, content is laid out one last time to respect the change.
	};
	bool inMeasureContentLayoutPhase() const { return m_layoutPhase == LayoutPhaseMeasureContent; }
	bool inConstrainedLayoutPhase() const { return m_layoutPhase == LayoutPhaseConstrained; }
	bool inOverflowLayoutPhase() const { return m_layoutPhase == LayoutPhaseOverflow; }
	bool inFinalLayoutPhase() const { return m_layoutPhase == LayoutPhaseFinal; }
	void setLayoutPhase(LayoutPhase phase) { m_layoutPhase = phase; }

	bool needsTwoPhasesLayout() const { return m_needsTwoPhasesLayout; }
	void clearNeedsTwoPhasesLayout() { m_needsTwoPhasesLayout = false; }

	#if USE(ACCELERATED_COMPOSITING)
	// Whether any of the regions has a compositing descendant.
	bool hasCompositingRegionDescendant() const;

	void setNeedsLayerToRegionMappingsUpdate() { m_layersToRegionMappingsDirty = true; }
	void updateAllLayerToRegionMappingsIfNeeded()
	{
	if (m_layersToRegionMappingsDirty)
	updateAllLayerToRegionMappings();
	}

	const RenderLayerList* getLayerListForRegion(RenderNamedFlowFragment*);

	RenderNamedFlowFragment* regionForCompositedLayer(RenderLayer&); // By means of getRegionRangeForBox or regionAtBlockOffset.
	RenderNamedFlowFragment* cachedRegionForCompositedLayer(RenderLayer&);

	#endif
	virtual bool collectsGraphicsLayersUnderRegions() const;

	void pushFlowThreadLayoutState(const RenderObject&);
	void popFlowThreadLayoutState();
	LayoutUnit offsetFromLogicalTopOfFirstRegion(const RenderBlock*) const;
	void clearRenderBoxRegionInfoAndCustomStyle(const RenderBox, const RenderRegion, const RenderRegion, const RenderRegion, const RenderRegion*);

	void addRegionsVisualEffectOverflow(const RenderBox*);
	void addRegionsVisualOverflowFromTheme(const RenderBlock*);
	void addRegionsOverflowFromChild(const RenderBox, const RenderBox, const LayoutSize&);
	void addRegionsLayoutOverflow(const RenderBox*, const LayoutRect&);
	void addRegionsVisualOverflow(const RenderBox*, const LayoutRect&);
	void clearRegionsOverflow(const RenderBox*);

	LayoutRect mapFromFlowThreadToLocal(const RenderBox*, const LayoutRect&) const;
	LayoutRect mapFromLocalToFlowThread(const RenderBox*, const LayoutRect&) const;

	LayoutRect decorationsClipRectForBoxInRegion(const RenderBox&, RenderRegion&) const;

	void flipForWritingModeLocalCoordinates(LayoutRect&) const;

	// Used to estimate the maximum height of the flow thread.
	static LayoutUnit maxLogicalHeight() { return LayoutUnit::max() / 2; }

	bool regionInRange(const RenderRegion* targetRegion, const RenderRegion* startRegion, const RenderRegion* endRegion) const;

	protected:
	virtual const char* renderName() const = 0;

	// Overridden by columns/pages to set up an initial logical width of the page width even when
	// no regions have been generated yet.
	virtual LayoutUnit initialLogicalWidth() const { return 0; };

	virtual void mapLocalToContainer(const RenderLayerModelObject* repaintContainer, TransformState&, MapCoordinatesFlags = ApplyContainerFlip, bool* wasFixed = 0) const OVERRIDE;

	void updateRegionsFlowThreadPortionRect(const RenderRegion* = 0);
	bool shouldRepaint(const LayoutRect&) const;

	LayoutRect computeRegionClippingRect(const LayoutPoint&, const LayoutRect&, const LayoutRect&) const;

	#if USE(ACCELERATED_COMPOSITING)
	bool updateAllLayerToRegionMappings();

	// Triggers a layers' update if a layer has moved from a region to another since the last update.
	void updateLayerToRegionMappings(RenderLayer&, LayerToRegionMap&, RegionToLayerListMap&, bool& needsLayerUpdate);
	RenderNamedFlowFragment* regionForCompositedLayer(RenderLayer*);
	bool updateLayerToRegionMappings();
	void updateRegionForRenderLayer(RenderLayer*, LayerToRegionMap&, RegionToLayerListMap&, bool& needsLayerUpdate);
	#endif

	void setDispatchRegionLayoutUpdateEvent(bool value) { m_dispatchRegionLayoutUpdateEvent = value; }
	bool shouldDispatchRegionLayoutUpdateEvent() { return m_dispatchRegionLayoutUpdateEvent; }

	void setDispatchRegionOversetChangeEvent(bool value) { m_dispatchRegionOversetChangeEvent = value; }
	bool shouldDispatchRegionOversetChangeEvent() const { return m_dispatchRegionOversetChangeEvent; }

	// Override if the flow thread implementation supports dispatching events when the flow layout is updated (e.g. for named flows)
	virtual void dispatchRegionLayoutUpdateEvent() { m_dispatchRegionLayoutUpdateEvent = false; }
	virtual void dispatchRegionOversetChangeEvent() { m_dispatchRegionOversetChangeEvent = false; }

	void initializeRegionsComputedAutoHeight(RenderRegion* = 0);

	virtual void autoGenerateRegionsToBlockOffset(LayoutUnit) { };

	inline bool hasCachedOffsetFromLogicalTopOfFirstRegion(const RenderBox*) const;
	inline LayoutUnit cachedOffsetFromLogicalTopOfFirstRegion(const RenderBox*) const;
	inline void setOffsetFromLogicalTopOfFirstRegion(const RenderBox*, LayoutUnit);
	inline void clearOffsetFromLogicalTopOfFirstRegion(const RenderBox*);

	inline const RenderBox* currentActiveRenderBox() const;

	RenderRegionList m_regionList;
	unsigned short m_previousRegionCount;

	class RenderRegionRange {
	public:
	RenderRegionRange()
	{
	setRange(0, 0);
	}

	RenderRegionRange(RenderRegion* start, RenderRegion* end)
	{
	setRange(start, end);
	}

	void setRange(RenderRegion* start, RenderRegion* end)
	{
	m_startRegion = start;
	m_endRegion = end;
	m_rangeInvalidated = true;
	}

	RenderRegion* startRegion() const { return m_startRegion; }
	RenderRegion* endRegion() const { return m_endRegion; }
	bool rangeInvalidated() const { return m_rangeInvalidated; }
	void clearRangeInvalidated() { m_rangeInvalidated = false; }

	private:
	RenderRegion* m_startRegion;
	RenderRegion* m_endRegion;
	bool m_rangeInvalidated;
	};

	typedef PODInterval<LayoutUnit, RenderRegion*> RegionInterval;
	typedef PODIntervalTree<LayoutUnit, RenderRegion*> RegionIntervalTree;

	class RegionSearchAdapter {
	public:
	RegionSearchAdapter(LayoutUnit offset)
	: m_offset(offset)
	, m_result(0)
	{
	}

	const LayoutUnit& lowValue() const { return m_offset; }
	const LayoutUnit& highValue() const { return m_offset; }
	void collectIfNeeded(const RegionInterval&);

	RenderRegion* result() const { return m_result; }

	private:
	LayoutUnit m_offset;
	RenderRegion* m_result;
	};

	#if USE(ACCELERATED_COMPOSITING)
	// To easily find the region where a layer should be painted.
	OwnPtr<LayerToRegionMap> m_layerToRegionMap;

	// To easily find the list of layers that paint in a region.
	OwnPtr<RegionToLayerListMap> m_regionToLayerListMap;
	#endif

	// Map a box to the list of regions in which the box is rendered.
	typedef HashMap<const RenderBox*, RenderRegionRange> RenderRegionRangeMap;
	RenderRegionRangeMap m_regionRangeMap;

	// Map a box with a region break to the auto height region affected by that break.
	typedef HashMap<RenderBox, RenderRegion> RenderBoxToRegionMap;
	RenderBoxToRegionMap m_breakBeforeToRegionMap;
	RenderBoxToRegionMap m_breakAfterToRegionMap;

	typedef ListHashSet<const RenderObject*> RenderObjectStack;
	RenderObjectStack m_activeObjectsStack;

	typedef HashMap<const RenderBox*, LayoutUnit> RenderBoxToOffsetMap;
	RenderBoxToOffsetMap m_boxesToOffsetMap;

	unsigned m_autoLogicalHeightRegionsCount;

	RegionIntervalTree m_regionIntervalTree;

	bool m_regionsInvalidated : 1;
	bool m_regionsHaveUniformLogicalWidth : 1;
	bool m_regionsHaveUniformLogicalHeight : 1;
	bool m_dispatchRegionLayoutUpdateEvent : 1;
	bool m_dispatchRegionOversetChangeEvent : 1;
	bool m_pageLogicalSizeChanged : 1;
	unsigned m_layoutPhase : 2;
	bool m_needsTwoPhasesLayout : 1;
	bool m_layersToRegionMappingsDirty : 1;
	};

	RENDER_OBJECT_TYPE_CASTS(RenderFlowThread, isRenderFlowThread())

	class CurrentRenderFlowThreadMaintainer {
	WTF_MAKE_NONCOPYABLE(CurrentRenderFlowThreadMaintainer);
	public:
	CurrentRenderFlowThreadMaintainer(RenderFlowThread*);
	~CurrentRenderFlowThreadMaintainer();
	private:
	RenderFlowThread* m_renderFlowThread;
	RenderFlowThread* m_previousRenderFlowThread;
	};

	// This structure is used by PODIntervalTree for debugging.
	#ifndef NDEBUG
	template <> struct ValueToString<RenderRegion*> {
	static String string(const RenderRegion* value) { return String::format("%p", value); }
	};
	#endif

	} // namespace WebCore

	#endif // RenderFlowThread_h