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android / platform / external / chromium_org / third_party / WebKit / 8abfc58 / . / Source / core / rendering / RenderBlockLineLayout.cpp
blob: 1d0408eed45cf925f959c8dac35128090df9cc11 [file] [log] [blame]
/*
* Copyright (C) 2000 Lars Knoll (knoll@kde.org)
* Copyright (C) 2003, 2004, 2006, 2007, 2008, 2009, 2010, 2011 Apple Inc. All right 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 "core/platform/text/BidiResolver.h"
#include "core/rendering/InlineIterator.h"
#include "core/rendering/InlineTextBox.h"
#include "core/rendering/RenderCombineText.h"
#include "core/rendering/RenderCounter.h"
#include "core/rendering/RenderFlowThread.h"
#include "core/rendering/RenderInline.h"
#include "core/rendering/RenderLayer.h"
#include "core/rendering/RenderListMarker.h"
#include "core/rendering/RenderRegion.h"
#include "core/rendering/RenderRubyRun.h"
#include "core/rendering/RenderView.h"
#include "core/rendering/TrailingFloatsRootInlineBox.h"
#include "core/rendering/VerticalPositionCache.h"
#include "core/rendering/break_lines.h"
#include "core/rendering/shapes/ShapeInsideInfo.h"
#include "core/rendering/svg/RenderSVGInlineText.h"
#include "core/rendering/svg/SVGRootInlineBox.h"
#include "wtf/RefCountedLeakCounter.h"
#include "wtf/StdLibExtras.h"
#include "wtf/Vector.h"
#include "wtf/unicode/CharacterNames.h"
using namespace std;
using namespace WTF;
using namespace Unicode;
namespace WebCore {
// We don't let our line box tree for a single line get any deeper than this.
const unsigned cMaxLineDepth = 200;
struct RenderTextInfo {
// Destruction of m_layout requires TextLayout to be a complete type, so the constructor and destructor are made non-inline to avoid compilation errors.
RenderTextInfo();
~RenderTextInfo();
RenderText* m_text;
OwnPtr<TextLayout> m_layout;
LazyLineBreakIterator m_lineBreakIterator;
const Font* m_font;
};
class LineBreaker {
public:
LineBreaker(RenderBlock* block)
: m_block(block)
{
reset();
}
InlineIterator nextLineBreak(InlineBidiResolver&, LineInfo&, RenderTextInfo&, FloatingObject* lastFloatFromPreviousLine, unsigned consecutiveHyphenatedLines, WordMeasurements&);
bool lineWasHyphenated() { return m_hyphenated; }
const Vector<RenderBox*>& positionedObjects() { return m_positionedObjects; }
EClear clear() { return m_clear; }
private:
void reset();
InlineIterator nextSegmentBreak(InlineBidiResolver&, LineInfo&, RenderTextInfo&, FloatingObject* lastFloatFromPreviousLine, unsigned consecutiveHyphenatedLines, WordMeasurements&);
void skipTrailingWhitespace(InlineIterator&, const LineInfo&);
void skipLeadingWhitespace(InlineBidiResolver&, LineInfo&, FloatingObject* lastFloatFromPreviousLine, LineWidth&);
RenderBlock* m_block;
bool m_hyphenated;
EClear m_clear;
Vector<RenderBox*> m_positionedObjects;
};
static LayoutUnit logicalHeightForLine(const RenderBlock* block, bool isFirstLine, LayoutUnit replacedHeight = 0)
{
if (!block->document().inNoQuirksMode() && replacedHeight)
return replacedHeight;
if (!(block->style(isFirstLine)->lineBoxContain() & LineBoxContainBlock))
return 0;
return max<LayoutUnit>(replacedHeight, block->lineHeight(isFirstLine, block->isHorizontalWritingMode() ? HorizontalLine : VerticalLine, PositionOfInteriorLineBoxes));
}
ShapeInsideInfo* RenderBlock::layoutShapeInsideInfo() const
{
ShapeInsideInfo* shapeInsideInfo = view()->layoutState()->shapeInsideInfo();
if (!shapeInsideInfo && flowThreadContainingBlock() && allowsShapeInsideInfoSharing()) {
// regionAtBlockOffset returns regions like an array first={0,N-1}, second={N,M-1}, ...
LayoutUnit offset = logicalHeight() + logicalHeightForLine(this, false) - LayoutUnit(1);
RenderRegion* region = regionAtBlockOffset(offset);
if (region)
shapeInsideInfo = region->shapeInsideInfo();
}
return shapeInsideInfo;
}
enum IndentTextOrNot { DoNotIndentText, IndentText };
class LineWidth {
public:
LineWidth(RenderBlock* block, bool isFirstLine, IndentTextOrNot shouldIndentText)
: m_block(block)
, m_uncommittedWidth(0)
, m_committedWidth(0)
, m_overhangWidth(0)
, m_left(0)
, m_right(0)
, m_availableWidth(0)
, m_segment(0)
, m_isFirstLine(isFirstLine)
, m_shouldIndentText(shouldIndentText)
{
ASSERT(block);
ShapeInsideInfo* shapeInsideInfo = m_block->layoutShapeInsideInfo();
if (shapeInsideInfo)
m_segment = shapeInsideInfo->currentSegment();
updateAvailableWidth();
}
bool fitsOnLine() const { return currentWidth() <= m_availableWidth; }
bool fitsOnLine(float extra) const { return currentWidth() + extra <= m_availableWidth; }
float currentWidth() const { return m_committedWidth + m_uncommittedWidth; }
// FIXME: We should eventually replace these three functions by ones that work on a higher abstraction.
float uncommittedWidth() const { return m_uncommittedWidth; }
float committedWidth() const { return m_committedWidth; }
float availableWidth() const { return m_availableWidth; }
void updateAvailableWidth(LayoutUnit minimumHeight = 0);
void shrinkAvailableWidthForNewFloatIfNeeded(FloatingObject*);
void addUncommittedWidth(float delta) { m_uncommittedWidth += delta; }
void commit()
{
m_committedWidth += m_uncommittedWidth;
m_uncommittedWidth = 0;
}
void applyOverhang(RenderRubyRun*, RenderObject* startRenderer, RenderObject* endRenderer);
void fitBelowFloats();
bool shouldIndentText() const { return m_shouldIndentText == IndentText; }
private:
void computeAvailableWidthFromLeftAndRight()
{
m_availableWidth = max(0.0f, m_right - m_left) + m_overhangWidth;
}
private:
RenderBlock* m_block;
float m_uncommittedWidth;
float m_committedWidth;
float m_overhangWidth; // The amount by which |m_availableWidth| has been inflated to account for possible contraction due to ruby overhang.
float m_left;
float m_right;
float m_availableWidth;
const LineSegment* m_segment;
bool m_isFirstLine;
IndentTextOrNot m_shouldIndentText;
};
inline void LineWidth::updateAvailableWidth(LayoutUnit replacedHeight)
{
LayoutUnit height = m_block->logicalHeight();
LayoutUnit logicalHeight = logicalHeightForLine(m_block, m_isFirstLine, replacedHeight);
m_left = m_block->logicalLeftOffsetForLine(height, shouldIndentText(), logicalHeight);
m_right = m_block->logicalRightOffsetForLine(height, shouldIndentText(), logicalHeight);
if (m_segment) {
m_left = max<float>(m_segment->logicalLeft, m_left);
m_right = min<float>(m_segment->logicalRight, m_right);
}
computeAvailableWidthFromLeftAndRight();
}
inline void LineWidth::shrinkAvailableWidthForNewFloatIfNeeded(FloatingObject* newFloat)
{
LayoutUnit height = m_block->logicalHeight();
if (height < newFloat->logicalTop(m_block->isHorizontalWritingMode()) || height >= newFloat->logicalBottom(m_block->isHorizontalWritingMode()))
return;
// When floats with shape outside are stacked, the floats are positioned based on the margin box of the float,
// not the shape's contour. Since we computed the width based on the shape contour when we added the float,
// when we add a subsequent float on the same line, we need to undo the shape delta in order to position
// based on the margin box. In order to do this, we need to walk back through the floating object list to find
// the first previous float that is on the same side as our newFloat.
ShapeOutsideInfo* previousShapeOutsideInfo = 0;
const FloatingObjectSet& floatingObjectSet = m_block->m_floatingObjects->set();
FloatingObjectSetIterator it = floatingObjectSet.end();
FloatingObjectSetIterator begin = floatingObjectSet.begin();
while (it != begin) {
--it;
FloatingObject* previousFloat = *it;
if (previousFloat != newFloat && previousFloat->type() == newFloat->type()) {
previousShapeOutsideInfo = previousFloat->renderer()->shapeOutsideInfo();
if (previousShapeOutsideInfo) {
previousShapeOutsideInfo->computeSegmentsForContainingBlockLine(m_block->logicalHeight(), previousFloat->logicalTop(m_block->isHorizontalWritingMode()), logicalHeightForLine(m_block, m_isFirstLine));
}
break;
}
}
ShapeOutsideInfo* shapeOutsideInfo = newFloat->renderer()->shapeOutsideInfo();
if (shapeOutsideInfo)
shapeOutsideInfo->computeSegmentsForContainingBlockLine(m_block->logicalHeight(), newFloat->logicalTop(m_block->isHorizontalWritingMode()), logicalHeightForLine(m_block, m_isFirstLine));
if (newFloat->type() == FloatingObject::FloatLeft) {
float newLeft = newFloat->logicalRight(m_block->isHorizontalWritingMode());
if (previousShapeOutsideInfo)
newLeft -= previousShapeOutsideInfo->rightSegmentMarginBoxDelta();
if (shapeOutsideInfo)
newLeft += shapeOutsideInfo->rightSegmentMarginBoxDelta();
if (shouldIndentText() && m_block->style()->isLeftToRightDirection())
newLeft += floorToInt(m_block->textIndentOffset());
m_left = max<float>(m_left, newLeft);
} else {
float newRight = newFloat->logicalLeft(m_block->isHorizontalWritingMode());
if (previousShapeOutsideInfo)
newRight -= previousShapeOutsideInfo->leftSegmentMarginBoxDelta();
if (shapeOutsideInfo)
newRight += shapeOutsideInfo->leftSegmentMarginBoxDelta();
if (shouldIndentText() && !m_block->style()->isLeftToRightDirection())
newRight -= floorToInt(m_block->textIndentOffset());
m_right = min<float>(m_right, newRight);
}
computeAvailableWidthFromLeftAndRight();
}
void LineWidth::applyOverhang(RenderRubyRun* rubyRun, RenderObject* startRenderer, RenderObject* endRenderer)
{
int startOverhang;
int endOverhang;
rubyRun->getOverhang(m_isFirstLine, startRenderer, endRenderer, startOverhang, endOverhang);
startOverhang = min<int>(startOverhang, m_committedWidth);
m_availableWidth += startOverhang;
endOverhang = max(min<int>(endOverhang, m_availableWidth - currentWidth()), 0);
m_availableWidth += endOverhang;
m_overhangWidth += startOverhang + endOverhang;
}
void LineWidth::fitBelowFloats()
{
ASSERT(!m_committedWidth);
ASSERT(!fitsOnLine());
LayoutUnit floatLogicalBottom;
LayoutUnit lastFloatLogicalBottom = m_block->logicalHeight();
float newLineWidth = m_availableWidth;
float newLineLeft = m_left;
float newLineRight = m_right;
while (true) {
floatLogicalBottom = m_block->nextFloatLogicalBottomBelow(lastFloatLogicalBottom);
if (floatLogicalBottom <= lastFloatLogicalBottom)
break;
newLineLeft = m_block->logicalLeftOffsetForLine(floatLogicalBottom, shouldIndentText());
newLineRight = m_block->logicalRightOffsetForLine(floatLogicalBottom, shouldIndentText());
newLineWidth = max(0.0f, newLineRight - newLineLeft);
lastFloatLogicalBottom = floatLogicalBottom;
if (newLineWidth >= m_uncommittedWidth)
break;
}
if (newLineWidth > m_availableWidth) {
m_block->setLogicalHeight(lastFloatLogicalBottom);
m_availableWidth = newLineWidth + m_overhangWidth;
m_left = newLineLeft;
m_right = newLineRight;
}
}
class LineInfo {
public:
LineInfo()
: m_isFirstLine(true)
, m_isLastLine(false)
, m_isEmpty(true)
, m_previousLineBrokeCleanly(true)
, m_floatPaginationStrut(0)
, m_runsFromLeadingWhitespace(0)
{ }
bool isFirstLine() const { return m_isFirstLine; }
bool isLastLine() const { return m_isLastLine; }
bool isEmpty() const { return m_isEmpty; }
bool previousLineBrokeCleanly() const { return m_previousLineBrokeCleanly; }
LayoutUnit floatPaginationStrut() const { return m_floatPaginationStrut; }
unsigned runsFromLeadingWhitespace() const { return m_runsFromLeadingWhitespace; }
void resetRunsFromLeadingWhitespace() { m_runsFromLeadingWhitespace = 0; }
void incrementRunsFromLeadingWhitespace() { m_runsFromLeadingWhitespace++; }
void setFirstLine(bool firstLine) { m_isFirstLine = firstLine; }
void setLastLine(bool lastLine) { m_isLastLine = lastLine; }
void setEmpty(bool empty, RenderBlock* block = 0, LineWidth* lineWidth = 0)
{
if (m_isEmpty == empty)
return;
m_isEmpty = empty;
if (!empty && block && floatPaginationStrut()) {
block->setLogicalHeight(block->logicalHeight() + floatPaginationStrut());
setFloatPaginationStrut(0);
lineWidth->updateAvailableWidth();
}
}
void setPreviousLineBrokeCleanly(bool previousLineBrokeCleanly) { m_previousLineBrokeCleanly = previousLineBrokeCleanly; }
void setFloatPaginationStrut(LayoutUnit strut) { m_floatPaginationStrut = strut; }
private:
bool m_isFirstLine;
bool m_isLastLine;
bool m_isEmpty;
bool m_previousLineBrokeCleanly;
LayoutUnit m_floatPaginationStrut;
unsigned m_runsFromLeadingWhitespace;
};
static inline LayoutUnit borderPaddingMarginStart(RenderInline* child)
{
return child->marginStart() + child->paddingStart() + child->borderStart();
}
static inline LayoutUnit borderPaddingMarginEnd(RenderInline* child)
{
return child->marginEnd() + child->paddingEnd() + child->borderEnd();
}
static bool shouldAddBorderPaddingMargin(RenderObject* child, bool &checkSide)
{
if (!child || (child->isText() && !toRenderText(child)->textLength()))
return true;
checkSide = false;
return checkSide;
}
static LayoutUnit inlineLogicalWidth(RenderObject* child, bool start = true, bool end = true)
{
unsigned lineDepth = 1;
LayoutUnit extraWidth = 0;
RenderObject* parent = child->parent();
while (parent->isRenderInline() && lineDepth++ < cMaxLineDepth) {
RenderInline* parentAsRenderInline = toRenderInline(parent);
if (!isEmptyInline(parentAsRenderInline)) {
if (start && shouldAddBorderPaddingMargin(child->previousSibling(), start))
extraWidth += borderPaddingMarginStart(parentAsRenderInline);
if (end && shouldAddBorderPaddingMargin(child->nextSibling(), end))
extraWidth += borderPaddingMarginEnd(parentAsRenderInline);
if (!start && !end)
return extraWidth;
}
child = parent;
parent = child->parent();
}
return extraWidth;
}
static RenderObject* firstRenderObjectForDirectionalityDetermination(RenderObject* root, RenderObject* current = 0)
{
RenderObject* next = current;
while (current) {
if (isIsolated(current->style()->unicodeBidi())
&& (current->isRenderInline() || current->isRenderBlock())) {
if (current != root)
current = 0;
else
current = next;
break;
}
current = current->parent();
}
if (!current)
current = root->firstChild();
while (current) {
next = 0;
if (isIteratorTarget(current) && !(current->isText() && toRenderText(current)->isAllCollapsibleWhitespace()))
break;
if (!isIteratorTarget(current) && !isIsolated(current->style()->unicodeBidi()))
next = current->firstChild();
if (!next) {
while (current && current != root) {
next = current->nextSibling();
if (next)
break;
current = current->parent();
}
}
if (!next)
break;
current = next;
}
return current;
}
static TextDirection determinePlaintextDirectionality(RenderObject* root, RenderObject* current = 0, unsigned pos = 0)
{
InlineIterator iter(root, firstRenderObjectForDirectionalityDetermination(root, current), pos);
InlineBidiResolver observer;
observer.setPositionIgnoringNestedIsolates(iter);
observer.setStatus(BidiStatus(root->style()->direction(), isOverride(root->style()->unicodeBidi())));
while (!iter.atEnd()) {
if (observer.inIsolate()) {
iter.increment(&observer, InlineIterator::FastIncrementInlineRenderer);
continue;
}
if (iter.atParagraphSeparator())
break;
if (UChar current = iter.current()) {
Direction charDirection = direction(current);
if (charDirection == LeftToRight)
return LTR;
if (charDirection == RightToLeft || charDirection == RightToLeftArabic)
return RTL;
}
iter.increment(&observer);
}
return LTR;
}
static void checkMidpoints(LineMidpointState& lineMidpointState, InlineIterator& lBreak)
{
// Check to see if our last midpoint is a start point beyond the line break. If so,
// shave it off the list, and shave off a trailing space if the previous end point doesn't
// preserve whitespace.
if (lBreak.m_obj && lineMidpointState.numMidpoints && !(lineMidpointState.numMidpoints % 2)) {
InlineIterator* midpoints = lineMidpointState.midpoints.data();
InlineIterator& endpoint = midpoints[lineMidpointState.numMidpoints - 2];
const InlineIterator& startpoint = midpoints[lineMidpointState.numMidpoints - 1];
InlineIterator currpoint = endpoint;
while (!currpoint.atEnd() && currpoint != startpoint && currpoint != lBreak)
currpoint.increment();
if (currpoint == lBreak) {
// We hit the line break before the start point. Shave off the start point.
lineMidpointState.numMidpoints--;
if (endpoint.m_obj->style()->collapseWhiteSpace() && endpoint.m_obj->isText())
endpoint.m_pos--;
}
}
}
// Don't call this directly. Use one of the descriptive helper functions below.
static void deprecatedAddMidpoint(LineMidpointState& lineMidpointState, const InlineIterator& midpoint)
{
if (lineMidpointState.midpoints.size() <= lineMidpointState.numMidpoints)
lineMidpointState.midpoints.grow(lineMidpointState.numMidpoints + 10);
InlineIterator* midpoints = lineMidpointState.midpoints.data();
midpoints[lineMidpointState.numMidpoints++] = midpoint;
}
static inline void startIgnoringSpaces(LineMidpointState& lineMidpointState, const InlineIterator& midpoint)
{
ASSERT(!(lineMidpointState.numMidpoints % 2));
deprecatedAddMidpoint(lineMidpointState, midpoint);
}
static inline void stopIgnoringSpaces(LineMidpointState& lineMidpointState, const InlineIterator& midpoint)
{
ASSERT(lineMidpointState.numMidpoints % 2);
deprecatedAddMidpoint(lineMidpointState, midpoint);
}
// When ignoring spaces, this needs to be called for objects that need line boxes such as RenderInlines or
// hard line breaks to ensure that they're not ignored.
static inline void ensureLineBoxInsideIgnoredSpaces(LineMidpointState& lineMidpointState, RenderObject* renderer)
{
InlineIterator midpoint(0, renderer, 0);
stopIgnoringSpaces(lineMidpointState, midpoint);
startIgnoringSpaces(lineMidpointState, midpoint);
}
// Adding a pair of midpoints before a character will split it out into a new line box.
static inline void ensureCharacterGetsLineBox(LineMidpointState& lineMidpointState, InlineIterator& textParagraphSeparator)
{
InlineIterator midpoint(0, textParagraphSeparator.m_obj, textParagraphSeparator.m_pos);
startIgnoringSpaces(lineMidpointState, InlineIterator(0, textParagraphSeparator.m_obj, textParagraphSeparator.m_pos - 1));
stopIgnoringSpaces(lineMidpointState, InlineIterator(0, textParagraphSeparator.m_obj, textParagraphSeparator.m_pos));
}
static inline BidiRun* createRun(int start, int end, RenderObject* obj, InlineBidiResolver& resolver)
{
return new BidiRun(start, end, obj, resolver.context(), resolver.dir());
}
void RenderBlock::appendRunsForObject(BidiRunList<BidiRun>& runs, int start, int end, RenderObject* obj, InlineBidiResolver& resolver)
{
if (start > end || shouldSkipCreatingRunsForObject(obj))
return;
LineMidpointState& lineMidpointState = resolver.midpointState();
bool haveNextMidpoint = (lineMidpointState.currentMidpoint < lineMidpointState.numMidpoints);
InlineIterator nextMidpoint;
if (haveNextMidpoint)
nextMidpoint = lineMidpointState.midpoints[lineMidpointState.currentMidpoint];
if (lineMidpointState.betweenMidpoints) {
if (!(haveNextMidpoint && nextMidpoint.m_obj == obj))
return;
// This is a new start point. Stop ignoring objects and
// adjust our start.
lineMidpointState.betweenMidpoints = false;
start = nextMidpoint.m_pos;
lineMidpointState.currentMidpoint++;
if (start < end)
return appendRunsForObject(runs, start, end, obj, resolver);
} else {
if (!haveNextMidpoint || (obj != nextMidpoint.m_obj)) {
runs.addRun(createRun(start, end, obj, resolver));
return;
}
// An end midpoint has been encountered within our object. We
// need to go ahead and append a run with our endpoint.
if (static_cast<int>(nextMidpoint.m_pos + 1) <= end) {
lineMidpointState.betweenMidpoints = true;
lineMidpointState.currentMidpoint++;
if (nextMidpoint.m_pos != UINT_MAX) { // UINT_MAX means stop at the object and don't include any of it.
if (static_cast<int>(nextMidpoint.m_pos + 1) > start)
runs.addRun(createRun(start, nextMidpoint.m_pos + 1, obj, resolver));
return appendRunsForObject(runs, nextMidpoint.m_pos + 1, end, obj, resolver);
}
} else
runs.addRun(createRun(start, end, obj, resolver));
}
}
static inline InlineBox* createInlineBoxForRenderer(RenderObject* obj, bool isRootLineBox, bool isOnlyRun = false)
{
if (isRootLineBox)
return toRenderBlock(obj)->createAndAppendRootInlineBox();
if (obj->isText()) {
InlineTextBox* textBox = toRenderText(obj)->createInlineTextBox();
// We only treat a box as text for a <br> if we are on a line by ourself or in strict mode
// (Note the use of strict mode. In "almost strict" mode, we don't treat the box for <br> as text.)
if (obj->isBR())
textBox->setIsText(isOnlyRun || obj->document().inNoQuirksMode());
return textBox;
}
if (obj->isBox())
return toRenderBox(obj)->createInlineBox();
return toRenderInline(obj)->createAndAppendInlineFlowBox();
}
static inline void dirtyLineBoxesForRenderer(RenderObject* o, bool fullLayout)
{
if (o->isText()) {
RenderText* renderText = toRenderText(o);
renderText->dirtyLineBoxes(fullLayout);
} else
toRenderInline(o)->dirtyLineBoxes(fullLayout);
}
static bool parentIsConstructedOrHaveNext(InlineFlowBox* parentBox)
{
do {
if (parentBox->isConstructed() || parentBox->nextOnLine())
return true;
parentBox = parentBox->parent();
} while (parentBox);
return false;
}
InlineFlowBox* RenderBlock::createLineBoxes(RenderObject* obj, const LineInfo& lineInfo, InlineBox* childBox, bool startNewSegment)
{
// See if we have an unconstructed line box for this object that is also
// the last item on the line.
unsigned lineDepth = 1;
InlineFlowBox* parentBox = 0;
InlineFlowBox* result = 0;
bool hasDefaultLineBoxContain = style()->lineBoxContain() == RenderStyle::initialLineBoxContain();
do {
ASSERT_WITH_SECURITY_IMPLICATION(obj->isRenderInline() || obj == this);
RenderInline* inlineFlow = (obj != this) ? toRenderInline(obj) : 0;
// Get the last box we made for this render object.
parentBox = inlineFlow ? inlineFlow->lastLineBox() : toRenderBlock(obj)->lastLineBox();
// If this box or its ancestor is constructed then it is from a previous line, and we need
// to make a new box for our line. If this box or its ancestor is unconstructed but it has
// something following it on the line, then we know we have to make a new box
// as well. In this situation our inline has actually been split in two on
// the same line (this can happen with very fancy language mixtures).
bool constructedNewBox = false;
bool allowedToConstructNewBox = !hasDefaultLineBoxContain || !inlineFlow || inlineFlow->alwaysCreateLineBoxes();
bool mustCreateBoxesToRoot = startNewSegment && !(parentBox && parentBox->isRootInlineBox());
bool canUseExistingParentBox = parentBox && !parentIsConstructedOrHaveNext(parentBox) && !mustCreateBoxesToRoot;
if (allowedToConstructNewBox && !canUseExistingParentBox) {
// We need to make a new box for this render object. Once
// made, we need to place it at the end of the current line.
InlineBox* newBox = createInlineBoxForRenderer(obj, obj == this);
ASSERT_WITH_SECURITY_IMPLICATION(newBox->isInlineFlowBox());
parentBox = toInlineFlowBox(newBox);
parentBox->setFirstLineStyleBit(lineInfo.isFirstLine());
parentBox->setIsHorizontal(isHorizontalWritingMode());
if (!hasDefaultLineBoxContain)
parentBox->clearDescendantsHaveSameLineHeightAndBaseline();
constructedNewBox = true;
}
if (constructedNewBox || canUseExistingParentBox) {
if (!result)
result = parentBox;
// If we have hit the block itself, then |box| represents the root
// inline box for the line, and it doesn't have to be appended to any parent
// inline.
if (childBox)
parentBox->addToLine(childBox);
if (!constructedNewBox || obj == this)
break;
childBox = parentBox;
}
// If we've exceeded our line depth, then jump straight to the root and skip all the remaining
// intermediate inline flows.
obj = (++lineDepth >= cMaxLineDepth) ? this : obj->parent();
} while (true);
return result;
}
template <typename CharacterType>
static inline bool endsWithASCIISpaces(const CharacterType* characters, unsigned pos, unsigned end)
{
while (isASCIISpace(characters[pos])) {
pos++;
if (pos >= end)
return true;
}
return false;
}
static bool reachedEndOfTextRenderer(const BidiRunList<BidiRun>& bidiRuns)
{
BidiRun* run = bidiRuns.logicallyLastRun();
if (!run)
return true;
unsigned pos = run->stop();
RenderObject* r = run->m_object;
if (!r->isText() || r->isBR())
return false;
RenderText* renderText = toRenderText(r);
unsigned length = renderText->textLength();
if (pos >= length)
return true;
if (renderText->is8Bit())
return endsWithASCIISpaces(renderText->characters8(), pos, length);
return endsWithASCIISpaces(renderText->characters16(), pos, length);
}
RootInlineBox* RenderBlock::constructLine(BidiRunList<BidiRun>& bidiRuns, const LineInfo& lineInfo)
{
ASSERT(bidiRuns.firstRun());
bool rootHasSelectedChildren = false;
InlineFlowBox* parentBox = 0;
int runCount = bidiRuns.runCount() - lineInfo.runsFromLeadingWhitespace();
for (BidiRun* r = bidiRuns.firstRun(); r; r = r->next()) {
// Create a box for our object.
bool isOnlyRun = (runCount == 1);
if (runCount == 2 && !r->m_object->isListMarker())
isOnlyRun = (!style()->isLeftToRightDirection() ? bidiRuns.lastRun() : bidiRuns.firstRun())->m_object->isListMarker();
if (lineInfo.isEmpty())
continue;
InlineBox* box = createInlineBoxForRenderer(r->m_object, false, isOnlyRun);
r->m_box = box;
ASSERT(box);
if (!box)
continue;
if (!rootHasSelectedChildren && box->renderer()->selectionState() != RenderObject::SelectionNone)
rootHasSelectedChildren = true;
// If we have no parent box yet, or if the run is not simply a sibling,
// then we need to construct inline boxes as necessary to properly enclose the
// run's inline box. Segments can only be siblings at the root level, as
// they are positioned separately.
bool runStartsSegment = r->m_startsSegment;
if (!parentBox || parentBox->renderer() != r->m_object->parent() || runStartsSegment)
// Create new inline boxes all the way back to the appropriate insertion point.
parentBox = createLineBoxes(r->m_object->parent(), lineInfo, box, runStartsSegment);
else {
// Append the inline box to this line.
parentBox->addToLine(box);
}
bool visuallyOrdered = r->m_object->style()->rtlOrdering() == VisualOrder;
box->setBidiLevel(r->level());
if (box->isInlineTextBox()) {
InlineTextBox* text = toInlineTextBox(box);
text->setStart(r->m_start);
text->setLen(r->m_stop - r->m_start);
text->setDirOverride(r->dirOverride(visuallyOrdered));
if (r->m_hasHyphen)
text->setHasHyphen(true);
}
}
// We should have a root inline box. It should be unconstructed and
// be the last continuation of our line list.
ASSERT(lastLineBox() && !lastLineBox()->isConstructed());
// Set the m_selectedChildren flag on the root inline box if one of the leaf inline box
// from the bidi runs walk above has a selection state.
if (rootHasSelectedChildren)
lastLineBox()->root()->setHasSelectedChildren(true);
// Set bits on our inline flow boxes that indicate which sides should
// paint borders/margins/padding. This knowledge will ultimately be used when
// we determine the horizontal positions and widths of all the inline boxes on
// the line.
bool isLogicallyLastRunWrapped = bidiRuns.logicallyLastRun()->m_object && bidiRuns.logicallyLastRun()->m_object->isText() ? !reachedEndOfTextRenderer(bidiRuns) : true;
lastLineBox()->determineSpacingForFlowBoxes(lineInfo.isLastLine(), isLogicallyLastRunWrapped, bidiRuns.logicallyLastRun()->m_object);
// Now mark the line boxes as being constructed.
lastLineBox()->setConstructed();
// Return the last line.
return lastRootBox();
}
ETextAlign RenderBlock::textAlignmentForLine(bool endsWithSoftBreak) const
{
ETextAlign alignment = style()->textAlign();
if (!endsWithSoftBreak && alignment == JUSTIFY)
alignment = TASTART;
return alignment;
}
static void updateLogicalWidthForLeftAlignedBlock(bool isLeftToRightDirection, BidiRun* trailingSpaceRun, float& logicalLeft, float& totalLogicalWidth, float availableLogicalWidth)
{
// The direction of the block should determine what happens with wide lines.
// In particular with RTL blocks, wide lines should still spill out to the left.
if (isLeftToRightDirection) {
if (totalLogicalWidth > availableLogicalWidth && trailingSpaceRun)
trailingSpaceRun->m_box->setLogicalWidth(max<float>(0, trailingSpaceRun->m_box->logicalWidth() - totalLogicalWidth + availableLogicalWidth));
return;
}
if (trailingSpaceRun)
trailingSpaceRun->m_box->setLogicalWidth(0);
else if (totalLogicalWidth > availableLogicalWidth)
logicalLeft -= (totalLogicalWidth - availableLogicalWidth);
}
static void updateLogicalWidthForRightAlignedBlock(bool isLeftToRightDirection, BidiRun* trailingSpaceRun, float& logicalLeft, float& totalLogicalWidth, float availableLogicalWidth)
{
// Wide lines spill out of the block based off direction.
// So even if text-align is right, if direction is LTR, wide lines should overflow out of the right
// side of the block.
if (isLeftToRightDirection) {
if (trailingSpaceRun) {
totalLogicalWidth -= trailingSpaceRun->m_box->logicalWidth();
trailingSpaceRun->m_box->setLogicalWidth(0);
}
if (totalLogicalWidth < availableLogicalWidth)
logicalLeft += availableLogicalWidth - totalLogicalWidth;
return;
}
if (totalLogicalWidth > availableLogicalWidth && trailingSpaceRun) {
trailingSpaceRun->m_box->setLogicalWidth(max<float>(0, trailingSpaceRun->m_box->logicalWidth() - totalLogicalWidth + availableLogicalWidth));
totalLogicalWidth -= trailingSpaceRun->m_box->logicalWidth();
} else
logicalLeft += availableLogicalWidth - totalLogicalWidth;
}
static void updateLogicalWidthForCenterAlignedBlock(bool isLeftToRightDirection, BidiRun* trailingSpaceRun, float& logicalLeft, float& totalLogicalWidth, float availableLogicalWidth)
{
float trailingSpaceWidth = 0;
if (trailingSpaceRun) {
totalLogicalWidth -= trailingSpaceRun->m_box->logicalWidth();
trailingSpaceWidth = min(trailingSpaceRun->m_box->logicalWidth(), (availableLogicalWidth - totalLogicalWidth + 1) / 2);
trailingSpaceRun->m_box->setLogicalWidth(max<float>(0, trailingSpaceWidth));
}
if (isLeftToRightDirection)
logicalLeft += max<float>((availableLogicalWidth - totalLogicalWidth) / 2, 0);
else
logicalLeft += totalLogicalWidth > availableLogicalWidth ? (availableLogicalWidth - totalLogicalWidth) : (availableLogicalWidth - totalLogicalWidth) / 2 - trailingSpaceWidth;
}
void RenderBlock::setMarginsForRubyRun(BidiRun* run, RenderRubyRun* renderer, RenderObject* previousObject, const LineInfo& lineInfo)
{
int startOverhang;
int endOverhang;
RenderObject* nextObject = 0;
for (BidiRun* runWithNextObject = run->next(); runWithNextObject; runWithNextObject = runWithNextObject->next()) {
if (!runWithNextObject->m_object->isOutOfFlowPositioned() && !runWithNextObject->m_box->isLineBreak()) {
nextObject = runWithNextObject->m_object;
break;
}
}
renderer->getOverhang(lineInfo.isFirstLine(), renderer->style()->isLeftToRightDirection() ? previousObject : nextObject, renderer->style()->isLeftToRightDirection() ? nextObject : previousObject, startOverhang, endOverhang);
setMarginStartForChild(renderer, -startOverhang);
setMarginEndForChild(renderer, -endOverhang);
}
static inline float measureHyphenWidth(RenderText* renderer, const Font& font)
{
RenderStyle* style = renderer->style();
return font.width(RenderBlock::constructTextRun(renderer, font, style->hyphenString().string(), style));
}
class WordMeasurement {
public:
WordMeasurement()
: renderer(0)
, width(0)
, startOffset(0)
, endOffset(0)
{
}
RenderText* renderer;
float width;
int startOffset;
int endOffset;
HashSet<const SimpleFontData*> fallbackFonts;
};
static inline void setLogicalWidthForTextRun(RootInlineBox* lineBox, BidiRun* run, RenderText* renderer, float xPos, const LineInfo& lineInfo,
GlyphOverflowAndFallbackFontsMap& textBoxDataMap, VerticalPositionCache& verticalPositionCache, WordMeasurements& wordMeasurements)
{
HashSet<const SimpleFontData*> fallbackFonts;
GlyphOverflow glyphOverflow;
const Font& font = renderer->style(lineInfo.isFirstLine())->font();
// Always compute glyph overflow if the block's line-box-contain value is "glyphs".
if (lineBox->fitsToGlyphs()) {
// If we don't stick out of the root line's font box, then don't bother computing our glyph overflow. This optimization
// will keep us from computing glyph bounds in nearly all cases.
bool includeRootLine = lineBox->includesRootLineBoxFontOrLeading();
int baselineShift = lineBox->verticalPositionForBox(run->m_box, verticalPositionCache);
int rootDescent = includeRootLine ? font.fontMetrics().descent() : 0;
int rootAscent = includeRootLine ? font.fontMetrics().ascent() : 0;
int boxAscent = font.fontMetrics().ascent() - baselineShift;
int boxDescent = font.fontMetrics().descent() + baselineShift;
if (boxAscent > rootDescent || boxDescent > rootAscent)
glyphOverflow.computeBounds = true;
}
LayoutUnit hyphenWidth = 0;
if (toInlineTextBox(run->m_box)->hasHyphen()) {
const Font& font = renderer->style(lineInfo.isFirstLine())->font();
hyphenWidth = measureHyphenWidth(renderer, font);
}
float measuredWidth = 0;
bool kerningIsEnabled = font.typesettingFeatures() & Kerning;
#if OS(MACOSX)
// FIXME: Having any font feature settings enabled can lead to selection gaps on
// Chromium-mac. https://bugs.webkit.org/show_bug.cgi?id=113418
bool canUseSimpleFontCodePath = renderer->canUseSimpleFontCodePath() && !font.fontDescription().featureSettings();
#else
bool canUseSimpleFontCodePath = renderer->canUseSimpleFontCodePath();
#endif
// Since we don't cache glyph overflows, we need to re-measure the run if
// the style is linebox-contain: glyph.
if (!lineBox->fitsToGlyphs() && canUseSimpleFontCodePath) {
int lastEndOffset = run->m_start;
for (size_t i = 0, size = wordMeasurements.size(); i < size && lastEndOffset < run->m_stop; ++i) {
const WordMeasurement& wordMeasurement = wordMeasurements[i];
if (wordMeasurement.width <=0 || wordMeasurement.startOffset == wordMeasurement.endOffset)
continue;
if (wordMeasurement.renderer != renderer || wordMeasurement.startOffset != lastEndOffset || wordMeasurement.endOffset > run->m_stop)
continue;
lastEndOffset = wordMeasurement.endOffset;
if (kerningIsEnabled && lastEndOffset == run->m_stop) {
int wordLength = lastEndOffset - wordMeasurement.startOffset;
measuredWidth += renderer->width(wordMeasurement.startOffset, wordLength, xPos, lineInfo.isFirstLine());
if (i > 0 && wordLength == 1 && renderer->characterAt(wordMeasurement.startOffset) == ' ')
measuredWidth += renderer->style()->wordSpacing();
} else
measuredWidth += wordMeasurement.width;
if (!wordMeasurement.fallbackFonts.isEmpty()) {
HashSet<const SimpleFontData*>::const_iterator end = wordMeasurement.fallbackFonts.end();
for (HashSet<const SimpleFontData*>::const_iterator it = wordMeasurement.fallbackFonts.begin(); it != end; ++it)
fallbackFonts.add(*it);
}
}
if (measuredWidth && lastEndOffset != run->m_stop) {
// If we don't have enough cached data, we'll measure the run again.
measuredWidth = 0;
fallbackFonts.clear();
}
}
if (!measuredWidth)
measuredWidth = renderer->width(run->m_start, run->m_stop - run->m_start, xPos, lineInfo.isFirstLine(), &fallbackFonts, &glyphOverflow);
run->m_box->setLogicalWidth(measuredWidth + hyphenWidth);
if (!fallbackFonts.isEmpty()) {
ASSERT(run->m_box->isText());
GlyphOverflowAndFallbackFontsMap::iterator it = textBoxDataMap.add(toInlineTextBox(run->m_box), make_pair(Vector<const SimpleFontData*>(), GlyphOverflow())).iterator;
ASSERT(it->value.first.isEmpty());
copyToVector(fallbackFonts, it->value.first);
run->m_box->parent()->clearDescendantsHaveSameLineHeightAndBaseline();
}
if ((glyphOverflow.top || glyphOverflow.bottom || glyphOverflow.left || glyphOverflow.right)) {
ASSERT(run->m_box->isText());
GlyphOverflowAndFallbackFontsMap::iterator it = textBoxDataMap.add(toInlineTextBox(run->m_box), make_pair(Vector<const SimpleFontData*>(), GlyphOverflow())).iterator;
it->value.second = glyphOverflow;
run->m_box->clearKnownToHaveNoOverflow();
}
}
static inline void computeExpansionForJustifiedText(BidiRun* firstRun, BidiRun* trailingSpaceRun, Vector<unsigned, 16>& expansionOpportunities, unsigned expansionOpportunityCount, float& totalLogicalWidth, float availableLogicalWidth)
{
if (!expansionOpportunityCount || availableLogicalWidth <= totalLogicalWidth)
return;
size_t i = 0;
for (BidiRun* r = firstRun; r; r = r->next()) {
// This method is called once per segment, do not move past the current segment.
if (r->m_startsSegment)
break;
if (!r->m_box || r == trailingSpaceRun)
continue;
if (r->m_object->isText()) {
unsigned opportunitiesInRun = expansionOpportunities[i++];
ASSERT(opportunitiesInRun <= expansionOpportunityCount);
// Only justify text if whitespace is collapsed.
if (r->m_object->style()->collapseWhiteSpace()) {
InlineTextBox* textBox = toInlineTextBox(r->m_box);
int expansion = (availableLogicalWidth - totalLogicalWidth) * opportunitiesInRun / expansionOpportunityCount;
textBox->setExpansion(expansion);
totalLogicalWidth += expansion;
}
expansionOpportunityCount -= opportunitiesInRun;
if (!expansionOpportunityCount)
break;
}
}
}
void RenderBlock::updateLogicalWidthForAlignment(const ETextAlign& textAlign, const RootInlineBox* rootInlineBox, BidiRun* trailingSpaceRun, float& logicalLeft, float& totalLogicalWidth, float& availableLogicalWidth, int expansionOpportunityCount)
{
TextDirection direction;
if (rootInlineBox && rootInlineBox->renderer()->style()->unicodeBidi() == Plaintext)
direction = rootInlineBox->direction();
else
direction = style()->direction();
// Armed with the total width of the line (without justification),
// we now examine our text-align property in order to determine where to position the
// objects horizontally. The total width of the line can be increased if we end up
// justifying text.
switch (textAlign) {
case LEFT:
case WEBKIT_LEFT:
updateLogicalWidthForLeftAlignedBlock(style()->isLeftToRightDirection(), trailingSpaceRun, logicalLeft, totalLogicalWidth, availableLogicalWidth);
break;
case RIGHT:
case WEBKIT_RIGHT:
updateLogicalWidthForRightAlignedBlock(style()->isLeftToRightDirection(), trailingSpaceRun, logicalLeft, totalLogicalWidth, availableLogicalWidth);
break;
case CENTER:
case WEBKIT_CENTER:
updateLogicalWidthForCenterAlignedBlock(style()->isLeftToRightDirection(), trailingSpaceRun, logicalLeft, totalLogicalWidth, availableLogicalWidth);
break;
case JUSTIFY:
adjustInlineDirectionLineBounds(expansionOpportunityCount, logicalLeft, availableLogicalWidth);
if (expansionOpportunityCount) {
if (trailingSpaceRun) {
totalLogicalWidth -= trailingSpaceRun->m_box->logicalWidth();
trailingSpaceRun->m_box->setLogicalWidth(0);
}
break;
}
// Fall through
case TASTART:
if (direction == LTR)
updateLogicalWidthForLeftAlignedBlock(style()->isLeftToRightDirection(), trailingSpaceRun, logicalLeft, totalLogicalWidth, availableLogicalWidth);
else
updateLogicalWidthForRightAlignedBlock(style()->isLeftToRightDirection(), trailingSpaceRun, logicalLeft, totalLogicalWidth, availableLogicalWidth);
break;
case TAEND:
if (direction == LTR)
updateLogicalWidthForRightAlignedBlock(style()->isLeftToRightDirection(), trailingSpaceRun, logicalLeft, totalLogicalWidth, availableLogicalWidth);
else
updateLogicalWidthForLeftAlignedBlock(style()->isLeftToRightDirection(), trailingSpaceRun, logicalLeft, totalLogicalWidth, availableLogicalWidth);
break;
}
}
static IndentTextOrNot requiresIndent(bool isFirstLine, bool isAfterHardLineBreak, RenderStyle* style)
{
if (isFirstLine)
return IndentText;
if (isAfterHardLineBreak && style->textIndentLine() == TextIndentEachLine)
return IndentText;
return DoNotIndentText;
}
static void updateLogicalInlinePositions(RenderBlock* block, float& lineLogicalLeft, float& lineLogicalRight, float& availableLogicalWidth, bool firstLine, IndentTextOrNot shouldIndentText, LayoutUnit boxLogicalHeight)
{
LayoutUnit lineLogicalHeight = logicalHeightForLine(block, firstLine, boxLogicalHeight);
lineLogicalLeft = block->pixelSnappedLogicalLeftOffsetForLine(block->logicalHeight(), shouldIndentText == IndentText, lineLogicalHeight);
lineLogicalRight = block->pixelSnappedLogicalRightOffsetForLine(block->logicalHeight(), shouldIndentText == IndentText, lineLogicalHeight);
availableLogicalWidth = lineLogicalRight - lineLogicalLeft;
}
void RenderBlock::computeInlineDirectionPositionsForLine(RootInlineBox* lineBox, const LineInfo& lineInfo, BidiRun* firstRun, BidiRun* trailingSpaceRun, bool reachedEnd,
GlyphOverflowAndFallbackFontsMap& textBoxDataMap, VerticalPositionCache& verticalPositionCache, WordMeasurements& wordMeasurements)
{
ETextAlign textAlign = textAlignmentForLine(!reachedEnd && !lineBox->endsWithBreak());
// CSS 2.1: "'Text-indent' only affects a line if it is the first formatted line of an element. For example, the first line of an anonymous block
// box is only affected if it is the first child of its parent element."
// CSS3 "text-indent", "each-line" affects the first line of the block container as well as each line after a forced line break,
// but does not affect lines after a soft wrap break.
bool isFirstLine = lineInfo.isFirstLine() && !(isAnonymousBlock() && parent()->firstChild() != this);
bool isAfterHardLineBreak = lineBox->prevRootBox() && lineBox->prevRootBox()->endsWithBreak();
IndentTextOrNot shouldIndentText = requiresIndent(isFirstLine, isAfterHardLineBreak, style());
float lineLogicalLeft;
float lineLogicalRight;
float availableLogicalWidth;
updateLogicalInlinePositions(this, lineLogicalLeft, lineLogicalRight, availableLogicalWidth, isFirstLine, shouldIndentText, 0);
bool needsWordSpacing;
ShapeInsideInfo* shapeInsideInfo = layoutShapeInsideInfo();
if (shapeInsideInfo && shapeInsideInfo->hasSegments()) {
BidiRun* segmentStart = firstRun;
const SegmentList& segments = shapeInsideInfo->segments();
float logicalLeft = max<float>(roundToInt(segments[0].logicalLeft), lineLogicalLeft);
float logicalRight = min<float>(floorToInt(segments[0].logicalRight), lineLogicalRight);
float startLogicalLeft = logicalLeft;
float endLogicalRight = logicalLeft;
float minLogicalLeft = logicalLeft;
float maxLogicalRight = logicalLeft;
lineBox->beginPlacingBoxRangesInInlineDirection(logicalLeft);
for (size_t i = 0; i < segments.size(); i++) {
if (i) {
logicalLeft = max<float>(roundToInt(segments[i].logicalLeft), lineLogicalLeft);
logicalRight = min<float>(floorToInt(segments[i].logicalRight), lineLogicalRight);
}
availableLogicalWidth = logicalRight - logicalLeft;
BidiRun* newSegmentStart = computeInlineDirectionPositionsForSegment(lineBox, lineInfo, textAlign, logicalLeft, availableLogicalWidth, segmentStart, trailingSpaceRun, textBoxDataMap, verticalPositionCache, wordMeasurements);
needsWordSpacing = false;
endLogicalRight = lineBox->placeBoxRangeInInlineDirection(segmentStart->m_box, newSegmentStart ? newSegmentStart->m_box : 0, logicalLeft, minLogicalLeft, maxLogicalRight, needsWordSpacing, textBoxDataMap);
if (!newSegmentStart || !newSegmentStart->next())
break;
ASSERT(newSegmentStart->m_startsSegment);
// Discard the empty segment start marker bidi runs
segmentStart = newSegmentStart->next();
}
lineBox->endPlacingBoxRangesInInlineDirection(startLogicalLeft, endLogicalRight, minLogicalLeft, maxLogicalRight);
return;
}
if (firstRun && firstRun->m_object->isReplaced()) {
RenderBox* renderBox = toRenderBox(firstRun->m_object);
updateLogicalInlinePositions(this, lineLogicalLeft, lineLogicalRight, availableLogicalWidth, isFirstLine, shouldIndentText, renderBox->logicalHeight());
}
computeInlineDirectionPositionsForSegment(lineBox, lineInfo, textAlign, lineLogicalLeft, availableLogicalWidth, firstRun, trailingSpaceRun, textBoxDataMap, verticalPositionCache, wordMeasurements);
// The widths of all runs are now known. We can now place every inline box (and
// compute accurate widths for the inline flow boxes).
needsWordSpacing = false;
lineBox->placeBoxesInInlineDirection(lineLogicalLeft, needsWordSpacing, textBoxDataMap);
}
BidiRun* RenderBlock::computeInlineDirectionPositionsForSegment(RootInlineBox* lineBox, const LineInfo& lineInfo, ETextAlign textAlign, float& logicalLeft,
float& availableLogicalWidth, BidiRun* firstRun, BidiRun* trailingSpaceRun, GlyphOverflowAndFallbackFontsMap& textBoxDataMap, VerticalPositionCache& verticalPositionCache,
WordMeasurements& wordMeasurements)
{
bool needsWordSpacing = false;
float totalLogicalWidth = lineBox->getFlowSpacingLogicalWidth();
unsigned expansionOpportunityCount = 0;
bool isAfterExpansion = true;
Vector<unsigned, 16> expansionOpportunities;
RenderObject* previousObject = 0;
BidiRun* r = firstRun;
for (; r; r = r->next()) {
// Once we have reached the start of the next segment, we have finished
// computing the positions for this segment's contents.
if (r->m_startsSegment)
break;
if (!r->m_box || r->m_object->isOutOfFlowPositioned() || r->m_box->isLineBreak())
continue; // Positioned objects are only participating to figure out their
// correct static x position. They have no effect on the width.
// Similarly, line break boxes have no effect on the width.
if (r->m_object->isText()) {
RenderText* rt = toRenderText(r->m_object);
if (textAlign == JUSTIFY && r != trailingSpaceRun) {
if (!isAfterExpansion)
toInlineTextBox(r->m_box)->setCanHaveLeadingExpansion(true);
unsigned opportunitiesInRun;
if (rt->is8Bit())
opportunitiesInRun = Font::expansionOpportunityCount(rt->characters8() + r->m_start, r->m_stop - r->m_start, r->m_box->direction(), isAfterExpansion);
else
opportunitiesInRun = Font::expansionOpportunityCount(rt->characters16() + r->m_start, r->m_stop - r->m_start, r->m_box->direction(), isAfterExpansion);
expansionOpportunities.append(opportunitiesInRun);
expansionOpportunityCount += opportunitiesInRun;
}
if (int length = rt->textLength()) {
if (!r->m_start && needsWordSpacing && isSpaceOrNewline(rt->characterAt(r->m_start)))
totalLogicalWidth += rt->style(lineInfo.isFirstLine())->font().wordSpacing();
needsWordSpacing = !isSpaceOrNewline(rt->characterAt(r->m_stop - 1)) && r->m_stop == length;
}
setLogicalWidthForTextRun(lineBox, r, rt, totalLogicalWidth, lineInfo, textBoxDataMap, verticalPositionCache, wordMeasurements);
} else {
isAfterExpansion = false;
if (!r->m_object->isRenderInline()) {
RenderBox* renderBox = toRenderBox(r->m_object);
if (renderBox->isRubyRun())
setMarginsForRubyRun(r, toRenderRubyRun(renderBox), previousObject, lineInfo);
r->m_box->setLogicalWidth(logicalWidthForChild(renderBox));
totalLogicalWidth += marginStartForChild(renderBox) + marginEndForChild(renderBox);
}
}
totalLogicalWidth += r->m_box->logicalWidth();
previousObject = r->m_object;
}
if (isAfterExpansion && !expansionOpportunities.isEmpty()) {
expansionOpportunities.last()--;
expansionOpportunityCount--;
}
updateLogicalWidthForAlignment(textAlign, lineBox, trailingSpaceRun, logicalLeft, totalLogicalWidth, availableLogicalWidth, expansionOpportunityCount);
computeExpansionForJustifiedText(firstRun, trailingSpaceRun, expansionOpportunities, expansionOpportunityCount, totalLogicalWidth, availableLogicalWidth);
return r;
}
void RenderBlock::computeBlockDirectionPositionsForLine(RootInlineBox* lineBox, BidiRun* firstRun, GlyphOverflowAndFallbackFontsMap& textBoxDataMap,
VerticalPositionCache& verticalPositionCache)
{
setLogicalHeight(lineBox->alignBoxesInBlockDirection(logicalHeight(), textBoxDataMap, verticalPositionCache));
// Now make sure we place replaced render objects correctly.
for (BidiRun* r = firstRun; r; r = r->next()) {
ASSERT(r->m_box);
if (!r->m_box)
continue; // Skip runs with no line boxes.
// Align positioned boxes with the top of the line box. This is
// a reasonable approximation of an appropriate y position.
if (r->m_object->isOutOfFlowPositioned())
r->m_box->setLogicalTop(logicalHeight());
// Position is used to properly position both replaced elements and
// to update the static normal flow x/y of positioned elements.
if (r->m_object->isText())
toRenderText(r->m_object)->positionLineBox(r->m_box);
else if (r->m_object->isBox())
toRenderBox(r->m_object)->positionLineBox(r->m_box);
}
// Positioned objects and zero-length text nodes destroy their boxes in
// position(), which unnecessarily dirties the line.
lineBox->markDirty(false);
}
static inline bool isCollapsibleSpace(UChar character, RenderText* renderer)
{
if (character == ' ' || character == '\t' || character == softHyphen)
return true;
if (character == '\n')
return !renderer->style()->preserveNewline();
return false;
}
static void setStaticPositions(RenderBlock* block, RenderBox* child)
{
// FIXME: The math here is actually not really right. It's a best-guess approximation that
// will work for the common cases
RenderObject* containerBlock = child->container();
LayoutUnit blockHeight = block->logicalHeight();
if (containerBlock->isRenderInline()) {
// A relative positioned inline encloses us. In this case, we also have to determine our
// position as though we were an inline. Set |staticInlinePosition| and |staticBlockPosition| on the relative positioned
// inline so that we can obtain the value later.
toRenderInline(containerBlock)->layer()->setStaticInlinePosition(block->startAlignedOffsetForLine(blockHeight, false));
toRenderInline(containerBlock)->layer()->setStaticBlockPosition(blockHeight);
}
block->updateStaticInlinePositionForChild(child, blockHeight);
child->layer()->setStaticBlockPosition(blockHeight);
}
template <typename CharacterType>
static inline int findFirstTrailingSpace(RenderText* lastText, const CharacterType* characters, int start, int stop)
{
int firstSpace = stop;
while (firstSpace > start) {
UChar current = characters[firstSpace - 1];
if (!isCollapsibleSpace(current, lastText))
break;
firstSpace--;
}
return firstSpace;
}
inline BidiRun* RenderBlock::handleTrailingSpaces(BidiRunList<BidiRun>& bidiRuns, BidiContext* currentContext)
{
if (!bidiRuns.runCount()
|| !bidiRuns.logicallyLastRun()->m_object->style()->breakOnlyAfterWhiteSpace()
|| !bidiRuns.logicallyLastRun()->m_object->style()->autoWrap())
return 0;
BidiRun* trailingSpaceRun = bidiRuns.logicallyLastRun();
RenderObject* lastObject = trailingSpaceRun->m_object;
if (!lastObject->isText())
return 0;
RenderText* lastText = toRenderText(lastObject);
int firstSpace;
if (lastText->is8Bit())
firstSpace = findFirstTrailingSpace(lastText, lastText->characters8(), trailingSpaceRun->start(), trailingSpaceRun->stop());
else
firstSpace = findFirstTrailingSpace(lastText, lastText->characters16(), trailingSpaceRun->start(), trailingSpaceRun->stop());
if (firstSpace == trailingSpaceRun->stop())
return 0;
TextDirection direction = style()->direction();
bool shouldReorder = trailingSpaceRun != (direction == LTR ? bidiRuns.lastRun() : bidiRuns.firstRun());
if (firstSpace != trailingSpaceRun->start()) {
BidiContext* baseContext = currentContext;
while (BidiContext* parent = baseContext->parent())
baseContext = parent;
BidiRun* newTrailingRun = new BidiRun(firstSpace, trailingSpaceRun->m_stop, trailingSpaceRun->m_object, baseContext, OtherNeutral);
trailingSpaceRun->m_stop = firstSpace;
if (direction == LTR)
bidiRuns.addRun(newTrailingRun);
else
bidiRuns.prependRun(newTrailingRun);
trailingSpaceRun = newTrailingRun;
return trailingSpaceRun;
}
if (!shouldReorder)
return trailingSpaceRun;
if (direction == LTR) {
bidiRuns.moveRunToEnd(trailingSpaceRun);
trailingSpaceRun->m_level = 0;
} else {
bidiRuns.moveRunToBeginning(trailingSpaceRun);
trailingSpaceRun->m_level = 1;
}
return trailingSpaceRun;
}
void RenderBlock::appendFloatingObjectToLastLine(FloatingObject* floatingObject)
{
ASSERT(!floatingObject->originatingLine());
floatingObject->setOriginatingLine(lastRootBox());
lastRootBox()->appendFloat(floatingObject->renderer());
}
// FIXME: This should be a BidiStatus constructor or create method.
static inline BidiStatus statusWithDirection(TextDirection textDirection, bool isOverride)
{
WTF::Unicode::Direction direction = textDirection == LTR ? LeftToRight : RightToLeft;
RefPtr<BidiContext> context = BidiContext::create(textDirection == LTR ? 0 : 1, direction, isOverride, FromStyleOrDOM);
// This copies BidiStatus and may churn the ref on BidiContext. I doubt it matters.
return BidiStatus(direction, direction, direction, context.release());
}
static inline void setupResolverToResumeInIsolate(InlineBidiResolver& resolver, RenderObject* root, RenderObject* startObject)
{
if (root != startObject) {
RenderObject* parent = startObject->parent();
setupResolverToResumeInIsolate(resolver, root, parent);
notifyObserverEnteredObject(&resolver, startObject);
}
}
// FIXME: BidiResolver should have this logic.
static inline void constructBidiRunsForSegment(InlineBidiResolver& topResolver, BidiRunList<BidiRun>& bidiRuns, const InlineIterator& endOfRuns, VisualDirectionOverride override, bool previousLineBrokeCleanly)
{
// FIXME: We should pass a BidiRunList into createBidiRunsForLine instead
// of the resolver owning the runs.
ASSERT(&topResolver.runs() == &bidiRuns);
ASSERT(topResolver.position() != endOfRuns);
RenderObject* currentRoot = topResolver.position().root();
topResolver.createBidiRunsForLine(endOfRuns, override, previousLineBrokeCleanly);
while (!topResolver.isolatedRuns().isEmpty()) {
// It does not matter which order we resolve the runs as long as we resolve them all.
BidiRun* isolatedRun = topResolver.isolatedRuns().last();
topResolver.isolatedRuns().removeLast();
RenderObject* startObj = isolatedRun->object();
// Only inlines make sense with unicode-bidi: isolate (blocks are already isolated).
// FIXME: Because enterIsolate is not passed a RenderObject, we have to crawl up the
// tree to see which parent inline is the isolate. We could change enterIsolate
// to take a RenderObject and do this logic there, but that would be a layering
// violation for BidiResolver (which knows nothing about RenderObject).
RenderInline* isolatedInline = toRenderInline(highestContainingIsolateWithinRoot(startObj, currentRoot));
ASSERT(isolatedInline);
InlineBidiResolver isolatedResolver;
EUnicodeBidi unicodeBidi = isolatedInline->style()->unicodeBidi();
TextDirection direction = isolatedInline->style()->direction();
if (unicodeBidi == Plaintext)
direction = determinePlaintextDirectionality(isolatedInline, startObj);
else {
ASSERT(unicodeBidi == Isolate || unicodeBidi == IsolateOverride);
direction = isolatedInline->style()->direction();
}
isolatedResolver.setStatus(statusWithDirection(direction, isOverride(unicodeBidi)));
setupResolverToResumeInIsolate(isolatedResolver, isolatedInline, startObj);
// The starting position is the beginning of the first run within the isolate that was identified
// during the earlier call to createBidiRunsForLine. This can be but is not necessarily the
// first run within the isolate.
InlineIterator iter = InlineIterator(isolatedInline, startObj, isolatedRun->m_start);
isolatedResolver.setPositionIgnoringNestedIsolates(iter);
// We stop at the next end of line; we may re-enter this isolate in the next call to constructBidiRuns().
// FIXME: What should end and previousLineBrokeCleanly be?
// rniwa says previousLineBrokeCleanly is just a WinIE hack and could always be false here?
isolatedResolver.createBidiRunsForLine(endOfRuns, NoVisualOverride, previousLineBrokeCleanly);
// Note that we do not delete the runs from the resolver.
// We're not guaranteed to get any BidiRuns in the previous step. If we don't, we allow the placeholder
// itself to be turned into an InlineBox. We can't remove it here without potentially losing track of
// the logically last run.
if (isolatedResolver.runs().runCount())
bidiRuns.replaceRunWithRuns(isolatedRun, isolatedResolver.runs());
// If we encountered any nested isolate runs, just move them
// to the top resolver's list for later processing.
if (!isolatedResolver.isolatedRuns().isEmpty()) {
topResolver.isolatedRuns().append(isolatedResolver.isolatedRuns());
isolatedResolver.isolatedRuns().clear();
currentRoot = isolatedInline;
}
}
}
static inline bool segmentIsEmpty(const InlineIterator& segmentStart, const InlineIterator& segmentEnd)
{
return segmentStart == segmentEnd;
}
static inline void constructBidiRunsForLine(const RenderBlock* block, InlineBidiResolver& topResolver, BidiRunList<BidiRun>& bidiRuns, const InlineIterator& endOfLine, VisualDirectionOverride override, bool previousLineBrokeCleanly)
{
ShapeInsideInfo* shapeInsideInfo = block->layoutShapeInsideInfo();
if (!shapeInsideInfo || !shapeInsideInfo->hasSegments()) {
constructBidiRunsForSegment(topResolver, bidiRuns, endOfLine, override, previousLineBrokeCleanly);
return;
}
const SegmentRangeList& segmentRanges = shapeInsideInfo->segmentRanges();
ASSERT(segmentRanges.size());
for (size_t i = 0; i < segmentRanges.size(); i++) {
LineSegmentIterator iterator = segmentRanges[i].start;
InlineIterator segmentStart(iterator.root, iterator.object, iterator.offset);
iterator = segmentRanges[i].end;
InlineIterator segmentEnd(iterator.root, iterator.object, iterator.offset);
if (i) {
ASSERT(segmentStart.m_obj);
BidiRun* segmentMarker = createRun(segmentStart.m_pos, segmentStart.m_pos, segmentStart.m_obj, topResolver);
segmentMarker->m_startsSegment = true;
bidiRuns.addRun(segmentMarker);
// Do not collapse midpoints between segments
topResolver.midpointState().betweenMidpoints = false;
}
if (!segmentIsEmpty(segmentStart, segmentEnd)) {
topResolver.setPosition(segmentStart, numberOfIsolateAncestors(segmentStart));
constructBidiRunsForSegment(topResolver, bidiRuns, segmentEnd, override, previousLineBrokeCleanly);
}
}
}
// This function constructs line boxes for all of the text runs in the resolver and computes their position.
RootInlineBox* RenderBlock::createLineBoxesFromBidiRuns(unsigned bidiLevel, BidiRunList<BidiRun>& bidiRuns, const InlineIterator& end, LineInfo& lineInfo, VerticalPositionCache& verticalPositionCache, BidiRun* trailingSpaceRun, WordMeasurements& wordMeasurements)
{
if (!bidiRuns.runCount())
return 0;
// FIXME: Why is this only done when we had runs?
lineInfo.setLastLine(!end.m_obj);
RootInlineBox* lineBox = constructLine(bidiRuns, lineInfo);
if (!lineBox)
return 0;
lineBox->setBidiLevel(bidiLevel);
lineBox->setEndsWithBreak(lineInfo.previousLineBrokeCleanly());
bool isSVGRootInlineBox = lineBox->isSVGRootInlineBox();
GlyphOverflowAndFallbackFontsMap textBoxDataMap;
// Now we position all of our text runs horizontally.
if (!isSVGRootInlineBox)
computeInlineDirectionPositionsForLine(lineBox, lineInfo, bidiRuns.firstRun(), trailingSpaceRun, end.atEnd(), textBoxDataMap, verticalPositionCache, wordMeasurements);
// Now position our text runs vertically.
computeBlockDirectionPositionsForLine(lineBox, bidiRuns.firstRun(), textBoxDataMap, verticalPositionCache);
// SVG text layout code computes vertical & horizontal positions on its own.
// Note that we still need to execute computeVerticalPositionsForLine() as
// it calls InlineTextBox::positionLineBox(), which tracks whether the box
// contains reversed text or not. If we wouldn't do that editing and thus
// text selection in RTL boxes would not work as expected.
if (isSVGRootInlineBox) {
ASSERT(isSVGText());
static_cast<SVGRootInlineBox*>(lineBox)->computePerCharacterLayoutInformation();
}
// Compute our overflow now.
lineBox->computeOverflow(lineBox->lineTop(), lineBox->lineBottom(), textBoxDataMap);
return lineBox;
}
// Like LayoutState for layout(), LineLayoutState keeps track of global information
// during an entire linebox tree layout pass (aka layoutInlineChildren).
class LineLayoutState {
public:
LineLayoutState(bool fullLayout, LayoutUnit& repaintLogicalTop, LayoutUnit& repaintLogicalBottom, RenderFlowThread* flowThread)
: m_lastFloat(0)
, m_endLine(0)
, m_floatIndex(0)
, m_endLineLogicalTop(0)
, m_endLineMatched(false)
, m_checkForFloatsFromLastLine(false)
, m_isFullLayout(fullLayout)
, m_repaintLogicalTop(repaintLogicalTop)
, m_repaintLogicalBottom(repaintLogicalBottom)
, m_adjustedLogicalLineTop(0)
, m_usesRepaintBounds(false)
, m_flowThread(flowThread)
{ }
void markForFullLayout() { m_isFullLayout = true; }
bool isFullLayout() const { return m_isFullLayout; }
bool usesRepaintBounds() const { return m_usesRepaintBounds; }
void setRepaintRange(LayoutUnit logicalHeight)
{
m_usesRepaintBounds = true;
m_repaintLogicalTop = m_repaintLogicalBottom = logicalHeight;
}
void updateRepaintRangeFromBox(RootInlineBox* box, LayoutUnit paginationDelta = 0)
{
m_usesRepaintBounds = true;
m_repaintLogicalTop = min(m_repaintLogicalTop, box->logicalTopVisualOverflow() + min<LayoutUnit>(paginationDelta, 0));
m_repaintLogicalBottom = max(m_repaintLogicalBottom, box->logicalBottomVisualOverflow() + max<LayoutUnit>(paginationDelta, 0));
}
bool endLineMatched() const { return m_endLineMatched; }
void setEndLineMatched(bool endLineMatched) { m_endLineMatched = endLineMatched; }
bool checkForFloatsFromLastLine() const { return m_checkForFloatsFromLastLine; }
void setCheckForFloatsFromLastLine(bool check) { m_checkForFloatsFromLastLine = check; }
LineInfo& lineInfo() { return m_lineInfo; }
const LineInfo& lineInfo() const { return m_lineInfo; }
LayoutUnit endLineLogicalTop() const { return m_endLineLogicalTop; }
void setEndLineLogicalTop(LayoutUnit logicalTop) { m_endLineLogicalTop = logicalTop; }
RootInlineBox* endLine() const { return m_endLine; }
void setEndLine(RootInlineBox* line) { m_endLine = line; }
FloatingObject* lastFloat() const { return m_lastFloat; }
void setLastFloat(FloatingObject* lastFloat) { m_lastFloat = lastFloat; }
Vector<RenderBlock::FloatWithRect>& floats() { return m_floats; }
unsigned floatIndex() const { return m_floatIndex; }
void setFloatIndex(unsigned floatIndex) { m_floatIndex = floatIndex; }
LayoutUnit adjustedLogicalLineTop() const { return m_adjustedLogicalLineTop; }
void setAdjustedLogicalLineTop(LayoutUnit value) { m_adjustedLogicalLineTop = value; }
RenderFlowThread* flowThread() const { return m_flowThread; }
void setFlowThread(RenderFlowThread* thread) { m_flowThread = thread; }
private:
Vector<RenderBlock::FloatWithRect> m_floats;
FloatingObject* m_lastFloat;
RootInlineBox* m_endLine;
LineInfo m_lineInfo;
unsigned m_floatIndex;
LayoutUnit m_endLineLogicalTop;
bool m_endLineMatched;
bool m_checkForFloatsFromLastLine;
bool m_isFullLayout;
// FIXME: Should this be a range object instead of two ints?
LayoutUnit& m_repaintLogicalTop;
LayoutUnit& m_repaintLogicalBottom;
LayoutUnit m_adjustedLogicalLineTop;
bool m_usesRepaintBounds;
RenderFlowThread* m_flowThread;
};
static void deleteLineRange(LineLayoutState& layoutState, RootInlineBox* startLine, RootInlineBox* stopLine = 0)
{
RootInlineBox* boxToDelete = startLine;
while (boxToDelete && boxToDelete != stopLine) {
layoutState.updateRepaintRangeFromBox(boxToDelete);
// Note: deleteLineRange(firstRootBox()) is not identical to deleteLineBoxTree().
// deleteLineBoxTree uses nextLineBox() instead of nextRootBox() when traversing.
RootInlineBox* next = boxToDelete->nextRootBox();
boxToDelete->deleteLine();
boxToDelete = next;
}
}
void RenderBlock::layoutRunsAndFloats(LineLayoutState& layoutState, bool hasInlineChild)
{
// We want to skip ahead to the first dirty line
InlineBidiResolver resolver;
RootInlineBox* startLine = determineStartPosition(layoutState, resolver);
unsigned consecutiveHyphenatedLines = 0;
if (startLine) {
for (RootInlineBox* line = startLine->prevRootBox(); line && line->isHyphenated(); line = line->prevRootBox())
consecutiveHyphenatedLines++;
}
// FIXME: This would make more sense outside of this function, but since
// determineStartPosition can change the fullLayout flag we have to do this here. Failure to call
// determineStartPosition first will break fast/repaint/line-flow-with-floats-9.html.
if (layoutState.isFullLayout() && hasInlineChild && !selfNeedsLayout()) {
setNeedsLayout(MarkOnlyThis); // Mark as needing a full layout to force us to repaint.
RenderView* v = view();
if (v && !v->doingFullRepaint() && hasLayer()) {
// Because we waited until we were already inside layout to discover
// that the block really needed a full layout, we missed our chance to repaint the layer
// before layout started. Luckily the layer has cached the repaint rect for its original
// position and size, and so we can use that to make a repaint happen now.
repaintUsingContainer(containerForRepaint(), pixelSnappedIntRect(layer()->repaintRect()));
}
}
if (containsFloats())
layoutState.setLastFloat(m_floatingObjects->set().last());
// We also find the first clean line and extract these lines. We will add them back
// if we determine that we're able to synchronize after handling all our dirty lines.
InlineIterator cleanLineStart;
BidiStatus cleanLineBidiStatus;
if (!layoutState.isFullLayout() && startLine)
determineEndPosition(layoutState, startLine, cleanLineStart, cleanLineBidiStatus);
if (startLine) {
if (!layoutState.usesRepaintBounds())
layoutState.setRepaintRange(logicalHeight());
deleteLineRange(layoutState, startLine);
}
if (!layoutState.isFullLayout() && lastRootBox() && lastRootBox()->endsWithBreak()) {
// If the last line before the start line ends with a line break that clear floats,
// adjust the height accordingly.
// A line break can be either the first or the last object on a line, depending on its direction.
if (InlineBox* lastLeafChild = lastRootBox()->lastLeafChild()) {
RenderObject* lastObject = lastLeafChild->renderer();
if (!lastObject->isBR())
lastObject = lastRootBox()->firstLeafChild()->renderer();
if (lastObject->isBR()) {
EClear clear = lastObject->style()->clear();
if (clear != CNONE)
newLine(clear);
}
}
}
layoutRunsAndFloatsInRange(layoutState, resolver, cleanLineStart, cleanLineBidiStatus, consecutiveHyphenatedLines);
linkToEndLineIfNeeded(layoutState);
repaintDirtyFloats(layoutState.floats());
}
RenderTextInfo::RenderTextInfo()
: m_text(0)
, m_font(0)
{
}
RenderTextInfo::~RenderTextInfo()
{
}
// Before restarting the layout loop with a new logicalHeight, remove all floats that were added and reset the resolver.
inline const InlineIterator& RenderBlock::restartLayoutRunsAndFloatsInRange(LayoutUnit oldLogicalHeight, LayoutUnit newLogicalHeight, FloatingObject* lastFloatFromPreviousLine, InlineBidiResolver& resolver, const InlineIterator& oldEnd)
{
removeFloatingObjectsBelow(lastFloatFromPreviousLine, oldLogicalHeight);
setLogicalHeight(newLogicalHeight);
resolver.setPositionIgnoringNestedIsolates(oldEnd);
return oldEnd;
}
static inline float firstPositiveWidth(const WordMeasurements& wordMeasurements)
{
for (size_t i = 0; i < wordMeasurements.size(); ++i) {
if (wordMeasurements[i].width > 0)
return wordMeasurements[i].width;
}
return 0;
}
static inline LayoutUnit adjustLogicalLineTop(ShapeInsideInfo* shapeInsideInfo, InlineIterator start, InlineIterator end, const WordMeasurements& wordMeasurements)
{
if (!shapeInsideInfo || end != start)
return 0;
float minWidth = firstPositiveWidth(wordMeasurements);
ASSERT(minWidth || wordMeasurements.isEmpty());
if (minWidth > 0 && shapeInsideInfo->adjustLogicalLineTop(minWidth))
return shapeInsideInfo->logicalLineTop();
return shapeInsideInfo->shapeLogicalBottom();
}
static inline void pushShapeContentOverflowBelowTheContentBox(RenderBlock* block, ShapeInsideInfo* shapeInsideInfo, LayoutUnit lineTop, LayoutUnit lineHeight)
{
ASSERT(shapeInsideInfo);
LayoutUnit logicalLineBottom = lineTop + lineHeight;
LayoutUnit shapeLogicalBottom = shapeInsideInfo->shapeLogicalBottom();
LayoutUnit shapeContainingBlockHeight = shapeInsideInfo->shapeContainingBlockHeight();
bool isOverflowPositionedAlready = (shapeContainingBlockHeight - shapeInsideInfo->owner()->borderAndPaddingAfter() + lineHeight) <= lineTop;
// If the last line overlaps with the shape, we don't need the segments anymore
if (lineTop < shapeLogicalBottom && shapeLogicalBottom < logicalLineBottom)
shapeInsideInfo->clearSegments();
if (logicalLineBottom <= shapeLogicalBottom || !shapeContainingBlockHeight || isOverflowPositionedAlready)
return;
LayoutUnit newLogicalHeight = block->logicalHeight() + (shapeContainingBlockHeight - (lineTop + shapeInsideInfo->owner()->borderAndPaddingAfter()));
block->setLogicalHeight(newLogicalHeight);
}
void RenderBlock::updateShapeAndSegmentsForCurrentLine(ShapeInsideInfo*& shapeInsideInfo, LayoutUnit& absoluteLogicalTop, LineLayoutState& layoutState)
{
if (layoutState.flowThread())
return updateShapeAndSegmentsForCurrentLineInFlowThread(shapeInsideInfo, layoutState);
if (!shapeInsideInfo)
return;
LayoutUnit lineTop = logicalHeight() + absoluteLogicalTop;
LayoutUnit lineHeight = this->lineHeight(layoutState.lineInfo().isFirstLine(), isHorizontalWritingMode() ? HorizontalLine : VerticalLine, PositionOfInteriorLineBoxes);
// FIXME: Bug 95361: It is possible for a line to grow beyond lineHeight, in which case these segments may be incorrect.
shapeInsideInfo->computeSegmentsForLine(lineTop, lineHeight);
pushShapeContentOverflowBelowTheContentBox(this, shapeInsideInfo, lineTop, lineHeight);
}
void RenderBlock::updateShapeAndSegmentsForCurrentLineInFlowThread(ShapeInsideInfo*& shapeInsideInfo, LineLayoutState& layoutState)
{
ASSERT(layoutState.flowThread());
LayoutUnit lineHeight = this->lineHeight(layoutState.lineInfo().isFirstLine(), isHorizontalWritingMode() ? HorizontalLine : VerticalLine, PositionOfInteriorLineBoxes);
RenderRegion* currentRegion = regionAtBlockOffset(logicalHeight());
if (!currentRegion)
return;
shapeInsideInfo = currentRegion->shapeInsideInfo();
LayoutUnit logicalLineTopInFlowThread = logicalHeight() + offsetFromLogicalTopOfFirstPage();
LayoutUnit logicalLineBottomInFlowThread = logicalLineTopInFlowThread + lineHeight;
LayoutUnit logicalRegionTopInFlowThread = currentRegion->logicalTopForFlowThreadContent();
LayoutUnit logicalRegionBottomInFlowThread = logicalRegionTopInFlowThread + currentRegion->logicalHeight() - currentRegion->borderAndPaddingBefore() - currentRegion->borderAndPaddingAfter();
// We only want to deal regions with shapes, so we look up for the next region whether it has a shape
if (!shapeInsideInfo && !currentRegion->isLastRegion()) {
LayoutUnit deltaToNextRegion = logicalHeight() + logicalRegionBottomInFlowThread - logicalLineTopInFlowThread;
RenderRegion* lookupForNextRegion = regionAtBlockOffset(logicalHeight() + deltaToNextRegion);
if (!lookupForNextRegion->shapeInsideInfo())
return;
}
LayoutUnit shapeBottomInFlowThread = LayoutUnit::max();
if (shapeInsideInfo)
shapeBottomInFlowThread = shapeInsideInfo->shapeLogicalBottom() + currentRegion->logicalTopForFlowThreadContent();
// If the line is between two shapes/regions we position the line to the top of the next shape/region
RenderRegion* nextRegion = regionAtBlockOffset(logicalHeight() + lineHeight);
if ((currentRegion != nextRegion && (logicalLineBottomInFlowThread > logicalRegionBottomInFlowThread)) || (!currentRegion->isLastRegion() && shapeBottomInFlowThread < logicalLineBottomInFlowThread)) {
LayoutUnit deltaToNextRegion = logicalRegionBottomInFlowThread - logicalLineTopInFlowThread;
nextRegion = regionAtBlockOffset(logicalHeight() + deltaToNextRegion);
ASSERT(currentRegion != nextRegion);
shapeInsideInfo = nextRegion->shapeInsideInfo();
setLogicalHeight(logicalHeight() + deltaToNextRegion);
currentRegion = nextRegion;
logicalLineTopInFlowThread = logicalHeight() + offsetFromLogicalTopOfFirstPage();
logicalLineBottomInFlowThread = logicalLineTopInFlowThread + lineHeight;
logicalRegionTopInFlowThread = currentRegion->logicalTopForFlowThreadContent();
logicalRegionBottomInFlowThread = logicalRegionTopInFlowThread + currentRegion->logicalHeight() - currentRegion->borderAndPaddingBefore() - currentRegion->borderAndPaddingAfter();
}
if (!shapeInsideInfo)
return;
// We position the first line to the top of the shape in the region or to the previously adjusted position in the shape
if (logicalLineBottomInFlowThread <= (logicalRegionTopInFlowThread + lineHeight) || (logicalLineTopInFlowThread - logicalRegionTopInFlowThread) < (layoutState.adjustedLogicalLineTop() - currentRegion->borderAndPaddingBefore())) {
LayoutUnit shapeTopOffset = layoutState.adjustedLogicalLineTop();
if (!shapeTopOffset)
shapeTopOffset = shapeInsideInfo->shapeLogicalTop();
LayoutUnit shapePositionInFlowThread = currentRegion->logicalTopForFlowThreadContent() + shapeTopOffset;
LayoutUnit shapeTopLineTopDelta = shapePositionInFlowThread - logicalLineTopInFlowThread - currentRegion->borderAndPaddingBefore();
setLogicalHeight(logicalHeight() + shapeTopLineTopDelta);
logicalLineTopInFlowThread += shapeTopLineTopDelta;
layoutState.setAdjustedLogicalLineTop(0);
}
LayoutUnit lineTop = logicalLineTopInFlowThread - currentRegion->logicalTopForFlowThreadContent() + currentRegion->borderAndPaddingBefore();
shapeInsideInfo->computeSegmentsForLine(lineTop, lineHeight);
if (currentRegion->isLastRegion())
pushShapeContentOverflowBelowTheContentBox(this, shapeInsideInfo, lineTop, lineHeight);
}
bool RenderBlock::adjustLogicalLineTopAndLogicalHeightIfNeeded(ShapeInsideInfo* shapeInsideInfo, LayoutUnit absoluteLogicalTop, LineLayoutState& layoutState, InlineBidiResolver& resolver, FloatingObject* lastFloatFromPreviousLine, InlineIterator& end, WordMeasurements& wordMeasurements)
{
LayoutUnit adjustedLogicalLineTop = adjustLogicalLineTop(shapeInsideInfo, resolver.position(), end, wordMeasurements);
if (!adjustedLogicalLineTop)
return false;
LayoutUnit newLogicalHeight = adjustedLogicalLineTop - absoluteLogicalTop;
if (layoutState.flowThread()) {
layoutState.setAdjustedLogicalLineTop(adjustedLogicalLineTop);
newLogicalHeight = logicalHeight();
}
end = restartLayoutRunsAndFloatsInRange(logicalHeight(), newLogicalHeight, lastFloatFromPreviousLine, resolver, end);
return true;
}
void RenderBlock::layoutRunsAndFloatsInRange(LineLayoutState& layoutState, InlineBidiResolver& resolver, const InlineIterator& cleanLineStart, const BidiStatus& cleanLineBidiStatus, unsigned consecutiveHyphenatedLines)
{
RenderStyle* styleToUse = style();
bool paginated = view()->layoutState() && view()->layoutState()->isPaginated();
LineMidpointState& lineMidpointState = resolver.midpointState();
InlineIterator end = resolver.position();
bool checkForEndLineMatch = layoutState.endLine();
RenderTextInfo renderTextInfo;
VerticalPositionCache verticalPositionCache;
LineBreaker lineBreaker(this);
LayoutUnit absoluteLogicalTop;
ShapeInsideInfo* shapeInsideInfo = layoutShapeInsideInfo();
if (shapeInsideInfo) {
ASSERT(shapeInsideInfo->owner() == this || allowsShapeInsideInfoSharing());
if (shapeInsideInfo != this->shapeInsideInfo()) {
// FIXME Bug 100284: If subsequent LayoutStates are pushed, we will have to add
// their offsets from the original shape-inside container.
absoluteLogicalTop = logicalTop();
}
// Begin layout at the logical top of our shape inside.
if (logicalHeight() + absoluteLogicalTop < shapeInsideInfo->shapeLogicalTop()) {
LayoutUnit logicalHeight = shapeInsideInfo->shapeLogicalTop() - absoluteLogicalTop;
if (layoutState.flowThread())
logicalHeight -= shapeInsideInfo->owner()->borderAndPaddingBefore();
setLogicalHeight(logicalHeight);
}
}
while (!end.atEnd()) {
// FIXME: Is this check necessary before the first iteration or can it be moved to the end?
if (checkForEndLineMatch) {
layoutState.setEndLineMatched(matchedEndLine(layoutState, resolver, cleanLineStart, cleanLineBidiStatus));
if (layoutState.endLineMatched()) {
resolver.setPosition(InlineIterator(resolver.position().root(), 0, 0), 0);
break;
}
}
lineMidpointState.reset();
layoutState.lineInfo().setEmpty(true);
layoutState.lineInfo().resetRunsFromLeadingWhitespace();
const InlineIterator oldEnd = end;
bool isNewUBAParagraph = layoutState.lineInfo().previousLineBrokeCleanly();
FloatingObject* lastFloatFromPreviousLine = (containsFloats()) ? m_floatingObjects->set().last() : 0;
updateShapeAndSegmentsForCurrentLine(shapeInsideInfo, absoluteLogicalTop, layoutState);
WordMeasurements wordMeasurements;
end = lineBreaker.nextLineBreak(resolver, layoutState.lineInfo(), renderTextInfo, lastFloatFromPreviousLine, consecutiveHyphenatedLines, wordMeasurements);
renderTextInfo.m_lineBreakIterator.resetPriorContext();
if (resolver.position().atEnd()) {
// FIXME: We shouldn't be creating any runs in nextLineBreak to begin with!
// Once BidiRunList is separated from BidiResolver this will not be needed.
resolver.runs().deleteRuns();
resolver.markCurrentRunEmpty(); // FIXME: This can probably be replaced by an ASSERT (or just removed).
layoutState.setCheckForFloatsFromLastLine(true);
resolver.setPosition(InlineIterator(resolver.position().root(), 0, 0), 0);
break;
}
if (adjustLogicalLineTopAndLogicalHeightIfNeeded(shapeInsideInfo, absoluteLogicalTop, layoutState, resolver, lastFloatFromPreviousLine, end, wordMeasurements))
continue;
ASSERT(end != resolver.position());
// This is a short-cut for empty lines.
if (layoutState.lineInfo().isEmpty()) {
if (lastRootBox())
lastRootBox()->setLineBreakInfo(end.m_obj, end.m_pos, resolver.status());
} else {
VisualDirectionOverride override = (styleToUse->rtlOrdering() == VisualOrder ? (styleToUse->direction() == LTR ? VisualLeftToRightOverride : VisualRightToLeftOverride) : NoVisualOverride);
if (isNewUBAParagraph && styleToUse->unicodeBidi() == Plaintext && !resolver.context()->parent()) {
TextDirection direction = determinePlaintextDirectionality(resolver.position().root(), resolver.position().object(), resolver.position().offset());
resolver.setStatus(BidiStatus(direction, isOverride(styleToUse->unicodeBidi())));
}
// FIXME: This ownership is reversed. We should own the BidiRunList and pass it to createBidiRunsForLine.
BidiRunList<BidiRun>& bidiRuns = resolver.runs();
constructBidiRunsForLine(this, resolver, bidiRuns, end, override, layoutState.lineInfo().previousLineBrokeCleanly());
ASSERT(resolver.position() == end);
BidiRun* trailingSpaceRun = !layoutState.lineInfo().previousLineBrokeCleanly() ? handleTrailingSpaces(bidiRuns, resolver.context()) : 0;
if (bidiRuns.runCount() && lineBreaker.lineWasHyphenated()) {
bidiRuns.logicallyLastRun()->m_hasHyphen = true;
consecutiveHyphenatedLines++;
} else
consecutiveHyphenatedLines = 0;
// Now that the runs have been ordered, we create the line boxes.
// At the same time we figure out where border/padding/margin should be applied for
// inline flow boxes.
LayoutUnit oldLogicalHeight = logicalHeight();
RootInlineBox* lineBox = createLineBoxesFromBidiRuns(resolver.status().context->level(), bidiRuns, end, layoutState.lineInfo(), verticalPositionCache, trailingSpaceRun, wordMeasurements);
bidiRuns.deleteRuns();
resolver.markCurrentRunEmpty(); // FIXME: This can probably be replaced by an ASSERT (or just removed).
if (lineBox) {
lineBox->setLineBreakInfo(end.m_obj, end.m_pos, resolver.status());
if (layoutState.usesRepaintBounds())
layoutState.updateRepaintRangeFromBox(lineBox);
if (paginated) {
LayoutUnit adjustment = 0;
adjustLinePositionForPagination(lineBox, adjustment, layoutState.flowThread());
if (adjustment) {
LayoutUnit oldLineWidth = availableLogicalWidthForLine(oldLogicalHeight, layoutState.lineInfo().isFirstLine());
lineBox->adjustBlockDirectionPosition(adjustment);
if (layoutState.usesRepaintBounds())
layoutState.updateRepaintRangeFromBox(lineBox);
if (availableLogicalWidthForLine(oldLogicalHeight + adjustment, layoutState.lineInfo().isFirstLine()) != oldLineWidth) {
// We have to delete this line, remove all floats that got added, and let line layout re-run.
lineBox->deleteLine();
end = restartLayoutRunsAndFloatsInRange(oldLogicalHeight, oldLogicalHeight + adjustment, lastFloatFromPreviousLine, resolver, oldEnd);
continue;
}
setLogicalHeight(lineBox->lineBottomWithLeading());
}
if (layoutState.flowThread())
lineBox->setContainingRegion(regionAtBlockOffset(lineBox->lineTopWithLeading()));
}
}
}
for (size_t i = 0; i < lineBreaker.positionedObjects().size(); ++i)
setStaticPositions(this, lineBreaker.positionedObjects()[i]);
if (!layoutState.lineInfo().isEmpty()) {
layoutState.lineInfo().setFirstLine(false);
newLine(lineBreaker.clear());
}
if (m_floatingObjects && lastRootBox()) {
const FloatingObjectSet& floatingObjectSet = m_floatingObjects->set();
FloatingObjectSetIterator it = floatingObjectSet.begin();
FloatingObjectSetIterator end = floatingObjectSet.end();
if (layoutState.lastFloat()) {
FloatingObjectSetIterator lastFloatIterator = floatingObjectSet.find(layoutState.lastFloat());
ASSERT(lastFloatIterator != end);
++lastFloatIterator;
it = lastFloatIterator;
}
for (; it != end; ++it) {
FloatingObject* f = *it;
appendFloatingObjectToLastLine(f);
ASSERT(f->renderer() == layoutState.floats()[layoutState.floatIndex()].object);
// If a float's geometry has changed, give up on syncing with clean lines.
if (layoutState.floats()[layoutState.floatIndex()].rect != f->frameRect())
checkForEndLineMatch = false;
layoutState.setFloatIndex(layoutState.floatIndex() + 1);
}
layoutState.setLastFloat(!floatingObjectSet.isEmpty() ? floatingObjectSet.last() : 0);
}
lineMidpointState.reset();
resolver.setPosition(end, numberOfIsolateAncestors(end));
}
if (paginated && !style()->hasAutoWidows()) {
// Check the line boxes to make sure we didn't create unacceptable widows.
// However, we'll prioritize orphans - so nothing we do here should create
// a new orphan.
RootInlineBox* lineBox = lastRootBox();
// Count from the end of the block backwards, to see how many hanging
// lines we have.
RootInlineBox* firstLineInBlock = firstRootBox();
int numLinesHanging = 1;
while (lineBox && lineBox != firstLineInBlock && !lineBox->isFirstAfterPageBreak()) {
++numLinesHanging;
lineBox = lineBox->prevRootBox();
}
// If there were no breaks in the block, we didn't create any widows.
if (!lineBox || !lineBox->isFirstAfterPageBreak() || lineBox == firstLineInBlock)
return;
if (numLinesHanging < style()->widows()) {
// We have detected a widow. Now we need to work out how many
// lines there are on the previous page, and how many we need
// to steal.
int numLinesNeeded = style()->widows() - numLinesHanging;
RootInlineBox* currentFirstLineOfNewPage = lineBox;
// Count the number of lines in the previous page.
lineBox = lineBox->prevRootBox();
int numLinesInPreviousPage = 1;
while (lineBox && lineBox != firstLineInBlock && !lineBox->isFirstAfterPageBreak()) {
++numLinesInPreviousPage;
lineBox = lineBox->prevRootBox();
}
// If there was an explicit value for orphans, respect that. If not, we still
// shouldn't create a situation where we make an orphan bigger than the initial value.
// This means that setting widows implies we also care about orphans, but given
// the specification says the initial orphan value is non-zero, this is ok. The
// author is always free to set orphans explicitly as well.
int orphans = style()->hasAutoOrphans() ? style()->initialOrphans() : style()->orphans();
int numLinesAvailable = numLinesInPreviousPage - orphans;
if (numLinesAvailable <= 0)
return;
int numLinesToTake = min(numLinesAvailable, numLinesNeeded);
// Wind back from our first widowed line.
lineBox = currentFirstLineOfNewPage;
for (int i = 0; i < numLinesToTake; ++i)
lineBox = lineBox->prevRootBox();
// We now want to break at this line. Remember for next layout and trigger relayout.
setBreakAtLineToAvoidWidow(lineBox);
markLinesDirtyInBlockRange(lastRootBox()->lineBottomWithLeading(), lineBox->lineBottomWithLeading(), lineBox);
}
}
}
void RenderBlock::linkToEndLineIfNeeded(LineLayoutState& layoutState)
{
if (layoutState.endLine()) {
if (layoutState.endLineMatched()) {
bool paginated = view()->layoutState() && view()->layoutState()->isPaginated();
// Attach all the remaining lines, and then adjust their y-positions as needed.
LayoutUnit delta = logicalHeight() - layoutState.endLineLogicalTop();
for (RootInlineBox* line = layoutState.endLine(); line; line = line->nextRootBox()) {
line->attachLine();
if (paginated) {
delta -= line->paginationStrut();
adjustLinePositionForPagination(line, delta, layoutState.flowThread());
}
if (delta) {
layoutState.updateRepaintRangeFromBox(line, delta);
line->adjustBlockDirectionPosition(delta);
}
if (layoutState.flowThread())
line->setContainingRegion(regionAtBlockOffset(line->lineTopWithLeading()));
if (Vector<RenderBox*>* cleanLineFloats = line->floatsPtr()) {
Vector<RenderBox*>::iterator end = cleanLineFloats->end();
for (Vector<RenderBox*>::iterator f = cleanLineFloats->begin(); f != end; ++f) {
FloatingObject* floatingObject = insertFloatingObject(*f);
ASSERT(!floatingObject->originatingLine());
floatingObject->setOriginatingLine(line);
setLogicalHeight(logicalTopForChild(*f) - marginBeforeForChild(*f) + delta);
positionNewFloats();
}
}
}
setLogicalHeight(lastRootBox()->lineBottomWithLeading());
} else {
// Delete all the remaining lines.
deleteLineRange(layoutState, layoutState.endLine());
}
}
if (m_floatingObjects && (layoutState.checkForFloatsFromLastLine() || positionNewFloats()) && lastRootBox()) {
// In case we have a float on the last line, it might not be positioned up to now.
// This has to be done before adding in the bottom border/padding, or the float will
// include the padding incorrectly. -dwh
if (layoutState.checkForFloatsFromLastLine()) {
LayoutUnit bottomVisualOverflow = lastRootBox()->logicalBottomVisualOverflow();
LayoutUnit bottomLayoutOverflow = lastRootBox()->logicalBottomLayoutOverflow();
TrailingFloatsRootInlineBox* trailingFloatsLineBox = new TrailingFloatsRootInlineBox(this);
m_lineBoxes.appendLineBox(trailingFloatsLineBox);
trailingFloatsLineBox->setConstructed();
GlyphOverflowAndFallbackFontsMap textBoxDataMap;
VerticalPositionCache verticalPositionCache;
LayoutUnit blockLogicalHeight = logicalHeight();
trailingFloatsLineBox->alignBoxesInBlockDirection(blockLogicalHeight, textBoxDataMap, verticalPositionCache);
trailingFloatsLineBox->setLineTopBottomPositions(blockLogicalHeight, blockLogicalHeight, blockLogicalHeight, blockLogicalHeight);
trailingFloatsLineBox->setPaginatedLineWidth(availableLogicalWidthForContent(blockLogicalHeight));
LayoutRect logicalLayoutOverflow(0, blockLogicalHeight, 1, bottomLayoutOverflow - blockLogicalHeight);
LayoutRect logicalVisualOverflow(0, blockLogicalHeight, 1, bottomVisualOverflow - blockLogicalHeight);
trailingFloatsLineBox->setOverflowFromLogicalRects(logicalLayoutOverflow, logicalVisualOverflow, trailingFloatsLineBox->lineTop(), trailingFloatsLineBox->lineBottom());
if (layoutState.flowThread())
trailingFloatsLineBox->setContainingRegion(regionAtBlockOffset(trailingFloatsLineBox->lineTopWithLeading()));
}
const FloatingObjectSet& floatingObjectSet = m_floatingObjects->set();
FloatingObjectSetIterator it = floatingObjectSet.begin();
FloatingObjectSetIterator end = floatingObjectSet.end();
if (layoutState.lastFloat()) {
FloatingObjectSetIterator lastFloatIterator = floatingObjectSet.find(layoutState.lastFloat());
ASSERT(lastFloatIterator != end);
++lastFloatIterator;
it = lastFloatIterator;
}
for (; it != end; ++it)
appendFloatingObjectToLastLine(*it);
layoutState.setLastFloat(!floatingObjectSet.isEmpty() ? floatingObjectSet.last() : 0);
}
}
void RenderBlock::repaintDirtyFloats(Vector<FloatWithRect>& floats)
{
size_t floatCount = floats.size();
// Floats that did not have layout did not repaint when we laid them out. They would have
// painted by now if they had moved, but if they stayed at (0, 0), they still need to be
// painted.
for (size_t i = 0; i < floatCount; ++i) {
if (!floats[i].everHadLayout) {
RenderBox* f = floats[i].object;
if (!f->x() && !f->y() && f->checkForRepaintDuringLayout())
f->repaint();
}
}
}
void RenderBlockFlow::layoutInlineChildren(bool relayoutChildren, LayoutUnit& repaintLogicalTop, LayoutUnit& repaintLogicalBottom)
{
setLogicalHeight(borderBefore() + paddingBefore());
// Lay out our hypothetical grid line as though it occurs at the top of the block.
if (view()->layoutState() && view()->layoutState()->lineGrid() == this)
layoutLineGridBox();
RenderFlowThread* flowThread = flowThreadContainingBlock();
bool clearLinesForPagination = firstLineBox() && flowThread && !flowThread->hasRegions();
// Figure out if we should clear out our line boxes.
// FIXME: Handle resize eventually!
bool isFullLayout = !firstLineBox() || selfNeedsLayout() || relayoutChildren || clearLinesForPagination;
LineLayoutState layoutState(isFullLayout, repaintLogicalTop, repaintLogicalBottom, flowThread);
if (isFullLayout)
lineBoxes()->deleteLineBoxes();
// Text truncation kicks in in two cases:
// 1) If your overflow isn't visible and your text-overflow-mode isn't clip.
// 2) If you're an anonymous block with a block parent that satisfies #1.
// FIXME: CSS3 says that descendants that are clipped must also know how to truncate. This is insanely
// difficult to figure out in general (especially in the middle of doing layout), so we only handle the
// simple case of an anonymous block truncating when it's parent is clipped.
bool hasTextOverflow = (style()->textOverflow() && hasOverflowClip())
|| (isAnonymousBlock() && parent() && parent()->isRenderBlock() && parent()->style()->textOverflow() && parent()->hasOverflowClip());
// Walk all the lines and delete our ellipsis line boxes if they exist.
if (hasTextOverflow)
deleteEllipsisLineBoxes();
if (firstChild()) {
// In full layout mode, clear the line boxes of children upfront. Otherwise,
// siblings can run into stale root lineboxes during layout. Then layout
// the replaced elements later. In partial layout mode, line boxes are not
// deleted and only dirtied. In that case, we can layout the replaced
// elements at the same time.
bool hasInlineChild = false;
Vector<RenderBox*> replacedChildren;
for (InlineWalker walker(this); !walker.atEnd(); walker.advance()) {
RenderObject* o = walker.current();
if (!hasInlineChild && o->isInline())
hasInlineChild = true;
if (o->isReplaced() || o->isFloating() || o->isOutOfFlowPositioned()) {
RenderBox* box = toRenderBox(o);
if (relayoutChildren || box->hasRelativeDimensions())
o->setChildNeedsLayout(MarkOnlyThis);
// If relayoutChildren is set and the child has percentage padding or an embedded content box, we also need to invalidate the childs pref widths.
if (relayoutChildren && box->needsPreferredWidthsRecalculation())
o->setPreferredLogicalWidthsDirty(MarkOnlyThis);
if (o->isOutOfFlowPositioned())
o->containingBlock()->insertPositionedObject(box);
else if (o->isFloating())
layoutState.floats().append(FloatWithRect(box));
else if (isFullLayout || o->needsLayout()) {
// Replaced element.
box->dirtyLineBoxes(isFullLayout);
if (isFullLayout)
replacedChildren.append(box);
else
o->layoutIfNeeded();
}
} else if (o->isText() || (o->isRenderInline() && !walker.atEndOfInline())) {
if (!o->isText())
toRenderInline(o)->updateAlwaysCreateLineBoxes(layoutState.isFullLayout());
if (layoutState.isFullLayout() || o->selfNeedsLayout())
dirtyLineBoxesForRenderer(o, layoutState.isFullLayout());
o->clearNeedsLayout();
}
}
for (size_t i = 0; i < replacedChildren.size(); i++)
replacedChildren[i]->layoutIfNeeded();
layoutRunsAndFloats(layoutState, hasInlineChild);
}
// Expand the last line to accommodate Ruby and emphasis marks.
int lastLineAnnotationsAdjustment = 0;
if (lastRootBox()) {
LayoutUnit lowestAllowedPosition = max(lastRootBox()->lineBottom(), logicalHeight() + paddingAfter());
if (!style()->isFlippedLinesWritingMode())
lastLineAnnotationsAdjustment = lastRootBox()->computeUnderAnnotationAdjustment(lowestAllowedPosition);
else
lastLineAnnotationsAdjustment = lastRootBox()->computeOverAnnotationAdjustment(lowestAllowedPosition);
}
// Now add in the bottom border/padding.
setLogicalHeight(logicalHeight() + lastLineAnnotationsAdjustment + borderAfter() + paddingAfter() + scrollbarLogicalHeight());
if (!firstLineBox() && hasLineIfEmpty())
setLogicalHeight(logicalHeight() + lineHeight(true, isHorizontalWritingMode() ? HorizontalLine : VerticalLine, PositionOfInteriorLineBoxes));
// See if we have any lines that spill out of our block. If we do, then we will possibly need to
// truncate text.
if (hasTextOverflow)
checkLinesForTextOverflow();
}
void RenderBlock::checkFloatsInCleanLine(RootInlineBox* line, Vector<FloatWithRect>& floats, size_t& floatIndex, bool& encounteredNewFloat, bool& dirtiedByFloat)
{
Vector<RenderBox*>* cleanLineFloats = line->floatsPtr();
if (!cleanLineFloats)
return;
Vector<RenderBox*>::iterator end = cleanLineFloats->end();
for (Vector<RenderBox*>::iterator it = cleanLineFloats->begin(); it != end; ++it) {
RenderBox* floatingBox = *it;
floatingBox->layoutIfNeeded();
LayoutSize newSize(floatingBox->width() + floatingBox->marginWidth(), floatingBox->height() + floatingBox->marginHeight());
if (floats[floatIndex].object != floatingBox) {
encounteredNewFloat = true;
return;
}
if (floats[floatIndex].rect.size() != newSize) {
LayoutUnit floatTop = isHorizontalWritingMode() ? floats[floatIndex].rect.y() : floats[floatIndex].rect.x();
LayoutUnit floatHeight = isHorizontalWritingMode() ? max(floats[floatIndex].rect.height(), newSize.height())
: max(floats[floatIndex].rect.width(), newSize.width());
floatHeight = min(floatHeight, LayoutUnit::max() - floatTop);
line->markDirty();
markLinesDirtyInBlockRange(line->lineBottomWithLeading(), floatTop + floatHeight, line);
floats[floatIndex].rect.setSize(newSize);
dirtiedByFloat = true;
}
floatIndex++;
}
}
RootInlineBox* RenderBlock::determineStartPosition(LineLayoutState& layoutState, InlineBidiResolver& resolver)
{
RootInlineBox* curr = 0;
RootInlineBox* last = 0;
// FIXME: This entire float-checking block needs to be broken into a new function.
bool dirtiedByFloat = false;
if (!layoutState.isFullLayout()) {
// Paginate all of the clean lines.
bool paginated = view()->layoutState() && view()->layoutState()->isPaginated();
LayoutUnit paginationDelta = 0;
size_t floatIndex = 0;
for (curr = firstRootBox(); curr && !curr->isDirty(); curr = curr->nextRootBox()) {
if (paginated) {
if (lineWidthForPaginatedLineChanged(curr, 0, layoutState.flowThread())) {
curr->markDirty();
break;
}
paginationDelta -= curr->paginationStrut();
adjustLinePositionForPagination(curr, paginationDelta, layoutState.flowThread());
if (paginationDelta) {
if (containsFloats() || !layoutState.floats().isEmpty()) {
// FIXME: Do better eventually. For now if we ever shift because of pagination and floats are present just go to a full layout.
layoutState.markForFullLayout();
break;
}
layoutState.updateRepaintRangeFromBox(curr, paginationDelta);
curr->adjustBlockDirectionPosition(paginationDelta);
}
if (layoutState.flowThread())
curr->setContainingRegion(regionAtBlockOffset(curr->lineTopWithLeading()));
}
// If a new float has been inserted before this line or before its last known float, just do a full layout.
bool encounteredNewFloat = false;
checkFloatsInCleanLine(curr, layoutState.floats(), floatIndex, encounteredNewFloat, dirtiedByFloat);
if (encounteredNewFloat)
layoutState.markForFullLayout();
if (dirtiedByFloat || layoutState.isFullLayout())
break;
}
// Check if a new float has been inserted after the last known float.
if (!curr && floatIndex < layoutState.floats().size())
layoutState.markForFullLayout();
}
if (layoutState.isFullLayout()) {
// FIXME: This should just call deleteLineBoxTree, but that causes
// crashes for fast/repaint tests.
curr = firstRootBox();
while (curr) {
// Note: This uses nextRootBox() insted of nextLineBox() like deleteLineBoxTree does.
RootInlineBox* next = curr->nextRootBox();
curr->deleteLine();
curr = next;
}
ASSERT(!firstLineBox() && !lastLineBox());
} else {
if (curr) {
// We have a dirty line.
if (RootInlineBox* prevRootBox = curr->prevRootBox()) {
// We have a previous line.
if (!dirtiedByFloat && (!prevRootBox->endsWithBreak() || !prevRootBox->lineBreakObj() || (prevRootBox->lineBreakObj()->isText() && prevRootBox->lineBreakPos() >= toRenderText(prevRootBox->lineBreakObj())->textLength())))
// The previous line didn't break cleanly or broke at a newline
// that has been deleted, so treat it as dirty too.
curr = prevRootBox;
}
} else {
// No dirty lines were found.
// If the last line didn't break cleanly, treat it as dirty.
if (lastRootBox() && !lastRootBox()->endsWithBreak())
curr = lastRootBox();
}
// If we have no dirty lines, then last is just the last root box.
last = curr ? curr->prevRootBox() : lastRootBox();
}
unsigned numCleanFloats = 0;
if (!layoutState.floats().isEmpty()) {
LayoutUnit savedLogicalHeight = logicalHeight();
// Restore floats from clean lines.
RootInlineBox* line = firstRootBox();
while (line != curr) {
if (Vector<RenderBox*>* cleanLineFloats = line->floatsPtr()) {
Vector<RenderBox*>::iterator end = cleanLineFloats->end();
for (Vector<RenderBox*>::iterator f = cleanLineFloats->begin(); f != end; ++f) {
FloatingObject* floatingObject = insertFloatingObject(*f);
ASSERT(!floatingObject->originatingLine());
floatingObject->setOriginatingLine(line);
setLogicalHeight(logicalTopForChild(*f) - marginBeforeForChild(*f));
positionNewFloats();
ASSERT(layoutState.floats()[numCleanFloats].object == *f);
numCleanFloats++;
}
}
line = line->nextRootBox();
}
setLogicalHeight(savedLogicalHeight);
}
layoutState.setFloatIndex(numCleanFloats);
layoutState.lineInfo().setFirstLine(!last);
layoutState.lineInfo().setPreviousLineBrokeCleanly(!last || last->endsWithBreak());
if (last) {
setLogicalHeight(last->lineBottomWithLeading());
InlineIterator iter = InlineIterator(this, last->lineBreakObj(), last->lineBreakPos());
resolver.setPosition(iter, numberOfIsolateAncestors(iter));
resolver.setStatus(last->lineBreakBidiStatus());
} else {
TextDirection direction = style()->direction();
if (style()->unicodeBidi() == Plaintext)
direction = determinePlaintextDirectionality(this);
resolver.setStatus(BidiStatus(direction, isOverride(style()->unicodeBidi())));
InlineIterator iter = InlineIterator(this, bidiFirstSkippingEmptyInlines(this, &resolver), 0);
resolver.setPosition(iter, numberOfIsolateAncestors(iter));
}
return curr;
}
void RenderBlock::determineEndPosition(LineLayoutState& layoutState, RootInlineBox* startLine, InlineIterator& cleanLineStart, BidiStatus& cleanLineBidiStatus)
{
ASSERT(!layoutState.endLine());
size_t floatIndex = layoutState.floatIndex();
RootInlineBox* last = 0;
for (RootInlineBox* curr = startLine->nextRootBox(); curr; curr = curr->nextRootBox()) {
if (!curr->isDirty()) {
bool encounteredNewFloat = false;
bool dirtiedByFloat = false;
checkFloatsInCleanLine(curr, layoutState.floats(), floatIndex, encounteredNewFloat, dirtiedByFloat);
if (encounteredNewFloat)
return;
}
if (curr->isDirty())
last = 0;
else if (!last)
last = curr;
}
if (!last)
return;
// At this point, |last| is the first line in a run of clean lines that ends with the last line
// in the block.
RootInlineBox* prev = last->prevRootBox();
cleanLineStart = InlineIterator(this, prev->lineBreakObj(), prev->lineBreakPos());
cleanLineBidiStatus = prev->lineBreakBidiStatus();
layoutState.setEndLineLogicalTop(prev->lineBottomWithLeading());
for (RootInlineBox* line = last; line; line = line->nextRootBox())
line->extractLine(); // Disconnect all line boxes from their render objects while preserving
// their connections to one another.
layoutState.setEndLine(last);
}
bool RenderBlock::checkPaginationAndFloatsAtEndLine(LineLayoutState& layoutState)
{
LayoutUnit lineDelta = logicalHeight() - layoutState.endLineLogicalTop();
bool paginated = view()->layoutState() && view()->layoutState()->isPaginated();
if (paginated && layoutState.flowThread()) {
// Check all lines from here to the end, and see if the hypothetical new position for the lines will result
// in a different available line width.
for (RootInlineBox* lineBox = layoutState.endLine(); lineBox; lineBox = lineBox->nextRootBox()) {
if (paginated) {
// This isn't the real move we're going to do, so don't update the line box's pagination
// strut yet.
LayoutUnit oldPaginationStrut = lineBox->paginationStrut();
lineDelta -= oldPaginationStrut;
adjustLinePositionForPagination(lineBox, lineDelta, layoutState.flowThread());
lineBox->setPaginationStrut(oldPaginationStrut);
}
if (lineWidthForPaginatedLineChanged(lineBox, lineDelta, layoutState.flowThread()))
return false;
}
}
if (!lineDelta || !m_floatingObjects)
return true;
// See if any floats end in the range along which we want to shift the lines vertically.
LayoutUnit logicalTop = min(logicalHeight(), layoutState.endLineLogicalTop());
RootInlineBox* lastLine = layoutState.endLine();
while (RootInlineBox* nextLine = lastLine->nextRootBox())
lastLine = nextLine;
LayoutUnit logicalBottom = lastLine->lineBottomWithLeading() + absoluteValue(lineDelta);
const FloatingObjectSet& floatingObjectSet = m_floatingObjects->set();
FloatingObjectSetIterator end = floatingObjectSet.end();
for (FloatingObjectSetIterator it = floatingObjectSet.begin(); it != end; ++it) {
FloatingObject* f = *it;
if (f->logicalBottom(isHorizontalWritingMode()) >= logicalTop && f->logicalBottom(isHorizontalWritingMode()) < logicalBottom)
return false;
}
return true;
}
bool RenderBlock::matchedEndLine(LineLayoutState& layoutState, const InlineBidiResolver& resolver, const InlineIterator& endLineStart, const BidiStatus& endLineStatus)
{
if (resolver.position() == endLineStart) {
if (resolver.status() != endLineStatus)
return false;
return checkPaginationAndFloatsAtEndLine(layoutState);
}
// The first clean line doesn't match, but we can check a handful of following lines to try
// to match back up.
static int numLines = 8; // The # of lines we're willing to match against.
RootInlineBox* originalEndLine = layoutState.endLine();
RootInlineBox* line = originalEndLine;
for (int i = 0; i < numLines && line; i++, line = line->nextRootBox()) {
if (line->lineBreakObj() == resolver.position().m_obj && line->lineBreakPos() == resolver.position().m_pos) {
// We have a match.
if (line->lineBreakBidiStatus() != resolver.status())
return false; // ...but the bidi state doesn't match.
bool matched = false;
RootInlineBox* result = line->nextRootBox();
layoutState.setEndLine(result);
if (result) {
layoutState.setEndLineLogicalTop(line->lineBottomWithLeading());
matched = checkPaginationAndFloatsAtEndLine(layoutState);
}
// Now delete the lines that we failed to sync.
deleteLineRange(layoutState, originalEndLine, result);
return matched;
}
}
return false;
}
enum WhitespacePosition { LeadingWhitespace, TrailingWhitespace };
static inline bool shouldCollapseWhiteSpace(const RenderStyle* style, const LineInfo& lineInfo, WhitespacePosition whitespacePosition)
{
// CSS2 16.6.1
// If a space (U+0020) at the beginning of a line has 'white-space' set to 'normal', 'nowrap', or 'pre-line', it is removed.
// If a space (U+0020) at the end of a line has 'white-space' set to 'normal', 'nowrap', or 'pre-line', it is also removed.
// If spaces (U+0020) or tabs (U+0009) at the end of a line have 'white-space' set to 'pre-wrap', UAs may visually collapse them.
return style->collapseWhiteSpace()
|| (whitespacePosition == TrailingWhitespace && style->whiteSpace() == PRE_WRAP && (!lineInfo.isEmpty() || !lineInfo.previousLineBrokeCleanly()));
}
static bool requiresLineBoxForContent(RenderInline* flow, const LineInfo& lineInfo)
{
RenderObject* parent = flow->parent();
if (flow->document().inNoQuirksMode()
&& (flow->style(lineInfo.isFirstLine())->lineHeight() != parent->style(lineInfo.isFirstLine())->lineHeight()
|| flow->style()->verticalAlign() != parent->style()->verticalAlign()
|| !parent->style()->font().fontMetrics().hasIdenticalAscentDescentAndLineGap(flow->style()->font().fontMetrics())))
return true;
return false;
}
static bool alwaysRequiresLineBox(RenderObject* flow)
{
// FIXME: Right now, we only allow line boxes for inlines that are truly empty.
// We need to fix this, though, because at the very least, inlines containing only
// ignorable whitespace should should also have line boxes.
return isEmptyInline(flow) && toRenderInline(flow)->hasInlineDirectionBordersPaddingOrMargin();
}
static bool requiresLineBox(const InlineIterator& it, const LineInfo& lineInfo = LineInfo(), WhitespacePosition whitespacePosition = LeadingWhitespace)
{
if (it.m_obj->isFloatingOrOutOfFlowPositioned())
return false;
if (it.m_obj->isRenderInline() && !alwaysRequiresLineBox(it.m_obj) && !requiresLineBoxForContent(toRenderInline(it.m_obj), lineInfo))
return false;
if (!shouldCollapseWhiteSpace(it.m_obj->style(), lineInfo, whitespacePosition) || it.m_obj->isBR())
return true;
UChar current = it.current();
bool notJustWhitespace = current != ' ' && current != '\t' && current != softHyphen && (current != '\n' || it.m_obj->preservesNewline());
return notJustWhitespace || isEmptyInline(it.m_obj);
}
bool RenderBlock::generatesLineBoxesForInlineChild(RenderObject* inlineObj)
{
ASSERT(inlineObj->parent() == this);
InlineIterator it(this, inlineObj, 0);
// FIXME: We should pass correct value for WhitespacePosition.
while (!it.atEnd() && !requiresLineBox(it))
it.increment();
return !it.atEnd();
}
// FIXME: The entire concept of the skipTrailingWhitespace function is flawed, since we really need to be building
// line boxes even for containers that may ultimately collapse away. Otherwise we'll never get positioned
// elements quite right. In other words, we need to build this function's work into the normal line
// object iteration process.
// NB. this function will insert any floating elements that would otherwise
// be skipped but it will not position them.
void LineBreaker::skipTrailingWhitespace(InlineIterator& iterator, const LineInfo& lineInfo)
{
while (!iterator.atEnd() && !requiresLineBox(iterator, lineInfo, TrailingWhitespace)) {
RenderObject* object = iterator.m_obj;
if (object->isOutOfFlowPositioned())
setStaticPositions(m_block, toRenderBox(object));
else if (object->isFloating())
m_block->insertFloatingObject(toRenderBox(object));
iterator.increment();
}
}
void LineBreaker::skipLeadingWhitespace(InlineBidiResolver& resolver, LineInfo& lineInfo,
FloatingObject* lastFloatFromPreviousLine, LineWidth& width)
{
while (!resolver.position().atEnd() && !requiresLineBox(resolver.position(), lineInfo, LeadingWhitespace)) {
RenderObject* object = resolver.position().m_obj;
if (object->isOutOfFlowPositioned()) {
setStaticPositions(m_block, toRenderBox(object));
if (object->style()->isOriginalDisplayInlineType()) {
resolver.runs().addRun(createRun(0, 1, object, resolver));
lineInfo.incrementRunsFromLeadingWhitespace();
}
} else if (object->isFloating()) {
// The top margin edge of a self-collapsing block that clears a float intrudes up into it by the height of the margin,
// so in order to place this first child float at the top content edge of the self-collapsing block add the margin back in before placement.
LayoutUnit marginOffset = (!object->previousSibling() && m_block->isSelfCollapsingBlock() && m_block->style()->clear() && m_block->getClearDelta(m_block, LayoutUnit())) ? m_block->collapsedMarginBeforeForChild(m_block) : LayoutUnit();
LayoutUnit oldLogicalHeight = m_block->logicalHeight();
m_block->setLogicalHeight(oldLogicalHeight + marginOffset);
m_block->positionNewFloatOnLine(m_block->insertFloatingObject(toRenderBox(object)), lastFloatFromPreviousLine, lineInfo, width);
m_block->setLogicalHeight(oldLogicalHeight);
} else if (object->isText() && object->style()->hasTextCombine() && object->isCombineText() && !toRenderCombineText(object)->isCombined()) {
toRenderCombineText(object)->combineText();
if (toRenderCombineText(object)->isCombined())
continue;
}
resolver.increment();
}
resolver.commitExplicitEmbedding();
}
// This is currently just used for list markers and inline flows that have line boxes. Neither should
// have an effect on whitespace at the start of the line.
static bool shouldSkipWhitespaceAfterStartObject(RenderBlock* block, RenderObject* o, LineMidpointState& lineMidpointState)
{
RenderObject* next = bidiNextSkippingEmptyInlines(block, o);
while (next && next->isFloatingOrOutOfFlowPositioned())
next = bidiNextSkippingEmptyInlines(block, next);
if (next && !next->isBR() && next->isText() && toRenderText(next)->textLength() > 0) {
RenderText* nextText = toRenderText(next);
UChar nextChar = nextText->characterAt(0);
if (nextText->style()->isCollapsibleWhiteSpace(nextChar)) {
startIgnoringSpaces(lineMidpointState, InlineIterator(0, o, 0));
return true;
}
}
return false;
}
static ALWAYS_INLINE float textWidth(RenderText* text, unsigned from, unsigned len, const Font& font, float xPos, bool isFixedPitch, bool collapseWhiteSpace, HashSet<const SimpleFontData*>* fallbackFonts = 0, TextLayout* layout = 0)
{
GlyphOverflow glyphOverflow;
if (isFixedPitch || (!from && len == text->textLength()) || text->style()->hasTextCombine())
return text->width(from, len, font, xPos, fallbackFonts, &glyphOverflow);
if (layout)
return Font::width(*layout, from, len, fallbackFonts);
TextRun run = RenderBlock::constructTextRun(text, font, text, from, len, text->style());
run.setCharactersLength(text->textLength() - from);
ASSERT(run.charactersLength() >= run.length());
run.setCharacterScanForCodePath(!text->canUseSimpleFontCodePath());
run.setTabSize(!collapseWhiteSpace, text->style()->tabSize());
run.setXPos(xPos);
return font.width(run, fallbackFonts, &glyphOverflow);
}
class TrailingObjects {
public:
TrailingObjects();
void setTrailingWhitespace(RenderText*);
void clear();
void appendBoxIfNeeded(RenderBox*);
enum CollapseFirstSpaceOrNot { DoNotCollapseFirstSpace, CollapseFirstSpace };
void updateMidpointsForTrailingBoxes(LineMidpointState&, const InlineIterator& lBreak, CollapseFirstSpaceOrNot);
private:
RenderText* m_whitespace;
Vector<RenderBox*, 4> m_boxes;
};
TrailingObjects::TrailingObjects()
: m_whitespace(0)
{
}
inline void TrailingObjects::setTrailingWhitespace(RenderText* whitespace)
{
ASSERT(whitespace);
m_whitespace = whitespace;
}
inline void TrailingObjects::clear()
{
m_whitespace = 0;
// Using resize(0) rather than clear() here saves 2% on
// PerformanceTests/Layout/line-layout.html because we avoid freeing and
// re-allocating the underlying buffer repeatedly.
m_boxes.resize(0);
}
inline void TrailingObjects::appendBoxIfNeeded(RenderBox* box)
{
if (m_whitespace)
m_boxes.append(box);
}
void TrailingObjects::updateMidpointsForTrailingBoxes(LineMidpointState& lineMidpointState, const InlineIterator& lBreak, CollapseFirstSpaceOrNot collapseFirstSpace)
{
if (!m_whitespace)
return;
// This object is either going to be part of the last midpoint, or it is going to be the actual endpoint.
// In both cases we just decrease our pos by 1 level to exclude the space, allowing it to - in effect - collapse into the newline.
if (lineMidpointState.numMidpoints % 2) {
// Find the trailing space object's midpoint.
int trailingSpaceMidpoint = lineMidpointState.numMidpoints - 1;
for ( ; trailingSpaceMidpoint > 0 && lineMidpointState.midpoints[trailingSpaceMidpoint].m_obj != m_whitespace; --trailingSpaceMidpoint) { }
ASSERT(trailingSpaceMidpoint >= 0);
if (collapseFirstSpace == CollapseFirstSpace)
lineMidpointState.midpoints[trailingSpaceMidpoint].m_pos--;
// Now make sure every single trailingPositionedBox following the trailingSpaceMidpoint properly stops and starts
// ignoring spaces.
size_t currentMidpoint = trailingSpaceMidpoint + 1;
for (size_t i = 0; i < m_boxes.size(); ++i) {
if (currentMidpoint >= lineMidpointState.numMidpoints) {
// We don't have a midpoint for this box yet.
ensureLineBoxInsideIgnoredSpaces(lineMidpointState, m_boxes[i]);
} else {
ASSERT(lineMidpointState.midpoints[currentMidpoint].m_obj == m_boxes[i]);
ASSERT(lineMidpointState.midpoints[currentMidpoint + 1].m_obj == m_boxes[i]);
}
currentMidpoint += 2;
}
} else if (!lBreak.m_obj) {
ASSERT(m_whitespace->isText());
ASSERT(collapseFirstSpace == CollapseFirstSpace);
// Add a new end midpoint that stops right at the very end.
unsigned length = m_whitespace->textLength();
unsigned pos = length >= 2 ? length - 2 : UINT_MAX;
InlineIterator endMid(0, m_whitespace, pos);
startIgnoringSpaces(lineMidpointState, endMid);
for (size_t i = 0; i < m_boxes.size(); ++i) {
ensureLineBoxInsideIgnoredSpaces(lineMidpointState, m_boxes[i]);
}
}
}
void LineBreaker::reset()
{
m_positionedObjects.clear();
m_hyphenated = false;
m_clear = CNONE;
}
InlineIterator LineBreaker::nextLineBreak(InlineBidiResolver& resolver, LineInfo& lineInfo, RenderTextInfo& renderTextInfo, FloatingObject* lastFloatFromPreviousLine, unsigned consecutiveHyphenatedLines, WordMeasurements& wordMeasurements)
{
ShapeInsideInfo* shapeInsideInfo = m_block->layoutShapeInsideInfo();
if (!shapeInsideInfo || !shapeInsideInfo->lineOverlapsShapeBounds())
return nextSegmentBreak(resolver, lineInfo, renderTextInfo, lastFloatFromPreviousLine, consecutiveHyphenatedLines, wordMeasurements);
InlineIterator end = resolver.position();
InlineIterator oldEnd = end;
if (!shapeInsideInfo->hasSegments()) {
end = nextSegmentBreak(resolver, lineInfo, renderTextInfo, lastFloatFromPreviousLine, consecutiveHyphenatedLines, wordMeasurements);
resolver.setPositionIgnoringNestedIsolates(oldEnd);
return oldEnd;
}
const SegmentList& segments = shapeInsideInfo->segments();
SegmentRangeList& segmentRanges = shapeInsideInfo->segmentRanges();
for (unsigned i = 0; i < segments.size() && !end.atEnd(); i++) {
InlineIterator segmentStart = resolver.position();
end = nextSegmentBreak(resolver, lineInfo, renderTextInfo, lastFloatFromPreviousLine, consecutiveHyphenatedLines, wordMeasurements);
ASSERT(segmentRanges.size() == i);
if (resolver.position().atEnd()) {
segmentRanges.append(LineSegmentRange(segmentStart, end));
break;
}
if (resolver.position() == end) {
// Nothing fit this segment
end = segmentStart;
segmentRanges.append(LineSegmentRange(segmentStart, segmentStart));
resolver.setPositionIgnoringNestedIsolates(segmentStart);
} else {
// Note that resolver.position is already skipping some of the white space at the beginning of the line,
// so that's why segmentStart might be different than resolver.position().
LineSegmentRange range(resolver.position(), end);
segmentRanges.append(range);
resolver.setPosition(end, numberOfIsolateAncestors(end));
if (lineInfo.previousLineBrokeCleanly()) {
// If we hit a new line break, just stop adding anything to this line.
break;
}
}
}
resolver.setPositionIgnoringNestedIsolates(oldEnd);
return end;
}
static inline bool iteratorIsBeyondEndOfRenderCombineText(const InlineIterator& iter, RenderCombineText* renderer)
{
return iter.m_obj == renderer && iter.m_pos >= renderer->textLength();
}
InlineIterator LineBreaker::nextSegmentBreak(InlineBidiResolver& resolver, LineInfo& lineInfo, RenderTextInfo& renderTextInfo, FloatingObject* lastFloatFromPreviousLine, unsigned consecutiveHyphenatedLines, WordMeasurements& wordMeasurements)
{
reset();
ASSERT(resolver.position().root() == m_block);
bool appliedStartWidth = resolver.position().m_pos > 0;
bool includeEndWidth = true;
LineMidpointState& lineMidpointState = resolver.midpointState();
LineWidth width(m_block, lineInfo.isFirstLine(), requiresIndent(lineInfo.isFirstLine(), lineInfo.previousLineBrokeCleanly(), m_block->style()));
skipLeadingWhitespace(resolver, lineInfo, lastFloatFromPreviousLine, width);
if (resolver.position().atEnd())
return resolver.position();
// This variable is used only if whitespace isn't set to PRE, and it tells us whether
// or not we are currently ignoring whitespace.
bool ignoringSpaces = false;
InlineIterator ignoreStart;
// This variable tracks whether the very last character we saw was a space. We use
// this to detect when we encounter a second space so we know we have to terminate
// a run.
bool currentCharacterIsSpace = false;
bool currentCharacterShouldCollapseIfPreWap = false;
TrailingObjects trailingObjects;
InlineIterator lBreak = resolver.position();
// FIXME: It is error-prone to split the position object out like this.
// Teach this code to work with objects instead of this split tuple.
InlineIterator current = resolver.position();
RenderObject* last = current.m_obj;
bool atStart = true;
bool startingNewParagraph = lineInfo.previousLineBrokeCleanly();
lineInfo.setPreviousLineBrokeCleanly(false);
bool autoWrapWasEverTrueOnLine = false;
bool floatsFitOnLine = true;
// Firefox and Opera will allow a table cell to grow to fit an image inside it under
// very specific circumstances (in order to match common WinIE renderings).
// Not supporting the quirk has caused us to mis-render some real sites. (See Bugzilla 10517.)
RenderStyle* blockStyle = m_block->style();
bool allowImagesToBreak = !m_block->document().inQuirksMode() || !m_block->isTableCell() || !blockStyle->logicalWidth().isIntrinsicOrAuto();
EWhiteSpace currWS = blockStyle->whiteSpace();
EWhiteSpace lastWS = currWS;
while (current.m_obj) {
RenderStyle* currentStyle = current.m_obj->style();
RenderObject* next = bidiNextSkippingEmptyInlines(m_block, current.m_obj);
if (next && next->parent() && !next->parent()->isDescendantOf(current.m_obj->parent()))
includeEndWidth = true;
currWS = current.m_obj->isReplaced() ? current.m_obj->parent()->style()->whiteSpace() : currentStyle->whiteSpace();
lastWS = last->isReplaced() ? last->parent()->style()->whiteSpace() : last->style()->whiteSpace();
bool autoWrap = RenderStyle::autoWrap(currWS);
autoWrapWasEverTrueOnLine = autoWrapWasEverTrueOnLine || autoWrap;
bool preserveNewline = current.m_obj->isSVGInlineText() ? false : RenderStyle::preserveNewline(currWS);
bool collapseWhiteSpace = RenderStyle::collapseWhiteSpace(currWS);
if (current.m_obj->isBR()) {
if (width.fitsOnLine()) {
lBreak.moveToStartOf(current.m_obj);
lBreak.increment();
// A <br> always breaks a line, so don't let the line be collapsed
// away. Also, the space at the end of a line with a <br> does not
// get collapsed away. It only does this if the previous line broke
// cleanly. Otherwise the <br> has no effect on whether the line is
// empty or not.
if (startingNewParagraph)
lineInfo.setEmpty(false, m_block, &width);
trailingObjects.clear();
lineInfo.setPreviousLineBrokeCleanly(true);
// A <br> with clearance always needs a linebox in case the lines below it get dirtied later and
// need to check for floats to clear - so if we're ignoring spaces, stop ignoring them and add a
// run for this object.
if (ignoringSpaces && currentStyle->clear() != CNONE)
ensureLineBoxInsideIgnoredSpaces(lineMidpointState, current.m_obj);
if (!lineInfo.isEmpty())
m_clear = currentStyle->clear();
}
goto end;
}
if (current.m_obj->isOutOfFlowPositioned()) {
// If our original display wasn't an inline type, then we can
// go ahead and determine our static inline position now.
RenderBox* box = toRenderBox(current.m_obj);
bool isInlineType = box->style()->isOriginalDisplayInlineType();
if (!isInlineType)
m_block->setStaticInlinePositionForChild(box, m_block->logicalHeight(), m_block->startOffsetForContent(m_block->logicalHeight()));
else {
// If our original display was an INLINE type, then we can go ahead
// and determine our static y position now.
box->layer()->setStaticBlockPosition(m_block->logicalHeight());
}
// If we're ignoring spaces, we have to stop and include this object and
// then start ignoring spaces again.
if (isInlineType || current.m_obj->container()->isRenderInline()) {
if (ignoringSpaces)
ensureLineBoxInsideIgnoredSpaces(lineMidpointState, current.m_obj);
trailingObjects.appendBoxIfNeeded(box);
} else
m_positionedObjects.append(box);
width.addUncommittedWidth(inlineLogicalWidth(current.m_obj));
// Reset prior line break context characters.
renderTextInfo.m_lineBreakIterator.resetPriorContext();
} else if (current.m_obj->isFloating()) {
RenderBox* floatBox = toRenderBox(current.m_obj);
FloatingObject* f = m_block->insertFloatingObject(floatBox);
// check if it fits in the current line.
// If it does, position it now, otherwise, position
// it after moving to next line (in newLine() func)
// FIXME: Bug 110372: Properly position multiple stacked floats with non-rectangular shape outside.
if (floatsFitOnLine && width.fitsOnLine(f->logicalWidth(m_block->isHorizontalWritingMode()))) {
m_block->positionNewFloatOnLine(f, lastFloatFromPreviousLine, lineInfo, width);
if (lBreak.m_obj == current.m_obj) {
ASSERT(!lBreak.m_pos);
lBreak.increment();
}
} else
floatsFitOnLine = false;
// Update prior line break context characters, using U+FFFD (OBJECT REPLACEMENT CHARACTER) for floating element.
renderTextInfo.m_lineBreakIterator.updatePriorContext(replacementCharacter);
} else if (current.m_obj->isRenderInline()) {
// Right now, we should only encounter empty inlines here.
ASSERT(isEmptyInline(current.m_obj));
RenderInline* flowBox = toRenderInline(current.m_obj);
// Now that some inline flows have line boxes, if we are already ignoring spaces, we need
// to make sure that we stop to include this object and then start ignoring spaces again.
// If this object is at the start of the line, we need to behave like list markers and
// start ignoring spaces.
bool requiresLineBox = alwaysRequiresLineBox(current.m_obj);
if (requiresLineBox || requiresLineBoxForContent(flowBox, lineInfo)) {
// An empty inline that only has line-height, vertical-align or font-metrics will only get a
// line box to affect the height of the line if the rest of the line is not empty.
if (requiresLineBox)
lineInfo.setEmpty(false, m_block, &width);
if (ignoringSpaces) {
trailingObjects.clear();
ensureLineBoxInsideIgnoredSpaces(lineMidpointState, current.m_obj);
} else if (blockStyle->collapseWhiteSpace() && resolver.position().m_obj == current.m_obj
&& shouldSkipWhitespaceAfterStartObject(m_block, current.m_obj, lineMidpointState)) {
// Like with list markers, we start ignoring spaces to make sure that any
// additional spaces we see will be discarded.
currentCharacterShouldCollapseIfPreWap = currentCharacterIsSpace = true;
ignoringSpaces = true;
}
}
width.addUncommittedWidth(inlineLogicalWidth(current.m_obj) + borderPaddingMarginStart(flowBox) + borderPaddingMarginEnd(flowBox));
} else if (current.m_obj->isReplaced()) {
RenderBox* replacedBox = toRenderBox(current.m_obj);
if (atStart)
width.updateAvailableWidth(replacedBox->logicalHeight());
// Break on replaced elements if either has normal white-space.
if ((autoWrap || RenderStyle::autoWrap(lastWS)) && (!current.m_obj->isImage() || allowImagesToBreak)) {
width.commit();
lBreak.moveToStartOf(current.m_obj);
}
if (ignoringSpaces)
stopIgnoringSpaces(lineMidpointState, InlineIterator(0, current.m_obj, 0));
lineInfo.setEmpty(false, m_block, &width);
ignoringSpaces = false;
currentCharacterShouldCollapseIfPreWap = currentCharacterIsSpace = false;
trailingObjects.clear();
// Optimize for a common case. If we can't find whitespace after the list
// item, then this is all moot.
LayoutUnit replacedLogicalWidth = m_block->logicalWidthForChild(replacedBox) + m_block->marginStartForChild(replacedBox) + m_block->marginEndForChild(replacedBox) + inlineLogicalWidth(current.m_obj);
if (current.m_obj->isListMarker()) {
if (blockStyle->collapseWhiteSpace() && shouldSkipWhitespaceAfterStartObject(m_block, current.m_obj, lineMidpointState)) {
// Like with inline flows, we start ignoring spaces to make sure that any
// additional spaces we see will be discarded.
currentCharacterShouldCollapseIfPreWap = currentCharacterIsSpace = true;
ignoringSpaces = true;
}
if (toRenderListMarker(current.m_obj)->isInside())
width.addUncommittedWidth(replacedLogicalWidth);
} else
width.addUncommittedWidth(replacedLogicalWidth);
if (current.m_obj->isRubyRun())
width.applyOverhang(toRenderRubyRun(current.m_obj), last, next);
// Update prior line break context characters, using U+FFFD (OBJECT REPLACEMENT CHARACTER) for replaced element.
renderTextInfo.m_lineBreakIterator.updatePriorContext(replacementCharacter);
} else if (current.m_obj->isText()) {
if (!current.m_pos)
appliedStartWidth = false;
RenderText* t = toRenderText(current.m_obj);
bool isSVGText = t->isSVGInlineText();
if (t->style()->hasTextCombine() && current.m_obj->isCombineText() && !toRenderCombineText(current.m_obj)->isCombined()) {
RenderCombineText* combineRenderer = toRenderCombineText(current.m_obj);
combineRenderer->combineText();
// The length of the renderer's text may have changed. Increment stale iterator positions
if (iteratorIsBeyondEndOfRenderCombineText(lBreak, combineRenderer)) {
ASSERT(iteratorIsBeyondEndOfRenderCombineText(resolver.position(), combineRenderer));
lBreak.increment();
resolver.increment();
}
}
RenderStyle* style = t->style(lineInfo.isFirstLine());
const Font& f = style->font();
bool isFixedPitch = f.isFixedPitch();
unsigned lastSpace = current.m_pos;
float wordSpacing = currentStyle->wordSpacing();
float lastSpaceWordSpacing = 0;
float wordSpacingForWordMeasurement = 0;
float wrapW = width.uncommittedWidth() + inlineLogicalWidth(current.m_obj, !appliedStartWidth, true);
float charWidth = 0;
// Auto-wrapping text should wrap in the middle of a word only if it could not wrap before the word,
// which is only possible if the word is the first thing on the line, that is, if |w| is zero.
bool breakWords = currentStyle->breakWords() && ((autoWrap && !width.committedWidth()) || currWS == PRE);
bool midWordBreak = false;
bool breakAll = currentStyle->wordBreak() == BreakAllWordBreak && autoWrap;
float hyphenWidth = 0;
if (isSVGText) {
breakWords = false;
breakAll = false;
}
if (t->isWordBreak()) {
width.commit();
lBreak.moveToStartOf(current.m_obj);
ASSERT(current.m_pos == t->textLength());
}
if (renderTextInfo.m_text != t) {
renderTextInfo.m_text = t;
renderTextInfo.m_font = &f;
renderTextInfo.m_layout = f.createLayout(t, width.currentWidth(), collapseWhiteSpace);
renderTextInfo.m_lineBreakIterator.resetStringAndReleaseIterator(t->text(), style->locale());
} else if (renderTextInfo.m_layout && renderTextInfo.m_font != &f) {
renderTextInfo.m_font = &f;
renderTextInfo.m_layout = f.createLayout(t, width.currentWidth(), collapseWhiteSpace);
}
TextLayout* textLayout = renderTextInfo.m_layout.get();
// Non-zero only when kerning is enabled and TextLayout isn't used, in which case we measure
// words with their trailing space, then subtract its width.
float wordTrailingSpaceWidth = (f.typesettingFeatures() & Kerning) && !textLayout ? f.width(RenderBlock::constructTextRun(t, f, &space, 1, style)) + wordSpacing : 0;
UChar lastCharacter = renderTextInfo.m_lineBreakIterator.lastCharacter();
UChar secondToLastCharacter = renderTextInfo.m_lineBreakIterator.secondToLastCharacter();
for (; current.m_pos < t->textLength(); current.fastIncrementInTextNode()) {
bool previousCharacterIsSpace = currentCharacterIsSpace;
bool previousCharacterShouldCollapseIfPreWap = currentCharacterShouldCollapseIfPreWap;
UChar c = current.current();
currentCharacterShouldCollapseIfPreWap = currentCharacterIsSpace = c == ' ' || c == '\t' || (!preserveNewline && (c == '\n'));
if (!collapseWhiteSpace || !currentCharacterIsSpace)
lineInfo.setEmpty(false, m_block, &width);
if (c == softHyphen && autoWrap && !hyphenWidth) {
hyphenWidth = measureHyphenWidth(t, f);
width.addUncommittedWidth(hyphenWidth);
}
bool applyWordSpacing = false;
if ((breakAll || breakWords) && !midWordBreak) {
wrapW += charWidth;
bool midWordBreakIsBeforeSurrogatePair = U16_IS_LEAD(c) && current.m_pos + 1 < t->textLength() && U16_IS_TRAIL((*t)[current.m_pos + 1]);
charWidth = textWidth(t, current.m_pos, midWordBreakIsBeforeSurrogatePair ? 2 : 1, f, width.committedWidth() + wrapW, isFixedPitch, collapseWhiteSpace, 0, textLayout);
midWordBreak = width.committedWidth() + wrapW + charWidth > width.availableWidth();
}
bool betweenWords = c == '\n' || (currWS != PRE && !atStart && isBreakable(renderTextInfo.m_lineBreakIterator, current.m_pos, current.m_nextBreakablePosition));
if (betweenWords || midWordBreak) {
bool stoppedIgnoringSpaces = false;
if (ignoringSpaces) {
lastSpaceWordSpacing = 0;
if (!currentCharacterIsSpace) {
// Stop ignoring spaces and begin at this
// new point.
ignoringSpaces = false;
wordSpacingForWordMeasurement = 0;
lastSpace = current.m_pos; // e.g., "Foo goo", don't add in any of the ignored spaces.
stopIgnoringSpaces(lineMidpointState, InlineIterator(0, current.m_obj, current.m_pos));
stoppedIgnoringSpaces = true;
} else {
// Just keep ignoring these spaces.
goto nextCharacter;
}
}
wordMeasurements.grow(wordMeasurements.size() + 1);
WordMeasurement& wordMeasurement = wordMeasurements.last();
wordMeasurement.renderer = t;
wordMeasurement.endOffset = current.m_pos;
wordMeasurement.startOffset = lastSpace;
float additionalTmpW;
if (wordTrailingSpaceWidth && c == ' ')
additionalTmpW = textWidth(t, lastSpace, current.m_pos + 1 - lastSpace, f, width.currentWidth(), isFixedPitch, collapseWhiteSpace, &wordMeasurement.fallbackFonts, textLayout) - wordTrailingSpaceWidth;
else
additionalTmpW = textWidth(t, lastSpace, current.m_pos - lastSpace, f, width.currentWidth(), isFixedPitch, collapseWhiteSpace, &wordMeasurement.fallbackFonts, textLayout);
wordMeasurement.width = additionalTmpW + wordSpacingForWordMeasurement;
additionalTmpW += lastSpaceWordSpacing;
width.addUncommittedWidth(additionalTmpW);
if (!appliedStartWidth) {
width.addUncommittedWidth(inlineLogicalWidth(current.m_obj, true, false));
appliedStartWidth = true;
}
applyWordSpacing = wordSpacing && currentCharacterIsSpace;
if (!width.committedWidth() && autoWrap && !width.fitsOnLine())
width.fitBelowFloats();
if (autoWrap || breakWords) {
// If we break only after white-space, consider the current character
// as candidate width for this line.
bool lineWasTooWide = false;
if (width.fitsOnLine() && currentCharacterIsSpace && currentStyle->breakOnlyAfterWhiteSpace() && !midWordBreak) {
float charWidth = textWidth(t, current.m_pos, 1, f, width.currentWidth(), isFixedPitch, collapseWhiteSpace, &wordMeasurement.fallbackFonts, textLayout) + (applyWordSpacing ? wordSpacing : 0);
// Check if line is too big even without the extra space
// at the end of the line. If it is not, do nothing.
// If the line needs the extra whitespace to be too long,
// then move the line break to the space and skip all
// additional whitespace.
if (!width.fitsOnLine(charWidth)) {
lineWasTooWide = true;
lBreak.moveTo(current.m_obj, current.m_pos, current.m_nextBreakablePosition);
skipTrailingWhitespace(lBreak, lineInfo);
}
}
if (lineWasTooWide || !width.fitsOnLine()) {
if (lBreak.atTextParagraphSeparator()) {
if (!stoppedIgnoringSpaces && current.m_pos > 0)
ensureCharacterGetsLineBox(lineMidpointState, current);
lBreak.increment();
lineInfo.setPreviousLineBrokeCleanly(true);
wordMeasurement.endOffset = lBreak.m_pos;
}
if (lBreak.m_obj && lBreak.m_pos && lBreak.m_obj->isText() && toRenderText(lBreak.m_obj)->textLength() && toRenderText(lBreak.m_obj)->characterAt(lBreak.m_pos - 1) == softHyphen)
m_hyphenated = true;
if (lBreak.m_pos && lBreak.m_pos != (unsigned)wordMeasurement.endOffset && !wordMeasurement.width) {
if (charWidth) {
wordMeasurement.endOffset = lBreak.m_pos;
wordMeasurement.width = charWidth;
}
}
// Didn't fit. Jump to the end unless there's still an opportunity to collapse whitespace.
if (ignoringSpaces || !collapseWhiteSpace || !currentCharacterIsSpace || !previousCharacterIsSpace)
goto end;
} else {
if (!betweenWords || (midWordBreak && !autoWrap))
width.addUncommittedWidth(-additionalTmpW);
if (hyphenWidth) {
// Subtract the width of the soft hyphen out since we fit on a line.
width.addUncommittedWidth(-hyphenWidth);
hyphenWidth = 0;
}
}
}
if (c == '\n' && preserveNewline) {
if (!stoppedIgnoringSpaces && current.m_pos > 0)
ensureCharacterGetsLineBox(lineMidpointState, current);
lBreak.moveTo(current.m_obj, current.m_pos, current.m_nextBreakablePosition);
lBreak.increment();
lineInfo.setPreviousLineBrokeCleanly(true);
return lBreak;
}
if (autoWrap && betweenWords) {
width.commit();
wrapW = 0;
lBreak.moveTo(current.m_obj, current.m_pos, current.m_nextBreakablePosition);
// Auto-wrapping text should not wrap in the middle of a word once it has had an
// opportunity to break after a word.
breakWords = false;
}
if (midWordBreak && !U16_IS_TRAIL(c) && !(category(c) & (Mark_NonSpacing | Mark_Enclosing | Mark_SpacingCombining))) {
// Remember this as a breakable position in case
// adding the end width forces a break.
lBreak.moveTo(current.m_obj, current.m_pos, current.m_nextBreakablePosition);
midWordBreak &= (breakWords || breakAll);
}
if (betweenWords) {
lastSpaceWordSpacing = applyWordSpacing ? wordSpacing : 0;
wordSpacingForWordMeasurement = (applyWordSpacing && wordMeasurement.width) ? wordSpacing : 0;
lastSpace = current.m_pos;
}
if (!ignoringSpaces && currentStyle->collapseWhiteSpace()) {
// If we encounter a newline, or if we encounter a
// second space, we need to go ahead and break up this
// run and enter a mode where we start collapsing spaces.
if (currentCharacterIsSpace && previousCharacterIsSpace) {
ignoringSpaces = true;
// We just entered a mode where we are ignoring
// spaces. Create a midpoint to terminate the run
// before the second space.
startIgnoringSpaces(lineMidpointState, ignoreStart);
trailingObjects.updateMidpointsForTrailingBoxes(lineMidpointState, InlineIterator(), TrailingObjects::DoNotCollapseFirstSpace);
}
}
} else if (ignoringSpaces) {
// Stop ignoring spaces and begin at this
// new point.
ignoringSpaces = false;
lastSpaceWordSpacing = applyWordSpacing ? wordSpacing : 0;
wordSpacingForWordMeasurement = (applyWordSpacing && wordMeasurements.last().width) ? wordSpacing : 0;
lastSpace = current.m_pos; // e.g., "Foo goo", don't add in any of the ignored spaces.
stopIgnoringSpaces(lineMidpointState, InlineIterator(0, current.m_obj, current.m_pos));
}
if (isSVGText && current.m_pos > 0) {
// Force creation of new InlineBoxes for each absolute positioned character (those that start new text chunks).
if (toRenderSVGInlineText(t)->characterStartsNewTextChunk(current.m_pos))
ensureCharacterGetsLineBox(lineMidpointState, current);
}
if (currentCharacterIsSpace && !previousCharacterIsSpace) {
ignoreStart.m_obj = current.m_obj;
ignoreStart.m_pos = current.m_pos;
}
if (!currentCharacterIsSpace && previousCharacterShouldCollapseIfPreWap) {
if (autoWrap && currentStyle->breakOnlyAfterWhiteSpace())
lBreak.moveTo(current.m_obj, current.m_pos, current.m_nextBreakablePosition);
}
if (collapseWhiteSpace && currentCharacterIsSpace && !ignoringSpaces)
trailingObjects.setTrailingWhitespace(toRenderText(current.m_obj));
else if (!currentStyle->collapseWhiteSpace() || !currentCharacterIsSpace)
trailingObjects.clear();
atStart = false;
nextCharacter:
secondToLastCharacter = lastCharacter;
lastCharacter = c;
}
renderTextInfo.m_lineBreakIterator.setPriorContext(lastCharacter, secondToLastCharacter);
wordMeasurements.grow(wordMeasurements.size() + 1);
WordMeasurement& wordMeasurement = wordMeasurements.last();
wordMeasurement.renderer = t;
// IMPORTANT: current.m_pos is > length here!
float additionalTmpW = ignoringSpaces ? 0 : textWidth(t, lastSpace, current.m_pos - lastSpace, f, width.currentWidth(), isFixedPitch, collapseWhiteSpace, &wordMeasurement.fallbackFonts, textLayout);
wordMeasurement.startOffset = lastSpace;
wordMeasurement.endOffset = current.m_pos;
wordMeasurement.width = ignoringSpaces ? 0 : additionalTmpW + wordSpacingForWordMeasurement;
additionalTmpW += lastSpaceWordSpacing;
width.addUncommittedWidth(additionalTmpW + inlineLogicalWidth(current.m_obj, !appliedStartWidth, includeEndWidth));
includeEndWidth = false;
if (!width.fitsOnLine()) {
if (!m_hyphenated && lBreak.previousInSameNode() == softHyphen)
m_hyphenated = true;
if (m_hyphenated)
goto end;
}
} else
ASSERT_NOT_REACHED();
bool checkForBreak = autoWrap;
if (width.committedWidth() && !width.fitsOnLine() && lBreak.m_obj && currWS == NOWRAP)
checkForBreak = true;
else if (next && current.m_obj->isText() && next->isText() && !next->isBR() && (autoWrap || next->style()->autoWrap())) {
if (autoWrap && currentCharacterIsSpace)
checkForBreak = true;
else {
RenderText* nextText = toRenderText(next);
if (nextText->textLength()) {
UChar c = nextText->characterAt(0);
// If the next item on the line is text, and if we did not end with
// a space, then the next text run continues our word (and so it needs to
// keep adding to the uncommitted width. Just update and continue.
checkForBreak = !currentCharacterIsSpace && (c == ' ' || c == '\t' || (c == '\n' && !next->preservesNewline()));
} else if (nextText->isWordBreak())
checkForBreak = true;
if (!width.fitsOnLine() && !width.committedWidth())
width.fitBelowFloats();
bool canPlaceOnLine = width.fitsOnLine() || !autoWrapWasEverTrueOnLine;
if (canPlaceOnLine && checkForBreak) {
width.commit();
lBreak.moveToStartOf(next);
}
}
}
if (checkForBreak && !width.fitsOnLine()) {
// if we have floats, try to get below them.
if (currentCharacterIsSpace && !ignoringSpaces && currentStyle->collapseWhiteSpace())
trailingObjects.clear();
if (width.committedWidth())
goto end;
width.fitBelowFloats();
// |width| may have been adjusted because we got shoved down past a float (thus
// giving us more room), so we need to retest, and only jump to
// the end label if we still don't fit on the line. -dwh
if (!width.fitsOnLine())
goto end;
} else if (blockStyle->autoWrap() && !width.fitsOnLine() && !width.committedWidth()) {
// If the container autowraps but the current child does not then we still need to ensure that it
// wraps and moves below any floats.
width.fitBelowFloats();
}
if (!current.m_obj->isFloatingOrOutOfFlowPositioned()) {
last = current.m_obj;
if (last->isReplaced() && autoWrap && (!last->isImage() || allowImagesToBreak) && (!last->isListMarker() || toRenderListMarker(last)->isInside())) {
width.commit();
lBreak.moveToStartOf(next);
}
}
// Clear out our character space bool, since inline <pre>s don't collapse whitespace
// with adjacent inline normal/nowrap spans.
if (!collapseWhiteSpace)
currentCharacterIsSpace = false;
current.moveToStartOf(next);
atStart = false;
}
if (width.fitsOnLine() || lastWS == NOWRAP)
lBreak.clear();
end:
ShapeInsideInfo* shapeInfo = m_block->layoutShapeInsideInfo();
bool segmentAllowsOverflow = !shapeInfo || !shapeInfo->hasSegments();
if (lBreak == resolver.position() && (!lBreak.m_obj || !lBreak.m_obj->isBR()) && segmentAllowsOverflow) {
// we just add as much as possible
if (blockStyle->whiteSpace() == PRE && !current.m_pos) {
lBreak.moveTo(last, last->isText() ? last->length() : 0);
} else if (lBreak.m_obj) {
// Don't ever break in the middle of a word if we can help it.
// There's no room at all. We just have to be on this line,
// even though we'll spill out.
lBreak.moveTo(current.m_obj, current.m_pos);
}
}
// FIXME Bug 100049: We do not need to consume input in a multi-segment line
// unless no segment will.
// make sure we consume at least one char/object.
if (lBreak == resolver.position() && segmentAllowsOverflow)
lBreak.increment();
// Sanity check our midpoints.
checkMidpoints(lineMidpointState, lBreak);
trailingObjects.updateMidpointsForTrailingBoxes(lineMidpointState, lBreak, TrailingObjects::CollapseFirstSpace);
// We might have made lBreak an iterator that points past the end
// of the object. Do this adjustment to make it point to the start
// of the next object instead to avoid confusing the rest of the
// code.
if (lBreak.m_pos > 0) {
lBreak.m_pos--;
lBreak.increment();
}
return lBreak;
}
void RenderBlock::addOverflowFromInlineChildren()
{
LayoutUnit endPadding = hasOverflowClip() ? paddingEnd() : LayoutUnit();
// FIXME: Need to find another way to do this, since scrollbars could show when we don't want them to.
if (hasOverflowClip() && !endPadding && node() && node()->isRootEditableElement() && style()->isLeftToRightDirection())
endPadding = 1;
for (RootInlineBox* curr = firstRootBox(); curr; curr = curr->nextRootBox()) {
addLayoutOverflow(curr->paddedLayoutOverflowRect(endPadding));
LayoutRect visualOverflow = curr->visualOverflowRect(curr->lineTop(), curr->lineBottom());
addContentsVisualOverflow(visualOverflow);
}
}
void RenderBlock::deleteEllipsisLineBoxes()
{
ETextAlign textAlign = style()->textAlign();
bool ltr = style()->isLeftToRightDirection();
bool firstLine = true;
for (RootInlineBox* curr = firstRootBox(); curr; curr = curr->nextRootBox()) {
if (curr->hasEllipsisBox()) {
curr->clearTruncation();
// Shift the line back where it belongs if we cannot accomodate an ellipsis.
float logicalLeft = pixelSnappedLogicalLeftOffsetForLine(curr->lineTop(), firstLine);
float availableLogicalWidth = logicalRightOffsetForLine(curr->lineTop(), false) - logicalLeft;
float totalLogicalWidth = curr->logicalWidth();
updateLogicalWidthForAlignment(textAlign, curr, 0, logicalLeft, totalLogicalWidth, availableLogicalWidth, 0);
if (ltr)
curr->adjustLogicalPosition((logicalLeft - curr->logicalLeft()), 0);
else
curr->adjustLogicalPosition(-(curr->logicalLeft() - logicalLeft), 0);
}
firstLine = false;
}
}
void RenderBlock::checkLinesForTextOverflow()
{
// Determine the width of the ellipsis using the current font.
// FIXME: CSS3 says this is configurable, also need to use 0x002E (FULL STOP) if horizontal ellipsis is "not renderable"
const Font& font = style()->font();
DEFINE_STATIC_LOCAL(AtomicString, ellipsisStr, (&horizontalEllipsis, 1));
const Font& firstLineFont = firstLineStyle()->font();
int firstLineEllipsisWidth = firstLineFont.width(constructTextRun(this, firstLineFont, &horizontalEllipsis, 1, firstLineStyle()));
int ellipsisWidth = (font == firstLineFont) ? firstLineEllipsisWidth : font.width(constructTextRun(this, font, &horizontalEllipsis, 1, style()));
// For LTR text truncation, we want to get the right edge of our padding box, and then we want to see
// if the right edge of a line box exceeds that. For RTL, we use the left edge of the padding box and
// check the left edge of the line box to see if it is less
// Include the scrollbar for overflow blocks, which means we want to use "contentWidth()"
bool ltr = style()->isLeftToRightDirection();
ETextAlign textAlign = style()->textAlign();
bool firstLine = true;
for (RootInlineBox* curr = firstRootBox(); curr; curr = curr->nextRootBox()) {
// FIXME: Use pixelSnappedLogicalRightOffsetForLine instead of snapping it ourselves once the column workaround in said method has been fixed.
// https://bugs.webkit.org/show_bug.cgi?id=105461
int blockRightEdge = snapSizeToPixel(logicalRightOffsetForLine(curr->lineTop(), firstLine), curr->x());
int blockLeftEdge = pixelSnappedLogicalLeftOffsetForLine(curr->lineTop(), firstLine);
int lineBoxEdge = ltr ? snapSizeToPixel(curr->x() + curr->logicalWidth(), curr->x()) : snapSizeToPixel(curr->x(), 0);
if ((ltr && lineBoxEdge > blockRightEdge) || (!ltr && lineBoxEdge < blockLeftEdge)) {
// This line spills out of our box in the appropriate direction. Now we need to see if the line
// can be truncated. In order for truncation to be possible, the line must have sufficient space to
// accommodate our truncation string, and no replaced elements (images, tables) can overlap the ellipsis
// space.
LayoutUnit width = firstLine ? firstLineEllipsisWidth : ellipsisWidth;
LayoutUnit blockEdge = ltr ? blockRightEdge : blockLeftEdge;
if (curr->lineCanAccommodateEllipsis(ltr, blockEdge, lineBoxEdge, width)) {
float totalLogicalWidth = curr->placeEllipsis(ellipsisStr, ltr, blockLeftEdge, blockRightEdge, width);
float logicalLeft = 0; // We are only intersted in the delta from the base position.
float truncatedWidth = pixelSnappedLogicalRightOffsetForLine(curr->lineTop(), firstLine);
updateLogicalWidthForAlignment(textAlign, curr, 0, logicalLeft, totalLogicalWidth, truncatedWidth, 0);
if (ltr)
curr->adjustLogicalPosition(logicalLeft, 0);
else
curr->adjustLogicalPosition(-(truncatedWidth - (logicalLeft + totalLogicalWidth)), 0);
}
}
firstLine = false;
}
}
bool RenderBlock::positionNewFloatOnLine(FloatingObject* newFloat, FloatingObject* lastFloatFromPreviousLine, LineInfo& lineInfo, LineWidth& width)
{
if (!positionNewFloats())
return false;
width.shrinkAvailableWidthForNewFloatIfNeeded(newFloat);
// We only connect floats to lines for pagination purposes if the floats occur at the start of
// the line and the previous line had a hard break (so this line is either the first in the block
// or follows a <br>).
if (!newFloat->paginationStrut() || !lineInfo.previousLineBrokeCleanly() || !lineInfo.isEmpty())
return true;
const FloatingObjectSet& floatingObjectSet = m_floatingObjects->set();
ASSERT(floatingObjectSet.last() == newFloat);
LayoutUnit floatLogicalTop = newFloat->logicalTop(isHorizontalWritingMode());
int paginationStrut = newFloat->paginationStrut();
if (floatLogicalTop - paginationStrut != logicalHeight() + lineInfo.floatPaginationStrut())
return true;
FloatingObjectSetIterator it = floatingObjectSet.end();
--it; // Last float is newFloat, skip that one.
FloatingObjectSetIterator begin = floatingObjectSet.begin();
while (it != begin) {
--it;
FloatingObject* f = *it;
if (f == lastFloatFromPreviousLine)
break;
if (f->logicalTop(isHorizontalWritingMode()) == logicalHeight() + lineInfo.floatPaginationStrut()) {
f->setPaginationStrut(paginationStrut + f->paginationStrut());
RenderBox* o = f->renderer();
setLogicalTopForChild(o, logicalTopForChild(o) + marginBeforeForChild(o) + paginationStrut);
if (o->isRenderBlock())
o->forceChildLayout();
else
o->layoutIfNeeded();
// Save the old logical top before calling removePlacedObject which will set
// isPlaced to false. Otherwise it will trigger an assert in logicalTopForFloat.
LayoutUnit oldLogicalTop = f->logicalTop(isHorizontalWritingMode());
m_floatingObjects->removePlacedObject(f);
f->setLogicalTop(oldLogicalTop + paginationStrut, isHorizontalWritingMode());
m_floatingObjects->addPlacedObject(f);
}
}
// Just update the line info's pagination strut without altering our logical height yet. If the line ends up containing
// no content, then we don't want to improperly grow the height of the block.
lineInfo.setFloatPaginationStrut(lineInfo.floatPaginationStrut() + paginationStrut);
return true;
}
LayoutUnit RenderBlock::startAlignedOffsetForLine(LayoutUnit position, bool firstLine)
{
ETextAlign textAlign = style()->textAlign();
if (textAlign == TASTART) // FIXME: Handle TAEND here
return startOffsetForLine(position, firstLine);
// updateLogicalWidthForAlignment() handles the direction of the block so no need to consider it here
float totalLogicalWidth = 0;
float logicalLeft = logicalLeftOffsetForLine(logicalHeight(), false);
float availableLogicalWidth = logicalRightOffsetForLine(logicalHeight(), false) - logicalLeft;
updateLogicalWidthForAlignment(textAlign, 0, 0, logicalLeft, totalLogicalWidth, availableLogicalWidth, 0);
if (!style()->isLeftToRightDirection())
return logicalWidth() - logicalLeft;
return logicalLeft;
}
void RenderBlock::layoutLineGridBox()
{
if (style()->lineGrid() == RenderStyle::initialLineGrid()) {
setLineGridBox(0);
return;
}
setLineGridBox(0);
RootInlineBox* lineGridBox = new RootInlineBox(this);
lineGridBox->setHasTextChildren(); // Needed to make the line ascent/descent actually be honored in quirks mode.
lineGridBox->setConstructed();
GlyphOverflowAndFallbackFontsMap textBoxDataMap;
VerticalPositionCache verticalPositionCache;
lineGridBox->alignBoxesInBlockDirection(logicalHeight(), textBoxDataMap, verticalPositionCache);
setLineGridBox(lineGridBox);
// FIXME: If any of the characteristics of the box change compared to the old one, then we need to do a deep dirtying
// (similar to what happens when the page height changes). Ideally, though, we only do this if someone is actually snapping
// to this grid.
}
}