blob: 301300f6e37ded5672bc0d65a1af3ccf2e1c4336 [file] [log] [blame]
/*
* Copyright (C) 2013 Apple Inc. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY APPLE INC. AND ITS CONTRIBUTORS ``AS IS''
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
* THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR ITS CONTRIBUTORS
* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
* THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "config.h"
#include "SimpleLineLayout.h"
#include "FontCache.h"
#include "Frame.h"
#include "GraphicsContext.h"
#include "HTMLTextFormControlElement.h"
#include "HitTestLocation.h"
#include "HitTestRequest.h"
#include "HitTestResult.h"
#include "Hyphenation.h"
#include "InlineTextBox.h"
#include "LineWidth.h"
#include "Logging.h"
#include "PaintInfo.h"
#include "RenderBlockFlow.h"
#include "RenderChildIterator.h"
#include "RenderFragmentedFlow.h"
#include "RenderLineBreak.h"
#include "RenderMultiColumnFlow.h"
#include "RenderStyle.h"
#include "RenderText.h"
#include "RenderTextControl.h"
#include "RenderView.h"
#include "Settings.h"
#include "SimpleLineLayoutFlowContents.h"
#include "SimpleLineLayoutFunctions.h"
#include "SimpleLineLayoutTextFragmentIterator.h"
#include "Text.h"
#include "TextPaintStyle.h"
#include <pal/Logging.h>
namespace WebCore {
namespace SimpleLineLayout {
#ifndef NDEBUG
#define SET_REASON_AND_RETURN_IF_NEEDED(reason, reasons, includeReasons) { \
reasons |= reason; \
if (includeReasons == IncludeReasons::First) \
return reasons; \
}
#else
#define SET_REASON_AND_RETURN_IF_NEEDED(reason, reasons, includeReasons) { \
ASSERT_UNUSED(includeReasons, includeReasons == IncludeReasons::First); \
reasons |= reason; \
return reasons; \
}
#endif
template <typename CharacterType> AvoidanceReasonFlags canUseForCharacter(CharacterType, bool textIsJustified, IncludeReasons);
template<> AvoidanceReasonFlags canUseForCharacter(UChar character, bool textIsJustified, IncludeReasons includeReasons)
{
AvoidanceReasonFlags reasons = { };
if (textIsJustified) {
// Include characters up to Latin Extended-B and some punctuation range when text is justified.
bool isLatinIncludingExtendedB = character <= 0x01FF;
bool isPunctuationRange = character >= 0x2010 && character <= 0x2027;
if (!(isLatinIncludingExtendedB || isPunctuationRange))
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasJustifiedNonLatinText, reasons, includeReasons);
}
if (U16_IS_SURROGATE(character))
SET_REASON_AND_RETURN_IF_NEEDED(FlowTextHasSurrogatePair, reasons, includeReasons);
UCharDirection direction = u_charDirection(character);
if (direction == U_RIGHT_TO_LEFT || direction == U_RIGHT_TO_LEFT_ARABIC
|| direction == U_RIGHT_TO_LEFT_EMBEDDING || direction == U_RIGHT_TO_LEFT_OVERRIDE
|| direction == U_LEFT_TO_RIGHT_EMBEDDING || direction == U_LEFT_TO_RIGHT_OVERRIDE
|| direction == U_POP_DIRECTIONAL_FORMAT || direction == U_BOUNDARY_NEUTRAL)
SET_REASON_AND_RETURN_IF_NEEDED(FlowTextHasDirectionCharacter, reasons, includeReasons);
return reasons;
}
template<> AvoidanceReasonFlags canUseForCharacter(LChar, bool, IncludeReasons)
{
return { };
}
template <typename CharacterType>
static AvoidanceReasonFlags canUseForText(const CharacterType* text, unsigned length, const FontCascade& fontCascade, std::optional<float> lineHeightConstraint,
bool textIsJustified, IncludeReasons includeReasons)
{
AvoidanceReasonFlags reasons = { };
auto& primaryFont = fontCascade.primaryFont();
auto& fontMetrics = primaryFont.fontMetrics();
auto availableSpaceForGlyphAscent = fontMetrics.ascent();
auto availableSpaceForGlyphDescent = fontMetrics.descent();
if (lineHeightConstraint) {
auto lineHeightPadding = *lineHeightConstraint - fontMetrics.height();
availableSpaceForGlyphAscent += lineHeightPadding / 2;
availableSpaceForGlyphDescent += lineHeightPadding / 2;
}
for (unsigned i = 0; i < length; ++i) {
auto character = text[i];
if (FontCascade::treatAsSpace(character))
continue;
if (character == softHyphen)
SET_REASON_AND_RETURN_IF_NEEDED(FlowTextHasSoftHyphen, reasons, includeReasons);
auto characterReasons = canUseForCharacter(character, textIsJustified, includeReasons);
if (characterReasons != NoReason)
SET_REASON_AND_RETURN_IF_NEEDED(characterReasons, reasons, includeReasons);
auto glyphData = fontCascade.glyphDataForCharacter(character, false);
if (!glyphData.isValid() || glyphData.font != &primaryFont)
SET_REASON_AND_RETURN_IF_NEEDED(FlowPrimaryFontIsInsufficient, reasons, includeReasons);
if (lineHeightConstraint) {
auto bounds = primaryFont.boundsForGlyph(glyphData.glyph);
if (ceilf(-bounds.y()) > availableSpaceForGlyphAscent || ceilf(bounds.maxY()) > availableSpaceForGlyphDescent)
SET_REASON_AND_RETURN_IF_NEEDED(FlowFontHasOverflowGlyph, reasons, includeReasons);
}
}
return reasons;
}
static AvoidanceReasonFlags canUseForText(StringView text, const FontCascade& fontCascade, std::optional<float> lineHeightConstraint, bool textIsJustified, IncludeReasons includeReasons)
{
if (text.is8Bit())
return canUseForText(text.characters8(), text.length(), fontCascade, lineHeightConstraint, textIsJustified, includeReasons);
return canUseForText(text.characters16(), text.length(), fontCascade, lineHeightConstraint, textIsJustified, includeReasons);
}
static AvoidanceReasonFlags canUseForFontAndText(const RenderBlockFlow& flow, IncludeReasons includeReasons)
{
AvoidanceReasonFlags reasons = { };
// We assume that all lines have metrics based purely on the primary font.
const auto& style = flow.style();
auto& fontCascade = style.fontCascade();
if (fontCascade.primaryFont().isInterstitial())
SET_REASON_AND_RETURN_IF_NEEDED(FlowIsMissingPrimaryFont, reasons, includeReasons);
std::optional<float> lineHeightConstraint;
if (style.lineBoxContain() & LineBoxContainGlyphs)
lineHeightConstraint = lineHeightFromFlow(flow).toFloat();
bool flowIsJustified = style.textAlign() == JUSTIFY;
for (const auto& textRenderer : childrenOfType<RenderText>(flow)) {
// FIXME: Do not return until after checking all children.
if (textRenderer.text().isEmpty())
SET_REASON_AND_RETURN_IF_NEEDED(FlowTextIsEmpty, reasons, includeReasons);
if (textRenderer.isCombineText())
SET_REASON_AND_RETURN_IF_NEEDED(FlowTextIsCombineText, reasons, includeReasons);
if (textRenderer.isCounter())
SET_REASON_AND_RETURN_IF_NEEDED(FlowTextIsRenderCounter, reasons, includeReasons);
if (textRenderer.isQuote())
SET_REASON_AND_RETURN_IF_NEEDED(FlowTextIsRenderQuote, reasons, includeReasons);
if (textRenderer.isTextFragment())
SET_REASON_AND_RETURN_IF_NEEDED(FlowTextIsTextFragment, reasons, includeReasons);
if (textRenderer.isSVGInlineText())
SET_REASON_AND_RETURN_IF_NEEDED(FlowTextIsSVGInlineText, reasons, includeReasons);
if (!textRenderer.canUseSimpleFontCodePath()) {
// No need to check the code path at this point. We already know it can't be simple.
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasComplexFontCodePath, reasons, includeReasons);
} else {
TextRun run(String(textRenderer.text()));
run.setCharacterScanForCodePath(false);
if (style.fontCascade().codePath(run) != FontCascade::Simple)
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasComplexFontCodePath, reasons, includeReasons);
}
auto textReasons = canUseForText(textRenderer.stringView(), fontCascade, lineHeightConstraint, flowIsJustified, includeReasons);
if (textReasons != NoReason)
SET_REASON_AND_RETURN_IF_NEEDED(textReasons, reasons, includeReasons);
}
return reasons;
}
static AvoidanceReasonFlags canUseForStyle(const RenderStyle& style, IncludeReasons includeReasons)
{
AvoidanceReasonFlags reasons = { };
if (style.textOverflow())
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasTextOverflow, reasons, includeReasons);
if ((style.textDecorationsInEffect() & TextDecorationUnderline) && style.textUnderlinePosition() == TextUnderlinePositionUnder)
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasUnsupportedUnderlineDecoration, reasons, includeReasons);
// Non-visible overflow should be pretty easy to support.
if (style.overflowX() != OVISIBLE || style.overflowY() != OVISIBLE)
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasOverflowNotVisible, reasons, includeReasons);
if (!style.isLeftToRightDirection())
SET_REASON_AND_RETURN_IF_NEEDED(FlowIsNotLTR, reasons, includeReasons);
if (!(style.lineBoxContain() & LineBoxContainBlock))
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasLineBoxContainProperty, reasons, includeReasons);
if (style.writingMode() != TopToBottomWritingMode)
SET_REASON_AND_RETURN_IF_NEEDED(FlowIsNotTopToBottom, reasons, includeReasons);
if (style.lineBreak() != LineBreakAuto)
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasLineBreak, reasons, includeReasons);
if (style.unicodeBidi() != UBNormal)
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasNonNormalUnicodeBiDi, reasons, includeReasons);
if (style.rtlOrdering() != LogicalOrder)
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasRTLOrdering, reasons, includeReasons);
if (style.lineAlign() != LineAlignNone)
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasLineAlignEdges, reasons, includeReasons);
if (style.lineSnap() != LineSnapNone)
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasLineSnap, reasons, includeReasons);
if (style.textEmphasisFill() != TextEmphasisFillFilled || style.textEmphasisMark() != TextEmphasisMarkNone)
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasTextEmphasisFillOrMark, reasons, includeReasons);
if (style.textShadow())
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasTextShadow, reasons, includeReasons);
if (style.hasPseudoStyle(FIRST_LINE))
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasPseudoFirstLine, reasons, includeReasons);
if (style.hasPseudoStyle(FIRST_LETTER))
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasPseudoFirstLetter, reasons, includeReasons);
if (style.hasTextCombine())
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasTextCombine, reasons, includeReasons);
if (style.backgroundClip() == TextFillBox)
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasTextFillBox, reasons, includeReasons);
if (style.borderFit() == BorderFitLines)
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasBorderFitLines, reasons, includeReasons);
if (style.lineBreak() != LineBreakAuto)
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasNonAutoLineBreak, reasons, includeReasons);
if (style.nbspMode() != NBNORMAL)
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasWebKitNBSPMode, reasons, includeReasons);
#if ENABLE(CSS_TRAILING_WORD)
if (style.trailingWord() != TrailingWord::Auto)
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasNonAutoTrailingWord, reasons, includeReasons);
#endif
if (style.hyphens() == HyphensAuto) {
auto textReasons = canUseForText(style.hyphenString(), style.fontCascade(), std::nullopt, false, includeReasons);
if (textReasons != NoReason)
SET_REASON_AND_RETURN_IF_NEEDED(textReasons, reasons, includeReasons);
}
return reasons;
}
AvoidanceReasonFlags canUseForWithReason(const RenderBlockFlow& flow, IncludeReasons includeReasons)
{
#ifndef NDEBUG
static std::once_flag onceFlag;
std::call_once(onceFlag, [] {
PAL::registerNotifyCallback("com.apple.WebKit.showSimpleLineLayoutCoverage", WTF::Function<void()> { printSimpleLineLayoutCoverage });
PAL::registerNotifyCallback("com.apple.WebKit.showSimpleLineLayoutReasons", WTF::Function<void()> { printSimpleLineLayoutBlockList });
PAL::registerNotifyCallback("com.apple.WebKit.toggleSimpleLineLayout", WTF::Function<void()> { toggleSimpleLineLayout });
});
#endif
AvoidanceReasonFlags reasons = { };
if (!flow.settings().simpleLineLayoutEnabled())
SET_REASON_AND_RETURN_IF_NEEDED(FeatureIsDisabled, reasons, includeReasons);
if (!flow.parent())
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasNoParent, reasons, includeReasons);
if (!flow.firstChild())
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasNoChild, reasons, includeReasons);
if (flow.fragmentedFlowState() != RenderObject::NotInsideFragmentedFlow) {
auto* fragmentedFlow = flow.enclosingFragmentedFlow();
if (!is<RenderMultiColumnFlow>(fragmentedFlow))
SET_REASON_AND_RETURN_IF_NEEDED(FlowIsInsideANonMultiColumnThread, reasons, includeReasons);
auto& columnThread = downcast<RenderMultiColumnFlow>(*fragmentedFlow);
if (columnThread.parent() != &flow.view())
SET_REASON_AND_RETURN_IF_NEEDED(MultiColumnFlowIsNotTopLevel, reasons, includeReasons);
if (columnThread.hasColumnSpanner())
SET_REASON_AND_RETURN_IF_NEEDED(MultiColumnFlowHasColumnSpanner, reasons, includeReasons);
auto& style = flow.style();
if (style.verticalAlign() != BASELINE)
SET_REASON_AND_RETURN_IF_NEEDED(MultiColumnFlowVerticalAlign, reasons, includeReasons);
if (style.isFloating())
SET_REASON_AND_RETURN_IF_NEEDED(MultiColumnFlowIsFloating, reasons, includeReasons);
}
if (!flow.isHorizontalWritingMode())
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasHorizonalWritingMode, reasons, includeReasons);
if (flow.hasOutline())
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasOutline, reasons, includeReasons);
if (flow.isRubyText() || flow.isRubyBase())
SET_REASON_AND_RETURN_IF_NEEDED(FlowIsRuby, reasons, includeReasons);
if (flow.style().hangingPunctuation() != NoHangingPunctuation)
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasHangingPunctuation, reasons, includeReasons);
// Printing does pagination without a flow thread.
if (flow.document().paginated())
SET_REASON_AND_RETURN_IF_NEEDED(FlowIsPaginated, reasons, includeReasons);
if (flow.firstLineBlock())
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasPseudoFirstLine, reasons, includeReasons);
if (flow.isAnonymousBlock() && flow.parent()->style().textOverflow())
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasTextOverflow, reasons, includeReasons);
if (flow.parent()->isDeprecatedFlexibleBox())
SET_REASON_AND_RETURN_IF_NEEDED(FlowIsDepricatedFlexBox, reasons, includeReasons);
// FIXME: Placeholders do something strange.
if (is<RenderTextControl>(*flow.parent()) && downcast<RenderTextControl>(*flow.parent()).textFormControlElement().placeholderElement())
SET_REASON_AND_RETURN_IF_NEEDED(FlowParentIsPlaceholderElement, reasons, includeReasons);
// FIXME: Implementation of wrap=hard looks into lineboxes.
if (flow.parent()->isTextArea() && flow.parent()->element()->hasAttributeWithoutSynchronization(HTMLNames::wrapAttr))
SET_REASON_AND_RETURN_IF_NEEDED(FlowParentIsTextAreaWithWrapping, reasons, includeReasons);
// This currently covers <blockflow>#text</blockflow>, <blockflow>#text<br></blockflow> and mutiple (sibling) RenderText cases.
// The <blockflow><inline>#text</inline></blockflow> case is also popular and should be relatively easy to cover.
for (const auto* child = flow.firstChild(); child;) {
if (child->selectionState() != RenderObject::SelectionNone)
SET_REASON_AND_RETURN_IF_NEEDED(FlowChildIsSelected, reasons, includeReasons);
if (is<RenderText>(*child)) {
child = child->nextSibling();
continue;
}
if (is<RenderLineBreak>(child) && !downcast<RenderLineBreak>(*child).isWBR() && child->style().clear() == CNONE) {
child = child->nextSibling();
continue;
}
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasNonSupportedChild, reasons, includeReasons);
break;
}
auto styleReasons = canUseForStyle(flow.style(), includeReasons);
if (styleReasons != NoReason)
SET_REASON_AND_RETURN_IF_NEEDED(styleReasons, reasons, includeReasons);
// We can't use the code path if any lines would need to be shifted below floats. This is because we don't keep per-line y coordinates.
if (flow.containsFloats()) {
float minimumWidthNeeded = std::numeric_limits<float>::max();
for (const auto& textRenderer : childrenOfType<RenderText>(flow)) {
minimumWidthNeeded = std::min(minimumWidthNeeded, textRenderer.minLogicalWidth());
for (auto& floatingObject : *flow.floatingObjectSet()) {
ASSERT(floatingObject);
// if a float has a shape, we cannot tell if content will need to be shifted until after we lay it out,
// since the amount of space is not uniform for the height of the float.
if (floatingObject->renderer().shapeOutsideInfo())
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasUnsupportedFloat, reasons, includeReasons);
float availableWidth = flow.availableLogicalWidthForLine(floatingObject->y(), DoNotIndentText);
if (availableWidth < minimumWidthNeeded)
SET_REASON_AND_RETURN_IF_NEEDED(FlowHasUnsupportedFloat, reasons, includeReasons);
}
}
}
auto fontAndTextReasons = canUseForFontAndText(flow, includeReasons);
if (fontAndTextReasons != NoReason)
SET_REASON_AND_RETURN_IF_NEEDED(fontAndTextReasons, reasons, includeReasons);
return reasons;
}
bool canUseFor(const RenderBlockFlow& flow)
{
return canUseForWithReason(flow, IncludeReasons::First) == NoReason;
}
static float computeLineLeft(ETextAlign textAlign, float availableWidth, float committedWidth, float logicalLeftOffset)
{
float remainingWidth = availableWidth - committedWidth;
float left = logicalLeftOffset;
switch (textAlign) {
case LEFT:
case WEBKIT_LEFT:
case TASTART:
return left;
case RIGHT:
case WEBKIT_RIGHT:
case TAEND:
return left + std::max<float>(remainingWidth, 0);
case CENTER:
case WEBKIT_CENTER:
return left + std::max<float>(remainingWidth / 2, 0);
case JUSTIFY:
ASSERT_NOT_REACHED();
break;
}
ASSERT_NOT_REACHED();
return 0;
}
static void revertAllRunsOnCurrentLine(Layout::RunVector& runs)
{
while (!runs.isEmpty() && !runs.last().isEndOfLine)
runs.removeLast();
}
static void revertRuns(Layout::RunVector& runs, unsigned positionToRevertTo, float width)
{
while (runs.size()) {
auto& lastRun = runs.last();
if (lastRun.end <= positionToRevertTo)
break;
if (lastRun.start >= positionToRevertTo) {
// Revert this run completely.
width -= (lastRun.logicalRight - lastRun.logicalLeft);
runs.removeLast();
} else {
lastRun.logicalRight -= width;
width = 0;
lastRun.end = positionToRevertTo;
// Partial removal.
break;
}
}
}
class LineState {
public:
void setAvailableWidth(float width) { m_availableWidth = width; }
void setCollapedWhitespaceWidth(float width) { m_collapsedWhitespaceWidth = width; }
void setLogicalLeftOffset(float offset) { m_logicalLeftOffset = offset; }
void setOverflowedFragment(const TextFragmentIterator::TextFragment& fragment) { m_overflowedFragment = fragment; }
void setNeedsAllFragments()
{
ASSERT(!m_fragments);
m_fragments.emplace();
}
void setHyphenationDisabled() { m_hyphenationDisabled = true; }
bool isHyphenationDisabled() const { return m_hyphenationDisabled; }
float availableWidth() const { return m_availableWidth; }
float logicalLeftOffset() const { return m_logicalLeftOffset; }
const TextFragmentIterator::TextFragment& overflowedFragment() const { return m_overflowedFragment; }
bool hasTrailingWhitespace() const { return m_lastFragment.type() == TextFragmentIterator::TextFragment::Whitespace; }
TextFragmentIterator::TextFragment lastFragment() const { return m_lastFragment; }
bool isWhitespaceOnly() const { return m_trailingWhitespaceWidth && m_runsWidth == m_trailingWhitespaceWidth; }
bool fits(float extra) const { return m_availableWidth >= m_runsWidth + extra; }
bool firstCharacterFits() const { return m_firstCharacterFits; }
float width() const { return m_runsWidth; }
std::pair<unsigned, bool> expansionOpportunityCount(unsigned from, unsigned to) const
{
ASSERT(m_fragments);
// linebreak runs are special.
if (from == to)
return std::make_pair(0, false);
unsigned expansionOpportunityCount = 0;
auto previousFragmentType = TextFragmentIterator::TextFragment::ContentEnd;
for (const auto& fragment : *m_fragments) {
if (fragment.end() <= from)
continue;
auto currentFragmentType = fragment.type();
auto expansionOpportunity = this->expansionOpportunity(currentFragmentType, previousFragmentType);
if (expansionOpportunity)
++expansionOpportunityCount;
previousFragmentType = currentFragmentType;
if (fragment.end() >= to)
return std::make_pair(expansionOpportunityCount, expansionOpportunity);
}
ASSERT_NOT_REACHED();
return std::make_pair(expansionOpportunityCount, false);
}
bool isEmpty() const
{
if (!m_lastFragment.isValid())
return true;
if (!m_lastCompleteFragment.isEmpty())
return false;
return m_lastFragment.overlapsToNextRenderer();
}
static inline unsigned endPositionForCollapsedFragment(const TextFragmentIterator::TextFragment& fragment)
{
return fragment.isCollapsed() ? fragment.start() + 1 : fragment.end();
}
void appendFragmentAndCreateRunIfNeeded(const TextFragmentIterator::TextFragment& fragment, Layout::RunVector& runs)
{
// Adjust end position while collapsing.
unsigned endPosition = endPositionForCollapsedFragment(fragment);
// New line needs new run.
if (!m_runsWidth) {
ASSERT(!m_uncompletedWidth);
runs.append(Run(fragment.start(), endPosition, m_runsWidth, m_runsWidth + fragment.width(), false, fragment.hasHyphen()));
} else {
// Advance last completed fragment when the previous fragment is all set (including multiple parts across renderers)
if ((m_lastFragment.type() != fragment.type()) || !m_lastFragment.overlapsToNextRenderer()) {
m_lastCompleteFragment = m_lastFragment;
m_uncompletedWidth = fragment.width();
} else
m_uncompletedWidth += fragment.width();
// Collapse neighbouring whitespace, if they are across multiple renderers and are not collapsed yet.
if (m_lastFragment.isCollapsible() && fragment.isCollapsible()) {
ASSERT(m_lastFragment.isLastInRenderer());
if (!m_lastFragment.isCollapsed()) {
// Line width needs to be adjusted so that now it takes collapsing into consideration.
m_runsWidth -= (m_lastFragment.width() - m_collapsedWhitespaceWidth);
}
// This fragment is collapsed completely. No run is needed.
return;
}
if (m_lastFragment.isLastInRenderer() || m_lastFragment.isCollapsed())
runs.append(Run(fragment.start(), endPosition, m_runsWidth, m_runsWidth + fragment.width(), false, fragment.hasHyphen()));
else {
Run& lastRun = runs.last();
lastRun.end = endPosition;
lastRun.logicalRight += fragment.width();
ASSERT(!lastRun.hasHyphen);
lastRun.hasHyphen = fragment.hasHyphen();
}
}
m_runsWidth += fragment.width();
m_lastFragment = fragment;
if (m_fragments)
(*m_fragments).append(fragment);
if (fragment.type() == TextFragmentIterator::TextFragment::Whitespace)
m_trailingWhitespaceWidth += fragment.width();
else {
m_trailingWhitespaceWidth = 0;
m_lastNonWhitespaceFragment = fragment;
}
if (!m_firstCharacterFits)
m_firstCharacterFits = fragment.start() + 1 > endPosition || m_runsWidth <= m_availableWidth;
}
TextFragmentIterator::TextFragment revertToLastCompleteFragment(Layout::RunVector& runs)
{
if (!m_uncompletedWidth) {
ASSERT(m_lastFragment == m_lastCompleteFragment);
return m_lastFragment;
}
ASSERT(m_lastFragment.isValid());
m_runsWidth -= m_uncompletedWidth;
revertRuns(runs, endPositionForCollapsedFragment(m_lastCompleteFragment), m_uncompletedWidth);
m_uncompletedWidth = 0;
ASSERT(m_lastCompleteFragment.isValid());
return m_lastCompleteFragment;
}
void removeTrailingWhitespace(Layout::RunVector& runs)
{
if (m_lastFragment.type() != TextFragmentIterator::TextFragment::Whitespace)
return;
if (m_lastNonWhitespaceFragment) {
auto needsReverting = m_lastNonWhitespaceFragment->end() != m_lastFragment.end();
// Trailing whitespace fragment might actually have zero length.
ASSERT(needsReverting || !m_trailingWhitespaceWidth);
if (needsReverting) {
revertRuns(runs, m_lastNonWhitespaceFragment->end(), m_trailingWhitespaceWidth);
m_runsWidth -= m_trailingWhitespaceWidth;
}
m_trailingWhitespaceWidth = 0;
m_lastFragment = *m_lastNonWhitespaceFragment;
return;
}
// This line is all whitespace.
revertAllRunsOnCurrentLine(runs);
m_runsWidth = 0;
m_trailingWhitespaceWidth = 0;
// FIXME: Make m_lastFragment optional.
m_lastFragment = TextFragmentIterator::TextFragment();
}
private:
bool expansionOpportunity(TextFragmentIterator::TextFragment::Type currentFragmentType, TextFragmentIterator::TextFragment::Type previousFragmentType) const
{
return (currentFragmentType == TextFragmentIterator::TextFragment::Whitespace
|| (currentFragmentType == TextFragmentIterator::TextFragment::NonWhitespace && previousFragmentType == TextFragmentIterator::TextFragment::NonWhitespace));
}
float m_availableWidth { 0 };
float m_logicalLeftOffset { 0 };
float m_runsWidth { 0 };
TextFragmentIterator::TextFragment m_overflowedFragment;
TextFragmentIterator::TextFragment m_lastFragment;
std::optional<TextFragmentIterator::TextFragment> m_lastNonWhitespaceFragment;
TextFragmentIterator::TextFragment m_lastCompleteFragment;
float m_uncompletedWidth { 0 };
float m_trailingWhitespaceWidth { 0 }; // Use this to remove trailing whitespace without re-mesuring the text.
float m_collapsedWhitespaceWidth { 0 };
// Having one character on the line does not necessarily mean it actually fits.
// First character of the first fragment might be forced on to the current line even if it does not fit.
bool m_firstCharacterFits { false };
bool m_hyphenationDisabled { false };
std::optional<Vector<TextFragmentIterator::TextFragment, 30>> m_fragments;
};
static bool preWrap(const TextFragmentIterator::Style& style)
{
return style.wrapLines && !style.collapseWhitespace;
}
static void removeTrailingWhitespace(LineState& lineState, Layout::RunVector& runs, const TextFragmentIterator& textFragmentIterator)
{
if (!lineState.hasTrailingWhitespace())
return;
// Remove collapsed whitespace, or non-collapsed pre-wrap whitespace, unless it's the only content on the line -so removing the whitesapce
// would produce an empty line.
const auto& style = textFragmentIterator.style();
bool collapseWhitespace = style.collapseWhitespace | preWrap(style);
if (!collapseWhitespace)
return;
if (preWrap(style) && lineState.isWhitespaceOnly())
return;
lineState.removeTrailingWhitespace(runs);
}
static void updateLineConstrains(const RenderBlockFlow& flow, LineState& line, const LineState& previousLine, unsigned& numberOfPrecedingLinesWithHyphen, const TextFragmentIterator::Style& style, bool isFirstLine)
{
bool shouldApplyTextIndent = !flow.isAnonymous() || flow.parent()->firstChild() == &flow;
LayoutUnit height = flow.logicalHeight();
LayoutUnit logicalHeight = flow.minLineHeightForReplacedRenderer(false, 0);
line.setLogicalLeftOffset(flow.logicalLeftOffsetForLine(height, DoNotIndentText, logicalHeight) + (shouldApplyTextIndent && isFirstLine ? flow.textIndentOffset() : LayoutUnit(0)));
float logicalRightOffset = flow.logicalRightOffsetForLine(height, DoNotIndentText, logicalHeight);
line.setAvailableWidth(std::max<float>(0, logicalRightOffset - line.logicalLeftOffset()));
if (style.textAlign == JUSTIFY)
line.setNeedsAllFragments();
numberOfPrecedingLinesWithHyphen = (previousLine.isEmpty() || !previousLine.lastFragment().hasHyphen()) ? 0 : numberOfPrecedingLinesWithHyphen + 1;
if (style.hyphenLimitLines && numberOfPrecedingLinesWithHyphen >= *style.hyphenLimitLines)
line.setHyphenationDisabled();
line.setCollapedWhitespaceWidth(style.font.spaceWidth() + style.wordSpacing);
}
struct SplitFragmentData {
unsigned position;
float width;
};
static std::optional<unsigned> hyphenPositionForFragment(SplitFragmentData splitData, const TextFragmentIterator::TextFragment& fragmentToSplit,
const LineState& line, const TextFragmentIterator& textFragmentIterator, float availableWidth)
{
auto& style = textFragmentIterator.style();
if (!style.shouldHyphenate || line.isHyphenationDisabled())
return std::nullopt;
// FIXME: This is a workaround for webkit.org/b/169613. See maxPrefixWidth computation in tryHyphenating().
// It does not work properly with non-collapsed leading tabs when font is enlarged.
auto adjustedAvailableWidth = availableWidth - style.hyphenStringWidth;
if (!line.isEmpty())
adjustedAvailableWidth += style.font.spaceWidth();
if (!enoughWidthForHyphenation(adjustedAvailableWidth, style.font.pixelSize()))
return std::nullopt;
// We might be able to fit the hyphen at the split position.
auto splitPositionWithHyphen = splitData.position;
// Find a splitting position where hyphen surely fits.
unsigned start = fragmentToSplit.start();
auto leftSideWidth = splitData.width;
while (leftSideWidth + style.hyphenStringWidth > availableWidth) {
if (--splitPositionWithHyphen <= start)
return std::nullopt; // No space for hyphen.
leftSideWidth -= textFragmentIterator.textWidth(splitPositionWithHyphen, splitPositionWithHyphen + 1, 0);
}
ASSERT(splitPositionWithHyphen > start);
return textFragmentIterator.lastHyphenPosition(fragmentToSplit, splitPositionWithHyphen + 1);
}
static SplitFragmentData split(const TextFragmentIterator::TextFragment& fragment, float availableWidth,
const TextFragmentIterator& textFragmentIterator)
{
ASSERT(availableWidth >= 0);
auto left = fragment.start();
// Pathological case of (extremely)long string and narrow lines.
// Adjust the range so that we can pick a reasonable midpoint.
auto averageCharacterWidth = fragment.width() / fragment.length();
auto right = std::min<unsigned>(left + (2 * availableWidth / averageCharacterWidth), fragment.end() - 1);
// Preserve the left width for the final split position so that we don't need to remeasure the left side again.
float leftSideWidth = 0;
while (left < right) {
auto middle = (left + right) / 2;
auto width = textFragmentIterator.textWidth(fragment.start(), middle + 1, 0);
if (width < availableWidth) {
left = middle + 1;
leftSideWidth = width;
} else if (width > availableWidth)
right = middle;
else {
right = middle + 1;
leftSideWidth = width;
break;
}
}
return { right, leftSideWidth };
}
static TextFragmentIterator::TextFragment splitFragmentToFitLine(TextFragmentIterator::TextFragment& fragmentToSplit,
const LineState& line, const TextFragmentIterator& textFragmentIterator)
{
auto availableWidth = line.availableWidth() - line.width();
auto splitFragmentData = split(fragmentToSplit, availableWidth, textFragmentIterator);
std::optional<unsigned> hyphenPosition = std::nullopt;
// Does first character fit this line?
if (splitFragmentData.position == fragmentToSplit.start()) {
// Keep at least one character on empty lines.
if (line.isEmpty())
splitFragmentData.width = textFragmentIterator.textWidth(fragmentToSplit.start(), ++splitFragmentData.position, 0);
} else {
hyphenPosition = hyphenPositionForFragment(splitFragmentData, fragmentToSplit, line, textFragmentIterator, availableWidth);
if (hyphenPosition) {
splitFragmentData.position = *hyphenPosition;
splitFragmentData.width = textFragmentIterator.textWidth(fragmentToSplit.start(), splitFragmentData.position, 0);
}
}
// If the right side surely does not fit the (next)line, we don't need the width to be kerning/ligature adjusted.
// Part of it gets re-measured as the left side during next split.
// This saves measuring long chunk of text repeatedly (see pathological case at ::split).
auto rightSideWidth = fragmentToSplit.width() - splitFragmentData.width;
if (rightSideWidth < 2 * availableWidth)
rightSideWidth = textFragmentIterator.textWidth(splitFragmentData.position, fragmentToSplit.end(), 0);
return hyphenPosition ? fragmentToSplit.splitWithHyphen(splitFragmentData.position, textFragmentIterator.style().hyphenStringWidth,
splitFragmentData.width, rightSideWidth) : fragmentToSplit.split(splitFragmentData.position, splitFragmentData.width, rightSideWidth);
}
enum PreWrapLineBreakRule { Preserve, Ignore };
static TextFragmentIterator::TextFragment consumeLineBreakIfNeeded(const TextFragmentIterator::TextFragment& fragment, TextFragmentIterator& textFragmentIterator, LineState& line, Layout::RunVector& runs,
PreWrapLineBreakRule preWrapLineBreakRule = PreWrapLineBreakRule::Preserve)
{
if (!fragment.isLineBreak())
return fragment;
bool isHardLinebreak = fragment.type() == TextFragmentIterator::TextFragment::HardLineBreak;
// <br> always produces a run. (required by testing output)
if (isHardLinebreak)
line.appendFragmentAndCreateRunIfNeeded(fragment, runs);
auto& style = textFragmentIterator.style();
if (style.preserveNewline && preWrapLineBreakRule == PreWrapLineBreakRule::Preserve) {
if (!isHardLinebreak)
return fragment;
}
return textFragmentIterator.nextTextFragment();
}
static TextFragmentIterator::TextFragment skipWhitespaceIfNeeded(const TextFragmentIterator::TextFragment& fragment, TextFragmentIterator& textFragmentIterator)
{
if (!textFragmentIterator.style().collapseWhitespace)
return fragment;
TextFragmentIterator::TextFragment firstNonWhitespaceFragment = fragment;
while (firstNonWhitespaceFragment.type() == TextFragmentIterator::TextFragment::Whitespace)
firstNonWhitespaceFragment = textFragmentIterator.nextTextFragment();
return firstNonWhitespaceFragment;
}
static TextFragmentIterator::TextFragment firstFragment(TextFragmentIterator& textFragmentIterator, LineState& currentLine, const LineState& previousLine, Layout::RunVector& runs)
{
// Handle overflow fragment from previous line.
auto overflowedFragment = previousLine.overflowedFragment();
if (overflowedFragment.isEmpty())
return skipWhitespaceIfNeeded(textFragmentIterator.nextTextFragment(), textFragmentIterator);
if (overflowedFragment.type() != TextFragmentIterator::TextFragment::Whitespace)
return overflowedFragment;
// Leading whitespace handling.
auto& style = textFragmentIterator.style();
// Special overflow pre-wrap whitespace handling: skip the overflowed whitespace (even when style says not-collapsible)
// if we manage to fit at least one character on the previous line.
auto preWrapIsOn = preWrap(style);
if ((style.collapseWhitespace || preWrapIsOn) && previousLine.firstCharacterFits()) {
// If skipping the whitespace puts us on a newline, skip the newline too as we already wrapped the line.
auto firstFragmentCandidate = consumeLineBreakIfNeeded(textFragmentIterator.nextTextFragment(), textFragmentIterator, currentLine, runs,
preWrapIsOn ? PreWrapLineBreakRule::Ignore : PreWrapLineBreakRule::Preserve);
return skipWhitespaceIfNeeded(firstFragmentCandidate, textFragmentIterator);
}
return skipWhitespaceIfNeeded(overflowedFragment, textFragmentIterator);
}
static void forceFragmentToLine(LineState& line, TextFragmentIterator& textFragmentIterator, Layout::RunVector& runs, const TextFragmentIterator::TextFragment& fragment)
{
line.appendFragmentAndCreateRunIfNeeded(fragment, runs);
// Check if there are more fragments to add to the current line.
auto nextFragment = textFragmentIterator.nextTextFragment();
if (fragment.overlapsToNextRenderer()) {
while (true) {
if (nextFragment.type() != fragment.type())
break;
line.appendFragmentAndCreateRunIfNeeded(nextFragment, runs);
// Does it overlap to the next segment?
if (!nextFragment.overlapsToNextRenderer())
return;
nextFragment = textFragmentIterator.nextTextFragment();
}
}
// When the forced fragment is followed by either whitespace and/or line break, consume them too, otherwise we end up with an extra whitespace and/or line break.
nextFragment = skipWhitespaceIfNeeded(nextFragment, textFragmentIterator);
nextFragment = consumeLineBreakIfNeeded(nextFragment, textFragmentIterator, line, runs);
line.setOverflowedFragment(nextFragment);
}
static bool createLineRuns(LineState& line, const LineState& previousLine, Layout::RunVector& runs, TextFragmentIterator& textFragmentIterator)
{
const auto& style = textFragmentIterator.style();
bool lineCanBeWrapped = style.wrapLines || style.breakFirstWordOnOverflow || style.breakAnyWordOnOverflow;
auto fragment = firstFragment(textFragmentIterator, line, previousLine, runs);
while (fragment.type() != TextFragmentIterator::TextFragment::ContentEnd) {
// Hard and soft linebreaks.
if (fragment.isLineBreak()) {
// Add the new line fragment only if there's nothing on the line. (otherwise the extra new line character would show up at the end of the content.)
if (line.isEmpty() || fragment.type() == TextFragmentIterator::TextFragment::HardLineBreak) {
if (style.textAlign == RIGHT || style.textAlign == WEBKIT_RIGHT)
line.removeTrailingWhitespace(runs);
line.appendFragmentAndCreateRunIfNeeded(fragment, runs);
}
break;
}
if (lineCanBeWrapped && !line.fits(fragment.width())) {
// Overflow wrapping behaviour:
// 1. Whitesapce collapse on: whitespace is skipped. Jump to next line.
// 2. Whitespace collapse off: whitespace is wrapped.
// 3. First, non-whitespace fragment is either wrapped or kept on the line. (depends on overflow-wrap)
// 5. Non-whitespace fragment when there's already another fragment on the line either gets wrapped (word-break: break-all)
// or gets pushed to the next line.
bool emptyLine = line.isEmpty();
// Whitespace fragment.
if (fragment.type() == TextFragmentIterator::TextFragment::Whitespace) {
if (style.collapseWhitespace) {
// Push collapased whitespace to the next line.
line.setOverflowedFragment(fragment);
break;
}
// Split the whitespace; left part stays on this line, right is pushed to next line.
line.setOverflowedFragment(splitFragmentToFitLine(fragment, line, textFragmentIterator));
line.appendFragmentAndCreateRunIfNeeded(fragment, runs);
break;
}
// Non-whitespace fragment. (!style.wrapLines: bug138102(preserve existing behavior)
if (((emptyLine && style.breakFirstWordOnOverflow) || style.breakAnyWordOnOverflow) || !style.wrapLines) {
// Split the fragment; (modified)fragment stays on this line, overflowedFragment is pushed to next line.
line.setOverflowedFragment(splitFragmentToFitLine(fragment, line, textFragmentIterator));
line.appendFragmentAndCreateRunIfNeeded(fragment, runs);
break;
}
ASSERT(fragment.type() == TextFragmentIterator::TextFragment::NonWhitespace);
// Find out if this non-whitespace fragment has a hyphen where we can break.
if (style.shouldHyphenate) {
auto fragmentToSplit = fragment;
// Split and check if we actually ended up with a hyphen.
auto overflowFragment = splitFragmentToFitLine(fragmentToSplit, line, textFragmentIterator);
if (fragmentToSplit.hasHyphen()) {
line.setOverflowedFragment(overflowFragment);
line.appendFragmentAndCreateRunIfNeeded(fragmentToSplit, runs);
break;
}
// No hyphen, no split.
}
// Non-breakable non-whitespace first fragment. Add it to the current line. -it overflows though.
if (emptyLine) {
forceFragmentToLine(line, textFragmentIterator, runs, fragment);
break;
}
// Non-breakable non-whitespace fragment when there's already content on the line. Push it to the next line.
ASSERT(line.lastFragment().isValid());
if (line.lastFragment().overlapsToNextRenderer()) {
// Check if this fragment is a continuation of a previous segment. In such cases, we need to remove them all.
textFragmentIterator.revertToEndOfFragment(line.revertToLastCompleteFragment(runs));
break;
}
line.setOverflowedFragment(fragment);
break;
}
line.appendFragmentAndCreateRunIfNeeded(fragment, runs);
// Find the next text fragment.
fragment = textFragmentIterator.nextTextFragment(line.width());
}
return (fragment.type() == TextFragmentIterator::TextFragment::ContentEnd && line.overflowedFragment().isEmpty()) || line.overflowedFragment().type() == TextFragmentIterator::TextFragment::ContentEnd;
}
static ExpansionBehavior expansionBehavior(bool isAfterExpansion, bool lastRunOnLine)
{
ExpansionBehavior expansionBehavior;
expansionBehavior = isAfterExpansion ? ForbidLeadingExpansion : AllowLeadingExpansion;
expansionBehavior |= lastRunOnLine ? ForbidTrailingExpansion : AllowTrailingExpansion;
return expansionBehavior;
}
static void justifyRuns(const LineState& line, Layout::RunVector& runs, unsigned firstRunIndex)
{
ASSERT(runs.size());
auto widthToDistribute = line.availableWidth() - line.width();
if (widthToDistribute <= 0)
return;
auto lastRunIndex = runs.size() - 1;
ASSERT(firstRunIndex <= lastRunIndex);
Vector<std::pair<unsigned, ExpansionBehavior>> expansionOpportunityList;
unsigned expansionOpportunityCountOnThisLine = 0;
auto isAfterExpansion = true;
for (auto i = firstRunIndex; i <= lastRunIndex; ++i) {
const auto& run = runs.at(i);
unsigned opportunityCountInRun = 0;
std::tie(opportunityCountInRun, isAfterExpansion) = line.expansionOpportunityCount(run.start, run.end);
expansionOpportunityList.append(std::make_pair(opportunityCountInRun, expansionBehavior(isAfterExpansion, i == lastRunIndex)));
expansionOpportunityCountOnThisLine += opportunityCountInRun;
}
if (!expansionOpportunityCountOnThisLine)
return;
ASSERT(expansionOpportunityList.size() == lastRunIndex - firstRunIndex + 1);
auto expansion = widthToDistribute / expansionOpportunityCountOnThisLine;
float accumulatedExpansion = 0;
for (auto i = firstRunIndex; i <= lastRunIndex; ++i) {
auto& run = runs.at(i);
unsigned opportunityCountInRun;
std::tie(opportunityCountInRun, run.expansionBehavior) = expansionOpportunityList.at(i - firstRunIndex);
run.expansion = opportunityCountInRun * expansion;
run.logicalLeft += accumulatedExpansion;
run.logicalRight += (accumulatedExpansion + run.expansion);
accumulatedExpansion += run.expansion;
}
}
static ETextAlign textAlignForLine(const TextFragmentIterator::Style& style, bool lastLine)
{
// Fallback to LEFT (START) alignment for non-collapsable content and for the last line before a forced break or the end of the block.
auto textAlign = style.textAlign;
if (textAlign == JUSTIFY && (!style.collapseWhitespace || lastLine))
textAlign = LEFT;
return textAlign;
}
static void closeLineEndingAndAdjustRuns(LineState& line, Layout::RunVector& runs, std::optional<unsigned> lastRunIndexOfPreviousLine, unsigned& lineCount,
const TextFragmentIterator& textFragmentIterator, bool lastLineInFlow)
{
if (!runs.size() || (lastRunIndexOfPreviousLine && runs.size() - 1 == lastRunIndexOfPreviousLine.value()))
return;
removeTrailingWhitespace(line, runs, textFragmentIterator);
if (!runs.size())
return;
// Adjust runs' position by taking line's alignment into account.
const auto& style = textFragmentIterator.style();
auto firstRunIndex = lastRunIndexOfPreviousLine ? lastRunIndexOfPreviousLine.value() + 1 : 0;
auto lineLogicalLeft = line.logicalLeftOffset();
auto textAlign = textAlignForLine(style, lastLineInFlow || (line.lastFragment().isValid() && line.lastFragment().type() == TextFragmentIterator::TextFragment::HardLineBreak));
if (textAlign == JUSTIFY)
justifyRuns(line, runs, firstRunIndex);
else
lineLogicalLeft = computeLineLeft(textAlign, line.availableWidth(), line.width(), line.logicalLeftOffset());
for (auto i = firstRunIndex; i < runs.size(); ++i) {
runs[i].logicalLeft += lineLogicalLeft;
runs[i].logicalRight += lineLogicalLeft;
}
runs.last().isEndOfLine = true;
++lineCount;
}
static void createTextRuns(Layout::RunVector& runs, RenderBlockFlow& flow, unsigned& lineCount)
{
LayoutUnit borderAndPaddingBefore = flow.borderAndPaddingBefore();
LayoutUnit lineHeight = lineHeightFromFlow(flow);
LineState line;
unsigned numberOfPrecedingLinesWithHyphen = 0;
bool isEndOfContent = false;
TextFragmentIterator textFragmentIterator = TextFragmentIterator(flow);
std::optional<unsigned> lastRunIndexOfPreviousLine;
do {
flow.setLogicalHeight(lineHeight * lineCount + borderAndPaddingBefore);
LineState previousLine = line;
line = LineState();
updateLineConstrains(flow, line, previousLine, numberOfPrecedingLinesWithHyphen, textFragmentIterator.style(), !lineCount);
isEndOfContent = createLineRuns(line, previousLine, runs, textFragmentIterator);
closeLineEndingAndAdjustRuns(line, runs, lastRunIndexOfPreviousLine, lineCount, textFragmentIterator, isEndOfContent);
if (runs.size())
lastRunIndexOfPreviousLine = runs.size() - 1;
} while (!isEndOfContent);
}
std::unique_ptr<Layout> create(RenderBlockFlow& flow)
{
unsigned lineCount = 0;
Layout::RunVector runs;
createTextRuns(runs, flow, lineCount);
return Layout::create(runs, lineCount);
}
std::unique_ptr<Layout> Layout::create(const RunVector& runVector, unsigned lineCount)
{
void* slot = WTF::fastMalloc(sizeof(Layout) + sizeof(Run) * runVector.size());
return std::unique_ptr<Layout>(new (NotNull, slot) Layout(runVector, lineCount));
}
Layout::Layout(const RunVector& runVector, unsigned lineCount)
: m_lineCount(lineCount)
, m_runCount(runVector.size())
{
memcpy(m_runs, runVector.data(), m_runCount * sizeof(Run));
}
Layout::~Layout()
{
simpleLineLayoutWillBeDeleted(*this);
}
}
}