Source/WebCore/rendering/mathml/RenderMathMLUnderOver.cpp - WebKit - Git at Google

 /*
  * Copyright (C) 2009 Alex Milowski (alex@milowski.com). All rights reserved.
  * Copyright (C) 2016 Igalia S.L.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions
  * are met:
  * 1. Redistributions of source code must retain the above copyright
  *    notice, this list of conditions and the following disclaimer.
  * 2. Redistributions in binary form must reproduce the above copyright
  *    notice, this list of conditions and the following disclaimer in the
  *    documentation and/or other materials provided with the distribution.
  *
  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND 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 THE COPYRIGHT
  * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
  * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
  * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
  * DATA, OR PROFITS; OR BUSINESS 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 "RenderMathMLUnderOver.h"

 #if ENABLE(MATHML)

 #include "MathMLElement.h"
 #include "MathMLOperatorDictionary.h"
 #include "MathMLUnderOverElement.h"
 #include "RenderIterator.h"
 #include "RenderMathMLOperator.h"
 #include <wtf/IsoMallocInlines.h>

 namespace WebCore {

 WTF_MAKE_ISO_ALLOCATED_IMPL(RenderMathMLUnderOver);

 RenderMathMLUnderOver::RenderMathMLUnderOver(MathMLUnderOverElement& element, RenderStyle&& style)
     : RenderMathMLScripts(element, WTFMove(style))
 {
 }

 MathMLUnderOverElement& RenderMathMLUnderOver::element() const
 {
     return static_cast<MathMLUnderOverElement&>(nodeForNonAnonymous());
 }

 static RenderMathMLOperator* horizontalStretchyOperator(const RenderBox& box)
 {
     if (!is<RenderMathMLBlock>(box))
         return nullptr;

     auto* renderOperator = downcast<RenderMathMLBlock>(box).unembellishedOperator();
     if (!renderOperator)
         return nullptr;

     if (!renderOperator->isStretchy() || renderOperator->isVertical() || renderOperator->isStretchWidthLocked())
         return nullptr;

     return renderOperator;
 }

 static void fixLayoutAfterStretch(RenderBox& ancestor, RenderMathMLOperator& stretchyOperator)
 {
     stretchyOperator.setStretchWidthLocked(true);
     stretchyOperator.setNeedsLayout();
     ancestor.layoutIfNeeded();
     stretchyOperator.setStretchWidthLocked(false);
 }

 void RenderMathMLUnderOver::stretchHorizontalOperatorsAndLayoutChildren()
 {
     ASSERT(isValid());
     ASSERT(needsLayout());

     // We apply horizontal stretchy rules from the MathML spec (sections 3.2.5.8.3 and 3.2.5.8.4), which
     // can be roughly summarized as "stretching opersators to the maximum widths of all children" and
     // minor variations of that algorithm do not affect the result. However, the spec is a bit ambiguous
     // for embellished operators (section 3.2.5.7.3) and different approaches can lead to significant
     // stretch size differences. We made the following decisions:
     // - The unstretched size is the embellished operator width with the <mo> at the core unstretched.
     // - In general, the target size is just the maximum widths of non-stretchy children because the
     // embellishments could make widths significantly larger.
     // - In the edge case when all operators of stretchy, we follow the specification and take the
     // maximum of all unstretched sizes.
     // - The <mo> at the core is stretched to cover the target size, even if the embellished operator
     // might become much wider.

     Vector<RenderBox*, 3> embellishedOperators;
     Vector<RenderMathMLOperator*, 3> stretchyOperators;
     bool isAllStretchyOperators = true;
     LayoutUnit stretchWidth;

     for (auto* child = firstChildBox(); child; child = child->nextSiblingBox()) {
         if (auto* stretchyOperator = horizontalStretchyOperator(*child)) {
             embellishedOperators.append(child);
             stretchyOperators.append(stretchyOperator);
         } else {
             isAllStretchyOperators = false;
             child->layoutIfNeeded();
             stretchWidth = std::max(stretchWidth, child->logicalWidth());
         }
     }

     if (isAllStretchyOperators) {
         for (size_t i = 0; i < embellishedOperators.size(); i++) {
             stretchyOperators[i]->resetStretchSize();
             fixLayoutAfterStretch(*embellishedOperators[i], *stretchyOperators[i]);
             stretchWidth = std::max(stretchWidth, embellishedOperators[i]->logicalWidth());
         }
     }

     for (size_t i = 0; i < embellishedOperators.size(); i++) {
         stretchyOperators[i]->stretchTo(stretchWidth);
         fixLayoutAfterStretch(*embellishedOperators[i], *stretchyOperators[i]);
     }
 }

 bool RenderMathMLUnderOver::isValid() const
 {
     // Verify whether the list of children is valid:
     // <munder> base under </munder>
     // <mover> base over </mover>
     // <munderover> base under over </munderover>
     auto* child = firstChildBox();
     if (!child)
         return false;
     child = child->nextSiblingBox();
     if (!child)
         return false;
     child = child->nextSiblingBox();
     switch (scriptType()) {
     case MathMLScriptsElement::ScriptType::Over:
     case MathMLScriptsElement::ScriptType::Under:
         return !child;
     case MathMLScriptsElement::ScriptType::UnderOver:
         return child && !child->nextSiblingBox();
     default:
         ASSERT_NOT_REACHED();
         return false;
     }
 }

 bool RenderMathMLUnderOver::shouldMoveLimits()
 {
     if (auto* renderOperator = unembellishedOperator())
         return renderOperator->shouldMoveLimits();
     return false;
 }

 RenderBox& RenderMathMLUnderOver::base() const
 {
     ASSERT(isValid());
     return *firstChildBox();
 }

 RenderBox& RenderMathMLUnderOver::under() const
 {
     ASSERT(isValid());
     ASSERT(scriptType() == MathMLScriptsElement::ScriptType::Under || scriptType() == MathMLScriptsElement::ScriptType::UnderOver);
     return *firstChildBox()->nextSiblingBox();
 }

 RenderBox& RenderMathMLUnderOver::over() const
 {
     ASSERT(isValid());
     ASSERT(scriptType() == MathMLScriptsElement::ScriptType::Over || scriptType() == MathMLScriptsElement::ScriptType::UnderOver);
     auto* secondChild = firstChildBox()->nextSiblingBox();
     return scriptType() == MathMLScriptsElement::ScriptType::Over ? *secondChild : *secondChild->nextSiblingBox();
 }


 void RenderMathMLUnderOver::computePreferredLogicalWidths()
 {
     ASSERT(preferredLogicalWidthsDirty());

     if (!isValid()) {
         m_minPreferredLogicalWidth = m_maxPreferredLogicalWidth = 0;
         setPreferredLogicalWidthsDirty(false);
         return;
     }

     if (shouldMoveLimits()) {
         RenderMathMLScripts::computePreferredLogicalWidths();
         return;
     }

     LayoutUnit preferredWidth = base().maxPreferredLogicalWidth();

     if (scriptType() == MathMLScriptsElement::ScriptType::Under || scriptType() == MathMLScriptsElement::ScriptType::UnderOver)
         preferredWidth = std::max(preferredWidth, under().maxPreferredLogicalWidth());

     if (scriptType() == MathMLScriptsElement::ScriptType::Over || scriptType() == MathMLScriptsElement::ScriptType::UnderOver)
         preferredWidth = std::max(preferredWidth, over().maxPreferredLogicalWidth());

     m_minPreferredLogicalWidth = m_maxPreferredLogicalWidth = preferredWidth;

     setPreferredLogicalWidthsDirty(false);
 }

 LayoutUnit RenderMathMLUnderOver::horizontalOffset(const RenderBox& child) const
 {
     return (logicalWidth() - child.logicalWidth()) / 2;
 }

 bool RenderMathMLUnderOver::hasAccent(bool accentUnder) const
 {
     ASSERT(scriptType() == MathMLScriptsElement::ScriptType::UnderOver || (accentUnder && scriptType() == MathMLScriptsElement::ScriptType::Under) || (!accentUnder && scriptType() == MathMLScriptsElement::ScriptType::Over));

     const MathMLElement::BooleanValue& attributeValue = accentUnder ? element().accentUnder() : element().accent();
     if (attributeValue == MathMLElement::BooleanValue::True)
         return true;
     if (attributeValue == MathMLElement::BooleanValue::False)
         return false;
     RenderBox& script = accentUnder ? under() : over();
     if (!is<RenderMathMLBlock>(script))
         return false;
     auto* scriptOperator = downcast<RenderMathMLBlock>(script).unembellishedOperator();
     return scriptOperator && scriptOperator->hasOperatorFlag(MathMLOperatorDictionary::Accent);
 }

 RenderMathMLUnderOver::VerticalParameters RenderMathMLUnderOver::verticalParameters() const
 {
     VerticalParameters parameters;

     // By default, we set all values to zero.
     parameters.underGapMin = 0;
     parameters.overGapMin = 0;
     parameters.underShiftMin = 0;
     parameters.overShiftMin = 0;
     parameters.underExtraDescender = 0;
     parameters.overExtraAscender = 0;
     parameters.accentBaseHeight = 0;

     const auto& primaryFont = style().fontCascade().primaryFont();
     auto* mathData = primaryFont.mathData();
     if (!mathData) {
         // The MATH table specification does not really provide any suggestions, except for some underbar/overbar values and AccentBaseHeight.
         LayoutUnit defaultLineThickness = ruleThicknessFallback();
         parameters.underGapMin = 3 * defaultLineThickness;
         parameters.overGapMin = 3 * defaultLineThickness;
         parameters.underExtraDescender = defaultLineThickness;
         parameters.overExtraAscender = defaultLineThickness;
         parameters.accentBaseHeight = style().fontMetrics().xHeight();
         parameters.useUnderOverBarFallBack = true;
         return parameters;
     }

     if (is<RenderMathMLBlock>(base())) {
         if (auto* baseOperator = downcast<RenderMathMLBlock>(base()).unembellishedOperator()) {
             if (baseOperator->hasOperatorFlag(MathMLOperatorDictionary::LargeOp)) {
                 // The base is a large operator so we read UpperLimit/LowerLimit constants from the MATH table.
                 parameters.underGapMin = mathData->getMathConstant(primaryFont, OpenTypeMathData::LowerLimitGapMin);
                 parameters.overGapMin = mathData->getMathConstant(primaryFont, OpenTypeMathData::UpperLimitGapMin);
                 parameters.underShiftMin = mathData->getMathConstant(primaryFont, OpenTypeMathData::LowerLimitBaselineDropMin);
                 parameters.overShiftMin = mathData->getMathConstant(primaryFont, OpenTypeMathData::UpperLimitBaselineRiseMin);
                 parameters.useUnderOverBarFallBack = false;
                 return parameters;
             }
             if (baseOperator->isStretchy() && !baseOperator->isVertical()) {
                 // The base is a horizontal stretchy operator, so we read StretchStack constants from the MATH table.
                 parameters.underGapMin = mathData->getMathConstant(primaryFont, OpenTypeMathData::StretchStackGapBelowMin);
                 parameters.overGapMin = mathData->getMathConstant(primaryFont, OpenTypeMathData::StretchStackGapAboveMin);
                 parameters.underShiftMin = mathData->getMathConstant(primaryFont, OpenTypeMathData::StretchStackBottomShiftDown);
                 parameters.overShiftMin = mathData->getMathConstant(primaryFont, OpenTypeMathData::StretchStackTopShiftUp);
                 parameters.useUnderOverBarFallBack = false;
                 return parameters;
             }
         }
     }

     // By default, we just use the underbar/overbar constants.
     parameters.underGapMin = mathData->getMathConstant(primaryFont, OpenTypeMathData::UnderbarVerticalGap);
     parameters.overGapMin = mathData->getMathConstant(primaryFont, OpenTypeMathData::OverbarVerticalGap);
     parameters.underExtraDescender = mathData->getMathConstant(primaryFont, OpenTypeMathData::UnderbarExtraDescender);
     parameters.overExtraAscender = mathData->getMathConstant(primaryFont, OpenTypeMathData::OverbarExtraAscender);
     parameters.accentBaseHeight = mathData->getMathConstant(primaryFont, OpenTypeMathData::AccentBaseHeight);
     parameters.useUnderOverBarFallBack = true;
     return parameters;
 }

 void RenderMathMLUnderOver::layoutBlock(bool relayoutChildren, LayoutUnit pageLogicalHeight)
 {
     ASSERT(needsLayout());

     if (!relayoutChildren && simplifiedLayout())
         return;

     if (!isValid()) {
         layoutInvalidMarkup(relayoutChildren);
         return;
     }

     if (shouldMoveLimits()) {
         RenderMathMLScripts::layoutBlock(relayoutChildren, pageLogicalHeight);
         return;
     }

     recomputeLogicalWidth();

     stretchHorizontalOperatorsAndLayoutChildren();

     ASSERT(!base().needsLayout());
     ASSERT(scriptType() == MathMLScriptsElement::ScriptType::Over || !under().needsLayout());
     ASSERT(scriptType() == MathMLScriptsElement::ScriptType::Under || !over().needsLayout());

     LayoutUnit logicalWidth = base().logicalWidth();
     if (scriptType() == MathMLScriptsElement::ScriptType::Under || scriptType() == MathMLScriptsElement::ScriptType::UnderOver)
         logicalWidth = std::max(logicalWidth, under().logicalWidth());
     if (scriptType() == MathMLScriptsElement::ScriptType::Over || scriptType() == MathMLScriptsElement::ScriptType::UnderOver)
         logicalWidth = std::max(logicalWidth, over().logicalWidth());
     setLogicalWidth(logicalWidth);

     VerticalParameters parameters = verticalParameters();
     LayoutUnit verticalOffset;
     if (scriptType() == MathMLScriptsElement::ScriptType::Over || scriptType() == MathMLScriptsElement::ScriptType::UnderOver) {
         verticalOffset += parameters.overExtraAscender;
         over().setLocation(LayoutPoint(horizontalOffset(over()), verticalOffset));
         if (parameters.useUnderOverBarFallBack) {
             verticalOffset += over().logicalHeight();
             if (hasAccent()) {
                 LayoutUnit baseAscent = ascentForChild(base());
                 if (baseAscent < parameters.accentBaseHeight)
                     verticalOffset += parameters.accentBaseHeight - baseAscent;
             } else
                 verticalOffset += parameters.overGapMin;
         } else {
             LayoutUnit overAscent = ascentForChild(over());
             verticalOffset += std::max(over().logicalHeight() + parameters.overGapMin, overAscent + parameters.overShiftMin);
         }
     }
     base().setLocation(LayoutPoint(horizontalOffset(base()), verticalOffset));
     verticalOffset += base().logicalHeight();
     if (scriptType() == MathMLScriptsElement::ScriptType::Under || scriptType() == MathMLScriptsElement::ScriptType::UnderOver) {
         if (parameters.useUnderOverBarFallBack) {
             if (!hasAccentUnder())
                 verticalOffset += parameters.underGapMin;
         } else {
             LayoutUnit underAscent = ascentForChild(under());
             verticalOffset += std::max(parameters.underGapMin, parameters.underShiftMin - underAscent);
         }
         under().setLocation(LayoutPoint(horizontalOffset(under()), verticalOffset));
         verticalOffset += under().logicalHeight();
         verticalOffset += parameters.underExtraDescender;
     }

     setLogicalHeight(verticalOffset);

     layoutPositionedObjects(relayoutChildren);

     updateScrollInfoAfterLayout();

     clearNeedsLayout();
 }

 }

 #endif // ENABLE(MATHML)
	/*
	* Copyright (C) 2009 Alex Milowski (alex@milowski.com). All rights reserved.
	* Copyright (C) 2016 Igalia S.L.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions
	* are met:
	* 1. Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* 2. Redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in the
	* documentation and/or other materials provided with the distribution.
	*
	* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND 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 THE COPYRIGHT
	* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	* DATA, OR PROFITS; OR BUSINESS 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 "RenderMathMLUnderOver.h"

	#if ENABLE(MATHML)

	#include "MathMLElement.h"
	#include "MathMLOperatorDictionary.h"
	#include "MathMLUnderOverElement.h"
	#include "RenderIterator.h"
	#include "RenderMathMLOperator.h"
	#include <wtf/IsoMallocInlines.h>

	namespace WebCore {

	WTF_MAKE_ISO_ALLOCATED_IMPL(RenderMathMLUnderOver);

	RenderMathMLUnderOver::RenderMathMLUnderOver(MathMLUnderOverElement& element, RenderStyle&& style)
	: RenderMathMLScripts(element, WTFMove(style))
	{
	}

	MathMLUnderOverElement& RenderMathMLUnderOver::element() const
	{
	return static_cast<MathMLUnderOverElement&>(nodeForNonAnonymous());
	}

	static RenderMathMLOperator* horizontalStretchyOperator(const RenderBox& box)
	{
	if (!is<RenderMathMLBlock>(box))
	return nullptr;

	auto* renderOperator = downcast<RenderMathMLBlock>(box).unembellishedOperator();
	if (!renderOperator)
	return nullptr;

	if (!renderOperator->isStretchy() \|\| renderOperator->isVertical() \|\| renderOperator->isStretchWidthLocked())
	return nullptr;

	return renderOperator;
	}

	static void fixLayoutAfterStretch(RenderBox& ancestor, RenderMathMLOperator& stretchyOperator)
	{
	stretchyOperator.setStretchWidthLocked(true);
	stretchyOperator.setNeedsLayout();
	ancestor.layoutIfNeeded();
	stretchyOperator.setStretchWidthLocked(false);
	}

	void RenderMathMLUnderOver::stretchHorizontalOperatorsAndLayoutChildren()
	{
	ASSERT(isValid());
	ASSERT(needsLayout());

	// We apply horizontal stretchy rules from the MathML spec (sections 3.2.5.8.3 and 3.2.5.8.4), which
	// can be roughly summarized as "stretching opersators to the maximum widths of all children" and
	// minor variations of that algorithm do not affect the result. However, the spec is a bit ambiguous
	// for embellished operators (section 3.2.5.7.3) and different approaches can lead to significant
	// stretch size differences. We made the following decisions:
	// - The unstretched size is the embellished operator width with the <mo> at the core unstretched.
	// - In general, the target size is just the maximum widths of non-stretchy children because the
	// embellishments could make widths significantly larger.
	// - In the edge case when all operators of stretchy, we follow the specification and take the
	// maximum of all unstretched sizes.
	// - The <mo> at the core is stretched to cover the target size, even if the embellished operator
	// might become much wider.

	Vector<RenderBox*, 3> embellishedOperators;
	Vector<RenderMathMLOperator*, 3> stretchyOperators;
	bool isAllStretchyOperators = true;
	LayoutUnit stretchWidth;

	for (auto* child = firstChildBox(); child; child = child->nextSiblingBox()) {
	if (auto* stretchyOperator = horizontalStretchyOperator(*child)) {
	embellishedOperators.append(child);
	stretchyOperators.append(stretchyOperator);
	} else {
	isAllStretchyOperators = false;
	child->layoutIfNeeded();
	stretchWidth = std::max(stretchWidth, child->logicalWidth());
	}
	}

	if (isAllStretchyOperators) {
	for (size_t i = 0; i < embellishedOperators.size(); i++) {
	stretchyOperators[i]->resetStretchSize();
	fixLayoutAfterStretch(embellishedOperators[i], stretchyOperators[i]);
	stretchWidth = std::max(stretchWidth, embellishedOperators[i]->logicalWidth());
	}
	}

	for (size_t i = 0; i < embellishedOperators.size(); i++) {
	stretchyOperators[i]->stretchTo(stretchWidth);
	fixLayoutAfterStretch(embellishedOperators[i], stretchyOperators[i]);
	}
	}

	bool RenderMathMLUnderOver::isValid() const
	{
	// Verify whether the list of children is valid:
	// <munder> base under </munder>
	// <mover> base over </mover>
	// <munderover> base under over </munderover>
	auto* child = firstChildBox();
	if (!child)
	return false;
	child = child->nextSiblingBox();
	if (!child)
	return false;
	child = child->nextSiblingBox();
	switch (scriptType()) {
	case MathMLScriptsElement::ScriptType::Over:
	case MathMLScriptsElement::ScriptType::Under:
	return !child;
	case MathMLScriptsElement::ScriptType::UnderOver:
	return child && !child->nextSiblingBox();
	default:
	ASSERT_NOT_REACHED();
	return false;
	}
	}

	bool RenderMathMLUnderOver::shouldMoveLimits()
	{
	if (auto* renderOperator = unembellishedOperator())
	return renderOperator->shouldMoveLimits();
	return false;
	}

	RenderBox& RenderMathMLUnderOver::base() const
	{
	ASSERT(isValid());
	return *firstChildBox();
	}

	RenderBox& RenderMathMLUnderOver::under() const
	{
	ASSERT(isValid());
	ASSERT(scriptType() == MathMLScriptsElement::ScriptType::Under \|\| scriptType() == MathMLScriptsElement::ScriptType::UnderOver);
	return *firstChildBox()->nextSiblingBox();
	}

	RenderBox& RenderMathMLUnderOver::over() const
	{
	ASSERT(isValid());
	ASSERT(scriptType() == MathMLScriptsElement::ScriptType::Over \|\| scriptType() == MathMLScriptsElement::ScriptType::UnderOver);
	auto* secondChild = firstChildBox()->nextSiblingBox();
	return scriptType() == MathMLScriptsElement::ScriptType::Over ? secondChild : secondChild->nextSiblingBox();
	}


	void RenderMathMLUnderOver::computePreferredLogicalWidths()
	{
	ASSERT(preferredLogicalWidthsDirty());

	if (!isValid()) {
	m_minPreferredLogicalWidth = m_maxPreferredLogicalWidth = 0;
	setPreferredLogicalWidthsDirty(false);
	return;
	}

	if (shouldMoveLimits()) {
	RenderMathMLScripts::computePreferredLogicalWidths();
	return;
	}

	LayoutUnit preferredWidth = base().maxPreferredLogicalWidth();

	if (scriptType() == MathMLScriptsElement::ScriptType::Under \|\| scriptType() == MathMLScriptsElement::ScriptType::UnderOver)
	preferredWidth = std::max(preferredWidth, under().maxPreferredLogicalWidth());

	if (scriptType() == MathMLScriptsElement::ScriptType::Over \|\| scriptType() == MathMLScriptsElement::ScriptType::UnderOver)
	preferredWidth = std::max(preferredWidth, over().maxPreferredLogicalWidth());

	m_minPreferredLogicalWidth = m_maxPreferredLogicalWidth = preferredWidth;

	setPreferredLogicalWidthsDirty(false);
	}

	LayoutUnit RenderMathMLUnderOver::horizontalOffset(const RenderBox& child) const
	{
	return (logicalWidth() - child.logicalWidth()) / 2;
	}

	bool RenderMathMLUnderOver::hasAccent(bool accentUnder) const
	{
	ASSERT(scriptType() == MathMLScriptsElement::ScriptType::UnderOver \|\| (accentUnder && scriptType() == MathMLScriptsElement::ScriptType::Under) \|\| (!accentUnder && scriptType() == MathMLScriptsElement::ScriptType::Over));

	const MathMLElement::BooleanValue& attributeValue = accentUnder ? element().accentUnder() : element().accent();
	if (attributeValue == MathMLElement::BooleanValue::True)
	return true;
	if (attributeValue == MathMLElement::BooleanValue::False)
	return false;
	RenderBox& script = accentUnder ? under() : over();
	if (!is<RenderMathMLBlock>(script))
	return false;
	auto* scriptOperator = downcast<RenderMathMLBlock>(script).unembellishedOperator();
	return scriptOperator && scriptOperator->hasOperatorFlag(MathMLOperatorDictionary::Accent);
	}

	RenderMathMLUnderOver::VerticalParameters RenderMathMLUnderOver::verticalParameters() const
	{
	VerticalParameters parameters;

	// By default, we set all values to zero.
	parameters.underGapMin = 0;
	parameters.overGapMin = 0;
	parameters.underShiftMin = 0;
	parameters.overShiftMin = 0;
	parameters.underExtraDescender = 0;
	parameters.overExtraAscender = 0;
	parameters.accentBaseHeight = 0;

	const auto& primaryFont = style().fontCascade().primaryFont();
	auto* mathData = primaryFont.mathData();
	if (!mathData) {
	// The MATH table specification does not really provide any suggestions, except for some underbar/overbar values and AccentBaseHeight.
	LayoutUnit defaultLineThickness = ruleThicknessFallback();
	parameters.underGapMin = 3 * defaultLineThickness;
	parameters.overGapMin = 3 * defaultLineThickness;
	parameters.underExtraDescender = defaultLineThickness;
	parameters.overExtraAscender = defaultLineThickness;
	parameters.accentBaseHeight = style().fontMetrics().xHeight();
	parameters.useUnderOverBarFallBack = true;
	return parameters;
	}

	if (is<RenderMathMLBlock>(base())) {
	if (auto* baseOperator = downcast<RenderMathMLBlock>(base()).unembellishedOperator()) {
	if (baseOperator->hasOperatorFlag(MathMLOperatorDictionary::LargeOp)) {
	// The base is a large operator so we read UpperLimit/LowerLimit constants from the MATH table.
	parameters.underGapMin = mathData->getMathConstant(primaryFont, OpenTypeMathData::LowerLimitGapMin);
	parameters.overGapMin = mathData->getMathConstant(primaryFont, OpenTypeMathData::UpperLimitGapMin);
	parameters.underShiftMin = mathData->getMathConstant(primaryFont, OpenTypeMathData::LowerLimitBaselineDropMin);
	parameters.overShiftMin = mathData->getMathConstant(primaryFont, OpenTypeMathData::UpperLimitBaselineRiseMin);
	parameters.useUnderOverBarFallBack = false;
	return parameters;
	}
	if (baseOperator->isStretchy() && !baseOperator->isVertical()) {
	// The base is a horizontal stretchy operator, so we read StretchStack constants from the MATH table.
	parameters.underGapMin = mathData->getMathConstant(primaryFont, OpenTypeMathData::StretchStackGapBelowMin);
	parameters.overGapMin = mathData->getMathConstant(primaryFont, OpenTypeMathData::StretchStackGapAboveMin);
	parameters.underShiftMin = mathData->getMathConstant(primaryFont, OpenTypeMathData::StretchStackBottomShiftDown);
	parameters.overShiftMin = mathData->getMathConstant(primaryFont, OpenTypeMathData::StretchStackTopShiftUp);
	parameters.useUnderOverBarFallBack = false;
	return parameters;
	}
	}
	}

	// By default, we just use the underbar/overbar constants.
	parameters.underGapMin = mathData->getMathConstant(primaryFont, OpenTypeMathData::UnderbarVerticalGap);
	parameters.overGapMin = mathData->getMathConstant(primaryFont, OpenTypeMathData::OverbarVerticalGap);
	parameters.underExtraDescender = mathData->getMathConstant(primaryFont, OpenTypeMathData::UnderbarExtraDescender);
	parameters.overExtraAscender = mathData->getMathConstant(primaryFont, OpenTypeMathData::OverbarExtraAscender);
	parameters.accentBaseHeight = mathData->getMathConstant(primaryFont, OpenTypeMathData::AccentBaseHeight);
	parameters.useUnderOverBarFallBack = true;
	return parameters;
	}

	void RenderMathMLUnderOver::layoutBlock(bool relayoutChildren, LayoutUnit pageLogicalHeight)
	{
	ASSERT(needsLayout());

	if (!relayoutChildren && simplifiedLayout())
	return;

	if (!isValid()) {
	layoutInvalidMarkup(relayoutChildren);
	return;
	}

	if (shouldMoveLimits()) {
	RenderMathMLScripts::layoutBlock(relayoutChildren, pageLogicalHeight);
	return;
	}

	recomputeLogicalWidth();

	stretchHorizontalOperatorsAndLayoutChildren();

	ASSERT(!base().needsLayout());
	ASSERT(scriptType() == MathMLScriptsElement::ScriptType::Over \|\| !under().needsLayout());
	ASSERT(scriptType() == MathMLScriptsElement::ScriptType::Under \|\| !over().needsLayout());

	LayoutUnit logicalWidth = base().logicalWidth();
	if (scriptType() == MathMLScriptsElement::ScriptType::Under \|\| scriptType() == MathMLScriptsElement::ScriptType::UnderOver)
	logicalWidth = std::max(logicalWidth, under().logicalWidth());
	if (scriptType() == MathMLScriptsElement::ScriptType::Over \|\| scriptType() == MathMLScriptsElement::ScriptType::UnderOver)
	logicalWidth = std::max(logicalWidth, over().logicalWidth());
	setLogicalWidth(logicalWidth);

	VerticalParameters parameters = verticalParameters();
	LayoutUnit verticalOffset;
	if (scriptType() == MathMLScriptsElement::ScriptType::Over \|\| scriptType() == MathMLScriptsElement::ScriptType::UnderOver) {
	verticalOffset += parameters.overExtraAscender;
	over().setLocation(LayoutPoint(horizontalOffset(over()), verticalOffset));
	if (parameters.useUnderOverBarFallBack) {
	verticalOffset += over().logicalHeight();
	if (hasAccent()) {
	LayoutUnit baseAscent = ascentForChild(base());
	if (baseAscent < parameters.accentBaseHeight)
	verticalOffset += parameters.accentBaseHeight - baseAscent;
	} else
	verticalOffset += parameters.overGapMin;
	} else {
	LayoutUnit overAscent = ascentForChild(over());
	verticalOffset += std::max(over().logicalHeight() + parameters.overGapMin, overAscent + parameters.overShiftMin);
	}
	}
	base().setLocation(LayoutPoint(horizontalOffset(base()), verticalOffset));
	verticalOffset += base().logicalHeight();
	if (scriptType() == MathMLScriptsElement::ScriptType::Under \|\| scriptType() == MathMLScriptsElement::ScriptType::UnderOver) {
	if (parameters.useUnderOverBarFallBack) {
	if (!hasAccentUnder())
	verticalOffset += parameters.underGapMin;
	} else {
	LayoutUnit underAscent = ascentForChild(under());
	verticalOffset += std::max(parameters.underGapMin, parameters.underShiftMin - underAscent);
	}
	under().setLocation(LayoutPoint(horizontalOffset(under()), verticalOffset));
	verticalOffset += under().logicalHeight();
	verticalOffset += parameters.underExtraDescender;
	}

	setLogicalHeight(verticalOffset);

	layoutPositionedObjects(relayoutChildren);

	updateScrollInfoAfterLayout();

	clearNeedsLayout();
	}

	}

	#endif // ENABLE(MATHML)