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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 tw=80: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
/*
* structs that contain the data provided by ComputedStyle, the
* internal API for computed style data for an element
*/
#include "nsStyleStruct.h"
#include "nsStyleStructInlines.h"
#include "nsStyleConsts.h"
#include "nsString.h"
#include "nsPresContext.h"
#include "nsIWidget.h"
#include "nsCRTGlue.h"
#include "nsCSSProps.h"
#include "nsDeviceContext.h"
#include "nsStyleUtil.h"
#include "nsIURIMutator.h"
#include "nsCOMPtr.h"
#include "nsBidiUtils.h"
#include "nsLayoutUtils.h"
#include "imgIRequest.h"
#include "imgIContainer.h"
#include "CounterStyleManager.h"
#include "mozilla/dom/AnimationEffectBinding.h" // for PlaybackDirection
#include "mozilla/dom/BaseKeyframeTypesBinding.h" // for CompositeOperation
#include "mozilla/dom/DocGroup.h"
#include "mozilla/dom/ImageTracker.h"
#include "mozilla/CORSMode.h"
#include "mozilla/ClearOnShutdown.h"
#include "mozilla/GeckoBindings.h"
#include "mozilla/PreferenceSheet.h"
#include "mozilla/SchedulerGroup.h"
#include "mozilla/StaticPresData.h"
#include "mozilla/Likely.h"
#include "nsIURI.h"
#include "mozilla/dom/Document.h"
#include "mozilla/dom/DocumentInlines.h"
#include <algorithm>
#include "ImageLoader.h"
#include "mozilla/StaticPrefs_layout.h"
using namespace mozilla;
using namespace mozilla::dom;
MOZ_RUNINIT static const nscoord kMediumBorderWidth =
nsPresContext::CSSPixelsToAppUnits(3);
// We set the size limit of style structs to 504 bytes so that when they
// are allocated by Servo side with Arc, the total size doesn't exceed
// 512 bytes, which minimizes allocator slop.
static constexpr size_t kStyleStructSizeLimit = 504;
template <typename Struct, size_t Actual, size_t Limit>
struct AssertSizeIsLessThan {
static_assert(Actual == sizeof(Struct), "Bogus invocation");
static_assert(Actual <= Limit,
"Style struct became larger than the size limit");
static constexpr bool instantiate = true;
};
#define STYLE_STRUCT(name_) \
static_assert(AssertSizeIsLessThan<nsStyle##name_, sizeof(nsStyle##name_), \
kStyleStructSizeLimit>::instantiate, \
"");
#include "nsStyleStructList.h"
#undef STYLE_STRUCT
bool StyleCssUrlData::operator==(const StyleCssUrlData& aOther) const {
// This very intentionally avoids comparing LoadData and such.
const auto& extra = extra_data.get();
const auto& otherExtra = aOther.extra_data.get();
if (extra.BaseURI() != otherExtra.BaseURI() ||
extra.Principal() != otherExtra.Principal() ||
cors_mode != aOther.cors_mode) {
// NOTE(emilio): This does pointer comparison, but it's what URLValue used
// to do. That's ok though since this is only used for style struct diffing.
return false;
}
return serialization == aOther.serialization;
}
StyleLoadData::~StyleLoadData() { Gecko_LoadData_Drop(this); }
already_AddRefed<nsIURI> StyleComputedUrl::ResolveLocalRef(
nsIURI* aBase) const {
nsCOMPtr<nsIURI> result = GetURI();
if (result && IsLocalRef()) {
nsCString ref;
result->GetRef(ref);
nsresult rv = NS_MutateURI(aBase).SetRef(ref).Finalize(result);
if (NS_FAILED(rv)) {
// If setting the ref failed, just return the original URI.
result = aBase;
}
}
return result.forget();
}
already_AddRefed<nsIURI> StyleComputedUrl::ResolveLocalRef(
const nsIContent* aContent) const {
return ResolveLocalRef(aContent->GetBaseURI());
}
void StyleComputedUrl::ResolveImage(Document& aDocument,
const StyleComputedUrl* aOldImage) {
MOZ_DIAGNOSTIC_ASSERT(NS_IsMainThread());
StyleLoadData& data = LoadData();
MOZ_ASSERT(!(data.flags & StyleLoadDataFlags::TRIED_TO_RESOLVE_IMAGE));
data.flags |= StyleLoadDataFlags::TRIED_TO_RESOLVE_IMAGE;
MOZ_ASSERT(NS_IsMainThread());
// 1440305, but that seems too risky, and a lot of work to do before 60.
//
// Once that's fixed, the "old style" argument to TriggerImageLoads can go
// away, and same for mSharedCount in the image loader and so on.
const bool reuseProxy = nsContentUtils::IsChromeDoc(&aDocument) &&
aOldImage && aOldImage->IsImageResolved() &&
*this == *aOldImage;
RefPtr<imgRequestProxy> request;
if (reuseProxy) {
request = aOldImage->LoadData().resolved_image;
if (request) {
css::ImageLoader::NoteSharedLoad(request);
}
} else {
request = css::ImageLoader::LoadImage(*this, aDocument);
}
if (!request) {
return;
}
data.resolved_image = request.forget().take();
// Boost priority now that we know the image is present in the ComputedStyle
// of some frame.
data.resolved_image->BoostPriority(imgIRequest::CATEGORY_FRAME_STYLE);
}
/**
* Runnable to release the image request's mRequestProxy
* and mImageTracker on the main thread, and to perform
* any necessary unlocking and untracking of the image.
*/
class StyleImageRequestCleanupTask final : public mozilla::Runnable {
public:
explicit StyleImageRequestCleanupTask(StyleLoadData& aData)
: mozilla::Runnable("StyleImageRequestCleanupTask"),
mRequestProxy(dont_AddRef(aData.resolved_image)) {
MOZ_ASSERT(mRequestProxy);
aData.resolved_image = nullptr;
}
NS_IMETHOD Run() final {
MOZ_ASSERT(NS_IsMainThread());
css::ImageLoader::UnloadImage(mRequestProxy);
return NS_OK;
}
protected:
virtual ~StyleImageRequestCleanupTask() {
MOZ_ASSERT(!mRequestProxy || NS_IsMainThread(),
"mRequestProxy destructor need to run on the main thread!");
}
private:
// Since we always dispatch this runnable to the main thread, these will be
// released on the main thread when the runnable itself is released.
RefPtr<imgRequestProxy> mRequestProxy;
};
// This is defined here for parallelism with LoadURI.
void Gecko_LoadData_Drop(StyleLoadData* aData) {
if (aData->resolved_image) {
// We want to dispatch this async to prevent reentrancy issues, as
auto task = MakeRefPtr<StyleImageRequestCleanupTask>(*aData);
SchedulerGroup::Dispatch(task.forget());
}
// URIs are safe to refcount from any thread.
NS_IF_RELEASE(aData->resolved_uri);
}
// --------------------
// nsStyleFont
//
nsStyleFont::nsStyleFont(const nsStyleFont& aSrc)
: mFont(aSrc.mFont),
mSize(aSrc.mSize),
mFontSizeFactor(aSrc.mFontSizeFactor),
mFontSizeOffset(aSrc.mFontSizeOffset),
mFontSizeKeyword(aSrc.mFontSizeKeyword),
mFontPalette(aSrc.mFontPalette),
mMathDepth(aSrc.mMathDepth),
mLineHeight(aSrc.mLineHeight),
mMinFontSizeRatio(aSrc.mMinFontSizeRatio),
mMathVariant(aSrc.mMathVariant),
mMathStyle(aSrc.mMathStyle),
mExplicitLanguage(aSrc.mExplicitLanguage),
mXTextScale(aSrc.mXTextScale),
mScriptUnconstrainedSize(aSrc.mScriptUnconstrainedSize),
mScriptMinSize(aSrc.mScriptMinSize),
mLanguage(aSrc.mLanguage) {
MOZ_COUNT_CTOR(nsStyleFont);
}
static StyleXTextScale InitialTextScale(const Document& aDoc) {
if (nsContentUtils::IsChromeDoc(&aDoc) ||
nsContentUtils::IsPDFJS(aDoc.NodePrincipal())) {
return StyleXTextScale::ZoomOnly;
}
return StyleXTextScale::All;
}
nsStyleFont::nsStyleFont(const Document& aDocument)
: mFont(*aDocument.GetFontPrefsForLang(nullptr)->GetDefaultFont(
StyleGenericFontFamily::None)),
mSize(ZoomText(aDocument, mFont.size)),
mFontSizeFactor(1.0),
mFontSizeOffset{0},
mFontSizeKeyword(StyleFontSizeKeyword::Medium),
mFontPalette(StyleFontPalette::Normal()),
mMathDepth(0),
mLineHeight(StyleLineHeight::Normal()),
mMathVariant(StyleMathVariant::None),
mMathStyle(StyleMathStyle::Normal),
mXTextScale(InitialTextScale(aDocument)),
mScriptUnconstrainedSize(mSize),
mScriptMinSize(Length::FromPixels(
CSSPixel::FromPoints(kMathMLDefaultScriptMinSizePt))),
mLanguage(aDocument.GetLanguageForStyle()) {
MOZ_COUNT_CTOR(nsStyleFont);
MOZ_ASSERT(NS_IsMainThread());
mFont.family.is_initial = true;
mFont.size = mSize;
if (MinFontSizeEnabled()) {
const Length minimumFontSize =
aDocument.GetFontPrefsForLang(mLanguage)->mMinimumFontSize;
mFont.size = Length::FromPixels(
std::max(mSize.ToCSSPixels(), minimumFontSize.ToCSSPixels()));
}
}
nsChangeHint nsStyleFont::CalcDifference(const nsStyleFont& aNewData) const {
MOZ_ASSERT(mXTextScale == aNewData.mXTextScale,
"expected -x-text-scale to be the same on both nsStyleFonts");
if (mSize != aNewData.mSize || mLanguage != aNewData.mLanguage ||
mExplicitLanguage != aNewData.mExplicitLanguage ||
mMathVariant != aNewData.mMathVariant ||
mMathStyle != aNewData.mMathStyle ||
mMinFontSizeRatio != aNewData.mMinFontSizeRatio ||
mLineHeight != aNewData.mLineHeight) {
return NS_STYLE_HINT_REFLOW;
}
switch (mFont.CalcDifference(aNewData.mFont)) {
case nsFont::MaxDifference::eLayoutAffecting:
return NS_STYLE_HINT_REFLOW;
case nsFont::MaxDifference::eVisual:
return NS_STYLE_HINT_VISUAL;
case nsFont::MaxDifference::eNone:
break;
}
if (mFontPalette != aNewData.mFontPalette) {
return NS_STYLE_HINT_VISUAL;
}
// XXX Should any of these cause a non-nsChangeHint_NeutralChange change?
if (mMathDepth != aNewData.mMathDepth ||
mScriptUnconstrainedSize != aNewData.mScriptUnconstrainedSize ||
mScriptMinSize != aNewData.mScriptMinSize) {
return nsChangeHint_NeutralChange;
}
return nsChangeHint(0);
}
Length nsStyleFont::ZoomText(const Document& aDocument, Length aSize) {
if (auto* pc = aDocument.GetPresContext()) {
aSize.ScaleBy(pc->TextZoom());
}
return aSize;
}
template <typename T>
static StyleRect<T> StyleRectWithAllSides(const T& aSide) {
return {aSide, aSide, aSide, aSide};
}
MOZ_RUNINIT const StyleMargin nsStyleMargin::kZeroMargin =
StyleMargin::LengthPercentage(StyleLengthPercentage::Zero());
nsStyleMargin::nsStyleMargin()
: mMargin(StyleRectWithAllSides(
StyleMargin::LengthPercentage(LengthPercentage::Zero()))),
mScrollMargin(StyleRectWithAllSides(StyleLength{0.})),
mOverflowClipMargin(StyleLength::Zero()) {
MOZ_COUNT_CTOR(nsStyleMargin);
}
nsStyleMargin::nsStyleMargin(const nsStyleMargin& aSrc)
: mMargin(aSrc.mMargin),
mScrollMargin(aSrc.mScrollMargin),
mOverflowClipMargin(aSrc.mOverflowClipMargin) {
MOZ_COUNT_CTOR(nsStyleMargin);
}
nsChangeHint nsStyleMargin::CalcDifference(
const nsStyleMargin& aNewData) const {
nsChangeHint hint = nsChangeHint(0);
if (!MarginEquals(aNewData)) {
// Margin differences can't affect descendant intrinsic sizes and
// don't need to force children to reflow.
hint |= nsChangeHint_NeedReflow | nsChangeHint_ReflowChangesSizeOrPosition |
nsChangeHint_ClearAncestorIntrinsics;
}
if (mScrollMargin != aNewData.mScrollMargin) {
hint |= nsChangeHint_NeutralChange;
}
if (mOverflowClipMargin != aNewData.mOverflowClipMargin) {
hint |= nsChangeHint_UpdateOverflow | nsChangeHint_RepaintFrame;
}
return hint;
}
nsStylePadding::nsStylePadding()
: mPadding(StyleRectWithAllSides(LengthPercentage::Zero())),
mScrollPadding(StyleRectWithAllSides(LengthPercentageOrAuto::Auto())) {
MOZ_COUNT_CTOR(nsStylePadding);
}
nsStylePadding::nsStylePadding(const nsStylePadding& aSrc)
: mPadding(aSrc.mPadding), mScrollPadding(aSrc.mScrollPadding) {
MOZ_COUNT_CTOR(nsStylePadding);
}
nsChangeHint nsStylePadding::CalcDifference(
const nsStylePadding& aNewData) const {
nsChangeHint hint = nsChangeHint(0);
if (mPadding != aNewData.mPadding) {
// Padding differences can't affect descendant intrinsic sizes, but do need
// to force children to reflow so that we can reposition them, since their
// offsets are from our frame bounds but our content rect's position within
// those bounds is moving.
// FIXME: It would be good to return a weaker hint here that doesn't
// force reflow of all descendants, but the hint would need to force
// reflow of the frame's children (see how
// ReflowInput::InitResizeFlags initializes the inline-resize flag).
hint |= NS_STYLE_HINT_REFLOW & ~nsChangeHint_ClearDescendantIntrinsics;
}
if (mScrollPadding != aNewData.mScrollPadding) {
hint |= nsChangeHint_NeutralChange;
}
return hint;
}
static inline BorderRadius ZeroBorderRadius() {
auto zero = LengthPercentage::Zero();
return {{{zero, zero}}, {{zero, zero}}, {{zero, zero}}, {{zero, zero}}};
}
nsStyleBorder::nsStyleBorder()
: mBorderRadius(ZeroBorderRadius()),
mBorderImageSource(StyleImage::None()),
mBorderImageWidth(
StyleRectWithAllSides(StyleBorderImageSideWidth::Number(1.))),
mBorderImageOutset(
StyleRectWithAllSides(StyleNonNegativeLengthOrNumber::Number(0.))),
mBorderImageSlice(
{StyleRectWithAllSides(StyleNumberOrPercentage::Percentage({1.})),
false}),
mBorderImageRepeat{StyleBorderImageRepeatKeyword::Stretch,
StyleBorderImageRepeatKeyword::Stretch},
mFloatEdge(StyleFloatEdge::ContentBox),
mBoxDecorationBreak(StyleBoxDecorationBreak::Slice),
mBorderTopColor(StyleColor::CurrentColor()),
mBorderRightColor(StyleColor::CurrentColor()),
mBorderBottomColor(StyleColor::CurrentColor()),
mBorderLeftColor(StyleColor::CurrentColor()),
mComputedBorder(0, 0, 0, 0) {
MOZ_COUNT_CTOR(nsStyleBorder);
nscoord medium = kMediumBorderWidth;
for (const auto side : mozilla::AllPhysicalSides()) {
mBorder.Side(side) = medium;
mBorderStyle[side] = StyleBorderStyle::None;
}
}
nsStyleBorder::nsStyleBorder(const nsStyleBorder& aSrc)
: mBorderRadius(aSrc.mBorderRadius),
mBorderImageSource(aSrc.mBorderImageSource),
mBorderImageWidth(aSrc.mBorderImageWidth),
mBorderImageOutset(aSrc.mBorderImageOutset),
mBorderImageSlice(aSrc.mBorderImageSlice),
mBorderImageRepeat(aSrc.mBorderImageRepeat),
mFloatEdge(aSrc.mFloatEdge),
mBoxDecorationBreak(aSrc.mBoxDecorationBreak),
mBorderTopColor(aSrc.mBorderTopColor),
mBorderRightColor(aSrc.mBorderRightColor),
mBorderBottomColor(aSrc.mBorderBottomColor),
mBorderLeftColor(aSrc.mBorderLeftColor),
mComputedBorder(aSrc.mComputedBorder),
mBorder(aSrc.mBorder) {
MOZ_COUNT_CTOR(nsStyleBorder);
for (const auto side : mozilla::AllPhysicalSides()) {
mBorderStyle[side] = aSrc.mBorderStyle[side];
}
}
void nsStyleBorder::TriggerImageLoads(Document& aDocument,
const nsStyleBorder* aOldStyle) {
MOZ_ASSERT(NS_IsMainThread());
mBorderImageSource.ResolveImage(
aDocument, aOldStyle ? &aOldStyle->mBorderImageSource : nullptr);
}
nsMargin nsStyleBorder::GetImageOutset() const {
// We don't check whether there is a border-image (which is OK since
// the initial values yields 0 outset) so that we don't have to
// reflow to update overflow areas when an image loads.
nsMargin outset;
for (const auto s : mozilla::AllPhysicalSides()) {
const auto& coord = mBorderImageOutset.Get(s);
nscoord value;
if (coord.IsLength()) {
value = coord.AsLength().ToAppUnits();
} else {
MOZ_ASSERT(coord.IsNumber());
value = coord.AsNumber() * mComputedBorder.Side(s);
}
outset.Side(s) = value;
}
return outset;
}
nsChangeHint nsStyleBorder::CalcDifference(
const nsStyleBorder& aNewData) const {
// FIXME: XXXbz: As in nsStylePadding::CalcDifference, many of these
// differences should not need to clear descendant intrinsics.
// FIXME: It would be good to return a weaker hint for the
// GetComputedBorder() differences (and perhaps others) that doesn't
// force reflow of all descendants, but the hint would need to force
// reflow of the frame's children (see how
// ReflowInput::InitResizeFlags initializes the inline-resize flag).
if (GetComputedBorder() != aNewData.GetComputedBorder() ||
mFloatEdge != aNewData.mFloatEdge ||
mBorderImageOutset != aNewData.mBorderImageOutset ||
mBoxDecorationBreak != aNewData.mBoxDecorationBreak) {
return NS_STYLE_HINT_REFLOW;
}
for (const auto ix : mozilla::AllPhysicalSides()) {
// See the explanation in nsChangeHint.h of
// nsChangeHint_BorderStyleNoneChange .
// Furthermore, even though we know *this* side is 0 width, just
// assume a repaint hint for some other change rather than bother
// tracking this result through the rest of the function.
if (HasVisibleStyle(ix) != aNewData.HasVisibleStyle(ix)) {
return nsChangeHint_RepaintFrame | nsChangeHint_BorderStyleNoneChange;
}
}
// Note that mBorderStyle stores not only the border style but also
// color-related flags. Given that we've already done an mComputedBorder
// comparison, border-style differences can only lead to a repaint hint. So
// it's OK to just compare the values directly -- if either the actual
// style or the color flags differ we want to repaint.
for (const auto ix : mozilla::AllPhysicalSides()) {
if (mBorderStyle[ix] != aNewData.mBorderStyle[ix] ||
BorderColorFor(ix) != aNewData.BorderColorFor(ix)) {
return nsChangeHint_RepaintFrame;
}
}
// Note that border radius also controls the outline radius if the
// layout.css.outline-follows-border-radius.enabled pref is set. Any
// optimizations here should apply to both.
if (mBorderRadius != aNewData.mBorderRadius) {
return nsChangeHint_RepaintFrame;
}
// Loading status of the border image can be accessed in main thread only
// while CalcDifference might be executed on a background thread. As a
// result, we have to check mBorderImage* fields even before border image was
// actually loaded.
if (!mBorderImageSource.IsNone() || !aNewData.mBorderImageSource.IsNone()) {
if (mBorderImageSource != aNewData.mBorderImageSource ||
mBorderImageRepeat != aNewData.mBorderImageRepeat ||
mBorderImageSlice != aNewData.mBorderImageSlice ||
mBorderImageWidth != aNewData.mBorderImageWidth) {
return nsChangeHint_RepaintFrame;
}
}
// mBorder is the specified border value. Changes to this don't
// need any change processing, since we operate on the computed
// border values instead.
if (mBorder != aNewData.mBorder) {
return nsChangeHint_NeutralChange;
}
// mBorderImage* fields are checked only when border-image is not 'none'.
if (mBorderImageSource != aNewData.mBorderImageSource ||
mBorderImageRepeat != aNewData.mBorderImageRepeat ||
mBorderImageSlice != aNewData.mBorderImageSlice ||
mBorderImageWidth != aNewData.mBorderImageWidth) {
return nsChangeHint_NeutralChange;
}
return nsChangeHint(0);
}
nsStyleOutline::nsStyleOutline()
: mOutlineWidth(kMediumBorderWidth),
mOutlineOffset({0.0f}),
mOutlineColor(StyleColor::CurrentColor()),
mOutlineStyle(StyleOutlineStyle::BorderStyle(StyleBorderStyle::None)),
mActualOutlineWidth(0) {
MOZ_COUNT_CTOR(nsStyleOutline);
}
nsStyleOutline::nsStyleOutline(const nsStyleOutline& aSrc)
: mOutlineWidth(aSrc.mOutlineWidth),
mOutlineOffset(aSrc.mOutlineOffset),
mOutlineColor(aSrc.mOutlineColor),
mOutlineStyle(aSrc.mOutlineStyle),
mActualOutlineWidth(aSrc.mActualOutlineWidth) {
MOZ_COUNT_CTOR(nsStyleOutline);
}
nsChangeHint nsStyleOutline::CalcDifference(
const nsStyleOutline& aNewData) const {
const bool shouldPaintOutline = ShouldPaintOutline();
// We need the explicit 'outline-style: auto' check because
// 'outline-style: auto' effectively also changes 'outline-width'.
if (shouldPaintOutline != aNewData.ShouldPaintOutline() ||
mActualOutlineWidth != aNewData.mActualOutlineWidth ||
mOutlineStyle.IsAuto() != aNewData.mOutlineStyle.IsAuto() ||
(shouldPaintOutline && mOutlineOffset != aNewData.mOutlineOffset)) {
return nsChangeHint_UpdateOverflow | nsChangeHint_SchedulePaint |
nsChangeHint_RepaintFrame;
}
if (mOutlineStyle != aNewData.mOutlineStyle ||
mOutlineColor != aNewData.mOutlineColor) {
return shouldPaintOutline ? nsChangeHint_RepaintFrame
: nsChangeHint_NeutralChange;
}
if (mOutlineWidth != aNewData.mOutlineWidth ||
mOutlineOffset != aNewData.mOutlineOffset) {
return nsChangeHint_NeutralChange;
}
return nsChangeHint(0);
}
nsSize nsStyleOutline::EffectiveOffsetFor(const nsRect& aRect) const {
const nscoord offset = mOutlineOffset.ToAppUnits();
if (offset >= 0) {
// Fast path for non-negative offset values
return nsSize(offset, offset);
}
return nsSize(std::max(offset, -(aRect.Width() / 2)),
std::max(offset, -(aRect.Height() / 2)));
}
// --------------------
// nsStyleList
//
nsStyleList::nsStyleList()
: mListStylePosition(StyleListStylePosition::Outside),
mListStyleType(StyleCounterStyle::Name({StyleAtom(nsGkAtoms::disc)})),
mQuotes(StyleQuotes::Auto()),
mListStyleImage(StyleImage::None()) {
MOZ_COUNT_CTOR(nsStyleList);
MOZ_ASSERT(NS_IsMainThread());
}
nsStyleList::nsStyleList(const nsStyleList& aSource)
: mListStylePosition(aSource.mListStylePosition),
mListStyleType(aSource.mListStyleType),
mQuotes(aSource.mQuotes),
mListStyleImage(aSource.mListStyleImage) {
MOZ_COUNT_CTOR(nsStyleList);
}
void nsStyleList::TriggerImageLoads(Document& aDocument,
const nsStyleList* aOldStyle) {
MOZ_ASSERT(NS_IsMainThread());
mListStyleImage.ResolveImage(
aDocument, aOldStyle ? &aOldStyle->mListStyleImage : nullptr);
}
nsChangeHint nsStyleList::CalcDifference(const nsStyleList& aNewData,
const ComputedStyle& aOldStyle) const {
// If the quotes implementation is ever going to change we might not need
if (mQuotes != aNewData.mQuotes) {
return nsChangeHint_ReconstructFrame;
}
nsChangeHint hint = nsChangeHint(0);
// Only elements whose display value is list-item can be affected by
// list-style-{position,type,image}. This also relies on that when the display
// value changes from something else to list-item, that change itself would
// cause ReconstructFrame.
if (mListStylePosition != aNewData.mListStylePosition ||
mListStyleType != aNewData.mListStyleType ||
mListStyleImage != aNewData.mListStyleImage) {
if (aOldStyle.StyleDisplay()->IsListItem()) {
return nsChangeHint_ReconstructFrame;
}
// list-style-image may affect nsImageFrame for XUL elements, but that is
// dealt with explicitly in nsImageFrame::DidSetComputedStyle.
hint = nsChangeHint_NeutralChange;
}
return hint;
}
already_AddRefed<nsIURI> nsStyleList::GetListStyleImageURI() const {
if (!mListStyleImage.IsUrl()) {
return nullptr;
}
return do_AddRef(mListStyleImage.AsUrl().GetURI());
}
// --------------------
// nsStyleXUL
//
nsStyleXUL::nsStyleXUL()
: mBoxFlex(0.0f),
mBoxOrdinal(1),
mBoxAlign(StyleBoxAlign::Stretch),
mBoxDirection(StyleBoxDirection::Normal),
mBoxOrient(StyleBoxOrient::Horizontal),
mBoxPack(StyleBoxPack::Start) {
MOZ_COUNT_CTOR(nsStyleXUL);
}
nsStyleXUL::nsStyleXUL(const nsStyleXUL& aSource)
: mBoxFlex(aSource.mBoxFlex),
mBoxOrdinal(aSource.mBoxOrdinal),
mBoxAlign(aSource.mBoxAlign),
mBoxDirection(aSource.mBoxDirection),
mBoxOrient(aSource.mBoxOrient),
mBoxPack(aSource.mBoxPack) {
MOZ_COUNT_CTOR(nsStyleXUL);
}
nsChangeHint nsStyleXUL::CalcDifference(const nsStyleXUL& aNewData) const {
if (mBoxAlign == aNewData.mBoxAlign &&
mBoxDirection == aNewData.mBoxDirection &&
mBoxFlex == aNewData.mBoxFlex && mBoxOrient == aNewData.mBoxOrient &&
mBoxPack == aNewData.mBoxPack && mBoxOrdinal == aNewData.mBoxOrdinal) {
return nsChangeHint(0);
}
if (mBoxOrdinal != aNewData.mBoxOrdinal) {
return nsChangeHint_ReconstructFrame;
}
return NS_STYLE_HINT_REFLOW;
}
// --------------------
// nsStyleColumn
//
nsStyleColumn::nsStyleColumn()
: mColumnWidth(LengthOrAuto::Auto()),
mColumnRuleColor(StyleColor::CurrentColor()),
mColumnRuleStyle(StyleBorderStyle::None),
mColumnRuleWidth(kMediumBorderWidth),
mActualColumnRuleWidth(0) {
MOZ_COUNT_CTOR(nsStyleColumn);
}
nsStyleColumn::nsStyleColumn(const nsStyleColumn& aSource)
: mColumnCount(aSource.mColumnCount),
mColumnWidth(aSource.mColumnWidth),
mColumnRuleColor(aSource.mColumnRuleColor),
mColumnRuleStyle(aSource.mColumnRuleStyle),
mColumnFill(aSource.mColumnFill),
mColumnSpan(aSource.mColumnSpan),
mColumnRuleWidth(aSource.mColumnRuleWidth),
mActualColumnRuleWidth(aSource.mActualColumnRuleWidth) {
MOZ_COUNT_CTOR(nsStyleColumn);
}
nsChangeHint nsStyleColumn::CalcDifference(
const nsStyleColumn& aNewData) const {
if (mColumnWidth.IsAuto() != aNewData.mColumnWidth.IsAuto() ||
mColumnCount != aNewData.mColumnCount ||
mColumnSpan != aNewData.mColumnSpan) {
// We force column count changes to do a reframe, because it's tricky to
// handle some edge cases where the column count gets smaller and content
// overflows.
// XXX not ideal
return nsChangeHint_ReconstructFrame;
}
if (mColumnWidth != aNewData.mColumnWidth ||
mColumnFill != aNewData.mColumnFill) {
return NS_STYLE_HINT_REFLOW;
}
if (mActualColumnRuleWidth != aNewData.mActualColumnRuleWidth ||
mColumnRuleStyle != aNewData.mColumnRuleStyle ||
mColumnRuleColor != aNewData.mColumnRuleColor) {
return NS_STYLE_HINT_VISUAL;
}
if (mColumnRuleWidth != aNewData.mColumnRuleWidth) {
return nsChangeHint_NeutralChange;
}
return nsChangeHint(0);
}
using SVGPaintFallback = StyleGenericSVGPaintFallback<StyleColor>;
// --------------------
// nsStyleSVG
//
nsStyleSVG::nsStyleSVG()
: mFill{StyleSVGPaintKind::Color(StyleColor::Black()),
SVGPaintFallback::Unset()},
mStroke{StyleSVGPaintKind::None(), SVGPaintFallback::Unset()},
mMarkerEnd(StyleUrlOrNone::None()),
mMarkerMid(StyleUrlOrNone::None()),
mMarkerStart(StyleUrlOrNone::None()),
mMozContextProperties{{}, {0}},
mStrokeDasharray(StyleSVGStrokeDashArray::Values({})),
mStrokeDashoffset(
StyleSVGLength::LengthPercentage(LengthPercentage::Zero())),
mStrokeWidth(
StyleSVGWidth::LengthPercentage(LengthPercentage::FromPixels(1.0f))),
mFillOpacity(StyleSVGOpacity::Opacity(1.0f)),
mStrokeMiterlimit(4.0f),
mStrokeOpacity(StyleSVGOpacity::Opacity(1.0f)),
mClipRule(StyleFillRule::Nonzero),
mColorInterpolation(StyleColorInterpolation::Srgb),
mColorInterpolationFilters(StyleColorInterpolation::Linearrgb),
mFillRule(StyleFillRule::Nonzero),
mPaintOrder(0),
mShapeRendering(StyleShapeRendering::Auto),
mStrokeLinecap(StyleStrokeLinecap::Butt),
mStrokeLinejoin(StyleStrokeLinejoin::Miter),
mDominantBaseline(StyleDominantBaseline::Auto),
mTextAnchor(StyleTextAnchor::Start) {
MOZ_COUNT_CTOR(nsStyleSVG);
}
nsStyleSVG::nsStyleSVG(const nsStyleSVG& aSource)
: mFill(aSource.mFill),
mStroke(aSource.mStroke),
mMarkerEnd(aSource.mMarkerEnd),
mMarkerMid(aSource.mMarkerMid),
mMarkerStart(aSource.mMarkerStart),
mMozContextProperties(aSource.mMozContextProperties),
mStrokeDasharray(aSource.mStrokeDasharray),
mStrokeDashoffset(aSource.mStrokeDashoffset),
mStrokeWidth(aSource.mStrokeWidth),
mFillOpacity(aSource.mFillOpacity),
mStrokeMiterlimit(aSource.mStrokeMiterlimit),
mStrokeOpacity(aSource.mStrokeOpacity),
mClipRule(aSource.mClipRule),
mColorInterpolation(aSource.mColorInterpolation),
mColorInterpolationFilters(aSource.mColorInterpolationFilters),
mFillRule(aSource.mFillRule),
mPaintOrder(aSource.mPaintOrder),
mShapeRendering(aSource.mShapeRendering),
mStrokeLinecap(aSource.mStrokeLinecap),
mStrokeLinejoin(aSource.mStrokeLinejoin),
mDominantBaseline(aSource.mDominantBaseline),
mTextAnchor(aSource.mTextAnchor) {
MOZ_COUNT_CTOR(nsStyleSVG);
}
static bool PaintURIChanged(const StyleSVGPaint& aPaint1,
const StyleSVGPaint& aPaint2) {
if (aPaint1.kind.IsPaintServer() != aPaint2.kind.IsPaintServer()) {
return true;
}
return aPaint1.kind.IsPaintServer() &&
aPaint1.kind.AsPaintServer() != aPaint2.kind.AsPaintServer();
}
nsChangeHint nsStyleSVG::CalcDifference(const nsStyleSVG& aNewData) const {
nsChangeHint hint = nsChangeHint(0);
if (mMarkerEnd != aNewData.mMarkerEnd || mMarkerMid != aNewData.mMarkerMid ||
mMarkerStart != aNewData.mMarkerStart) {
// Markers currently contribute to SVGGeometryFrame::mRect,
// so we need a reflow as well as a repaint. No intrinsic sizes need
// to change, so nsChangeHint_NeedReflow is sufficient.
return nsChangeHint_UpdateEffects | nsChangeHint_NeedReflow |
nsChangeHint_RepaintFrame;
}
if (mFill != aNewData.mFill || mStroke != aNewData.mStroke ||
mFillOpacity != aNewData.mFillOpacity ||
mStrokeOpacity != aNewData.mStrokeOpacity) {
hint |= nsChangeHint_RepaintFrame;
if (HasStroke() != aNewData.HasStroke() ||
(!HasStroke() && HasFill() != aNewData.HasFill())) {
// Frame bounds and overflow rects depend on whether we "have" fill or
// stroke. Whether we have stroke or not just changed, or else we have no
// stroke (in which case whether we have fill or not is significant to
// frame bounds) and whether we have fill or not just changed. In either
// case we need to reflow so the frame rect is updated.
// XXXperf this is a waste on non SVGGeometryFrames.
hint |= nsChangeHint_NeedReflow;
}
if (PaintURIChanged(mFill, aNewData.mFill) ||
PaintURIChanged(mStroke, aNewData.mStroke)) {
hint |= nsChangeHint_UpdateEffects;
}
}
// Stroke currently contributes to SVGGeometryFrame::mRect, so
// we need a reflow here. No intrinsic sizes need to change, so
// nsChangeHint_NeedReflow is sufficient.
// Note that stroke-dashoffset does not affect SVGGeometryFrame::mRect.
// text-anchor and dominant-baseline changes also require a reflow since
// they change frames' rects.
if (mStrokeWidth != aNewData.mStrokeWidth ||
mStrokeMiterlimit != aNewData.mStrokeMiterlimit ||
mStrokeLinecap != aNewData.mStrokeLinecap ||
mStrokeLinejoin != aNewData.mStrokeLinejoin ||
mDominantBaseline != aNewData.mDominantBaseline ||
mTextAnchor != aNewData.mTextAnchor) {
return hint | nsChangeHint_NeedReflow | nsChangeHint_RepaintFrame;
}
if (hint & nsChangeHint_RepaintFrame) {
return hint; // we don't add anything else below
}
if (mStrokeDashoffset != aNewData.mStrokeDashoffset ||
mClipRule != aNewData.mClipRule ||
mColorInterpolation != aNewData.mColorInterpolation ||
mColorInterpolationFilters != aNewData.mColorInterpolationFilters ||
mFillRule != aNewData.mFillRule || mPaintOrder != aNewData.mPaintOrder ||
mShapeRendering != aNewData.mShapeRendering ||
mStrokeDasharray != aNewData.mStrokeDasharray ||
mMozContextProperties.bits != aNewData.mMozContextProperties.bits) {
return hint | nsChangeHint_RepaintFrame;
}
if (!hint) {
if (mMozContextProperties.idents != aNewData.mMozContextProperties.idents) {
hint = nsChangeHint_NeutralChange;
}
}
return hint;
}
// --------------------
// nsStyleSVGReset
//
nsStyleSVGReset::nsStyleSVGReset()
: mX(LengthPercentage::Zero()),
mY(LengthPercentage::Zero()),
mCx(LengthPercentage::Zero()),
mCy(LengthPercentage::Zero()),
mRx(NonNegativeLengthPercentageOrAuto::Auto()),
mRy(NonNegativeLengthPercentageOrAuto::Auto()),
mR(NonNegativeLengthPercentage::Zero()),
mMask(nsStyleImageLayers::LayerType::Mask),
mClipPath(StyleClipPath::None()),
mStopColor(StyleColor::Black()),
mFloodColor(StyleColor::Black()),
mLightingColor(StyleColor::White()),
mStopOpacity(1.0f),
mFloodOpacity(1.0f),
mVectorEffect(StyleVectorEffect::NONE),
mMaskType(StyleMaskType::Luminance),
mD(StyleDProperty::None()) {
MOZ_COUNT_CTOR(nsStyleSVGReset);
}
nsStyleSVGReset::nsStyleSVGReset(const nsStyleSVGReset& aSource)
: mX(aSource.mX),
mY(aSource.mY),
mCx(aSource.mCx),
mCy(aSource.mCy),
mRx(aSource.mRx),
mRy(aSource.mRy),
mR(aSource.mR),
mMask(aSource.mMask),
mClipPath(aSource.mClipPath),
mStopColor(aSource.mStopColor),
mFloodColor(aSource.mFloodColor),
mLightingColor(aSource.mLightingColor),
mStopOpacity(aSource.mStopOpacity),
mFloodOpacity(aSource.mFloodOpacity),
mVectorEffect(aSource.mVectorEffect),
mMaskType(aSource.mMaskType),
mD(aSource.mD) {
MOZ_COUNT_CTOR(nsStyleSVGReset);
}
void nsStyleSVGReset::TriggerImageLoads(Document& aDocument,
const nsStyleSVGReset* aOldStyle) {
MOZ_ASSERT(NS_IsMainThread());
// NOTE(emilio): we intentionally don't call TriggerImageLoads for clip-path.
NS_FOR_VISIBLE_IMAGE_LAYERS_BACK_TO_FRONT(i, mMask) {
auto& image = mMask.mLayers[i].mImage;
if (!image.IsImageRequestType()) {
continue;
}
const auto* url = image.GetImageRequestURLValue();
// If the url is a local ref, it must be a <mask-resource>, so we don't
// need to resolve the style image.
if (url->IsLocalRef()) {
continue;
}
#if 0
// XXX The old style system also checks whether this is a reference to
// the current document with reference, but it doesn't seem to be a
// behavior mentioned anywhere, so we comment out the code for now.
nsIURI* docURI = aPresContext->Document()->GetDocumentURI();
if (url->EqualsExceptRef(docURI)) {
continue;
}
#endif
// Otherwise, we may need the image even if it has a reference, in case
// the referenced element isn't a valid SVG <mask> element.
const auto* oldImage = (aOldStyle && aOldStyle->mMask.mLayers.Length() > i)
? &aOldStyle->mMask.mLayers[i].mImage
: nullptr;
image.ResolveImage(aDocument, oldImage);
}
}
nsChangeHint nsStyleSVGReset::CalcDifference(
const nsStyleSVGReset& aNewData) const {
nsChangeHint hint = nsChangeHint(0);
if (mX != aNewData.mX || mY != aNewData.mY || mCx != aNewData.mCx ||
mCy != aNewData.mCy || mR != aNewData.mR || mRx != aNewData.mRx ||
mRy != aNewData.mRy || mD != aNewData.mD) {
hint |= nsChangeHint_InvalidateRenderingObservers | nsChangeHint_NeedReflow;
}
if (mClipPath != aNewData.mClipPath) {
hint |= nsChangeHint_UpdateEffects | nsChangeHint_RepaintFrame;
}
if (mVectorEffect != aNewData.mVectorEffect) {
// Stroke currently affects SVGGeometryFrame::mRect, and
// vector-effect affect stroke. As a result we need to reflow if
// vector-effect changes in order to have SVGGeometryFrame::
// ReflowSVG called to update its mRect. No intrinsic sizes need
// to change so nsChangeHint_NeedReflow is sufficient.
hint |= nsChangeHint_NeedReflow | nsChangeHint_RepaintFrame;
} else if (mStopColor != aNewData.mStopColor ||
mFloodColor != aNewData.mFloodColor ||
mLightingColor != aNewData.mLightingColor ||
mStopOpacity != aNewData.mStopOpacity ||
mFloodOpacity != aNewData.mFloodOpacity ||
mMaskType != aNewData.mMaskType || mD != aNewData.mD) {
hint |= nsChangeHint_RepaintFrame;
}
hint |=
mMask.CalcDifference(aNewData.mMask, nsStyleImageLayers::LayerType::Mask);
return hint;
}
bool nsStyleSVGReset::HasMask() const {
for (uint32_t i = 0; i < mMask.mImageCount; i++) {
if (!mMask.mLayers[i].mImage.IsNone()) {
return true;
}
}
return false;
}
// --------------------
// nsStylePage
//
nsStylePage::nsStylePage(const nsStylePage& aSrc)
: mSize(aSrc.mSize),
mPage(aSrc.mPage),
mPageOrientation(aSrc.mPageOrientation) {
MOZ_COUNT_CTOR(nsStylePage);
}
nsChangeHint nsStylePage::CalcDifference(const nsStylePage& aNewData) const {
// Page rule styling only matters when printing or using print preview.
if (aNewData.mSize != mSize || aNewData.mPage != mPage ||
aNewData.mPageOrientation != mPageOrientation) {
return nsChangeHint_NeutralChange;
}
return nsChangeHint_Empty;
}
// --------------------
// nsStylePosition
//
nsStylePosition::nsStylePosition()
: mObjectPosition(Position::FromPercentage(0.5f)),
mOffset(StyleRectWithAllSides(StyleInset::Auto())),
mWidth(StyleSize::Auto()),
mMinWidth(StyleSize::Auto()),
mMaxWidth(StyleMaxSize::None()),
mHeight(StyleSize::Auto()),
mMinHeight(StyleSize::Auto()),
mMaxHeight(StyleMaxSize::None()),
mPositionAnchor(StylePositionAnchor::Auto()),
mPositionArea(StylePositionArea{StylePositionAreaKeyword::None,
StylePositionAreaKeyword::None}),
mPositionVisibility(StylePositionVisibility::ALWAYS),
mPositionTryFallbacks(StylePositionTryFallbacks()),
mPositionTryOrder(StylePositionTryOrder::Normal),
mFlexBasis(StyleFlexBasis::Size(StyleSize::Auto())),
mAspectRatio(StyleAspectRatio::Auto()),
mGridAutoFlow(StyleGridAutoFlow::ROW),
mMasonryAutoFlow(
{StyleMasonryPlacement::Pack, StyleMasonryItemOrder::DefiniteFirst}),
mAlignContent({StyleAlignFlags::NORMAL}),
mAlignItems({StyleAlignFlags::NORMAL}),
mAlignSelf({StyleAlignFlags::AUTO}),
mJustifyContent({StyleAlignFlags::NORMAL}),
mJustifyItems({{StyleAlignFlags::LEGACY}, {StyleAlignFlags::NORMAL}}),
mJustifySelf({StyleAlignFlags::AUTO}),
mFlexDirection(StyleFlexDirection::Row),
mFlexWrap(StyleFlexWrap::Nowrap),
mObjectFit(StyleObjectFit::Fill),
mBoxSizing(StyleBoxSizing::Content),
mOrder(0),
mFlexGrow(0.0f),
mFlexShrink(1.0f),
mZIndex(StyleZIndex::Auto()),
mGridTemplateColumns(StyleGridTemplateComponent::None()),
mGridTemplateRows(StyleGridTemplateComponent::None()),
mGridTemplateAreas(StyleGridTemplateAreas::None()),
mColumnGap(NonNegativeLengthPercentageOrNormal::Normal()),
mRowGap(NonNegativeLengthPercentageOrNormal::Normal()),
mContainIntrinsicWidth(StyleContainIntrinsicSize::None()),
mContainIntrinsicHeight(StyleContainIntrinsicSize::None()) {
MOZ_COUNT_CTOR(nsStylePosition);
// The initial value of grid-auto-columns and grid-auto-rows is 'auto',
// which computes to 'minmax(auto, auto)'.
// Other members get their default constructors
// which initialize them to representations of their respective initial value.
// mGridTemplate{Rows,Columns}: false and empty arrays for 'none'
// mGrid{Column,Row}{Start,End}: false/0/empty values for 'auto'
}
nsStylePosition::nsStylePosition(const nsStylePosition& aSource)
: mObjectPosition(aSource.mObjectPosition),
mOffset(aSource.mOffset),
mWidth(aSource.mWidth),
mMinWidth(aSource.mMinWidth),
mMaxWidth(aSource.mMaxWidth),
mHeight(aSource.mHeight),
mMinHeight(aSource.mMinHeight),
mMaxHeight(aSource.mMaxHeight),
mPositionAnchor(aSource.mPositionAnchor),
mPositionArea(aSource.mPositionArea),
mPositionVisibility(aSource.mPositionVisibility),
mPositionTryFallbacks(aSource.mPositionTryFallbacks),
mPositionTryOrder(aSource.mPositionTryOrder),
mFlexBasis(aSource.mFlexBasis),
mGridAutoColumns(aSource.mGridAutoColumns),
mGridAutoRows(aSource.mGridAutoRows),
mAspectRatio(aSource.mAspectRatio),
mGridAutoFlow(aSource.mGridAutoFlow),
mMasonryAutoFlow(aSource.mMasonryAutoFlow),
mAlignContent(aSource.mAlignContent),
mAlignItems(aSource.mAlignItems),
mAlignSelf(aSource.mAlignSelf),
mJustifyContent(aSource.mJustifyContent),
mJustifyItems(aSource.mJustifyItems),
mJustifySelf(aSource.mJustifySelf),
mFlexDirection(aSource.mFlexDirection),
mFlexWrap(aSource.mFlexWrap),
mObjectFit(aSource.mObjectFit),
mBoxSizing(aSource.mBoxSizing),
mOrder(aSource.mOrder),
mFlexGrow(aSource.mFlexGrow),
mFlexShrink(aSource.mFlexShrink),
mZIndex(aSource.mZIndex),
mGridTemplateColumns(aSource.mGridTemplateColumns),
mGridTemplateRows(aSource.mGridTemplateRows),
mGridTemplateAreas(aSource.mGridTemplateAreas),
mGridColumnStart(aSource.mGridColumnStart),
mGridColumnEnd(aSource.mGridColumnEnd),
mGridRowStart(aSource.mGridRowStart),
mGridRowEnd(aSource.mGridRowEnd),
mColumnGap(aSource.mColumnGap),
mRowGap(aSource.mRowGap),
mContainIntrinsicWidth(aSource.mContainIntrinsicWidth),
mContainIntrinsicHeight(aSource.mContainIntrinsicHeight) {
MOZ_COUNT_CTOR(nsStylePosition);
}
static bool IsEqualInsetType(const StyleRect<StyleInset>& aSides1,
const StyleRect<StyleInset>& aSides2) {
for (const auto side : mozilla::AllPhysicalSides()) {
if (aSides1.Get(side).tag != aSides2.Get(side).tag) {
return false;
}
}
return true;
}
nsChangeHint nsStylePosition::CalcDifference(
const nsStylePosition& aNewData, const ComputedStyle& aOldStyle) const {
if (mGridTemplateColumns.IsMasonry() !=
aNewData.mGridTemplateColumns.IsMasonry() ||
mGridTemplateRows.IsMasonry() != aNewData.mGridTemplateRows.IsMasonry()) {
// XXXmats this could be optimized to AllReflowHints with a bit of work,
return nsChangeHint_ReconstructFrame;
}
nsChangeHint hint = nsChangeHint(0);
// Changes to "z-index" require a repaint.
if (mZIndex != aNewData.mZIndex) {
hint |= nsChangeHint_RepaintFrame;
}
// Changes to "object-fit" & "object-position" require a repaint. They
// may also require a reflow, if we have a nsSubDocumentFrame, so that we
// can adjust the size & position of the subdocument.
if (mObjectFit != aNewData.mObjectFit ||
mObjectPosition != aNewData.mObjectPosition) {
hint |= nsChangeHint_RepaintFrame | nsChangeHint_NeedReflow;
}
if (mContainIntrinsicWidth != aNewData.mContainIntrinsicWidth ||
mContainIntrinsicHeight != aNewData.mContainIntrinsicHeight) {
hint |= NS_STYLE_HINT_REFLOW;
}
if (mOrder != aNewData.mOrder) {
// "order" impacts both layout order and stacking order, so we need both a
// reflow and a repaint when it changes. (Technically, we only need a
// reflow if we're in a multi-line flexbox (which we can't be sure about,
// since that's determined by styling on our parent) -- there, "order" can
// affect which flex line we end up on, & hence can affect our sizing by
// changing the group of flex items we're competing with for space.)
return hint | nsChangeHint_RepaintFrame | nsChangeHint_AllReflowHints;
}
if (mBoxSizing != aNewData.mBoxSizing) {
// Can affect both widths and heights; just a bad scene.
return hint | nsChangeHint_AllReflowHints;
}
if (mAlignItems != aNewData.mAlignItems ||
mAlignSelf != aNewData.mAlignSelf) {
return hint | nsChangeHint_AllReflowHints;
}
// Properties that apply to flex items:
if (mFlexBasis != aNewData.mFlexBasis || mFlexGrow != aNewData.mFlexGrow ||
mFlexShrink != aNewData.mFlexShrink) {
return hint | nsChangeHint_AllReflowHints;
}
// Properties that apply to flex containers:
// - flex-direction can swap a flex container between vertical & horizontal.
// - flex-wrap changes whether a flex container's children are wrapped, which
// impacts their sizing/positioning and hence impacts the container's size.
if (mFlexDirection != aNewData.mFlexDirection ||
mFlexWrap != aNewData.mFlexWrap) {
return hint | nsChangeHint_AllReflowHints;
}
// Properties that apply to grid containers:
// FIXME: only for grid containers
// (ie. 'display: grid' or 'display: inline-grid')
if (mGridTemplateColumns != aNewData.mGridTemplateColumns ||
mGridTemplateRows != aNewData.mGridTemplateRows ||
mGridTemplateAreas != aNewData.mGridTemplateAreas ||
mGridAutoColumns != aNewData.mGridAutoColumns ||
mGridAutoRows != aNewData.mGridAutoRows ||
mGridAutoFlow != aNewData.mGridAutoFlow ||
mMasonryAutoFlow != aNewData.mMasonryAutoFlow) {
return hint | nsChangeHint_AllReflowHints;
}
// Properties that apply to grid items:
// FIXME: only for grid items
// (ie. parent frame is 'display: grid' or 'display: inline-grid')
if (mGridColumnStart != aNewData.mGridColumnStart ||
mGridColumnEnd != aNewData.mGridColumnEnd ||
mGridRowStart != aNewData.mGridRowStart ||
mGridRowEnd != aNewData.mGridRowEnd ||
mColumnGap != aNewData.mColumnGap || mRowGap != aNewData.mRowGap) {
return hint | nsChangeHint_AllReflowHints;
}
// Changing 'justify-content/items/self' might affect the positioning,
// but it won't affect any sizing.
if (mJustifyContent != aNewData.mJustifyContent ||
mJustifyItems.computed != aNewData.mJustifyItems.computed ||
mJustifySelf != aNewData.mJustifySelf) {
hint |= nsChangeHint_NeedReflow;
}
// No need to do anything if specified justify-items changes, as long as the
// computed one (tested above) is unchanged.
if (mJustifyItems.specified != aNewData.mJustifyItems.specified) {
hint |= nsChangeHint_NeutralChange;
}
// 'align-content' doesn't apply to a single-line flexbox but we don't know
// if we're a flex container at this point so we can't optimize for that.
if (mAlignContent != aNewData.mAlignContent) {
hint |= nsChangeHint_NeedReflow;
}
bool widthChanged = GetWidth() != aNewData.GetWidth() ||
GetMinWidth() != aNewData.GetMinWidth() ||
GetMaxWidth() != aNewData.GetMaxWidth();
bool heightChanged = GetHeight() != aNewData.GetHeight() ||
GetMinHeight() != aNewData.GetMinHeight() ||
GetMaxHeight() != aNewData.GetMaxHeight();
if (widthChanged || heightChanged) {
// It doesn't matter whether we're looking at the old or new visibility
// struct, since a change between vertical and horizontal writing-mode will
// cause a reframe.
const bool isVertical = aOldStyle.StyleVisibility()->mWritingMode !=
StyleWritingModeProperty::HorizontalTb;
if (isVertical ? widthChanged : heightChanged) {
hint |= nsChangeHint_ReflowHintsForBSizeChange;
}
if (isVertical ? heightChanged : widthChanged) {
hint |= nsChangeHint_ReflowHintsForISizeChange;
}
}
if (mPositionAnchor != aNewData.mPositionAnchor) {
// 'position-anchor' provides a default anchor for other anchor positioning
// properties in the event that they don't specify one explicitly.
// TODO(jwatt): Re-evaluate what we're doing here.
hint |= nsChangeHint_NeutralChange;
}
if (mPositionVisibility != aNewData.mPositionVisibility ||
mPositionTryFallbacks != aNewData.mPositionTryFallbacks ||
mPositionTryOrder != aNewData.mPositionTryOrder ||
mPositionArea != aNewData.mPositionArea) {
hint |= nsChangeHint_NeutralChange;
}
if (mAspectRatio != aNewData.mAspectRatio) {
hint |= nsChangeHint_ReflowHintsForISizeChange |
nsChangeHint_ReflowHintsForBSizeChange;
}
// If any of the offsets have changed, then return the respective hints
// so that we would hopefully be able to avoid reflowing.
// Note that it is possible that we'll need to reflow when processing
// restyles, but we don't have enough information to make a good decision
// right now.
// Don't try to handle changes between types efficiently; at least for
// changing into/out of `auto`, we will hardly ever be able to avoid a reflow.
if (!InsetEquals(aNewData)) {
if (IsEqualInsetType(mOffset, aNewData.mOffset)) {
hint |=
nsChangeHint_RecomputePosition | nsChangeHint_UpdateParentOverflow;
} else {
hint |=
nsChangeHint_NeedReflow | nsChangeHint_ReflowChangesSizeOrPosition;
}
}
return hint;
}
const StyleContainIntrinsicSize& nsStylePosition::ContainIntrinsicBSize(
const WritingMode& aWM) const {
return aWM.IsVertical() ? mContainIntrinsicWidth : mContainIntrinsicHeight;
}
const StyleContainIntrinsicSize& nsStylePosition::ContainIntrinsicISize(
const WritingMode& aWM) const {
return aWM.IsVertical() ? mContainIntrinsicHeight : mContainIntrinsicWidth;
}
StyleAlignSelf nsStylePosition::UsedAlignSelf(
const ComputedStyle* aParent) const {
if (mAlignSelf._0 != StyleAlignFlags::AUTO) {
return mAlignSelf;
}
if (MOZ_LIKELY(aParent)) {
auto parentAlignItems = aParent->StylePosition()->mAlignItems;
MOZ_ASSERT(!(parentAlignItems._0 & StyleAlignFlags::LEGACY),
"align-items can't have 'legacy'");
return {parentAlignItems._0};
}
return {StyleAlignFlags::NORMAL};
}
StyleJustifySelf nsStylePosition::UsedJustifySelf(
const ComputedStyle* aParent) const {
if (mJustifySelf._0 != StyleAlignFlags::AUTO) {
return mJustifySelf;
}
if (MOZ_LIKELY(aParent)) {
const auto& inheritedJustifyItems =
aParent->StylePosition()->mJustifyItems.computed;
return {inheritedJustifyItems._0 & ~StyleAlignFlags::LEGACY};
}
return {StyleAlignFlags::NORMAL};
}
MOZ_RUNINIT const StyleInset nsStylePosition::kAutoInset = StyleInset::Auto();
MOZ_RUNINIT const StyleSize nsStylePosition::kAutoSize = StyleSize::Auto();
MOZ_RUNINIT const StyleMaxSize nsStylePosition::kNoneMaxSize =
StyleMaxSize::None();
// --------------------
// nsStyleTable
//
nsStyleTable::nsStyleTable()
: mLayoutStrategy(StyleTableLayout::Auto), mXSpan(1) {
MOZ_COUNT_CTOR(nsStyleTable);
}
nsStyleTable::nsStyleTable(const nsStyleTable& aSource)
: mLayoutStrategy(aSource.mLayoutStrategy), mXSpan(aSource.mXSpan) {
MOZ_COUNT_CTOR(nsStyleTable);
}
nsChangeHint nsStyleTable::CalcDifference(const nsStyleTable& aNewData) const {
if (mXSpan != aNewData.mXSpan ||
mLayoutStrategy != aNewData.mLayoutStrategy) {
return nsChangeHint_ReconstructFrame;
}
return nsChangeHint(0);
}
// -----------------------
// nsStyleTableBorder
nsStyleTableBorder::nsStyleTableBorder()
: mBorderSpacing{Length::Zero(), Length::Zero()},
mBorderCollapse(StyleBorderCollapse::Separate),
mCaptionSide(StyleCaptionSide::Top),
mEmptyCells(StyleEmptyCells::Show) {
MOZ_COUNT_CTOR(nsStyleTableBorder);
}
nsStyleTableBorder::nsStyleTableBorder(const nsStyleTableBorder& aSource)
: mBorderSpacing(aSource.mBorderSpacing),
mBorderCollapse(aSource.mBorderCollapse),
mCaptionSide(aSource.mCaptionSide),
mEmptyCells(aSource.mEmptyCells) {
MOZ_COUNT_CTOR(nsStyleTableBorder);
}
nsChangeHint nsStyleTableBorder::CalcDifference(
const nsStyleTableBorder& aNewData) const {
// Border-collapse changes need a reframe, because we use a different frame
// class for table cells in the collapsed border model. This is used to
// conserve memory when using the separated border model (collapsed borders
// require extra state to be stored).
if (mBorderCollapse != aNewData.mBorderCollapse) {
return nsChangeHint_ReconstructFrame;
}
if (mCaptionSide != aNewData.mCaptionSide ||
mBorderSpacing != aNewData.mBorderSpacing) {
return NS_STYLE_HINT_REFLOW;
}
if (mEmptyCells != aNewData.mEmptyCells) {
return NS_STYLE_HINT_VISUAL;
}
return nsChangeHint(0);
}
template <typename T>
static bool GradientItemsAreOpaque(
Span<const StyleGenericGradientItem<StyleColor, T>> aItems) {
for (auto& stop : aItems) {
if (stop.IsInterpolationHint()) {
continue;
}
auto& color = stop.IsSimpleColorStop() ? stop.AsSimpleColorStop()
: stop.AsComplexColorStop().color;
if (color.MaybeTransparent()) {
// We don't know the foreground color here, so if it's being used
// we must assume it might be transparent.
return false;
}
}
return true;
}
template <>
bool StyleGradient::IsOpaque() const {
if (IsLinear()) {
return GradientItemsAreOpaque(AsLinear().items.AsSpan());
}
if (IsRadial()) {
return GradientItemsAreOpaque(AsRadial().items.AsSpan());
}
return GradientItemsAreOpaque(AsConic().items.AsSpan());
}
template <>
bool StyleImage::IsOpaque() const {
if (IsImageSet()) {
return FinalImage().IsOpaque();
}
if (!IsComplete()) {
return false;
}
if (IsGradient()) {
return AsGradient()->IsOpaque();
}
if (IsElement()) {
return false;
}
MOZ_ASSERT(IsImageRequestType(), "unexpected image type");
MOZ_ASSERT(GetImageRequest(), "should've returned earlier above");
nsCOMPtr<imgIContainer> imageContainer;
GetImageRequest()->GetImage(getter_AddRefs(imageContainer));
MOZ_ASSERT(imageContainer, "IsComplete() said image container is ready");
return imageContainer->WillDrawOpaqueNow();
}
template <>
bool StyleImage::IsComplete() const {
switch (tag) {
case Tag::None:
return false;
case Tag::Gradient:
case Tag::Element:
return true;
case Tag::Url: {
if (!IsResolved()) {
return false;
}
imgRequestProxy* req = GetImageRequest();
if (!req) {
return false;
}
uint32_t status = imgIRequest::STATUS_ERROR;
return NS_SUCCEEDED(req->GetImageStatus(&status)) &&
(status & imgIRequest::STATUS_SIZE_AVAILABLE) &&
(status & imgIRequest::STATUS_FRAME_COMPLETE);
}
case Tag::ImageSet:
return FinalImage().IsComplete();
case Tag::CrossFade:
return true;
}
MOZ_ASSERT_UNREACHABLE("unexpected image type");
return false;
}
template <>
bool StyleImage::IsSizeAvailable() const {
switch (tag) {
case Tag::None:
return false;
case Tag::Gradient:
case Tag::Element:
return true;
case Tag::Url: {
imgRequestProxy* req = GetImageRequest();
if (!req) {
return false;
}
uint32_t status = imgIRequest::STATUS_ERROR;
return NS_SUCCEEDED(req->GetImageStatus(&status)) &&
!(status & imgIRequest::STATUS_ERROR) &&
(status & imgIRequest::STATUS_SIZE_AVAILABLE);
}
case Tag::ImageSet:
return FinalImage().IsSizeAvailable();
case Tag::CrossFade:
return true;
}
MOZ_ASSERT_UNREACHABLE("unexpected image type");
return false;
}
template <>
void StyleImage::ResolveImage(Document& aDoc, const StyleImage* aOld) {
if (IsResolved()) {
return;
}
const auto* old = aOld ? aOld->GetImageRequestURLValue() : nullptr;
const auto* url = GetImageRequestURLValue();
// We could avoid this const_cast generating more code but it's not really
// worth it.
const_cast<StyleComputedImageUrl*>(url)->ResolveImage(aDoc, old);
}
template <>
ImageResolution StyleImage::GetResolution(const ComputedStyle& aStyle) const {
ImageResolution resolution;
if (imgRequestProxy* request = GetImageRequest()) {
RefPtr<imgIContainer> image;
request->GetImage(getter_AddRefs(image));
if (image) {
resolution = image->GetResolution();
}
}
if (IsImageSet()) {
const auto& set = *AsImageSet();
auto items = set.items.AsSpan();
if (MOZ_LIKELY(set.selected_index < items.Length())) {
float r = items[set.selected_index].resolution._0;
resolution.ScaleBy(r);
}
}
if (aStyle.EffectiveZoom() != StyleZoom::ONE) {
resolution.ScaleBy(1.0f / aStyle.EffectiveZoom().ToFloat());
}
return resolution;
}
// --------------------
// nsStyleImageLayers
//
const nsCSSPropertyID nsStyleImageLayers::kBackgroundLayerTable[] = {
eCSSProperty_background, // shorthand
eCSSProperty_background_color, // color
eCSSProperty_background_image, // image
eCSSProperty_background_repeat, // repeat
eCSSProperty_background_position_x, // positionX
eCSSProperty_background_position_y, // positionY
eCSSProperty_background_clip, // clip
eCSSProperty_background_origin, // origin
eCSSProperty_background_size, // size
eCSSProperty_background_attachment, // attachment
eCSSProperty_UNKNOWN, // maskMode
eCSSProperty_UNKNOWN // composite
};
const nsCSSPropertyID nsStyleImageLayers::kMaskLayerTable[] = {
eCSSProperty_mask, // shorthand
eCSSProperty_UNKNOWN, // color
eCSSProperty_mask_image, // image
eCSSProperty_mask_repeat, // repeat
eCSSProperty_mask_position_x, // positionX
eCSSProperty_mask_position_y, // positionY
eCSSProperty_mask_clip, // clip
eCSSProperty_mask_origin, // origin
eCSSProperty_mask_size, // size
eCSSProperty_UNKNOWN, // attachment
eCSSProperty_mask_mode, // maskMode
eCSSProperty_mask_composite // composite
};
nsStyleImageLayers::nsStyleImageLayers(nsStyleImageLayers::LayerType aType)
: mAttachmentCount(1),
mClipCount(1),
mOriginCount(1),
mRepeatCount(1),
mPositionXCount(1),
mPositionYCount(1),
mImageCount(1),
mSizeCount(1),
mMaskModeCount(1),
mBlendModeCount(1),
mCompositeCount(1),
mLayers(nsStyleAutoArray<Layer>::WITH_SINGLE_INITIAL_ELEMENT) {
// Ensure first layer is initialized as specified layer type
mLayers[0].Initialize(aType);
}
nsStyleImageLayers::nsStyleImageLayers(const nsStyleImageLayers& aSource)
: mAttachmentCount(aSource.mAttachmentCount),
mClipCount(aSource.mClipCount),
mOriginCount(aSource.mOriginCount),
mRepeatCount(aSource.mRepeatCount),
mPositionXCount(aSource.mPositionXCount),
mPositionYCount(aSource.mPositionYCount),
mImageCount(aSource.mImageCount),
mSizeCount(aSource.mSizeCount),
mMaskModeCount(aSource.mMaskModeCount),
mBlendModeCount(aSource.mBlendModeCount),
mCompositeCount(aSource.mCompositeCount),
mLayers(aSource.mLayers.Clone()) {}
static bool AnyLayerIsElementImage(const nsStyleImageLayers& aLayers) {
NS_FOR_VISIBLE_IMAGE_LAYERS_BACK_TO_FRONT(i, aLayers) {
if (aLayers.mLayers[i].mImage.FinalImage().IsElement()) {
return true;
}
}
return false;
}
nsChangeHint nsStyleImageLayers::CalcDifference(
const nsStyleImageLayers& aNewLayers, LayerType aType) const {
nsChangeHint hint = nsChangeHint(0);
// If the number of visible images changes, then it's easy-peasy.
if (mImageCount != aNewLayers.mImageCount) {
hint |= nsChangeHint_RepaintFrame;
if (aType == nsStyleImageLayers::LayerType::Mask ||
AnyLayerIsElementImage(*this) || AnyLayerIsElementImage(aNewLayers)) {
hint |= nsChangeHint_UpdateEffects;
}
return hint;
}
const nsStyleImageLayers& moreLayers =
mLayers.Length() > aNewLayers.mLayers.Length() ? *this : aNewLayers;
const nsStyleImageLayers& lessLayers =
mLayers.Length() > aNewLayers.mLayers.Length() ? aNewLayers : *this;
for (size_t i = 0; i < moreLayers.mLayers.Length(); ++i) {
const Layer& moreLayersLayer = moreLayers.mLayers[i];
if (i < moreLayers.mImageCount) {
// This is a visible image we're diffing, we may need to repaint.
const Layer& lessLayersLayer = lessLayers.mLayers[i];
nsChangeHint layerDifference =
moreLayersLayer.CalcDifference(lessLayersLayer);
if (layerDifference &&
(moreLayersLayer.mImage.FinalImage().IsElement() ||
lessLayersLayer.mImage.FinalImage().IsElement())) {
layerDifference |=
nsChangeHint_UpdateEffects | nsChangeHint_RepaintFrame;
}
hint |= layerDifference;
continue;
}
if (hint) {
// If they're different by now, we're done.
return hint;
}
if (i >= lessLayers.mLayers.Length()) {
// The layer count differs, we know some property has changed, but if we
// got here we know it won't affect rendering.
return nsChangeHint_NeutralChange;
}
const Layer& lessLayersLayer = lessLayers.mLayers[i];
MOZ_ASSERT(moreLayersLayer.mImage.IsNone());
MOZ_ASSERT(lessLayersLayer.mImage.IsNone());
if (moreLayersLayer.CalcDifference(lessLayersLayer)) {
// We don't care about the difference returned, we know it's not visible,
// but if something changed, then we need to return the neutral change.
return nsChangeHint_NeutralChange;
}
}
if (hint) {
// If they're different by now, we're done.
return hint;
}
// We could have same layers and values, but different count still.
if (mAttachmentCount != aNewLayers.mAttachmentCount ||
mBlendModeCount != aNewLayers.mBlendModeCount ||
mClipCount != aNewLayers.mClipCount ||
mCompositeCount != aNewLayers.mCompositeCount ||
mMaskModeCount != aNewLayers.mMaskModeCount ||
mOriginCount != aNewLayers.mOriginCount ||
mRepeatCount != aNewLayers.mRepeatCount ||
mPositionXCount != aNewLayers.mPositionXCount ||
mPositionYCount != aNewLayers.mPositionYCount ||
mSizeCount != aNewLayers.mSizeCount) {
hint |= nsChangeHint_NeutralChange;
}
return hint;
}
nsStyleImageLayers& nsStyleImageLayers::operator=(
const nsStyleImageLayers& aOther) {
mAttachmentCount = aOther.mAttachmentCount;
mClipCount = aOther.mClipCount;
mOriginCount = aOther.mOriginCount;
mRepeatCount = aOther.mRepeatCount;
mPositionXCount = aOther.mPositionXCount;
mPositionYCount = aOther.mPositionYCount;
mImageCount = aOther.mImageCount;
mSizeCount = aOther.mSizeCount;
mMaskModeCount = aOther.mMaskModeCount;
mBlendModeCount = aOther.mBlendModeCount;
mCompositeCount = aOther.mCompositeCount;
mLayers = aOther.mLayers.Clone();
return *this;
}
bool nsStyleImageLayers::operator==(const nsStyleImageLayers& aOther) const {
if (mAttachmentCount != aOther.mAttachmentCount ||
mClipCount != aOther.mClipCount || mOriginCount != aOther.mOriginCount ||
mRepeatCount != aOther.mRepeatCount ||
mPositionXCount != aOther.mPositionXCount ||
mPositionYCount != aOther.mPositionYCount ||
mImageCount != aOther.mImageCount || mSizeCount != aOther.mSizeCount ||
mMaskModeCount != aOther.mMaskModeCount ||
mBlendModeCount != aOther.mBlendModeCount) {
return false;
}
if (mLayers.Length() != aOther.mLayers.Length()) {
return false;
}
for (uint32_t i = 0; i < mLayers.Length(); i++) {
if (mLayers[i].mPosition != aOther.mLayers[i].mPosition ||
mLayers[i].mImage != aOther.mLayers[i].mImage ||
mLayers[i].mSize != aOther.mLayers[i].mSize ||
mLayers[i].mClip != aOther.mLayers[i].mClip ||
mLayers[i].mOrigin != aOther.mLayers[i].mOrigin ||
mLayers[i].mAttachment != aOther.mLayers[i].mAttachment ||
mLayers[i].mBlendMode != aOther.mLayers[i].mBlendMode ||
mLayers[i].mComposite != aOther.mLayers[i].mComposite ||
mLayers[i].mMaskMode != aOther.mLayers[i].mMaskMode ||
mLayers[i].mRepeat != aOther.mLayers[i].mRepeat) {
return false;
}
}
return true;
}
static bool SizeDependsOnPositioningAreaSize(const StyleBackgroundSize& aSize,
const StyleImage& aImage) {
MOZ_ASSERT(!aImage.IsNone(), "caller should have handled this");
MOZ_ASSERT(!aImage.IsImageSet(), "caller should have handled this");
// Contain and cover straightforwardly depend on frame size.
if (aSize.IsCover() || aSize.IsContain()) {
return true;
}
MOZ_ASSERT(aSize.IsExplicitSize());
const auto& size = aSize.AsExplicitSize();
// If either dimension contains a non-zero percentage, rendering for that
// dimension straightforwardly depends on frame size.
if (size.width.HasPercent() || size.height.HasPercent()) {
return true;
}
// If both dimensions are fixed lengths, there's no dependency.
if (!size.width.IsAuto() && !size.height.IsAuto()) {
return false;
}
// Gradient rendering depends on frame size when auto is involved because
// gradients have no intrinsic ratio or dimensions, and therefore the relevant
// dimension is "treat[ed] as 100%".
if (aImage.IsGradient()) {
return true;
}
// XXX Element rendering for auto or fixed length doesn't depend on frame size
// according to the spec. However, we don't implement the spec yet, so
// for now we bail and say element() plus auto affects ultimate size.
if (aImage.IsElement()) {
return true;
}
MOZ_ASSERT(aImage.IsImageRequestType(), "Missed some image");
if (auto* request = aImage.GetImageRequest()) {
nsCOMPtr<imgIContainer> imgContainer;
request->GetImage(getter_AddRefs(imgContainer));
if (imgContainer) {
CSSIntSize imageSize;
AspectRatio imageRatio;
bool hasWidth, hasHeight;
// We could bother getting the right resolution here but it doesn't matter
// since we ignore `imageSize`.
nsLayoutUtils::ComputeSizeForDrawing(imgContainer, ImageResolution(),
imageSize, imageRatio, hasWidth,
hasHeight);
// If the image has a fixed width and height, rendering never depends on
// the frame size.
if (hasWidth && hasHeight) {
return false;
}
// If the image has an intrinsic ratio, rendering will depend on frame
// size when background-size is all auto.
if (imageRatio) {
return size.width.IsAuto() == size.height.IsAuto();
}
// Otherwise, rendering depends on frame size when the image dimensions
// and background-size don't complement each other.
return !(hasWidth && size.width.IsLengthPercentage()) &&
!(hasHeight && size.height.IsLengthPercentage());
}
}
// Passed the gauntlet: no dependency.
return false;
}
nsStyleImageLayers::Layer::Layer()
: mImage(StyleImage::None()),
mSize(StyleBackgroundSize::ExplicitSize(LengthPercentageOrAuto::Auto(),
LengthPercentageOrAuto::Auto())),
mClip(StyleGeometryBox::BorderBox),
mAttachment(StyleImageLayerAttachment::Scroll),
mBlendMode(StyleBlend::Normal),
mComposite(StyleMaskComposite::Add),
mMaskMode(StyleMaskMode::MatchSource) {}
nsStyleImageLayers::Layer::~Layer() = default;
void nsStyleImageLayers::Layer::Initialize(
nsStyleImageLayers::LayerType aType) {
mPosition = Position::FromPercentage(0.);
if (aType == LayerType::Background) {
mOrigin = StyleGeometryBox::PaddingBox;
} else {
MOZ_ASSERT(aType == LayerType::Mask, "unsupported layer type.");
mOrigin = StyleGeometryBox::BorderBox;
}
}
bool nsStyleImageLayers::Layer::
RenderingMightDependOnPositioningAreaSizeChange() const {
// Do we even have an image?
if (mImage.IsNone()) {
return false;
}
return mPosition.DependsOnPositioningAreaSize() ||
SizeDependsOnPositioningAreaSize(mSize, mImage.FinalImage()) ||
mRepeat.DependsOnPositioningAreaSize();
}
bool nsStyleImageLayers::Layer::operator==(const Layer& aOther) const {
return mAttachment == aOther.mAttachment && mClip == aOther.mClip &&
mOrigin == aOther.mOrigin && mRepeat == aOther.mRepeat &&
mBlendMode == aOther.mBlendMode && mPosition == aOther.mPosition &&
mSize == aOther.mSize && mImage == aOther.mImage &&
mMaskMode == aOther.mMaskMode && mComposite == aOther.mComposite;
}
template <class ComputedValueItem>
static void FillImageLayerList(
nsStyleAutoArray<nsStyleImageLayers::Layer>& aLayers,
ComputedValueItem nsStyleImageLayers::Layer::*aResultLocation,
uint32_t aItemCount, uint32_t aFillCount) {
MOZ_ASSERT(aFillCount <= aLayers.Length(), "unexpected array length");
for (uint32_t sourceLayer = 0, destLayer = aItemCount; destLayer < aFillCount;
++sourceLayer, ++destLayer) {
aLayers[destLayer].*aResultLocation = aLayers[sourceLayer].*aResultLocation;
}
}
// The same as FillImageLayerList, but for values stored in
// layer.mPosition.*aResultLocation instead of layer.*aResultLocation.
static void FillImageLayerPositionCoordList(
nsStyleAutoArray<nsStyleImageLayers::Layer>& aLayers,
LengthPercentage Position::*aResultLocation, uint32_t aItemCount,
uint32_t aFillCount) {
MOZ_ASSERT(aFillCount <= aLayers.Length(), "unexpected array length");
for (uint32_t sourceLayer = 0, destLayer = aItemCount; destLayer < aFillCount;
++sourceLayer, ++destLayer) {
aLayers[destLayer].mPosition.*aResultLocation =
aLayers[sourceLayer].mPosition.*aResultLocation;
}
}
void nsStyleImageLayers::FillAllLayers(uint32_t aMaxItemCount) {
// Delete any extra items. We need to keep layers in which any
// property was specified.
mLayers.TruncateLengthNonZero(aMaxItemCount);
uint32_t fillCount = mImageCount;
FillImageLayerList(mLayers, &Layer::mImage, mImageCount, fillCount);
FillImageLayerList(mLayers, &Layer::mRepeat, mRepeatCount, fillCount);
FillImageLayerList(mLayers, &Layer::mAttachment, mAttachmentCount, fillCount);
FillImageLayerList(mLayers, &Layer::mClip, mClipCount, fillCount);
FillImageLayerList(mLayers, &Layer::mBlendMode, mBlendModeCount, fillCount);
FillImageLayerList(mLayers, &Layer::mOrigin, mOriginCount, fillCount);
FillImageLayerPositionCoordList(mLayers, &Position::horizontal,
mPositionXCount, fillCount);
FillImageLayerPositionCoordList(mLayers, &Position::vertical, mPositionYCount,
fillCount);
FillImageLayerList(mLayers, &Layer::mSize, mSizeCount, fillCount);
FillImageLayerList(mLayers, &Layer::mMaskMode, mMaskModeCount, fillCount);
FillImageLayerList(mLayers, &Layer::mComposite, mCompositeCount, fillCount);
}
static bool UrlValuesEqual(const StyleImage& aImage,
const StyleImage& aOtherImage) {
const auto* url = aImage.GetImageRequestURLValue();
const auto* other = aOtherImage.GetImageRequestURLValue();
return url == other || (url && other && *url == *other);
}
nsChangeHint nsStyleImageLayers::Layer::CalcDifference(
const nsStyleImageLayers::Layer& aNewLayer) const {
nsChangeHint hint = nsChangeHint(0);
if (!UrlValuesEqual(mImage, aNewLayer.mImage)) {
hint |= nsChangeHint_RepaintFrame | nsChangeHint_UpdateEffects;
} else if (mAttachment != aNewLayer.mAttachment || mClip != aNewLayer.mClip ||
mOrigin != aNewLayer.mOrigin || mRepeat != aNewLayer.mRepeat ||
mBlendMode != aNewLayer.mBlendMode || mSize != aNewLayer.mSize ||
mImage != aNewLayer.mImage || mMaskMode != aNewLayer.mMaskMode ||
mComposite != aNewLayer.mComposite) {
hint |= nsChangeHint_RepaintFrame;
}
if (mPosition != aNewLayer.mPosition) {
hint |= nsChangeHint_UpdateBackgroundPosition;
}
return hint;
}
// --------------------
// nsStyleBackground
//
nsStyleBackground::nsStyleBackground()
: mImage(nsStyleImageLayers::LayerType::Background),
mBackgroundColor(StyleColor::Transparent()) {
MOZ_COUNT_CTOR(nsStyleBackground);
}
nsStyleBackground::nsStyleBackground(const nsStyleBackground& aSource)
: mImage(aSource.mImage), mBackgroundColor(aSource.mBackgroundColor) {
MOZ_COUNT_CTOR(nsStyleBackground);
}
void nsStyleBackground::TriggerImageLoads(Document& aDocument,
const nsStyleBackground* aOldStyle) {
MOZ_ASSERT(NS_IsMainThread());
mImage.ResolveImages(aDocument, aOldStyle ? &aOldStyle->mImage : nullptr);
}
nsChangeHint nsStyleBackground::CalcDifference(
const nsStyleBackground& aNewData) const {
nsChangeHint hint = nsChangeHint(0);
if (mBackgroundColor != aNewData.mBackgroundColor) {
hint |= nsChangeHint_RepaintFrame;
}
hint |= mImage.CalcDifference(aNewData.mImage,
nsStyleImageLayers::LayerType::Background);
return hint;
}
bool nsStyleBackground::HasFixedBackground(nsIFrame* aFrame) const {
NS_FOR_VISIBLE_IMAGE_LAYERS_BACK_TO_FRONT(i, mImage) {
const nsStyleImageLayers::Layer& layer = mImage.mLayers[i];
if (layer.mAttachment == StyleImageLayerAttachment::Fixed &&
!layer.mImage.IsNone() && !nsLayoutUtils::IsTransformed(aFrame)) {
return true;
}
}
return false;
}
nscolor nsStyleBackground::BackgroundColor(const nsIFrame* aFrame) const {
return mBackgroundColor.CalcColor(aFrame);
}
nscolor nsStyleBackground::BackgroundColor(const ComputedStyle* aStyle) const {
return mBackgroundColor.CalcColor(*aStyle);
}
bool nsStyleBackground::IsTransparent(const nsIFrame* aFrame) const {
return IsTransparent(aFrame->Style());
}
bool nsStyleBackground::IsTransparent(const ComputedStyle* aStyle) const {
return BottomLayer().mImage.IsNone() && mImage.mImageCount == 1 &&
NS_GET_A(BackgroundColor(aStyle)) == 0;
}
StyleTransition::StyleTransition(const StyleTransition& aCopy) = default;
bool StyleTransition::operator==(const StyleTransition& aOther) const {
return mTimingFunction == aOther.mTimingFunction &&
mDuration == aOther.mDuration && mDelay == aOther.mDelay &&
mProperty == aOther.mProperty && mBehavior == aOther.mBehavior;
}
StyleAnimation::StyleAnimation(const StyleAnimation& aCopy) = default;
bool StyleAnimation::operator==(const StyleAnimation& aOther) const {
return mTimingFunction == aOther.mTimingFunction &&
mDuration == aOther.mDuration && mDelay == aOther.mDelay &&
mName == aOther.mName && mDirection == aOther.mDirection &&
mFillMode == aOther.mFillMode && mPlayState == aOther.mPlayState &&
mIterationCount == aOther.mIterationCount &&
mComposition == aOther.mComposition && mTimeline == aOther.mTimeline;
}
// --------------------
// nsStyleDisplay
//
nsStyleDisplay::nsStyleDisplay()
: mDisplay(StyleDisplay::Inline),
mOriginalDisplay(StyleDisplay::Inline),
mContentVisibility(StyleContentVisibility::Visible),
mContainerType(StyleContainerType::Normal),
mAppearance(StyleAppearance::None),
mContain(StyleContain::NONE),
mEffectiveContainment(StyleContain::NONE),
mDefaultAppearance(StyleAppearance::None),
mPosition(StylePositionProperty::Static),
mFloat(StyleFloat::None),
mClear(StyleClear::None),
mBreakInside(StyleBreakWithin::Auto),
mBreakBefore(StyleBreakBetween::Auto),
mBreakAfter(StyleBreakBetween::Auto),
mOverflowX(StyleOverflow::Visible),
mOverflowY(StyleOverflow::Visible),
mOverflowClipBoxBlock(StyleOverflowClipBox::PaddingBox),
mOverflowClipBoxInline(StyleOverflowClipBox::PaddingBox),
mScrollbarGutter(StyleScrollbarGutter::AUTO),
mResize(StyleResize::None),
mOrient(StyleOrient::Inline),
mIsolation(StyleIsolation::Auto),
mTopLayer(StyleTopLayer::None),
mTouchAction(StyleTouchAction::AUTO),
mScrollBehavior(StyleScrollBehavior::Auto),
mOverscrollBehaviorX(StyleOverscrollBehavior::Auto),
mOverscrollBehaviorY(StyleOverscrollBehavior::Auto),
mOverflowAnchor(StyleOverflowAnchor::Auto),
mScrollSnapAlign{StyleScrollSnapAlignKeyword::None,
StyleScrollSnapAlignKeyword::None},
mScrollSnapStop{StyleScrollSnapStop::Normal},
mScrollSnapType{StyleScrollSnapAxis::Both,
StyleScrollSnapStrictness::None},
mBackfaceVisibility(StyleBackfaceVisibility::Visible),
mTransformStyle(StyleTransformStyle::Flat),
mTransformBox(StyleTransformBox::ViewBox),
mRotate(StyleRotate::None()),
mTranslate(StyleTranslate::None()),
mScale(StyleScale::None()),
mWillChange{{}, {0}},
mOffsetPath(StyleOffsetPath::None()),
mOffsetDistance(LengthPercentage::Zero()),
mOffsetRotate{true, StyleAngle{0.0}},
mOffsetAnchor(StylePositionOrAuto::Auto()),
mOffsetPosition(StyleOffsetPosition::Normal()),
mTransformOrigin{LengthPercentage::FromPercentage(0.5),
LengthPercentage::FromPercentage(0.5),
{0.}},
mChildPerspective(StylePerspective::None()),
mPerspectiveOrigin(Position::FromPercentage(0.5f)),
mVerticalAlign(
StyleVerticalAlign::Keyword(StyleVerticalAlignKeyword::Baseline)),
mBaselineSource(StyleBaselineSource::Auto),
mWebkitLineClamp(0),
mShapeMargin(LengthPercentage::Zero()),
mShapeOutside(StyleShapeOutside::None()),
mAnchorScope(StyleAnchorScope::None()) {
MOZ_COUNT_CTOR(nsStyleDisplay);
}
nsStyleDisplay::nsStyleDisplay(const nsStyleDisplay& aSource)
: mDisplay(aSource.mDisplay),
mOriginalDisplay(aSource.mOriginalDisplay),
mContentVisibility(aSource.mContentVisibility),
mContainerType(aSource.mContainerType),
mAppearance(aSource.mAppearance),
mContain(aSource.mContain),
mEffectiveContainment(aSource.mEffectiveContainment),
mDefaultAppearance(aSource.mDefaultAppearance),
mPosition(aSource.mPosition),
mFloat(aSource.mFloat),
mClear(aSource.mClear),
mBreakInside(aSource.mBreakInside),
mBreakBefore(aSource.mBreakBefore),
mBreakAfter(aSource.mBreakAfter),
mOverflowX(aSource.mOverflowX),
mOverflowY(aSource.mOverflowY),
mOverflowClipBoxBlock(aSource.mOverflowClipBoxBlock),
mOverflowClipBoxInline(aSource.mOverflowClipBoxInline),
mScrollbarGutter(aSource.mScrollbarGutter),
mResize(aSource.mResize),
mOrient(aSource.mOrient),
mIsolation(aSource.mIsolation),
mTopLayer(aSource.mTopLayer),
mTouchAction(aSource.mTouchAction),
mScrollBehavior(aSource.mScrollBehavior),
mOverscrollBehaviorX(aSource.mOverscrollBehaviorX),
mOverscrollBehaviorY(aSource.mOverscrollBehaviorY),
mOverflowAnchor(aSource.mOverflowAnchor),
mScrollSnapAlign(aSource.mScrollSnapAlign),
mScrollSnapStop(aSource.mScrollSnapStop),
mScrollSnapType(aSource.mScrollSnapType),
mBackfaceVisibility(aSource.mBackfaceVisibility),
mTransformStyle(aSource.mTransformStyle),
mTransformBox(aSource.mTransformBox),
mTransform(aSource.mTransform),
mRotate(aSource.mRotate),
mTranslate(aSource.mTranslate),
mScale(aSource.mScale),
mContainerName(aSource.mContainerName),
mWillChange(aSource.mWillChange),
mOffsetPath(aSource.mOffsetPath),
mOffsetDistance(aSource.mOffsetDistance),
mOffsetRotate(aSource.mOffsetRotate),
mOffsetAnchor(aSource.mOffsetAnchor),
mOffsetPosition(aSource.mOffsetPosition),
mTransformOrigin(aSource.mTransformOrigin),
mChildPerspective(aSource.mChildPerspective),
mPerspectiveOrigin(aSource.mPerspectiveOrigin),
mVerticalAlign(aSource.mVerticalAlign),
mBaselineSource(aSource.mBaselineSource),
mWebkitLineClamp(aSource.mWebkitLineClamp),
mShapeImageThreshold(aSource.mShapeImageThreshold),
mShapeMargin(aSource.mShapeMargin),
mShapeOutside(aSource.mShapeOutside),
mAnchorName(aSource.mAnchorName),
mAnchorScope(aSource.mAnchorScope) {
MOZ_COUNT_CTOR(nsStyleDisplay);
}
void nsStyleDisplay::TriggerImageLoads(Document& aDocument,
const nsStyleDisplay* aOldStyle) {
MOZ_ASSERT(NS_IsMainThread());
if (mShapeOutside.IsImage()) {
const auto* old = aOldStyle && aOldStyle->mShapeOutside.IsImage()
? &aOldStyle->mShapeOutside.AsImage()
: nullptr;
// Const-cast is ugly but legit, we could avoid it by generating mut-casts
// with cbindgen.
const_cast<StyleImage&>(mShapeOutside.AsImage())
.ResolveImage(aDocument, old);
}
}
template <typename TransformLike>
static inline nsChangeHint CompareTransformValues(
const TransformLike& aOldTransform, const TransformLike& aNewTransform) {
nsChangeHint result = nsChangeHint(0);
// Note: If we add a new change hint for transform changes here, we have to
// modify KeyframeEffect::CalculateCumulativeChangeHint too!
if (aOldTransform != aNewTransform) {
result |= nsChangeHint_UpdateTransformLayer;
if (!aOldTransform.IsNone() && !aNewTransform.IsNone()) {
result |= nsChangeHint_UpdatePostTransformOverflow;
} else {
result |= nsChangeHint_UpdateOverflow;
}
}
return result;
}
static inline nsChangeHint CompareMotionValues(
const nsStyleDisplay& aDisplay, const nsStyleDisplay& aNewDisplay) {
if (aDisplay.mOffsetPath == aNewDisplay.mOffsetPath) {
if (aDisplay.mOffsetDistance == aNewDisplay.mOffsetDistance &&
aDisplay.mOffsetRotate == aNewDisplay.mOffsetRotate &&
aDisplay.mOffsetAnchor == aNewDisplay.mOffsetAnchor &&
aDisplay.mOffsetPosition == aNewDisplay.mOffsetPosition) {
return nsChangeHint(0);
}
// No motion path transform is applied.
if (aDisplay.mOffsetPath.IsNone()) {
return nsChangeHint_NeutralChange;
}
}
// (or UpdateTransformLayer) if there's already a transform.
// Set the same hints as what we use for transform because motion path is
// a kind of transform and will be combined with other transforms.
nsChangeHint result = nsChangeHint_UpdateTransformLayer;
if (!aDisplay.mOffsetPath.IsNone() && !aNewDisplay.mOffsetPath.IsNone()) {
result |= nsChangeHint_UpdatePostTransformOverflow;
} else {
result |= nsChangeHint_UpdateOverflow;
}
return result;
}
static bool ScrollbarGenerationChanged(const nsStyleDisplay& aOld,
const nsStyleDisplay& aNew) {
auto changed = [](StyleOverflow aOld, StyleOverflow aNew) {
return aOld != aNew &&
(aOld == StyleOverflow::Hidden || aNew == StyleOverflow::Hidden);
};
return changed(aOld.mOverflowX, aNew.mOverflowX) ||
changed(aOld.mOverflowY, aNew.mOverflowY);
}
static bool AppearanceValueAffectsFrames(StyleAppearance aAppearance,
StyleAppearance aDefaultAppearance) {
switch (aAppearance) {
case StyleAppearance::None:
// Checkbox / radio with appearance none doesn't construct an
// nsCheckboxRadioFrame.
return aDefaultAppearance == StyleAppearance::Checkbox ||
aDefaultAppearance == StyleAppearance::Radio;
case StyleAppearance::Textfield:
// This is for <input type=number/search> where we allow authors to
// specify a |-moz-appearance:textfield| to get a control without buttons.
// We need to reframe since this affects the spinbox creation in
// nsNumber/SearchControlFrame::CreateAnonymousContent.
return aDefaultAppearance == StyleAppearance::NumberInput ||
aDefaultAppearance == StyleAppearance::PasswordInput ||
aDefaultAppearance == StyleAppearance::Searchfield;
case StyleAppearance::Menulist:
// This affects the menulist button creation.
return aDefaultAppearance == StyleAppearance::Menulist;
default:
return false;
}
}
nsChangeHint nsStyleDisplay::CalcDifference(
const nsStyleDisplay& aNewData, const ComputedStyle& aOldStyle) const {
if (mDisplay != aNewData.mDisplay ||
(mFloat == StyleFloat::None) != (aNewData.mFloat == StyleFloat::None) ||
mTopLayer != aNewData.mTopLayer || mResize != aNewData.mResize) {
return nsChangeHint_ReconstructFrame;
}
auto oldAppearance = EffectiveAppearance();
auto newAppearance = aNewData.EffectiveAppearance();
if (oldAppearance != newAppearance) {
// Changes to the mDefaultAppearance values handled in
// AppearanceValueAffectsFrames reconstruct their frames via other means.
// E.g. switching the <input> type attribute reframes via
// GetAttributeChangeHint. Thus, it doesn't matter whether we pick
// mDefaultAppearance or aNewData.mDefaultAppearance for the check below.
if (AppearanceValueAffectsFrames(oldAppearance, mDefaultAppearance) ||
AppearanceValueAffectsFrames(newAppearance, mDefaultAppearance)) {
return nsChangeHint_ReconstructFrame;
}
}
auto hint = nsChangeHint(0);
const auto containmentDiff =
mEffectiveContainment ^ aNewData.mEffectiveContainment;
if (containmentDiff) {
if (containmentDiff & StyleContain::STYLE) {
// Style containment affects counters so we need to re-frame.
return nsChangeHint_ReconstructFrame;
}
if (containmentDiff & (StyleContain::PAINT | StyleContain::LAYOUT)) {
// Paint and layout containment boxes are absolutely/fixed positioning
// containers.
hint |= nsChangeHint_UpdateContainingBlock;
}
// The other container types only need a reflow.
hint |= nsChangeHint_AllReflowHints | nsChangeHint_RepaintFrame;
}
if (mPosition != aNewData.mPosition) {
if (IsAbsolutelyPositionedStyle() ||
aNewData.IsAbsolutelyPositionedStyle()) {
// This changes our parent relationship on the frame tree and / or needs
// to create a placeholder, so gotta reframe. There are some cases (when
// switching from fixed to absolute or viceversa, if our containing block
// happens to remain the same, i.e., if it has a transform or such) where
// this wouldn't really be needed (though we'd still need to move the
// frame from one child list to another). In any case we don't have a hand
// to that information from here, and it doesn't seem like a case worth
// optimizing for.
return nsChangeHint_ReconstructFrame;
}
// We start or stop being a containing block for abspos descendants. This
// also causes painting to change, as we'd become a pseudo-stacking context.
if (IsRelativelyOrStickyPositionedStyle() !=
aNewData.IsRelativelyOrStickyPositionedStyle()) {
hint |= nsChangeHint_UpdateContainingBlock | nsChangeHint_RepaintFrame;
}
if (IsPositionForcingStackingContext() !=
aNewData.IsPositionForcingStackingContext()) {
hint |= nsChangeHint_RepaintFrame;
}
// On top of that: if the above ends up not reframing, we need a reflow to
// compute our relative, static or sticky position.
hint |= nsChangeHint_NeedReflow | nsChangeHint_ReflowChangesSizeOrPosition;
}
if (mScrollSnapAlign != aNewData.mScrollSnapAlign ||
mScrollSnapType != aNewData.mScrollSnapType ||
mScrollSnapStop != aNewData.mScrollSnapStop) {
hint |= nsChangeHint_RepaintFrame;
}
if (mScrollBehavior != aNewData.mScrollBehavior) {
hint |= nsChangeHint_NeutralChange;
}
if (mOverflowX != aNewData.mOverflowX || mOverflowY != aNewData.mOverflowY) {
const bool isScrollable = IsScrollableOverflow();
if (isScrollable != aNewData.IsScrollableOverflow()) {
// We may need to construct or destroy a scroll frame as a result of this
// change. If we don't, we still need to update our overflow in some cases
// (like svg:foreignObject), which ignore the scrollable-ness of our
// overflow.
hint |= nsChangeHint_ScrollbarChange | nsChangeHint_UpdateOverflow |
nsChangeHint_RepaintFrame;
} else if (isScrollable) {
if (ScrollbarGenerationChanged(*this, aNewData)) {
// We might need to reframe in the case of hidden -> non-hidden case
// though, since ScrollContainerFrame::CreateAnonymousContent avoids
// creating scrollbars altogether for overflow: hidden. That seems it
// could create some interesting perf cliffs...
hint |= nsChangeHint_ScrollbarChange;
} else {
// Otherwise, for changes where both overflow values are scrollable,
// means that scrollbars may appear or disappear. We need to reflow,
// since reflow is what determines which scrollbars if any are visible.
hint |= nsChangeHint_ReflowHintsForScrollbarChange;
}
} else {
// Otherwise this is a change between 'visible' and 'clip'.
// Here only whether we have a 'clip' changes, so just repaint and
// update our overflow areas in that case.
hint |= nsChangeHint_UpdateOverflow | nsChangeHint_RepaintFrame;
}
}
if (mScrollbarGutter != aNewData.mScrollbarGutter) {
if (IsScrollableOverflow() || aOldStyle.IsRootElementStyle()) {
// Changing scrollbar-gutter affects available inline-size of a inner
// scrolled frame, so we need a reflow for scrollbar change. Note that the
// root is always scrollable in HTML, even if its style doesn't say so.
hint |= nsChangeHint_ReflowHintsForScrollbarChange;
} else {
// scrollbar-gutter only applies to scroll containers.
hint |= nsChangeHint_NeutralChange;
}
}
if (mFloat != aNewData.mFloat) {
// Changing which side we're floating on (float:none was handled above).
hint |= nsChangeHint_ReflowHintsForFloatAreaChange;
}
if (mShapeOutside != aNewData.mShapeOutside ||
mShapeMargin != aNewData.mShapeMargin ||
mShapeImageThreshold != aNewData.mShapeImageThreshold) {
if (aNewData.mFloat != StyleFloat::None) {
// If we are floating, and our shape-outside, shape-margin, or
// shape-image-threshold are changed, our descendants are not impacted,
// but our ancestor and siblings are.
hint |= nsChangeHint_ReflowHintsForFloatAreaChange;
} else {
// shape-outside or shape-margin or shape-image-threshold changed,
// but we don't need to reflow because we're not floating.
hint |= nsChangeHint_NeutralChange;
}
}
if (mWebkitLineClamp != aNewData.mWebkitLineClamp ||
mVerticalAlign != aNewData.mVerticalAlign ||
mBaselineSource != aNewData.mBaselineSource) {
// XXX Can this just be AllReflowHints + RepaintFrame, and be included in
// the block below?
hint |= NS_STYLE_HINT_REFLOW;
}
// XXX the following is conservative, for now: changing float breaking
// shouldn't necessarily require a repaint, reflow should suffice.
//
// FIXME(emilio): We definitely change the frame tree in nsCSSFrameConstructor
// based on break-before / break-after... Shouldn't that reframe?
if (mClear != aNewData.mClear || mBreakInside != aNewData.mBreakInside ||
mBreakBefore != aNewData.mBreakBefore ||
mBreakAfter != aNewData.mBreakAfter ||
mAppearance != aNewData.mAppearance ||
mDefaultAppearance != aNewData.mDefaultAppearance ||
mOrient != aNewData.mOrient ||
mOverflowClipBoxBlock != aNewData.mOverflowClipBoxBlock ||
mOverflowClipBoxInline != aNewData.mOverflowClipBoxInline) {
hint |= nsChangeHint_AllReflowHints | nsChangeHint_RepaintFrame;
}
if (mIsolation != aNewData.mIsolation) {
hint |= nsChangeHint_RepaintFrame;
}
/* If we've added or removed the transform property, we need to reconstruct
* the frame to add or remove the view object, and also to handle abs-pos and
* fixed-pos containers.
*/
if (HasTransformStyle() != aNewData.HasTransformStyle()) {
hint |= nsChangeHint_ComprehensiveAddOrRemoveTransform;
} else {
/* Otherwise, if we've kept the property lying around and we already had a
* transform, we need to see whether or not we've changed the transform.
* If so, we need to recompute its overflow rect (which probably changed
* if the transform changed) and to redraw within the bounds of that new
* overflow rect.
*
* If the property isn't present in either style struct, we still do the
* comparisons but turn all the resulting change hints into
* nsChangeHint_NeutralChange.
*/
nsChangeHint transformHint = CalcTransformPropertyDifference(aNewData);
if (transformHint) {
if (HasTransformStyle()) {
hint |= transformHint;
} else {
hint |= nsChangeHint_NeutralChange;
}
}
}
if (HasPerspectiveStyle() != aNewData.HasPerspectiveStyle()) {
// A change from/to being a containing block for position:fixed.
hint |= nsChangeHint_UpdateContainingBlock | nsChangeHint_UpdateOverflow |
nsChangeHint_RepaintFrame;
} else if (mChildPerspective != aNewData.mChildPerspective) {
hint |= nsChangeHint_UpdateOverflow | nsChangeHint_RepaintFrame;
}
// Note that the HasTransformStyle() != aNewData.HasTransformStyle()
// test above handles relevant changes in the StyleWillChangeBit_TRANSFORM
// bit, which in turn handles frame reconstruction for changes in the
// containing block of fixed-positioned elements.
auto willChangeBitsChanged = mWillChange.bits ^ aNewData.mWillChange.bits;
if (willChangeBitsChanged &
(StyleWillChangeBits::STACKING_CONTEXT_UNCONDITIONAL |
StyleWillChangeBits::SCROLL | StyleWillChangeBits::OPACITY |
StyleWillChangeBits::PERSPECTIVE | StyleWillChangeBits::TRANSFORM |
StyleWillChangeBits::Z_INDEX)) {
hint |= nsChangeHint_RepaintFrame;
}
if (willChangeBitsChanged &
(StyleWillChangeBits::FIXPOS_CB_NON_SVG | StyleWillChangeBits::TRANSFORM |
StyleWillChangeBits::PERSPECTIVE | StyleWillChangeBits::POSITION |
StyleWillChangeBits::CONTAIN)) {
hint |= nsChangeHint_UpdateContainingBlock;
}
// If touch-action is changed, we need to regenerate the event regions on
// the layers and send it over to the compositor for APZ to handle.
if (mTouchAction != aNewData.mTouchAction) {
hint |= nsChangeHint_RepaintFrame;
}
// If overscroll-behavior has changed, the changes are picked up
// during a repaint.
if (mOverscrollBehaviorX != aNewData.mOverscrollBehaviorX ||
mOverscrollBehaviorY != aNewData.mOverscrollBehaviorY) {
hint |= nsChangeHint_SchedulePaint;
}
if (mOriginalDisplay != aNewData.mOriginalDisplay) {
// Our hypothetical box position may have changed.
//
// Note that it doesn't matter if we look at the old or the new struct,
// since a change on whether we need a hypothetical position would trigger
// reflow anyway.
if (IsAbsolutelyPositionedStyle() &&
aOldStyle.StylePosition()->NeedsHypotheticalPositionIfAbsPos()) {
hint |=
nsChangeHint_NeedReflow | nsChangeHint_ReflowChangesSizeOrPosition;
} else {
hint |= nsChangeHint_NeutralChange;
}
}
// Note: Our current behavior for handling changes to the
// transition-duration, transition-delay, and transition-timing-function
// properties is to do nothing. In other words, the transition
// property that matters is what it is when the transition begins, and
// we don't stop a transition later because the transition property
// changed.
// We do handle changes to transition-property, but we don't need to
// bother with anything here, since the transition manager is notified
// of any ComputedStyle change anyway.
// Note: Likewise, for animation-*, the animation manager gets
// notified about every new ComputedStyle constructed, and it uses
// that opportunity to handle dynamic changes appropriately.
// But we still need to return nsChangeHint_NeutralChange for these
// properties, since some data did change in the style struct.
// TODO(emilio): Figure out change hints for container-name, maybe it needs to
// be handled by the style system as a special-case (since it changes
// container-query selection on descendants).
// container-type / contain / content-visibility are handled by the
// mEffectiveContainment check.
if (!hint && (mWillChange != aNewData.mWillChange ||
mOverflowAnchor != aNewData.mOverflowAnchor ||
mContentVisibility != aNewData.mContentVisibility ||
mContainerType != aNewData.mContainerType ||
mContain != aNewData.mContain ||
mContainerName != aNewData.mContainerName ||
mAnchorName != aNewData.mAnchorName ||
mAnchorScope != aNewData.mAnchorScope)) {
hint |= nsChangeHint_NeutralChange;
}
return hint;
}
nsChangeHint nsStyleDisplay::CalcTransformPropertyDifference(
const nsStyleDisplay& aNewData) const {
nsChangeHint transformHint = nsChangeHint(0);
transformHint |= CompareTransformValues(mTransform, aNewData.mTransform);
transformHint |= CompareTransformValues(mRotate, aNewData.mRotate);
transformHint |= CompareTransformValues(mTranslate, aNewData.mTranslate);
transformHint |= CompareTransformValues(mScale, aNewData.mScale);
transformHint |= CompareMotionValues(*this, aNewData);
if (mTransformOrigin != aNewData.mTransformOrigin) {
transformHint |= nsChangeHint_UpdateTransformLayer |
nsChangeHint_UpdatePostTransformOverflow;
}
if (mPerspectiveOrigin != aNewData.mPerspectiveOrigin ||
mTransformStyle != aNewData.mTransformStyle ||
mTransformBox != aNewData.mTransformBox) {
transformHint |= nsChangeHint_UpdateOverflow | nsChangeHint_RepaintFrame;
}
if (mBackfaceVisibility != aNewData.mBackfaceVisibility) {
transformHint |= nsChangeHint_RepaintFrame;
}
return transformHint;
}
// --------------------
// nsStyleVisibility
//
nsStyleVisibility::nsStyleVisibility(const Document& aDocument)
: mDirection(aDocument.GetBidiOptions() == IBMBIDI_TEXTDIRECTION_RTL
? StyleDirection::Rtl
: StyleDirection::Ltr),
mVisible(StyleVisibility::Visible),
mImageRendering(StyleImageRendering::Auto),
mWritingMode(StyleWritingModeProperty::HorizontalTb),
mTextOrientation(StyleTextOrientation::Mixed),
mMozBoxCollapse(StyleMozBoxCollapse::Flex),
mPrintColorAdjust(StylePrintColorAdjust::Economy),
mImageOrientation(StyleImageOrientation::FromImage) {
MOZ_COUNT_CTOR(nsStyleVisibility);
}
nsStyleVisibility::nsStyleVisibility(const nsStyleVisibility& aSource)
: mDirection(aSource.mDirection),
mVisible(aSource.mVisible),
mImageRendering(aSource.mImageRendering),
mWritingMode(aSource.mWritingMode),
mTextOrientation(aSource.mTextOrientation),
mMozBoxCollapse(aSource.mMozBoxCollapse),
mPrintColorAdjust(aSource.mPrintColorAdjust),
mImageOrientation(aSource.mImageOrientation) {
MOZ_COUNT_CTOR(nsStyleVisibility);
}
nsChangeHint nsStyleVisibility::CalcDifference(
const nsStyleVisibility& aNewData) const {
nsChangeHint hint = nsChangeHint(0);
if (mDirection != aNewData.mDirection ||
mWritingMode != aNewData.mWritingMode) {
// It's important that a change in mWritingMode results in frame
// reconstruction, because it may affect intrinsic size (see
// nsSubDocumentFrame::GetIntrinsicISize/BSize).
// Also, the used writing-mode value is now a field on nsIFrame and some
// classes (e.g. table rows/cells) copy their value from an ancestor.
return nsChangeHint_ReconstructFrame;
}
if (mImageOrientation != aNewData.mImageOrientation) {
hint |= nsChangeHint_AllReflowHints | nsChangeHint_RepaintFrame;
}
if (mVisible != aNewData.mVisible) {
if (mVisible == StyleVisibility::Visible ||
aNewData.mVisible == StyleVisibility::Visible) {
hint |= nsChangeHint_VisibilityChange;
}
if (mVisible == StyleVisibility::Collapse ||
aNewData.mVisible == StyleVisibility::Collapse) {
hint |= NS_STYLE_HINT_REFLOW;
} else {
hint |= NS_STYLE_HINT_VISUAL;
}
}
if (mTextOrientation != aNewData.mTextOrientation ||
mMozBoxCollapse != aNewData.mMozBoxCollapse) {
hint |= NS_STYLE_HINT_REFLOW;
}
if (mImageRendering != aNewData.mImageRendering) {
hint |= nsChangeHint_RepaintFrame;
}
if (mPrintColorAdjust != aNewData.mPrintColorAdjust) {
// color-adjust only affects media where dynamic changes can't happen.
hint |= nsChangeHint_NeutralChange;
}
return hint;
}
StyleImageOrientation nsStyleVisibility::UsedImageOrientation(
imgIRequest* aRequest, StyleImageOrientation aOrientation) {
if (aOrientation == StyleImageOrientation::FromImage || !aRequest) {
return aOrientation;
}
nsCOMPtr<nsIPrincipal> triggeringPrincipal =
aRequest->GetTriggeringPrincipal();
// If the request was for a blob, the request may not have a triggering
// principal and we should use the input orientation.
if (!triggeringPrincipal) {
return aOrientation;
}
nsCOMPtr<nsIURI> uri = aRequest->GetURI();
// If the image request is a data uri, then treat the request as a
// same origin request.
bool isSameOrigin =
uri->SchemeIs("data") || triggeringPrincipal->IsSameOrigin(uri);
// If the image request is a cross-origin request that does not use CORS,
// do not enforce the image orientation found in the style. Use the image
// orientation found in the exif data.
if (!isSameOrigin && !nsLayoutUtils::ImageRequestUsesCORS(aRequest)) {
return StyleImageOrientation::FromImage;
}
return aOrientation;
}
//-----------------------
// nsStyleContent
//
nsStyleContent::nsStyleContent() : mContent(StyleContent::Normal()) {
MOZ_COUNT_CTOR(nsStyleContent);
}
nsStyleContent::nsStyleContent(const nsStyleContent& aSource)
: mContent(aSource.mContent),
mCounterIncrement(aSource.mCounterIncrement),
mCounterReset(aSource.mCounterReset),
mCounterSet(aSource.mCounterSet) {
MOZ_COUNT_CTOR(nsStyleContent);
}
nsChangeHint nsStyleContent::CalcDifference(
const nsStyleContent& aNewData) const {
// Unfortunately we need to reframe even if the content lengths are the same;
// a simple reflow will not pick up different text or different image URLs,
// since we set all that up in the CSSFrameConstructor
if (mContent != aNewData.mContent ||
mCounterIncrement != aNewData.mCounterIncrement ||
mCounterReset != aNewData.mCounterReset ||
mCounterSet != aNewData.mCounterSet) {
return nsChangeHint_ReconstructFrame;
}
return nsChangeHint(0);
}
void nsStyleContent::TriggerImageLoads(Document& aDoc,
const nsStyleContent* aOld) {
if (!mContent.IsItems()) {
return;
}
Span<const StyleContentItem> oldItems;
if (aOld) {
oldItems = aOld->NonAltContentItems();
}
auto items = NonAltContentItems();
for (size_t i = 0; i < items.Length(); ++i) {
const auto& item = items[i];
if (!item.IsImage()) {
continue;
}
const auto& image = item.AsImage();
const auto* oldImage = i < oldItems.Length() && oldItems[i].IsImage()
? &oldItems[i].AsImage()
: nullptr;
const_cast<StyleImage&>(image).ResolveImage(aDoc, oldImage);
}
}
// --------------------
// nsStyleTextReset
//
nsStyleTextReset::nsStyleTextReset()
: mTextDecorationLine(StyleTextDecorationLine::NONE),
mTextDecorationStyle(StyleTextDecorationStyle::Solid),
mUnicodeBidi(StyleUnicodeBidi::Normal),
mInitialLetter{0, 0},
mTextDecorationColor(StyleColor::CurrentColor()),
mTextDecorationThickness(StyleTextDecorationLength::Auto()) {
MOZ_COUNT_CTOR(nsStyleTextReset);
}
nsStyleTextReset::nsStyleTextReset(const nsStyleTextReset& aSource)
: mTextOverflow(aSource.mTextOverflow),
mTextDecorationLine(aSource.mTextDecorationLine),
mTextDecorationStyle(aSource.mTextDecorationStyle),
mUnicodeBidi(aSource.mUnicodeBidi),
mInitialLetter(aSource.mInitialLetter),
mTextDecorationColor(aSource.mTextDecorationColor),
mTextDecorationThickness(aSource.mTextDecorationThickness) {
MOZ_COUNT_CTOR(nsStyleTextReset);
}
nsChangeHint nsStyleTextReset::CalcDifference(
const nsStyleTextReset& aNewData) const {
if (mUnicodeBidi != aNewData.mUnicodeBidi ||
mInitialLetter != aNewData.mInitialLetter) {
return NS_STYLE_HINT_REFLOW;
}
if (mTextDecorationLine != aNewData.mTextDecorationLine ||
mTextDecorationStyle != aNewData.mTextDecorationStyle ||
mTextDecorationThickness != aNewData.mTextDecorationThickness) {
// Changes to our text-decoration line can impact our overflow area &
// also our descendants' overflow areas (particularly for text-frame
// descendants). So, we update those areas & trigger a repaint.
return nsChangeHint_RepaintFrame | nsChangeHint_UpdateSubtreeOverflow |
nsChangeHint_SchedulePaint;
}
// Repaint for decoration color changes or text-overflow.
if (mTextDecorationColor != aNewData.mTextDecorationColor ||
mTextOverflow != aNewData.mTextOverflow) {
return nsChangeHint_RepaintFrame;
}
return nsChangeHint(0);
}
// --------------------
// nsStyleText
//
static StyleAbsoluteColor DefaultColor(const Document& aDocument) {
return StyleAbsoluteColor::FromColor(
PreferenceSheet::PrefsFor(aDocument)
.ColorsFor(aDocument.DefaultColorScheme())
.mDefault);
}
nsStyleText::nsStyleText(const Document& aDocument)
: mColor(DefaultColor(aDocument)),
mForcedColorAdjust(StyleForcedColorAdjust::Auto),
mTextTransform(StyleTextTransform::NONE),
mTextAlign(StyleTextAlign::Start),
mTextAlignLast(StyleTextAlignLast::Auto),
mTextJustify(StyleTextJustify::Auto),
mHyphens(StyleHyphens::Manual),
mRubyAlign(StyleRubyAlign::SpaceAround),
mRubyPosition(StyleRubyPosition::AlternateOver),
mTextSizeAdjust(StyleTextSizeAdjust::Auto),
mTextCombineUpright(StyleTextCombineUpright::None),
mMozControlCharacterVisibility(
StaticPrefs::layout_css_control_characters_visible()
? StyleMozControlCharacterVisibility::Visible
: StyleMozControlCharacterVisibility::Hidden),
mTextEmphasisPosition(StyleTextEmphasisPosition::AUTO),
mTextRendering(StyleTextRendering::Auto),
mTextEmphasisColor(StyleColor::CurrentColor()),
mWebkitTextFillColor(StyleColor::CurrentColor()),
mWebkitTextStrokeColor(StyleColor::CurrentColor()),
mTabSize(StyleNonNegativeLengthOrNumber::Number(8.f)),
mWordSpacing(LengthPercentage::Zero()),
mLetterSpacing(LengthPercentage::Zero()),
mTextUnderlineOffset(LengthPercentageOrAuto::Auto()),
mTextDecorationSkipInk(StyleTextDecorationSkipInk::Auto),
mTextUnderlinePosition(StyleTextUnderlinePosition::AUTO),
mWebkitTextStrokeWidth(0),
mTextEmphasisStyle(StyleTextEmphasisStyle::None()) {
MOZ_COUNT_CTOR(nsStyleText);
}
nsStyleText::nsStyleText(const nsStyleText& aSource)
: mColor(aSource.mColor),
mForcedColorAdjust(aSource.mForcedColorAdjust),
mTextTransform(aSource.mTextTransform),
mTextAlign(aSource.mTextAlign),
mTextAlignLast(aSource.mTextAlignLast),
mTextJustify(aSource.mTextJustify),
mWhiteSpaceCollapse(aSource.mWhiteSpaceCollapse),
mTextWrapMode(aSource.mTextWrapMode),
mLineBreak(aSource.mLineBreak),
mWordBreak(aSource.mWordBreak),
mOverflowWrap(aSource.mOverflowWrap),
mHyphens(aSource.mHyphens),
mRubyAlign(aSource.mRubyAlign),
mRubyPosition(aSource.mRubyPosition),
mTextSizeAdjust(aSource.mTextSizeAdjust),
mTextCombineUpright(aSource.mTextCombineUpright),
mMozControlCharacterVisibility(aSource.mMozControlCharacterVisibility),
mTextEmphasisPosition(aSource.mTextEmphasisPosition),
mTextRendering(aSource.mTextRendering),
mTextEmphasisColor(aSource.mTextEmphasisColor),
mWebkitTextFillColor(aSource.mWebkitTextFillColor),
mWebkitTextStrokeColor(aSource.mWebkitTextStrokeColor),
mTabSize(aSource.mTabSize),
mWordSpacing(aSource.mWordSpacing),
mLetterSpacing(aSource.mLetterSpacing),
mTextIndent(aSource.mTextIndent),
mTextUnderlineOffset(aSource.mTextUnderlineOffset),
mTextDecorationSkipInk(aSource.mTextDecorationSkipInk),
mTextUnderlinePosition(aSource.mTextUnderlinePosition),
mWebkitTextStrokeWidth(aSource.mWebkitTextStrokeWidth),
mTextShadow(aSource.mTextShadow),
mTextEmphasisStyle(aSource.mTextEmphasisStyle),
mHyphenateCharacter(aSource.mHyphenateCharacter),
mWebkitTextSecurity(aSource.mWebkitTextSecurity),
mTextWrapStyle(aSource.mTextWrapStyle) {
MOZ_COUNT_CTOR(nsStyleText);
}
nsChangeHint nsStyleText::CalcDifference(const nsStyleText& aNewData) const {
if (WhiteSpaceOrNewlineIsSignificant() !=
aNewData.WhiteSpaceOrNewlineIsSignificant()) {
// This may require construction of suppressed text frames
return nsChangeHint_ReconstructFrame;
}
if (mTextCombineUpright != aNewData.mTextCombineUpright ||
mMozControlCharacterVisibility !=
aNewData.mMozControlCharacterVisibility) {
return nsChangeHint_ReconstructFrame;
}
if ((mTextAlign != aNewData.mTextAlign) ||
(mTextAlignLast != aNewData.mTextAlignLast) ||
(mTextTransform != aNewData.mTextTransform) ||
(mWhiteSpaceCollapse != aNewData.mWhiteSpaceCollapse) ||
(mTextWrapMode != aNewData.mTextWrapMode) ||
(mLineBreak != aNewData.mLineBreak) ||
(mWordBreak != aNewData.mWordBreak) ||
(mOverflowWrap != aNewData.mOverflowWrap) ||
(mHyphens != aNewData.mHyphens) || (mRubyAlign != aNewData.mRubyAlign) ||
(mRubyPosition != aNewData.mRubyPosition) ||
(mTextSizeAdjust != aNewData.mTextSizeAdjust) ||
(mLetterSpacing != aNewData.mLetterSpacing) ||
(mTextIndent != aNewData.mTextIndent) ||
(mTextJustify != aNewData.mTextJustify) ||
(mWordSpacing != aNewData.mWordSpacing) ||
(mTabSize != aNewData.mTabSize) ||
(mHyphenateCharacter != aNewData.mHyphenateCharacter) ||
(mWebkitTextSecurity != aNewData.mWebkitTextSecurity) ||
(mTextWrapStyle != aNewData.mTextWrapStyle)) {
return NS_STYLE_HINT_REFLOW;
}
if (HasEffectiveTextEmphasis() != aNewData.HasEffectiveTextEmphasis() ||
(HasEffectiveTextEmphasis() &&
mTextEmphasisPosition != aNewData.mTextEmphasisPosition)) {
// Text emphasis position change could affect line height calculation.
return nsChangeHint_AllReflowHints | nsChangeHint_RepaintFrame;
}
nsChangeHint hint = nsChangeHint(0);
// text-rendering changes require a reflow since they change SVG
// frames' rects.
if (mTextRendering != aNewData.mTextRendering) {
hint |= nsChangeHint_NeedReflow | nsChangeHint_RepaintFrame;
}
if (mTextShadow != aNewData.mTextShadow ||
mTextEmphasisStyle != aNewData.mTextEmphasisStyle ||
mWebkitTextStrokeWidth != aNewData.mWebkitTextStrokeWidth ||
mTextUnderlineOffset != aNewData.mTextUnderlineOffset ||
mTextDecorationSkipInk != aNewData.mTextDecorationSkipInk ||
mTextUnderlinePosition != aNewData.mTextUnderlinePosition) {
hint |= nsChangeHint_UpdateSubtreeOverflow | nsChangeHint_SchedulePaint |
nsChangeHint_RepaintFrame;
// We don't add any other hints below.
return hint;
}
if (mColor != aNewData.mColor) {
hint |= nsChangeHint_RepaintFrame;
}
if (mTextEmphasisColor != aNewData.mTextEmphasisColor ||
mWebkitTextFillColor != aNewData.mWebkitTextFillColor ||
mWebkitTextStrokeColor != aNewData.mWebkitTextStrokeColor) {
hint |= nsChangeHint_SchedulePaint | nsChangeHint_RepaintFrame;
}
if (hint) {
return hint;
}
if (mTextEmphasisPosition != aNewData.mTextEmphasisPosition ||
mForcedColorAdjust != aNewData.mForcedColorAdjust) {
return nsChangeHint_NeutralChange;
}
return nsChangeHint(0);
}
LogicalSide nsStyleText::TextEmphasisSide(WritingMode aWM,
const nsAtom* aLanguage) const {
mozilla::Side side;
if (mTextEmphasisPosition & StyleTextEmphasisPosition::AUTO) {
// 'auto' resolves to 'under right' for Chinese, 'over right' otherwise.
if (aWM.IsVertical()) {
side = eSideRight;
} else {
if (nsStyleUtil::MatchesLanguagePrefix(aLanguage, u"zh")) {
side = eSideBottom;
} else {
side = eSideTop;
}
}
} else {
if (aWM.IsVertical()) {
side = mTextEmphasisPosition & StyleTextEmphasisPosition::LEFT
? eSideLeft
: eSideRight;
} else {
side = mTextEmphasisPosition & StyleTextEmphasisPosition::OVER
? eSideTop
: eSideBottom;
}
}
LogicalSide result = aWM.LogicalSideForPhysicalSide(side);
MOZ_ASSERT(IsBlock(result));
return result;
}
//-----------------------
// nsStyleUI
//
nsStyleUI::nsStyleUI()
: mInert(StyleInert::None),
mMozTheme(StyleMozTheme::Auto),
mUserInput(StyleUserInput::Auto),
mUserFocus(StyleUserFocus::Normal),
mPointerEvents(StylePointerEvents::Auto),
mCursor{{}, StyleCursorKind::Auto},
mAccentColor(StyleColorOrAuto::Auto()),
mCaretColor(StyleColorOrAuto::Auto()),
mScrollbarColor(StyleScrollbarColor::Auto()),
mColorScheme(StyleColorScheme{{}, {}}) {
MOZ_COUNT_CTOR(nsStyleUI);
}
nsStyleUI::nsStyleUI(const nsStyleUI& aSource)
: mInert(aSource.mInert),
mMozTheme(aSource.mMozTheme),
mUserInput(aSource.mUserInput),
mUserFocus(aSource.mUserFocus),
mPointerEvents(aSource.mPointerEvents),
mCursor(aSource.mCursor),
mAccentColor(aSource.mAccentColor),
mCaretColor(aSource.mCaretColor),
mScrollbarColor(aSource.mScrollbarColor),
mColorScheme(aSource.mColorScheme) {
MOZ_COUNT_CTOR(nsStyleUI);
}
void nsStyleUI::TriggerImageLoads(Document& aDocument,
const nsStyleUI* aOldStyle) {
MOZ_ASSERT(NS_IsMainThread());
auto cursorImages = mCursor.images.AsSpan();
auto oldCursorImages = aOldStyle ? aOldStyle->mCursor.images.AsSpan()
: Span<const StyleCursorImage>();
for (size_t i = 0; i < cursorImages.Length(); ++i) {
const auto& cursor = cursorImages[i];
const auto* oldCursorImage =
oldCursorImages.Length() > i ? &oldCursorImages[i].image : nullptr;
const_cast<StyleCursorImage&>(cursor).image.ResolveImage(aDocument,
oldCursorImage);
}
}
nsChangeHint nsStyleUI::CalcDifference(const nsStyleUI& aNewData) const {
// SVGGeometryFrame's mRect depends on stroke _and_ on the value of
// pointer-events. See SVGGeometryFrame::ReflowSVG's use of GetHitTestFlags.
// (Only a reflow, no visual change.)
//
// pointer-events changes can change event regions overrides on layers and
// so needs a repaint.
const auto kPointerEventsHint =
nsChangeHint_NeedReflow | nsChangeHint_SchedulePaint;
nsChangeHint hint = nsChangeHint(0);
if (mCursor != aNewData.mCursor) {
hint |= nsChangeHint_UpdateCursor;
}
if (mPointerEvents != aNewData.mPointerEvents) {
hint |= kPointerEventsHint;
}
if (mInert != aNewData.mInert) {
// inert affects pointer-events, user-modify, user-select, user-focus and
// -moz-user-input, do the union of all them (minus
// nsChangeHint_NeutralChange which isn't needed if there's any other hint).
hint |= NS_STYLE_HINT_VISUAL | kPointerEventsHint;
}
if (mUserFocus != aNewData.mUserFocus || mUserInput != aNewData.mUserInput) {
hint |= nsChangeHint_NeutralChange;
}
if (mCaretColor != aNewData.mCaretColor ||
mAccentColor != aNewData.mAccentColor ||
mScrollbarColor != aNewData.mScrollbarColor ||
mMozTheme != aNewData.mMozTheme ||
mColorScheme != aNewData.mColorScheme) {
hint |= nsChangeHint_RepaintFrame;
}
return hint;
}
//-----------------------
// nsStyleUIReset
//
nsStyleUIReset::nsStyleUIReset()
: mUserSelect(StyleUserSelect::Auto),
mScrollbarWidth(StyleScrollbarWidth::Auto),
mMozForceBrokenImageIcon(false),
mMozSubtreeHiddenOnlyVisually(false),
mIMEMode(StyleImeMode::Auto),
mWindowDragging(StyleWindowDragging::Default),
mWindowShadow(StyleWindowShadow::Auto),
mWindowOpacity(1.0),
mMozWindowInputRegionMargin(StyleLength::Zero()),
mTransitions(
nsStyleAutoArray<StyleTransition>::WITH_SINGLE_INITIAL_ELEMENT),
mTransitionTimingFunctionCount(1),
mTransitionDurationCount(1),
mTransitionDelayCount(1),
mTransitionPropertyCount(1),
mTransitionBehaviorCount(1),
mAnimations(
nsStyleAutoArray<StyleAnimation>::WITH_SINGLE_INITIAL_ELEMENT),
mAnimationTimingFunctionCount(1),
mAnimationDurationCount(1),
mAnimationDelayCount(1),
mAnimationNameCount(1),
mAnimationDirectionCount(1),
mAnimationFillModeCount(1),
mAnimationPlayStateCount(1),
mAnimationIterationCountCount(1),
mAnimationCompositionCount(1),
mAnimationTimelineCount(1),
mScrollTimelines(
nsStyleAutoArray<StyleScrollTimeline>::WITH_SINGLE_INITIAL_ELEMENT),
mScrollTimelineNameCount(1),
mScrollTimelineAxisCount(1),
mViewTimelines(
nsStyleAutoArray<StyleViewTimeline>::WITH_SINGLE_INITIAL_ELEMENT),
mViewTimelineNameCount(1),
mViewTimelineAxisCount(1),
mViewTimelineInsetCount(1),
mFieldSizing(StyleFieldSizing::Fixed) {
MOZ_COUNT_CTOR(nsStyleUIReset);
}
nsStyleUIReset::nsStyleUIReset(const nsStyleUIReset& aSource)
: mUserSelect(aSource.mUserSelect),
mScrollbarWidth(aSource.mScrollbarWidth),
mMozForceBrokenImageIcon(aSource.mMozForceBrokenImageIcon),
mMozSubtreeHiddenOnlyVisually(aSource.mMozSubtreeHiddenOnlyVisually),
mIMEMode(aSource.mIMEMode),
mWindowDragging(aSource.mWindowDragging),
mWindowShadow(aSource.mWindowShadow),
mWindowOpacity(aSource.mWindowOpacity),
mMozWindowInputRegionMargin(aSource.mMozWindowInputRegionMargin),
mMozWindowTransform(aSource.mMozWindowTransform),
mTransitions(aSource.mTransitions.Clone()),
mTransitionTimingFunctionCount(aSource.mTransitionTimingFunctionCount),
mTransitionDurationCount(aSource.mTransitionDurationCount),
mTransitionDelayCount(aSource.mTransitionDelayCount),
mTransitionPropertyCount(aSource.mTransitionPropertyCount),
mTransitionBehaviorCount(aSource.mTransitionBehaviorCount),
mAnimations(aSource.mAnimations.Clone()),
mAnimationTimingFunctionCount(aSource.mAnimationTimingFunctionCount),
mAnimationDurationCount(aSource.mAnimationDurationCount),
mAnimationDelayCount(aSource.mAnimationDelayCount),
mAnimationNameCount(aSource.mAnimationNameCount),
mAnimationDirectionCount(aSource.mAnimationDirectionCount),
mAnimationFillModeCount(aSource.mAnimationFillModeCount),
mAnimationPlayStateCount(aSource.mAnimationPlayStateCount),
mAnimationIterationCountCount(aSource.mAnimationIterationCountCount),
mAnimationCompositionCount(aSource.mAnimationCompositionCount),
mAnimationTimelineCount(aSource.mAnimationTimelineCount),
mScrollTimelines(aSource.mScrollTimelines.Clone()),
mScrollTimelineNameCount(aSource.mScrollTimelineNameCount),
mScrollTimelineAxisCount(aSource.mScrollTimelineAxisCount),
mViewTimelines(aSource.mViewTimelines.Clone()),
mViewTimelineNameCount(aSource.mViewTimelineNameCount),
mViewTimelineAxisCount(aSource.mViewTimelineAxisCount),
mViewTimelineInsetCount(aSource.mViewTimelineInsetCount),
mFieldSizing(aSource.mFieldSizing),
mViewTransitionName(aSource.mViewTransitionName) {
MOZ_COUNT_CTOR(nsStyleUIReset);
}
nsChangeHint nsStyleUIReset::CalcDifference(
const nsStyleUIReset& aNewData) const {
nsChangeHint hint = nsChangeHint(0);
if (mMozForceBrokenImageIcon != aNewData.mMozForceBrokenImageIcon) {
hint |= nsChangeHint_ReconstructFrame;
}
if (mMozSubtreeHiddenOnlyVisually != aNewData.mMozSubtreeHiddenOnlyVisually) {
hint |= nsChangeHint_RepaintFrame;
}
if (mFieldSizing != aNewData.mFieldSizing) {
hint |= nsChangeHint_NeutralChange;
}
if (mScrollbarWidth != aNewData.mScrollbarWidth) {
// For scrollbar-width change, we need some special handling similar
// to overflow properties. Specifically, we may need to reconstruct
// the scrollbar or force reflow of the viewport scrollbar.
hint |= nsChangeHint_ScrollbarChange;
}
if (mWindowShadow != aNewData.mWindowShadow) {
// We really need just an nsChangeHint_SyncFrameView, except
// on an ancestor of the frame, so we get that by doing a
// reflow.
hint |= NS_STYLE_HINT_REFLOW;
}
if (mUserSelect != aNewData.mUserSelect) {
hint |= NS_STYLE_HINT_VISUAL;
}
if (mWindowDragging != aNewData.mWindowDragging) {
hint |= nsChangeHint_SchedulePaint;
}
if (mViewTransitionName != aNewData.mViewTransitionName) {
hint |= nsChangeHint_NeutralChange;
}
if (!hint &&
(mTransitions != aNewData.mTransitions ||
mTransitionTimingFunctionCount !=
aNewData.mTransitionTimingFunctionCount ||
mTransitionDurationCount != aNewData.mTransitionDurationCount ||
mTransitionDelayCount != aNewData.mTransitionDelayCount ||
mTransitionPropertyCount != aNewData.mTransitionPropertyCount ||
mTransitionBehaviorCount != aNewData.mTransitionBehaviorCount ||
mAnimations != aNewData.mAnimations ||
mAnimationTimingFunctionCount !=
aNewData.mAnimationTimingFunctionCount ||
mAnimationDurationCount != aNewData.mAnimationDurationCount ||
mAnimationDelayCount != aNewData.mAnimationDelayCount ||
mAnimationNameCount != aNewData.mAnimationNameCount ||
mAnimationDirectionCount != aNewData.mAnimationDirectionCount ||
mAnimationFillModeCount != aNewData.mAnimationFillModeCount ||
mAnimationPlayStateCount != aNewData.mAnimationPlayStateCount ||
mAnimationIterationCountCount !=
aNewData.mAnimationIterationCountCount ||
mAnimationCompositionCount != aNewData.mAnimationCompositionCount ||
mAnimationTimelineCount != aNewData.mAnimationTimelineCount ||
mIMEMode != aNewData.mIMEMode ||
mWindowOpacity != aNewData.mWindowOpacity ||
mMozWindowInputRegionMargin != aNewData.mMozWindowInputRegionMargin ||
mMozWindowTransform != aNewData.mMozWindowTransform ||
mScrollTimelines != aNewData.mScrollTimelines ||
mScrollTimelineNameCount != aNewData.mScrollTimelineNameCount ||
mScrollTimelineAxisCount != aNewData.mScrollTimelineAxisCount ||
mViewTimelines != aNewData.mViewTimelines ||
mViewTimelineNameCount != aNewData.mViewTimelineNameCount ||
mViewTimelineAxisCount != aNewData.mViewTimelineAxisCount ||
mViewTimelineInsetCount != aNewData.mViewTimelineInsetCount)) {
hint |= nsChangeHint_NeutralChange;
}
return hint;
}
StyleScrollbarWidth nsStyleUIReset::ScrollbarWidth() const {
if (MOZ_UNLIKELY(StaticPrefs::layout_css_scrollbar_width_thin_disabled())) {
if (mScrollbarWidth == StyleScrollbarWidth::Thin) {
return StyleScrollbarWidth::Auto;
}
}
return mScrollbarWidth;
}
//-----------------------
// nsStyleEffects
//
nsStyleEffects::nsStyleEffects()
: mClip(StyleClipRectOrAuto::Auto()),
mOpacity(1.0f),
mMixBlendMode(StyleBlend::Normal) {
MOZ_COUNT_CTOR(nsStyleEffects);
}
nsStyleEffects::nsStyleEffects(const nsStyleEffects& aSource)
: mFilters(aSource.mFilters),
mBoxShadow(aSource.mBoxShadow),
mBackdropFilters(aSource.mBackdropFilters),
mClip(aSource.mClip),
mOpacity(aSource.mOpacity),
mMixBlendMode(aSource.mMixBlendMode) {
MOZ_COUNT_CTOR(nsStyleEffects);
}
static bool AnyAutonessChanged(const StyleClipRectOrAuto& aOld,
const StyleClipRectOrAuto& aNew) {
if (aOld.IsAuto() != aNew.IsAuto()) {
return true;
}
if (aOld.IsAuto()) {
return false;
}
const auto& oldRect = aOld.AsRect();
const auto& newRect = aNew.AsRect();
return oldRect.top.IsAuto() != newRect.top.IsAuto() ||
oldRect.right.IsAuto() != newRect.right.IsAuto() ||
oldRect.bottom.IsAuto() != newRect.bottom.IsAuto() ||
oldRect.left.IsAuto() != newRect.left.IsAuto();
}
nsChangeHint nsStyleEffects::CalcDifference(
const nsStyleEffects& aNewData) const {
nsChangeHint hint = nsChangeHint(0);
if (mBoxShadow != aNewData.mBoxShadow) {
// Update overflow regions & trigger DLBI to be sure it's noticed.
// Also request a repaint, since it's possible that only the color
// of the shadow is changing (and UpdateOverflow/SchedulePaint won't
// repaint for that, since they won't know what needs invalidating.)
hint |= nsChangeHint_UpdateOverflow | nsChangeHint_SchedulePaint |
nsChangeHint_RepaintFrame;
}
if (AnyAutonessChanged(mClip, aNewData.mClip)) {
hint |= nsChangeHint_AllReflowHints | nsChangeHint_RepaintFrame;
} else if (mClip != aNewData.mClip) {
// If the clip has changed, we just need to update overflow areas. DLBI
// will handle the invalidation.
hint |= nsChangeHint_UpdateOverflow | nsChangeHint_SchedulePaint;
}
if (mOpacity != aNewData.mOpacity) {
hint |= nsChangeHint_UpdateOpacityLayer;
// If we're going from the optimized >=0.99 opacity value to 1.0 or back,
// then repaint the frame because DLBI will not catch the invalidation.
// Otherwise, just update the opacity layer.
if ((mOpacity >= 0.99f && mOpacity < 1.0f && aNewData.mOpacity == 1.0f) ||
(aNewData.mOpacity >= 0.99f && aNewData.mOpacity < 1.0f &&
mOpacity == 1.0f)) {
hint |= nsChangeHint_RepaintFrame;
} else {
if ((mOpacity == 1.0f) != (aNewData.mOpacity == 1.0f)) {
hint |= nsChangeHint_UpdateUsesOpacity;
}
}
}
if (HasFilters() != aNewData.HasFilters()) {
// A change from/to being a containing block for position:fixed.
hint |= nsChangeHint_UpdateContainingBlock;
}
if (mFilters != aNewData.mFilters) {
hint |= nsChangeHint_UpdateEffects | nsChangeHint_RepaintFrame |
nsChangeHint_UpdateOverflow;
}
if (mMixBlendMode != aNewData.mMixBlendMode) {
hint |= nsChangeHint_RepaintFrame;
}
if (HasBackdropFilters() != aNewData.HasBackdropFilters()) {
// A change from/to being a containing block for position:fixed.
hint |= nsChangeHint_UpdateContainingBlock;
}
if (mBackdropFilters != aNewData.mBackdropFilters) {
hint |= nsChangeHint_UpdateEffects | nsChangeHint_RepaintFrame;
}
return hint;
}
static bool TransformOperationHasPercent(const StyleTransformOperation& aOp) {
switch (aOp.tag) {
case StyleTransformOperation::Tag::TranslateX:
return aOp.AsTranslateX().HasPercent();
case StyleTransformOperation::Tag::TranslateY:
return aOp.AsTranslateY().HasPercent();
case StyleTransformOperation::Tag::TranslateZ:
return false;
case StyleTransformOperation::Tag::Translate3D: {
const auto& translate = aOp.AsTranslate3D();
// NOTE(emilio): z translation is a `<length>`, so can't have percentages.
return translate._0.HasPercent() || translate._1.HasPercent();
}
case StyleTransformOperation::Tag::Translate: {
const auto& translate = aOp.AsTranslate();
return translate._0.HasPercent() || translate._1.HasPercent();
}
case StyleTransformOperation::Tag::AccumulateMatrix: {
const auto& accum = aOp.AsAccumulateMatrix();
return accum.from_list.HasPercent() || accum.to_list.HasPercent();
}
case StyleTransformOperation::Tag::InterpolateMatrix: {
const auto& interpolate = aOp.AsInterpolateMatrix();
return interpolate.from_list.HasPercent() ||
interpolate.to_list.HasPercent();
}
case StyleTransformOperation::Tag::Perspective:
case StyleTransformOperation::Tag::RotateX:
case StyleTransformOperation::Tag::RotateY:
case StyleTransformOperation::Tag::RotateZ:
case StyleTransformOperation::Tag::Rotate:
case StyleTransformOperation::Tag::Rotate3D:
case StyleTransformOperation::Tag::SkewX:
case StyleTransformOperation::Tag::SkewY:
case StyleTransformOperation::Tag::Skew:
case StyleTransformOperation::Tag::ScaleX:
case StyleTransformOperation::Tag::ScaleY:
case StyleTransformOperation::Tag::ScaleZ:
case StyleTransformOperation::Tag::Scale:
case StyleTransformOperation::Tag::Scale3D:
case StyleTransformOperation::Tag::Matrix:
case StyleTransformOperation::Tag::Matrix3D:
return false;
default:
MOZ_ASSERT_UNREACHABLE("Unknown transform operation");
return false;
}
}
template <>
bool StyleTransform::HasPercent() const {
for (const auto& op : Operations()) {
if (TransformOperationHasPercent(op)) {
return true;
}
}
return false;
}
template <>
void StyleCalcNode::ScaleLengthsBy(float aScale) {
auto ScaleNode = [aScale](const StyleCalcNode& aNode) {
// This const_cast could be removed by generating more mut-casts, if
// needed.
const_cast<StyleCalcNode&>(aNode).ScaleLengthsBy(aScale);
};
switch (tag) {
case Tag::Leaf: {
const auto& leaf = AsLeaf();
if (leaf.IsLength()) {
// This const_cast could be removed by generating more mut-casts, if
// needed.
const_cast<Length&>(leaf.AsLength()).ScaleBy(aScale);
}
break;
}
case Tag::Clamp: {
const auto& clamp = AsClamp();
ScaleNode(*clamp.min);
ScaleNode(*clamp.center);
ScaleNode(*clamp.max);
break;
}
case Tag::Round: {
const auto& round = AsRound();
ScaleNode(*round.value);
ScaleNode(*round.step);
break;
}
case Tag::ModRem: {
const auto& modRem = AsModRem();
ScaleNode(*modRem.dividend);
ScaleNode(*modRem.divisor);
break;
}
case Tag::MinMax: {
for (const auto& child : AsMinMax()._0.AsSpan()) {
ScaleNode(child);
}
break;
}
case Tag::Sum: {
for (const auto& child : AsSum().AsSpan()) {
ScaleNode(child);
}
break;
}
case Tag::Product: {
for (const auto& child : AsProduct().AsSpan()) {
ScaleNode(child);
}
break;
}
case Tag::Negate: {
const auto& negate = AsNegate();
ScaleNode(*negate);
break;
}
case Tag::Invert: {
const auto& invert = AsInvert();
ScaleNode(*invert);
break;
}
case Tag::Hypot: {
for (const auto& child : AsHypot().AsSpan()) {
ScaleNode(child);
}
break;
}
case Tag::Abs: {
const auto& abs = AsAbs();
ScaleNode(*abs);
break;
}
case Tag::Sign: {
const auto& sign = AsSign();
ScaleNode(*sign);
break;
}
case Tag::Anchor: {
MOZ_ASSERT_UNREACHABLE("Unresolved anchor() function");
break;
}
case Tag::AnchorSize: {
MOZ_ASSERT_UNREACHABLE("Unresolved anchor-size() function");
break;
}
}
}
bool nsStyleDisplay::PrecludesSizeContainmentOrContentVisibilityWithFrame(
const nsIFrame& aFrame) const {
// The spec says that in the case of SVG, the contain property only applies
// to <svg> elements that have an associated CSS layout box.
// Internal SVG elements do not use the standard CSS box model, and wouldn't
// be affected by size containment. By disabling it we prevent them from
// becoming query containers for size features.
if (aFrame.HasAnyStateBits(NS_FRAME_SVG_LAYOUT)) {
return true;
}
// Note: The spec for size containment says it should have no effect
// - on non-atomic, inline-level boxes.
// - on internal ruby boxes.
// - if inner display type is table.
// - on internal table boxes.
bool isNonReplacedInline = aFrame.IsLineParticipant() && !aFrame.IsReplaced();
return isNonReplacedInline || IsInternalRubyDisplayType() ||
DisplayInside() == mozilla::StyleDisplayInside::Table ||
IsInnerTableStyle();
}
ContainSizeAxes nsStyleDisplay::GetContainSizeAxes(
const nsIFrame& aFrame) const {
// Short circuit for no containment whatsoever
if (MOZ_LIKELY(!mEffectiveContainment)) {
return ContainSizeAxes(false, false);
}
if (PrecludesSizeContainmentOrContentVisibilityWithFrame(aFrame)) {
return ContainSizeAxes(false, false);
}
// If this content skips its content via content-visibility, it always has
// size containment.
if (MOZ_LIKELY(!(mEffectiveContainment & StyleContain::SIZE)) &&
MOZ_UNLIKELY(aFrame.HidesContent())) {
return ContainSizeAxes(true, true);
}
return ContainSizeAxes(
static_cast<bool>(mEffectiveContainment & StyleContain::INLINE_SIZE),
static_cast<bool>(mEffectiveContainment & StyleContain::BLOCK_SIZE));
}
StyleContentVisibility nsStyleDisplay::ContentVisibility(
const nsIFrame& aFrame) const {
if (MOZ_LIKELY(mContentVisibility == StyleContentVisibility::Visible)) {
return StyleContentVisibility::Visible;
}
// content-visibility applies to elements for which size containment applies.
if (PrecludesSizeContainmentOrContentVisibilityWithFrame(aFrame)) {
return StyleContentVisibility::Visible;
}
// If we're in print/print-preview, or being used as an image, we should
// always treat `auto` as `visible`.
if (mContentVisibility == StyleContentVisibility::Auto &&
(aFrame.PresContext()->IsPrintingOrPrintPreview() ||
aFrame.PresContext()->Document()->IsBeingUsedAsImage())) {
return StyleContentVisibility::Visible;
}
return mContentVisibility;
}
static nscoord Resolve(const StyleContainIntrinsicSize& aSize,
nscoord aNoneValue, const nsIFrame& aFrame,
LogicalAxis aAxis) {
if (aSize.IsNone()) {
return aNoneValue;
}
if (aSize.IsLength()) {
return aSize.AsLength().ToAppUnits();
}
MOZ_ASSERT(aSize.HasAuto());
if (const auto* element = Element::FromNodeOrNull(aFrame.GetContent())) {
Maybe<float> lastSize = aAxis == LogicalAxis::Block
? element->GetLastRememberedBSize()
: element->GetLastRememberedISize();
if (lastSize && aFrame.HidesContent()) {
return CSSPixel::ToAppUnits(*lastSize);
}
}
if (aSize.IsAutoNone()) {
return aNoneValue;
}
return aSize.AsAutoLength().ToAppUnits();
}
Maybe<nscoord> ContainSizeAxes::ContainIntrinsicBSize(
const nsIFrame& aFrame, nscoord aNoneValue) const {
if (!mBContained) {
return Nothing();
}
const StyleContainIntrinsicSize& bSize =
aFrame.StylePosition()->ContainIntrinsicBSize(aFrame.GetWritingMode());
return Some(Resolve(bSize, aNoneValue, aFrame, LogicalAxis::Block));
}
Maybe<nscoord> ContainSizeAxes::ContainIntrinsicISize(
const nsIFrame& aFrame, nscoord aNoneValue) const {
if (!mIContained) {
return Nothing();
}
const StyleContainIntrinsicSize& iSize =
aFrame.StylePosition()->ContainIntrinsicISize(aFrame.GetWritingMode());
return Some(Resolve(iSize, aNoneValue, aFrame, LogicalAxis::Inline));
}
nsSize ContainSizeAxes::ContainSize(const nsSize& aUncontainedSize,
const nsIFrame& aFrame) const {
if (!IsAny()) {
return aUncontainedSize;
}
if (aFrame.GetWritingMode().IsVertical()) {
return nsSize(
ContainIntrinsicBSize(aFrame).valueOr(aUncontainedSize.Width()),
ContainIntrinsicISize(aFrame).valueOr(aUncontainedSize.Height()));
}
return nsSize(
ContainIntrinsicISize(aFrame).valueOr(aUncontainedSize.Width()),
ContainIntrinsicBSize(aFrame).valueOr(aUncontainedSize.Height()));
}
IntrinsicSize ContainSizeAxes::ContainIntrinsicSize(
const IntrinsicSize& aUncontainedSize, const nsIFrame& aFrame) const {
if (!IsAny()) {
return aUncontainedSize;
}
IntrinsicSize result(aUncontainedSize);
const auto wm = aFrame.GetWritingMode();
if (Maybe<nscoord> containBSize = ContainIntrinsicBSize(aFrame)) {
result.BSize(wm) = containBSize;
}
if (Maybe<nscoord> containISize = ContainIntrinsicISize(aFrame)) {
result.ISize(wm) = containISize;
}
return result;
}