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ladybird/Libraries/LibWeb/CSS/StyleComputer.cpp
Aliaksandr Kalenik 714ff4e3f9 LibWeb: Fix previous style calculation for CSS transitions on pseudo 
...elements. Adds missing pseudo-element type passed into computed
properties getter.

Previously, due to this bug, we were using the element's computed
properties as the previous computed properties for its pseudo-elements.
This caused an excessive number of unintended CSS transitions to run.
The issue was particularly noticeable in Discord's emoji picker, where
each emoji has `::after` pseudo-element. We were incorrectly triggering
transitions on all their properties, resulting in significant
unnecessary work in style computation and animation event dispatching.
2025-07-18 21:19:37 +02:00

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/*
* Copyright (c) 2018-2023, Andreas Kling <andreas@ladybird.org>
* Copyright (c) 2021, the SerenityOS developers.
* Copyright (c) 2021-2025, Sam Atkins <sam@ladybird.org>
* Copyright (c) 2024, Matthew Olsson <mattco@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/BinarySearch.h>
#include <AK/Bitmap.h>
#include <AK/Debug.h>
#include <AK/Error.h>
#include <AK/Find.h>
#include <AK/Function.h>
#include <AK/HashMap.h>
#include <AK/Math.h>
#include <AK/NonnullRawPtr.h>
#include <AK/QuickSort.h>
#include <LibGfx/Font/Font.h>
#include <LibGfx/Font/FontDatabase.h>
#include <LibGfx/Font/FontStyleMapping.h>
#include <LibGfx/Font/Typeface.h>
#include <LibGfx/Font/WOFF/Loader.h>
#include <LibGfx/Font/WOFF2/Loader.h>
#include <LibWeb/Animations/AnimationEffect.h>
#include <LibWeb/Animations/DocumentTimeline.h>
#include <LibWeb/Bindings/PrincipalHostDefined.h>
#include <LibWeb/CSS/AnimationEvent.h>
#include <LibWeb/CSS/CSSAnimation.h>
#include <LibWeb/CSS/CSSFontFaceRule.h>
#include <LibWeb/CSS/CSSImportRule.h>
#include <LibWeb/CSS/CSSLayerBlockRule.h>
#include <LibWeb/CSS/CSSLayerStatementRule.h>
#include <LibWeb/CSS/CSSNestedDeclarations.h>
#include <LibWeb/CSS/CSSStyleProperties.h>
#include <LibWeb/CSS/CSSStyleRule.h>
#include <LibWeb/CSS/CSSTransition.h>
#include <LibWeb/CSS/ComputedProperties.h>
#include <LibWeb/CSS/Fetch.h>
#include <LibWeb/CSS/Interpolation.h>
#include <LibWeb/CSS/InvalidationSet.h>
#include <LibWeb/CSS/Parser/ArbitrarySubstitutionFunctions.h>
#include <LibWeb/CSS/Parser/Parser.h>
#include <LibWeb/CSS/SelectorEngine.h>
#include <LibWeb/CSS/StyleComputer.h>
#include <LibWeb/CSS/StyleSheet.h>
#include <LibWeb/CSS/StyleValues/AngleStyleValue.h>
#include <LibWeb/CSS/StyleValues/BorderRadiusStyleValue.h>
#include <LibWeb/CSS/StyleValues/CSSColorValue.h>
#include <LibWeb/CSS/StyleValues/CSSKeywordValue.h>
#include <LibWeb/CSS/StyleValues/CustomIdentStyleValue.h>
#include <LibWeb/CSS/StyleValues/DisplayStyleValue.h>
#include <LibWeb/CSS/StyleValues/EasingStyleValue.h>
#include <LibWeb/CSS/StyleValues/FilterValueListStyleValue.h>
#include <LibWeb/CSS/StyleValues/FrequencyStyleValue.h>
#include <LibWeb/CSS/StyleValues/GridTrackPlacementStyleValue.h>
#include <LibWeb/CSS/StyleValues/GridTrackSizeListStyleValue.h>
#include <LibWeb/CSS/StyleValues/GuaranteedInvalidStyleValue.h>
#include <LibWeb/CSS/StyleValues/IntegerStyleValue.h>
#include <LibWeb/CSS/StyleValues/LengthStyleValue.h>
#include <LibWeb/CSS/StyleValues/MathDepthStyleValue.h>
#include <LibWeb/CSS/StyleValues/NumberStyleValue.h>
#include <LibWeb/CSS/StyleValues/PendingSubstitutionStyleValue.h>
#include <LibWeb/CSS/StyleValues/PercentageStyleValue.h>
#include <LibWeb/CSS/StyleValues/PositionStyleValue.h>
#include <LibWeb/CSS/StyleValues/RatioStyleValue.h>
#include <LibWeb/CSS/StyleValues/RectStyleValue.h>
#include <LibWeb/CSS/StyleValues/ShorthandStyleValue.h>
#include <LibWeb/CSS/StyleValues/StringStyleValue.h>
#include <LibWeb/CSS/StyleValues/StyleValueList.h>
#include <LibWeb/CSS/StyleValues/TimeStyleValue.h>
#include <LibWeb/CSS/StyleValues/TransformationStyleValue.h>
#include <LibWeb/CSS/StyleValues/TransitionStyleValue.h>
#include <LibWeb/CSS/StyleValues/UnresolvedStyleValue.h>
#include <LibWeb/DOM/Attr.h>
#include <LibWeb/DOM/Document.h>
#include <LibWeb/DOM/Element.h>
#include <LibWeb/DOM/ShadowRoot.h>
#include <LibWeb/Fetch/Infrastructure/FetchController.h>
#include <LibWeb/Fetch/Response.h>
#include <LibWeb/HTML/HTMLBRElement.h>
#include <LibWeb/HTML/HTMLHtmlElement.h>
#include <LibWeb/HTML/Parser/HTMLParser.h>
#include <LibWeb/HTML/Scripting/TemporaryExecutionContext.h>
#include <LibWeb/Layout/Node.h>
#include <LibWeb/MimeSniff/MimeType.h>
#include <LibWeb/MimeSniff/Resource.h>
#include <LibWeb/Namespace.h>
#include <LibWeb/Painting/PaintableBox.h>
#include <LibWeb/Platform/FontPlugin.h>
#include <math.h>
#include <stdio.h>
namespace Web::CSS {
struct FontFaceKey {
NonnullRawPtr<FlyString const> family_name;
int weight { 0 };
int slope { 0 };
};
}
namespace AK {
namespace Detail {
template<>
inline constexpr bool IsHashCompatible<Web::CSS::FontFaceKey, Web::CSS::OwnFontFaceKey> = true;
template<>
inline constexpr bool IsHashCompatible<Web::CSS::OwnFontFaceKey, Web::CSS::FontFaceKey> = true;
}
template<>
struct Traits<Web::CSS::FontFaceKey> : public DefaultTraits<Web::CSS::FontFaceKey> {
static unsigned hash(Web::CSS::FontFaceKey const& key) { return pair_int_hash(key.family_name->hash(), pair_int_hash(key.weight, key.slope)); }
};
template<>
struct Traits<Web::CSS::OwnFontFaceKey> : public DefaultTraits<Web::CSS::OwnFontFaceKey> {
static unsigned hash(Web::CSS::OwnFontFaceKey const& key) { return pair_int_hash(key.family_name.hash(), pair_int_hash(key.weight, key.slope)); }
};
}
namespace Web::CSS {
CSSStyleProperties const& MatchingRule::declaration() const
{
if (rule->type() == CSSRule::Type::Style)
return static_cast<CSSStyleRule const&>(*rule).declaration();
if (rule->type() == CSSRule::Type::NestedDeclarations)
return static_cast<CSSNestedDeclarations const&>(*rule).declaration();
VERIFY_NOT_REACHED();
}
SelectorList const& MatchingRule::absolutized_selectors() const
{
if (rule->type() == CSSRule::Type::Style)
return static_cast<CSSStyleRule const&>(*rule).absolutized_selectors();
if (rule->type() == CSSRule::Type::NestedDeclarations)
return static_cast<CSSNestedDeclarations const&>(*rule).parent_style_rule().absolutized_selectors();
VERIFY_NOT_REACHED();
}
FlyString const& MatchingRule::qualified_layer_name() const
{
if (rule->type() == CSSRule::Type::Style)
return static_cast<CSSStyleRule const&>(*rule).qualified_layer_name();
if (rule->type() == CSSRule::Type::NestedDeclarations)
return static_cast<CSSNestedDeclarations const&>(*rule).parent_style_rule().qualified_layer_name();
VERIFY_NOT_REACHED();
}
OwnFontFaceKey::OwnFontFaceKey(FontFaceKey const& other)
: family_name(other.family_name)
, weight(other.weight)
, slope(other.slope)
{
}
OwnFontFaceKey::operator FontFaceKey() const
{
return FontFaceKey {
family_name,
weight,
slope
};
}
[[nodiscard]] bool OwnFontFaceKey::operator==(FontFaceKey const& other) const
{
return family_name == other.family_name
&& weight == other.weight
&& slope == other.slope;
}
static DOM::Element const* element_to_inherit_style_from(DOM::Element const*, Optional<CSS::PseudoElement>);
StyleComputer::StyleComputer(DOM::Document& document)
: m_document(document)
, m_default_font_metrics(16, Platform::FontPlugin::the().default_font(16)->pixel_metrics())
, m_root_element_font_metrics(m_default_font_metrics)
{
m_qualified_layer_names_in_order.append({});
}
StyleComputer::~StyleComputer() = default;
FontLoader::FontLoader(StyleComputer& style_computer, GC::Ptr<CSSStyleSheet> parent_style_sheet, FlyString family_name, Vector<Gfx::UnicodeRange> unicode_ranges, Vector<URL> urls, Function<void(RefPtr<Gfx::Typeface const>)> on_load)
: m_style_computer(style_computer)
, m_parent_style_sheet(parent_style_sheet)
, m_family_name(move(family_name))
, m_unicode_ranges(move(unicode_ranges))
, m_urls(move(urls))
, m_on_load(move(on_load))
{
}
FontLoader::~FontLoader() = default;
bool FontLoader::is_loading() const
{
return m_fetch_controller && !m_vector_font;
}
RefPtr<Gfx::Font const> FontLoader::font_with_point_size(float point_size)
{
if (!m_vector_font) {
if (!m_fetch_controller)
start_loading_next_url();
return nullptr;
}
return m_vector_font->font(point_size);
}
void FontLoader::start_loading_next_url()
{
// FIXME: Load local() fonts somehow.
if (m_fetch_controller && m_fetch_controller->state() == Fetch::Infrastructure::FetchController::State::Ongoing)
return;
if (m_urls.is_empty())
return;
// https://drafts.csswg.org/css-fonts-4/#fetch-a-font
// To fetch a font given a selected <url> url for @font-face rule, fetch url, with stylesheet being rule’s parent
// CSS style sheet, destination "font", CORS mode "cors", and processResponse being the following steps given
// response res and null, failure or a byte stream stream:
auto style_sheet_or_document = m_parent_style_sheet ? StyleSheetOrDocument { *m_parent_style_sheet } : StyleSheetOrDocument { m_style_computer.document() };
auto maybe_fetch_controller = fetch_a_style_resource(m_urls.take_first(), style_sheet_or_document, Fetch::Infrastructure::Request::Destination::Font, CorsMode::Cors,
[weak_loader = make_weak_ptr()](auto response, auto stream) {
// NB: If the FontLoader died before this fetch completed, nobody wants the data.
if (weak_loader.is_null())
return;
auto& loader = *weak_loader;
// 1. If stream is null, return.
// 2. Load a font from stream according to its type.
// NB: We need to fetch the next source if this one fails to fetch OR decode. So, first try to decode it.
RefPtr<Gfx::Typeface const> typeface;
if (auto* bytes = stream.template get_pointer<ByteBuffer>()) {
if (auto maybe_typeface = loader.try_load_font(response, *bytes); !maybe_typeface.is_error())
typeface = maybe_typeface.release_value();
}
if (!typeface) {
// NB: If we have other sources available, try the next one.
if (loader.m_urls.is_empty()) {
loader.font_did_load_or_fail(nullptr);
} else {
loader.m_fetch_controller = nullptr;
loader.start_loading_next_url();
}
} else {
loader.font_did_load_or_fail(move(typeface));
}
});
if (maybe_fetch_controller.is_error()) {
font_did_load_or_fail(nullptr);
} else {
m_fetch_controller = maybe_fetch_controller.release_value();
}
}
void FontLoader::font_did_load_or_fail(RefPtr<Gfx::Typeface const> typeface)
{
if (typeface) {
m_vector_font = typeface.release_nonnull();
m_style_computer.did_load_font(m_family_name);
if (m_on_load)
m_on_load(m_vector_font);
} else {
if (m_on_load)
m_on_load(nullptr);
}
m_fetch_controller = nullptr;
}
ErrorOr<NonnullRefPtr<Gfx::Typeface const>> FontLoader::try_load_font(Fetch::Infrastructure::Response const& response, ByteBuffer const& bytes)
{
// FIXME: This could maybe use the format() provided in @font-face as well, since often the mime type is just application/octet-stream and we have to try every format
auto mime_type = response.header_list()->extract_mime_type();
if (!mime_type.has_value() || !mime_type->is_font()) {
mime_type = MimeSniff::Resource::sniff(bytes, MimeSniff::SniffingConfiguration { .sniffing_context = MimeSniff::SniffingContext::Font });
}
if (mime_type.has_value()) {
if (mime_type->essence() == "font/ttf"sv || mime_type->essence() == "application/x-font-ttf"sv || mime_type->essence() == "font/otf"sv) {
if (auto result = Gfx::Typeface::try_load_from_temporary_memory(bytes); !result.is_error()) {
return result;
}
}
if (mime_type->essence() == "font/woff"sv || mime_type->essence() == "application/font-woff"sv) {
if (auto result = WOFF::try_load_from_bytes(bytes); !result.is_error()) {
return result;
}
}
if (mime_type->essence() == "font/woff2"sv || mime_type->essence() == "application/font-woff2"sv) {
if (auto result = WOFF2::try_load_from_bytes(bytes); !result.is_error()) {
return result;
}
}
}
return Error::from_string_literal("Automatic format detection failed");
}
struct StyleComputer::MatchingFontCandidate {
FontFaceKey key;
Variant<FontLoaderList*, Gfx::Typeface const*> loader_or_typeface;
[[nodiscard]] RefPtr<Gfx::FontCascadeList const> font_with_point_size(float point_size) const
{
auto font_list = Gfx::FontCascadeList::create();
if (auto* loader_list = loader_or_typeface.get_pointer<FontLoaderList*>(); loader_list) {
for (auto const& loader : **loader_list) {
if (auto font = loader->font_with_point_size(point_size); font)
font_list->add(*font, loader->unicode_ranges());
}
return font_list;
}
font_list->add(loader_or_typeface.get<Gfx::Typeface const*>()->font(point_size));
return font_list;
}
};
static CSSStyleSheet& default_stylesheet()
{
static GC::Root<CSSStyleSheet> sheet;
if (!sheet.cell()) {
extern String default_stylesheet_source;
sheet = GC::make_root(parse_css_stylesheet(CSS::Parser::ParsingParams(internal_css_realm()), default_stylesheet_source));
}
return *sheet;
}
static CSSStyleSheet& quirks_mode_stylesheet()
{
static GC::Root<CSSStyleSheet> sheet;
if (!sheet.cell()) {
extern String quirks_mode_stylesheet_source;
sheet = GC::make_root(parse_css_stylesheet(CSS::Parser::ParsingParams(internal_css_realm()), quirks_mode_stylesheet_source));
}
return *sheet;
}
static CSSStyleSheet& mathml_stylesheet()
{
static GC::Root<CSSStyleSheet> sheet;
if (!sheet.cell()) {
extern String mathml_stylesheet_source;
sheet = GC::make_root(parse_css_stylesheet(CSS::Parser::ParsingParams(internal_css_realm()), mathml_stylesheet_source));
}
return *sheet;
}
static CSSStyleSheet& svg_stylesheet()
{
static GC::Root<CSSStyleSheet> sheet;
if (!sheet.cell()) {
extern String svg_stylesheet_source;
sheet = GC::make_root(parse_css_stylesheet(CSS::Parser::ParsingParams(internal_css_realm()), svg_stylesheet_source));
}
return *sheet;
}
Optional<String> StyleComputer::user_agent_style_sheet_source(StringView name)
{
extern String default_stylesheet_source;
extern String quirks_mode_stylesheet_source;
extern String mathml_stylesheet_source;
extern String svg_stylesheet_source;
if (name == "CSS/Default.css"sv)
return default_stylesheet_source;
if (name == "CSS/QuirksMode.css"sv)
return quirks_mode_stylesheet_source;
if (name == "MathML/Default.css"sv)
return mathml_stylesheet_source;
if (name == "SVG/Default.css"sv)
return svg_stylesheet_source;
return {};
}
template<typename Callback>
void StyleComputer::for_each_stylesheet(CascadeOrigin cascade_origin, Callback callback) const
{
if (cascade_origin == CascadeOrigin::UserAgent) {
callback(default_stylesheet(), {});
if (document().in_quirks_mode())
callback(quirks_mode_stylesheet(), {});
callback(mathml_stylesheet(), {});
callback(svg_stylesheet(), {});
}
if (cascade_origin == CascadeOrigin::User) {
if (m_user_style_sheet)
callback(*m_user_style_sheet, {});
}
if (cascade_origin == CascadeOrigin::Author) {
document().for_each_active_css_style_sheet([&](auto& sheet, auto shadow_root) {
callback(sheet, shadow_root);
});
}
}
RuleCache const* StyleComputer::rule_cache_for_cascade_origin(CascadeOrigin cascade_origin, FlyString const& qualified_layer_name, GC::Ptr<DOM::ShadowRoot const> shadow_root) const
{
auto const* rule_caches_for_document_and_shadow_roots = [&]() -> RuleCachesForDocumentAndShadowRoots const* {
switch (cascade_origin) {
case CascadeOrigin::Author:
return m_author_rule_cache;
case CascadeOrigin::User:
return m_user_rule_cache;
case CascadeOrigin::UserAgent:
return m_user_agent_rule_cache;
default:
VERIFY_NOT_REACHED();
}
}();
auto const* rule_caches_by_layer = [&]() -> RuleCaches const* {
if (shadow_root)
return rule_caches_for_document_and_shadow_roots->for_shadow_roots.get(*shadow_root).value_or(nullptr);
return &rule_caches_for_document_and_shadow_roots->for_document;
}();
if (!rule_caches_by_layer)
return nullptr;
if (qualified_layer_name.is_empty())
return &rule_caches_by_layer->main;
return rule_caches_by_layer->by_layer.get(qualified_layer_name).value_or(nullptr);
}
[[nodiscard]] static bool filter_namespace_rule(Optional<FlyString> const& element_namespace_uri, MatchingRule const& rule)
{
// FIXME: Filter out non-default namespace using prefixes
if (rule.default_namespace.has_value() && element_namespace_uri != rule.default_namespace)
return false;
return true;
}
RuleCache const& StyleComputer::get_pseudo_class_rule_cache(PseudoClass pseudo_class) const
{
build_rule_cache_if_needed();
return *m_pseudo_class_rule_cache[to_underlying(pseudo_class)];
}
InvalidationSet StyleComputer::invalidation_set_for_properties(Vector<InvalidationSet::Property> const& properties) const
{
if (!m_style_invalidation_data)
return {};
auto const& descendant_invalidation_sets = m_style_invalidation_data->descendant_invalidation_sets;
InvalidationSet result;
for (auto const& property : properties) {
if (auto it = descendant_invalidation_sets.find(property); it != descendant_invalidation_sets.end())
result.include_all_from(it->value);
}
return result;
}
bool StyleComputer::invalidation_property_used_in_has_selector(InvalidationSet::Property const& property) const
{
if (!m_style_invalidation_data)
return true;
switch (property.type) {
case InvalidationSet::Property::Type::Id:
if (m_style_invalidation_data->ids_used_in_has_selectors.contains(property.name()))
return true;
break;
case InvalidationSet::Property::Type::Class:
if (m_style_invalidation_data->class_names_used_in_has_selectors.contains(property.name()))
return true;
break;
case InvalidationSet::Property::Type::Attribute:
if (m_style_invalidation_data->attribute_names_used_in_has_selectors.contains(property.name()))
return true;
break;
case InvalidationSet::Property::Type::TagName:
if (m_style_invalidation_data->tag_names_used_in_has_selectors.contains(property.name()))
return true;
break;
case InvalidationSet::Property::Type::PseudoClass:
if (m_style_invalidation_data->pseudo_classes_used_in_has_selectors.contains(property.value.get<PseudoClass>()))
return true;
break;
default:
break;
}
return false;
}
Vector<MatchingRule const*> StyleComputer::collect_matching_rules(DOM::Element const& element, CascadeOrigin cascade_origin, Optional<CSS::PseudoElement> pseudo_element, PseudoClassBitmap& attempted_pseudo_class_matches, FlyString const& qualified_layer_name) const
{
auto const& root_node = element.root();
auto shadow_root = is<DOM::ShadowRoot>(root_node) ? static_cast<DOM::ShadowRoot const*>(&root_node) : nullptr;
auto element_shadow_root = element.shadow_root();
auto const& element_namespace_uri = element.namespace_uri();
GC::Ptr<DOM::Element const> shadow_host;
if (element_shadow_root)
shadow_host = element;
else if (shadow_root)
shadow_host = shadow_root->host();
Vector<MatchingRule const&, 512> rules_to_run;
auto add_rule_to_run = [&](MatchingRule const& rule_to_run) {
// FIXME: This needs to be revised when adding support for the ::shadow selector, as it needs to cross shadow boundaries.
auto rule_root = rule_to_run.shadow_root;
auto from_user_agent_or_user_stylesheet = rule_to_run.cascade_origin == CascadeOrigin::UserAgent || rule_to_run.cascade_origin == CascadeOrigin::User;
// NOTE: Inside shadow trees, we only match rules that are defined in the shadow tree's style sheets.
// The key exception is the shadow tree's *shadow host*, which needs to match :host rules from inside the shadow root.
// Also note that UA or User style sheets don't have a scope, so they are always relevant.
// FIXME: We should reorganize the data so that the document-level StyleComputer doesn't cache *all* rules,
// but instead we'd have some kind of "style scope" at the document level, and also one for each shadow root.
// Then we could only evaluate rules from the current style scope.
bool rule_is_relevant_for_current_scope = rule_root == shadow_root
|| (element_shadow_root && rule_root == element_shadow_root)
|| from_user_agent_or_user_stylesheet;
if (!rule_is_relevant_for_current_scope)
return;
auto const& selector = rule_to_run.selector;
if (selector.can_use_ancestor_filter() && should_reject_with_ancestor_filter(selector))
return;
rules_to_run.unchecked_append(rule_to_run);
};
auto add_rules_to_run = [&](Vector<MatchingRule> const& rules) {
rules_to_run.grow_capacity(rules_to_run.size() + rules.size());
if (pseudo_element.has_value()) {
for (auto const& rule : rules) {
if (rule.contains_pseudo_element && filter_namespace_rule(element_namespace_uri, rule))
add_rule_to_run(rule);
}
} else {
for (auto const& rule : rules) {
if (!rule.contains_pseudo_element && filter_namespace_rule(element_namespace_uri, rule))
add_rule_to_run(rule);
}
}
};
auto add_rules_from_cache = [&](RuleCache const& rule_cache) {
rule_cache.for_each_matching_rules(element, pseudo_element, [&](auto const& matching_rules) {
add_rules_to_run(matching_rules);
return IterationDecision::Continue;
});
};
if (auto const* rule_cache = rule_cache_for_cascade_origin(cascade_origin, qualified_layer_name, nullptr))
add_rules_from_cache(*rule_cache);
if (shadow_root) {
if (auto const* rule_cache = rule_cache_for_cascade_origin(cascade_origin, qualified_layer_name, shadow_root))
add_rules_from_cache(*rule_cache);
}
if (element_shadow_root) {
if (auto const* rule_cache = rule_cache_for_cascade_origin(cascade_origin, qualified_layer_name, element_shadow_root))
add_rules_from_cache(*rule_cache);
}
Vector<MatchingRule const*> matching_rules;
matching_rules.ensure_capacity(rules_to_run.size());
for (auto const& rule_to_run : rules_to_run) {
// NOTE: When matching an element against a rule from outside the shadow root's style scope,
// we have to pass in null for the shadow host, otherwise combinator traversal will
// be confined to the element itself (since it refuses to cross the shadow boundary).
auto rule_root = rule_to_run.shadow_root;
auto shadow_host_to_use = shadow_host;
if (element.is_shadow_host() && rule_root != element.shadow_root())
shadow_host_to_use = nullptr;
auto const& selector = rule_to_run.selector;
SelectorEngine::MatchContext context {
.style_sheet_for_rule = *rule_to_run.sheet,
.subject = element,
.collect_per_element_selector_involvement_metadata = true,
};
ScopeGuard guard = [&] {
attempted_pseudo_class_matches |= context.attempted_pseudo_class_matches;
};
if (!SelectorEngine::matches(selector, element, shadow_host_to_use, context, pseudo_element))
continue;
matching_rules.append(&rule_to_run);
}
return matching_rules;
}
static void sort_matching_rules(Vector<MatchingRule const*>& matching_rules)
{
quick_sort(matching_rules, [&](MatchingRule const* a, MatchingRule const* b) {
auto const& a_selector = a->selector;
auto const& b_selector = b->selector;
auto a_specificity = a_selector.specificity();
auto b_specificity = b_selector.specificity();
if (a_specificity == b_specificity) {
if (a->style_sheet_index == b->style_sheet_index)
return a->rule_index < b->rule_index;
return a->style_sheet_index < b->style_sheet_index;
}
return a_specificity < b_specificity;
});
}
void StyleComputer::for_each_property_expanding_shorthands(PropertyID property_id, CSSStyleValue const& value, Function<void(PropertyID, CSSStyleValue const&)> const& set_longhand_property)
{
if (property_is_shorthand(property_id) && (value.is_unresolved() || value.is_pending_substitution())) {
// If a shorthand property contains an arbitrary substitution function in its value, the longhand properties
// it’s associated with must instead be filled in with a special, unobservable-to-authors pending-substitution
// value that indicates the shorthand contains an arbitrary substitution function, and thus the longhand’s
// value can’t be determined until after substituted.
// https://drafts.csswg.org/css-values-5/#pending-substitution-value
// Ensure we keep the longhand around until it can be resolved.
set_longhand_property(property_id, value);
auto pending_substitution_value = PendingSubstitutionStyleValue::create();
for (auto longhand_id : longhands_for_shorthand(property_id)) {
for_each_property_expanding_shorthands(longhand_id, pending_substitution_value, set_longhand_property);
}
return;
}
if (value.is_shorthand()) {
auto& shorthand_value = value.as_shorthand();
auto& properties = shorthand_value.sub_properties();
auto& values = shorthand_value.values();
for (size_t i = 0; i < properties.size(); ++i)
for_each_property_expanding_shorthands(properties[i], values[i], set_longhand_property);
return;
}
// FIXME: We should add logic in parse_css_value to parse "positional-value-list-shorthand"s as
// ShorthandStyleValues to avoid the need for this (and assign_start_and_end_values).
auto assign_edge_values = [&](PropertyID top_property, PropertyID right_property, PropertyID bottom_property, PropertyID left_property, CSSStyleValue const& value) {
if (value.is_value_list()) {
auto values = value.as_value_list().values();
if (values.size() == 4) {
set_longhand_property(top_property, values[0]);
set_longhand_property(right_property, values[1]);
set_longhand_property(bottom_property, values[2]);
set_longhand_property(left_property, values[3]);
} else if (values.size() == 3) {
set_longhand_property(top_property, values[0]);
set_longhand_property(right_property, values[1]);
set_longhand_property(bottom_property, values[2]);
set_longhand_property(left_property, values[1]);
} else if (values.size() == 2) {
set_longhand_property(top_property, values[0]);
set_longhand_property(right_property, values[1]);
set_longhand_property(bottom_property, values[0]);
set_longhand_property(left_property, values[1]);
} else if (values.size() == 1) {
set_longhand_property(top_property, values[0]);
set_longhand_property(right_property, values[0]);
set_longhand_property(bottom_property, values[0]);
set_longhand_property(left_property, values[0]);
}
} else {
set_longhand_property(top_property, value);
set_longhand_property(right_property, value);
set_longhand_property(bottom_property, value);
set_longhand_property(left_property, value);
}
};
auto assign_start_and_end_values = [&](PropertyID start_property, PropertyID end_property, auto const& values) {
if (values.is_value_list()) {
set_longhand_property(start_property, value.as_value_list().values()[0]);
set_longhand_property(end_property, value.as_value_list().values()[1]);
} else {
set_longhand_property(start_property, value);
set_longhand_property(end_property, value);
}
};
if (property_id == CSS::PropertyID::BorderStyle) {
assign_edge_values(PropertyID::BorderTopStyle, PropertyID::BorderRightStyle, PropertyID::BorderBottomStyle, PropertyID::BorderLeftStyle, value);
return;
}
if (property_id == CSS::PropertyID::BorderBlockStyle) {
assign_start_and_end_values(PropertyID::BorderBlockStartStyle, PropertyID::BorderBlockEndStyle, value);
return;
}
if (property_id == CSS::PropertyID::BorderInlineStyle) {
assign_start_and_end_values(PropertyID::BorderInlineStartStyle, PropertyID::BorderInlineEndStyle, value);
return;
}
if (property_id == CSS::PropertyID::BorderWidth) {
assign_edge_values(PropertyID::BorderTopWidth, PropertyID::BorderRightWidth, PropertyID::BorderBottomWidth, PropertyID::BorderLeftWidth, value);
return;
}
if (property_id == CSS::PropertyID::BorderBlockWidth) {
assign_start_and_end_values(PropertyID::BorderBlockStartWidth, PropertyID::BorderBlockEndWidth, value);
return;
}
if (property_id == CSS::PropertyID::BorderInlineWidth) {
assign_start_and_end_values(PropertyID::BorderInlineStartWidth, PropertyID::BorderInlineEndWidth, value);
return;
}
if (property_id == CSS::PropertyID::BorderColor) {
assign_edge_values(PropertyID::BorderTopColor, PropertyID::BorderRightColor, PropertyID::BorderBottomColor, PropertyID::BorderLeftColor, value);
return;
}
if (property_id == CSS::PropertyID::BorderBlockColor) {
assign_start_and_end_values(PropertyID::BorderBlockStartColor, PropertyID::BorderBlockEndColor, value);
return;
}
if (property_id == CSS::PropertyID::BorderInlineColor) {
assign_start_and_end_values(PropertyID::BorderInlineStartColor, PropertyID::BorderInlineEndColor, value);
return;
}
if (property_id == CSS::PropertyID::BackgroundPosition) {
if (value.is_position()) {
auto const& position = value.as_position();
set_longhand_property(CSS::PropertyID::BackgroundPositionX, position.edge_x());
set_longhand_property(CSS::PropertyID::BackgroundPositionY, position.edge_y());
} else if (value.is_value_list()) {
// Expand background-position layer list into separate lists for x and y positions:
auto const& values_list = value.as_value_list();
StyleValueVector x_positions {};
StyleValueVector y_positions {};
x_positions.ensure_capacity(values_list.size());
y_positions.ensure_capacity(values_list.size());
for (auto& layer : values_list.values()) {
if (layer->is_position()) {
auto const& position = layer->as_position();
x_positions.unchecked_append(position.edge_x());
y_positions.unchecked_append(position.edge_y());
} else {
x_positions.unchecked_append(layer);
y_positions.unchecked_append(layer);
}
}
set_longhand_property(CSS::PropertyID::BackgroundPositionX, StyleValueList::create(move(x_positions), values_list.separator()));
set_longhand_property(CSS::PropertyID::BackgroundPositionY, StyleValueList::create(move(y_positions), values_list.separator()));
} else {
set_longhand_property(CSS::PropertyID::BackgroundPositionX, value);
set_longhand_property(CSS::PropertyID::BackgroundPositionY, value);
}
return;
}
if (property_id == CSS::PropertyID::Inset) {
assign_edge_values(PropertyID::Top, PropertyID::Right, PropertyID::Bottom, PropertyID::Left, value);
return;
}
if (property_id == CSS::PropertyID::InsetBlock) {
assign_start_and_end_values(PropertyID::InsetBlockStart, PropertyID::InsetBlockEnd, value);
return;
}
if (property_id == CSS::PropertyID::InsetInline) {
assign_start_and_end_values(PropertyID::InsetInlineStart, PropertyID::InsetInlineEnd, value);
return;
}
if (property_id == CSS::PropertyID::Margin) {
assign_edge_values(PropertyID::MarginTop, PropertyID::MarginRight, PropertyID::MarginBottom, PropertyID::MarginLeft, value);
return;
}
if (property_id == CSS::PropertyID::MarginBlock) {
assign_start_and_end_values(PropertyID::MarginBlockStart, PropertyID::MarginBlockEnd, value);
return;
}
if (property_id == CSS::PropertyID::MarginInline) {
assign_start_and_end_values(PropertyID::MarginInlineStart, PropertyID::MarginInlineEnd, value);
return;
}
if (property_id == CSS::PropertyID::Padding) {
assign_edge_values(PropertyID::PaddingTop, PropertyID::PaddingRight, PropertyID::PaddingBottom, PropertyID::PaddingLeft, value);
return;
}
if (property_id == CSS::PropertyID::PaddingBlock) {
assign_start_and_end_values(PropertyID::PaddingBlockStart, PropertyID::PaddingBlockEnd, value);
return;
}
if (property_id == CSS::PropertyID::PaddingInline) {
assign_start_and_end_values(PropertyID::PaddingInlineStart, PropertyID::PaddingInlineEnd, value);
return;
}
if (property_id == CSS::PropertyID::Gap) {
if (value.is_value_list()) {
auto const& values_list = value.as_value_list();
set_longhand_property(CSS::PropertyID::RowGap, values_list.values()[0]);
set_longhand_property(CSS::PropertyID::ColumnGap, values_list.values()[1]);
return;
}
set_longhand_property(CSS::PropertyID::RowGap, value);
set_longhand_property(CSS::PropertyID::ColumnGap, value);
return;
}
if (property_id == CSS::PropertyID::Transition) {
if (value.to_keyword() == Keyword::None) {
// Handle `none` as a shorthand for `all 0s ease 0s`.
set_longhand_property(CSS::PropertyID::TransitionProperty, CSSKeywordValue::create(Keyword::All));
set_longhand_property(CSS::PropertyID::TransitionDuration, TimeStyleValue::create(CSS::Time::make_seconds(0)));
set_longhand_property(CSS::PropertyID::TransitionDelay, TimeStyleValue::create(CSS::Time::make_seconds(0)));
set_longhand_property(CSS::PropertyID::TransitionTimingFunction, EasingStyleValue::create(EasingStyleValue::CubicBezier::ease()));
set_longhand_property(CSS::PropertyID::TransitionBehavior, CSSKeywordValue::create(Keyword::Normal));
} else if (value.is_transition()) {
auto const& transitions = value.as_transition().transitions();
Array<Vector<ValueComparingNonnullRefPtr<CSSStyleValue const>>, 5> transition_values;
for (auto const& transition : transitions) {
transition_values[0].append(*transition.property_name);
transition_values[1].append(transition.duration.as_style_value());
transition_values[2].append(transition.delay.as_style_value());
if (transition.easing)
transition_values[3].append(*transition.easing);
transition_values[4].append(CSSKeywordValue::create(to_keyword(transition.transition_behavior)));
}
set_longhand_property(CSS::PropertyID::TransitionProperty, StyleValueList::create(move(transition_values[0]), StyleValueList::Separator::Comma));
set_longhand_property(CSS::PropertyID::TransitionDuration, StyleValueList::create(move(transition_values[1]), StyleValueList::Separator::Comma));
set_longhand_property(CSS::PropertyID::TransitionDelay, StyleValueList::create(move(transition_values[2]), StyleValueList::Separator::Comma));
set_longhand_property(CSS::PropertyID::TransitionTimingFunction, StyleValueList::create(move(transition_values[3]), StyleValueList::Separator::Comma));
set_longhand_property(CSS::PropertyID::TransitionBehavior, StyleValueList::create(move(transition_values[4]), StyleValueList::Separator::Comma));
} else {
set_longhand_property(CSS::PropertyID::TransitionProperty, value);
set_longhand_property(CSS::PropertyID::TransitionDuration, value);
set_longhand_property(CSS::PropertyID::TransitionDelay, value);
set_longhand_property(CSS::PropertyID::TransitionTimingFunction, value);
set_longhand_property(CSS::PropertyID::TransitionBehavior, value);
}
return;
}
if (property_is_shorthand(property_id)) {
// ShorthandStyleValue was handled already, as were unresolved shorthands.
// That means the only values we should see are the CSS-wide keywords, or the guaranteed-invalid value.
// Both should be applied to our longhand properties.
// We don't directly call `set_longhand_property()` because the longhands might have longhands of their own.
// (eg `grid` -> `grid-template` -> `grid-template-areas` & `grid-template-rows` & `grid-template-columns`)
VERIFY(value.is_css_wide_keyword() || value.is_guaranteed_invalid());
for (auto longhand : longhands_for_shorthand(property_id))
for_each_property_expanding_shorthands(longhand, value, set_longhand_property);
return;
}
set_longhand_property(property_id, value);
}
void StyleComputer::cascade_declarations(
CascadedProperties& cascaded_properties,
DOM::Element& element,
Optional<CSS::PseudoElement> pseudo_element,
Vector<MatchingRule const*> const& matching_rules,
CascadeOrigin cascade_origin,
Important important,
Optional<FlyString> layer_name,
Optional<LogicalAliasMappingContext> logical_alias_mapping_context) const
{
auto seen_properties = MUST(Bitmap::create(to_underlying(last_property_id) + 1, false));
auto cascade_style_declaration = [&](CSSStyleProperties const& declaration) {
seen_properties.fill(false);
for (auto const& property : declaration.properties()) {
if (important != property.important)
continue;
if (pseudo_element.has_value() && !pseudo_element_supports_property(*pseudo_element, property.property_id))
continue;
auto property_value = property.value;
if (property_value->is_unresolved())
property_value = Parser::Parser::resolve_unresolved_style_value(Parser::ParsingParams { element.document() }, element, pseudo_element, property.property_id, property_value->as_unresolved());
if (property_value->is_guaranteed_invalid()) {
// https://drafts.csswg.org/css-values-5/#invalid-at-computed-value-time
// When substitution results in a property’s value containing the guaranteed-invalid value, this makes the
// declaration invalid at computed-value time. When this happens, the computed value is one of the
// following depending on the property’s type:
// -> The property is a non-registered custom property
// -> The property is a registered custom property with universal syntax
// FIXME: Process custom properties here?
if (false) {
// The computed value is the guaranteed-invalid value.
}
// -> Otherwise
else {
// Either the property’s inherited value or its initial value depending on whether the property is
// inherited or not, respectively, as if the property’s value had been specified as the unset keyword.
property_value = CSSKeywordValue::create(Keyword::Unset);
}
}
for_each_property_expanding_shorthands(property.property_id, property_value, [&](PropertyID longhand_id, CSSStyleValue const& longhand_value) {
// If we're a PSV that's already been seen, that should mean that our shorthand already got
// resolved and gave us a value, so we don't want to overwrite it with a PSV.
if (seen_properties.get(to_underlying(longhand_id)) && property_value->is_pending_substitution())
return;
seen_properties.set(to_underlying(longhand_id), true);
PropertyID physical_property_id;
if (property_is_logical_alias(longhand_id)) {
if (!logical_alias_mapping_context.has_value())
return;
physical_property_id = map_logical_alias_to_physical_property(longhand_id, logical_alias_mapping_context.value());
} else {
physical_property_id = longhand_id;
}
if (longhand_value.is_revert()) {
cascaded_properties.revert_property(physical_property_id, important, cascade_origin);
} else if (longhand_value.is_revert_layer()) {
cascaded_properties.revert_layer_property(physical_property_id, important, layer_name);
} else {
cascaded_properties.set_property(physical_property_id, longhand_value, important, cascade_origin, layer_name, declaration);
}
});
}
};
for (auto const& match : matching_rules) {
cascade_style_declaration(match->declaration());
}
if (cascade_origin == CascadeOrigin::Author && !pseudo_element.has_value()) {
if (auto const inline_style = element.inline_style()) {
cascade_style_declaration(*inline_style);
}
}
}
static void cascade_custom_properties(DOM::Element& element, Optional<CSS::PseudoElement> pseudo_element, Vector<MatchingRule const*> const& matching_rules, HashMap<FlyString, StyleProperty>& custom_properties)
{
size_t needed_capacity = 0;
for (auto const& matching_rule : matching_rules)
needed_capacity += matching_rule->declaration().custom_properties().size();
if (!pseudo_element.has_value()) {
if (auto const inline_style = element.inline_style())
needed_capacity += inline_style->custom_properties().size();
}
custom_properties.ensure_capacity(custom_properties.size() + needed_capacity);
for (auto const& matching_rule : matching_rules) {
for (auto const& it : matching_rule->declaration().custom_properties()) {
auto style_value = it.value.value;
if (style_value->is_revert_layer())
continue;
custom_properties.set(it.key, it.value);
}
}
if (!pseudo_element.has_value()) {
if (auto const inline_style = element.inline_style()) {
for (auto const& it : inline_style->custom_properties())
custom_properties.set(it.key, it.value);
}
}
}
void StyleComputer::collect_animation_into(DOM::Element& element, Optional<CSS::PseudoElement> pseudo_element, GC::Ref<Animations::KeyframeEffect> effect, ComputedProperties& computed_properties, AnimationRefresh refresh) const
{
auto animation = effect->associated_animation();
if (!animation)
return;
auto output_progress = effect->transformed_progress();
if (!output_progress.has_value())
return;
if (!effect->key_frame_set())
return;
auto& keyframes = effect->key_frame_set()->keyframes_by_key;
if (keyframes.size() < 2) {
if constexpr (LIBWEB_CSS_ANIMATION_DEBUG) {
dbgln(" Did not find enough keyframes ({} keyframes)", keyframes.size());
for (auto it = keyframes.begin(); it != keyframes.end(); ++it)
dbgln(" - {}", it.key());
}
return;
}
auto key = static_cast<i64>(round(output_progress.value() * 100.0 * Animations::KeyframeEffect::AnimationKeyFrameKeyScaleFactor));
auto keyframe_start_it = [&] {
if (output_progress.value() <= 0) {
return keyframes.begin();
}
auto potential_match = keyframes.find_largest_not_above_iterator(key);
auto next = potential_match;
++next;
if (next.is_end()) {
--potential_match;
}
return potential_match;
}();
auto keyframe_start = static_cast<i64>(keyframe_start_it.key());
auto keyframe_values = *keyframe_start_it;
auto keyframe_end_it = ++keyframe_start_it;
VERIFY(!keyframe_end_it.is_end());
auto keyframe_end = static_cast<i64>(keyframe_end_it.key());
auto keyframe_end_values = *keyframe_end_it;
auto progress_in_keyframe
= static_cast<float>(key - keyframe_start) / static_cast<float>(keyframe_end - keyframe_start);
if constexpr (LIBWEB_CSS_ANIMATION_DEBUG) {
auto valid_properties = keyframe_values.properties.size();
dbgln("Animation {} contains {} properties to interpolate, progress = {}%", animation->id(), valid_properties, progress_in_keyframe * 100);
}
// FIXME: Follow https://drafts.csswg.org/web-animations-1/#ref-for-computed-keyframes in whatever the right place is.
auto compute_keyframe_values = [refresh, &computed_properties, &element, &pseudo_element, this](auto const& keyframe_values) {
HashMap<PropertyID, RefPtr<CSSStyleValue const>> result;
HashMap<PropertyID, PropertyID> longhands_set_by_property_id;
auto property_is_set_by_use_initial = MUST(Bitmap::create(to_underlying(last_longhand_property_id) - to_underlying(first_longhand_property_id) + 1, false));
auto property_is_logical_alias_including_shorthands = [&](PropertyID property_id) {
if (property_is_shorthand(property_id))
// NOTE: All expanded longhands for a logical alias shorthand are logical aliases so we only need to check the first one.
return property_is_logical_alias(expanded_longhands_for_shorthand(property_id)[0]);
return property_is_logical_alias(property_id);
};
// https://drafts.csswg.org/web-animations-1/#ref-for-computed-keyframes
auto is_property_preferred = [&](PropertyID a, PropertyID b) {
// If conflicts arise when expanding shorthand properties or replacing logical properties with physical properties, apply the following rules in order until the conflict is resolved:
// 1. Longhand properties override shorthand properties (e.g. border-top-color overrides border-top).
if (property_is_shorthand(a) != property_is_shorthand(b))
return !property_is_shorthand(a);
// 2. Shorthand properties with fewer longhand components override those with more longhand components (e.g. border-top overrides border-color).
if (property_is_shorthand(a)) {
auto number_of_expanded_shorthands_a = expanded_longhands_for_shorthand(a).size();
auto number_of_expanded_shorthands_b = expanded_longhands_for_shorthand(b).size();
if (number_of_expanded_shorthands_a != number_of_expanded_shorthands_b)
return number_of_expanded_shorthands_a < number_of_expanded_shorthands_b;
}
auto property_a_is_logical_alias = property_is_logical_alias_including_shorthands(a);
auto property_b_is_logical_alias = property_is_logical_alias_including_shorthands(b);
// 3. Physical properties override logical properties.
if (property_a_is_logical_alias != property_b_is_logical_alias)
return !property_a_is_logical_alias;
// 4. For shorthand properties with an equal number of longhand components, properties whose IDL name (see
// the CSS property to IDL attribute algorithm [CSSOM]) appears earlier when sorted in ascending order
// by the Unicode codepoints that make up each IDL name, override those who appear later.
return camel_case_string_from_property_id(a) < camel_case_string_from_property_id(b);
};
compute_font(computed_properties, &element, pseudo_element);
Length::FontMetrics font_metrics {
root_element_font_metrics_for_element(element).font_size,
computed_properties.first_available_computed_font().pixel_metrics()
};
for (auto const& [property_id, value] : keyframe_values.properties) {
bool is_use_initial = false;
auto style_value = value.visit(
[&](Animations::KeyframeEffect::KeyFrameSet::UseInitial) -> RefPtr<CSSStyleValue const> {
if (refresh == AnimationRefresh::Yes)
return {};
if (property_is_shorthand(property_id))
return {};
is_use_initial = true;
return computed_properties.property(property_id);
},
[&](RefPtr<CSSStyleValue const> value) -> RefPtr<CSSStyleValue const> {
return value;
});
if (!style_value) {
result.set(property_id, nullptr);
continue;
}
// If the style value is a PendingSubstitutionStyleValue we should skip it to avoid overwriting any value
// already set by resolving the relevant shorthand's value.
if (style_value->is_pending_substitution())
continue;
if (style_value->is_revert() || style_value->is_revert_layer())
style_value = computed_properties.property(property_id);
if (style_value->is_unresolved())
style_value = Parser::Parser::resolve_unresolved_style_value(Parser::ParsingParams { element.document() }, element, pseudo_element, property_id, style_value->as_unresolved());
for_each_property_expanding_shorthands(property_id, *style_value, [&](PropertyID longhand_id, CSSStyleValue const& longhand_value) {
auto physical_longhand_id = map_logical_alias_to_physical_property(longhand_id, LogicalAliasMappingContext { computed_properties.writing_mode(), computed_properties.direction() });
auto physical_longhand_id_bitmap_index = to_underlying(physical_longhand_id) - to_underlying(first_longhand_property_id);
// Don't overwrite values if this is the result of a UseInitial
if (result.contains(physical_longhand_id) && result.get(physical_longhand_id) != nullptr && is_use_initial)
return;
// Don't overwrite unless the value was originally set by a UseInitial or this property is preferred over the one that set it originally
if (result.contains(physical_longhand_id) && result.get(physical_longhand_id) != nullptr && !property_is_set_by_use_initial.get(physical_longhand_id_bitmap_index) && !is_property_preferred(property_id, longhands_set_by_property_id.get(physical_longhand_id).value()))
return;
longhands_set_by_property_id.set(physical_longhand_id, property_id);
property_is_set_by_use_initial.set(physical_longhand_id_bitmap_index, is_use_initial);
result.set(physical_longhand_id, { longhand_value.absolutized(viewport_rect(), font_metrics, m_root_element_font_metrics) });
});
}
return result;
};
HashMap<PropertyID, RefPtr<CSSStyleValue const>> computed_start_values = compute_keyframe_values(keyframe_values);
HashMap<PropertyID, RefPtr<CSSStyleValue const>> computed_end_values = compute_keyframe_values(keyframe_end_values);
for (auto const& it : computed_start_values) {
auto resolved_start_property = it.value;
RefPtr resolved_end_property = computed_end_values.get(it.key).value_or(nullptr);
if (!resolved_end_property) {
if (resolved_start_property) {
computed_properties.set_animated_property(it.key, *resolved_start_property);
dbgln_if(LIBWEB_CSS_ANIMATION_DEBUG, "No end property for property {}, using {}", string_from_property_id(it.key), resolved_start_property->to_string(SerializationMode::Normal));
}
continue;
}
if (resolved_end_property && !resolved_start_property)
resolved_start_property = property_initial_value(it.key);
if (!resolved_start_property || !resolved_end_property)
continue;
auto start = resolved_start_property.release_nonnull();
auto end = resolved_end_property.release_nonnull();
if (computed_properties.is_property_important(it.key)) {
continue;
}
if (auto next_value = interpolate_property(*effect->target(), it.key, *start, *end, progress_in_keyframe, AllowDiscrete::Yes)) {
dbgln_if(LIBWEB_CSS_ANIMATION_DEBUG, "Interpolated value for property {} at {}: {} -> {} = {}", string_from_property_id(it.key), progress_in_keyframe, start->to_string(SerializationMode::Normal), end->to_string(SerializationMode::Normal), next_value->to_string(SerializationMode::Normal));
computed_properties.set_animated_property(it.key, *next_value);
} else {
// If interpolate_property() fails, the element should not be rendered
dbgln_if(LIBWEB_CSS_ANIMATION_DEBUG, "Interpolated value for property {} at {}: {} -> {} is invalid", string_from_property_id(it.key), progress_in_keyframe, start->to_string(SerializationMode::Normal), end->to_string(SerializationMode::Normal));
computed_properties.set_animated_property(PropertyID::Visibility, CSSKeywordValue::create(Keyword::Hidden));
}
}
}
static void apply_animation_properties(DOM::Document& document, CascadedProperties& cascaded_properties, Animations::Animation& animation)
{
if (!animation.effect())
return;
auto& effect = as<Animations::KeyframeEffect>(*animation.effect());
Optional<CSS::Time> duration;
if (auto duration_value = cascaded_properties.property(PropertyID::AnimationDuration); duration_value) {
if (duration_value->is_time()) {
duration = duration_value->as_time().time();
} else if (duration_value->is_keyword() && duration_value->as_keyword().keyword() == Keyword::Auto) {
// We use empty optional to represent "auto".
duration = {};
}
}
CSS::Time delay { 0, CSS::Time::Type::S };
if (auto delay_value = cascaded_properties.property(PropertyID::AnimationDelay); delay_value && delay_value->is_time())
delay = delay_value->as_time().time();
double iteration_count = 1.0;
if (auto iteration_count_value = cascaded_properties.property(PropertyID::AnimationIterationCount); iteration_count_value) {
if (iteration_count_value->is_keyword() && iteration_count_value->to_keyword() == Keyword::Infinite)
iteration_count = HUGE_VAL;
else if (iteration_count_value->is_number())
iteration_count = iteration_count_value->as_number().number();
}
CSS::AnimationFillMode fill_mode { CSS::AnimationFillMode::None };
if (auto fill_mode_property = cascaded_properties.property(PropertyID::AnimationFillMode); fill_mode_property && fill_mode_property->is_keyword()) {
if (auto fill_mode_value = keyword_to_animation_fill_mode(fill_mode_property->to_keyword()); fill_mode_value.has_value())
fill_mode = *fill_mode_value;
}
CSS::AnimationDirection direction { CSS::AnimationDirection::Normal };
if (auto direction_property = cascaded_properties.property(PropertyID::AnimationDirection); direction_property && direction_property->is_keyword()) {
if (auto direction_value = keyword_to_animation_direction(direction_property->to_keyword()); direction_value.has_value())
direction = *direction_value;
}
CSS::AnimationPlayState play_state { CSS::AnimationPlayState::Running };
if (auto play_state_property = cascaded_properties.property(PropertyID::AnimationPlayState); play_state_property && play_state_property->is_keyword()) {
if (auto play_state_value = keyword_to_animation_play_state(play_state_property->to_keyword()); play_state_value.has_value())
play_state = *play_state_value;
}
CSS::EasingStyleValue::Function timing_function { CSS::EasingStyleValue::CubicBezier::ease() };
if (auto timing_property = cascaded_properties.property(PropertyID::AnimationTimingFunction); timing_property && timing_property->is_easing())
timing_function = timing_property->as_easing().function();
auto iteration_duration = duration.has_value()
? Variant<double, String> { duration.release_value().to_milliseconds() }
: "auto"_string;
effect.set_iteration_duration(iteration_duration);
effect.set_start_delay(delay.to_milliseconds());
effect.set_iteration_count(iteration_count);
effect.set_timing_function(move(timing_function));
effect.set_fill_mode(Animations::css_fill_mode_to_bindings_fill_mode(fill_mode));
effect.set_playback_direction(Animations::css_animation_direction_to_bindings_playback_direction(direction));
if (play_state != effect.last_css_animation_play_state()) {
if (play_state == CSS::AnimationPlayState::Running && animation.play_state() != Bindings::AnimationPlayState::Running) {
HTML::TemporaryExecutionContext context(document.realm());
animation.play().release_value_but_fixme_should_propagate_errors();
} else if (play_state == CSS::AnimationPlayState::Paused && animation.play_state() != Bindings::AnimationPlayState::Paused) {
HTML::TemporaryExecutionContext context(document.realm());
animation.pause().release_value_but_fixme_should_propagate_errors();
}
effect.set_last_css_animation_play_state(play_state);
}
}
static void apply_dimension_attribute(CascadedProperties& cascaded_properties, DOM::Element const& element, FlyString const& attribute_name, CSS::PropertyID property_id)
{
auto attribute = element.attribute(attribute_name);
if (!attribute.has_value())
return;
auto parsed_value = HTML::parse_dimension_value(*attribute);
if (!parsed_value)
return;
cascaded_properties.set_property_from_presentational_hint(property_id, parsed_value.release_nonnull());
}
static void compute_transitioned_properties(ComputedProperties const& style, DOM::Element& element, Optional<PseudoElement> pseudo_element)
{
auto const source_declaration = style.transition_property_source();
if (!source_declaration)
return;
if (!element.computed_properties())
return;
if (source_declaration == element.cached_transition_property_source(pseudo_element))
return;
// Reparse this transition property
element.clear_transitions(pseudo_element);
element.set_cached_transition_property_source(pseudo_element, *source_declaration);
auto const& transition_properties_value = style.property(PropertyID::TransitionProperty);
auto transition_properties = transition_properties_value.is_value_list()
? transition_properties_value.as_value_list().values()
: StyleValueVector { transition_properties_value };
Vector<Vector<PropertyID>> properties;
for (size_t i = 0; i < transition_properties.size(); i++) {
auto property_value = transition_properties[i];
Vector<PropertyID> properties_for_this_transition;
if (property_value->is_keyword()) {
auto keyword = property_value->as_keyword().keyword();
if (keyword == Keyword::None)
continue;
if (keyword == Keyword::All) {
for (auto prop = first_property_id; prop != last_property_id; prop = static_cast<PropertyID>(to_underlying(prop) + 1))
properties_for_this_transition.append(prop);
}
} else {
auto maybe_property = property_id_from_string(property_value->as_custom_ident().custom_ident());
if (!maybe_property.has_value())
continue;
auto transition_property = maybe_property.release_value();
if (property_is_shorthand(transition_property)) {
for (auto const& prop : longhands_for_shorthand(transition_property))
properties_for_this_transition.append(prop);
} else {
properties_for_this_transition.append(transition_property);
}
}
properties.append(move(properties_for_this_transition));
}
auto normalize_transition_length_list = [&properties, &style](PropertyID property, auto make_default_value) {
auto const* style_value = style.maybe_null_property(property);
StyleValueVector list;
if (style_value && !style_value->is_value_list()) {
for (size_t i = 0; i < properties.size(); i++)
list.append(*style_value);
return list;
}
if (!style_value || !style_value->is_value_list() || style_value->as_value_list().size() == 0) {
auto default_value = make_default_value();
for (size_t i = 0; i < properties.size(); i++)
list.append(default_value);
return list;
}
auto const& value_list = style_value->as_value_list();
for (size_t i = 0; i < properties.size(); i++)
list.append(value_list.value_at(i, true));
return list;
};
auto delays = normalize_transition_length_list(
PropertyID::TransitionDelay,
[] { return TimeStyleValue::create(Time::make_seconds(0.0)); });
auto durations = normalize_transition_length_list(
PropertyID::TransitionDuration,
[] { return TimeStyleValue::create(Time::make_seconds(0.0)); });
auto timing_functions = normalize_transition_length_list(
PropertyID::TransitionTimingFunction,
[] { return EasingStyleValue::create(EasingStyleValue::CubicBezier::ease()); });
auto transition_behaviors = normalize_transition_length_list(
PropertyID::TransitionBehavior,
[] { return CSSKeywordValue::create(Keyword::None); });
element.add_transitioned_properties(pseudo_element, move(properties), move(delays), move(durations), move(timing_functions), move(transition_behaviors));
}
// https://drafts.csswg.org/css-transitions/#starting
void StyleComputer::start_needed_transitions(ComputedProperties const& previous_style, ComputedProperties& new_style, DOM::Element& element, Optional<PseudoElement> pseudo_element) const
{
// https://drafts.csswg.org/css-transitions/#transition-combined-duration
auto combined_duration = [](Animations::Animatable::TransitionAttributes const& transition_attributes) {
// Define the combined duration of the transition as the sum of max(matching transition duration, 0s) and the matching transition delay.
return max(transition_attributes.duration, 0) + transition_attributes.delay;
};
// For each element and property, the implementation must act as follows:
auto style_change_event_time = m_document->timeline()->current_time().value();
for (auto i = to_underlying(CSS::first_longhand_property_id); i <= to_underlying(CSS::last_longhand_property_id); ++i) {
auto property_id = static_cast<CSS::PropertyID>(i);
auto matching_transition_properties = element.property_transition_attributes(pseudo_element, property_id);
auto const& before_change_value = previous_style.property(property_id, ComputedProperties::WithAnimationsApplied::Yes);
auto const& after_change_value = new_style.property(property_id, ComputedProperties::WithAnimationsApplied::No);
auto existing_transition = element.property_transition(pseudo_element, property_id);
bool has_running_transition = existing_transition && !existing_transition->is_finished();
bool has_completed_transition = existing_transition && existing_transition->is_finished();
auto start_a_transition = [&](auto start_time, auto end_time, auto const& start_value, auto const& end_value, auto const& reversing_adjusted_start_value, auto reversing_shortening_factor) {
dbgln_if(CSS_TRANSITIONS_DEBUG, "Starting a transition of {} from {} to {}", string_from_property_id(property_id), start_value->to_string(), end_value->to_string());
auto transition = CSSTransition::start_a_transition(element, pseudo_element, property_id,
document().transition_generation(), start_time, end_time, start_value, end_value, reversing_adjusted_start_value, reversing_shortening_factor);
// Immediately set the property's value to the transition's current value, to prevent single-frame jumps.
collect_animation_into(element, {}, as<Animations::KeyframeEffect>(*transition->effect()), new_style, AnimationRefresh::No);
};
// 1. If all of the following are true:
if (
// - the element does not have a running transition for the property,
(!has_running_transition) &&
// - there is a matching transition-property value, and
(matching_transition_properties.has_value()) &&
// - the before-change style is different from the after-change style for that property, and the values for the property are transitionable,
(!before_change_value.equals(after_change_value) && property_values_are_transitionable(property_id, before_change_value, after_change_value, element, matching_transition_properties->transition_behavior)) &&
// - the element does not have a completed transition for the property
// or the end value of the completed transition is different from the after-change style for the property,
(!has_completed_transition || !existing_transition->transition_end_value()->equals(after_change_value)) &&
// - the combined duration is greater than 0s,
(combined_duration(matching_transition_properties.value()) > 0)) {
dbgln_if(CSS_TRANSITIONS_DEBUG, "Transition step 1.");
// then implementations must remove the completed transition (if present) from the set of completed transitions
if (has_completed_transition)
element.remove_transition(pseudo_element, property_id);
// and start a transition whose:
// - start time is the time of the style change event plus the matching transition delay,
auto start_time = style_change_event_time + matching_transition_properties->delay;
// - end time is the start time plus the matching transition duration,
auto end_time = start_time + matching_transition_properties->duration;
// - start value is the value of the transitioning property in the before-change style,
auto const& start_value = before_change_value;
// - end value is the value of the transitioning property in the after-change style,
auto const& end_value = after_change_value;
// - reversing-adjusted start value is the same as the start value, and
auto const& reversing_adjusted_start_value = start_value;
// - reversing shortening factor is 1.
double reversing_shortening_factor = 1;
start_a_transition(start_time, end_time, start_value, end_value, reversing_adjusted_start_value, reversing_shortening_factor);
}
// 2. Otherwise, if the element has a completed transition for the property
// and the end value of the completed transition is different from the after-change style for the property,
// then implementations must remove the completed transition from the set of completed transitions.
else if (has_completed_transition && !existing_transition->transition_end_value()->equals(after_change_value)) {
dbgln_if(CSS_TRANSITIONS_DEBUG, "Transition step 2.");
element.remove_transition(pseudo_element, property_id);
}
// 3. If the element has a running transition or completed transition for the property,
// and there is not a matching transition-property value,
if (existing_transition && !matching_transition_properties.has_value()) {
// then implementations must cancel the running transition or remove the completed transition from the set of completed transitions.
dbgln_if(CSS_TRANSITIONS_DEBUG, "Transition step 3.");
if (has_running_transition)
existing_transition->cancel();
else
element.remove_transition(pseudo_element, property_id);
}
// 4. If the element has a running transition for the property,
// there is a matching transition-property value,
// and the end value of the running transition is not equal to the value of the property in the after-change style, then:
if (has_running_transition && matching_transition_properties.has_value() && !existing_transition->transition_end_value()->equals(after_change_value)) {
dbgln_if(CSS_TRANSITIONS_DEBUG, "Transition step 4. existing end value = {}, after change value = {}", existing_transition->transition_end_value()->to_string(SerializationMode::Normal), after_change_value.to_string(SerializationMode::Normal));
// 1. If the current value of the property in the running transition is equal to the value of the property in the after-change style,
// or if these two values are not transitionable,
// then implementations must cancel the running transition.
auto& current_value = new_style.property(property_id, ComputedProperties::WithAnimationsApplied::Yes);
if (current_value.equals(after_change_value) || !property_values_are_transitionable(property_id, current_value, after_change_value, element, matching_transition_properties->transition_behavior)) {
dbgln_if(CSS_TRANSITIONS_DEBUG, "Transition step 4.1");
existing_transition->cancel();
}
// 2. Otherwise, if the combined duration is less than or equal to 0s,
// or if the current value of the property in the running transition is not transitionable with the value of the property in the after-change style,
// then implementations must cancel the running transition.
else if ((combined_duration(matching_transition_properties.value()) <= 0)
|| !property_values_are_transitionable(property_id, current_value, after_change_value, element, matching_transition_properties->transition_behavior)) {
dbgln_if(CSS_TRANSITIONS_DEBUG, "Transition step 4.2");
existing_transition->cancel();
}
// 3. Otherwise, if the reversing-adjusted start value of the running transition is the same as the value of the property in the after-change style
// (see the section on reversing of transitions for why these case exists),
else if (existing_transition->reversing_adjusted_start_value()->equals(after_change_value)) {
dbgln_if(CSS_TRANSITIONS_DEBUG, "Transition step 4.3");
// implementations must cancel the running transition and start a new transition whose:
existing_transition->cancel();
// AD-HOC: Remove the cancelled transition, otherwise it breaks the invariant that there is only one
// running or completed transition for a property at once.
element.remove_transition(pseudo_element, property_id);
// - reversing-adjusted start value is the end value of the running transition,
auto reversing_adjusted_start_value = existing_transition->transition_end_value();
// - reversing shortening factor is the absolute value, clamped to the range [0, 1], of the sum of:
// 1. the output of the timing function of the old transition at the time of the style change event,
// times the reversing shortening factor of the old transition
auto term_1 = existing_transition->timing_function_output_at_time(style_change_event_time) * existing_transition->reversing_shortening_factor();
// 2. 1 minus the reversing shortening factor of the old transition.
auto term_2 = 1 - existing_transition->reversing_shortening_factor();
double reversing_shortening_factor = clamp(abs(term_1 + term_2), 0.0, 1.0);
// - start time is the time of the style change event plus:
// 1. if the matching transition delay is nonnegative, the matching transition delay, or
// 2. if the matching transition delay is negative, the product of the new transition’s reversing shortening factor and the matching transition delay,
auto start_time = style_change_event_time
+ (matching_transition_properties->delay >= 0
? (matching_transition_properties->delay)
: (reversing_shortening_factor * matching_transition_properties->delay));
// - end time is the start time plus the product of the matching transition duration and the new transition’s reversing shortening factor,
auto end_time = start_time + (matching_transition_properties->duration * reversing_shortening_factor);
// - start value is the current value of the property in the running transition,
auto const& start_value = current_value;
// - end value is the value of the property in the after-change style,
auto const& end_value = after_change_value;
start_a_transition(start_time, end_time, start_value, end_value, reversing_adjusted_start_value, reversing_shortening_factor);
}
// 4. Otherwise,
else {
dbgln_if(CSS_TRANSITIONS_DEBUG, "Transition step 4.4");
// implementations must cancel the running transition and start a new transition whose:
existing_transition->cancel();
// AD-HOC: Remove the cancelled transition, otherwise it breaks the invariant that there is only one
// running or completed transition for a property at once.
element.remove_transition(pseudo_element, property_id);
// - start time is the time of the style change event plus the matching transition delay,
auto start_time = style_change_event_time + matching_transition_properties->delay;
// - end time is the start time plus the matching transition duration,
auto end_time = start_time + matching_transition_properties->duration;
// - start value is the current value of the property in the running transition,
auto const& start_value = current_value;
// - end value is the value of the property in the after-change style,
auto const& end_value = after_change_value;
// - reversing-adjusted start value is the same as the start value, and
auto const& reversing_adjusted_start_value = start_value;
// - reversing shortening factor is 1.
double reversing_shortening_factor = 1;
start_a_transition(start_time, end_time, start_value, end_value, reversing_adjusted_start_value, reversing_shortening_factor);
}
}
}
}
// https://www.w3.org/TR/css-cascade/#cascading
// https://drafts.csswg.org/css-cascade-5/#layering
GC::Ref<CascadedProperties> StyleComputer::compute_cascaded_values(DOM::Element& element, Optional<CSS::PseudoElement> pseudo_element, bool& did_match_any_pseudo_element_rules, PseudoClassBitmap& attempted_pseudo_class_matches, ComputeStyleMode mode, Optional<LogicalAliasMappingContext> logical_alias_mapping_context) const
{
auto cascaded_properties = m_document->heap().allocate<CascadedProperties>();
// First, we collect all the CSS rules whose selectors match `element`:
MatchingRuleSet matching_rule_set;
matching_rule_set.user_agent_rules = collect_matching_rules(element, CascadeOrigin::UserAgent, pseudo_element, attempted_pseudo_class_matches);
sort_matching_rules(matching_rule_set.user_agent_rules);
matching_rule_set.user_rules = collect_matching_rules(element, CascadeOrigin::User, pseudo_element, attempted_pseudo_class_matches);
sort_matching_rules(matching_rule_set.user_rules);
// @layer-ed author rules
for (auto const& layer_name : m_qualified_layer_names_in_order) {
auto layer_rules = collect_matching_rules(element, CascadeOrigin::Author, pseudo_element, attempted_pseudo_class_matches, layer_name);
sort_matching_rules(layer_rules);
matching_rule_set.author_rules.append({ layer_name, layer_rules });
}
// Un-@layer-ed author rules
auto unlayered_author_rules = collect_matching_rules(element, CascadeOrigin::Author, pseudo_element, attempted_pseudo_class_matches);
sort_matching_rules(unlayered_author_rules);
matching_rule_set.author_rules.append({ {}, unlayered_author_rules });
if (mode == ComputeStyleMode::CreatePseudoElementStyleIfNeeded) {
VERIFY(pseudo_element.has_value());
if (matching_rule_set.author_rules.is_empty() && matching_rule_set.user_rules.is_empty() && matching_rule_set.user_agent_rules.is_empty()) {
did_match_any_pseudo_element_rules = false;
return cascaded_properties;
}
did_match_any_pseudo_element_rules = true;
}
// Then we resolve all the CSS custom properties ("variables") for this element:
// FIXME: Also resolve !important custom properties, in a second cascade.
if (!pseudo_element.has_value() || pseudo_element_supports_property(*pseudo_element, PropertyID::Custom)) {
HashMap<FlyString, CSS::StyleProperty> custom_properties;
for (auto& layer : matching_rule_set.author_rules) {
cascade_custom_properties(element, pseudo_element, layer.rules, custom_properties);
}
element.set_custom_properties(pseudo_element, move(custom_properties));
}
// Then we apply the declarations from the matched rules in cascade order:
// Normal user agent declarations
cascade_declarations(*cascaded_properties, element, pseudo_element, matching_rule_set.user_agent_rules, CascadeOrigin::UserAgent, Important::No, {}, logical_alias_mapping_context);
// Normal user declarations
cascade_declarations(*cascaded_properties, element, pseudo_element, matching_rule_set.user_rules, CascadeOrigin::User, Important::No, {}, logical_alias_mapping_context);
// Author presentational hints
// The spec calls this a special "Author presentational hint origin":
// "For the purpose of cascading this author presentational hint origin is treated as an independent origin;
// however for the purpose of the revert keyword (but not for the revert-layer keyword) it is considered
// part of the author origin."
// https://drafts.csswg.org/css-cascade-5/#author-presentational-hint-origin
if (!pseudo_element.has_value()) {
element.apply_presentational_hints(cascaded_properties);
if (element.supports_dimension_attributes()) {
apply_dimension_attribute(cascaded_properties, element, HTML::AttributeNames::width, CSS::PropertyID::Width);
apply_dimension_attribute(cascaded_properties, element, HTML::AttributeNames::height, CSS::PropertyID::Height);
}
// SVG presentation attributes are parsed as CSS values, so we need to handle potential custom properties here.
if (element.is_svg_element()) {
cascaded_properties->resolve_unresolved_properties(element, pseudo_element);
}
}
// Normal author declarations, ordered by @layer, with un-@layer-ed rules last
for (auto const& layer : matching_rule_set.author_rules) {
cascade_declarations(cascaded_properties, element, pseudo_element, layer.rules, CascadeOrigin::Author, Important::No, layer.qualified_layer_name, logical_alias_mapping_context);
}
// Important author declarations, with un-@layer-ed rules first, followed by each @layer in reverse order.
for (auto const& layer : matching_rule_set.author_rules.in_reverse()) {
cascade_declarations(cascaded_properties, element, pseudo_element, layer.rules, CascadeOrigin::Author, Important::Yes, {}, logical_alias_mapping_context);
}
// Important user declarations
cascade_declarations(cascaded_properties, element, pseudo_element, matching_rule_set.user_rules, CascadeOrigin::User, Important::Yes, {}, logical_alias_mapping_context);
// Important user agent declarations
cascade_declarations(cascaded_properties, element, pseudo_element, matching_rule_set.user_agent_rules, CascadeOrigin::UserAgent, Important::Yes, {}, logical_alias_mapping_context);
// Transition declarations [css-transitions-1]
// Note that we have to do these after finishing computing the style,
// so they're not done here, but as the final step in compute_properties()
return cascaded_properties;
}
DOM::Element const* element_to_inherit_style_from(DOM::Element const* element, Optional<CSS::PseudoElement> pseudo_element)
{
// Pseudo-elements treat their originating element as their parent.
DOM::Element const* parent_element = nullptr;
if (pseudo_element.has_value()) {
parent_element = element;
} else if (element) {
parent_element = element->parent_or_shadow_host_element();
}
return parent_element;
}
NonnullRefPtr<CSSStyleValue const> StyleComputer::get_inherit_value(CSS::PropertyID property_id, DOM::Element const* element, Optional<CSS::PseudoElement> pseudo_element)
{
auto* parent_element = element_to_inherit_style_from(element, pseudo_element);
if (!parent_element || !parent_element->computed_properties())
return property_initial_value(property_id);
return parent_element->computed_properties()->property(property_id);
}
void StyleComputer::compute_defaulted_property_value(ComputedProperties& style, DOM::Element const* element, CSS::PropertyID property_id, Optional<CSS::PseudoElement> pseudo_element) const
{
auto& value_slot = style.m_property_values[to_underlying(property_id)];
if (!value_slot) {
if (is_inherited_property(property_id)) {
style.set_property(
property_id,
get_inherit_value(property_id, element, pseudo_element),
ComputedProperties::Inherited::Yes,
Important::No);
} else {
style.set_property(property_id, property_initial_value(property_id));
}
return;
}
if (value_slot->is_initial()) {
value_slot = property_initial_value(property_id);
return;
}
if (value_slot->is_inherit()) {
value_slot = get_inherit_value(property_id, element, pseudo_element);
style.set_property_inherited(property_id, ComputedProperties::Inherited::Yes);
return;
}
// https://www.w3.org/TR/css-cascade-4/#inherit-initial
// If the cascaded value of a property is the unset keyword,
if (value_slot->is_unset()) {
if (is_inherited_property(property_id)) {
// then if it is an inherited property, this is treated as inherit,
value_slot = get_inherit_value(property_id, element, pseudo_element);
style.set_property_inherited(property_id, ComputedProperties::Inherited::Yes);
} else {
// and if it is not, this is treated as initial.
value_slot = property_initial_value(property_id);
}
}
}
// https://www.w3.org/TR/css-cascade/#defaulting
void StyleComputer::compute_defaulted_values(ComputedProperties& style, DOM::Element const* element, Optional<CSS::PseudoElement> pseudo_element) const
{
// Walk the list of all known CSS properties and:
// - Add them to `style` if they are missing.
// - Resolve `inherit` and `initial` as needed.
for (auto i = to_underlying(CSS::first_longhand_property_id); i <= to_underlying(CSS::last_longhand_property_id); ++i) {
auto property_id = (CSS::PropertyID)i;
compute_defaulted_property_value(style, element, property_id, pseudo_element);
}
// https://www.w3.org/TR/css-color-4/#resolving-other-colors
// In the color property, the used value of currentcolor is the inherited value.
auto const& color = style.property(CSS::PropertyID::Color);
if (color.to_keyword() == Keyword::Currentcolor) {
auto const& inherited_value = get_inherit_value(CSS::PropertyID::Color, element, pseudo_element);
style.set_property(CSS::PropertyID::Color, inherited_value);
}
// AD-HOC: The -libweb-inherit-or-center style defaults to centering, unless a style value usually would have been
// inherited. This is used to support the ad-hoc default <th> text-align behavior.
if (element && element->local_name() == HTML::TagNames::th
&& style.property(PropertyID::TextAlign).to_keyword() == Keyword::LibwebInheritOrCenter) {
auto const* parent_element = element;
while ((parent_element = element_to_inherit_style_from(parent_element, {}))) {
auto parent_computed = parent_element->computed_properties();
auto parent_cascaded = parent_element->cascaded_properties({});
if (!parent_computed || !parent_cascaded)
break;
if (parent_cascaded->property(PropertyID::TextAlign)) {
auto const& style_value = parent_computed->property(PropertyID::TextAlign);
style.set_property(PropertyID::TextAlign, style_value, ComputedProperties::Inherited::Yes);
break;
}
}
}
}
Length::FontMetrics StyleComputer::calculate_root_element_font_metrics(ComputedProperties const& style) const
{
auto const& root_value = style.property(CSS::PropertyID::FontSize);
auto font_pixel_metrics = style.first_available_computed_font().pixel_metrics();
Length::FontMetrics font_metrics { m_default_font_metrics.font_size, font_pixel_metrics };
font_metrics.font_size = root_value.as_length().length().to_px(viewport_rect(), font_metrics, font_metrics);
font_metrics.line_height = style.compute_line_height(viewport_rect(), font_metrics, font_metrics);
return font_metrics;
}
RefPtr<Gfx::FontCascadeList const> StyleComputer::find_matching_font_weight_ascending(Vector<MatchingFontCandidate> const& candidates, int target_weight, float font_size_in_pt, bool inclusive)
{
using Fn = AK::Function<bool(MatchingFontCandidate const&)>;
auto pred = inclusive ? Fn([&](auto const& matching_font_candidate) { return matching_font_candidate.key.weight >= target_weight; })
: Fn([&](auto const& matching_font_candidate) { return matching_font_candidate.key.weight > target_weight; });
auto it = find_if(candidates.begin(), candidates.end(), pred);
for (; it != candidates.end(); ++it) {
if (auto found_font = it->font_with_point_size(font_size_in_pt))
return found_font;
}
return {};
}
RefPtr<Gfx::FontCascadeList const> StyleComputer::find_matching_font_weight_descending(Vector<MatchingFontCandidate> const& candidates, int target_weight, float font_size_in_pt, bool inclusive)
{
using Fn = AK::Function<bool(MatchingFontCandidate const&)>;
auto pred = inclusive ? Fn([&](auto const& matching_font_candidate) { return matching_font_candidate.key.weight <= target_weight; })
: Fn([&](auto const& matching_font_candidate) { return matching_font_candidate.key.weight < target_weight; });
auto it = find_if(candidates.rbegin(), candidates.rend(), pred);
for (; it != candidates.rend(); ++it) {
if (auto found_font = it->font_with_point_size(font_size_in_pt))
return found_font;
}
return {};
}
// Partial implementation of the font-matching algorithm: https://www.w3.org/TR/css-fonts-4/#font-matching-algorithm
// FIXME: This should be replaced by the full CSS font selection algorithm.
RefPtr<Gfx::FontCascadeList const> StyleComputer::font_matching_algorithm(FlyString const& family_name, int weight, int slope, float font_size_in_pt) const
{
// If a font family match occurs, the user agent assembles the set of font faces in that family and then
// narrows the set to a single face using other font properties in the order given below.
Vector<MatchingFontCandidate> matching_family_fonts;
for (auto const& font_key_and_loader : m_loaded_fonts) {
if (font_key_and_loader.key.family_name.equals_ignoring_ascii_case(family_name))
matching_family_fonts.empend(font_key_and_loader.key, const_cast<FontLoaderList*>(&font_key_and_loader.value));
}
Gfx::FontDatabase::the().for_each_typeface_with_family_name(family_name, [&](Gfx::Typeface const& typeface) {
matching_family_fonts.empend(
FontFaceKey {
.family_name = typeface.family(),
.weight = static_cast<int>(typeface.weight()),
.slope = typeface.slope(),
},
&typeface);
});
quick_sort(matching_family_fonts, [](auto const& a, auto const& b) {
return a.key.weight < b.key.weight;
});
// FIXME: 1. font-stretch is tried first.
// FIXME: 2. font-style is tried next.
// We don't have complete support of italic and oblique fonts, so matching on font-style can be simplified to:
// If a matching slope is found, all faces which don't have that matching slope are excluded from the matching set.
auto style_it = find_if(matching_family_fonts.begin(), matching_family_fonts.end(),
[&](auto const& matching_font_candidate) { return matching_font_candidate.key.slope == slope; });
if (style_it != matching_family_fonts.end()) {
matching_family_fonts.remove_all_matching([&](auto const& matching_font_candidate) {
return matching_font_candidate.key.slope != slope;
});
}
// 3. font-weight is matched next.
// If the desired weight is inclusively between 400 and 500, weights greater than or equal to the target weight
// are checked in ascending order until 500 is hit and checked, followed by weights less than the target weight
// in descending order, followed by weights greater than 500, until a match is found.
if (weight >= 400 && weight <= 500) {
auto it = find_if(matching_family_fonts.begin(), matching_family_fonts.end(),
[&](auto const& matching_font_candidate) { return matching_font_candidate.key.weight >= weight; });
for (; it != matching_family_fonts.end() && it->key.weight <= 500; ++it) {
if (auto found_font = it->font_with_point_size(font_size_in_pt))
return found_font;
}
if (auto found_font = find_matching_font_weight_descending(matching_family_fonts, weight, font_size_in_pt, false))
return found_font;
for (; it != matching_family_fonts.end(); ++it) {
if (auto found_font = it->font_with_point_size(font_size_in_pt))
return found_font;
}
}
// If the desired weight is less than 400, weights less than or equal to the desired weight are checked in descending order
// followed by weights above the desired weight in ascending order until a match is found.
if (weight < 400) {
if (auto found_font = find_matching_font_weight_descending(matching_family_fonts, weight, font_size_in_pt, true))
return found_font;
if (auto found_font = find_matching_font_weight_ascending(matching_family_fonts, weight, font_size_in_pt, false))
return found_font;
}
// If the desired weight is greater than 500, weights greater than or equal to the desired weight are checked in ascending order
// followed by weights below the desired weight in descending order until a match is found.
if (weight > 500) {
if (auto found_font = find_matching_font_weight_ascending(matching_family_fonts, weight, font_size_in_pt, true))
return found_font;
if (auto found_font = find_matching_font_weight_descending(matching_family_fonts, weight, font_size_in_pt, false))
return found_font;
}
return {};
}
CSSPixels StyleComputer::default_user_font_size()
{
// FIXME: This value should be configurable by the user.
return 16;
}
// https://w3c.github.io/csswg-drafts/css-fonts/#absolute-size-mapping
CSSPixelFraction StyleComputer::absolute_size_mapping(Keyword keyword)
{
switch (keyword) {
case Keyword::XxSmall:
return CSSPixels(3) / 5;
case Keyword::XSmall:
return CSSPixels(3) / 4;
case Keyword::Small:
return CSSPixels(8) / 9;
case Keyword::Medium:
return 1;
case Keyword::Large:
return CSSPixels(6) / 5;
case Keyword::XLarge:
return CSSPixels(3) / 2;
case Keyword::XxLarge:
return 2;
case Keyword::XxxLarge:
return 3;
case Keyword::Smaller:
return CSSPixels(4) / 5;
case Keyword::Larger:
return CSSPixels(5) / 4;
default:
return 1;
}
}
RefPtr<Gfx::FontCascadeList const> StyleComputer::compute_font_for_style_values(DOM::Element const* element, Optional<CSS::PseudoElement> pseudo_element, CSSStyleValue const& font_family, CSSStyleValue const& font_size, CSSStyleValue const& font_style, CSSStyleValue const& font_weight, CSSStyleValue const& font_stretch, int math_depth) const
{
auto* parent_element = element_to_inherit_style_from(element, pseudo_element);
auto width = font_stretch.to_font_width();
auto weight = font_weight.to_font_weight();
auto font_size_in_px = default_user_font_size();
Gfx::FontPixelMetrics font_pixel_metrics;
if (parent_element && parent_element->computed_properties())
font_pixel_metrics = parent_element->computed_properties()->first_available_computed_font().pixel_metrics();
else
font_pixel_metrics = Platform::FontPlugin::the().default_font(font_size_in_px.to_float())->pixel_metrics();
auto parent_font_size = [&]() -> CSSPixels {
if (!parent_element || !parent_element->computed_properties())
return font_size_in_px;
auto const& value = parent_element->computed_properties()->property(CSS::PropertyID::FontSize);
if (value.is_length()) {
auto length = value.as_length().length();
if (length.is_absolute() || length.is_relative()) {
Length::FontMetrics font_metrics { font_size_in_px, font_pixel_metrics };
return length.to_px(viewport_rect(), font_metrics, root_element_font_metrics_for_element(element));
}
}
return font_size_in_px;
}();
if (font_size.is_keyword()) {
auto const keyword = font_size.to_keyword();
if (keyword == Keyword::Math) {
auto math_scaling_factor = [&]() {
// https://w3c.github.io/mathml-core/#the-math-script-level-property
// If the specified value font-size is math then the computed value of font-size is obtained by multiplying
// the inherited value of font-size by a nonzero scale factor calculated by the following procedure:
// 1. Let A be the inherited math-depth value, B the computed math-depth value, C be 0.71 and S be 1.0
int inherited_math_depth = parent_element && parent_element->computed_properties()
? parent_element->computed_properties()->math_depth()
: InitialValues::math_depth();
int computed_math_depth = math_depth;
auto size_ratio = 0.71;
auto scale = 1.0;
// 2. If A = B then return S.
bool invert_scale_factor = false;
if (inherited_math_depth == computed_math_depth) {
return scale;
}
// If B < A, swap A and B and set InvertScaleFactor to true.
else if (computed_math_depth < inherited_math_depth) {
AK::swap(inherited_math_depth, computed_math_depth);
invert_scale_factor = true;
}
// Otherwise B > A and set InvertScaleFactor to false.
else {
invert_scale_factor = false;
}
// 3. Let E be B - A > 0.
double e = (computed_math_depth - inherited_math_depth) > 0;
// FIXME: 4. If the inherited first available font has an OpenType MATH table:
// - If A ≤ 0 and B ≥ 2 then multiply S by scriptScriptPercentScaleDown and decrement E by 2.
// - Otherwise if A = 1 then multiply S by scriptScriptPercentScaleDown / scriptPercentScaleDown and decrement E by 1.
// - Otherwise if B = 1 then multiply S by scriptPercentScaleDown and decrement E by 1.
// 5. Multiply S by C^E.
scale *= AK::pow(size_ratio, e);
// 6. Return S if InvertScaleFactor is false and 1/S otherwise.
if (!invert_scale_factor)
return scale;
return 1.0 / scale;
};
font_size_in_px = parent_font_size.scale_by(math_scaling_factor());
} else {
// https://w3c.github.io/csswg-drafts/css-fonts/#valdef-font-size-relative-size
// TODO: If the parent element has a keyword font size in the absolute size keyword mapping table,
// larger may compute the font size to the next entry in the table,
// and smaller may compute the font size to the previous entry in the table.
if (keyword == Keyword::Smaller || keyword == Keyword::Larger) {
if (parent_element && parent_element->computed_properties()) {
font_size_in_px = CSSPixels::nearest_value_for(parent_element->computed_properties()->first_available_computed_font().pixel_metrics().size);
}
}
font_size_in_px *= absolute_size_mapping(keyword);
}
} else {
Length::ResolutionContext const length_resolution_context {
.viewport_rect = viewport_rect(),
.font_metrics = Length::FontMetrics { parent_font_size, font_pixel_metrics },
.root_font_metrics = root_element_font_metrics_for_element(element),
};
Optional<Length> maybe_length;
if (font_size.is_percentage()) {
// Percentages refer to parent element's font size
maybe_length = Length::make_px(CSSPixels::nearest_value_for(font_size.as_percentage().percentage().as_fraction() * parent_font_size.to_double()));
} else if (font_size.is_length()) {
maybe_length = font_size.as_length().length();
} else if (font_size.is_calculated()) {
maybe_length = font_size.as_calculated().resolve_length_deprecated({
.percentage_basis = Length::make_px(parent_font_size),
.length_resolution_context = length_resolution_context,
});
}
if (maybe_length.has_value()) {
font_size_in_px = maybe_length.value().to_px(length_resolution_context);
}
}
auto slope = font_style.to_font_slope();
// FIXME: Implement the full font-matching algorithm: https://www.w3.org/TR/css-fonts-4/#font-matching-algorithm
float const font_size_in_pt = font_size_in_px * 0.75f;
auto find_font = [&](FlyString const& family) -> RefPtr<Gfx::FontCascadeList const> {
FontFaceKey key {
.family_name = family,
.weight = weight,
.slope = slope,
};
auto result = Gfx::FontCascadeList::create();
if (auto it = m_loaded_fonts.find(key); it != m_loaded_fonts.end()) {
auto const& loaders = it->value;
for (auto const& loader : loaders) {
if (auto found_font = loader->font_with_point_size(font_size_in_pt))
result->add(*found_font, loader->unicode_ranges());
}
return result;
}
if (auto found_font = font_matching_algorithm(family, weight, slope, font_size_in_pt); found_font && !found_font->is_empty()) {
return found_font;
}
if (auto found_font = Gfx::FontDatabase::the().get(family, font_size_in_pt, weight, width, slope)) {
result->add(*found_font);
return result;
}
return {};
};
auto find_generic_font = [&](Keyword font_id) -> RefPtr<Gfx::FontCascadeList const> {
Platform::GenericFont generic_font {};
switch (font_id) {
case Keyword::Monospace:
case Keyword::UiMonospace:
generic_font = Platform::GenericFont::Monospace;
break;
case Keyword::Serif:
generic_font = Platform::GenericFont::Serif;
break;
case Keyword::Fantasy:
generic_font = Platform::GenericFont::Fantasy;
break;
case Keyword::SansSerif:
generic_font = Platform::GenericFont::SansSerif;
break;
case Keyword::Cursive:
generic_font = Platform::GenericFont::Cursive;
break;
case Keyword::UiSerif:
generic_font = Platform::GenericFont::UiSerif;
break;
case Keyword::UiSansSerif:
generic_font = Platform::GenericFont::UiSansSerif;
break;
case Keyword::UiRounded:
generic_font = Platform::GenericFont::UiRounded;
break;
default:
return {};
}
return find_font(Platform::FontPlugin::the().generic_font_name(generic_font));
};
auto font_list = Gfx::FontCascadeList::create();
if (font_family.is_value_list()) {
auto const& family_list = static_cast<StyleValueList const&>(font_family).values();
for (auto const& family : family_list) {
RefPtr<Gfx::FontCascadeList const> other_font_list;
if (family->is_keyword()) {
other_font_list = find_generic_font(family->to_keyword());
} else if (family->is_string()) {
other_font_list = find_font(family->as_string().string_value());
} else if (family->is_custom_ident()) {
other_font_list = find_font(family->as_custom_ident().custom_ident());
}
if (other_font_list)
font_list->extend(*other_font_list);
}
} else if (font_family.is_keyword()) {
if (auto other_font_list = find_generic_font(font_family.to_keyword()))
font_list->extend(*other_font_list);
} else if (font_family.is_string()) {
if (auto other_font_list = find_font(font_family.as_string().string_value()))
font_list->extend(*other_font_list);
} else if (font_family.is_custom_ident()) {
if (auto other_font_list = find_font(font_family.as_custom_ident().custom_ident()))
font_list->extend(*other_font_list);
}
auto default_font = Platform::FontPlugin::the().default_font(font_size_in_pt);
if (font_list->is_empty()) {
// This is needed to make sure we check default font before reaching to emojis.
font_list->add(*default_font);
}
if (auto emoji_font = Platform::FontPlugin::the().default_emoji_font(font_size_in_pt); emoji_font) {
font_list->add(*emoji_font);
}
// The default font is already included in the font list, but we explicitly set it
// as the last-resort font. This ensures that if none of the specified fonts contain
// the requested code point, there is still a font available to provide a fallback glyph.
font_list->set_last_resort_font(*default_font);
return font_list;
}
void StyleComputer::compute_font(ComputedProperties& style, DOM::Element const* element, Optional<CSS::PseudoElement> pseudo_element) const
{
// To compute the font, first ensure that we've defaulted the relevant CSS font properties.
// FIXME: This should be more sophisticated.
compute_defaulted_property_value(style, element, CSS::PropertyID::FontFamily, pseudo_element);
compute_defaulted_property_value(style, element, CSS::PropertyID::FontSize, pseudo_element);
compute_defaulted_property_value(style, element, CSS::PropertyID::FontWidth, pseudo_element);
compute_defaulted_property_value(style, element, CSS::PropertyID::FontStyle, pseudo_element);
compute_defaulted_property_value(style, element, CSS::PropertyID::FontWeight, pseudo_element);
compute_defaulted_property_value(style, element, CSS::PropertyID::LineHeight, pseudo_element);
compute_defaulted_property_value(style, element, CSS::PropertyID::FontVariant, pseudo_element);
compute_defaulted_property_value(style, element, CSS::PropertyID::FontVariantAlternates, pseudo_element);
compute_defaulted_property_value(style, element, CSS::PropertyID::FontVariantCaps, pseudo_element);
compute_defaulted_property_value(style, element, CSS::PropertyID::FontVariantEmoji, pseudo_element);
compute_defaulted_property_value(style, element, CSS::PropertyID::FontVariantEastAsian, pseudo_element);
compute_defaulted_property_value(style, element, CSS::PropertyID::FontVariantLigatures, pseudo_element);
compute_defaulted_property_value(style, element, CSS::PropertyID::FontVariantNumeric, pseudo_element);
compute_defaulted_property_value(style, element, CSS::PropertyID::FontVariantPosition, pseudo_element);
auto const& font_family = style.property(CSS::PropertyID::FontFamily);
auto const& font_size = style.property(CSS::PropertyID::FontSize);
auto const& font_style = style.property(CSS::PropertyID::FontStyle);
auto const& font_weight = style.property(CSS::PropertyID::FontWeight);
auto const& font_width = style.property(CSS::PropertyID::FontWidth);
auto font_list = compute_font_for_style_values(element, pseudo_element, font_family, font_size, font_style, font_weight, font_width, style.math_depth());
VERIFY(font_list);
VERIFY(!font_list->is_empty());
RefPtr<Gfx::Font const> const found_font = font_list->first();
style.set_property(
CSS::PropertyID::FontSize,
LengthStyleValue::create(CSS::Length::make_px(CSSPixels::nearest_value_for(found_font->pixel_size()))),
style.is_property_inherited(CSS::PropertyID::FontSize) ? ComputedProperties::Inherited::Yes : ComputedProperties::Inherited::No);
style.set_property(
CSS::PropertyID::FontWeight,
NumberStyleValue::create(font_weight.to_font_weight()),
style.is_property_inherited(CSS::PropertyID::FontWeight) ? ComputedProperties::Inherited::Yes : ComputedProperties::Inherited::No);
style.set_computed_font_list(*font_list);
if (element && is<HTML::HTMLHtmlElement>(*element)) {
const_cast<StyleComputer&>(*this).m_root_element_font_metrics = calculate_root_element_font_metrics(style);
}
}
LogicalAliasMappingContext StyleComputer::compute_logical_alias_mapping_context(DOM::Element& element, Optional<PseudoElement> pseudo_element, ComputeStyleMode mode) const
{
auto normalize_value = [&](auto property_id, auto value) {
if (!value || value->is_inherit() || value->is_unset()) {
if (auto const* inheritance_parent = element_to_inherit_style_from(&element, pseudo_element)) {
value = inheritance_parent->computed_properties()->property(property_id);
} else {
value = property_initial_value(property_id);
}
}
if (value->is_initial())
value = property_initial_value(property_id);
return value;
};
bool did_match_any_pseudo_element_rules = false;
PseudoClassBitmap attempted_pseudo_class_matches;
// FIXME: Ideally we wouldn't run the whole cascade just for these few properties.
auto cascaded_properties = compute_cascaded_values(element, pseudo_element, did_match_any_pseudo_element_rules, attempted_pseudo_class_matches, mode, {});
auto writing_mode = normalize_value(PropertyID::WritingMode, cascaded_properties->property(PropertyID::WritingMode));
auto direction = normalize_value(PropertyID::Direction, cascaded_properties->property(PropertyID::Direction));
return LogicalAliasMappingContext {
.writing_mode = keyword_to_writing_mode(writing_mode->to_keyword()).release_value(),
.direction = keyword_to_direction(direction->to_keyword()).release_value()
};
}
Gfx::Font const& StyleComputer::initial_font() const
{
// FIXME: This is not correct.
static auto font = ComputedProperties::font_fallback(false, false, 12);
return font;
}
void StyleComputer::absolutize_values(ComputedProperties& style, GC::Ptr<DOM::Element const> element) const
{
Length::FontMetrics font_metrics {
root_element_font_metrics_for_element(element).font_size,
style.first_available_computed_font().pixel_metrics()
};
// "A percentage value specifies an absolute font size relative to the parent element’s computed font-size. Negative percentages are invalid."
auto& font_size_value_slot = style.m_property_values[to_underlying(CSS::PropertyID::FontSize)];
if (font_size_value_slot && font_size_value_slot->is_percentage()) {
auto parent_font_size = get_inherit_value(CSS::PropertyID::FontSize, element)->as_length().length().to_px(viewport_rect(), font_metrics, m_root_element_font_metrics);
font_size_value_slot = LengthStyleValue::create(
Length::make_px(CSSPixels::nearest_value_for(parent_font_size * font_size_value_slot->as_percentage().percentage().as_fraction())));
}
auto font_size = font_size_value_slot->as_length().length().to_px(viewport_rect(), font_metrics, m_root_element_font_metrics);
font_metrics.font_size = font_size;
style.set_font_size({}, font_size);
// NOTE: Percentage line-height values are relative to the font-size of the element.
// We have to resolve them right away, so that the *computed* line-height is ready for inheritance.
// We can't simply absolutize *all* percentage values against the font size,
// because most percentages are relative to containing block metrics.
auto& line_height_value_slot = style.m_property_values[to_underlying(CSS::PropertyID::LineHeight)];
if (line_height_value_slot && line_height_value_slot->is_percentage()) {
line_height_value_slot = LengthStyleValue::create(
Length::make_px(CSSPixels::nearest_value_for(font_size * static_cast<double>(line_height_value_slot->as_percentage().percentage().as_fraction()))));
}
auto line_height = style.compute_line_height(viewport_rect(), font_metrics, m_root_element_font_metrics);
font_metrics.line_height = line_height;
// NOTE: line-height might be using lh which should be resolved against the parent line height (like we did here already)
if (line_height_value_slot && line_height_value_slot->is_length())
line_height_value_slot = LengthStyleValue::create(Length::make_px(line_height));
for (size_t i = 0; i < style.m_property_values.size(); ++i) {
auto& value_slot = style.m_property_values[i];
if (!value_slot)
continue;
value_slot = value_slot->absolutized(viewport_rect(), font_metrics, m_root_element_font_metrics);
}
style.set_line_height({}, line_height);
}
void StyleComputer::resolve_effective_overflow_values(ComputedProperties& style) const
{
// https://www.w3.org/TR/css-overflow-3/#overflow-control
// The visible/clip values of overflow compute to auto/hidden (respectively) if one of overflow-x or
// overflow-y is neither visible nor clip.
auto overflow_x = keyword_to_overflow(style.property(PropertyID::OverflowX).to_keyword());
auto overflow_y = keyword_to_overflow(style.property(PropertyID::OverflowY).to_keyword());
auto overflow_x_is_visible_or_clip = overflow_x == Overflow::Visible || overflow_x == Overflow::Clip;
auto overflow_y_is_visible_or_clip = overflow_y == Overflow::Visible || overflow_y == Overflow::Clip;
if (!overflow_x_is_visible_or_clip || !overflow_y_is_visible_or_clip) {
if (overflow_x == CSS::Overflow::Visible)
style.set_property(CSS::PropertyID::OverflowX, CSSKeywordValue::create(Keyword::Auto));
if (overflow_x == CSS::Overflow::Clip)
style.set_property(CSS::PropertyID::OverflowX, CSSKeywordValue::create(Keyword::Hidden));
if (overflow_y == CSS::Overflow::Visible)
style.set_property(CSS::PropertyID::OverflowY, CSSKeywordValue::create(Keyword::Auto));
if (overflow_y == CSS::Overflow::Clip)
style.set_property(CSS::PropertyID::OverflowY, CSSKeywordValue::create(Keyword::Hidden));
}
}
static void compute_text_align(ComputedProperties& style, DOM::Element const& element, Optional<PseudoElement> pseudo_element)
{
// https://drafts.csswg.org/css-text-4/#valdef-text-align-match-parent
// This value behaves the same as inherit (computes to its parent’s computed value) except that an inherited
// value of start or end is interpreted against the parent’s direction value and results in a computed value of
// either left or right. Computes to start when specified on the root element.
if (style.property(PropertyID::TextAlign).to_keyword() == Keyword::MatchParent) {
// If it's a pseudo-element, then the "parent" is the originating element instead.
auto const* parent = [&]() -> DOM::Element const* {
if (pseudo_element.has_value())
return &element;
return element.parent_element();
}();
if (parent) {
auto const& parent_text_align = parent->computed_properties()->property(PropertyID::TextAlign);
auto const& parent_direction = parent->computed_properties()->direction();
switch (parent_text_align.to_keyword()) {
case Keyword::Start:
if (parent_direction == Direction::Ltr) {
style.set_property(PropertyID::TextAlign, CSSKeywordValue::create(Keyword::Left));
} else {
style.set_property(PropertyID::TextAlign, CSSKeywordValue::create(Keyword::Right));
}
break;
case Keyword::End:
if (parent_direction == Direction::Ltr) {
style.set_property(PropertyID::TextAlign, CSSKeywordValue::create(Keyword::Right));
} else {
style.set_property(PropertyID::TextAlign, CSSKeywordValue::create(Keyword::Left));
}
break;
default:
style.set_property(PropertyID::TextAlign, parent_text_align);
}
} else {
style.set_property(PropertyID::TextAlign, CSSKeywordValue::create(Keyword::Start));
}
}
}
enum class BoxTypeTransformation {
None,
Blockify,
Inlinify,
};
static BoxTypeTransformation required_box_type_transformation(ComputedProperties const& style, DOM::Element const& element, Optional<CSS::PseudoElement> const& pseudo_element)
{
// NOTE: We never blockify <br> elements. They are always inline.
// There is currently no way to express in CSS how a <br> element really behaves.
// Spec issue: https://github.com/whatwg/html/issues/2291
if (is<HTML::HTMLBRElement>(element))
return BoxTypeTransformation::None;
// Absolute positioning or floating an element blockifies the box’s display type. [CSS2]
if (style.position() == CSS::Positioning::Absolute || style.position() == CSS::Positioning::Fixed || style.float_() != CSS::Float::None)
return BoxTypeTransformation::Blockify;
// FIXME: Containment in a ruby container inlinifies the box’s display type, as described in [CSS-RUBY-1].
// NOTE: If we're computing style for a pseudo-element, the effective parent will be the originating element itself, not its parent.
auto parent = pseudo_element.has_value() ? GC::Ptr<DOM::Element const> { &element } : element.parent_element();
// A parent with a grid or flex display value blockifies the box’s display type. [CSS-GRID-1] [CSS-FLEXBOX-1]
if (parent && parent->computed_properties()) {
auto const& parent_display = parent->computed_properties()->display();
if (parent_display.is_grid_inside() || parent_display.is_flex_inside())
return BoxTypeTransformation::Blockify;
}
return BoxTypeTransformation::None;
}
// https://drafts.csswg.org/css-display/#transformations
void StyleComputer::transform_box_type_if_needed(ComputedProperties& style, DOM::Element const& element, Optional<CSS::PseudoElement> pseudo_element) const
{
// 2.7. Automatic Box Type Transformations
// Some layout effects require blockification or inlinification of the box type,
// which sets the box’s computed outer display type to block or inline (respectively).
// (This has no effect on display types that generate no box at all, such as none or contents.)
auto display = style.display();
if (display.is_none() || (display.is_contents() && !element.is_document_element()))
return;
// https://drafts.csswg.org/css-display/#root
// The root element’s display type is always blockified, and its principal box always establishes an independent formatting context.
if (element.is_document_element() && !display.is_block_outside()) {
style.set_property(CSS::PropertyID::Display, DisplayStyleValue::create(Display::from_short(CSS::Display::Short::Block)));
return;
}
auto new_display = display;
if (display.is_math_inside()) {
// https://w3c.github.io/mathml-core/#new-display-math-value
// For elements that are not MathML elements, if the specified value of display is inline math or block math
// then the computed value is block flow and inline flow respectively.
if (element.namespace_uri() != Namespace::MathML)
new_display = CSS::Display { display.outside(), CSS::DisplayInside::Flow };
// For the mtable element the computed value is block table and inline table respectively.
else if (element.tag_name().equals_ignoring_ascii_case("mtable"sv))
new_display = CSS::Display { display.outside(), CSS::DisplayInside::Table };
// For the mtr element, the computed value is table-row.
else if (element.tag_name().equals_ignoring_ascii_case("mtr"sv))
new_display = CSS::Display { CSS::DisplayInternal::TableRow };
// For the mtd element, the computed value is table-cell.
else if (element.tag_name().equals_ignoring_ascii_case("mtd"sv))
new_display = CSS::Display { CSS::DisplayInternal::TableCell };
}
switch (required_box_type_transformation(style, element, pseudo_element)) {
case BoxTypeTransformation::None:
break;
case BoxTypeTransformation::Blockify:
if (display.is_block_outside())
return;
// If a layout-internal box is blockified, its inner display type converts to flow so that it becomes a block container.
if (display.is_internal()) {
new_display = CSS::Display::from_short(CSS::Display::Short::Block);
} else {
VERIFY(display.is_outside_and_inside());
// For legacy reasons, if an inline block box (inline flow-root) is blockified, it becomes a block box (losing its flow-root nature).
// For consistency, a run-in flow-root box also blockifies to a block box.
if (display.is_inline_block()) {
new_display = CSS::Display { CSS::DisplayOutside::Block, CSS::DisplayInside::Flow, display.list_item() };
} else {
new_display = CSS::Display { CSS::DisplayOutside::Block, display.inside(), display.list_item() };
}
}
break;
case BoxTypeTransformation::Inlinify:
if (display.is_inline_outside()) {
// FIXME: If an inline box (inline flow) is inlinified, it recursively inlinifies all of its in-flow children,
// so that no block-level descendants break up the inline formatting context in which it participates.
if (display.is_flow_inside()) {
dbgln("FIXME: Inlinify inline box children recursively");
}
break;
}
if (display.is_internal()) {
// Inlinification has no effect on layout-internal boxes. (However, placement in such an inline context will typically cause them
// to be wrapped in an appropriately-typed anonymous inline-level box.)
} else {
VERIFY(display.is_outside_and_inside());
// If a block box (block flow) is inlinified, its inner display type is set to flow-root so that it remains a block container.
if (display.is_block_outside() && display.is_flow_inside()) {
new_display = CSS::Display { CSS::DisplayOutside::Inline, CSS::DisplayInside::FlowRoot, display.list_item() };
}
new_display = CSS::Display { CSS::DisplayOutside::Inline, display.inside(), display.list_item() };
}
break;
}
if (new_display != display)
style.set_property(CSS::PropertyID::Display, DisplayStyleValue::create(new_display));
}
GC::Ref<ComputedProperties> StyleComputer::create_document_style() const
{
auto style = document().heap().allocate<CSS::ComputedProperties>();
compute_math_depth(style, nullptr, {});
compute_font(style, nullptr, {});
compute_defaulted_values(style, nullptr, {});
absolutize_values(style, nullptr);
style->set_property(CSS::PropertyID::Width, CSS::LengthStyleValue::create(CSS::Length::make_px(viewport_rect().width())));
style->set_property(CSS::PropertyID::Height, CSS::LengthStyleValue::create(CSS::Length::make_px(viewport_rect().height())));
style->set_property(CSS::PropertyID::Display, CSS::DisplayStyleValue::create(CSS::Display::from_short(CSS::Display::Short::Block)));
return style;
}
GC::Ref<ComputedProperties> StyleComputer::compute_style(DOM::Element& element, Optional<CSS::PseudoElement> pseudo_element) const
{
return *compute_style_impl(element, move(pseudo_element), ComputeStyleMode::Normal);
}
GC::Ptr<ComputedProperties> StyleComputer::compute_pseudo_element_style_if_needed(DOM::Element& element, Optional<CSS::PseudoElement> pseudo_element) const
{
return compute_style_impl(element, move(pseudo_element), ComputeStyleMode::CreatePseudoElementStyleIfNeeded);
}
GC::Ptr<ComputedProperties> StyleComputer::compute_style_impl(DOM::Element& element, Optional<CSS::PseudoElement> pseudo_element, ComputeStyleMode mode) const
{
build_rule_cache_if_needed();
// Special path for elements that use pseudo element as style selector
if (element.use_pseudo_element().has_value()) {
auto& parent_element = as<HTML::HTMLElement>(*element.root().parent_or_shadow_host());
auto style = compute_style(parent_element, *element.use_pseudo_element());
// Merge back inline styles
if (auto inline_style = element.inline_style()) {
for (auto const& property : inline_style->properties())
style->set_property(property.property_id, property.value);
}
return style;
}
ScopeGuard guard { [&element]() { element.set_needs_style_update(false); } };
// 1. Perform the cascade. This produces the "specified style"
bool did_match_any_pseudo_element_rules = false;
PseudoClassBitmap attempted_pseudo_class_matches;
auto logical_alias_mapping_context = compute_logical_alias_mapping_context(element, pseudo_element, mode);
auto cascaded_properties = compute_cascaded_values(element, pseudo_element, did_match_any_pseudo_element_rules, attempted_pseudo_class_matches, mode, logical_alias_mapping_context);
element.set_cascaded_properties(pseudo_element, cascaded_properties);
if (mode == ComputeStyleMode::CreatePseudoElementStyleIfNeeded) {
// NOTE: If we're computing style for a pseudo-element, we look for a number of reasons to bail early.
// Bail if no pseudo-element rules matched.
if (!did_match_any_pseudo_element_rules)
return {};
// Bail if no pseudo-element would be generated due to...
// - content: none
// - content: normal (for ::before and ::after)
bool content_is_normal = false;
if (auto content_value = cascaded_properties->property(CSS::PropertyID::Content)) {
if (content_value->is_keyword()) {
auto content = content_value->as_keyword().keyword();
if (content == CSS::Keyword::None)
return {};
content_is_normal = content == CSS::Keyword::Normal;
} else {
content_is_normal = false;
}
} else {
// NOTE: `normal` is the initial value, so the absence of a value is treated as `normal`.
content_is_normal = true;
}
if (content_is_normal && first_is_one_of(*pseudo_element, CSS::PseudoElement::Before, CSS::PseudoElement::After)) {
return {};
}
}
auto computed_properties = compute_properties(element, pseudo_element, cascaded_properties);
computed_properties->set_attempted_pseudo_class_matches(attempted_pseudo_class_matches);
return computed_properties;
}
static bool is_monospace(CSSStyleValue const& value)
{
if (value.to_keyword() == Keyword::Monospace)
return true;
if (value.is_value_list()) {
auto const& values = value.as_value_list().values();
if (values.size() == 1 && values[0]->to_keyword() == Keyword::Monospace)
return true;
}
return false;
}
// HACK: This function implements time-travelling inheritance for the font-size property
// in situations where the cascade ended up with `font-family: monospace`.
// In such cases, other browsers will magically change the meaning of keyword font sizes
// *even in earlier stages of the cascade!!* to be relative to the default monospace font size (13px)
// instead of the default font size (16px).
// See this blog post for a lot more details about this weirdness:
// https://manishearth.github.io/blog/2017/08/10/font-size-an-unexpectedly-complex-css-property/
RefPtr<CSSStyleValue const> StyleComputer::recascade_font_size_if_needed(
DOM::Element& element,
Optional<CSS::PseudoElement> pseudo_element,
CascadedProperties& cascaded_properties) const
{
// Check for `font-family: monospace`. Note that `font-family: monospace, AnythingElse` does not trigger this path.
// Some CSS frameworks use `font-family: monospace, monospace` to work around this behavior.
auto font_family_value = cascaded_properties.property(CSS::PropertyID::FontFamily);
if (!font_family_value || !is_monospace(*font_family_value))
return nullptr;
// FIXME: This should be configurable.
constexpr CSSPixels default_monospace_font_size_in_px = 13;
static auto monospace_font_family_name = Platform::FontPlugin::the().generic_font_name(Platform::GenericFont::Monospace);
static auto monospace_font = Gfx::FontDatabase::the().get(monospace_font_family_name, default_monospace_font_size_in_px * 0.75f, 400, Gfx::FontWidth::Normal, 0);
// Reconstruct the line of ancestor elements we need to inherit style from, and then do the cascade again
// but only for the font-size property.
Vector<DOM::Element&> ancestors;
if (pseudo_element.has_value())
ancestors.append(element);
for (auto ancestor = element.parent_element(); ancestor; ancestor = ancestor->parent_element())
ancestors.append(*ancestor);
NonnullRefPtr<CSSStyleValue const> new_font_size = CSS::LengthStyleValue::create(CSS::Length::make_px(default_monospace_font_size_in_px));
CSSPixels current_size_in_px = default_monospace_font_size_in_px;
for (auto& ancestor : ancestors.in_reverse()) {
auto& ancestor_cascaded_properties = *ancestor.cascaded_properties({});
auto font_size_value = ancestor_cascaded_properties.property(CSS::PropertyID::FontSize);
if (!font_size_value)
continue;
if (font_size_value->is_initial() || font_size_value->is_unset()) {
current_size_in_px = default_monospace_font_size_in_px;
continue;
}
if (font_size_value->is_inherit()) {
// Do nothing.
continue;
}
if (font_size_value->is_keyword()) {
current_size_in_px = default_monospace_font_size_in_px * absolute_size_mapping(font_size_value->to_keyword());
continue;
}
if (font_size_value->is_percentage()) {
current_size_in_px = CSSPixels::nearest_value_for(font_size_value->as_percentage().percentage().as_fraction() * current_size_in_px);
continue;
}
if (font_size_value->is_calculated()) {
dbgln("FIXME: Support calc() when time-traveling for monospace font-size");
continue;
}
VERIFY(font_size_value->is_length());
current_size_in_px = font_size_value->as_length().length().to_px(viewport_rect(), Length::FontMetrics { current_size_in_px, monospace_font->with_size(current_size_in_px * 0.75f)->pixel_metrics() }, m_root_element_font_metrics);
};
return CSS::LengthStyleValue::create(CSS::Length::make_px(current_size_in_px));
}
GC::Ref<ComputedProperties> StyleComputer::compute_properties(DOM::Element& element, Optional<PseudoElement> pseudo_element, CascadedProperties& cascaded_properties) const
{
DOM::AbstractElement abstract_element { element, pseudo_element };
auto computed_style = document().heap().allocate<CSS::ComputedProperties>();
auto new_font_size = recascade_font_size_if_needed(element, pseudo_element, cascaded_properties);
if (new_font_size)
computed_style->set_property(PropertyID::FontSize, *new_font_size, ComputedProperties::Inherited::No, Important::No);
for (auto i = to_underlying(first_longhand_property_id); i <= to_underlying(last_longhand_property_id); ++i) {
auto property_id = static_cast<CSS::PropertyID>(i);
auto value = cascaded_properties.property(property_id);
auto inherited = ComputedProperties::Inherited::No;
// NOTE: We've already handled font-size above.
if (property_id == PropertyID::FontSize && !value && new_font_size)
continue;
// FIXME: Logical properties should inherit from their parent's equivalent unmapped logical property.
if ((!value && is_inherited_property(property_id))
|| (value && value->is_inherit())) {
if (auto inheritance_parent = element_to_inherit_style_from(&element, pseudo_element)) {
value = inheritance_parent->computed_properties()->property(property_id);
inherited = ComputedProperties::Inherited::Yes;
} else {
value = property_initial_value(property_id);
}
}
if (!value || value->is_initial())
value = property_initial_value(property_id);
if (value->is_unset()) {
if (is_inherited_property(property_id))
value = CSSKeywordValue::create(Keyword::Inherit);
else
value = CSSKeywordValue::create(Keyword::Initial);
}
computed_style->set_property(property_id, value.release_nonnull(), inherited);
if (property_id == PropertyID::AnimationName) {
computed_style->set_animation_name_source(cascaded_properties.property_source(property_id));
}
if (property_id == PropertyID::TransitionProperty) {
computed_style->set_transition_property_source(cascaded_properties.property_source(property_id));
}
}
// Animation declarations [css-animations-2]
auto animation_name = [&]() -> Optional<String> {
auto const animation_name = computed_style->maybe_null_property(PropertyID::AnimationName);
if (!animation_name)
return OptionalNone {};
if (animation_name->is_keyword() && animation_name->to_keyword() == Keyword::None)
return OptionalNone {};
if (animation_name->is_string())
return animation_name->as_string().string_value().to_string();
return animation_name->to_string(SerializationMode::Normal);
}();
if (animation_name.has_value()) {
if (auto source_declaration = computed_style->animation_name_source()) {
auto& realm = element.realm();
if (source_declaration != element.cached_animation_name_source(pseudo_element)) {
// This animation name is new, so we need to create a new animation for it.
if (auto existing_animation = element.cached_animation_name_animation(pseudo_element))
existing_animation->cancel(Animations::Animation::ShouldInvalidate::No);
element.set_cached_animation_name_source(source_declaration, pseudo_element);
auto effect = Animations::KeyframeEffect::create(realm);
auto animation = CSSAnimation::create(realm);
animation->set_id(animation_name.release_value());
animation->set_timeline(m_document->timeline());
animation->set_owning_element(element);
animation->set_effect(effect);
apply_animation_properties(m_document, cascaded_properties, animation);
if (pseudo_element.has_value())
effect->set_pseudo_element(Selector::PseudoElementSelector { pseudo_element.value() });
if (auto* rule_cache = rule_cache_for_cascade_origin(CascadeOrigin::Author, {}, {})) {
if (auto keyframe_set = rule_cache->rules_by_animation_keyframes.get(animation->id()); keyframe_set.has_value())
effect->set_key_frame_set(keyframe_set.value());
}
effect->set_target(&element);
element.set_cached_animation_name_animation(animation, pseudo_element);
} else {
// The animation hasn't changed, but some properties of the animation may have
if (auto animation = element.cached_animation_name_animation(pseudo_element); animation)
apply_animation_properties(m_document, cascaded_properties, *animation);
}
}
} else {
// If the element had an existing animation, cancel it
if (auto existing_animation = element.cached_animation_name_animation(pseudo_element)) {
existing_animation->cancel(Animations::Animation::ShouldInvalidate::No);
element.set_cached_animation_name_animation({}, pseudo_element);
element.set_cached_animation_name_source({}, pseudo_element);
}
}
auto animations = element.get_animations_internal(Animations::GetAnimationsOptions { .subtree = false });
if (animations.is_exception()) {
dbgln("Error getting animations for element {}", element.debug_description());
} else {
for (auto& animation : animations.value()) {
if (auto effect = animation->effect(); effect && effect->is_keyframe_effect()) {
auto& keyframe_effect = *static_cast<Animations::KeyframeEffect*>(effect.ptr());
if (keyframe_effect.pseudo_element_type() == pseudo_element)
collect_animation_into(element, pseudo_element, keyframe_effect, computed_style);
}
}
}
// Compute the value of custom properties
compute_custom_properties(computed_style, abstract_element);
// 2. Compute the math-depth property, since that might affect the font-size
compute_math_depth(computed_style, &element, pseudo_element);
// 3. Compute the font, since that may be needed for font-relative CSS units
compute_font(computed_style, &element, pseudo_element);
// 4. Absolutize values, turning font/viewport relative lengths into absolute lengths
absolutize_values(computed_style, element);
// 5. Default the values, applying inheritance and 'initial' as needed
compute_defaulted_values(computed_style, &element, pseudo_element);
// 6. Run automatic box type transformations
transform_box_type_if_needed(computed_style, element, pseudo_element);
// 7. Apply any property-specific computed value logic
resolve_effective_overflow_values(computed_style);
compute_text_align(computed_style, element, pseudo_element);
// 8. Let the element adjust computed style
element.adjust_computed_style(computed_style);
// 9. Transition declarations [css-transitions-1]
// Theoretically this should be part of the cascade, but it works with computed values, which we don't have until now.
compute_transitioned_properties(computed_style, element, pseudo_element);
if (auto previous_style = element.computed_properties(pseudo_element)) {
start_needed_transitions(*previous_style, computed_style, element, pseudo_element);
}
return computed_style;
}
void StyleComputer::build_rule_cache_if_needed() const
{
if (has_valid_rule_cache())
return;
const_cast<StyleComputer&>(*this).build_rule_cache();
}
struct SimplifiedSelectorForBucketing {
CSS::Selector::SimpleSelector::Type type;
FlyString name;
};
static Optional<SimplifiedSelectorForBucketing> is_roundabout_selector_bucketable_as_something_simpler(CSS::Selector::SimpleSelector const& simple_selector)
{
if (simple_selector.type != CSS::Selector::SimpleSelector::Type::PseudoClass)
return {};
if (simple_selector.pseudo_class().type != CSS::PseudoClass::Is
&& simple_selector.pseudo_class().type != CSS::PseudoClass::Where)
return {};
if (simple_selector.pseudo_class().argument_selector_list.size() != 1)
return {};
auto const& argument_selector = *simple_selector.pseudo_class().argument_selector_list.first();
auto const& compound_selector = argument_selector.compound_selectors().last();
if (compound_selector.simple_selectors.size() != 1)
return {};
auto const& inner_simple_selector = compound_selector.simple_selectors.first();
if (inner_simple_selector.type == CSS::Selector::SimpleSelector::Type::Class
|| inner_simple_selector.type == CSS::Selector::SimpleSelector::Type::Id) {
return SimplifiedSelectorForBucketing { inner_simple_selector.type, inner_simple_selector.name() };
}
if (inner_simple_selector.type == CSS::Selector::SimpleSelector::Type::TagName) {
return SimplifiedSelectorForBucketing { inner_simple_selector.type, inner_simple_selector.qualified_name().name.lowercase_name };
}
return {};
}
void StyleComputer::collect_selector_insights(Selector const& selector, SelectorInsights& insights)
{
for (auto const& compound_selector : selector.compound_selectors()) {
for (auto const& simple_selector : compound_selector.simple_selectors) {
if (simple_selector.type == Selector::SimpleSelector::Type::PseudoClass) {
if (simple_selector.pseudo_class().type == PseudoClass::Has) {
insights.has_has_selectors = true;
}
for (auto const& argument_selector : simple_selector.pseudo_class().argument_selector_list) {
collect_selector_insights(*argument_selector, insights);
}
}
}
}
}
void StyleComputer::make_rule_cache_for_cascade_origin(CascadeOrigin cascade_origin, SelectorInsights& insights)
{
Vector<MatchingRule> matching_rules;
size_t style_sheet_index = 0;
for_each_stylesheet(cascade_origin, [&](auto& sheet, GC::Ptr<DOM::ShadowRoot> shadow_root) {
auto& rule_caches = [&] -> RuleCaches& {
RuleCachesForDocumentAndShadowRoots* rule_caches_for_document_or_shadow_root = nullptr;
switch (cascade_origin) {
case CascadeOrigin::Author:
rule_caches_for_document_or_shadow_root = m_author_rule_cache;
break;
case CascadeOrigin::User:
rule_caches_for_document_or_shadow_root = m_user_rule_cache;
break;
case CascadeOrigin::UserAgent:
rule_caches_for_document_or_shadow_root = m_user_agent_rule_cache;
break;
default:
VERIFY_NOT_REACHED();
}
if (!shadow_root)
return rule_caches_for_document_or_shadow_root->for_document;
return *rule_caches_for_document_or_shadow_root->for_shadow_roots.ensure(*shadow_root, [] { return make<RuleCaches>(); });
}();
size_t rule_index = 0;
sheet.for_each_effective_style_producing_rule([&](auto const& rule) {
SelectorList const& absolutized_selectors = [&]() {
if (rule.type() == CSSRule::Type::Style)
return static_cast<CSSStyleRule const&>(rule).absolutized_selectors();
if (rule.type() == CSSRule::Type::NestedDeclarations)
return static_cast<CSSNestedDeclarations const&>(rule).parent_style_rule().absolutized_selectors();
VERIFY_NOT_REACHED();
}();
for (auto const& selector : absolutized_selectors) {
m_style_invalidation_data->build_invalidation_sets_for_selector(selector);
}
for (CSS::Selector const& selector : absolutized_selectors) {
MatchingRule matching_rule {
shadow_root,
&rule,
sheet,
sheet.default_namespace(),
selector,
style_sheet_index,
rule_index,
selector.specificity(),
cascade_origin,
false,
};
auto const& qualified_layer_name = matching_rule.qualified_layer_name();
auto& rule_cache = qualified_layer_name.is_empty() ? rule_caches.main : *rule_caches.by_layer.ensure(qualified_layer_name, [] { return make<RuleCache>(); });
bool contains_root_pseudo_class = false;
Optional<CSS::PseudoElement> pseudo_element;
collect_selector_insights(selector, insights);
for (auto const& simple_selector : selector.compound_selectors().last().simple_selectors) {
if (!matching_rule.contains_pseudo_element) {
if (simple_selector.type == CSS::Selector::SimpleSelector::Type::PseudoElement) {
matching_rule.contains_pseudo_element = true;
pseudo_element = simple_selector.pseudo_element().type();
}
}
if (!contains_root_pseudo_class) {
if (simple_selector.type == CSS::Selector::SimpleSelector::Type::PseudoClass
&& simple_selector.pseudo_class().type == CSS::PseudoClass::Root) {
contains_root_pseudo_class = true;
}
}
}
for (size_t i = 0; i < to_underlying(PseudoClass::__Count); ++i) {
auto pseudo_class = static_cast<PseudoClass>(i);
// If we're not building a rule cache for this pseudo class, just ignore it.
if (!m_pseudo_class_rule_cache[i])
continue;
if (selector.contains_pseudo_class(pseudo_class)) {
// For pseudo class rule caches we intentionally pass no pseudo-element, because we don't want to bucket pseudo class rules by pseudo-element type.
m_pseudo_class_rule_cache[i]->add_rule(matching_rule, {}, contains_root_pseudo_class);
}
}
rule_cache.add_rule(matching_rule, pseudo_element, contains_root_pseudo_class);
}
++rule_index;
});
// Loosely based on https://drafts.csswg.org/css-animations-2/#keyframe-processing
sheet.for_each_effective_keyframes_at_rule([&](CSSKeyframesRule const& rule) {
auto keyframe_set = adopt_ref(*new Animations::KeyframeEffect::KeyFrameSet);
HashTable<PropertyID> animated_properties;
// Forwards pass, resolve all the user-specified keyframe properties.
for (auto const& keyframe_rule : *rule.css_rules()) {
auto const& keyframe = as<CSSKeyframeRule>(*keyframe_rule);
Animations::KeyframeEffect::KeyFrameSet::ResolvedKeyFrame resolved_keyframe;
auto key = static_cast<u64>(keyframe.key().value() * Animations::KeyframeEffect::AnimationKeyFrameKeyScaleFactor);
auto const& keyframe_style = *keyframe.style();
for (auto const& it : keyframe_style.properties()) {
// Unresolved properties will be resolved in collect_animation_into()
for_each_property_expanding_shorthands(it.property_id, it.value, [&](PropertyID shorthand_id, CSSStyleValue const& shorthand_value) {
animated_properties.set(shorthand_id);
resolved_keyframe.properties.set(shorthand_id, NonnullRefPtr<CSSStyleValue const> { shorthand_value });
});
}
keyframe_set->keyframes_by_key.insert(key, resolved_keyframe);
}
Animations::KeyframeEffect::generate_initial_and_final_frames(keyframe_set, animated_properties);
if constexpr (LIBWEB_CSS_DEBUG) {
dbgln("Resolved keyframe set '{}' into {} keyframes:", rule.name(), keyframe_set->keyframes_by_key.size());
for (auto it = keyframe_set->keyframes_by_key.begin(); it != keyframe_set->keyframes_by_key.end(); ++it)
dbgln(" - keyframe {}: {} properties", it.key(), it->properties.size());
}
rule_caches.main.rules_by_animation_keyframes.set(rule.name(), move(keyframe_set));
});
++style_sheet_index;
});
}
struct LayerNode {
OrderedHashMap<FlyString, LayerNode> children {};
};
static void flatten_layer_names_tree(Vector<FlyString>& layer_names, StringView const& parent_qualified_name, FlyString const& name, LayerNode const& node)
{
FlyString qualified_name = parent_qualified_name.is_empty() ? name : MUST(String::formatted("{}.{}", parent_qualified_name, name));
for (auto const& item : node.children)
flatten_layer_names_tree(layer_names, qualified_name, item.key, item.value);
layer_names.append(qualified_name);
}
void StyleComputer::build_qualified_layer_names_cache()
{
LayerNode root;
auto insert_layer_name = [&](FlyString const& internal_qualified_name) {
auto* node = &root;
internal_qualified_name.bytes_as_string_view()
.for_each_split_view('.', SplitBehavior::Nothing, [&](StringView part) {
auto local_name = MUST(FlyString::from_utf8(part));
node = &node->children.ensure(local_name);
});
};
// Walk all style sheets, identifying when we first see a @layer name, and add its qualified name to the list.
// TODO: Separate the light and shadow-dom layers.
for_each_stylesheet(CascadeOrigin::Author, [&](auto& sheet, GC::Ptr<DOM::ShadowRoot>) {
// NOTE: Postorder so that a @layer block is iterated after its children,
// because we want those children to occur before it in the list.
sheet.for_each_effective_rule(TraversalOrder::Postorder, [&](auto& rule) {
switch (rule.type()) {
case CSSRule::Type::Import:
// TODO: Handle `layer(foo)` in import rules once we implement that.
break;
case CSSRule::Type::LayerBlock: {
auto& layer_block = static_cast<CSSLayerBlockRule const&>(rule);
insert_layer_name(layer_block.internal_qualified_name({}));
break;
}
case CSSRule::Type::LayerStatement: {
auto& layer_statement = static_cast<CSSLayerStatementRule const&>(rule);
auto qualified_names = layer_statement.internal_qualified_name_list({});
for (auto& name : qualified_names)
insert_layer_name(name);
break;
}
// Ignore everything else
case CSSRule::Type::Style:
case CSSRule::Type::Media:
case CSSRule::Type::FontFace:
case CSSRule::Type::Keyframes:
case CSSRule::Type::Keyframe:
case CSSRule::Type::Margin:
case CSSRule::Type::Namespace:
case CSSRule::Type::NestedDeclarations:
case CSSRule::Type::Page:
case CSSRule::Type::Property:
case CSSRule::Type::Supports:
break;
}
});
});
// Now, produce a flat list of qualified names to use later
m_qualified_layer_names_in_order.clear();
flatten_layer_names_tree(m_qualified_layer_names_in_order, ""sv, {}, root);
}
void StyleComputer::build_rule_cache()
{
m_author_rule_cache = make<RuleCachesForDocumentAndShadowRoots>();
m_user_rule_cache = make<RuleCachesForDocumentAndShadowRoots>();
m_user_agent_rule_cache = make<RuleCachesForDocumentAndShadowRoots>();
m_selector_insights = make<SelectorInsights>();
m_style_invalidation_data = make<StyleInvalidationData>();
if (auto user_style_source = document().page().user_style(); user_style_source.has_value()) {
m_user_style_sheet = GC::make_root(parse_css_stylesheet(CSS::Parser::ParsingParams(document()), user_style_source.value()));
}
build_qualified_layer_names_cache();
m_pseudo_class_rule_cache[to_underlying(PseudoClass::Hover)] = make<RuleCache>();
m_pseudo_class_rule_cache[to_underlying(PseudoClass::Active)] = make<RuleCache>();
m_pseudo_class_rule_cache[to_underlying(PseudoClass::Focus)] = make<RuleCache>();
m_pseudo_class_rule_cache[to_underlying(PseudoClass::FocusWithin)] = make<RuleCache>();
m_pseudo_class_rule_cache[to_underlying(PseudoClass::FocusVisible)] = make<RuleCache>();
m_pseudo_class_rule_cache[to_underlying(PseudoClass::Target)] = make<RuleCache>();
make_rule_cache_for_cascade_origin(CascadeOrigin::Author, *m_selector_insights);
make_rule_cache_for_cascade_origin(CascadeOrigin::User, *m_selector_insights);
make_rule_cache_for_cascade_origin(CascadeOrigin::UserAgent, *m_selector_insights);
}
void StyleComputer::invalidate_rule_cache()
{
m_author_rule_cache = nullptr;
// NOTE: We could be smarter about keeping the user rule cache, and style sheet.
// Currently we are re-parsing the user style sheet every time we build the caches,
// as it may have changed.
m_user_rule_cache = nullptr;
m_user_style_sheet = nullptr;
// NOTE: It might not be necessary to throw away the UA rule cache.
// If we are sure that it's safe, we could keep it as an optimization.
m_user_agent_rule_cache = nullptr;
m_pseudo_class_rule_cache = {};
m_style_invalidation_data = nullptr;
}
void StyleComputer::did_load_font(FlyString const&)
{
document().invalidate_style(DOM::StyleInvalidationReason::CSSFontLoaded);
}
Optional<FontLoader&> StyleComputer::load_font_face(ParsedFontFace const& font_face, Function<void(RefPtr<Gfx::Typeface const>)> on_load)
{
if (font_face.sources().is_empty()) {
if (on_load)
on_load({});
return {};
}
FontFaceKey key {
.family_name = font_face.font_family(),
.weight = font_face.weight().value_or(0),
.slope = font_face.slope().value_or(0),
};
// FIXME: Pass the sources directly, so the font loader can make use of the format information, or load local fonts.
Vector<URL> urls;
for (auto const& source : font_face.sources()) {
if (source.local_or_url.has<URL>())
urls.append(source.local_or_url.get<URL>());
// FIXME: Handle local()
}
if (urls.is_empty()) {
if (on_load)
on_load({});
return {};
}
auto loader = make<FontLoader>(*this, font_face.parent_style_sheet(), font_face.font_family(), font_face.unicode_ranges(), move(urls), move(on_load));
auto& loader_ref = *loader;
auto maybe_font_loaders_list = m_loaded_fonts.get(key);
if (maybe_font_loaders_list.has_value()) {
maybe_font_loaders_list->append(move(loader));
} else {
FontLoaderList loaders;
loaders.append(move(loader));
m_loaded_fonts.set(OwnFontFaceKey(key), move(loaders));
}
// Actual object owned by font loader list inside m_loaded_fonts, this isn't use-after-move/free
return loader_ref;
}
void StyleComputer::load_fonts_from_sheet(CSSStyleSheet& sheet)
{
for (auto const& rule : sheet.rules()) {
if (!is<CSSFontFaceRule>(*rule))
continue;
auto const& font_face_rule = static_cast<CSSFontFaceRule const&>(*rule);
if (!font_face_rule.is_valid())
continue;
if (auto font_loader = load_font_face(font_face_rule.font_face()); font_loader.has_value()) {
sheet.add_associated_font_loader(font_loader.value());
}
}
}
void StyleComputer::unload_fonts_from_sheet(CSSStyleSheet& sheet)
{
for (auto& [_, font_loader_list] : m_loaded_fonts) {
font_loader_list.remove_all_matching([&](auto& font_loader) {
return sheet.has_associated_font_loader(*font_loader);
});
}
}
NonnullRefPtr<CSSStyleValue const> StyleComputer::compute_value_of_custom_property(DOM::AbstractElement abstract_element, FlyString const& name, Optional<Parser::GuardedSubstitutionContexts&> guarded_contexts)
{
// https://drafts.csswg.org/css-variables/#propdef-
// The computed value of a custom property is its specified value with any arbitrary-substitution functions replaced.
// FIXME: These should probably be part of ComputedProperties.
auto& document = abstract_element.document();
auto value = abstract_element.get_custom_property(name);
if (!value || value->is_initial())
return document.custom_property_initial_value(name);
// Unset is the same as inherit for inherited properties, and by default all custom properties are inherited.
// FIXME: Support non-inherited registered custom properties.
if (value->is_inherit() || value->is_unset()) {
if (!abstract_element.parent_element())
return document.custom_property_initial_value(name);
auto inherited_value = DOM::AbstractElement { const_cast<DOM::Element&>(*abstract_element.parent_element()) }.get_custom_property(name);
if (!inherited_value)
return document.custom_property_initial_value(name);
return inherited_value.release_nonnull();
}
if (value->is_revert()) {
// FIXME: Implement reverting custom properties.
}
if (value->is_revert_layer()) {
// FIXME: Implement reverting custom properties.
}
if (!value->is_unresolved() || !value->as_unresolved().contains_arbitrary_substitution_function())
return value.release_nonnull();
auto& unresolved = value->as_unresolved();
return Parser::Parser::resolve_unresolved_style_value(Parser::ParsingParams {}, abstract_element.element(), abstract_element.pseudo_element(), name, unresolved, guarded_contexts);
}
void StyleComputer::compute_custom_properties(ComputedProperties&, DOM::AbstractElement abstract_element) const
{
// https://drafts.csswg.org/css-variables/#propdef-
// The computed value of a custom property is its specified value with any arbitrary-substitution functions replaced.
// FIXME: These should probably be part of ComputedProperties.
auto custom_properties = abstract_element.custom_properties();
decltype(custom_properties) resolved_custom_properties;
for (auto const& [name, style_property] : custom_properties) {
resolved_custom_properties.set(name,
StyleProperty {
.important = style_property.important,
.property_id = style_property.property_id,
.value = compute_value_of_custom_property(abstract_element, name),
.custom_name = style_property.custom_name,
});
}
abstract_element.set_custom_properties(move(resolved_custom_properties));
}
void StyleComputer::compute_math_depth(ComputedProperties& style, DOM::Element const* element, Optional<CSS::PseudoElement> pseudo_element) const
{
// https://w3c.github.io/mathml-core/#propdef-math-depth
// First, ensure that the relevant CSS properties have been defaulted.
// FIXME: This should be more sophisticated.
compute_defaulted_property_value(style, element, CSS::PropertyID::MathDepth, pseudo_element);
compute_defaulted_property_value(style, element, CSS::PropertyID::MathStyle, pseudo_element);
auto inherited_math_depth = [&]() {
if (!element || !element->parent_element())
return InitialValues::math_depth();
return element->parent_element()->computed_properties()->math_depth();
};
auto const& value = style.property(CSS::PropertyID::MathDepth);
if (!value.is_math_depth()) {
style.set_math_depth(inherited_math_depth());
return;
}
auto const& math_depth = value.as_math_depth();
auto resolve_integer = [&](CSSStyleValue const& integer_value) {
if (integer_value.is_integer())
return integer_value.as_integer().integer();
if (integer_value.is_calculated())
return integer_value.as_calculated().resolve_integer_deprecated({}).value();
VERIFY_NOT_REACHED();
};
// The computed value of the math-depth value is determined as follows:
// - If the specified value of math-depth is auto-add and the inherited value of math-style is compact
// then the computed value of math-depth of the element is its inherited value plus one.
if (math_depth.is_auto_add() && style.property(CSS::PropertyID::MathStyle).to_keyword() == Keyword::Compact) {
style.set_math_depth(inherited_math_depth() + 1);
return;
}
// - If the specified value of math-depth is of the form add(<integer>) then the computed value of
// math-depth of the element is its inherited value plus the specified integer.
if (math_depth.is_add()) {
style.set_math_depth(inherited_math_depth() + resolve_integer(*math_depth.integer_value()));
return;
}
// - If the specified value of math-depth is of the form <integer> then the computed value of math-depth
// of the element is the specified integer.
if (math_depth.is_integer()) {
style.set_math_depth(resolve_integer(*math_depth.integer_value()));
return;
}
// - Otherwise, the computed value of math-depth of the element is the inherited one.
style.set_math_depth(inherited_math_depth());
}
static void for_each_element_hash(DOM::Element const& element, auto callback)
{
callback(element.local_name().ascii_case_insensitive_hash());
if (element.id().has_value())
callback(element.id().value().hash());
for (auto const& class_ : element.class_names())
callback(class_.hash());
element.for_each_attribute([&](auto& attribute) {
callback(attribute.lowercase_name().hash());
});
}
void StyleComputer::reset_ancestor_filter()
{
m_ancestor_filter.clear();
}
void StyleComputer::push_ancestor(DOM::Element const& element)
{
for_each_element_hash(element, [&](u32 hash) {
m_ancestor_filter.increment(hash);
});
}
void StyleComputer::pop_ancestor(DOM::Element const& element)
{
for_each_element_hash(element, [&](u32 hash) {
m_ancestor_filter.decrement(hash);
});
}
size_t StyleComputer::number_of_css_font_faces_with_loading_in_progress() const
{
size_t count = 0;
for (auto const& [_, loaders] : m_loaded_fonts) {
for (auto const& loader : loaders) {
if (loader->is_loading())
++count;
}
}
return count;
}
bool StyleComputer::may_have_has_selectors() const
{
if (!has_valid_rule_cache())
return true;
build_rule_cache_if_needed();
return m_selector_insights->has_has_selectors;
}
bool StyleComputer::have_has_selectors() const
{
build_rule_cache_if_needed();
return m_selector_insights->has_has_selectors;
}
void RuleCache::add_rule(MatchingRule const& matching_rule, Optional<PseudoElement> pseudo_element, bool contains_root_pseudo_class)
{
// NOTE: We traverse the simple selectors in reverse order to make sure that class/ID buckets are preferred over tag buckets
// in the common case of div.foo or div#foo selectors.
auto add_to_id_bucket = [&](FlyString const& name) {
rules_by_id.ensure(name).append(matching_rule);
};
auto add_to_class_bucket = [&](FlyString const& name) {
rules_by_class.ensure(name).append(matching_rule);
};
auto add_to_tag_name_bucket = [&](FlyString const& name) {
rules_by_tag_name.ensure(name).append(matching_rule);
};
for (auto const& simple_selector : matching_rule.selector.compound_selectors().last().simple_selectors.in_reverse()) {
if (simple_selector.type == Selector::SimpleSelector::Type::Id) {
add_to_id_bucket(simple_selector.name());
return;
}
if (simple_selector.type == Selector::SimpleSelector::Type::Class) {
add_to_class_bucket(simple_selector.name());
return;
}
if (simple_selector.type == Selector::SimpleSelector::Type::TagName) {
add_to_tag_name_bucket(simple_selector.qualified_name().name.lowercase_name);
return;
}
// NOTE: Selectors like `:is/where(.foo)` and `:is/where(.foo .bar)` are bucketed as class selectors for `foo` and `bar` respectively.
if (auto simplified = is_roundabout_selector_bucketable_as_something_simpler(simple_selector); simplified.has_value()) {
if (simplified->type == Selector::SimpleSelector::Type::TagName) {
add_to_tag_name_bucket(simplified->name);
return;
}
if (simplified->type == Selector::SimpleSelector::Type::Class) {
add_to_class_bucket(simplified->name);
return;
}
if (simplified->type == Selector::SimpleSelector::Type::Id) {
add_to_id_bucket(simplified->name);
return;
}
}
}
if (matching_rule.contains_pseudo_element && pseudo_element.has_value()) {
if (Selector::PseudoElementSelector::is_known_pseudo_element_type(pseudo_element.value())) {
rules_by_pseudo_element[to_underlying(pseudo_element.value())].append(matching_rule);
} else {
// NOTE: We don't cache rules for unknown pseudo-elements. They can't match anything anyway.
}
} else if (contains_root_pseudo_class) {
root_rules.append(matching_rule);
} else {
for (auto const& simple_selector : matching_rule.selector.compound_selectors().last().simple_selectors) {
if (simple_selector.type == Selector::SimpleSelector::Type::Attribute) {
rules_by_attribute_name.ensure(simple_selector.attribute().qualified_name.name.lowercase_name).append(matching_rule);
return;
}
}
other_rules.append(matching_rule);
}
}
void RuleCache::for_each_matching_rules(DOM::Element const& element, Optional<PseudoElement> pseudo_element, Function<IterationDecision(Vector<MatchingRule> const&)> callback) const
{
for (auto const& class_name : element.class_names()) {
if (auto it = rules_by_class.find(class_name); it != rules_by_class.end()) {
if (callback(it->value) == IterationDecision::Break)
return;
}
}
if (auto id = element.id(); id.has_value()) {
if (auto it = rules_by_id.find(id.value()); it != rules_by_id.end()) {
if (callback(it->value) == IterationDecision::Break)
return;
}
}
if (auto it = rules_by_tag_name.find(element.lowercased_local_name()); it != rules_by_tag_name.end()) {
if (callback(it->value) == IterationDecision::Break)
return;
}
if (pseudo_element.has_value()) {
if (Selector::PseudoElementSelector::is_known_pseudo_element_type(pseudo_element.value())) {
if (callback(rules_by_pseudo_element.at(to_underlying(pseudo_element.value()))) == IterationDecision::Break)
return;
} else {
// NOTE: We don't cache rules for unknown pseudo-elements. They can't match anything anyway.
}
}
if (element.is_document_element()) {
if (callback(root_rules) == IterationDecision::Break)
return;
}
IterationDecision decision = IterationDecision::Continue;
element.for_each_attribute([&](auto& name, auto&) {
if (auto it = rules_by_attribute_name.find(name); it != rules_by_attribute_name.end()) {
decision = callback(it->value);
}
});
if (decision == IterationDecision::Break)
return;
(void)callback(other_rules);
}
Length::FontMetrics const& StyleComputer::root_element_font_metrics_for_element(GC::Ptr<DOM::Element const> element) const
{
if (element && element->document().document_element() == element)
return m_default_font_metrics;
return m_root_element_font_metrics;
}
}
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