/* * Copyright (c) 2018-2023, Andreas Kling * Copyright (c) 2021, the SerenityOS developers. * Copyright (c) 2021-2023, Sam Atkins * Copyright (c) 2024, Matthew Olsson * * SPDX-License-Identifier: BSD-2-Clause */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace AK { // traits for FontFaceKey template<> struct Traits : public DefaultTraits { static unsigned hash(Web::CSS::FontFaceKey const& key) { return pair_int_hash(key.family_name.hash(), pair_int_hash(key.weight, key.slope)); } }; } namespace Web::CSS { static DOM::Element const* element_to_inherit_style_from(DOM::Element const*, Optional); StyleComputer::StyleComputer(DOM::Document& document) : m_document(document) , m_default_font_metrics(16, Gfx::FontDatabase::default_font().pixel_metrics()) , m_root_element_font_metrics(m_default_font_metrics) { } StyleComputer::~StyleComputer() = default; class StyleComputer::FontLoader : public ResourceClient { public: explicit FontLoader(StyleComputer& style_computer, FlyString family_name, Vector unicode_ranges, Vector urls) : m_style_computer(style_computer) , m_family_name(move(family_name)) , m_unicode_ranges(move(unicode_ranges)) , m_urls(move(urls)) { } virtual ~FontLoader() override { } Vector const& unicode_ranges() const { return m_unicode_ranges; } virtual void resource_did_load() override { auto result = try_load_font(); if (result.is_error()) return start_loading_next_url(); m_vector_font = result.release_value(); m_style_computer.did_load_font(m_family_name); } virtual void resource_did_fail() override { } RefPtr font_with_point_size(float point_size) { if (!m_vector_font) { start_loading_next_url(); return nullptr; } return m_vector_font->scaled_font(point_size); } private: void start_loading_next_url() { if (resource() && resource()->is_pending()) return; if (m_urls.is_empty()) return; LoadRequest request; request.set_url(m_urls.take_first()); // HACK: We're crudely computing the referer value and shoving it into the // request until fetch infrastructure is used here. auto referrer_url = ReferrerPolicy::strip_url_for_use_as_referrer(m_style_computer.document().url()); if (referrer_url.has_value() && !request.headers().contains("Referer")) request.set_header("Referer", referrer_url->serialize()); set_resource(ResourceLoader::the().load_resource(Resource::Type::Generic, request)); } ErrorOr> try_load_font() { // 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 = resource()->mime_type(); if (mime_type == "font/ttf"sv || mime_type == "application/x-font-ttf"sv) return TRY(OpenType::Font::try_load_from_externally_owned_memory(resource()->encoded_data())); if (mime_type == "font/woff"sv || mime_type == "application/font-woff"sv) return TRY(WOFF::Font::try_load_from_externally_owned_memory(resource()->encoded_data())); if (mime_type == "font/woff2"sv || mime_type == "application/font-woff2"sv) { auto woff2 = WOFF2::Font::try_load_from_externally_owned_memory(resource()->encoded_data()); if (woff2.is_error()) { dbgln("WOFF2 error: {}", woff2.error()); return woff2.release_error(); } return woff2.release_value(); } auto ttf = OpenType::Font::try_load_from_externally_owned_memory(resource()->encoded_data()); if (!ttf.is_error()) return ttf.release_value(); auto woff = WOFF::Font::try_load_from_externally_owned_memory(resource()->encoded_data()); if (!woff.is_error()) return woff.release_value(); auto woff2 = WOFF2::Font::try_load_from_externally_owned_memory(resource()->encoded_data()); if (!woff2.is_error()) return woff2.release_value(); return woff2.release_error(); } StyleComputer& m_style_computer; FlyString m_family_name; Vector m_unicode_ranges; RefPtr m_vector_font; Vector m_urls; }; struct StyleComputer::MatchingFontCandidate { FontFaceKey key; Variant loader_or_typeface; [[nodiscard]] RefPtr font_with_point_size(float point_size) const { RefPtr font_list = Gfx::FontCascadeList::create(); if (auto* loader_list = loader_or_typeface.get_pointer(); 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; } if (auto font = loader_or_typeface.get()->get_font(point_size)) font_list->add(*font); return font_list; } }; static CSSStyleSheet& default_stylesheet(DOM::Document const& document) { static JS::Handle sheet; if (!sheet.cell()) { extern StringView default_stylesheet_source; sheet = JS::make_handle(parse_css_stylesheet(CSS::Parser::ParsingContext(document), default_stylesheet_source)); } return *sheet; } static CSSStyleSheet& quirks_mode_stylesheet(DOM::Document const& document) { static JS::Handle sheet; if (!sheet.cell()) { extern StringView quirks_mode_stylesheet_source; sheet = JS::make_handle(parse_css_stylesheet(CSS::Parser::ParsingContext(document), quirks_mode_stylesheet_source)); } return *sheet; } static CSSStyleSheet& mathml_stylesheet(DOM::Document const& document) { static JS::Handle sheet; if (!sheet.cell()) { extern StringView mathml_stylesheet_source; sheet = JS::make_handle(parse_css_stylesheet(CSS::Parser::ParsingContext(document), mathml_stylesheet_source)); } return *sheet; } static CSSStyleSheet& svg_stylesheet(DOM::Document const& document) { static JS::Handle sheet; if (!sheet.cell()) { extern StringView svg_stylesheet_source; sheet = JS::make_handle(parse_css_stylesheet(CSS::Parser::ParsingContext(document), svg_stylesheet_source)); } return *sheet; } template void StyleComputer::for_each_stylesheet(CascadeOrigin cascade_origin, Callback callback) const { if (cascade_origin == CascadeOrigin::UserAgent) { callback(default_stylesheet(document()), {}); if (document().in_quirks_mode()) callback(quirks_mode_stylesheet(document()), {}); callback(mathml_stylesheet(document()), {}); callback(svg_stylesheet(document()), {}); } if (cascade_origin == CascadeOrigin::User) { if (m_user_style_sheet) callback(*m_user_style_sheet, {}); } if (cascade_origin == CascadeOrigin::Author) { document().for_each_css_style_sheet([&](CSSStyleSheet& sheet) { callback(sheet, {}); }); const_cast(document()).for_each_shadow_root([&](DOM::ShadowRoot& shadow_root) { shadow_root.for_each_css_style_sheet([&](CSSStyleSheet& sheet) { callback(sheet, &shadow_root); }); }); } } StyleComputer::RuleCache const& StyleComputer::rule_cache_for_cascade_origin(CascadeOrigin cascade_origin) 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: TODO(); } } [[nodiscard]] static bool filter_namespace_rule(DOM::Element const& element, MatchingRule const& rule) { // FIXME: Filter out non-default namespace using prefixes if (auto namespace_rule = rule.sheet->default_namespace_rule()) { if (namespace_rule->namespace_uri() != element.namespace_uri()) return false; } return true; } Vector StyleComputer::collect_matching_rules(DOM::Element const& element, CascadeOrigin cascade_origin, Optional pseudo_element) const { auto const& root_node = element.root(); auto shadow_root = is(root_node) ? static_cast(&root_node) : nullptr; auto const& rule_cache = rule_cache_for_cascade_origin(cascade_origin); Vector rules_to_run; auto add_rules_to_run = [&](Vector 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, rule)) rules_to_run.unchecked_append(rule); } } else { for (auto const& rule : rules) { if (!rule.contains_pseudo_element && filter_namespace_rule(element, rule)) rules_to_run.unchecked_append(rule); } } }; for (auto const& class_name : element.class_names()) { if (auto it = rule_cache.rules_by_class.find(class_name); it != rule_cache.rules_by_class.end()) add_rules_to_run(it->value); } if (auto id = element.id(); id.has_value()) { if (auto it = rule_cache.rules_by_id.find(id.value()); it != rule_cache.rules_by_id.end()) add_rules_to_run(it->value); } if (auto it = rule_cache.rules_by_tag_name.find(element.local_name()); it != rule_cache.rules_by_tag_name.end()) add_rules_to_run(it->value); if (pseudo_element.has_value()) add_rules_to_run(rule_cache.pseudo_element_rules); if (element.is_document_element()) add_rules_to_run(rule_cache.root_rules); element.for_each_attribute([&](auto& name, auto&) { if (auto it = rule_cache.rules_by_attribute_name.find(name); it != rule_cache.rules_by_attribute_name.end()) { add_rules_to_run(it->value); } }); add_rules_to_run(rule_cache.other_rules); Vector matching_rules; matching_rules.ensure_capacity(rules_to_run.size()); for (auto const& rule_to_run : rules_to_run) { // FIXME: This needs to be revised when adding support for the :host and ::shadow selectors, which transition shadow tree 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; if (rule_root != shadow_root && !from_user_agent_or_user_stylesheet) continue; auto const& selector = rule_to_run.rule->selectors()[rule_to_run.selector_index]; if (rule_to_run.can_use_fast_matches) { if (!SelectorEngine::fast_matches(selector, *rule_to_run.sheet, element)) continue; } else { if (!SelectorEngine::matches(selector, *rule_to_run.sheet, element, pseudo_element)) continue; } matching_rules.append(rule_to_run); } return matching_rules; } static void sort_matching_rules(Vector& matching_rules) { quick_sort(matching_rules, [&](MatchingRule& a, MatchingRule& b) { auto const& a_selector = a.rule->selectors()[a.selector_index]; auto const& b_selector = b.rule->selectors()[b.selector_index]; 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, StyleValue const& value, Function const& set_longhand_property) { auto map_logical_property_to_real_property = [](PropertyID property_id) -> Optional { // FIXME: Honor writing-mode, direction and text-orientation. switch (property_id) { case PropertyID::MarginBlockStart: return PropertyID::MarginTop; case PropertyID::MarginBlockEnd: return PropertyID::MarginBottom; case PropertyID::MarginInlineStart: return PropertyID::MarginLeft; case PropertyID::MarginInlineEnd: return PropertyID::MarginRight; case PropertyID::PaddingBlockStart: return PropertyID::PaddingTop; case PropertyID::PaddingBlockEnd: return PropertyID::PaddingBottom; case PropertyID::PaddingInlineStart: return PropertyID::PaddingLeft; case PropertyID::PaddingInlineEnd: return PropertyID::PaddingRight; case PropertyID::InlineSize: return PropertyID::Width; case PropertyID::InsetBlockStart: return PropertyID::Top; case PropertyID::InsetBlockEnd: return PropertyID::Bottom; case PropertyID::InsetInlineStart: return PropertyID::Left; case PropertyID::InsetInlineEnd: return PropertyID::Right; case PropertyID::WebkitAppearance: return PropertyID::Appearance; default: return {}; } }; struct StartAndEndPropertyIDs { PropertyID start; PropertyID end; }; auto map_logical_property_to_real_properties = [](PropertyID property_id) -> Optional { // FIXME: Honor writing-mode, direction and text-orientation. switch (property_id) { case PropertyID::MarginBlock: return StartAndEndPropertyIDs { PropertyID::MarginTop, PropertyID::MarginBottom }; case PropertyID::MarginInline: return StartAndEndPropertyIDs { PropertyID::MarginLeft, PropertyID::MarginRight }; case PropertyID::PaddingBlock: return StartAndEndPropertyIDs { PropertyID::PaddingTop, PropertyID::PaddingBottom }; case PropertyID::PaddingInline: return StartAndEndPropertyIDs { PropertyID::PaddingLeft, PropertyID::PaddingRight }; case PropertyID::InsetBlock: return StartAndEndPropertyIDs { PropertyID::Top, PropertyID::Bottom }; case PropertyID::InsetInline: return StartAndEndPropertyIDs { PropertyID::Left, PropertyID::Right }; default: return {}; } }; if (auto real_property_id = map_logical_property_to_real_property(property_id); real_property_id.has_value()) { for_each_property_expanding_shorthands(real_property_id.value(), value, set_longhand_property); return; } if (auto real_property_ids = map_logical_property_to_real_properties(property_id); real_property_ids.has_value()) { if (value.is_value_list() && value.as_value_list().size() == 2) { auto const& start = value.as_value_list().values()[0]; auto const& end = value.as_value_list().values()[1]; for_each_property_expanding_shorthands(real_property_ids->start, start, set_longhand_property); for_each_property_expanding_shorthands(real_property_ids->end, end, set_longhand_property); return; } for_each_property_expanding_shorthands(real_property_ids->start, value, set_longhand_property); for_each_property_expanding_shorthands(real_property_ids->end, 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; } auto assign_edge_values = [&](PropertyID top_property, PropertyID right_property, PropertyID bottom_property, PropertyID left_property, auto const& 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]); } }; if (property_id == CSS::PropertyID::Border) { for_each_property_expanding_shorthands(CSS::PropertyID::BorderTop, value, set_longhand_property); for_each_property_expanding_shorthands(CSS::PropertyID::BorderRight, value, set_longhand_property); for_each_property_expanding_shorthands(CSS::PropertyID::BorderBottom, value, set_longhand_property); for_each_property_expanding_shorthands(CSS::PropertyID::BorderLeft, value, set_longhand_property); // FIXME: Also reset border-image, in line with the spec: https://www.w3.org/TR/css-backgrounds-3/#border-shorthands return; } if (property_id == CSS::PropertyID::BorderStyle) { if (value.is_value_list()) { auto const& values_list = value.as_value_list(); assign_edge_values(PropertyID::BorderTopStyle, PropertyID::BorderRightStyle, PropertyID::BorderBottomStyle, PropertyID::BorderLeftStyle, values_list.values()); return; } set_longhand_property(CSS::PropertyID::BorderTopStyle, value); set_longhand_property(CSS::PropertyID::BorderRightStyle, value); set_longhand_property(CSS::PropertyID::BorderBottomStyle, value); set_longhand_property(CSS::PropertyID::BorderLeftStyle, value); return; } if (property_id == CSS::PropertyID::BorderWidth) { if (value.is_value_list()) { auto const& values_list = value.as_value_list(); assign_edge_values(PropertyID::BorderTopWidth, PropertyID::BorderRightWidth, PropertyID::BorderBottomWidth, PropertyID::BorderLeftWidth, values_list.values()); return; } set_longhand_property(CSS::PropertyID::BorderTopWidth, value); set_longhand_property(CSS::PropertyID::BorderRightWidth, value); set_longhand_property(CSS::PropertyID::BorderBottomWidth, value); set_longhand_property(CSS::PropertyID::BorderLeftWidth, value); return; } if (property_id == CSS::PropertyID::BorderColor) { if (value.is_value_list()) { auto const& values_list = value.as_value_list(); assign_edge_values(PropertyID::BorderTopColor, PropertyID::BorderRightColor, PropertyID::BorderBottomColor, PropertyID::BorderLeftColor, values_list.values()); return; } set_longhand_property(CSS::PropertyID::BorderTopColor, value); set_longhand_property(CSS::PropertyID::BorderRightColor, value); set_longhand_property(CSS::PropertyID::BorderBottomColor, value); set_longhand_property(CSS::PropertyID::BorderLeftColor, 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) { if (value.is_value_list()) { auto const& values_list = value.as_value_list(); assign_edge_values(PropertyID::Top, PropertyID::Right, PropertyID::Bottom, PropertyID::Left, values_list.values()); return; } set_longhand_property(CSS::PropertyID::Top, value); set_longhand_property(CSS::PropertyID::Right, value); set_longhand_property(CSS::PropertyID::Bottom, value); set_longhand_property(CSS::PropertyID::Left, value); return; } if (property_id == CSS::PropertyID::Margin) { if (value.is_value_list()) { auto const& values_list = value.as_value_list(); assign_edge_values(PropertyID::MarginTop, PropertyID::MarginRight, PropertyID::MarginBottom, PropertyID::MarginLeft, values_list.values()); return; } set_longhand_property(CSS::PropertyID::MarginTop, value); set_longhand_property(CSS::PropertyID::MarginRight, value); set_longhand_property(CSS::PropertyID::MarginBottom, value); set_longhand_property(CSS::PropertyID::MarginLeft, value); return; } if (property_id == CSS::PropertyID::Padding) { if (value.is_value_list()) { auto const& values_list = value.as_value_list(); assign_edge_values(PropertyID::PaddingTop, PropertyID::PaddingRight, PropertyID::PaddingBottom, PropertyID::PaddingLeft, values_list.values()); return; } set_longhand_property(CSS::PropertyID::PaddingTop, value); set_longhand_property(CSS::PropertyID::PaddingRight, value); set_longhand_property(CSS::PropertyID::PaddingBottom, value); set_longhand_property(CSS::PropertyID::PaddingLeft, value); return; } if (property_id == CSS::PropertyID::Gap || property_id == CSS::PropertyID::GridGap) { 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::RowGap || property_id == CSS::PropertyID::GridRowGap) { set_longhand_property(CSS::PropertyID::RowGap, value); return; } if (property_id == CSS::PropertyID::ColumnGap || property_id == CSS::PropertyID::GridColumnGap) { set_longhand_property(CSS::PropertyID::ColumnGap, value); return; } if (property_id == CSS::PropertyID::MaxInlineSize || property_id == CSS::PropertyID::MinInlineSize) { // FIXME: Use writing-mode to determine if we should set width or height. bool is_horizontal = true; if (is_horizontal) { if (property_id == CSS::PropertyID::MaxInlineSize) { set_longhand_property(CSS::PropertyID::MaxWidth, value); } else { set_longhand_property(CSS::PropertyID::MinWidth, value); } } else { if (property_id == CSS::PropertyID::MaxInlineSize) { set_longhand_property(CSS::PropertyID::MaxHeight, value); } else { set_longhand_property(CSS::PropertyID::MinHeight, value); } } return; } if (property_is_shorthand(property_id)) { // ShorthandStyleValue was handled already. // That means if we got here, that `value` must be a CSS-wide keyword, which we should apply 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()); 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::set_property_expanding_shorthands(StyleProperties& style, CSS::PropertyID property_id, StyleValue const& value, CSS::CSSStyleDeclaration const* declaration, StyleProperties::PropertyValues const& properties_for_revert, StyleProperties::Important important) { for_each_property_expanding_shorthands(property_id, value, [&](PropertyID shorthand_id, StyleValue const& shorthand_value) { if (shorthand_value.is_revert()) { auto& property_in_previous_cascade_origin = properties_for_revert[to_underlying(shorthand_id)]; if (property_in_previous_cascade_origin.style) style.set_property(shorthand_id, *property_in_previous_cascade_origin.style, property_in_previous_cascade_origin.declaration, StyleProperties::Inherited::No, important); } else { style.set_property(shorthand_id, shorthand_value, declaration, StyleProperties::Inherited::No, important); } }); } void StyleComputer::set_all_properties(DOM::Element& element, Optional pseudo_element, StyleProperties& style, StyleValue const& value, DOM::Document& document, CSS::CSSStyleDeclaration const* declaration, StyleProperties::PropertyValues const& properties_for_revert, StyleProperties::Important important) const { 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; if (value.is_revert()) { style.m_property_values[to_underlying(property_id)] = properties_for_revert[to_underlying(property_id)]; style.m_property_values[to_underlying(property_id)].important = important; continue; } if (value.is_unset()) { if (is_inherited_property(property_id)) style.m_property_values[to_underlying(property_id)] = { get_inherit_value(document.realm(), property_id, &element, pseudo_element), nullptr }; else style.m_property_values[to_underlying(property_id)] = { property_initial_value(document.realm(), property_id), nullptr }; style.m_property_values[to_underlying(property_id)].important = important; continue; } NonnullRefPtr property_value = value; if (property_value->is_unresolved()) property_value = Parser::Parser::resolve_unresolved_style_value({}, Parser::ParsingContext { document }, element, pseudo_element, property_id, property_value->as_unresolved()); if (!property_value->is_unresolved()) set_property_expanding_shorthands(style, property_id, property_value, declaration, properties_for_revert); style.m_property_values[to_underlying(property_id)].important = important; set_property_expanding_shorthands(style, property_id, value, declaration, properties_for_revert, important); } } void StyleComputer::cascade_declarations(StyleProperties& style, DOM::Element& element, Optional pseudo_element, Vector const& matching_rules, CascadeOrigin cascade_origin, Important important) const { auto properties_for_revert = style.properties(); for (auto const& match : matching_rules) { for (auto const& property : match.rule->declaration().properties()) { if (important != property.important) continue; if (property.property_id == CSS::PropertyID::All) { set_all_properties(element, pseudo_element, style, property.value, m_document, &match.rule->declaration(), properties_for_revert, important == Important::Yes ? StyleProperties::Important::Yes : StyleProperties::Important::No); continue; } auto property_value = property.value; if (property.value->is_unresolved()) property_value = Parser::Parser::resolve_unresolved_style_value({}, Parser::ParsingContext { document() }, element, pseudo_element, property.property_id, property.value->as_unresolved()); if (!property_value->is_unresolved()) set_property_expanding_shorthands(style, property.property_id, property_value, &match.rule->declaration(), properties_for_revert, important == Important::Yes ? StyleProperties::Important::Yes : StyleProperties::Important::No); } } if (cascade_origin == CascadeOrigin::Author && !pseudo_element.has_value()) { if (auto const inline_style = element.inline_style()) { for (auto const& property : inline_style->properties()) { if (important != property.important) continue; if (property.property_id == CSS::PropertyID::All) { set_all_properties(element, pseudo_element, style, property.value, m_document, inline_style, properties_for_revert, important == Important::Yes ? StyleProperties::Important::Yes : StyleProperties::Important::No); continue; } auto property_value = property.value; if (property.value->is_unresolved()) property_value = Parser::Parser::resolve_unresolved_style_value({}, Parser::ParsingContext { document() }, element, pseudo_element, property.property_id, property.value->as_unresolved()); if (!property_value->is_unresolved()) set_property_expanding_shorthands(style, property.property_id, property_value, inline_style, properties_for_revert, important == Important::Yes ? StyleProperties::Important::Yes : StyleProperties::Important::No); } } } } static void cascade_custom_properties(DOM::Element& element, Optional pseudo_element, Vector const& matching_rules) { size_t needed_capacity = 0; for (auto const& matching_rule : matching_rules) needed_capacity += matching_rule.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(); } HashMap custom_properties; custom_properties.ensure_capacity(needed_capacity); for (auto const& matching_rule : matching_rules) { for (auto const& it : matching_rule.rule->declaration().custom_properties()) 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); } } element.set_custom_properties(pseudo_element, move(custom_properties)); } static NonnullRefPtr interpolate_value(DOM::Element& element, StyleValue const& from, StyleValue const& to, float delta); template static T interpolate_raw(T from, T to, float delta) { if constexpr (IsSame) { return from + (to - from) * static_cast(delta); } else { return static_cast>(from + (to - from) * delta); } } // A null return value means the interpolated matrix was not invertible or otherwise invalid static RefPtr interpolate_transform(DOM::Element& element, StyleValue const& from, StyleValue const& to, float delta) { // Note that the spec uses column-major notation, so all the matrix indexing is reversed. static constexpr auto make_transformation = [](TransformationStyleValue const& transformation) -> Optional { Vector values; for (auto const& value : transformation.values()) { switch (value->type()) { case StyleValue::Type::Angle: values.append(AngleOrCalculated { value->as_angle().angle() }); break; case StyleValue::Type::Calculated: values.append(AngleOrCalculated { value->as_calculated() }); break; case StyleValue::Type::Length: values.append(LengthPercentage { value->as_length().length() }); break; case StyleValue::Type::Percentage: values.append(LengthPercentage { value->as_percentage().percentage() }); break; case StyleValue::Type::Number: values.append(NumberPercentage { Number(Number::Type::Number, value->as_number().number()) }); break; default: return {}; } } return Transformation { transformation.transform_function(), move(values) }; }; static constexpr auto transformation_style_value_to_matrix = [](DOM::Element& element, TransformationStyleValue const& value) -> Optional { auto transformation = make_transformation(value.as_transformation()); if (!transformation.has_value()) return {}; Optional paintable_box; if (auto layout_node = element.layout_node()) { if (auto paintable = layout_node->paintable(); paintable && is(paintable)) paintable_box = *static_cast(paintable); } if (auto matrix = transformation->to_matrix(paintable_box); !matrix.is_error()) return matrix.value(); return {}; }; static constexpr auto style_value_to_matrix = [](DOM::Element& element, StyleValue const& value) -> FloatMatrix4x4 { if (value.is_transformation()) return transformation_style_value_to_matrix(element, value.as_transformation()).value_or(FloatMatrix4x4::identity()); // This encompasses both the allowed value "none" and any invalid values if (!value.is_value_list()) return FloatMatrix4x4::identity(); auto matrix = FloatMatrix4x4::identity(); for (auto const& value_element : value.as_value_list().values()) { if (value_element->is_transformation()) { if (auto value_matrix = transformation_style_value_to_matrix(element, value_element->as_transformation()); value_matrix.has_value()) matrix = matrix * value_matrix.value(); } } return matrix; }; struct DecomposedValues { FloatVector3 translation; FloatVector3 scale; FloatVector3 skew; FloatVector4 rotation; FloatVector4 perspective; }; // https://drafts.csswg.org/css-transforms-2/#decomposing-a-3d-matrix static constexpr auto decompose = [](FloatMatrix4x4 matrix) -> Optional { // https://drafts.csswg.org/css-transforms-1/#supporting-functions static constexpr auto combine = [](auto a, auto b, float ascl, float bscl) { return FloatVector3 { ascl * a[0] + bscl * b[0], ascl * a[1] + bscl * b[1], ascl * a[2] + bscl * b[2], }; }; // Normalize the matrix. if (matrix(3, 3) == 0.f) return {}; for (int i = 0; i < 4; i++) for (int j = 0; j < 4; j++) matrix(i, j) /= matrix(3, 3); // perspectiveMatrix is used to solve for perspective, but it also provides // an easy way to test for singularity of the upper 3x3 component. auto perspective_matrix = matrix; for (int i = 0; i < 3; i++) perspective_matrix(3, i) = 0.f; perspective_matrix(3, 3) = 1.f; if (!perspective_matrix.is_invertible()) return {}; DecomposedValues values; // First, isolate perspective. if (matrix(3, 0) != 0.f || matrix(3, 1) != 0.f || matrix(3, 2) != 0.f) { // rightHandSide is the right hand side of the equation. // Note: It is the bottom side in a row-major matrix FloatVector4 bottom_side = { matrix(3, 0), matrix(3, 1), matrix(3, 2), matrix(3, 3), }; // Solve the equation by inverting perspectiveMatrix and multiplying // rightHandSide by the inverse. auto inverse_perspective_matrix = perspective_matrix.inverse(); auto transposed_inverse_perspective_matrix = inverse_perspective_matrix.transpose(); values.perspective = transposed_inverse_perspective_matrix * bottom_side; } else { // No perspective. values.perspective = { 0.0, 0.0, 0.0, 1.0 }; } // Next take care of translation for (int i = 0; i < 3; i++) values.translation[i] = matrix(i, 3); // Now get scale and shear. 'row' is a 3 element array of 3 component vectors FloatVector3 row[3]; for (int i = 0; i < 3; i++) row[i] = { matrix(0, i), matrix(1, i), matrix(2, i) }; // Compute X scale factor and normalize first row. values.scale[0] = row[0].length(); row[0].normalize(); // Compute XY shear factor and make 2nd row orthogonal to 1st. values.skew[0] = row[0].dot(row[1]); row[1] = combine(row[1], row[0], 1.f, -values.skew[0]); // Now, compute Y scale and normalize 2nd row. values.scale[1] = row[1].length(); row[1].normalize(); values.skew[0] /= values.scale[1]; // Compute XZ and YZ shears, orthogonalize 3rd row values.skew[1] = row[0].dot(row[2]); row[2] = combine(row[2], row[0], 1.f, -values.skew[1]); values.skew[2] = row[1].dot(row[2]); row[2] = combine(row[2], row[1], 1.f, -values.skew[2]); // Next, get Z scale and normalize 3rd row. values.scale[2] = row[2].length(); row[2].normalize(); values.skew[1] /= values.scale[2]; values.skew[2] /= values.scale[2]; // At this point, the matrix (in rows) is orthonormal. // Check for a coordinate system flip. If the determinant // is -1, then negate the matrix and the scaling factors. auto pdum3 = row[1].cross(row[2]); if (row[0].dot(pdum3) < 0.f) { for (int i = 0; i < 3; i++) { values.scale[i] *= -1.f; row[i][0] *= -1.f; row[i][1] *= -1.f; row[i][2] *= -1.f; } } // Now, get the rotations out values.rotation[0] = 0.5f * sqrt(max(1.f + row[0][0] - row[1][1] - row[2][2], 0.f)); values.rotation[1] = 0.5f * sqrt(max(1.f - row[0][0] + row[1][1] - row[2][2], 0.f)); values.rotation[2] = 0.5f * sqrt(max(1.f - row[0][0] - row[1][1] + row[2][2], 0.f)); values.rotation[3] = 0.5f * sqrt(max(1.f + row[0][0] + row[1][1] + row[2][2], 0.f)); if (row[2][1] > row[1][2]) values.rotation[0] = -values.rotation[0]; if (row[0][2] > row[2][0]) values.rotation[1] = -values.rotation[1]; if (row[1][0] > row[0][1]) values.rotation[2] = -values.rotation[2]; // FIXME: This accounts for the fact that the browser coordinate system is left-handed instead of right-handed. // The reason for this is that the positive Y-axis direction points down instead of up. To fix this, we // invert the Y axis. However, it feels like the spec pseudo-code above should have taken something like // this into account, so we're probably doing something else wrong. values.rotation[2] *= -1; return values; }; // https://drafts.csswg.org/css-transforms-2/#recomposing-to-a-3d-matrix static constexpr auto recompose = [](DecomposedValues const& values) -> FloatMatrix4x4 { auto matrix = FloatMatrix4x4::identity(); // apply perspective for (int i = 0; i < 4; i++) matrix(3, i) = values.perspective[i]; // apply translation for (int i = 0; i < 4; i++) { for (int j = 0; j < 3; j++) matrix(i, 3) += values.translation[j] * matrix(i, j); } // apply rotation auto x = values.rotation[0]; auto y = values.rotation[1]; auto z = values.rotation[2]; auto w = values.rotation[3]; // Construct a composite rotation matrix from the quaternion values // rotationMatrix is a identity 4x4 matrix initially auto rotation_matrix = FloatMatrix4x4::identity(); rotation_matrix(0, 0) = 1.f - 2.f * (y * y + z * z); rotation_matrix(1, 0) = 2.f * (x * y - z * w); rotation_matrix(2, 0) = 2.f * (x * z + y * w); rotation_matrix(0, 1) = 2.f * (x * y + z * w); rotation_matrix(1, 1) = 1.f - 2.f * (x * x + z * z); rotation_matrix(2, 1) = 2.f * (y * z - x * w); rotation_matrix(0, 2) = 2.f * (x * z - y * w); rotation_matrix(1, 2) = 2.f * (y * z + x * w); rotation_matrix(2, 2) = 1.f - 2.f * (x * x + y * y); matrix = matrix * rotation_matrix; // apply skew // temp is a identity 4x4 matrix initially auto temp = FloatMatrix4x4::identity(); if (values.skew[2] != 0.f) { temp(1, 2) = values.skew[2]; matrix = matrix * temp; } if (values.skew[1] != 0.f) { temp(1, 2) = 0.f; temp(0, 2) = values.skew[1]; matrix = matrix * temp; } if (values.skew[0] != 0.f) { temp(0, 2) = 0.f; temp(0, 1) = values.skew[0]; matrix = matrix * temp; } // apply scale for (int i = 0; i < 3; i++) { for (int j = 0; j < 4; j++) matrix(j, i) *= values.scale[i]; } return matrix; }; // https://drafts.csswg.org/css-transforms-2/#interpolation-of-decomposed-3d-matrix-values static constexpr auto interpolate = [](DecomposedValues& from, DecomposedValues& to, float delta) -> DecomposedValues { auto product = clamp(from.rotation.dot(to.rotation), -1.0f, 1.0f); FloatVector4 interpolated_rotation; if (fabsf(product) == 1.0f) { interpolated_rotation = from.rotation; } else { auto theta = acos(product); auto w = sin(delta * theta) / sqrtf(1.0f - product * product); for (int i = 0; i < 4; i++) { from.rotation[i] *= cos(delta * theta) - product * w; to.rotation[i] *= w; interpolated_rotation[i] = from.rotation[i] + to.rotation[i]; } } return { interpolate_raw(from.translation, to.translation, delta), interpolate_raw(from.scale, to.scale, delta), interpolate_raw(from.skew, to.skew, delta), interpolated_rotation, interpolate_raw(from.perspective, to.perspective, delta), }; }; auto from_matrix = style_value_to_matrix(element, from); auto to_matrix = style_value_to_matrix(element, to); auto from_decomposed = decompose(from_matrix); auto to_decomposed = decompose(to_matrix); if (!from_decomposed.has_value() || !to_decomposed.has_value()) return {}; auto interpolated_decomposed = interpolate(from_decomposed.value(), to_decomposed.value(), delta); auto interpolated = recompose(interpolated_decomposed); StyleValueVector values; values.ensure_capacity(16); for (int i = 0; i < 16; i++) values.append(NumberStyleValue::create(static_cast(interpolated(i % 4, i / 4)))); return StyleValueList::create({ TransformationStyleValue::create(TransformFunction::Matrix3d, move(values)) }, StyleValueList::Separator::Comma); } static Color interpolate_color(Color from, Color to, float delta) { // https://drafts.csswg.org/css-color/#interpolation-space // If the host syntax does not define what color space interpolation should take place in, it defaults to Oklab. auto from_oklab = from.to_oklab(); auto to_oklab = to.to_oklab(); auto color = Color::from_oklab( interpolate_raw(from_oklab.L, to_oklab.L, delta), interpolate_raw(from_oklab.a, to_oklab.a, delta), interpolate_raw(from_oklab.b, to_oklab.b, delta)); color.set_alpha(interpolate_raw(from.alpha(), to.alpha(), delta)); return color; } static NonnullRefPtr interpolate_box_shadow(DOM::Element& element, StyleValue const& from, StyleValue const& to, float delta) { // https://drafts.csswg.org/css-backgrounds/#box-shadow // Animation type: by computed value, treating none as a zero-item list and appending blank shadows // (transparent 0 0 0 0) with a corresponding inset keyword as needed to match the longer list if // the shorter list is otherwise compatible with the longer one static constexpr auto process_list = [](StyleValue const& value) { StyleValueVector shadows; if (value.is_value_list()) { for (auto const& element : value.as_value_list().values()) { if (element->is_shadow()) shadows.append(element); } } else if (value.is_shadow()) { shadows.append(value); } else if (!value.is_identifier() || value.as_identifier().id() != ValueID::None) { VERIFY_NOT_REACHED(); } return shadows; }; static constexpr auto extend_list_if_necessary = [](StyleValueVector& values, StyleValueVector const& other) { values.ensure_capacity(other.size()); for (size_t i = values.size(); i < other.size(); i++) { values.unchecked_append(ShadowStyleValue::create( Color::Transparent, LengthStyleValue::create(Length::make_px(0)), LengthStyleValue::create(Length::make_px(0)), LengthStyleValue::create(Length::make_px(0)), LengthStyleValue::create(Length::make_px(0)), other[i]->as_shadow().placement())); } }; StyleValueVector from_shadows = process_list(from); StyleValueVector to_shadows = process_list(to); extend_list_if_necessary(from_shadows, to_shadows); extend_list_if_necessary(to_shadows, from_shadows); VERIFY(from_shadows.size() == to_shadows.size()); StyleValueVector result_shadows; result_shadows.ensure_capacity(from_shadows.size()); for (size_t i = 0; i < from_shadows.size(); i++) { auto const& from_shadow = from_shadows[i]->as_shadow(); auto const& to_shadow = to_shadows[i]->as_shadow(); auto result_shadow = ShadowStyleValue::create( interpolate_color(from_shadow.color(), to_shadow.color(), delta), interpolate_value(element, from_shadow.offset_x(), to_shadow.offset_x(), delta), interpolate_value(element, from_shadow.offset_y(), to_shadow.offset_y(), delta), interpolate_value(element, from_shadow.blur_radius(), to_shadow.blur_radius(), delta), interpolate_value(element, from_shadow.spread_distance(), to_shadow.spread_distance(), delta), delta >= 0.5f ? to_shadow.placement() : from_shadow.placement()); result_shadows.unchecked_append(result_shadow); } return StyleValueList::create(move(result_shadows), StyleValueList::Separator::Comma); } static NonnullRefPtr interpolate_value(DOM::Element& element, StyleValue const& from, StyleValue const& to, float delta) { if (from.type() != to.type()) return delta >= 0.5f ? to : from; switch (from.type()) { case StyleValue::Type::Angle: return AngleStyleValue::create(Angle::make_degrees(interpolate_raw(from.as_angle().angle().to_degrees(), to.as_angle().angle().to_degrees(), delta))); case StyleValue::Type::Color: return ColorStyleValue::create(interpolate_color(from.as_color().color(), to.as_color().color(), delta)); case StyleValue::Type::Integer: return IntegerStyleValue::create(interpolate_raw(from.as_integer().integer(), to.as_integer().integer(), delta)); case StyleValue::Type::Length: { auto& from_length = from.as_length().length(); auto& to_length = to.as_length().length(); return LengthStyleValue::create(Length(interpolate_raw(from_length.raw_value(), to_length.raw_value(), delta), from_length.type())); } case StyleValue::Type::Number: return NumberStyleValue::create(interpolate_raw(from.as_number().number(), to.as_number().number(), delta)); case StyleValue::Type::Percentage: return PercentageStyleValue::create(Percentage(interpolate_raw(from.as_percentage().percentage().value(), to.as_percentage().percentage().value(), delta))); case StyleValue::Type::Position: { // https://www.w3.org/TR/css-values-4/#combine-positions // FIXME: Interpolation of is defined as the independent interpolation of each component (x, y) normalized as an offset from the top left corner as a . auto& from_position = from.as_position(); auto& to_position = to.as_position(); return PositionStyleValue::create( interpolate_value(element, from_position.edge_x(), to_position.edge_x(), delta)->as_edge(), interpolate_value(element, from_position.edge_y(), to_position.edge_y(), delta)->as_edge()); } case StyleValue::Type::Ratio: { auto from_ratio = from.as_ratio().ratio(); auto to_ratio = to.as_ratio().ratio(); // The interpolation of a is defined by converting each to a number by dividing the first value // by the second (so a ratio of 3 / 2 would become 1.5), taking the logarithm of that result (so the 1.5 would // become approximately 0.176), then interpolating those values. The result during the interpolation is // converted back to a by inverting the logarithm, then interpreting the result as a with the // result as the first value and 1 as the second value. auto from_number = log(from_ratio.value()); auto to_number = log(to_ratio.value()); auto interp_number = interpolate_raw(from_number, to_number, delta); return RatioStyleValue::create(Ratio(pow(M_E, interp_number))); } case StyleValue::Type::Rect: { auto from_rect = from.as_rect().rect(); auto to_rect = to.as_rect().rect(); return RectStyleValue::create({ Length(interpolate_raw(from_rect.top_edge.raw_value(), to_rect.top_edge.raw_value(), delta), from_rect.top_edge.type()), Length(interpolate_raw(from_rect.right_edge.raw_value(), to_rect.right_edge.raw_value(), delta), from_rect.right_edge.type()), Length(interpolate_raw(from_rect.bottom_edge.raw_value(), to_rect.bottom_edge.raw_value(), delta), from_rect.bottom_edge.type()), Length(interpolate_raw(from_rect.left_edge.raw_value(), to_rect.left_edge.raw_value(), delta), from_rect.left_edge.type()), }); } case StyleValue::Type::Transformation: VERIFY_NOT_REACHED(); case StyleValue::Type::ValueList: { auto& from_list = from.as_value_list(); auto& to_list = to.as_value_list(); if (from_list.size() != to_list.size()) return from; StyleValueVector interpolated_values; interpolated_values.ensure_capacity(from_list.size()); for (size_t i = 0; i < from_list.size(); ++i) interpolated_values.append(interpolate_value(element, from_list.values()[i], to_list.values()[i], delta)); return StyleValueList::create(move(interpolated_values), from_list.separator()); } default: return from; } } static ValueComparingRefPtr interpolate_property(DOM::Element& element, PropertyID property_id, StyleValue const& from, StyleValue const& to, float delta) { auto animation_type = animation_type_from_longhand_property(property_id); switch (animation_type) { case AnimationType::ByComputedValue: return interpolate_value(element, from, to, delta); case AnimationType::None: return to; case AnimationType::Custom: { if (property_id == PropertyID::Transform) { if (auto interpolated_transform = interpolate_transform(element, from, to, delta)) return *interpolated_transform; // https://drafts.csswg.org/css-transforms-1/#interpolation-of-transforms // In some cases, an animation might cause a transformation matrix to be singular or non-invertible. // For example, an animation in which scale moves from 1 to -1. At the time when the matrix is in // such a state, the transformed element is not rendered. return {}; } if (property_id == PropertyID::BoxShadow) return interpolate_box_shadow(element, from, to, delta); // FIXME: Handle all custom animatable properties [[fallthrough]]; } // FIXME: Handle repeatable-list animatable properties case AnimationType::RepeatableList: case AnimationType::Discrete: default: return delta >= 0.5f ? to : from; } } void StyleComputer::collect_animation_into(JS::NonnullGCPtr effect, StyleProperties& style_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; auto key = static_cast(output_progress.value() * 100.0 * Animations::KeyframeEffect::AnimationKeyFrameKeyScaleFactor); auto matching_keyframe_it = keyframes.find_largest_not_above_iterator(key); if (matching_keyframe_it.is_end()) { if constexpr (LIBWEB_CSS_ANIMATION_DEBUG) { dbgln(" Did not find any start keyframe for the current state ({}) :(", key); dbgln(" (have {} keyframes)", keyframes.size()); for (auto it = keyframes.begin(); it != keyframes.end(); ++it) dbgln(" - {}", it.key()); } return; } auto keyframe_start = matching_keyframe_it.key(); auto keyframe_values = *matching_keyframe_it; auto initial_keyframe_it = matching_keyframe_it; auto keyframe_end_it = ++matching_keyframe_it; if (keyframe_end_it.is_end()) keyframe_end_it = initial_keyframe_it; auto keyframe_end = keyframe_end_it.key(); auto keyframe_end_values = *keyframe_end_it; auto progress_in_keyframe = [&] { if (keyframe_start == keyframe_end) return 0.f; return static_cast(key - keyframe_start) / static_cast(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); } for (auto const& it : keyframe_values.properties) { auto resolve_property = [&](auto& property) { return property.visit( [&](Animations::KeyframeEffect::KeyFrameSet::UseInitial) -> RefPtr { if (refresh == AnimationRefresh::Yes) return {}; return style_properties.maybe_null_property(it.key); }, [&](RefPtr value) { return value; }); }; auto resolved_start_property = resolve_property(it.value); auto const& end_property = keyframe_end_values.properties.get(it.key); if (!end_property.has_value()) { if (resolved_start_property) { style_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()); } continue; } auto resolved_end_property = resolve_property(end_property.value()); if (resolved_end_property && !resolved_start_property) resolved_start_property = CSS::property_initial_value(document().realm(), 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 (style_properties.is_property_important(it.key)) { continue; } if (auto next_value = interpolate_property(*effect->target(), it.key, *start, *end, progress_in_keyframe)) { dbgln_if(LIBWEB_CSS_ANIMATION_DEBUG, "Interpolated value for property {} at {}: {} -> {} = {}", string_from_property_id(it.key), progress_in_keyframe, start->to_string(), end->to_string(), next_value->to_string()); style_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(), end->to_string()); style_properties.set_animated_property(PropertyID::Visibility, IdentifierStyleValue::create(ValueID::Hidden)); } } } static void apply_animation_properties(DOM::Document& document, StyleProperties& style, Animations::Animation& animation) { auto& effect = verify_cast(*animation.effect()); Optional duration; if (auto duration_value = style.maybe_null_property(PropertyID::AnimationDuration); duration_value) { if (duration_value->is_time()) { duration = duration_value->as_time().time(); } else if (duration_value->is_identifier() && duration_value->as_identifier().id() == ValueID::Auto) { // We use empty optional to represent "auto". duration = {}; } } CSS::Time delay { 0, CSS::Time::Type::S }; if (auto delay_value = style.maybe_null_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 = style.maybe_null_property(PropertyID::AnimationIterationCount); iteration_count_value) { if (iteration_count_value->is_identifier() && iteration_count_value->to_identifier() == ValueID::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 = style.maybe_null_property(PropertyID::AnimationFillMode); fill_mode_property && fill_mode_property->is_identifier()) { if (auto fill_mode_value = value_id_to_animation_fill_mode(fill_mode_property->to_identifier()); fill_mode_value.has_value()) fill_mode = *fill_mode_value; } CSS::AnimationDirection direction { CSS::AnimationDirection::Normal }; if (auto direction_property = style.maybe_null_property(PropertyID::AnimationDirection); direction_property && direction_property->is_identifier()) { if (auto direction_value = value_id_to_animation_direction(direction_property->to_identifier()); direction_value.has_value()) direction = *direction_value; } CSS::AnimationPlayState play_state { CSS::AnimationPlayState::Running }; if (auto play_state_property = style.maybe_null_property(PropertyID::AnimationPlayState); play_state_property && play_state_property->is_identifier()) { if (auto play_state_value = value_id_to_animation_play_state(play_state_property->to_identifier()); play_state_value.has_value()) play_state = *play_state_value; } Animations::TimingFunction timing_function = Animations::ease_timing_function; if (auto timing_property = style.maybe_null_property(PropertyID::AnimationTimingFunction); timing_property && timing_property->is_easing()) timing_function = Animations::TimingFunction::from_easing_style_value(timing_property->as_easing()); auto iteration_duration = duration.has_value() ? Variant { 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)); HTML::TemporaryExecutionContext context(document.relevant_settings_object()); if (play_state == CSS::AnimationPlayState::Running && !animation.is_relevant()) { animation.play().release_value_but_fixme_should_propagate_errors(); } else if (play_state == CSS::AnimationPlayState::Paused && animation.play_state() != Bindings::AnimationPlayState::Paused) { animation.pause().release_value_but_fixme_should_propagate_errors(); } } // https://www.w3.org/TR/css-cascade/#cascading void StyleComputer::compute_cascaded_values(StyleProperties& style, DOM::Element& element, Optional pseudo_element, bool& did_match_any_pseudo_element_rules, ComputeStyleMode mode) const { // 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); sort_matching_rules(matching_rule_set.user_agent_rules); matching_rule_set.user_rules = collect_matching_rules(element, CascadeOrigin::User, pseudo_element); sort_matching_rules(matching_rule_set.user_rules); matching_rule_set.author_rules = collect_matching_rules(element, CascadeOrigin::Author, pseudo_element); sort_matching_rules(matching_rule_set.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; } did_match_any_pseudo_element_rules = true; } // Then we resolve all the CSS custom properties ("variables") for this element: cascade_custom_properties(element, pseudo_element, matching_rule_set.author_rules); // Then we apply the declarations from the matched rules in cascade order: // Normal user agent declarations cascade_declarations(style, element, pseudo_element, matching_rule_set.user_agent_rules, CascadeOrigin::UserAgent, Important::No); // Normal user declarations cascade_declarations(style, element, pseudo_element, matching_rule_set.user_rules, CascadeOrigin::User, Important::No); // Author presentational hints (NOTE: The spec doesn't say exactly how to prioritize these.) if (!pseudo_element.has_value()) { element.apply_presentational_hints(style); // SVG presentation attributes are parsed as CSS values, so we need to handle potential custom properties here. if (element.is_svg_element()) { // FIXME: This is not very efficient, we should only resolve the custom properties that are actually used. for (auto i = to_underlying(CSS::first_property_id); i <= to_underlying(CSS::last_property_id); ++i) { auto property_id = (CSS::PropertyID)i; auto& property = style.m_property_values[i]; if (property.style && property.style->is_unresolved()) property.style = Parser::Parser::resolve_unresolved_style_value({}, Parser::ParsingContext { document() }, element, pseudo_element, property_id, property.style->as_unresolved()); } } } // Normal author declarations cascade_declarations(style, element, pseudo_element, matching_rule_set.author_rules, CascadeOrigin::Author, Important::No); // Animation declarations [css-animations-2] auto animation_name = [&]() -> Optional { auto animation_name = style.maybe_null_property(PropertyID::AnimationName); if (animation_name.is_null()) return OptionalNone {}; if (animation_name->is_string()) return animation_name->as_string().string_value(); return animation_name->to_string(); }(); if (animation_name.has_value()) { if (auto source_declaration = style.property_source_declaration(PropertyID::AnimationName); source_declaration) { auto& realm = element.realm(); if (source_declaration != element.cached_animation_name_source()) { // This animation name is new, so we need to create a new animation for it. if (auto existing_animation = element.cached_animation_name_animation()) existing_animation->cancel(Animations::Animation::ShouldInvalidate::No); element.set_cached_animation_name_source(source_declaration); 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, style, animation); if (pseudo_element.has_value()) effect->set_pseudo_element(Selector::PseudoElement { pseudo_element.value() }); auto const& 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); } else { // The animation hasn't changed, but some properties of the animation may have apply_animation_properties(m_document, style, *element.cached_animation_name_animation()); } } } else { // If the element had an existing animation, cancel it if (auto existing_animation = element.cached_animation_name_animation()) { existing_animation->cancel(Animations::Animation::ShouldInvalidate::No); element.set_cached_animation_name_animation({}); element.set_cached_animation_name_source({}); } } auto animations = element.get_animations({ .subtree = false }); for (auto& animation : animations) { if (!animation->is_relevant()) continue; if (auto effect = animation->effect(); effect && effect->is_keyframe_effect()) { auto& keyframe_effect = *static_cast(effect.ptr()); if (keyframe_effect.pseudo_element_type() == pseudo_element) collect_animation_into(keyframe_effect, style); } } // Important author declarations cascade_declarations(style, element, pseudo_element, matching_rule_set.author_rules, CascadeOrigin::Author, Important::Yes); // Important user declarations cascade_declarations(style, element, pseudo_element, matching_rule_set.user_rules, CascadeOrigin::User, Important::Yes); // Important user agent declarations cascade_declarations(style, element, pseudo_element, matching_rule_set.user_agent_rules, CascadeOrigin::UserAgent, Important::Yes); // FIXME: Transition declarations [css-transitions-1] } DOM::Element const* element_to_inherit_style_from(DOM::Element const* element, Optional 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 StyleComputer::get_inherit_value(JS::Realm& initial_value_context_realm, CSS::PropertyID property_id, DOM::Element const* element, Optional pseudo_element) { auto* parent_element = element_to_inherit_style_from(element, pseudo_element); if (!parent_element || !parent_element->computed_css_values()) return property_initial_value(initial_value_context_realm, property_id); return parent_element->computed_css_values()->property(property_id); } void StyleComputer::compute_defaulted_property_value(StyleProperties& style, DOM::Element const* element, CSS::PropertyID property_id, Optional pseudo_element) const { // FIXME: If we don't know the correct initial value for a property, we fall back to InitialStyleValue. auto& value_slot = style.m_property_values[to_underlying(property_id)]; if (!value_slot.style) { if (is_inherited_property(property_id)) style.m_property_values[to_underlying(property_id)] = { get_inherit_value(document().realm(), property_id, element, pseudo_element), nullptr, StyleProperties::Important::No, StyleProperties::Inherited::Yes }; else style.m_property_values[to_underlying(property_id)] = { property_initial_value(document().realm(), property_id), nullptr }; return; } if (value_slot.style->is_initial()) { value_slot.style = property_initial_value(document().realm(), property_id); return; } if (value_slot.style->is_inherit()) { value_slot.style = get_inherit_value(document().realm(), property_id, element, pseudo_element); value_slot.inherited = StyleProperties::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.style->is_unset()) { if (is_inherited_property(property_id)) { // then if it is an inherited property, this is treated as inherit, value_slot.style = get_inherit_value(document().realm(), property_id, element, pseudo_element); value_slot.inherited = StyleProperties::Inherited::Yes; } else { // and if it is not, this is treated as initial. value_slot.style = property_initial_value(document().realm(), property_id); } } } // https://www.w3.org/TR/css-cascade/#defaulting void StyleComputer::compute_defaulted_values(StyleProperties& style, DOM::Element const* element, Optional 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 color = style.property(CSS::PropertyID::Color); if (color->to_identifier() == CSS::ValueID::Currentcolor) { color = get_inherit_value(document().realm(), CSS::PropertyID::Color, element, pseudo_element); style.set_property(CSS::PropertyID::Color, color); } } Length::FontMetrics StyleComputer::calculate_root_element_font_metrics(StyleProperties const& style) const { auto 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 StyleComputer::find_matching_font_weight_ascending(Vector const& candidates, int target_weight, float font_size_in_pt, bool inclusive) { using Fn = AK::Function; 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 StyleComputer::find_matching_font_weight_descending(Vector const& candidates, int target_weight, float font_size_in_pt, bool inclusive) { using Fn = AK::Function; 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 StyleComputer::font_matching_algorithm(FontFaceKey const& key, 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 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(key.family_name)) matching_family_fonts.empend(font_key_and_loader.key, const_cast(&font_key_and_loader.value)); } Gfx::FontDatabase::the().for_each_typeface_with_family_name(key.family_name, [&](Gfx::Typeface const& typeface) { matching_family_fonts.empend( FontFaceKey { .family_name = typeface.family(), .weight = static_cast(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 == key.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 != key.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 (key.weight >= 400 && key.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 >= key.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, key.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 (key.weight < 400) { if (auto found_font = find_matching_font_weight_descending(matching_family_fonts, key.weight, font_size_in_pt, true)) return found_font; if (auto found_font = find_matching_font_weight_ascending(matching_family_fonts, key.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 (key.weight > 500) { if (auto found_font = find_matching_font_weight_ascending(matching_family_fonts, key.weight, font_size_in_pt, true)) return found_font; if (auto found_font = find_matching_font_weight_descending(matching_family_fonts, key.weight, font_size_in_pt, false)) return found_font; } return {}; } RefPtr StyleComputer::compute_font_for_style_values(DOM::Element const* element, Optional pseudo_element, StyleValue const& font_family, StyleValue const& font_size, StyleValue const& font_style, StyleValue const& font_weight, StyleValue const& font_stretch, int math_depth) const { auto* parent_element = element_to_inherit_style_from(element, pseudo_element); auto width = font_stretch.to_font_stretch_width(); auto weight = font_weight.to_font_weight(); bool bold = weight > Gfx::FontWeight::Regular; // FIXME: Should be based on "user's default font size" CSSPixels font_size_in_px = 16; Gfx::FontPixelMetrics font_pixel_metrics; if (parent_element && parent_element->computed_css_values()) font_pixel_metrics = parent_element->computed_css_values()->first_available_computed_font().pixel_metrics(); else font_pixel_metrics = Platform::FontPlugin::the().default_font().pixel_metrics(); auto parent_font_size = [&]() -> CSSPixels { if (!parent_element || !parent_element->computed_css_values()) return font_size_in_px; auto value = parent_element->computed_css_values()->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, m_root_element_font_metrics); } } return font_size_in_px; }; Length::FontMetrics font_metrics { parent_font_size(), font_pixel_metrics }; if (font_size.is_identifier()) { // https://w3c.github.io/csswg-drafts/css-fonts/#absolute-size-mapping auto get_absolute_size_mapping = [](Web::CSS::ValueID identifier) -> CSSPixelFraction { switch (identifier) { case CSS::ValueID::XxSmall: return CSSPixels(3) / 5; case CSS::ValueID::XSmall: return CSSPixels(3) / 4; case CSS::ValueID::Small: return CSSPixels(8) / 9; case CSS::ValueID::Medium: return 1; case CSS::ValueID::Large: return CSSPixels(6) / 5; case CSS::ValueID::XLarge: return CSSPixels(3) / 2; case CSS::ValueID::XxLarge: return 2; case CSS::ValueID::XxxLarge: return 3; case CSS::ValueID::Smaller: return CSSPixels(4) / 5; case CSS::ValueID::Larger: return CSSPixels(5) / 4; default: return 1; } }; auto const identifier = static_cast(font_size).id(); if (identifier == ValueID::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_css_values() ? parent_element->computed_css_values()->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 (identifier == CSS::ValueID::Smaller || identifier == CSS::ValueID::Larger) { if (parent_element && parent_element->computed_css_values()) { font_size_in_px = CSSPixels::nearest_value_for(parent_element->computed_css_values()->first_available_computed_font().pixel_metrics().size); } } font_size_in_px *= get_absolute_size_mapping(identifier); } } else { Length::ResolutionContext const length_resolution_context { .viewport_rect = viewport_rect(), .font_metrics = font_metrics, .root_font_metrics = m_root_element_font_metrics, }; Optional 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()) { if (font_size.as_calculated().contains_percentage()) { maybe_length = font_size.as_calculated().resolve_length_percentage(length_resolution_context, Length::make_px(parent_font_size())); } else { maybe_length = font_size.as_calculated().resolve_length(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 // Note: This is modified by the find_font() lambda bool monospace = false; float const font_size_in_pt = font_size_in_px * 0.75f; auto find_font = [&](FlyString const& family) -> RefPtr { 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(key, 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, Gfx::Font::AllowInexactSizeMatch::Yes)) { result->add(*found_font); return result; } return {}; }; auto find_generic_font = [&](ValueID font_id) -> RefPtr { Platform::GenericFont generic_font {}; switch (font_id) { case ValueID::Monospace: case ValueID::UiMonospace: generic_font = Platform::GenericFont::Monospace; monospace = true; break; case ValueID::Serif: generic_font = Platform::GenericFont::Serif; break; case ValueID::Fantasy: generic_font = Platform::GenericFont::Fantasy; break; case ValueID::SansSerif: generic_font = Platform::GenericFont::SansSerif; break; case ValueID::Cursive: generic_font = Platform::GenericFont::Cursive; break; case ValueID::UiSerif: generic_font = Platform::GenericFont::UiSerif; break; case ValueID::UiSansSerif: generic_font = Platform::GenericFont::UiSansSerif; break; case ValueID::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(font_family).values(); for (auto const& family : family_list) { RefPtr other_font_list; if (family->is_identifier()) { other_font_list = find_generic_font(family->to_identifier()); } 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_identifier()) { if (auto other_font_list = find_generic_font(font_family.to_identifier())) 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 found_font = StyleProperties::font_fallback(monospace, bold); if (auto scaled_fallback_font = found_font->with_size(font_size_in_pt)) { font_list->add(*scaled_fallback_font); } else { font_list->add(*found_font); } return font_list; } void StyleComputer::compute_font(StyleProperties& style, DOM::Element const* element, Optional 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::FontStretch, 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); auto font_family = style.property(CSS::PropertyID::FontFamily); auto font_size = style.property(CSS::PropertyID::FontSize); auto font_style = style.property(CSS::PropertyID::FontStyle); auto font_weight = style.property(CSS::PropertyID::FontWeight); auto font_stretch = style.property(CSS::PropertyID::FontStretch); auto font_list = compute_font_for_style_values(element, pseudo_element, font_family, font_size, font_style, font_weight, font_stretch, style.math_depth()); VERIFY(font_list); VERIFY(!font_list->is_empty()); RefPtr 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()))), nullptr); style.set_property(CSS::PropertyID::FontWeight, NumberStyleValue::create(font_weight->to_font_weight())); style.set_computed_font_list(*font_list); if (element && is(*element)) { const_cast(*this).m_root_element_font_metrics = calculate_root_element_font_metrics(style); } } Gfx::Font const& StyleComputer::initial_font() const { // FIXME: This is not correct. return StyleProperties::font_fallback(false, false); } void StyleComputer::absolutize_values(StyleProperties& style) const { Length::FontMetrics font_metrics { m_root_element_font_metrics.font_size, style.first_available_computed_font().pixel_metrics() }; auto font_size = style.property(CSS::PropertyID::FontSize)->as_length().length().to_px(viewport_rect(), font_metrics, m_root_element_font_metrics); font_metrics.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)].style; 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(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.style) continue; value_slot.style = value_slot.style->absolutized(viewport_rect(), font_metrics, m_root_element_font_metrics); } style.set_line_height({}, line_height); } void StyleComputer::resolve_effective_overflow_values(StyleProperties& 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 = value_id_to_overflow(style.property(PropertyID::OverflowX)->to_identifier()); auto overflow_y = value_id_to_overflow(style.property(PropertyID::OverflowY)->to_identifier()); 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, IdentifierStyleValue::create(CSS::ValueID::Auto), nullptr); if (overflow_x == CSS::Overflow::Clip) style.set_property(CSS::PropertyID::OverflowX, IdentifierStyleValue::create(CSS::ValueID::Hidden), nullptr); if (overflow_y == CSS::Overflow::Visible) style.set_property(CSS::PropertyID::OverflowY, IdentifierStyleValue::create(CSS::ValueID::Auto), nullptr); if (overflow_y == CSS::Overflow::Clip) style.set_property(CSS::PropertyID::OverflowY, IdentifierStyleValue::create(CSS::ValueID::Hidden), nullptr); } } enum class BoxTypeTransformation { None, Blockify, Inlinify, }; static BoxTypeTransformation required_box_type_transformation(StyleProperties const& style, DOM::Element const& element, Optional const& pseudo_element) { // NOTE: We never blockify
elements. They are always inline. // There is currently no way to express in CSS how a
element really behaves. // Spec issue: https://github.com/whatwg/html/issues/2291 if (is(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 const* parent = pseudo_element.has_value() ? &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_css_values()) { auto const& parent_display = parent->computed_css_values()->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(StyleProperties& style, DOM::Element const& element, Optional 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()) 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), style.property_source_declaration(CSS::PropertyID::Display)); } NonnullRefPtr StyleComputer::create_document_style() const { auto style = StyleProperties::create(); compute_math_depth(style, nullptr, {}); compute_font(style, nullptr, {}); compute_defaulted_values(style, nullptr, {}); absolutize_values(style); style->set_property(CSS::PropertyID::Width, CSS::LengthStyleValue::create(CSS::Length::make_px(viewport_rect().width())), nullptr); style->set_property(CSS::PropertyID::Height, CSS::LengthStyleValue::create(CSS::Length::make_px(viewport_rect().height())), nullptr); style->set_property(CSS::PropertyID::Display, CSS::DisplayStyleValue::create(CSS::Display::from_short(CSS::Display::Short::Block)), nullptr); return style; } NonnullRefPtr StyleComputer::compute_style(DOM::Element& element, Optional pseudo_element) const { return compute_style_impl(element, move(pseudo_element), ComputeStyleMode::Normal).release_nonnull(); } RefPtr StyleComputer::compute_pseudo_element_style_if_needed(DOM::Element& element, Optional pseudo_element) const { return compute_style_impl(element, move(pseudo_element), ComputeStyleMode::CreatePseudoElementStyleIfNeeded); } RefPtr StyleComputer::compute_style_impl(DOM::Element& element, Optional 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 = verify_cast(*element.root().parent_or_shadow_host()); auto style = compute_style(parent_element, *element.use_pseudo_element()); // Merge back inline styles if (element.has_attribute(HTML::AttributeNames::style)) { auto* inline_style = parse_css_style_attribute(CSS::Parser::ParsingContext(document()), *element.get_attribute(HTML::AttributeNames::style), element); for (auto const& property : inline_style->properties()) style->set_property(property.property_id, property.value); } return style; } auto style = StyleProperties::create(); // 1. Perform the cascade. This produces the "specified style" bool did_match_any_pseudo_element_rules = false; compute_cascaded_values(style, element, pseudo_element, did_match_any_pseudo_element_rules, mode); if (mode == ComputeStyleMode::CreatePseudoElementStyleIfNeeded && !did_match_any_pseudo_element_rules) return nullptr; // 2. Compute the math-depth property, since that might affect the font-size compute_math_depth(style, &element, pseudo_element); // 3. Compute the font, since that may be needed for font-relative CSS units compute_font(style, &element, pseudo_element); // 4. Absolutize values, turning font/viewport relative lengths into absolute lengths absolutize_values(style); // 5. Default the values, applying inheritance and 'initial' as needed compute_defaulted_values(style, &element, pseudo_element); // 6. Run automatic box type transformations transform_box_type_if_needed(style, element, pseudo_element); // 7. Resolve effective overflow values resolve_effective_overflow_values(style); // 8. Let the element adjust computed style element.adjust_computed_style(style); return style; } void StyleComputer::build_rule_cache_if_needed() const { if (m_author_rule_cache && m_user_rule_cache && m_user_agent_rule_cache) return; const_cast(*this).build_rule_cache(); } NonnullOwnPtr StyleComputer::make_rule_cache_for_cascade_origin(CascadeOrigin cascade_origin) { auto rule_cache = make(); size_t num_class_rules = 0; size_t num_id_rules = 0; size_t num_tag_name_rules = 0; size_t num_pseudo_element_rules = 0; size_t num_root_rules = 0; size_t num_attribute_rules = 0; Vector matching_rules; size_t style_sheet_index = 0; for_each_stylesheet(cascade_origin, [&](auto& sheet, JS::GCPtr shadow_root) { size_t rule_index = 0; sheet.for_each_effective_style_rule([&](auto const& rule) { size_t selector_index = 0; for (CSS::Selector const& selector : rule.selectors()) { MatchingRule matching_rule { shadow_root, &rule, sheet, style_sheet_index, rule_index, selector_index, selector.specificity(), cascade_origin, false, false, SelectorEngine::can_use_fast_matches(selector), }; 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; ++num_pseudo_element_rules; } } if (!matching_rule.contains_root_pseudo_class) { if (simple_selector.type == CSS::Selector::SimpleSelector::Type::PseudoClass && simple_selector.pseudo_class().type == CSS::PseudoClass::Root) { matching_rule.contains_root_pseudo_class = true; ++num_root_rules; } } } bool added_to_bucket = false; for (auto const& simple_selector : selector.compound_selectors().last().simple_selectors) { if (simple_selector.type == CSS::Selector::SimpleSelector::Type::Id) { rule_cache->rules_by_id.ensure(simple_selector.name()).append(move(matching_rule)); ++num_id_rules; added_to_bucket = true; break; } if (simple_selector.type == CSS::Selector::SimpleSelector::Type::Class) { rule_cache->rules_by_class.ensure(simple_selector.name()).append(move(matching_rule)); ++num_class_rules; added_to_bucket = true; break; } if (simple_selector.type == CSS::Selector::SimpleSelector::Type::TagName) { rule_cache->rules_by_tag_name.ensure(simple_selector.qualified_name().name.lowercase_name).append(move(matching_rule)); ++num_tag_name_rules; added_to_bucket = true; break; } } if (!added_to_bucket) { if (matching_rule.contains_pseudo_element) { rule_cache->pseudo_element_rules.append(move(matching_rule)); } else if (matching_rule.contains_root_pseudo_class) { rule_cache->root_rules.append(move(matching_rule)); } else { for (auto const& simple_selector : selector.compound_selectors().last().simple_selectors) { if (simple_selector.type == CSS::Selector::SimpleSelector::Type::Attribute) { rule_cache->rules_by_attribute_name.ensure(simple_selector.attribute().qualified_name.name.lowercase_name).append(move(matching_rule)); ++num_attribute_rules; added_to_bucket = true; break; } } if (!added_to_bucket) { rule_cache->other_rules.append(move(matching_rule)); } } } ++selector_index; } ++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 animated_properties; // Forwards pass, resolve all the user-specified keyframe properties. for (auto const& keyframe : rule.keyframes()) { Animations::KeyframeEffect::KeyFrameSet::ResolvedKeyFrame resolved_keyframe; auto key = static_cast(keyframe->key().value() * Animations::KeyframeEffect::AnimationKeyFrameKeyScaleFactor); auto keyframe_rule = keyframe->style(); if (!is(*keyframe_rule)) continue; auto const& keyframe_style = static_cast(*keyframe_rule); for (auto const& it : keyframe_style.properties()) { for_each_property_expanding_shorthands(it.property_id, it.value, [&](PropertyID shorthand_id, StyleValue const& shorthand_value) { animated_properties.set(shorthand_id); resolved_keyframe.properties.set(shorthand_id, NonnullRefPtr { 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_cache->rules_by_animation_keyframes.set(rule.name(), move(keyframe_set)); }); ++style_sheet_index; }); size_t total_rules = num_class_rules + num_id_rules + num_tag_name_rules + num_pseudo_element_rules + num_root_rules + num_attribute_rules + rule_cache->other_rules.size(); if constexpr (LIBWEB_CSS_DEBUG) { dbgln("Built rule cache!"); dbgln(" ID: {}", num_id_rules); dbgln(" Class: {}", num_class_rules); dbgln(" TagName: {}", num_tag_name_rules); dbgln("PseudoElement: {}", num_pseudo_element_rules); dbgln(" Root: {}", num_root_rules); dbgln(" Attribute: {}", num_attribute_rules); dbgln(" Other: {}", rule_cache->other_rules.size()); dbgln(" Total: {}", total_rules); } return rule_cache; } void StyleComputer::build_rule_cache() { if (auto user_style_source = document().page().user_style(); user_style_source.has_value()) { m_user_style_sheet = JS::make_handle(parse_css_stylesheet(CSS::Parser::ParsingContext(document()), user_style_source.value())); } m_author_rule_cache = make_rule_cache_for_cascade_origin(CascadeOrigin::Author); m_user_rule_cache = make_rule_cache_for_cascade_origin(CascadeOrigin::User); m_user_agent_rule_cache = make_rule_cache_for_cascade_origin(CascadeOrigin::UserAgent); } 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; } void StyleComputer::did_load_font(FlyString const&) { document().invalidate_style(); } void StyleComputer::load_fonts_from_sheet(CSSStyleSheet const& sheet) { for (auto const& rule : static_cast(sheet).rules()) { if (!is(*rule)) continue; auto const& font_face = static_cast(*rule).font_face(); if (font_face.sources().is_empty()) continue; FontFaceKey key { .family_name = font_face.font_family(), .weight = font_face.weight().value_or(0), .slope = font_face.slope().value_or(0), }; Vector urls; for (auto& source : font_face.sources()) { // FIXME: These should be loaded relative to the stylesheet URL instead of the document URL. if (source.local_or_url.has()) urls.append(m_document->parse_url(MUST(source.local_or_url.get().to_string()))); // FIXME: Handle local() } if (urls.is_empty()) continue; auto loader = make(const_cast(*this), font_face.font_family(), font_face.unicode_ranges(), move(urls)); auto maybe_font_loaders_list = const_cast(*this).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)); const_cast(*this).m_loaded_fonts.set(key, move(loaders)); } } } void StyleComputer::compute_math_depth(StyleProperties& style, DOM::Element const* element, Optional 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_css_values()->math_depth(); }; auto value = style.property(CSS::PropertyID::MathDepth); if (!value->is_math_depth()) { style.set_math_depth(inherited_math_depth()); return; } auto& math_depth = value->as_math_depth(); auto resolve_integer = [&](StyleValue 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().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_identifier() == CSS::ValueID::Compact) { style.set_math_depth(inherited_math_depth() + 1); return; } // - If the specified value of math-depth is of the form add() 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 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()); } }