Stowage/ladybird
2
0
Fork 0
mirror of https://github.com/LadybirdBrowser/ladybird.git synced 2025-11-03 23:00:58 +00:00
Code Issues Projects Releases Packages Wiki Activity
ladybird/Userland/Libraries/LibWeb/CSS/Parser/Parser.cpp
Tobias Christiansen d00c7e55a5 LibWeb: Add plumbing for the new 'object-position' property 
Now, the 'object-position' property gets properly parsed and is
provided to the rest of the ecosystem.
In the parser we use the same parsing as for the background-position,
which is not entirely correct but almost a <position>.
2023-10-30 10:40:30 +00:00

7102 lines
302 KiB
C++
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

/*
* Copyright (c) 2018-2022, Andreas Kling <kling@serenityos.org>
* Copyright (c) 2020-2021, the SerenityOS developers.
* Copyright (c) 2021-2023, Sam Atkins <atkinssj@serenityos.org>
* Copyright (c) 2021, Tobias Christiansen <tobyase@serenityos.org>
* Copyright (c) 2022, MacDue <macdue@dueutil.tech>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/CharacterTypes.h>
#include <AK/Debug.h>
#include <AK/GenericLexer.h>
#include <AK/SourceLocation.h>
#include <AK/TemporaryChange.h>
#include <LibWeb/CSS/CSSFontFaceRule.h>
#include <LibWeb/CSS/CSSImportRule.h>
#include <LibWeb/CSS/CSSKeyframeRule.h>
#include <LibWeb/CSS/CSSKeyframesRule.h>
#include <LibWeb/CSS/CSSMediaRule.h>
#include <LibWeb/CSS/CSSNamespaceRule.h>
#include <LibWeb/CSS/CSSStyleDeclaration.h>
#include <LibWeb/CSS/CSSStyleRule.h>
#include <LibWeb/CSS/CSSStyleSheet.h>
#include <LibWeb/CSS/CSSSupportsRule.h>
#include <LibWeb/CSS/CalculatedOr.h>
#include <LibWeb/CSS/EdgeRect.h>
#include <LibWeb/CSS/MediaList.h>
#include <LibWeb/CSS/Parser/Block.h>
#include <LibWeb/CSS/Parser/ComponentValue.h>
#include <LibWeb/CSS/Parser/DeclarationOrAtRule.h>
#include <LibWeb/CSS/Parser/Function.h>
#include <LibWeb/CSS/Parser/Parser.h>
#include <LibWeb/CSS/Parser/Rule.h>
#include <LibWeb/CSS/Selector.h>
#include <LibWeb/CSS/StyleValue.h>
#include <LibWeb/CSS/StyleValues/AngleStyleValue.h>
#include <LibWeb/CSS/StyleValues/BackgroundRepeatStyleValue.h>
#include <LibWeb/CSS/StyleValues/BackgroundSizeStyleValue.h>
#include <LibWeb/CSS/StyleValues/BorderRadiusStyleValue.h>
#include <LibWeb/CSS/StyleValues/ColorStyleValue.h>
#include <LibWeb/CSS/StyleValues/ContentStyleValue.h>
#include <LibWeb/CSS/StyleValues/CustomIdentStyleValue.h>
#include <LibWeb/CSS/StyleValues/DisplayStyleValue.h>
#include <LibWeb/CSS/StyleValues/EasingStyleValue.h>
#include <LibWeb/CSS/StyleValues/EdgeStyleValue.h>
#include <LibWeb/CSS/StyleValues/FilterValueListStyleValue.h>
#include <LibWeb/CSS/StyleValues/FlexStyleValue.h>
#include <LibWeb/CSS/StyleValues/FrequencyStyleValue.h>
#include <LibWeb/CSS/StyleValues/GridAutoFlowStyleValue.h>
#include <LibWeb/CSS/StyleValues/GridTemplateAreaStyleValue.h>
#include <LibWeb/CSS/StyleValues/GridTrackPlacementStyleValue.h>
#include <LibWeb/CSS/StyleValues/GridTrackSizeListStyleValue.h>
#include <LibWeb/CSS/StyleValues/IdentifierStyleValue.h>
#include <LibWeb/CSS/StyleValues/ImageStyleValue.h>
#include <LibWeb/CSS/StyleValues/InheritStyleValue.h>
#include <LibWeb/CSS/StyleValues/InitialStyleValue.h>
#include <LibWeb/CSS/StyleValues/IntegerStyleValue.h>
#include <LibWeb/CSS/StyleValues/LengthStyleValue.h>
#include <LibWeb/CSS/StyleValues/MathDepthStyleValue.h>
#include <LibWeb/CSS/StyleValues/NumberStyleValue.h>
#include <LibWeb/CSS/StyleValues/PercentageStyleValue.h>
#include <LibWeb/CSS/StyleValues/PositionStyleValue.h>
#include <LibWeb/CSS/StyleValues/RatioStyleValue.h>
#include <LibWeb/CSS/StyleValues/RectStyleValue.h>
#include <LibWeb/CSS/StyleValues/ResolutionStyleValue.h>
#include <LibWeb/CSS/StyleValues/RevertStyleValue.h>
#include <LibWeb/CSS/StyleValues/ShadowStyleValue.h>
#include <LibWeb/CSS/StyleValues/ShorthandStyleValue.h>
#include <LibWeb/CSS/StyleValues/StringStyleValue.h>
#include <LibWeb/CSS/StyleValues/StyleValueList.h>
#include <LibWeb/CSS/StyleValues/TimeStyleValue.h>
#include <LibWeb/CSS/StyleValues/TransformationStyleValue.h>
#include <LibWeb/CSS/StyleValues/URLStyleValue.h>
#include <LibWeb/CSS/StyleValues/UnresolvedStyleValue.h>
#include <LibWeb/CSS/StyleValues/UnsetStyleValue.h>
#include <LibWeb/Dump.h>
#include <LibWeb/Infra/Strings.h>
static void log_parse_error(SourceLocation const& location = SourceLocation::current())
{
dbgln_if(CSS_PARSER_DEBUG, "Parse error (CSS) {}", location);
}
namespace Web::CSS::Parser {
ErrorOr<Parser> Parser::create(ParsingContext const& context, StringView input, StringView encoding)
{
auto tokens = TRY(Tokenizer::tokenize(input, encoding));
return Parser { context, move(tokens) };
}
Parser::Parser(ParsingContext const& context, Vector<Token> tokens)
: m_context(context)
, m_tokens(move(tokens))
, m_token_stream(m_tokens)
{
}
Parser::Parser(Parser&& other)
: m_context(other.m_context)
, m_tokens(move(other.m_tokens))
, m_token_stream(m_tokens)
{
// Moving the TokenStream directly from `other` would break it, because TokenStream holds
// a reference to the Vector<Token>, so it would be pointing at the old Parser's tokens.
// So instead, we create a new TokenStream from this Parser's tokens, and then tell it to
// copy the other TokenStream's state. This is quite hacky.
m_token_stream.copy_state({}, other.m_token_stream);
}
// 5.3.3. Parse a stylesheet
// https://www.w3.org/TR/css-syntax-3/#parse-stylesheet
template<typename T>
Parser::ParsedStyleSheet Parser::parse_a_stylesheet(TokenStream<T>& tokens, Optional<AK::URL> location)
{
// To parse a stylesheet from an input given an optional url location:
// 1. If input is a byte stream for stylesheet, decode bytes from input, and set input to the result.
// 2. Normalize input, and set input to the result.
// NOTE: These are done automatically when creating the Parser.
// 3. Create a new stylesheet, with its location set to location (or null, if location was not passed).
ParsedStyleSheet style_sheet;
style_sheet.location = move(location);
// 4. Consume a list of rules from input, with the top-level flag set, and set the stylesheets value to the result.
style_sheet.rules = consume_a_list_of_rules(tokens, TopLevel::Yes);
// 5. Return the stylesheet.
return style_sheet;
}
// https://www.w3.org/TR/css-syntax-3/#parse-a-css-stylesheet
CSSStyleSheet* Parser::parse_as_css_stylesheet(Optional<AK::URL> location)
{
// To parse a CSS stylesheet, first parse a stylesheet.
auto style_sheet = parse_a_stylesheet(m_token_stream, {});
// Interpret all of the resulting top-level qualified rules as style rules, defined below.
JS::MarkedVector<CSSRule*> rules(m_context.realm().heap());
for (auto& raw_rule : style_sheet.rules) {
auto* rule = convert_to_rule(raw_rule);
// If any style rule is invalid, or any at-rule is not recognized or is invalid according to its grammar or context, its a parse error. Discard that rule.
if (rule)
rules.append(rule);
}
auto rule_list = CSSRuleList::create(m_context.realm(), rules);
auto media_list = MediaList::create(m_context.realm(), {});
return CSSStyleSheet::create(m_context.realm(), rule_list, media_list, move(location));
}
RefPtr<Supports> Parser::parse_as_supports()
{
return parse_a_supports(m_token_stream);
}
template<typename T>
RefPtr<Supports> Parser::parse_a_supports(TokenStream<T>& tokens)
{
auto component_values = parse_a_list_of_component_values(tokens);
TokenStream<ComponentValue> token_stream { component_values };
auto maybe_condition = parse_supports_condition(token_stream);
token_stream.skip_whitespace();
if (maybe_condition && !token_stream.has_next_token())
return Supports::create(maybe_condition.release_nonnull());
return {};
}
OwnPtr<Supports::Condition> Parser::parse_supports_condition(TokenStream<ComponentValue>& tokens)
{
auto transaction = tokens.begin_transaction();
tokens.skip_whitespace();
auto const& peeked_token = tokens.peek_token();
// `not <supports-in-parens>`
if (peeked_token.is(Token::Type::Ident) && peeked_token.token().ident().equals_ignoring_ascii_case("not"sv)) {
tokens.next_token();
tokens.skip_whitespace();
auto child = parse_supports_in_parens(tokens);
if (!child.has_value())
return {};
transaction.commit();
auto condition = make<Supports::Condition>();
condition->type = Supports::Condition::Type::Not;
condition->children.append(child.release_value());
return condition;
}
// ` <supports-in-parens> [ and <supports-in-parens> ]*
// | <supports-in-parens> [ or <supports-in-parens> ]*`
Vector<Supports::InParens> children;
Optional<Supports::Condition::Type> condition_type {};
auto as_condition_type = [](auto& token) -> Optional<Supports::Condition::Type> {
if (!token.is(Token::Type::Ident))
return {};
auto ident = token.token().ident();
if (ident.equals_ignoring_ascii_case("and"sv))
return Supports::Condition::Type::And;
if (ident.equals_ignoring_ascii_case("or"sv))
return Supports::Condition::Type::Or;
return {};
};
while (tokens.has_next_token()) {
if (!children.is_empty()) {
// Expect `and` or `or` here
auto maybe_combination = as_condition_type(tokens.next_token());
if (!maybe_combination.has_value())
return {};
if (!condition_type.has_value()) {
condition_type = maybe_combination.value();
} else if (maybe_combination != condition_type) {
return {};
}
}
tokens.skip_whitespace();
if (auto in_parens = parse_supports_in_parens(tokens); in_parens.has_value()) {
children.append(in_parens.release_value());
} else {
return {};
}
tokens.skip_whitespace();
}
if (children.is_empty())
return {};
transaction.commit();
auto condition = make<Supports::Condition>();
condition->type = condition_type.value_or(Supports::Condition::Type::Or);
condition->children = move(children);
return condition;
}
Optional<Supports::InParens> Parser::parse_supports_in_parens(TokenStream<ComponentValue>& tokens)
{
// `( <supports-condition> )`
auto const& first_token = tokens.peek_token();
if (first_token.is_block() && first_token.block().is_paren()) {
auto transaction = tokens.begin_transaction();
tokens.next_token();
tokens.skip_whitespace();
TokenStream child_tokens { first_token.block().values() };
if (auto condition = parse_supports_condition(child_tokens)) {
if (child_tokens.has_next_token())
return {};
transaction.commit();
return Supports::InParens {
.value = { condition.release_nonnull() }
};
}
}
// `<supports-feature>`
if (auto feature = parse_supports_feature(tokens); feature.has_value()) {
return Supports::InParens {
.value = { feature.release_value() }
};
}
// `<general-enclosed>`
if (auto general_enclosed = parse_general_enclosed(tokens); general_enclosed.has_value()) {
return Supports::InParens {
.value = general_enclosed.release_value()
};
}
return {};
}
Optional<Supports::Feature> Parser::parse_supports_feature(TokenStream<ComponentValue>& tokens)
{
auto transaction = tokens.begin_transaction();
tokens.skip_whitespace();
auto const& first_token = tokens.next_token();
// `<supports-decl>`
if (first_token.is_block() && first_token.block().is_paren()) {
TokenStream block_tokens { first_token.block().values() };
// FIXME: Parsing and then converting back to a string is weird.
if (auto declaration = consume_a_declaration(block_tokens); declaration.has_value()) {
transaction.commit();
return Supports::Feature {
Supports::Declaration { declaration->to_string(), JS::make_handle(m_context.realm()) }
};
}
}
// `<supports-selector-fn>`
if (first_token.is_function() && first_token.function().name().equals_ignoring_ascii_case("selector"sv)) {
// FIXME: Parsing and then converting back to a string is weird.
StringBuilder builder;
for (auto const& item : first_token.function().values())
builder.append(item.to_string());
transaction.commit();
return Supports::Feature {
Supports::Selector { builder.to_string().release_value_but_fixme_should_propagate_errors(), JS::make_handle(m_context.realm()) }
};
}
return {};
}
// https://www.w3.org/TR/mediaqueries-4/#typedef-general-enclosed
Optional<GeneralEnclosed> Parser::parse_general_enclosed(TokenStream<ComponentValue>& tokens)
{
auto transaction = tokens.begin_transaction();
tokens.skip_whitespace();
auto const& first_token = tokens.next_token();
// `[ <function-token> <any-value>? ) ]`
if (first_token.is_function()) {
transaction.commit();
return GeneralEnclosed { first_token.to_string() };
}
// `( <any-value>? )`
if (first_token.is_block() && first_token.block().is_paren()) {
transaction.commit();
return GeneralEnclosed { first_token.to_string() };
}
return {};
}
// 5.4.1. Consume a list of rules
// https://www.w3.org/TR/css-syntax-3/#consume-list-of-rules
template<typename T>
Vector<NonnullRefPtr<Rule>> Parser::consume_a_list_of_rules(TokenStream<T>& tokens, TopLevel top_level)
{
// To consume a list of rules, given a top-level flag:
// Create an initially empty list of rules.
Vector<NonnullRefPtr<Rule>> rules;
// Repeatedly consume the next input token:
for (;;) {
auto& token = tokens.next_token();
// <whitespace-token>
if (token.is(Token::Type::Whitespace)) {
// Do nothing.
continue;
}
// <EOF-token>
if (token.is(Token::Type::EndOfFile)) {
// Return the list of rules.
return rules;
}
// <CDO-token>
// <CDC-token>
if (token.is(Token::Type::CDO) || token.is(Token::Type::CDC)) {
// If the top-level flag is set, do nothing.
if (top_level == TopLevel::Yes)
continue;
// Otherwise, reconsume the current input token.
tokens.reconsume_current_input_token();
// Consume a qualified rule. If anything is returned, append it to the list of rules.
if (auto maybe_qualified = consume_a_qualified_rule(tokens))
rules.append(maybe_qualified.release_nonnull());
continue;
}
// <at-keyword-token>
if (token.is(Token::Type::AtKeyword)) {
// Reconsume the current input token.
tokens.reconsume_current_input_token();
// Consume an at-rule, and append the returned value to the list of rules.
rules.append(consume_an_at_rule(tokens));
continue;
}
// anything else
{
// Reconsume the current input token.
tokens.reconsume_current_input_token();
// Consume a qualified rule. If anything is returned, append it to the list of rules.
if (auto maybe_qualified = consume_a_qualified_rule(tokens))
rules.append(maybe_qualified.release_nonnull());
continue;
}
}
}
// 5.4.2. Consume an at-rule
// https://www.w3.org/TR/css-syntax-3/#consume-at-rule
template<typename T>
NonnullRefPtr<Rule> Parser::consume_an_at_rule(TokenStream<T>& tokens)
{
// To consume an at-rule:
// Consume the next input token.
auto& name_ident = tokens.next_token();
VERIFY(name_ident.is(Token::Type::AtKeyword));
// Create a new at-rule with its name set to the value of the current input token, its prelude initially set to an empty list, and its value initially set to nothing.
// NOTE: We create the Rule fully initialized when we return it instead.
auto at_rule_name = FlyString::from_utf8(((Token)name_ident).at_keyword()).release_value_but_fixme_should_propagate_errors();
Vector<ComponentValue> prelude;
RefPtr<Block> block;
// Repeatedly consume the next input token:
for (;;) {
auto& token = tokens.next_token();
// <semicolon-token>
if (token.is(Token::Type::Semicolon)) {
// Return the at-rule.
return Rule::make_at_rule(move(at_rule_name), move(prelude), move(block));
}
// <EOF-token>
if (token.is(Token::Type::EndOfFile)) {
// This is a parse error. Return the at-rule.
log_parse_error();
return Rule::make_at_rule(move(at_rule_name), move(prelude), move(block));
}
// <{-token>
if (token.is(Token::Type::OpenCurly)) {
// Consume a simple block and assign it to the at-rules block. Return the at-rule.
block = consume_a_simple_block(tokens);
return Rule::make_at_rule(move(at_rule_name), move(prelude), move(block));
}
// simple block with an associated token of <{-token>
if constexpr (IsSame<T, ComponentValue>) {
ComponentValue const& component_value = token;
if (component_value.is_block() && component_value.block().is_curly()) {
// Assign the block to the at-rules block. Return the at-rule.
block = component_value.block();
return Rule::make_at_rule(move(at_rule_name), move(prelude), move(block));
}
}
// anything else
{
// Reconsume the current input token.
tokens.reconsume_current_input_token();
// Consume a component value. Append the returned value to the at-rules prelude.
prelude.append(consume_a_component_value(tokens));
}
}
}
// 5.4.3. Consume a qualified rule
// https://www.w3.org/TR/css-syntax-3/#consume-qualified-rule
template<typename T>
RefPtr<Rule> Parser::consume_a_qualified_rule(TokenStream<T>& tokens)
{
// To consume a qualified rule:
// Create a new qualified rule with its prelude initially set to an empty list, and its value initially set to nothing.
// NOTE: We create the Rule fully initialized when we return it instead.
Vector<ComponentValue> prelude;
RefPtr<Block> block;
// Repeatedly consume the next input token:
for (;;) {
auto& token = tokens.next_token();
// <EOF-token>
if (token.is(Token::Type::EndOfFile)) {
// This is a parse error. Return nothing.
log_parse_error();
return {};
}
// <{-token>
if (token.is(Token::Type::OpenCurly)) {
// Consume a simple block and assign it to the qualified rules block. Return the qualified rule.
block = consume_a_simple_block(tokens);
return Rule::make_qualified_rule(move(prelude), move(block));
}
// simple block with an associated token of <{-token>
if constexpr (IsSame<T, ComponentValue>) {
ComponentValue const& component_value = token;
if (component_value.is_block() && component_value.block().is_curly()) {
// Assign the block to the qualified rules block. Return the qualified rule.
block = component_value.block();
return Rule::make_qualified_rule(move(prelude), move(block));
}
}
// anything else
{
// Reconsume the current input token.
tokens.reconsume_current_input_token();
// Consume a component value. Append the returned value to the qualified rules prelude.
prelude.append(consume_a_component_value(tokens));
}
}
}
// 5.4.4. Consume a style blocks contents
// https://www.w3.org/TR/css-syntax-3/#consume-a-style-blocks-contents
template<typename T>
Vector<DeclarationOrAtRule> Parser::consume_a_style_blocks_contents(TokenStream<T>& tokens)
{
// To consume a style blocks contents:
// Create an initially empty list of declarations decls, and an initially empty list of rules rules.
Vector<DeclarationOrAtRule> declarations;
Vector<DeclarationOrAtRule> rules;
// Repeatedly consume the next input token:
for (;;) {
auto& token = tokens.next_token();
// <whitespace-token>
// <semicolon-token>
if (token.is(Token::Type::Whitespace) || token.is(Token::Type::Semicolon)) {
// Do nothing.
continue;
}
// <EOF-token>
if (token.is(Token::Type::EndOfFile)) {
// Extend decls with rules, then return decls.
declarations.extend(move(rules));
return declarations;
}
// <at-keyword-token>
if (token.is(Token::Type::AtKeyword)) {
// Reconsume the current input token.
tokens.reconsume_current_input_token();
// Consume an at-rule, and append the result to rules.
rules.empend(consume_an_at_rule(tokens));
continue;
}
// <ident-token>
if (token.is(Token::Type::Ident)) {
// Initialize a temporary list initially filled with the current input token.
Vector<ComponentValue> temporary_list;
temporary_list.append(token);
// As long as the next input token is anything other than a <semicolon-token> or <EOF-token>,
// consume a component value and append it to the temporary list.
for (;;) {
auto& next_input_token = tokens.peek_token();
if (next_input_token.is(Token::Type::Semicolon) || next_input_token.is(Token::Type::EndOfFile))
break;
temporary_list.append(consume_a_component_value(tokens));
}
// Consume a declaration from the temporary list. If anything was returned, append it to decls.
auto token_stream = TokenStream(temporary_list);
if (auto maybe_declaration = consume_a_declaration(token_stream); maybe_declaration.has_value())
declarations.empend(maybe_declaration.release_value());
continue;
}
// <delim-token> with a value of "&" (U+0026 AMPERSAND)
if (token.is_delim('&')) {
// Reconsume the current input token.
tokens.reconsume_current_input_token();
// Consume a qualified rule. If anything was returned, append it to rules.
if (auto qualified_rule = consume_a_qualified_rule(tokens))
rules.empend(qualified_rule);
continue;
}
// anything else
{
// This is a parse error.
log_parse_error();
// Reconsume the current input token.
tokens.reconsume_current_input_token();
// As long as the next input token is anything other than a <semicolon-token> or <EOF-token>,
// consume a component value and throw away the returned value.
for (;;) {
auto& peek = tokens.peek_token();
if (peek.is(Token::Type::Semicolon) || peek.is(Token::Type::EndOfFile))
break;
(void)consume_a_component_value(tokens);
}
}
}
}
template<>
ComponentValue Parser::consume_a_component_value(TokenStream<ComponentValue>& tokens)
{
// Note: This overload is called once tokens have already been converted into component values,
// so we do not need to do the work in the more general overload.
return tokens.next_token();
}
// 5.4.7. Consume a component value
// https://www.w3.org/TR/css-syntax-3/#consume-component-value
template<typename T>
ComponentValue Parser::consume_a_component_value(TokenStream<T>& tokens)
{
// To consume a component value:
// Consume the next input token.
auto& token = tokens.next_token();
// If the current input token is a <{-token>, <[-token>, or <(-token>, consume a simple block and return it.
if (token.is(Token::Type::OpenCurly) || token.is(Token::Type::OpenSquare) || token.is(Token::Type::OpenParen))
return ComponentValue(consume_a_simple_block(tokens));
// Otherwise, if the current input token is a <function-token>, consume a function and return it.
if (token.is(Token::Type::Function))
return ComponentValue(consume_a_function(tokens));
// Otherwise, return the current input token.
return ComponentValue(token);
}
// 5.4.8. Consume a simple block
// https://www.w3.org/TR/css-syntax-3/#consume-simple-block
template<typename T>
NonnullRefPtr<Block> Parser::consume_a_simple_block(TokenStream<T>& tokens)
{
// Note: This algorithm assumes that the current input token has already been checked
// to be an <{-token>, <[-token>, or <(-token>.
// To consume a simple block:
// The ending token is the mirror variant of the current input token.
// (E.g. if it was called with <[-token>, the ending token is <]-token>.)
auto ending_token = ((Token)tokens.current_token()).mirror_variant();
// Create a simple block with its associated token set to the current input token
// and with its value initially set to an empty list.
// NOTE: We create the Block fully initialized when we return it instead.
Token block_token = tokens.current_token();
Vector<ComponentValue> block_values;
// Repeatedly consume the next input token and process it as follows:
for (;;) {
auto& token = tokens.next_token();
// ending token
if (token.is(ending_token)) {
// Return the block.
return Block::create(move(block_token), move(block_values));
}
// <EOF-token>
if (token.is(Token::Type::EndOfFile)) {
// This is a parse error. Return the block.
log_parse_error();
return Block::create(move(block_token), move(block_values));
}
// anything else
{
// Reconsume the current input token.
tokens.reconsume_current_input_token();
// Consume a component value and append it to the value of the block.
block_values.empend(consume_a_component_value(tokens));
}
}
}
// 5.4.9. Consume a function
// https://www.w3.org/TR/css-syntax-3/#consume-function
template<typename T>
NonnullRefPtr<Function> Parser::consume_a_function(TokenStream<T>& tokens)
{
// Note: This algorithm assumes that the current input token has already been checked to be a <function-token>.
auto name_ident = tokens.current_token();
VERIFY(name_ident.is(Token::Type::Function));
// To consume a function:
// Create a function with its name equal to the value of the current input token
// and with its value initially set to an empty list.
// NOTE: We create the Function fully initialized when we return it instead.
auto function_name = FlyString::from_utf8(((Token)name_ident).function()).release_value_but_fixme_should_propagate_errors();
Vector<ComponentValue> function_values;
// Repeatedly consume the next input token and process it as follows:
for (;;) {
auto& token = tokens.next_token();
// <)-token>
if (token.is(Token::Type::CloseParen)) {
// Return the function.
return Function::create(move(function_name), move(function_values));
}
// <EOF-token>
if (token.is(Token::Type::EndOfFile)) {
// This is a parse error. Return the function.
log_parse_error();
return Function::create(move(function_name), move(function_values));
}
// anything else
{
// Reconsume the current input token.
tokens.reconsume_current_input_token();
// Consume a component value and append the returned value to the functions value.
function_values.append(consume_a_component_value(tokens));
}
}
}
// 5.4.6. Consume a declaration
// https://www.w3.org/TR/css-syntax-3/#consume-declaration
template<typename T>
Optional<Declaration> Parser::consume_a_declaration(TokenStream<T>& tokens)
{
// Note: This algorithm assumes that the next input token has already been checked to
// be an <ident-token>.
// NOTE: This is not true in our implementation! For convenience, we both skip whitespace
// and gracefully handle the first token not being an <ident-token>.
// To consume a declaration:
// Consume the next input token.
auto transaction = tokens.begin_transaction();
tokens.skip_whitespace();
auto& token = tokens.next_token();
// NOTE: Not to spec, handle the case where the input token *isn't* an <ident-token>.
if (!token.is(Token::Type::Ident))
return {};
// Create a new declaration with its name set to the value of the current input token
// and its value initially set to the empty list.
// NOTE: We create a fully-initialized Declaration just before returning it instead.
auto declaration_name = FlyString::from_utf8(((Token)token).ident()).release_value_but_fixme_should_propagate_errors();
Vector<ComponentValue> declaration_values;
Important declaration_important = Important::No;
// 1. While the next input token is a <whitespace-token>, consume the next input token.
tokens.skip_whitespace();
// 2. If the next input token is anything other than a <colon-token>, this is a parse error.
// Return nothing.
auto& maybe_colon = tokens.peek_token();
if (!maybe_colon.is(Token::Type::Colon)) {
log_parse_error();
return {};
}
// Otherwise, consume the next input token.
tokens.next_token();
// 3. While the next input token is a <whitespace-token>, consume the next input token.
tokens.skip_whitespace();
// 4. As long as the next input token is anything other than an <EOF-token>, consume a
// component value and append it to the declarations value.
for (;;) {
if (tokens.peek_token().is(Token::Type::EndOfFile)) {
break;
}
declaration_values.append(consume_a_component_value(tokens));
}
// 5. If the last two non-<whitespace-token>s in the declarations value are a <delim-token>
// with the value "!" followed by an <ident-token> with a value that is an ASCII case-insensitive
// match for "important", remove them from the declarations value and set the declarations
// important flag to true.
if (declaration_values.size() >= 2) {
// Walk backwards from the end until we find "important"
Optional<size_t> important_index;
for (size_t i = declaration_values.size() - 1; i > 0; i--) {
auto value = declaration_values[i];
if (value.is(Token::Type::Ident) && Infra::is_ascii_case_insensitive_match(value.token().ident(), "important"sv)) {
important_index = i;
break;
}
if (value.is(Token::Type::Whitespace))
continue;
break;
}
// Walk backwards from important until we find "!"
if (important_index.has_value()) {
Optional<size_t> bang_index;
for (size_t i = important_index.value() - 1; i > 0; i--) {
auto value = declaration_values[i];
if (value.is_delim('!')) {
bang_index = i;
break;
}
if (value.is(Token::Type::Whitespace))
continue;
break;
}
if (bang_index.has_value()) {
declaration_values.remove(important_index.value());
declaration_values.remove(bang_index.value());
declaration_important = Important::Yes;
}
}
}
// 6. While the last token in the declarations value is a <whitespace-token>, remove that token.
while (!declaration_values.is_empty()) {
auto maybe_whitespace = declaration_values.last();
if (!(maybe_whitespace.is(Token::Type::Whitespace))) {
break;
}
declaration_values.take_last();
}
// 7. Return the declaration.
transaction.commit();
return Declaration { move(declaration_name), move(declaration_values), declaration_important };
}
// 5.4.5. Consume a list of declarations
// https://www.w3.org/TR/css-syntax-3/#consume-list-of-declarations
template<typename T>
Vector<DeclarationOrAtRule> Parser::consume_a_list_of_declarations(TokenStream<T>& tokens)
{
// To consume a list of declarations:
// Create an initially empty list of declarations.
Vector<DeclarationOrAtRule> list_of_declarations;
// Repeatedly consume the next input token:
for (;;) {
auto& token = tokens.next_token();
// <whitespace-token>
// <semicolon-token>
if (token.is(Token::Type::Whitespace) || token.is(Token::Type::Semicolon)) {
// Do nothing.
continue;
}
// <EOF-token>
if (token.is(Token::Type::EndOfFile)) {
// Return the list of declarations.
return list_of_declarations;
}
// <at-keyword-token>
if (token.is(Token::Type::AtKeyword)) {
// Reconsume the current input token.
tokens.reconsume_current_input_token();
// Consume an at-rule. Append the returned rule to the list of declarations.
list_of_declarations.empend(consume_an_at_rule(tokens));
continue;
}
// <ident-token>
if (token.is(Token::Type::Ident)) {
// Initialize a temporary list initially filled with the current input token.
Vector<ComponentValue> temporary_list;
temporary_list.append(token);
// As long as the next input token is anything other than a <semicolon-token> or <EOF-token>,
// consume a component value and append it to the temporary list.
for (;;) {
auto& peek = tokens.peek_token();
if (peek.is(Token::Type::Semicolon) || peek.is(Token::Type::EndOfFile))
break;
temporary_list.append(consume_a_component_value(tokens));
}
// Consume a declaration from the temporary list. If anything was returned, append it to the list of declarations.
auto token_stream = TokenStream(temporary_list);
if (auto maybe_declaration = consume_a_declaration(token_stream); maybe_declaration.has_value())
list_of_declarations.empend(maybe_declaration.value());
continue;
}
// anything else
{
// This is a parse error.
log_parse_error();
// Reconsume the current input token.
tokens.reconsume_current_input_token();
// As long as the next input token is anything other than a <semicolon-token> or <EOF-token>,
// consume a component value and throw away the returned value.
for (;;) {
auto& peek = tokens.peek_token();
if (peek.is(Token::Type::Semicolon) || peek.is(Token::Type::EndOfFile))
break;
dbgln_if(CSS_PARSER_DEBUG, "Discarding token: '{}'", peek.to_debug_string());
(void)consume_a_component_value(tokens);
}
}
}
}
CSSRule* Parser::parse_as_css_rule()
{
auto maybe_rule = parse_a_rule(m_token_stream);
if (maybe_rule)
return convert_to_rule(maybe_rule.release_nonnull());
return {};
}
// 5.3.5. Parse a rule
// https://www.w3.org/TR/css-syntax-3/#parse-rule
template<typename T>
RefPtr<Rule> Parser::parse_a_rule(TokenStream<T>& tokens)
{
// To parse a rule from input:
RefPtr<Rule> rule;
// 1. Normalize input, and set input to the result.
// Note: This is done when initializing the Parser.
// 2. While the next input token from input is a <whitespace-token>, consume the next input token from input.
tokens.skip_whitespace();
// 3. If the next input token from input is an <EOF-token>, return a syntax error.
auto& token = tokens.peek_token();
if (token.is(Token::Type::EndOfFile)) {
return {};
}
// Otherwise, if the next input token from input is an <at-keyword-token>, consume an at-rule from input, and let rule be the return value.
else if (token.is(Token::Type::AtKeyword)) {
rule = consume_an_at_rule(m_token_stream);
}
// Otherwise, consume a qualified rule from input and let rule be the return value. If nothing was returned, return a syntax error.
else {
auto qualified_rule = consume_a_qualified_rule(tokens);
if (!qualified_rule)
return {};
rule = qualified_rule;
}
// 4. While the next input token from input is a <whitespace-token>, consume the next input token from input.
tokens.skip_whitespace();
// 5. If the next input token from input is an <EOF-token>, return rule. Otherwise, return a syntax error.
if (tokens.peek_token().is(Token::Type::EndOfFile))
return rule;
return {};
}
// 5.3.4. Parse a list of rules
// https://www.w3.org/TR/css-syntax-3/#parse-list-of-rules
template<typename T>
Vector<NonnullRefPtr<Rule>> Parser::parse_a_list_of_rules(TokenStream<T>& tokens)
{
// To parse a list of rules from input:
// 1. Normalize input, and set input to the result.
// Note: This is done when initializing the Parser.
// 2. Consume a list of rules from the input, with the top-level flag unset.
auto list_of_rules = consume_a_list_of_rules(tokens, TopLevel::No);
// 3. Return the returned list.
return list_of_rules;
}
template Vector<NonnullRefPtr<Rule>> Parser::parse_a_list_of_rules(TokenStream<Token>& tokens);
template Vector<NonnullRefPtr<Rule>> Parser::parse_a_list_of_rules(TokenStream<ComponentValue>& tokens);
Optional<StyleProperty> Parser::parse_as_supports_condition()
{
auto maybe_declaration = parse_a_declaration(m_token_stream);
if (maybe_declaration.has_value())
return convert_to_style_property(maybe_declaration.release_value());
return {};
}
// 5.3.6. Parse a declaration
// https://www.w3.org/TR/css-syntax-3/#parse-a-declaration
template<typename T>
Optional<Declaration> Parser::parse_a_declaration(TokenStream<T>& tokens)
{
// To parse a declaration from input:
// 1. Normalize input, and set input to the result.
// Note: This is done when initializing the Parser.
// 2. While the next input token from input is a <whitespace-token>, consume the next input token.
tokens.skip_whitespace();
// 3. If the next input token from input is not an <ident-token>, return a syntax error.
auto& token = tokens.peek_token();
if (!token.is(Token::Type::Ident)) {
return {};
}
// 4. Consume a declaration from input. If anything was returned, return it. Otherwise, return a syntax error.
if (auto declaration = consume_a_declaration(tokens); declaration.has_value())
return declaration.release_value();
return {};
}
// 5.3.7. Parse a style blocks contents
// https://www.w3.org/TR/css-syntax-3/#parse-style-blocks-contents
template<typename T>
Vector<DeclarationOrAtRule> Parser::parse_a_style_blocks_contents(TokenStream<T>& tokens)
{
// To parse a style blocks contents from input:
// 1. Normalize input, and set input to the result.
// Note: This is done when initializing the Parser.
// 2. Consume a style blocks contents from input, and return the result.
return consume_a_style_blocks_contents(tokens);
}
// 5.3.8. Parse a list of declarations
// https://www.w3.org/TR/css-syntax-3/#parse-list-of-declarations
template<typename T>
Vector<DeclarationOrAtRule> Parser::parse_a_list_of_declarations(TokenStream<T>& tokens)
{
// To parse a list of declarations from input:
// 1. Normalize input, and set input to the result.
// Note: This is done when initializing the Parser.
// 2. Consume a list of declarations from input, and return the result.
return consume_a_list_of_declarations(tokens);
}
Optional<ComponentValue> Parser::parse_as_component_value()
{
return parse_a_component_value(m_token_stream);
}
// 5.3.9. Parse a component value
// https://www.w3.org/TR/css-syntax-3/#parse-component-value
template<typename T>
Optional<ComponentValue> Parser::parse_a_component_value(TokenStream<T>& tokens)
{
// To parse a component value from input:
// 1. Normalize input, and set input to the result.
// Note: This is done when initializing the Parser.
// 2. While the next input token from input is a <whitespace-token>, consume the next input token from input.
tokens.skip_whitespace();
// 3. If the next input token from input is an <EOF-token>, return a syntax error.
if (tokens.peek_token().is(Token::Type::EndOfFile))
return {};
// 4. Consume a component value from input and let value be the return value.
auto value = consume_a_component_value(tokens);
// 5. While the next input token from input is a <whitespace-token>, consume the next input token.
tokens.skip_whitespace();
// 6. If the next input token from input is an <EOF-token>, return value. Otherwise, return a syntax error.
if (tokens.peek_token().is(Token::Type::EndOfFile))
return value;
return {};
}
// 5.3.10. Parse a list of component values
// https://www.w3.org/TR/css-syntax-3/#parse-list-of-component-values
template<typename T>
Vector<ComponentValue> Parser::parse_a_list_of_component_values(TokenStream<T>& tokens)
{
// To parse a list of component values from input:
// 1. Normalize input, and set input to the result.
// Note: This is done when initializing the Parser.
// 2. Repeatedly consume a component value from input until an <EOF-token> is returned, appending the returned values (except the final <EOF-token>) into a list. Return the list.
Vector<ComponentValue> component_values;
for (;;) {
if (tokens.peek_token().is(Token::Type::EndOfFile)) {
break;
}
component_values.append(consume_a_component_value(tokens));
}
return component_values;
}
// 5.3.11. Parse a comma-separated list of component values
// https://www.w3.org/TR/css-syntax-3/#parse-comma-separated-list-of-component-values
template<typename T>
Vector<Vector<ComponentValue>> Parser::parse_a_comma_separated_list_of_component_values(TokenStream<T>& tokens)
{
// To parse a comma-separated list of component values from input:
// 1. Normalize input, and set input to the result.
// Note: This is done when initializing the Parser.
// 2. Let list of cvls be an initially empty list of component value lists.
Vector<Vector<ComponentValue>> list_of_component_value_lists;
// 3. Repeatedly consume a component value from input until an <EOF-token> or <comma-token> is returned,
// appending the returned values (except the final <EOF-token> or <comma-token>) into a list.
// Append the list to list of cvls.
// If it was a <comma-token> that was returned, repeat this step.
Vector<ComponentValue> current_list;
for (;;) {
auto component_value = consume_a_component_value(tokens);
if (component_value.is(Token::Type::EndOfFile)) {
list_of_component_value_lists.append(move(current_list));
break;
}
if (component_value.is(Token::Type::Comma)) {
list_of_component_value_lists.append(move(current_list));
current_list = {};
continue;
}
current_list.append(component_value);
}
// 4. Return list of cvls.
return list_of_component_value_lists;
}
template Vector<Vector<ComponentValue>> Parser::parse_a_comma_separated_list_of_component_values(TokenStream<ComponentValue>&);
template Vector<Vector<ComponentValue>> Parser::parse_a_comma_separated_list_of_component_values(TokenStream<Token>&);
ElementInlineCSSStyleDeclaration* Parser::parse_as_style_attribute(DOM::Element& element)
{
auto declarations_and_at_rules = parse_a_list_of_declarations(m_token_stream);
auto [properties, custom_properties] = extract_properties(declarations_and_at_rules);
return ElementInlineCSSStyleDeclaration::create(element, move(properties), move(custom_properties));
}
Optional<AK::URL> Parser::parse_url_function(ComponentValue const& component_value)
{
// FIXME: Handle list of media queries. https://www.w3.org/TR/css-cascade-3/#conditional-import
auto convert_string_to_url = [&](StringView& url_string) -> Optional<AK::URL> {
auto url = m_context.complete_url(url_string);
if (url.is_valid())
return url;
return {};
};
if (component_value.is(Token::Type::Url)) {
auto url_string = component_value.token().url();
return convert_string_to_url(url_string);
}
if (component_value.is_function() && component_value.function().name().equals_ignoring_ascii_case("url"sv)) {
auto const& function_values = component_value.function().values();
// FIXME: Handle url-modifiers. https://www.w3.org/TR/css-values-4/#url-modifiers
for (size_t i = 0; i < function_values.size(); ++i) {
auto const& value = function_values[i];
if (value.is(Token::Type::Whitespace))
continue;
if (value.is(Token::Type::String)) {
auto url_string = value.token().string();
return convert_string_to_url(url_string);
}
break;
}
}
return {};
}
RefPtr<StyleValue> Parser::parse_url_value(ComponentValue const& component_value)
{
auto url = parse_url_function(component_value);
if (!url.has_value())
return nullptr;
return URLStyleValue::create(*url);
}
Optional<PositionValue> Parser::parse_position(TokenStream<ComponentValue>& tokens, PositionValue initial_value)
{
auto transaction = tokens.begin_transaction();
tokens.skip_whitespace();
if (!tokens.has_next_token())
return {};
auto parse_horizontal_preset = [&](auto ident) -> Optional<PositionValue::HorizontalPreset> {
if (ident.equals_ignoring_ascii_case("left"sv))
return PositionValue::HorizontalPreset::Left;
if (ident.equals_ignoring_ascii_case("center"sv))
return PositionValue::HorizontalPreset::Center;
if (ident.equals_ignoring_ascii_case("right"sv))
return PositionValue::HorizontalPreset::Right;
return {};
};
auto parse_vertical_preset = [&](auto ident) -> Optional<PositionValue::VerticalPreset> {
if (ident.equals_ignoring_ascii_case("top"sv))
return PositionValue::VerticalPreset::Top;
if (ident.equals_ignoring_ascii_case("center"sv))
return PositionValue::VerticalPreset::Center;
if (ident.equals_ignoring_ascii_case("bottom"sv))
return PositionValue::VerticalPreset::Bottom;
return {};
};
auto parse_horizontal_edge = [&](auto ident) -> Optional<PositionValue::HorizontalEdge> {
if (ident.equals_ignoring_ascii_case("left"sv))
return PositionValue::HorizontalEdge::Left;
if (ident.equals_ignoring_ascii_case("right"sv))
return PositionValue::HorizontalEdge::Right;
return {};
};
auto parse_vertical_edge = [&](auto ident) -> Optional<PositionValue::VerticalEdge> {
if (ident.equals_ignoring_ascii_case("top"sv))
return PositionValue::VerticalEdge::Top;
if (ident.equals_ignoring_ascii_case("bottom"sv))
return PositionValue::VerticalEdge::Bottom;
return {};
};
// <position> = [
// [ left | center | right ] || [ top | center | bottom ]
// |
// [ left | center | right | <length-percentage> ]
// [ top | center | bottom | <length-percentage> ]?
// |
// [ [ left | right ] <length-percentage> ] &&
// [ [ top | bottom ] <length-percentage> ]
// ]
// [ left | center | right ] || [ top | center | bottom ]
auto alternation_1 = [&]() -> Optional<PositionValue> {
auto transaction = tokens.begin_transaction();
PositionValue position = initial_value;
auto& first_token = tokens.next_token();
if (!first_token.is(Token::Type::Ident))
return {};
auto ident = first_token.token().ident();
// <horizontal-position> <vertical-position>?
auto horizontal_position = parse_horizontal_preset(ident);
if (horizontal_position.has_value()) {
position.horizontal_position = *horizontal_position;
auto transaction_optional_parse = tokens.begin_transaction();
tokens.skip_whitespace();
if (tokens.has_next_token()) {
auto& second_token = tokens.next_token();
if (second_token.is(Token::Type::Ident)) {
auto vertical_position = parse_vertical_preset(second_token.token().ident());
if (vertical_position.has_value()) {
transaction_optional_parse.commit();
position.vertical_position = *vertical_position;
}
}
}
} else {
// <vertical-position> <horizontal-position>?
auto vertical_position = parse_vertical_preset(ident);
if (!vertical_position.has_value())
return {};
position.vertical_position = *vertical_position;
auto transaction_optional_parse = tokens.begin_transaction();
tokens.skip_whitespace();
if (tokens.has_next_token()) {
auto& second_token = tokens.next_token();
if (second_token.is(Token::Type::Ident)) {
auto horizontal_position = parse_horizontal_preset(second_token.token().ident());
if (horizontal_position.has_value()) {
transaction_optional_parse.commit();
position.horizontal_position = *horizontal_position;
}
}
}
}
transaction.commit();
return position;
};
// [ left | center | right | <length-percentage> ]
// [ top | center | bottom | <length-percentage> ]?
auto alternation_2 = [&]() -> Optional<PositionValue> {
auto transaction = tokens.begin_transaction();
PositionValue position = initial_value;
auto& first_token = tokens.next_token();
if (first_token.is(Token::Type::Ident)) {
auto horizontal_position = parse_horizontal_preset(first_token.token().ident());
if (!horizontal_position.has_value())
return {};
position.horizontal_position = *horizontal_position;
} else {
auto dimension = parse_dimension(first_token);
if (!dimension.has_value() || !dimension->is_length_percentage())
return {};
position.horizontal_position = dimension->length_percentage();
}
auto transaction_optional_parse = tokens.begin_transaction();
tokens.skip_whitespace();
if (tokens.has_next_token()) {
auto& second_token = tokens.next_token();
if (second_token.is(Token::Type::Ident)) {
auto vertical_position = parse_vertical_preset(second_token.token().ident());
if (vertical_position.has_value()) {
transaction_optional_parse.commit();
position.vertical_position = *vertical_position;
}
} else {
auto dimension = parse_dimension(second_token);
if (dimension.has_value() && dimension->is_length_percentage()) {
transaction_optional_parse.commit();
position.vertical_position = dimension->length_percentage();
}
}
}
transaction.commit();
return position;
};
// [ [ left | right ] <length-percentage> ] &&
// [ [ top | bottom ] <length-percentage> ]
auto alternation_3 = [&]() -> Optional<PositionValue> {
auto transaction = tokens.begin_transaction();
PositionValue position {};
auto parse_horizontal = [&] {
// [ left | right ] <length-percentage> ]
auto transaction = tokens.begin_transaction();
tokens.skip_whitespace();
if (!tokens.has_next_token())
return false;
auto& first_token = tokens.next_token();
if (!first_token.is(Token::Type::Ident))
return false;
auto horizontal_egde = parse_horizontal_edge(first_token.token().ident());
if (!horizontal_egde.has_value())
return false;
position.x_relative_to = *horizontal_egde;
tokens.skip_whitespace();
if (!tokens.has_next_token())
return false;
auto& second_token = tokens.next_token();
auto dimension = parse_dimension(second_token);
if (!dimension.has_value() || !dimension->is_length_percentage())
return false;
position.horizontal_position = dimension->length_percentage();
transaction.commit();
return true;
};
auto parse_vertical = [&] {
// [ top | bottom ] <length-percentage> ]
auto transaction = tokens.begin_transaction();
tokens.skip_whitespace();
if (!tokens.has_next_token())
return false;
auto& first_token = tokens.next_token();
if (!first_token.is(Token::Type::Ident))
return false;
auto vertical_edge = parse_vertical_edge(first_token.token().ident());
if (!vertical_edge.has_value())
return false;
position.y_relative_to = *vertical_edge;
tokens.skip_whitespace();
if (!tokens.has_next_token())
return false;
auto& second_token = tokens.next_token();
auto dimension = parse_dimension(second_token);
if (!dimension.has_value() || !dimension->is_length_percentage())
return false;
position.vertical_position = dimension->length_percentage();
transaction.commit();
return true;
};
if ((parse_horizontal() && parse_vertical()) || (parse_vertical() && parse_horizontal())) {
transaction.commit();
return position;
}
return {};
};
// Note: The alternatives must be attempted in this order since `alternation_2' can match a prefix of `alternation_3'
auto position = alternation_3();
if (!position.has_value())
position = alternation_2();
if (!position.has_value())
position = alternation_1();
if (position.has_value())
transaction.commit();
return position;
}
CSSRule* Parser::convert_to_rule(NonnullRefPtr<Rule> rule)
{
if (rule->is_at_rule()) {
if (has_ignored_vendor_prefix(rule->at_rule_name()))
return {};
if (rule->at_rule_name().equals_ignoring_ascii_case("font-face"sv)) {
if (!rule->block() || !rule->block()->is_curly()) {
dbgln_if(CSS_PARSER_DEBUG, "@font-face rule is malformed.");
return {};
}
TokenStream tokens { rule->block()->values() };
return parse_font_face_rule(tokens);
}
if (rule->at_rule_name().equals_ignoring_ascii_case("import"sv) && !rule->prelude().is_empty()) {
Optional<AK::URL> url;
for (auto const& token : rule->prelude()) {
if (token.is(Token::Type::Whitespace))
continue;
if (token.is(Token::Type::String)) {
url = m_context.complete_url(token.token().string());
} else {
url = parse_url_function(token);
}
// FIXME: Handle list of media queries. https://www.w3.org/TR/css-cascade-3/#conditional-import
if (url.has_value())
break;
}
if (url.has_value())
return CSSImportRule::create(url.value(), const_cast<DOM::Document&>(*m_context.document()));
dbgln_if(CSS_PARSER_DEBUG, "Unable to parse url from @import rule");
return {};
}
if (rule->at_rule_name().equals_ignoring_ascii_case("media"sv))
return convert_to_media_rule(rule);
if (rule->at_rule_name().equals_ignoring_ascii_case("supports"sv)) {
auto supports_tokens = TokenStream { rule->prelude() };
auto supports = parse_a_supports(supports_tokens);
if (!supports) {
if constexpr (CSS_PARSER_DEBUG) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: @supports rule invalid; discarding.");
supports_tokens.dump_all_tokens();
}
return {};
}
if (!rule->block())
return {};
auto child_tokens = TokenStream { rule->block()->values() };
auto parser_rules = parse_a_list_of_rules(child_tokens);
JS::MarkedVector<CSSRule*> child_rules(m_context.realm().heap());
for (auto& raw_rule : parser_rules) {
if (auto* child_rule = convert_to_rule(raw_rule))
child_rules.append(child_rule);
}
auto rule_list = CSSRuleList::create(m_context.realm(), child_rules);
return CSSSupportsRule::create(m_context.realm(), supports.release_nonnull(), rule_list);
}
if (rule->at_rule_name().equals_ignoring_ascii_case("keyframes"sv)) {
auto prelude_stream = TokenStream { rule->prelude() };
prelude_stream.skip_whitespace();
auto token = prelude_stream.next_token();
if (!token.is_token()) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: @keyframes has invalid prelude, prelude = {}; discarding.", rule->prelude());
return {};
}
auto name_token = token.token();
prelude_stream.skip_whitespace();
if (prelude_stream.has_next_token()) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: @keyframes has invalid prelude, prelude = {}; discarding.", rule->prelude());
return {};
}
if (name_token.is(Token::Type::Ident) && (is_css_wide_keyword(name_token.ident()) || name_token.ident().equals_ignoring_ascii_case("none"sv))) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: @keyframes rule name is invalid: {}; discarding.", name_token.ident());
return {};
}
if (!name_token.is(Token::Type::String) && !name_token.is(Token::Type::Ident)) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: @keyframes rule name is invalid: {}; discarding.", name_token.to_debug_string());
return {};
}
auto name = name_token.to_string();
if (!rule->block())
return {};
auto child_tokens = TokenStream { rule->block()->values() };
JS::MarkedVector<JS::NonnullGCPtr<CSSKeyframeRule>> keyframes(m_context.realm().heap());
while (child_tokens.has_next_token()) {
child_tokens.skip_whitespace();
// keyframe-selector = <keyframe-keyword> | <percentage>
// keyframe-keyword = "from" | "to"
// selector = <keyframe-selector>#
// keyframes-block = "{" <declaration-list>? "}"
// keyframe-rule = <selector> <keyframes-block>
auto selectors = Vector<CSS::Percentage> {};
while (child_tokens.has_next_token()) {
child_tokens.skip_whitespace();
if (!child_tokens.has_next_token())
break;
auto tok = child_tokens.next_token();
if (!tok.is_token()) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: @keyframes rule has invalid selector: {}; discarding.", tok.to_debug_string());
child_tokens.reconsume_current_input_token();
break;
}
auto token = tok.token();
auto read_a_selector = false;
if (token.is(Token::Type::Ident)) {
if (token.ident().equals_ignoring_ascii_case("from"sv)) {
selectors.append(CSS::Percentage(0));
read_a_selector = true;
}
if (token.ident().equals_ignoring_ascii_case("to"sv)) {
selectors.append(CSS::Percentage(100));
read_a_selector = true;
}
} else if (token.is(Token::Type::Percentage)) {
selectors.append(CSS::Percentage(token.percentage()));
read_a_selector = true;
}
if (read_a_selector) {
child_tokens.skip_whitespace();
if (child_tokens.next_token().is(Token::Type::Comma))
continue;
}
child_tokens.reconsume_current_input_token();
break;
}
if (!child_tokens.has_next_token())
break;
child_tokens.skip_whitespace();
auto token = child_tokens.next_token();
if (token.is_block()) {
auto block_tokens = token.block().values();
auto block_stream = TokenStream { block_tokens };
auto block_declarations = parse_a_list_of_declarations(block_stream);
auto style = convert_to_style_declaration(block_declarations);
for (auto& selector : selectors) {
auto keyframe_rule = CSSKeyframeRule::create(m_context.realm(), selector, *style);
keyframes.append(keyframe_rule);
}
} else {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: @keyframes rule has invalid block: {}; discarding.", token.to_debug_string());
}
}
return CSSKeyframesRule::create(m_context.realm(), name, move(keyframes));
}
if (rule->at_rule_name().equals_ignoring_ascii_case("namespace"sv)) {
// https://drafts.csswg.org/css-namespaces/#syntax
auto token_stream = TokenStream { rule->prelude() };
token_stream.skip_whitespace();
auto token = token_stream.next_token();
Optional<DeprecatedString> prefix = {};
if (token.is(Token::Type::Ident)) {
prefix = token.token().ident();
token_stream.skip_whitespace();
token = token_stream.next_token();
}
DeprecatedString namespace_uri;
if (token.is(Token::Type::String)) {
namespace_uri = token.token().string();
} else if (auto url = parse_url_function(token); url.has_value()) {
namespace_uri = url.value().to_deprecated_string();
} else {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: @namespace rule invalid; discarding.");
return {};
}
token_stream.skip_whitespace();
if (token_stream.has_next_token()) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: @namespace rule invalid; discarding.");
return {};
}
return CSSNamespaceRule::create(m_context.realm(), prefix, namespace_uri);
}
// FIXME: More at rules!
dbgln_if(CSS_PARSER_DEBUG, "Unrecognized CSS at-rule: @{}", rule->at_rule_name());
return {};
}
auto prelude_stream = TokenStream(rule->prelude());
auto selectors = parse_a_selector_list(prelude_stream, SelectorType::Standalone);
if (selectors.is_error()) {
if (selectors.error() == ParseError::SyntaxError) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: style rule selectors invalid; discarding.");
if constexpr (CSS_PARSER_DEBUG) {
prelude_stream.dump_all_tokens();
}
}
return {};
}
if (selectors.value().is_empty()) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: empty selector; discarding.");
return {};
}
if (!rule->block()->is_curly())
return {};
auto stream = TokenStream(rule->block()->values());
auto declarations_and_at_rules = parse_a_style_blocks_contents(stream);
auto* declaration = convert_to_style_declaration(declarations_and_at_rules);
if (!declaration) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: style rule declaration invalid; discarding.");
return {};
}
return CSSStyleRule::create(m_context.realm(), move(selectors.value()), *declaration);
}
auto Parser::extract_properties(Vector<DeclarationOrAtRule> const& declarations_and_at_rules) -> PropertiesAndCustomProperties
{
PropertiesAndCustomProperties result;
for (auto const& declaration_or_at_rule : declarations_and_at_rules) {
if (declaration_or_at_rule.is_at_rule()) {
dbgln_if(CSS_PARSER_DEBUG, "!!! CSS at-rule is not allowed here!");
continue;
}
auto const& declaration = declaration_or_at_rule.declaration();
if (auto maybe_property = convert_to_style_property(declaration); maybe_property.has_value()) {
auto property = maybe_property.release_value();
if (property.property_id == PropertyID::Custom) {
result.custom_properties.set(property.custom_name, property);
} else {
result.properties.append(move(property));
}
}
}
return result;
}
PropertyOwningCSSStyleDeclaration* Parser::convert_to_style_declaration(Vector<DeclarationOrAtRule> const& declarations_and_at_rules)
{
auto [properties, custom_properties] = extract_properties(declarations_and_at_rules);
return PropertyOwningCSSStyleDeclaration::create(m_context.realm(), move(properties), move(custom_properties));
}
Optional<StyleProperty> Parser::convert_to_style_property(Declaration const& declaration)
{
auto property_name = declaration.name();
auto property_id = property_id_from_string(property_name);
if (!property_id.has_value()) {
if (property_name.starts_with("--"sv)) {
property_id = PropertyID::Custom;
} else if (has_ignored_vendor_prefix(property_name)) {
return {};
} else if (!property_name.starts_with('-')) {
dbgln_if(CSS_PARSER_DEBUG, "Unrecognized CSS property '{}'", property_name);
return {};
}
}
auto value_token_stream = TokenStream(declaration.values());
auto value = parse_css_value(property_id.value(), value_token_stream);
if (value.is_error()) {
if (value.error() == ParseError::SyntaxError) {
dbgln_if(CSS_PARSER_DEBUG, "Unable to parse value for CSS property '{}'.", property_name);
if constexpr (CSS_PARSER_DEBUG) {
value_token_stream.dump_all_tokens();
}
}
return {};
}
if (property_id.value() == PropertyID::Custom)
return StyleProperty { declaration.importance(), property_id.value(), value.release_value(), declaration.name() };
return StyleProperty { declaration.importance(), property_id.value(), value.release_value(), {} };
}
RefPtr<StyleValue> Parser::parse_builtin_value(ComponentValue const& component_value)
{
if (component_value.is(Token::Type::Ident)) {
auto ident = component_value.token().ident();
if (ident.equals_ignoring_ascii_case("inherit"sv))
return InheritStyleValue::the();
if (ident.equals_ignoring_ascii_case("initial"sv))
return InitialStyleValue::the();
if (ident.equals_ignoring_ascii_case("unset"sv))
return UnsetStyleValue::the();
if (ident.equals_ignoring_ascii_case("revert"sv))
return RevertStyleValue::the();
// FIXME: Implement `revert-layer` from CSS-CASCADE-5.
}
return nullptr;
}
RefPtr<CalculatedStyleValue> Parser::parse_calculated_value(ComponentValue const& component_value)
{
if (!component_value.is_function())
return nullptr;
auto const& function = component_value.function();
auto function_node = parse_a_calc_function_node(function);
if (!function_node)
return nullptr;
auto function_type = function_node->determine_type(m_context.current_property_id());
if (!function_type.has_value())
return nullptr;
return CalculatedStyleValue::create(function_node.release_nonnull(), function_type.release_value());
}
OwnPtr<CalculationNode> Parser::parse_a_calc_function_node(Function const& function)
{
if (function.name().equals_ignoring_ascii_case("calc"sv))
return parse_a_calculation(function.values());
if (auto maybe_function = parse_math_function(m_context.current_property_id(), function))
return maybe_function;
return nullptr;
}
Optional<Dimension> Parser::parse_dimension(ComponentValue const& component_value)
{
if (component_value.is(Token::Type::Dimension)) {
auto numeric_value = component_value.token().dimension_value();
auto unit_string = component_value.token().dimension_unit();
if (auto length_type = Length::unit_from_name(unit_string); length_type.has_value())
return Length { numeric_value, length_type.release_value() };
if (auto angle_type = Angle::unit_from_name(unit_string); angle_type.has_value())
return Angle { numeric_value, angle_type.release_value() };
if (auto flex_type = Flex::unit_from_name(unit_string); flex_type.has_value())
return Flex { numeric_value, flex_type.release_value() };
if (auto frequency_type = Frequency::unit_from_name(unit_string); frequency_type.has_value())
return Frequency { numeric_value, frequency_type.release_value() };
if (auto resolution_type = Resolution::unit_from_name(unit_string); resolution_type.has_value())
return Resolution { numeric_value, resolution_type.release_value() };
if (auto time_type = Time::unit_from_name(unit_string); time_type.has_value())
return Time { numeric_value, time_type.release_value() };
}
if (component_value.is(Token::Type::Percentage))
return Percentage { component_value.token().percentage() };
if (component_value.is(Token::Type::Number)) {
auto numeric_value = component_value.token().number_value();
if (numeric_value == 0)
return Length::make_px(0);
if (m_context.in_quirks_mode() && property_has_quirk(m_context.current_property_id(), Quirk::UnitlessLength)) {
// https://quirks.spec.whatwg.org/#quirky-length-value
// FIXME: Disallow quirk when inside a CSS sub-expression (like `calc()`)
// "The <quirky-length> value must not be supported in arguments to CSS expressions other than the rect()
// expression, and must not be supported in the supports() static method of the CSS interface."
return Length::make_px(CSSPixels::nearest_value_for(numeric_value));
}
}
return {};
}
Optional<LengthOrCalculated> Parser::parse_source_size_value(ComponentValue const& component_value)
{
if (component_value.is(Token::Type::Ident) && component_value.token().ident().equals_ignoring_ascii_case("auto"sv)) {
return LengthOrCalculated { Length::make_auto() };
}
if (auto calculated_value = parse_calculated_value(component_value)) {
return LengthOrCalculated { calculated_value.release_nonnull() };
}
if (auto length = parse_length(component_value); length.has_value()) {
return LengthOrCalculated { length.release_value() };
}
return {};
}
Optional<Length> Parser::parse_length(ComponentValue const& component_value)
{
auto dimension = parse_dimension(component_value);
if (!dimension.has_value())
return {};
if (dimension->is_length())
return dimension->length();
return {};
}
Optional<Ratio> Parser::parse_ratio(TokenStream<ComponentValue>& tokens)
{
auto transaction = tokens.begin_transaction();
tokens.skip_whitespace();
auto read_number_value = [this](ComponentValue const& component_value) -> Optional<double> {
if (component_value.is(Token::Type::Number)) {
return component_value.token().number_value();
} else if (component_value.is_function()) {
auto maybe_calc = parse_calculated_value(component_value);
if (!maybe_calc || !maybe_calc->resolves_to_number())
return {};
if (auto resolved_number = maybe_calc->resolve_number(); resolved_number.has_value() && resolved_number.value() >= 0) {
return resolved_number.value();
}
}
return {};
};
// `<ratio> = <number [0,∞]> [ / <number [0,∞]> ]?`
auto maybe_numerator = read_number_value(tokens.next_token());
if (!maybe_numerator.has_value() || maybe_numerator.value() < 0)
return {};
auto numerator = maybe_numerator.value();
{
auto two_value_transaction = tokens.begin_transaction();
tokens.skip_whitespace();
auto solidus = tokens.next_token();
tokens.skip_whitespace();
auto maybe_denominator = read_number_value(tokens.next_token());
if (solidus.is_delim('/') && maybe_denominator.has_value() && maybe_denominator.value() >= 0) {
auto denominator = maybe_denominator.value();
// Two-value ratio
two_value_transaction.commit();
transaction.commit();
return Ratio { numerator, denominator };
}
}
// Single-value ratio
transaction.commit();
return Ratio { numerator };
}
// https://www.w3.org/TR/css-syntax-3/#urange-syntax
Optional<UnicodeRange> Parser::parse_unicode_range(TokenStream<ComponentValue>& tokens)
{
auto transaction = tokens.begin_transaction();
tokens.skip_whitespace();
// <urange> =
// u '+' <ident-token> '?'* |
// u <dimension-token> '?'* |
// u <number-token> '?'* |
// u <number-token> <dimension-token> |
// u <number-token> <number-token> |
// u '+' '?'+
// (All with no whitespace in between tokens.)
// NOTE: Parsing this is different from usual. We take these steps:
// 1. Match the grammar above against the tokens, concatenating them into a string using their original representation.
// 2. Then, parse that string according to the spec algorithm.
// Step 2 is performed by calling the other parse_unicode_range() overload.
auto is_ending_token = [](ComponentValue const& component_value) {
return component_value.is(Token::Type::EndOfFile)
|| component_value.is(Token::Type::Comma)
|| component_value.is(Token::Type::Semicolon)
|| component_value.is(Token::Type::Whitespace);
};
auto create_unicode_range = [&](StringView text, auto& local_transaction) -> Optional<UnicodeRange> {
auto maybe_unicode_range = parse_unicode_range(text);
if (maybe_unicode_range.has_value()) {
local_transaction.commit();
transaction.commit();
}
return maybe_unicode_range;
};
// All options start with 'u'/'U'.
auto const& u = tokens.next_token();
if (!(u.is(Token::Type::Ident) && u.token().ident().equals_ignoring_ascii_case("u"sv))) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: <urange> does not start with 'u'");
return {};
}
auto const& second_token = tokens.next_token();
// u '+' <ident-token> '?'* |
// u '+' '?'+
if (second_token.is_delim('+')) {
auto local_transaction = tokens.begin_transaction();
StringBuilder string_builder;
string_builder.append(second_token.token().representation());
auto const& third_token = tokens.next_token();
if (third_token.is(Token::Type::Ident) || third_token.is_delim('?')) {
string_builder.append(third_token.token().representation());
while (tokens.peek_token().is_delim('?'))
string_builder.append(tokens.next_token().token().representation());
if (is_ending_token(tokens.peek_token()))
return create_unicode_range(string_builder.string_view(), local_transaction);
}
}
// u <dimension-token> '?'*
if (second_token.is(Token::Type::Dimension)) {
auto local_transaction = tokens.begin_transaction();
StringBuilder string_builder;
string_builder.append(second_token.token().representation());
while (tokens.peek_token().is_delim('?'))
string_builder.append(tokens.next_token().token().representation());
if (is_ending_token(tokens.peek_token()))
return create_unicode_range(string_builder.string_view(), local_transaction);
}
// u <number-token> '?'* |
// u <number-token> <dimension-token> |
// u <number-token> <number-token>
if (second_token.is(Token::Type::Number)) {
auto local_transaction = tokens.begin_transaction();
StringBuilder string_builder;
string_builder.append(second_token.token().representation());
if (is_ending_token(tokens.peek_token()))
return create_unicode_range(string_builder.string_view(), local_transaction);
auto const& third_token = tokens.next_token();
if (third_token.is_delim('?')) {
string_builder.append(third_token.token().representation());
while (tokens.peek_token().is_delim('?'))
string_builder.append(tokens.next_token().token().representation());
if (is_ending_token(tokens.peek_token()))
return create_unicode_range(string_builder.string_view(), local_transaction);
} else if (third_token.is(Token::Type::Dimension)) {
string_builder.append(third_token.token().representation());
if (is_ending_token(tokens.peek_token()))
return create_unicode_range(string_builder.string_view(), local_transaction);
} else if (third_token.is(Token::Type::Number)) {
string_builder.append(third_token.token().representation());
if (is_ending_token(tokens.peek_token()))
return create_unicode_range(string_builder.string_view(), local_transaction);
}
}
if constexpr (CSS_PARSER_DEBUG) {
dbgln("CSSParser: Tokens did not match <urange> grammar.");
tokens.dump_all_tokens();
}
return {};
}
Optional<UnicodeRange> Parser::parse_unicode_range(StringView text)
{
auto make_valid_unicode_range = [&](u32 start_value, u32 end_value) -> Optional<UnicodeRange> {
// https://www.w3.org/TR/css-syntax-3/#maximum-allowed-code-point
constexpr u32 maximum_allowed_code_point = 0x10FFFF;
// To determine what codepoints the <urange> represents:
// 1. If end value is greater than the maximum allowed code point,
// the <urange> is invalid and a syntax error.
if (end_value > maximum_allowed_code_point) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: Invalid <urange>: end_value ({}) > maximum ({})", end_value, maximum_allowed_code_point);
return {};
}
// 2. If start value is greater than end value, the <urange> is invalid and a syntax error.
if (start_value > end_value) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: Invalid <urange>: start_value ({}) > end_value ({})", start_value, end_value);
return {};
}
// 3. Otherwise, the <urange> represents a contiguous range of codepoints from start value to end value, inclusive.
return UnicodeRange { start_value, end_value };
};
// 1. Skipping the first u token, concatenate the representations of all the tokens in the production together.
// Let this be text.
// NOTE: The concatenation is already done by the caller.
GenericLexer lexer { text };
// 2. If the first character of text is U+002B PLUS SIGN, consume it.
// Otherwise, this is an invalid <urange>, and this algorithm must exit.
if (lexer.next_is('+')) {
lexer.consume();
} else {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: Second character of <urange> was not '+'; got: '{}'", lexer.consume());
return {};
}
// 3. Consume as many hex digits from text as possible.
// then consume as many U+003F QUESTION MARK (?) code points as possible.
auto hex_digits = lexer.consume_while(is_ascii_hex_digit);
auto question_marks = lexer.consume_while([](auto it) { return it == '?'; });
// If zero code points were consumed, or more than six code points were consumed,
// this is an invalid <urange>, and this algorithm must exit.
size_t consumed_code_points = hex_digits.length() + question_marks.length();
if (consumed_code_points == 0 || consumed_code_points > 6) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: <urange> start value had {} digits/?s, expected between 1 and 6.", consumed_code_points);
return {};
}
StringView start_value_code_points { hex_digits.characters_without_null_termination(), consumed_code_points };
// If any U+003F QUESTION MARK (?) code points were consumed, then:
if (question_marks.length() > 0) {
// 1. If there are any code points left in text, this is an invalid <urange>,
// and this algorithm must exit.
if (lexer.tell_remaining() != 0) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: <urange> invalid; had {} code points left over.", lexer.tell_remaining());
return {};
}
// 2. Interpret the consumed code points as a hexadecimal number,
// with the U+003F QUESTION MARK (?) code points replaced by U+0030 DIGIT ZERO (0) code points.
// This is the start value.
auto start_value_string = start_value_code_points.replace("?"sv, "0"sv, ReplaceMode::All);
auto maybe_start_value = AK::StringUtils::convert_to_uint_from_hex<u32>(start_value_string);
if (!maybe_start_value.has_value()) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: <urange> ?-converted start value did not parse as hex number.");
return {};
}
u32 start_value = maybe_start_value.release_value();
// 3. Interpret the consumed code points as a hexadecimal number again,
// with the U+003F QUESTION MARK (?) code points replaced by U+0046 LATIN CAPITAL LETTER F (F) code points.
// This is the end value.
auto end_value_string = start_value_code_points.replace("?"sv, "F"sv, ReplaceMode::All);
auto maybe_end_value = AK::StringUtils::convert_to_uint_from_hex<u32>(end_value_string);
if (!maybe_end_value.has_value()) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: <urange> ?-converted end value did not parse as hex number.");
return {};
}
u32 end_value = maybe_end_value.release_value();
// 4. Exit this algorithm.
return make_valid_unicode_range(start_value, end_value);
}
// Otherwise, interpret the consumed code points as a hexadecimal number. This is the start value.
auto maybe_start_value = AK::StringUtils::convert_to_uint_from_hex<u32>(start_value_code_points);
if (!maybe_start_value.has_value()) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: <urange> start value did not parse as hex number.");
return {};
}
u32 start_value = maybe_start_value.release_value();
// 4. If there are no code points left in text, The end value is the same as the start value.
// Exit this algorithm.
if (lexer.tell_remaining() == 0)
return make_valid_unicode_range(start_value, start_value);
// 5. If the next code point in text is U+002D HYPHEN-MINUS (-), consume it.
if (lexer.next_is('-')) {
lexer.consume();
}
// Otherwise, this is an invalid <urange>, and this algorithm must exit.
else {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: <urange> start and end values not separated by '-'.");
return {};
}
// 6. Consume as many hex digits as possible from text.
auto end_hex_digits = lexer.consume_while(is_ascii_hex_digit);
// If zero hex digits were consumed, or more than 6 hex digits were consumed,
// this is an invalid <urange>, and this algorithm must exit.
if (end_hex_digits.length() == 0 || end_hex_digits.length() > 6) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: <urange> end value had {} digits, expected between 1 and 6.", end_hex_digits.length());
return {};
}
// If there are any code points left in text, this is an invalid <urange>, and this algorithm must exit.
if (lexer.tell_remaining() != 0) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: <urange> invalid; had {} code points left over.", lexer.tell_remaining());
return {};
}
// 7. Interpret the consumed code points as a hexadecimal number. This is the end value.
auto maybe_end_value = AK::StringUtils::convert_to_uint_from_hex<u32>(end_hex_digits);
if (!maybe_end_value.has_value()) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: <urange> end value did not parse as hex number.");
return {};
}
u32 end_value = maybe_end_value.release_value();
return make_valid_unicode_range(start_value, end_value);
}
RefPtr<StyleValue> Parser::parse_dimension_value(ComponentValue const& component_value)
{
// Numbers with no units can be lengths, in two situations:
// 1) We're in quirks mode, and it's an integer.
// 2) It's a 0.
// We handle case 1 here. Case 2 is handled by NumericStyleValue pretending to be a LengthStyleValue if it is 0.
if (component_value.is(Token::Type::Number) && component_value.token().number_value() != 0 && !(m_context.in_quirks_mode() && property_has_quirk(m_context.current_property_id(), Quirk::UnitlessLength)))
return nullptr;
auto dimension = parse_dimension(component_value);
if (!dimension.has_value())
return nullptr;
if (dimension->is_angle())
return AngleStyleValue::create(dimension->angle());
if (dimension->is_frequency())
return FrequencyStyleValue::create(dimension->frequency());
if (dimension->is_length())
return LengthStyleValue::create(dimension->length());
if (dimension->is_percentage())
return PercentageStyleValue::create(dimension->percentage());
if (dimension->is_resolution())
return ResolutionStyleValue::create(dimension->resolution());
if (dimension->is_time())
return TimeStyleValue::create(dimension->time());
VERIFY_NOT_REACHED();
}
RefPtr<StyleValue> Parser::parse_integer_value(TokenStream<ComponentValue>& tokens)
{
auto peek_token = tokens.peek_token();
if (peek_token.is(Token::Type::Number) && peek_token.token().number().is_integer()) {
(void)tokens.next_token();
return IntegerStyleValue::create(peek_token.token().number().integer_value());
}
return nullptr;
}
RefPtr<StyleValue> Parser::parse_number_value(TokenStream<ComponentValue>& tokens)
{
auto peek_token = tokens.peek_token();
if (peek_token.is(Token::Type::Number)) {
(void)tokens.next_token();
return NumberStyleValue::create(peek_token.token().number().value());
}
return nullptr;
}
RefPtr<StyleValue> Parser::parse_identifier_value(ComponentValue const& component_value)
{
if (component_value.is(Token::Type::Ident)) {
auto value_id = value_id_from_string(component_value.token().ident());
if (value_id.has_value())
return IdentifierStyleValue::create(value_id.value());
}
return nullptr;
}
Optional<Color> Parser::parse_rgb_or_hsl_color(StringView function_name, Vector<ComponentValue> const& component_values)
{
Token params[4];
bool legacy_syntax = false;
auto tokens = TokenStream { component_values };
tokens.skip_whitespace();
auto const& component1 = tokens.next_token();
if (!component1.is(Token::Type::Number)
&& !component1.is(Token::Type::Percentage)
&& !component1.is(Token::Type::Dimension))
return {};
params[0] = component1.token();
tokens.skip_whitespace();
if (tokens.peek_token().is(Token::Type::Comma)) {
legacy_syntax = true;
tokens.next_token();
}
tokens.skip_whitespace();
auto const& component2 = tokens.next_token();
if (!component2.is(Token::Type::Number) && !component2.is(Token::Type::Percentage))
return {};
params[1] = component2.token();
tokens.skip_whitespace();
if (legacy_syntax && !tokens.next_token().is(Token::Type::Comma))
return {};
tokens.skip_whitespace();
auto const& component3 = tokens.next_token();
if (!component3.is(Token::Type::Number) && !component3.is(Token::Type::Percentage))
return {};
params[2] = component3.token();
tokens.skip_whitespace();
auto const& alpha_separator = tokens.peek_token();
bool has_comma = alpha_separator.is(Token::Type::Comma);
bool has_slash = alpha_separator.is_delim('/');
if (legacy_syntax ? has_comma : has_slash) {
tokens.next_token();
tokens.skip_whitespace();
auto const& component4 = tokens.next_token();
if (!component4.is(Token::Type::Number) && !component4.is(Token::Type::Percentage))
return {};
params[3] = component4.token();
}
tokens.skip_whitespace();
if (tokens.has_next_token())
return {};
if (function_name.equals_ignoring_ascii_case("rgb"sv)
|| function_name.equals_ignoring_ascii_case("rgba"sv)) {
// https://www.w3.org/TR/css-color-4/#rgb-functions
u8 a_val = 255;
if (params[3].is(Token::Type::Number))
a_val = clamp(lround(params[3].number_value() * 255.0), 0, 255);
else if (params[3].is(Token::Type::Percentage))
a_val = clamp(lround(params[3].percentage() * 2.55), 0, 255);
if (params[0].is(Token::Type::Number)
&& params[1].is(Token::Type::Number)
&& params[2].is(Token::Type::Number)) {
u8 r_val = clamp(llroundf(params[0].number_value()), 0, 255);
u8 g_val = clamp(llroundf(params[1].number_value()), 0, 255);
u8 b_val = clamp(llroundf(params[2].number_value()), 0, 255);
return Color(r_val, g_val, b_val, a_val);
}
if (params[0].is(Token::Type::Percentage)
&& params[1].is(Token::Type::Percentage)
&& params[2].is(Token::Type::Percentage)) {
u8 r_val = lround(clamp(params[0].percentage() * 2.55, 0, 255));
u8 g_val = lround(clamp(params[1].percentage() * 2.55, 0, 255));
u8 b_val = lround(clamp(params[2].percentage() * 2.55, 0, 255));
return Color(r_val, g_val, b_val, a_val);
}
} else if (function_name.equals_ignoring_ascii_case("hsl"sv)
|| function_name.equals_ignoring_ascii_case("hsla"sv)) {
// https://www.w3.org/TR/css-color-4/#the-hsl-notation
auto a_val = 1.0;
if (params[3].is(Token::Type::Number))
a_val = params[3].number_value();
else if (params[3].is(Token::Type::Percentage))
a_val = params[3].percentage() / 100.0;
if (params[0].is(Token::Type::Dimension)
&& params[1].is(Token::Type::Percentage)
&& params[2].is(Token::Type::Percentage)) {
auto numeric_value = params[0].dimension_value();
auto unit_string = params[0].dimension_unit();
auto angle_type = Angle::unit_from_name(unit_string);
if (!angle_type.has_value())
return {};
auto angle = Angle { numeric_value, angle_type.release_value() };
float h_val = fmod(angle.to_degrees(), 360.0);
float s_val = params[1].percentage() / 100.0;
float l_val = params[2].percentage() / 100.0;
return Color::from_hsla(h_val, s_val, l_val, a_val);
}
if (params[0].is(Token::Type::Number)
&& params[1].is(Token::Type::Percentage)
&& params[2].is(Token::Type::Percentage)) {
float h_val = fmod(params[0].number_value(), 360.0);
float s_val = params[1].percentage() / 100.0;
float l_val = params[2].percentage() / 100.0;
return Color::from_hsla(h_val, s_val, l_val, a_val);
}
}
return {};
}
// https://www.w3.org/TR/CSS2/visufx.html#value-def-shape
RefPtr<StyleValue> Parser::parse_rect_value(ComponentValue const& component_value)
{
if (!component_value.is_function())
return nullptr;
auto const& function = component_value.function();
if (!function.name().equals_ignoring_ascii_case("rect"sv))
return nullptr;
Vector<Length, 4> params;
auto tokens = TokenStream { function.values() };
enum class CommaRequirement {
Unknown,
RequiresCommas,
RequiresNoCommas
};
enum class Side {
Top = 0,
Right = 1,
Bottom = 2,
Left = 3
};
auto comma_requirement = CommaRequirement::Unknown;
// In CSS 2.1, the only valid <shape> value is: rect(<top>, <right>, <bottom>, <left>) where
// <top> and <bottom> specify offsets from the top border edge of the box, and <right>, and
// <left> specify offsets from the left border edge of the box.
for (size_t side = 0; side < 4; side++) {
tokens.skip_whitespace();
// <top>, <right>, <bottom>, and <left> may either have a <length> value or 'auto'.
// Negative lengths are permitted.
auto current_token = tokens.next_token().token();
if (current_token.is(Token::Type::Ident) && current_token.ident().equals_ignoring_ascii_case("auto"sv)) {
params.append(Length::make_auto());
} else {
auto maybe_length = parse_length(current_token);
if (!maybe_length.has_value())
return nullptr;
params.append(maybe_length.value());
}
tokens.skip_whitespace();
// The last side, should be no more tokens following it.
if (static_cast<Side>(side) == Side::Left) {
if (tokens.has_next_token())
return nullptr;
break;
}
bool next_is_comma = tokens.peek_token().is(Token::Type::Comma);
// Authors should separate offset values with commas. User agents must support separation
// with commas, but may also support separation without commas (but not a combination),
// because a previous revision of this specification was ambiguous in this respect.
if (comma_requirement == CommaRequirement::Unknown)
comma_requirement = next_is_comma ? CommaRequirement::RequiresCommas : CommaRequirement::RequiresNoCommas;
if (comma_requirement == CommaRequirement::RequiresCommas) {
if (next_is_comma)
tokens.next_token();
else
return nullptr;
} else if (comma_requirement == CommaRequirement::RequiresNoCommas) {
if (next_is_comma)
return nullptr;
} else {
VERIFY_NOT_REACHED();
}
}
return RectStyleValue::create(EdgeRect { params[0], params[1], params[2], params[3] });
}
Optional<Color> Parser::parse_color(ComponentValue const& component_value)
{
// https://www.w3.org/TR/css-color-4/
if (component_value.is(Token::Type::Ident)) {
auto ident = component_value.token().ident();
auto color = Color::from_string(ident);
if (color.has_value())
return color;
} else if (component_value.is(Token::Type::Hash)) {
auto color = Color::from_string(DeprecatedString::formatted("#{}", component_value.token().hash_value()));
if (color.has_value())
return color;
return {};
} else if (component_value.is_function()) {
auto const& function = component_value.function();
auto const& values = function.values();
return parse_rgb_or_hsl_color(function.name(), values);
}
// https://quirks.spec.whatwg.org/#the-hashless-hex-color-quirk
if (m_context.in_quirks_mode() && property_has_quirk(m_context.current_property_id(), Quirk::HashlessHexColor)) {
// The value of a quirky color is obtained from the possible component values using the following algorithm,
// aborting on the first step that returns a value:
// 1. Let cv be the component value.
auto const& cv = component_value;
DeprecatedString serialization;
// 2. If cv is a <number-token> or a <dimension-token>, follow these substeps:
if (cv.is(Token::Type::Number) || cv.is(Token::Type::Dimension)) {
// 1. If cvs type flag is not "integer", return an error.
// This means that values that happen to use scientific notation, e.g., 5e5e5e, will fail to parse.
if (!cv.token().number().is_integer())
return {};
// 2. If cvs value is less than zero, return an error.
auto value = cv.is(Token::Type::Number) ? cv.token().to_integer() : cv.token().dimension_value_int();
if (value < 0)
return {};
// 3. Let serialization be the serialization of cvs value, as a base-ten integer using digits 0-9 (U+0030 to U+0039) in the shortest form possible.
StringBuilder serialization_builder;
serialization_builder.appendff("{}", value);
// 4. If cv is a <dimension-token>, append the unit to serialization.
if (cv.is(Token::Type::Dimension))
serialization_builder.append(cv.token().dimension_unit());
// 5. If serialization consists of fewer than six characters, prepend zeros (U+0030) so that it becomes six characters.
serialization = serialization_builder.to_deprecated_string();
if (serialization_builder.length() < 6) {
StringBuilder builder;
for (size_t i = 0; i < (6 - serialization_builder.length()); i++)
builder.append('0');
builder.append(serialization_builder.string_view());
serialization = builder.to_deprecated_string();
}
}
// 3. Otherwise, cv is an <ident-token>; let serialization be cvs value.
else {
if (!cv.is(Token::Type::Ident))
return {};
serialization = cv.token().ident();
}
// 4. If serialization does not consist of three or six characters, return an error.
if (serialization.length() != 3 && serialization.length() != 6)
return {};
// 5. If serialization contains any characters not in the range [0-9A-Fa-f] (U+0030 to U+0039, U+0041 to U+0046, U+0061 to U+0066), return an error.
for (auto c : serialization) {
if (!((c >= '0' && c <= '9') || (c >= 'A' && c <= 'F') || (c >= 'a' && c <= 'f')))
return {};
}
// 6. Return the concatenation of "#" (U+0023) and serialization.
DeprecatedString concatenation = DeprecatedString::formatted("#{}", serialization);
return Color::from_string(concatenation);
}
return {};
}
RefPtr<StyleValue> Parser::parse_color_value(ComponentValue const& component_value)
{
auto color = parse_color(component_value);
if (color.has_value())
return ColorStyleValue::create(color.value());
if (component_value.is(Token::Type::Ident)) {
auto ident = value_id_from_string(component_value.token().ident());
if (ident.has_value() && IdentifierStyleValue::is_color(ident.value()))
return IdentifierStyleValue::create(ident.value());
}
return nullptr;
}
RefPtr<StyleValue> Parser::parse_ratio_value(TokenStream<ComponentValue>& tokens)
{
if (auto ratio = parse_ratio(tokens); ratio.has_value())
return RatioStyleValue::create(ratio.release_value());
return nullptr;
}
RefPtr<StyleValue> Parser::parse_string_value(ComponentValue const& component_value)
{
if (component_value.is(Token::Type::String))
return StringStyleValue::create(MUST(String::from_utf8(component_value.token().string())));
return nullptr;
}
RefPtr<StyleValue> Parser::parse_image_value(ComponentValue const& component_value)
{
auto url = parse_url_function(component_value);
if (url.has_value())
return ImageStyleValue::create(url.value());
auto linear_gradient = parse_linear_gradient_function(component_value);
if (linear_gradient)
return linear_gradient;
auto conic_gradient = parse_conic_gradient_function(component_value);
if (conic_gradient)
return conic_gradient;
return parse_radial_gradient_function(component_value);
}
// https://svgwg.org/svg2-draft/painting.html#SpecifyingPaint
RefPtr<StyleValue> Parser::parse_paint_value(TokenStream<ComponentValue>& tokens)
{
// `<paint> = none | <color> | <url> [none | <color>]? | context-fill | context-stroke`
auto parse_color_or_none = [&]() -> Optional<RefPtr<StyleValue>> {
if (auto color = parse_color_value(tokens.peek_token())) {
(void)tokens.next_token();
return color;
}
// NOTE: <color> also accepts identifiers, so we do this identifier check last.
if (tokens.peek_token().is(Token::Type::Ident)) {
auto maybe_ident = value_id_from_string(tokens.peek_token().token().ident());
if (maybe_ident.has_value()) {
// FIXME: Accept `context-fill` and `context-stroke`
switch (*maybe_ident) {
case ValueID::None:
(void)tokens.next_token();
return IdentifierStyleValue::create(*maybe_ident);
default:
return nullptr;
}
}
}
return OptionalNone {};
};
// FIMXE: Allow context-fill/context-stroke here
if (auto color_or_none = parse_color_or_none(); color_or_none.has_value())
return *color_or_none;
if (auto url = parse_url_value(tokens.peek_token())) {
(void)tokens.next_token();
tokens.skip_whitespace();
if (auto color_or_none = parse_color_or_none(); color_or_none == nullptr) {
// Fail to parse if the fallback is invalid, but otherwise ignore it.
// FIXME: Use fallback color
return nullptr;
}
return url;
}
return nullptr;
}
template<typename ParseFunction>
RefPtr<StyleValue> Parser::parse_comma_separated_value_list(Vector<ComponentValue> const& component_values, ParseFunction parse_one_value)
{
auto tokens = TokenStream { component_values };
auto first = parse_one_value(tokens);
if (!first || !tokens.has_next_token())
return first;
StyleValueVector values;
values.append(first.release_nonnull());
while (tokens.has_next_token()) {
if (!tokens.next_token().is(Token::Type::Comma))
return nullptr;
if (auto maybe_value = parse_one_value(tokens)) {
values.append(maybe_value.release_nonnull());
continue;
}
return nullptr;
}
return StyleValueList::create(move(values), StyleValueList::Separator::Comma);
}
RefPtr<StyleValue> Parser::parse_simple_comma_separated_value_list(PropertyID property_id, Vector<ComponentValue> const& component_values)
{
return parse_comma_separated_value_list(component_values, [=, this](auto& tokens) -> RefPtr<StyleValue> {
if (auto value = parse_css_value_for_property(property_id, tokens))
return value;
tokens.reconsume_current_input_token();
return nullptr;
});
}
static void remove_property(Vector<PropertyID>& properties, PropertyID property_to_remove)
{
properties.remove_first_matching([&](auto it) { return it == property_to_remove; });
}
// https://www.w3.org/TR/css-sizing-4/#aspect-ratio
RefPtr<StyleValue> Parser::parse_aspect_ratio_value(Vector<ComponentValue> const& component_values)
{
// `auto || <ratio>`
RefPtr<StyleValue> auto_value;
RefPtr<StyleValue> ratio_value;
auto tokens = TokenStream { component_values };
while (tokens.has_next_token()) {
auto maybe_value = parse_css_value_for_property(PropertyID::AspectRatio, tokens);
if (!maybe_value)
return nullptr;
if (maybe_value->is_ratio()) {
if (ratio_value)
return nullptr;
ratio_value = maybe_value.release_nonnull();
continue;
}
if (maybe_value->is_identifier() && maybe_value->as_identifier().id() == ValueID::Auto) {
if (auto_value)
return nullptr;
auto_value = maybe_value.release_nonnull();
continue;
}
return nullptr;
}
if (auto_value && ratio_value) {
return StyleValueList::create(
StyleValueVector { auto_value.release_nonnull(), ratio_value.release_nonnull() },
StyleValueList::Separator::Space);
}
if (ratio_value)
return ratio_value.release_nonnull();
if (auto_value)
return auto_value.release_nonnull();
return nullptr;
}
RefPtr<StyleValue> Parser::parse_background_value(Vector<ComponentValue> const& component_values)
{
auto make_background_shorthand = [&](auto background_color, auto background_image, auto background_position, auto background_size, auto background_repeat, auto background_attachment, auto background_origin, auto background_clip) {
return ShorthandStyleValue::create(PropertyID::Background,
{ PropertyID::BackgroundColor, PropertyID::BackgroundImage, PropertyID::BackgroundPosition, PropertyID::BackgroundSize, PropertyID::BackgroundRepeat, PropertyID::BackgroundAttachment, PropertyID::BackgroundOrigin, PropertyID::BackgroundClip },
{ move(background_color), move(background_image), move(background_position), move(background_size), move(background_repeat), move(background_attachment), move(background_origin), move(background_clip) });
};
StyleValueVector background_images;
StyleValueVector background_positions;
StyleValueVector background_sizes;
StyleValueVector background_repeats;
StyleValueVector background_attachments;
StyleValueVector background_clips;
StyleValueVector background_origins;
RefPtr<StyleValue> background_color;
auto initial_background_image = property_initial_value(m_context.realm(), PropertyID::BackgroundImage);
auto initial_background_position = property_initial_value(m_context.realm(), PropertyID::BackgroundPosition);
auto initial_background_size = property_initial_value(m_context.realm(), PropertyID::BackgroundSize);
auto initial_background_repeat = property_initial_value(m_context.realm(), PropertyID::BackgroundRepeat);
auto initial_background_attachment = property_initial_value(m_context.realm(), PropertyID::BackgroundAttachment);
auto initial_background_clip = property_initial_value(m_context.realm(), PropertyID::BackgroundClip);
auto initial_background_origin = property_initial_value(m_context.realm(), PropertyID::BackgroundOrigin);
auto initial_background_color = property_initial_value(m_context.realm(), PropertyID::BackgroundColor);
// Per-layer values
RefPtr<StyleValue> background_image;
RefPtr<StyleValue> background_position;
RefPtr<StyleValue> background_size;
RefPtr<StyleValue> background_repeat;
RefPtr<StyleValue> background_attachment;
RefPtr<StyleValue> background_clip;
RefPtr<StyleValue> background_origin;
bool has_multiple_layers = false;
// BackgroundSize is always parsed as part of BackgroundPosition, so we don't include it here.
Vector<PropertyID> remaining_layer_properties {
PropertyID::BackgroundAttachment,
PropertyID::BackgroundClip,
PropertyID::BackgroundColor,
PropertyID::BackgroundImage,
PropertyID::BackgroundOrigin,
PropertyID::BackgroundPosition,
PropertyID::BackgroundRepeat,
};
auto background_layer_is_valid = [&](bool allow_background_color) -> bool {
if (allow_background_color) {
if (background_color)
return true;
} else {
if (background_color)
return false;
}
return background_image || background_position || background_size || background_repeat || background_attachment || background_clip || background_origin;
};
auto complete_background_layer = [&]() {
background_images.append(background_image ? background_image.release_nonnull() : initial_background_image);
background_positions.append(background_position ? background_position.release_nonnull() : initial_background_position);
background_sizes.append(background_size ? background_size.release_nonnull() : initial_background_size);
background_repeats.append(background_repeat ? background_repeat.release_nonnull() : initial_background_repeat);
background_attachments.append(background_attachment ? background_attachment.release_nonnull() : initial_background_attachment);
if (!background_origin && !background_clip) {
background_origin = initial_background_origin;
background_clip = initial_background_clip;
} else if (!background_clip) {
background_clip = background_origin;
}
background_origins.append(background_origin.release_nonnull());
background_clips.append(background_clip.release_nonnull());
background_image = nullptr;
background_position = nullptr;
background_size = nullptr;
background_repeat = nullptr;
background_attachment = nullptr;
background_clip = nullptr;
background_origin = nullptr;
remaining_layer_properties.clear_with_capacity();
remaining_layer_properties.unchecked_append(PropertyID::BackgroundAttachment);
remaining_layer_properties.unchecked_append(PropertyID::BackgroundClip);
remaining_layer_properties.unchecked_append(PropertyID::BackgroundColor);
remaining_layer_properties.unchecked_append(PropertyID::BackgroundImage);
remaining_layer_properties.unchecked_append(PropertyID::BackgroundOrigin);
remaining_layer_properties.unchecked_append(PropertyID::BackgroundPosition);
remaining_layer_properties.unchecked_append(PropertyID::BackgroundRepeat);
};
auto tokens = TokenStream { component_values };
while (tokens.has_next_token()) {
if (tokens.peek_token().is(Token::Type::Comma)) {
has_multiple_layers = true;
if (!background_layer_is_valid(false))
return nullptr;
complete_background_layer();
(void)tokens.next_token();
continue;
}
auto value_and_property = parse_css_value_for_properties(remaining_layer_properties, tokens);
if (!value_and_property.has_value())
return nullptr;
auto& value = value_and_property->style_value;
remove_property(remaining_layer_properties, value_and_property->property);
switch (value_and_property->property) {
case PropertyID::BackgroundAttachment:
VERIFY(!background_attachment);
background_attachment = value.release_nonnull();
continue;
case PropertyID::BackgroundColor:
VERIFY(!background_color);
background_color = value.release_nonnull();
continue;
case PropertyID::BackgroundImage:
VERIFY(!background_image);
background_image = value.release_nonnull();
continue;
case PropertyID::BackgroundClip:
case PropertyID::BackgroundOrigin: {
// background-origin and background-clip accept the same values. From the spec:
// "If one <box> value is present then it sets both background-origin and background-clip to that value.
// If two values are present, then the first sets background-origin and the second background-clip."
// - https://www.w3.org/TR/css-backgrounds-3/#background
// So, we put the first one in background-origin, then if we get a second, we put it in background-clip.
// If we only get one, we copy the value before creating the ShorthandStyleValue.
if (!background_origin) {
background_origin = value.release_nonnull();
} else if (!background_clip) {
background_clip = value.release_nonnull();
} else {
VERIFY_NOT_REACHED();
}
continue;
}
case PropertyID::BackgroundPosition: {
VERIFY(!background_position);
tokens.reconsume_current_input_token();
if (auto maybe_background_position = parse_single_background_position_value(tokens)) {
background_position = maybe_background_position.release_nonnull();
// Attempt to parse `/ <background-size>`
auto transaction = tokens.begin_transaction();
auto& maybe_slash = tokens.next_token();
if (maybe_slash.is_delim('/')) {
if (auto maybe_background_size = parse_single_background_size_value(tokens)) {
transaction.commit();
background_size = maybe_background_size.release_nonnull();
continue;
}
return nullptr;
}
continue;
}
return nullptr;
}
case PropertyID::BackgroundRepeat: {
VERIFY(!background_repeat);
tokens.reconsume_current_input_token();
if (auto maybe_repeat = parse_single_background_repeat_value(tokens)) {
background_repeat = maybe_repeat.release_nonnull();
continue;
}
return nullptr;
}
default:
VERIFY_NOT_REACHED();
}
return nullptr;
}
if (!background_layer_is_valid(true))
return nullptr;
// We only need to create StyleValueLists if there are multiple layers.
// Otherwise, we can pass the single StyleValues directly.
if (has_multiple_layers) {
complete_background_layer();
if (!background_color)
background_color = initial_background_color;
return make_background_shorthand(
background_color.release_nonnull(),
StyleValueList::create(move(background_images), StyleValueList::Separator::Comma),
StyleValueList::create(move(background_positions), StyleValueList::Separator::Comma),
StyleValueList::create(move(background_sizes), StyleValueList::Separator::Comma),
StyleValueList::create(move(background_repeats), StyleValueList::Separator::Comma),
StyleValueList::create(move(background_attachments), StyleValueList::Separator::Comma),
StyleValueList::create(move(background_origins), StyleValueList::Separator::Comma),
StyleValueList::create(move(background_clips), StyleValueList::Separator::Comma));
}
if (!background_color)
background_color = initial_background_color;
if (!background_image)
background_image = initial_background_image;
if (!background_position)
background_position = initial_background_position;
if (!background_size)
background_size = initial_background_size;
if (!background_repeat)
background_repeat = initial_background_repeat;
if (!background_attachment)
background_attachment = initial_background_attachment;
if (!background_origin && !background_clip) {
background_origin = initial_background_origin;
background_clip = initial_background_clip;
} else if (!background_clip) {
background_clip = background_origin;
}
return make_background_shorthand(
background_color.release_nonnull(),
background_image.release_nonnull(),
background_position.release_nonnull(),
background_size.release_nonnull(),
background_repeat.release_nonnull(),
background_attachment.release_nonnull(),
background_origin.release_nonnull(),
background_clip.release_nonnull());
}
static Optional<PositionEdge> identifier_to_edge(ValueID identifier)
{
switch (identifier) {
case ValueID::Top:
return PositionEdge::Top;
case ValueID::Bottom:
return PositionEdge::Bottom;
case ValueID::Left:
return PositionEdge::Left;
case ValueID::Right:
return PositionEdge::Right;
default:
return {};
}
}
static Optional<LengthPercentage> style_value_to_length_percentage(auto value)
{
if (value->is_percentage())
return LengthPercentage { value->as_percentage().percentage() };
if (value->is_length())
return LengthPercentage { value->as_length().length() };
if (value->is_calculated())
return LengthPercentage { value->as_calculated() };
return {};
}
RefPtr<StyleValue> Parser::parse_single_background_position_value(TokenStream<ComponentValue>& tokens)
{
// NOTE: This *looks* like it parses a <position>, but it doesn't. From the spec:
// "Note: The background-position property also accepts a three-value syntax.
// This has been disallowed generically because it creates parsing ambiguities
// when combined with other length or percentage components in a property value."
// - https://www.w3.org/TR/css-values-4/#typedef-position
// So, we'll need a separate function to parse <position> later.
auto transaction = tokens.begin_transaction();
auto is_horizontal = [](ValueID identifier) -> bool {
switch (identifier) {
case ValueID::Left:
case ValueID::Right:
return true;
default:
return false;
}
};
auto is_vertical = [](ValueID identifier) -> bool {
switch (identifier) {
case ValueID::Top:
case ValueID::Bottom:
return true;
default:
return false;
}
};
struct EdgeOffset {
PositionEdge edge;
LengthPercentage offset;
bool edge_provided;
bool offset_provided;
};
Optional<EdgeOffset> horizontal;
Optional<EdgeOffset> vertical;
bool found_center = false;
auto const center_offset = Percentage { 50 };
auto const zero_offset = Length::make_px(0);
while (tokens.has_next_token()) {
// Check if we're done
auto seen_items = (horizontal.has_value() ? 1 : 0) + (vertical.has_value() ? 1 : 0) + (found_center ? 1 : 0);
if (seen_items == 2)
break;
auto maybe_value = parse_css_value_for_property(PropertyID::BackgroundPosition, tokens);
if (!maybe_value)
break;
auto value = maybe_value.release_nonnull();
if (auto offset = style_value_to_length_percentage(value); offset.has_value()) {
if (!horizontal.has_value()) {
horizontal = EdgeOffset { PositionEdge::Left, *offset, false, true };
} else if (!vertical.has_value()) {
vertical = EdgeOffset { PositionEdge::Top, *offset, false, true };
} else {
return nullptr;
}
continue;
}
auto try_parse_offset = [&](bool& offset_provided) -> LengthPercentage {
auto transaction = tokens.begin_transaction();
if (tokens.has_next_token()) {
auto maybe_value = parse_css_value_for_property(PropertyID::BackgroundPosition, tokens);
if (!maybe_value)
return zero_offset;
auto offset = style_value_to_length_percentage(maybe_value.release_nonnull());
if (offset.has_value()) {
offset_provided = true;
transaction.commit();
return *offset;
}
}
return zero_offset;
};
if (value->is_identifier()) {
auto identifier = value->to_identifier();
if (is_horizontal(identifier)) {
bool offset_provided = false;
auto offset = try_parse_offset(offset_provided);
horizontal = EdgeOffset { *identifier_to_edge(identifier), offset, true, offset_provided };
} else if (is_vertical(identifier)) {
bool offset_provided = false;
auto offset = try_parse_offset(offset_provided);
vertical = EdgeOffset { *identifier_to_edge(identifier), offset, true, offset_provided };
} else if (identifier == ValueID::Center) {
found_center = true;
} else {
return nullptr;
}
continue;
}
tokens.reconsume_current_input_token();
break;
}
if (found_center) {
if (horizontal.has_value() && vertical.has_value())
return nullptr;
if (!horizontal.has_value())
horizontal = EdgeOffset { PositionEdge::Left, center_offset, true, false };
if (!vertical.has_value())
vertical = EdgeOffset { PositionEdge::Top, center_offset, true, false };
}
if (!horizontal.has_value() && !vertical.has_value())
return nullptr;
// Unpack `<edge> <length>`:
// The loop above reads this pattern as a single EdgeOffset, when actually, it should be treated
// as `x y` if the edge is horizontal, and `y` (with the second token reconsumed) otherwise.
if (!vertical.has_value() && horizontal->edge_provided && horizontal->offset_provided) {
// Split into `x y`
vertical = EdgeOffset { PositionEdge::Top, horizontal->offset, false, true };
horizontal->offset = zero_offset;
horizontal->offset_provided = false;
} else if (!horizontal.has_value() && vertical->edge_provided && vertical->offset_provided) {
// `y`, reconsume
vertical->offset = zero_offset;
vertical->offset_provided = false;
tokens.reconsume_current_input_token();
}
// If only one value is specified, the second value is assumed to be center.
if (!horizontal.has_value())
horizontal = EdgeOffset { PositionEdge::Left, center_offset, false, false };
if (!vertical.has_value())
vertical = EdgeOffset { PositionEdge::Top, center_offset, false, false };
transaction.commit();
return PositionStyleValue::create(
EdgeStyleValue::create(horizontal->edge, horizontal->offset),
EdgeStyleValue::create(vertical->edge, vertical->offset));
}
RefPtr<StyleValue> Parser::parse_single_background_position_x_or_y_value(TokenStream<ComponentValue>& tokens, PropertyID property)
{
PositionEdge relative_edge {};
if (property == PropertyID::BackgroundPositionX) {
// [ center | [ [ left | right | x-start | x-end ]? <length-percentage>? ]! ]#
relative_edge = PositionEdge::Left;
} else if (property == PropertyID::BackgroundPositionY) {
// [ center | [ [ top | bottom | y-start | y-end ]? <length-percentage>? ]! ]#
relative_edge = PositionEdge::Top;
} else {
VERIFY_NOT_REACHED();
}
auto transaction = tokens.begin_transaction();
if (!tokens.has_next_token())
return nullptr;
auto value = parse_css_value_for_property(property, tokens);
if (!value)
return nullptr;
if (value->is_identifier()) {
auto identifier = value->to_identifier();
if (identifier == ValueID::Center) {
transaction.commit();
return EdgeStyleValue::create(relative_edge, Percentage { 50 });
}
if (auto edge = identifier_to_edge(identifier); edge.has_value()) {
relative_edge = *edge;
} else {
return nullptr;
}
if (tokens.has_next_token()) {
value = parse_css_value_for_property(property, tokens);
if (!value) {
transaction.commit();
return EdgeStyleValue::create(relative_edge, Length::make_px(0));
}
}
}
auto offset = style_value_to_length_percentage(value);
if (offset.has_value()) {
transaction.commit();
return EdgeStyleValue::create(relative_edge, *offset);
}
// If no offset is provided create this element but with an offset of default value of zero
transaction.commit();
return EdgeStyleValue::create(relative_edge, Length::make_px(0));
}
RefPtr<StyleValue> Parser::parse_single_background_repeat_value(TokenStream<ComponentValue>& tokens)
{
auto transaction = tokens.begin_transaction();
auto is_directional_repeat = [](StyleValue const& value) -> bool {
auto value_id = value.to_identifier();
return value_id == ValueID::RepeatX || value_id == ValueID::RepeatY;
};
auto as_repeat = [](ValueID identifier) -> Optional<Repeat> {
switch (identifier) {
case ValueID::NoRepeat:
return Repeat::NoRepeat;
case ValueID::Repeat:
return Repeat::Repeat;
case ValueID::Round:
return Repeat::Round;
case ValueID::Space:
return Repeat::Space;
default:
return {};
}
};
auto maybe_x_value = parse_css_value_for_property(PropertyID::BackgroundRepeat, tokens);
if (!maybe_x_value)
return nullptr;
auto x_value = maybe_x_value.release_nonnull();
if (is_directional_repeat(*x_value)) {
auto value_id = x_value->to_identifier();
transaction.commit();
return BackgroundRepeatStyleValue::create(
value_id == ValueID::RepeatX ? Repeat::Repeat : Repeat::NoRepeat,
value_id == ValueID::RepeatX ? Repeat::NoRepeat : Repeat::Repeat);
}
auto x_repeat = as_repeat(x_value->to_identifier());
if (!x_repeat.has_value())
return nullptr;
// See if we have a second value for Y
auto maybe_y_value = parse_css_value_for_property(PropertyID::BackgroundRepeat, tokens);
if (!maybe_y_value) {
// We don't have a second value, so use x for both
transaction.commit();
return BackgroundRepeatStyleValue::create(x_repeat.value(), x_repeat.value());
}
auto y_value = maybe_y_value.release_nonnull();
if (is_directional_repeat(*y_value))
return nullptr;
auto y_repeat = as_repeat(y_value->to_identifier());
if (!y_repeat.has_value())
return nullptr;
transaction.commit();
return BackgroundRepeatStyleValue::create(x_repeat.value(), y_repeat.value());
}
RefPtr<StyleValue> Parser::parse_single_background_size_value(TokenStream<ComponentValue>& tokens)
{
auto transaction = tokens.begin_transaction();
auto get_length_percentage = [](StyleValue& style_value) -> Optional<LengthPercentage> {
if (style_value.has_auto())
return LengthPercentage { Length::make_auto() };
if (style_value.is_percentage())
return LengthPercentage { style_value.as_percentage().percentage() };
if (style_value.is_length())
return LengthPercentage { style_value.as_length().length() };
if (style_value.is_calculated())
return LengthPercentage { style_value.as_calculated() };
return {};
};
auto maybe_x_value = parse_css_value_for_property(PropertyID::BackgroundSize, tokens);
if (!maybe_x_value)
return nullptr;
auto x_value = maybe_x_value.release_nonnull();
if (x_value->to_identifier() == ValueID::Cover || x_value->to_identifier() == ValueID::Contain) {
transaction.commit();
return x_value;
}
auto maybe_y_value = parse_css_value_for_property(PropertyID::BackgroundSize, tokens);
if (!maybe_y_value) {
auto y_value = LengthPercentage { Length::make_auto() };
auto x_size = get_length_percentage(*x_value);
if (!x_size.has_value())
return nullptr;
transaction.commit();
return BackgroundSizeStyleValue::create(x_size.value(), y_value);
}
auto y_value = maybe_y_value.release_nonnull();
auto x_size = get_length_percentage(*x_value);
auto y_size = get_length_percentage(*y_value);
if (!x_size.has_value() || !y_size.has_value())
return nullptr;
transaction.commit();
return BackgroundSizeStyleValue::create(x_size.release_value(), y_size.release_value());
}
RefPtr<StyleValue> Parser::parse_border_value(PropertyID property_id, Vector<ComponentValue> const& component_values)
{
if (component_values.size() > 3)
return nullptr;
RefPtr<StyleValue> border_width;
RefPtr<StyleValue> border_color;
RefPtr<StyleValue> border_style;
auto color_property = PropertyID::Invalid;
auto style_property = PropertyID::Invalid;
auto width_property = PropertyID::Invalid;
switch (property_id) {
case PropertyID::Border:
color_property = PropertyID::BorderColor;
style_property = PropertyID::BorderStyle;
width_property = PropertyID::BorderWidth;
break;
case PropertyID::BorderBottom:
color_property = PropertyID::BorderBottomColor;
style_property = PropertyID::BorderBottomStyle;
width_property = PropertyID::BorderBottomWidth;
break;
case PropertyID::BorderLeft:
color_property = PropertyID::BorderLeftColor;
style_property = PropertyID::BorderLeftStyle;
width_property = PropertyID::BorderLeftWidth;
break;
case PropertyID::BorderRight:
color_property = PropertyID::BorderRightColor;
style_property = PropertyID::BorderRightStyle;
width_property = PropertyID::BorderRightWidth;
break;
case PropertyID::BorderTop:
color_property = PropertyID::BorderTopColor;
style_property = PropertyID::BorderTopStyle;
width_property = PropertyID::BorderTopWidth;
break;
default:
VERIFY_NOT_REACHED();
}
auto remaining_longhands = Vector { width_property, color_property, style_property };
auto tokens = TokenStream { component_values };
while (tokens.has_next_token()) {
auto property_and_value = parse_css_value_for_properties(remaining_longhands, tokens);
if (!property_and_value.has_value())
return nullptr;
auto& value = property_and_value->style_value;
remove_property(remaining_longhands, property_and_value->property);
if (property_and_value->property == width_property) {
VERIFY(!border_width);
border_width = value.release_nonnull();
} else if (property_and_value->property == color_property) {
VERIFY(!border_color);
border_color = value.release_nonnull();
} else if (property_and_value->property == style_property) {
VERIFY(!border_style);
border_style = value.release_nonnull();
} else {
VERIFY_NOT_REACHED();
}
}
if (!border_width)
border_width = property_initial_value(m_context.realm(), width_property);
if (!border_style)
border_style = property_initial_value(m_context.realm(), style_property);
if (!border_color)
border_color = property_initial_value(m_context.realm(), color_property);
return ShorthandStyleValue::create(property_id,
{ width_property, style_property, color_property },
{ border_width.release_nonnull(), border_style.release_nonnull(), border_color.release_nonnull() });
}
RefPtr<StyleValue> Parser::parse_border_radius_value(Vector<ComponentValue> const& component_values)
{
if (component_values.size() == 2) {
auto horizontal = parse_dimension(component_values[0]);
auto vertical = parse_dimension(component_values[1]);
if (horizontal.has_value() && horizontal->is_length_percentage() && vertical.has_value() && vertical->is_length_percentage())
return BorderRadiusStyleValue::create(horizontal->length_percentage(), vertical->length_percentage());
return nullptr;
}
if (component_values.size() == 1) {
auto radius = parse_dimension(component_values[0]);
if (radius.has_value() && radius->is_length_percentage())
return BorderRadiusStyleValue::create(radius->length_percentage(), radius->length_percentage());
return nullptr;
}
return nullptr;
}
RefPtr<StyleValue> Parser::parse_border_radius_shorthand_value(Vector<ComponentValue> const& component_values)
{
auto top_left = [&](Vector<LengthPercentage>& radii) { return radii[0]; };
auto top_right = [&](Vector<LengthPercentage>& radii) {
switch (radii.size()) {
case 4:
case 3:
case 2:
return radii[1];
case 1:
return radii[0];
default:
VERIFY_NOT_REACHED();
}
};
auto bottom_right = [&](Vector<LengthPercentage>& radii) {
switch (radii.size()) {
case 4:
case 3:
return radii[2];
case 2:
case 1:
return radii[0];
default:
VERIFY_NOT_REACHED();
}
};
auto bottom_left = [&](Vector<LengthPercentage>& radii) {
switch (radii.size()) {
case 4:
return radii[3];
case 3:
case 2:
return radii[1];
case 1:
return radii[0];
default:
VERIFY_NOT_REACHED();
}
};
Vector<LengthPercentage> horizontal_radii;
Vector<LengthPercentage> vertical_radii;
bool reading_vertical = false;
for (auto const& value : component_values) {
if (value.is_delim('/')) {
if (reading_vertical || horizontal_radii.is_empty())
return nullptr;
reading_vertical = true;
continue;
}
auto maybe_dimension = parse_dimension(value);
if (!maybe_dimension.has_value() || !maybe_dimension->is_length_percentage())
return nullptr;
if (reading_vertical) {
vertical_radii.append(maybe_dimension->length_percentage());
} else {
horizontal_radii.append(maybe_dimension->length_percentage());
}
}
if (horizontal_radii.size() > 4 || vertical_radii.size() > 4
|| horizontal_radii.is_empty()
|| (reading_vertical && vertical_radii.is_empty()))
return nullptr;
auto top_left_radius = BorderRadiusStyleValue::create(top_left(horizontal_radii),
vertical_radii.is_empty() ? top_left(horizontal_radii) : top_left(vertical_radii));
auto top_right_radius = BorderRadiusStyleValue::create(top_right(horizontal_radii),
vertical_radii.is_empty() ? top_right(horizontal_radii) : top_right(vertical_radii));
auto bottom_right_radius = BorderRadiusStyleValue::create(bottom_right(horizontal_radii),
vertical_radii.is_empty() ? bottom_right(horizontal_radii) : bottom_right(vertical_radii));
auto bottom_left_radius = BorderRadiusStyleValue::create(bottom_left(horizontal_radii),
vertical_radii.is_empty() ? bottom_left(horizontal_radii) : bottom_left(vertical_radii));
return ShorthandStyleValue::create(PropertyID::BorderRadius,
{ PropertyID::BorderTopLeftRadius, PropertyID::BorderTopRightRadius, PropertyID::BorderBottomRightRadius, PropertyID::BorderBottomLeftRadius },
{ move(top_left_radius), move(top_right_radius), move(bottom_right_radius), move(bottom_left_radius) });
}
RefPtr<StyleValue> Parser::parse_shadow_value(Vector<ComponentValue> const& component_values, AllowInsetKeyword allow_inset_keyword)
{
// "none"
if (component_values.size() == 1 && component_values.first().is(Token::Type::Ident)) {
auto ident = parse_identifier_value(component_values.first());
if (ident && ident->to_identifier() == ValueID::None)
return ident;
}
return parse_comma_separated_value_list(component_values, [this, allow_inset_keyword](auto& tokens) {
return parse_single_shadow_value(tokens, allow_inset_keyword);
});
}
RefPtr<StyleValue> Parser::parse_single_shadow_value(TokenStream<ComponentValue>& tokens, AllowInsetKeyword allow_inset_keyword)
{
auto transaction = tokens.begin_transaction();
Optional<Color> color;
RefPtr<StyleValue> offset_x;
RefPtr<StyleValue> offset_y;
RefPtr<StyleValue> blur_radius;
RefPtr<StyleValue> spread_distance;
Optional<ShadowPlacement> placement;
auto possibly_dynamic_length = [&](ComponentValue const& token) -> RefPtr<StyleValue> {
if (auto calculated_value = parse_calculated_value(token)) {
if (!calculated_value->resolves_to_length())
return nullptr;
return calculated_value;
}
auto maybe_length = parse_length(token);
if (!maybe_length.has_value())
return nullptr;
return LengthStyleValue::create(maybe_length.release_value());
};
while (tokens.has_next_token()) {
auto const& token = tokens.peek_token();
if (auto maybe_color = parse_color(token); maybe_color.has_value()) {
if (color.has_value())
return nullptr;
color = maybe_color.release_value();
tokens.next_token();
continue;
}
if (auto maybe_offset_x = possibly_dynamic_length(token); maybe_offset_x) {
// horizontal offset
if (offset_x)
return nullptr;
offset_x = maybe_offset_x;
tokens.next_token();
// vertical offset
if (!tokens.has_next_token())
return nullptr;
auto maybe_offset_y = possibly_dynamic_length(tokens.peek_token());
if (!maybe_offset_y)
return nullptr;
offset_y = maybe_offset_y;
tokens.next_token();
// blur radius (optional)
if (!tokens.has_next_token())
break;
auto maybe_blur_radius = possibly_dynamic_length(tokens.peek_token());
if (!maybe_blur_radius)
continue;
blur_radius = maybe_blur_radius;
tokens.next_token();
// spread distance (optional)
if (!tokens.has_next_token())
break;
auto maybe_spread_distance = possibly_dynamic_length(tokens.peek_token());
if (!maybe_spread_distance)
continue;
spread_distance = maybe_spread_distance;
tokens.next_token();
continue;
}
if (allow_inset_keyword == AllowInsetKeyword::Yes
&& token.is(Token::Type::Ident) && token.token().ident().equals_ignoring_ascii_case("inset"sv)) {
if (placement.has_value())
return nullptr;
placement = ShadowPlacement::Inner;
tokens.next_token();
continue;
}
if (token.is(Token::Type::Comma))
break;
return nullptr;
}
// FIXME: If color is absent, default to `currentColor`
if (!color.has_value())
color = Color::NamedColor::Black;
// x/y offsets are required
if (!offset_x || !offset_y)
return nullptr;
// Other lengths default to 0
if (!blur_radius)
blur_radius = LengthStyleValue::create(Length::make_px(0));
if (!spread_distance)
spread_distance = LengthStyleValue::create(Length::make_px(0));
// Placement is outer by default
if (!placement.has_value())
placement = ShadowPlacement::Outer;
transaction.commit();
return ShadowStyleValue::create(color.release_value(), offset_x.release_nonnull(), offset_y.release_nonnull(), blur_radius.release_nonnull(), spread_distance.release_nonnull(), placement.release_value());
}
RefPtr<StyleValue> Parser::parse_content_value(Vector<ComponentValue> const& component_values)
{
// FIXME: `content` accepts several kinds of function() type, which we don't handle in property_accepts_value() yet.
auto is_single_value_identifier = [](ValueID identifier) -> bool {
switch (identifier) {
case ValueID::None:
case ValueID::Normal:
return true;
default:
return false;
}
};
if (component_values.size() == 1) {
if (auto identifier = parse_identifier_value(component_values.first())) {
if (is_single_value_identifier(identifier->to_identifier()))
return identifier;
}
}
StyleValueVector content_values;
StyleValueVector alt_text_values;
bool in_alt_text = false;
auto tokens = TokenStream { component_values };
while (tokens.has_next_token()) {
auto& next = tokens.peek_token();
if (next.is_delim('/')) {
if (in_alt_text || content_values.is_empty())
return nullptr;
in_alt_text = true;
(void)tokens.next_token();
continue;
}
if (auto style_value = parse_css_value_for_property(PropertyID::Content, tokens)) {
if (is_single_value_identifier(style_value->to_identifier()))
return nullptr;
if (in_alt_text) {
alt_text_values.append(style_value.release_nonnull());
} else {
content_values.append(style_value.release_nonnull());
}
continue;
}
return nullptr;
}
if (content_values.is_empty())
return nullptr;
if (in_alt_text && alt_text_values.is_empty())
return nullptr;
RefPtr<StyleValueList> alt_text;
if (!alt_text_values.is_empty())
alt_text = StyleValueList::create(move(alt_text_values), StyleValueList::Separator::Space);
return ContentStyleValue::create(StyleValueList::create(move(content_values), StyleValueList::Separator::Space), move(alt_text));
}
// https://www.w3.org/TR/css-display-3/#the-display-properties
RefPtr<StyleValue> Parser::parse_display_value(Vector<ComponentValue> const& component_values)
{
auto parse_single_component_display = [&](Vector<ComponentValue> const& component_values) -> Optional<Display> {
if (auto identifier_value = parse_identifier_value(component_values.first())) {
auto identifier = identifier_value->to_identifier();
if (identifier == ValueID::ListItem)
return Display::from_short(Display::Short::ListItem);
if (auto display_outside = value_id_to_display_outside(identifier); display_outside.has_value()) {
switch (display_outside.value()) {
case DisplayOutside::Block:
return Display::from_short(Display::Short::Block);
case DisplayOutside::Inline:
return Display::from_short(Display::Short::Inline);
case DisplayOutside::RunIn:
return Display::from_short(Display::Short::RunIn);
}
}
if (auto display_inside = value_id_to_display_inside(identifier); display_inside.has_value()) {
switch (display_inside.value()) {
case DisplayInside::Flow:
return Display::from_short(Display::Short::Flow);
case DisplayInside::FlowRoot:
return Display::from_short(Display::Short::FlowRoot);
case DisplayInside::Table:
return Display::from_short(Display::Short::Table);
case DisplayInside::Flex:
return Display::from_short(Display::Short::Flex);
case DisplayInside::Grid:
return Display::from_short(Display::Short::Grid);
case DisplayInside::Ruby:
return Display::from_short(Display::Short::Ruby);
case DisplayInside::Math:
return Display::from_short(Display::Short::Math);
}
}
if (auto display_internal = value_id_to_display_internal(identifier); display_internal.has_value()) {
return Display { display_internal.value() };
}
if (auto display_box = value_id_to_display_box(identifier); display_box.has_value()) {
switch (display_box.value()) {
case DisplayBox::Contents:
return Display::from_short(Display::Short::Contents);
case DisplayBox::None:
return Display::from_short(Display::Short::None);
}
}
if (auto display_legacy = value_id_to_display_legacy(identifier); display_legacy.has_value()) {
switch (display_legacy.value()) {
case DisplayLegacy::InlineBlock:
return Display::from_short(Display::Short::InlineBlock);
case DisplayLegacy::InlineTable:
return Display::from_short(Display::Short::InlineTable);
case DisplayLegacy::InlineFlex:
return Display::from_short(Display::Short::InlineFlex);
case DisplayLegacy::InlineGrid:
return Display::from_short(Display::Short::InlineGrid);
}
}
}
return OptionalNone {};
};
auto parse_multi_component_display = [&](Vector<ComponentValue> const& component_values) -> Optional<Display> {
auto list_item = Display::ListItem::No;
Optional<DisplayInside> inside;
Optional<DisplayOutside> outside;
for (size_t i = 0; i < component_values.size(); ++i) {
if (auto value = parse_identifier_value(component_values[i])) {
auto identifier = value->to_identifier();
if (identifier == ValueID::ListItem) {
if (list_item == Display::ListItem::Yes)
return {};
list_item = Display::ListItem::Yes;
continue;
}
if (auto inside_value = value_id_to_display_inside(identifier); inside_value.has_value()) {
if (inside.has_value())
return {};
inside = inside_value.value();
continue;
}
if (auto outside_value = value_id_to_display_outside(identifier); outside_value.has_value()) {
if (outside.has_value())
return {};
outside = outside_value.value();
continue;
}
}
// Not a display value, abort.
dbgln_if(CSS_PARSER_DEBUG, "Unrecognized display value: `{}`", component_values[i].to_string());
return {};
}
// The spec does not allow any other inside values to be combined with list-item
// <display-outside>? && [ flow | flow-root ]? && list-item
if (list_item == Display::ListItem::Yes && inside.has_value() && inside != DisplayInside::Flow && inside != DisplayInside::FlowRoot)
return {};
return Display { outside.value_or(DisplayOutside::Block), inside.value_or(DisplayInside::Flow), list_item };
};
Optional<Display> display;
if (component_values.size() == 1)
display = parse_single_component_display(component_values);
else
display = parse_multi_component_display(component_values);
if (display.has_value())
return DisplayStyleValue::create(display.value());
return nullptr;
}
RefPtr<StyleValue> Parser::parse_filter_value_list_value(Vector<ComponentValue> const& component_values)
{
if (component_values.size() == 1 && component_values.first().is(Token::Type::Ident)) {
auto ident = parse_identifier_value(component_values.first());
if (ident && ident->to_identifier() == ValueID::None)
return ident;
}
TokenStream tokens { component_values };
// FIXME: <url>s are ignored for now
// <filter-value-list> = [ <filter-function> | <url> ]+
enum class FilterToken {
// Color filters:
Brightness,
Contrast,
Grayscale,
Invert,
Opacity,
Saturate,
Sepia,
// Special filters:
Blur,
DropShadow,
HueRotate
};
auto filter_token_to_operation = [&](auto filter) {
VERIFY(to_underlying(filter) < to_underlying(FilterToken::Blur));
return static_cast<Filter::Color::Operation>(filter);
};
auto parse_number_percentage = [&](auto& token) -> Optional<NumberPercentage> {
if (token.is(Token::Type::Percentage))
return NumberPercentage(Percentage(token.token().percentage()));
if (token.is(Token::Type::Number))
return NumberPercentage(Number(Number::Type::Number, token.token().number_value()));
return {};
};
auto parse_filter_function_name = [&](auto name) -> Optional<FilterToken> {
if (name.equals_ignoring_ascii_case("blur"sv))
return FilterToken::Blur;
if (name.equals_ignoring_ascii_case("brightness"sv))
return FilterToken::Brightness;
if (name.equals_ignoring_ascii_case("contrast"sv))
return FilterToken::Contrast;
if (name.equals_ignoring_ascii_case("drop-shadow"sv))
return FilterToken::DropShadow;
if (name.equals_ignoring_ascii_case("grayscale"sv))
return FilterToken::Grayscale;
if (name.equals_ignoring_ascii_case("hue-rotate"sv))
return FilterToken::HueRotate;
if (name.equals_ignoring_ascii_case("invert"sv))
return FilterToken::Invert;
if (name.equals_ignoring_ascii_case("opacity"sv))
return FilterToken::Opacity;
if (name.equals_ignoring_ascii_case("saturate"sv))
return FilterToken::Saturate;
if (name.equals_ignoring_ascii_case("sepia"sv))
return FilterToken::Sepia;
return {};
};
auto parse_filter_function = [&](auto filter_token, auto function_values) -> Optional<FilterFunction> {
TokenStream tokens { function_values };
tokens.skip_whitespace();
auto if_no_more_tokens_return = [&](auto filter) -> Optional<FilterFunction> {
tokens.skip_whitespace();
if (tokens.has_next_token())
return {};
return filter;
};
if (filter_token == FilterToken::Blur) {
// blur( <length>? )
if (!tokens.has_next_token())
return Filter::Blur {};
auto blur_radius = parse_length(tokens.next_token());
if (!blur_radius.has_value())
return {};
return if_no_more_tokens_return(Filter::Blur { *blur_radius });
} else if (filter_token == FilterToken::DropShadow) {
if (!tokens.has_next_token())
return {};
auto next_token = [&]() -> auto& {
auto& token = tokens.next_token();
tokens.skip_whitespace();
return token;
};
// drop-shadow( [ <color>? && <length>{2,3} ] )
// Note: The following code is a little awkward to allow the color to be before or after the lengths.
auto& first_param = next_token();
Optional<Length> maybe_radius = {};
auto maybe_color = parse_color(first_param);
auto x_offset = parse_length(maybe_color.has_value() ? next_token() : first_param);
if (!x_offset.has_value() || !tokens.has_next_token()) {
return {};
}
auto y_offset = parse_length(next_token());
if (!y_offset.has_value()) {
return {};
}
if (tokens.has_next_token()) {
auto& token = next_token();
maybe_radius = parse_length(token);
if (!maybe_color.has_value() && (!maybe_radius.has_value() || tokens.has_next_token())) {
maybe_color = parse_color(!maybe_radius.has_value() ? token : next_token());
if (!maybe_color.has_value()) {
return {};
}
} else if (!maybe_radius.has_value()) {
return {};
}
}
return if_no_more_tokens_return(Filter::DropShadow { *x_offset, *y_offset, maybe_radius, maybe_color });
} else if (filter_token == FilterToken::HueRotate) {
// hue-rotate( [ <angle> | <zero> ]? )
if (!tokens.has_next_token())
return Filter::HueRotate {};
auto& token = tokens.next_token();
if (token.is(Token::Type::Number)) {
// hue-rotate(0)
auto number = token.token().number();
if (number.is_integer() && number.integer_value() == 0)
return if_no_more_tokens_return(Filter::HueRotate { Filter::HueRotate::Zero {} });
return {};
}
if (!token.is(Token::Type::Dimension))
return {};
auto angle_value = token.token().dimension_value();
auto angle_unit_name = token.token().dimension_unit();
auto angle_unit = Angle::unit_from_name(angle_unit_name);
if (!angle_unit.has_value())
return {};
Angle angle { angle_value, angle_unit.release_value() };
return if_no_more_tokens_return(Filter::HueRotate { angle });
} else {
// Simple filters:
// brightness( <number-percentage>? )
// contrast( <number-percentage>? )
// grayscale( <number-percentage>? )
// invert( <number-percentage>? )
// opacity( <number-percentage>? )
// sepia( <number-percentage>? )
// saturate( <number-percentage>? )
if (!tokens.has_next_token())
return Filter::Color { filter_token_to_operation(filter_token) };
auto amount = parse_number_percentage(tokens.next_token());
if (!amount.has_value())
return {};
return if_no_more_tokens_return(Filter::Color { filter_token_to_operation(filter_token), *amount });
}
};
Vector<FilterFunction> filter_value_list {};
while (tokens.has_next_token()) {
tokens.skip_whitespace();
if (!tokens.has_next_token())
break;
auto& token = tokens.next_token();
if (!token.is_function())
return nullptr;
auto filter_token = parse_filter_function_name(token.function().name());
if (!filter_token.has_value())
return nullptr;
auto filter_function = parse_filter_function(*filter_token, token.function().values());
if (!filter_function.has_value())
return nullptr;
filter_value_list.append(*filter_function);
}
if (filter_value_list.is_empty())
return nullptr;
return FilterValueListStyleValue::create(move(filter_value_list));
}
RefPtr<StyleValue> Parser::parse_flex_value(Vector<ComponentValue> const& component_values)
{
auto tokens = TokenStream { component_values };
auto make_flex_shorthand = [&](NonnullRefPtr<StyleValue> flex_grow, NonnullRefPtr<StyleValue> flex_shrink, NonnullRefPtr<StyleValue> flex_basis) {
return ShorthandStyleValue::create(PropertyID::Flex,
{ PropertyID::FlexGrow, PropertyID::FlexShrink, PropertyID::FlexBasis },
{ move(flex_grow), move(flex_shrink), move(flex_basis) });
};
if (component_values.size() == 1) {
// One-value syntax: <flex-grow> | <flex-basis> | none
auto properties = Array { PropertyID::FlexGrow, PropertyID::FlexBasis, PropertyID::Flex };
auto property_and_value = parse_css_value_for_properties(properties, tokens);
if (!property_and_value.has_value())
return nullptr;
auto& value = property_and_value->style_value;
switch (property_and_value->property) {
case PropertyID::FlexGrow: {
// NOTE: The spec says that flex-basis should be 0 here, but other engines currently use 0%.
// https://github.com/w3c/csswg-drafts/issues/5742
auto flex_basis = PercentageStyleValue::create(Percentage(0));
auto one = NumberStyleValue::create(1);
return make_flex_shorthand(*value, one, flex_basis);
}
case PropertyID::FlexBasis: {
auto one = NumberStyleValue::create(1);
return make_flex_shorthand(one, one, *value);
}
case PropertyID::Flex: {
if (value->is_identifier() && value->to_identifier() == ValueID::None) {
auto zero = NumberStyleValue::create(0);
return make_flex_shorthand(zero, zero, IdentifierStyleValue::create(ValueID::Auto));
}
break;
}
default:
VERIFY_NOT_REACHED();
}
return nullptr;
}
RefPtr<StyleValue> flex_grow;
RefPtr<StyleValue> flex_shrink;
RefPtr<StyleValue> flex_basis;
// NOTE: FlexGrow has to be before FlexBasis. `0` is a valid FlexBasis, but only
// if FlexGrow (along with optional FlexShrink) have already been specified.
auto remaining_longhands = Vector { PropertyID::FlexGrow, PropertyID::FlexBasis };
while (tokens.has_next_token()) {
auto property_and_value = parse_css_value_for_properties(remaining_longhands, tokens);
if (!property_and_value.has_value())
return nullptr;
auto& value = property_and_value->style_value;
remove_property(remaining_longhands, property_and_value->property);
switch (property_and_value->property) {
case PropertyID::FlexGrow: {
VERIFY(!flex_grow);
flex_grow = value.release_nonnull();
// Flex-shrink may optionally follow directly after.
auto maybe_flex_shrink = parse_css_value_for_property(PropertyID::FlexShrink, tokens);
if (maybe_flex_shrink)
flex_shrink = maybe_flex_shrink.release_nonnull();
continue;
}
case PropertyID::FlexBasis: {
VERIFY(!flex_basis);
flex_basis = value.release_nonnull();
continue;
}
default:
VERIFY_NOT_REACHED();
}
}
if (!flex_grow)
flex_grow = property_initial_value(m_context.realm(), PropertyID::FlexGrow);
if (!flex_shrink)
flex_shrink = property_initial_value(m_context.realm(), PropertyID::FlexShrink);
if (!flex_basis) {
// NOTE: The spec says that flex-basis should be 0 here, but other engines currently use 0%.
// https://github.com/w3c/csswg-drafts/issues/5742
flex_basis = PercentageStyleValue::create(Percentage(0));
}
return make_flex_shorthand(flex_grow.release_nonnull(), flex_shrink.release_nonnull(), flex_basis.release_nonnull());
}
RefPtr<StyleValue> Parser::parse_flex_flow_value(Vector<ComponentValue> const& component_values)
{
if (component_values.size() > 2)
return nullptr;
RefPtr<StyleValue> flex_direction;
RefPtr<StyleValue> flex_wrap;
auto remaining_longhands = Vector { PropertyID::FlexDirection, PropertyID::FlexWrap };
auto tokens = TokenStream { component_values };
while (tokens.has_next_token()) {
auto property_and_value = parse_css_value_for_properties(remaining_longhands, tokens);
if (!property_and_value.has_value())
return nullptr;
auto& value = property_and_value->style_value;
remove_property(remaining_longhands, property_and_value->property);
switch (property_and_value->property) {
case PropertyID::FlexDirection:
VERIFY(!flex_direction);
flex_direction = value.release_nonnull();
continue;
case PropertyID::FlexWrap:
VERIFY(!flex_wrap);
flex_wrap = value.release_nonnull();
continue;
default:
VERIFY_NOT_REACHED();
}
}
if (!flex_direction)
flex_direction = property_initial_value(m_context.realm(), PropertyID::FlexDirection);
if (!flex_wrap)
flex_wrap = property_initial_value(m_context.realm(), PropertyID::FlexWrap);
return ShorthandStyleValue::create(PropertyID::FlexFlow,
{ PropertyID::FlexDirection, PropertyID::FlexWrap },
{ flex_direction.release_nonnull(), flex_wrap.release_nonnull() });
}
static bool is_generic_font_family(ValueID identifier)
{
switch (identifier) {
case ValueID::Cursive:
case ValueID::Fantasy:
case ValueID::Monospace:
case ValueID::Serif:
case ValueID::SansSerif:
case ValueID::UiMonospace:
case ValueID::UiRounded:
case ValueID::UiSerif:
case ValueID::UiSansSerif:
return true;
default:
return false;
}
}
RefPtr<StyleValue> Parser::parse_font_value(Vector<ComponentValue> const& component_values)
{
RefPtr<StyleValue> font_stretch;
RefPtr<StyleValue> font_style;
RefPtr<StyleValue> font_weight;
RefPtr<StyleValue> font_size;
RefPtr<StyleValue> line_height;
RefPtr<StyleValue> font_families;
RefPtr<StyleValue> font_variant;
// FIXME: Handle system fonts. (caption, icon, menu, message-box, small-caption, status-bar)
// Several sub-properties can be "normal", and appear in any order: style, variant, weight, stretch
// So, we have to handle that separately.
int normal_count = 0;
auto tokens = TokenStream { component_values };
auto remaining_longhands = Vector { PropertyID::FontSize, PropertyID::FontStretch, PropertyID::FontStyle, PropertyID::FontVariant, PropertyID::FontWeight };
while (tokens.has_next_token()) {
auto& peek_token = tokens.peek_token();
if (peek_token.is(Token::Type::Ident) && value_id_from_string(peek_token.token().ident()) == ValueID::Normal) {
normal_count++;
(void)tokens.next_token();
continue;
}
auto property_and_value = parse_css_value_for_properties(remaining_longhands, tokens);
if (!property_and_value.has_value())
return nullptr;
auto& value = property_and_value->style_value;
remove_property(remaining_longhands, property_and_value->property);
switch (property_and_value->property) {
case PropertyID::FontSize: {
VERIFY(!font_size);
font_size = value.release_nonnull();
// Consume `/ line-height` if present
if (tokens.peek_token().is_delim('/')) {
(void)tokens.next_token();
auto maybe_line_height = parse_css_value_for_property(PropertyID::LineHeight, tokens);
if (!maybe_line_height)
return nullptr;
line_height = maybe_line_height.release_nonnull();
}
// Consume font-families
auto maybe_font_families = parse_font_family_value(tokens);
// font-family comes last, so we must not have any tokens left over.
if (!maybe_font_families || tokens.has_next_token())
return nullptr;
font_families = maybe_font_families.release_nonnull();
continue;
}
case PropertyID::FontStretch: {
VERIFY(!font_stretch);
font_stretch = value.release_nonnull();
continue;
}
case PropertyID::FontStyle: {
// FIXME: Handle angle parameter to `oblique`: https://www.w3.org/TR/css-fonts-4/#font-style-prop
VERIFY(!font_style);
font_style = value.release_nonnull();
continue;
}
case PropertyID::FontVariant: {
VERIFY(!font_variant);
font_variant = value.release_nonnull();
continue;
}
case PropertyID::FontWeight: {
VERIFY(!font_weight);
font_weight = value.release_nonnull();
continue;
}
default:
VERIFY_NOT_REACHED();
}
return nullptr;
}
// Since normal is the default value for all the properties that can have it, we don't have to actually
// set anything to normal here. It'll be set when we create the ShorthandStyleValue below.
// We just need to make sure we were not given more normals than will fit.
int unset_value_count = (font_style ? 0 : 1) + (font_weight ? 0 : 1) + (font_variant ? 0 : 1) + (font_stretch ? 0 : 1);
if (unset_value_count < normal_count)
return nullptr;
if (!font_size || !font_families)
return nullptr;
if (!font_style)
font_style = property_initial_value(m_context.realm(), PropertyID::FontStyle);
if (!font_variant)
font_variant = property_initial_value(m_context.realm(), PropertyID::FontVariant);
if (!font_weight)
font_weight = property_initial_value(m_context.realm(), PropertyID::FontWeight);
if (!font_stretch)
font_stretch = property_initial_value(m_context.realm(), PropertyID::FontStretch);
if (!line_height)
line_height = property_initial_value(m_context.realm(), PropertyID::LineHeight);
return ShorthandStyleValue::create(PropertyID::Font,
{ PropertyID::FontStyle, PropertyID::FontVariant, PropertyID::FontWeight, PropertyID::FontStretch, PropertyID::FontSize, PropertyID::LineHeight, PropertyID::FontFamily },
{ font_style.release_nonnull(), font_variant.release_nonnull(), font_weight.release_nonnull(), font_stretch.release_nonnull(), font_size.release_nonnull(), line_height.release_nonnull(), font_families.release_nonnull() });
}
RefPtr<StyleValue> Parser::parse_font_family_value(TokenStream<ComponentValue>& tokens)
{
auto next_is_comma_or_eof = [&]() -> bool {
return !tokens.has_next_token() || tokens.peek_token().is(Token::Type::Comma);
};
// Note: Font-family names can either be a quoted string, or a keyword, or a series of custom-idents.
// eg, these are equivalent:
// font-family: my cool font\!, serif;
// font-family: "my cool font!", serif;
StyleValueVector font_families;
Vector<DeprecatedString> current_name_parts;
while (tokens.has_next_token()) {
auto const& peek = tokens.peek_token();
if (peek.is(Token::Type::String)) {
// `font-family: my cool "font";` is invalid.
if (!current_name_parts.is_empty())
return nullptr;
(void)tokens.next_token(); // String
if (!next_is_comma_or_eof())
return nullptr;
font_families.append(StringStyleValue::create(MUST(String::from_utf8(peek.token().string()))));
(void)tokens.next_token(); // Comma
continue;
}
if (peek.is(Token::Type::Ident)) {
// If this is a valid identifier, it's NOT a custom-ident and can't be part of a larger name.
// CSS-wide keywords are not allowed
if (auto builtin = parse_builtin_value(peek))
return nullptr;
auto maybe_ident = value_id_from_string(peek.token().ident());
// Can't have a generic-font-name as a token in an unquoted font name.
if (maybe_ident.has_value() && is_generic_font_family(maybe_ident.value())) {
if (!current_name_parts.is_empty())
return nullptr;
(void)tokens.next_token(); // Ident
if (!next_is_comma_or_eof())
return nullptr;
font_families.append(IdentifierStyleValue::create(maybe_ident.value()));
(void)tokens.next_token(); // Comma
continue;
}
current_name_parts.append(tokens.next_token().token().ident());
continue;
}
if (peek.is(Token::Type::Comma)) {
if (current_name_parts.is_empty())
return nullptr;
(void)tokens.next_token(); // Comma
// This is really a series of custom-idents, not just one. But for the sake of simplicity we'll make it one.
font_families.append(CustomIdentStyleValue::create(MUST(String::join(' ', current_name_parts))));
current_name_parts.clear();
// Can't have a trailing comma
if (!tokens.has_next_token())
return nullptr;
continue;
}
return nullptr;
}
if (!current_name_parts.is_empty()) {
// This is really a series of custom-idents, not just one. But for the sake of simplicity we'll make it one.
font_families.append(CustomIdentStyleValue::create(MUST(String::join(' ', current_name_parts))));
current_name_parts.clear();
}
if (font_families.is_empty())
return nullptr;
return StyleValueList::create(move(font_families), StyleValueList::Separator::Comma);
}
CSSRule* Parser::parse_font_face_rule(TokenStream<ComponentValue>& tokens)
{
auto declarations_and_at_rules = parse_a_list_of_declarations(tokens);
Optional<FlyString> font_family;
Vector<FontFace::Source> src;
Vector<UnicodeRange> unicode_range;
Optional<int> weight;
Optional<int> slope;
for (auto& declaration_or_at_rule : declarations_and_at_rules) {
if (declaration_or_at_rule.is_at_rule()) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: CSS at-rules are not allowed in @font-face; discarding.");
continue;
}
auto const& declaration = declaration_or_at_rule.declaration();
if (declaration.name().equals_ignoring_ascii_case("font-weight"sv)) {
TokenStream token_stream { declaration.values() };
if (auto value = parse_css_value(CSS::PropertyID::FontWeight, token_stream); !value.is_error()) {
weight = value.value()->to_font_weight();
}
continue;
}
if (declaration.name().equals_ignoring_ascii_case("font-style"sv)) {
TokenStream token_stream { declaration.values() };
if (auto value = parse_css_value(CSS::PropertyID::FontStyle, token_stream); !value.is_error()) {
slope = value.value()->to_font_slope();
}
continue;
}
if (declaration.name().equals_ignoring_ascii_case("font-family"sv)) {
// FIXME: This is very similar to, but different from, the logic in parse_font_family_value().
// Ideally they could share code.
Vector<DeprecatedString> font_family_parts;
bool had_syntax_error = false;
for (size_t i = 0; i < declaration.values().size(); ++i) {
auto const& part = declaration.values()[i];
if (part.is(Token::Type::Whitespace))
continue;
if (part.is(Token::Type::String)) {
if (!font_family_parts.is_empty()) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: @font-face font-family format invalid; discarding.");
had_syntax_error = true;
break;
}
font_family_parts.append(part.token().string());
continue;
}
if (part.is(Token::Type::Ident)) {
if (is_css_wide_keyword(part.token().ident())) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: @font-face font-family format invalid; discarding.");
had_syntax_error = true;
break;
}
auto value_id = value_id_from_string(part.token().ident());
if (value_id.has_value() && is_generic_font_family(value_id.value())) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: @font-face font-family format invalid; discarding.");
had_syntax_error = true;
break;
}
font_family_parts.append(part.token().ident());
continue;
}
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: @font-face font-family format invalid; discarding.");
had_syntax_error = true;
break;
}
if (had_syntax_error || font_family_parts.is_empty())
continue;
font_family = String::join(' ', font_family_parts).release_value_but_fixme_should_propagate_errors();
continue;
}
if (declaration.name().equals_ignoring_ascii_case("src"sv)) {
TokenStream token_stream { declaration.values() };
Vector<FontFace::Source> supported_sources = parse_font_face_src(token_stream);
if (!supported_sources.is_empty())
src = move(supported_sources);
continue;
}
if (declaration.name().equals_ignoring_ascii_case("unicode-range"sv)) {
Vector<UnicodeRange> unicode_ranges;
bool unicode_range_invalid = false;
TokenStream all_tokens { declaration.values() };
auto range_token_lists = parse_a_comma_separated_list_of_component_values(all_tokens);
for (auto& range_tokens : range_token_lists) {
TokenStream range_token_stream { range_tokens };
auto maybe_unicode_range = parse_unicode_range(range_token_stream);
if (!maybe_unicode_range.has_value()) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: @font-face unicode-range format invalid; discarding.");
unicode_range_invalid = true;
break;
}
unicode_ranges.append(maybe_unicode_range.release_value());
}
if (unicode_range_invalid || unicode_ranges.is_empty())
continue;
unicode_range = move(unicode_ranges);
continue;
}
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: Unrecognized descriptor '{}' in @font-face; discarding.", declaration.name());
}
if (!font_family.has_value()) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: Failed to parse @font-face: no font-family!");
return {};
}
if (unicode_range.is_empty()) {
unicode_range.empend(0x0u, 0x10FFFFu);
}
return CSSFontFaceRule::create(m_context.realm(), FontFace { font_family.release_value(), weight, slope, move(src), move(unicode_range) });
}
Vector<FontFace::Source> Parser::parse_font_face_src(TokenStream<ComponentValue>& component_values)
{
// FIXME: Get this information from the system somehow?
// Format-name table: https://www.w3.org/TR/css-fonts-4/#font-format-definitions
auto font_format_is_supported = [](StringView name) {
// The spec requires us to treat opentype and truetype as synonymous.
if (name.is_one_of_ignoring_ascii_case("opentype"sv, "truetype"sv, "woff"sv, "woff2"sv))
return true;
return false;
};
Vector<FontFace::Source> supported_sources;
auto list_of_source_token_lists = parse_a_comma_separated_list_of_component_values(component_values);
for (auto const& source_token_list : list_of_source_token_lists) {
TokenStream source_tokens { source_token_list };
source_tokens.skip_whitespace();
auto const& first = source_tokens.next_token();
// <url> [ format(<font-format>)]?
// FIXME: Implement optional tech() function from CSS-Fonts-4.
if (auto maybe_url = parse_url_function(first); maybe_url.has_value()) {
auto url = maybe_url.release_value();
if (!url.is_valid()) {
continue;
}
Optional<FlyString> format;
source_tokens.skip_whitespace();
if (!source_tokens.has_next_token()) {
supported_sources.empend(move(url), format);
continue;
}
auto maybe_function = source_tokens.next_token();
if (!maybe_function.is_function()) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: @font-face src invalid (token after `url()` that isn't a function: {}); discarding.", maybe_function.to_debug_string());
return {};
}
auto const& function = maybe_function.function();
if (function.name().equals_ignoring_ascii_case("format"sv)) {
TokenStream format_tokens { function.values() };
format_tokens.skip_whitespace();
auto const& format_name_token = format_tokens.next_token();
StringView format_name;
if (format_name_token.is(Token::Type::Ident)) {
format_name = format_name_token.token().ident();
} else if (format_name_token.is(Token::Type::String)) {
format_name = format_name_token.token().string();
} else {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: @font-face src invalid (`format()` parameter not an ident or string; is: {}); discarding.", format_name_token.to_debug_string());
return {};
}
if (!font_format_is_supported(format_name)) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: @font-face src format({}) not supported; skipping.", format_name);
continue;
}
format = FlyString::from_utf8(format_name).release_value_but_fixme_should_propagate_errors();
} else {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: @font-face src invalid (unrecognized function token `{}`); discarding.", function.name());
return {};
}
source_tokens.skip_whitespace();
if (source_tokens.has_next_token()) {
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: @font-face src invalid (extra token `{}`); discarding.", source_tokens.peek_token().to_debug_string());
return {};
}
supported_sources.empend(move(url), format);
continue;
}
if (first.is_function() && first.function().name().equals_ignoring_ascii_case("local"sv)) {
if (first.function().values().is_empty()) {
continue;
}
supported_sources.empend(first.function().values().first().to_string(), Optional<FlyString> {});
continue;
}
dbgln_if(CSS_PARSER_DEBUG, "CSSParser: @font-face src invalid (failed to parse url from: {}); discarding.", first.to_debug_string());
return {};
}
return supported_sources;
}
RefPtr<StyleValue> Parser::parse_list_style_value(Vector<ComponentValue> const& component_values)
{
if (component_values.size() > 3)
return nullptr;
RefPtr<StyleValue> list_position;
RefPtr<StyleValue> list_image;
RefPtr<StyleValue> list_type;
int found_nones = 0;
Vector<PropertyID> remaining_longhands { PropertyID::ListStyleImage, PropertyID::ListStylePosition, PropertyID::ListStyleType };
auto tokens = TokenStream { component_values };
while (tokens.has_next_token()) {
if (auto peek = tokens.peek_token(); peek.is(Token::Type::Ident) && peek.token().ident().equals_ignoring_ascii_case("none"sv)) {
(void)tokens.next_token();
found_nones++;
continue;
}
auto property_and_value = parse_css_value_for_properties(remaining_longhands, tokens);
if (!property_and_value.has_value())
return nullptr;
auto& value = property_and_value->style_value;
remove_property(remaining_longhands, property_and_value->property);
switch (property_and_value->property) {
case PropertyID::ListStylePosition: {
VERIFY(!list_position);
list_position = value.release_nonnull();
continue;
}
case PropertyID::ListStyleImage: {
VERIFY(!list_image);
list_image = value.release_nonnull();
continue;
}
case PropertyID::ListStyleType: {
VERIFY(!list_type);
list_type = value.release_nonnull();
continue;
}
default:
VERIFY_NOT_REACHED();
}
}
if (found_nones > 2)
return nullptr;
if (found_nones == 2) {
if (list_image || list_type)
return nullptr;
auto none = IdentifierStyleValue::create(ValueID::None);
list_image = none;
list_type = none;
} else if (found_nones == 1) {
if (list_image && list_type)
return nullptr;
auto none = IdentifierStyleValue::create(ValueID::None);
if (!list_image)
list_image = none;
if (!list_type)
list_type = none;
}
if (!list_position)
list_position = property_initial_value(m_context.realm(), PropertyID::ListStylePosition);
if (!list_image)
list_image = property_initial_value(m_context.realm(), PropertyID::ListStyleImage);
if (!list_type)
list_type = property_initial_value(m_context.realm(), PropertyID::ListStyleType);
return ShorthandStyleValue::create(PropertyID::ListStyle,
{ PropertyID::ListStylePosition, PropertyID::ListStyleImage, PropertyID::ListStyleType },
{ list_position.release_nonnull(), list_image.release_nonnull(), list_type.release_nonnull() });
}
RefPtr<StyleValue> Parser::parse_math_depth_value(Vector<ComponentValue> const& component_values)
{
// https://w3c.github.io/mathml-core/#propdef-math-depth
// auto-add | add(<integer>) | <integer>
auto tokens = TokenStream { component_values };
tokens.skip_whitespace();
auto token = tokens.next_token();
tokens.skip_whitespace();
if (tokens.has_next_token())
return nullptr;
// auto-add
if (token.is_ident("auto-add"sv))
return MathDepthStyleValue::create_auto_add();
// FIXME: Make it easier to parse "thing that might be <bar> or literally anything that resolves to it" and get rid of this
auto parse_something_that_resolves_to_integer = [this](ComponentValue& token) -> RefPtr<StyleValue> {
if (token.is(Token::Type::Number) && token.token().number().is_integer())
return IntegerStyleValue::create(token.token().to_integer());
if (auto value = parse_calculated_value(token); value && value->resolves_to_number())
return value;
return nullptr;
};
// add(<integer>)
if (token.is_function("add"sv)) {
auto add_tokens = TokenStream { token.function().values() };
add_tokens.skip_whitespace();
auto integer_token = add_tokens.next_token();
add_tokens.skip_whitespace();
if (add_tokens.has_next_token())
return nullptr;
if (auto integer_value = parse_something_that_resolves_to_integer(integer_token))
return MathDepthStyleValue::create_add(integer_value.release_nonnull());
return nullptr;
}
// <integer>
if (auto integer_value = parse_something_that_resolves_to_integer(token))
return MathDepthStyleValue::create_integer(integer_value.release_nonnull());
return nullptr;
}
RefPtr<StyleValue> Parser::parse_overflow_value(Vector<ComponentValue> const& component_values)
{
auto tokens = TokenStream { component_values };
if (component_values.size() == 1) {
auto maybe_value = parse_css_value_for_property(PropertyID::Overflow, tokens);
if (!maybe_value)
return nullptr;
return ShorthandStyleValue::create(PropertyID::Overflow,
{ PropertyID::OverflowX, PropertyID::OverflowY },
{ *maybe_value, *maybe_value });
}
if (component_values.size() == 2) {
auto maybe_x_value = parse_css_value_for_property(PropertyID::OverflowX, tokens);
auto maybe_y_value = parse_css_value_for_property(PropertyID::OverflowY, tokens);
if (!maybe_x_value || !maybe_y_value)
return nullptr;
return ShorthandStyleValue::create(PropertyID::Overflow,
{ PropertyID::OverflowX, PropertyID::OverflowY },
{ maybe_x_value.release_nonnull(), maybe_y_value.release_nonnull() });
}
return nullptr;
}
RefPtr<StyleValue> Parser::parse_place_content_value(Vector<ComponentValue> const& component_values)
{
if (component_values.size() > 2)
return nullptr;
auto tokens = TokenStream { component_values };
auto maybe_align_content_value = parse_css_value_for_property(PropertyID::AlignContent, tokens);
if (!maybe_align_content_value)
return nullptr;
if (component_values.size() == 1) {
if (!property_accepts_identifier(PropertyID::JustifyContent, maybe_align_content_value->to_identifier()))
return nullptr;
return ShorthandStyleValue::create(PropertyID::PlaceContent,
{ PropertyID::AlignContent, PropertyID::JustifyContent },
{ *maybe_align_content_value, *maybe_align_content_value });
}
auto maybe_justify_content_value = parse_css_value_for_property(PropertyID::JustifyContent, tokens);
if (!maybe_justify_content_value)
return nullptr;
return ShorthandStyleValue::create(PropertyID::PlaceContent,
{ PropertyID::AlignContent, PropertyID::JustifyContent },
{ maybe_align_content_value.release_nonnull(), maybe_justify_content_value.release_nonnull() });
}
RefPtr<StyleValue> Parser::parse_place_items_value(Vector<ComponentValue> const& component_values)
{
auto tokens = TokenStream { component_values };
auto maybe_align_items_value = parse_css_value_for_property(PropertyID::AlignItems, tokens);
if (!maybe_align_items_value)
return nullptr;
if (component_values.size() == 1) {
if (!property_accepts_identifier(PropertyID::JustifyItems, maybe_align_items_value->to_identifier()))
return nullptr;
return ShorthandStyleValue::create(PropertyID::PlaceItems,
{ PropertyID::AlignItems, PropertyID::JustifyItems },
{ *maybe_align_items_value, *maybe_align_items_value });
}
auto maybe_justify_items_value = parse_css_value_for_property(PropertyID::JustifyItems, tokens);
if (!maybe_justify_items_value)
return nullptr;
return ShorthandStyleValue::create(PropertyID::PlaceItems,
{ PropertyID::AlignItems, PropertyID::JustifyItems },
{ *maybe_align_items_value, *maybe_justify_items_value });
}
RefPtr<StyleValue> Parser::parse_place_self_value(Vector<ComponentValue> const& component_values)
{
auto tokens = TokenStream { component_values };
auto maybe_align_self_value = parse_css_value_for_property(PropertyID::AlignSelf, tokens);
if (!maybe_align_self_value)
return nullptr;
if (component_values.size() == 1) {
if (!property_accepts_identifier(PropertyID::JustifySelf, maybe_align_self_value->to_identifier()))
return nullptr;
return ShorthandStyleValue::create(PropertyID::PlaceSelf,
{ PropertyID::AlignSelf, PropertyID::JustifySelf },
{ *maybe_align_self_value, *maybe_align_self_value });
}
auto maybe_justify_self_value = parse_css_value_for_property(PropertyID::JustifySelf, tokens);
if (!maybe_justify_self_value)
return nullptr;
return ShorthandStyleValue::create(PropertyID::PlaceSelf,
{ PropertyID::AlignSelf, PropertyID::JustifySelf },
{ *maybe_align_self_value, *maybe_justify_self_value });
}
RefPtr<StyleValue> Parser::parse_quotes_value(Vector<ComponentValue> const& component_values)
{
// https://www.w3.org/TR/css-content-3/#quotes-property
// auto | none | [ <string> <string> ]+
if (component_values.size() == 1) {
auto identifier = parse_identifier_value(component_values.first());
if (identifier && property_accepts_identifier(PropertyID::Quotes, identifier->to_identifier()))
return identifier;
return nullptr;
}
// Parse an even number of <string> values.
if (component_values.size() % 2 != 0)
return nullptr;
auto tokens = TokenStream { component_values };
StyleValueVector string_values;
while (tokens.has_next_token()) {
auto maybe_string = parse_string_value(tokens.next_token());
if (!maybe_string)
return nullptr;
string_values.append(maybe_string.release_nonnull());
}
return StyleValueList::create(move(string_values), StyleValueList::Separator::Space);
}
RefPtr<StyleValue> Parser::parse_text_decoration_value(Vector<ComponentValue> const& component_values)
{
RefPtr<StyleValue> decoration_line;
RefPtr<StyleValue> decoration_thickness;
RefPtr<StyleValue> decoration_style;
RefPtr<StyleValue> decoration_color;
auto remaining_longhands = Vector { PropertyID::TextDecorationColor, PropertyID::TextDecorationLine, PropertyID::TextDecorationStyle, PropertyID::TextDecorationThickness };
auto tokens = TokenStream { component_values };
while (tokens.has_next_token()) {
auto property_and_value = parse_css_value_for_properties(remaining_longhands, tokens);
if (!property_and_value.has_value())
return nullptr;
auto& value = property_and_value->style_value;
remove_property(remaining_longhands, property_and_value->property);
switch (property_and_value->property) {
case PropertyID::TextDecorationColor: {
VERIFY(!decoration_color);
decoration_color = value.release_nonnull();
continue;
}
case PropertyID::TextDecorationLine: {
VERIFY(!decoration_line);
tokens.reconsume_current_input_token();
auto parsed_decoration_line = parse_text_decoration_line_value(tokens);
if (!parsed_decoration_line)
return nullptr;
decoration_line = parsed_decoration_line.release_nonnull();
continue;
}
case PropertyID::TextDecorationThickness: {
VERIFY(!decoration_thickness);
decoration_thickness = value.release_nonnull();
continue;
}
case PropertyID::TextDecorationStyle: {
VERIFY(!decoration_style);
decoration_style = value.release_nonnull();
continue;
}
default:
VERIFY_NOT_REACHED();
}
}
if (!decoration_line)
decoration_line = property_initial_value(m_context.realm(), PropertyID::TextDecorationLine);
if (!decoration_thickness)
decoration_thickness = property_initial_value(m_context.realm(), PropertyID::TextDecorationThickness);
if (!decoration_style)
decoration_style = property_initial_value(m_context.realm(), PropertyID::TextDecorationStyle);
if (!decoration_color)
decoration_color = property_initial_value(m_context.realm(), PropertyID::TextDecorationColor);
return ShorthandStyleValue::create(PropertyID::TextDecoration,
{ PropertyID::TextDecorationLine, PropertyID::TextDecorationThickness, PropertyID::TextDecorationStyle, PropertyID::TextDecorationColor },
{ decoration_line.release_nonnull(), decoration_thickness.release_nonnull(), decoration_style.release_nonnull(), decoration_color.release_nonnull() });
}
RefPtr<StyleValue> Parser::parse_text_decoration_line_value(TokenStream<ComponentValue>& tokens)
{
StyleValueVector style_values;
while (tokens.has_next_token()) {
auto maybe_value = parse_css_value_for_property(PropertyID::TextDecorationLine, tokens);
if (!maybe_value)
break;
auto value = maybe_value.release_nonnull();
if (auto maybe_line = value_id_to_text_decoration_line(value->to_identifier()); maybe_line.has_value()) {
if (maybe_line == TextDecorationLine::None) {
if (!style_values.is_empty())
break;
return value;
}
if (style_values.contains_slow(value))
break;
style_values.append(move(value));
continue;
}
break;
}
if (style_values.is_empty())
return nullptr;
return StyleValueList::create(move(style_values), StyleValueList::Separator::Space);
}
RefPtr<StyleValue> Parser::parse_easing_value(TokenStream<ComponentValue>& tokens)
{
auto transaction = tokens.begin_transaction();
tokens.skip_whitespace();
auto const& part = tokens.next_token();
StringView name;
Optional<Vector<ComponentValue> const&> arguments;
if (part.is(Token::Type::Ident)) {
name = part.token().ident();
} else if (part.is_function()) {
name = part.function().name();
arguments = part.function().values();
} else {
return nullptr;
}
auto maybe_function = easing_function_from_string(name);
if (!maybe_function.has_value())
return nullptr;
auto function = maybe_function.release_value();
auto function_metadata = easing_function_metadata(function);
if (function_metadata.parameters.is_empty() && arguments.has_value()) {
dbgln_if(CSS_PARSER_DEBUG, "Too many arguments to {}. max: 0", name);
return nullptr;
}
StyleValueVector values;
size_t argument_index = 0;
if (arguments.has_value()) {
auto argument_tokens = TokenStream { *arguments };
auto arguments_values = parse_a_comma_separated_list_of_component_values(argument_tokens);
if (arguments_values.size() > function_metadata.parameters.size()) {
dbgln_if(CSS_PARSER_DEBUG, "Too many arguments to {}. max: {}", name, function_metadata.parameters.size());
return nullptr;
}
for (auto& argument_values : arguments_values) {
// Prune any whitespace before and after the actual argument values.
argument_values.remove_all_matching([](auto& value) { return value.is(Token::Type::Whitespace); });
if (argument_values.size() != 1) {
dbgln_if(CSS_PARSER_DEBUG, "Too many values in argument to {}. max: 1", name);
return nullptr;
}
auto& value = argument_values[0];
switch (function_metadata.parameters[argument_index].type) {
case EasingFunctionParameterType::Number: {
if (value.is(Token::Type::Number))
values.append(NumberStyleValue::create(value.token().number().value()));
else
return nullptr;
break;
}
case EasingFunctionParameterType::NumberZeroToOne: {
if (value.is(Token::Type::Number) && value.token().number_value() >= 0 && value.token().number_value() <= 1)
values.append(NumberStyleValue::create(value.token().number().value()));
else
return nullptr;
break;
}
case EasingFunctionParameterType::Integer: {
if (value.is(Token::Type::Number) && value.token().number().is_integer())
values.append(IntegerStyleValue::create(value.token().number().integer_value()));
else
return nullptr;
break;
}
case EasingFunctionParameterType::StepPosition: {
if (!value.is(Token::Type::Ident))
return nullptr;
auto ident = parse_identifier_value(value);
if (!ident)
return nullptr;
switch (ident->to_identifier()) {
case ValueID::JumpStart:
case ValueID::JumpEnd:
case ValueID::JumpNone:
case ValueID::Start:
case ValueID::End:
values.append(*ident);
break;
default:
return nullptr;
}
}
}
++argument_index;
}
}
if (argument_index < function_metadata.parameters.size() && !function_metadata.parameters[argument_index].is_optional) {
dbgln_if(CSS_PARSER_DEBUG, "Required parameter at position {} is missing", argument_index);
return nullptr;
}
transaction.commit();
return EasingStyleValue::create(function, move(values));
}
RefPtr<StyleValue> Parser::parse_transform_value(Vector<ComponentValue> const& component_values)
{
StyleValueVector transformations;
auto tokens = TokenStream { component_values };
tokens.skip_whitespace();
while (tokens.has_next_token()) {
tokens.skip_whitespace();
auto const& part = tokens.next_token();
if (part.is(Token::Type::Ident) && part.token().ident().equals_ignoring_ascii_case("none"sv)) {
if (!transformations.is_empty())
return nullptr;
tokens.skip_whitespace();
if (tokens.has_next_token())
return nullptr;
return IdentifierStyleValue::create(ValueID::None);
}
if (!part.is_function())
return nullptr;
auto maybe_function = transform_function_from_string(part.function().name());
if (!maybe_function.has_value())
return nullptr;
auto function = maybe_function.release_value();
auto function_metadata = transform_function_metadata(function);
StyleValueVector values;
auto argument_tokens = TokenStream { part.function().values() };
argument_tokens.skip_whitespace();
size_t argument_index = 0;
while (argument_tokens.has_next_token()) {
if (argument_index == function_metadata.parameters.size()) {
dbgln_if(CSS_PARSER_DEBUG, "Too many arguments to {}. max: {}", part.function().name(), function_metadata.parameters.size());
return nullptr;
}
auto const& value = argument_tokens.next_token();
RefPtr<CalculatedStyleValue> maybe_calc_value = parse_calculated_value(value);
switch (function_metadata.parameters[argument_index].type) {
case TransformFunctionParameterType::Angle: {
// These are `<angle> | <zero>` in the spec, so we have to check for both kinds.
if (maybe_calc_value && maybe_calc_value->resolves_to_angle()) {
values.append(maybe_calc_value.release_nonnull());
} else if (value.is(Token::Type::Number) && value.token().number_value() == 0) {
values.append(AngleStyleValue::create(Angle::make_degrees(0)));
} else {
auto dimension_value = parse_dimension_value(value);
if (!dimension_value || !dimension_value->is_angle())
return nullptr;
values.append(dimension_value.release_nonnull());
}
break;
}
case TransformFunctionParameterType::Length: {
if (maybe_calc_value && maybe_calc_value->resolves_to_length()) {
values.append(maybe_calc_value.release_nonnull());
} else {
auto dimension_value = parse_dimension_value(value);
if (!dimension_value)
return nullptr;
if (dimension_value->is_length())
values.append(dimension_value.release_nonnull());
else
return nullptr;
}
break;
}
case TransformFunctionParameterType::LengthPercentage: {
if (maybe_calc_value && maybe_calc_value->resolves_to_length()) {
values.append(maybe_calc_value.release_nonnull());
} else {
auto dimension_value = parse_dimension_value(value);
if (!dimension_value)
return nullptr;
if (dimension_value->is_percentage() || dimension_value->is_length())
values.append(dimension_value.release_nonnull());
else
return nullptr;
}
break;
}
case TransformFunctionParameterType::Number: {
if (maybe_calc_value && maybe_calc_value->resolves_to_number()) {
values.append(maybe_calc_value.release_nonnull());
} else {
// FIXME: Remove this reconsume once all parsing functions are TokenStream-based.
argument_tokens.reconsume_current_input_token();
auto number = parse_number_value(argument_tokens);
if (!number)
return nullptr;
values.append(number.release_nonnull());
}
break;
}
}
argument_tokens.skip_whitespace();
if (argument_tokens.has_next_token()) {
// Arguments must be separated by commas.
if (!argument_tokens.next_token().is(Token::Type::Comma))
return nullptr;
argument_tokens.skip_whitespace();
// If there are no more parameters after the comma, this is invalid.
if (!argument_tokens.has_next_token())
return nullptr;
}
argument_index++;
}
if (argument_index < function_metadata.parameters.size() && function_metadata.parameters[argument_index].required) {
dbgln_if(CSS_PARSER_DEBUG, "Required parameter at position {} is missing", argument_index);
return nullptr;
}
transformations.append(TransformationStyleValue::create(function, move(values)));
}
return StyleValueList::create(move(transformations), StyleValueList::Separator::Space);
}
// https://www.w3.org/TR/css-transforms-1/#propdef-transform-origin
// FIXME: This only supports a 2D position
RefPtr<StyleValue> Parser::parse_transform_origin_value(Vector<ComponentValue> const& component_values)
{
enum class Axis {
None,
X,
Y,
};
struct AxisOffset {
Axis axis;
NonnullRefPtr<StyleValue> offset;
};
auto to_axis_offset = [](RefPtr<StyleValue> value) -> Optional<AxisOffset> {
if (!value)
return OptionalNone {};
if (value->is_percentage())
return AxisOffset { Axis::None, value->as_percentage() };
if (value->is_length())
return AxisOffset { Axis::None, value->as_length() };
if (value->is_identifier()) {
switch (value->to_identifier()) {
case ValueID::Top:
return AxisOffset { Axis::Y, PercentageStyleValue::create(Percentage(0)) };
case ValueID::Left:
return AxisOffset { Axis::X, PercentageStyleValue::create(Percentage(0)) };
case ValueID::Center:
return AxisOffset { Axis::None, PercentageStyleValue::create(Percentage(50)) };
case ValueID::Bottom:
return AxisOffset { Axis::Y, PercentageStyleValue::create(Percentage(100)) };
case ValueID::Right:
return AxisOffset { Axis::X, PercentageStyleValue::create(Percentage(100)) };
default:
return OptionalNone {};
}
}
return OptionalNone {};
};
auto make_list = [](NonnullRefPtr<StyleValue> const& x_value, NonnullRefPtr<StyleValue> const& y_value) -> NonnullRefPtr<StyleValueList> {
StyleValueVector values;
values.append(x_value);
values.append(y_value);
return StyleValueList::create(move(values), StyleValueList::Separator::Space);
};
auto tokens = TokenStream { component_values };
switch (component_values.size()) {
case 1: {
auto single_value = to_axis_offset(parse_css_value_for_property(PropertyID::TransformOrigin, tokens));
if (!single_value.has_value())
return nullptr;
// If only one value is specified, the second value is assumed to be center.
// FIXME: If one or two values are specified, the third value is assumed to be 0px.
switch (single_value->axis) {
case Axis::None:
case Axis::X:
return make_list(single_value->offset, PercentageStyleValue::create(Percentage(50)));
case Axis::Y:
return make_list(PercentageStyleValue::create(Percentage(50)), single_value->offset);
}
VERIFY_NOT_REACHED();
}
case 2: {
auto first_value = to_axis_offset(parse_css_value_for_property(PropertyID::TransformOrigin, tokens));
auto second_value = to_axis_offset(parse_css_value_for_property(PropertyID::TransformOrigin, tokens));
if (!first_value.has_value() || !second_value.has_value())
return nullptr;
RefPtr<StyleValue> x_value;
RefPtr<StyleValue> y_value;
if (first_value->axis == Axis::X) {
x_value = first_value->offset;
} else if (first_value->axis == Axis::Y) {
y_value = first_value->offset;
}
if (second_value->axis == Axis::X) {
if (x_value)
return nullptr;
x_value = second_value->offset;
// Put the other in Y since its axis can't have been X
y_value = first_value->offset;
} else if (second_value->axis == Axis::Y) {
if (y_value)
return nullptr;
y_value = second_value->offset;
// Put the other in X since its axis can't have been Y
x_value = first_value->offset;
} else {
if (x_value) {
VERIFY(!y_value);
y_value = second_value->offset;
} else {
VERIFY(!x_value);
x_value = second_value->offset;
}
}
// If two or more values are defined and either no value is a keyword, or the only used keyword is center,
// then the first value represents the horizontal position (or offset) and the second represents the vertical position (or offset).
// FIXME: A third value always represents the Z position (or offset) and must be of type <length>.
if (first_value->axis == Axis::None && second_value->axis == Axis::None) {
x_value = first_value->offset;
y_value = second_value->offset;
}
return make_list(x_value.release_nonnull(), y_value.release_nonnull());
}
}
return nullptr;
}
RefPtr<StyleValue> Parser::parse_as_css_value(PropertyID property_id)
{
auto component_values = parse_a_list_of_component_values(m_token_stream);
auto tokens = TokenStream(component_values);
auto parsed_value = parse_css_value(property_id, tokens);
if (parsed_value.is_error())
return nullptr;
return parsed_value.release_value();
}
Optional<CSS::GridSize> Parser::parse_grid_size(ComponentValue const& component_value)
{
if (component_value.is_function()) {
if (auto maybe_calculated = parse_calculated_value(component_value)) {
if (maybe_calculated->resolves_to_length_percentage())
return GridSize(LengthPercentage(maybe_calculated.release_nonnull()));
// FIXME: Support calculated <flex>
}
return {};
}
auto token = component_value.token();
if (token.is(Token::Type::Ident) && token.ident().equals_ignoring_ascii_case("auto"sv))
return GridSize::make_auto();
if (token.is(Token::Type::Ident) && token.ident().equals_ignoring_ascii_case("max-content"sv))
return GridSize(GridSize::Type::MaxContent);
if (token.is(Token::Type::Ident) && token.ident().equals_ignoring_ascii_case("min-content"sv))
return GridSize(GridSize::Type::MinContent);
auto dimension = parse_dimension(token);
if (!dimension.has_value())
return {};
if (dimension->is_length())
return GridSize(dimension->length());
else if (dimension->is_percentage())
return GridSize(dimension->percentage());
else if (dimension->is_flex())
return GridSize(dimension->flex());
return {};
}
Optional<CSS::GridMinMax> Parser::parse_min_max(Vector<ComponentValue> const& component_values)
{
// https://www.w3.org/TR/css-grid-2/#valdef-grid-template-columns-minmax
// 'minmax(min, max)'
// Defines a size range greater than or equal to min and less than or equal to max. If the max is
// less than the min, then the max will be floored by the min (essentially yielding minmax(min,
// min)). As a maximum, a <flex> value sets the tracks flex factor; it is invalid as a minimum.
auto function_tokens = TokenStream(component_values);
auto comma_separated_list = parse_a_comma_separated_list_of_component_values(function_tokens);
if (comma_separated_list.size() != 2)
return {};
TokenStream part_one_tokens { comma_separated_list[0] };
part_one_tokens.skip_whitespace();
if (!part_one_tokens.has_next_token())
return {};
auto current_token = part_one_tokens.next_token();
auto min_grid_size = parse_grid_size(current_token);
TokenStream part_two_tokens { comma_separated_list[1] };
part_two_tokens.skip_whitespace();
if (!part_two_tokens.has_next_token())
return {};
current_token = part_two_tokens.next_token();
auto max_grid_size = parse_grid_size(current_token);
if (min_grid_size.has_value() && max_grid_size.has_value()) {
// https://www.w3.org/TR/css-grid-2/#valdef-grid-template-columns-minmax
// As a maximum, a <flex> value sets the tracks flex factor; it is invalid as a minimum.
if (min_grid_size.value().is_flexible_length())
return {};
return CSS::GridMinMax(min_grid_size.value(), max_grid_size.value());
}
return {};
}
Optional<CSS::GridRepeat> Parser::parse_repeat(Vector<ComponentValue> const& component_values)
{
// https://www.w3.org/TR/css-grid-2/#repeat-syntax
// 7.2.3.1. Syntax of repeat()
// The generic form of the repeat() syntax is, approximately,
// repeat( [ <integer [1,∞]> | auto-fill | auto-fit ] , <track-list> )
auto is_auto_fill = false;
auto is_auto_fit = false;
auto function_tokens = TokenStream(component_values);
auto comma_separated_list = parse_a_comma_separated_list_of_component_values(function_tokens);
if (comma_separated_list.size() != 2)
return {};
// The first argument specifies the number of repetitions.
TokenStream part_one_tokens { comma_separated_list[0] };
part_one_tokens.skip_whitespace();
if (!part_one_tokens.has_next_token())
return {};
auto current_token = part_one_tokens.next_token().token();
auto repeat_count = 0;
if (current_token.is(Token::Type::Number) && current_token.number().is_integer() && current_token.number_value() > 0)
repeat_count = current_token.number_value();
else if (current_token.is(Token::Type::Ident) && current_token.ident().equals_ignoring_ascii_case("auto-fill"sv))
is_auto_fill = true;
else if (current_token.is(Token::Type::Ident) && current_token.ident().equals_ignoring_ascii_case("auto-fit"sv))
is_auto_fit = true;
// The second argument is a track list, which is repeated that number of times.
TokenStream part_two_tokens { comma_separated_list[1] };
part_two_tokens.skip_whitespace();
if (!part_two_tokens.has_next_token())
return {};
Vector<CSS::ExplicitGridTrack> repeat_params;
Vector<Vector<String>> line_names_list;
auto last_object_was_line_names = false;
while (part_two_tokens.has_next_token()) {
auto token = part_two_tokens.next_token();
Vector<String> line_names;
if (token.is_block()) {
if (last_object_was_line_names)
return {};
last_object_was_line_names = true;
if (!token.block().is_square())
return {};
TokenStream block_tokens { token.block().values() };
while (block_tokens.has_next_token()) {
auto current_block_token = block_tokens.next_token();
auto maybe_string = String::from_utf8(current_block_token.token().ident());
if (maybe_string.is_error())
return {};
line_names.append(maybe_string.value());
block_tokens.skip_whitespace();
}
line_names_list.append(line_names);
part_two_tokens.skip_whitespace();
} else {
last_object_was_line_names = false;
auto track_sizing_function = parse_track_sizing_function(token);
if (!track_sizing_function.has_value())
return {};
// However, there are some restrictions:
// The repeat() notation cant be nested.
if (track_sizing_function.value().is_repeat())
return {};
// Automatic repetitions (auto-fill or auto-fit) cannot be combined with intrinsic or flexible sizes.
if (track_sizing_function.value().is_default() && track_sizing_function.value().grid_size().is_flexible_length() && (is_auto_fill || is_auto_fit))
return {};
repeat_params.append(track_sizing_function.value());
part_two_tokens.skip_whitespace();
}
}
while (line_names_list.size() <= repeat_params.size())
line_names_list.append({});
// Thus the precise syntax of the repeat() notation has several forms:
// <track-repeat> = repeat( [ <integer [1,∞]> ] , [ <line-names>? <track-size> ]+ <line-names>? )
// <auto-repeat> = repeat( [ auto-fill | auto-fit ] , [ <line-names>? <fixed-size> ]+ <line-names>? )
// <fixed-repeat> = repeat( [ <integer [1,∞]> ] , [ <line-names>? <fixed-size> ]+ <line-names>? )
// <name-repeat> = repeat( [ <integer [1,∞]> | auto-fill ], <line-names>+)
// The <track-repeat> variant can represent the repetition of any <track-size>, but is limited to a
// fixed number of repetitions.
// The <auto-repeat> variant can repeat automatically to fill a space, but requires definite track
// sizes so that the number of repetitions can be calculated. It can only appear once in the track
// list, but the same track list can also contain <fixed-repeat>s.
// The <name-repeat> variant is for adding line names to subgrids. It can only be used with the
// subgrid keyword and cannot specify track sizes, only line names.
// If a repeat() function that is not a <name-repeat> ends up placing two <line-names> adjacent to
// each other, the name lists are merged. For example, repeat(2, [a] 1fr [b]) is equivalent to [a]
// 1fr [b a] 1fr [b].
if (is_auto_fill)
return CSS::GridRepeat(CSS::GridTrackSizeList(repeat_params, line_names_list), CSS::GridRepeat::Type::AutoFill);
else if (is_auto_fit)
return CSS::GridRepeat(CSS::GridTrackSizeList(repeat_params, line_names_list), CSS::GridRepeat::Type::AutoFit);
else
return CSS::GridRepeat(CSS::GridTrackSizeList(repeat_params, line_names_list), repeat_count);
}
Optional<CSS::ExplicitGridTrack> Parser::parse_track_sizing_function(ComponentValue const& token)
{
if (token.is_function()) {
auto const& function_token = token.function();
if (function_token.name().equals_ignoring_ascii_case("repeat"sv)) {
auto maybe_repeat = parse_repeat(function_token.values());
if (maybe_repeat.has_value())
return CSS::ExplicitGridTrack(maybe_repeat.value());
else
return {};
} else if (function_token.name().equals_ignoring_ascii_case("minmax"sv)) {
auto maybe_min_max_value = parse_min_max(function_token.values());
if (maybe_min_max_value.has_value())
return CSS::ExplicitGridTrack(maybe_min_max_value.value());
else
return {};
} else if (auto maybe_calculated = parse_calculated_value(token)) {
return CSS::ExplicitGridTrack(GridSize(LengthPercentage(maybe_calculated.release_nonnull())));
}
return {};
} else if (token.is(Token::Type::Ident) && token.token().ident().equals_ignoring_ascii_case("auto"sv)) {
return CSS::ExplicitGridTrack(GridSize(Length::make_auto()));
} else if (token.is_block()) {
return {};
} else {
auto grid_size = parse_grid_size(token);
if (!grid_size.has_value())
return {};
return CSS::ExplicitGridTrack(grid_size.value());
}
}
RefPtr<StyleValue> Parser::parse_grid_track_size_list(Vector<ComponentValue> const& component_values, bool allow_separate_line_name_blocks)
{
if (component_values.size() == 1 && component_values.first().is(Token::Type::Ident)) {
auto ident = parse_identifier_value(component_values.first());
if (ident && ident->to_identifier() == ValueID::None) {
return GridTrackSizeListStyleValue::make_none();
}
}
Vector<CSS::ExplicitGridTrack> track_list;
Vector<Vector<String>> line_names_list;
auto last_object_was_line_names = false;
TokenStream tokens { component_values };
while (tokens.has_next_token()) {
auto token = tokens.next_token();
if (token.is_block()) {
if (last_object_was_line_names && !allow_separate_line_name_blocks)
return GridTrackSizeListStyleValue::make_auto();
last_object_was_line_names = true;
Vector<String> line_names;
if (!token.block().is_square())
return GridTrackSizeListStyleValue::make_auto();
TokenStream block_tokens { token.block().values() };
block_tokens.skip_whitespace();
while (block_tokens.has_next_token()) {
auto current_block_token = block_tokens.next_token();
auto maybe_string = String::from_utf8(current_block_token.token().ident());
if (maybe_string.is_error())
return nullptr;
line_names.append(maybe_string.value());
block_tokens.skip_whitespace();
}
line_names_list.append(line_names);
} else {
last_object_was_line_names = false;
auto track_sizing_function = parse_track_sizing_function(token);
if (!track_sizing_function.has_value())
return GridTrackSizeListStyleValue::make_auto();
// FIXME: Handle multiple repeat values (should combine them here, or remove
// any other ones if the first one is auto-fill, etc.)
track_list.append(track_sizing_function.value());
}
}
while (line_names_list.size() <= track_list.size())
line_names_list.append({});
return GridTrackSizeListStyleValue::create(CSS::GridTrackSizeList(track_list, line_names_list));
}
// https://www.w3.org/TR/css-grid-1/#grid-auto-flow-property
RefPtr<GridAutoFlowStyleValue> Parser::parse_grid_auto_flow_value(Vector<ComponentValue> const& component_values)
{
// [ row | column ] || dense
TokenStream<ComponentValue> tokens { component_values };
if (!tokens.has_next_token())
return nullptr;
auto parse_axis = [&]() -> Optional<GridAutoFlowStyleValue::Axis> {
auto transaction = tokens.begin_transaction();
auto token = tokens.next_token();
if (!token.is(Token::Type::Ident))
return {};
auto const& ident = token.token().ident();
if (ident.equals_ignoring_ascii_case("row"sv)) {
transaction.commit();
return GridAutoFlowStyleValue::Axis::Row;
} else if (ident.equals_ignoring_ascii_case("column"sv)) {
transaction.commit();
return GridAutoFlowStyleValue::Axis::Column;
}
return {};
};
auto parse_dense = [&]() -> Optional<GridAutoFlowStyleValue::Dense> {
auto transaction = tokens.begin_transaction();
auto token = tokens.next_token();
if (!token.is(Token::Type::Ident))
return {};
auto const& ident = token.token().ident();
if (ident.equals_ignoring_ascii_case("dense"sv)) {
transaction.commit();
return GridAutoFlowStyleValue::Dense::Yes;
}
return {};
};
Optional<GridAutoFlowStyleValue::Axis> axis;
Optional<GridAutoFlowStyleValue::Dense> dense;
if (axis = parse_axis(); axis.has_value()) {
dense = parse_dense();
} else if (dense = parse_dense(); dense.has_value()) {
axis = parse_axis();
}
if (tokens.has_next_token())
return nullptr;
return GridAutoFlowStyleValue::create(axis.value_or(GridAutoFlowStyleValue::Axis::Row), dense.value_or(GridAutoFlowStyleValue::Dense::No));
}
RefPtr<StyleValue> Parser::parse_grid_auto_track_sizes(Vector<ComponentValue> const& component_values)
{
// https://www.w3.org/TR/css-grid-2/#auto-tracks
// <track-size>+
Vector<CSS::ExplicitGridTrack> track_list;
TokenStream tokens { component_values };
while (tokens.has_next_token()) {
auto token = tokens.next_token();
auto track_sizing_function = parse_track_sizing_function(token);
if (!track_sizing_function.has_value())
return GridTrackSizeListStyleValue::make_auto();
// FIXME: Handle multiple repeat values (should combine them here, or remove
// any other ones if the first one is auto-fill, etc.)
track_list.append(track_sizing_function.value());
}
return GridTrackSizeListStyleValue::create(CSS::GridTrackSizeList(track_list, {}));
}
RefPtr<StyleValue> Parser::parse_grid_track_placement(Vector<ComponentValue> const& component_values)
{
// https://www.w3.org/TR/css-grid-2/#line-placement
// Line-based Placement: the grid-row-start, grid-column-start, grid-row-end, and grid-column-end properties
// <grid-line> =
// auto |
// <custom-ident> |
// [ <integer> && <custom-ident>? ] |
// [ span && [ <integer> || <custom-ident> ] ]
auto is_auto = [](Token token) -> bool {
if (token.is(Token::Type::Ident) && token.ident().equals_ignoring_ascii_case("auto"sv))
return true;
return false;
};
auto is_span = [](Token token) -> bool {
if (token.is(Token::Type::Ident) && token.ident().equals_ignoring_ascii_case("span"sv))
return true;
return false;
};
auto is_valid_integer = [](Token token) -> bool {
// An <integer> value of zero makes the declaration invalid.
if (token.is(Token::Type::Number) && token.number().is_integer() && token.number_value() != 0)
return true;
return false;
};
auto is_identifier = [](Token token) -> bool {
// The <custom-ident> additionally excludes the keywords span and auto.
if (token.is(Token::Type::Ident) && !token.ident().equals_ignoring_ascii_case("span"sv) && !token.ident().equals_ignoring_ascii_case("auto"sv))
return true;
return false;
};
auto tokens = TokenStream { component_values };
tokens.skip_whitespace();
auto current_token = tokens.next_token().token();
if (!tokens.has_next_token()) {
if (is_auto(current_token))
return GridTrackPlacementStyleValue::create(GridTrackPlacement::make_auto());
if (is_span(current_token))
return GridTrackPlacementStyleValue::create(GridTrackPlacement::make_span(1));
if (is_valid_integer(current_token))
return GridTrackPlacementStyleValue::create(GridTrackPlacement::make_line(static_cast<int>(current_token.number_value()), {}));
if (is_identifier(current_token)) {
auto maybe_string = String::from_utf8(current_token.ident());
if (!maybe_string.is_error())
return GridTrackPlacementStyleValue::create(GridTrackPlacement::make_line({}, maybe_string.value()));
}
return nullptr;
}
auto span_value = false;
auto span_or_position_value = 0;
String identifier_value;
while (true) {
if (is_auto(current_token))
return nullptr;
if (is_span(current_token)) {
if (span_value == false)
span_value = true;
else
return nullptr;
}
if (is_valid_integer(current_token)) {
if (span_or_position_value == 0)
span_or_position_value = static_cast<int>(current_token.number_value());
else
return nullptr;
}
if (is_identifier(current_token)) {
if (identifier_value.is_empty()) {
auto maybe_string = String::from_utf8(current_token.ident());
if (maybe_string.is_error())
return nullptr;
identifier_value = maybe_string.release_value();
} else {
return nullptr;
}
}
tokens.skip_whitespace();
if (tokens.has_next_token())
current_token = tokens.next_token().token();
else
break;
}
// Negative integers or zero are invalid.
if (span_value && span_or_position_value < 1)
return nullptr;
// If the <integer> is omitted, it defaults to 1.
if (span_or_position_value == 0)
span_or_position_value = 1;
if (!identifier_value.is_empty())
return GridTrackPlacementStyleValue::create(GridTrackPlacement::make_line(span_or_position_value, identifier_value));
return GridTrackPlacementStyleValue::create(GridTrackPlacement::make_span(span_or_position_value));
}
RefPtr<StyleValue> Parser::parse_grid_track_placement_shorthand_value(PropertyID property_id, Vector<ComponentValue> const& component_values)
{
auto start_property = (property_id == PropertyID::GridColumn) ? PropertyID::GridColumnStart : PropertyID::GridRowStart;
auto end_property = (property_id == PropertyID::GridColumn) ? PropertyID::GridColumnEnd : PropertyID::GridRowEnd;
auto tokens = TokenStream { component_values };
auto current_token = tokens.next_token().token();
Vector<ComponentValue> track_start_placement_tokens;
while (true) {
if (current_token.is(Token::Type::Delim) && current_token.delim() == "/"sv)
break;
track_start_placement_tokens.append(current_token);
if (!tokens.has_next_token())
break;
current_token = tokens.next_token().token();
}
Vector<ComponentValue> track_end_placement_tokens;
if (tokens.has_next_token()) {
current_token = tokens.next_token().token();
while (true) {
track_end_placement_tokens.append(current_token);
if (!tokens.has_next_token())
break;
current_token = tokens.next_token().token();
}
}
auto parsed_start_value = parse_grid_track_placement(track_start_placement_tokens);
if (parsed_start_value && track_end_placement_tokens.is_empty()) {
return ShorthandStyleValue::create(property_id,
{ start_property, end_property },
{ parsed_start_value.release_nonnull(), GridTrackPlacementStyleValue::create(GridTrackPlacement::make_auto()) });
}
auto parsed_end_value = parse_grid_track_placement(track_end_placement_tokens);
if (parsed_start_value && parsed_end_value) {
return ShorthandStyleValue::create(property_id,
{ start_property, end_property },
{ parsed_start_value.release_nonnull(), parsed_end_value.release_nonnull() });
}
return nullptr;
}
// https://www.w3.org/TR/css-grid-2/#explicit-grid-shorthand
// 7.4. Explicit Grid Shorthand: the grid-template property
RefPtr<StyleValue> Parser::parse_grid_track_size_list_shorthand_value(PropertyID property_id, Vector<ComponentValue> const& component_values)
{
// The grid-template property is a shorthand for setting grid-template-columns, grid-template-rows,
// and grid-template-areas in a single declaration. It has several distinct syntax forms:
// none
// - Sets all three properties to their initial values (none).
// <'grid-template-rows'> / <'grid-template-columns'>
// - Sets grid-template-rows and grid-template-columns to the specified values, respectively, and sets grid-template-areas to none.
// [ <line-names>? <string> <track-size>? <line-names>? ]+ [ / <explicit-track-list> ]?
// - Sets grid-template-areas to the strings listed.
// - Sets grid-template-rows to the <track-size>s following each string (filling in auto for any missing sizes),
// and splicing in the named lines defined before/after each size.
// - Sets grid-template-columns to the track listing specified after the slash (or none, if not specified).
Vector<ComponentValue> template_rows_tokens;
Vector<ComponentValue> template_columns_tokens;
Vector<ComponentValue> template_area_tokens;
int forward_slash_index = -1;
for (size_t x = 0; x < component_values.size(); x++) {
if (component_values[x].is_delim('/')) {
forward_slash_index = x;
break;
}
}
for (size_t x = 0; x < (forward_slash_index > -1 ? forward_slash_index : component_values.size()); x++) {
if (component_values[x].is_token() && component_values[x].token().is(Token::Type::String))
template_area_tokens.append(component_values[x]);
else
template_rows_tokens.append(component_values[x]);
}
if (forward_slash_index > -1) {
for (size_t x = forward_slash_index + 1; x < component_values.size(); x++)
template_columns_tokens.append(component_values[x]);
}
auto parsed_template_areas_values = parse_grid_template_areas_value(template_area_tokens);
auto parsed_template_rows_values = parse_grid_track_size_list(template_rows_tokens, true);
auto parsed_template_columns_values = parse_grid_track_size_list(template_columns_tokens);
return ShorthandStyleValue::create(property_id,
{ PropertyID::GridTemplateAreas, PropertyID::GridTemplateRows, PropertyID::GridTemplateColumns },
{ parsed_template_areas_values.release_nonnull(), parsed_template_rows_values.release_nonnull(), parsed_template_columns_values.release_nonnull() });
}
RefPtr<StyleValue> Parser::parse_grid_area_shorthand_value(Vector<ComponentValue> const& component_values)
{
auto tokens = TokenStream { component_values };
Token current_token;
auto parse_placement_tokens = [&](Vector<ComponentValue>& placement_tokens, bool check_for_delimiter = true) -> void {
current_token = tokens.next_token().token();
while (true) {
if (check_for_delimiter && current_token.is(Token::Type::Delim) && current_token.delim() == "/"sv)
break;
placement_tokens.append(current_token);
tokens.skip_whitespace();
if (!tokens.has_next_token())
break;
current_token = tokens.next_token().token();
}
};
Vector<ComponentValue> row_start_placement_tokens;
parse_placement_tokens(row_start_placement_tokens);
Vector<ComponentValue> column_start_placement_tokens;
if (tokens.has_next_token())
parse_placement_tokens(column_start_placement_tokens);
Vector<ComponentValue> row_end_placement_tokens;
if (tokens.has_next_token())
parse_placement_tokens(row_end_placement_tokens);
Vector<ComponentValue> column_end_placement_tokens;
if (tokens.has_next_token())
parse_placement_tokens(column_end_placement_tokens, false);
// https://www.w3.org/TR/css-grid-2/#placement-shorthands
// The grid-area property is a shorthand for grid-row-start, grid-column-start, grid-row-end and
// grid-column-end.
auto row_start_style_value = parse_grid_track_placement(row_start_placement_tokens);
auto column_start_style_value = parse_grid_track_placement(column_start_placement_tokens);
auto row_end_style_value = parse_grid_track_placement(row_end_placement_tokens);
auto column_end_style_value = parse_grid_track_placement(column_end_placement_tokens);
// If four <grid-line> values are specified, grid-row-start is set to the first value, grid-column-start
// is set to the second value, grid-row-end is set to the third value, and grid-column-end is set to the
// fourth value.
auto row_start = GridTrackPlacement::make_auto();
auto column_start = GridTrackPlacement::make_auto();
auto row_end = GridTrackPlacement::make_auto();
auto column_end = GridTrackPlacement::make_auto();
if (row_start_style_value)
row_start = row_start_style_value.release_nonnull()->as_grid_track_placement().grid_track_placement();
// When grid-column-start is omitted, if grid-row-start is a <custom-ident>, all four longhands are set to
// that value. Otherwise, it is set to auto.
if (column_start_style_value)
column_start = column_start_style_value.release_nonnull()->as_grid_track_placement().grid_track_placement();
else
column_start = row_start;
// When grid-row-end is omitted, if grid-row-start is a <custom-ident>, grid-row-end is set to that
// <custom-ident>; otherwise, it is set to auto.
if (row_end_style_value)
row_end = row_end_style_value.release_nonnull()->as_grid_track_placement().grid_track_placement();
else
row_end = column_start;
// When grid-column-end is omitted, if grid-column-start is a <custom-ident>, grid-column-end is set to
// that <custom-ident>; otherwise, it is set to auto.
if (column_end_style_value)
column_end = column_end_style_value.release_nonnull()->as_grid_track_placement().grid_track_placement();
else
column_end = row_end;
return ShorthandStyleValue::create(PropertyID::GridArea,
{ PropertyID::GridRowStart, PropertyID::GridColumnStart, PropertyID::GridRowEnd, PropertyID::GridColumnEnd },
{ GridTrackPlacementStyleValue::create(row_start), GridTrackPlacementStyleValue::create(column_start), GridTrackPlacementStyleValue::create(row_end), GridTrackPlacementStyleValue::create(column_end) });
}
RefPtr<StyleValue> Parser::parse_grid_shorthand_value(Vector<ComponentValue> const& component_value)
{
// <'grid-template'> |
// FIXME: <'grid-template-rows'> / [ auto-flow && dense? ] <'grid-auto-columns'>? |
// FIXME: [ auto-flow && dense? ] <'grid-auto-rows'>? / <'grid-template-columns'>
return parse_grid_track_size_list_shorthand_value(PropertyID::Grid, component_value);
}
RefPtr<StyleValue> Parser::parse_grid_template_areas_value(Vector<ComponentValue> const& component_values)
{
Vector<Vector<String>> grid_area_rows;
for (auto& component_value : component_values) {
Vector<String> grid_area_columns;
if (component_value.is(Token::Type::String)) {
auto const parts = MUST(MUST(String::from_utf8(component_value.token().string())).split(' '));
for (auto& part : parts) {
grid_area_columns.append(part);
}
}
grid_area_rows.append(move(grid_area_columns));
}
return GridTemplateAreaStyleValue::create(grid_area_rows);
}
static bool block_contains_var_or_attr(Block const& block);
static bool function_contains_var_or_attr(Function const& function)
{
if (function.name().equals_ignoring_ascii_case("var"sv) || function.name().equals_ignoring_ascii_case("attr"sv))
return true;
for (auto const& token : function.values()) {
if (token.is_function() && function_contains_var_or_attr(token.function()))
return true;
if (token.is_block() && block_contains_var_or_attr(token.block()))
return true;
}
return false;
}
bool block_contains_var_or_attr(Block const& block)
{
for (auto const& token : block.values()) {
if (token.is_function() && function_contains_var_or_attr(token.function()))
return true;
if (token.is_block() && block_contains_var_or_attr(token.block()))
return true;
}
return false;
}
Parser::ParseErrorOr<NonnullRefPtr<StyleValue>> Parser::parse_css_value(PropertyID property_id, TokenStream<ComponentValue>& tokens)
{
m_context.set_current_property_id(property_id);
Vector<ComponentValue> component_values;
bool contains_var_or_attr = false;
bool const property_accepts_custom_ident = property_accepts_type(property_id, ValueType::CustomIdent);
while (tokens.has_next_token()) {
auto const& token = tokens.next_token();
if (token.is(Token::Type::Semicolon)) {
tokens.reconsume_current_input_token();
break;
}
if (property_id != PropertyID::Custom) {
if (token.is(Token::Type::Whitespace))
continue;
if (!property_accepts_custom_ident && token.is(Token::Type::Ident) && has_ignored_vendor_prefix(token.token().ident()))
return ParseError::IncludesIgnoredVendorPrefix;
}
if (!contains_var_or_attr) {
if (token.is_function() && function_contains_var_or_attr(token.function()))
contains_var_or_attr = true;
else if (token.is_block() && block_contains_var_or_attr(token.block()))
contains_var_or_attr = true;
}
component_values.append(token);
}
if (property_id == PropertyID::Custom || contains_var_or_attr)
return UnresolvedStyleValue::create(move(component_values), contains_var_or_attr);
if (component_values.is_empty())
return ParseError::SyntaxError;
if (component_values.size() == 1) {
if (auto parsed_value = parse_builtin_value(component_values.first()))
return parsed_value.release_nonnull();
}
// Special-case property handling
switch (property_id) {
case PropertyID::AspectRatio:
if (auto parsed_value = parse_aspect_ratio_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::BackdropFilter:
if (auto parsed_value = parse_filter_value_list_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::Background:
if (auto parsed_value = parse_background_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::BackgroundAttachment:
case PropertyID::BackgroundClip:
case PropertyID::BackgroundImage:
case PropertyID::BackgroundOrigin:
if (auto parsed_value = parse_simple_comma_separated_value_list(property_id, component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::BackgroundPosition:
if (auto parsed_value = parse_comma_separated_value_list(component_values, [this](auto& tokens) { return parse_single_background_position_value(tokens); }))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::BackgroundPositionX:
case PropertyID::BackgroundPositionY:
if (auto parsed_value = parse_comma_separated_value_list(component_values, [this, property_id](auto& tokens) { return parse_single_background_position_x_or_y_value(tokens, property_id); }))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::BackgroundRepeat:
if (auto parsed_value = parse_comma_separated_value_list(component_values, [this](auto& tokens) { return parse_single_background_repeat_value(tokens); }))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::BackgroundSize:
if (auto parsed_value = parse_comma_separated_value_list(component_values, [this](auto& tokens) { return parse_single_background_size_value(tokens); }))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::Border:
case PropertyID::BorderBottom:
case PropertyID::BorderLeft:
case PropertyID::BorderRight:
case PropertyID::BorderTop:
if (auto parsed_value = parse_border_value(property_id, component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::BorderTopLeftRadius:
case PropertyID::BorderTopRightRadius:
case PropertyID::BorderBottomRightRadius:
case PropertyID::BorderBottomLeftRadius:
if (auto parsed_value = parse_border_radius_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::BorderRadius:
if (auto parsed_value = parse_border_radius_shorthand_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::BoxShadow:
if (auto parsed_value = parse_shadow_value(component_values, AllowInsetKeyword::Yes))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::Content:
if (auto parsed_value = parse_content_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::Display:
if (auto parsed_value = parse_display_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::Flex:
if (auto parsed_value = parse_flex_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::FlexFlow:
if (auto parsed_value = parse_flex_flow_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::Font:
if (auto parsed_value = parse_font_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::FontFamily: {
auto tokens_without_whitespace = TokenStream { component_values };
if (auto parsed_value = parse_font_family_value(tokens_without_whitespace))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
}
case PropertyID::GridColumn:
if (auto parsed_value = parse_grid_track_placement_shorthand_value(property_id, component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::GridArea:
if (auto parsed_value = parse_grid_area_shorthand_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::GridAutoFlow:
if (auto parsed_value = parse_grid_auto_flow_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::GridTemplateAreas:
if (auto parsed_value = parse_grid_template_areas_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::GridColumnEnd:
if (auto parsed_value = parse_grid_track_placement(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::GridColumnStart:
if (auto parsed_value = parse_grid_track_placement(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::GridRow:
if (auto parsed_value = parse_grid_track_placement_shorthand_value(property_id, component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::GridRowEnd:
if (auto parsed_value = parse_grid_track_placement(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::GridRowStart:
if (auto parsed_value = parse_grid_track_placement(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::Grid:
if (auto parsed_value = parse_grid_shorthand_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::GridTemplate:
if (auto parsed_value = parse_grid_track_size_list_shorthand_value(property_id, component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::GridTemplateColumns:
if (auto parsed_value = parse_grid_track_size_list(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::GridTemplateRows:
if (auto parsed_value = parse_grid_track_size_list(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::GridAutoColumns:
if (auto parsed_value = parse_grid_auto_track_sizes(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::GridAutoRows:
if (auto parsed_value = parse_grid_auto_track_sizes(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::ListStyle:
if (auto parsed_value = parse_list_style_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::MathDepth:
if (auto parsed_value = parse_math_depth_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::ObjectPosition:
// FIXME: This should use a parse_position compatible to VALUES-4
// and not the background position, which is almost the same.
if (auto parsed_value = parse_comma_separated_value_list(component_values, [this](auto& tokens) { return parse_single_background_position_value(tokens); }))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::Overflow:
if (auto parsed_value = parse_overflow_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::PlaceContent:
if (auto parsed_value = parse_place_content_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::PlaceItems:
if (auto parsed_value = parse_place_items_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::PlaceSelf:
if (auto parsed_value = parse_place_self_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::Quotes:
if (auto parsed_value = parse_quotes_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::TextDecoration:
if (auto parsed_value = parse_text_decoration_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::TextDecorationLine: {
TokenStream value_tokens { component_values };
auto parsed_value = parse_text_decoration_line_value(value_tokens);
if (parsed_value && !value_tokens.has_next_token())
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
}
case PropertyID::TextShadow:
if (auto parsed_value = parse_shadow_value(component_values, AllowInsetKeyword::No))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::Transform:
if (auto parsed_value = parse_transform_value(component_values))
return parsed_value.release_nonnull();
return ParseError::SyntaxError;
case PropertyID::TransformOrigin:
if (auto parsed_value = parse_transform_origin_value(component_values))
return parsed_value.release_nonnull();
return ParseError ::SyntaxError;
default:
break;
}
// If there's only 1 ComponentValue, we can only produce a single StyleValue.
if (component_values.size() == 1) {
auto stream = TokenStream { component_values };
if (auto parsed_value = parse_css_value_for_property(property_id, stream))
return parsed_value.release_nonnull();
} else {
StyleValueVector parsed_values;
auto stream = TokenStream { component_values };
while (auto parsed_value = parse_css_value_for_property(property_id, stream)) {
parsed_values.append(parsed_value.release_nonnull());
if (!stream.has_next_token())
break;
}
// Some types (such as <ratio>) can be made from multiple ComponentValues, so if we only made 1 StyleValue, return it directly.
if (parsed_values.size() == 1)
return *parsed_values.take_first();
if (!parsed_values.is_empty() && parsed_values.size() <= property_maximum_value_count(property_id))
return StyleValueList::create(move(parsed_values), StyleValueList::Separator::Space);
}
// We have multiple values, but the property claims to accept only a single one, check if it's a shorthand property.
auto unassigned_properties = longhands_for_shorthand(property_id);
if (unassigned_properties.is_empty())
return ParseError::SyntaxError;
auto stream = TokenStream { component_values };
HashMap<UnderlyingType<PropertyID>, Vector<ValueComparingNonnullRefPtr<StyleValue const>>> assigned_values;
while (stream.has_next_token() && !unassigned_properties.is_empty()) {
auto property_and_value = parse_css_value_for_properties(unassigned_properties, stream);
if (property_and_value.has_value()) {
auto property = property_and_value->property;
auto value = property_and_value->style_value;
auto& values = assigned_values.ensure(to_underlying(property));
if (values.size() + 1 == property_maximum_value_count(property)) {
// We're done with this property, move on to the next one.
unassigned_properties.remove_first_matching([&](auto& unassigned_property) { return unassigned_property == property; });
}
values.append(value.release_nonnull());
continue;
}
// No property matched, so we're done.
dbgln("No property (from {} properties) matched {}", unassigned_properties.size(), stream.peek_token().to_debug_string());
for (auto id : unassigned_properties)
dbgln(" {}", string_from_property_id(id));
break;
}
for (auto& property : unassigned_properties)
assigned_values.ensure(to_underlying(property)).append(property_initial_value(m_context.realm(), property));
stream.skip_whitespace();
if (stream.has_next_token())
return ParseError::SyntaxError;
Vector<PropertyID> longhand_properties;
longhand_properties.ensure_capacity(assigned_values.size());
for (auto& it : assigned_values)
longhand_properties.unchecked_append(static_cast<PropertyID>(it.key));
StyleValueVector longhand_values;
longhand_values.ensure_capacity(assigned_values.size());
for (auto& it : assigned_values) {
if (it.value.size() == 1)
longhand_values.unchecked_append(it.value.take_first());
else
longhand_values.unchecked_append(StyleValueList::create(move(it.value), StyleValueList::Separator::Space));
}
return { ShorthandStyleValue::create(property_id, move(longhand_properties), move(longhand_values)) };
}
RefPtr<StyleValue> Parser::parse_css_value_for_property(PropertyID property_id, TokenStream<ComponentValue>& tokens)
{
return parse_css_value_for_properties({ &property_id, 1 }, tokens)
.map([](auto& it) { return it.style_value; })
.value_or(nullptr);
}
Optional<Parser::PropertyAndValue> Parser::parse_css_value_for_properties(ReadonlySpan<PropertyID> property_ids, TokenStream<ComponentValue>& tokens)
{
auto any_property_accepts_type = [](ReadonlySpan<PropertyID> property_ids, ValueType value_type) -> Optional<PropertyID> {
for (auto const& property : property_ids) {
if (property_accepts_type(property, value_type))
return property;
}
return {};
};
auto any_property_accepts_type_percentage = [](ReadonlySpan<PropertyID> property_ids, ValueType value_type) -> Optional<PropertyID> {
for (auto const& property : property_ids) {
if (property_accepts_type(property, value_type) && property_accepts_type(property, ValueType::Percentage))
return property;
}
return {};
};
auto any_property_accepts_identifier = [](ReadonlySpan<PropertyID> property_ids, ValueID identifier) -> Optional<PropertyID> {
for (auto const& property : property_ids) {
if (property_accepts_identifier(property, identifier))
return property;
}
return {};
};
auto& peek_token = tokens.peek_token();
if (auto property = any_property_accepts_type(property_ids, ValueType::EasingFunction); property.has_value()) {
if (auto maybe_easing_function = parse_easing_value(tokens))
return PropertyAndValue { *property, maybe_easing_function };
}
if (peek_token.is(Token::Type::Ident)) {
// NOTE: We do not try to parse "CSS-wide keywords" here. https://www.w3.org/TR/css-values-4/#common-keywords
// These are only valid on their own, and so should be parsed directly in `parse_css_value()`.
auto ident = value_id_from_string(peek_token.token().ident());
if (ident.has_value()) {
if (auto property = any_property_accepts_identifier(property_ids, ident.value()); property.has_value()) {
(void)tokens.next_token();
return PropertyAndValue { *property, IdentifierStyleValue::create(ident.value()) };
}
}
// Custom idents
if (auto property = any_property_accepts_type(property_ids, ValueType::CustomIdent); property.has_value()) {
(void)tokens.next_token();
return PropertyAndValue { *property, CustomIdentStyleValue::create(MUST(FlyString::from_utf8(peek_token.token().ident()))) };
}
}
if (auto property = any_property_accepts_type(property_ids, ValueType::Color); property.has_value()) {
if (auto maybe_color = parse_color_value(peek_token)) {
(void)tokens.next_token();
return PropertyAndValue { *property, maybe_color };
}
}
if (auto property = any_property_accepts_type(property_ids, ValueType::Image); property.has_value()) {
if (auto maybe_image = parse_image_value(peek_token)) {
(void)tokens.next_token();
return PropertyAndValue { *property, maybe_image };
}
}
if (auto property = any_property_accepts_type(property_ids, ValueType::Ratio); property.has_value()) {
if (auto maybe_ratio = parse_ratio_value(tokens))
return PropertyAndValue { *property, maybe_ratio };
}
auto property_accepting_integer = any_property_accepts_type(property_ids, ValueType::Integer);
auto property_accepting_number = any_property_accepts_type(property_ids, ValueType::Number);
bool property_accepts_numeric = property_accepting_integer.has_value() || property_accepting_number.has_value();
if (peek_token.is(Token::Type::Number) && property_accepts_numeric) {
if (property_accepting_integer.has_value()) {
auto transaction = tokens.begin_transaction();
if (auto integer = parse_integer_value(tokens); integer && property_accepts_integer(*property_accepting_integer, integer->as_integer().integer())) {
transaction.commit();
return PropertyAndValue { *property_accepting_integer, integer };
}
}
if (property_accepting_number.has_value()) {
auto transaction = tokens.begin_transaction();
if (auto number = parse_number_value(tokens); number && property_accepts_number(*property_accepting_number, number->as_number().number())) {
transaction.commit();
return PropertyAndValue { *property_accepting_number, number };
}
}
}
if (peek_token.is(Token::Type::Percentage)) {
auto percentage = Percentage(peek_token.token().percentage());
if (auto property = any_property_accepts_type(property_ids, ValueType::Percentage); property.has_value() && property_accepts_percentage(*property, percentage)) {
(void)tokens.next_token();
return PropertyAndValue { *property, PercentageStyleValue::create(percentage) };
}
}
if (auto property = any_property_accepts_type(property_ids, ValueType::Rect); property.has_value()) {
if (auto maybe_rect = parse_rect_value(peek_token)) {
(void)tokens.next_token();
return PropertyAndValue { *property, maybe_rect };
}
}
if (peek_token.is(Token::Type::String)) {
if (auto property = any_property_accepts_type(property_ids, ValueType::String); property.has_value())
return PropertyAndValue { *property, StringStyleValue::create(MUST(String::from_utf8(tokens.next_token().token().string()))) };
}
if (auto property = any_property_accepts_type(property_ids, ValueType::Url); property.has_value()) {
if (auto url = parse_url_value(peek_token)) {
(void)tokens.next_token();
return PropertyAndValue { *property, url };
}
}
bool property_accepts_dimension = any_property_accepts_type(property_ids, ValueType::Angle).has_value()
|| any_property_accepts_type(property_ids, ValueType::Flex).has_value()
|| any_property_accepts_type(property_ids, ValueType::Frequency).has_value()
|| any_property_accepts_type(property_ids, ValueType::Length).has_value()
|| any_property_accepts_type(property_ids, ValueType::Percentage).has_value()
|| any_property_accepts_type(property_ids, ValueType::Resolution).has_value()
|| any_property_accepts_type(property_ids, ValueType::Time).has_value();
if (property_accepts_dimension) {
if (peek_token.is(Token::Type::Number) && m_context.is_parsing_svg_presentation_attribute()) {
auto transaction = tokens.begin_transaction();
auto token = tokens.next_token();
// https://svgwg.org/svg2-draft/types.html#presentation-attribute-css-value
// We need to allow <number> in any place that expects a <length> or <angle>.
// FIXME: How should these numbers be interpreted? https://github.com/w3c/svgwg/issues/792
// For now: Convert them to px lengths, or deg angles.
auto angle = Angle::make_degrees(token.token().number_value());
if (auto property = any_property_accepts_type(property_ids, ValueType::Angle); property.has_value() && property_accepts_angle(*property, angle)) {
transaction.commit();
return PropertyAndValue { *property, AngleStyleValue::create(angle) };
}
auto length = Length::make_px(CSSPixels::nearest_value_for(token.token().number_value()));
if (auto property = any_property_accepts_type(property_ids, ValueType::Length); property.has_value() && property_accepts_length(*property, length)) {
transaction.commit();
return PropertyAndValue { *property, LengthStyleValue::create(length) };
}
}
auto transaction = tokens.begin_transaction();
if (auto maybe_dimension = parse_dimension(peek_token); maybe_dimension.has_value()) {
(void)tokens.next_token();
auto dimension = maybe_dimension.release_value();
if (dimension.is_angle()) {
auto angle = dimension.angle();
if (auto property = any_property_accepts_type(property_ids, ValueType::Angle); property.has_value() && property_accepts_angle(*property, angle)) {
transaction.commit();
return PropertyAndValue { *property, AngleStyleValue::create(angle) };
}
}
if (dimension.is_flex()) {
auto flex = dimension.flex();
if (auto property = any_property_accepts_type(property_ids, ValueType::Flex); property.has_value() && property_accepts_flex(*property, flex)) {
transaction.commit();
return PropertyAndValue { *property, FlexStyleValue::create(flex) };
}
}
if (dimension.is_frequency()) {
auto frequency = dimension.frequency();
if (auto property = any_property_accepts_type(property_ids, ValueType::Frequency); property.has_value() && property_accepts_frequency(*property, frequency)) {
transaction.commit();
return PropertyAndValue { *property, FrequencyStyleValue::create(frequency) };
}
}
if (dimension.is_length()) {
auto length = dimension.length();
if (auto property = any_property_accepts_type(property_ids, ValueType::Length); property.has_value() && property_accepts_length(*property, length)) {
transaction.commit();
return PropertyAndValue { *property, LengthStyleValue::create(length) };
}
}
if (dimension.is_resolution()) {
auto resolution = dimension.resolution();
if (auto property = any_property_accepts_type(property_ids, ValueType::Resolution); property.has_value() && property_accepts_resolution(*property, resolution)) {
transaction.commit();
return PropertyAndValue { *property, ResolutionStyleValue::create(resolution) };
}
}
if (dimension.is_time()) {
auto time = dimension.time();
if (auto property = any_property_accepts_type(property_ids, ValueType::Time); property.has_value() && property_accepts_time(*property, time)) {
transaction.commit();
return PropertyAndValue { *property, TimeStyleValue::create(time) };
}
}
}
}
// In order to not end up parsing `calc()` and other math expressions multiple times,
// we parse it once, and then see if its resolved type matches what the property accepts.
if (peek_token.is_function() && (property_accepts_dimension || property_accepts_numeric)) {
if (auto maybe_calculated = parse_calculated_value(peek_token); maybe_calculated) {
(void)tokens.next_token();
auto& calculated = *maybe_calculated;
// This is a bit sensitive to ordering: `<foo>` and `<percentage>` have to be checked before `<foo-percentage>`.
// FIXME: When parsing SVG presentation attributes, <number> is permitted wherever <length>, <length-percentage>, or <angle> are.
// The specifics are unclear, so I'm ignoring this for calculated values for now.
// See https://github.com/w3c/svgwg/issues/792
if (calculated.resolves_to_percentage()) {
if (auto property = any_property_accepts_type(property_ids, ValueType::Percentage); property.has_value())
return PropertyAndValue { *property, calculated };
} else if (calculated.resolves_to_angle()) {
if (auto property = any_property_accepts_type(property_ids, ValueType::Angle); property.has_value())
return PropertyAndValue { *property, calculated };
} else if (calculated.resolves_to_angle_percentage()) {
if (auto property = any_property_accepts_type_percentage(property_ids, ValueType::Angle); property.has_value())
return PropertyAndValue { *property, calculated };
} else if (calculated.resolves_to_flex()) {
if (auto property = any_property_accepts_type(property_ids, ValueType::Flex); property.has_value())
return PropertyAndValue { *property, calculated };
} else if (calculated.resolves_to_frequency()) {
if (auto property = any_property_accepts_type(property_ids, ValueType::Frequency); property.has_value())
return PropertyAndValue { *property, calculated };
} else if (calculated.resolves_to_frequency_percentage()) {
if (auto property = any_property_accepts_type_percentage(property_ids, ValueType::Frequency); property.has_value())
return PropertyAndValue { *property, calculated };
} else if (calculated.resolves_to_number()) {
if (property_accepts_numeric) {
auto property_or_resolved = property_accepting_integer.value_or_lazy_evaluated([property_accepting_number]() { return property_accepting_number.value(); });
return PropertyAndValue { property_or_resolved, calculated };
}
} else if (calculated.resolves_to_number_percentage()) {
if (auto property = any_property_accepts_type_percentage(property_ids, ValueType::Number); property.has_value())
return PropertyAndValue { *property, calculated };
} else if (calculated.resolves_to_length()) {
if (auto property = any_property_accepts_type(property_ids, ValueType::Length); property.has_value())
return PropertyAndValue { *property, calculated };
} else if (calculated.resolves_to_length_percentage()) {
if (auto property = any_property_accepts_type_percentage(property_ids, ValueType::Length); property.has_value())
return PropertyAndValue { *property, calculated };
} else if (calculated.resolves_to_time()) {
if (auto property = any_property_accepts_type(property_ids, ValueType::Time); property.has_value())
return PropertyAndValue { *property, calculated };
} else if (calculated.resolves_to_time_percentage()) {
if (auto property = any_property_accepts_type_percentage(property_ids, ValueType::Time); property.has_value())
return PropertyAndValue { *property, calculated };
}
}
}
if (auto property = any_property_accepts_type(property_ids, ValueType::Paint); property.has_value()) {
if (auto value = parse_paint_value(tokens))
return PropertyAndValue { *property, value.release_nonnull() };
}
return OptionalNone {};
}
class UnparsedCalculationNode final : public CalculationNode {
public:
static NonnullOwnPtr<UnparsedCalculationNode> create(ComponentValue component_value)
{
return adopt_own(*new (nothrow) UnparsedCalculationNode(move(component_value)));
}
virtual ~UnparsedCalculationNode() = default;
ComponentValue& component_value() { return m_component_value; }
virtual String to_string() const override { VERIFY_NOT_REACHED(); }
virtual Optional<CalculatedStyleValue::ResolvedType> resolved_type() const override { VERIFY_NOT_REACHED(); }
virtual Optional<CSSNumericType> determine_type(Web::CSS::PropertyID) const override { VERIFY_NOT_REACHED(); }
virtual bool contains_percentage() const override { VERIFY_NOT_REACHED(); }
virtual CalculatedStyleValue::CalculationResult resolve(Optional<Length::ResolutionContext const&>, CalculatedStyleValue::PercentageBasis const&) const override { VERIFY_NOT_REACHED(); }
virtual void for_each_child_node(AK::Function<void(NonnullOwnPtr<CalculationNode>&)> const&) override { }
virtual void dump(StringBuilder& builder, int indent) const override
{
builder.appendff("{: >{}}UNPARSED({})\n", "", indent, m_component_value.to_debug_string());
}
private:
UnparsedCalculationNode(ComponentValue component_value)
: CalculationNode(Type::Unparsed)
, m_component_value(move(component_value))
{
}
ComponentValue m_component_value;
};
// https://html.spec.whatwg.org/multipage/images.html#parsing-a-sizes-attribute
LengthOrCalculated Parser::Parser::parse_as_sizes_attribute()
{
// 1. Let unparsed sizes list be the result of parsing a comma-separated list of component values
// from the value of element's sizes attribute (or the empty string, if the attribute is absent).
auto unparsed_sizes_list = parse_a_comma_separated_list_of_component_values(m_token_stream);
// 2. Let size be null.
Optional<LengthOrCalculated> size;
// 3. For each unparsed size in unparsed sizes list:
for (auto& unparsed_size : unparsed_sizes_list) {
// 1. Remove all consecutive <whitespace-token>s from the end of unparsed size.
// If unparsed size is now empty, that is a parse error; continue.
while (!unparsed_size.is_empty() && unparsed_size.last().is_token() && unparsed_size.last().token().is(Token::Type::Whitespace))
unparsed_size.take_last();
if (unparsed_size.is_empty()) {
log_parse_error();
continue;
}
// 2. If the last component value in unparsed size is a valid non-negative <source-size-value>,
// let size be its value and remove the component value from unparsed size.
// FIXME: Any CSS function other than the math functions is invalid.
// Otherwise, there is a parse error; continue.
if (auto source_size_value = parse_source_size_value(unparsed_size.last()); source_size_value.has_value()) {
size = source_size_value.value();
unparsed_size.take_last();
} else {
log_parse_error();
continue;
}
// 3. Remove all consecutive <whitespace-token>s from the end of unparsed size.
while (!unparsed_size.is_empty() && unparsed_size.last().is_token() && unparsed_size.last().token().is(Token::Type::Whitespace))
unparsed_size.take_last();
// If unparsed size is now empty, then return size.
if (unparsed_size.is_empty())
return size.value();
// FIXME: If this was not the keyword auto and it was not the last item in unparsed sizes list, that is a parse error.
// 4. Parse the remaining component values in unparsed size as a <media-condition>.
// If it does not parse correctly, or it does parse correctly but the <media-condition> evaluates to false, continue.
TokenStream<ComponentValue> token_stream { unparsed_size };
auto media_condition = parse_media_condition(token_stream, MediaCondition::AllowOr::Yes);
if (media_condition && media_condition->evaluate(*m_context.window()) == MatchResult::True) {
return size.value();
} else {
continue;
}
// 5. If size is not auto, then return size.
if (size.value().is_calculated() || !size.value().value().is_auto())
return size.value();
}
return Length(100, Length::Type::Vw);
}
// https://www.w3.org/TR/css-values-4/#parse-a-calculation
OwnPtr<CalculationNode> Parser::parse_a_calculation(Vector<ComponentValue> const& original_values)
{
// 1. Discard any <whitespace-token>s from values.
// 2. An item in values is an “operator” if its a <delim-token> with the value "+", "-", "*", or "/". Otherwise, its a “value”.
struct Operator {
char delim;
};
using Value = Variant<NonnullOwnPtr<CalculationNode>, Operator>;
Vector<Value> values;
for (auto& value : original_values) {
if (value.is(Token::Type::Whitespace))
continue;
if (value.is(Token::Type::Delim)) {
if (first_is_one_of(value.token().delim(), static_cast<u32>('+'), static_cast<u32>('-'), static_cast<u32>('*'), static_cast<u32>('/'))) {
// NOTE: Sequential operators are invalid syntax.
if (!values.is_empty() && values.last().has<Operator>())
return nullptr;
values.append(Operator { static_cast<char>(value.token().delim()) });
continue;
}
}
if (value.is(Token::Type::Ident)) {
auto maybe_constant = CalculationNode::constant_type_from_string(value.token().ident());
if (maybe_constant.has_value()) {
values.append({ ConstantCalculationNode::create(maybe_constant.value()) });
continue;
}
}
if (value.is(Token::Type::Number)) {
values.append({ NumericCalculationNode::create(value.token().number()) });
continue;
}
if (auto dimension = parse_dimension(value); dimension.has_value()) {
if (dimension->is_angle())
values.append({ NumericCalculationNode::create(dimension->angle()) });
else if (dimension->is_frequency())
values.append({ NumericCalculationNode::create(dimension->frequency()) });
else if (dimension->is_length())
values.append({ NumericCalculationNode::create(dimension->length()) });
else if (dimension->is_percentage())
values.append({ NumericCalculationNode::create(dimension->percentage()) });
// FIXME: Resolutions, once calc() supports them.
else if (dimension->is_time())
values.append({ NumericCalculationNode::create(dimension->time()) });
else if (dimension->is_flex()) {
// https://www.w3.org/TR/css3-grid-layout/#fr-unit
// NOTE: <flex> values are not <length>s (nor are they compatible with <length>s, like some <percentage> values),
// so they cannot be represented in or combined with other unit types in calc() expressions.
return nullptr;
} else {
VERIFY_NOT_REACHED();
}
continue;
}
values.append({ UnparsedCalculationNode::create(value) });
}
// If we have no values, the syntax is invalid.
if (values.is_empty())
return nullptr;
// NOTE: If the first or last value is an operator, the syntax is invalid.
if (values.first().has<Operator>() || values.last().has<Operator>())
return nullptr;
// 3. Collect children into Product and Invert nodes.
// For every consecutive run of value items in values separated by "*" or "/" operators:
while (true) {
Optional<size_t> first_product_operator = values.find_first_index_if([](auto const& item) {
return item.template has<Operator>()
&& first_is_one_of(item.template get<Operator>().delim, '*', '/');
});
if (!first_product_operator.has_value())
break;
auto start_of_run = first_product_operator.value() - 1;
auto end_of_run = first_product_operator.value() + 1;
for (auto i = start_of_run + 1; i < values.size(); i += 2) {
auto& item = values[i];
if (!item.has<Operator>()) {
end_of_run = i - 1;
break;
}
auto delim = item.get<Operator>().delim;
if (!first_is_one_of(delim, '*', '/')) {
end_of_run = i - 1;
break;
}
}
// 1. For each "/" operator in the run, replace its right-hand value item rhs with an Invert node containing rhs as its child.
Vector<NonnullOwnPtr<CalculationNode>> run_values;
run_values.append(move(values[start_of_run].get<NonnullOwnPtr<CalculationNode>>()));
for (auto i = start_of_run + 1; i <= end_of_run; i += 2) {
auto& operator_ = values[i].get<Operator>().delim;
auto& rhs = values[i + 1];
if (operator_ == '/') {
run_values.append(InvertCalculationNode::create(move(rhs.get<NonnullOwnPtr<CalculationNode>>())));
continue;
}
VERIFY(operator_ == '*');
run_values.append(move(rhs.get<NonnullOwnPtr<CalculationNode>>()));
}
// 2. Replace the entire run with a Product node containing the value items of the run as its children.
auto product_node = ProductCalculationNode::create(move(run_values));
values.remove(start_of_run, end_of_run - start_of_run + 1);
values.insert(start_of_run, { move(product_node) });
}
// 4. Collect children into Sum and Negate nodes.
Optional<NonnullOwnPtr<CalculationNode>> single_value;
{
// 1. For each "-" operator item in values, replace its right-hand value item rhs with a Negate node containing rhs as its child.
for (auto i = 0u; i < values.size(); ++i) {
auto& maybe_minus_operator = values[i];
if (!maybe_minus_operator.has<Operator>() || maybe_minus_operator.get<Operator>().delim != '-')
continue;
auto rhs_index = ++i;
auto& rhs = values[rhs_index];
NonnullOwnPtr<CalculationNode> negate_node = NegateCalculationNode::create(move(rhs.get<NonnullOwnPtr<CalculationNode>>()));
values.remove(rhs_index);
values.insert(rhs_index, move(negate_node));
}
// 2. If values has only one item, and it is a Product node or a parenthesized simple block, replace values with that item.
if (values.size() == 1) {
values.first().visit(
[&](ComponentValue& component_value) {
if (component_value.is_block() && component_value.block().is_paren())
single_value = UnparsedCalculationNode::create(component_value);
},
[&](NonnullOwnPtr<CalculationNode>& node) {
if (node->type() == CalculationNode::Type::Product)
single_value = move(node);
},
[](auto&) {});
}
// Otherwise, replace values with a Sum node containing the value items of values as its children.
if (!single_value.has_value()) {
values.remove_all_matching([](Value& value) { return value.has<Operator>(); });
Vector<NonnullOwnPtr<CalculationNode>> value_items;
value_items.ensure_capacity(values.size());
for (auto& value : values) {
if (value.has<Operator>())
continue;
value_items.unchecked_append(move(value.get<NonnullOwnPtr<CalculationNode>>()));
}
single_value = SumCalculationNode::create(move(value_items));
}
}
// 5. At this point values is a tree of Sum, Product, Negate, and Invert nodes, with other types of values at the leaf nodes. Process the leaf nodes.
// For every leaf node leaf in values:
bool parsing_failed_for_child_node = false;
single_value.value()->for_each_child_node([&](NonnullOwnPtr<CalculationNode>& node) {
if (node->type() != CalculationNode::Type::Unparsed)
return;
auto& unparsed_node = static_cast<UnparsedCalculationNode&>(*node);
auto& component_value = unparsed_node.component_value();
// 1. If leaf is a parenthesized simple block, replace leaf with the result of parsing a calculation from leafs contents.
if (component_value.is_block() && component_value.block().is_paren()) {
auto leaf_calculation = parse_a_calculation(component_value.block().values());
if (!leaf_calculation) {
parsing_failed_for_child_node = true;
return;
}
node = leaf_calculation.release_nonnull();
return;
}
// 2. If leaf is a math function, replace leaf with the internal representation of that math function.
// NOTE: All function tokens at this point should be math functions.
else if (component_value.is_function()) {
auto& function = component_value.function();
auto leaf_calculation = parse_a_calc_function_node(function);
if (!leaf_calculation) {
parsing_failed_for_child_node = true;
return;
}
node = leaf_calculation.release_nonnull();
return;
}
// NOTE: If we get here, then we have an UnparsedCalculationNode that didn't get replaced with something else.
// So, the calc() is invalid.
dbgln_if(CSS_PARSER_DEBUG, "Leftover UnparsedCalculationNode in calc tree! That probably means the syntax is invalid, but maybe we just didn't implement `{}` yet.", component_value.to_debug_string());
parsing_failed_for_child_node = true;
return;
});
if (parsing_failed_for_child_node)
return nullptr;
// FIXME: 6. Return the result of simplifying a calculation tree from values.
return single_value.release_value();
}
bool Parser::has_ignored_vendor_prefix(StringView string)
{
if (!string.starts_with('-'))
return false;
if (string.starts_with("--"sv))
return false;
if (string.starts_with("-libweb-"sv))
return false;
return true;
}
NonnullRefPtr<StyleValue> Parser::resolve_unresolved_style_value(Badge<StyleComputer>, ParsingContext const& context, DOM::Element& element, Optional<Selector::PseudoElement> pseudo_element, PropertyID property_id, UnresolvedStyleValue const& unresolved)
{
// Unresolved always contains a var() or attr(), unless it is a custom property's value, in which case we shouldn't be trying
// to produce a different StyleValue from it.
VERIFY(unresolved.contains_var_or_attr());
// If the value is invalid, we fall back to `unset`: https://www.w3.org/TR/css-variables-1/#invalid-at-computed-value-time
auto parser = MUST(Parser::create(context, ""sv));
return parser.resolve_unresolved_style_value(element, pseudo_element, property_id, unresolved);
}
class PropertyDependencyNode : public RefCounted<PropertyDependencyNode> {
public:
static NonnullRefPtr<PropertyDependencyNode> create(String name)
{
return adopt_ref(*new PropertyDependencyNode(move(name)));
}
void add_child(NonnullRefPtr<PropertyDependencyNode> new_child)
{
for (auto const& child : m_children) {
if (child->m_name == new_child->m_name)
return;
}
// We detect self-reference already.
VERIFY(new_child->m_name != m_name);
m_children.append(move(new_child));
}
bool has_cycles()
{
if (m_marked)
return true;
TemporaryChange change { m_marked, true };
for (auto& child : m_children) {
if (child->has_cycles())
return true;
}
return false;
}
private:
explicit PropertyDependencyNode(String name)
: m_name(move(name))
{
}
String m_name;
Vector<NonnullRefPtr<PropertyDependencyNode>> m_children;
bool m_marked { false };
};
NonnullRefPtr<StyleValue> Parser::resolve_unresolved_style_value(DOM::Element& element, Optional<Selector::PseudoElement> pseudo_element, PropertyID property_id, UnresolvedStyleValue const& unresolved)
{
TokenStream unresolved_values_without_variables_expanded { unresolved.values() };
Vector<ComponentValue> values_with_variables_expanded;
HashMap<FlyString, NonnullRefPtr<PropertyDependencyNode>> dependencies;
if (!expand_variables(element, pseudo_element, string_from_property_id(property_id), dependencies, unresolved_values_without_variables_expanded, values_with_variables_expanded))
return UnsetStyleValue::the();
TokenStream unresolved_values_with_variables_expanded { values_with_variables_expanded };
Vector<ComponentValue> expanded_values;
if (!expand_unresolved_values(element, string_from_property_id(property_id), unresolved_values_with_variables_expanded, expanded_values))
return UnsetStyleValue::the();
auto expanded_value_tokens = TokenStream { expanded_values };
if (auto parsed_value = parse_css_value(property_id, expanded_value_tokens); !parsed_value.is_error())
return parsed_value.release_value();
return UnsetStyleValue::the();
}
static RefPtr<StyleValue const> get_custom_property(DOM::Element const& element, Optional<CSS::Selector::PseudoElement> pseudo_element, FlyString const& custom_property_name)
{
if (pseudo_element.has_value()) {
if (auto it = element.custom_properties(pseudo_element).find(custom_property_name.to_string().to_deprecated_string()); it != element.custom_properties(pseudo_element).end())
return it->value.value;
}
for (auto const* current_element = &element; current_element; current_element = current_element->parent_element()) {
if (auto it = current_element->custom_properties({}).find(custom_property_name.to_string().to_deprecated_string()); it != current_element->custom_properties({}).end())
return it->value.value;
}
return nullptr;
}
bool Parser::expand_variables(DOM::Element& element, Optional<Selector::PseudoElement> pseudo_element, StringView property_name, HashMap<FlyString, NonnullRefPtr<PropertyDependencyNode>>& dependencies, TokenStream<ComponentValue>& source, Vector<ComponentValue>& dest)
{
// Arbitrary large value chosen to avoid the billion-laughs attack.
// https://www.w3.org/TR/css-variables-1/#long-variables
size_t const MAX_VALUE_COUNT = 16384;
if (source.remaining_token_count() + dest.size() > MAX_VALUE_COUNT) {
dbgln("Stopped expanding CSS variables: maximum length reached.");
return false;
}
auto get_dependency_node = [&](FlyString name) -> NonnullRefPtr<PropertyDependencyNode> {
if (auto existing = dependencies.get(name); existing.has_value())
return *existing.value();
auto new_node = PropertyDependencyNode::create(name.to_string());
dependencies.set(name, new_node);
return new_node;
};
while (source.has_next_token()) {
auto const& value = source.next_token();
if (value.is_block()) {
auto const& source_block = value.block();
Vector<ComponentValue> block_values;
TokenStream source_block_contents { source_block.values() };
if (!expand_variables(element, pseudo_element, property_name, dependencies, source_block_contents, block_values))
return false;
NonnullRefPtr<Block> block = Block::create(source_block.token(), move(block_values));
dest.empend(block);
continue;
}
if (!value.is_function()) {
dest.empend(value);
continue;
}
if (!value.function().name().equals_ignoring_ascii_case("var"sv)) {
auto const& source_function = value.function();
Vector<ComponentValue> function_values;
TokenStream source_function_contents { source_function.values() };
if (!expand_variables(element, pseudo_element, property_name, dependencies, source_function_contents, function_values))
return false;
NonnullRefPtr<Function> function = Function::create(FlyString::from_utf8(source_function.name()).release_value_but_fixme_should_propagate_errors(), move(function_values));
dest.empend(function);
continue;
}
TokenStream var_contents { value.function().values() };
var_contents.skip_whitespace();
if (!var_contents.has_next_token())
return false;
auto const& custom_property_name_token = var_contents.next_token();
if (!custom_property_name_token.is(Token::Type::Ident))
return false;
auto custom_property_name = custom_property_name_token.token().ident();
if (!custom_property_name.starts_with("--"sv))
return false;
// Detect dependency cycles. https://www.w3.org/TR/css-variables-1/#cycles
// We do not do this by the spec, since we are not keeping a graph of var dependencies around,
// but rebuilding it every time.
if (custom_property_name == property_name)
return false;
auto parent = get_dependency_node(FlyString::from_utf8(property_name).release_value_but_fixme_should_propagate_errors());
auto child = get_dependency_node(FlyString::from_utf8(custom_property_name).release_value_but_fixme_should_propagate_errors());
parent->add_child(child);
if (parent->has_cycles())
return false;
if (auto custom_property_value = get_custom_property(element, pseudo_element, FlyString::from_utf8(custom_property_name).release_value_but_fixme_should_propagate_errors())) {
VERIFY(custom_property_value->is_unresolved());
TokenStream custom_property_tokens { custom_property_value->as_unresolved().values() };
if (!expand_variables(element, pseudo_element, custom_property_name, dependencies, custom_property_tokens, dest))
return false;
continue;
}
// Use the provided fallback value, if any.
var_contents.skip_whitespace();
if (var_contents.has_next_token()) {
auto const& comma_token = var_contents.next_token();
if (!comma_token.is(Token::Type::Comma))
return false;
var_contents.skip_whitespace();
if (!expand_variables(element, pseudo_element, property_name, dependencies, var_contents, dest))
return false;
}
}
return true;
}
bool Parser::expand_unresolved_values(DOM::Element& element, StringView property_name, TokenStream<ComponentValue>& source, Vector<ComponentValue>& dest)
{
while (source.has_next_token()) {
auto const& value = source.next_token();
if (value.is_function()) {
if (value.function().name().equals_ignoring_ascii_case("attr"sv)) {
if (!substitute_attr_function(element, property_name, value.function(), dest))
return false;
continue;
}
if (auto maybe_calc_value = parse_calculated_value(value); maybe_calc_value && maybe_calc_value->is_calculated()) {
auto& calc_value = maybe_calc_value->as_calculated();
if (calc_value.resolves_to_angle()) {
auto resolved_value = calc_value.resolve_angle();
dest.empend(Token::create_dimension(resolved_value->to_degrees(), "deg"_fly_string));
continue;
}
if (calc_value.resolves_to_frequency()) {
auto resolved_value = calc_value.resolve_frequency();
dest.empend(Token::create_dimension(resolved_value->to_hertz(), "hz"_fly_string));
continue;
}
if (calc_value.resolves_to_length()) {
// FIXME: In order to resolve lengths, we need to know the font metrics in case a font-relative unit
// is used. So... we can't do that until style is computed?
// This might be easier once we have calc-simplification implemented.
}
if (calc_value.resolves_to_percentage()) {
auto resolved_value = calc_value.resolve_percentage();
dest.empend(Token::create_percentage(resolved_value.value().value()));
continue;
}
if (calc_value.resolves_to_time()) {
auto resolved_value = calc_value.resolve_time();
dest.empend(Token::create_dimension(resolved_value->to_seconds(), "s"_fly_string));
continue;
}
if (calc_value.resolves_to_number()) {
auto resolved_value = calc_value.resolve_number();
dest.empend(Token::create_number(resolved_value.value()));
continue;
}
}
auto const& source_function = value.function();
Vector<ComponentValue> function_values;
TokenStream source_function_contents { source_function.values() };
if (!expand_unresolved_values(element, property_name, source_function_contents, function_values))
return false;
NonnullRefPtr<Function> function = Function::create(source_function.name(), move(function_values));
dest.empend(function);
continue;
}
if (value.is_block()) {
auto const& source_block = value.block();
TokenStream source_block_values { source_block.values() };
Vector<ComponentValue> block_values;
if (!expand_unresolved_values(element, property_name, source_block_values, block_values))
return false;
NonnullRefPtr<Block> block = Block::create(source_block.token(), move(block_values));
dest.empend(move(block));
continue;
}
dest.empend(value.token());
}
return true;
}
// https://drafts.csswg.org/css-values-5/#attr-substitution
bool Parser::substitute_attr_function(DOM::Element& element, StringView property_name, Function const& attr_function, Vector<ComponentValue>& dest)
{
// First, parse the arguments to attr():
// attr() = attr( <q-name> <attr-type>? , <declaration-value>?)
// <attr-type> = string | url | ident | color | number | percentage | length | angle | time | frequency | flex | <dimension-unit>
TokenStream attr_contents { attr_function.values() };
attr_contents.skip_whitespace();
if (!attr_contents.has_next_token())
return false;
// - Attribute name
// FIXME: Support optional attribute namespace
if (!attr_contents.peek_token().is(Token::Type::Ident))
return false;
auto attribute_name = attr_contents.next_token().token().ident();
attr_contents.skip_whitespace();
// - Attribute type (optional)
auto attribute_type = "string"_fly_string;
if (attr_contents.peek_token().is(Token::Type::Ident)) {
attribute_type = MUST(FlyString::from_utf8(attr_contents.next_token().token().ident()));
attr_contents.skip_whitespace();
}
// - Comma, then fallback values (optional)
bool has_fallback_values = false;
if (attr_contents.has_next_token()) {
if (!attr_contents.peek_token().is(Token::Type::Comma))
return false;
(void)attr_contents.next_token(); // Comma
has_fallback_values = true;
}
// Then, run the substitution algorithm:
// 1. If the attr() function has a substitution value, replace the attr() function by the substitution value.
// https://drafts.csswg.org/css-values-5/#attr-types
if (element.has_attribute(attribute_name)) {
auto attribute_value = element.get_attribute_value(attribute_name);
if (attribute_type.equals_ignoring_ascii_case("angle"_fly_string)) {
// Parse a component value from the attributes value.
auto component_value = MUST(Parser::Parser::create(m_context, attribute_value)).parse_as_component_value();
// If the result is a <dimension-token> whose unit matches the given type, the result is the substitution value.
// Otherwise, there is no substitution value.
if (component_value.has_value() && component_value->is(Token::Type::Dimension)) {
if (Angle::unit_from_name(component_value->token().dimension_unit()).has_value()) {
dest.append(component_value.release_value());
return true;
}
}
} else if (attribute_type.equals_ignoring_ascii_case("color"_fly_string)) {
// Parse a component value from the attributes value.
// If the result is a <hex-color> or a named color ident, the substitution value is that result as a <color>.
// Otherwise there is no substitution value.
auto component_value = MUST(Parser::Parser::create(m_context, attribute_value)).parse_as_component_value();
if (component_value.has_value()) {
if ((component_value->is(Token::Type::Hash)
&& Color::from_string(MUST(String::formatted("#{}", component_value->token().hash_value()))).has_value())
|| (component_value->is(Token::Type::Ident)
&& Color::from_string(component_value->token().ident()).has_value())) {
dest.append(component_value.release_value());
return true;
}
}
} else if (attribute_type.equals_ignoring_ascii_case("flex"_fly_string)) {
// Parse a component value from the attributes value.
auto component_value = MUST(Parser::Parser::create(m_context, attribute_value)).parse_as_component_value();
// If the result is a <dimension-token> whose unit matches the given type, the result is the substitution value.
// Otherwise, there is no substitution value.
if (component_value.has_value() && component_value->is(Token::Type::Dimension)) {
if (Flex::unit_from_name(component_value->token().dimension_unit()).has_value()) {
dest.append(component_value.release_value());
return true;
}
}
} else if (attribute_type.equals_ignoring_ascii_case("frequency"_fly_string)) {
// Parse a component value from the attributes value.
auto component_value = MUST(Parser::Parser::create(m_context, attribute_value)).parse_as_component_value();
// If the result is a <dimension-token> whose unit matches the given type, the result is the substitution value.
// Otherwise, there is no substitution value.
if (component_value.has_value() && component_value->is(Token::Type::Dimension)) {
if (Frequency::unit_from_name(component_value->token().dimension_unit()).has_value()) {
dest.append(component_value.release_value());
return true;
}
}
} else if (attribute_type.equals_ignoring_ascii_case("ident"_fly_string)) {
// The substitution value is a CSS <custom-ident>, whose value is the literal value of the attribute,
// with leading and trailing ASCII whitespace stripped. (No CSS parsing of the value is performed.)
// If the attribute value, after trimming, is the empty string, there is instead no substitution value.
// If the <custom-ident>s value is a CSS-wide keyword or `default`, there is instead no substitution value.
auto substitution_value = attribute_value.trim_whitespace();
if (!substitution_value.is_empty()
&& !substitution_value.equals_ignoring_ascii_case("default"sv)
&& !is_css_wide_keyword(substitution_value)) {
dest.empend(Token::create_ident(MUST(FlyString::from_deprecated_fly_string(substitution_value))));
return true;
}
} else if (attribute_type.equals_ignoring_ascii_case("length"_fly_string)) {
// Parse a component value from the attributes value.
auto component_value = MUST(Parser::Parser::create(m_context, attribute_value)).parse_as_component_value();
// If the result is a <dimension-token> whose unit matches the given type, the result is the substitution value.
// Otherwise, there is no substitution value.
if (component_value.has_value() && component_value->is(Token::Type::Dimension)) {
if (Length::unit_from_name(component_value->token().dimension_unit()).has_value()) {
dest.append(component_value.release_value());
return true;
}
}
} else if (attribute_type.equals_ignoring_ascii_case("number"_fly_string)) {
// Parse a component value from the attributes value.
// If the result is a <number-token>, the result is the substitution value.
// Otherwise, there is no substitution value.
auto component_value = MUST(Parser::Parser::create(m_context, attribute_value)).parse_as_component_value();
if (component_value.has_value() && component_value->is(Token::Type::Number)) {
dest.append(component_value.release_value());
return true;
}
} else if (attribute_type.equals_ignoring_ascii_case("percentage"_fly_string)) {
// Parse a component value from the attributes value.
auto component_value = MUST(Parser::Parser::create(m_context, attribute_value)).parse_as_component_value();
// If the result is a <percentage-token>, the result is the substitution value.
// Otherwise, there is no substitution value.
if (component_value.has_value() && component_value->is(Token::Type::Percentage)) {
dest.append(component_value.release_value());
return true;
}
} else if (attribute_type.equals_ignoring_ascii_case("string"_fly_string)) {
// The substitution value is a CSS string, whose value is the literal value of the attribute.
// (No CSS parsing or "cleanup" of the value is performed.)
// No value triggers fallback.
dest.empend(Token::create_string(MUST(FlyString::from_deprecated_fly_string(attribute_value))));
return true;
} else if (attribute_type.equals_ignoring_ascii_case("time"_fly_string)) {
// Parse a component value from the attributes value.
auto component_value = MUST(Parser::Parser::create(m_context, attribute_value)).parse_as_component_value();
// If the result is a <dimension-token> whose unit matches the given type, the result is the substitution value.
// Otherwise, there is no substitution value.
if (component_value.has_value() && component_value->is(Token::Type::Dimension)) {
if (Time::unit_from_name(component_value->token().dimension_unit()).has_value()) {
dest.append(component_value.release_value());
return true;
}
}
} else if (attribute_type.equals_ignoring_ascii_case("url"_fly_string)) {
// The substitution value is a CSS <url> value, whose url is the literal value of the attribute.
// (No CSS parsing or "cleanup" of the value is performed.)
// No value triggers fallback.
dest.empend(Token::create_url(MUST(FlyString::from_deprecated_fly_string(attribute_value))));
return true;
} else {
// Dimension units
// Parse a component value from the attributes value.
// If the result is a <number-token>, the substitution value is a dimension with the results value, and the given unit.
// Otherwise, there is no substitution value.
auto component_value = MUST(Parser::Parser::create(m_context, attribute_value)).parse_as_component_value();
if (component_value.has_value() && component_value->is(Token::Type::Number)) {
if (attribute_value == "%"sv) {
dest.empend(Token::create_dimension(component_value->token().number_value(), attribute_type));
return true;
} else if (auto angle_unit = Angle::unit_from_name(attribute_type); angle_unit.has_value()) {
dest.empend(Token::create_dimension(component_value->token().number_value(), attribute_type));
return true;
} else if (auto flex_unit = Flex::unit_from_name(attribute_type); flex_unit.has_value()) {
dest.empend(Token::create_dimension(component_value->token().number_value(), attribute_type));
return true;
} else if (auto frequency_unit = Frequency::unit_from_name(attribute_type); frequency_unit.has_value()) {
dest.empend(Token::create_dimension(component_value->token().number_value(), attribute_type));
return true;
} else if (auto length_unit = Length::unit_from_name(attribute_type); length_unit.has_value()) {
dest.empend(Token::create_dimension(component_value->token().number_value(), attribute_type));
return true;
} else if (auto time_unit = Time::unit_from_name(attribute_type); time_unit.has_value()) {
dest.empend(Token::create_dimension(component_value->token().number_value(), attribute_type));
return true;
} else {
// Not a dimension unit.
return false;
}
}
}
}
// 2. Otherwise, if the attr() function has a fallback value as its last argument, replace the attr() function by the fallback value.
// If there are any var() or attr() references in the fallback, substitute them as well.
if (has_fallback_values)
return expand_unresolved_values(element, property_name, attr_contents, dest);
// 3. Otherwise, the property containing the attr() function is invalid at computed-value time.
return false;
}
}
Reference in a new issue View git blame Copy permalink