ladybird/Libraries/LibIDL/IDLParser.cpp

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/*
* Copyright (c) 2020-2023, Andreas Kling <andreas@ladybird.org>
* Copyright (c) 2021-2022, Linus Groh <linusg@serenityos.org>
* Copyright (c) 2021, Luke Wilde <lukew@serenityos.org>
* Copyright (c) 2022, Ali Mohammad Pur <mpfard@serenityos.org>
* Copyright (c) 2024, Jelle Raaijmakers <jelle@ladybird.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include "IDLParser.h"
#include <AK/Assertions.h>
#include <AK/Function.h>
#include <AK/LexicalPath.h>
#include <AK/QuickSort.h>
#include <LibCore/File.h>
#include <LibFileSystem/FileSystem.h>
[[noreturn]] static void report_parsing_error(StringView message, StringView filename, StringView input, size_t offset)
{
// FIXME: Spaghetti code ahead.
size_t lineno = 1;
size_t colno = 1;
size_t start_line = 0;
size_t line_length = 0;
for (size_t index = 0; index < input.length(); ++index) {
if (offset == index)
colno = index - start_line + 1;
if (input[index] == '\n') {
if (index >= offset)
break;
start_line = index + 1;
line_length = 0;
++lineno;
} else {
++line_length;
}
}
StringBuilder error_message;
error_message.appendff("{}\n", input.substring_view(start_line, line_length));
for (size_t i = 0; i < colno - 1; ++i)
error_message.append(' ');
error_message.append("\033[1;31m^\n"sv);
error_message.appendff("{}:{}: error: {}\033[0m\n", filename, lineno, message);
warnln("{}", error_message.string_view());
exit(EXIT_FAILURE);
}
static ByteString convert_enumeration_value_to_cpp_enum_member(ByteString const& value, HashTable<ByteString>& names_already_seen)
{
StringBuilder builder;
GenericLexer lexer { value };
while (!lexer.is_eof()) {
lexer.ignore_while([](auto c) { return is_ascii_space(c) || c == '-' || c == '_'; });
auto word = lexer.consume_while([](auto c) { return is_ascii_alphanumeric(c); });
if (!word.is_empty()) {
builder.append(word.to_titlecase_string());
} else {
auto non_alnum_string = lexer.consume_while([](auto c) { return !is_ascii_alphanumeric(c); });
if (!non_alnum_string.is_empty())
builder.append('_');
}
}
if (builder.is_empty())
builder.append("Empty"sv);
while (names_already_seen.contains(builder.string_view()))
builder.append('_');
names_already_seen.set(builder.string_view());
return builder.to_byte_string();
}
namespace IDL {
void Parser::assert_specific(char ch)
{
if (!lexer.consume_specific(ch))
report_parsing_error(ByteString::formatted("expected '{}'", ch), filename, input, lexer.tell());
}
void Parser::consume_whitespace()
{
bool consumed = true;
while (consumed) {
consumed = lexer.consume_while(is_ascii_space).length() > 0;
if (lexer.consume_specific("//"sv)) {
lexer.consume_until('\n');
lexer.ignore();
consumed = true;
}
}
}
void Parser::assert_string(StringView expected)
{
if (!lexer.consume_specific(expected))
report_parsing_error(ByteString::formatted("expected '{}'", expected), filename, input, lexer.tell());
}
ByteString Parser::parse_identifier_until(AK::Function<bool(char)> predicate)
{
auto identifier = lexer.consume_until(move(predicate));
return identifier.trim("_"sv, TrimMode::Left);
}
ByteString Parser::parse_identifier_ending_with_space_or(auto... possible_terminating_characters)
{
return parse_identifier_until([&](auto ch) { return (is_ascii_space(ch) || ... || (ch == possible_terminating_characters)); });
}
ByteString Parser::parse_identifier_ending_with(auto... possible_terminating_characters)
{
return parse_identifier_until([&](auto ch) { return (... || (ch == possible_terminating_characters)); });
}
ByteString Parser::parse_identifier_ending_with_space()
{
return parse_identifier_ending_with_space_or();
}
HashMap<ByteString, ByteString> Parser::parse_extended_attributes()
{
HashMap<ByteString, ByteString> extended_attributes;
for (;;) {
consume_whitespace();
if (lexer.consume_specific(']'))
break;
auto name = parse_identifier_ending_with(']', '=', ',');
if (lexer.consume_specific('=')) {
bool did_open_paren = false;
auto value = lexer.consume_until(
[&did_open_paren](auto ch) {
if (ch == '(') {
did_open_paren = true;
return false;
}
if (did_open_paren)
return ch == ')';
return ch == ']' || ch == ',';
});
extended_attributes.set(name, value);
} else {
extended_attributes.set(name, {});
}
lexer.consume_specific(',');
}
consume_whitespace();
return extended_attributes;
}
static HashTable<ByteString> import_stack;
Optional<Interface&> Parser::resolve_import(auto path)
{
ByteString include_path;
for (auto import_base_path : import_base_paths) {
auto maybe_include_path = LexicalPath::join(import_base_path, path).string();
if (!FileSystem::exists(maybe_include_path))
continue;
include_path = maybe_include_path;
break;
}
if (include_path.is_empty()) {
StringBuilder error_message;
error_message.appendff("Failed to find {} in the following directories:\n", path);
error_message.join('\n', import_base_paths);
report_parsing_error(error_message.to_byte_string(), filename, input, lexer.tell());
}
auto real_path_error_or = FileSystem::real_path(include_path);
if (real_path_error_or.is_error())
report_parsing_error(ByteString::formatted("Failed to resolve path {}: {}", include_path, real_path_error_or.error()), filename, input, lexer.tell());
auto real_path = real_path_error_or.release_value();
if (top_level_resolved_imports().contains(real_path))
return *top_level_resolved_imports().find(real_path)->value;
if (import_stack.contains(real_path))
report_parsing_error(ByteString::formatted("Circular import detected: {}", include_path), filename, input, lexer.tell());
import_stack.set(real_path);
auto file_or_error = Core::File::open(real_path, Core::File::OpenMode::Read);
if (file_or_error.is_error())
report_parsing_error(ByteString::formatted("Failed to open {}: {}", real_path, file_or_error.error()), filename, input, lexer.tell());
auto data_or_error = file_or_error.value()->read_until_eof();
if (data_or_error.is_error())
report_parsing_error(ByteString::formatted("Failed to read {}: {}", real_path, data_or_error.error()), filename, input, lexer.tell());
auto& result = Parser(this, real_path, data_or_error.value(), import_base_paths).parse();
import_stack.remove(real_path);
top_level_resolved_imports().set(real_path, &result);
return result;
}
NonnullRefPtr<Type const> Parser::parse_type()
{
if (lexer.consume_specific('(')) {
Vector<NonnullRefPtr<Type const>> union_member_types;
union_member_types.append(parse_type());
consume_whitespace();
assert_string("or"sv);
consume_whitespace();
union_member_types.append(parse_type());
consume_whitespace();
while (lexer.consume_specific("or"sv)) {
consume_whitespace();
union_member_types.append(parse_type());
consume_whitespace();
}
assert_specific(')');
bool nullable = lexer.consume_specific('?');
auto type = adopt_ref(*new UnionType("", nullable, move(union_member_types)));
if (nullable) {
if (type->number_of_nullable_member_types() > 0)
report_parsing_error("nullable union type cannot contain another nullable type"sv, filename, input, lexer.tell());
// FIXME: A nullable union type cannot include a dictionary type as one of its flattened member types.
}
return type;
}
bool unsigned_ = lexer.consume_specific("unsigned"sv);
if (unsigned_)
consume_whitespace();
bool unrestricted = lexer.consume_specific("unrestricted"sv);
if (unrestricted)
consume_whitespace();
VERIFY(!(unsigned_ && unrestricted));
auto name = lexer.consume_until([](auto ch) { return !is_ascii_alphanumeric(ch) && ch != '_'; });
if (name.equals_ignoring_ascii_case("long"sv)) {
consume_whitespace();
if (lexer.consume_specific("long"sv))
name = "long long"sv;
}
Vector<NonnullRefPtr<Type const>> parameters;
bool is_parameterized_type = false;
if (lexer.consume_specific('<')) {
is_parameterized_type = true;
parameters.append(parse_type());
while (lexer.consume_specific(',')) {
consume_whitespace();
parameters.append(parse_type());
}
lexer.consume_specific('>');
}
auto nullable = lexer.consume_specific('?');
StringBuilder builder;
if (unsigned_)
builder.append("unsigned "sv);
if (unrestricted)
builder.append("unrestricted "sv);
builder.append(name);
if (nullable) {
// https://webidl.spec.whatwg.org/#dfn-nullable-type
// The inner type must not be:
// - any,
if (name == "any"sv)
report_parsing_error("'any' cannot be nullable"sv, filename, input, lexer.tell());
// - a promise type,
if (name == "Promise"sv)
report_parsing_error("'Promise' cannot be nullable"sv, filename, input, lexer.tell());
// - an observable array type,
if (name == "ObservableArray")
report_parsing_error("'ObservableArray' cannot be nullable"sv, filename, input, lexer.tell());
// - another nullable type, or
// - a union type that itself includes a nullable type or has a dictionary type as one of its flattened
// member types
// Note: This case is handled above
}
if (is_parameterized_type)
return adopt_ref(*new ParameterizedType(builder.to_byte_string(), nullable, move(parameters)));
return adopt_ref(*new Type(builder.to_byte_string(), nullable));
}
void Parser::parse_attribute(HashMap<ByteString, ByteString>& extended_attributes, Interface& interface, IsStatic is_static)
{
bool inherit = lexer.consume_specific("inherit"sv);
if (inherit)
consume_whitespace();
bool readonly = lexer.consume_specific("readonly"sv);
if (readonly)
consume_whitespace();
// FIXME: Should we parse 'readonly setlike<T>' differently than this?
if (lexer.consume_specific("attribute"sv))
consume_whitespace();
else if (lexer.consume_specific("setlike"sv) && !inherit)
parse_setlike(interface, readonly);
else
report_parsing_error("expected 'attribute'"sv, filename, input, lexer.tell());
auto type = parse_type();
consume_whitespace();
auto name = parse_identifier_ending_with_space_or(';');
consume_whitespace();
assert_specific(';');
ByteString attribute_callback_name;
auto custom_callback_name = extended_attributes.find("AttributeCallbackName");
if (custom_callback_name != extended_attributes.end()) {
attribute_callback_name = custom_callback_name->value;
} else {
attribute_callback_name = name.to_snakecase().replace("-"sv, "_"sv, ReplaceMode::All);
}
auto getter_callback_name = ByteString::formatted("{}_getter", attribute_callback_name);
auto setter_callback_name = ByteString::formatted("{}_setter", attribute_callback_name);
Attribute attribute {
inherit,
readonly,
move(type),
move(name),
move(extended_attributes),
move(getter_callback_name),
move(setter_callback_name),
};
if (is_static == IsStatic::No)
interface.attributes.append(move(attribute));
else
interface.static_attributes.append(move(attribute));
}
void Parser::parse_constant(Interface& interface)
{
lexer.consume_specific("const"sv);
consume_whitespace();
auto type = parse_type();
consume_whitespace();
auto name = parse_identifier_ending_with_space_or('=');
consume_whitespace();
lexer.consume_specific('=');
consume_whitespace();
auto value = lexer.consume_while([](auto ch) { return !is_ascii_space(ch) && ch != ';'; });
consume_whitespace();
assert_specific(';');
Constant constant {
move(type),
move(name),
move(value),
};
interface.constants.append(move(constant));
}
Vector<Parameter> Parser::parse_parameters()
{
consume_whitespace();
Vector<Parameter> parameters;
for (;;) {
if (lexer.next_is(')'))
break;
HashMap<ByteString, ByteString> extended_attributes;
if (lexer.consume_specific('['))
extended_attributes = parse_extended_attributes();
bool optional = lexer.consume_specific("optional"sv);
if (optional)
consume_whitespace();
if (lexer.consume_specific('[')) {
// Not explicitly forbidden by the grammar but unlikely to happen in practice - if it does,
// we'll have to teach the parser how to merge two sets of extended attributes.
VERIFY(extended_attributes.is_empty());
extended_attributes = parse_extended_attributes();
}
auto type = parse_type();
bool variadic = lexer.consume_specific("..."sv);
consume_whitespace();
auto name = parse_identifier_ending_with_space_or(',', ')', '=');
2023-05-13 19:09:12 +00:00
Parameter parameter = { move(type), move(name), optional, {}, move(extended_attributes), variadic };
consume_whitespace();
if (variadic) {
// Variadic parameters must be last and do not have default values.
parameters.append(move(parameter));
break;
}
if (lexer.next_is(')')) {
parameters.append(move(parameter));
break;
}
if (lexer.next_is('=') && optional) {
assert_specific('=');
consume_whitespace();
auto default_value = lexer.consume_until([](auto ch) { return is_ascii_space(ch) || ch == ',' || ch == ')'; });
parameter.optional_default_value = default_value;
}
parameters.append(move(parameter));
if (lexer.next_is(')'))
break;
assert_specific(',');
consume_whitespace();
}
return parameters;
}
Function Parser::parse_function(HashMap<ByteString, ByteString>& extended_attributes, Interface& interface, IsStatic is_static, IsSpecialOperation is_special_operation)
{
auto position = lexer.current_position();
auto return_type = parse_type();
consume_whitespace();
auto name = parse_identifier_ending_with_space_or('(');
consume_whitespace();
assert_specific('(');
auto parameters = parse_parameters();
assert_specific(')');
consume_whitespace();
assert_specific(';');
Function function { move(return_type), name, move(parameters), move(extended_attributes), position, {}, false };
// "Defining a special operation with an identifier is equivalent to separating the special operation out into its own declaration without an identifier."
if (is_special_operation == IsSpecialOperation::No || (is_special_operation == IsSpecialOperation::Yes && !name.is_empty())) {
if (is_static == IsStatic::No)
interface.functions.append(function);
else
interface.static_functions.append(function);
}
return function;
}
void Parser::parse_constructor(HashMap<ByteString, ByteString>& extended_attributes, Interface& interface)
{
assert_string("constructor"sv);
consume_whitespace();
assert_specific('(');
auto parameters = parse_parameters();
assert_specific(')');
consume_whitespace();
assert_specific(';');
interface.constructors.append(Constructor { interface.name, move(parameters), move(extended_attributes) });
}
void Parser::parse_stringifier(HashMap<ByteString, ByteString>& extended_attributes, Interface& interface)
{
assert_string("stringifier"sv);
consume_whitespace();
interface.has_stringifier = true;
if (lexer.next_is("attribute"sv) || lexer.next_is("inherit"sv) || lexer.next_is("readonly"sv)) {
parse_attribute(extended_attributes, interface);
interface.stringifier_attribute = interface.attributes.last().name;
} else {
assert_specific(';');
}
}
void Parser::parse_iterable(Interface& interface)
{
assert_string("iterable"sv);
assert_specific('<');
auto first_type = parse_type();
if (lexer.next_is(',')) {
if (interface.supports_indexed_properties())
report_parsing_error("Interfaces with a pair iterator must not supported indexed properties."sv, filename, input, lexer.tell());
assert_specific(',');
consume_whitespace();
auto second_type = parse_type();
interface.pair_iterator_types = Tuple { move(first_type), move(second_type) };
} else {
if (!interface.supports_indexed_properties())
report_parsing_error("Interfaces with a value iterator must supported indexed properties."sv, filename, input, lexer.tell());
interface.value_iterator_type = move(first_type);
}
if (interface.set_entry_type.has_value())
report_parsing_error("Interfaces with an iterable declaration must not have a setlike declaration."sv, filename, input, lexer.tell());
assert_specific('>');
assert_specific(';');
}
void Parser::parse_setlike(Interface& interface, bool is_readonly)
{
if (interface.supports_indexed_properties())
report_parsing_error("Interfaces with a setlike declaration must not supported indexed properties."sv, filename, input, lexer.tell());
if (interface.value_iterator_type.has_value() || interface.pair_iterator_types.has_value())
report_parsing_error("Interfaces with a setlike declaration must not must not be iterable."sv, filename, input, lexer.tell());
assert_string("setlike"sv);
assert_specific('<');
interface.set_entry_type = parse_type();
interface.is_set_readonly = is_readonly;
assert_specific('>');
assert_specific(';');
}
void Parser::parse_getter(HashMap<ByteString, ByteString>& extended_attributes, Interface& interface)
{
assert_string("getter"sv);
consume_whitespace();
auto function = parse_function(extended_attributes, interface, IsStatic::No, IsSpecialOperation::Yes);
if (function.parameters.size() != 1)
report_parsing_error(ByteString::formatted("Named/indexed property getters must have only 1 parameter, got {} parameters.", function.parameters.size()), filename, input, lexer.tell());
auto& identifier = function.parameters.first();
if (identifier.type->is_nullable())
report_parsing_error("identifier's type must not be nullable."sv, filename, input, lexer.tell());
if (identifier.optional)
report_parsing_error("identifier must not be optional."sv, filename, input, lexer.tell());
// FIXME: Disallow variadic functions once they're supported.
if (identifier.type->name() == "DOMString") {
if (interface.named_property_getter.has_value())
report_parsing_error("An interface can only have one named property getter."sv, filename, input, lexer.tell());
interface.named_property_getter = move(function);
} else if (identifier.type->name() == "unsigned long") {
if (interface.indexed_property_getter.has_value())
report_parsing_error("An interface can only have one indexed property getter."sv, filename, input, lexer.tell());
interface.indexed_property_getter = move(function);
} else {
report_parsing_error(ByteString::formatted("Named/indexed property getter's identifier's type must be either 'DOMString' or 'unsigned long', got '{}'.", identifier.type->name()), filename, input, lexer.tell());
}
}
void Parser::parse_setter(HashMap<ByteString, ByteString>& extended_attributes, Interface& interface)
{
assert_string("setter"sv);
consume_whitespace();
auto function = parse_function(extended_attributes, interface, IsStatic::No, IsSpecialOperation::Yes);
if (function.parameters.size() != 2)
report_parsing_error(ByteString::formatted("Named/indexed property setters must have only 2 parameters, got {} parameter(s).", function.parameters.size()), filename, input, lexer.tell());
auto& identifier = function.parameters.first();
if (identifier.type->is_nullable())
report_parsing_error("identifier's type must not be nullable."sv, filename, input, lexer.tell());
if (identifier.optional)
report_parsing_error("identifier must not be optional."sv, filename, input, lexer.tell());
// FIXME: Disallow variadic functions once they're supported.
if (identifier.type->name() == "DOMString") {
if (interface.named_property_setter.has_value())
report_parsing_error("An interface can only have one named property setter."sv, filename, input, lexer.tell());
if (!interface.named_property_getter.has_value())
report_parsing_error("A named property setter must be accompanied by a named property getter."sv, filename, input, lexer.tell());
interface.named_property_setter = move(function);
} else if (identifier.type->name() == "unsigned long") {
if (interface.indexed_property_setter.has_value())
report_parsing_error("An interface can only have one indexed property setter."sv, filename, input, lexer.tell());
if (!interface.indexed_property_getter.has_value())
report_parsing_error("An indexed property setter must be accompanied by an indexed property getter."sv, filename, input, lexer.tell());
interface.indexed_property_setter = move(function);
} else {
report_parsing_error(ByteString::formatted("Named/indexed property setter's identifier's type must be either 'DOMString' or 'unsigned long', got '{}'.", identifier.type->name()), filename, input, lexer.tell());
}
}
void Parser::parse_deleter(HashMap<ByteString, ByteString>& extended_attributes, Interface& interface)
{
assert_string("deleter"sv);
consume_whitespace();
auto function = parse_function(extended_attributes, interface, IsStatic::No, IsSpecialOperation::Yes);
if (function.parameters.size() != 1)
report_parsing_error(ByteString::formatted("Named property deleter must have only 1 parameter, got {} parameters.", function.parameters.size()), filename, input, lexer.tell());
auto& identifier = function.parameters.first();
if (identifier.type->is_nullable())
report_parsing_error("identifier's type must not be nullable."sv, filename, input, lexer.tell());
if (identifier.optional)
report_parsing_error("identifier must not be optional."sv, filename, input, lexer.tell());
// FIXME: Disallow variadic functions once they're supported.
if (identifier.type->name() == "DOMString") {
if (interface.named_property_deleter.has_value())
report_parsing_error("An interface can only have one named property deleter."sv, filename, input, lexer.tell());
if (!interface.named_property_getter.has_value())
report_parsing_error("A named property deleter must be accompanied by a named property getter."sv, filename, input, lexer.tell());
interface.named_property_deleter = move(function);
} else {
report_parsing_error(ByteString::formatted("Named property deleter's identifier's type must be 'DOMString', got '{}'.", identifier.type->name()), filename, input, lexer.tell());
}
}
void Parser::parse_interface(Interface& interface)
{
consume_whitespace();
interface.name = parse_identifier_ending_with_space();
consume_whitespace();
if (lexer.consume_specific(':')) {
consume_whitespace();
interface.parent_name = parse_identifier_ending_with_space();
consume_whitespace();
}
assert_specific('{');
for (;;) {
HashMap<ByteString, ByteString> extended_attributes;
consume_whitespace();
if (lexer.consume_specific('}')) {
consume_whitespace();
assert_specific(';');
break;
}
if (lexer.consume_specific('[')) {
extended_attributes = parse_extended_attributes();
if (!interface.has_unscopable_member && extended_attributes.contains("Unscopable"))
interface.has_unscopable_member = true;
}
if (lexer.next_is("constructor")) {
parse_constructor(extended_attributes, interface);
continue;
}
if (lexer.next_is("const")) {
parse_constant(interface);
continue;
}
if (lexer.next_is("stringifier")) {
parse_stringifier(extended_attributes, interface);
continue;
}
if (lexer.next_is("iterable")) {
parse_iterable(interface);
continue;
}
if (lexer.next_is("setlike")) {
bool is_readonly = false;
parse_setlike(interface, is_readonly);
continue;
}
if (lexer.next_is("inherit") || lexer.next_is("readonly") || lexer.next_is("attribute")) {
parse_attribute(extended_attributes, interface);
continue;
}
if (lexer.next_is("getter")) {
parse_getter(extended_attributes, interface);
continue;
}
if (lexer.next_is("setter")) {
parse_setter(extended_attributes, interface);
continue;
}
if (lexer.next_is("deleter")) {
parse_deleter(extended_attributes, interface);
continue;
}
bool is_static = lexer.consume_specific("static");
if (!is_static) {
parse_function(extended_attributes, interface, IsStatic::No);
} else {
consume_whitespace();
if (lexer.next_is("readonly") || lexer.next_is("attribute")) {
parse_attribute(extended_attributes, interface, IsStatic::Yes);
} else {
parse_function(extended_attributes, interface, IsStatic::Yes);
}
}
}
if (auto legacy_namespace = interface.extended_attributes.get("LegacyNamespace"sv); legacy_namespace.has_value())
interface.namespaced_name = ByteString::formatted("{}.{}", *legacy_namespace, interface.name);
else
interface.namespaced_name = interface.name;
if (auto maybe_implemented_as = interface.extended_attributes.get("ImplementedAs"); maybe_implemented_as.has_value())
interface.implemented_name = maybe_implemented_as.release_value();
else
interface.implemented_name = interface.name;
interface.constructor_class = ByteString::formatted("{}Constructor", interface.implemented_name);
interface.prototype_class = ByteString::formatted("{}Prototype", interface.implemented_name);
interface.prototype_base_class = ByteString::formatted("{}Prototype", interface.parent_name.is_empty() ? "Object" : interface.parent_name);
interface.global_mixin_class = ByteString::formatted("{}GlobalMixin", interface.name);
consume_whitespace();
}
void Parser::parse_namespace(Interface& interface)
{
consume_whitespace();
interface.name = parse_identifier_ending_with_space();
interface.is_namespace = true;
consume_whitespace();
assert_specific('{');
for (;;) {
consume_whitespace();
if (lexer.consume_specific('}')) {
consume_whitespace();
assert_specific(';');
break;
}
HashMap<ByteString, ByteString> extended_attributes;
parse_function(extended_attributes, interface);
}
interface.namespace_class = ByteString::formatted("{}Namespace", interface.name);
consume_whitespace();
}
// https://webidl.spec.whatwg.org/#prod-Enum
void Parser::parse_enumeration(HashMap<ByteString, ByteString> extended_attributes, Interface& interface)
{
assert_string("enum"sv);
consume_whitespace();
Enumeration enumeration {};
enumeration.extended_attributes = move(extended_attributes);
auto name = parse_identifier_ending_with_space();
consume_whitespace();
assert_specific('{');
for (; !lexer.is_eof();) {
consume_whitespace();
if (lexer.next_is('}'))
break;
assert_specific('"');
auto string = lexer.consume_until('"');
assert_specific('"');
consume_whitespace();
if (enumeration.values.contains(string))
report_parsing_error(ByteString::formatted("Enumeration {} contains duplicate member '{}'", name, string), filename, input, lexer.tell());
else
enumeration.values.set(string);
if (enumeration.first_member.is_empty())
enumeration.first_member = move(string);
if (!lexer.next_is('}'))
assert_specific(',');
}
consume_whitespace();
assert_specific('}');
assert_specific(';');
HashTable<ByteString> names_already_seen;
for (auto& entry : enumeration.values)
enumeration.translated_cpp_names.set(entry, convert_enumeration_value_to_cpp_enum_member(entry, names_already_seen));
interface.enumerations.set(name, move(enumeration));
consume_whitespace();
}
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void Parser::parse_typedef(Interface& interface)
{
assert_string("typedef"sv);
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consume_whitespace();
HashMap<ByteString, ByteString> extended_attributes;
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if (lexer.consume_specific('['))
extended_attributes = parse_extended_attributes();
auto type = parse_type();
consume_whitespace();
auto name = parse_identifier_ending_with(';');
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assert_specific(';');
interface.typedefs.set(move(name), Typedef { move(extended_attributes), move(type) });
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consume_whitespace();
}
void Parser::parse_dictionary(Interface& interface)
{
assert_string("dictionary"sv);
consume_whitespace();
Dictionary dictionary {};
auto name = parse_identifier_ending_with_space();
consume_whitespace();
if (lexer.consume_specific(':')) {
consume_whitespace();
dictionary.parent_name = parse_identifier_ending_with_space();
consume_whitespace();
}
assert_specific('{');
for (;;) {
consume_whitespace();
if (lexer.consume_specific('}')) {
consume_whitespace();
assert_specific(';');
break;
}
bool required = false;
HashMap<ByteString, ByteString> extended_attributes;
if (lexer.consume_specific("required"sv)) {
required = true;
consume_whitespace();
}
if (lexer.consume_specific('['))
extended_attributes = parse_extended_attributes();
auto type = parse_type();
consume_whitespace();
auto name = parse_identifier_ending_with_space_or(';');
consume_whitespace();
Optional<StringView> default_value;
if (lexer.consume_specific('=')) {
VERIFY(!required);
consume_whitespace();
default_value = lexer.consume_until([](auto ch) { return is_ascii_space(ch) || ch == ';'; });
consume_whitespace();
}
assert_specific(';');
DictionaryMember member {
required,
move(type),
move(name),
move(extended_attributes),
Optional<ByteString>(move(default_value)),
};
dictionary.members.append(move(member));
}
// dictionary members need to be evaluated in lexicographical order
quick_sort(dictionary.members, [&](auto& one, auto& two) {
return one.name < two.name;
});
interface.dictionaries.set(name, move(dictionary));
consume_whitespace();
}
void Parser::parse_interface_mixin(Interface& interface)
{
auto mixin_interface_ptr = make<Interface>();
auto& mixin_interface = *mixin_interface_ptr;
VERIFY(top_level_interfaces().set(move(mixin_interface_ptr)) == AK::HashSetResult::InsertedNewEntry);
mixin_interface.module_own_path = interface.module_own_path;
mixin_interface.is_mixin = true;
assert_string("interface"sv);
consume_whitespace();
assert_string("mixin"sv);
auto offset = lexer.tell();
parse_interface(mixin_interface);
if (!mixin_interface.parent_name.is_empty())
report_parsing_error("Mixin interfaces are not allowed to have inherited parents"sv, filename, input, offset);
auto name = mixin_interface.name;
interface.mixins.set(move(name), &mixin_interface);
}
void Parser::parse_callback_function(HashMap<ByteString, ByteString>& extended_attributes, Interface& interface)
{
assert_string("callback"sv);
consume_whitespace();
auto name = parse_identifier_ending_with_space();
consume_whitespace();
assert_specific('=');
consume_whitespace();
auto return_type = parse_type();
consume_whitespace();
assert_specific('(');
auto parameters = parse_parameters();
assert_specific(')');
consume_whitespace();
assert_specific(';');
interface.callback_functions.set(move(name), CallbackFunction { move(return_type), move(parameters), extended_attributes.contains("LegacyTreatNonObjectAsNull") });
consume_whitespace();
}
void Parser::parse_non_interface_entities(bool allow_interface, Interface& interface)
{
consume_whitespace();
while (!lexer.is_eof()) {
HashMap<ByteString, ByteString> extended_attributes;
if (lexer.consume_specific('['))
extended_attributes = parse_extended_attributes();
if (lexer.next_is("dictionary")) {
parse_dictionary(interface);
} else if (lexer.next_is("enum")) {
parse_enumeration(extended_attributes, interface);
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} else if (lexer.next_is("typedef")) {
parse_typedef(interface);
} else if (lexer.next_is("interface mixin")) {
parse_interface_mixin(interface);
} else if (lexer.next_is("callback")) {
parse_callback_function(extended_attributes, interface);
} else if ((allow_interface && !lexer.next_is("interface") && !lexer.next_is("namespace")) || !allow_interface) {
auto current_offset = lexer.tell();
auto name = parse_identifier_ending_with_space();
consume_whitespace();
if (lexer.consume_specific("includes"sv)) {
consume_whitespace();
auto mixin_name = parse_identifier_ending_with_space_or(';');
interface.included_mixins.ensure(name).set(mixin_name);
consume_whitespace();
assert_specific(';');
consume_whitespace();
} else {
report_parsing_error("expected 'enum' or 'dictionary'"sv, filename, input, current_offset);
}
} else {
interface.extended_attributes = move(extended_attributes);
break;
}
}
consume_whitespace();
}
static void resolve_union_typedefs(Interface& interface, UnionType& union_);
static void resolve_typedef(Interface& interface, NonnullRefPtr<Type const>& type, HashMap<ByteString, ByteString>* extended_attributes = {})
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{
if (is<ParameterizedType>(*type)) {
auto& parameterized_type = const_cast<Type&>(*type).as_parameterized();
auto& parameters = static_cast<Vector<NonnullRefPtr<Type const>>&>(parameterized_type.parameters());
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for (auto& parameter : parameters)
resolve_typedef(interface, parameter);
return;
}
// Resolve anonymous union types until we get named types that can be resolved in the next step.
if (is<UnionType>(*type) && type->name().is_empty()) {
resolve_union_typedefs(interface, const_cast<Type&>(*type).as_union());
return;
}
auto it = interface.typedefs.find(type->name());
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if (it == interface.typedefs.end())
return;
bool nullable = type->is_nullable();
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type = it->value.type;
const_cast<Type&>(*type).set_nullable(nullable);
if (extended_attributes) {
for (auto& attribute : it->value.extended_attributes)
extended_attributes->set(attribute.key, attribute.value);
}
// Recursively resolve typedefs in unions after we resolved the type itself - e.g. for this:
// typedef (A or B) Union1;
// typedef (C or D) Union2;
// typedef (Union1 or Union2) NestedUnion;
// We run:
// - resolve_typedef(NestedUnion) -> NestedUnion gets replaced by UnionType(Union1, Union2)
// - resolve_typedef(Union1) -> Union1 gets replaced by UnionType(A, B)
// - resolve_typedef(Union2) -> Union2 gets replaced by UnionType(C, D)
// So whatever referenced NestedUnion ends up with the following resolved union:
// UnionType(UnionType(A, B), UnionType(C, D))
// Note that flattening unions is handled separately as per the spec.
if (is<UnionType>(*type))
resolve_union_typedefs(interface, const_cast<Type&>(*type).as_union());
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}
static void resolve_union_typedefs(Interface& interface, UnionType& union_)
{
auto& member_types = static_cast<Vector<NonnullRefPtr<Type const>>&>(union_.member_types());
for (auto& member_type : member_types)
resolve_typedef(interface, member_type);
}
static void resolve_parameters_typedefs(Interface& interface, Vector<Parameter>& parameters)
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{
for (auto& parameter : parameters)
resolve_typedef(interface, parameter.type, &parameter.extended_attributes);
}
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template<typename FunctionType>
void resolve_function_typedefs(Interface& interface, FunctionType& function)
{
resolve_typedef(interface, function.return_type);
resolve_parameters_typedefs(interface, function.parameters);
}
Interface& Parser::parse()
{
auto this_module_or_error = FileSystem::real_path(filename);
if (this_module_or_error.is_error()) {
report_parsing_error(ByteString::formatted("Failed to resolve path '{}': {}", filename, this_module_or_error.error()), filename, input, 0);
VERIFY_NOT_REACHED();
}
auto this_module = this_module_or_error.release_value();
auto interface_ptr = make<Interface>();
auto& interface = *interface_ptr;
VERIFY(top_level_interfaces().set(move(interface_ptr)) == AK::HashSetResult::InsertedNewEntry);
interface.module_own_path = this_module;
top_level_resolved_imports().set(this_module, &interface);
Vector<Interface&> imports;
{
while (lexer.consume_specific("#import"sv)) {
consume_whitespace();
assert_specific('<');
auto path = lexer.consume_until('>');
lexer.ignore();
auto maybe_interface = resolve_import(path);
if (maybe_interface.has_value()) {
imports.append(maybe_interface.release_value());
}
consume_whitespace();
}
}
parse_non_interface_entities(true, interface);
if (lexer.consume_specific("interface"sv))
parse_interface(interface);
else if (lexer.consume_specific("namespace"sv))
parse_namespace(interface);
parse_non_interface_entities(false, interface);
for (auto& import : imports) {
// FIXME: Instead of copying every imported entity into the current interface, query imports directly
for (auto& dictionary : import.dictionaries)
interface.dictionaries.set(dictionary.key, dictionary.value);
for (auto& enumeration : import.enumerations) {
auto enumeration_copy = enumeration.value;
enumeration_copy.is_original_definition = false;
interface.enumerations.set(enumeration.key, move(enumeration_copy));
}
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for (auto& typedef_ : import.typedefs)
interface.typedefs.set(typedef_.key, typedef_.value);
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for (auto& mixin : import.mixins) {
if (auto it = interface.mixins.find(mixin.key); it != interface.mixins.end() && it->value != mixin.value)
report_parsing_error(ByteString::formatted("Mixin '{}' was already defined in {}", mixin.key, mixin.value->module_own_path), filename, input, lexer.tell());
interface.mixins.set(mixin.key, mixin.value);
}
for (auto& callback_function : import.callback_functions)
interface.callback_functions.set(callback_function.key, callback_function.value);
}
// Resolve mixins
if (auto it = interface.included_mixins.find(interface.name); it != interface.included_mixins.end()) {
for (auto& entry : it->value) {
auto mixin_it = interface.mixins.find(entry);
if (mixin_it == interface.mixins.end())
report_parsing_error(ByteString::formatted("Mixin '{}' was never defined", entry), filename, input, lexer.tell());
auto& mixin = mixin_it->value;
interface.attributes.extend(mixin->attributes);
interface.constants.extend(mixin->constants);
interface.functions.extend(mixin->functions);
interface.static_functions.extend(mixin->static_functions);
if (interface.has_stringifier && mixin->has_stringifier)
report_parsing_error(ByteString::formatted("Both interface '{}' and mixin '{}' have defined stringifier attributes", interface.name, mixin->name), filename, input, lexer.tell());
if (mixin->has_stringifier) {
interface.stringifier_attribute = mixin->stringifier_attribute;
interface.has_stringifier = true;
}
if (mixin->has_unscopable_member)
interface.has_unscopable_member = true;
}
}
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// Resolve typedefs
for (auto& attribute : interface.attributes)
resolve_typedef(interface, attribute.type, &attribute.extended_attributes);
for (auto& attribute : interface.static_attributes)
resolve_typedef(interface, attribute.type, &attribute.extended_attributes);
for (auto& constant : interface.constants)
resolve_typedef(interface, constant.type);
for (auto& constructor : interface.constructors)
resolve_parameters_typedefs(interface, constructor.parameters);
for (auto& function : interface.functions)
resolve_function_typedefs(interface, function);
for (auto& static_function : interface.static_functions)
resolve_function_typedefs(interface, static_function);
if (interface.value_iterator_type.has_value())
resolve_typedef(interface, *interface.value_iterator_type);
if (interface.pair_iterator_types.has_value()) {
resolve_typedef(interface, interface.pair_iterator_types->get<0>());
resolve_typedef(interface, interface.pair_iterator_types->get<1>());
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}
if (interface.named_property_getter.has_value())
resolve_function_typedefs(interface, *interface.named_property_getter);
if (interface.named_property_setter.has_value())
resolve_function_typedefs(interface, *interface.named_property_setter);
if (interface.indexed_property_getter.has_value())
resolve_function_typedefs(interface, *interface.indexed_property_getter);
if (interface.indexed_property_setter.has_value())
resolve_function_typedefs(interface, *interface.indexed_property_setter);
if (interface.named_property_deleter.has_value())
resolve_function_typedefs(interface, *interface.named_property_deleter);
if (interface.named_property_getter.has_value())
resolve_function_typedefs(interface, *interface.named_property_getter);
for (auto& dictionary : interface.dictionaries) {
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for (auto& dictionary_member : dictionary.value.members)
resolve_typedef(interface, dictionary_member.type, &dictionary_member.extended_attributes);
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}
for (auto& callback_function : interface.callback_functions)
resolve_function_typedefs(interface, callback_function.value);
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// Create overload sets
for (auto& function : interface.functions) {
if (function.extended_attributes.contains("FIXME"))
continue;
auto& overload_set = interface.overload_sets.ensure(function.name);
function.overload_index = overload_set.size();
overload_set.append(function);
}
for (auto& overload_set : interface.overload_sets) {
if (overload_set.value.size() == 1)
continue;
for (auto& overloaded_function : overload_set.value)
overloaded_function.is_overloaded = true;
}
for (auto& function : interface.static_functions) {
if (function.extended_attributes.contains("FIXME"))
continue;
auto& overload_set = interface.static_overload_sets.ensure(function.name);
function.overload_index = overload_set.size();
overload_set.append(function);
}
for (auto& overload_set : interface.static_overload_sets) {
if (overload_set.value.size() == 1)
continue;
for (auto& overloaded_function : overload_set.value)
overloaded_function.is_overloaded = true;
}
for (auto& constructor : interface.constructors) {
if (constructor.extended_attributes.contains("FIXME"))
continue;
auto& overload_set = interface.constructor_overload_sets.ensure(constructor.name);
constructor.overload_index = overload_set.size();
overload_set.append(constructor);
}
for (auto& overload_set : interface.constructor_overload_sets) {
if (overload_set.value.size() == 1)
continue;
for (auto& overloaded_constructor : overload_set.value)
overloaded_constructor.is_overloaded = true;
}
// Check overload sets for repeated instances of the same function
// as these will produce very cryptic errors if left alone.
for (auto& overload_set : interface.overload_sets) {
auto& functions = overload_set.value;
for (size_t i = 0; i < functions.size(); ++i) {
for (size_t j = i + 1; j < functions.size(); ++j) {
if (functions[i].parameters.size() != functions[j].parameters.size())
continue;
auto same = true;
for (size_t k = 0; k < functions[i].parameters.size(); ++k) {
if (functions[i].parameters[k].type->is_distinguishable_from(interface, functions[j].parameters[k].type)) {
same = false;
break;
}
}
if (same) {
report_parsing_error(
ByteString::formatted("Overload set '{}' contains multiple identical declarations", overload_set.key),
filename,
input,
functions[j].source_position.offset);
}
}
}
}
interface.imported_modules = move(imports);
if (top_level_parser() == this)
VERIFY(import_stack.is_empty());
return interface;
}
Parser::Parser(ByteString filename, StringView contents, Vector<ByteString> import_base_paths)
: import_base_paths(move(import_base_paths))
, filename(move(filename))
, input(contents)
, lexer(input)
{
}
Parser::Parser(Parser* parent, ByteString filename, StringView contents, Vector<ByteString> import_base_paths)
: import_base_paths(move(import_base_paths))
, filename(move(filename))
, input(contents)
, lexer(input)
, parent(parent)
{
}
Parser* Parser::top_level_parser()
{
Parser* current = this;
for (Parser* next = this; next; next = next->parent)
current = next;
return current;
}
HashMap<ByteString, Interface*>& Parser::top_level_resolved_imports()
{
return top_level_parser()->resolved_imports;
}
HashTable<NonnullOwnPtr<Interface>>& Parser::top_level_interfaces()
{
return top_level_parser()->interfaces;
}
Vector<ByteString> Parser::imported_files() const
{
return const_cast<Parser*>(this)->top_level_resolved_imports().keys();
}
}