ladybird/Libraries/LibJS/Parser.cpp

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/*
* Copyright (c) 2020, Stephan Unverwerth <s.unverwerth@gmx.de>
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
* SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
* CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "Parser.h"
#include <AK/HashMap.h>
#include <AK/ScopeGuard.h>
#include <AK/StdLibExtras.h>
#include <stdio.h>
namespace JS {
class ScopePusher {
public:
enum Type {
Var = 1,
Let = 2,
};
ScopePusher(Parser& parser, unsigned mask)
: m_parser(parser)
, m_mask(mask)
{
if (m_mask & Var)
m_parser.m_parser_state.m_var_scopes.append(NonnullRefPtrVector<VariableDeclaration>());
if (m_mask & Let)
m_parser.m_parser_state.m_let_scopes.append(NonnullRefPtrVector<VariableDeclaration>());
}
~ScopePusher()
{
if (m_mask & Var)
m_parser.m_parser_state.m_var_scopes.take_last();
if (m_mask & Let)
m_parser.m_parser_state.m_let_scopes.take_last();
}
Parser& m_parser;
unsigned m_mask { 0 };
};
static HashMap<TokenType, int> g_operator_precedence;
Parser::ParserState::ParserState(Lexer lexer)
: m_lexer(move(lexer))
, m_current_token(m_lexer.next())
{
}
Parser::Parser(Lexer lexer)
: m_parser_state(move(lexer))
{
if (g_operator_precedence.is_empty()) {
// https://developer.mozilla.org/en-US/docs/Web/JavaScript/Reference/Operators/Operator_Precedence
g_operator_precedence.set(TokenType::Period, 20);
g_operator_precedence.set(TokenType::BracketOpen, 20);
g_operator_precedence.set(TokenType::ParenOpen, 20);
g_operator_precedence.set(TokenType::QuestionMarkPeriod, 20);
g_operator_precedence.set(TokenType::New, 19);
g_operator_precedence.set(TokenType::PlusPlus, 18);
g_operator_precedence.set(TokenType::MinusMinus, 18);
g_operator_precedence.set(TokenType::ExclamationMark, 17);
g_operator_precedence.set(TokenType::Tilde, 17);
g_operator_precedence.set(TokenType::Typeof, 17);
g_operator_precedence.set(TokenType::Void, 17);
g_operator_precedence.set(TokenType::Delete, 17);
g_operator_precedence.set(TokenType::Await, 17);
g_operator_precedence.set(TokenType::DoubleAsterisk, 16);
g_operator_precedence.set(TokenType::Asterisk, 15);
g_operator_precedence.set(TokenType::Slash, 15);
g_operator_precedence.set(TokenType::Percent, 15);
g_operator_precedence.set(TokenType::Plus, 14);
g_operator_precedence.set(TokenType::Minus, 14);
g_operator_precedence.set(TokenType::ShiftLeft, 13);
g_operator_precedence.set(TokenType::ShiftRight, 13);
g_operator_precedence.set(TokenType::UnsignedShiftRight, 13);
g_operator_precedence.set(TokenType::LessThan, 12);
g_operator_precedence.set(TokenType::LessThanEquals, 12);
g_operator_precedence.set(TokenType::GreaterThan, 12);
g_operator_precedence.set(TokenType::GreaterThanEquals, 12);
g_operator_precedence.set(TokenType::In, 12);
g_operator_precedence.set(TokenType::Instanceof, 12);
g_operator_precedence.set(TokenType::EqualsEquals, 11);
g_operator_precedence.set(TokenType::ExclamationMarkEquals, 11);
g_operator_precedence.set(TokenType::EqualsEqualsEquals, 11);
g_operator_precedence.set(TokenType::ExclamationMarkEqualsEquals, 11);
g_operator_precedence.set(TokenType::Ampersand, 10);
g_operator_precedence.set(TokenType::Caret, 9);
g_operator_precedence.set(TokenType::Pipe, 8);
g_operator_precedence.set(TokenType::DoubleQuestionMark, 7);
g_operator_precedence.set(TokenType::DoubleAmpersand, 6);
g_operator_precedence.set(TokenType::DoublePipe, 5);
g_operator_precedence.set(TokenType::QuestionMark, 4);
g_operator_precedence.set(TokenType::Equals, 3);
g_operator_precedence.set(TokenType::PlusEquals, 3);
g_operator_precedence.set(TokenType::MinusEquals, 3);
g_operator_precedence.set(TokenType::AsteriskAsteriskEquals, 3);
g_operator_precedence.set(TokenType::AsteriskEquals, 3);
g_operator_precedence.set(TokenType::SlashEquals, 3);
g_operator_precedence.set(TokenType::PercentEquals, 3);
g_operator_precedence.set(TokenType::ShiftLeftEquals, 3);
g_operator_precedence.set(TokenType::ShiftRightEquals, 3);
g_operator_precedence.set(TokenType::UnsignedShiftRightEquals, 3);
g_operator_precedence.set(TokenType::PipeEquals, 3);
g_operator_precedence.set(TokenType::Yield, 2);
g_operator_precedence.set(TokenType::Comma, 1);
}
}
int Parser::operator_precedence(TokenType type) const
{
auto it = g_operator_precedence.find(type);
if (it == g_operator_precedence.end()) {
fprintf(stderr, "No precedence for operator %s\n", Token::name(type));
ASSERT_NOT_REACHED();
return -1;
}
return it->value;
}
Associativity Parser::operator_associativity(TokenType type) const
{
switch (type) {
case TokenType::Period:
case TokenType::BracketOpen:
case TokenType::ParenOpen:
case TokenType::QuestionMarkPeriod:
case TokenType::Asterisk:
case TokenType::Slash:
case TokenType::Percent:
case TokenType::Plus:
case TokenType::Minus:
case TokenType::ShiftLeft:
case TokenType::ShiftRight:
case TokenType::UnsignedShiftRight:
case TokenType::LessThan:
case TokenType::LessThanEquals:
case TokenType::GreaterThan:
case TokenType::GreaterThanEquals:
case TokenType::In:
case TokenType::Instanceof:
case TokenType::EqualsEquals:
case TokenType::ExclamationMarkEquals:
case TokenType::EqualsEqualsEquals:
case TokenType::ExclamationMarkEqualsEquals:
case TokenType::Typeof:
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case TokenType::Void:
case TokenType::Ampersand:
case TokenType::Caret:
case TokenType::Pipe:
case TokenType::DoubleQuestionMark:
case TokenType::DoubleAmpersand:
case TokenType::DoublePipe:
case TokenType::Comma:
return Associativity::Left;
default:
return Associativity::Right;
}
}
NonnullRefPtr<Program> Parser::parse_program()
{
ScopePusher scope(*this, ScopePusher::Var | ScopePusher::Let);
auto program = adopt(*new Program);
while (!done()) {
if (match(TokenType::Semicolon)) {
consume();
} else if (match_statement()) {
program->append(parse_statement());
} else {
expected("statement");
consume();
}
}
ASSERT(m_parser_state.m_var_scopes.size() == 1);
program->add_variables(m_parser_state.m_var_scopes.last());
program->add_variables(m_parser_state.m_let_scopes.last());
return program;
}
NonnullRefPtr<Statement> Parser::parse_statement()
{
auto statement = [this]() -> NonnullRefPtr<Statement> {
switch (m_parser_state.m_current_token.type()) {
case TokenType::Function:
return parse_function_node<FunctionDeclaration>();
case TokenType::CurlyOpen:
return parse_block_statement();
case TokenType::Return:
return parse_return_statement();
case TokenType::Var:
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case TokenType::Let:
case TokenType::Const:
return parse_variable_declaration();
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case TokenType::For:
return parse_for_statement();
case TokenType::If:
return parse_if_statement();
case TokenType::Throw:
return parse_throw_statement();
case TokenType::Try:
return parse_try_statement();
case TokenType::Break:
return parse_break_statement();
case TokenType::Continue:
return parse_continue_statement();
case TokenType::Switch:
return parse_switch_statement();
case TokenType::Do:
return parse_do_while_statement();
default:
if (match_expression())
return adopt(*new ExpressionStatement(parse_expression(0)));
m_parser_state.m_has_errors = true;
expected("statement (missing switch case)");
consume();
return create_ast_node<ErrorStatement>();
} }();
if (match(TokenType::Semicolon))
consume();
return statement;
}
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RefPtr<FunctionExpression> Parser::try_parse_arrow_function_expression(bool expect_parens)
{
save_state();
m_parser_state.m_var_scopes.append(NonnullRefPtrVector<VariableDeclaration>());
ArmedScopeGuard state_rollback_guard = [&] {
m_parser_state.m_var_scopes.take_last();
load_state();
};
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Vector<FlyString> parameters;
bool parse_failed = false;
while (true) {
if (match(TokenType::Comma)) {
consume(TokenType::Comma);
} else if (match(TokenType::Identifier)) {
auto token = consume(TokenType::Identifier);
parameters.append(token.value());
} else if (match(TokenType::ParenClose)) {
if (expect_parens) {
consume(TokenType::ParenClose);
if (match(TokenType::Arrow)) {
consume(TokenType::Arrow);
} else {
parse_failed = true;
}
break;
}
parse_failed = true;
break;
} else if (match(TokenType::Arrow)) {
if (!expect_parens) {
consume(TokenType::Arrow);
break;
}
parse_failed = true;
break;
} else {
parse_failed = true;
break;
}
}
if (parse_failed)
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return nullptr;
auto function_body_result = [this]() -> RefPtr<BlockStatement> {
if (match(TokenType::CurlyOpen)) {
// Parse a function body with statements
return parse_block_statement();
}
if (match_expression()) {
// Parse a function body which returns a single expression
// FIXME: We synthesize a block with a return statement
// for arrow function bodies which are a single expression.
// Esprima generates a single "ArrowFunctionExpression"
// with a "body" property.
auto return_expression = parse_expression(0);
auto return_block = create_ast_node<BlockStatement>();
return_block->append<ReturnStatement>(move(return_expression));
return return_block;
}
// Invalid arrow function body
return nullptr;
}();
if (!function_body_result.is_null()) {
state_rollback_guard.disarm();
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auto body = function_body_result.release_nonnull();
return create_ast_node<FunctionExpression>("", move(body), move(parameters), m_parser_state.m_var_scopes.take_last());
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}
return nullptr;
}
NonnullRefPtr<Expression> Parser::parse_primary_expression()
{
if (match_unary_prefixed_expression())
return parse_unary_prefixed_expression();
switch (m_parser_state.m_current_token.type()) {
case TokenType::ParenOpen: {
consume(TokenType::ParenOpen);
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if (match(TokenType::ParenClose) || match(TokenType::Identifier)) {
auto arrow_function_result = try_parse_arrow_function_expression(true);
if (!arrow_function_result.is_null()) {
return arrow_function_result.release_nonnull();
}
}
auto expression = parse_expression(0);
consume(TokenType::ParenClose);
return expression;
}
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case TokenType::This:
consume();
return create_ast_node<ThisExpression>();
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case TokenType::Identifier: {
auto arrow_function_result = try_parse_arrow_function_expression(false);
if (!arrow_function_result.is_null()) {
return arrow_function_result.release_nonnull();
}
return create_ast_node<Identifier>(consume().value());
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}
case TokenType::NumericLiteral:
return create_ast_node<NumericLiteral>(consume().double_value());
case TokenType::BoolLiteral:
return create_ast_node<BooleanLiteral>(consume().bool_value());
case TokenType::StringLiteral:
return create_ast_node<StringLiteral>(consume().string_value());
case TokenType::NullLiteral:
consume();
return create_ast_node<NullLiteral>();
case TokenType::CurlyOpen:
return parse_object_expression();
case TokenType::Function:
return parse_function_node<FunctionExpression>();
case TokenType::BracketOpen:
return parse_array_expression();
case TokenType::New:
return parse_new_expression();
default:
m_parser_state.m_has_errors = true;
expected("primary expression (missing switch case)");
consume();
return create_ast_node<ErrorExpression>();
}
}
NonnullRefPtr<Expression> Parser::parse_unary_prefixed_expression()
{
auto precedence = operator_precedence(m_parser_state.m_current_token.type());
auto associativity = operator_associativity(m_parser_state.m_current_token.type());
switch (m_parser_state.m_current_token.type()) {
case TokenType::PlusPlus:
consume();
return create_ast_node<UpdateExpression>(UpdateOp::Increment, parse_expression(precedence, associativity), true);
case TokenType::MinusMinus:
consume();
return create_ast_node<UpdateExpression>(UpdateOp::Decrement, parse_expression(precedence, associativity), true);
case TokenType::ExclamationMark:
consume();
return create_ast_node<UnaryExpression>(UnaryOp::Not, parse_expression(precedence, associativity));
case TokenType::Tilde:
consume();
return create_ast_node<UnaryExpression>(UnaryOp::BitwiseNot, parse_expression(precedence, associativity));
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case TokenType::Plus:
consume();
return create_ast_node<UnaryExpression>(UnaryOp::Plus, parse_expression(precedence, associativity));
case TokenType::Minus:
consume();
return create_ast_node<UnaryExpression>(UnaryOp::Minus, parse_expression(precedence, associativity));
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case TokenType::Typeof:
consume();
return create_ast_node<UnaryExpression>(UnaryOp::Typeof, parse_expression(precedence, associativity));
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case TokenType::Void:
consume();
return create_ast_node<UnaryExpression>(UnaryOp::Void, parse_expression(precedence, associativity));
default:
m_parser_state.m_has_errors = true;
expected("primary expression (missing switch case)");
consume();
return create_ast_node<ErrorExpression>();
}
}
NonnullRefPtr<ObjectExpression> Parser::parse_object_expression()
{
HashMap<FlyString, NonnullRefPtr<Expression>> properties;
consume(TokenType::CurlyOpen);
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while (!done() && !match(TokenType::CurlyClose)) {
FlyString property_name;
if (match(TokenType::Identifier)) {
property_name = consume(TokenType::Identifier).value();
} else if (match(TokenType::StringLiteral)) {
property_name = consume(TokenType::StringLiteral).string_value();
} else if (match(TokenType::NumericLiteral)) {
property_name = consume(TokenType::NumericLiteral).value();
} else {
m_parser_state.m_has_errors = true;
auto& current_token = m_parser_state.m_current_token;
fprintf(stderr, "Error: Unexpected token %s as member in object initialization. Expected a numeric literal, string literal or identifier (line: %zu, column: %zu))\n",
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current_token.name(),
current_token.line_number(),
current_token.line_column());
consume();
continue;
}
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if (match(TokenType::Colon)) {
consume(TokenType::Colon);
properties.set(property_name, parse_expression(0));
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} else {
properties.set(property_name, create_ast_node<Identifier>(property_name));
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}
if (!match(TokenType::Comma))
break;
consume(TokenType::Comma);
}
consume(TokenType::CurlyClose);
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return create_ast_node<ObjectExpression>(properties);
}
NonnullRefPtr<ArrayExpression> Parser::parse_array_expression()
{
consume(TokenType::BracketOpen);
NonnullRefPtrVector<Expression> elements;
while (match_expression()) {
elements.append(parse_expression(0));
if (!match(TokenType::Comma))
break;
consume(TokenType::Comma);
}
consume(TokenType::BracketClose);
return create_ast_node<ArrayExpression>(move(elements));
}
NonnullRefPtr<Expression> Parser::parse_expression(int min_precedence, Associativity associativity)
{
auto expression = parse_primary_expression();
while (match_secondary_expression()) {
int new_precedence = operator_precedence(m_parser_state.m_current_token.type());
if (new_precedence < min_precedence)
break;
if (new_precedence == min_precedence && associativity == Associativity::Left)
break;
Associativity new_associativity = operator_associativity(m_parser_state.m_current_token.type());
expression = parse_secondary_expression(move(expression), new_precedence, new_associativity);
}
return expression;
}
NonnullRefPtr<Expression> Parser::parse_secondary_expression(NonnullRefPtr<Expression> lhs, int min_precedence, Associativity associativity)
{
switch (m_parser_state.m_current_token.type()) {
case TokenType::Plus:
consume();
return create_ast_node<BinaryExpression>(BinaryOp::Addition, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::PlusEquals:
consume();
return create_ast_node<AssignmentExpression>(AssignmentOp::AdditionAssignment, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::Minus:
consume();
return create_ast_node<BinaryExpression>(BinaryOp::Subtraction, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::MinusEquals:
consume();
return create_ast_node<AssignmentExpression>(AssignmentOp::SubtractionAssignment, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::Asterisk:
consume();
return create_ast_node<BinaryExpression>(BinaryOp::Multiplication, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::AsteriskEquals:
consume();
return create_ast_node<AssignmentExpression>(AssignmentOp::MultiplicationAssignment, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::Slash:
consume();
return create_ast_node<BinaryExpression>(BinaryOp::Division, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::SlashEquals:
consume();
return create_ast_node<AssignmentExpression>(AssignmentOp::DivisionAssignment, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::Percent:
consume();
return create_ast_node<BinaryExpression>(BinaryOp::Modulo, move(lhs), parse_expression(min_precedence, associativity));
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case TokenType::DoubleAsterisk:
consume();
return create_ast_node<BinaryExpression>(BinaryOp::Exponentiation, move(lhs), parse_expression(min_precedence, associativity));
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case TokenType::GreaterThan:
consume();
return create_ast_node<BinaryExpression>(BinaryOp::GreaterThan, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::GreaterThanEquals:
consume();
return create_ast_node<BinaryExpression>(BinaryOp::GreaterThanEquals, move(lhs), parse_expression(min_precedence, associativity));
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case TokenType::LessThan:
consume();
return create_ast_node<BinaryExpression>(BinaryOp::LessThan, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::LessThanEquals:
consume();
return create_ast_node<BinaryExpression>(BinaryOp::LessThanEquals, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::EqualsEqualsEquals:
consume();
return create_ast_node<BinaryExpression>(BinaryOp::TypedEquals, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::ExclamationMarkEqualsEquals:
consume();
return create_ast_node<BinaryExpression>(BinaryOp::TypedInequals, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::EqualsEquals:
consume();
return create_ast_node<BinaryExpression>(BinaryOp::AbstractEquals, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::ExclamationMarkEquals:
consume();
return create_ast_node<BinaryExpression>(BinaryOp::AbstractInequals, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::Instanceof:
consume();
return create_ast_node<BinaryExpression>(BinaryOp::InstanceOf, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::Ampersand:
consume();
return create_ast_node<BinaryExpression>(BinaryOp::BitwiseAnd, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::Pipe:
consume();
return create_ast_node<BinaryExpression>(BinaryOp::BitwiseOr, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::Caret:
consume();
return create_ast_node<BinaryExpression>(BinaryOp::BitwiseXor, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::ParenOpen:
return parse_call_expression(move(lhs));
case TokenType::Equals:
consume();
return create_ast_node<AssignmentExpression>(AssignmentOp::Assignment, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::Period:
consume();
return create_ast_node<MemberExpression>(move(lhs), parse_expression(min_precedence, associativity));
case TokenType::BracketOpen: {
consume(TokenType::BracketOpen);
auto expression = create_ast_node<MemberExpression>(move(lhs), parse_expression(0), true);
consume(TokenType::BracketClose);
return expression;
}
case TokenType::PlusPlus:
consume();
return create_ast_node<UpdateExpression>(UpdateOp::Increment, move(lhs));
case TokenType::MinusMinus:
consume();
return create_ast_node<UpdateExpression>(UpdateOp::Decrement, move(lhs));
case TokenType::DoubleAmpersand:
consume();
return create_ast_node<LogicalExpression>(LogicalOp::And, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::DoublePipe:
consume();
return create_ast_node<LogicalExpression>(LogicalOp::Or, move(lhs), parse_expression(min_precedence, associativity));
case TokenType::QuestionMark:
return parse_conditional_expression(move(lhs));
default:
m_parser_state.m_has_errors = true;
expected("secondary expression (missing switch case)");
consume();
return create_ast_node<ErrorExpression>();
}
}
NonnullRefPtr<CallExpression> Parser::parse_call_expression(NonnullRefPtr<Expression> lhs)
{
consume(TokenType::ParenOpen);
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NonnullRefPtrVector<Expression> arguments;
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while (match_expression()) {
arguments.append(parse_expression(0));
if (!match(TokenType::Comma))
break;
consume();
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}
consume(TokenType::ParenClose);
return create_ast_node<CallExpression>(move(lhs), move(arguments));
}
NonnullRefPtr<NewExpression> Parser::parse_new_expression()
{
consume(TokenType::New);
// FIXME: Support full expressions as the callee as well.
auto callee = create_ast_node<Identifier>(consume(TokenType::Identifier).value());
NonnullRefPtrVector<Expression> arguments;
if (match(TokenType::ParenOpen)) {
consume(TokenType::ParenOpen);
while (match_expression()) {
arguments.append(parse_expression(0));
if (!match(TokenType::Comma))
break;
consume();
}
consume(TokenType::ParenClose);
}
return create_ast_node<NewExpression>(move(callee), move(arguments));
}
NonnullRefPtr<ReturnStatement> Parser::parse_return_statement()
{
consume(TokenType::Return);
if (match_expression()) {
return create_ast_node<ReturnStatement>(parse_expression(0));
}
return create_ast_node<ReturnStatement>(nullptr);
}
NonnullRefPtr<BlockStatement> Parser::parse_block_statement()
{
ScopePusher scope(*this, ScopePusher::Let);
auto block = create_ast_node<BlockStatement>();
consume(TokenType::CurlyOpen);
while (!done() && !match(TokenType::CurlyClose)) {
if (match(TokenType::Semicolon)) {
consume();
} else if (match_statement()) {
block->append(parse_statement());
} else {
expected("statement");
consume();
}
}
consume(TokenType::CurlyClose);
block->add_variables(m_parser_state.m_let_scopes.last());
return block;
}
template<typename FunctionNodeType>
NonnullRefPtr<FunctionNodeType> Parser::parse_function_node()
{
ScopePusher scope(*this, ScopePusher::Var);
consume(TokenType::Function);
String name;
if (FunctionNodeType::must_have_name()) {
name = consume(TokenType::Identifier).value();
} else {
if (match(TokenType::Identifier))
name = consume(TokenType::Identifier).value();
}
consume(TokenType::ParenOpen);
Vector<FlyString> parameters;
while (match(TokenType::Identifier)) {
auto parameter = consume(TokenType::Identifier).value();
parameters.append(parameter);
if (match(TokenType::ParenClose)) {
break;
}
consume(TokenType::Comma);
}
consume(TokenType::ParenClose);
auto body = parse_block_statement();
body->add_variables(m_parser_state.m_var_scopes.last());
return create_ast_node<FunctionNodeType>(name, move(body), move(parameters), NonnullRefPtrVector<VariableDeclaration>());
}
NonnullRefPtr<VariableDeclaration> Parser::parse_variable_declaration()
{
DeclarationKind declaration_kind;
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switch (m_parser_state.m_current_token.type()) {
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case TokenType::Var:
declaration_kind = DeclarationKind::Var;
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consume(TokenType::Var);
break;
case TokenType::Let:
declaration_kind = DeclarationKind::Let;
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consume(TokenType::Let);
break;
case TokenType::Const:
declaration_kind = DeclarationKind::Const;
consume(TokenType::Const);
break;
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default:
ASSERT_NOT_REACHED();
}
NonnullRefPtrVector<VariableDeclarator> declarations;
for (;;) {
auto id = consume(TokenType::Identifier).value();
RefPtr<Expression> init;
if (match(TokenType::Equals)) {
consume();
init = parse_expression(0);
}
declarations.append(create_ast_node<VariableDeclarator>(create_ast_node<Identifier>(move(id)), move(init)));
if (match(TokenType::Comma)) {
consume();
continue;
}
break;
}
auto declaration = create_ast_node<VariableDeclaration>(declaration_kind, move(declarations));
if (declaration->declaration_kind() == DeclarationKind::Var)
m_parser_state.m_var_scopes.last().append(declaration);
else
m_parser_state.m_let_scopes.last().append(declaration);
return declaration;
}
NonnullRefPtr<ThrowStatement> Parser::parse_throw_statement()
{
consume(TokenType::Throw);
return create_ast_node<ThrowStatement>(parse_expression(0));
}
NonnullRefPtr<BreakStatement> Parser::parse_break_statement()
{
consume(TokenType::Break);
// FIXME: Handle labels.
return create_ast_node<BreakStatement>();
}
NonnullRefPtr<ContinueStatement> Parser::parse_continue_statement()
{
consume(TokenType::Continue);
// FIXME: Handle labels.
return create_ast_node<ContinueStatement>();
}
NonnullRefPtr<ConditionalExpression> Parser::parse_conditional_expression(NonnullRefPtr<Expression> test)
{
consume(TokenType::QuestionMark);
auto consequent = parse_expression(0);
consume(TokenType::Colon);
auto alternate = parse_expression(0);
return create_ast_node<ConditionalExpression>(move(test), move(consequent), move(alternate));
}
NonnullRefPtr<TryStatement> Parser::parse_try_statement()
{
consume(TokenType::Try);
auto block = parse_block_statement();
RefPtr<CatchClause> handler;
if (match(TokenType::Catch))
handler = parse_catch_clause();
RefPtr<BlockStatement> finalizer;
if (match(TokenType::Finally)) {
consume();
finalizer = parse_block_statement();
}
return create_ast_node<TryStatement>(move(block), move(handler), move(finalizer));
}
NonnullRefPtr<DoWhileStatement> Parser::parse_do_while_statement()
{
consume(TokenType::Do);
auto body = parse_statement();
consume(TokenType::While);
consume(TokenType::ParenOpen);
auto test = parse_expression(0);
consume(TokenType::ParenClose);
return create_ast_node<DoWhileStatement>(move(test), move(body));
}
NonnullRefPtr<SwitchStatement> Parser::parse_switch_statement()
{
consume(TokenType::Switch);
consume(TokenType::ParenOpen);
auto determinant = parse_expression(0);
consume(TokenType::ParenClose);
consume(TokenType::CurlyOpen);
NonnullRefPtrVector<SwitchCase> cases;
while (match(TokenType::Case) || match(TokenType::Default))
cases.append(parse_switch_case());
consume(TokenType::CurlyClose);
return create_ast_node<SwitchStatement>(move(determinant), move(cases));
}
NonnullRefPtr<SwitchCase> Parser::parse_switch_case()
{
RefPtr<Expression> test;
if (consume().type() == TokenType::Case) {
test = parse_expression(0);
}
consume(TokenType::Colon);
NonnullRefPtrVector<Statement> consequent;
while (match_statement())
consequent.append(parse_statement());
return create_ast_node<SwitchCase>(move(test), move(consequent));
}
NonnullRefPtr<CatchClause> Parser::parse_catch_clause()
{
consume(TokenType::Catch);
String parameter;
if (match(TokenType::ParenOpen)) {
consume();
parameter = consume(TokenType::Identifier).value();
consume(TokenType::ParenClose);
}
auto body = parse_block_statement();
return create_ast_node<CatchClause>(parameter, move(body));
}
NonnullRefPtr<IfStatement> Parser::parse_if_statement()
{
consume(TokenType::If);
consume(TokenType::ParenOpen);
auto predicate = parse_expression(0);
consume(TokenType::ParenClose);
auto consequent = parse_statement();
RefPtr<Statement> alternate;
if (match(TokenType::Else)) {
consume(TokenType::Else);
alternate = parse_statement();
}
return create_ast_node<IfStatement>(move(predicate), move(consequent), move(alternate));
}
NonnullRefPtr<ForStatement> Parser::parse_for_statement()
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{
consume(TokenType::For);
consume(TokenType::ParenOpen);
RefPtr<ASTNode> init;
switch (m_parser_state.m_current_token.type()) {
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case TokenType::Semicolon:
break;
default:
if (match_expression())
init = parse_expression(0);
else if (match_variable_declaration())
init = parse_variable_declaration();
else
ASSERT_NOT_REACHED();
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break;
}
consume(TokenType::Semicolon);
RefPtr<Expression> test;
switch (m_parser_state.m_current_token.type()) {
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case TokenType::Semicolon:
break;
default:
test = parse_expression(0);
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break;
}
consume(TokenType::Semicolon);
RefPtr<Expression> update;
switch (m_parser_state.m_current_token.type()) {
case TokenType::ParenClose:
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break;
default:
update = parse_expression(0);
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break;
}
consume(TokenType::ParenClose);
auto body = parse_statement();
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return create_ast_node<ForStatement>(move(init), move(test), move(update), move(body));
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}
bool Parser::match(TokenType type) const
{
return m_parser_state.m_current_token.type() == type;
}
bool Parser::match_variable_declaration() const
{
switch (m_parser_state.m_current_token.type()) {
case TokenType::Var:
case TokenType::Let:
case TokenType::Const:
return true;
default:
return false;
}
}
bool Parser::match_expression() const
{
auto type = m_parser_state.m_current_token.type();
return type == TokenType::BoolLiteral
|| type == TokenType::NumericLiteral
|| type == TokenType::StringLiteral
|| type == TokenType::NullLiteral
|| type == TokenType::Identifier
|| type == TokenType::New
|| type == TokenType::CurlyOpen
|| type == TokenType::BracketOpen
|| type == TokenType::ParenOpen
|| type == TokenType::Function
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|| type == TokenType::This
|| match_unary_prefixed_expression();
}
bool Parser::match_unary_prefixed_expression() const
{
auto type = m_parser_state.m_current_token.type();
return type == TokenType::PlusPlus
|| type == TokenType::MinusMinus
|| type == TokenType::ExclamationMark
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|| type == TokenType::Tilde
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|| type == TokenType::Plus
|| type == TokenType::Minus
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|| type == TokenType::Typeof
|| type == TokenType::Void;
}
bool Parser::match_secondary_expression() const
{
auto type = m_parser_state.m_current_token.type();
return type == TokenType::Plus
|| type == TokenType::PlusEquals
|| type == TokenType::Minus
|| type == TokenType::MinusEquals
|| type == TokenType::Asterisk
|| type == TokenType::AsteriskEquals
|| type == TokenType::Slash
|| type == TokenType::SlashEquals
|| type == TokenType::Percent
|| type == TokenType::DoubleAsterisk
|| type == TokenType::Equals
|| type == TokenType::EqualsEqualsEquals
|| type == TokenType::ExclamationMarkEqualsEquals
|| type == TokenType::EqualsEquals
|| type == TokenType::ExclamationMarkEquals
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|| type == TokenType::GreaterThan
|| type == TokenType::GreaterThanEquals
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|| type == TokenType::LessThan
|| type == TokenType::LessThanEquals
|| type == TokenType::ParenOpen
|| type == TokenType::Period
|| type == TokenType::BracketOpen
|| type == TokenType::PlusPlus
|| type == TokenType::MinusMinus
|| type == TokenType::Instanceof
|| type == TokenType::QuestionMark
|| type == TokenType::Ampersand
|| type == TokenType::Pipe
|| type == TokenType::Caret
|| type == TokenType::DoubleAmpersand
|| type == TokenType::DoublePipe;
}
bool Parser::match_statement() const
{
auto type = m_parser_state.m_current_token.type();
return match_expression()
|| type == TokenType::Function
|| type == TokenType::Return
|| type == TokenType::Let
|| type == TokenType::Class
|| type == TokenType::Delete
|| type == TokenType::Do
|| type == TokenType::If
|| type == TokenType::Throw
|| type == TokenType::Try
|| type == TokenType::While
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|| type == TokenType::For
|| type == TokenType::Const
|| type == TokenType::CurlyOpen
|| type == TokenType::Switch
|| type == TokenType::Break
|| type == TokenType::Continue
|| type == TokenType::Var;
}
bool Parser::done() const
{
return match(TokenType::Eof);
}
Token Parser::consume()
{
auto old_token = m_parser_state.m_current_token;
m_parser_state.m_current_token = m_parser_state.m_lexer.next();
return old_token;
}
Token Parser::consume(TokenType type)
{
if (m_parser_state.m_current_token.type() != type) {
m_parser_state.m_has_errors = true;
auto& current_token = m_parser_state.m_current_token;
fprintf(stderr, "Error: Unexpected token %s. Expected %s (line: %zu, column: %zu))\n",
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current_token.name(),
Token::name(type),
current_token.line_number(),
current_token.line_column());
}
return consume();
}
void Parser::expected(const char* what)
{
m_parser_state.m_has_errors = true;
auto& current_token = m_parser_state.m_current_token;
fprintf(stderr, "Error: Unexpected token %s. Expected %s (line: %zu, column: %zu)\n",
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current_token.name(),
what,
current_token.line_number(),
current_token.line_column());
}
void Parser::save_state()
{
m_saved_state = m_parser_state;
}
void Parser::load_state()
{
ASSERT(m_saved_state.has_value());
m_parser_state = m_saved_state.value();
m_saved_state.clear();
}
}