ladybird/Libraries/LibJS/AST.h

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/*
* Copyright (c) 2020, Andreas Kling <kling@serenityos.org>
* Copyright (c) 2020, Linus Groh <mail@linusgroh.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.
*/
#pragma once
#include <AK/FlyString.h>
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#include <AK/HashMap.h>
#include <AK/NonnullRefPtrVector.h>
#include <AK/RefPtr.h>
#include <AK/String.h>
#include <AK/Vector.h>
#include <LibJS/Forward.h>
#include <LibJS/Runtime/PropertyName.h>
#include <LibJS/Runtime/Value.h>
namespace JS {
class VariableDeclaration;
template<class T, class... Args>
static inline NonnullRefPtr<T>
create_ast_node(Args&&... args)
{
return adopt(*new T(forward<Args>(args)...));
}
class ASTNode : public RefCounted<ASTNode> {
public:
virtual ~ASTNode() { }
virtual const char* class_name() const = 0;
virtual Value execute(Interpreter&) const = 0;
virtual void dump(int indent) const;
virtual bool is_identifier() const { return false; }
virtual bool is_spread_expression() const { return false; }
virtual bool is_member_expression() const { return false; }
virtual bool is_scope_node() const { return false; }
virtual bool is_program() const { return false; }
virtual bool is_variable_declaration() const { return false; }
virtual bool is_new_expression() const { return false; }
protected:
ASTNode() { }
private:
};
class Statement : public ASTNode {
};
class EmptyStatement final : public Statement {
public:
Value execute(Interpreter&) const override { return js_undefined(); }
const char* class_name() const override { return "EmptyStatement"; }
};
class ErrorStatement final : public Statement {
public:
Value execute(Interpreter&) const override { return js_undefined(); }
const char* class_name() const override { return "ErrorStatement"; }
};
class ExpressionStatement final : public Statement {
public:
ExpressionStatement(NonnullRefPtr<Expression> expression)
: m_expression(move(expression))
{
}
Value execute(Interpreter&) const override;
const char* class_name() const override { return "ExpressionStatement"; }
virtual void dump(int indent) const override;
private:
NonnullRefPtr<Expression> m_expression;
};
class ScopeNode : public Statement {
public:
template<typename T, typename... Args>
T& append(Args&&... args)
{
auto child = create_ast_node<T>(forward<Args>(args)...);
m_children.append(move(child));
return static_cast<T&>(m_children.last());
}
void append(NonnullRefPtr<Statement> child)
{
m_children.append(move(child));
}
const NonnullRefPtrVector<Statement>& children() const { return m_children; }
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
void add_variables(NonnullRefPtrVector<VariableDeclaration>);
const NonnullRefPtrVector<VariableDeclaration>& variables() const { return m_variables; }
protected:
ScopeNode() { }
private:
virtual bool is_scope_node() const final { return true; }
NonnullRefPtrVector<Statement> m_children;
NonnullRefPtrVector<VariableDeclaration> m_variables;
};
class Program : public ScopeNode {
public:
Program() { }
private:
virtual bool is_program() const override { return true; }
virtual const char* class_name() const override { return "Program"; }
};
class BlockStatement : public ScopeNode {
public:
BlockStatement() { }
private:
virtual const char* class_name() const override { return "BlockStatement"; }
};
class Expression : public ASTNode {
public:
virtual Reference to_reference(Interpreter&) const;
};
class Declaration : public Statement {
};
class FunctionNode {
public:
struct Parameter {
FlyString name;
RefPtr<Expression> default_value;
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bool is_rest { false };
};
const FlyString& name() const { return m_name; }
const Statement& body() const { return *m_body; }
const Vector<Parameter>& parameters() const { return m_parameters; };
protected:
FunctionNode(const FlyString& name, NonnullRefPtr<Statement> body, Vector<Parameter> parameters, NonnullRefPtrVector<VariableDeclaration> variables)
: m_name(name)
, m_body(move(body))
, m_parameters(move(parameters))
, m_variables(move(variables))
{
}
void dump(int indent, const char* class_name) const;
const NonnullRefPtrVector<VariableDeclaration>& variables() const { return m_variables; }
private:
FlyString m_name;
NonnullRefPtr<Statement> m_body;
const Vector<Parameter> m_parameters;
NonnullRefPtrVector<VariableDeclaration> m_variables;
};
class FunctionDeclaration final
: public Declaration
, public FunctionNode {
public:
static bool must_have_name() { return true; }
FunctionDeclaration(const FlyString& name, NonnullRefPtr<Statement> body, Vector<Parameter> parameters, NonnullRefPtrVector<VariableDeclaration> variables)
: FunctionNode(name, move(body), move(parameters), move(variables))
{
}
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
private:
virtual const char* class_name() const override { return "FunctionDeclaration"; }
};
class FunctionExpression final : public Expression
, public FunctionNode {
public:
static bool must_have_name() { return false; }
FunctionExpression(const FlyString& name, NonnullRefPtr<Statement> body, Vector<Parameter> parameters, NonnullRefPtrVector<VariableDeclaration> variables)
: FunctionNode(name, move(body), move(parameters), move(variables))
{
}
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
private:
virtual const char* class_name() const override { return "FunctionExpression"; }
};
class ErrorExpression final : public Expression {
public:
Value execute(Interpreter&) const override { return js_undefined(); }
const char* class_name() const override { return "ErrorExpression"; }
};
class ReturnStatement : public Statement {
public:
explicit ReturnStatement(RefPtr<Expression> argument)
: m_argument(move(argument))
{
}
const Expression* argument() const { return m_argument; }
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
private:
virtual const char* class_name() const override { return "ReturnStatement"; }
RefPtr<Expression> m_argument;
};
class IfStatement : public Statement {
public:
IfStatement(NonnullRefPtr<Expression> predicate, NonnullRefPtr<Statement> consequent, RefPtr<Statement> alternate)
: m_predicate(move(predicate))
, m_consequent(move(consequent))
, m_alternate(move(alternate))
{
}
const Expression& predicate() const { return *m_predicate; }
const Statement& consequent() const { return *m_consequent; }
const Statement* alternate() const { return m_alternate; }
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
private:
virtual const char* class_name() const override { return "IfStatement"; }
NonnullRefPtr<Expression> m_predicate;
NonnullRefPtr<Statement> m_consequent;
RefPtr<Statement> m_alternate;
};
class WhileStatement : public Statement {
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public:
WhileStatement(NonnullRefPtr<Expression> test, NonnullRefPtr<Statement> body)
: m_test(move(test))
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, m_body(move(body))
{
}
const Expression& test() const { return *m_test; }
const Statement& body() const { return *m_body; }
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virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
private:
virtual const char* class_name() const override { return "WhileStatement"; }
NonnullRefPtr<Expression> m_test;
NonnullRefPtr<Statement> m_body;
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};
class DoWhileStatement : public Statement {
public:
DoWhileStatement(NonnullRefPtr<Expression> test, NonnullRefPtr<Statement> body)
: m_test(move(test))
, m_body(move(body))
{
}
const Expression& test() const { return *m_test; }
const Statement& body() const { return *m_body; }
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
private:
virtual const char* class_name() const override { return "DoWhileStatement"; }
NonnullRefPtr<Expression> m_test;
NonnullRefPtr<Statement> m_body;
};
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class ForStatement : public Statement {
public:
ForStatement(RefPtr<ASTNode> init, RefPtr<Expression> test, RefPtr<Expression> update, NonnullRefPtr<Statement> body)
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: m_init(move(init))
, m_test(move(test))
, m_update(move(update))
, m_body(move(body))
{
}
const ASTNode* init() const { return m_init; }
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const Expression* test() const { return m_test; }
const Expression* update() const { return m_update; }
const Statement& body() const { return *m_body; }
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virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
private:
virtual const char* class_name() const override { return "ForStatement"; }
RefPtr<ASTNode> m_init;
RefPtr<Expression> m_test;
RefPtr<Expression> m_update;
NonnullRefPtr<Statement> m_body;
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};
enum class BinaryOp {
Addition,
Subtraction,
Multiplication,
Division,
Modulo,
Exponentiation,
TypedEquals,
TypedInequals,
AbstractEquals,
AbstractInequals,
GreaterThan,
GreaterThanEquals,
LessThan,
LessThanEquals,
BitwiseAnd,
BitwiseOr,
BitwiseXor,
LeftShift,
RightShift,
UnsignedRightShift,
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In,
InstanceOf,
};
class BinaryExpression : public Expression {
public:
BinaryExpression(BinaryOp op, NonnullRefPtr<Expression> lhs, NonnullRefPtr<Expression> rhs)
: m_op(op)
, m_lhs(move(lhs))
, m_rhs(move(rhs))
{
}
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
private:
virtual const char* class_name() const override { return "BinaryExpression"; }
BinaryOp m_op;
NonnullRefPtr<Expression> m_lhs;
NonnullRefPtr<Expression> m_rhs;
};
enum class LogicalOp {
And,
Or,
NullishCoalescing,
};
class LogicalExpression : public Expression {
public:
LogicalExpression(LogicalOp op, NonnullRefPtr<Expression> lhs, NonnullRefPtr<Expression> rhs)
: m_op(op)
, m_lhs(move(lhs))
, m_rhs(move(rhs))
{
}
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
private:
virtual const char* class_name() const override { return "LogicalExpression"; }
LogicalOp m_op;
NonnullRefPtr<Expression> m_lhs;
NonnullRefPtr<Expression> m_rhs;
};
enum class UnaryOp {
BitwiseNot,
Not,
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Plus,
Minus,
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Typeof,
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Void,
Delete,
};
class UnaryExpression : public Expression {
public:
UnaryExpression(UnaryOp op, NonnullRefPtr<Expression> lhs)
: m_op(op)
, m_lhs(move(lhs))
{
}
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
private:
virtual const char* class_name() const override { return "UnaryExpression"; }
UnaryOp m_op;
NonnullRefPtr<Expression> m_lhs;
};
class SequenceExpression final : public Expression {
public:
SequenceExpression(NonnullRefPtrVector<Expression> expressions)
: m_expressions(move(expressions))
{
}
virtual void dump(int indent) const override;
virtual Value execute(Interpreter&) const override;
private:
virtual const char* class_name() const override { return "SequenceExpression"; }
NonnullRefPtrVector<Expression> m_expressions;
};
class Literal : public Expression {
protected:
explicit Literal() { }
};
class BooleanLiteral final : public Literal {
public:
explicit BooleanLiteral(bool value)
: m_value(value)
{
}
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
private:
virtual const char* class_name() const override { return "BooleanLiteral"; }
bool m_value { false };
};
class NumericLiteral final : public Literal {
public:
explicit NumericLiteral(double value)
: m_value(value)
{
}
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
private:
virtual const char* class_name() const override { return "NumericLiteral"; }
double m_value { 0 };
};
class StringLiteral final : public Literal {
public:
explicit StringLiteral(String value)
: m_value(move(value))
{
}
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
private:
virtual const char* class_name() const override { return "StringLiteral"; }
String m_value;
};
class NullLiteral final : public Literal {
public:
explicit NullLiteral() { }
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
private:
virtual const char* class_name() const override { return "NullLiteral"; }
};
class Identifier final : public Expression {
public:
explicit Identifier(const FlyString& string)
: m_string(string)
{
}
const FlyString& string() const { return m_string; }
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
virtual bool is_identifier() const override { return true; }
virtual Reference to_reference(Interpreter&) const override;
private:
virtual const char* class_name() const override { return "Identifier"; }
FlyString m_string;
};
class SpreadExpression final : public Expression {
public:
explicit SpreadExpression(NonnullRefPtr<Expression> target)
: m_target(target)
{
}
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
virtual bool is_spread_expression() const override { return true; }
private:
virtual const char* class_name() const override { return "SpreadExpression"; }
NonnullRefPtr<Expression> m_target;
};
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class ThisExpression final : public Expression {
public:
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
private:
virtual const char* class_name() const override { return "ThisExpression"; }
};
class CallExpression : public Expression {
public:
CallExpression(NonnullRefPtr<Expression> callee, NonnullRefPtrVector<Expression> arguments = {})
: m_callee(move(callee))
, m_arguments(move(arguments))
{
}
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
private:
virtual const char* class_name() const override { return "CallExpression"; }
struct ThisAndCallee {
Value this_value;
Value callee;
};
ThisAndCallee compute_this_and_callee(Interpreter&) const;
NonnullRefPtr<Expression> m_callee;
const NonnullRefPtrVector<Expression> m_arguments;
};
class NewExpression final : public CallExpression {
public:
NewExpression(NonnullRefPtr<Expression> callee, NonnullRefPtrVector<Expression> arguments = {})
: CallExpression(move(callee), move(arguments))
{
}
private:
virtual const char* class_name() const override { return "NewExpression"; }
virtual bool is_new_expression() const override { return true; }
};
enum class AssignmentOp {
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Assignment,
AdditionAssignment,
SubtractionAssignment,
MultiplicationAssignment,
DivisionAssignment,
BitwiseAndAssignment,
BitwiseOrAssignment,
BitwiseXorAssignment,
LeftShiftAssignment,
RightShiftAssignment,
UnsignedRightShiftAssignment,
};
class AssignmentExpression : public Expression {
public:
AssignmentExpression(AssignmentOp op, NonnullRefPtr<Expression> lhs, NonnullRefPtr<Expression> rhs)
: m_op(op)
, m_lhs(move(lhs))
, m_rhs(move(rhs))
{
}
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
private:
virtual const char* class_name() const override { return "AssignmentExpression"; }
AssignmentOp m_op;
NonnullRefPtr<Expression> m_lhs;
NonnullRefPtr<Expression> m_rhs;
};
enum class UpdateOp {
Increment,
Decrement,
};
class UpdateExpression : public Expression {
public:
UpdateExpression(UpdateOp op, NonnullRefPtr<Expression> argument, bool prefixed = false)
: m_op(op)
, m_argument(move(argument))
, m_prefixed(prefixed)
{
}
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
private:
virtual const char* class_name() const override { return "UpdateExpression"; }
UpdateOp m_op;
NonnullRefPtr<Expression> m_argument;
bool m_prefixed;
};
enum class DeclarationKind {
Var,
Let,
Const,
};
class VariableDeclarator final : public ASTNode {
public:
VariableDeclarator(NonnullRefPtr<Identifier> id, RefPtr<Expression> init)
: m_id(move(id))
, m_init(move(init))
{
}
const Identifier& id() const { return m_id; }
const Expression* init() const { return m_init; }
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
private:
virtual const char* class_name() const override { return "VariableDeclarator"; }
NonnullRefPtr<Identifier> m_id;
RefPtr<Expression> m_init;
};
class VariableDeclaration : public Declaration {
public:
VariableDeclaration(DeclarationKind declaration_kind, NonnullRefPtrVector<VariableDeclarator> declarations)
: m_declaration_kind(declaration_kind)
, m_declarations(move(declarations))
{
}
virtual bool is_variable_declaration() const override { return true; }
DeclarationKind declaration_kind() const { return m_declaration_kind; }
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
const NonnullRefPtrVector<VariableDeclarator>& declarations() const { return m_declarations; }
private:
virtual const char* class_name() const override { return "VariableDeclaration"; }
DeclarationKind m_declaration_kind;
NonnullRefPtrVector<VariableDeclarator> m_declarations;
};
class ObjectProperty final : public ASTNode {
public:
ObjectProperty(NonnullRefPtr<Expression> key, NonnullRefPtr<Expression> value)
: m_key(move(key))
, m_value(move(value))
{
}
const Expression& key() const { return m_key; }
const Expression& value() const { return m_value; }
bool is_spread() const { return m_is_spread; }
void set_is_spread() { m_is_spread = true; }
virtual void dump(int indent) const override;
virtual Value execute(Interpreter&) const override;
private:
virtual const char* class_name() const override { return "ObjectProperty"; }
NonnullRefPtr<Expression> m_key;
NonnullRefPtr<Expression> m_value;
bool m_is_spread { false };
};
class ObjectExpression : public Expression {
public:
ObjectExpression(NonnullRefPtrVector<ObjectProperty> properties = {})
: m_properties(move(properties))
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{
}
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
private:
virtual const char* class_name() const override { return "ObjectExpression"; }
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NonnullRefPtrVector<ObjectProperty> m_properties;
};
class ArrayExpression : public Expression {
public:
ArrayExpression(Vector<RefPtr<Expression>> elements)
: m_elements(move(elements))
{
}
const Vector<RefPtr<Expression>>& elements() const { return m_elements; }
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
private:
virtual const char* class_name() const override { return "ArrayExpression"; }
Vector<RefPtr<Expression>> m_elements;
};
LibJS: Add template literals Adds fully functioning template literals. Because template literals contain expressions, most of the work has to be done in the Lexer rather than the Parser. And because of the complexity of template literals (expressions, nesting, escapes, etc), the Lexer needs to have some template-related state. When entering a new template literal, a TemplateLiteralStart token is emitted. When inside a literal, all text will be parsed up until a '${' or '`' (or EOF, but that's a syntax error) is seen, and then a TemplateLiteralExprStart token is emitted. At this point, the Lexer proceeds as normal, however it keeps track of the number of opening and closing curly braces it has seen in order to determine the close of the expression. Once it finds a matching curly brace for the '${', a TemplateLiteralExprEnd token is emitted and the state is updated accordingly. When the Lexer is inside of a template literal, but not an expression, and sees a '`', this must be the closing grave: a TemplateLiteralEnd token is emitted. The state required to correctly parse template strings consists of a vector (for nesting) of two pieces of information: whether or not we are in a template expression (as opposed to a template string); and the count of the number of unmatched open curly braces we have seen (only applicable if the Lexer is currently in a template expression). TODO: Add support for template literal newlines in the JS REPL (this will cause a syntax error currently): > `foo > bar` 'foo bar'
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class TemplateLiteral final : public Expression {
public:
TemplateLiteral(NonnullRefPtrVector<Expression> expressions)
: m_expressions(expressions)
{
}
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
const NonnullRefPtrVector<Expression>& expressions() const { return m_expressions; }
private:
virtual const char* class_name() const override { return "TemplateLiteral"; }
const NonnullRefPtrVector<Expression> m_expressions;
};
class MemberExpression final : public Expression {
public:
MemberExpression(NonnullRefPtr<Expression> object, NonnullRefPtr<Expression> property, bool computed = false)
: m_object(move(object))
, m_property(move(property))
, m_computed(computed)
{
}
virtual Value execute(Interpreter&) const override;
virtual void dump(int indent) const override;
virtual Reference to_reference(Interpreter&) const override;
bool is_computed() const { return m_computed; }
const Expression& object() const { return *m_object; }
const Expression& property() const { return *m_property; }
PropertyName computed_property_name(Interpreter&) const;
String to_string_approximation() const;
private:
virtual bool is_member_expression() const override { return true; }
virtual const char* class_name() const override { return "MemberExpression"; }
NonnullRefPtr<Expression> m_object;
NonnullRefPtr<Expression> m_property;
bool m_computed { false };
};
class ConditionalExpression final : public Expression {
public:
ConditionalExpression(NonnullRefPtr<Expression> test, NonnullRefPtr<Expression> consequent, NonnullRefPtr<Expression> alternate)
: m_test(move(test))
, m_consequent(move(consequent))
, m_alternate(move(alternate))
{
}
virtual void dump(int indent) const override;
virtual Value execute(Interpreter&) const override;
private:
virtual const char* class_name() const override { return "ConditionalExpression"; }
NonnullRefPtr<Expression> m_test;
NonnullRefPtr<Expression> m_consequent;
NonnullRefPtr<Expression> m_alternate;
};
class CatchClause final : public ASTNode {
public:
CatchClause(const FlyString& parameter, NonnullRefPtr<BlockStatement> body)
: m_parameter(parameter)
, m_body(move(body))
{
}
const FlyString& parameter() const { return m_parameter; }
const BlockStatement& body() const { return m_body; }
virtual void dump(int indent) const override;
virtual Value execute(Interpreter&) const override;
private:
virtual const char* class_name() const override { return "CatchClause"; }
FlyString m_parameter;
NonnullRefPtr<BlockStatement> m_body;
};
class TryStatement final : public Statement {
public:
TryStatement(NonnullRefPtr<BlockStatement> block, RefPtr<CatchClause> handler, RefPtr<BlockStatement> finalizer)
: m_block(move(block))
, m_handler(move(handler))
, m_finalizer(move(finalizer))
{
}
const BlockStatement& block() const { return m_block; }
const CatchClause* handler() const { return m_handler; }
const BlockStatement* finalizer() const { return m_finalizer; }
virtual void dump(int indent) const override;
virtual Value execute(Interpreter&) const override;
private:
virtual const char* class_name() const override { return "TryStatement"; }
NonnullRefPtr<BlockStatement> m_block;
RefPtr<CatchClause> m_handler;
RefPtr<BlockStatement> m_finalizer;
};
class ThrowStatement final : public Statement {
public:
explicit ThrowStatement(NonnullRefPtr<Expression> argument)
: m_argument(move(argument))
{
}
const Expression& argument() const { return m_argument; }
virtual void dump(int indent) const override;
virtual Value execute(Interpreter&) const override;
private:
virtual const char* class_name() const override { return "ThrowStatement"; }
NonnullRefPtr<Expression> m_argument;
};
class SwitchCase final : public ASTNode {
public:
SwitchCase(RefPtr<Expression> test, NonnullRefPtrVector<Statement> consequent)
: m_test(move(test))
, m_consequent(move(consequent))
{
}
const Expression* test() const { return m_test; }
const NonnullRefPtrVector<Statement>& consequent() const { return m_consequent; }
virtual void dump(int indent) const override;
virtual Value execute(Interpreter&) const override;
private:
virtual const char* class_name() const override { return "SwitchCase"; }
RefPtr<Expression> m_test;
NonnullRefPtrVector<Statement> m_consequent;
};
class SwitchStatement final : public Statement {
public:
SwitchStatement(NonnullRefPtr<Expression> discriminant, NonnullRefPtrVector<SwitchCase> cases)
: m_discriminant(move(discriminant))
, m_cases(move(cases))
{
}
virtual void dump(int indent) const override;
virtual Value execute(Interpreter&) const override;
private:
virtual const char* class_name() const override { return "SwitchStatement"; }
NonnullRefPtr<Expression> m_discriminant;
NonnullRefPtrVector<SwitchCase> m_cases;
};
class BreakStatement final : public Statement {
public:
BreakStatement() { }
virtual Value execute(Interpreter&) const override;
private:
virtual const char* class_name() const override { return "BreakStatement"; }
};
class ContinueStatement final : public Statement {
public:
ContinueStatement() { }
virtual Value execute(Interpreter&) const override;
private:
virtual const char* class_name() const override { return "ContinueStatement"; }
};
class DebuggerStatement final : public Statement {
public:
DebuggerStatement() { }
virtual Value execute(Interpreter&) const override;
private:
virtual const char* class_name() const override { return "DebuggerStatement"; }
};
}