ladybird/Libraries/LibJS/AST.h

/*
 * Copyright (c) 2020, Andreas Kling <kling@serenityos.org>
 * 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/NonnullOwnPtrVector.h>
#include <AK/OwnPtr.h>
#include <AK/String.h>
#include <LibJS/Forward.h>
#include <LibJS/Value.h>

namespace JS {

class 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; }

protected:
    ASTNode() {}

private:
};

class ScopeNode : public ASTNode {
public:
    template<typename T, typename... Args>
    T& append(Args&&... args)
    {
        auto child = make<T>(forward<Args>(args)...);
        m_children.append(move(child));
        return static_cast<T&>(m_children.last());
    }

    const NonnullOwnPtrVector<ASTNode>& children() const { return m_children; }
    virtual Value execute(Interpreter&) const override;
    virtual void dump(int indent) const override;

protected:
    ScopeNode() {}

private:
    NonnullOwnPtrVector<ASTNode> m_children;
};

class Program : public ScopeNode {
public:
    Program() {}

private:
    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 FunctionDeclaration : public ASTNode {
public:
    FunctionDeclaration(String name, NonnullOwnPtr<ScopeNode> body)
        : m_name(move(name))
        , m_body(move(body))
    {
    }

    String name() const { return m_name; }
    const ScopeNode& 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 "FunctionDeclaration"; }

    String m_name;
    NonnullOwnPtr<ScopeNode> m_body;
};

class Expression : public ASTNode {
public:
};

class ReturnStatement : public ASTNode {
public:
    explicit ReturnStatement(NonnullOwnPtr<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"; }

    NonnullOwnPtr<Expression> m_argument;
};

class IfStatement : public ASTNode {
public:
    IfStatement(NonnullOwnPtr<Expression> predicate, NonnullOwnPtr<ScopeNode> consequent, NonnullOwnPtr<ScopeNode> alternate)
        : m_predicate(move(predicate))
        , m_consequent(move(consequent))
        , m_alternate(move(alternate))
    {
    }

    const Expression& predicate() const { return *m_predicate; }
    const ScopeNode& consequent() const { return *m_consequent; }
    const ScopeNode& 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"; }

    NonnullOwnPtr<Expression> m_predicate;
    NonnullOwnPtr<ScopeNode> m_consequent;
    NonnullOwnPtr<ScopeNode> m_alternate;
};

class WhileStatement : public ASTNode {
public:
    WhileStatement(NonnullOwnPtr<Expression> predicate, NonnullOwnPtr<ScopeNode> body)
        : m_predicate(move(predicate))
        , m_body(move(body))
    {
    }

    const Expression& predicate() const { return *m_predicate; }
    const ScopeNode& 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 "WhileStatement"; }

    NonnullOwnPtr<Expression> m_predicate;
    NonnullOwnPtr<ScopeNode> m_body;
};

enum class BinaryOp {
    Plus,
    Minus,
    TypedEquals,
    TypedInequals,
    GreaterThan,
    LessThan,
    BitwiseAnd,
    BitwiseOr,
    BitwiseXor,
    LeftShift,
    RightShift,
};

class BinaryExpression : public Expression {
public:
    BinaryExpression(BinaryOp op, NonnullOwnPtr<Expression> lhs, NonnullOwnPtr<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;
    NonnullOwnPtr<Expression> m_lhs;
    NonnullOwnPtr<Expression> m_rhs;
};

enum class LogicalOp {
    And,
    Or,
};

class LogicalExpression : public Expression {
public:
    LogicalExpression(LogicalOp op, NonnullOwnPtr<Expression> lhs, NonnullOwnPtr<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;
    NonnullOwnPtr<Expression> m_lhs;
    NonnullOwnPtr<Expression> m_rhs;
};

enum class UnaryOp {
    BitNot,
    Not,
};

class UnaryExpression : public Expression {
public:
    UnaryExpression(UnaryOp op, NonnullOwnPtr<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;
    NonnullOwnPtr<Expression> m_lhs;
};

class Literal : public Expression {
public:
    explicit Literal(Value value)
        : m_value(move(value))
    {
    }

    virtual Value execute(Interpreter&) const override { return m_value; }
    virtual void dump(int indent) const override;

private:
    virtual const char* class_name() const override { return "Literal"; }

    Value m_value;
};

class Identifier final : public Expression {
public:
    explicit Identifier(String string)
        : m_string(move(string))
    {
    }

    const String& 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; }

private:
    virtual const char* class_name() const override { return "Identifier"; }

    String m_string;
};

class CallExpression : public Expression {
public:
    explicit CallExpression(String name)
        : m_name(move(name))
    {
    }

    virtual Value execute(Interpreter&) const override;
    virtual void dump(int indent) const override;

    const String& name() const { return m_name; }

private:
    virtual const char* class_name() const override { return "CallExpression"; }

    String m_name;
};

enum class AssignmentOp {
    Assign,
};

class AssignmentExpression : public Expression {
public:
    AssignmentExpression(AssignmentOp op, NonnullOwnPtr<ASTNode> lhs, NonnullOwnPtr<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;
    NonnullOwnPtr<ASTNode> m_lhs;
    NonnullOwnPtr<Expression> m_rhs;
};

class VariableDeclaration : public ASTNode {
public:
    VariableDeclaration(NonnullOwnPtr<Identifier> name, OwnPtr<Expression> initializer)
        : m_name(move(name))
        , m_initializer(move(initializer))
    {
    }

    const Identifier& name() const { return *m_name; }

    virtual Value execute(Interpreter&) const override;
    virtual void dump(int indent) const override;

private:
    virtual const char* class_name() const override { return "VariableDeclaration"; }

    NonnullOwnPtr<Identifier> m_name;
    OwnPtr<Expression> m_initializer;
};

class ObjectExpression : public Expression {
public:
    ObjectExpression() {}

    virtual Value execute(Interpreter&) const override;
    virtual void dump(int indent) const override;

private:
    virtual const char* class_name() const override { return "ObjectExpression"; }
};

}
LibJS: Start building a JavaScript engine for SerenityOS :^) I always tell people to start building things by working on the thing that seems the most interesting right now. The most interesting thing here was an AST + simple interpreter, so that's where we start! There is no lexer or parser yet, we build an AST directly and then execute it in the interpreter, producing a return value. This seems like the start of something interesting. :^) 2020-03-07 19:42:11 +01:00			`/*`
			`* Copyright (c) 2020, Andreas Kling <kling@serenityos.org>`
			`* 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/NonnullOwnPtrVector.h>`
LibJS: Implement logical expressions Logical expressions are expressions which can return either true or false according to a provided condition. 2020-03-08 07:55:44 +02:00			`#include <AK/OwnPtr.h>`
LibJS: Start building a JavaScript engine for SerenityOS :^) I always tell people to start building things by working on the thing that seems the most interesting right now. The most interesting thing here was an AST + simple interpreter, so that's where we start! There is no lexer or parser yet, we build an AST directly and then execute it in the interpreter, producing a return value. This seems like the start of something interesting. :^) 2020-03-07 19:42:11 +01:00			`#include <AK/String.h>`
			`#include <LibJS/Forward.h>`
			`#include <LibJS/Value.h>`

			`namespace JS {`

			`class ASTNode {`
			`public:`
			`virtual ~ASTNode() {}`
			`virtual const char* class_name() const = 0;`
			`virtual Value execute(Interpreter&) const = 0;`
			`virtual void dump(int indent) const;`
LibJS: Add basic support for (scoped) variables It's now possible to assign expressions to variables. The variables are put into the current scope of the interpreter. Variable lookup follows the scope chain, ending in the global object. 2020-03-09 21:13:55 +01:00			`virtual bool is_identifier() const { return false; }`
LibJS: Start building a JavaScript engine for SerenityOS :^) I always tell people to start building things by working on the thing that seems the most interesting right now. The most interesting thing here was an AST + simple interpreter, so that's where we start! There is no lexer or parser yet, we build an AST directly and then execute it in the interpreter, producing a return value. This seems like the start of something interesting. :^) 2020-03-07 19:42:11 +01:00
			`protected:`
			`ASTNode() {}`

			`private:`
			`};`

			`class ScopeNode : public ASTNode {`
			`public:`
			`template<typename T, typename... Args>`
			`T& append(Args&&... args)`
			`{`
			`auto child = make<T>(forward<Args>(args)...);`
			`m_children.append(move(child));`
			`return static_cast<T&>(m_children.last());`
			`}`

			`const NonnullOwnPtrVector<ASTNode>& children() const { return m_children; }`
			`virtual Value execute(Interpreter&) const override;`
			`virtual void dump(int indent) const override;`

			`protected:`
			`ScopeNode() {}`

			`private:`
			`NonnullOwnPtrVector<ASTNode> m_children;`
			`};`

			`class Program : public ScopeNode {`
			`public:`
			`Program() {}`

			`private:`
			`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 FunctionDeclaration : public ASTNode {`
			`public:`
			`FunctionDeclaration(String name, NonnullOwnPtr<ScopeNode> body)`
			`: m_name(move(name))`
			`, m_body(move(body))`
			`{`
			`}`

			`String name() const { return m_name; }`
			`const ScopeNode& 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 "FunctionDeclaration"; }`

			`String m_name;`
			`NonnullOwnPtr<ScopeNode> m_body;`
			`};`

			`class Expression : public ASTNode {`
			`public:`
			`};`

			`class ReturnStatement : public ASTNode {`
			`public:`
			`explicit ReturnStatement(NonnullOwnPtr<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"; }`

			`NonnullOwnPtr<Expression> m_argument;`
			`};`

LibJS: Implement if statements If statements execute a certain action or an alternative one depending on whether the tested condition is true or false, this commit helps establish basic control flow capabilities in the AST. 2020-03-08 07:58:58 +02:00			`class IfStatement : public ASTNode {`
			`public:`
LibJS: Remove superfluous explicit in AST.h (#1395) 2020-03-09 21:37:08 +08:00			`IfStatement(NonnullOwnPtr<Expression> predicate, NonnullOwnPtr<ScopeNode> consequent, NonnullOwnPtr<ScopeNode> alternate)`
LibJS: Implement if statements If statements execute a certain action or an alternative one depending on whether the tested condition is true or false, this commit helps establish basic control flow capabilities in the AST. 2020-03-08 07:58:58 +02:00			`: m_predicate(move(predicate))`
			`, m_consequent(move(consequent))`
			`, m_alternate(move(alternate))`
			`{`
			`}`

			`const Expression& predicate() const { return *m_predicate; }`
			`const ScopeNode& consequent() const { return *m_consequent; }`
			`const ScopeNode& 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"; }`

			`NonnullOwnPtr<Expression> m_predicate;`
			`NonnullOwnPtr<ScopeNode> m_consequent;`
			`NonnullOwnPtr<ScopeNode> m_alternate;`
			`};`

LibJS: Implement While statements 2020-03-09 03:22:21 +08:00			`class WhileStatement : public ASTNode {`
			`public:`
			`WhileStatement(NonnullOwnPtr<Expression> predicate, NonnullOwnPtr<ScopeNode> body)`
			`: m_predicate(move(predicate))`
			`, m_body(move(body))`
			`{`
			`}`

			`const Expression& predicate() const { return *m_predicate; }`
			`const ScopeNode& 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 "WhileStatement"; }`

			`NonnullOwnPtr<Expression> m_predicate;`
			`NonnullOwnPtr<ScopeNode> m_body;`
			`};`

LibJS: Start building a JavaScript engine for SerenityOS :^) I always tell people to start building things by working on the thing that seems the most interesting right now. The most interesting thing here was an AST + simple interpreter, so that's where we start! There is no lexer or parser yet, we build an AST directly and then execute it in the interpreter, producing a return value. This seems like the start of something interesting. :^) 2020-03-07 19:42:11 +01:00			`enum class BinaryOp {`
			`Plus,`
			`Minus,`
LibJS: Add typed comparison operator The `===` operator allows us to compare two values while taking their type into consideration. 2020-03-08 07:53:02 +02:00			`TypedEquals,`
LibJS: Add new bitwise and relational operators Do note that when it comes to evaluating binary expressions, we are asserting in multiple contexts that the values we're operating on are numbers, we should probably handle other value types to be more tolerant in the future, since for example, adding a number and a string, in which case the number is converted to a string implicitly which is then concatenated, although ugly, is valid javascript. 2020-03-08 23:27:18 +02:00			`TypedInequals,`
LibJS: Move Value ops into Value.cpp and tweak BinaryOp names 2020-03-10 11:35:05 +01:00			`GreaterThan,`
			`LessThan,`
			`BitwiseAnd,`
			`BitwiseOr,`
			`BitwiseXor,`
			`LeftShift,`
			`RightShift,`
LibJS: Start building a JavaScript engine for SerenityOS :^) I always tell people to start building things by working on the thing that seems the most interesting right now. The most interesting thing here was an AST + simple interpreter, so that's where we start! There is no lexer or parser yet, we build an AST directly and then execute it in the interpreter, producing a return value. This seems like the start of something interesting. :^) 2020-03-07 19:42:11 +01:00			`};`

			`class BinaryExpression : public Expression {`
			`public:`
LibJS: Let's say that Identifier is an Expression for now This allows us to tighten typing in various other classes. 2020-03-10 11:48:49 +01:00			`BinaryExpression(BinaryOp op, NonnullOwnPtr<Expression> lhs, NonnullOwnPtr<Expression> rhs)`
LibJS: Start building a JavaScript engine for SerenityOS :^) I always tell people to start building things by working on the thing that seems the most interesting right now. The most interesting thing here was an AST + simple interpreter, so that's where we start! There is no lexer or parser yet, we build an AST directly and then execute it in the interpreter, producing a return value. This seems like the start of something interesting. :^) 2020-03-07 19:42:11 +01:00			`: 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;`
LibJS: Let's say that Identifier is an Expression for now This allows us to tighten typing in various other classes. 2020-03-10 11:48:49 +01:00			`NonnullOwnPtr<Expression> m_lhs;`
			`NonnullOwnPtr<Expression> m_rhs;`
LibJS: Start building a JavaScript engine for SerenityOS :^) I always tell people to start building things by working on the thing that seems the most interesting right now. The most interesting thing here was an AST + simple interpreter, so that's where we start! There is no lexer or parser yet, we build an AST directly and then execute it in the interpreter, producing a return value. This seems like the start of something interesting. :^) 2020-03-07 19:42:11 +01:00			`};`

LibJS: Implement logical expressions Logical expressions are expressions which can return either true or false according to a provided condition. 2020-03-08 07:55:44 +02:00			`enum class LogicalOp {`
			`And,`
			`Or,`
			`};`

			`class LogicalExpression : public Expression {`
			`public:`
			`LogicalExpression(LogicalOp op, NonnullOwnPtr<Expression> lhs, NonnullOwnPtr<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;`
			`NonnullOwnPtr<Expression> m_lhs;`
LibJS: Move logical not operator to new unary expression class 2020-03-09 19:04:44 +02:00			`NonnullOwnPtr<Expression> m_rhs;`
LibJS: Implement logical expressions Logical expressions are expressions which can return either true or false according to a provided condition. 2020-03-08 07:55:44 +02:00			`};`

LibJS: Add new bitwise and relational operators Do note that when it comes to evaluating binary expressions, we are asserting in multiple contexts that the values we're operating on are numbers, we should probably handle other value types to be more tolerant in the future, since for example, adding a number and a string, in which case the number is converted to a string implicitly which is then concatenated, although ugly, is valid javascript. 2020-03-08 23:27:18 +02:00			`enum class UnaryOp {`
			`BitNot,`
LibJS: Move logical not operator to new unary expression class 2020-03-09 19:04:44 +02:00			`Not,`
LibJS: Add new bitwise and relational operators Do note that when it comes to evaluating binary expressions, we are asserting in multiple contexts that the values we're operating on are numbers, we should probably handle other value types to be more tolerant in the future, since for example, adding a number and a string, in which case the number is converted to a string implicitly which is then concatenated, although ugly, is valid javascript. 2020-03-08 23:27:18 +02:00			`};`

			`class UnaryExpression : public Expression {`
			`public:`
			`UnaryExpression(UnaryOp op, NonnullOwnPtr<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;`
			`NonnullOwnPtr<Expression> m_lhs;`
			`};`

LibJS: Start building a JavaScript engine for SerenityOS :^) I always tell people to start building things by working on the thing that seems the most interesting right now. The most interesting thing here was an AST + simple interpreter, so that's where we start! There is no lexer or parser yet, we build an AST directly and then execute it in the interpreter, producing a return value. This seems like the start of something interesting. :^) 2020-03-07 19:42:11 +01:00			`class Literal : public Expression {`
			`public:`
			`explicit Literal(Value value)`
			`: m_value(move(value))`
			`{`
			`}`

			`virtual Value execute(Interpreter&) const override { return m_value; }`
			`virtual void dump(int indent) const override;`

			`private:`
			`virtual const char* class_name() const override { return "Literal"; }`

			`Value m_value;`
			`};`

LibJS: Let's say that Identifier is an Expression for now This allows us to tighten typing in various other classes. 2020-03-10 11:48:49 +01:00			`class Identifier final : public Expression {`
LibJS: Add basic support for (scoped) variables It's now possible to assign expressions to variables. The variables are put into the current scope of the interpreter. Variable lookup follows the scope chain, ending in the global object. 2020-03-09 21:13:55 +01:00			`public:`
			`explicit Identifier(String string)`
			`: m_string(move(string))`
			`{`
			`}`

			`const String& 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; }`

			`private:`
			`virtual const char* class_name() const override { return "Identifier"; }`

			`String m_string;`
			`};`

LibJS: Start building a JavaScript engine for SerenityOS :^) I always tell people to start building things by working on the thing that seems the most interesting right now. The most interesting thing here was an AST + simple interpreter, so that's where we start! There is no lexer or parser yet, we build an AST directly and then execute it in the interpreter, producing a return value. This seems like the start of something interesting. :^) 2020-03-07 19:42:11 +01:00			`class CallExpression : public Expression {`
			`public:`
			`explicit CallExpression(String name)`
			`: m_name(move(name))`
			`{`
			`}`

			`virtual Value execute(Interpreter&) const override;`
			`virtual void dump(int indent) const override;`

			`const String& name() const { return m_name; }`

			`private:`
			`virtual const char* class_name() const override { return "CallExpression"; }`

			`String m_name;`
			`};`

LibJS: Add basic support for (scoped) variables It's now possible to assign expressions to variables. The variables are put into the current scope of the interpreter. Variable lookup follows the scope chain, ending in the global object. 2020-03-09 21:13:55 +01:00			`enum class AssignmentOp {`
			`Assign,`
			`};`

			`class AssignmentExpression : public Expression {`
			`public:`
LibJS: Let's say that Identifier is an Expression for now This allows us to tighten typing in various other classes. 2020-03-10 11:48:49 +01:00			`AssignmentExpression(AssignmentOp op, NonnullOwnPtr<ASTNode> lhs, NonnullOwnPtr<Expression> rhs)`
LibJS: Add basic support for (scoped) variables It's now possible to assign expressions to variables. The variables are put into the current scope of the interpreter. Variable lookup follows the scope chain, ending in the global object. 2020-03-09 21:13:55 +01:00			`: 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;`
			`NonnullOwnPtr<ASTNode> m_lhs;`
LibJS: Let's say that Identifier is an Expression for now This allows us to tighten typing in various other classes. 2020-03-10 11:48:49 +01:00			`NonnullOwnPtr<Expression> m_rhs;`
LibJS: Add basic support for (scoped) variables It's now possible to assign expressions to variables. The variables are put into the current scope of the interpreter. Variable lookup follows the scope chain, ending in the global object. 2020-03-09 21:13:55 +01:00			`};`

			`class VariableDeclaration : public ASTNode {`
			`public:`
LibJS: Let's say that Identifier is an Expression for now This allows us to tighten typing in various other classes. 2020-03-10 11:48:49 +01:00			`VariableDeclaration(NonnullOwnPtr<Identifier> name, OwnPtr<Expression> initializer)`
LibJS: Add basic support for (scoped) variables It's now possible to assign expressions to variables. The variables are put into the current scope of the interpreter. Variable lookup follows the scope chain, ending in the global object. 2020-03-09 21:13:55 +01:00			`: m_name(move(name))`
			`, m_initializer(move(initializer))`
			`{`
			`}`

			`const Identifier& name() const { return *m_name; }`

			`virtual Value execute(Interpreter&) const override;`
			`virtual void dump(int indent) const override;`

			`private:`
			`virtual const char* class_name() const override { return "VariableDeclaration"; }`

			`NonnullOwnPtr<Identifier> m_name;`
LibJS: Let's say that Identifier is an Expression for now This allows us to tighten typing in various other classes. 2020-03-10 11:48:49 +01:00			`OwnPtr<Expression> m_initializer;`
LibJS: Add basic support for (scoped) variables It's now possible to assign expressions to variables. The variables are put into the current scope of the interpreter. Variable lookup follows the scope chain, ending in the global object. 2020-03-09 21:13:55 +01:00			`};`

LibJS: Add a very simple ObjectExpression for "var x = {}" This allows us to allocate an empty new Object on the GC heap. 2020-03-09 21:28:31 +01:00			`class ObjectExpression : public Expression {`
			`public:`
			`ObjectExpression() {}`

			`virtual Value execute(Interpreter&) const override;`
			`virtual void dump(int indent) const override;`

			`private:`
			`virtual const char* class_name() const override { return "ObjectExpression"; }`
			`};`

LibJS: Start building a JavaScript engine for SerenityOS :^) I always tell people to start building things by working on the thing that seems the most interesting right now. The most interesting thing here was an AST + simple interpreter, so that's where we start! There is no lexer or parser yet, we build an AST directly and then execute it in the interpreter, producing a return value. This seems like the start of something interesting. :^) 2020-03-07 19:42:11 +01:00			`}`