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elna/boot/ast.cc

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/* Abstract syntax tree representation.
Copyright (C) 2025 Free Software Foundation, Inc.
GCC is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 3, or (at your option)
any later version.
GCC is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with GCC; see the file COPYING3. If not see
<http://www.gnu.org/licenses/>. */
#include "elna/boot/ast.h"
namespace elna
{
namespace boot
{
void empty_visitor::visit(variable_declaration *)
{
}
void empty_visitor::visit(constant_definition *definition)
{
definition->body().accept(this);
}
void empty_visitor::visit(procedure_definition *definition)
{
for (auto parameter : definition->parameters)
{
parameter->accept(this);
}
if (definition->body() != nullptr)
{
definition->body()->accept(this);
}
}
void empty_visitor::visit(type_definition *definition)
{
definition->body().accept(this);
}
void empty_visitor::visit(call_expression *expression)
{
for (auto& argument : expression->arguments())
{
argument->accept(this);
}
}
void empty_visitor::visit(cast_expression *expression)
{
expression->target().accept(this);
expression->value().accept(this);
}
void empty_visitor::visit(size_of_expression *expression)
{
expression->body().accept(this);
}
void empty_visitor::visit(call_statement *statement)
{
statement->body().accept(this);
}
void empty_visitor::visit(assign_statement *statement)
{
statement->rvalue().accept(this);
}
void empty_visitor::visit(if_statement *statement)
{
statement->body().prerequisite().accept(this);
for (const auto body_statement : statement->body().statements)
{
body_statement->accept(this);
}
}
void empty_visitor::visit(while_statement *statement)
{
statement->body().prerequisite().accept(this);
for (const auto body_statement : statement->body().statements)
{
body_statement->accept(this);
}
}
void empty_visitor::visit(return_statement *statement)
{
expression *return_expression = statement->return_expression();
if (return_expression != nullptr)
{
return_expression->accept(this);
}
}
void empty_visitor::visit(defer_statement *defer)
{
for (statement *const body_statement : defer->statements)
{
body_statement->accept(this);
}
}
void empty_visitor::visit(block *block)
{
for (constant_definition *const constant : block->constants)
{
constant->accept(this);
}
for (variable_declaration *const variable : block->variables)
{
variable->accept(this);
}
for (statement *const body_statement : block->body)
{
body_statement->accept(this);
}
}
void empty_visitor::visit(program *program)
{
visit(reinterpret_cast<block *>(program));
for (type_definition *const type : program->types)
{
type->accept(this);
}
for (procedure_definition *const procedure : program->procedures)
{
procedure->accept(this);
}
}
void empty_visitor::visit(binary_expression *expression)
{
expression->lhs().accept(this);
expression->rhs().accept(this);
}
void empty_visitor::visit(unary_expression *expression)
{
expression->operand().accept(this);
}
void empty_visitor::visit(basic_type_expression *)
{
}
void empty_visitor::visit(array_type_expression *expression)
{
expression->base().accept(this);
}
void empty_visitor::visit(pointer_type_expression *expression)
{
expression->base().accept(this);
}
void empty_visitor::visit(record_type_expression *expression)
{
for (auto& field : expression->fields)
{
field.second->accept(this);
}
}
void empty_visitor::visit(union_type_expression *expression)
{
for (auto& field : expression->fields)
{
field.second->accept(this);
}
}
void empty_visitor::visit(variable_expression *)
{
}
void empty_visitor::visit(array_access_expression *expression)
{
expression->base().accept(this);
expression->index().accept(this);
}
void empty_visitor::visit(field_access_expression *expression)
{
expression->base().accept(this);
}
void empty_visitor::visit(dereference_expression *expression)
{
expression->base().accept(this);
}
void empty_visitor::visit(number_literal<std::int32_t> *)
{
}
void empty_visitor::visit(number_literal<std::uint32_t> *)
{
}
void empty_visitor::visit(number_literal<double> *)
{
}
void empty_visitor::visit(number_literal<bool> *)
{
}
void empty_visitor::visit(number_literal<unsigned char> *)
{
}
void empty_visitor::visit(number_literal<std::nullptr_t> *)
{
}
void empty_visitor::visit(number_literal<std::string> *)
{
}
node::node(const struct position position)
: source_position(position)
{
}
const struct position& node::position() const
{
return this->source_position;
}
statement::statement(const struct position position)
: node(position)
{
}
expression::expression(const struct position position)
: node(position)
{
}
type_expression::type_expression(const struct position position)
: node(position)
{
}
basic_type_expression *type_expression::is_basic()
{
return nullptr;
}
array_type_expression *type_expression::is_array()
{
return nullptr;
}
record_type_expression *type_expression::is_record()
{
return nullptr;
}
union_type_expression *type_expression::is_union()
{
return nullptr;
}
pointer_type_expression *type_expression::is_pointer()
{
return nullptr;
}
basic_type_expression::basic_type_expression(
const struct position position, const std::string& name)
: type_expression(position), m_name(name)
{
}
void basic_type_expression::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
const std::string& basic_type_expression::base_name()
{
return m_name;
}
basic_type_expression *basic_type_expression::is_basic()
{
return this;
}
array_type_expression::array_type_expression(const struct position position, type_expression *base,
const std::uint32_t size)
: type_expression(position), m_base(base), size(size)
{
}
void array_type_expression::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
type_expression& array_type_expression::base()
{
return *m_base;
}
array_type_expression *array_type_expression::is_array()
{
return this;
}
array_type_expression::~array_type_expression()
{
delete m_base;
}
pointer_type_expression::pointer_type_expression(const struct position position, type_expression *base)
: type_expression(position), m_base(base)
{
}
void pointer_type_expression::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
type_expression& pointer_type_expression::base()
{
return *m_base;
}
pointer_type_expression *pointer_type_expression::is_pointer()
{
return this;
}
pointer_type_expression::~pointer_type_expression()
{
delete m_base;
}
composite_type_expression::composite_type_expression(const struct position position,
fields_t&& fields)
: type_expression(position), fields(std::move(fields))
{
}
composite_type_expression::~composite_type_expression()
{
for (auto& field_declaration : fields)
{
delete field_declaration.second;
}
}
record_type_expression::record_type_expression(const struct position position,
fields_t&& fields)
: composite_type_expression(position, std::move(fields))
{
}
void record_type_expression::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
record_type_expression *record_type_expression::is_record()
{
return this;
}
union_type_expression::union_type_expression(const struct position position,
fields_t&& fields)
: composite_type_expression(position, std::move(fields))
{
}
union_type_expression *union_type_expression::is_union()
{
return this;
}
void union_type_expression::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
variable_declaration::variable_declaration(const struct position position, const std::string& identifier,
const bool exported, type_expression *type)
: definition(position, identifier, exported), m_type(type)
{
}
variable_declaration::~variable_declaration()
{
delete m_type;
}
void variable_declaration::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
type_expression& variable_declaration::type()
{
return *m_type;
}
definition::definition(const struct position position, const std::string& identifier, const bool exported)
: node(position), identifier(identifier), exported(exported)
{
}
constant_definition::constant_definition(const struct position position, const std::string& identifier,
const bool exported, literal *body)
: definition(position, identifier, exported), m_body(body)
{
}
void constant_definition::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
literal& constant_definition::body()
{
return *m_body;
}
constant_definition::~constant_definition()
{
delete m_body;
}
procedure_definition::procedure_definition(const struct position position, const std::string& identifier,
const bool exported, type_expression *return_type)
: definition(position, identifier, exported), m_return_type(return_type)
{
}
void procedure_definition::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
block *procedure_definition::body()
{
return m_body;
}
procedure_definition *procedure_definition::add_body(block *procedure_body)
{
m_body = procedure_body;
return this;
}
type_expression *procedure_definition::return_type()
{
return m_return_type;
}
procedure_definition::~procedure_definition()
{
if (m_body != nullptr)
{
delete m_body;
}
for (auto parameter : parameters)
{
delete parameter;
}
}
type_definition::type_definition(const struct position position, const std::string& identifier,
const bool exported, type_expression *body)
: definition(position, identifier, exported), m_body(body)
{
}
void type_definition::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
type_expression& type_definition::body()
{
return *m_body;
}
type_definition::~type_definition()
{
delete m_body;
}
block::block(const struct position position)
: node(position)
{
}
void block::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
block::~block()
{
for (statement *body_statement : this->body)
{
delete body_statement;
}
for (variable_declaration *variable : this->variables)
{
delete variable;
}
for (constant_definition *constant : this->constants)
{
delete constant;
}
}
program::program(const struct position position)
: block(position)
{
}
void program::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
program::~program()
{
for (procedure_definition *procedure : this->procedures)
{
delete procedure;
}
for (type_definition *type : this->types)
{
delete type;
}
}
literal::literal(const struct position position)
: expression(position)
{
}
defer_statement::defer_statement(const struct position position)
: statement(position)
{
}
void defer_statement::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
defer_statement::~defer_statement()
{
for (statement *body_statement : statements)
{
delete body_statement;
}
}
designator_expression::designator_expression(const struct position position)
: expression(position)
{
}
variable_expression::variable_expression(const struct position position, const std::string& name)
: designator_expression(position), m_name(name)
{
}
void variable_expression::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
const std::string& variable_expression::name() const
{
return m_name;
}
variable_expression *variable_expression::is_variable()
{
return this;
}
array_access_expression::array_access_expression(const struct position position,
expression *base, expression *index)
: designator_expression(position), m_base(base), m_index(index)
{
}
void array_access_expression::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
expression& array_access_expression::index()
{
return *m_index;
}
expression& array_access_expression::base()
{
return *m_base;
}
array_access_expression *array_access_expression::is_array_access()
{
return this;
}
array_access_expression::~array_access_expression()
{
delete m_index;
delete m_base;
}
field_access_expression::field_access_expression(const struct position position,
expression *base, const std::string& field)
: designator_expression(position), m_base(base), m_field(field)
{
}
void field_access_expression::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
expression& field_access_expression::base()
{
return *m_base;
}
std::string& field_access_expression::field()
{
return m_field;
}
field_access_expression *field_access_expression::is_field_access()
{
return this;
}
field_access_expression::~field_access_expression()
{
delete m_base;
}
dereference_expression::dereference_expression(const struct position position,
expression *base)
: designator_expression(position), m_base(base)
{
}
void dereference_expression::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
expression& dereference_expression::base()
{
return *m_base;
}
dereference_expression *dereference_expression::is_dereference()
{
return this;
}
dereference_expression::~dereference_expression()
{
delete m_base;
}
binary_expression::binary_expression(const struct position position, expression *lhs,
expression *rhs, const binary_operator operation)
: expression(position), m_lhs(lhs), m_rhs(rhs), m_operator(operation)
{
}
void binary_expression::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
expression& binary_expression::lhs()
{
return *m_lhs;
}
expression& binary_expression::rhs()
{
return *m_rhs;
}
binary_operator binary_expression::operation() const
{
return m_operator;
}
binary_expression::~binary_expression()
{
delete m_lhs;
delete m_rhs;
}
unary_expression::unary_expression(const struct position position, expression *operand,
const unary_operator operation)
: expression(position), m_operand(std::move(operand)), m_operator(operation)
{
}
void unary_expression::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
expression& unary_expression::operand()
{
return *m_operand;
}
unary_operator unary_expression::operation() const
{
return this->m_operator;
}
unary_expression::~unary_expression()
{
delete m_operand;
}
call_expression::call_expression(const struct position position, const std::string& name)
: expression(position), m_name(name)
{
}
void call_expression::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
std::string& call_expression::name()
{
return m_name;
}
std::vector<expression *>& call_expression::arguments()
{
return m_arguments;
}
call_expression::~call_expression()
{
for (auto argument : m_arguments)
{
delete argument;
}
}
cast_expression::cast_expression(const struct position position, type_expression *target, expression *value)
: expression(position), m_target(target), m_value(value)
{
}
void cast_expression::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
type_expression& cast_expression::target()
{
return *m_target;
}
expression& cast_expression::value()
{
return *m_value;
}
cast_expression::~cast_expression()
{
delete m_target;
delete m_value;
}
size_of_expression::size_of_expression(const struct position position, type_expression *body)
: expression(position), m_body(body)
{
}
void size_of_expression::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
type_expression& size_of_expression::body()
{
return *m_body;
}
size_of_expression::~size_of_expression()
{
delete m_body;
}
call_statement::call_statement(const struct position position, call_expression *body)
: statement(position), m_body(body)
{
}
void call_statement::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
call_expression& call_statement::body()
{
return *m_body;
}
call_statement::~call_statement()
{
delete m_body;
}
conditional_statements::conditional_statements(expression *prerequisite)
: m_prerequisite(prerequisite)
{
}
expression& conditional_statements::prerequisite()
{
return *m_prerequisite;
}
conditional_statements::~conditional_statements()
{
delete m_prerequisite;
for (auto statement : statements)
{
delete statement;
}
}
return_statement::return_statement(const struct position position, expression *return_expression)
: statement(position), m_return_expression(return_expression)
{
}
void return_statement::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
expression *return_statement::return_expression()
{
return m_return_expression;
}
return_statement::~return_statement()
{
if (m_return_expression != nullptr)
{
delete m_return_expression;
}
}
void assign_statement::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
assign_statement::assign_statement(const struct position position, designator_expression *lvalue,
expression *rvalue)
: statement(position), m_lvalue(lvalue), m_rvalue(rvalue)
{
}
variable_expression *designator_expression::is_variable()
{
return nullptr;
}
array_access_expression *designator_expression::is_array_access()
{
return nullptr;
}
field_access_expression *designator_expression::is_field_access()
{
return nullptr;
}
dereference_expression *designator_expression::is_dereference()
{
return nullptr;
}
designator_expression& assign_statement::lvalue()
{
return *m_lvalue;
}
expression& assign_statement::rvalue()
{
return *m_rvalue;
}
assign_statement::~assign_statement()
{
delete m_rvalue;
}
if_statement::if_statement(const struct position position, conditional_statements *body,
std::vector<statement *> *alternative)
: statement(position), m_body(body), m_alternative(alternative)
{
}
void if_statement::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
conditional_statements& if_statement::body()
{
return *m_body;
}
std::vector<statement *> *if_statement::alternative()
{
return m_alternative;
}
if_statement::~if_statement()
{
delete m_body;
for (const auto branch : branches)
{
delete branch;
}
if (m_alternative != nullptr)
{
delete m_alternative;
}
}
while_statement::while_statement(const struct position position, conditional_statements *body)
: statement(position), m_body(body)
{
}
void while_statement::accept(parser_visitor *visitor)
{
visitor->visit(this);
}
conditional_statements& while_statement::body()
{
return *m_body;
}
while_statement::~while_statement()
{
delete m_body;
}
const char *print_binary_operator(const binary_operator operation)
{
switch (operation)
{
case binary_operator::sum:
return "+";
case binary_operator::subtraction:
return "-";
case binary_operator::multiplication:
return "*";
case binary_operator::division:
return "/";
case binary_operator::remainder:
return "%";
case binary_operator::equals:
return "=";
case binary_operator::not_equals:
return "<>";
case binary_operator::less:
return "<";
case binary_operator::less_equal:
return "<=";
case binary_operator::greater:
return ">";
case binary_operator::greater_equal:
return ">=";
case binary_operator::conjunction:
return "and";
case binary_operator::disjunction:
return "or";
}
__builtin_unreachable();
};
}
}
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