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| author | Eugen Wissner <belka@caraus.de> | 2026-02-15 04:10:38 +0100 |
|---|---|---|
| committer | Eugen Wissner <belka@caraus.de> | 2026-02-15 04:10:38 +0100 |
| commit | 5959fbb5524bbeb05a96eb15aba59e961a3efcb7 (patch) | |
| tree | 811be9bb8fba9bec6ae549c50f9cf92000b259c9 /gcc/elna-generic.cc | |
| download | elna-5959fbb5524bbeb05a96eb15aba59e961a3efcb7.tar.gz | |
Initial commit
Diffstat (limited to 'gcc/elna-generic.cc')
| -rw-r--r-- | gcc/elna-generic.cc | 1277 |
1 files changed, 1277 insertions, 0 deletions
diff --git a/gcc/elna-generic.cc b/gcc/elna-generic.cc new file mode 100644 index 0000000..b37b111 --- /dev/null +++ b/gcc/elna-generic.cc @@ -0,0 +1,1277 @@ +/* Visitor generating a GENERIC tree. + 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 <array> + +#include "elna/gcc/elna-generic.h" +#include "elna/gcc/elna-diagnostic.h" +#include "elna/gcc/elna1.h" +#include "elna/gcc/elna-builtins.h" + +#include "ggc.h" +#include "function.h" +#include "cgraph.h" +#include "gimplify.h" +#include "stringpool.h" +#include "diagnostic.h" +#include "realmpfr.h" +#include "varasm.h" +#include "fold-const.h" +#include "langhooks.h" + +namespace elna::gcc +{ + generic_visitor::generic_visitor(std::shared_ptr<symbol_table> symbol_table, elna::frontend::symbol_bag bag) + : bag(bag), symbols(symbol_table) + { + } + + void generic_visitor::build_procedure_call(location_t call_location, + tree procedure_address, const std::vector<frontend::expression *>& arguments) + { + vec<tree, va_gc> *argument_trees = nullptr; + tree symbol_type = TREE_TYPE(TREE_TYPE(procedure_address)); + + tree current_parameter = TYPE_ARG_TYPES(symbol_type); + + vec_alloc(argument_trees, arguments.size()); + for (frontend::expression *const argument : arguments) + { + location_t argument_location = get_location(&argument->position()); + if (VOID_TYPE_P(TREE_VALUE(current_parameter))) + { + error_at(argument_location, "Too many arguments, expected %i, got %lu", + list_length(TYPE_ARG_TYPES(symbol_type)) - 1, arguments.size()); + this->current_expression = error_mark_node; + break; + } + argument->accept(this); + this->current_expression = prepare_rvalue(this->current_expression); + if (!is_assignable_from(TREE_VALUE(current_parameter), this->current_expression)) + { + error_at(argument_location, + "Cannot assign value of type '%s' to variable of type '%s'", + print_type(TREE_TYPE(this->current_expression)).c_str(), + print_type(TREE_VALUE(current_parameter)).c_str()); + this->current_expression = error_mark_node; + } + current_parameter = TREE_CHAIN(current_parameter); + argument_trees->quick_push(this->current_expression); + } + tree stmt = fold_build_call_array_loc(call_location, TREE_TYPE(symbol_type), + procedure_address, vec_safe_length(argument_trees), vec_safe_address(argument_trees)); + + if (!VOID_TYPE_P(TREE_VALUE(current_parameter))) + { + error_at(call_location, "Too few arguments, expected %i, got %lu", + list_length(TYPE_ARG_TYPES(symbol_type)) - 1, arguments.size()); + this->current_expression = error_mark_node; + } + else + { + this->current_expression = stmt; + } + } + + void generic_visitor::build_record_call(location_t call_location, + tree symbol, const std::vector<frontend::expression *>& arguments) + { + vec<constructor_elt, va_gc> *tree_arguments = nullptr; + tree record_fields = TYPE_FIELDS(symbol); + for (frontend::expression *const argument : arguments) + { + location_t argument_location = get_location(&argument->position()); + + if (is_void_type(record_fields)) + { + error_at(argument_location, "Too many arguments, expected %i, got %lu", + list_length(TYPE_FIELDS(symbol)), arguments.size()); + this->current_expression = error_mark_node; + break; + } + argument->accept(this); + tree unqualified_field = get_qualified_type(TREE_TYPE(record_fields), TYPE_UNQUALIFIED); + if (!is_assignable_from(unqualified_field, this->current_expression)) + { + error_at(argument_location, + "Cannot assign value of type '%s' to variable of type '%s'", + print_type(TREE_TYPE(this->current_expression)).c_str(), + print_type(TREE_TYPE(record_fields)).c_str()); + this->current_expression = error_mark_node; + } + CONSTRUCTOR_APPEND_ELT(tree_arguments, record_fields, this->current_expression); + record_fields = TREE_CHAIN(record_fields); + } + if (!is_void_type(record_fields)) + { + error_at(call_location, "Too few arguments, expected %i, got %lu", + list_length(TYPE_FIELDS(symbol)), arguments.size()); + this->current_expression = error_mark_node; + } + else + { + this->current_expression = build_constructor(symbol, tree_arguments); + } + } + + void generic_visitor::build_assert_builtin(location_t call_location, + const std::vector<frontend::expression *>& arguments) + { + if (arguments.size() != 1) + { + error_at(call_location, "assert expects exactly one boolean argument, got %lu", arguments.size()); + this->current_expression = error_mark_node; + } + else + { + arguments.at(0)->accept(this); + tree argument_type = TREE_TYPE(this->current_expression); + + if (argument_type != elna_bool_type_node) + { + error_at(call_location, "assert expects exactly one boolean argument, got %s", + print_type(argument_type).c_str()); + this->current_expression = error_mark_node; + } + tree constant_expression = extract_constant(this->current_expression); + if (constant_expression == boolean_false_node) + { + this->current_expression = call_built_in(call_location, "__builtin_unreachable", void_type_node); + } + else if (constant_expression != boolean_true_node) + { + tree assert_expression = call_built_in(call_location, "__builtin_trap", void_type_node); + this->current_expression = build3(COND_EXPR, void_type_node, this->current_expression, + NULL_TREE, assert_expression); + } + else + { + this->current_expression = NULL_TREE; + } + } + } + + bool generic_visitor::build_builtin_procedures(frontend::procedure_call *call) + { + location_t call_location = get_location(&call->position()); + + if (frontend::variable_expression *named_call = call->callable().is_variable()) + { + if (named_call->name == "assert") + { + build_assert_builtin(call_location, call->arguments); + return true; + } + } + return false; + } + + void generic_visitor::visit(frontend::procedure_call *call) + { + if (build_builtin_procedures(call)) + { + return; + } + location_t call_location = get_location(&call->position()); + call->callable().accept(this); + + tree expression_type = TYPE_P(this->current_expression) + ? this->current_expression + : TREE_TYPE(this->current_expression); + + if (TREE_CODE(expression_type) == RECORD_TYPE) + { + build_record_call(call_location, expression_type, call->arguments); + } + else if (TREE_CODE(expression_type) == FUNCTION_TYPE) + { + this->current_expression = build1(ADDR_EXPR, + build_global_pointer_type(expression_type), this->current_expression); + build_procedure_call(call_location, this->current_expression, call->arguments); + } + else if (POINTER_TYPE_P(expression_type) && TREE_CODE(TREE_TYPE(expression_type)) == FUNCTION_TYPE) + { + build_procedure_call(call_location, this->current_expression, call->arguments); + } + else + { + error_at(call_location, "'%s' cannot be called, it is neither a procedure nor record", + print_type(expression_type).c_str()); + this->current_expression = error_mark_node; + } + } + + void generic_visitor::visit(frontend::cast_expression *expression) + { + tree cast_target = get_inner_alias(expression->expression_type, this->symbols->scope()); + + expression->value().accept(this); + tree cast_source = TREE_TYPE(this->current_expression); + + if (is_castable_type(cast_target) && (is_castable_type(cast_source))) + { + this->current_expression = build1_loc(get_location(&expression->position()), CONVERT_EXPR, + cast_target, this->current_expression); + } + else + { + error_at(get_location(&expression->position()), "Type '%s' cannot be converted to '%s'", + print_type(cast_source).c_str(), print_type(cast_target).c_str()); + this->current_expression = error_mark_node; + } + } + + void generic_visitor::visit(frontend::program *program) + { + visit(static_cast<frontend::unit *>(program)); + + tree declaration_type = build_function_type_list(elna_int_type_node, + elna_int_type_node, + build_global_pointer_type(build_global_pointer_type(elna_char_type_node)), + NULL_TREE); + tree fndecl = build_fn_decl("main", declaration_type); + + tree resdecl = build_decl(UNKNOWN_LOCATION, RESULT_DECL, NULL_TREE, integer_type_node); + DECL_CONTEXT(resdecl) = fndecl; + DECL_RESULT(fndecl) = resdecl; + + push_struct_function(fndecl, false); + DECL_STRUCT_FUNCTION(fndecl)->language = ggc_cleared_alloc<language_function>(); + + enter_scope(); + + tree parameter_type = TYPE_ARG_TYPES(declaration_type); + for (const char *argument_name : std::array<const char *, 2>{ "count", "parameters" }) + { + tree declaration_tree = build_decl(UNKNOWN_LOCATION, PARM_DECL, + get_identifier(argument_name), TREE_VALUE(parameter_type)); + DECL_CONTEXT(declaration_tree) = fndecl; + DECL_ARG_TYPE(declaration_tree) = TREE_VALUE(parameter_type); + + this->symbols->enter(argument_name, declaration_tree); + DECL_ARGUMENTS(fndecl) = chainon(DECL_ARGUMENTS(fndecl), declaration_tree); + parameter_type = TREE_CHAIN(parameter_type); + } + visit_statements(program->body); + tree set_result = build2(INIT_EXPR, void_type_node, DECL_RESULT(fndecl), + build_int_cst_type(integer_type_node, 0)); + tree return_stmt = build1(RETURN_EXPR, void_type_node, set_result); + append_statement(return_stmt); + tree mapping = leave_scope(); + + BLOCK_SUPERCONTEXT(BIND_EXPR_BLOCK(mapping)) = fndecl; + DECL_INITIAL(fndecl) = BIND_EXPR_BLOCK(mapping); + DECL_SAVED_TREE(fndecl) = mapping; + + DECL_EXTERNAL(fndecl) = 0; + DECL_PRESERVE_P(fndecl) = 1; + + pop_cfun(); + gimplify_function_tree(fndecl); + cgraph_node::finalize_function(fndecl, true); + } + + void generic_visitor::visit(frontend::unit *unit) + { + for (frontend::import_declaration *const declaration : unit->imports) + { + declaration->accept(this); + } + for (frontend::constant_declaration *const constant : unit->constants) + { + constant->accept(this); + } + for (frontend::variable_declaration *const variable : unit->variables) + { + variable->accept(this); + } + for (frontend::procedure_declaration *const procedure : unit->procedures) + { + procedure->accept(this); + } + } + + void generic_visitor::visit(frontend::procedure_declaration *definition) + { + tree fndecl = this->symbols->lookup(definition->identifier.name); + + if (!definition->body.has_value()) + { + return; + } + push_struct_function(fndecl, false); + DECL_STRUCT_FUNCTION(fndecl)->language = ggc_cleared_alloc<language_function>(); + + enter_scope(); + this->bag.enter(this->bag.lookup(definition->identifier.name)->is_procedure()->scope); + + tree argument_chain = DECL_ARGUMENTS(fndecl); + for (; argument_chain != NULL_TREE; argument_chain = TREE_CHAIN(argument_chain)) + { + this->symbols->enter(IDENTIFIER_POINTER(DECL_NAME(argument_chain)), argument_chain); + } + for (frontend::constant_declaration *const constant : definition->body.value().constants()) + { + constant->accept(this); + } + for (frontend::variable_declaration *const variable : definition->body.value().variables()) + { + variable->accept(this); + } + visit_statements(definition->body.value().body()); + + tree mapping = leave_scope(); + this->bag.leave(); + + BLOCK_SUPERCONTEXT(BIND_EXPR_BLOCK(mapping)) = fndecl; + DECL_INITIAL(fndecl) = BIND_EXPR_BLOCK(mapping); + DECL_SAVED_TREE(fndecl) = mapping; + + DECL_PRESERVE_P(fndecl) = 1; + + pop_cfun(); + gimplify_function_tree(fndecl); + cgraph_node::finalize_function(fndecl, true); + } + + void generic_visitor::enter_scope() + { + this->symbols = std::make_shared<symbol_table>(this->symbols); + + // Chain the binding levels. + struct binding_level *new_level = ggc_cleared_alloc<binding_level>(); + new_level->level_chain = f_binding_level; + new_level->statement_list = alloc_stmt_list(); + f_binding_level = new_level; + } + + tree generic_visitor::leave_scope() + { + // Variables are only defined in the top function scope. + tree variables = f_binding_level->level_chain == nullptr ? f_names : NULL_TREE; + tree new_block = build_block(variables, f_binding_level->blocks, NULL_TREE, NULL_TREE); + + for (tree it = f_binding_level->blocks; it != NULL_TREE; it = BLOCK_CHAIN(it)) + { + BLOCK_SUPERCONTEXT(it) = new_block; + } + tree bind_expr = build3(BIND_EXPR, void_type_node, variables, chain_defer(), new_block); + this->symbols = this->symbols->scope(); + + f_binding_level = f_binding_level->level_chain; + + if (f_binding_level != nullptr) + { + f_binding_level->blocks = chainon(f_binding_level->blocks, new_block); + } + return bind_expr; + } + + void generic_visitor::visit(frontend::literal<std::int32_t> *literal) + { + this->current_expression = build_int_cst(elna_int_type_node, literal->value); + } + + void generic_visitor::visit(frontend::literal<std::uint32_t> *literal) + { + this->current_expression = build_int_cstu(elna_word_type_node, literal->value); + } + + void generic_visitor::visit(frontend::literal<double> *literal) + { + REAL_VALUE_TYPE real_value1; + + mpfr_t number; + mpfr_init2(number, SIGNIFICAND_BITS); + mpfr_set_d(number, literal->value, MPFR_RNDN); + + real_from_mpfr(&real_value1, number, double_type_node, MPFR_RNDN); + + this->current_expression = build_real(double_type_node, real_value1); + + mpfr_clear(number); + } + + void generic_visitor::visit(frontend::literal<bool> *boolean) + { + this->current_expression = boolean->value ? boolean_true_node : boolean_false_node; + } + + void generic_visitor::visit(frontend::literal<unsigned char> *character) + { + this->current_expression = build_int_cstu(elna_char_type_node, character->value); + } + + void generic_visitor::visit(frontend::literal<nullptr_t> *) + { + this->current_expression = elna_pointer_nil_node; + } + + void generic_visitor::visit(frontend::literal<std::string> *string) + { + tree index_constant = build_int_cstu(elna_word_type_node, string->value.size()); + tree string_type = build_array_type(elna_char_type_node, build_index_type(index_constant)); + + tree string_literal = build_string(string->value.size(), string->value.c_str()); + TREE_TYPE(string_literal) = string_type; + TREE_CONSTANT(string_literal) = 1; + TREE_READONLY(string_literal) = 1; + TREE_STATIC(string_literal) = 1; + + string_type = TREE_TYPE(elna_string_ptr_field_node); + string_literal = build4(ARRAY_REF, elna_char_type_node, + string_literal, integer_zero_node, NULL_TREE, NULL_TREE); + string_literal = build1(ADDR_EXPR, string_type, string_literal); + + vec<constructor_elt, va_gc> *elms = nullptr; + CONSTRUCTOR_APPEND_ELT(elms, elna_string_ptr_field_node, string_literal); + CONSTRUCTOR_APPEND_ELT(elms, elna_string_length_field_node, index_constant); + + this->current_expression = build_constructor(elna_string_type_node, elms); + } + + tree generic_visitor::build_arithmetic_operation(frontend::binary_expression *expression, + tree_code operator_code, tree left, tree right) + { + return build_binary_operation(is_numeric_type(TREE_TYPE(left)), + expression, operator_code, left, right, TREE_TYPE(left)); + } + + tree generic_visitor::build_comparison_operation(frontend::binary_expression *expression, + tree_code operator_code, tree left, tree right) + { + return build_binary_operation(is_numeric_type(TREE_TYPE(left)) || POINTER_TYPE_P(TREE_TYPE(left)), + expression, operator_code, left, right, elna_bool_type_node); + } + + tree generic_visitor::build_bit_logic_operation(frontend::binary_expression *expression, tree left, tree right) + { + location_t expression_location = get_location(&expression->position()); + tree left_type = TREE_TYPE(left); + tree right_type = TREE_TYPE(right); + tree_code logical_code, bit_code; + + if (expression->operation() == frontend::binary_operator::conjunction) + { + bit_code = BIT_AND_EXPR; + logical_code = TRUTH_ANDIF_EXPR; + } + else if (expression->operation() == frontend::binary_operator::disjunction) + { + bit_code = BIT_IOR_EXPR; + logical_code = TRUTH_ORIF_EXPR; + } + else if (expression->operation() == frontend::binary_operator::exclusive_disjunction) + { + bit_code = BIT_XOR_EXPR; + logical_code = TRUTH_XOR_EXPR; + } + else + { + gcc_unreachable(); + } + if (left_type == elna_bool_type_node) + { + return build2_loc(expression_location, logical_code, elna_bool_type_node, left, right); + } + else if (is_integral_type(left_type)) + { + return build2_loc(expression_location, bit_code, left_type, left, right); + } + else + { + error_at(expression_location, "Invalid operands of type '%s' and '%s' for operator %s", + print_type(left_type).c_str(), print_type(right_type).c_str(), + elna::frontend::print_binary_operator(expression->operation())); + return error_mark_node; + } + } + + tree generic_visitor::build_equality_operation(frontend::binary_expression *expression, tree left, tree right) + { + location_t expression_location = get_location(&expression->position()); + tree_code equality_code, combination_code; + + if (expression->operation() == frontend::binary_operator::equals) + { + equality_code = EQ_EXPR; + combination_code = TRUTH_ANDIF_EXPR; + } + else if (expression->operation() == frontend::binary_operator::not_equals) + { + equality_code = NE_EXPR; + combination_code = TRUTH_ORIF_EXPR; + } + else + { + gcc_unreachable(); + } + if (TREE_TYPE(left) == elna_string_type_node) + { + tree lhs_length = build3(COMPONENT_REF, TREE_TYPE(elna_string_length_field_node), + left, elna_string_length_field_node, NULL_TREE); + tree lhs_ptr = build3(COMPONENT_REF, TREE_TYPE(elna_string_ptr_field_node), + left, elna_string_ptr_field_node, NULL_TREE); + + tree rhs_length = build3(COMPONENT_REF, TREE_TYPE(elna_string_length_field_node), + right, elna_string_length_field_node, NULL_TREE); + tree rhs_ptr = build3(COMPONENT_REF, TREE_TYPE(elna_string_ptr_field_node), + right, elna_string_ptr_field_node, NULL_TREE); + + tree length_equality = build2(equality_code, elna_bool_type_node, lhs_length, rhs_length); + tree memcmp_call = call_built_in(UNKNOWN_LOCATION, "__builtin_memcmp", integer_type_node, + lhs_ptr, rhs_ptr, lhs_length); + tree equals_zero = build2(equality_code, elna_bool_type_node, memcmp_call, integer_zero_node); + + return build2(combination_code, elna_bool_type_node, length_equality, equals_zero); + } + else + { + return build2_loc(expression_location, equality_code, elna_bool_type_node, left, right); + } + } + + void generic_visitor::visit(frontend::binary_expression *expression) + { + expression->lhs().accept(this); + tree left = this->current_expression; + tree left_type = get_qualified_type(TREE_TYPE(left), TYPE_UNQUALIFIED); + + expression->rhs().accept(this); + tree right = this->current_expression; + tree right_type = get_qualified_type(TREE_TYPE(right), TYPE_UNQUALIFIED); + + location_t expression_location = get_location(&expression->position()); + + if ((POINTER_TYPE_P(left_type) || POINTER_TYPE_P(right_type)) + && (expression->operation() == frontend::binary_operator::sum + || expression->operation() == frontend::binary_operator::subtraction)) + { + this->current_expression = do_pointer_arithmetic(expression->operation(), + left, right, expression_location); + if (this->current_expression == error_mark_node) + { + error_at(expression_location, + "invalid operation %s on a pointer and an integral type", + frontend::print_binary_operator(expression->operation())); + } + else if (TREE_TYPE(this->current_expression) == ssizetype) + { + this->current_expression = fold_convert(elna_int_type_node, this->current_expression); + } + return; + } + if (left_type != right_type + && !are_compatible_pointers(left_type, right) + && !are_compatible_pointers(right_type, left) + && !(is_integral_type(left_type) && right_type == elna_word_type_node)) + { + error_at(expression_location, + "invalid operands of type '%s' and '%s' for operator %s", + print_type(left_type).c_str(), print_type(right_type).c_str(), + frontend::print_binary_operator(expression->operation())); + this->current_expression = error_mark_node; + return; + } + switch (expression->operation()) + { + case frontend::binary_operator::sum: + this->current_expression = build_arithmetic_operation(expression, PLUS_EXPR, left, right); + break; + case frontend::binary_operator::subtraction: + this->current_expression = build_arithmetic_operation(expression, MINUS_EXPR, left, right); + break; + case frontend::binary_operator::division: + this->current_expression = build_arithmetic_operation(expression, TRUNC_DIV_EXPR, left, right); + break; + case frontend::binary_operator::remainder: + this->current_expression = build_arithmetic_operation(expression, TRUNC_MOD_EXPR, left, right); + break; + case frontend::binary_operator::multiplication: + this->current_expression = build_arithmetic_operation(expression, MULT_EXPR, left, right); + break; + case frontend::binary_operator::less: + this->current_expression = build_comparison_operation(expression, LT_EXPR, left, right); + break; + case frontend::binary_operator::greater: + this->current_expression = build_comparison_operation(expression, GT_EXPR, left, right); + break; + case frontend::binary_operator::less_equal: + this->current_expression = build_comparison_operation(expression, LE_EXPR, left, right); + break; + case frontend::binary_operator::greater_equal: + this->current_expression = build_comparison_operation(expression, GE_EXPR, left, right); + break; + case frontend::binary_operator::conjunction: + this->current_expression = build_bit_logic_operation(expression, left, right); + break; + case frontend::binary_operator::disjunction: + this->current_expression = build_bit_logic_operation(expression, left, right); + break; + case frontend::binary_operator::exclusive_disjunction: + this->current_expression = build_bit_logic_operation(expression, left, right); + break; + case frontend::binary_operator::equals: + this->current_expression = build_equality_operation(expression, left, right); + break; + case frontend::binary_operator::not_equals: + this->current_expression = build_equality_operation(expression, left, right); + break; + case frontend::binary_operator::shift_left: + this->current_expression = build_binary_operation( + is_numeric_type(left_type) && right_type == elna_word_type_node, + expression, LSHIFT_EXPR, left, right, left_type); + break; + case frontend::binary_operator::shift_right: + this->current_expression = build_binary_operation( + is_numeric_type(left_type) && right_type == elna_word_type_node, + expression, RSHIFT_EXPR, left, right, left_type); + break; + } + } + + void generic_visitor::visit(frontend::unary_expression *expression) + { + expression->operand().accept(this); + location_t location = get_location(&expression->position()); + + switch (expression->operation()) + { + case frontend::unary_operator::reference: + this->current_expression = prepare_rvalue(this->current_expression); + TREE_ADDRESSABLE(this->current_expression) = 1; + this->current_expression = build_fold_addr_expr_with_type_loc(location, + this->current_expression, + build_global_pointer_type(TREE_TYPE(this->current_expression))); + TREE_NO_TRAMPOLINE(this->current_expression) = 1; + break; + case frontend::unary_operator::negation: + if (TREE_TYPE(this->current_expression) == elna_bool_type_node) + { + this->current_expression = build1_loc(location, TRUTH_NOT_EXPR, + boolean_type_node, this->current_expression); + } + else if (is_integral_type(TREE_TYPE(this->current_expression))) + { + this->current_expression = build1_loc(location, BIT_NOT_EXPR, + TREE_TYPE(this->current_expression), this->current_expression); + } + else + { + error_at(location, "type '%s' cannot be negated", + print_type(TREE_TYPE(this->current_expression)).c_str()); + this->current_expression = error_mark_node; + } + break; + case frontend::unary_operator::minus: + if (is_integral_type(TREE_TYPE(this->current_expression))) + { + this->current_expression = fold_build1(NEGATE_EXPR, TREE_TYPE(this->current_expression), + this->current_expression); + } + else + { + error_at(location, "type '%s' cannot be negated", + print_type(TREE_TYPE(this->current_expression)).c_str()); + this->current_expression = error_mark_node; + } + } + } + + void generic_visitor::visit(frontend::constant_declaration *definition) + { + location_t definition_location = get_location(&definition->position()); + definition->body().accept(this); + + if (assert_constant(definition_location)) + { + this->current_expression = fold_init(this->current_expression); + } + else + { + this->current_expression = NULL_TREE; + return; + } + tree definition_tree = build_decl(definition_location, CONST_DECL, + get_identifier(definition->identifier.name.c_str()), TREE_TYPE(this->current_expression)); + auto result = this->symbols->enter(definition->identifier.name, definition_tree); + + if (result) + { + DECL_INITIAL(definition_tree) = this->current_expression; + TREE_CONSTANT(definition_tree) = 1; + TREE_READONLY(definition_tree) = 1; + TREE_PUBLIC(definition_tree) = definition->identifier.exported; + + if (!lang_hooks.decls.global_bindings_p()) + { + auto declaration_statement = build1_loc(definition_location, DECL_EXPR, + void_type_node, definition_tree); + append_statement(declaration_statement); + } + } + else + { + error_at(definition_location, "Variable '%s' already declared in this scope", + definition->identifier.name.c_str()); + } + this->current_expression = NULL_TREE; + } + + void generic_visitor::visit(frontend::variable_declaration *declaration) + { + for (const auto& variable_identifier : declaration->identifiers) + { + location_t declaration_location = get_location(&declaration->position()); + tree declaration_tree = this->symbols->lookup(variable_identifier.name); + + if (declaration_tree == NULL_TREE) + { + auto variable_symbol = this->bag.lookup(variable_identifier.name)->is_variable(); + + declaration_tree = declare_variable(variable_identifier.name, *variable_symbol, this->symbols); + } + // Set initializer if given. + if (declaration->body != nullptr) + { + declaration->body->accept(this); + if (is_assignable_from(TREE_TYPE(declaration_tree), this->current_expression)) + { + DECL_INITIAL(declaration_tree) = this->current_expression; + } + else + { + error_at(declaration_location, "Cannot initialize variable of type '%s' with a value of type '%s'", + print_type(TREE_TYPE(declaration_tree)).c_str(), + print_type(TREE_TYPE(this->current_expression)).c_str()); + } + } + else if (!declaration->is_extern && POINTER_TYPE_P(TREE_TYPE(declaration_tree))) + { + DECL_INITIAL(declaration_tree) = elna_pointer_nil_node; + } + this->current_expression = NULL_TREE; + + if (lang_hooks.decls.global_bindings_p()) + { + TREE_STATIC(declaration_tree) = !variable_identifier.exported && !declaration->is_extern; + varpool_node::get_create(declaration_tree); + varpool_node::finalize_decl(declaration_tree); + } + else + { + DECL_CONTEXT(declaration_tree) = current_function_decl; + f_names = chainon(f_names, declaration_tree); + + auto declaration_statement = build1_loc(declaration_location, DECL_EXPR, + void_type_node, declaration_tree); + append_statement(declaration_statement); + } + } + } + + void generic_visitor::visit(frontend::variable_expression *expression) + { + auto symbol = this->symbols->lookup(expression->name); + + if (symbol == NULL_TREE) + { + error_at(get_location(&expression->position()), "Symbol '%s' not declared in the current scope", + expression->name.c_str()); + this->current_expression = error_mark_node; + } + else + { + this->current_expression = symbol; + } + } + + void generic_visitor::visit(frontend::array_access_expression *expression) + { + expression->base().accept(this); + tree designator = this->current_expression; + location_t location = get_location(&expression->position()); + + expression->index().accept(this); + if (!is_integral_type(TREE_TYPE(this->current_expression))) + { + error_at(location, "Type '%s' cannot be used as index", + print_type(TREE_TYPE(this->current_expression)).c_str()); + this->current_expression = error_mark_node; + return; + } + tree offset = fold_convert(elna_word_type_node, this->current_expression); + + if (TREE_CODE(TREE_TYPE(designator)) == ARRAY_TYPE) + { + tree element_type = TREE_TYPE(TREE_TYPE(designator)); + + this->current_expression = build4_loc(location, + ARRAY_REF, element_type, designator, offset, size_one_node, NULL_TREE); + } + else if (TREE_TYPE(designator) == elna_string_type_node) + { + offset = build2(MINUS_EXPR, elna_word_type_node, offset, size_one_node); + tree string_ptr = build3_loc(location, COMPONENT_REF, TREE_TYPE(elna_string_ptr_field_node), + designator, elna_string_ptr_field_node, NULL_TREE); + + tree target_pointer = do_pointer_arithmetic(frontend::binary_operator::sum, string_ptr, offset, location); + + this->current_expression = build1_loc(location, INDIRECT_REF, + elna_char_type_node, target_pointer); + } + else + { + error_at(location, "Indexing is not allowed on type '%s'", + print_type(TREE_TYPE(designator)).c_str()); + this->current_expression = error_mark_node; + } + } + + bool generic_visitor::expect_trait_type_only(frontend::traits_expression *trait) + { + if (trait->parameters.size() != 1) + { + error_at(get_location(&trait->position()), "Trait '%s' expects 1 argument, got %lu", + trait->name.c_str(), trait->parameters.size()); + this->current_expression = error_mark_node; + return false; + } + this->current_expression = get_inner_alias(trait->types.front(), this->symbols); + + return this->current_expression != error_mark_node; + } + + bool generic_visitor::expect_trait_for_integral_type(frontend::traits_expression *trait) + { + if (!expect_trait_type_only(trait)) + { + return false; + } + else if (!is_integral_type(this->current_expression) && TREE_CODE(this->current_expression) != ENUMERAL_TYPE) + { + error_at(get_location(&trait->position()), "Type '%s' does not support trait '%s'", + print_type(this->current_expression).c_str(), trait->name.c_str()); + this->current_expression = error_mark_node; + return false; + } + return true; + } + + void generic_visitor::visit(frontend::traits_expression *trait) + { + location_t trait_location = get_location(&trait->position()); + + if (trait->name == "size") + { + if (expect_trait_type_only(trait)) + { + this->current_expression = build1_loc(trait_location, CONVERT_EXPR, elna_word_type_node, + size_in_bytes(this->current_expression)); + } + } + else if (trait->name == "alignment") + { + if (expect_trait_type_only(trait)) + { + this->current_expression = build_int_cstu(elna_word_type_node, + TYPE_ALIGN_UNIT(this->current_expression)); + } + } + else if (trait->name == "min") + { + if (expect_trait_for_integral_type(trait)) + { + this->current_expression = TYPE_MIN_VALUE(this->current_expression); + } + } + else if (trait->name == "max") + { + if (expect_trait_for_integral_type(trait)) + { + this->current_expression = TYPE_MAX_VALUE(this->current_expression); + } + } + else if (trait->name == "offset") + { + if (trait->parameters.size() != 2) + { + error_at(trait_location, "Trait '%s' expects 2 arguments, got %lu", + trait->name.c_str(), trait->parameters.size()); + this->current_expression = error_mark_node; + return; + } + this->current_expression = get_inner_alias(trait->types.front(), this->symbols); + auto field_type = trait->parameters.at(1)->is_named(); + + if (field_type == nullptr) + { + error_at(trait_location, + "The second argument to the offset trait is expected to be a field name," + "got a type expression"); + this->current_expression = error_mark_node; + return; + } + tree field_declaration = find_field_by_name(trait_location, this->current_expression, field_type->name); + + if (field_declaration != error_mark_node) + { + this->current_expression = build1(CONVERT_EXPR, elna_word_type_node, + byte_position(field_declaration)); + } + else + { + this->current_expression = error_mark_node; + } + } + else + { + error_at(get_location(&trait->position()), "Trait '%s' is unknown", trait->name.c_str()); + this->current_expression = error_mark_node; + } + } + + void generic_visitor::visit(frontend::field_access_expression *expression) + { + expression->base().accept(this); + location_t expression_location = get_location(&expression->position()); + tree aggregate_type = TREE_TYPE(this->current_expression); + + if (TREE_CODE(aggregate_type) == ARRAY_TYPE && expression->field() == "length") + { + this->current_expression = convert(build_qualified_type(elna_word_type_node, TYPE_QUAL_CONST), + TYPE_MAX_VALUE(TYPE_DOMAIN(aggregate_type))); + } + else if (TREE_CODE(aggregate_type) == ARRAY_TYPE && expression->field() == "ptr") + { + tree ptr_type = build_global_pointer_type(TREE_TYPE(aggregate_type)); + this->current_expression = build1(ADDR_EXPR, + build_qualified_type(ptr_type, TYPE_QUAL_CONST), this->current_expression); + } + else if (TREE_CODE(aggregate_type) == ENUMERAL_TYPE) + { + tree iterator{ NULL_TREE }; + + for (iterator = TYPE_VALUES(aggregate_type); iterator != NULL_TREE; iterator = TREE_CHAIN(iterator)) + { + if (IDENTIFIER_POINTER(TREE_PURPOSE(iterator)) == expression->field()) + { + this->current_expression = TREE_VALUE(iterator); + return; + } + } + this->current_expression = error_mark_node; + error_at(expression_location, "Unknown enumeration member '%s'", expression->field().c_str()); + } + else + { + tree field_declaration = find_field_by_name(expression_location, + TREE_TYPE(this->current_expression), expression->field()); + + if (field_declaration != error_mark_node) + { + this->current_expression = build3_loc(expression_location, COMPONENT_REF, + TREE_TYPE(field_declaration), this->current_expression, + field_declaration, NULL_TREE); + } + } + } + + void generic_visitor::visit(frontend::dereference_expression *expression) + { + expression->base().accept(this); + location_t expression_location = get_location(&expression->position()); + tree expression_type = TREE_TYPE(this->current_expression); + + if (POINTER_TYPE_P(expression_type)) + { + this->current_expression = build1_loc(expression_location, INDIRECT_REF, + TREE_TYPE(expression_type), this->current_expression); + } + else + { + error_at(expression_location, "Type '%s' cannot be dereferenced, it is not a pointer", + print_type(expression_type).c_str()); + this->current_expression = error_mark_node; + } + } + + void generic_visitor::visit(frontend::assign_statement *statement) + { + statement->lvalue().accept(this); + + tree lvalue = this->current_expression; + location_t statement_location = get_location(&statement->position()); + + statement->rvalue().accept(this); + tree rvalue = prepare_rvalue(this->current_expression); + + if (TREE_CODE(lvalue) == CONST_DECL) + { + error_at(statement_location, "Cannot modify constant '%s'", + statement->lvalue().is_variable()->name.c_str()); + } + else if (TYPE_READONLY(TREE_TYPE(lvalue))) + { + error_at(statement_location, "Cannot modify a constant expression of type '%s'", + print_type(TREE_TYPE(lvalue)).c_str()); + } + else if (is_assignable_from(TREE_TYPE(lvalue), rvalue)) + { + tree assignment = build2_loc(statement_location, MODIFY_EXPR, void_type_node, lvalue, rvalue); + + append_statement(assignment); + } + else + { + error_at(statement_location, "Cannot assign value of type '%s' to variable of type '%s'", + print_type(TREE_TYPE(rvalue)).c_str(), + print_type(TREE_TYPE(lvalue)).c_str()); + } + this->current_expression = NULL_TREE; + } + + void generic_visitor::visit(frontend::if_statement *statement) + { + tree endif_label_decl = create_artificial_label(UNKNOWN_LOCATION); + tree goto_endif = build1(GOTO_EXPR, void_type_node, endif_label_decl); + + make_if_branch(statement->body(), goto_endif); + + for (const auto branch : statement->branches) + { + make_if_branch(*branch, goto_endif); + } + if (statement->alternative != nullptr) + { + enter_scope(); + visit_statements(*statement->alternative); + tree mapping = leave_scope(); + append_statement(mapping); + } + tree endif_label_expr = build1(LABEL_EXPR, void_type_node, endif_label_decl); + append_statement(endif_label_expr); + this->current_expression = NULL_TREE; + } + + void generic_visitor::make_if_branch(frontend::conditional_statements& branch, tree goto_endif) + { + branch.prerequisite().accept(this); + + if (TREE_TYPE(this->current_expression) != elna_bool_type_node) + { + error_at(get_location(&branch.prerequisite().position()), + "Expected expression of boolean type but its type is %s", + print_type(TREE_TYPE(this->current_expression)).c_str()); + this->current_expression = error_mark_node; + return; + } + tree then_label_decl = build_label_decl("then", UNKNOWN_LOCATION); + tree goto_then = build1(GOTO_EXPR, void_type_node, then_label_decl); + + tree else_label_decl = build_label_decl("else", UNKNOWN_LOCATION); + tree goto_else = build1(GOTO_EXPR, void_type_node, else_label_decl); + + auto cond_expr = build3(COND_EXPR, void_type_node, this->current_expression, goto_then, goto_else); + append_statement(cond_expr); + + tree then_label_expr = build1(LABEL_EXPR, void_type_node, then_label_decl); + append_statement(then_label_expr); + enter_scope(); + + visit_statements(branch.statements); + tree mapping = leave_scope(); + append_statement(mapping); + append_statement(goto_endif); + + tree else_label_expr = build1(LABEL_EXPR, void_type_node, else_label_decl); + append_statement(else_label_expr); + } + + void generic_visitor::visit(frontend::import_declaration *) + { + } + + void generic_visitor::visit(frontend::while_statement *statement) + { + location_t prerequisite_location = get_location(&statement->body().prerequisite().position()); + tree prerequisite_label_decl = build_label_decl("while_do", prerequisite_location); + auto prerequisite_label_expr = build1_loc(prerequisite_location, LABEL_EXPR, + void_type_node, prerequisite_label_decl); + auto goto_check = build1(GOTO_EXPR, void_type_node, prerequisite_label_decl); + tree branch_end_declaration = build_label_decl("while_end", UNKNOWN_LOCATION); + tree branch_end_expression = build1_loc(UNKNOWN_LOCATION, LABEL_EXPR, void_type_node, branch_end_declaration); + + append_statement(prerequisite_label_expr); + make_if_branch(statement->body(), goto_check); + + for (const auto branch : statement->branches) + { + make_if_branch(*branch, goto_check); + } + append_statement(branch_end_expression); + this->current_expression = NULL_TREE; + } + + void generic_visitor::visit_statements(const std::vector<frontend::statement *>& statements) + { + for (frontend::statement *const statement : statements) + { + statement->accept(this); + + if (this->current_expression != NULL_TREE && this->current_expression != error_mark_node) + { + append_statement(this->current_expression); + this->current_expression = NULL_TREE; + } + } + } + + void generic_visitor::visit(frontend::return_statement *statement) + { + frontend::expression *return_expression = &statement->return_expression(); + location_t statement_position = get_location(&statement->position()); + tree set_result{ NULL_TREE }; + tree return_type = TREE_TYPE(TREE_TYPE(current_function_decl)); + + if (TREE_THIS_VOLATILE(current_function_decl) == 1) + { + error_at(statement_position, "This procedure is not allowed to return"); + return; + } + if (return_expression != nullptr) + { + return_expression->accept(this); + + set_result = build2(INIT_EXPR, void_type_node, DECL_RESULT(current_function_decl), + this->current_expression); + } + if (return_type == void_type_node && set_result != NULL_TREE) + { + error_at(statement_position, "Proper procedure is not allowed to return a value"); + } + else if (return_type != void_type_node && set_result == NULL_TREE) + { + error_at(statement_position, "Procedure is expected to return a value of type '%s'", + print_type(return_type).c_str()); + } + else if (return_type != void_type_node && !is_assignable_from(return_type, this->current_expression)) + { + error_at(statement_position, "Cannot return '%s' from a procedure returning '%s'", + print_type(return_type).c_str(), + print_type(TREE_TYPE(this->current_expression)).c_str()); + } + else + { + tree return_stmt = build1_loc(statement_position, RETURN_EXPR, void_type_node, set_result); + append_statement(return_stmt); + } + this->current_expression = NULL_TREE; + } + + void generic_visitor::visit(frontend::defer_statement *statement) + { + enter_scope(); + visit_statements(statement->statements); + defer(leave_scope()); + } + + void generic_visitor::visit(frontend::case_statement *statement) + { + statement->condition().accept(this); + tree condition_expression = this->current_expression; + tree unqualified_condition = get_qualified_type(TREE_TYPE(this->current_expression), TYPE_UNQUALIFIED); + + if (!INTEGRAL_TYPE_P(unqualified_condition)) + { + error_at(get_location(&statement->condition().position()), + "Case expressions can only be integral numbers, characters and enumerations, given '%s'", + print_type(unqualified_condition).c_str()); + this->current_expression = NULL_TREE; + return; + } + tree end_label_declaration = create_artificial_label(get_location(&statement->position())); + tree switch_statements = alloc_stmt_list(); + + for (const frontend::switch_case& case_block : statement->cases) + { + for (frontend::expression *const case_label : case_block.labels) + { + case_label->accept(this); + location_t case_location = get_location(&case_label->position()); + + if (assert_constant(case_location) + && !is_assignable_from(unqualified_condition, this->current_expression)) + { + error_at(case_location, "Case type '%s' does not match the expression type '%s'", + print_type(TREE_TYPE(this->current_expression)).c_str(), + print_type(unqualified_condition).c_str()); + this->current_expression = error_mark_node; + } + tree case_label_declaration = create_artificial_label(case_location); + tree case_expression = build_case_label(this->current_expression, NULL_TREE, case_label_declaration); + + append_to_statement_list(case_expression, &switch_statements); + } + enter_scope(); + visit_statements(case_block.statements); + append_to_statement_list(leave_scope(), &switch_statements); + tree goto_end = build1(GOTO_EXPR, void_type_node, end_label_declaration); + + append_to_statement_list(goto_end, &switch_statements); + TREE_USED(end_label_declaration) = 1; + } + if (statement->alternative != nullptr) + { + tree case_label_declaration = create_artificial_label(UNKNOWN_LOCATION); + tree case_expression = build_case_label(NULL_TREE, NULL_TREE, case_label_declaration); + + append_to_statement_list(case_expression, &switch_statements); + + enter_scope(); + visit_statements(*statement->alternative); + append_to_statement_list(leave_scope(), &switch_statements); + + TREE_USED(end_label_declaration) = 1; + } + tree switch_expression = build2(SWITCH_EXPR, TREE_TYPE(condition_expression), + condition_expression, switch_statements); + + append_statement(switch_expression); + + tree end_label_expression = build1(LABEL_EXPR, void_type_node, end_label_declaration); + append_statement(end_label_expression); + + this->current_expression = NULL_TREE; + } + + bool generic_visitor::assert_constant(location_t expression_location) + { + tree constant_expression = extract_constant(this->current_expression); + + if (constant_expression == NULL_TREE) + { + error_at(expression_location, "Expected a constant expression"); + this->current_expression = error_mark_node; + } + else + { + this->current_expression = constant_expression; + } + return this->current_expression != error_mark_node; + } +} |