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// go-gcc.cc -- Go frontend to gcc IR. // Copyright (C) 2011, 2012 Free Software Foundation, Inc. // Contributed by Ian Lance Taylor, Google. // This file is part of GCC. // 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 "go-system.h" // This has to be included outside of extern "C", so we have to // include it here before tree.h includes it later. #include <gmp.h> #ifndef ENABLE_BUILD_WITH_CXX extern "C" { #endif #include "tree.h" #include "tree-iterator.h" #include "gimple.h" #include "toplev.h" #ifndef ENABLE_BUILD_WITH_CXX } #endif #include "go-c.h" #include "gogo.h" #include "backend.h" // A class wrapping a tree. class Gcc_tree { public: Gcc_tree(tree t) : t_(t) { } tree get_tree() const { return this->t_; } private: tree t_; }; // In gcc, types, expressions, and statements are all trees. class Btype : public Gcc_tree { public: Btype(tree t) : Gcc_tree(t) { } }; class Bexpression : public Gcc_tree { public: Bexpression(tree t) : Gcc_tree(t) { } }; class Bstatement : public Gcc_tree { public: Bstatement(tree t) : Gcc_tree(t) { } }; class Bfunction : public Gcc_tree { public: Bfunction(tree t) : Gcc_tree(t) { } }; class Bblock : public Gcc_tree { public: Bblock(tree t) : Gcc_tree(t) { } }; class Bvariable : public Gcc_tree { public: Bvariable(tree t) : Gcc_tree(t) { } }; class Blabel : public Gcc_tree { public: Blabel(tree t) : Gcc_tree(t) { } }; // This file implements the interface between the Go frontend proper // and the gcc IR. This implements specific instantiations of // abstract classes defined by the Go frontend proper. The Go // frontend proper class methods of these classes to generate the // backend representation. class Gcc_backend : public Backend { public: // Types. Btype* error_type() { return this->make_type(error_mark_node); } Btype* void_type() { return this->make_type(void_type_node); } Btype* bool_type() { return this->make_type(boolean_type_node); } Btype* integer_type(bool, int); Btype* float_type(int); Btype* complex_type(int); Btype* pointer_type(Btype*); Btype* function_type(const Btyped_identifier&, const std::vector<Btyped_identifier>&, const std::vector<Btyped_identifier>&, const Location); Btype* struct_type(const std::vector<Btyped_identifier>&); Btype* array_type(Btype*, Bexpression*); Btype* placeholder_pointer_type(const std::string&, Location, bool); bool set_placeholder_pointer_type(Btype*, Btype*); bool set_placeholder_function_type(Btype*, Btype*); Btype* placeholder_struct_type(const std::string&, Location); bool set_placeholder_struct_type(Btype* placeholder, const std::vector<Btyped_identifier>&); Btype* placeholder_array_type(const std::string&, Location); bool set_placeholder_array_type(Btype*, Btype*, Bexpression*); Btype* named_type(const std::string&, Btype*, Location); Btype* circular_pointer_type(Btype*, bool); bool is_circular_pointer_type(Btype*); size_t type_size(Btype*); size_t type_alignment(Btype*); size_t type_field_alignment(Btype*); size_t type_field_offset(Btype*, size_t index); // Expressions. Bexpression* zero_expression(Btype*); // Statements. Bstatement* error_statement() { return this->make_statement(error_mark_node); } Bstatement* expression_statement(Bexpression*); Bstatement* init_statement(Bvariable* var, Bexpression* init); Bstatement* assignment_statement(Bexpression* lhs, Bexpression* rhs, Location); Bstatement* return_statement(Bfunction*, const std::vector<Bexpression*>&, Location); Bstatement* if_statement(Bexpression* condition, Bblock* then_block, Bblock* else_block, Location); Bstatement* switch_statement(Bexpression* value, const std::vector<std::vector<Bexpression*> >& cases, const std::vector<Bstatement*>& statements, Location); Bstatement* compound_statement(Bstatement*, Bstatement*); Bstatement* statement_list(const std::vector<Bstatement*>&); // Blocks. Bblock* block(Bfunction*, Bblock*, const std::vector<Bvariable*>&, Location, Location); void block_add_statements(Bblock*, const std::vector<Bstatement*>&); Bstatement* block_statement(Bblock*); // Variables. Bvariable* error_variable() { return new Bvariable(error_mark_node); } Bvariable* global_variable(const std::string& package_name, const std::string& unique_prefix, const std::string& name, Btype* btype, bool is_external, bool is_hidden, Location location); void global_variable_set_init(Bvariable*, Bexpression*); Bvariable* local_variable(Bfunction*, const std::string&, Btype*, bool, Location); Bvariable* parameter_variable(Bfunction*, const std::string&, Btype*, bool, Location); Bvariable* temporary_variable(Bfunction*, Bblock*, Btype*, Bexpression*, bool, Location, Bstatement**); Bvariable* immutable_struct(const std::string&, bool, Btype*, Location); void immutable_struct_set_init(Bvariable*, const std::string&, bool, Btype*, Location, Bexpression*); Bvariable* immutable_struct_reference(const std::string&, Btype*, Location); // Labels. Blabel* label(Bfunction*, const std::string& name, Location); Bstatement* label_definition_statement(Blabel*); Bstatement* goto_statement(Blabel*, Location); Bexpression* label_address(Blabel*, Location); private: // Make a Bexpression from a tree. Bexpression* make_expression(tree t) { return new Bexpression(t); } // Make a Bstatement from a tree. Bstatement* make_statement(tree t) { return new Bstatement(t); } // Make a Btype from a tree. Btype* make_type(tree t) { return new Btype(t); } Btype* fill_in_struct(Btype*, const std::vector<Btyped_identifier>&); Btype* fill_in_array(Btype*, Btype*, Bexpression*); }; // A helper function. static inline tree get_identifier_from_string(const std::string& str) { return get_identifier_with_length(str.data(), str.length()); } // Get an unnamed integer type. Btype* Gcc_backend::integer_type(bool is_unsigned, int bits) { tree type; if (is_unsigned) { if (bits == INT_TYPE_SIZE) type = unsigned_type_node; else if (bits == CHAR_TYPE_SIZE) type = unsigned_char_type_node; else if (bits == SHORT_TYPE_SIZE) type = short_unsigned_type_node; else if (bits == LONG_TYPE_SIZE) type = long_unsigned_type_node; else if (bits == LONG_LONG_TYPE_SIZE) type = long_long_unsigned_type_node; else type = make_unsigned_type(bits); } else { if (bits == INT_TYPE_SIZE) type = integer_type_node; else if (bits == CHAR_TYPE_SIZE) type = signed_char_type_node; else if (bits == SHORT_TYPE_SIZE) type = short_integer_type_node; else if (bits == LONG_TYPE_SIZE) type = long_integer_type_node; else if (bits == LONG_LONG_TYPE_SIZE) type = long_long_integer_type_node; else type = make_signed_type(bits); } return this->make_type(type); } // Get an unnamed float type. Btype* Gcc_backend::float_type(int bits) { tree type; if (bits == FLOAT_TYPE_SIZE) type = float_type_node; else if (bits == DOUBLE_TYPE_SIZE) type = double_type_node; else if (bits == LONG_DOUBLE_TYPE_SIZE) type = long_double_type_node; else { type = make_node(REAL_TYPE); TYPE_PRECISION(type) = bits; layout_type(type); } return this->make_type(type); } // Get an unnamed complex type. Btype* Gcc_backend::complex_type(int bits) { tree type; if (bits == FLOAT_TYPE_SIZE * 2) type = complex_float_type_node; else if (bits == DOUBLE_TYPE_SIZE * 2) type = complex_double_type_node; else if (bits == LONG_DOUBLE_TYPE_SIZE * 2) type = complex_long_double_type_node; else { type = make_node(REAL_TYPE); TYPE_PRECISION(type) = bits / 2; layout_type(type); type = build_complex_type(type); } return this->make_type(type); } // Get a pointer type. Btype* Gcc_backend::pointer_type(Btype* to_type) { tree to_type_tree = to_type->get_tree(); if (to_type_tree == error_mark_node) return this->error_type(); tree type = build_pointer_type(to_type_tree); return this->make_type(type); } // Make a function type. Btype* Gcc_backend::function_type(const Btyped_identifier& receiver, const std::vector<Btyped_identifier>& parameters, const std::vector<Btyped_identifier>& results, Location location) { tree args = NULL_TREE; tree* pp = &args; if (receiver.btype != NULL) { tree t = receiver.btype->get_tree(); if (t == error_mark_node) return this->error_type(); *pp = tree_cons(NULL_TREE, t, NULL_TREE); pp = &TREE_CHAIN(*pp); } for (std::vector<Btyped_identifier>::const_iterator p = parameters.begin(); p != parameters.end(); ++p) { tree t = p->btype->get_tree(); if (t == error_mark_node) return this->error_type(); *pp = tree_cons(NULL_TREE, t, NULL_TREE); pp = &TREE_CHAIN(*pp); } // Varargs is handled entirely at the Go level. When converted to // GENERIC functions are not varargs. *pp = void_list_node; tree result; if (results.empty()) result = void_type_node; else if (results.size() == 1) result = results.front().btype->get_tree(); else { result = make_node(RECORD_TYPE); tree field_trees = NULL_TREE; pp = &field_trees; for (std::vector<Btyped_identifier>::const_iterator p = results.begin(); p != results.end(); ++p) { const std::string name = (p->name.empty() ? "UNNAMED" : p->name); tree name_tree = get_identifier_from_string(name); tree field_type_tree = p->btype->get_tree(); if (field_type_tree == error_mark_node) return this->error_type(); gcc_assert(TYPE_SIZE(field_type_tree) != NULL_TREE); tree field = build_decl(location.gcc_location(), FIELD_DECL, name_tree, field_type_tree); DECL_CONTEXT(field) = result; *pp = field; pp = &DECL_CHAIN(field); } TYPE_FIELDS(result) = field_trees; layout_type(result); } if (result == error_mark_node) return this->error_type(); tree fntype = build_function_type(result, args); if (fntype == error_mark_node) return this->error_type(); return this->make_type(build_pointer_type(fntype)); } // Make a struct type. Btype* Gcc_backend::struct_type(const std::vector<Btyped_identifier>& fields) { return this->fill_in_struct(this->make_type(make_node(RECORD_TYPE)), fields); } // Fill in the fields of a struct type. Btype* Gcc_backend::fill_in_struct(Btype* fill, const std::vector<Btyped_identifier>& fields) { tree fill_tree = fill->get_tree(); tree field_trees = NULL_TREE; tree* pp = &field_trees; for (std::vector<Btyped_identifier>::const_iterator p = fields.begin(); p != fields.end(); ++p) { tree name_tree = get_identifier_from_string(p->name); tree type_tree = p->btype->get_tree(); if (type_tree == error_mark_node) return this->error_type(); tree field = build_decl(p->location.gcc_location(), FIELD_DECL, name_tree, type_tree); DECL_CONTEXT(field) = fill_tree; *pp = field; pp = &DECL_CHAIN(field); } TYPE_FIELDS(fill_tree) = field_trees; layout_type(fill_tree); return fill; } // Make an array type. Btype* Gcc_backend::array_type(Btype* element_btype, Bexpression* length) { return this->fill_in_array(this->make_type(make_node(ARRAY_TYPE)), element_btype, length); } // Fill in an array type. Btype* Gcc_backend::fill_in_array(Btype* fill, Btype* element_type, Bexpression* length) { tree element_type_tree = element_type->get_tree(); tree length_tree = length->get_tree(); if (element_type_tree == error_mark_node || length_tree == error_mark_node) return this->error_type(); gcc_assert(TYPE_SIZE(element_type_tree) != NULL_TREE); length_tree = fold_convert(sizetype, length_tree); // build_index_type takes the maximum index, which is one less than // the length. tree index_type_tree = build_index_type(fold_build2(MINUS_EXPR, sizetype, length_tree, size_one_node)); tree fill_tree = fill->get_tree(); TREE_TYPE(fill_tree) = element_type_tree; TYPE_DOMAIN(fill_tree) = index_type_tree; TYPE_ADDR_SPACE(fill_tree) = TYPE_ADDR_SPACE(element_type_tree); layout_type(fill_tree); if (TYPE_STRUCTURAL_EQUALITY_P(element_type_tree)) SET_TYPE_STRUCTURAL_EQUALITY(fill_tree); else if (TYPE_CANONICAL(element_type_tree) != element_type_tree || TYPE_CANONICAL(index_type_tree) != index_type_tree) TYPE_CANONICAL(fill_tree) = build_array_type(TYPE_CANONICAL(element_type_tree), TYPE_CANONICAL(index_type_tree)); return fill; } // Create a placeholder for a pointer type. Btype* Gcc_backend::placeholder_pointer_type(const std::string& name, Location location, bool) { tree ret = build_distinct_type_copy(ptr_type_node); if (!name.empty()) { tree decl = build_decl(location.gcc_location(), TYPE_DECL, get_identifier_from_string(name), ret); TYPE_NAME(ret) = decl; } return this->make_type(ret); } // Set the real target type for a placeholder pointer type. bool Gcc_backend::set_placeholder_pointer_type(Btype* placeholder, Btype* to_type) { tree pt = placeholder->get_tree(); if (pt == error_mark_node) return false; gcc_assert(TREE_CODE(pt) == POINTER_TYPE); tree tt = to_type->get_tree(); if (tt == error_mark_node) { TREE_TYPE(pt) = tt; return false; } gcc_assert(TREE_CODE(tt) == POINTER_TYPE); TREE_TYPE(pt) = TREE_TYPE(tt); if (TYPE_NAME(pt) != NULL_TREE) { // Build the data structure gcc wants to see for a typedef. tree copy = build_variant_type_copy(pt); TYPE_NAME(copy) = NULL_TREE; DECL_ORIGINAL_TYPE(TYPE_NAME(pt)) = copy; } return true; } // Set the real values for a placeholder function type. bool Gcc_backend::set_placeholder_function_type(Btype* placeholder, Btype* ft) { return this->set_placeholder_pointer_type(placeholder, ft); } // Create a placeholder for a struct type. Btype* Gcc_backend::placeholder_struct_type(const std::string& name, Location location) { tree ret = make_node(RECORD_TYPE); if (!name.empty()) { tree decl = build_decl(location.gcc_location(), TYPE_DECL, get_identifier_from_string(name), ret); TYPE_NAME(ret) = decl; } return this->make_type(ret); } // Fill in the fields of a placeholder struct type. bool Gcc_backend::set_placeholder_struct_type( Btype* placeholder, const std::vector<Btyped_identifier>& fields) { tree t = placeholder->get_tree(); gcc_assert(TREE_CODE(t) == RECORD_TYPE && TYPE_FIELDS(t) == NULL_TREE); Btype* r = this->fill_in_struct(placeholder, fields); if (TYPE_NAME(t) != NULL_TREE) { // Build the data structure gcc wants to see for a typedef. tree copy = build_distinct_type_copy(t); TYPE_NAME(copy) = NULL_TREE; DECL_ORIGINAL_TYPE(TYPE_NAME(t)) = copy; } return r->get_tree() != error_mark_node; } // Create a placeholder for an array type. Btype* Gcc_backend::placeholder_array_type(const std::string& name, Location location) { tree ret = make_node(ARRAY_TYPE); tree decl = build_decl(location.gcc_location(), TYPE_DECL, get_identifier_from_string(name), ret); TYPE_NAME(ret) = decl; return this->make_type(ret); } // Fill in the fields of a placeholder array type. bool Gcc_backend::set_placeholder_array_type(Btype* placeholder, Btype* element_btype, Bexpression* length) { tree t = placeholder->get_tree(); gcc_assert(TREE_CODE(t) == ARRAY_TYPE && TREE_TYPE(t) == NULL_TREE); Btype* r = this->fill_in_array(placeholder, element_btype, length); // Build the data structure gcc wants to see for a typedef. tree copy = build_distinct_type_copy(t); TYPE_NAME(copy) = NULL_TREE; DECL_ORIGINAL_TYPE(TYPE_NAME(t)) = copy; return r->get_tree() != error_mark_node; } // Return a named version of a type. Btype* Gcc_backend::named_type(const std::string& name, Btype* btype, Location location) { tree type = btype->get_tree(); if (type == error_mark_node) return this->error_type(); // The middle-end expects a basic type to have a name. In Go every // basic type will have a name. The first time we see a basic type, // give it whatever Go name we have at this point. if (TYPE_NAME(type) == NULL_TREE && location.gcc_location() == BUILTINS_LOCATION && (TREE_CODE(type) == INTEGER_TYPE || TREE_CODE(type) == REAL_TYPE || TREE_CODE(type) == COMPLEX_TYPE || TREE_CODE(type) == BOOLEAN_TYPE)) { tree decl = build_decl(BUILTINS_LOCATION, TYPE_DECL, get_identifier_from_string(name), type); TYPE_NAME(type) = decl; return this->make_type(type); } tree copy = build_variant_type_copy(type); tree decl = build_decl(location.gcc_location(), TYPE_DECL, get_identifier_from_string(name), copy); DECL_ORIGINAL_TYPE(decl) = type; TYPE_NAME(copy) = decl; return this->make_type(copy); } // Return a pointer type used as a marker for a circular type. Btype* Gcc_backend::circular_pointer_type(Btype*, bool) { return this->make_type(ptr_type_node); } // Return whether we might be looking at a circular type. bool Gcc_backend::is_circular_pointer_type(Btype* btype) { return btype->get_tree() == ptr_type_node; } // Return the size of a type. size_t Gcc_backend::type_size(Btype* btype) { tree t = btype->get_tree(); if (t == error_mark_node) return 1; t = TYPE_SIZE_UNIT(t); gcc_assert(TREE_CODE(t) == INTEGER_CST); gcc_assert(TREE_INT_CST_HIGH(t) == 0); unsigned HOST_WIDE_INT val_wide = TREE_INT_CST_LOW(t); size_t ret = static_cast<size_t>(val_wide); gcc_assert(ret == val_wide); return ret; } // Return the alignment of a type. size_t Gcc_backend::type_alignment(Btype* btype) { tree t = btype->get_tree(); if (t == error_mark_node) return 1; return TYPE_ALIGN_UNIT(t); } // Return the alignment of a struct field of type BTYPE. size_t Gcc_backend::type_field_alignment(Btype* btype) { tree t = btype->get_tree(); if (t == error_mark_node) return 1; return go_field_alignment(t); } // Return the offset of a field in a struct. size_t Gcc_backend::type_field_offset(Btype* btype, size_t index) { tree struct_tree = btype->get_tree(); if (struct_tree == error_mark_node) return 0; gcc_assert(TREE_CODE(struct_tree) == RECORD_TYPE); tree field = TYPE_FIELDS(struct_tree); for (; index > 0; --index) { field = DECL_CHAIN(field); gcc_assert(field != NULL_TREE); } HOST_WIDE_INT offset_wide = int_byte_position(field); gcc_assert(offset_wide >= 0); size_t ret = static_cast<size_t>(offset_wide); gcc_assert(ret == static_cast<unsigned HOST_WIDE_INT>(offset_wide)); return ret; } // Return the zero value for a type. Bexpression* Gcc_backend::zero_expression(Btype* btype) { tree t = btype->get_tree(); tree ret; if (t == error_mark_node) ret = error_mark_node; else ret = build_zero_cst(t); return tree_to_expr(ret); } // An expression as a statement. Bstatement* Gcc_backend::expression_statement(Bexpression* expr) { return this->make_statement(expr->get_tree()); } // Variable initialization. Bstatement* Gcc_backend::init_statement(Bvariable* var, Bexpression* init) { tree var_tree = var->get_tree(); tree init_tree = init->get_tree(); if (var_tree == error_mark_node || init_tree == error_mark_node) return this->error_statement(); gcc_assert(TREE_CODE(var_tree) == VAR_DECL); DECL_INITIAL(var_tree) = init_tree; return this->make_statement(build1_loc(DECL_SOURCE_LOCATION(var_tree), DECL_EXPR, void_type_node, var_tree)); } // Assignment. Bstatement* Gcc_backend::assignment_statement(Bexpression* lhs, Bexpression* rhs, Location location) { tree lhs_tree = lhs->get_tree(); tree rhs_tree = rhs->get_tree(); if (lhs_tree == error_mark_node || rhs_tree == error_mark_node) return this->error_statement(); return this->make_statement(fold_build2_loc(location.gcc_location(), MODIFY_EXPR, void_type_node, lhs_tree, rhs_tree)); } // Return. Bstatement* Gcc_backend::return_statement(Bfunction* bfunction, const std::vector<Bexpression*>& vals, Location location) { tree fntree = bfunction->get_tree(); if (fntree == error_mark_node) return this->error_statement(); tree result = DECL_RESULT(fntree); if (result == error_mark_node) return this->error_statement(); tree ret; if (vals.empty()) ret = fold_build1_loc(location.gcc_location(), RETURN_EXPR, void_type_node, NULL_TREE); else if (vals.size() == 1) { tree val = vals.front()->get_tree(); if (val == error_mark_node) return this->error_statement(); tree set = fold_build2_loc(location.gcc_location(), MODIFY_EXPR, void_type_node, result, vals.front()->get_tree()); ret = fold_build1_loc(location.gcc_location(), RETURN_EXPR, void_type_node, set); } else { // To return multiple values, copy the values into a temporary // variable of the right structure type, and then assign the // temporary variable to the DECL_RESULT in the return // statement. tree stmt_list = NULL_TREE; tree rettype = TREE_TYPE(result); tree rettmp = create_tmp_var(rettype, "RESULT"); tree field = TYPE_FIELDS(rettype); for (std::vector<Bexpression*>::const_iterator p = vals.begin(); p != vals.end(); p++, field = DECL_CHAIN(field)) { gcc_assert(field != NULL_TREE); tree ref = fold_build3_loc(location.gcc_location(), COMPONENT_REF, TREE_TYPE(field), rettmp, field, NULL_TREE); tree val = (*p)->get_tree(); if (val == error_mark_node) return this->error_statement(); tree set = fold_build2_loc(location.gcc_location(), MODIFY_EXPR, void_type_node, ref, (*p)->get_tree()); append_to_statement_list(set, &stmt_list); } gcc_assert(field == NULL_TREE); tree set = fold_build2_loc(location.gcc_location(), MODIFY_EXPR, void_type_node, result, rettmp); tree ret_expr = fold_build1_loc(location.gcc_location(), RETURN_EXPR, void_type_node, set); append_to_statement_list(ret_expr, &stmt_list); ret = stmt_list; } return this->make_statement(ret); } // If. Bstatement* Gcc_backend::if_statement(Bexpression* condition, Bblock* then_block, Bblock* else_block, Location location) { tree cond_tree = condition->get_tree(); tree then_tree = then_block->get_tree(); tree else_tree = else_block == NULL ? NULL_TREE : else_block->get_tree(); if (cond_tree == error_mark_node || then_tree == error_mark_node || else_tree == error_mark_node) return this->error_statement(); tree ret = build3_loc(location.gcc_location(), COND_EXPR, void_type_node, cond_tree, then_tree, else_tree); return this->make_statement(ret); } // Switch. Bstatement* Gcc_backend::switch_statement( Bexpression* value, const std::vector<std::vector<Bexpression*> >& cases, const std::vector<Bstatement*>& statements, Location switch_location) { gcc_assert(cases.size() == statements.size()); tree stmt_list = NULL_TREE; std::vector<std::vector<Bexpression*> >::const_iterator pc = cases.begin(); for (std::vector<Bstatement*>::const_iterator ps = statements.begin(); ps != statements.end(); ++ps, ++pc) { if (pc->empty()) { source_location loc = (*ps != NULL ? EXPR_LOCATION((*ps)->get_tree()) : UNKNOWN_LOCATION); tree label = create_artificial_label(loc); tree c = build_case_label(NULL_TREE, NULL_TREE, label); append_to_statement_list(c, &stmt_list); } else { for (std::vector<Bexpression*>::const_iterator pcv = pc->begin(); pcv != pc->end(); ++pcv) { tree t = (*pcv)->get_tree(); if (t == error_mark_node) return this->error_statement(); source_location loc = EXPR_LOCATION(t); tree label = create_artificial_label(loc); tree c = build_case_label((*pcv)->get_tree(), NULL_TREE, label); append_to_statement_list(c, &stmt_list); } } if (*ps != NULL) { tree t = (*ps)->get_tree(); if (t == error_mark_node) return this->error_statement(); append_to_statement_list(t, &stmt_list); } } tree tv = value->get_tree(); if (tv == error_mark_node) return this->error_statement(); tree t = build3_loc(switch_location.gcc_location(), SWITCH_EXPR, void_type_node, tv, stmt_list, NULL_TREE); return this->make_statement(t); } // Pair of statements. Bstatement* Gcc_backend::compound_statement(Bstatement* s1, Bstatement* s2) { tree stmt_list = NULL_TREE; tree t = s1->get_tree(); if (t == error_mark_node) return this->error_statement(); append_to_statement_list(t, &stmt_list); t = s2->get_tree(); if (t == error_mark_node) return this->error_statement(); append_to_statement_list(t, &stmt_list); return this->make_statement(stmt_list); } // List of statements. Bstatement* Gcc_backend::statement_list(const std::vector<Bstatement*>& statements) { tree stmt_list = NULL_TREE; for (std::vector<Bstatement*>::const_iterator p = statements.begin(); p != statements.end(); ++p) { tree t = (*p)->get_tree(); if (t == error_mark_node) return this->error_statement(); append_to_statement_list(t, &stmt_list); } return this->make_statement(stmt_list); } // Make a block. For some reason gcc uses a dual structure for // blocks: BLOCK tree nodes and BIND_EXPR tree nodes. Since the // BIND_EXPR node points to the BLOCK node, we store the BIND_EXPR in // the Bblock. Bblock* Gcc_backend::block(Bfunction* function, Bblock* enclosing, const std::vector<Bvariable*>& vars, Location start_location, Location) { tree block_tree = make_node(BLOCK); if (enclosing == NULL) { // FIXME: Permitting FUNCTION to be NULL is a temporary measure // until we have a proper representation of the init function. tree fndecl; if (function == NULL) fndecl = current_function_decl; else fndecl = function->get_tree(); gcc_assert(fndecl != NULL_TREE); // We may have already created a block for local variables when // we take the address of a parameter. if (DECL_INITIAL(fndecl) == NULL_TREE) { BLOCK_SUPERCONTEXT(block_tree) = fndecl; DECL_INITIAL(fndecl) = block_tree; } else { tree superblock_tree = DECL_INITIAL(fndecl); BLOCK_SUPERCONTEXT(block_tree) = superblock_tree; tree* pp; for (pp = &BLOCK_SUBBLOCKS(superblock_tree); *pp != NULL_TREE; pp = &BLOCK_CHAIN(*pp)) ; *pp = block_tree; } } else { tree superbind_tree = enclosing->get_tree(); tree superblock_tree = BIND_EXPR_BLOCK(superbind_tree); gcc_assert(TREE_CODE(superblock_tree) == BLOCK); BLOCK_SUPERCONTEXT(block_tree) = superblock_tree; tree* pp; for (pp = &BLOCK_SUBBLOCKS(superblock_tree); *pp != NULL_TREE; pp = &BLOCK_CHAIN(*pp)) ; *pp = block_tree; } tree* pp = &BLOCK_VARS(block_tree); for (std::vector<Bvariable*>::const_iterator pv = vars.begin(); pv != vars.end(); ++pv) { *pp = (*pv)->get_tree(); if (*pp != error_mark_node) pp = &DECL_CHAIN(*pp); } *pp = NULL_TREE; TREE_USED(block_tree) = 1; tree bind_tree = build3_loc(start_location.gcc_location(), BIND_EXPR, void_type_node, BLOCK_VARS(block_tree), NULL_TREE, block_tree); TREE_SIDE_EFFECTS(bind_tree) = 1; return new Bblock(bind_tree); } // Add statements to a block. void Gcc_backend::block_add_statements(Bblock* bblock, const std::vector<Bstatement*>& statements) { tree stmt_list = NULL_TREE; for (std::vector<Bstatement*>::const_iterator p = statements.begin(); p != statements.end(); ++p) { tree s = (*p)->get_tree(); if (s != error_mark_node) append_to_statement_list(s, &stmt_list); } tree bind_tree = bblock->get_tree(); gcc_assert(TREE_CODE(bind_tree) == BIND_EXPR); BIND_EXPR_BODY(bind_tree) = stmt_list; } // Return a block as a statement. Bstatement* Gcc_backend::block_statement(Bblock* bblock) { tree bind_tree = bblock->get_tree(); gcc_assert(TREE_CODE(bind_tree) == BIND_EXPR); return this->make_statement(bind_tree); } // Make a global variable. Bvariable* Gcc_backend::global_variable(const std::string& package_name, const std::string& unique_prefix, const std::string& name, Btype* btype, bool is_external, bool is_hidden, Location location) { tree type_tree = btype->get_tree(); if (type_tree == error_mark_node) return this->error_variable(); std::string var_name(package_name); var_name.push_back('.'); var_name.append(name); tree decl = build_decl(location.gcc_location(), VAR_DECL, get_identifier_from_string(var_name), type_tree); if (is_external) DECL_EXTERNAL(decl) = 1; else TREE_STATIC(decl) = 1; if (!is_hidden) { TREE_PUBLIC(decl) = 1; std::string asm_name(unique_prefix); asm_name.push_back('.'); asm_name.append(var_name); SET_DECL_ASSEMBLER_NAME(decl, get_identifier_from_string(asm_name)); } TREE_USED(decl) = 1; go_preserve_from_gc(decl); return new Bvariable(decl); } // Set the initial value of a global variable. void Gcc_backend::global_variable_set_init(Bvariable* var, Bexpression* expr) { tree expr_tree = expr->get_tree(); if (expr_tree == error_mark_node) return; gcc_assert(TREE_CONSTANT(expr_tree)); tree var_decl = var->get_tree(); if (var_decl == error_mark_node) return; DECL_INITIAL(var_decl) = expr_tree; } // Make a local variable. Bvariable* Gcc_backend::local_variable(Bfunction* function, const std::string& name, Btype* btype, bool is_address_taken, Location location) { tree type_tree = btype->get_tree(); if (type_tree == error_mark_node) return this->error_variable(); tree decl = build_decl(location.gcc_location(), VAR_DECL, get_identifier_from_string(name), type_tree); DECL_CONTEXT(decl) = function->get_tree(); TREE_USED(decl) = 1; if (is_address_taken) TREE_ADDRESSABLE(decl) = 1; go_preserve_from_gc(decl); return new Bvariable(decl); } // Make a function parameter variable. Bvariable* Gcc_backend::parameter_variable(Bfunction* function, const std::string& name, Btype* btype, bool is_address_taken, Location location) { tree type_tree = btype->get_tree(); if (type_tree == error_mark_node) return this->error_variable(); tree decl = build_decl(location.gcc_location(), PARM_DECL, get_identifier_from_string(name), type_tree); DECL_CONTEXT(decl) = function->get_tree(); DECL_ARG_TYPE(decl) = type_tree; TREE_USED(decl) = 1; if (is_address_taken) TREE_ADDRESSABLE(decl) = 1; go_preserve_from_gc(decl); return new Bvariable(decl); } // Make a temporary variable. Bvariable* Gcc_backend::temporary_variable(Bfunction* function, Bblock* bblock, Btype* btype, Bexpression* binit, bool is_address_taken, Location location, Bstatement** pstatement) { tree type_tree = btype->get_tree(); tree init_tree = binit == NULL ? NULL_TREE : binit->get_tree(); if (type_tree == error_mark_node || init_tree == error_mark_node) { *pstatement = this->error_statement(); return this->error_variable(); } tree var; // We can only use create_tmp_var if the type is not addressable. if (!TREE_ADDRESSABLE(type_tree)) var = create_tmp_var(type_tree, "GOTMP"); else { gcc_assert(bblock != NULL); var = build_decl(location.gcc_location(), VAR_DECL, create_tmp_var_name("GOTMP"), type_tree); DECL_ARTIFICIAL(var) = 1; DECL_IGNORED_P(var) = 1; TREE_USED(var) = 1; // FIXME: Permitting function to be NULL here is a temporary // measure until we have a proper representation of the init // function. if (function != NULL) DECL_CONTEXT(var) = function->get_tree(); else { gcc_assert(current_function_decl != NULL_TREE); DECL_CONTEXT(var) = current_function_decl; } // We have to add this variable to the BLOCK and the BIND_EXPR. tree bind_tree = bblock->get_tree(); gcc_assert(TREE_CODE(bind_tree) == BIND_EXPR); tree block_tree = BIND_EXPR_BLOCK(bind_tree); gcc_assert(TREE_CODE(block_tree) == BLOCK); DECL_CHAIN(var) = BLOCK_VARS(block_tree); BLOCK_VARS(block_tree) = var; BIND_EXPR_VARS(bind_tree) = BLOCK_VARS(block_tree); } if (init_tree != NULL_TREE) DECL_INITIAL(var) = fold_convert_loc(location.gcc_location(), type_tree, init_tree); if (is_address_taken) TREE_ADDRESSABLE(var) = 1; *pstatement = this->make_statement(build1_loc(location.gcc_location(), DECL_EXPR, void_type_node, var)); return new Bvariable(var); } // Create a named immutable initialized data structure. Bvariable* Gcc_backend::immutable_struct(const std::string& name, bool, Btype* btype, Location location) { tree type_tree = btype->get_tree(); if (type_tree == error_mark_node) return this->error_variable(); gcc_assert(TREE_CODE(type_tree) == RECORD_TYPE); tree decl = build_decl(location.gcc_location(), VAR_DECL, get_identifier_from_string(name), build_qualified_type(type_tree, TYPE_QUAL_CONST)); TREE_STATIC(decl) = 1; TREE_READONLY(decl) = 1; TREE_CONSTANT(decl) = 1; TREE_USED(decl) = 1; DECL_ARTIFICIAL(decl) = 1; // We don't call rest_of_decl_compilation until we have the // initializer. go_preserve_from_gc(decl); return new Bvariable(decl); } // Set the initializer for a variable created by immutable_struct. // This is where we finish compiling the variable. void Gcc_backend::immutable_struct_set_init(Bvariable* var, const std::string&, bool is_common, Btype*, Location, Bexpression* initializer) { tree decl = var->get_tree(); tree init_tree = initializer->get_tree(); if (decl == error_mark_node || init_tree == error_mark_node) return; DECL_INITIAL(decl) = init_tree; // We can't call make_decl_one_only until we set DECL_INITIAL. if (!is_common) TREE_PUBLIC(decl) = 1; else { make_decl_one_only(decl, DECL_ASSEMBLER_NAME(decl)); resolve_unique_section(decl, 1, 0); } rest_of_decl_compilation(decl, 1, 0); } // Return a reference to an immutable initialized data structure // defined in another package. Bvariable* Gcc_backend::immutable_struct_reference(const std::string& name, Btype* btype, Location location) { tree type_tree = btype->get_tree(); if (type_tree == error_mark_node) return this->error_variable(); gcc_assert(TREE_CODE(type_tree) == RECORD_TYPE); tree decl = build_decl(location.gcc_location(), VAR_DECL, get_identifier_from_string(name), build_qualified_type(type_tree, TYPE_QUAL_CONST)); TREE_READONLY(decl) = 1; TREE_CONSTANT(decl) = 1; DECL_ARTIFICIAL(decl) = 1; TREE_PUBLIC(decl) = 1; DECL_EXTERNAL(decl) = 1; go_preserve_from_gc(decl); return new Bvariable(decl); } // Make a label. Blabel* Gcc_backend::label(Bfunction* function, const std::string& name, Location location) { tree decl; if (name.empty()) decl = create_artificial_label(location.gcc_location()); else { tree id = get_identifier_from_string(name); decl = build_decl(location.gcc_location(), LABEL_DECL, id, void_type_node); DECL_CONTEXT(decl) = function->get_tree(); } return new Blabel(decl); } // Make a statement which defines a label. Bstatement* Gcc_backend::label_definition_statement(Blabel* label) { tree lab = label->get_tree(); tree ret = fold_build1_loc(DECL_SOURCE_LOCATION(lab), LABEL_EXPR, void_type_node, lab); return this->make_statement(ret); } // Make a goto statement. Bstatement* Gcc_backend::goto_statement(Blabel* label, Location location) { tree lab = label->get_tree(); tree ret = fold_build1_loc(location.gcc_location(), GOTO_EXPR, void_type_node, lab); return this->make_statement(ret); } // Get the address of a label. Bexpression* Gcc_backend::label_address(Blabel* label, Location location) { tree lab = label->get_tree(); TREE_USED(lab) = 1; TREE_ADDRESSABLE(lab) = 1; tree ret = fold_convert_loc(location.gcc_location(), ptr_type_node, build_fold_addr_expr_loc(location.gcc_location(), lab)); return this->make_expression(ret); } // The single backend. static Gcc_backend gcc_backend; // Return the backend generator. Backend* go_get_backend() { return &gcc_backend; } // FIXME: Temporary functions while converting to the new backend // interface. Btype* tree_to_type(tree t) { return new Btype(t); } Bexpression* tree_to_expr(tree t) { return new Bexpression(t); } Bstatement* tree_to_stat(tree t) { return new Bstatement(t); } Bfunction* tree_to_function(tree t) { return new Bfunction(t); } Bblock* tree_to_block(tree t) { gcc_assert(TREE_CODE(t) == BIND_EXPR); return new Bblock(t); } tree type_to_tree(Btype* bt) { return bt->get_tree(); } tree expr_to_tree(Bexpression* be) { return be->get_tree(); } tree stat_to_tree(Bstatement* bs) { return bs->get_tree(); } tree block_to_tree(Bblock* bb) { return bb->get_tree(); } tree var_to_tree(Bvariable* bv) { return bv->get_tree(); }