From: Ian Lance Taylor Date: Thu, 3 Mar 2011 00:15:16 +0000 (+0000) Subject: Rewrite conversion of named types to backend representation. X-Git-Url: https://git.libre-soc.org/?a=commitdiff_plain;h=91349ecb122f1270f57617796fcfe0b597e997a2;p=gcc.git Rewrite conversion of named types to backend representation. From-SVN: r170627 --- diff --git a/gcc/go/gofrontend/expressions.cc b/gcc/go/gofrontend/expressions.cc index cebcbca7a07..ee486ffb27a 100644 --- a/gcc/go/gofrontend/expressions.cc +++ b/gcc/go/gofrontend/expressions.cc @@ -7013,6 +7013,8 @@ Builtin_call_expression::do_integer_constant_value(bool iota_is_constant, return false; if (arg_type->is_abstract()) return false; + if (arg_type->named_type() != NULL) + arg_type->named_type()->convert(this->gogo_); tree arg_type_tree = arg_type->get_tree(this->gogo_); if (arg_type_tree == error_mark_node) return false; @@ -7057,6 +7059,8 @@ Builtin_call_expression::do_integer_constant_value(bool iota_is_constant, Type* st = struct_expr->type(); if (st->struct_type() == NULL) return false; + if (st->named_type() != NULL) + st->named_type()->convert(this->gogo_); tree struct_tree = st->get_tree(this->gogo_); gcc_assert(TREE_CODE(struct_tree) == RECORD_TYPE); tree field = TYPE_FIELDS(struct_tree); @@ -8793,10 +8797,21 @@ Call_expression::do_get_tree(Translate_context* context) return error_mark_node; } - // This is to support builtin math functions when using 80387 math. tree fndecl = fn; if (TREE_CODE(fndecl) == ADDR_EXPR) fndecl = TREE_OPERAND(fndecl, 0); + + // Add a type cast in case the type of the function is a recursive + // type which refers to itself. + if (!DECL_P(fndecl) || !DECL_IS_BUILTIN(fndecl)) + { + tree fnt = fntype->get_tree(gogo); + if (fnt == error_mark_node) + return error_mark_node; + fn = fold_convert_loc(location, fnt, fn); + } + + // This is to support builtin math functions when using 80387 math. tree excess_type = NULL_TREE; if (DECL_P(fndecl) && DECL_IS_BUILTIN(fndecl) @@ -8842,7 +8857,7 @@ Call_expression::do_get_tree(Translate_context* context) // to the correct type. if (TREE_TYPE(ret) == ptr_type_node) { - tree t = this->type()->get_tree(gogo); + tree t = this->type()->base()->get_tree(gogo); ret = fold_convert_loc(location, t, ret); } diff --git a/gcc/go/gofrontend/go.cc b/gcc/go/gofrontend/go.cc index 2f30fd804b6..7b1fd7eccbb 100644 --- a/gcc/go/gofrontend/go.cc +++ b/gcc/go/gofrontend/go.cc @@ -118,9 +118,6 @@ go_parse_input_files(const char** filenames, unsigned int filename_count, // Export global identifiers as appropriate. ::gogo->do_exports(); - // Build required interface method tables. - ::gogo->build_interface_method_tables(); - // Turn short-cut operators (&&, ||) into explicit if statements. ::gogo->remove_shortcuts(); diff --git a/gcc/go/gofrontend/gogo-tree.cc b/gcc/go/gofrontend/gogo-tree.cc index 3228c42ec3b..722a23a52d7 100644 --- a/gcc/go/gofrontend/gogo-tree.cc +++ b/gcc/go/gofrontend/gogo-tree.cc @@ -640,6 +640,9 @@ sort_var_inits(Var_inits* var_inits) void Gogo::write_globals() { + this->convert_named_types(); + this->build_interface_method_tables(); + Bindings* bindings = this->current_bindings(); size_t count = bindings->size_definitions(); diff --git a/gcc/go/gofrontend/gogo.cc b/gcc/go/gofrontend/gogo.cc index a63abfefde3..bb2fcab8230 100644 --- a/gcc/go/gofrontend/gogo.cc +++ b/gcc/go/gofrontend/gogo.cc @@ -34,7 +34,8 @@ Gogo::Gogo(int int_type_size, int pointer_size) imported_init_fns_(), unique_prefix_(), unique_prefix_specified_(false), - interface_types_() + interface_types_(), + named_types_are_converted_(false) { const source_location loc = BUILTINS_LOCATION; @@ -1119,11 +1120,6 @@ class Verify_types : public Traverse int Verify_types::type(Type* t) { - // Don't verify types defined in other packages. - Named_type* nt = t->named_type(); - if (nt != NULL && nt->named_object()->package() != NULL) - return TRAVERSE_SKIP_COMPONENTS; - if (!t->verify()) return TRAVERSE_SKIP_COMPONENTS; return TRAVERSE_CONTINUE; @@ -2520,6 +2516,83 @@ Gogo::do_exports() this->package_->bindings()); } +// Find the blocks in order to convert named types defined in blocks. + +class Convert_named_types : public Traverse +{ + public: + Convert_named_types(Gogo* gogo) + : Traverse(traverse_blocks), + gogo_(gogo) + { } + + protected: + int + block(Block* block); + + private: + Gogo* gogo_; +}; + +int +Convert_named_types::block(Block* block) +{ + this->gogo_->convert_named_types_in_bindings(block->bindings()); + return TRAVERSE_CONTINUE; +} + +// Convert all named types to the backend representation. Since named +// types can refer to other types, this needs to be done in the right +// sequence, which is handled by Named_type::convert. Here we arrange +// to call that for each named type. + +void +Gogo::convert_named_types() +{ + this->convert_named_types_in_bindings(this->globals_); + for (Packages::iterator p = this->packages_.begin(); + p != this->packages_.end(); + ++p) + { + Package* package = p->second; + this->convert_named_types_in_bindings(package->bindings()); + } + + Convert_named_types cnt(this); + this->traverse(&cnt); + + // Make all the builtin named types used for type descriptors, and + // then convert them. They will only be written out if they are + // needed. + Type::make_type_descriptor_type(); + Type::make_type_descriptor_ptr_type(); + Function_type::make_function_type_descriptor_type(); + Pointer_type::make_pointer_type_descriptor_type(); + Struct_type::make_struct_type_descriptor_type(); + Array_type::make_array_type_descriptor_type(); + Array_type::make_slice_type_descriptor_type(); + Map_type::make_map_type_descriptor_type(); + Channel_type::make_chan_type_descriptor_type(); + Interface_type::make_interface_type_descriptor_type(); + Type::convert_builtin_named_types(this); + + this->named_types_are_converted_ = true; +} + +// Convert all names types in a set of bindings. + +void +Gogo::convert_named_types_in_bindings(Bindings* bindings) +{ + for (Bindings::const_definitions_iterator p = bindings->begin_definitions(); + p != bindings->end_definitions(); + ++p) + { + if ((*p)->is_type()) + (*p)->type_value()->convert(this); + } +} + // Class Function. Function::Function(Function_type* type, Function* enclosing, Block* block, diff --git a/gcc/go/gofrontend/gogo.h b/gcc/go/gofrontend/gogo.h index 57928d6600b..8db802ea53e 100644 --- a/gcc/go/gofrontend/gogo.h +++ b/gcc/go/gofrontend/gogo.h @@ -405,6 +405,20 @@ class Gogo void simplify_thunk_statements(); + // Convert named types to the backend representation. + void + convert_named_types(); + + // Convert named types in a list of bindings. + void + convert_named_types_in_bindings(Bindings*); + + // True if named types have been converted to the backend + // representation. + bool + named_types_are_converted() const + { return this->named_types_are_converted_; } + // Write out the global values. void write_globals(); @@ -661,6 +675,8 @@ class Gogo bool unique_prefix_specified_; // A list of interface types defined while parsing. std::vector interface_types_; + // Whether named types have been converted. + bool named_types_are_converted_; }; // A block of statements. diff --git a/gcc/go/gofrontend/types.cc b/gcc/go/gofrontend/types.cc index 3e149b93734..368ecae127a 100644 --- a/gcc/go/gofrontend/types.cc +++ b/gcc/go/gofrontend/types.cc @@ -835,8 +835,9 @@ Type::get_tree(Gogo* gogo) Type::type_trees.insert(val); if (!ins.second && ins.first->second != NULL_TREE) { - this->tree_ = ins.first->second; - return this->tree_; + if (gogo != NULL && gogo->named_types_are_converted()) + this->tree_ = ins.first->second; + return ins.first->second; } tree t = this->get_tree_without_hash(gogo); @@ -850,6 +851,8 @@ Type::get_tree(Gogo* gogo) // which in turns uses an identical unnamed type. Use the tree // we created earlier and ignore the one we just built. t = ins.first->second; + if (gogo == NULL || !gogo->named_types_are_converted()) + return t; this->tree_ = t; } @@ -874,6 +877,9 @@ Type::get_tree_without_hash(Gogo* gogo) if (t == ptr_type_node && this->forward_declaration_type() != NULL) return t; + if (gogo == NULL || !gogo->named_types_are_converted()) + return t; + this->tree_ = t; go_preserve_from_gc(t); } @@ -961,6 +967,10 @@ Type::make_builtin_struct_type(int nfields, ...) return Type::make_struct_type(sfl, bloc); } +// A list of builtin named types. + +std::vector Type::named_builtin_types; + // Make a builtin named type. Named_type* @@ -968,7 +978,25 @@ Type::make_builtin_named_type(const char* name, Type* type) { source_location bloc = BUILTINS_LOCATION; Named_object* no = Named_object::make_type(name, NULL, type, bloc); - return no->type_value(); + Named_type* ret = no->type_value(); + Type::named_builtin_types.push_back(ret); + return ret; +} + +// Convert the named builtin types. + +void +Type::convert_builtin_named_types(Gogo* gogo) +{ + for (std::vector::const_iterator p = + Type::named_builtin_types.begin(); + p != Type::named_builtin_types.end(); + ++p) + { + bool r = (*p)->verify(); + gcc_assert(r); + (*p)->convert(gogo); + } } // Return the type of a type descriptor. We should really tie this to @@ -3309,20 +3337,10 @@ Call_multiple_result_type::do_get_tree(Gogo* gogo) gcc_assert(fntype != NULL); const Typed_identifier_list* results = fntype->results(); gcc_assert(results != NULL && results->size() > 1); - - Struct_field_list* sfl = new Struct_field_list; - for (Typed_identifier_list::const_iterator p = results->begin(); - p != results->end(); - ++p) - { - const std::string name = ((p->name().empty() - || p->name() == Import::import_marker) - ? "UNNAMED" - : p->name()); - sfl->push_back(Struct_field(Typed_identifier(name, p->type(), - this->call_->location()))); - } - return Type::make_struct_type(sfl, this->call_->location())->get_tree(gogo); + tree fntype_tree = fntype->get_tree(gogo); + if (fntype_tree == error_mark_node) + return error_mark_node; + return TREE_TYPE(fntype_tree); } // Make a call result type. @@ -3782,7 +3800,6 @@ Struct_type::fill_in_tree(Gogo* gogo, tree type) { tree field_trees = NULL_TREE; tree* pp = &field_trees; - bool has_pointer = false; for (Struct_field_list::const_iterator p = this->fields_->begin(); p != this->fields_->end(); ++p) @@ -3790,20 +3807,10 @@ Struct_type::fill_in_tree(Gogo* gogo, tree type) std::string name = Gogo::unpack_hidden_name(p->field_name()); tree name_tree = get_identifier_with_length(name.data(), name.length()); - // Don't follow pointers yet, so that we don't get confused by a - // pointer to an array of this struct type. - tree field_type_tree; - if (p->type()->points_to() != NULL || p->type()->function_type() != NULL) - { - field_type_tree = ptr_type_node; - has_pointer = true; - } - else - { - field_type_tree = p->type()->get_tree(gogo); - if (field_type_tree == error_mark_node) - return error_mark_node; - } + tree field_type_tree = p->type()->get_tree(gogo); + if (field_type_tree == error_mark_node) + return error_mark_node; + gcc_assert(TYPE_SIZE(field_type_tree) != NULL_TREE); tree field = build_decl(p->location(), FIELD_DECL, name_tree, field_type_tree); @@ -3816,35 +3823,9 @@ Struct_type::fill_in_tree(Gogo* gogo, tree type) layout_type(type); - if (has_pointer) - { - tree field = field_trees; - for (Struct_field_list::const_iterator p = this->fields_->begin(); - p != this->fields_->end(); - ++p, field = DECL_CHAIN(field)) - { - if (p->type()->points_to() != NULL - || p->type()->function_type() != NULL) - TREE_TYPE(field) = p->type()->get_tree(gogo); - } - } - return type; } -// Make sure that all structs which must be converted to the backend -// representation before this one are in fact converted. - -void -Struct_type::convert_prerequisites(Gogo* gogo) -{ - for (std::vector::const_iterator p - = this->prerequisites_.begin(); - p != this->prerequisites_.end(); - ++p) - (*p)->get_tree(gogo); -} - // Initialize struct fields. tree @@ -4487,6 +4468,8 @@ Array_type::fill_in_array_tree(Gogo* gogo, tree array_type) || length_tree == error_mark_node) return error_mark_node; + 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 @@ -6074,70 +6057,86 @@ tree Interface_type::do_get_tree(Gogo* gogo) { if (this->methods_ == NULL) + return Interface_type::empty_type_tree(gogo); + else { - // At the tree level, use the same type for all empty - // interfaces. This lets us assign them to each other directly - // without triggering GIMPLE type errors. - tree dtype = Type::make_type_descriptor_type()->get_tree(gogo); - dtype = build_pointer_type(build_qualified_type(dtype, TYPE_QUAL_CONST)); - static tree empty_interface; - return Gogo::builtin_struct(&empty_interface, "__go_empty_interface", - NULL_TREE, 2, - "__type_descriptor", - dtype, - "__object", - ptr_type_node); + tree t = Interface_type::non_empty_type_tree(this->location_); + return this->fill_in_tree(gogo, t); } - - return this->fill_in_tree(gogo, make_node(RECORD_TYPE)); } -// Fill in the tree for an interface type. This is used for named -// interface types. +// Return a singleton struct for an empty interface type. We use the +// same type for all empty interfaces. This lets us assign them to +// each other directly without triggering GIMPLE type errors. tree -Interface_type::fill_in_tree(Gogo* gogo, tree type) +Interface_type::empty_type_tree(Gogo* gogo) { - gcc_assert(this->methods_ != NULL); + static tree empty_interface; + if (empty_interface != NULL_TREE) + return empty_interface; + + tree dtype = Type::make_type_descriptor_type()->get_tree(gogo); + dtype = build_pointer_type(build_qualified_type(dtype, TYPE_QUAL_CONST)); + return Gogo::builtin_struct(&empty_interface, "__go_empty_interface", + NULL_TREE, 2, + "__type_descriptor", + dtype, + "__object", + ptr_type_node); +} - // Because the methods may refer to the interface type itself, we - // need to build the interface type first, and then update the - // method pointer later. +// Return a new struct for a non-empty interface type. The correct +// values are filled in by fill_in_tree. + +tree +Interface_type::non_empty_type_tree(source_location location) +{ + tree ret = make_node(RECORD_TYPE); tree field_trees = NULL_TREE; tree* pp = &field_trees; tree name_tree = get_identifier("__methods"); - tree methods_field = build_decl(this->location_, FIELD_DECL, name_tree, - ptr_type_node); - DECL_CONTEXT(methods_field) = type; - *pp = methods_field; - pp = &DECL_CHAIN(methods_field); + tree field = build_decl(location, FIELD_DECL, name_tree, ptr_type_node); + DECL_CONTEXT(field) = ret; + *pp = field; + pp = &DECL_CHAIN(field); name_tree = get_identifier("__object"); - tree field = build_decl(this->location_, FIELD_DECL, name_tree, - ptr_type_node); - DECL_CONTEXT(field) = type; + field = build_decl(location, FIELD_DECL, name_tree, ptr_type_node); + DECL_CONTEXT(field) = ret; *pp = field; - TYPE_FIELDS(type) = field_trees; + TYPE_FIELDS(ret) = field_trees; - layout_type(type); + layout_type(ret); + + return ret; +} + +// Fill in the tree for an interface type. This is used for named +// interface types. + +tree +Interface_type::fill_in_tree(Gogo* gogo, tree type) +{ + gcc_assert(this->methods_ != NULL); // Build the type of the table of methods. tree method_table = make_node(RECORD_TYPE); // The first field is a pointer to the type descriptor. - name_tree = get_identifier("__type_descriptor"); + tree name_tree = get_identifier("__type_descriptor"); tree dtype = Type::make_type_descriptor_type()->get_tree(gogo); dtype = build_pointer_type(build_qualified_type(dtype, TYPE_QUAL_CONST)); - field = build_decl(this->location_, FIELD_DECL, name_tree, dtype); + tree field = build_decl(this->location_, FIELD_DECL, name_tree, dtype); DECL_CONTEXT(field) = method_table; TYPE_FIELDS(method_table) = field; std::string last_name = ""; - pp = &DECL_CHAIN(field); + tree* pp = &DECL_CHAIN(field); for (Typed_identifier_list::const_iterator p = this->methods_->begin(); p != this->methods_->end(); ++p) @@ -6159,7 +6158,10 @@ Interface_type::fill_in_tree(Gogo* gogo, tree type) // Update the type of the __methods field from a generic pointer to // a pointer to the method table. - TREE_TYPE(methods_field) = build_pointer_type(method_table); + field = TYPE_FIELDS(type); + gcc_assert(strcmp(IDENTIFIER_POINTER(DECL_NAME(field)), "__methods") == 0); + + TREE_TYPE(field) = build_pointer_type(method_table); return type; } @@ -6876,7 +6878,7 @@ Named_type::named_type_has_hidden_fields(std::string* reason) const class Find_type_use : public Traverse { public: - Find_type_use(Type* find_type) + Find_type_use(Named_type* find_type) : Traverse(traverse_types), find_type_(find_type), found_(false) { } @@ -6892,7 +6894,7 @@ class Find_type_use : public Traverse private: // The type we are looking for. - Type* find_type_; + Named_type* find_type_; // Whether we found the type. bool found_; }; @@ -6902,11 +6904,12 @@ class Find_type_use : public Traverse int Find_type_use::type(Type* type) { - if (this->find_type_ == type) + if (type->named_type() != NULL && this->find_type_ == type->named_type()) { this->found_ = true; return TRAVERSE_EXIT; } + // It's OK if we see a reference to the type in any type which is // essentially a pointer: a pointer, a slice, a function, a map, or // a channel. @@ -6940,6 +6943,42 @@ Find_type_use::type(Type* type) return TRAVERSE_SKIP_COMPONENTS; } + // Otherwise, FIND_TYPE_ depends on TYPE, in the sense that we need + // to convert TYPE to the backend representation before we convert + // FIND_TYPE_. + if (type->named_type() != NULL) + { + switch (type->base()->classification()) + { + case Type::TYPE_ERROR: + case Type::TYPE_BOOLEAN: + case Type::TYPE_INTEGER: + case Type::TYPE_FLOAT: + case Type::TYPE_COMPLEX: + case Type::TYPE_STRING: + case Type::TYPE_NIL: + break; + + case Type::TYPE_ARRAY: + case Type::TYPE_STRUCT: + this->find_type_->add_dependency(type->named_type()); + break; + + case Type::TYPE_VOID: + case Type::TYPE_SINK: + case Type::TYPE_FUNCTION: + case Type::TYPE_POINTER: + case Type::TYPE_CALL_MULTIPLE_RESULT: + case Type::TYPE_MAP: + case Type::TYPE_CHANNEL: + case Type::TYPE_INTERFACE: + case Type::TYPE_NAMED: + case Type::TYPE_FORWARD: + default: + gcc_unreachable(); + } + } + return TRAVERSE_CONTINUE; } @@ -6995,36 +7034,6 @@ Named_type::do_verify() return false; } - // If this is a struct, then if any of the fields of the struct - // themselves have struct type, or array of struct type, then this - // struct must be converted to the backend representation before the - // field's type is converted. That may seem backward, but it works - // because if the field's type refers to this one, e.g., via a - // pointer, then the conversion process will pick up the half-built - // struct and do the right thing. - if (this->struct_type() != NULL) - { - const Struct_field_list* fields = this->struct_type()->fields(); - for (Struct_field_list::const_iterator p = fields->begin(); - p != fields->end(); - ++p) - { - Struct_type* st = p->type()->struct_type(); - if (st != NULL) - st->add_prerequisite(this); - else - { - Array_type* at = p->type()->array_type(); - if (at != NULL && !at->is_open_array_type()) - { - st = at->element_type()->struct_type(); - if (st != NULL) - st->add_prerequisite(this); - } - } - } - } - return true; } @@ -7074,21 +7083,109 @@ Named_type::do_hash_for_method(Gogo* gogo) const return ret; } -// Get a tree for a named type. +// Convert a named type to the backend representation. In order to +// get dependencies right, we fill in a dummy structure for this type, +// then convert all the dependencies, then complete this type. When +// this function is complete, the size of the type is known. -tree -Named_type::do_get_tree(Gogo* gogo) +void +Named_type::convert(Gogo* gogo) +{ + if (this->is_error_ || this->is_converted_) + return; + + this->create_placeholder(gogo); + + // Convert all the dependencies. If they refer indirectly back to + // this type, they will pick up the intermediate tree we just + // created. + for (std::vector::const_iterator p = this->dependencies_.begin(); + p != this->dependencies_.end(); + ++p) + (*p)->convert(gogo); + + // Complete this type. + tree t = this->named_tree_; + Type* base = this->type_->base(); + switch (base->classification()) + { + case TYPE_VOID: + case TYPE_BOOLEAN: + case TYPE_INTEGER: + case TYPE_FLOAT: + case TYPE_COMPLEX: + case TYPE_STRING: + case TYPE_NIL: + break; + + case TYPE_MAP: + case TYPE_CHANNEL: + break; + + case TYPE_FUNCTION: + case TYPE_POINTER: + // The size of these types is already correct. + break; + + case TYPE_STRUCT: + t = base->struct_type()->fill_in_tree(gogo, t); + break; + + case TYPE_ARRAY: + if (!base->is_open_array_type()) + t = base->array_type()->fill_in_array_tree(gogo, t); + break; + + case TYPE_INTERFACE: + if (!base->interface_type()->is_empty()) + t = base->interface_type()->fill_in_tree(gogo, t); + break; + + case TYPE_ERROR: + return; + + default: + case TYPE_SINK: + case TYPE_CALL_MULTIPLE_RESULT: + case TYPE_NAMED: + case TYPE_FORWARD: + gcc_unreachable(); + } + + this->named_tree_ = t; + + if (t == error_mark_node) + this->is_error_ = true; + else + gcc_assert(TYPE_SIZE(t) != NULL_TREE); + + this->is_converted_ = true; +} + +// Create the placeholder for a named type. This is the first step in +// converting to the backend representation. + +void +Named_type::create_placeholder(Gogo* gogo) { if (this->is_error_) - return error_mark_node; + this->named_tree_ = error_mark_node; - // Go permits types to refer to themselves in various ways. Break - // the recursion here. + if (this->named_tree_ != NULL_TREE) + return; + + // Create the structure for this type. Note that because we call + // base() here, we don't attempt to represent a named type defined + // as another named type. Instead both named types will point to + // different base representations. + Type* base = this->type_->base(); tree t; - switch (this->type_->forwarded()->classification()) + switch (base->classification()) { case TYPE_ERROR: - return error_mark_node; + this->is_error_ = true; + this->named_tree_ = error_mark_node; + return; case TYPE_VOID: case TYPE_BOOLEAN: @@ -7097,163 +7194,194 @@ Named_type::do_get_tree(Gogo* gogo) case TYPE_COMPLEX: case TYPE_STRING: case TYPE_NIL: - // These types can not refer to themselves. - case TYPE_MAP: - case TYPE_CHANNEL: - // All maps and channels have the same type in GENERIC. - t = Type::get_named_type_tree(gogo, this->type_); + // These are simple basic types, we can just create them + // directly. + t = Type::get_named_type_tree(gogo, base); if (t == error_mark_node) - return error_mark_node; - // Build a copy to set TYPE_NAME. + { + this->is_error_ = true; + this->named_tree_ = error_mark_node; + return; + } t = build_variant_type_copy(t); break; - case TYPE_FUNCTION: - // GENERIC can't handle a pointer to a function type whose - // return type is a pointer to the function type itself. It - // goes into an infinite loop when walking the types. - if (this->seen_ > 0) + case TYPE_MAP: + case TYPE_CHANNEL: + // All maps and channels have the same type in GENERIC. + t = Type::get_named_type_tree(gogo, base); + if (t == error_mark_node) { - Function_type* fntype = this->type_->function_type(); - if (fntype->results() != NULL - && fntype->results()->size() == 1 - && fntype->results()->front().type()->forwarded() == this) - return ptr_type_node; - - // We can legitimately see ourselves here twice when a named - // type is defined using a struct which refers to the named - // type. If we see ourselves too often we are in a loop. - if (this->seen_ > 3) - return ptr_type_node; + this->is_error_ = true; + this->named_tree_ = error_mark_node; + return; } - ++this->seen_; - t = Type::get_named_type_tree(gogo, this->type_); - --this->seen_; - if (t == error_mark_node) - return error_mark_node; t = build_variant_type_copy(t); break; + case TYPE_FUNCTION: case TYPE_POINTER: - // Don't recur infinitely if a pointer type refers to itself. - // Ideally we would build a circular data structure here, but - // GENERIC can't handle them. - if (this->seen_ > 0) - { - if (this->type_->points_to()->forwarded() == this) - return ptr_type_node; - - if (this->seen_ > 3) - return ptr_type_node; - } - ++this->seen_; - t = Type::get_named_type_tree(gogo, this->type_); - --this->seen_; - if (t == error_mark_node) - return error_mark_node; - t = build_variant_type_copy(t); + t = build_variant_type_copy(ptr_type_node); break; case TYPE_STRUCT: - // If there are structs which must be converted first, do them. - if (this->seen_ == 0) - { - ++this->seen_; - this->type_->struct_type()->convert_prerequisites(gogo); - --this->seen_; - } - - if (this->named_tree_ != NULL_TREE) - return this->named_tree_; - t = make_node(RECORD_TYPE); - this->named_tree_ = t; - t = this->type_->struct_type()->fill_in_tree(gogo, t); - if (t == error_mark_node) - { - this->named_tree_ = error_mark_node; - return error_mark_node; - } break; case TYPE_ARRAY: - if (this->named_tree_ != NULL_TREE) - return this->named_tree_; - if (!this->is_open_array_type()) - { - t = make_node(ARRAY_TYPE); - this->named_tree_ = t; - t = this->type_->array_type()->fill_in_array_tree(gogo, t); - } + if (base->is_open_array_type()) + t = gogo->slice_type_tree(void_type_node); else - { - t = gogo->slice_type_tree(void_type_node); - this->named_tree_ = t; - t = this->type_->array_type()->fill_in_slice_tree(gogo, t); - } - if (t == error_mark_node) - return error_mark_node; - t = build_variant_type_copy(t); + t = make_node(ARRAY_TYPE); break; case TYPE_INTERFACE: - if (this->type_->interface_type()->is_empty()) + if (base->interface_type()->is_empty()) { - t = Type::get_named_type_tree(gogo, this->type_); - if (t == error_mark_node) - return error_mark_node; + t = Interface_type::empty_type_tree(gogo); t = build_variant_type_copy(t); } else { - if (this->named_tree_ != NULL_TREE) - return this->named_tree_; - t = make_node(RECORD_TYPE); - this->named_tree_ = t; - t = this->type_->interface_type()->fill_in_tree(gogo, t); - if (t == error_mark_node) - { - this->named_tree_ = error_mark_node; - return error_mark_node; - } + source_location loc = base->interface_type()->location(); + t = Interface_type::non_empty_type_tree(loc); } break; - case TYPE_NAMED: - { - // When a named type T1 is defined as another named type T2, - // the definition must simply be "type T1 T2". If the - // definition of T2 may refer to T1, then we must simply - // return the type for T2 here. It's not precisely correct, - // but it's as close as we can get with GENERIC. - ++this->seen_; - t = Type::get_named_type_tree(gogo, this->type_); - --this->seen_; - if (this->seen_ > 0) - return t; - if (t == error_mark_node) - return error_mark_node; - t = build_variant_type_copy(t); - } - break; - - case TYPE_FORWARD: - // An undefined forwarding type. Make sure the error is - // emitted. - this->type_->forward_declaration_type()->real_type(); - return error_mark_node; - default: case TYPE_SINK: case TYPE_CALL_MULTIPLE_RESULT: + case TYPE_NAMED: + case TYPE_FORWARD: gcc_unreachable(); } + // Create the named type. + tree id = this->named_object_->get_id(gogo); tree decl = build_decl(this->location_, TYPE_DECL, id, t); TYPE_NAME(t) = decl; - return t; + this->named_tree_ = t; +} + +// Get a tree for a named type. + +tree +Named_type::do_get_tree(Gogo* gogo) +{ + if (this->is_error_) + return error_mark_node; + + tree t = this->named_tree_; + + // FIXME: GOGO can be NULL when called from go_type_for_size, which + // is only used for basic types. + if (gogo == NULL || !gogo->named_types_are_converted()) + { + // We have not completed converting named types. NAMED_TREE_ is + // a placeholder and we shouldn't do anything further. + if (t != NULL_TREE) + return t; + + // We don't build dependencies for types whose sizes do not + // change or are not relevant, so we may see them here while + // converting types. + this->create_placeholder(gogo); + t = this->named_tree_; + gcc_assert(t != NULL_TREE); + return t; + } + + // We are not converting types. This should only be called if the + // type has already been converted. + gcc_assert(this->is_converted_); + gcc_assert(t != NULL_TREE && TYPE_SIZE(t) != NULL_TREE); + + // Complete the tree. + Type* base = this->type_->base(); + tree t1; + switch (base->classification()) + { + case TYPE_ERROR: + return error_mark_node; + + case TYPE_VOID: + case TYPE_BOOLEAN: + case TYPE_INTEGER: + case TYPE_FLOAT: + case TYPE_COMPLEX: + case TYPE_STRING: + case TYPE_NIL: + case TYPE_MAP: + case TYPE_CHANNEL: + case TYPE_STRUCT: + case TYPE_INTERFACE: + return t; + + case TYPE_FUNCTION: + // Don't build a circular data structure. GENERIC can't handle + // it. + if (this->seen_ > 0) + { + this->is_circular_ = true; + return ptr_type_node; + } + ++this->seen_; + t1 = Type::get_named_type_tree(gogo, base); + --this->seen_; + if (t1 == error_mark_node) + return error_mark_node; + if (this->is_circular_) + t1 = ptr_type_node; + gcc_assert(t != NULL_TREE && TREE_CODE(t) == POINTER_TYPE); + gcc_assert(TREE_CODE(t1) == POINTER_TYPE); + TREE_TYPE(t) = TREE_TYPE(t1); + return t; + + case TYPE_POINTER: + // Don't build a circular data structure. GENERIC can't handle + // it. + if (this->seen_ > 0) + { + this->is_circular_ = true; + return ptr_type_node; + } + ++this->seen_; + t1 = Type::get_named_type_tree(gogo, base); + --this->seen_; + if (t1 == error_mark_node) + return error_mark_node; + if (this->is_circular_) + t1 = ptr_type_node; + gcc_assert(t != NULL_TREE && TREE_CODE(t) == POINTER_TYPE); + gcc_assert(TREE_CODE(t1) == POINTER_TYPE); + TREE_TYPE(t) = TREE_TYPE(t1); + return t; + + case TYPE_ARRAY: + if (base->is_open_array_type()) + { + if (this->seen_ > 0) + return t; + else + { + ++this->seen_; + t = base->array_type()->fill_in_slice_tree(gogo, t); + --this->seen_; + } + } + return t; + + default: + case TYPE_SINK: + case TYPE_CALL_MULTIPLE_RESULT: + case TYPE_NAMED: + case TYPE_FORWARD: + gcc_unreachable(); + } + + gcc_unreachable(); } // Build a type descriptor for a named type. diff --git a/gcc/go/gofrontend/types.h b/gcc/go/gofrontend/types.h index b0dbefed455..8e91dfcab07 100644 --- a/gcc/go/gofrontend/types.h +++ b/gcc/go/gofrontend/types.h @@ -799,6 +799,10 @@ class Type check_make_expression(Expression_list* args, source_location location) { return this->do_check_make_expression(args, location); } + // Convert the builtin named types. + static void + convert_builtin_named_types(Gogo*); + // Return a tree representing this type. tree get_tree(Gogo*); @@ -1082,6 +1086,9 @@ class Type static Type_trees type_trees; + // A list of builtin named types. + static std::vector named_builtin_types; + // The type classification. Type_classification classification_; // The tree representation of the type, once it has been determined. @@ -1605,6 +1612,9 @@ class Function_type : public Type Function_type* copy_with_receiver(Type*) const; + static Type* + make_function_type_descriptor_type(); + protected: int do_traverse(Traverse*); @@ -1636,9 +1646,6 @@ class Function_type : public Type do_export(Export*) const; private: - static Type* - make_function_type_descriptor_type(); - Expression* type_descriptor_params(Type*, const Typed_identifier*, const Typed_identifier_list*); @@ -1680,6 +1687,9 @@ class Pointer_type : public Type static Pointer_type* do_import(Import*); + static Type* + make_pointer_type_descriptor_type(); + protected: int do_traverse(Traverse*); @@ -1710,9 +1720,6 @@ class Pointer_type : public Type do_export(Export*) const; private: - static Type* - make_pointer_type_descriptor_type(); - // The type to which this type points. Type* to_type_; }; @@ -1841,8 +1848,7 @@ class Struct_type : public Type public: Struct_type(Struct_field_list* fields, source_location location) : Type(TYPE_STRUCT), - fields_(fields), location_(location), all_methods_(NULL), - prerequisites_() + fields_(fields), location_(location), all_methods_(NULL) { } // Return the field NAME. This only looks at local fields, not at @@ -1937,16 +1943,8 @@ class Struct_type : public Type tree fill_in_tree(Gogo*, tree); - // Note that a struct must be converted to the backend - // representation before we convert this struct. - void - add_prerequisite(Named_type* nt) - { this->prerequisites_.push_back(nt); } - - // If there are any structs which must be converted to the backend - // representation before this one, convert them. - void - convert_prerequisites(Gogo*); + static Type* + make_struct_type_descriptor_type(); protected: int @@ -1992,25 +1990,12 @@ class Struct_type : public Type source_location, Saw_named_type*, unsigned int* depth) const; - static Type* - make_struct_type_descriptor_type(); - // The fields of the struct. Struct_field_list* fields_; // The place where the struct was declared. source_location location_; // If this struct is unnamed, a list of methods. Methods* all_methods_; - // A list of structs which must be converted to the backend - // representation before this struct can be converted. This is for - // cases like - // type S1 { p *S2 } - // type S2 { s S1 } - // where we must start converting S2 before we start converting S1. - // That is because we can fully convert S1 before S2 is complete, - // but we can not fully convert S2 before S1 is complete. If we - // start converting S1 first, we won't be able to convert S2. - std::vector prerequisites_; }; // The type of an array. @@ -2066,6 +2051,12 @@ class Array_type : public Type tree fill_in_slice_tree(Gogo*, tree); + static Type* + make_array_type_descriptor_type(); + + static Type* + make_slice_type_descriptor_type(); + protected: int do_traverse(Traverse* traverse); @@ -2114,12 +2105,6 @@ class Array_type : public Type tree get_length_tree(Gogo*); - Type* - make_array_type_descriptor_type(); - - Type* - make_slice_type_descriptor_type(); - Expression* array_type_descriptor(Gogo*, Named_type*); @@ -2162,6 +2147,9 @@ class Map_type : public Type static Map_type* do_import(Import*); + static Type* + make_map_type_descriptor_type(); + protected: int do_traverse(Traverse*); @@ -2202,9 +2190,6 @@ class Map_type : public Type do_export(Export*) const; private: - static Type* - make_map_type_descriptor_type(); - // The key type. Type* key_type_; // The value type. @@ -2248,6 +2233,9 @@ class Channel_type : public Type static Channel_type* do_import(Import*); + static Type* + make_chan_type_descriptor_type(); + protected: int do_traverse(Traverse* traverse) @@ -2286,9 +2274,6 @@ class Channel_type : public Type do_export(Export*) const; private: - static Type* - make_chan_type_descriptor_type(); - // Whether this channel can send data. bool may_send_; // Whether this channel can receive data. @@ -2308,6 +2293,11 @@ class Interface_type : public Type methods_(methods), location_(location) { gcc_assert(methods == NULL || !methods->empty()); } + // The location where the interface type was defined. + source_location + location() const + { return this->location_; } + // Return whether this is an empty interface. bool is_empty() const @@ -2361,10 +2351,21 @@ class Interface_type : public Type static Interface_type* do_import(Import*); + // Make a struct for an empty interface type. + static tree + empty_type_tree(Gogo*); + + // Make a struct for non-empty interface type. + static tree + non_empty_type_tree(source_location); + // Fill in the fields for a named interface type. tree fill_in_tree(Gogo*, tree); + static Type* + make_interface_type_descriptor_type(); + protected: int do_traverse(Traverse*); @@ -2395,9 +2396,6 @@ class Interface_type : public Type do_export(Export*) const; private: - static Type* - make_interface_type_descriptor_type(); - // The list of methods associated with the interface. This will be // NULL for the empty interface. Typed_identifier_list* methods_; @@ -2419,8 +2417,9 @@ class Named_type : public Type named_object_(named_object), in_function_(NULL), type_(type), local_methods_(NULL), all_methods_(NULL), interface_method_tables_(NULL), pointer_interface_method_tables_(NULL), - location_(location), named_tree_(NULL), is_visible_(true), - is_error_(false), seen_(0) + location_(location), named_tree_(NULL), dependencies_(), + is_visible_(true), is_error_(false), is_converted_(false), + is_circular_(false), seen_(0) { } // Return the associated Named_object. This holds the actual name. @@ -2493,6 +2492,12 @@ class Named_type : public Type is_builtin() const { return this->location_ == BUILTINS_LOCATION; } + // Whether this is a circular type: a pointer or function type that + // refers to itself, which is not possible in C. + bool + is_circular() const + { return this->is_circular_; } + // Return the base type for this type. Type* named_base(); @@ -2567,6 +2572,12 @@ class Named_type : public Type bool named_type_has_hidden_fields(std::string* reason) const; + // Note that a type must be converted to the backend representation + // before we convert this type. + void + add_dependency(Named_type* nt) + { this->dependencies_.push_back(nt); } + // Export the type. void export_named_type(Export*, const std::string& name) const; @@ -2575,6 +2586,10 @@ class Named_type : public Type static void import_named_type(Import*, Named_type**); + // Initial conversion to backend representation. + void + convert(Gogo*); + protected: int do_traverse(Traverse* traverse) @@ -2618,6 +2633,10 @@ class Named_type : public Type do_export(Export*) const; private: + // Create the placeholder during conversion. + void + create_placeholder(Gogo*); + // A mapping from interfaces to the associated interface method // tables for this type. This maps to a decl. typedef Unordered_map_hash(const Interface_type*, tree, Type_hash_identical, @@ -2647,6 +2666,14 @@ class Named_type : public Type // The tree for this type while converting to GENERIC. This is used // to avoid endless recursion when a named type refers to itself. tree named_tree_; + // A list of types which must be converted to the backend + // representation before this type can be converted. This is for + // cases like + // type S1 { p *S2 } + // type S2 { s S1 } + // where we can't convert S2 to the backend representation unless we + // have converted S1. + std::vector dependencies_; // Whether this type is visible. This is false if this type was // created because it was referenced by an imported object, but the // type itself was not exported. This will always be true for types @@ -2654,6 +2681,12 @@ class Named_type : public Type bool is_visible_; // Whether this type is erroneous. bool is_error_; + // Whether this type has been converted to the backend + // representation. + bool is_converted_; + // Whether this is a pointer or function type which refers to the + // type itself. + bool is_circular_; // In a recursive operation such as has_hidden_fields, this flag is // used to prevent infinite recursion when a type refers to itself. // This is mutable because it is always reset to false when the