Mercurial > hg > CbC > CbC_gcc
view gcc/go/gofrontend/gogo.cc @ 145:1830386684a0
gcc-9.2.0
| author | anatofuz |
|---|---|
| date | Thu, 13 Feb 2020 11:34:05 +0900 |
| parents | 84e7813d76e9 |
| children |
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// gogo.cc -- Go frontend parsed representation. // Copyright 2009 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. #include "go-system.h" #include <fstream> #include "filenames.h" #include "go-c.h" #include "go-diagnostics.h" #include "go-encode-id.h" #include "go-dump.h" #include "go-optimize.h" #include "lex.h" #include "types.h" #include "statements.h" #include "expressions.h" #include "runtime.h" #include "import.h" #include "export.h" #include "backend.h" #include "gogo.h" // Class Gogo. Gogo::Gogo(Backend* backend, Linemap* linemap, int, int pointer_size) : backend_(backend), linemap_(linemap), package_(NULL), functions_(), globals_(new Bindings(NULL)), file_block_names_(), imports_(), imported_unsafe_(false), current_file_imported_unsafe_(false), packages_(), init_functions_(), var_deps_(), need_init_fn_(false), init_fn_name_(), imported_init_fns_(), pkgpath_(), pkgpath_symbol_(), prefix_(), pkgpath_set_(false), pkgpath_from_option_(false), prefix_from_option_(false), relative_import_path_(), c_header_(), check_divide_by_zero_(true), check_divide_overflow_(true), compiling_runtime_(false), debug_escape_level_(0), debug_optimization_(false), nil_check_size_threshold_(4096), verify_types_(), interface_types_(), specific_type_functions_(), specific_type_functions_are_written_(false), named_types_are_converted_(false), analysis_sets_(), gc_roots_(), type_descriptors_(), imported_inlinable_functions_(), imported_inline_functions_() { const Location loc = Linemap::predeclared_location(); Named_type* uint8_type = Type::make_integer_type("uint8", true, 8, RUNTIME_TYPE_KIND_UINT8); this->add_named_type(uint8_type); this->add_named_type(Type::make_integer_type("uint16", true, 16, RUNTIME_TYPE_KIND_UINT16)); this->add_named_type(Type::make_integer_type("uint32", true, 32, RUNTIME_TYPE_KIND_UINT32)); this->add_named_type(Type::make_integer_type("uint64", true, 64, RUNTIME_TYPE_KIND_UINT64)); this->add_named_type(Type::make_integer_type("int8", false, 8, RUNTIME_TYPE_KIND_INT8)); this->add_named_type(Type::make_integer_type("int16", false, 16, RUNTIME_TYPE_KIND_INT16)); Named_type* int32_type = Type::make_integer_type("int32", false, 32, RUNTIME_TYPE_KIND_INT32); this->add_named_type(int32_type); this->add_named_type(Type::make_integer_type("int64", false, 64, RUNTIME_TYPE_KIND_INT64)); this->add_named_type(Type::make_float_type("float32", 32, RUNTIME_TYPE_KIND_FLOAT32)); this->add_named_type(Type::make_float_type("float64", 64, RUNTIME_TYPE_KIND_FLOAT64)); this->add_named_type(Type::make_complex_type("complex64", 64, RUNTIME_TYPE_KIND_COMPLEX64)); this->add_named_type(Type::make_complex_type("complex128", 128, RUNTIME_TYPE_KIND_COMPLEX128)); int int_type_size = pointer_size; if (int_type_size < 32) int_type_size = 32; this->add_named_type(Type::make_integer_type("uint", true, int_type_size, RUNTIME_TYPE_KIND_UINT)); Named_type* int_type = Type::make_integer_type("int", false, int_type_size, RUNTIME_TYPE_KIND_INT); this->add_named_type(int_type); this->add_named_type(Type::make_integer_type("uintptr", true, pointer_size, RUNTIME_TYPE_KIND_UINTPTR)); // "byte" is an alias for "uint8". uint8_type->integer_type()->set_is_byte(); Named_object* byte_type = Named_object::make_type("byte", NULL, uint8_type, loc); byte_type->type_value()->set_is_alias(); this->add_named_type(byte_type->type_value()); // "rune" is an alias for "int32". int32_type->integer_type()->set_is_rune(); Named_object* rune_type = Named_object::make_type("rune", NULL, int32_type, loc); rune_type->type_value()->set_is_alias(); this->add_named_type(rune_type->type_value()); this->add_named_type(Type::make_named_bool_type()); this->add_named_type(Type::make_named_string_type()); // "error" is interface { Error() string }. { Typed_identifier_list *methods = new Typed_identifier_list; Typed_identifier_list *results = new Typed_identifier_list; results->push_back(Typed_identifier("", Type::lookup_string_type(), loc)); Type *method_type = Type::make_function_type(NULL, NULL, results, loc); methods->push_back(Typed_identifier("Error", method_type, loc)); Interface_type *error_iface = Type::make_interface_type(methods, loc); error_iface->finalize_methods(); Named_type *error_type = Named_object::make_type("error", NULL, error_iface, loc)->type_value(); this->add_named_type(error_type); } this->globals_->add_constant(Typed_identifier("true", Type::make_boolean_type(), loc), NULL, Expression::make_boolean(true, loc), 0); this->globals_->add_constant(Typed_identifier("false", Type::make_boolean_type(), loc), NULL, Expression::make_boolean(false, loc), 0); this->globals_->add_constant(Typed_identifier("nil", Type::make_nil_type(), loc), NULL, Expression::make_nil(loc), 0); Type* abstract_int_type = Type::make_abstract_integer_type(); this->globals_->add_constant(Typed_identifier("iota", abstract_int_type, loc), NULL, Expression::make_iota(), 0); Function_type* new_type = Type::make_function_type(NULL, NULL, NULL, loc); new_type->set_is_varargs(); new_type->set_is_builtin(); this->globals_->add_function_declaration("new", NULL, new_type, loc); Function_type* make_type = Type::make_function_type(NULL, NULL, NULL, loc); make_type->set_is_varargs(); make_type->set_is_builtin(); this->globals_->add_function_declaration("make", NULL, make_type, loc); Typed_identifier_list* len_result = new Typed_identifier_list(); len_result->push_back(Typed_identifier("", int_type, loc)); Function_type* len_type = Type::make_function_type(NULL, NULL, len_result, loc); len_type->set_is_builtin(); this->globals_->add_function_declaration("len", NULL, len_type, loc); Typed_identifier_list* cap_result = new Typed_identifier_list(); cap_result->push_back(Typed_identifier("", int_type, loc)); Function_type* cap_type = Type::make_function_type(NULL, NULL, len_result, loc); cap_type->set_is_builtin(); this->globals_->add_function_declaration("cap", NULL, cap_type, loc); Function_type* print_type = Type::make_function_type(NULL, NULL, NULL, loc); print_type->set_is_varargs(); print_type->set_is_builtin(); this->globals_->add_function_declaration("print", NULL, print_type, loc); print_type = Type::make_function_type(NULL, NULL, NULL, loc); print_type->set_is_varargs(); print_type->set_is_builtin(); this->globals_->add_function_declaration("println", NULL, print_type, loc); Type *empty = Type::make_empty_interface_type(loc); Typed_identifier_list* panic_parms = new Typed_identifier_list(); panic_parms->push_back(Typed_identifier("e", empty, loc)); Function_type *panic_type = Type::make_function_type(NULL, panic_parms, NULL, loc); panic_type->set_is_builtin(); this->globals_->add_function_declaration("panic", NULL, panic_type, loc); Typed_identifier_list* recover_result = new Typed_identifier_list(); recover_result->push_back(Typed_identifier("", empty, loc)); Function_type* recover_type = Type::make_function_type(NULL, NULL, recover_result, loc); recover_type->set_is_builtin(); this->globals_->add_function_declaration("recover", NULL, recover_type, loc); Function_type* close_type = Type::make_function_type(NULL, NULL, NULL, loc); close_type->set_is_varargs(); close_type->set_is_builtin(); this->globals_->add_function_declaration("close", NULL, close_type, loc); Typed_identifier_list* copy_result = new Typed_identifier_list(); copy_result->push_back(Typed_identifier("", int_type, loc)); Function_type* copy_type = Type::make_function_type(NULL, NULL, copy_result, loc); copy_type->set_is_varargs(); copy_type->set_is_builtin(); this->globals_->add_function_declaration("copy", NULL, copy_type, loc); Function_type* append_type = Type::make_function_type(NULL, NULL, NULL, loc); append_type->set_is_varargs(); append_type->set_is_builtin(); this->globals_->add_function_declaration("append", NULL, append_type, loc); Function_type* complex_type = Type::make_function_type(NULL, NULL, NULL, loc); complex_type->set_is_varargs(); complex_type->set_is_builtin(); this->globals_->add_function_declaration("complex", NULL, complex_type, loc); Function_type* real_type = Type::make_function_type(NULL, NULL, NULL, loc); real_type->set_is_varargs(); real_type->set_is_builtin(); this->globals_->add_function_declaration("real", NULL, real_type, loc); Function_type* imag_type = Type::make_function_type(NULL, NULL, NULL, loc); imag_type->set_is_varargs(); imag_type->set_is_builtin(); this->globals_->add_function_declaration("imag", NULL, imag_type, loc); Function_type* delete_type = Type::make_function_type(NULL, NULL, NULL, loc); delete_type->set_is_varargs(); delete_type->set_is_builtin(); this->globals_->add_function_declaration("delete", NULL, delete_type, loc); } std::string Gogo::pkgpath_for_symbol(const std::string& pkgpath) { go_assert(!pkgpath.empty()); return go_encode_id(pkgpath); } // Return a hash code for a string, given a starting hash. unsigned int Gogo::hash_string(const std::string& s, unsigned int h) { const char* p = s.data(); size_t len = s.length(); for (; len > 0; --len) { h ^= *p++; h*= 16777619; } return h; } // Get the package path to use for type reflection data. This should // ideally be unique across the entire link. const std::string& Gogo::pkgpath() const { go_assert(this->pkgpath_set_); return this->pkgpath_; } // Set the package path from the -fgo-pkgpath command line option. void Gogo::set_pkgpath(const std::string& arg) { go_assert(!this->pkgpath_set_); this->pkgpath_ = go_mangle_pkgpath(arg); this->pkgpath_set_ = true; this->pkgpath_from_option_ = true; } // Get the package path to use for symbol names. const std::string& Gogo::pkgpath_symbol() const { go_assert(this->pkgpath_set_); return this->pkgpath_symbol_; } // Set the unique prefix to use to determine the package path, from // the -fgo-prefix command line option. void Gogo::set_prefix(const std::string& arg) { go_assert(!this->prefix_from_option_); this->prefix_ = arg; this->prefix_from_option_ = true; } // Given a name which may or may not have been hidden, append the // appropriate version of the name to the result string. Take care // to avoid creating a sequence that will be rejected by go_encode_id // (avoid ..u, ..U, ..z). void Gogo::append_possibly_hidden_name(std::string *result, const std::string& name) { // FIXME: This adds in pkgpath twice for hidden symbols, which is // less than ideal. if (!Gogo::is_hidden_name(name)) (*result) += name; else { std::string n = "."; std::string pkgpath = Gogo::hidden_name_pkgpath(name); char lastR = result->at(result->length() - 1); char firstP = pkgpath.at(0); if (lastR == '.' && (firstP == 'u' || firstP == 'U' || firstP == 'z')) n = "_."; n.append(pkgpath); n.append(1, '.'); n.append(Gogo::unpack_hidden_name(name)); (*result) += n; } } // Munge name for use in an error message. std::string Gogo::message_name(const std::string& name) { return go_localize_identifier(Gogo::unpack_hidden_name(name).c_str()); } // Get the package name. const std::string& Gogo::package_name() const { go_assert(this->package_ != NULL); return this->package_->package_name(); } // Set the package name. void Gogo::set_package_name(const std::string& package_name, Location location) { if (this->package_ != NULL) { if (this->package_->package_name() != package_name) go_error_at(location, "expected package %<%s%>", Gogo::message_name(this->package_->package_name()).c_str()); return; } // Now that we know the name of the package we are compiling, set // the package path to use for reflect.Type.PkgPath and global // symbol names. if (this->pkgpath_set_) this->pkgpath_symbol_ = Gogo::pkgpath_for_symbol(this->pkgpath_); else { if (!this->prefix_from_option_ && package_name == "main") { this->pkgpath_ = package_name; this->pkgpath_symbol_ = Gogo::pkgpath_for_symbol(package_name); } else { if (!this->prefix_from_option_) this->prefix_ = "go"; this->pkgpath_ = (go_mangle_pkgpath(this->prefix_) + '.' + package_name); this->pkgpath_symbol_ = (Gogo::pkgpath_for_symbol(this->prefix_) + '.' + Gogo::pkgpath_for_symbol(package_name)); } this->pkgpath_set_ = true; } this->package_ = this->register_package(this->pkgpath_, this->pkgpath_symbol_, location); this->package_->set_package_name(package_name, location); if (this->is_main_package()) { // Declare "main" as a function which takes no parameters and // returns no value. Location uloc = Linemap::unknown_location(); this->declare_function(Gogo::pack_hidden_name("main", false), Type::make_function_type (NULL, NULL, NULL, uloc), uloc); } } // Return whether this is the "main" package. This is not true if // -fgo-pkgpath or -fgo-prefix was used. bool Gogo::is_main_package() const { return (this->package_name() == "main" && !this->pkgpath_from_option_ && !this->prefix_from_option_); } // Import a package. void Gogo::import_package(const std::string& filename, const std::string& local_name, bool is_local_name_exported, bool must_exist, Location location) { if (filename.empty()) { go_error_at(location, "import path is empty"); return; } const char *pf = filename.data(); const char *pend = pf + filename.length(); while (pf < pend) { unsigned int c; int adv = Lex::fetch_char(pf, &c); if (adv == 0) { go_error_at(location, "import path contains invalid UTF-8 sequence"); return; } if (c == '\0') { go_error_at(location, "import path contains NUL"); return; } if (c < 0x20 || c == 0x7f) { go_error_at(location, "import path contains control character"); return; } if (c == '\\') { go_error_at(location, "import path contains backslash; use slash"); return; } if (Lex::is_unicode_space(c)) { go_error_at(location, "import path contains space character"); return; } if (c < 0x7f && strchr("!\"#$%&'()*,:;<=>?[]^`{|}", c) != NULL) { go_error_at(location, "import path contains invalid character '%c'", c); return; } pf += adv; } if (IS_ABSOLUTE_PATH(filename.c_str())) { go_error_at(location, "import path cannot be absolute path"); return; } if (local_name == "init") go_error_at(location, "cannot import package as init"); if (filename == "unsafe") { this->import_unsafe(local_name, is_local_name_exported, location); this->current_file_imported_unsafe_ = true; return; } Imports::const_iterator p = this->imports_.find(filename); if (p != this->imports_.end()) { Package* package = p->second; package->set_location(location); std::string ln = local_name; bool is_ln_exported = is_local_name_exported; if (ln.empty()) { ln = package->package_name(); go_assert(!ln.empty()); is_ln_exported = Lex::is_exported_name(ln); } if (ln == "_") ; else if (ln == ".") { Bindings* bindings = package->bindings(); for (Bindings::const_declarations_iterator pd = bindings->begin_declarations(); pd != bindings->end_declarations(); ++pd) this->add_dot_import_object(pd->second); std::string dot_alias = "." + package->package_name(); package->add_alias(dot_alias, location); } else { package->add_alias(ln, location); ln = this->pack_hidden_name(ln, is_ln_exported); this->package_->bindings()->add_package(ln, package); } return; } Import::Stream* stream = Import::open_package(filename, location, this->relative_import_path_); if (stream == NULL) { if (must_exist) go_error_at(location, "import file %qs not found", filename.c_str()); return; } Import* imp = new Import(stream, location); imp->register_builtin_types(this); Package* package = imp->import(this, local_name, is_local_name_exported); if (package != NULL) { if (package->pkgpath() == this->pkgpath()) go_error_at(location, ("imported package uses same package path as package " "being compiled (see %<-fgo-pkgpath%> option)")); this->imports_.insert(std::make_pair(filename, package)); } imp->clear_stream(); delete stream; // FIXME: we never delete imp; we may need it for inlinable functions. } Import_init * Gogo::lookup_init(const std::string& init_name) { Import_init tmp("", init_name, -1); Import_init_set::iterator it = this->imported_init_fns_.find(&tmp); return (it != this->imported_init_fns_.end()) ? *it : NULL; } // Add an import control function for an imported package to the list. void Gogo::add_import_init_fn(const std::string& package_name, const std::string& init_name, int prio) { for (Import_init_set::iterator p = this->imported_init_fns_.begin(); p != this->imported_init_fns_.end(); ++p) { Import_init *ii = (*p); if (ii->init_name() == init_name) { // If a test of package P1, built as part of package P1, // imports package P2, and P2 imports P1 (perhaps // indirectly), then we will see the same import name with // different import priorities. That is OK, so don't give // an error about it. if (ii->package_name() != package_name) { go_error_at(Linemap::unknown_location(), "duplicate package initialization name %qs", Gogo::message_name(init_name).c_str()); go_inform(Linemap::unknown_location(), "used by package %qs", Gogo::message_name(ii->package_name()).c_str()); go_inform(Linemap::unknown_location(), " and by package %qs", Gogo::message_name(package_name).c_str()); } ii->set_priority(prio); return; } } Import_init* nii = new Import_init(package_name, init_name, prio); this->imported_init_fns_.insert(nii); } // Return whether we are at the global binding level. bool Gogo::in_global_scope() const { return this->functions_.empty(); } // Return the current binding contour. Bindings* Gogo::current_bindings() { if (!this->functions_.empty()) return this->functions_.back().blocks.back()->bindings(); else if (this->package_ != NULL) return this->package_->bindings(); else return this->globals_; } const Bindings* Gogo::current_bindings() const { if (!this->functions_.empty()) return this->functions_.back().blocks.back()->bindings(); else if (this->package_ != NULL) return this->package_->bindings(); else return this->globals_; } void Gogo::update_init_priority(Import_init* ii, std::set<const Import_init *>* visited) { visited->insert(ii); int succ_prior = -1; for (std::set<std::string>::const_iterator pci = ii->precursors().begin(); pci != ii->precursors().end(); ++pci) { Import_init* succ = this->lookup_init(*pci); if (visited->find(succ) == visited->end()) update_init_priority(succ, visited); succ_prior = std::max(succ_prior, succ->priority()); } if (ii->priority() <= succ_prior) ii->set_priority(succ_prior + 1); } void Gogo::recompute_init_priorities() { std::set<Import_init *> nonroots; for (Import_init_set::const_iterator p = this->imported_init_fns_.begin(); p != this->imported_init_fns_.end(); ++p) { const Import_init *ii = *p; for (std::set<std::string>::const_iterator pci = ii->precursors().begin(); pci != ii->precursors().end(); ++pci) { Import_init* ii_init = this->lookup_init(*pci); nonroots.insert(ii_init); } } // Recursively update priorities starting at roots. std::set<const Import_init*> visited; for (Import_init_set::iterator p = this->imported_init_fns_.begin(); p != this->imported_init_fns_.end(); ++p) { Import_init* ii = *p; if (nonroots.find(ii) != nonroots.end()) continue; update_init_priority(ii, &visited); } } // Add statements to INIT_STMTS which run the initialization // functions for imported packages. This is only used for the "main" // package. void Gogo::init_imports(std::vector<Bstatement*>& init_stmts, Bfunction *bfunction) { go_assert(this->is_main_package()); if (this->imported_init_fns_.empty()) return; Location unknown_loc = Linemap::unknown_location(); Function_type* func_type = Type::make_function_type(NULL, NULL, NULL, unknown_loc); Btype* fntype = func_type->get_backend_fntype(this); // Recompute init priorities based on a walk of the init graph. recompute_init_priorities(); // We must call them in increasing priority order. std::vector<const Import_init*> v; for (Import_init_set::const_iterator p = this->imported_init_fns_.begin(); p != this->imported_init_fns_.end(); ++p) { // Don't include dummy inits. They are not real functions. if ((*p)->is_dummy()) continue; if ((*p)->priority() < 0) go_error_at(Linemap::unknown_location(), "internal error: failed to set init priority for %s", (*p)->package_name().c_str()); v.push_back(*p); } std::sort(v.begin(), v.end(), priority_compare); // We build calls to the init functions, which take no arguments. std::vector<Bexpression*> empty_args; for (std::vector<const Import_init*>::const_iterator p = v.begin(); p != v.end(); ++p) { const Import_init* ii = *p; std::string user_name = ii->package_name() + ".init"; const std::string& init_name(ii->init_name()); const unsigned int flags = (Backend::function_is_visible | Backend::function_is_declaration | Backend::function_is_inlinable); Bfunction* pfunc = this->backend()->function(fntype, user_name, init_name, flags, unknown_loc); Bexpression* pfunc_code = this->backend()->function_code_expression(pfunc, unknown_loc); Bexpression* pfunc_call = this->backend()->call_expression(bfunction, pfunc_code, empty_args, NULL, unknown_loc); init_stmts.push_back(this->backend()->expression_statement(bfunction, pfunc_call)); } } // Register global variables with the garbage collector. We need to // register all variables which can hold a pointer value. They become // roots during the mark phase. We build a struct that is easy to // hook into a list of roots. // type gcRoot struct { // decl unsafe.Pointer // Pointer to variable. // size uintptr // Total size of variable. // ptrdata uintptr // Length of variable's gcdata. // gcdata *byte // Pointer mask. // } // // type gcRootList struct { // next *gcRootList // count int // roots [...]gcRoot // } // The last entry in the roots array has a NULL decl field. void Gogo::register_gc_vars(const std::vector<Named_object*>& var_gc, std::vector<Bstatement*>& init_stmts, Bfunction* init_bfn) { if (var_gc.empty() && this->gc_roots_.empty()) return; Type* pvt = Type::make_pointer_type(Type::make_void_type()); Type* uintptr_type = Type::lookup_integer_type("uintptr"); Type* byte_type = this->lookup_global("byte")->type_value(); Type* pointer_byte_type = Type::make_pointer_type(byte_type); Struct_type* root_type = Type::make_builtin_struct_type(4, "decl", pvt, "size", uintptr_type, "ptrdata", uintptr_type, "gcdata", pointer_byte_type); Location builtin_loc = Linemap::predeclared_location(); unsigned long roots_len = var_gc.size() + this->gc_roots_.size(); Expression* length = Expression::make_integer_ul(roots_len, NULL, builtin_loc); Array_type* root_array_type = Type::make_array_type(root_type, length); root_array_type->set_is_array_incomparable(); Type* int_type = Type::lookup_integer_type("int"); Struct_type* root_list_type = Type::make_builtin_struct_type(3, "next", pvt, "count", int_type, "roots", root_array_type); // Build an initializer for the roots array. Expression_list* roots_init = new Expression_list(); for (std::vector<Named_object*>::const_iterator p = var_gc.begin(); p != var_gc.end(); ++p) { Expression_list* init = new Expression_list(); Location no_loc = (*p)->location(); Expression* decl = Expression::make_var_reference(*p, no_loc); Expression* decl_addr = Expression::make_unary(OPERATOR_AND, decl, no_loc); decl_addr->unary_expression()->set_does_not_escape(); decl_addr = Expression::make_cast(pvt, decl_addr, no_loc); init->push_back(decl_addr); Expression* size = Expression::make_type_info(decl->type(), Expression::TYPE_INFO_SIZE); init->push_back(size); Expression* ptrdata = Expression::make_type_info(decl->type(), Expression::TYPE_INFO_BACKEND_PTRDATA); init->push_back(ptrdata); Expression* gcdata = Expression::make_ptrmask_symbol(decl->type()); init->push_back(gcdata); Expression* root_ctor = Expression::make_struct_composite_literal(root_type, init, no_loc); roots_init->push_back(root_ctor); } for (std::vector<Expression*>::const_iterator p = this->gc_roots_.begin(); p != this->gc_roots_.end(); ++p) { Expression_list *init = new Expression_list(); Expression* expr = *p; Location eloc = expr->location(); init->push_back(Expression::make_cast(pvt, expr, eloc)); Type* type = expr->type()->points_to(); go_assert(type != NULL); Expression* size = Expression::make_type_info(type, Expression::TYPE_INFO_SIZE); init->push_back(size); Expression* ptrdata = Expression::make_type_info(type, Expression::TYPE_INFO_BACKEND_PTRDATA); init->push_back(ptrdata); Expression* gcdata = Expression::make_ptrmask_symbol(type); init->push_back(gcdata); Expression* root_ctor = Expression::make_struct_composite_literal(root_type, init, eloc); roots_init->push_back(root_ctor); } // Build a constructor for the struct. Expression_list* root_list_init = new Expression_list(); root_list_init->push_back(Expression::make_nil(builtin_loc)); root_list_init->push_back(Expression::make_integer_ul(roots_len, int_type, builtin_loc)); Expression* roots_ctor = Expression::make_array_composite_literal(root_array_type, roots_init, builtin_loc); root_list_init->push_back(roots_ctor); Expression* root_list_ctor = Expression::make_struct_composite_literal(root_list_type, root_list_init, builtin_loc); Expression* root_addr = Expression::make_unary(OPERATOR_AND, root_list_ctor, builtin_loc); root_addr->unary_expression()->set_is_gc_root(); Expression* register_roots = Runtime::make_call(Runtime::REGISTER_GC_ROOTS, builtin_loc, 1, root_addr); Translate_context context(this, NULL, NULL, NULL); Bexpression* bcall = register_roots->get_backend(&context); init_stmts.push_back(this->backend()->expression_statement(init_bfn, bcall)); } // Build the list of type descriptors defined in this package. This is to help // the reflect package to find compiler-generated types. // type typeDescriptorList struct { // count int // types [...]unsafe.Pointer // } static Struct_type* type_descriptor_list_type(unsigned long len) { Location builtin_loc = Linemap::predeclared_location(); Type* int_type = Type::lookup_integer_type("int"); Type* ptr_type = Type::make_pointer_type(Type::make_void_type()); // Avoid creating zero-length type. unsigned long nelems = (len != 0 ? len : 1); Expression* len_expr = Expression::make_integer_ul(nelems, NULL, builtin_loc); Array_type* array_type = Type::make_array_type(ptr_type, len_expr); array_type->set_is_array_incomparable(); Struct_type* list_type = Type::make_builtin_struct_type(2, "count", int_type, "types", array_type); return list_type; } void Gogo::build_type_descriptor_list() { // Create the list type Location builtin_loc = Linemap::predeclared_location(); unsigned long len = this->type_descriptors_.size(); Struct_type* list_type = type_descriptor_list_type(len); Btype* bt = list_type->get_backend(this); Btype* bat = list_type->field(1)->type()->get_backend(this); // Create the variable std::string name = this->type_descriptor_list_symbol(this->pkgpath_symbol()); Bvariable* bv = this->backend()->implicit_variable(name, name, bt, false, true, false, 0); // Build the initializer std::vector<unsigned long> indexes; std::vector<Bexpression*> vals; std::vector<Type*>::iterator p = this->type_descriptors_.begin(); for (unsigned long i = 0; i < len; ++i, ++p) { Bexpression* bexpr = (*p)->type_descriptor_pointer(this, builtin_loc); indexes.push_back(i); vals.push_back(bexpr); } Bexpression* barray = this->backend()->array_constructor_expression(bat, indexes, vals, builtin_loc); Translate_context context(this, NULL, NULL, NULL); std::vector<Bexpression*> fields; Expression* len_expr = Expression::make_integer_ul(len, NULL, builtin_loc); fields.push_back(len_expr->get_backend(&context)); fields.push_back(barray); Bexpression* binit = this->backend()->constructor_expression(bt, fields, builtin_loc); this->backend()->implicit_variable_set_init(bv, name, bt, false, true, false, binit); } // Register the type descriptors with the runtime. This is to help // the reflect package to find compiler-generated types. void Gogo::register_type_descriptors(std::vector<Bstatement*>& init_stmts, Bfunction* init_bfn) { // Create the list type Location builtin_loc = Linemap::predeclared_location(); Struct_type* list_type = type_descriptor_list_type(1); Btype* bt = list_type->get_backend(this); // Collect type lists from transitive imports. std::vector<std::string> list_names; for (Import_init_set::iterator it = this->imported_init_fns_.begin(); it != this->imported_init_fns_.end(); ++it) { std::string pkgpath = this->pkgpath_from_init_fn_name((*it)->init_name()); list_names.push_back(this->type_descriptor_list_symbol(pkgpath)); } // Add the main package itself. list_names.push_back(this->type_descriptor_list_symbol("main")); // Build a list of lists. std::vector<unsigned long> indexes; std::vector<Bexpression*> vals; unsigned long i = 0; for (std::vector<std::string>::iterator p = list_names.begin(); p != list_names.end(); ++p) { Bvariable* bv = this->backend()->implicit_variable_reference(*p, *p, bt); Bexpression* bexpr = this->backend()->var_expression(bv, builtin_loc); bexpr = this->backend()->address_expression(bexpr, builtin_loc); indexes.push_back(i); vals.push_back(bexpr); i++; } Expression* len_expr = Expression::make_integer_ul(i, NULL, builtin_loc); Type* list_ptr_type = Type::make_pointer_type(list_type); Type* list_array_type = Type::make_array_type(list_ptr_type, len_expr); Btype* bat = list_array_type->get_backend(this); Bexpression* barray = this->backend()->array_constructor_expression(bat, indexes, vals, builtin_loc); // Create a variable holding the list. std::string name = this->typelists_symbol(); Bvariable* bv = this->backend()->implicit_variable(name, name, bat, true, true, false, 0); this->backend()->implicit_variable_set_init(bv, name, bat, true, true, false, barray); // Build the call in main package's init function. Translate_context context(this, NULL, NULL, NULL); Bexpression* bexpr = this->backend()->var_expression(bv, builtin_loc); bexpr = this->backend()->address_expression(bexpr, builtin_loc); Type* array_ptr_type = Type::make_pointer_type(list_array_type); Expression* expr = Expression::make_backend(bexpr, array_ptr_type, builtin_loc); expr = Runtime::make_call(Runtime::REGISTER_TYPE_DESCRIPTORS, builtin_loc, 2, len_expr->copy(), expr); Bexpression* bcall = expr->get_backend(&context); init_stmts.push_back(this->backend()->expression_statement(init_bfn, bcall)); } // Build the decl for the initialization function. Named_object* Gogo::initialization_function_decl() { std::string name = this->get_init_fn_name(); Location loc = this->package_->location(); Function_type* fntype = Type::make_function_type(NULL, NULL, NULL, loc); Function* initfn = new Function(fntype, NULL, NULL, loc); return Named_object::make_function(name, NULL, initfn); } // Create the magic initialization function. CODE_STMT is the // code that it needs to run. Named_object* Gogo::create_initialization_function(Named_object* initfn, Bstatement* code_stmt) { // Make sure that we thought we needed an initialization function, // as otherwise we will not have reported it in the export data. go_assert(this->is_main_package() || this->need_init_fn_); if (initfn == NULL) initfn = this->initialization_function_decl(); // Bind the initialization function code to a block. Bfunction* fndecl = initfn->func_value()->get_or_make_decl(this, initfn); Location pkg_loc = this->package_->location(); std::vector<Bvariable*> vars; this->backend()->block(fndecl, NULL, vars, pkg_loc, pkg_loc); if (!this->backend()->function_set_body(fndecl, code_stmt)) { go_assert(saw_errors()); return NULL; } return initfn; } // Given an expression, collect all the global variables defined in // this package that it references. class Find_vars : public Traverse { private: // The list of variables we accumulate. typedef Unordered_set(Named_object*) Vars; // A hash table we use to avoid looping. The index is a // Named_object* or a Temporary_statement*. We only look through // objects defined in this package. typedef Unordered_set(const void*) Seen_objects; public: Find_vars() : Traverse(traverse_expressions), vars_(), seen_objects_() { } // An iterator through the variables found, after the traversal. typedef Vars::const_iterator const_iterator; const_iterator begin() const { return this->vars_.begin(); } const_iterator end() const { return this->vars_.end(); } int expression(Expression**); private: // Accumulated variables. Vars vars_; // Objects we have already seen. Seen_objects seen_objects_; }; // Collect global variables referenced by EXPR. Look through function // calls and variable initializations. int Find_vars::expression(Expression** pexpr) { Expression* e = *pexpr; Var_expression* ve = e->var_expression(); if (ve != NULL) { Named_object* v = ve->named_object(); if (!v->is_variable() || v->package() != NULL) { // This is a result parameter or a variable defined in a // different package. Either way we don't care about it. return TRAVERSE_CONTINUE; } std::pair<Seen_objects::iterator, bool> ins = this->seen_objects_.insert(v); if (!ins.second) { // We've seen this variable before. return TRAVERSE_CONTINUE; } if (v->var_value()->is_global()) this->vars_.insert(v); Expression* init = v->var_value()->init(); if (init != NULL) { if (Expression::traverse(&init, this) == TRAVERSE_EXIT) return TRAVERSE_EXIT; } } // We traverse the code of any function or bound method we see. Note that // this means that we will traverse the code of a function or bound method // whose address is taken even if it is not called. Func_expression* fe = e->func_expression(); Bound_method_expression* bme = e->bound_method_expression(); if (fe != NULL || bme != NULL) { const Named_object* f = fe != NULL ? fe->named_object() : bme->function(); if (f->is_function() && f->package() == NULL) { std::pair<Seen_objects::iterator, bool> ins = this->seen_objects_.insert(f); if (ins.second) { // This is the first time we have seen this name. if (f->func_value()->block()->traverse(this) == TRAVERSE_EXIT) return TRAVERSE_EXIT; } } } Temporary_reference_expression* tre = e->temporary_reference_expression(); if (tre != NULL) { Temporary_statement* ts = tre->statement(); Expression* init = ts->init(); if (init != NULL) { std::pair<Seen_objects::iterator, bool> ins = this->seen_objects_.insert(ts); if (ins.second) { // This is the first time we have seen this temporary // statement. if (Expression::traverse(&init, this) == TRAVERSE_EXIT) return TRAVERSE_EXIT; } } } return TRAVERSE_CONTINUE; } // Return true if EXPR, PREINIT, or DEP refers to VAR. static bool expression_requires(Expression* expr, Block* preinit, Named_object* dep, Named_object* var) { Find_vars find_vars; if (expr != NULL) Expression::traverse(&expr, &find_vars); if (preinit != NULL) preinit->traverse(&find_vars); if (dep != NULL) { Expression* init = dep->var_value()->init(); if (init != NULL) Expression::traverse(&init, &find_vars); if (dep->var_value()->has_pre_init()) dep->var_value()->preinit()->traverse(&find_vars); } for (Find_vars::const_iterator p = find_vars.begin(); p != find_vars.end(); ++p) { if (*p == var) return true; } return false; } // Sort variable initializations. If the initialization expression // for variable A refers directly or indirectly to the initialization // expression for variable B, then we must initialize B before A. class Var_init { public: Var_init() : var_(NULL), init_(NULL), refs_(NULL), dep_count_(0) { } Var_init(Named_object* var, Bstatement* init) : var_(var), init_(init), refs_(NULL), dep_count_(0) { } // Return the variable. Named_object* var() const { return this->var_; } // Return the initialization expression. Bstatement* init() const { return this->init_; } // Add a reference. void add_ref(Named_object* var); // The variables which this variable's initializers refer to. const std::vector<Named_object*>* refs() { return this->refs_; } // Clear the references, if any. void clear_refs(); // Return the number of remaining dependencies. size_t dep_count() const { return this->dep_count_; } // Increment the number of dependencies. void add_dependency() { ++this->dep_count_; } // Decrement the number of dependencies. void remove_dependency() { --this->dep_count_; } private: // The variable being initialized. Named_object* var_; // The backend initialization statement. Bstatement* init_; // Variables this refers to. std::vector<Named_object*>* refs_; // The number of initializations this is dependent on. A variable // initialization should not be emitted if any of its dependencies // have not yet been resolved. size_t dep_count_; }; // Add a reference. void Var_init::add_ref(Named_object* var) { if (this->refs_ == NULL) this->refs_ = new std::vector<Named_object*>; this->refs_->push_back(var); } // Clear the references, if any. void Var_init::clear_refs() { if (this->refs_ != NULL) { delete this->refs_; this->refs_ = NULL; } } // For comparing Var_init keys in a map. inline bool operator<(const Var_init& v1, const Var_init& v2) { return v1.var()->name() < v2.var()->name(); } typedef std::list<Var_init> Var_inits; // Sort the variable initializations. The rule we follow is that we // emit them in the order they appear in the array, except that if the // initialization expression for a variable V1 depends upon another // variable V2 then we initialize V1 after V2. static void sort_var_inits(Gogo* gogo, Var_inits* var_inits) { if (var_inits->empty()) return; std::map<Named_object*, Var_init*> var_to_init; // A mapping from a variable initialization to a set of // variable initializations that depend on it. typedef std::map<Var_init, std::set<Var_init*> > Init_deps; Init_deps init_deps; bool init_loop = false; // Compute all variable references. for (Var_inits::iterator pvar = var_inits->begin(); pvar != var_inits->end(); ++pvar) { Named_object* var = pvar->var(); var_to_init[var] = &*pvar; Find_vars find_vars; Expression* init = var->var_value()->init(); if (init != NULL) Expression::traverse(&init, &find_vars); if (var->var_value()->has_pre_init()) var->var_value()->preinit()->traverse(&find_vars); Named_object* dep = gogo->var_depends_on(var->var_value()); if (dep != NULL) { Expression* dinit = dep->var_value()->init(); if (dinit != NULL) Expression::traverse(&dinit, &find_vars); if (dep->var_value()->has_pre_init()) dep->var_value()->preinit()->traverse(&find_vars); } for (Find_vars::const_iterator p = find_vars.begin(); p != find_vars.end(); ++p) pvar->add_ref(*p); } // Add dependencies to init_deps, and check for cycles. for (Var_inits::iterator pvar = var_inits->begin(); pvar != var_inits->end(); ++pvar) { Named_object* var = pvar->var(); const std::vector<Named_object*>* refs = pvar->refs(); if (refs == NULL) continue; for (std::vector<Named_object*>::const_iterator pdep = refs->begin(); pdep != refs->end(); ++pdep) { Named_object* dep = *pdep; if (var == dep) { // This is a reference from a variable to itself, which // may indicate a loop. We only report an error if // there is an initializer and there is no dependency. // When there is no initializer, it means that the // preinitializer sets the variable, which will appear // to be a loop here. if (var->var_value()->init() != NULL && gogo->var_depends_on(var->var_value()) == NULL) go_error_at(var->location(), ("initialization expression for %qs " "depends upon itself"), var->message_name().c_str()); continue; } Var_init* dep_init = var_to_init[dep]; if (dep_init == NULL) { // This is a dependency on some variable that doesn't // have an initializer, so for purposes of // initialization ordering this is irrelevant. continue; } init_deps[*dep_init].insert(&(*pvar)); pvar->add_dependency(); // Check for cycles. const std::vector<Named_object*>* deprefs = dep_init->refs(); if (deprefs == NULL) continue; for (std::vector<Named_object*>::const_iterator pdepdep = deprefs->begin(); pdepdep != deprefs->end(); ++pdepdep) { if (*pdepdep == var) { go_error_at(var->location(), ("initialization expressions for %qs and " "%qs depend upon each other"), var->message_name().c_str(), dep->message_name().c_str()); go_inform(dep->location(), "%qs defined here", dep->message_name().c_str()); init_loop = true; break; } } } } var_to_init.clear(); for (Var_inits::iterator pvar = var_inits->begin(); pvar != var_inits->end(); ++pvar) pvar->clear_refs(); // If there are no dependencies then the declaration order is sorted. if (!init_deps.empty() && !init_loop) { // Otherwise, sort variable initializations by emitting all variables with // no dependencies in declaration order. VAR_INITS is already in // declaration order. Var_inits ready; while (!var_inits->empty()) { Var_inits::iterator v1;; for (v1 = var_inits->begin(); v1 != var_inits->end(); ++v1) { if (v1->dep_count() == 0) break; } go_assert(v1 != var_inits->end()); // V1 either has no dependencies or its dependencies have already // been emitted, add it to READY next. When V1 is emitted, remove // a dependency from each V that depends on V1. ready.splice(ready.end(), *var_inits, v1); Init_deps::iterator p1 = init_deps.find(*v1); if (p1 != init_deps.end()) { std::set<Var_init*> resolved = p1->second; for (std::set<Var_init*>::iterator pv = resolved.begin(); pv != resolved.end(); ++pv) (*pv)->remove_dependency(); init_deps.erase(p1); } } var_inits->swap(ready); go_assert(init_deps.empty()); } } // Give an error if the initialization expression for VAR depends on // itself. We only check if INIT is not NULL and there is no // dependency; when INIT is NULL, it means that PREINIT sets VAR, // which we will interpret as a loop. void Gogo::check_self_dep(Named_object* var) { Expression* init = var->var_value()->init(); Block* preinit = var->var_value()->preinit(); Named_object* dep = this->var_depends_on(var->var_value()); if (init != NULL && dep == NULL && expression_requires(init, preinit, NULL, var)) go_error_at(var->location(), "initialization expression for %qs depends upon itself", var->message_name().c_str()); } // Write out the global definitions. void Gogo::write_globals() { this->build_interface_method_tables(); Bindings* bindings = this->current_bindings(); for (Bindings::const_declarations_iterator p = bindings->begin_declarations(); p != bindings->end_declarations(); ++p) { // If any function declarations needed a descriptor, make sure // we build it. Named_object* no = p->second; if (no->is_function_declaration()) no->func_declaration_value()->build_backend_descriptor(this); } // Lists of globally declared types, variables, constants, and functions // that must be defined. std::vector<Btype*> type_decls; std::vector<Bvariable*> var_decls; std::vector<Bexpression*> const_decls; std::vector<Bfunction*> func_decls; // The init function declaration and associated Bfunction, if necessary. Named_object* init_fndecl = NULL; Bfunction* init_bfn = NULL; std::vector<Bstatement*> init_stmts; std::vector<Bstatement*> var_init_stmts; if (this->is_main_package()) { init_fndecl = this->initialization_function_decl(); init_bfn = init_fndecl->func_value()->get_or_make_decl(this, init_fndecl); } // A list of variable initializations. Var_inits var_inits; // A list of variables which need to be registered with the garbage // collector. size_t count_definitions = bindings->size_definitions(); std::vector<Named_object*> var_gc; var_gc.reserve(count_definitions); for (Bindings::const_definitions_iterator p = bindings->begin_definitions(); p != bindings->end_definitions(); ++p) { Named_object* no = *p; go_assert(!no->is_type_declaration() && !no->is_function_declaration()); // There is nothing to do for a package. if (no->is_package()) continue; // There is nothing to do for an object which was imported from // a different package into the global scope. if (no->package() != NULL) continue; // Skip blank named functions and constants. if ((no->is_function() && no->func_value()->is_sink()) || (no->is_const() && no->const_value()->is_sink())) continue; // There is nothing useful we can output for constants which // have ideal or non-integral type. if (no->is_const()) { Type* type = no->const_value()->type(); if (type == NULL) type = no->const_value()->expr()->type(); if (type->is_abstract() || !type->is_numeric_type()) continue; } if (!no->is_variable()) no->get_backend(this, const_decls, type_decls, func_decls); else { Variable* var = no->var_value(); Bvariable* bvar = no->get_backend_variable(this, NULL); var_decls.push_back(bvar); // Check for a sink variable, which may be used to run an // initializer purely for its side effects. bool is_sink = no->name()[0] == '_' && no->name()[1] == '.'; Bstatement* var_init_stmt = NULL; if (!var->has_pre_init()) { // If the backend representation of the variable initializer is // constant, we can just set the initial value using // global_var_set_init instead of during the init() function. // The initializer is constant if it is the zero-value of the // variable's type or if the initial value is an immutable value // that is not copied to the heap. bool is_static_initializer = false; if (var->init() == NULL) is_static_initializer = true; else { Type* var_type = var->type(); Expression* init = var->init(); Expression* init_cast = Expression::make_cast(var_type, init, var->location()); is_static_initializer = init_cast->is_static_initializer(); } // Non-constant variable initializations might need to create // temporary variables, which will need the initialization // function as context. Named_object* var_init_fn; if (is_static_initializer) var_init_fn = NULL; else { if (init_fndecl == NULL) { init_fndecl = this->initialization_function_decl(); Function* func = init_fndecl->func_value(); init_bfn = func->get_or_make_decl(this, init_fndecl); } var_init_fn = init_fndecl; } Bexpression* var_binit = var->get_init(this, var_init_fn); if (var_binit == NULL) ; else if (is_static_initializer) { if (expression_requires(var->init(), NULL, this->var_depends_on(var), no)) go_error_at(no->location(), "initialization expression for %qs depends " "upon itself", no->message_name().c_str()); this->backend()->global_variable_set_init(bvar, var_binit); } else if (is_sink) var_init_stmt = this->backend()->expression_statement(init_bfn, var_binit); else { Location loc = var->location(); Bexpression* var_expr = this->backend()->var_expression(bvar, loc); var_init_stmt = this->backend()->assignment_statement(init_bfn, var_expr, var_binit, loc); } } else { // We are going to create temporary variables which // means that we need an fndecl. if (init_fndecl == NULL) init_fndecl = this->initialization_function_decl(); Bvariable* var_decl = is_sink ? NULL : bvar; var_init_stmt = var->get_init_block(this, init_fndecl, var_decl); } if (var_init_stmt != NULL) { if (var->init() == NULL && !var->has_pre_init()) var_init_stmts.push_back(var_init_stmt); else var_inits.push_back(Var_init(no, var_init_stmt)); } else if (this->var_depends_on(var) != NULL) { // This variable is initialized from something that is // not in its init or preinit. This variable needs to // participate in dependency analysis sorting, in case // some other variable depends on this one. Btype* btype = no->var_value()->type()->get_backend(this); Bexpression* zero = this->backend()->zero_expression(btype); Bstatement* zero_stmt = this->backend()->expression_statement(init_bfn, zero); var_inits.push_back(Var_init(no, zero_stmt)); } // Collect a list of all global variables with pointers, // to register them for the garbage collector. if (!is_sink && var->type()->has_pointer()) { // Avoid putting runtime.gcRoots itself on the list. if (this->compiling_runtime() && this->package_name() == "runtime" && (Gogo::unpack_hidden_name(no->name()) == "gcRoots" || Gogo::unpack_hidden_name(no->name()) == "gcRootsIndex")) ; else var_gc.push_back(no); } } } // Output inline functions, which are in different packages. for (std::vector<Named_object*>::const_iterator p = this->imported_inline_functions_.begin(); p != this->imported_inline_functions_.end(); ++p) (*p)->get_backend(this, const_decls, type_decls, func_decls); // Build the list of type descriptors. this->build_type_descriptor_list(); if (this->is_main_package()) { // Register the type descriptor lists, so that at run time // the reflect package can find compiler-created types, and // deduplicate if the same type is created with reflection. // This needs to be done before calling any package's init // function, as it may create type through reflection. this->register_type_descriptors(init_stmts, init_bfn); // Initialize imported packages. this->init_imports(init_stmts, init_bfn); } // Register global variables with the garbage collector. this->register_gc_vars(var_gc, init_stmts, init_bfn); // Simple variable initializations, after all variables are // registered. init_stmts.push_back(this->backend()->statement_list(var_init_stmts)); // Complete variable initializations, first sorting them into a // workable order. if (!var_inits.empty()) { sort_var_inits(this, &var_inits); for (Var_inits::const_iterator p = var_inits.begin(); p != var_inits.end(); ++p) init_stmts.push_back(p->init()); } // After all the variables are initialized, call the init // functions if there are any. Init functions take no arguments, so // we pass in EMPTY_ARGS to call them. std::vector<Bexpression*> empty_args; for (std::vector<Named_object*>::const_iterator p = this->init_functions_.begin(); p != this->init_functions_.end(); ++p) { Location func_loc = (*p)->location(); Function* func = (*p)->func_value(); Bfunction* initfn = func->get_or_make_decl(this, *p); Bexpression* func_code = this->backend()->function_code_expression(initfn, func_loc); Bexpression* call = this->backend()->call_expression(init_bfn, func_code, empty_args, NULL, func_loc); Bstatement* ist = this->backend()->expression_statement(init_bfn, call); init_stmts.push_back(ist); } // Set up a magic function to do all the initialization actions. // This will be called if this package is imported. Bstatement* init_fncode = this->backend()->statement_list(init_stmts); if (this->need_init_fn_ || this->is_main_package()) { init_fndecl = this->create_initialization_function(init_fndecl, init_fncode); if (init_fndecl != NULL) func_decls.push_back(init_fndecl->func_value()->get_decl()); } // We should not have seen any new bindings created during the conversion. go_assert(count_definitions == this->current_bindings()->size_definitions()); // Define all globally declared values. if (!saw_errors()) this->backend()->write_global_definitions(type_decls, const_decls, func_decls, var_decls); } // Return the current block. Block* Gogo::current_block() { if (this->functions_.empty()) return NULL; else return this->functions_.back().blocks.back(); } // Look up a name in the current binding contour. If PFUNCTION is not // NULL, set it to the function in which the name is defined, or NULL // if the name is defined in global scope. Named_object* Gogo::lookup(const std::string& name, Named_object** pfunction) const { if (pfunction != NULL) *pfunction = NULL; if (Gogo::is_sink_name(name)) return Named_object::make_sink(); for (Open_functions::const_reverse_iterator p = this->functions_.rbegin(); p != this->functions_.rend(); ++p) { Named_object* ret = p->blocks.back()->bindings()->lookup(name); if (ret != NULL) { if (pfunction != NULL) *pfunction = p->function; return ret; } } if (this->package_ != NULL) { Named_object* ret = this->package_->bindings()->lookup(name); if (ret != NULL) { if (ret->package() != NULL) { std::string dot_alias = "." + ret->package()->package_name(); ret->package()->note_usage(dot_alias); } return ret; } } // We do not look in the global namespace. If we did, the global // namespace would effectively hide names which were defined in // package scope which we have not yet seen. Instead, // define_global_names is called after parsing is over to connect // undefined names at package scope with names defined at global // scope. return NULL; } // Look up a name in the current block, without searching enclosing // blocks. Named_object* Gogo::lookup_in_block(const std::string& name) const { go_assert(!this->functions_.empty()); go_assert(!this->functions_.back().blocks.empty()); return this->functions_.back().blocks.back()->bindings()->lookup_local(name); } // Look up a name in the global namespace. Named_object* Gogo::lookup_global(const char* name) const { return this->globals_->lookup(name); } // Add an imported package. Package* Gogo::add_imported_package(const std::string& real_name, const std::string& alias_arg, bool is_alias_exported, const std::string& pkgpath, const std::string& pkgpath_symbol, Location location, bool* padd_to_globals) { Package* ret = this->register_package(pkgpath, pkgpath_symbol, location); ret->set_package_name(real_name, location); *padd_to_globals = false; if (alias_arg == "_") ; else if (alias_arg == ".") { *padd_to_globals = true; std::string dot_alias = "." + real_name; ret->add_alias(dot_alias, location); } else { std::string alias = alias_arg; if (alias.empty()) { alias = real_name; is_alias_exported = Lex::is_exported_name(alias); } ret->add_alias(alias, location); alias = this->pack_hidden_name(alias, is_alias_exported); Named_object* no = this->package_->bindings()->add_package(alias, ret); if (!no->is_package()) return NULL; } return ret; } // Register a package. This package may or may not be imported. This // returns the Package structure for the package, creating if it // necessary. LOCATION is the location of the import statement that // led us to see this package. PKGPATH_SYMBOL is the symbol to use // for names in the package; it may be the empty string, in which case // we either get it later or make a guess when we need it. Package* Gogo::register_package(const std::string& pkgpath, const std::string& pkgpath_symbol, Location location) { Package* package = NULL; std::pair<Packages::iterator, bool> ins = this->packages_.insert(std::make_pair(pkgpath, package)); if (!ins.second) { // We have seen this package name before. package = ins.first->second; go_assert(package != NULL && package->pkgpath() == pkgpath); if (!pkgpath_symbol.empty()) package->set_pkgpath_symbol(pkgpath_symbol); if (Linemap::is_unknown_location(package->location())) package->set_location(location); } else { // First time we have seen this package name. package = new Package(pkgpath, pkgpath_symbol, location); go_assert(ins.first->second == NULL); ins.first->second = package; } return package; } // Return the pkgpath symbol for a package, given the pkgpath. std::string Gogo::pkgpath_symbol_for_package(const std::string& pkgpath) { Packages::iterator p = this->packages_.find(pkgpath); go_assert(p != this->packages_.end()); return p->second->pkgpath_symbol(); } // Start compiling a function. Named_object* Gogo::start_function(const std::string& name, Function_type* type, bool add_method_to_type, Location location) { bool at_top_level = this->functions_.empty(); Block* block = new Block(NULL, location); Named_object* enclosing = (at_top_level ? NULL : this->functions_.back().function); Function* function = new Function(type, enclosing, block, location); if (type->is_method()) { const Typed_identifier* receiver = type->receiver(); Variable* this_param = new Variable(receiver->type(), NULL, false, true, true, location); std::string rname = receiver->name(); unsigned rcounter = 0; // We need to give a nameless receiver parameter a synthesized name to // avoid having it clash with some other nameless param. FIXME. Gogo::rename_if_empty(&rname, "r", &rcounter); block->bindings()->add_variable(rname, NULL, this_param); } const Typed_identifier_list* parameters = type->parameters(); bool is_varargs = type->is_varargs(); unsigned pcounter = 0; if (parameters != NULL) { for (Typed_identifier_list::const_iterator p = parameters->begin(); p != parameters->end(); ++p) { Variable* param = new Variable(p->type(), NULL, false, true, false, p->location()); if (is_varargs && p + 1 == parameters->end()) param->set_is_varargs_parameter(); std::string pname = p->name(); // We need to give each nameless parameter a non-empty name to avoid // having it clash with some other nameless param. FIXME. Gogo::rename_if_empty(&pname, "p", &pcounter); block->bindings()->add_variable(pname, NULL, param); } } function->create_result_variables(this); const std::string* pname; std::string nested_name; bool is_init = false; if (Gogo::unpack_hidden_name(name) == "init" && !type->is_method()) { if ((type->parameters() != NULL && !type->parameters()->empty()) || (type->results() != NULL && !type->results()->empty())) go_error_at(location, "func init must have no arguments and no return values"); // There can be multiple "init" functions, so give them each a // different name. nested_name = this->init_function_name(); pname = &nested_name; is_init = true; } else if (!name.empty()) pname = &name; else { // Invent a name for a nested function. nested_name = this->nested_function_name(enclosing); pname = &nested_name; } Named_object* ret; if (Gogo::is_sink_name(*pname)) { std::string sname(this->sink_function_name()); ret = Named_object::make_function(sname, NULL, function); ret->func_value()->set_is_sink(); if (!type->is_method()) ret = this->package_->bindings()->add_named_object(ret); else if (add_method_to_type) { // We should report errors even for sink methods. Type* rtype = type->receiver()->type(); // Avoid points_to and deref to avoid getting an error if // the type is not yet defined. if (rtype->classification() == Type::TYPE_POINTER) rtype = rtype->points_to(); while (rtype->named_type() != NULL && rtype->named_type()->is_alias()) rtype = rtype->named_type()->real_type()->forwarded(); if (rtype->is_error_type()) ; else if (rtype->named_type() != NULL) { if (rtype->named_type()->named_object()->package() != NULL) go_error_at(type->receiver()->location(), "may not define methods on non-local type"); } else if (rtype->forward_declaration_type() != NULL) { // Go ahead and add the method in case we need to report // an error when we see the definition. rtype->forward_declaration_type()->add_existing_method(ret); } else go_error_at(type->receiver()->location(), ("invalid receiver type " "(receiver must be a named type)")); } } else if (!type->is_method()) { ret = this->package_->bindings()->add_function(*pname, NULL, function); if (!ret->is_function() || ret->func_value() != function) { // Redefinition error. Invent a name to avoid knockon // errors. std::string rname(this->redefined_function_name()); ret = this->package_->bindings()->add_function(rname, NULL, function); } } else { if (!add_method_to_type) ret = Named_object::make_function(name, NULL, function); else { go_assert(at_top_level); Type* rtype = type->receiver()->type(); while (rtype->named_type() != NULL && rtype->named_type()->is_alias()) rtype = rtype->named_type()->real_type()->forwarded(); // We want to look through the pointer created by the // parser, without getting an error if the type is not yet // defined. if (rtype->classification() == Type::TYPE_POINTER) rtype = rtype->points_to(); while (rtype->named_type() != NULL && rtype->named_type()->is_alias()) rtype = rtype->named_type()->real_type()->forwarded(); if (rtype->is_error_type()) ret = Named_object::make_function(name, NULL, function); else if (rtype->named_type() != NULL) { if (rtype->named_type()->named_object()->package() != NULL) { go_error_at(type->receiver()->location(), "may not define methods on non-local type"); ret = Named_object::make_function(name, NULL, function); } else { ret = rtype->named_type()->add_method(name, function); if (!ret->is_function()) { // Redefinition error. ret = Named_object::make_function(name, NULL, function); } } } else if (rtype->forward_declaration_type() != NULL) { Named_object* type_no = rtype->forward_declaration_type()->named_object(); if (type_no->is_unknown()) { // If we are seeing methods it really must be a // type. Declare it as such. An alternative would // be to support lists of methods for unknown // expressions. Either way the error messages if // this is not a type are going to get confusing. Named_object* declared = this->declare_package_type(type_no->name(), type_no->location()); go_assert(declared == type_no->unknown_value()->real_named_object()); } ret = rtype->forward_declaration_type()->add_method(name, function); } else { go_error_at(type->receiver()->location(), ("invalid receiver type (receiver must " "be a named type)")); ret = Named_object::make_function(name, NULL, function); } } this->package_->bindings()->add_method(ret); } this->functions_.resize(this->functions_.size() + 1); Open_function& of(this->functions_.back()); of.function = ret; of.blocks.push_back(block); if (is_init) { this->init_functions_.push_back(ret); this->need_init_fn_ = true; } return ret; } // Finish compiling a function. void Gogo::finish_function(Location location) { this->finish_block(location); go_assert(this->functions_.back().blocks.empty()); this->functions_.pop_back(); } // Return the current function. Named_object* Gogo::current_function() const { go_assert(!this->functions_.empty()); return this->functions_.back().function; } // Start a new block. void Gogo::start_block(Location location) { go_assert(!this->functions_.empty()); Block* block = new Block(this->current_block(), location); this->functions_.back().blocks.push_back(block); } // Finish a block. Block* Gogo::finish_block(Location location) { go_assert(!this->functions_.empty()); go_assert(!this->functions_.back().blocks.empty()); Block* block = this->functions_.back().blocks.back(); this->functions_.back().blocks.pop_back(); block->set_end_location(location); return block; } // Add an erroneous name. Named_object* Gogo::add_erroneous_name(const std::string& name) { return this->package_->bindings()->add_erroneous_name(name); } // Add an unknown name. Named_object* Gogo::add_unknown_name(const std::string& name, Location location) { return this->package_->bindings()->add_unknown_name(name, location); } // Declare a function. Named_object* Gogo::declare_function(const std::string& name, Function_type* type, Location location) { if (!type->is_method()) return this->current_bindings()->add_function_declaration(name, NULL, type, location); else { // We don't bother to add this to the list of global // declarations. Type* rtype = type->receiver()->type(); while (rtype->named_type() != NULL && rtype->named_type()->is_alias()) rtype = rtype->named_type()->real_type()->forwarded(); // We want to look through the pointer created by the // parser, without getting an error if the type is not yet // defined. if (rtype->classification() == Type::TYPE_POINTER) rtype = rtype->points_to(); while (rtype->named_type() != NULL && rtype->named_type()->is_alias()) rtype = rtype->named_type()->real_type()->forwarded(); if (rtype->is_error_type()) return NULL; else if (rtype->named_type() != NULL) return rtype->named_type()->add_method_declaration(name, NULL, type, location); else if (rtype->forward_declaration_type() != NULL) { Forward_declaration_type* ftype = rtype->forward_declaration_type(); return ftype->add_method_declaration(name, NULL, type, location); } else { go_error_at(type->receiver()->location(), "invalid receiver type (receiver must be a named type)"); return Named_object::make_erroneous_name(name); } } } // Add a label definition. Label* Gogo::add_label_definition(const std::string& label_name, Location location) { go_assert(!this->functions_.empty()); Function* func = this->functions_.back().function->func_value(); Label* label = func->add_label_definition(this, label_name, location); this->add_statement(Statement::make_label_statement(label, location)); return label; } // Add a label reference. Label* Gogo::add_label_reference(const std::string& label_name, Location location, bool issue_goto_errors) { go_assert(!this->functions_.empty()); Function* func = this->functions_.back().function->func_value(); return func->add_label_reference(this, label_name, location, issue_goto_errors); } // Return the current binding state. Bindings_snapshot* Gogo::bindings_snapshot(Location location) { return new Bindings_snapshot(this->current_block(), location); } // Add a statement. void Gogo::add_statement(Statement* statement) { go_assert(!this->functions_.empty() && !this->functions_.back().blocks.empty()); this->functions_.back().blocks.back()->add_statement(statement); } // Add a block. void Gogo::add_block(Block* block, Location location) { go_assert(!this->functions_.empty() && !this->functions_.back().blocks.empty()); Statement* statement = Statement::make_block_statement(block, location); this->functions_.back().blocks.back()->add_statement(statement); } // Add a constant. Named_object* Gogo::add_constant(const Typed_identifier& tid, Expression* expr, int iota_value) { return this->current_bindings()->add_constant(tid, NULL, expr, iota_value); } // Add a type. void Gogo::add_type(const std::string& name, Type* type, Location location) { Named_object* no = this->current_bindings()->add_type(name, NULL, type, location); if (!this->in_global_scope() && no->is_type()) { Named_object* f = this->functions_.back().function; unsigned int index; if (f->is_function()) index = f->func_value()->new_local_type_index(); else index = 0; no->type_value()->set_in_function(f, index); } } // Add a named type. void Gogo::add_named_type(Named_type* type) { go_assert(this->in_global_scope()); this->current_bindings()->add_named_type(type); } // Declare a type. Named_object* Gogo::declare_type(const std::string& name, Location location) { Bindings* bindings = this->current_bindings(); Named_object* no = bindings->add_type_declaration(name, NULL, location); if (!this->in_global_scope() && no->is_type_declaration()) { Named_object* f = this->functions_.back().function; unsigned int index; if (f->is_function()) index = f->func_value()->new_local_type_index(); else index = 0; no->type_declaration_value()->set_in_function(f, index); } return no; } // Declare a type at the package level. Named_object* Gogo::declare_package_type(const std::string& name, Location location) { return this->package_->bindings()->add_type_declaration(name, NULL, location); } // Declare a function at the package level. Named_object* Gogo::declare_package_function(const std::string& name, Function_type* type, Location location) { return this->package_->bindings()->add_function_declaration(name, NULL, type, location); } // Add a function declaration to the list of functions we may want to // inline. void Gogo::add_imported_inlinable_function(Named_object* no) { go_assert(no->is_function_declaration()); Function_declaration* fd = no->func_declaration_value(); if (fd->is_on_inlinable_list()) return; this->imported_inlinable_functions_.push_back(no); fd->set_is_on_inlinable_list(); } // Define a type which was already declared. void Gogo::define_type(Named_object* no, Named_type* type) { this->current_bindings()->define_type(no, type); } // Add a variable. Named_object* Gogo::add_variable(const std::string& name, Variable* variable) { Named_object* no = this->current_bindings()->add_variable(name, NULL, variable); // In a function the middle-end wants to see a DECL_EXPR node. if (no != NULL && no->is_variable() && !no->var_value()->is_parameter() && !this->functions_.empty()) this->add_statement(Statement::make_variable_declaration(no)); return no; } void Gogo::rename_if_empty(std::string* pname, const char* tag, unsigned* count) { if (pname->empty() || Gogo::is_sink_name(*pname)) { char buf[50]; go_assert(strlen(tag) < 10); snprintf(buf, sizeof buf, "%s.%u", tag, *count); ++(*count); *pname = buf; } } // Add a sink--a reference to the blank identifier _. Named_object* Gogo::add_sink() { return Named_object::make_sink(); } // Add a named object for a dot import. void Gogo::add_dot_import_object(Named_object* no) { // If the name already exists, then it was defined in some file seen // earlier. If the earlier name is just a declaration, don't add // this name, because that will cause the previous declaration to // merge to this imported name, which should not happen. Just add // this name to the list of file block names to get appropriate // errors if we see a later definition. Named_object* e = this->package_->bindings()->lookup(no->name()); if (e != NULL && e->package() == NULL) { if (e->is_unknown()) e = e->resolve(); if (e->package() == NULL && (e->is_type_declaration() || e->is_function_declaration() || e->is_unknown())) { this->add_file_block_name(no->name(), no->location()); return; } } this->current_bindings()->add_named_object(no); } // Add a linkname. This implements the go:linkname compiler directive. // We only support this for functions and function declarations. void Gogo::add_linkname(const std::string& go_name, bool is_exported, const std::string& ext_name, Location loc) { Named_object* no = this->package_->bindings()->lookup(this->pack_hidden_name(go_name, is_exported)); if (no == NULL) go_error_at(loc, "%s is not defined", go_name.c_str()); else if (no->is_function()) { if (ext_name.empty()) no->func_value()->set_is_exported_by_linkname(); else no->func_value()->set_asm_name(ext_name); } else if (no->is_function_declaration()) { if (ext_name.empty()) go_error_at(loc, ("%<//go:linkname%> missing external name " "for declaration of %s"), go_name.c_str()); else no->func_declaration_value()->set_asm_name(ext_name); } else go_error_at(loc, ("%s is not a function; " "%<//go:linkname%> is only supported for functions"), go_name.c_str()); } // Mark all local variables used. This is used when some types of // parse error occur. void Gogo::mark_locals_used() { for (Open_functions::iterator pf = this->functions_.begin(); pf != this->functions_.end(); ++pf) { for (std::vector<Block*>::iterator pb = pf->blocks.begin(); pb != pf->blocks.end(); ++pb) (*pb)->bindings()->mark_locals_used(); } } // Record that we've seen an interface type. void Gogo::record_interface_type(Interface_type* itype) { this->interface_types_.push_back(itype); } // Define the global names. We do this only after parsing all the // input files, because the program might define the global names // itself. void Gogo::define_global_names() { if (this->is_main_package()) { // Every Go program has to import the runtime package, so that // it is properly initialized. We can't use // predeclared_location here as it will cause runtime functions // to appear to be builtin functions. this->import_package("runtime", "_", false, false, this->package_->location()); } for (Bindings::const_declarations_iterator p = this->globals_->begin_declarations(); p != this->globals_->end_declarations(); ++p) { Named_object* global_no = p->second; std::string name(Gogo::pack_hidden_name(global_no->name(), false)); Named_object* no = this->package_->bindings()->lookup(name); if (no == NULL) continue; no = no->resolve(); if (no->is_type_declaration()) { if (global_no->is_type()) { if (no->type_declaration_value()->has_methods()) { for (std::vector<Named_object*>::const_iterator pm = no->type_declaration_value()->methods()->begin(); pm != no->type_declaration_value()->methods()->end(); pm++) go_error_at((*pm)->location(), "may not define methods on non-local type"); } no->set_type_value(global_no->type_value()); } else { go_error_at(no->location(), "expected type"); Type* errtype = Type::make_error_type(); Named_object* err = Named_object::make_type("erroneous_type", NULL, errtype, Linemap::predeclared_location()); no->set_type_value(err->type_value()); } } else if (no->is_unknown()) no->unknown_value()->set_real_named_object(global_no); } // Give an error if any name is defined in both the package block // and the file block. For example, this can happen if one file // imports "fmt" and another file defines a global variable fmt. for (Bindings::const_declarations_iterator p = this->package_->bindings()->begin_declarations(); p != this->package_->bindings()->end_declarations(); ++p) { if (p->second->is_unknown() && p->second->unknown_value()->real_named_object() == NULL) { // No point in warning about an undefined name, as we will // get other errors later anyhow. continue; } File_block_names::const_iterator pf = this->file_block_names_.find(p->second->name()); if (pf != this->file_block_names_.end()) { std::string n = p->second->message_name(); go_error_at(p->second->location(), "%qs defined as both imported name and global name", n.c_str()); go_inform(pf->second, "%qs imported here", n.c_str()); } // No package scope identifier may be named "init". if (!p->second->is_function() && Gogo::unpack_hidden_name(p->second->name()) == "init") { go_error_at(p->second->location(), "cannot declare init - must be func"); } } } // Clear out names in file scope. void Gogo::clear_file_scope() { this->package_->bindings()->clear_file_scope(this); // Warn about packages which were imported but not used. bool quiet = saw_errors(); for (Packages::iterator p = this->packages_.begin(); p != this->packages_.end(); ++p) { Package* package = p->second; if (package != this->package_ && !quiet) { for (Package::Aliases::const_iterator p1 = package->aliases().begin(); p1 != package->aliases().end(); ++p1) { if (!p1->second->used()) { // Give a more refined error message if the alias name is known. std::string pkg_name = package->package_name(); if (p1->first != pkg_name && p1->first[0] != '.') { go_error_at(p1->second->location(), "imported and not used: %s as %s", Gogo::message_name(pkg_name).c_str(), Gogo::message_name(p1->first).c_str()); } else go_error_at(p1->second->location(), "imported and not used: %s", Gogo::message_name(pkg_name).c_str()); } } } package->clear_used(); } this->current_file_imported_unsafe_ = false; } // Queue up a type-specific hash function for later writing. These // are written out in write_specific_type_functions, called after the // parse tree is lowered. void Gogo::queue_hash_function(Type* type, int64_t size, const std::string& hash_name, Function_type* hash_fntype) { go_assert(!this->specific_type_functions_are_written_); go_assert(!this->in_global_scope()); Specific_type_function::Specific_type_function_kind kind = Specific_type_function::SPECIFIC_HASH; Specific_type_function* tsf = new Specific_type_function(type, NULL, size, kind, hash_name, hash_fntype); this->specific_type_functions_.push_back(tsf); } // Queue up a type-specific equal function for later writing. These // are written out in write_specific_type_functions, called after the // parse tree is lowered. void Gogo::queue_equal_function(Type* type, Named_type* name, int64_t size, const std::string& equal_name, Function_type* equal_fntype) { go_assert(!this->specific_type_functions_are_written_); go_assert(!this->in_global_scope()); Specific_type_function::Specific_type_function_kind kind = Specific_type_function::SPECIFIC_EQUAL; Specific_type_function* tsf = new Specific_type_function(type, name, size, kind, equal_name, equal_fntype); this->specific_type_functions_.push_back(tsf); } // Look for types which need specific hash or equality functions. class Specific_type_functions : public Traverse { public: Specific_type_functions(Gogo* gogo) : Traverse(traverse_types), gogo_(gogo) { } int type(Type*); private: Gogo* gogo_; }; int Specific_type_functions::type(Type* t) { switch (t->classification()) { case Type::TYPE_NAMED: { Named_type* nt = t->named_type(); if (nt->is_alias()) return TRAVERSE_CONTINUE; if (t->needs_specific_type_functions(this->gogo_)) t->equal_function(this->gogo_, nt, NULL); // If this is a struct type, we don't want to make functions // for the unnamed struct. Type* rt = nt->real_type(); if (rt->struct_type() == NULL) { if (Type::traverse(rt, this) == TRAVERSE_EXIT) return TRAVERSE_EXIT; } else { // If this type is defined in another package, then we don't // need to worry about the unexported fields. bool is_defined_elsewhere = nt->named_object()->package() != NULL; const Struct_field_list* fields = rt->struct_type()->fields(); for (Struct_field_list::const_iterator p = fields->begin(); p != fields->end(); ++p) { if (is_defined_elsewhere && Gogo::is_hidden_name(p->field_name())) continue; if (Type::traverse(p->type(), this) == TRAVERSE_EXIT) return TRAVERSE_EXIT; } } return TRAVERSE_SKIP_COMPONENTS; } case Type::TYPE_STRUCT: case Type::TYPE_ARRAY: if (t->needs_specific_type_functions(this->gogo_)) t->equal_function(this->gogo_, NULL, NULL); break; case Type::TYPE_MAP: { Type* key_type = t->map_type()->key_type(); if (key_type->needs_specific_type_functions(this->gogo_)) key_type->hash_function(this->gogo_, NULL); } break; default: break; } return TRAVERSE_CONTINUE; } // Write out type specific functions. void Gogo::write_specific_type_functions() { Specific_type_functions stf(this); this->traverse(&stf); while (!this->specific_type_functions_.empty()) { Specific_type_function* tsf = this->specific_type_functions_.back(); this->specific_type_functions_.pop_back(); if (tsf->kind == Specific_type_function::SPECIFIC_HASH) tsf->type->write_hash_function(this, tsf->size, tsf->fnname, tsf->fntype); else tsf->type->write_equal_function(this, tsf->name, tsf->size, tsf->fnname, tsf->fntype); delete tsf; } this->specific_type_functions_are_written_ = true; } // Traverse the tree. void Gogo::traverse(Traverse* traverse) { // Traverse the current package first for consistency. The other // packages will only contain imported types, constants, and // declarations. if (this->package_->bindings()->traverse(traverse, true) == TRAVERSE_EXIT) return; for (Packages::const_iterator p = this->packages_.begin(); p != this->packages_.end(); ++p) { if (p->second != this->package_) { if (p->second->bindings()->traverse(traverse, true) == TRAVERSE_EXIT) break; } } } // Add a type to verify. This is used for types of sink variables, in // order to give appropriate error messages. void Gogo::add_type_to_verify(Type* type) { this->verify_types_.push_back(type); } // Traversal class used to verify types. class Verify_types : public Traverse { public: Verify_types() : Traverse(traverse_types) { } int type(Type*); }; // Verify that a type is correct. int Verify_types::type(Type* t) { if (!t->verify()) return TRAVERSE_SKIP_COMPONENTS; return TRAVERSE_CONTINUE; } // Verify that all types are correct. void Gogo::verify_types() { Verify_types traverse; this->traverse(&traverse); for (std::vector<Type*>::iterator p = this->verify_types_.begin(); p != this->verify_types_.end(); ++p) (*p)->verify(); this->verify_types_.clear(); } // Traversal class used to lower parse tree. class Lower_parse_tree : public Traverse { public: Lower_parse_tree(Gogo* gogo, Named_object* function) : Traverse(traverse_variables | traverse_constants | traverse_functions | traverse_statements | traverse_expressions), gogo_(gogo), function_(function), iota_value_(-1), inserter_() { } void set_inserter(const Statement_inserter* inserter) { this->inserter_ = *inserter; } int variable(Named_object*); int constant(Named_object*, bool); int function(Named_object*); int statement(Block*, size_t* pindex, Statement*); int expression(Expression**); private: // General IR. Gogo* gogo_; // The function we are traversing. Named_object* function_; // Value to use for the predeclared constant iota. int iota_value_; // Current statement inserter for use by expressions. Statement_inserter inserter_; }; // Lower variables. int Lower_parse_tree::variable(Named_object* no) { if (!no->is_variable()) return TRAVERSE_CONTINUE; if (no->is_variable() && no->var_value()->is_global()) { // Global variables can have loops in their initialization // expressions. This is handled in lower_init_expression. no->var_value()->lower_init_expression(this->gogo_, this->function_, &this->inserter_); return TRAVERSE_CONTINUE; } // This is a local variable. We are going to return // TRAVERSE_SKIP_COMPONENTS here because we want to traverse the // initialization expression when we reach the variable declaration // statement. However, that means that we need to traverse the type // ourselves. if (no->var_value()->has_type()) { Type* type = no->var_value()->type(); if (type != NULL) { if (Type::traverse(type, this) == TRAVERSE_EXIT) return TRAVERSE_EXIT; } } go_assert(!no->var_value()->has_pre_init()); return TRAVERSE_SKIP_COMPONENTS; } // Lower constants. We handle constants specially so that we can set // the right value for the predeclared constant iota. This works in // conjunction with the way we lower Const_expression objects. int Lower_parse_tree::constant(Named_object* no, bool) { Named_constant* nc = no->const_value(); // Don't get into trouble if the constant's initializer expression // refers to the constant itself. if (nc->lowering()) return TRAVERSE_CONTINUE; nc->set_lowering(); go_assert(this->iota_value_ == -1); this->iota_value_ = nc->iota_value(); nc->traverse_expression(this); this->iota_value_ = -1; nc->clear_lowering(); // We will traverse the expression a second time, but that will be // fast. return TRAVERSE_CONTINUE; } // Lower the body of a function, and set the closure type. Record the // function while lowering it, so that we can pass it down when // lowering an expression. int Lower_parse_tree::function(Named_object* no) { no->func_value()->set_closure_type(); go_assert(this->function_ == NULL); this->function_ = no; int t = no->func_value()->traverse(this); this->function_ = NULL; if (t == TRAVERSE_EXIT) return t; return TRAVERSE_SKIP_COMPONENTS; } // Lower statement parse trees. int Lower_parse_tree::statement(Block* block, size_t* pindex, Statement* sorig) { // Because we explicitly traverse the statement's contents // ourselves, we want to skip block statements here. There is // nothing to lower in a block statement. if (sorig->is_block_statement()) return TRAVERSE_CONTINUE; Statement_inserter hold_inserter(this->inserter_); this->inserter_ = Statement_inserter(block, pindex); // Lower the expressions first. int t = sorig->traverse_contents(this); if (t == TRAVERSE_EXIT) { this->inserter_ = hold_inserter; return t; } // Keep lowering until nothing changes. Statement* s = sorig; while (true) { Statement* snew = s->lower(this->gogo_, this->function_, block, &this->inserter_); if (snew == s) break; s = snew; t = s->traverse_contents(this); if (t == TRAVERSE_EXIT) { this->inserter_ = hold_inserter; return t; } } if (s != sorig) block->replace_statement(*pindex, s); this->inserter_ = hold_inserter; return TRAVERSE_SKIP_COMPONENTS; } // Lower expression parse trees. int Lower_parse_tree::expression(Expression** pexpr) { // We have to lower all subexpressions first, so that we can get // their type if necessary. This is awkward, because we don't have // a postorder traversal pass. if ((*pexpr)->traverse_subexpressions(this) == TRAVERSE_EXIT) return TRAVERSE_EXIT; // Keep lowering until nothing changes. while (true) { Expression* e = *pexpr; Expression* enew = e->lower(this->gogo_, this->function_, &this->inserter_, this->iota_value_); if (enew == e) break; if (enew->traverse_subexpressions(this) == TRAVERSE_EXIT) return TRAVERSE_EXIT; *pexpr = enew; } // Lower the type of this expression before the parent looks at it, // in case the type contains an array that has expressions in its // length. Skip an Unknown_expression, as at this point that means // a composite literal key that does not have a type. if ((*pexpr)->unknown_expression() == NULL) Type::traverse((*pexpr)->type(), this); return TRAVERSE_SKIP_COMPONENTS; } // Lower the parse tree. This is called after the parse is complete, // when all names should be resolved. void Gogo::lower_parse_tree() { Lower_parse_tree lower_parse_tree(this, NULL); this->traverse(&lower_parse_tree); // If we found any functions defined in other packages that are // inlinables, import their bodies and turn them into functions. // // Note that as we import inlinable functions we may find more // inlinable functions, so don't use an iterator. for (size_t i = 0; i < this->imported_inlinable_functions_.size(); i++) { Named_object* no = this->imported_inlinable_functions_[i]; no->func_declaration_value()->import_function_body(this, no); } // There might be type definitions that involve expressions such as the // array length. Make sure to lower these expressions as well. Otherwise, // errors hidden within a type can introduce unexpected errors into later // passes. for (std::vector<Type*>::iterator p = this->verify_types_.begin(); p != this->verify_types_.end(); ++p) Type::traverse(*p, &lower_parse_tree); } // Lower a block. void Gogo::lower_block(Named_object* function, Block* block) { Lower_parse_tree lower_parse_tree(this, function); block->traverse(&lower_parse_tree); } // Lower an expression. INSERTER may be NULL, in which case the // expression had better not need to create any temporaries. void Gogo::lower_expression(Named_object* function, Statement_inserter* inserter, Expression** pexpr) { Lower_parse_tree lower_parse_tree(this, function); if (inserter != NULL) lower_parse_tree.set_inserter(inserter); lower_parse_tree.expression(pexpr); } // Lower a constant. This is called when lowering a reference to a // constant. We have to make sure that the constant has already been // lowered. void Gogo::lower_constant(Named_object* no) { go_assert(no->is_const()); Lower_parse_tree lower(this, NULL); lower.constant(no, false); } // Make implicit type conversions explicit. Currently only does for // interface conversions, so the escape analysis can see them and // optimize. class Add_conversions : public Traverse { public: Add_conversions() : Traverse(traverse_statements | traverse_expressions) { } int statement(Block*, size_t* pindex, Statement*); int expression(Expression**); }; // Add explicit conversions in a statement. int Add_conversions::statement(Block*, size_t*, Statement* sorig) { sorig->add_conversions(); return TRAVERSE_CONTINUE; } // Add explicit conversions in an expression. int Add_conversions::expression(Expression** pexpr) { (*pexpr)->add_conversions(); return TRAVERSE_CONTINUE; } void Gogo::add_conversions() { Add_conversions add_conversions; this->traverse(&add_conversions); } void Gogo::add_conversions_in_block(Block *b) { Add_conversions add_conversions; b->traverse(&add_conversions); } // Traversal class for simple deadcode elimination. class Remove_deadcode : public Traverse { public: Remove_deadcode() : Traverse(traverse_statements | traverse_expressions) { } int statement(Block*, size_t* pindex, Statement*); int expression(Expression**); }; // Remove deadcode in a statement. int Remove_deadcode::statement(Block* block, size_t* pindex, Statement* sorig) { Location loc = sorig->location(); If_statement* ifs = sorig->if_statement(); if (ifs != NULL) { // Remove the dead branch of an if statement. bool bval; if (ifs->condition()->boolean_constant_value(&bval)) { Statement* s; if (bval) s = Statement::make_block_statement(ifs->then_block(), loc); else if (ifs->else_block() != NULL) s = Statement::make_block_statement(ifs->else_block(), loc); else // Make a dummy statement. s = Statement::make_statement(Expression::make_boolean(false, loc), true); block->replace_statement(*pindex, s); } } return TRAVERSE_CONTINUE; } // Remove deadcode in an expression. int Remove_deadcode::expression(Expression** pexpr) { // Discard the right arm of a shortcut expression of constant value. Binary_expression* be = (*pexpr)->binary_expression(); bool bval; if (be != NULL && be->boolean_constant_value(&bval) && (be->op() == OPERATOR_ANDAND || be->op() == OPERATOR_OROR)) *pexpr = Expression::make_boolean(bval, be->location()); return TRAVERSE_CONTINUE; } // Remove deadcode. void Gogo::remove_deadcode() { Remove_deadcode remove_deadcode; this->traverse(&remove_deadcode); } // Traverse the tree to create function descriptors as needed. class Create_function_descriptors : public Traverse { public: Create_function_descriptors(Gogo* gogo) : Traverse(traverse_functions | traverse_expressions), gogo_(gogo) { } int function(Named_object*); int expression(Expression**); private: Gogo* gogo_; }; // Create a descriptor for every top-level exported function. int Create_function_descriptors::function(Named_object* no) { if (no->is_function() && no->func_value()->enclosing() == NULL && !no->func_value()->is_method() && !Gogo::is_hidden_name(no->name()) && !Gogo::is_thunk(no)) no->func_value()->descriptor(this->gogo_, no); return TRAVERSE_CONTINUE; } // If we see a function referenced in any way other than calling it, // create a descriptor for it. int Create_function_descriptors::expression(Expression** pexpr) { Expression* expr = *pexpr; Func_expression* fe = expr->func_expression(); if (fe != NULL) { // We would not get here for a call to this function, so this is // a reference to a function other than calling it. We need a // descriptor. if (fe->closure() != NULL) return TRAVERSE_CONTINUE; Named_object* no = fe->named_object(); if (no->is_function() && !no->func_value()->is_method()) no->func_value()->descriptor(this->gogo_, no); else if (no->is_function_declaration() && !no->func_declaration_value()->type()->is_method() && !Linemap::is_predeclared_location(no->location())) no->func_declaration_value()->descriptor(this->gogo_, no); return TRAVERSE_CONTINUE; } Bound_method_expression* bme = expr->bound_method_expression(); if (bme != NULL) { // We would not get here for a call to this method, so this is a // method value. We need to create a thunk. Bound_method_expression::create_thunk(this->gogo_, bme->method(), bme->function()); return TRAVERSE_CONTINUE; } Interface_field_reference_expression* ifre = expr->interface_field_reference_expression(); if (ifre != NULL) { // We would not get here for a call to this interface method, so // this is a method value. We need to create a thunk. Interface_type* type = ifre->expr()->type()->interface_type(); if (type != NULL) Interface_field_reference_expression::create_thunk(this->gogo_, type, ifre->name()); return TRAVERSE_CONTINUE; } Call_expression* ce = expr->call_expression(); if (ce != NULL) { Expression* fn = ce->fn(); if (fn->func_expression() != NULL || fn->bound_method_expression() != NULL || fn->interface_field_reference_expression() != NULL) { // Traverse the arguments but not the function. Expression_list* args = ce->args(); if (args != NULL) { if (args->traverse(this) == TRAVERSE_EXIT) return TRAVERSE_EXIT; } return TRAVERSE_SKIP_COMPONENTS; } } return TRAVERSE_CONTINUE; } // Create function descriptors as needed. We need a function // descriptor for all exported functions and for all functions that // are referenced without being called. void Gogo::create_function_descriptors() { // Create a function descriptor for any exported function that is // declared in this package. This is so that we have a descriptor // for functions written in assembly. Gather the descriptors first // so that we don't add declarations while looping over them. std::vector<Named_object*> fndecls; Bindings* b = this->package_->bindings(); for (Bindings::const_declarations_iterator p = b->begin_declarations(); p != b->end_declarations(); ++p) { Named_object* no = p->second; if (no->is_function_declaration() && !no->func_declaration_value()->type()->is_method() && !Linemap::is_predeclared_location(no->location()) && !Gogo::is_hidden_name(no->name())) fndecls.push_back(no); } for (std::vector<Named_object*>::const_iterator p = fndecls.begin(); p != fndecls.end(); ++p) (*p)->func_declaration_value()->descriptor(this, *p); fndecls.clear(); Create_function_descriptors cfd(this); this->traverse(&cfd); } // Finalize the methods of an interface type. int Finalize_methods::type(Type* t) { // Check the classification so that we don't finalize the methods // twice for a named interface type. switch (t->classification()) { case Type::TYPE_INTERFACE: t->interface_type()->finalize_methods(); break; case Type::TYPE_NAMED: { Named_type* nt = t->named_type(); Type* rt = nt->real_type(); if (rt->classification() != Type::TYPE_STRUCT) { // Finalize the methods of the real type first. if (Type::traverse(rt, this) == TRAVERSE_EXIT) return TRAVERSE_EXIT; // Finalize the methods of this type. nt->finalize_methods(this->gogo_); } else { // We don't want to finalize the methods of a named struct // type, as the methods should be attached to the named // type, not the struct type. We just want to finalize // the field types. // // It is possible that a field type refers indirectly to // this type, such as via a field with function type with // an argument or result whose type is this type. To // avoid the cycle, first finalize the methods of any // embedded types, which are the only types we need to // know to finalize the methods of this type. const Struct_field_list* fields = rt->struct_type()->fields(); if (fields != NULL) { for (Struct_field_list::const_iterator pf = fields->begin(); pf != fields->end(); ++pf) { if (pf->is_anonymous()) { if (Type::traverse(pf->type(), this) == TRAVERSE_EXIT) return TRAVERSE_EXIT; } } } // Finalize the methods of this type. nt->finalize_methods(this->gogo_); // Finalize all the struct fields. if (rt->struct_type()->traverse_field_types(this) == TRAVERSE_EXIT) return TRAVERSE_EXIT; } // If this type is defined in a different package, then finalize the // types of all the methods, since we won't see them otherwise. if (nt->named_object()->package() != NULL && nt->has_any_methods()) { const Methods* methods = nt->methods(); for (Methods::const_iterator p = methods->begin(); p != methods->end(); ++p) { if (Type::traverse(p->second->type(), this) == TRAVERSE_EXIT) return TRAVERSE_EXIT; } } // Finalize the types of all methods that are declared but not // defined, since we won't see the declarations otherwise. if (nt->named_object()->package() == NULL && nt->local_methods() != NULL) { const Bindings* methods = nt->local_methods(); for (Bindings::const_declarations_iterator p = methods->begin_declarations(); p != methods->end_declarations(); p++) { if (p->second->is_function_declaration()) { Type* mt = p->second->func_declaration_value()->type(); if (Type::traverse(mt, this) == TRAVERSE_EXIT) return TRAVERSE_EXIT; } } } return TRAVERSE_SKIP_COMPONENTS; } case Type::TYPE_STRUCT: // Traverse the field types first in case there is an embedded // field with methods that the struct should inherit. if (t->struct_type()->traverse_field_types(this) == TRAVERSE_EXIT) return TRAVERSE_EXIT; t->struct_type()->finalize_methods(this->gogo_); return TRAVERSE_SKIP_COMPONENTS; default: break; } return TRAVERSE_CONTINUE; } // Finalize method lists and build stub methods for types. void Gogo::finalize_methods() { Finalize_methods finalize(this); this->traverse(&finalize); } // Finalize the method list for a type. This is called when a type is // parsed for an inlined function body, which happens after the // finalize_methods pass. void Gogo::finalize_methods_for_type(Type* type) { Finalize_methods finalize(this); Type::traverse(type, &finalize); } // Set types for unspecified variables and constants. void Gogo::determine_types() { Bindings* bindings = this->current_bindings(); for (Bindings::const_definitions_iterator p = bindings->begin_definitions(); p != bindings->end_definitions(); ++p) { if ((*p)->is_function()) (*p)->func_value()->determine_types(); else if ((*p)->is_variable()) (*p)->var_value()->determine_type(); else if ((*p)->is_const()) (*p)->const_value()->determine_type(); // See if a variable requires us to build an initialization // function. We know that we will see all global variables // here. if (!this->need_init_fn_ && (*p)->is_variable()) { Variable* variable = (*p)->var_value(); // If this is a global variable which requires runtime // initialization, we need an initialization function. if (!variable->is_global()) ; else if (variable->init() == NULL) ; else if (variable->type()->interface_type() != NULL) this->need_init_fn_ = true; else if (variable->init()->is_constant()) ; else if (!variable->init()->is_composite_literal()) this->need_init_fn_ = true; else if (variable->init()->is_nonconstant_composite_literal()) this->need_init_fn_ = true; // If this is a global variable which holds a pointer value, // then we need an initialization function to register it as a // GC root. if (variable->is_global() && variable->type()->has_pointer()) this->need_init_fn_ = true; } } // Determine the types of constants in packages. for (Packages::const_iterator p = this->packages_.begin(); p != this->packages_.end(); ++p) p->second->determine_types(); } // Traversal class used for type checking. class Check_types_traverse : public Traverse { public: Check_types_traverse(Gogo* gogo) : Traverse(traverse_variables | traverse_constants | traverse_functions | traverse_statements | traverse_expressions), gogo_(gogo) { } int variable(Named_object*); int constant(Named_object*, bool); int function(Named_object*); int statement(Block*, size_t* pindex, Statement*); int expression(Expression**); private: // General IR. Gogo* gogo_; }; // Check that a variable initializer has the right type. int Check_types_traverse::variable(Named_object* named_object) { if (named_object->is_variable()) { Variable* var = named_object->var_value(); // Give error if variable type is not defined. var->type()->base(); Expression* init = var->init(); std::string reason; if (init != NULL && !Type::are_assignable(var->type(), init->type(), &reason)) { if (reason.empty()) go_error_at(var->location(), "incompatible type in initialization"); else go_error_at(var->location(), "incompatible type in initialization (%s)", reason.c_str()); init = Expression::make_error(named_object->location()); var->clear_init(); } else if (init != NULL && init->func_expression() != NULL) { Named_object* no = init->func_expression()->named_object(); Function_type* fntype; if (no->is_function()) fntype = no->func_value()->type(); else if (no->is_function_declaration()) fntype = no->func_declaration_value()->type(); else go_unreachable(); // Builtin functions cannot be used as function values for variable // initialization. if (fntype->is_builtin()) { go_error_at(init->location(), "invalid use of special built-in function %qs; " "must be called", no->message_name().c_str()); } } if (!var->is_used() && !var->is_global() && !var->is_parameter() && !var->is_receiver() && !var->type()->is_error() && (init == NULL || !init->is_error_expression()) && !Lex::is_invalid_identifier(named_object->name())) go_error_at(var->location(), "%qs declared and not used", named_object->message_name().c_str()); } return TRAVERSE_CONTINUE; } // Check that a constant initializer has the right type. int Check_types_traverse::constant(Named_object* named_object, bool) { Named_constant* constant = named_object->const_value(); Type* ctype = constant->type(); if (ctype->integer_type() == NULL && ctype->float_type() == NULL && ctype->complex_type() == NULL && !ctype->is_boolean_type() && !ctype->is_string_type()) { if (ctype->is_nil_type()) go_error_at(constant->location(), "const initializer cannot be nil"); else if (!ctype->is_error()) go_error_at(constant->location(), "invalid constant type"); constant->set_error(); } else if (!constant->expr()->is_constant()) { go_error_at(constant->expr()->location(), "expression is not constant"); constant->set_error(); } else if (!Type::are_assignable(constant->type(), constant->expr()->type(), NULL)) { go_error_at(constant->location(), "initialization expression has wrong type"); constant->set_error(); } return TRAVERSE_CONTINUE; } // There are no types to check in a function, but this is where we // issue warnings about labels which are defined but not referenced. int Check_types_traverse::function(Named_object* no) { no->func_value()->check_labels(); return TRAVERSE_CONTINUE; } // Check that types are valid in a statement. int Check_types_traverse::statement(Block*, size_t*, Statement* s) { s->check_types(this->gogo_); return TRAVERSE_CONTINUE; } // Check that types are valid in an expression. int Check_types_traverse::expression(Expression** expr) { (*expr)->check_types(this->gogo_); return TRAVERSE_CONTINUE; } // Check that types are valid. void Gogo::check_types() { Check_types_traverse traverse(this); this->traverse(&traverse); Bindings* bindings = this->current_bindings(); for (Bindings::const_declarations_iterator p = bindings->begin_declarations(); p != bindings->end_declarations(); ++p) { // Also check the types in a function declaration's signature. Named_object* no = p->second; if (no->is_function_declaration()) no->func_declaration_value()->check_types(); } } // Check the types in a single block. void Gogo::check_types_in_block(Block* block) { Check_types_traverse traverse(this); block->traverse(&traverse); } // A traversal class which finds all the expressions which must be // evaluated in order within a statement or larger expression. This // is used to implement the rules about order of evaluation. class Find_eval_ordering : public Traverse { private: typedef std::vector<Expression**> Expression_pointers; public: Find_eval_ordering() : Traverse(traverse_blocks | traverse_statements | traverse_expressions), exprs_() { } size_t size() const { return this->exprs_.size(); } typedef Expression_pointers::const_iterator const_iterator; const_iterator begin() const { return this->exprs_.begin(); } const_iterator end() const { return this->exprs_.end(); } protected: int block(Block*) { return TRAVERSE_SKIP_COMPONENTS; } int statement(Block*, size_t*, Statement*) { return TRAVERSE_SKIP_COMPONENTS; } int expression(Expression**); private: // A list of pointers to expressions with side-effects. Expression_pointers exprs_; }; // If an expression must be evaluated in order, put it on the list. int Find_eval_ordering::expression(Expression** expression_pointer) { Binary_expression* binexp = (*expression_pointer)->binary_expression(); if (binexp != NULL && (binexp->op() == OPERATOR_ANDAND || binexp->op() == OPERATOR_OROR)) { // Shortcut expressions may potentially have side effects which need // to be ordered, so add them to the list. // We don't order its subexpressions here since they may be evaluated // conditionally. This is handled in remove_shortcuts. this->exprs_.push_back(expression_pointer); return TRAVERSE_SKIP_COMPONENTS; } // We have to look at subexpressions before this one. if ((*expression_pointer)->traverse_subexpressions(this) == TRAVERSE_EXIT) return TRAVERSE_EXIT; if ((*expression_pointer)->must_eval_in_order()) this->exprs_.push_back(expression_pointer); return TRAVERSE_SKIP_COMPONENTS; } // A traversal class for ordering evaluations. class Order_eval : public Traverse { public: Order_eval(Gogo* gogo) : Traverse(traverse_variables | traverse_statements), gogo_(gogo) { } int variable(Named_object*); int statement(Block*, size_t*, Statement*); private: // The IR. Gogo* gogo_; }; // Implement the order of evaluation rules for a statement. int Order_eval::statement(Block* block, size_t* pindex, Statement* stmt) { // FIXME: This approach doesn't work for switch statements, because // we add the new statements before the whole switch when we need to // instead add them just before the switch expression. The right // fix is probably to lower switch statements with nonconstant cases // to a series of conditionals. if (stmt->switch_statement() != NULL) return TRAVERSE_CONTINUE; Find_eval_ordering find_eval_ordering; // If S is a variable declaration, then ordinary traversal won't do // anything. We want to explicitly traverse the initialization // expression if there is one. Variable_declaration_statement* vds = stmt->variable_declaration_statement(); Expression* init = NULL; Expression* orig_init = NULL; if (vds == NULL) stmt->traverse_contents(&find_eval_ordering); else { init = vds->var()->var_value()->init(); if (init == NULL) return TRAVERSE_CONTINUE; orig_init = init; // It might seem that this could be // init->traverse_subexpressions. Unfortunately that can fail // in a case like // var err os.Error // newvar, err := call(arg()) // Here newvar will have an init of call result 0 of // call(arg()). If we only traverse subexpressions, we will // only find arg(), and we won't bother to move anything out. // Then we get to the assignment to err, we will traverse the // whole statement, and this time we will find both call() and // arg(), and so we will move them out. This will cause them to // be put into temporary variables before the assignment to err // but after the declaration of newvar. To avoid that problem, // we traverse the entire expression here. Expression::traverse(&init, &find_eval_ordering); } size_t c = find_eval_ordering.size(); if (c == 0) return TRAVERSE_CONTINUE; // If there is only one expression with a side-effect, we can // usually leave it in place. if (c == 1) { switch (stmt->classification()) { case Statement::STATEMENT_ASSIGNMENT: // For an assignment statement, we need to evaluate an // expression on the right hand side before we evaluate any // index expression on the left hand side, so for that case // we always move the expression. Otherwise we mishandle // m[0] = len(m) where m is a map. break; case Statement::STATEMENT_EXPRESSION: { // If this is a call statement that doesn't return any // values, it will not have been counted as a value to // move. We need to move any subexpressions in case they // are themselves call statements that require passing a // closure. Expression* expr = stmt->expression_statement()->expr(); if (expr->call_expression() != NULL && expr->call_expression()->result_count() == 0) break; return TRAVERSE_CONTINUE; } default: // We can leave the expression in place. return TRAVERSE_CONTINUE; } } bool is_thunk = stmt->thunk_statement() != NULL; Expression_statement* es = stmt->expression_statement(); for (Find_eval_ordering::const_iterator p = find_eval_ordering.begin(); p != find_eval_ordering.end(); ++p) { Expression** pexpr = *p; // The last expression in a thunk will be the call passed to go // or defer, which we must not evaluate early. if (is_thunk && p + 1 == find_eval_ordering.end()) break; Location loc = (*pexpr)->location(); Statement* s; if ((*pexpr)->call_expression() == NULL || (*pexpr)->call_expression()->result_count() < 2) { Temporary_statement* ts = Statement::make_temporary(NULL, *pexpr, loc); s = ts; *pexpr = Expression::make_temporary_reference(ts, loc); } else { // A call expression which returns multiple results needs to // be handled specially. We can't create a temporary // because there is no type to give it. Any actual uses of // the values will be done via Call_result_expressions. // // Since a given call expression can be shared by multiple // Call_result_expressions, avoid hoisting the call the // second time we see it here. In addition, don't try to // hoist the top-level multi-return call in the statement, // since doing this would result a tree with more than one copy // of the call. if (this->remember_expression(*pexpr)) s = NULL; else if (es != NULL && *pexpr == es->expr()) s = NULL; else s = Statement::make_statement(*pexpr, true); } if (s != NULL) { block->insert_statement_before(*pindex, s); ++*pindex; } } if (init != orig_init) vds->var()->var_value()->set_init(init); return TRAVERSE_CONTINUE; } // Implement the order of evaluation rules for the initializer of a // global variable. int Order_eval::variable(Named_object* no) { if (no->is_result_variable()) return TRAVERSE_CONTINUE; Variable* var = no->var_value(); Expression* init = var->init(); if (!var->is_global() || init == NULL) return TRAVERSE_CONTINUE; Find_eval_ordering find_eval_ordering; Expression::traverse(&init, &find_eval_ordering); if (find_eval_ordering.size() <= 1) { // If there is only one expression with a side-effect, we can // leave it in place. return TRAVERSE_SKIP_COMPONENTS; } Expression* orig_init = init; for (Find_eval_ordering::const_iterator p = find_eval_ordering.begin(); p != find_eval_ordering.end(); ++p) { Expression** pexpr = *p; Location loc = (*pexpr)->location(); Statement* s; if ((*pexpr)->call_expression() == NULL || (*pexpr)->call_expression()->result_count() < 2) { Temporary_statement* ts = Statement::make_temporary(NULL, *pexpr, loc); s = ts; *pexpr = Expression::make_temporary_reference(ts, loc); } else { // A call expression which returns multiple results needs to // be handled specially. s = Statement::make_statement(*pexpr, true); } var->add_preinit_statement(this->gogo_, s); } if (init != orig_init) var->set_init(init); return TRAVERSE_SKIP_COMPONENTS; } // Use temporary variables to implement the order of evaluation rules. void Gogo::order_evaluations() { Order_eval order_eval(this); this->traverse(&order_eval); } // Order evaluations in a block. void Gogo::order_block(Block* block) { Order_eval order_eval(this); block->traverse(&order_eval); } // A traversal class used to find a single shortcut operator within an // expression. class Find_shortcut : public Traverse { public: Find_shortcut() : Traverse(traverse_blocks | traverse_statements | traverse_expressions), found_(NULL) { } // A pointer to the expression which was found, or NULL if none was // found. Expression** found() const { return this->found_; } protected: int block(Block*) { return TRAVERSE_SKIP_COMPONENTS; } int statement(Block*, size_t*, Statement*) { return TRAVERSE_SKIP_COMPONENTS; } int expression(Expression**); private: Expression** found_; }; // Find a shortcut expression. int Find_shortcut::expression(Expression** pexpr) { Expression* expr = *pexpr; Binary_expression* be = expr->binary_expression(); if (be == NULL) return TRAVERSE_CONTINUE; Operator op = be->op(); if (op != OPERATOR_OROR && op != OPERATOR_ANDAND) return TRAVERSE_CONTINUE; go_assert(this->found_ == NULL); this->found_ = pexpr; return TRAVERSE_EXIT; } // A traversal class used to turn shortcut operators into explicit if // statements. class Shortcuts : public Traverse { public: Shortcuts(Gogo* gogo) : Traverse(traverse_variables | traverse_statements), gogo_(gogo) { } protected: int variable(Named_object*); int statement(Block*, size_t*, Statement*); private: // Convert a shortcut operator. Statement* convert_shortcut(Block* enclosing, Expression** pshortcut); // The IR. Gogo* gogo_; }; // Remove shortcut operators in a single statement. int Shortcuts::statement(Block* block, size_t* pindex, Statement* s) { // FIXME: This approach doesn't work for switch statements, because // we add the new statements before the whole switch when we need to // instead add them just before the switch expression. The right // fix is probably to lower switch statements with nonconstant cases // to a series of conditionals. if (s->switch_statement() != NULL) return TRAVERSE_CONTINUE; while (true) { Find_shortcut find_shortcut; // If S is a variable declaration, then ordinary traversal won't // do anything. We want to explicitly traverse the // initialization expression if there is one. Variable_declaration_statement* vds = s->variable_declaration_statement(); Expression* init = NULL; if (vds == NULL) s->traverse_contents(&find_shortcut); else { init = vds->var()->var_value()->init(); if (init == NULL) return TRAVERSE_CONTINUE; init->traverse(&init, &find_shortcut); } Expression** pshortcut = find_shortcut.found(); if (pshortcut == NULL) return TRAVERSE_CONTINUE; Statement* snew = this->convert_shortcut(block, pshortcut); block->insert_statement_before(*pindex, snew); ++*pindex; if (pshortcut == &init) vds->var()->var_value()->set_init(init); } } // Remove shortcut operators in the initializer of a global variable. int Shortcuts::variable(Named_object* no) { if (no->is_result_variable()) return TRAVERSE_CONTINUE; Variable* var = no->var_value(); Expression* init = var->init(); if (!var->is_global() || init == NULL) return TRAVERSE_CONTINUE; while (true) { Find_shortcut find_shortcut; init->traverse(&init, &find_shortcut); Expression** pshortcut = find_shortcut.found(); if (pshortcut == NULL) return TRAVERSE_CONTINUE; Statement* snew = this->convert_shortcut(NULL, pshortcut); var->add_preinit_statement(this->gogo_, snew); if (pshortcut == &init) var->set_init(init); } } // Given an expression which uses a shortcut operator, return a // statement which implements it, and update *PSHORTCUT accordingly. Statement* Shortcuts::convert_shortcut(Block* enclosing, Expression** pshortcut) { Binary_expression* shortcut = (*pshortcut)->binary_expression(); Expression* left = shortcut->left(); Expression* right = shortcut->right(); Location loc = shortcut->location(); Block* retblock = new Block(enclosing, loc); retblock->set_end_location(loc); Temporary_statement* ts = Statement::make_temporary(shortcut->type(), left, loc); retblock->add_statement(ts); Block* block = new Block(retblock, loc); block->set_end_location(loc); Expression* tmpref = Expression::make_temporary_reference(ts, loc); Statement* assign = Statement::make_assignment(tmpref, right, loc); block->add_statement(assign); Expression* cond = Expression::make_temporary_reference(ts, loc); if (shortcut->binary_expression()->op() == OPERATOR_OROR) cond = Expression::make_unary(OPERATOR_NOT, cond, loc); Statement* if_statement = Statement::make_if_statement(cond, block, NULL, loc); retblock->add_statement(if_statement); *pshortcut = Expression::make_temporary_reference(ts, loc); delete shortcut; // Now convert any shortcut operators in LEFT and RIGHT. // LEFT and RIGHT were skipped in the top level // Gogo::order_evaluations. We need to order their // components first. Order_eval order_eval(this->gogo_); retblock->traverse(&order_eval); Shortcuts shortcuts(this->gogo_); retblock->traverse(&shortcuts); return Statement::make_block_statement(retblock, loc); } // Turn shortcut operators into explicit if statements. Doing this // considerably simplifies the order of evaluation rules. void Gogo::remove_shortcuts() { Shortcuts shortcuts(this); this->traverse(&shortcuts); } // Turn shortcut operators into explicit if statements in a block. void Gogo::remove_shortcuts_in_block(Block* block) { Shortcuts shortcuts(this); block->traverse(&shortcuts); } // Traversal to flatten parse tree after order of evaluation rules are applied. class Flatten : public Traverse { public: Flatten(Gogo* gogo, Named_object* function) : Traverse(traverse_variables | traverse_functions | traverse_statements | traverse_expressions), gogo_(gogo), function_(function), inserter_() { } void set_inserter(const Statement_inserter* inserter) { this->inserter_ = *inserter; } int variable(Named_object*); int function(Named_object*); int statement(Block*, size_t* pindex, Statement*); int expression(Expression**); private: // General IR. Gogo* gogo_; // The function we are traversing. Named_object* function_; // Current statement inserter for use by expressions. Statement_inserter inserter_; }; // Flatten variables. int Flatten::variable(Named_object* no) { if (!no->is_variable()) return TRAVERSE_CONTINUE; if (no->is_variable() && no->var_value()->is_global()) { // Global variables can have loops in their initialization // expressions. This is handled in flatten_init_expression. no->var_value()->flatten_init_expression(this->gogo_, this->function_, &this->inserter_); return TRAVERSE_CONTINUE; } if (!no->var_value()->is_parameter() && !no->var_value()->is_receiver() && !no->var_value()->is_closure() && no->var_value()->is_non_escaping_address_taken() && !no->var_value()->is_in_heap() && no->var_value()->toplevel_decl() == NULL) { // Local variable that has address taken but not escape. // It needs to be live beyond its lexical scope. So we // create a top-level declaration for it. // No need to do it if it is already in the top level. Block* top_block = function_->func_value()->block(); if (top_block->bindings()->lookup_local(no->name()) != no) { Variable* var = no->var_value(); Temporary_statement* ts = Statement::make_temporary(var->type(), NULL, var->location()); ts->set_is_address_taken(); top_block->add_statement_at_front(ts); var->set_toplevel_decl(ts); } } go_assert(!no->var_value()->has_pre_init()); return TRAVERSE_SKIP_COMPONENTS; } // Flatten the body of a function. Record the function while flattening it, // so that we can pass it down when flattening an expression. int Flatten::function(Named_object* no) { go_assert(this->function_ == NULL); this->function_ = no; int t = no->func_value()->traverse(this); this->function_ = NULL; if (t == TRAVERSE_EXIT) return t; return TRAVERSE_SKIP_COMPONENTS; } // Flatten statement parse trees. int Flatten::statement(Block* block, size_t* pindex, Statement* sorig) { // Because we explicitly traverse the statement's contents // ourselves, we want to skip block statements here. There is // nothing to flatten in a block statement. if (sorig->is_block_statement()) return TRAVERSE_CONTINUE; Statement_inserter hold_inserter(this->inserter_); this->inserter_ = Statement_inserter(block, pindex); // Flatten the expressions first. int t = sorig->traverse_contents(this); if (t == TRAVERSE_EXIT) { this->inserter_ = hold_inserter; return t; } // Keep flattening until nothing changes. Statement* s = sorig; while (true) { Statement* snew = s->flatten(this->gogo_, this->function_, block, &this->inserter_); if (snew == s) break; s = snew; t = s->traverse_contents(this); if (t == TRAVERSE_EXIT) { this->inserter_ = hold_inserter; return t; } } if (s != sorig) block->replace_statement(*pindex, s); this->inserter_ = hold_inserter; return TRAVERSE_SKIP_COMPONENTS; } // Flatten expression parse trees. int Flatten::expression(Expression** pexpr) { // Keep flattening until nothing changes. while (true) { Expression* e = *pexpr; if (e->traverse_subexpressions(this) == TRAVERSE_EXIT) return TRAVERSE_EXIT; Expression* enew = e->flatten(this->gogo_, this->function_, &this->inserter_); if (enew == e) break; *pexpr = enew; } return TRAVERSE_SKIP_COMPONENTS; } // Flatten a block. void Gogo::flatten_block(Named_object* function, Block* block) { Flatten flatten(this, function); block->traverse(&flatten); } // Flatten an expression. INSERTER may be NULL, in which case the // expression had better not need to create any temporaries. void Gogo::flatten_expression(Named_object* function, Statement_inserter* inserter, Expression** pexpr) { Flatten flatten(this, function); if (inserter != NULL) flatten.set_inserter(inserter); flatten.expression(pexpr); } void Gogo::flatten() { Flatten flatten(this, NULL); this->traverse(&flatten); } // Traversal to convert calls to the predeclared recover function to // pass in an argument indicating whether it can recover from a panic // or not. class Convert_recover : public Traverse { public: Convert_recover(Named_object* arg) : Traverse(traverse_expressions), arg_(arg) { } protected: int expression(Expression**); private: // The argument to pass to the function. Named_object* arg_; }; // Convert calls to recover. int Convert_recover::expression(Expression** pp) { Call_expression* ce = (*pp)->call_expression(); if (ce != NULL && ce->is_recover_call()) ce->set_recover_arg(Expression::make_var_reference(this->arg_, ce->location())); return TRAVERSE_CONTINUE; } // Traversal for build_recover_thunks. class Build_recover_thunks : public Traverse { public: Build_recover_thunks(Gogo* gogo) : Traverse(traverse_functions), gogo_(gogo) { } int function(Named_object*); private: Expression* can_recover_arg(Location); // General IR. Gogo* gogo_; }; // If this function calls recover, turn it into a thunk. int Build_recover_thunks::function(Named_object* orig_no) { Function* orig_func = orig_no->func_value(); if (!orig_func->calls_recover() || orig_func->is_recover_thunk() || orig_func->has_recover_thunk()) return TRAVERSE_CONTINUE; Gogo* gogo = this->gogo_; Location location = orig_func->location(); static int count; char buf[50]; Function_type* orig_fntype = orig_func->type(); Typed_identifier_list* new_params = new Typed_identifier_list(); std::string receiver_name; if (orig_fntype->is_method()) { const Typed_identifier* receiver = orig_fntype->receiver(); snprintf(buf, sizeof buf, "rt.%u", count); ++count; receiver_name = buf; new_params->push_back(Typed_identifier(receiver_name, receiver->type(), receiver->location())); } const Typed_identifier_list* orig_params = orig_fntype->parameters(); if (orig_params != NULL && !orig_params->empty()) { for (Typed_identifier_list::const_iterator p = orig_params->begin(); p != orig_params->end(); ++p) { snprintf(buf, sizeof buf, "pt.%u", count); ++count; new_params->push_back(Typed_identifier(buf, p->type(), p->location())); } } snprintf(buf, sizeof buf, "pr.%u", count); ++count; std::string can_recover_name = buf; new_params->push_back(Typed_identifier(can_recover_name, Type::lookup_bool_type(), orig_fntype->location())); const Typed_identifier_list* orig_results = orig_fntype->results(); Typed_identifier_list* new_results; if (orig_results == NULL || orig_results->empty()) new_results = NULL; else { new_results = new Typed_identifier_list(); for (Typed_identifier_list::const_iterator p = orig_results->begin(); p != orig_results->end(); ++p) new_results->push_back(Typed_identifier("", p->type(), p->location())); } Function_type *new_fntype = Type::make_function_type(NULL, new_params, new_results, orig_fntype->location()); if (orig_fntype->is_varargs()) new_fntype->set_is_varargs(); Type* rtype = NULL; if (orig_fntype->is_method()) rtype = orig_fntype->receiver()->type(); std::string name(gogo->recover_thunk_name(orig_no->name(), rtype)); Named_object *new_no = gogo->start_function(name, new_fntype, false, location); Function *new_func = new_no->func_value(); if (orig_func->enclosing() != NULL) new_func->set_enclosing(orig_func->enclosing()); // We build the code for the original function attached to the new // function, and then swap the original and new function bodies. // This means that existing references to the original function will // then refer to the new function. That makes this code a little // confusing, in that the reference to NEW_NO really refers to the // other function, not the one we are building. Expression* closure = NULL; if (orig_func->needs_closure()) { // For the new function we are creating, declare a new parameter // variable NEW_CLOSURE_NO and set it to be the closure variable // of the function. This will be set to the closure value // passed in by the caller. Then pass a reference to this // variable as the closure value when calling the original // function. In other words, simply pass the closure value // through the thunk we are creating. Named_object* orig_closure_no = orig_func->closure_var(); Variable* orig_closure_var = orig_closure_no->var_value(); Variable* new_var = new Variable(orig_closure_var->type(), NULL, false, false, false, location); new_var->set_is_closure(); snprintf(buf, sizeof buf, "closure.%u", count); ++count; Named_object* new_closure_no = Named_object::make_variable(buf, NULL, new_var); new_func->set_closure_var(new_closure_no); closure = Expression::make_var_reference(new_closure_no, location); } Expression* fn = Expression::make_func_reference(new_no, closure, location); Expression_list* args = new Expression_list(); if (new_params != NULL) { // Note that we skip the last parameter, which is the boolean // indicating whether recover can succed. for (Typed_identifier_list::const_iterator p = new_params->begin(); p + 1 != new_params->end(); ++p) { Named_object* p_no = gogo->lookup(p->name(), NULL); go_assert(p_no != NULL && p_no->is_variable() && p_no->var_value()->is_parameter()); args->push_back(Expression::make_var_reference(p_no, location)); } } args->push_back(this->can_recover_arg(location)); gogo->start_block(location); Call_expression* call = Expression::make_call(fn, args, false, location); // Any varargs call has already been lowered. call->set_varargs_are_lowered(); Statement* s = Statement::make_return_from_call(call, location); s->determine_types(); gogo->add_statement(s); Block* b = gogo->finish_block(location); gogo->add_block(b, location); // Lower the call in case it returns multiple results. gogo->lower_block(new_no, b); gogo->finish_function(location); // Swap the function bodies and types. new_func->swap_for_recover(orig_func); orig_func->set_is_recover_thunk(); new_func->set_calls_recover(); new_func->set_has_recover_thunk(); Bindings* orig_bindings = orig_func->block()->bindings(); Bindings* new_bindings = new_func->block()->bindings(); if (orig_fntype->is_method()) { // We changed the receiver to be a regular parameter. We have // to update the binding accordingly in both functions. Named_object* orig_rec_no = orig_bindings->lookup_local(receiver_name); go_assert(orig_rec_no != NULL && orig_rec_no->is_variable() && !orig_rec_no->var_value()->is_receiver()); orig_rec_no->var_value()->set_is_receiver(); std::string new_receiver_name(orig_fntype->receiver()->name()); if (new_receiver_name.empty()) { // Find the receiver. It was named "r.NNN" in // Gogo::start_function. for (Bindings::const_definitions_iterator p = new_bindings->begin_definitions(); p != new_bindings->end_definitions(); ++p) { const std::string& pname((*p)->name()); if (pname[0] == 'r' && pname[1] == '.') { new_receiver_name = pname; break; } } go_assert(!new_receiver_name.empty()); } Named_object* new_rec_no = new_bindings->lookup_local(new_receiver_name); if (new_rec_no == NULL) go_assert(saw_errors()); else { go_assert(new_rec_no->is_variable() && new_rec_no->var_value()->is_receiver()); new_rec_no->var_value()->set_is_not_receiver(); } } // Because we flipped blocks but not types, the can_recover // parameter appears in the (now) old bindings as a parameter. // Change it to a local variable, whereupon it will be discarded. Named_object* can_recover_no = orig_bindings->lookup_local(can_recover_name); go_assert(can_recover_no != NULL && can_recover_no->is_variable() && can_recover_no->var_value()->is_parameter()); orig_bindings->remove_binding(can_recover_no); // Add the can_recover argument to the (now) new bindings, and // attach it to any recover statements. Variable* can_recover_var = new Variable(Type::lookup_bool_type(), NULL, false, true, false, location); can_recover_no = new_bindings->add_variable(can_recover_name, NULL, can_recover_var); Convert_recover convert_recover(can_recover_no); new_func->traverse(&convert_recover); // Update the function pointers in any named results. new_func->update_result_variables(); orig_func->update_result_variables(); return TRAVERSE_CONTINUE; } // Return the expression to pass for the .can_recover parameter to the // new function. This indicates whether a call to recover may return // non-nil. The expression is runtime.canrecover(__builtin_return_address()). Expression* Build_recover_thunks::can_recover_arg(Location location) { Type* uintptr_type = Type::lookup_integer_type("uintptr"); static Named_object* can_recover; if (can_recover == NULL) { const Location bloc = Linemap::predeclared_location(); Typed_identifier_list* param_types = new Typed_identifier_list(); param_types->push_back(Typed_identifier("a", uintptr_type, bloc)); Type* boolean_type = Type::lookup_bool_type(); Typed_identifier_list* results = new Typed_identifier_list(); results->push_back(Typed_identifier("", boolean_type, bloc)); Function_type* fntype = Type::make_function_type(NULL, param_types, results, bloc); can_recover = Named_object::make_function_declaration("runtime_canrecover", NULL, fntype, bloc); can_recover->func_declaration_value()->set_asm_name("runtime.canrecover"); } Expression* zexpr = Expression::make_integer_ul(0, NULL, location); Expression* call = Runtime::make_call(Runtime::BUILTIN_RETURN_ADDRESS, location, 1, zexpr); call = Expression::make_unsafe_cast(uintptr_type, call, location); Expression_list* args = new Expression_list(); args->push_back(call); Expression* fn = Expression::make_func_reference(can_recover, NULL, location); return Expression::make_call(fn, args, false, location); } // Build thunks for functions which call recover. We build a new // function with an extra parameter, which is whether a call to // recover can succeed. We then move the body of this function to // that one. We then turn this function into a thunk which calls the // new one, passing the value of runtime.canrecover(__builtin_return_address()). // The function will be marked as not splitting the stack. This will // cooperate with the implementation of defer to make recover do the // right thing. void Gogo::build_recover_thunks() { Build_recover_thunks build_recover_thunks(this); this->traverse(&build_recover_thunks); } // Look for named types to see whether we need to create an interface // method table. class Build_method_tables : public Traverse { public: Build_method_tables(Gogo* gogo, const std::vector<Interface_type*>& interfaces) : Traverse(traverse_types), gogo_(gogo), interfaces_(interfaces) { } int type(Type*); private: // The IR. Gogo* gogo_; // A list of locally defined interfaces which have hidden methods. const std::vector<Interface_type*>& interfaces_; }; // Build all required interface method tables for types. We need to // ensure that we have an interface method table for every interface // which has a hidden method, for every named type which implements // that interface. Normally we can just build interface method tables // as we need them. However, in some cases we can require an // interface method table for an interface defined in a different // package for a type defined in that package. If that interface and // type both use a hidden method, that is OK. However, we will not be // able to build that interface method table when we need it, because // the type's hidden method will be static. So we have to build it // here, and just refer it from other packages as needed. void Gogo::build_interface_method_tables() { if (saw_errors()) return; std::vector<Interface_type*> hidden_interfaces; hidden_interfaces.reserve(this->interface_types_.size()); for (std::vector<Interface_type*>::const_iterator pi = this->interface_types_.begin(); pi != this->interface_types_.end(); ++pi) { const Typed_identifier_list* methods = (*pi)->methods(); if (methods == NULL) continue; for (Typed_identifier_list::const_iterator pm = methods->begin(); pm != methods->end(); ++pm) { if (Gogo::is_hidden_name(pm->name())) { hidden_interfaces.push_back(*pi); break; } } } if (!hidden_interfaces.empty()) { // Now traverse the tree looking for all named types. Build_method_tables bmt(this, hidden_interfaces); this->traverse(&bmt); } // We no longer need the list of interfaces. this->interface_types_.clear(); } // This is called for each type. For a named type, for each of the // interfaces with hidden methods that it implements, create the // method table. int Build_method_tables::type(Type* type) { Named_type* nt = type->named_type(); Struct_type* st = type->struct_type(); if (nt != NULL || st != NULL) { Translate_context context(this->gogo_, NULL, NULL, NULL); for (std::vector<Interface_type*>::const_iterator p = this->interfaces_.begin(); p != this->interfaces_.end(); ++p) { // We ask whether a pointer to the named type implements the // interface, because a pointer can implement more methods // than a value. if (nt != NULL) { if ((*p)->implements_interface(Type::make_pointer_type(nt), NULL)) { nt->interface_method_table(*p, false)->get_backend(&context); nt->interface_method_table(*p, true)->get_backend(&context); } } else { if ((*p)->implements_interface(Type::make_pointer_type(st), NULL)) { st->interface_method_table(*p, false)->get_backend(&context); st->interface_method_table(*p, true)->get_backend(&context); } } } } return TRAVERSE_CONTINUE; } // Return an expression which allocates memory to hold values of type TYPE. Expression* Gogo::allocate_memory(Type* type, Location location) { Expression* td = Expression::make_type_descriptor(type, location); return Runtime::make_call(Runtime::NEW, location, 1, td); } // Traversal class used to check for return statements. class Check_return_statements_traverse : public Traverse { public: Check_return_statements_traverse() : Traverse(traverse_functions) { } int function(Named_object*); }; // Check that a function has a return statement if it needs one. int Check_return_statements_traverse::function(Named_object* no) { Function* func = no->func_value(); const Function_type* fntype = func->type(); const Typed_identifier_list* results = fntype->results(); // We only need a return statement if there is a return value. if (results == NULL || results->empty()) return TRAVERSE_CONTINUE; if (func->block()->may_fall_through()) go_error_at(func->block()->end_location(), "missing return at end of function"); return TRAVERSE_CONTINUE; } // Check return statements. void Gogo::check_return_statements() { Check_return_statements_traverse traverse; this->traverse(&traverse); } // Traversal class to decide whether a function body is less than the // inlining budget. This adjusts *available as it goes, and stops the // traversal if it goes negative. class Inline_within_budget : public Traverse { public: Inline_within_budget(int* available) : Traverse(traverse_statements | traverse_expressions), available_(available) { } int statement(Block*, size_t*, Statement*); int expression(Expression**); private: // Pointer to remaining budget. int* available_; }; // Adjust the budget for the inlining cost of a statement. int Inline_within_budget::statement(Block*, size_t*, Statement* s) { if (*this->available_ < 0) return TRAVERSE_EXIT; *this->available_ -= s->inlining_cost(); return TRAVERSE_CONTINUE; } // Adjust the budget for the inlining cost of an expression. int Inline_within_budget::expression(Expression** pexpr) { if (*this->available_ < 0) return TRAVERSE_EXIT; *this->available_ -= (*pexpr)->inlining_cost(); return TRAVERSE_CONTINUE; } // Traversal class to find functions whose body should be exported for // inlining by other packages. class Mark_inline_candidates : public Traverse { public: Mark_inline_candidates(Unordered_set(Named_object*)* marked) : Traverse(traverse_functions | traverse_types), marked_functions_(marked) { } int function(Named_object*); int type(Type*); private: // We traverse the function body trying to determine how expensive // it is for inlining. We start with a budget, and decrease that // budget for each statement and expression. If the budget goes // negative, we do not export the function body. The value of this // budget is a heuristic. In the usual GCC spirit, we could // consider setting this via a command line option. const int budget_heuristic = 80; // Set of named objects that are marked as inline candidates. Unordered_set(Named_object*)* marked_functions_; }; // Mark a function if it is an inline candidate. int Mark_inline_candidates::function(Named_object* no) { Function* func = no->func_value(); if ((func->pragmas() & GOPRAGMA_NOINLINE) != 0) return TRAVERSE_CONTINUE; int budget = budget_heuristic; Inline_within_budget iwb(&budget); func->block()->traverse(&iwb); if (budget >= 0) { func->set_export_for_inlining(); this->marked_functions_->insert(no); } return TRAVERSE_CONTINUE; } // Mark methods if they are inline candidates. int Mark_inline_candidates::type(Type* t) { Named_type* nt = t->named_type(); if (nt == NULL || nt->is_alias()) return TRAVERSE_CONTINUE; const Bindings* methods = nt->local_methods(); if (methods == NULL) return TRAVERSE_CONTINUE; for (Bindings::const_definitions_iterator p = methods->begin_definitions(); p != methods->end_definitions(); ++p) { Named_object* no = *p; go_assert(no->is_function()); Function *func = no->func_value(); if ((func->pragmas() & GOPRAGMA_NOINLINE) != 0) continue; int budget = budget_heuristic; Inline_within_budget iwb(&budget); func->block()->traverse(&iwb); if (budget >= 0) { func->set_export_for_inlining(); this->marked_functions_->insert(no); } } return TRAVERSE_CONTINUE; } // Export identifiers as requested. void Gogo::do_exports() { if (saw_errors()) return; // Mark any functions whose body should be exported for inlining by // other packages. Unordered_set(Named_object*) marked_functions; Mark_inline_candidates mic(&marked_functions); this->traverse(&mic); // For now we always stream to a section. Later we may want to // support streaming to a separate file. Stream_to_section stream(this->backend()); // Write out either the prefix or pkgpath depending on how we were // invoked. std::string prefix; std::string pkgpath; if (this->pkgpath_from_option_) pkgpath = this->pkgpath_; else if (this->prefix_from_option_) prefix = this->prefix_; else if (this->is_main_package()) pkgpath = "main"; else prefix = "go"; std::string init_fn_name; if (this->is_main_package()) init_fn_name = ""; else if (this->need_init_fn_) init_fn_name = this->get_init_fn_name(); else init_fn_name = this->dummy_init_fn_name(); Export exp(&stream); exp.register_builtin_types(this); exp.export_globals(this->package_name(), prefix, pkgpath, this->packages_, this->imports_, init_fn_name, this->imported_init_fns_, this->package_->bindings(), &marked_functions); if (!this->c_header_.empty() && !saw_errors()) this->write_c_header(); } // Write the top level named struct types in C format to a C header // file. This is used when building the runtime package, to share // struct definitions between C and Go. void Gogo::write_c_header() { std::ofstream out; out.open(this->c_header_.c_str()); if (out.fail()) { go_error_at(Linemap::unknown_location(), "cannot open %s: %m", this->c_header_.c_str()); return; } std::list<Named_object*> types; Bindings* top = this->package_->bindings(); for (Bindings::const_definitions_iterator p = top->begin_definitions(); p != top->end_definitions(); ++p) { Named_object* no = *p; // Skip names that start with underscore followed by something // other than an uppercase letter, as when compiling the runtime // package they are mostly types defined by mkrsysinfo.sh based // on the C system header files. We don't need to translate // types to C and back to Go. But do accept the special cases // _defer, _panic, and _type. std::string name = Gogo::unpack_hidden_name(no->name()); if (name[0] == '_' && (name[1] < 'A' || name[1] > 'Z') && (name != "_defer" && name != "_panic" && name != "_type")) continue; if (no->is_type() && no->type_value()->struct_type() != NULL) types.push_back(no); if (no->is_const() && no->const_value()->type()->integer_type() != NULL && !no->const_value()->is_sink()) { Numeric_constant nc; unsigned long val; if (no->const_value()->expr()->numeric_constant_value(&nc) && nc.to_unsigned_long(&val) == Numeric_constant::NC_UL_VALID) { out << "#define " << no->message_name() << ' ' << val << std::endl; } } } std::vector<const Named_object*> written; int loop = 0; while (!types.empty()) { Named_object* no = types.front(); types.pop_front(); std::vector<const Named_object*> requires; std::vector<const Named_object*> declare; if (!no->type_value()->struct_type()->can_write_to_c_header(&requires, &declare)) continue; bool ok = true; for (std::vector<const Named_object*>::const_iterator pr = requires.begin(); pr != requires.end() && ok; ++pr) { for (std::list<Named_object*>::const_iterator pt = types.begin(); pt != types.end() && ok; ++pt) if (*pr == *pt) ok = false; } if (!ok) { ++loop; if (loop > 10000) { // This should be impossible since the code parsed and // type checked. go_unreachable(); } types.push_back(no); continue; } for (std::vector<const Named_object*>::const_iterator pd = declare.begin(); pd != declare.end(); ++pd) { if (*pd == no) continue; std::vector<const Named_object*> drequires; std::vector<const Named_object*> ddeclare; if (!(*pd)->type_value()->struct_type()-> can_write_to_c_header(&drequires, &ddeclare)) continue; bool done = false; for (std::vector<const Named_object*>::const_iterator pw = written.begin(); pw != written.end(); ++pw) { if (*pw == *pd) { done = true; break; } } if (!done) { out << std::endl; out << "struct " << (*pd)->message_name() << ";" << std::endl; written.push_back(*pd); } } out << std::endl; out << "struct " << no->message_name() << " {" << std::endl; no->type_value()->struct_type()->write_to_c_header(out); out << "};" << std::endl; written.push_back(no); } out.close(); if (out.fail()) go_error_at(Linemap::unknown_location(), "error writing to %s: %m", this->c_header_.c_str()); } // 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(); Expression::make_func_descriptor_type(); Type::convert_builtin_named_types(this); Runtime::convert_types(this); this->named_types_are_converted_ = true; Type::finish_pointer_types(this); } // 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); } } void debug_go_gogo(Gogo* gogo) { if (gogo != NULL) gogo->debug_dump(); } void Gogo::debug_dump() { std::cerr << "Packages:\n"; for (Packages::const_iterator p = this->packages_.begin(); p != this->packages_.end(); ++p) { const char *tag = " "; if (p->second == this->package_) tag = "* "; std::cerr << tag << "'" << p->first << "' " << p->second->pkgpath() << " " << ((void*)p->second) << "\n"; } } // Class Function. Function::Function(Function_type* type, Named_object* enclosing, Block* block, Location location) : type_(type), enclosing_(enclosing), results_(NULL), closure_var_(NULL), block_(block), location_(location), labels_(), local_type_count_(0), descriptor_(NULL), fndecl_(NULL), defer_stack_(NULL), pragmas_(0), nested_functions_(0), is_sink_(false), results_are_named_(false), is_unnamed_type_stub_method_(false), calls_recover_(false), is_recover_thunk_(false), has_recover_thunk_(false), calls_defer_retaddr_(false), is_type_specific_function_(false), in_unique_section_(false), export_for_inlining_(false), is_inline_only_(false), is_referenced_by_inline_(false), is_exported_by_linkname_(false) { } // Create the named result variables. void Function::create_result_variables(Gogo* gogo) { const Typed_identifier_list* results = this->type_->results(); if (results == NULL || results->empty()) return; if (!results->front().name().empty()) this->results_are_named_ = true; this->results_ = new Results(); this->results_->reserve(results->size()); Block* block = this->block_; int index = 0; for (Typed_identifier_list::const_iterator p = results->begin(); p != results->end(); ++p, ++index) { std::string name = p->name(); if (name.empty() || Gogo::is_sink_name(name)) { static int result_counter; char buf[100]; snprintf(buf, sizeof buf, "$ret%d", result_counter); ++result_counter; name = gogo->pack_hidden_name(buf, false); } Result_variable* result = new Result_variable(p->type(), this, index, p->location()); Named_object* no = block->bindings()->add_result_variable(name, result); if (no->is_result_variable()) this->results_->push_back(no); else { static int dummy_result_count; char buf[100]; snprintf(buf, sizeof buf, "$dret%d", dummy_result_count); ++dummy_result_count; name = gogo->pack_hidden_name(buf, false); no = block->bindings()->add_result_variable(name, result); go_assert(no->is_result_variable()); this->results_->push_back(no); } } } // Update the named result variables when cloning a function which // calls recover. void Function::update_result_variables() { if (this->results_ == NULL) return; for (Results::iterator p = this->results_->begin(); p != this->results_->end(); ++p) (*p)->result_var_value()->set_function(this); } // Whether this method should not be included in the type descriptor. bool Function::nointerface() const { go_assert(this->is_method()); return (this->pragmas_ & GOPRAGMA_NOINTERFACE) != 0; } // Record that this method should not be included in the type // descriptor. void Function::set_nointerface() { this->pragmas_ |= GOPRAGMA_NOINTERFACE; } // Return the closure variable, creating it if necessary. Named_object* Function::closure_var() { if (this->closure_var_ == NULL) { go_assert(this->descriptor_ == NULL); // We don't know the type of the variable yet. We add fields as // we find them. Location loc = this->type_->location(); Struct_field_list* sfl = new Struct_field_list; Struct_type* struct_type = Type::make_struct_type(sfl, loc); struct_type->set_is_struct_incomparable(); Variable* var = new Variable(Type::make_pointer_type(struct_type), NULL, false, false, false, loc); var->set_is_used(); var->set_is_closure(); this->closure_var_ = Named_object::make_variable("$closure", NULL, var); // Note that the new variable is not in any binding contour. } return this->closure_var_; } // Set the type of the closure variable. void Function::set_closure_type() { if (this->closure_var_ == NULL) return; Named_object* closure = this->closure_var_; Struct_type* st = closure->var_value()->type()->deref()->struct_type(); // The first field of a closure is always a pointer to the function // code. Type* voidptr_type = Type::make_pointer_type(Type::make_void_type()); st->push_field(Struct_field(Typed_identifier(".f", voidptr_type, this->location_))); unsigned int index = 1; for (Closure_fields::const_iterator p = this->closure_fields_.begin(); p != this->closure_fields_.end(); ++p, ++index) { Named_object* no = p->first; char buf[20]; snprintf(buf, sizeof buf, "%u", index); std::string n = no->name() + buf; Type* var_type; if (no->is_variable()) var_type = no->var_value()->type(); else var_type = no->result_var_value()->type(); Type* field_type = Type::make_pointer_type(var_type); st->push_field(Struct_field(Typed_identifier(n, field_type, p->second))); } } // Return whether this function is a method. bool Function::is_method() const { return this->type_->is_method(); } // Add a label definition. Label* Function::add_label_definition(Gogo* gogo, const std::string& label_name, Location location) { Label* lnull = NULL; std::pair<Labels::iterator, bool> ins = this->labels_.insert(std::make_pair(label_name, lnull)); Label* label; if (label_name == "_") { label = Label::create_dummy_label(); if (ins.second) ins.first->second = label; } else if (ins.second) { // This is a new label. label = new Label(label_name); ins.first->second = label; } else { // The label was already in the hash table. label = ins.first->second; if (label->is_defined()) { go_error_at(location, "label %qs already defined", Gogo::message_name(label_name).c_str()); go_inform(label->location(), "previous definition of %qs was here", Gogo::message_name(label_name).c_str()); return new Label(label_name); } } label->define(location, gogo->bindings_snapshot(location)); // Issue any errors appropriate for any previous goto's to this // label. const std::vector<Bindings_snapshot*>& refs(label->refs()); for (std::vector<Bindings_snapshot*>::const_iterator p = refs.begin(); p != refs.end(); ++p) (*p)->check_goto_to(gogo->current_block()); label->clear_refs(); return label; } // Add a reference to a label. Label* Function::add_label_reference(Gogo* gogo, const std::string& label_name, Location location, bool issue_goto_errors) { Label* lnull = NULL; std::pair<Labels::iterator, bool> ins = this->labels_.insert(std::make_pair(label_name, lnull)); Label* label; if (!ins.second) { // The label was already in the hash table. label = ins.first->second; } else { go_assert(ins.first->second == NULL); label = new Label(label_name); ins.first->second = label; } label->set_is_used(); if (issue_goto_errors) { Bindings_snapshot* snapshot = label->snapshot(); if (snapshot != NULL) snapshot->check_goto_from(gogo->current_block(), location); else label->add_snapshot_ref(gogo->bindings_snapshot(location)); } return label; } // Warn about labels that are defined but not used. void Function::check_labels() const { for (Labels::const_iterator p = this->labels_.begin(); p != this->labels_.end(); p++) { Label* label = p->second; if (!label->is_used()) go_error_at(label->location(), "label %qs defined and not used", Gogo::message_name(label->name()).c_str()); } } // Swap one function with another. This is used when building the // thunk we use to call a function which calls recover. It may not // work for any other case. void Function::swap_for_recover(Function *x) { go_assert(this->enclosing_ == x->enclosing_); std::swap(this->results_, x->results_); std::swap(this->closure_var_, x->closure_var_); std::swap(this->block_, x->block_); go_assert(this->location_ == x->location_); go_assert(this->fndecl_ == NULL && x->fndecl_ == NULL); go_assert(this->defer_stack_ == NULL && x->defer_stack_ == NULL); } // Traverse the tree. int Function::traverse(Traverse* traverse) { unsigned int traverse_mask = traverse->traverse_mask(); if ((traverse_mask & (Traverse::traverse_types | Traverse::traverse_expressions)) != 0) { if (Type::traverse(this->type_, traverse) == TRAVERSE_EXIT) return TRAVERSE_EXIT; } // FIXME: We should check traverse_functions here if nested // functions are stored in block bindings. if (this->block_ != NULL && (traverse_mask & (Traverse::traverse_variables | Traverse::traverse_constants | Traverse::traverse_blocks | Traverse::traverse_statements | Traverse::traverse_expressions | Traverse::traverse_types)) != 0) { if (this->block_->traverse(traverse) == TRAVERSE_EXIT) return TRAVERSE_EXIT; } return TRAVERSE_CONTINUE; } // Work out types for unspecified variables and constants. void Function::determine_types() { if (this->block_ != NULL) this->block_->determine_types(); } // Return the function descriptor, the value you get when you refer to // the function in Go code without calling it. Expression* Function::descriptor(Gogo*, Named_object* no) { go_assert(!this->is_method()); go_assert(this->closure_var_ == NULL); if (this->descriptor_ == NULL) this->descriptor_ = Expression::make_func_descriptor(no); return this->descriptor_; } // Get a pointer to the variable representing the defer stack for this // function, making it if necessary. The value of the variable is set // by the runtime routines to true if the function is returning, // rather than panicing through. A pointer to this variable is used // as a marker for the functions on the defer stack associated with // this function. A function-specific variable permits inlining a // function which uses defer. Expression* Function::defer_stack(Location location) { if (this->defer_stack_ == NULL) { Type* t = Type::lookup_bool_type(); Expression* n = Expression::make_boolean(false, location); this->defer_stack_ = Statement::make_temporary(t, n, location); this->defer_stack_->set_is_address_taken(); } Expression* ref = Expression::make_temporary_reference(this->defer_stack_, location); return Expression::make_unary(OPERATOR_AND, ref, location); } // Export the function. void Function::export_func(Export* exp, const Named_object* no) const { Block* block = NULL; if (this->export_for_inlining()) block = this->block_; Function::export_func_with_type(exp, no, this->type_, this->results_, this->is_method() && this->nointerface(), this->asm_name(), block, this->location_); } // Export a function with a type. void Function::export_func_with_type(Export* exp, const Named_object* no, const Function_type* fntype, Function::Results* result_vars, bool nointerface, const std::string& asm_name, Block* block, Location loc) { exp->write_c_string("func "); if (nointerface) { go_assert(fntype->is_method()); exp->write_c_string("/*nointerface*/ "); } if (!asm_name.empty()) { exp->write_c_string("/*asm "); exp->write_string(asm_name); exp->write_c_string(" */ "); } if (fntype->is_method()) { exp->write_c_string("("); const Typed_identifier* receiver = fntype->receiver(); exp->write_name(receiver->name()); exp->write_escape(receiver->note()); exp->write_c_string(" "); exp->write_type(receiver->type()); exp->write_c_string(") "); } if (no->package() != NULL && !fntype->is_method()) { char buf[50]; snprintf(buf, sizeof buf, "<p%d>", exp->package_index(no->package())); exp->write_c_string(buf); } const std::string& name(no->name()); if (!Gogo::is_hidden_name(name)) exp->write_string(name); else { exp->write_c_string("."); exp->write_string(Gogo::unpack_hidden_name(name)); } exp->write_c_string(" ("); const Typed_identifier_list* parameters = fntype->parameters(); if (parameters != NULL) { size_t i = 0; bool is_varargs = fntype->is_varargs(); bool first = true; for (Typed_identifier_list::const_iterator p = parameters->begin(); p != parameters->end(); ++p, ++i) { if (first) first = false; else exp->write_c_string(", "); exp->write_name(p->name()); exp->write_escape(p->note()); exp->write_c_string(" "); if (!is_varargs || p + 1 != parameters->end()) exp->write_type(p->type()); else { exp->write_c_string("..."); exp->write_type(p->type()->array_type()->element_type()); } } } exp->write_c_string(")"); const Typed_identifier_list* result_decls = fntype->results(); if (result_decls != NULL) { if (result_decls->size() == 1 && result_decls->begin()->name().empty() && block == NULL) { exp->write_c_string(" "); exp->write_type(result_decls->begin()->type()); } else { exp->write_c_string(" ("); bool first = true; Results::const_iterator pr; if (result_vars != NULL) pr = result_vars->begin(); for (Typed_identifier_list::const_iterator pd = result_decls->begin(); pd != result_decls->end(); ++pd) { if (first) first = false; else exp->write_c_string(", "); // We only use pr->name, which may be artificial, if // need it for inlining. if (block == NULL || result_vars == NULL) exp->write_name(pd->name()); else exp->write_name((*pr)->name()); exp->write_escape(pd->note()); exp->write_c_string(" "); exp->write_type(pd->type()); if (result_vars != NULL) ++pr; } if (result_vars != NULL) go_assert(pr == result_vars->end()); exp->write_c_string(")"); } } if (block == NULL) exp->write_c_string("\n"); else { int indent = 1; if (fntype->is_method()) indent++; Export_function_body efb(exp, indent); efb.indent(); efb.write_c_string("// "); efb.write_string(Linemap::location_to_file(block->start_location())); efb.write_char(':'); char buf[100]; snprintf(buf, sizeof buf, "%d", Linemap::location_to_line(loc)); efb.write_c_string(buf); efb.write_char('\n'); block->export_block(&efb); const std::string& body(efb.body()); snprintf(buf, sizeof buf, " <inl:%lu>\n", static_cast<unsigned long>(body.length())); exp->write_c_string(buf); exp->write_string(body); } } // Import a function. bool Function::import_func(Import* imp, std::string* pname, Package** ppkg, bool* pis_exported, Typed_identifier** preceiver, Typed_identifier_list** pparameters, Typed_identifier_list** presults, bool* is_varargs, bool* nointerface, std::string* asm_name, std::string* body) { imp->require_c_string("func "); *nointerface = false; while (imp->match_c_string("/*")) { imp->advance(2); if (imp->match_c_string("nointerface")) { imp->require_c_string("nointerface*/ "); *nointerface = true; } else if (imp->match_c_string("asm")) { imp->require_c_string("asm "); *asm_name = imp->read_identifier(); imp->require_c_string(" */ "); } else { go_error_at(imp->location(), "import error at %d: unrecognized function comment", imp->pos()); return false; } } if (*nointerface) { // Only a method can be nointerface. go_assert(imp->peek_char() == '('); } *preceiver = NULL; if (imp->peek_char() == '(') { imp->require_c_string("("); std::string name = imp->read_name(); std::string escape_note = imp->read_escape(); imp->require_c_string(" "); Type* rtype = imp->read_type(); *preceiver = new Typed_identifier(name, rtype, imp->location()); (*preceiver)->set_note(escape_note); imp->require_c_string(") "); } if (!Import::read_qualified_identifier(imp, pname, ppkg, pis_exported)) { go_error_at(imp->location(), "import error at %d: bad function name in export data", imp->pos()); return false; } Typed_identifier_list* parameters; *is_varargs = false; imp->require_c_string(" ("); if (imp->peek_char() == ')') parameters = NULL; else { parameters = new Typed_identifier_list(); while (true) { std::string name = imp->read_name(); std::string escape_note = imp->read_escape(); imp->require_c_string(" "); if (imp->match_c_string("...")) { imp->advance(3); *is_varargs = true; } Type* ptype = imp->read_type(); if (*is_varargs) ptype = Type::make_array_type(ptype, NULL); Typed_identifier t = Typed_identifier(name, ptype, imp->location()); t.set_note(escape_note); parameters->push_back(t); if (imp->peek_char() != ',') break; go_assert(!*is_varargs); imp->require_c_string(", "); } } imp->require_c_string(")"); *pparameters = parameters; Typed_identifier_list* results; if (imp->peek_char() != ' ' || imp->match_c_string(" <inl")) results = NULL; else { results = new Typed_identifier_list(); imp->require_c_string(" "); if (imp->peek_char() != '(') { Type* rtype = imp->read_type(); results->push_back(Typed_identifier("", rtype, imp->location())); } else { imp->require_c_string("("); while (true) { std::string name = imp->read_name(); std::string note = imp->read_escape(); imp->require_c_string(" "); Type* rtype = imp->read_type(); Typed_identifier t = Typed_identifier(name, rtype, imp->location()); t.set_note(note); results->push_back(t); if (imp->peek_char() != ',') break; imp->require_c_string(", "); } imp->require_c_string(")"); } } *presults = results; if (!imp->match_c_string(" <inl:")) { imp->require_semicolon_if_old_version(); imp->require_c_string("\n"); body->clear(); } else { imp->require_c_string(" <inl:"); std::string lenstr; int c; while (true) { c = imp->peek_char(); if (c < '0' || c > '9') break; lenstr += c; imp->get_char(); } imp->require_c_string(">\n"); errno = 0; char* end; long llen = strtol(lenstr.c_str(), &end, 10); if (*end != '\0' || llen < 0 || (llen == LONG_MAX && errno == ERANGE)) { go_error_at(imp->location(), "invalid inline function length %s", lenstr.c_str()); return false; } *body = imp->read(static_cast<size_t>(llen)); } return true; } // Get the backend representation. Bfunction* Function::get_or_make_decl(Gogo* gogo, Named_object* no) { if (this->fndecl_ == NULL) { unsigned int flags = 0; bool is_init_fn = false; if (no->package() != NULL) { // Functions defined in other packages must be visible. flags |= Backend::function_is_visible; } else if (this->enclosing_ != NULL || Gogo::is_thunk(no)) ; else if (Gogo::unpack_hidden_name(no->name()) == "init" && !this->type_->is_method()) ; else if (no->name() == gogo->get_init_fn_name()) { flags |= Backend::function_is_visible; is_init_fn = true; } else if (Gogo::unpack_hidden_name(no->name()) == "main" && gogo->is_main_package()) flags |= Backend::function_is_visible; // Methods have to be public even if they are hidden because // they can be pulled into type descriptors when using // anonymous fields. else if (!Gogo::is_hidden_name(no->name()) || this->type_->is_method()) { if (!this->is_unnamed_type_stub_method_) flags |= Backend::function_is_visible; } Type* rtype = NULL; if (this->type_->is_method()) rtype = this->type_->receiver()->type(); std::string asm_name; if (!this->asm_name_.empty()) { asm_name = this->asm_name_; // If an assembler name is explicitly specified, there must // be some reason to refer to the symbol from a different // object file. flags |= Backend::function_is_visible; } else if (is_init_fn) { // These names appear in the export data and are used // directly in the assembler code. If we change this here // we need to change Gogo::init_imports. asm_name = no->name(); } else asm_name = gogo->function_asm_name(no->name(), no->package(), rtype); // If an inline body refers to this function, then it // needs to be visible in the symbol table. if (this->is_referenced_by_inline_) flags |= Backend::function_is_visible; // A go:linkname directive can be used to force a function to be // visible. if (this->is_exported_by_linkname_) flags |= Backend::function_is_visible; // If a function calls the predeclared recover function, we // can't inline it, because recover behaves differently in a // function passed directly to defer. If this is a recover // thunk that we built to test whether a function can be // recovered, we can't inline it, because that will mess up // our return address comparison. bool is_inlinable = !(this->calls_recover_ || this->is_recover_thunk_); // If a function calls __go_set_defer_retaddr, then mark it as // uninlinable. This prevents the GCC backend from splitting // the function; splitting the function is a bad idea because we // want the return address label to be in the same function as // the call. if (this->calls_defer_retaddr_) is_inlinable = false; // Check the //go:noinline compiler directive. if ((this->pragmas_ & GOPRAGMA_NOINLINE) != 0) is_inlinable = false; if (is_inlinable) flags |= Backend::function_is_inlinable; // If this is a thunk created to call a function which calls // the predeclared recover function, we need to disable // stack splitting for the thunk. bool disable_split_stack = this->is_recover_thunk_; // Check the //go:nosplit compiler directive. if ((this->pragmas_ & GOPRAGMA_NOSPLIT) != 0) disable_split_stack = true; if (disable_split_stack) flags |= Backend::function_no_split_stack; // This should go into a unique section if that has been // requested elsewhere, or if this is a nointerface function. // We want to put a nointerface function into a unique section // because there is a good chance that the linker garbage // collection can discard it. if (this->in_unique_section_ || (this->is_method() && this->nointerface())) flags |= Backend::function_in_unique_section; if (this->is_inline_only_) flags |= Backend::function_only_inline; Btype* functype = this->type_->get_backend_fntype(gogo); this->fndecl_ = gogo->backend()->function(functype, no->get_id(gogo), asm_name, flags, this->location()); } return this->fndecl_; } // Get the backend representation. Bfunction* Function_declaration::get_or_make_decl(Gogo* gogo, Named_object* no) { if (this->fndecl_ == NULL) { unsigned int flags = (Backend::function_is_visible | Backend::function_is_declaration | Backend::function_is_inlinable); // Let Go code use an asm declaration to pick up a builtin // function. if (!this->asm_name_.empty()) { Bfunction* builtin_decl = gogo->backend()->lookup_builtin(this->asm_name_); if (builtin_decl != NULL) { this->fndecl_ = builtin_decl; return this->fndecl_; } if (this->asm_name_ == "runtime.gopanic" || this->asm_name_.compare(0, 13, "runtime.panic") == 0 || this->asm_name_.compare(0, 15, "runtime.goPanic") == 0 || this->asm_name_ == "runtime.block") flags |= Backend::function_does_not_return; } std::string asm_name; if (this->asm_name_.empty()) { Type* rtype = NULL; if (this->fntype_->is_method()) rtype = this->fntype_->receiver()->type(); asm_name = gogo->function_asm_name(no->name(), no->package(), rtype); } else if (go_id_needs_encoding(no->get_id(gogo))) asm_name = go_encode_id(no->get_id(gogo)); Btype* functype = this->fntype_->get_backend_fntype(gogo); this->fndecl_ = gogo->backend()->function(functype, no->get_id(gogo), asm_name, flags, this->location()); } return this->fndecl_; } // Build the descriptor for a function declaration. This won't // necessarily happen if the package has just a declaration for the // function and no other reference to it, but we may still need the // descriptor for references from other packages. void Function_declaration::build_backend_descriptor(Gogo* gogo) { if (this->descriptor_ != NULL) { Translate_context context(gogo, NULL, NULL, NULL); this->descriptor_->get_backend(&context); } } // Check that the types used in this declaration's signature are defined. // Reports errors for any undefined type. void Function_declaration::check_types() const { // Calling Type::base will give errors for any undefined types. Function_type* fntype = this->type(); if (fntype->receiver() != NULL) fntype->receiver()->type()->base(); if (fntype->parameters() != NULL) { const Typed_identifier_list* params = fntype->parameters(); for (Typed_identifier_list::const_iterator p = params->begin(); p != params->end(); ++p) p->type()->base(); } } // Return the function's decl after it has been built. Bfunction* Function::get_decl() const { go_assert(this->fndecl_ != NULL); return this->fndecl_; } // Build the backend representation for the function code. void Function::build(Gogo* gogo, Named_object* named_function) { Translate_context context(gogo, named_function, NULL, NULL); // A list of parameter variables for this function. std::vector<Bvariable*> param_vars; // Variables that need to be declared for this function and their // initial values. std::vector<Bvariable*> vars; std::vector<Expression*> var_inits; std::vector<Statement*> var_decls_stmts; for (Bindings::const_definitions_iterator p = this->block_->bindings()->begin_definitions(); p != this->block_->bindings()->end_definitions(); ++p) { Location loc = (*p)->location(); if ((*p)->is_variable() && (*p)->var_value()->is_parameter()) { Bvariable* bvar = (*p)->get_backend_variable(gogo, named_function); Bvariable* parm_bvar = bvar; // We always pass the receiver to a method as a pointer. If // the receiver is declared as a non-pointer type, then we // copy the value into a local variable. For direct interface // type we pack the pointer into the type. if ((*p)->var_value()->is_receiver() && (*p)->var_value()->type()->points_to() == NULL) { std::string name = (*p)->name() + ".pointer"; Type* var_type = (*p)->var_value()->type(); Variable* parm_var = new Variable(Type::make_pointer_type(var_type), NULL, false, true, false, loc); Named_object* parm_no = Named_object::make_variable(name, NULL, parm_var); parm_bvar = parm_no->get_backend_variable(gogo, named_function); vars.push_back(bvar); Expression* parm_ref = Expression::make_var_reference(parm_no, loc); Type* recv_type = (*p)->var_value()->type(); if (recv_type->is_direct_iface_type()) parm_ref = Expression::pack_direct_iface(recv_type, parm_ref, loc); else parm_ref = Expression::make_dereference(parm_ref, Expression::NIL_CHECK_NEEDED, loc); if ((*p)->var_value()->is_in_heap()) parm_ref = Expression::make_heap_expression(parm_ref, loc); var_inits.push_back(parm_ref); } else if ((*p)->var_value()->is_in_heap()) { // If we take the address of a parameter, then we need // to copy it into the heap. std::string parm_name = (*p)->name() + ".param"; Variable* parm_var = new Variable((*p)->var_value()->type(), NULL, false, true, false, loc); Named_object* parm_no = Named_object::make_variable(parm_name, NULL, parm_var); parm_bvar = parm_no->get_backend_variable(gogo, named_function); vars.push_back(bvar); Expression* var_ref = Expression::make_var_reference(parm_no, loc); var_ref = Expression::make_heap_expression(var_ref, loc); var_inits.push_back(var_ref); } param_vars.push_back(parm_bvar); } else if ((*p)->is_result_variable()) { Bvariable* bvar = (*p)->get_backend_variable(gogo, named_function); Type* type = (*p)->result_var_value()->type(); Expression* init; if (!(*p)->result_var_value()->is_in_heap()) { Btype* btype = type->get_backend(gogo); Bexpression* binit = gogo->backend()->zero_expression(btype); init = Expression::make_backend(binit, type, loc); } else init = Expression::make_allocation(type, loc); vars.push_back(bvar); var_inits.push_back(init); } else if (this->defer_stack_ != NULL && (*p)->is_variable() && (*p)->var_value()->is_non_escaping_address_taken() && !(*p)->var_value()->is_in_heap()) { // Local variable captured by deferred closure needs to be live // until the end of the function. We create a top-level // declaration for it. // TODO: we don't need to do this if the variable is not captured // by the defer closure. There is no easy way to check it here, // so we do this for all address-taken variables for now. Variable* var = (*p)->var_value(); Temporary_statement* ts = Statement::make_temporary(var->type(), NULL, var->location()); ts->set_is_address_taken(); var->set_toplevel_decl(ts); var_decls_stmts.push_back(ts); } } if (!gogo->backend()->function_set_parameters(this->fndecl_, param_vars)) { go_assert(saw_errors()); return; } // If we need a closure variable, make sure to create it. // It gets installed in the function as a side effect of creation. if (this->closure_var_ != NULL) { go_assert(this->closure_var_->var_value()->is_closure()); this->closure_var_->get_backend_variable(gogo, named_function); } if (this->block_ != NULL) { // Declare variables if necessary. Bblock* var_decls = NULL; std::vector<Bstatement*> var_decls_bstmt_list; Bstatement* defer_init = NULL; if (!vars.empty() || this->defer_stack_ != NULL) { var_decls = gogo->backend()->block(this->fndecl_, NULL, vars, this->block_->start_location(), this->block_->end_location()); if (this->defer_stack_ != NULL) { Translate_context dcontext(gogo, named_function, this->block_, var_decls); defer_init = this->defer_stack_->get_backend(&dcontext); var_decls_bstmt_list.push_back(defer_init); for (std::vector<Statement*>::iterator p = var_decls_stmts.begin(); p != var_decls_stmts.end(); ++p) { Bstatement* bstmt = (*p)->get_backend(&dcontext); var_decls_bstmt_list.push_back(bstmt); } } } // Build the backend representation for all the statements in the // function. Translate_context bcontext(gogo, named_function, NULL, NULL); Bblock* code_block = this->block_->get_backend(&bcontext); // Initialize variables if necessary. Translate_context icontext(gogo, named_function, this->block_, var_decls); std::vector<Bstatement*> init; go_assert(vars.size() == var_inits.size()); for (size_t i = 0; i < vars.size(); ++i) { Bexpression* binit = var_inits[i]->get_backend(&icontext); Bstatement* init_stmt = gogo->backend()->init_statement(this->fndecl_, vars[i], binit); init.push_back(init_stmt); } Bstatement* var_init = gogo->backend()->statement_list(init); // Initialize all variables before executing this code block. Bstatement* code_stmt = gogo->backend()->block_statement(code_block); code_stmt = gogo->backend()->compound_statement(var_init, code_stmt); // If we have a defer stack, initialize it at the start of a // function. Bstatement* except = NULL; Bstatement* fini = NULL; if (defer_init != NULL) { // Clean up the defer stack when we leave the function. this->build_defer_wrapper(gogo, named_function, &except, &fini); // Wrap the code for this function in an exception handler to handle // defer calls. code_stmt = gogo->backend()->exception_handler_statement(code_stmt, except, fini, this->location_); } // Stick the code into the block we built for the receiver, if // we built one. if (var_decls != NULL) { var_decls_bstmt_list.push_back(code_stmt); gogo->backend()->block_add_statements(var_decls, var_decls_bstmt_list); code_stmt = gogo->backend()->block_statement(var_decls); } if (!gogo->backend()->function_set_body(this->fndecl_, code_stmt)) { go_assert(saw_errors()); return; } } // If we created a descriptor for the function, make sure we emit it. if (this->descriptor_ != NULL) { Translate_context dcontext(gogo, NULL, NULL, NULL); this->descriptor_->get_backend(&dcontext); } } // Build the wrappers around function code needed if the function has // any defer statements. This sets *EXCEPT to an exception handler // and *FINI to a finally handler. void Function::build_defer_wrapper(Gogo* gogo, Named_object* named_function, Bstatement** except, Bstatement** fini) { Location end_loc = this->block_->end_location(); // Add an exception handler. This is used if a panic occurs. Its // purpose is to stop the stack unwinding if a deferred function // calls recover. There are more details in // libgo/runtime/go-unwind.c. std::vector<Bstatement*> stmts; Expression* call = Runtime::make_call(Runtime::CHECKDEFER, end_loc, 1, this->defer_stack(end_loc)); Translate_context context(gogo, named_function, NULL, NULL); Bexpression* defer = call->get_backend(&context); stmts.push_back(gogo->backend()->expression_statement(this->fndecl_, defer)); Bstatement* ret_bstmt = this->return_value(gogo, named_function, end_loc); if (ret_bstmt != NULL) stmts.push_back(ret_bstmt); go_assert(*except == NULL); *except = gogo->backend()->statement_list(stmts); call = Runtime::make_call(Runtime::CHECKDEFER, end_loc, 1, this->defer_stack(end_loc)); defer = call->get_backend(&context); call = Runtime::make_call(Runtime::DEFERRETURN, end_loc, 1, this->defer_stack(end_loc)); Bexpression* undefer = call->get_backend(&context); Bstatement* function_defer = gogo->backend()->function_defer_statement(this->fndecl_, undefer, defer, end_loc); stmts = std::vector<Bstatement*>(1, function_defer); if (this->type_->results() != NULL && !this->type_->results()->empty() && !this->type_->results()->front().name().empty()) { // If the result variables are named, and we are returning from // this function rather than panicing through it, we need to // return them again, because they might have been changed by a // defer function. The runtime routines set the defer_stack // variable to true if we are returning from this function. ret_bstmt = this->return_value(gogo, named_function, end_loc); Bexpression* nil = Expression::make_nil(end_loc)->get_backend(&context); Bexpression* ret = gogo->backend()->compound_expression(ret_bstmt, nil, end_loc); Expression* ref = Expression::make_temporary_reference(this->defer_stack_, end_loc); Bexpression* bref = ref->get_backend(&context); ret = gogo->backend()->conditional_expression(this->fndecl_, NULL, bref, ret, NULL, end_loc); stmts.push_back(gogo->backend()->expression_statement(this->fndecl_, ret)); } go_assert(*fini == NULL); *fini = gogo->backend()->statement_list(stmts); } // Return the statement that assigns values to this function's result struct. Bstatement* Function::return_value(Gogo* gogo, Named_object* named_function, Location location) const { const Typed_identifier_list* results = this->type_->results(); if (results == NULL || results->empty()) return NULL; go_assert(this->results_ != NULL); if (this->results_->size() != results->size()) { go_assert(saw_errors()); return gogo->backend()->error_statement(); } std::vector<Bexpression*> vals(results->size()); for (size_t i = 0; i < vals.size(); ++i) { Named_object* no = (*this->results_)[i]; Bvariable* bvar = no->get_backend_variable(gogo, named_function); Bexpression* val = gogo->backend()->var_expression(bvar, location); if (no->result_var_value()->is_in_heap()) { Btype* bt = no->result_var_value()->type()->get_backend(gogo); val = gogo->backend()->indirect_expression(bt, val, true, location); } vals[i] = val; } return gogo->backend()->return_statement(this->fndecl_, vals, location); } // Class Block. Block::Block(Block* enclosing, Location location) : enclosing_(enclosing), statements_(), bindings_(new Bindings(enclosing == NULL ? NULL : enclosing->bindings())), start_location_(location), end_location_(Linemap::unknown_location()) { } // Add a statement to a block. void Block::add_statement(Statement* statement) { this->statements_.push_back(statement); } // Add a statement to the front of a block. This is slow but is only // used for reference counts of parameters. void Block::add_statement_at_front(Statement* statement) { this->statements_.insert(this->statements_.begin(), statement); } // Replace a statement in a block. void Block::replace_statement(size_t index, Statement* s) { go_assert(index < this->statements_.size()); this->statements_[index] = s; } // Add a statement before another statement. void Block::insert_statement_before(size_t index, Statement* s) { go_assert(index < this->statements_.size()); this->statements_.insert(this->statements_.begin() + index, s); } // Add a statement after another statement. void Block::insert_statement_after(size_t index, Statement* s) { go_assert(index < this->statements_.size()); this->statements_.insert(this->statements_.begin() + index + 1, s); } // Traverse the tree. int Block::traverse(Traverse* traverse) { unsigned int traverse_mask = traverse->traverse_mask(); if ((traverse_mask & Traverse::traverse_blocks) != 0) { int t = traverse->block(this); if (t == TRAVERSE_EXIT) return TRAVERSE_EXIT; else if (t == TRAVERSE_SKIP_COMPONENTS) return TRAVERSE_CONTINUE; } if ((traverse_mask & (Traverse::traverse_variables | Traverse::traverse_constants | Traverse::traverse_expressions | Traverse::traverse_types)) != 0) { const unsigned int e_or_t = (Traverse::traverse_expressions | Traverse::traverse_types); const unsigned int e_or_t_or_s = (e_or_t | Traverse::traverse_statements); for (Bindings::const_definitions_iterator pb = this->bindings_->begin_definitions(); pb != this->bindings_->end_definitions(); ++pb) { int t = TRAVERSE_CONTINUE; switch ((*pb)->classification()) { case Named_object::NAMED_OBJECT_CONST: if ((traverse_mask & Traverse::traverse_constants) != 0) t = traverse->constant(*pb, false); if (t == TRAVERSE_CONTINUE && (traverse_mask & e_or_t) != 0) { Type* tc = (*pb)->const_value()->type(); if (tc != NULL && Type::traverse(tc, traverse) == TRAVERSE_EXIT) return TRAVERSE_EXIT; t = (*pb)->const_value()->traverse_expression(traverse); } break; case Named_object::NAMED_OBJECT_VAR: case Named_object::NAMED_OBJECT_RESULT_VAR: if ((traverse_mask & Traverse::traverse_variables) != 0) t = traverse->variable(*pb); if (t == TRAVERSE_CONTINUE && (traverse_mask & e_or_t) != 0) { if ((*pb)->is_result_variable() || (*pb)->var_value()->has_type()) { Type* tv = ((*pb)->is_variable() ? (*pb)->var_value()->type() : (*pb)->result_var_value()->type()); if (tv != NULL && Type::traverse(tv, traverse) == TRAVERSE_EXIT) return TRAVERSE_EXIT; } } if (t == TRAVERSE_CONTINUE && (traverse_mask & e_or_t_or_s) != 0 && (*pb)->is_variable()) t = (*pb)->var_value()->traverse_expression(traverse, traverse_mask); break; case Named_object::NAMED_OBJECT_FUNC: case Named_object::NAMED_OBJECT_FUNC_DECLARATION: go_unreachable(); case Named_object::NAMED_OBJECT_TYPE: if ((traverse_mask & e_or_t) != 0) t = Type::traverse((*pb)->type_value(), traverse); break; case Named_object::NAMED_OBJECT_TYPE_DECLARATION: case Named_object::NAMED_OBJECT_UNKNOWN: case Named_object::NAMED_OBJECT_ERRONEOUS: break; case Named_object::NAMED_OBJECT_PACKAGE: case Named_object::NAMED_OBJECT_SINK: go_unreachable(); default: go_unreachable(); } if (t == TRAVERSE_EXIT) return TRAVERSE_EXIT; } } // No point in checking traverse_mask here--if we got here we always // want to walk the statements. The traversal can insert new // statements before or after the current statement. Inserting // statements before the current statement requires updating I via // the pointer; those statements will not be traversed. Any new // statements inserted after the current statement will be traversed // in their turn. for (size_t i = 0; i < this->statements_.size(); ++i) { if (this->statements_[i]->traverse(this, &i, traverse) == TRAVERSE_EXIT) return TRAVERSE_EXIT; } return TRAVERSE_CONTINUE; } // Work out types for unspecified variables and constants. void Block::determine_types() { for (Bindings::const_definitions_iterator pb = this->bindings_->begin_definitions(); pb != this->bindings_->end_definitions(); ++pb) { if ((*pb)->is_variable()) (*pb)->var_value()->determine_type(); else if ((*pb)->is_const()) (*pb)->const_value()->determine_type(); } for (std::vector<Statement*>::const_iterator ps = this->statements_.begin(); ps != this->statements_.end(); ++ps) (*ps)->determine_types(); } // Return true if the statements in this block may fall through. bool Block::may_fall_through() const { if (this->statements_.empty()) return true; return this->statements_.back()->may_fall_through(); } // Write export data for a block. void Block::export_block(Export_function_body* efb) { for (Block::iterator p = this->begin(); p != this->end(); ++p) { efb->indent(); efb->increment_indent(); (*p)->export_statement(efb); efb->decrement_indent(); Location loc = (*p)->location(); if ((*p)->is_block_statement()) { // For a block we put the start location on the first brace // in Block_statement::do_export_statement. Here we put the // end location on the final brace. loc = (*p)->block_statement()->block()->end_location(); } char buf[50]; snprintf(buf, sizeof buf, " //%d\n", Linemap::location_to_line(loc)); efb->write_c_string(buf); } } // Add exported block data to SET, reading from BODY starting at OFF. // Returns whether the import succeeded. bool Block::import_block(Block* set, Import_function_body *ifb, Location loc) { Location eloc = ifb->location(); Location sloc = loc; const std::string& body(ifb->body()); size_t off = ifb->off(); while (off < body.length()) { int indent = ifb->indent(); if (off + indent >= body.length()) { go_error_at(eloc, "invalid export data for %qs: insufficient indentation", ifb->name().c_str()); return false; } for (int i = 0; i < indent - 1; i++) { if (body[off + i] != ' ') { go_error_at(eloc, "invalid export data for %qs: bad indentation", ifb->name().c_str()); return false; } } bool at_end = false; if (body[off + indent - 1] == '}') at_end = true; else if (body[off + indent - 1] != ' ') { go_error_at(eloc, "invalid export data for %qs: bad indentation", ifb->name().c_str()); return false; } off += indent; size_t nl = body.find('\n', off); if (nl == std::string::npos) { go_error_at(eloc, "invalid export data for %qs: missing newline", ifb->name().c_str()); return false; } size_t lineno_pos = body.find(" //", off); if (lineno_pos == std::string::npos || lineno_pos >= nl) { go_error_at(eloc, "invalid export data for %qs: missing line number", ifb->name().c_str()); return false; } unsigned int lineno = 0; for (size_t i = lineno_pos + 3; i < nl; ++i) { char c = body[i]; if (c < '0' || c > '9') { go_error_at(loc, "invalid export data for %qs: invalid line number", ifb->name().c_str()); return false; } lineno = lineno * 10 + c - '0'; } ifb->gogo()->linemap()->start_line(lineno, 1); sloc = ifb->gogo()->linemap()->get_location(0); if (at_end) { // An if statement can have an "else" following the "}", in // which case we want to leave the offset where it is, just // after the "}". We don't get the block ending location // quite right for if statements. if (body.compare(off, 6, " else ") != 0) off = nl + 1; break; } ifb->set_off(off); Statement* s = Statement::import_statement(ifb, sloc); if (s == NULL) return false; set->add_statement(s); size_t at = ifb->off(); if (at < nl + 1) off = nl + 1; else off = at; } ifb->set_off(off); set->set_end_location(sloc); return true; } // Convert a block to the backend representation. Bblock* Block::get_backend(Translate_context* context) { Gogo* gogo = context->gogo(); Named_object* function = context->function(); std::vector<Bvariable*> vars; vars.reserve(this->bindings_->size_definitions()); for (Bindings::const_definitions_iterator pv = this->bindings_->begin_definitions(); pv != this->bindings_->end_definitions(); ++pv) { if ((*pv)->is_variable() && !(*pv)->var_value()->is_parameter()) vars.push_back((*pv)->get_backend_variable(gogo, function)); } go_assert(function != NULL); Bfunction* bfunction = function->func_value()->get_or_make_decl(gogo, function); Bblock* ret = context->backend()->block(bfunction, context->bblock(), vars, this->start_location_, this->end_location_); Translate_context subcontext(gogo, function, this, ret); std::vector<Bstatement*> bstatements; bstatements.reserve(this->statements_.size()); for (std::vector<Statement*>::const_iterator p = this->statements_.begin(); p != this->statements_.end(); ++p) bstatements.push_back((*p)->get_backend(&subcontext)); context->backend()->block_add_statements(ret, bstatements); return ret; } // Class Bindings_snapshot. Bindings_snapshot::Bindings_snapshot(const Block* b, Location location) : block_(b), counts_(), location_(location) { while (b != NULL) { this->counts_.push_back(b->bindings()->size_definitions()); b = b->enclosing(); } } // Report errors appropriate for a goto from B to this. void Bindings_snapshot::check_goto_from(const Block* b, Location loc) { size_t dummy; if (!this->check_goto_block(loc, b, this->block_, &dummy)) return; this->check_goto_defs(loc, this->block_, this->block_->bindings()->size_definitions(), this->counts_[0]); } // Report errors appropriate for a goto from this to B. void Bindings_snapshot::check_goto_to(const Block* b) { size_t index; if (!this->check_goto_block(this->location_, this->block_, b, &index)) return; this->check_goto_defs(this->location_, b, this->counts_[index], b->bindings()->size_definitions()); } // Report errors appropriate for a goto at LOC from BFROM to BTO. // Return true if all is well, false if we reported an error. If this // returns true, it sets *PINDEX to the number of blocks BTO is above // BFROM. bool Bindings_snapshot::check_goto_block(Location loc, const Block* bfrom, const Block* bto, size_t* pindex) { // It is an error if BTO is not either BFROM or above BFROM. size_t index = 0; for (const Block* pb = bfrom; pb != bto; pb = pb->enclosing(), ++index) { if (pb == NULL) { go_error_at(loc, "goto jumps into block"); go_inform(bto->start_location(), "goto target block starts here"); return false; } } *pindex = index; return true; } // Report errors appropriate for a goto at LOC ending at BLOCK, where // CFROM is the number of names defined at the point of the goto and // CTO is the number of names defined at the point of the label. void Bindings_snapshot::check_goto_defs(Location loc, const Block* block, size_t cfrom, size_t cto) { if (cfrom < cto) { Bindings::const_definitions_iterator p = block->bindings()->begin_definitions(); for (size_t i = 0; i < cfrom; ++i) { go_assert(p != block->bindings()->end_definitions()); ++p; } go_assert(p != block->bindings()->end_definitions()); for (; p != block->bindings()->end_definitions(); ++p) { if ((*p)->is_variable()) { std::string n = (*p)->message_name(); go_error_at(loc, "goto jumps over declaration of %qs", n.c_str()); go_inform((*p)->location(), "%qs defined here", n.c_str()); } } } } // Class Function_declaration. // Whether this declares a method. bool Function_declaration::is_method() const { return this->fntype_->is_method(); } // Whether this method should not be included in the type descriptor. bool Function_declaration::nointerface() const { go_assert(this->is_method()); return (this->pragmas_ & GOPRAGMA_NOINTERFACE) != 0; } // Record that this method should not be included in the type // descriptor. void Function_declaration::set_nointerface() { this->pragmas_ |= GOPRAGMA_NOINTERFACE; } // Import an inlinable function. This is used for an inlinable // function whose body is recorded in the export data. Parse the // export data into a Block and create a regular function using that // Block as its body. Redeclare this function declaration as the // function. void Function_declaration::import_function_body(Gogo* gogo, Named_object* no) { go_assert(no->func_declaration_value() == this); go_assert(no->package() != NULL); const std::string& body(this->imported_body_); go_assert(!body.empty()); // Read the "//FILE:LINE" comment starts the export data. size_t indent = 1; if (this->is_method()) indent = 2; size_t i = 0; for (; i < indent; i++) { if (body.at(i) != ' ') { go_error_at(this->location_, "invalid export body for %qs: bad initial indentation", no->message_name().c_str()); return; } } if (body.substr(i, 2) != "//") { go_error_at(this->location_, "invalid export body for %qs: missing file comment", no->message_name().c_str()); return; } size_t colon = body.find(':', i + 2); size_t nl = body.find('\n', i + 2); if (nl == std::string::npos) { go_error_at(this->location_, "invalid export body for %qs: missing file name", no->message_name().c_str()); return; } if (colon == std::string::npos || nl < colon) { go_error_at(this->location_, "invalid export body for %qs: missing initial line number", no->message_name().c_str()); return; } std::string file = body.substr(i + 2, colon - (i + 2)); std::string linestr = body.substr(colon + 1, nl - (colon + 1)); char* end; long linenol = strtol(linestr.c_str(), &end, 10); if (*end != '\0') { go_error_at(this->location_, "invalid export body for %qs: invalid initial line number", no->message_name().c_str()); return; } unsigned int lineno = static_cast<unsigned int>(linenol); // Turn the file/line into a location. char* alc = new char[file.length() + 1]; memcpy(alc, file.data(), file.length()); alc[file.length()] = '\0'; gogo->linemap()->start_file(alc, lineno); gogo->linemap()->start_line(lineno, 1); Location start_loc = gogo->linemap()->get_location(0); // Define the function with an outer block that declares the // parameters. Function_type* fntype = this->fntype_; Block* outer = new Block(NULL, start_loc); Function* fn = new Function(fntype, NULL, outer, start_loc); fn->set_is_inline_only(); if (fntype->is_method()) { if (this->nointerface()) fn->set_nointerface(); const Typed_identifier* receiver = fntype->receiver(); Variable* recv_param = new Variable(receiver->type(), NULL, false, true, true, start_loc); std::string rname = receiver->name(); unsigned rcounter = 0; // We need to give a nameless receiver a name to avoid having it // clash with some other nameless param. FIXME. Gogo::rename_if_empty(&rname, "r", &rcounter); outer->bindings()->add_variable(rname, NULL, recv_param); } const Typed_identifier_list* params = fntype->parameters(); bool is_varargs = fntype->is_varargs(); unsigned pcounter = 0; if (params != NULL) { for (Typed_identifier_list::const_iterator p = params->begin(); p != params->end(); ++p) { Variable* param = new Variable(p->type(), NULL, false, true, false, start_loc); if (is_varargs && p + 1 == params->end()) param->set_is_varargs_parameter(); std::string pname = p->name(); // We need to give each nameless parameter a non-empty name to avoid // having it clash with some other nameless param. FIXME. Gogo::rename_if_empty(&pname, "p", &pcounter); outer->bindings()->add_variable(pname, NULL, param); } } fn->create_result_variables(gogo); if (!fntype->is_method()) { const Package* package = no->package(); no = package->bindings()->add_function(no->name(), package, fn); } else { Named_type* rtype = fntype->receiver()->type()->deref()->named_type(); go_assert(rtype != NULL); no = rtype->add_method(no->name(), fn); const Package* package = rtype->named_object()->package(); package->bindings()->add_method(no); } Import_function_body ifb(gogo, this->imp_, no, body, nl + 1, outer, indent); if (!Block::import_block(outer, &ifb, start_loc)) return; gogo->lower_block(no, outer); outer->determine_types(); gogo->add_imported_inline_function(no); } // Return the function descriptor. Expression* Function_declaration::descriptor(Gogo*, Named_object* no) { go_assert(!this->fntype_->is_method()); if (this->descriptor_ == NULL) this->descriptor_ = Expression::make_func_descriptor(no); return this->descriptor_; } // Class Variable. Variable::Variable(Type* type, Expression* init, bool is_global, bool is_parameter, bool is_receiver, Location location) : type_(type), init_(init), preinit_(NULL), location_(location), backend_(NULL), is_global_(is_global), is_parameter_(is_parameter), is_closure_(false), is_receiver_(is_receiver), is_varargs_parameter_(false), is_used_(false), is_address_taken_(false), is_non_escaping_address_taken_(false), seen_(false), init_is_lowered_(false), init_is_flattened_(false), type_from_init_tuple_(false), type_from_range_index_(false), type_from_range_value_(false), type_from_chan_element_(false), is_type_switch_var_(false), determined_type_(false), in_unique_section_(false), is_referenced_by_inline_(false), toplevel_decl_(NULL) { go_assert(type != NULL || init != NULL); go_assert(!is_parameter || init == NULL); } // Traverse the initializer expression. int Variable::traverse_expression(Traverse* traverse, unsigned int traverse_mask) { if (this->preinit_ != NULL) { if (this->preinit_->traverse(traverse) == TRAVERSE_EXIT) return TRAVERSE_EXIT; } if (this->init_ != NULL && ((traverse_mask & (Traverse::traverse_expressions | Traverse::traverse_types)) != 0)) { if (Expression::traverse(&this->init_, traverse) == TRAVERSE_EXIT) return TRAVERSE_EXIT; } return TRAVERSE_CONTINUE; } // Lower the initialization expression after parsing is complete. void Variable::lower_init_expression(Gogo* gogo, Named_object* function, Statement_inserter* inserter) { Named_object* dep = gogo->var_depends_on(this); if (dep != NULL && dep->is_variable()) dep->var_value()->lower_init_expression(gogo, function, inserter); if (this->init_ != NULL && !this->init_is_lowered_) { if (this->seen_) { // We will give an error elsewhere, this is just to prevent // an infinite loop. return; } this->seen_ = true; Statement_inserter global_inserter; if (this->is_global_) { global_inserter = Statement_inserter(gogo, this); inserter = &global_inserter; } gogo->lower_expression(function, inserter, &this->init_); this->seen_ = false; this->init_is_lowered_ = true; } } // Flatten the initialization expression after ordering evaluations. void Variable::flatten_init_expression(Gogo* gogo, Named_object* function, Statement_inserter* inserter) { Named_object* dep = gogo->var_depends_on(this); if (dep != NULL && dep->is_variable()) dep->var_value()->flatten_init_expression(gogo, function, inserter); if (this->init_ != NULL && !this->init_is_flattened_) { if (this->seen_) { // We will give an error elsewhere, this is just to prevent // an infinite loop. return; } this->seen_ = true; Statement_inserter global_inserter; if (this->is_global_) { global_inserter = Statement_inserter(gogo, this); inserter = &global_inserter; } gogo->flatten_expression(function, inserter, &this->init_); // If an interface conversion is needed, we need a temporary // variable. if (this->type_ != NULL && !Type::are_identical(this->type_, this->init_->type(), Type::COMPARE_ERRORS | Type::COMPARE_TAGS, NULL) && this->init_->type()->interface_type() != NULL && !this->init_->is_variable()) { Temporary_statement* temp = Statement::make_temporary(NULL, this->init_, this->location_); inserter->insert(temp); this->init_ = Expression::make_temporary_reference(temp, this->location_); } this->seen_ = false; this->init_is_flattened_ = true; } } // Get the preinit block. Block* Variable::preinit_block(Gogo* gogo) { go_assert(this->is_global_); if (this->preinit_ == NULL) this->preinit_ = new Block(NULL, this->location()); // If a global variable has a preinitialization statement, then we // need to have an initialization function. gogo->set_need_init_fn(); return this->preinit_; } // Add a statement to be run before the initialization expression. void Variable::add_preinit_statement(Gogo* gogo, Statement* s) { Block* b = this->preinit_block(gogo); b->add_statement(s); b->set_end_location(s->location()); } // Whether this variable has a type. bool Variable::has_type() const { if (this->type_ == NULL) return false; // A variable created in a type switch case nil does not actually // have a type yet. It will be changed to use the initializer's // type in determine_type. if (this->is_type_switch_var_ && this->type_->is_nil_constant_as_type()) return false; return true; } // In an assignment which sets a variable to a tuple of EXPR, return // the type of the first element of the tuple. Type* Variable::type_from_tuple(Expression* expr, bool report_error) const { if (expr->map_index_expression() != NULL) { Map_type* mt = expr->map_index_expression()->get_map_type(); if (mt == NULL) return Type::make_error_type(); return mt->val_type(); } else if (expr->receive_expression() != NULL) { Expression* channel = expr->receive_expression()->channel(); Type* channel_type = channel->type(); if (channel_type->channel_type() == NULL) return Type::make_error_type(); return channel_type->channel_type()->element_type(); } else { if (report_error) go_error_at(this->location(), "invalid tuple definition"); return Type::make_error_type(); } } // Given EXPR used in a range clause, return either the index type or // the value type of the range, depending upon GET_INDEX_TYPE. Type* Variable::type_from_range(Expression* expr, bool get_index_type, bool report_error) const { Type* t = expr->type(); if (t->array_type() != NULL || (t->points_to() != NULL && t->points_to()->array_type() != NULL && !t->points_to()->is_slice_type())) { if (get_index_type) return Type::lookup_integer_type("int"); else return t->deref()->array_type()->element_type(); } else if (t->is_string_type()) { if (get_index_type) return Type::lookup_integer_type("int"); else return Type::lookup_integer_type("int32"); } else if (t->map_type() != NULL) { if (get_index_type) return t->map_type()->key_type(); else return t->map_type()->val_type(); } else if (t->channel_type() != NULL) { if (get_index_type) return t->channel_type()->element_type(); else { if (report_error) go_error_at(this->location(), ("invalid definition of value variable " "for channel range")); return Type::make_error_type(); } } else { if (report_error) go_error_at(this->location(), "invalid type for range clause"); return Type::make_error_type(); } } // EXPR should be a channel. Return the channel's element type. Type* Variable::type_from_chan_element(Expression* expr, bool report_error) const { Type* t = expr->type(); if (t->channel_type() != NULL) return t->channel_type()->element_type(); else { if (report_error) go_error_at(this->location(), "expected channel"); return Type::make_error_type(); } } // Return the type of the Variable. This may be called before // Variable::determine_type is called, which means that we may need to // get the type from the initializer. FIXME: If we combine lowering // with type determination, then this should be unnecessary. Type* Variable::type() { // A variable in a type switch with a nil case will have the wrong // type here. This gets fixed up in determine_type, below. Type* type = this->type_; Expression* init = this->init_; if (this->is_type_switch_var_ && type != NULL && this->type_->is_nil_constant_as_type()) { Type_guard_expression* tge = this->init_->type_guard_expression(); go_assert(tge != NULL); init = tge->expr(); type = NULL; } if (this->seen_) { if (this->type_ == NULL || !this->type_->is_error_type()) { go_error_at(this->location_, "variable initializer refers to itself"); this->type_ = Type::make_error_type(); } return this->type_; } this->seen_ = true; if (type != NULL) ; else if (this->type_from_init_tuple_) type = this->type_from_tuple(init, false); else if (this->type_from_range_index_ || this->type_from_range_value_) type = this->type_from_range(init, this->type_from_range_index_, false); else if (this->type_from_chan_element_) type = this->type_from_chan_element(init, false); else { go_assert(init != NULL); type = init->type(); go_assert(type != NULL); // Variables should not have abstract types. if (type->is_abstract()) type = type->make_non_abstract_type(); if (type->is_void_type()) type = Type::make_error_type(); } this->seen_ = false; return type; } // Fetch the type from a const pointer, in which case it should have // been set already. Type* Variable::type() const { go_assert(this->type_ != NULL); return this->type_; } // Set the type if necessary. void Variable::determine_type() { if (this->determined_type_) return; this->determined_type_ = true; if (this->preinit_ != NULL) this->preinit_->determine_types(); // A variable in a type switch with a nil case will have the wrong // type here. It will have an initializer which is a type guard. // We want to initialize it to the value without the type guard, and // use the type of that value as well. if (this->is_type_switch_var_ && this->type_ != NULL && this->type_->is_nil_constant_as_type()) { Type_guard_expression* tge = this->init_->type_guard_expression(); go_assert(tge != NULL); this->type_ = NULL; this->init_ = tge->expr(); } if (this->init_ == NULL) go_assert(this->type_ != NULL && !this->type_->is_abstract()); else if (this->type_from_init_tuple_) { Expression *init = this->init_; init->determine_type_no_context(); this->type_ = this->type_from_tuple(init, true); this->init_ = NULL; } else if (this->type_from_range_index_ || this->type_from_range_value_) { Expression* init = this->init_; init->determine_type_no_context(); this->type_ = this->type_from_range(init, this->type_from_range_index_, true); this->init_ = NULL; } else if (this->type_from_chan_element_) { Expression* init = this->init_; init->determine_type_no_context(); this->type_ = this->type_from_chan_element(init, true); this->init_ = NULL; } else { Type_context context(this->type_, false); this->init_->determine_type(&context); if (this->type_ == NULL) { Type* type = this->init_->type(); go_assert(type != NULL); if (type->is_abstract()) type = type->make_non_abstract_type(); if (type->is_void_type()) { go_error_at(this->location_, "variable has no type"); type = Type::make_error_type(); } else if (type->is_nil_type()) { go_error_at(this->location_, "variable defined to nil type"); type = Type::make_error_type(); } else if (type->is_call_multiple_result_type()) { go_error_at(this->location_, "single variable set to multiple-value function call"); type = Type::make_error_type(); } this->type_ = type; } } } // Get the initial value of a variable. This does not // consider whether the variable is in the heap--it returns the // initial value as though it were always stored in the stack. Bexpression* Variable::get_init(Gogo* gogo, Named_object* function) { go_assert(this->preinit_ == NULL); Location loc = this->location(); if (this->init_ == NULL) { go_assert(!this->is_parameter_); if (this->is_global_ || this->is_in_heap()) return NULL; Btype* btype = this->type()->get_backend(gogo); return gogo->backend()->zero_expression(btype); } else { Translate_context context(gogo, function, NULL, NULL); Expression* init = Expression::make_cast(this->type(), this->init_, loc); return init->get_backend(&context); } } // Get the initial value of a variable when a block is required. // VAR_DECL is the decl to set; it may be NULL for a sink variable. Bstatement* Variable::get_init_block(Gogo* gogo, Named_object* function, Bvariable* var_decl) { go_assert(this->preinit_ != NULL); // We want to add the variable assignment to the end of the preinit // block. Translate_context context(gogo, function, NULL, NULL); Bblock* bblock = this->preinit_->get_backend(&context); Bfunction* bfunction = function->func_value()->get_or_make_decl(gogo, function); // It's possible to have pre-init statements without an initializer // if the pre-init statements set the variable. Bstatement* decl_init = NULL; if (this->init_ != NULL) { if (var_decl == NULL) { Bexpression* init_bexpr = this->init_->get_backend(&context); decl_init = gogo->backend()->expression_statement(bfunction, init_bexpr); } else { Location loc = this->location(); Expression* val_expr = Expression::make_cast(this->type(), this->init_, loc); Bexpression* val = val_expr->get_backend(&context); Bexpression* var_ref = gogo->backend()->var_expression(var_decl, loc); decl_init = gogo->backend()->assignment_statement(bfunction, var_ref, val, loc); } } Bstatement* block_stmt = gogo->backend()->block_statement(bblock); if (decl_init != NULL) block_stmt = gogo->backend()->compound_statement(block_stmt, decl_init); return block_stmt; } // Export the variable void Variable::export_var(Export* exp, const Named_object* no) const { go_assert(this->is_global_); exp->write_c_string("var "); if (no->package() != NULL) { char buf[50]; snprintf(buf, sizeof buf, "<p%d>", exp->package_index(no->package())); exp->write_c_string(buf); } if (!Gogo::is_hidden_name(no->name())) exp->write_string(no->name()); else { exp->write_c_string("."); exp->write_string(Gogo::unpack_hidden_name(no->name())); } exp->write_c_string(" "); exp->write_type(this->type()); exp->write_c_string("\n"); } // Import a variable. bool Variable::import_var(Import* imp, std::string* pname, Package** ppkg, bool* pis_exported, Type** ptype) { imp->require_c_string("var "); if (!Import::read_qualified_identifier(imp, pname, ppkg, pis_exported)) { go_error_at(imp->location(), "import error at %d: bad variable name in export data", imp->pos()); return false; } imp->require_c_string(" "); *ptype = imp->read_type(); imp->require_semicolon_if_old_version(); imp->require_c_string("\n"); return true; } // Convert a variable to the backend representation. Bvariable* Variable::get_backend_variable(Gogo* gogo, Named_object* function, const Package* package, const std::string& name) { if (this->backend_ == NULL) { Backend* backend = gogo->backend(); Type* type = this->type_; if (type->is_error_type() || (type->is_undefined() && (!this->is_global_ || package == NULL))) this->backend_ = backend->error_variable(); else { bool is_parameter = this->is_parameter_; if (this->is_receiver_ && type->points_to() == NULL) is_parameter = false; if (this->is_in_heap()) { is_parameter = false; type = Type::make_pointer_type(type); } const std::string n = Gogo::unpack_hidden_name(name); Btype* btype = type->get_backend(gogo); Bvariable* bvar; if (Map_type::is_zero_value(this)) bvar = Map_type::backend_zero_value(gogo); else if (this->is_global_) { std::string var_name(package != NULL ? package->package_name() : gogo->package_name()); var_name.push_back('.'); var_name.append(n); std::string asm_name(gogo->global_var_asm_name(name, package)); bool is_hidden = Gogo::is_hidden_name(name); // Hack to export runtime.writeBarrier. FIXME. // This is because go:linkname doesn't work on variables. if (gogo->compiling_runtime() && var_name == "runtime.writeBarrier") is_hidden = false; // If an inline body refers to this variable, then it // needs to be visible in the symbol table. if (this->is_referenced_by_inline_) is_hidden = false; // If this variable is in a different package, then it // can't be treated as a hidden symbol. This case can // arise when an inlined function refers to a // package-scope unexported variable. if (package != NULL) is_hidden = false; bvar = backend->global_variable(var_name, asm_name, btype, package != NULL, is_hidden, this->in_unique_section_, this->location_); } else if (function == NULL) { go_assert(saw_errors()); bvar = backend->error_variable(); } else { Bfunction* bfunction = function->func_value()->get_decl(); bool is_address_taken = (this->is_non_escaping_address_taken_ && !this->is_in_heap()); if (this->is_closure()) bvar = backend->static_chain_variable(bfunction, n, btype, this->location_); else if (is_parameter) bvar = backend->parameter_variable(bfunction, n, btype, is_address_taken, this->location_); else { Bvariable* bvar_decl = NULL; if (this->toplevel_decl_ != NULL) { Translate_context context(gogo, NULL, NULL, NULL); bvar_decl = this->toplevel_decl_->temporary_statement() ->get_backend_variable(&context); } bvar = backend->local_variable(bfunction, n, btype, bvar_decl, is_address_taken, this->location_); } } this->backend_ = bvar; } } return this->backend_; } // Class Result_variable. // Convert a result variable to the backend representation. Bvariable* Result_variable::get_backend_variable(Gogo* gogo, Named_object* function, const std::string& name) { if (this->backend_ == NULL) { Backend* backend = gogo->backend(); Type* type = this->type_; if (type->is_error()) this->backend_ = backend->error_variable(); else { if (this->is_in_heap()) type = Type::make_pointer_type(type); Btype* btype = type->get_backend(gogo); Bfunction* bfunction = function->func_value()->get_decl(); std::string n = Gogo::unpack_hidden_name(name); bool is_address_taken = (this->is_non_escaping_address_taken_ && !this->is_in_heap()); this->backend_ = backend->local_variable(bfunction, n, btype, NULL, is_address_taken, this->location_); } } return this->backend_; } // Class Named_constant. // Set the type of a named constant. This is only used to set the // type to an error type. void Named_constant::set_type(Type* t) { go_assert(this->type_ == NULL || t->is_error_type()); this->type_ = t; } // Traverse the initializer expression. int Named_constant::traverse_expression(Traverse* traverse) { return Expression::traverse(&this->expr_, traverse); } // Determine the type of the constant. void Named_constant::determine_type() { if (this->type_ != NULL) { Type_context context(this->type_, false); this->expr_->determine_type(&context); } else { // A constant may have an abstract type. Type_context context(NULL, true); this->expr_->determine_type(&context); this->type_ = this->expr_->type(); go_assert(this->type_ != NULL); } } // Indicate that we found and reported an error for this constant. void Named_constant::set_error() { this->type_ = Type::make_error_type(); this->expr_ = Expression::make_error(this->location_); } // Export a constant. void Named_constant::export_const(Export* exp, const std::string& name) const { exp->write_c_string("const "); exp->write_string(name); exp->write_c_string(" "); if (!this->type_->is_abstract()) { exp->write_type(this->type_); exp->write_c_string(" "); } exp->write_c_string("= "); Export_function_body efb(exp, 0); if (!this->type_->is_abstract()) efb.set_type_context(this->type_); this->expr()->export_expression(&efb); exp->write_string(efb.body()); exp->write_c_string("\n"); } // Import a constant. void Named_constant::import_const(Import* imp, std::string* pname, Type** ptype, Expression** pexpr) { imp->require_c_string("const "); *pname = imp->read_identifier(); imp->require_c_string(" "); if (imp->peek_char() == '=') *ptype = NULL; else { *ptype = imp->read_type(); imp->require_c_string(" "); } imp->require_c_string("= "); *pexpr = Expression::import_expression(imp, imp->location()); imp->require_semicolon_if_old_version(); imp->require_c_string("\n"); } // Get the backend representation. Bexpression* Named_constant::get_backend(Gogo* gogo, Named_object* const_no) { if (this->bconst_ == NULL) { Translate_context subcontext(gogo, NULL, NULL, NULL); Type* type = this->type(); Location loc = this->location(); Expression* const_ref = Expression::make_const_reference(const_no, loc); Bexpression* const_decl = const_ref->get_backend(&subcontext); if (type != NULL && type->is_numeric_type()) { Btype* btype = type->get_backend(gogo); std::string name = const_no->get_id(gogo); const_decl = gogo->backend()->named_constant_expression(btype, name, const_decl, loc); } this->bconst_ = const_decl; } return this->bconst_; } // Add a method. Named_object* Type_declaration::add_method(const std::string& name, Function* function) { Named_object* ret = Named_object::make_function(name, NULL, function); this->methods_.push_back(ret); return ret; } // Add a method declaration. Named_object* Type_declaration::add_method_declaration(const std::string& name, Package* package, Function_type* type, Location location) { Named_object* ret = Named_object::make_function_declaration(name, package, type, location); this->methods_.push_back(ret); return ret; } // Return whether any methods are defined. bool Type_declaration::has_methods() const { return !this->methods_.empty(); } // Define methods for the real type. void Type_declaration::define_methods(Named_type* nt) { if (this->methods_.empty()) return; while (nt->is_alias()) { Type *t = nt->real_type()->forwarded(); if (t->named_type() != NULL) nt = t->named_type(); else if (t->forward_declaration_type() != NULL) { Named_object* no = t->forward_declaration_type()->named_object(); Type_declaration* td = no->type_declaration_value(); td->methods_.insert(td->methods_.end(), this->methods_.begin(), this->methods_.end()); this->methods_.clear(); return; } else { for (std::vector<Named_object*>::const_iterator p = this->methods_.begin(); p != this->methods_.end(); ++p) go_error_at((*p)->location(), ("invalid receiver type " "(receiver must be a named type)")); return; } } for (std::vector<Named_object*>::const_iterator p = this->methods_.begin(); p != this->methods_.end(); ++p) { if ((*p)->is_function_declaration() || !(*p)->func_value()->is_sink()) nt->add_existing_method(*p); } } // We are using the type. Return true if we should issue a warning. bool Type_declaration::using_type() { bool ret = !this->issued_warning_; this->issued_warning_ = true; return ret; } // Class Unknown_name. // Set the real named object. void Unknown_name::set_real_named_object(Named_object* no) { go_assert(this->real_named_object_ == NULL); go_assert(!no->is_unknown()); this->real_named_object_ = no; } // Class Named_object. Named_object::Named_object(const std::string& name, const Package* package, Classification classification) : name_(name), package_(package), classification_(classification), is_redefinition_(false) { if (Gogo::is_sink_name(name)) go_assert(classification == NAMED_OBJECT_SINK); } // Make an unknown name. This is used by the parser. The name must // be resolved later. Unknown names are only added in the current // package. Named_object* Named_object::make_unknown_name(const std::string& name, Location location) { Named_object* named_object = new Named_object(name, NULL, NAMED_OBJECT_UNKNOWN); Unknown_name* value = new Unknown_name(location); named_object->u_.unknown_value = value; return named_object; } // Make a constant. Named_object* Named_object::make_constant(const Typed_identifier& tid, const Package* package, Expression* expr, int iota_value) { Named_object* named_object = new Named_object(tid.name(), package, NAMED_OBJECT_CONST); Named_constant* named_constant = new Named_constant(tid.type(), expr, iota_value, tid.location()); named_object->u_.const_value = named_constant; return named_object; } // Make a named type. Named_object* Named_object::make_type(const std::string& name, const Package* package, Type* type, Location location) { Named_object* named_object = new Named_object(name, package, NAMED_OBJECT_TYPE); Named_type* named_type = Type::make_named_type(named_object, type, location); named_object->u_.type_value = named_type; return named_object; } // Make a type declaration. Named_object* Named_object::make_type_declaration(const std::string& name, const Package* package, Location location) { Named_object* named_object = new Named_object(name, package, NAMED_OBJECT_TYPE_DECLARATION); Type_declaration* type_declaration = new Type_declaration(location); named_object->u_.type_declaration = type_declaration; return named_object; } // Make a variable. Named_object* Named_object::make_variable(const std::string& name, const Package* package, Variable* variable) { Named_object* named_object = new Named_object(name, package, NAMED_OBJECT_VAR); named_object->u_.var_value = variable; return named_object; } // Make a result variable. Named_object* Named_object::make_result_variable(const std::string& name, Result_variable* result) { Named_object* named_object = new Named_object(name, NULL, NAMED_OBJECT_RESULT_VAR); named_object->u_.result_var_value = result; return named_object; } // Make a sink. This is used for the special blank identifier _. Named_object* Named_object::make_sink() { return new Named_object("_", NULL, NAMED_OBJECT_SINK); } // Make a named function. Named_object* Named_object::make_function(const std::string& name, const Package* package, Function* function) { Named_object* named_object = new Named_object(name, package, NAMED_OBJECT_FUNC); named_object->u_.func_value = function; return named_object; } // Make a function declaration. Named_object* Named_object::make_function_declaration(const std::string& name, const Package* package, Function_type* fntype, Location location) { Named_object* named_object = new Named_object(name, package, NAMED_OBJECT_FUNC_DECLARATION); Function_declaration *func_decl = new Function_declaration(fntype, location); named_object->u_.func_declaration_value = func_decl; return named_object; } // Make a package. Named_object* Named_object::make_package(const std::string& alias, Package* package) { Named_object* named_object = new Named_object(alias, NULL, NAMED_OBJECT_PACKAGE); named_object->u_.package_value = package; return named_object; } // Return the name to use in an error message. std::string Named_object::message_name() const { if (this->package_ == NULL) return Gogo::message_name(this->name_); std::string ret; if (this->package_->has_package_name()) ret = this->package_->package_name(); else ret = this->package_->pkgpath(); ret = Gogo::message_name(ret); ret += '.'; ret += Gogo::message_name(this->name_); return ret; } // Set the type when a declaration is defined. void Named_object::set_type_value(Named_type* named_type) { go_assert(this->classification_ == NAMED_OBJECT_TYPE_DECLARATION); Type_declaration* td = this->u_.type_declaration; td->define_methods(named_type); unsigned int index; Named_object* in_function = td->in_function(&index); if (in_function != NULL) named_type->set_in_function(in_function, index); delete td; this->classification_ = NAMED_OBJECT_TYPE; this->u_.type_value = named_type; } // Define a function which was previously declared. void Named_object::set_function_value(Function* function) { go_assert(this->classification_ == NAMED_OBJECT_FUNC_DECLARATION); if (this->func_declaration_value()->has_descriptor()) { Expression* descriptor = this->func_declaration_value()->descriptor(NULL, NULL); function->set_descriptor(descriptor); } this->classification_ = NAMED_OBJECT_FUNC; // FIXME: We should free the old value. this->u_.func_value = function; } // Declare an unknown object as a type declaration. void Named_object::declare_as_type() { go_assert(this->classification_ == NAMED_OBJECT_UNKNOWN); Unknown_name* unk = this->u_.unknown_value; this->classification_ = NAMED_OBJECT_TYPE_DECLARATION; this->u_.type_declaration = new Type_declaration(unk->location()); delete unk; } // Return the location of a named object. Location Named_object::location() const { switch (this->classification_) { default: case NAMED_OBJECT_UNINITIALIZED: go_unreachable(); case NAMED_OBJECT_ERRONEOUS: return Linemap::unknown_location(); case NAMED_OBJECT_UNKNOWN: return this->unknown_value()->location(); case NAMED_OBJECT_CONST: return this->const_value()->location(); case NAMED_OBJECT_TYPE: return this->type_value()->location(); case NAMED_OBJECT_TYPE_DECLARATION: return this->type_declaration_value()->location(); case NAMED_OBJECT_VAR: return this->var_value()->location(); case NAMED_OBJECT_RESULT_VAR: return this->result_var_value()->location(); case NAMED_OBJECT_SINK: go_unreachable(); case NAMED_OBJECT_FUNC: return this->func_value()->location(); case NAMED_OBJECT_FUNC_DECLARATION: return this->func_declaration_value()->location(); case NAMED_OBJECT_PACKAGE: return this->package_value()->location(); } } // Export a named object. void Named_object::export_named_object(Export* exp) const { switch (this->classification_) { default: case NAMED_OBJECT_UNINITIALIZED: case NAMED_OBJECT_UNKNOWN: go_unreachable(); case NAMED_OBJECT_ERRONEOUS: break; case NAMED_OBJECT_CONST: this->const_value()->export_const(exp, this->name_); break; case NAMED_OBJECT_TYPE: // Types are handled by export::write_types. go_unreachable(); case NAMED_OBJECT_TYPE_DECLARATION: go_error_at(this->type_declaration_value()->location(), "attempt to export %<%s%> which was declared but not defined", this->message_name().c_str()); break; case NAMED_OBJECT_FUNC_DECLARATION: this->func_declaration_value()->export_func(exp, this); break; case NAMED_OBJECT_VAR: this->var_value()->export_var(exp, this); break; case NAMED_OBJECT_RESULT_VAR: case NAMED_OBJECT_SINK: go_unreachable(); case NAMED_OBJECT_FUNC: this->func_value()->export_func(exp, this); break; } } // Convert a variable to the backend representation. Bvariable* Named_object::get_backend_variable(Gogo* gogo, Named_object* function) { if (this->classification_ == NAMED_OBJECT_VAR) return this->var_value()->get_backend_variable(gogo, function, this->package_, this->name_); else if (this->classification_ == NAMED_OBJECT_RESULT_VAR) return this->result_var_value()->get_backend_variable(gogo, function, this->name_); else go_unreachable(); } // Return the external identifier for this object. std::string Named_object::get_id(Gogo* gogo) { go_assert(!this->is_variable() && !this->is_result_variable() && !this->is_type()); std::string decl_name; if (this->is_function_declaration() && !this->func_declaration_value()->asm_name().empty()) decl_name = this->func_declaration_value()->asm_name(); else { std::string package_name; if (this->package_ == NULL) package_name = gogo->package_name(); else package_name = this->package_->package_name(); // Note that this will be misleading if this is an unexported // method generated for an embedded imported type. In that case // the unexported method should have the package name of the // package from which it is imported, but we are going to give // it our package name. Fixing this would require knowing the // package name, but we only know the package path. It might be // better to use package paths here anyhow. This doesn't affect // the assembler code, because we always set that name in // Function::get_or_make_decl anyhow. FIXME. decl_name = package_name + '.' + Gogo::unpack_hidden_name(this->name_); Function_type* fntype; if (this->is_function()) fntype = this->func_value()->type(); else if (this->is_function_declaration()) fntype = this->func_declaration_value()->type(); else fntype = NULL; if (fntype != NULL && fntype->is_method()) { decl_name.push_back('.'); decl_name.append(fntype->receiver()->type()->mangled_name(gogo)); } } return decl_name; } void debug_go_named_object(Named_object* no) { if (no == NULL) { std::cerr << "<null>"; return; } std::cerr << "'" << no->name() << "': "; const char *tag; switch (no->classification()) { case Named_object::NAMED_OBJECT_UNINITIALIZED: tag = "uninitialized"; break; case Named_object::NAMED_OBJECT_ERRONEOUS: tag = "<error>"; break; case Named_object::NAMED_OBJECT_UNKNOWN: tag = "<unknown>"; break; case Named_object::NAMED_OBJECT_CONST: tag = "constant"; break; case Named_object::NAMED_OBJECT_TYPE: tag = "type"; break; case Named_object::NAMED_OBJECT_TYPE_DECLARATION: tag = "type_decl"; break; case Named_object::NAMED_OBJECT_VAR: tag = "var"; break; case Named_object::NAMED_OBJECT_RESULT_VAR: tag = "result_var"; break; case Named_object::NAMED_OBJECT_SINK: tag = "<sink>"; break; case Named_object::NAMED_OBJECT_FUNC: tag = "func"; break; case Named_object::NAMED_OBJECT_FUNC_DECLARATION: tag = "func_decl"; break; case Named_object::NAMED_OBJECT_PACKAGE: tag = "package"; break; default: tag = "<unknown named object classification>"; break; }; std::cerr << tag << "\n"; } // Get the backend representation for this named object. void Named_object::get_backend(Gogo* gogo, std::vector<Bexpression*>& const_decls, std::vector<Btype*>& type_decls, std::vector<Bfunction*>& func_decls) { // If this is a definition, avoid trying to get the backend // representation, as that can crash. if (this->is_redefinition_) { go_assert(saw_errors()); return; } switch (this->classification_) { case NAMED_OBJECT_CONST: if (!Gogo::is_erroneous_name(this->name_)) const_decls.push_back(this->u_.const_value->get_backend(gogo, this)); break; case NAMED_OBJECT_TYPE: { Named_type* named_type = this->u_.type_value; // No need to do anything for aliases-- whatever has to be done // can be done for the alias target. if (named_type->is_alias()) break; if (!Gogo::is_erroneous_name(this->name_)) type_decls.push_back(named_type->get_backend(gogo)); // We need to produce a type descriptor for every named // type, and for a pointer to every named type, since // other files or packages might refer to them. We need // to do this even for hidden types, because they might // still be returned by some function. Simply calling the // type_descriptor method is enough to create the type // descriptor, even though we don't do anything with it. if (this->package_ == NULL && !saw_errors()) { named_type-> type_descriptor_pointer(gogo, Linemap::predeclared_location()); named_type->gc_symbol_pointer(gogo); Type* pn = Type::make_pointer_type(named_type); pn->type_descriptor_pointer(gogo, Linemap::predeclared_location()); pn->gc_symbol_pointer(gogo); } } break; case NAMED_OBJECT_TYPE_DECLARATION: go_error_at(Linemap::unknown_location(), "reference to undefined type %qs", this->message_name().c_str()); return; case NAMED_OBJECT_VAR: case NAMED_OBJECT_RESULT_VAR: case NAMED_OBJECT_SINK: go_unreachable(); case NAMED_OBJECT_FUNC: { Function* func = this->u_.func_value; if (!Gogo::is_erroneous_name(this->name_)) func_decls.push_back(func->get_or_make_decl(gogo, this)); if (func->block() != NULL) func->build(gogo, this); } break; case NAMED_OBJECT_ERRONEOUS: break; default: go_unreachable(); } } // Class Bindings. Bindings::Bindings(Bindings* enclosing) : enclosing_(enclosing), named_objects_(), bindings_() { } // Clear imports. void Bindings::clear_file_scope(Gogo* gogo) { Contour::iterator p = this->bindings_.begin(); while (p != this->bindings_.end()) { bool keep; if (p->second->package() != NULL) keep = false; else if (p->second->is_package()) keep = false; else if (p->second->is_function() && !p->second->func_value()->type()->is_method() && Gogo::unpack_hidden_name(p->second->name()) == "init") keep = false; else keep = true; if (keep) ++p; else { gogo->add_file_block_name(p->second->name(), p->second->location()); p = this->bindings_.erase(p); } } } // Look up a symbol. Named_object* Bindings::lookup(const std::string& name) const { Contour::const_iterator p = this->bindings_.find(name); if (p != this->bindings_.end()) return p->second->resolve(); else if (this->enclosing_ != NULL) return this->enclosing_->lookup(name); else return NULL; } // Look up a symbol locally. Named_object* Bindings::lookup_local(const std::string& name) const { Contour::const_iterator p = this->bindings_.find(name); if (p == this->bindings_.end()) return NULL; return p->second; } // Remove an object from a set of bindings. This is used for a // special case in thunks for functions which call recover. void Bindings::remove_binding(Named_object* no) { Contour::iterator pb = this->bindings_.find(no->name()); go_assert(pb != this->bindings_.end()); this->bindings_.erase(pb); for (std::vector<Named_object*>::iterator pn = this->named_objects_.begin(); pn != this->named_objects_.end(); ++pn) { if (*pn == no) { this->named_objects_.erase(pn); return; } } go_unreachable(); } // Add a method to the list of objects. This is not added to the // lookup table. This is so that we have a single list of objects // declared at the top level, which we walk through when it's time to // convert to trees. void Bindings::add_method(Named_object* method) { this->named_objects_.push_back(method); } // Add a generic Named_object to a Contour. Named_object* Bindings::add_named_object_to_contour(Contour* contour, Named_object* named_object) { go_assert(named_object == named_object->resolve()); const std::string& name(named_object->name()); go_assert(!Gogo::is_sink_name(name)); std::pair<Contour::iterator, bool> ins = contour->insert(std::make_pair(name, named_object)); if (!ins.second) { // The name was already there. if (named_object->package() != NULL && ins.first->second->package() == named_object->package() && (ins.first->second->classification() == named_object->classification())) { // This is a second import of the same object. return ins.first->second; } ins.first->second = this->new_definition(ins.first->second, named_object); return ins.first->second; } else { // Don't push declarations on the list. We push them on when // and if we find the definitions. That way we genericize the // functions in order. if (!named_object->is_type_declaration() && !named_object->is_function_declaration() && !named_object->is_unknown()) this->named_objects_.push_back(named_object); return named_object; } } // We had an existing named object OLD_OBJECT, and we've seen a new // one NEW_OBJECT with the same name. FIXME: This does not free the // new object when we don't need it. Named_object* Bindings::new_definition(Named_object* old_object, Named_object* new_object) { if (new_object->is_erroneous() && !old_object->is_erroneous()) return new_object; std::string reason; switch (old_object->classification()) { default: case Named_object::NAMED_OBJECT_UNINITIALIZED: go_unreachable(); case Named_object::NAMED_OBJECT_ERRONEOUS: return old_object; case Named_object::NAMED_OBJECT_UNKNOWN: { Named_object* real = old_object->unknown_value()->real_named_object(); if (real != NULL) return this->new_definition(real, new_object); go_assert(!new_object->is_unknown()); old_object->unknown_value()->set_real_named_object(new_object); if (!new_object->is_type_declaration() && !new_object->is_function_declaration()) this->named_objects_.push_back(new_object); return new_object; } case Named_object::NAMED_OBJECT_CONST: break; case Named_object::NAMED_OBJECT_TYPE: if (new_object->is_type_declaration()) return old_object; break; case Named_object::NAMED_OBJECT_TYPE_DECLARATION: if (new_object->is_type_declaration()) return old_object; if (new_object->is_type()) { old_object->set_type_value(new_object->type_value()); new_object->type_value()->set_named_object(old_object); this->named_objects_.push_back(old_object); return old_object; } break; case Named_object::NAMED_OBJECT_VAR: case Named_object::NAMED_OBJECT_RESULT_VAR: // We have already given an error in the parser for cases where // one parameter or result variable redeclares another one. if ((new_object->is_variable() && new_object->var_value()->is_parameter()) || new_object->is_result_variable()) return old_object; break; case Named_object::NAMED_OBJECT_SINK: go_unreachable(); case Named_object::NAMED_OBJECT_FUNC: break; case Named_object::NAMED_OBJECT_FUNC_DECLARATION: { // We declare the hash and equality functions before defining // them, because we sometimes see that we need the declaration // while we are in the middle of a different function. // // We declare the main function before the user defines it, to // give better error messages. // // We declare inline functions before we define them, as we // only define them if we need them. if (new_object->is_function() && ((Linemap::is_predeclared_location(old_object->location()) && Linemap::is_predeclared_location(new_object->location())) || (Gogo::unpack_hidden_name(old_object->name()) == "main" && Linemap::is_unknown_location(old_object->location())) || (new_object->package() != NULL && old_object->func_declaration_value()->has_imported_body() && new_object->func_value()->is_inline_only()))) { Function_type* old_type = old_object->func_declaration_value()->type(); Function_type* new_type = new_object->func_value()->type(); if (old_type->is_valid_redeclaration(new_type, &reason)) { Function_declaration* fd = old_object->func_declaration_value(); go_assert(fd->asm_name().empty()); old_object->set_function_value(new_object->func_value()); this->named_objects_.push_back(old_object); return old_object; } } } break; case Named_object::NAMED_OBJECT_PACKAGE: break; } std::string n = old_object->message_name(); if (reason.empty()) go_error_at(new_object->location(), "redefinition of %qs", n.c_str()); else go_error_at(new_object->location(), "redefinition of %qs: %s", n.c_str(), reason.c_str()); old_object->set_is_redefinition(); new_object->set_is_redefinition(); if (!Linemap::is_unknown_location(old_object->location()) && !Linemap::is_predeclared_location(old_object->location())) go_inform(old_object->location(), "previous definition of %qs was here", n.c_str()); return old_object; } // Add a named type. Named_object* Bindings::add_named_type(Named_type* named_type) { return this->add_named_object(named_type->named_object()); } // Add a function. Named_object* Bindings::add_function(const std::string& name, const Package* package, Function* function) { return this->add_named_object(Named_object::make_function(name, package, function)); } // Add a function declaration. Named_object* Bindings::add_function_declaration(const std::string& name, const Package* package, Function_type* type, Location location) { Named_object* no = Named_object::make_function_declaration(name, package, type, location); return this->add_named_object(no); } // Define a type which was previously declared. void Bindings::define_type(Named_object* no, Named_type* type) { no->set_type_value(type); this->named_objects_.push_back(no); } // Mark all local variables as used. This is used for some types of // parse error. void Bindings::mark_locals_used() { for (std::vector<Named_object*>::iterator p = this->named_objects_.begin(); p != this->named_objects_.end(); ++p) if ((*p)->is_variable()) (*p)->var_value()->set_is_used(); } // Traverse bindings. int Bindings::traverse(Traverse* traverse, bool is_global) { unsigned int traverse_mask = traverse->traverse_mask(); // We don't use an iterator because we permit the traversal to add // new global objects. const unsigned int e_or_t = (Traverse::traverse_expressions | Traverse::traverse_types); const unsigned int e_or_t_or_s = (e_or_t | Traverse::traverse_statements); for (size_t i = 0; i < this->named_objects_.size(); ++i) { Named_object* p = this->named_objects_[i]; int t = TRAVERSE_CONTINUE; switch (p->classification()) { case Named_object::NAMED_OBJECT_CONST: if ((traverse_mask & Traverse::traverse_constants) != 0) t = traverse->constant(p, is_global); if (t == TRAVERSE_CONTINUE && (traverse_mask & e_or_t) != 0) { Type* tc = p->const_value()->type(); if (tc != NULL && Type::traverse(tc, traverse) == TRAVERSE_EXIT) return TRAVERSE_EXIT; t = p->const_value()->traverse_expression(traverse); } break; case Named_object::NAMED_OBJECT_VAR: case Named_object::NAMED_OBJECT_RESULT_VAR: if ((traverse_mask & Traverse::traverse_variables) != 0) t = traverse->variable(p); if (t == TRAVERSE_CONTINUE && (traverse_mask & e_or_t) != 0) { if (p->is_result_variable() || p->var_value()->has_type()) { Type* tv = (p->is_variable() ? p->var_value()->type() : p->result_var_value()->type()); if (tv != NULL && Type::traverse(tv, traverse) == TRAVERSE_EXIT) return TRAVERSE_EXIT; } } if (t == TRAVERSE_CONTINUE && (traverse_mask & e_or_t_or_s) != 0 && p->is_variable()) t = p->var_value()->traverse_expression(traverse, traverse_mask); break; case Named_object::NAMED_OBJECT_FUNC: if ((traverse_mask & Traverse::traverse_functions) != 0) t = traverse->function(p); if (t == TRAVERSE_CONTINUE && (traverse_mask & (Traverse::traverse_variables | Traverse::traverse_constants | Traverse::traverse_functions | Traverse::traverse_blocks | Traverse::traverse_statements | Traverse::traverse_expressions | Traverse::traverse_types)) != 0) t = p->func_value()->traverse(traverse); break; case Named_object::NAMED_OBJECT_PACKAGE: // These are traversed in Gogo::traverse. go_assert(is_global); break; case Named_object::NAMED_OBJECT_TYPE: if ((traverse_mask & e_or_t) != 0) t = Type::traverse(p->type_value(), traverse); break; case Named_object::NAMED_OBJECT_TYPE_DECLARATION: case Named_object::NAMED_OBJECT_FUNC_DECLARATION: case Named_object::NAMED_OBJECT_UNKNOWN: case Named_object::NAMED_OBJECT_ERRONEOUS: break; case Named_object::NAMED_OBJECT_SINK: default: go_unreachable(); } if (t == TRAVERSE_EXIT) return TRAVERSE_EXIT; } // If we need to traverse types, check the function declarations, // which have types. Also check any methods of a type declaration. if ((traverse_mask & e_or_t) != 0) { for (Bindings::const_declarations_iterator p = this->begin_declarations(); p != this->end_declarations(); ++p) { if (p->second->is_function_declaration()) { if (Type::traverse(p->second->func_declaration_value()->type(), traverse) == TRAVERSE_EXIT) return TRAVERSE_EXIT; } else if (p->second->is_type_declaration()) { const std::vector<Named_object*>* methods = p->second->type_declaration_value()->methods(); for (std::vector<Named_object*>::const_iterator pm = methods->begin(); pm != methods->end(); pm++) { Named_object* no = *pm; Type *t; if (no->is_function()) t = no->func_value()->type(); else if (no->is_function_declaration()) t = no->func_declaration_value()->type(); else continue; if (Type::traverse(t, traverse) == TRAVERSE_EXIT) return TRAVERSE_EXIT; } } } } // Traverse function declarations when needed. if ((traverse_mask & Traverse::traverse_func_declarations) != 0) { for (Bindings::const_declarations_iterator p = this->begin_declarations(); p != this->end_declarations(); ++p) { if (p->second->is_function_declaration()) { if (traverse->function_declaration(p->second) == TRAVERSE_EXIT) return TRAVERSE_EXIT; } } } return TRAVERSE_CONTINUE; } void Bindings::debug_dump() { std::set<Named_object*> defs; for (size_t i = 0; i < this->named_objects_.size(); ++i) defs.insert(this->named_objects_[i]); for (Contour::iterator p = this->bindings_.begin(); p != this->bindings_.end(); ++p) { const char* tag = " "; if (defs.find(p->second) != defs.end()) tag = "* "; std::cerr << tag; debug_go_named_object(p->second); } } void debug_go_bindings(Bindings* bindings) { if (bindings != NULL) bindings->debug_dump(); } // Class Label. // Clear any references to this label. void Label::clear_refs() { for (std::vector<Bindings_snapshot*>::iterator p = this->refs_.begin(); p != this->refs_.end(); ++p) delete *p; this->refs_.clear(); } // Get the backend representation for a label. Blabel* Label::get_backend_label(Translate_context* context) { if (this->blabel_ == NULL) { Function* function = context->function()->func_value(); Bfunction* bfunction = function->get_decl(); this->blabel_ = context->backend()->label(bfunction, this->name_, this->location_); } return this->blabel_; } // Return an expression for the address of this label. Bexpression* Label::get_addr(Translate_context* context, Location location) { Blabel* label = this->get_backend_label(context); return context->backend()->label_address(label, location); } // Return the dummy label that represents any instance of the blank label. Label* Label::create_dummy_label() { static Label* dummy_label; if (dummy_label == NULL) { dummy_label = new Label("_"); dummy_label->set_is_used(); } return dummy_label; } // Class Unnamed_label. // Get the backend representation for an unnamed label. Blabel* Unnamed_label::get_blabel(Translate_context* context) { if (this->blabel_ == NULL) { Function* function = context->function()->func_value(); Bfunction* bfunction = function->get_decl(); this->blabel_ = context->backend()->label(bfunction, "", this->location_); } return this->blabel_; } // Return a statement which defines this unnamed label. Bstatement* Unnamed_label::get_definition(Translate_context* context) { Blabel* blabel = this->get_blabel(context); return context->backend()->label_definition_statement(blabel); } // Return a goto statement to this unnamed label. Bstatement* Unnamed_label::get_goto(Translate_context* context, Location location) { Blabel* blabel = this->get_blabel(context); return context->backend()->goto_statement(blabel, location); } // Class Package. Package::Package(const std::string& pkgpath, const std::string& pkgpath_symbol, Location location) : pkgpath_(pkgpath), pkgpath_symbol_(pkgpath_symbol), package_name_(), bindings_(new Bindings(NULL)), location_(location) { go_assert(!pkgpath.empty()); } // Set the package name. void Package::set_package_name(const std::string& package_name, Location location) { go_assert(!package_name.empty()); if (this->package_name_.empty()) this->package_name_ = package_name; else if (this->package_name_ != package_name) go_error_at(location, ("saw two different packages with " "the same package path %s: %s, %s"), this->pkgpath_.c_str(), this->package_name_.c_str(), package_name.c_str()); } // Return the pkgpath symbol, which is a prefix for symbols defined in // this package. std::string Package::pkgpath_symbol() const { if (this->pkgpath_symbol_.empty()) return Gogo::pkgpath_for_symbol(this->pkgpath_); return this->pkgpath_symbol_; } // Set the package path symbol. void Package::set_pkgpath_symbol(const std::string& pkgpath_symbol) { go_assert(!pkgpath_symbol.empty()); if (this->pkgpath_symbol_.empty()) this->pkgpath_symbol_ = pkgpath_symbol; else go_assert(this->pkgpath_symbol_ == pkgpath_symbol); } // Note that symbol from this package was and qualified by ALIAS. void Package::note_usage(const std::string& alias) const { Aliases::const_iterator p = this->aliases_.find(alias); go_assert(p != this->aliases_.end()); p->second->note_usage(); } // Forget a given usage. If forgetting this usage means this package becomes // unused, report that error. void Package::forget_usage(Expression* usage) const { if (this->fake_uses_.empty()) return; std::set<Expression*>::iterator p = this->fake_uses_.find(usage); go_assert(p != this->fake_uses_.end()); this->fake_uses_.erase(p); if (this->fake_uses_.empty()) go_error_at(this->location(), "imported and not used: %s", Gogo::message_name(this->package_name()).c_str()); } // Clear the used field for the next file. If the only usages of this package // are possibly fake, keep the fake usages for lowering. void Package::clear_used() { std::string dot_alias = "." + this->package_name(); Aliases::const_iterator p = this->aliases_.find(dot_alias); if (p != this->aliases_.end() && p->second->used() > this->fake_uses_.size()) this->fake_uses_.clear(); this->aliases_.clear(); } Package_alias* Package::add_alias(const std::string& alias, Location location) { Aliases::const_iterator p = this->aliases_.find(alias); if (p == this->aliases_.end()) { std::pair<Aliases::iterator, bool> ret; ret = this->aliases_.insert(std::make_pair(alias, new Package_alias(location))); p = ret.first; } return p->second; } // Determine types of constants. Everything else in a package // (variables, function declarations) should already have a fixed // type. Constants may have abstract types. void Package::determine_types() { Bindings* bindings = this->bindings_; for (Bindings::const_definitions_iterator p = bindings->begin_definitions(); p != bindings->end_definitions(); ++p) { if ((*p)->is_const()) (*p)->const_value()->determine_type(); } } // Class Traverse. // Destructor. Traverse::~Traverse() { if (this->types_seen_ != NULL) delete this->types_seen_; if (this->expressions_seen_ != NULL) delete this->expressions_seen_; } // Record that we are looking at a type, and return true if we have // already seen it. bool Traverse::remember_type(const Type* type) { if (type->is_error_type()) return true; go_assert((this->traverse_mask() & traverse_types) != 0 || (this->traverse_mask() & traverse_expressions) != 0); // We mostly only have to remember named types. But it turns out // that an interface type can refer to itself without using a name // by relying on interface inheritance, as in // // type I interface { F() interface{I} } // // Similarly it is possible for array types to refer to themselves // without a name, e.g. // // var x [uintptr(unsafe.Sizeof(&x))]byte // if (type->classification() != Type::TYPE_NAMED && type->classification() != Type::TYPE_ARRAY && type->classification() != Type::TYPE_INTERFACE) return false; if (this->types_seen_ == NULL) this->types_seen_ = new Types_seen(); std::pair<Types_seen::iterator, bool> ins = this->types_seen_->insert(type); return !ins.second; } // Record that we are looking at an expression, and return true if we // have already seen it. NB: this routine used to assert if the traverse // mask did not include expressions/types -- this is no longer the case, // since it can be useful to remember specific expressions during // walks that only cover statements. bool Traverse::remember_expression(const Expression* expression) { if (this->expressions_seen_ == NULL) this->expressions_seen_ = new Expressions_seen(); std::pair<Expressions_seen::iterator, bool> ins = this->expressions_seen_->insert(expression); return !ins.second; } // The default versions of these functions should never be called: the // traversal mask indicates which functions may be called. int Traverse::variable(Named_object*) { go_unreachable(); } int Traverse::constant(Named_object*, bool) { go_unreachable(); } int Traverse::function(Named_object*) { go_unreachable(); } int Traverse::block(Block*) { go_unreachable(); } int Traverse::statement(Block*, size_t*, Statement*) { go_unreachable(); } int Traverse::expression(Expression**) { go_unreachable(); } int Traverse::type(Type*) { go_unreachable(); } int Traverse::function_declaration(Named_object*) { go_unreachable(); } // Class Statement_inserter. void Statement_inserter::insert(Statement* s) { if (this->statements_added_ != NULL) this->statements_added_->insert(s); if (this->block_ != NULL) { go_assert(this->pindex_ != NULL); this->block_->insert_statement_before(*this->pindex_, s); ++*this->pindex_; } else if (this->var_ != NULL) this->var_->add_preinit_statement(this->gogo_, s); else go_assert(saw_errors()); }