//===-- DWARFASTParserClang.cpp ---------------------------------*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #include #include "DWARFASTParserClang.h" #include "DWARFDebugInfo.h" #include "DWARFDeclContext.h" #include "DWARFDefines.h" #include "SymbolFileDWARF.h" #include "SymbolFileDWARFDwo.h" #include "SymbolFileDWARFDebugMap.h" #include "UniqueDWARFASTType.h" #include "Plugins/Language/ObjC/ObjCLanguage.h" #include "lldb/Core/Module.h" #include "lldb/Core/Value.h" #include "lldb/Host/Host.h" #include "lldb/Symbol/ClangASTImporter.h" #include "lldb/Symbol/ClangExternalASTSourceCommon.h" #include "lldb/Symbol/ClangUtil.h" #include "lldb/Symbol/CompileUnit.h" #include "lldb/Symbol/Function.h" #include "lldb/Symbol/ObjectFile.h" #include "lldb/Symbol/SymbolFile.h" #include "lldb/Symbol/TypeList.h" #include "lldb/Symbol/TypeMap.h" #include "lldb/Target/Language.h" #include "lldb/Utility/LLDBAssert.h" #include "lldb/Utility/Log.h" #include "lldb/Utility/StreamString.h" #include "clang/AST/CXXInheritance.h" #include "clang/AST/DeclCXX.h" #include "clang/AST/DeclObjC.h" #include "clang/AST/DeclTemplate.h" #include #include #include //#define ENABLE_DEBUG_PRINTF // COMMENT OUT THIS LINE PRIOR TO CHECKIN #ifdef ENABLE_DEBUG_PRINTF #include #define DEBUG_PRINTF(fmt, ...) printf(fmt, __VA_ARGS__) #else #define DEBUG_PRINTF(fmt, ...) #endif using namespace lldb; using namespace lldb_private; DWARFASTParserClang::DWARFASTParserClang(ClangASTContext &ast) : m_ast(ast), m_die_to_decl_ctx(), m_decl_ctx_to_die() {} DWARFASTParserClang::~DWARFASTParserClang() {} static AccessType DW_ACCESS_to_AccessType(uint32_t dwarf_accessibility) { switch (dwarf_accessibility) { case DW_ACCESS_public: return eAccessPublic; case DW_ACCESS_private: return eAccessPrivate; case DW_ACCESS_protected: return eAccessProtected; default: break; } return eAccessNone; } static bool DeclKindIsCXXClass(clang::Decl::Kind decl_kind) { switch (decl_kind) { case clang::Decl::CXXRecord: case clang::Decl::ClassTemplateSpecialization: return true; default: break; } return false; } struct BitfieldInfo { uint64_t bit_size; uint64_t bit_offset; BitfieldInfo() : bit_size(LLDB_INVALID_ADDRESS), bit_offset(LLDB_INVALID_ADDRESS) {} void Clear() { bit_size = LLDB_INVALID_ADDRESS; bit_offset = LLDB_INVALID_ADDRESS; } bool IsValid() const { return (bit_size != LLDB_INVALID_ADDRESS) && (bit_offset != LLDB_INVALID_ADDRESS); } bool NextBitfieldOffsetIsValid(const uint64_t next_bit_offset) const { if (IsValid()) { // This bitfield info is valid, so any subsequent bitfields must not // overlap and must be at a higher bit offset than any previous bitfield // + size. return (bit_size + bit_offset) <= next_bit_offset; } else { // If the this BitfieldInfo is not valid, then any offset isOK return true; } } }; ClangASTImporter &DWARFASTParserClang::GetClangASTImporter() { if (!m_clang_ast_importer_up) { m_clang_ast_importer_up.reset(new ClangASTImporter); } return *m_clang_ast_importer_up; } /// Detect a forward declaration that is nested in a DW_TAG_module. static bool IsClangModuleFwdDecl(const DWARFDIE &Die) { if (!Die.GetAttributeValueAsUnsigned(DW_AT_declaration, 0)) return false; auto Parent = Die.GetParent(); while (Parent.IsValid()) { if (Parent.Tag() == DW_TAG_module) return true; Parent = Parent.GetParent(); } return false; } static DWARFDIE GetContainingClangModuleDIE(const DWARFDIE &die) { if (die.IsValid()) { DWARFDIE top_module_die; // Now make sure this DIE is scoped in a DW_TAG_module tag and return true // if so for (DWARFDIE parent = die.GetParent(); parent.IsValid(); parent = parent.GetParent()) { const dw_tag_t tag = parent.Tag(); if (tag == DW_TAG_module) top_module_die = parent; else if (tag == DW_TAG_compile_unit || tag == DW_TAG_partial_unit) break; } return top_module_die; } return DWARFDIE(); } static lldb::ModuleSP GetContainingClangModule(const DWARFDIE &die) { if (die.IsValid()) { DWARFDIE clang_module_die = GetContainingClangModuleDIE(die); if (clang_module_die) { const char *module_name = clang_module_die.GetName(); if (module_name) return die.GetDWARF()->GetExternalModule( lldb_private::ConstString(module_name)); } } return lldb::ModuleSP(); } TypeSP DWARFASTParserClang::ParseTypeFromClangModule(const SymbolContext &sc, const DWARFDIE &die, Log *log) { ModuleSP clang_module_sp = GetContainingClangModule(die); if (!clang_module_sp) return TypeSP(); // If this type comes from a Clang module, recursively look in the // DWARF section of the .pcm file in the module cache. Clang // generates DWO skeleton units as breadcrumbs to find them. llvm::SmallVector decl_context; die.GetDeclContext(decl_context); TypeMap pcm_types; // The type in the Clang module must have the same language as the current CU. LanguageSet languages; languages.Insert(die.GetCU()->GetLanguageType()); llvm::DenseSet searched_symbol_files; clang_module_sp->GetSymbolFile()->FindTypes(decl_context, languages, searched_symbol_files, pcm_types); if (pcm_types.Empty()) { // Since this type is defined in one of the Clang modules imported // by this symbol file, search all of them. Instead of calling // sym_file->FindTypes(), which would return this again, go straight // to the imported modules. auto &sym_file = die.GetCU()->GetSymbolFileDWARF(); // Well-formed clang modules never form cycles; guard against corrupted // ones by inserting the current file. searched_symbol_files.insert(&sym_file); sym_file.ForEachExternalModule( *sc.comp_unit, searched_symbol_files, [&](Module &module) { module.GetSymbolFile()->FindTypes(decl_context, languages, searched_symbol_files, pcm_types); return pcm_types.GetSize(); }); } if (!pcm_types.GetSize()) return TypeSP(); // We found a real definition for this type in the Clang module, so lets use // it and cache the fact that we found a complete type for this die. TypeSP pcm_type_sp = pcm_types.GetTypeAtIndex(0); if (!pcm_type_sp) return TypeSP(); lldb_private::CompilerType pcm_type = pcm_type_sp->GetForwardCompilerType(); lldb_private::CompilerType type = GetClangASTImporter().CopyType(m_ast, pcm_type); if (!type) return TypeSP(); // Under normal operation pcm_type is a shallow forward declaration // that gets completed later. This is necessary to support cyclic // data structures. If, however, pcm_type is already complete (for // example, because it was loaded for a different target before), // the definition needs to be imported right away, too. // Type::ResolveClangType() effectively ignores the ResolveState // inside type_sp and only looks at IsDefined(), so it never calls // ClangASTImporter::ASTImporterDelegate::ImportDefinitionTo(), // which does extra work for Objective-C classes. This would result // in only the forward declaration to be visible. if (pcm_type.IsDefined()) GetClangASTImporter().RequireCompleteType(ClangUtil::GetQualType(type)); SymbolFileDWARF *dwarf = die.GetDWARF(); TypeSP type_sp(new Type( die.GetID(), dwarf, pcm_type_sp->GetName(), pcm_type_sp->GetByteSize(), nullptr, LLDB_INVALID_UID, Type::eEncodingInvalid, &pcm_type_sp->GetDeclaration(), type, Type::ResolveState::Forward)); dwarf->GetTypeList().Insert(type_sp); dwarf->GetDIEToType()[die.GetDIE()] = type_sp.get(); clang::TagDecl *tag_decl = ClangASTContext::GetAsTagDecl(type); if (tag_decl) LinkDeclContextToDIE(tag_decl, die); else { clang::DeclContext *defn_decl_ctx = GetCachedClangDeclContextForDIE(die); if (defn_decl_ctx) LinkDeclContextToDIE(defn_decl_ctx, die); } return type_sp; } static void CompleteExternalTagDeclType(ClangASTImporter &ast_importer, clang::DeclContext *decl_ctx, DWARFDIE die, const char *type_name_cstr) { auto *tag_decl_ctx = clang::dyn_cast(decl_ctx); if (!tag_decl_ctx) return; // If this type was not imported from an external AST, there's nothing to do. CompilerType type = ClangASTContext::GetTypeForDecl(tag_decl_ctx); if (!type || !ast_importer.CanImport(type)) return; auto qual_type = ClangUtil::GetQualType(type); if (!ast_importer.RequireCompleteType(qual_type)) { die.GetDWARF()->GetObjectFile()->GetModule()->ReportError( "Unable to complete the Decl context for DIE '%s' at offset " "0x%8.8x.\nPlease file a bug report.", type_name_cstr ? type_name_cstr : "", die.GetOffset()); // We need to make the type look complete otherwise, we might crash in // Clang when adding children. if (ClangASTContext::StartTagDeclarationDefinition(type)) ClangASTContext::CompleteTagDeclarationDefinition(type); } } ParsedDWARFTypeAttributes::ParsedDWARFTypeAttributes(const DWARFDIE &die) { DWARFAttributes attributes; size_t num_attributes = die.GetAttributes(attributes); for (size_t i = 0; i < num_attributes; ++i) { dw_attr_t attr = attributes.AttributeAtIndex(i); DWARFFormValue form_value; if (!attributes.ExtractFormValueAtIndex(i, form_value)) continue; switch (attr) { case DW_AT_abstract_origin: abstract_origin = form_value; break; case DW_AT_accessibility: accessibility = DW_ACCESS_to_AccessType(form_value.Unsigned()); break; case DW_AT_artificial: is_artificial = form_value.Boolean(); break; case DW_AT_bit_stride: bit_stride = form_value.Unsigned(); break; case DW_AT_byte_size: byte_size = form_value.Unsigned(); break; case DW_AT_byte_stride: byte_stride = form_value.Unsigned(); break; case DW_AT_calling_convention: calling_convention = form_value.Unsigned(); break; case DW_AT_containing_type: containing_type = form_value; break; case DW_AT_decl_file: decl.SetFile(die.GetCU()->GetFile(form_value.Unsigned())); break; case DW_AT_decl_line: decl.SetLine(form_value.Unsigned()); break; case DW_AT_decl_column: decl.SetColumn(form_value.Unsigned()); break; case DW_AT_declaration: is_forward_declaration = form_value.Boolean(); break; case DW_AT_encoding: encoding = form_value.Unsigned(); break; case DW_AT_enum_class: is_scoped_enum = form_value.Boolean(); break; case DW_AT_explicit: is_explicit = form_value.Boolean(); break; case DW_AT_external: if (form_value.Unsigned()) storage = clang::SC_Extern; break; case DW_AT_inline: is_inline = form_value.Boolean(); break; case DW_AT_linkage_name: case DW_AT_MIPS_linkage_name: mangled_name = form_value.AsCString(); break; case DW_AT_name: name.SetCString(form_value.AsCString()); break; case DW_AT_object_pointer: object_pointer = form_value.Reference(); break; case DW_AT_signature: signature = form_value; break; case DW_AT_specification: specification = form_value; break; case DW_AT_type: type = form_value; break; case DW_AT_virtuality: is_virtual = form_value.Boolean(); break; case DW_AT_APPLE_objc_complete_type: is_complete_objc_class = form_value.Signed(); break; case DW_AT_APPLE_runtime_class: class_language = (LanguageType)form_value.Signed(); break; case DW_AT_GNU_vector: is_vector = form_value.Boolean(); break; case DW_AT_export_symbols: exports_symbols = form_value.Boolean(); break; } } } static std::string GetUnitName(const DWARFDIE &die) { if (DWARFUnit *unit = die.GetCU()) return unit->GetAbsolutePath().GetPath(); return ""; } TypeSP DWARFASTParserClang::ParseTypeFromDWARF(const SymbolContext &sc, const DWARFDIE &die, bool *type_is_new_ptr) { if (type_is_new_ptr) *type_is_new_ptr = false; if (!die) return nullptr; Log *log(LogChannelDWARF::GetLogIfAny(DWARF_LOG_TYPE_COMPLETION | DWARF_LOG_LOOKUPS)); SymbolFileDWARF *dwarf = die.GetDWARF(); if (log) { DWARFDIE context_die; clang::DeclContext *context = GetClangDeclContextContainingDIE(die, &context_die); dwarf->GetObjectFile()->GetModule()->LogMessage( log, "DWARFASTParserClang::ParseTypeFromDWARF " "(die = 0x%8.8x, decl_ctx = %p (die 0x%8.8x)) %s name = '%s')", die.GetOffset(), static_cast(context), context_die.GetOffset(), die.GetTagAsCString(), die.GetName()); } Type *type_ptr = dwarf->GetDIEToType().lookup(die.GetDIE()); if (type_ptr == DIE_IS_BEING_PARSED) return nullptr; if (type_ptr) return type_ptr->shared_from_this(); // Set a bit that lets us know that we are currently parsing this dwarf->GetDIEToType()[die.GetDIE()] = DIE_IS_BEING_PARSED; ParsedDWARFTypeAttributes attrs(die); if (DWARFDIE signature_die = attrs.signature.Reference()) { if (TypeSP type_sp = ParseTypeFromDWARF(sc, signature_die, type_is_new_ptr)) { dwarf->GetDIEToType()[die.GetDIE()] = type_sp.get(); if (clang::DeclContext *decl_ctx = GetCachedClangDeclContextForDIE(signature_die)) LinkDeclContextToDIE(decl_ctx, die); return type_sp; } return nullptr; } if (type_is_new_ptr) *type_is_new_ptr = true; const dw_tag_t tag = die.Tag(); TypeSP type_sp; switch (tag) { case DW_TAG_typedef: case DW_TAG_base_type: case DW_TAG_pointer_type: case DW_TAG_reference_type: case DW_TAG_rvalue_reference_type: case DW_TAG_const_type: case DW_TAG_restrict_type: case DW_TAG_volatile_type: case DW_TAG_atomic_type: case DW_TAG_unspecified_type: { type_sp = ParseTypeModifier(sc, die, attrs); break; } case DW_TAG_structure_type: case DW_TAG_union_type: case DW_TAG_class_type: { type_sp = ParseStructureLikeDIE(sc, die, attrs); break; } case DW_TAG_enumeration_type: { type_sp = ParseEnum(sc, die, attrs); break; } case DW_TAG_inlined_subroutine: case DW_TAG_subprogram: case DW_TAG_subroutine_type: { type_sp = ParseSubroutine(die, attrs); break; } case DW_TAG_array_type: { type_sp = ParseArrayType(die, attrs); break; } case DW_TAG_ptr_to_member_type: { type_sp = ParsePointerToMemberType(die, attrs); break; } default: dwarf->GetObjectFile()->GetModule()->ReportError( "{0x%8.8x}: unhandled type tag 0x%4.4x (%s), please file a bug and " "attach the file at the start of this error message", die.GetOffset(), tag, DW_TAG_value_to_name(tag)); break; } // TODO: We should consider making the switch above exhaustive to simplify // control flow in ParseTypeFromDWARF. Then, we could simply replace this // return statement with a call to llvm_unreachable. return UpdateSymbolContextScopeForType(sc, die, type_sp); } lldb::TypeSP DWARFASTParserClang::ParseTypeModifier(const SymbolContext &sc, const DWARFDIE &die, ParsedDWARFTypeAttributes &attrs) { Log *log(LogChannelDWARF::GetLogIfAny(DWARF_LOG_TYPE_COMPLETION | DWARF_LOG_LOOKUPS)); SymbolFileDWARF *dwarf = die.GetDWARF(); const dw_tag_t tag = die.Tag(); LanguageType cu_language = die.GetLanguage(); Type::ResolveState resolve_state = Type::ResolveState::Unresolved; Type::EncodingDataType encoding_data_type = Type::eEncodingIsUID; TypeSP type_sp; CompilerType clang_type; if (tag == DW_TAG_typedef && attrs.type.IsValid()) { // Try to parse a typedef from the (DWARF embedded in the) Clang // module file first as modules can contain typedef'ed // structures that have no names like: // // typedef struct { int a; } Foo; // // In this case we will have a structure with no name and a // typedef named "Foo" that points to this unnamed // structure. The name in the typedef is the only identifier for // the struct, so always try to get typedefs from Clang modules // if possible. // // The type_sp returned will be empty if the typedef doesn't // exist in a module file, so it is cheap to call this function // just to check. // // If we don't do this we end up creating a TypeSP that says // this is a typedef to type 0x123 (the DW_AT_type value would // be 0x123 in the DW_TAG_typedef), and this is the unnamed // structure type. We will have a hard time tracking down an // unnammed structure type in the module debug info, so we make // sure we don't get into this situation by always resolving // typedefs from the module. const DWARFDIE encoding_die = attrs.type.Reference(); // First make sure that the die that this is typedef'ed to _is_ // just a declaration (DW_AT_declaration == 1), not a full // definition since template types can't be represented in // modules since only concrete instances of templates are ever // emitted and modules won't contain those if (encoding_die && encoding_die.GetAttributeValueAsUnsigned(DW_AT_declaration, 0) == 1) { type_sp = ParseTypeFromClangModule(sc, die, log); if (type_sp) return type_sp; } } DEBUG_PRINTF("0x%8.8" PRIx64 ": %s (\"%s\") type => 0x%8.8lx\n", die.GetID(), DW_TAG_value_to_name(tag), type_name_cstr, encoding_uid.Reference()); switch (tag) { default: break; case DW_TAG_unspecified_type: if (attrs.name == "nullptr_t" || attrs.name == "decltype(nullptr)") { resolve_state = Type::ResolveState::Full; clang_type = m_ast.GetBasicType(eBasicTypeNullPtr); break; } // Fall through to base type below in case we can handle the type // there... LLVM_FALLTHROUGH; case DW_TAG_base_type: resolve_state = Type::ResolveState::Full; clang_type = m_ast.GetBuiltinTypeForDWARFEncodingAndBitSize( attrs.name.GetCString(), attrs.encoding, attrs.byte_size.getValueOr(0) * 8); break; case DW_TAG_pointer_type: encoding_data_type = Type::eEncodingIsPointerUID; break; case DW_TAG_reference_type: encoding_data_type = Type::eEncodingIsLValueReferenceUID; break; case DW_TAG_rvalue_reference_type: encoding_data_type = Type::eEncodingIsRValueReferenceUID; break; case DW_TAG_typedef: encoding_data_type = Type::eEncodingIsTypedefUID; break; case DW_TAG_const_type: encoding_data_type = Type::eEncodingIsConstUID; break; case DW_TAG_restrict_type: encoding_data_type = Type::eEncodingIsRestrictUID; break; case DW_TAG_volatile_type: encoding_data_type = Type::eEncodingIsVolatileUID; break; case DW_TAG_atomic_type: encoding_data_type = Type::eEncodingIsAtomicUID; break; } if (!clang_type && (encoding_data_type == Type::eEncodingIsPointerUID || encoding_data_type == Type::eEncodingIsTypedefUID)) { if (tag == DW_TAG_pointer_type) { DWARFDIE target_die = die.GetReferencedDIE(DW_AT_type); if (target_die.GetAttributeValueAsUnsigned(DW_AT_APPLE_block, 0)) { // Blocks have a __FuncPtr inside them which is a pointer to a // function of the proper type. for (DWARFDIE child_die = target_die.GetFirstChild(); child_die.IsValid(); child_die = child_die.GetSibling()) { if (!strcmp(child_die.GetAttributeValueAsString(DW_AT_name, ""), "__FuncPtr")) { DWARFDIE function_pointer_type = child_die.GetReferencedDIE(DW_AT_type); if (function_pointer_type) { DWARFDIE function_type = function_pointer_type.GetReferencedDIE(DW_AT_type); bool function_type_is_new_pointer; TypeSP lldb_function_type_sp = ParseTypeFromDWARF( sc, function_type, &function_type_is_new_pointer); if (lldb_function_type_sp) { clang_type = m_ast.CreateBlockPointerType( lldb_function_type_sp->GetForwardCompilerType()); encoding_data_type = Type::eEncodingIsUID; attrs.type.Clear(); resolve_state = Type::ResolveState::Full; } } break; } } } } if (cu_language == eLanguageTypeObjC || cu_language == eLanguageTypeObjC_plus_plus) { if (attrs.name) { if (attrs.name == "id") { if (log) dwarf->GetObjectFile()->GetModule()->LogMessage( log, "SymbolFileDWARF::ParseType (die = 0x%8.8x) %s '%s' " "is Objective-C 'id' built-in type.", die.GetOffset(), die.GetTagAsCString(), die.GetName()); clang_type = m_ast.GetBasicType(eBasicTypeObjCID); encoding_data_type = Type::eEncodingIsUID; attrs.type.Clear(); resolve_state = Type::ResolveState::Full; } else if (attrs.name == "Class") { if (log) dwarf->GetObjectFile()->GetModule()->LogMessage( log, "SymbolFileDWARF::ParseType (die = 0x%8.8x) %s '%s' " "is Objective-C 'Class' built-in type.", die.GetOffset(), die.GetTagAsCString(), die.GetName()); clang_type = m_ast.GetBasicType(eBasicTypeObjCClass); encoding_data_type = Type::eEncodingIsUID; attrs.type.Clear(); resolve_state = Type::ResolveState::Full; } else if (attrs.name == "SEL") { if (log) dwarf->GetObjectFile()->GetModule()->LogMessage( log, "SymbolFileDWARF::ParseType (die = 0x%8.8x) %s '%s' " "is Objective-C 'selector' built-in type.", die.GetOffset(), die.GetTagAsCString(), die.GetName()); clang_type = m_ast.GetBasicType(eBasicTypeObjCSel); encoding_data_type = Type::eEncodingIsUID; attrs.type.Clear(); resolve_state = Type::ResolveState::Full; } } else if (encoding_data_type == Type::eEncodingIsPointerUID && attrs.type.IsValid()) { // Clang sometimes erroneously emits id as objc_object*. In that // case we fix up the type to "id". const DWARFDIE encoding_die = attrs.type.Reference(); if (encoding_die && encoding_die.Tag() == DW_TAG_structure_type) { llvm::StringRef struct_name = encoding_die.GetName(); if (struct_name == "objc_object") { if (log) dwarf->GetObjectFile()->GetModule()->LogMessage( log, "SymbolFileDWARF::ParseType (die = 0x%8.8x) %s " "'%s' is 'objc_object*', which we overrode to " "'id'.", die.GetOffset(), die.GetTagAsCString(), die.GetName()); clang_type = m_ast.GetBasicType(eBasicTypeObjCID); encoding_data_type = Type::eEncodingIsUID; attrs.type.Clear(); resolve_state = Type::ResolveState::Full; } } } } } type_sp = std::make_shared( die.GetID(), dwarf, attrs.name, attrs.byte_size, nullptr, dwarf->GetUID(attrs.type.Reference()), encoding_data_type, &attrs.decl, clang_type, resolve_state); dwarf->GetDIEToType()[die.GetDIE()] = type_sp.get(); return type_sp; } TypeSP DWARFASTParserClang::ParseEnum(const SymbolContext &sc, const DWARFDIE &die, ParsedDWARFTypeAttributes &attrs) { Log *log(LogChannelDWARF::GetLogIfAny(DWARF_LOG_TYPE_COMPLETION | DWARF_LOG_LOOKUPS)); SymbolFileDWARF *dwarf = die.GetDWARF(); const dw_tag_t tag = die.Tag(); TypeSP type_sp; if (attrs.is_forward_declaration) { type_sp = ParseTypeFromClangModule(sc, die, log); if (type_sp) return type_sp; DWARFDeclContext die_decl_ctx; die.GetDWARFDeclContext(die_decl_ctx); type_sp = dwarf->FindDefinitionTypeForDWARFDeclContext(die_decl_ctx); if (!type_sp) { SymbolFileDWARFDebugMap *debug_map_symfile = dwarf->GetDebugMapSymfile(); if (debug_map_symfile) { // We weren't able to find a full declaration in this DWARF, // see if we have a declaration anywhere else... type_sp = debug_map_symfile->FindDefinitionTypeForDWARFDeclContext( die_decl_ctx); } } if (type_sp) { if (log) { dwarf->GetObjectFile()->GetModule()->LogMessage( log, "SymbolFileDWARF(%p) - 0x%8.8x: %s type \"%s\" is a " "forward declaration, complete type is 0x%8.8" PRIx64, static_cast(this), die.GetOffset(), DW_TAG_value_to_name(tag), attrs.name.GetCString(), type_sp->GetID()); } // We found a real definition for this type elsewhere so lets use // it and cache the fact that we found a complete type for this // die dwarf->GetDIEToType()[die.GetDIE()] = type_sp.get(); clang::DeclContext *defn_decl_ctx = GetCachedClangDeclContextForDIE(dwarf->GetDIE(type_sp->GetID())); if (defn_decl_ctx) LinkDeclContextToDIE(defn_decl_ctx, die); return type_sp; } } DEBUG_PRINTF("0x%8.8" PRIx64 ": %s (\"%s\")\n", die.GetID(), DW_TAG_value_to_name(tag), type_name_cstr); CompilerType enumerator_clang_type; CompilerType clang_type; clang_type.SetCompilerType( &m_ast, dwarf->GetForwardDeclDieToClangType().lookup(die.GetDIE())); if (!clang_type) { if (attrs.type.IsValid()) { Type *enumerator_type = dwarf->ResolveTypeUID(attrs.type.Reference(), true); if (enumerator_type) enumerator_clang_type = enumerator_type->GetFullCompilerType(); } if (!enumerator_clang_type) { if (attrs.byte_size) { enumerator_clang_type = m_ast.GetBuiltinTypeForDWARFEncodingAndBitSize( NULL, DW_ATE_signed, *attrs.byte_size * 8); } else { enumerator_clang_type = m_ast.GetBasicType(eBasicTypeInt); } } clang_type = m_ast.CreateEnumerationType( attrs.name.GetCString(), GetClangDeclContextContainingDIE(die, nullptr), attrs.decl, enumerator_clang_type, attrs.is_scoped_enum); } else { enumerator_clang_type = m_ast.GetEnumerationIntegerType(clang_type.GetOpaqueQualType()); } LinkDeclContextToDIE(ClangASTContext::GetDeclContextForType(clang_type), die); type_sp = std::make_shared( die.GetID(), dwarf, attrs.name, attrs.byte_size, nullptr, dwarf->GetUID(attrs.type.Reference()), Type::eEncodingIsUID, &attrs.decl, clang_type, Type::ResolveState::Forward); if (ClangASTContext::StartTagDeclarationDefinition(clang_type)) { if (die.HasChildren()) { bool is_signed = false; enumerator_clang_type.IsIntegerType(is_signed); ParseChildEnumerators(clang_type, is_signed, type_sp->GetByteSize().getValueOr(0), die); } ClangASTContext::CompleteTagDeclarationDefinition(clang_type); } else { dwarf->GetObjectFile()->GetModule()->ReportError( "DWARF DIE at 0x%8.8x named \"%s\" was not able to start its " "definition.\nPlease file a bug and attach the file at the " "start of this error message", die.GetOffset(), attrs.name.GetCString()); } return type_sp; } TypeSP DWARFASTParserClang::ParseSubroutine(const DWARFDIE &die, ParsedDWARFTypeAttributes &attrs) { Log *log(LogChannelDWARF::GetLogIfAny(DWARF_LOG_TYPE_COMPLETION | DWARF_LOG_LOOKUPS)); SymbolFileDWARF *dwarf = die.GetDWARF(); const dw_tag_t tag = die.Tag(); bool is_variadic = false; bool is_static = false; bool has_template_params = false; unsigned type_quals = 0; std::string object_pointer_name; if (attrs.object_pointer) { const char *object_pointer_name_cstr = attrs.object_pointer.GetName(); if (object_pointer_name_cstr) object_pointer_name = object_pointer_name_cstr; } DEBUG_PRINTF("0x%8.8" PRIx64 ": %s (\"%s\")\n", die.GetID(), DW_TAG_value_to_name(tag), type_name_cstr); CompilerType return_clang_type; Type *func_type = NULL; if (attrs.type.IsValid()) func_type = dwarf->ResolveTypeUID(attrs.type.Reference(), true); if (func_type) return_clang_type = func_type->GetForwardCompilerType(); else return_clang_type = m_ast.GetBasicType(eBasicTypeVoid); std::vector function_param_types; std::vector function_param_decls; // Parse the function children for the parameters DWARFDIE decl_ctx_die; clang::DeclContext *containing_decl_ctx = GetClangDeclContextContainingDIE(die, &decl_ctx_die); const clang::Decl::Kind containing_decl_kind = containing_decl_ctx->getDeclKind(); bool is_cxx_method = DeclKindIsCXXClass(containing_decl_kind); // Start off static. This will be set to false in // ParseChildParameters(...) if we find a "this" parameters as the // first parameter if (is_cxx_method) { is_static = true; } if (die.HasChildren()) { bool skip_artificial = true; ParseChildParameters(containing_decl_ctx, die, skip_artificial, is_static, is_variadic, has_template_params, function_param_types, function_param_decls, type_quals); } bool ignore_containing_context = false; // Check for templatized class member functions. If we had any // DW_TAG_template_type_parameter or DW_TAG_template_value_parameter // the DW_TAG_subprogram DIE, then we can't let this become a method in // a class. Why? Because templatized functions are only emitted if one // of the templatized methods is used in the current compile unit and // we will end up with classes that may or may not include these member // functions and this means one class won't match another class // definition and it affects our ability to use a class in the clang // expression parser. So for the greater good, we currently must not // allow any template member functions in a class definition. if (is_cxx_method && has_template_params) { ignore_containing_context = true; is_cxx_method = false; } // clang_type will get the function prototype clang type after this // call CompilerType clang_type = m_ast.CreateFunctionType( return_clang_type, function_param_types.data(), function_param_types.size(), is_variadic, type_quals); if (attrs.name) { bool type_handled = false; if (tag == DW_TAG_subprogram || tag == DW_TAG_inlined_subroutine) { ObjCLanguage::MethodName objc_method(attrs.name.GetStringRef(), true); if (objc_method.IsValid(true)) { CompilerType class_opaque_type; ConstString class_name(objc_method.GetClassName()); if (class_name) { TypeSP complete_objc_class_type_sp( dwarf->FindCompleteObjCDefinitionTypeForDIE(DWARFDIE(), class_name, false)); if (complete_objc_class_type_sp) { CompilerType type_clang_forward_type = complete_objc_class_type_sp->GetForwardCompilerType(); if (ClangASTContext::IsObjCObjectOrInterfaceType( type_clang_forward_type)) class_opaque_type = type_clang_forward_type; } } if (class_opaque_type) { // If accessibility isn't set to anything valid, assume public // for now... if (attrs.accessibility == eAccessNone) attrs.accessibility = eAccessPublic; clang::ObjCMethodDecl *objc_method_decl = m_ast.AddMethodToObjCObjectType( class_opaque_type, attrs.name.GetCString(), clang_type, attrs.accessibility, attrs.is_artificial, is_variadic); type_handled = objc_method_decl != NULL; if (type_handled) { LinkDeclContextToDIE(objc_method_decl, die); m_ast.SetMetadataAsUserID(objc_method_decl, die.GetID()); } else { dwarf->GetObjectFile()->GetModule()->ReportError( "{0x%8.8x}: invalid Objective-C method 0x%4.4x (%s), " "please file a bug and attach the file at the start of " "this error message", die.GetOffset(), tag, DW_TAG_value_to_name(tag)); } } } else if (is_cxx_method) { // Look at the parent of this DIE and see if is is a class or // struct and see if this is actually a C++ method Type *class_type = dwarf->ResolveType(decl_ctx_die); if (class_type) { bool alternate_defn = false; if (class_type->GetID() != decl_ctx_die.GetID() || IsClangModuleFwdDecl(decl_ctx_die)) { alternate_defn = true; // We uniqued the parent class of this function to another // class so we now need to associate all dies under // "decl_ctx_die" to DIEs in the DIE for "class_type"... DWARFDIE class_type_die = dwarf->GetDIE(class_type->GetID()); if (class_type_die) { std::vector failures; CopyUniqueClassMethodTypes(decl_ctx_die, class_type_die, class_type, failures); // FIXME do something with these failures that's // smarter than just dropping them on the ground. // Unfortunately classes don't like having stuff added // to them after their definitions are complete... Type *type_ptr = dwarf->GetDIEToType()[die.GetDIE()]; if (type_ptr && type_ptr != DIE_IS_BEING_PARSED) { return type_ptr->shared_from_this(); } } } if (attrs.specification.IsValid()) { // We have a specification which we are going to base our // function prototype off of, so we need this type to be // completed so that the m_die_to_decl_ctx for the method in // the specification has a valid clang decl context. class_type->GetForwardCompilerType(); // If we have a specification, then the function type should // have been made with the specification and not with this // die. DWARFDIE spec_die = attrs.specification.Reference(); clang::DeclContext *spec_clang_decl_ctx = GetClangDeclContextForDIE(spec_die); if (spec_clang_decl_ctx) { LinkDeclContextToDIE(spec_clang_decl_ctx, die); } else { dwarf->GetObjectFile()->GetModule()->ReportWarning( "0x%8.8" PRIx64 ": DW_AT_specification(0x%8.8x" ") has no decl\n", die.GetID(), spec_die.GetOffset()); } type_handled = true; } else if (attrs.abstract_origin.IsValid()) { // We have a specification which we are going to base our // function prototype off of, so we need this type to be // completed so that the m_die_to_decl_ctx for the method in // the abstract origin has a valid clang decl context. class_type->GetForwardCompilerType(); DWARFDIE abs_die = attrs.abstract_origin.Reference(); clang::DeclContext *abs_clang_decl_ctx = GetClangDeclContextForDIE(abs_die); if (abs_clang_decl_ctx) { LinkDeclContextToDIE(abs_clang_decl_ctx, die); } else { dwarf->GetObjectFile()->GetModule()->ReportWarning( "0x%8.8" PRIx64 ": DW_AT_abstract_origin(0x%8.8x" ") has no decl\n", die.GetID(), abs_die.GetOffset()); } type_handled = true; } else { CompilerType class_opaque_type = class_type->GetForwardCompilerType(); if (ClangASTContext::IsCXXClassType(class_opaque_type)) { if (class_opaque_type.IsBeingDefined() || alternate_defn) { if (!is_static && !die.HasChildren()) { // We have a C++ member function with no children (this // pointer!) and clang will get mad if we try and make // a function that isn't well formed in the DWARF, so // we will just skip it... type_handled = true; } else { bool add_method = true; if (alternate_defn) { // If an alternate definition for the class exists, // then add the method only if an equivalent is not // already present. clang::CXXRecordDecl *record_decl = m_ast.GetAsCXXRecordDecl( class_opaque_type.GetOpaqueQualType()); if (record_decl) { for (auto method_iter = record_decl->method_begin(); method_iter != record_decl->method_end(); method_iter++) { clang::CXXMethodDecl *method_decl = *method_iter; if (method_decl->getNameInfo().getAsString() == attrs.name.GetStringRef()) { if (method_decl->getType() == ClangUtil::GetQualType(clang_type)) { add_method = false; LinkDeclContextToDIE(method_decl, die); type_handled = true; break; } } } } } if (add_method) { llvm::PrettyStackTraceFormat stack_trace( "SymbolFileDWARF::ParseType() is adding a method " "%s to class %s in DIE 0x%8.8" PRIx64 " from %s", attrs.name.GetCString(), class_type->GetName().GetCString(), die.GetID(), dwarf->GetObjectFile() ->GetFileSpec() .GetPath() .c_str()); const bool is_attr_used = false; // Neither GCC 4.2 nor clang++ currently set a valid // accessibility in the DWARF for C++ methods... // Default to public for now... if (attrs.accessibility == eAccessNone) attrs.accessibility = eAccessPublic; clang::CXXMethodDecl *cxx_method_decl = m_ast.AddMethodToCXXRecordType( class_opaque_type.GetOpaqueQualType(), attrs.name.GetCString(), attrs.mangled_name, clang_type, attrs.accessibility, attrs.is_virtual, is_static, attrs.is_inline, attrs.is_explicit, is_attr_used, attrs.is_artificial); type_handled = cxx_method_decl != NULL; // Artificial methods are always handled even when we // don't create a new declaration for them. type_handled |= attrs.is_artificial; if (cxx_method_decl) { LinkDeclContextToDIE(cxx_method_decl, die); ClangASTMetadata metadata; metadata.SetUserID(die.GetID()); if (!object_pointer_name.empty()) { metadata.SetObjectPtrName( object_pointer_name.c_str()); LLDB_LOGF(log, "Setting object pointer name: %s on method " "object %p.\n", object_pointer_name.c_str(), static_cast(cxx_method_decl)); } m_ast.SetMetadata(cxx_method_decl, metadata); } else { ignore_containing_context = true; } } } } else { // We were asked to parse the type for a method in a // class, yet the class hasn't been asked to complete // itself through the clang::ExternalASTSource protocol, // so we need to just have the class complete itself and // do things the right way, then our // DIE should then have an entry in the // dwarf->GetDIEToType() map. First // we need to modify the dwarf->GetDIEToType() so it // doesn't think we are trying to parse this DIE // anymore... dwarf->GetDIEToType()[die.GetDIE()] = NULL; // Now we get the full type to force our class type to // complete itself using the clang::ExternalASTSource // protocol which will parse all base classes and all // methods (including the method for this DIE). class_type->GetFullCompilerType(); // The type for this DIE should have been filled in the // function call above Type *type_ptr = dwarf->GetDIEToType()[die.GetDIE()]; if (type_ptr && type_ptr != DIE_IS_BEING_PARSED) { return type_ptr->shared_from_this(); } // FIXME This is fixing some even uglier behavior but we // really need to // uniq the methods of each class as well as the class // itself. type_handled = true; } } } } } } if (!type_handled) { clang::FunctionDecl *function_decl = nullptr; clang::FunctionDecl *template_function_decl = nullptr; if (attrs.abstract_origin.IsValid()) { DWARFDIE abs_die = attrs.abstract_origin.Reference(); if (dwarf->ResolveType(abs_die)) { function_decl = llvm::dyn_cast_or_null( GetCachedClangDeclContextForDIE(abs_die)); if (function_decl) { LinkDeclContextToDIE(function_decl, die); } } } if (!function_decl) { // We just have a function that isn't part of a class function_decl = m_ast.CreateFunctionDeclaration( ignore_containing_context ? m_ast.GetTranslationUnitDecl() : containing_decl_ctx, attrs.name.GetCString(), clang_type, attrs.storage, attrs.is_inline); if (has_template_params) { ClangASTContext::TemplateParameterInfos template_param_infos; ParseTemplateParameterInfos(die, template_param_infos); template_function_decl = m_ast.CreateFunctionDeclaration( ignore_containing_context ? m_ast.GetTranslationUnitDecl() : containing_decl_ctx, attrs.name.GetCString(), clang_type, attrs.storage, attrs.is_inline); clang::FunctionTemplateDecl *func_template_decl = m_ast.CreateFunctionTemplateDecl( containing_decl_ctx, template_function_decl, attrs.name.GetCString(), template_param_infos); m_ast.CreateFunctionTemplateSpecializationInfo( function_decl, func_template_decl, template_param_infos); } lldbassert(function_decl); if (function_decl) { LinkDeclContextToDIE(function_decl, die); if (!function_param_decls.empty()) { m_ast.SetFunctionParameters(function_decl, &function_param_decls.front(), function_param_decls.size()); if (template_function_decl) m_ast.SetFunctionParameters(template_function_decl, &function_param_decls.front(), function_param_decls.size()); } ClangASTMetadata metadata; metadata.SetUserID(die.GetID()); if (!object_pointer_name.empty()) { metadata.SetObjectPtrName(object_pointer_name.c_str()); LLDB_LOGF(log, "Setting object pointer name: %s on function " "object %p.", object_pointer_name.c_str(), static_cast(function_decl)); } m_ast.SetMetadata(function_decl, metadata); } } } } return std::make_shared( die.GetID(), dwarf, attrs.name, llvm::None, nullptr, LLDB_INVALID_UID, Type::eEncodingIsUID, &attrs.decl, clang_type, Type::ResolveState::Full); } TypeSP DWARFASTParserClang::ParseArrayType(const DWARFDIE &die, ParsedDWARFTypeAttributes &attrs) { SymbolFileDWARF *dwarf = die.GetDWARF(); DEBUG_PRINTF("0x%8.8" PRIx64 ": %s (\"%s\")\n", die.GetID(), DW_TAG_value_to_name(tag), type_name_cstr); DWARFDIE type_die = attrs.type.Reference(); Type *element_type = dwarf->ResolveTypeUID(type_die, true); if (!element_type) return nullptr; llvm::Optional array_info = ParseChildArrayInfo(die); if (array_info) { attrs.byte_stride = array_info->byte_stride; attrs.bit_stride = array_info->bit_stride; } if (attrs.byte_stride == 0 && attrs.bit_stride == 0) attrs.byte_stride = element_type->GetByteSize().getValueOr(0); CompilerType array_element_type = element_type->GetForwardCompilerType(); if (ClangASTContext::IsCXXClassType(array_element_type) && !array_element_type.GetCompleteType()) { ModuleSP module_sp = die.GetModule(); if (module_sp) { if (die.GetCU()->GetProducer() == eProducerClang) module_sp->ReportError( "DWARF DW_TAG_array_type DIE at 0x%8.8x has a " "class/union/struct element type DIE 0x%8.8x that is a " "forward declaration, not a complete definition.\nTry " "compiling the source file with -fstandalone-debug or " "disable -gmodules", die.GetOffset(), type_die.GetOffset()); else module_sp->ReportError( "DWARF DW_TAG_array_type DIE at 0x%8.8x has a " "class/union/struct element type DIE 0x%8.8x that is a " "forward declaration, not a complete definition.\nPlease " "file a bug against the compiler and include the " "preprocessed output for %s", die.GetOffset(), type_die.GetOffset(), GetUnitName(die).c_str()); } // We have no choice other than to pretend that the element class // type is complete. If we don't do this, clang will crash when // trying to layout the class. Since we provide layout // assistance, all ivars in this class and other classes will be // fine, this is the best we can do short of crashing. if (ClangASTContext::StartTagDeclarationDefinition(array_element_type)) { ClangASTContext::CompleteTagDeclarationDefinition(array_element_type); } else { module_sp->ReportError("DWARF DIE at 0x%8.8x was not able to " "start its definition.\nPlease file a " "bug and attach the file at the start " "of this error message", type_die.GetOffset()); } } uint64_t array_element_bit_stride = attrs.byte_stride * 8 + attrs.bit_stride; CompilerType clang_type; if (array_info && array_info->element_orders.size() > 0) { uint64_t num_elements = 0; auto end = array_info->element_orders.rend(); for (auto pos = array_info->element_orders.rbegin(); pos != end; ++pos) { num_elements = *pos; clang_type = m_ast.CreateArrayType(array_element_type, num_elements, attrs.is_vector); array_element_type = clang_type; array_element_bit_stride = num_elements ? array_element_bit_stride * num_elements : array_element_bit_stride; } } else { clang_type = m_ast.CreateArrayType(array_element_type, 0, attrs.is_vector); } ConstString empty_name; TypeSP type_sp = std::make_shared( die.GetID(), dwarf, empty_name, array_element_bit_stride / 8, nullptr, dwarf->GetUID(type_die), Type::eEncodingIsUID, &attrs.decl, clang_type, Type::ResolveState::Full); type_sp->SetEncodingType(element_type); const clang::Type *type = ClangUtil::GetQualType(clang_type).getTypePtr(); m_ast.SetMetadataAsUserID(type, die.GetID()); return type_sp; } TypeSP DWARFASTParserClang::ParsePointerToMemberType( const DWARFDIE &die, const ParsedDWARFTypeAttributes &attrs) { SymbolFileDWARF *dwarf = die.GetDWARF(); Type *pointee_type = dwarf->ResolveTypeUID(attrs.type.Reference(), true); Type *class_type = dwarf->ResolveTypeUID(attrs.containing_type.Reference(), true); CompilerType pointee_clang_type = pointee_type->GetForwardCompilerType(); CompilerType class_clang_type = class_type->GetLayoutCompilerType(); CompilerType clang_type = ClangASTContext::CreateMemberPointerType( class_clang_type, pointee_clang_type); if (llvm::Optional clang_type_size = clang_type.GetByteSize(nullptr)) { return std::make_shared(die.GetID(), dwarf, attrs.name, *clang_type_size, nullptr, LLDB_INVALID_UID, Type::eEncodingIsUID, nullptr, clang_type, Type::ResolveState::Forward); } return nullptr; } TypeSP DWARFASTParserClang::UpdateSymbolContextScopeForType( const SymbolContext &sc, const DWARFDIE &die, TypeSP type_sp) { if (!type_sp) return type_sp; SymbolFileDWARF *dwarf = die.GetDWARF(); TypeList &type_list = dwarf->GetTypeList(); DWARFDIE sc_parent_die = SymbolFileDWARF::GetParentSymbolContextDIE(die); dw_tag_t sc_parent_tag = sc_parent_die.Tag(); SymbolContextScope *symbol_context_scope = nullptr; if (sc_parent_tag == DW_TAG_compile_unit || sc_parent_tag == DW_TAG_partial_unit) { symbol_context_scope = sc.comp_unit; } else if (sc.function != nullptr && sc_parent_die) { symbol_context_scope = sc.function->GetBlock(true).FindBlockByID(sc_parent_die.GetID()); if (symbol_context_scope == nullptr) symbol_context_scope = sc.function; } else { symbol_context_scope = sc.module_sp.get(); } if (symbol_context_scope != nullptr) type_sp->SetSymbolContextScope(symbol_context_scope); // We are ready to put this type into the uniqued list up at the module // level. type_list.Insert(type_sp); dwarf->GetDIEToType()[die.GetDIE()] = type_sp.get(); return type_sp; } TypeSP DWARFASTParserClang::ParseStructureLikeDIE(const SymbolContext &sc, const DWARFDIE &die, ParsedDWARFTypeAttributes &attrs) { TypeSP type_sp; CompilerType clang_type; const dw_tag_t tag = die.Tag(); SymbolFileDWARF *dwarf = die.GetDWARF(); LanguageType cu_language = die.GetLanguage(); Log *log = LogChannelDWARF::GetLogIfAll(DWARF_LOG_TYPE_COMPLETION | DWARF_LOG_LOOKUPS); // UniqueDWARFASTType is large, so don't create a local variables on the // stack, put it on the heap. This function is often called recursively and // clang isn't good at sharing the stack space for variables in different // blocks. auto unique_ast_entry_up = std::make_unique(); ConstString unique_typename(attrs.name); Declaration unique_decl(attrs.decl); if (attrs.name) { if (Language::LanguageIsCPlusPlus(cu_language)) { // For C++, we rely solely upon the one definition rule that says // only one thing can exist at a given decl context. We ignore the // file and line that things are declared on. std::string qualified_name; if (die.GetQualifiedName(qualified_name)) unique_typename = ConstString(qualified_name); unique_decl.Clear(); } if (dwarf->GetUniqueDWARFASTTypeMap().Find( unique_typename, die, unique_decl, attrs.byte_size.getValueOr(-1), *unique_ast_entry_up)) { type_sp = unique_ast_entry_up->m_type_sp; if (type_sp) { dwarf->GetDIEToType()[die.GetDIE()] = type_sp.get(); LinkDeclContextToDIE( GetCachedClangDeclContextForDIE(unique_ast_entry_up->m_die), die); return type_sp; } } } DEBUG_PRINTF("0x%8.8" PRIx64 ": %s (\"%s\")\n", die.GetID(), DW_TAG_value_to_name(tag), type_name_cstr); int tag_decl_kind = -1; AccessType default_accessibility = eAccessNone; if (tag == DW_TAG_structure_type) { tag_decl_kind = clang::TTK_Struct; default_accessibility = eAccessPublic; } else if (tag == DW_TAG_union_type) { tag_decl_kind = clang::TTK_Union; default_accessibility = eAccessPublic; } else if (tag == DW_TAG_class_type) { tag_decl_kind = clang::TTK_Class; default_accessibility = eAccessPrivate; } if (attrs.byte_size && *attrs.byte_size == 0 && attrs.name && !die.HasChildren() && cu_language == eLanguageTypeObjC) { // Work around an issue with clang at the moment where forward // declarations for objective C classes are emitted as: // DW_TAG_structure_type [2] // DW_AT_name( "ForwardObjcClass" ) // DW_AT_byte_size( 0x00 ) // DW_AT_decl_file( "..." ) // DW_AT_decl_line( 1 ) // // Note that there is no DW_AT_declaration and there are no children, // and the byte size is zero. attrs.is_forward_declaration = true; } if (attrs.class_language == eLanguageTypeObjC || attrs.class_language == eLanguageTypeObjC_plus_plus) { if (!attrs.is_complete_objc_class && die.Supports_DW_AT_APPLE_objc_complete_type()) { // We have a valid eSymbolTypeObjCClass class symbol whose name // matches the current objective C class that we are trying to find // and this DIE isn't the complete definition (we checked // is_complete_objc_class above and know it is false), so the real // definition is in here somewhere type_sp = dwarf->FindCompleteObjCDefinitionTypeForDIE(die, attrs.name, true); if (!type_sp) { SymbolFileDWARFDebugMap *debug_map_symfile = dwarf->GetDebugMapSymfile(); if (debug_map_symfile) { // We weren't able to find a full declaration in this DWARF, // see if we have a declaration anywhere else... type_sp = debug_map_symfile->FindCompleteObjCDefinitionTypeForDIE( die, attrs.name, true); } } if (type_sp) { if (log) { dwarf->GetObjectFile()->GetModule()->LogMessage( log, "SymbolFileDWARF(%p) - 0x%8.8x: %s type \"%s\" is an " "incomplete objc type, complete type is 0x%8.8" PRIx64, static_cast(this), die.GetOffset(), DW_TAG_value_to_name(tag), attrs.name.GetCString(), type_sp->GetID()); } // We found a real definition for this type elsewhere so lets use // it and cache the fact that we found a complete type for this // die dwarf->GetDIEToType()[die.GetDIE()] = type_sp.get(); return type_sp; } } } if (attrs.is_forward_declaration) { // We have a forward declaration to a type and we need to try and // find a full declaration. We look in the current type index just in // case we have a forward declaration followed by an actual // declarations in the DWARF. If this fails, we need to look // elsewhere... if (log) { dwarf->GetObjectFile()->GetModule()->LogMessage( log, "SymbolFileDWARF(%p) - 0x%8.8x: %s type \"%s\" is a " "forward declaration, trying to find complete type", static_cast(this), die.GetOffset(), DW_TAG_value_to_name(tag), attrs.name.GetCString()); } // See if the type comes from a Clang module and if so, track down // that type. type_sp = ParseTypeFromClangModule(sc, die, log); if (type_sp) return type_sp; DWARFDeclContext die_decl_ctx; die.GetDWARFDeclContext(die_decl_ctx); // type_sp = FindDefinitionTypeForDIE (dwarf_cu, die, // type_name_const_str); type_sp = dwarf->FindDefinitionTypeForDWARFDeclContext(die_decl_ctx); if (!type_sp) { SymbolFileDWARFDebugMap *debug_map_symfile = dwarf->GetDebugMapSymfile(); if (debug_map_symfile) { // We weren't able to find a full declaration in this DWARF, see // if we have a declaration anywhere else... type_sp = debug_map_symfile->FindDefinitionTypeForDWARFDeclContext( die_decl_ctx); } } if (type_sp) { if (log) { dwarf->GetObjectFile()->GetModule()->LogMessage( log, "SymbolFileDWARF(%p) - 0x%8.8x: %s type \"%s\" is a " "forward declaration, complete type is 0x%8.8" PRIx64, static_cast(this), die.GetOffset(), DW_TAG_value_to_name(tag), attrs.name.GetCString(), type_sp->GetID()); } // We found a real definition for this type elsewhere so lets use // it and cache the fact that we found a complete type for this die dwarf->GetDIEToType()[die.GetDIE()] = type_sp.get(); clang::DeclContext *defn_decl_ctx = GetCachedClangDeclContextForDIE(dwarf->GetDIE(type_sp->GetID())); if (defn_decl_ctx) LinkDeclContextToDIE(defn_decl_ctx, die); return type_sp; } } assert(tag_decl_kind != -1); bool clang_type_was_created = false; clang_type.SetCompilerType( &m_ast, dwarf->GetForwardDeclDieToClangType().lookup(die.GetDIE())); if (!clang_type) { clang::DeclContext *decl_ctx = GetClangDeclContextContainingDIE(die, nullptr); // If your decl context is a record that was imported from another // AST context (in the gmodules case), we need to make sure the type // backing the Decl is complete before adding children to it. This is // not an issue in the non-gmodules case because the debug info will // always contain a full definition of parent types in that case. CompleteExternalTagDeclType(GetClangASTImporter(), decl_ctx, die, attrs.name.GetCString()); if (attrs.accessibility == eAccessNone && decl_ctx) { // Check the decl context that contains this class/struct/union. If // it is a class we must give it an accessibility. const clang::Decl::Kind containing_decl_kind = decl_ctx->getDeclKind(); if (DeclKindIsCXXClass(containing_decl_kind)) attrs.accessibility = default_accessibility; } ClangASTMetadata metadata; metadata.SetUserID(die.GetID()); metadata.SetIsDynamicCXXType(dwarf->ClassOrStructIsVirtual(die)); if (attrs.name.GetStringRef().contains('<')) { ClangASTContext::TemplateParameterInfos template_param_infos; if (ParseTemplateParameterInfos(die, template_param_infos)) { clang::ClassTemplateDecl *class_template_decl = m_ast.ParseClassTemplateDecl(decl_ctx, attrs.accessibility, attrs.name.GetCString(), tag_decl_kind, template_param_infos); if (!class_template_decl) { if (log) { dwarf->GetObjectFile()->GetModule()->LogMessage( log, "SymbolFileDWARF(%p) - 0x%8.8x: %s type \"%s\" " "clang::ClassTemplateDecl failed to return a decl.", static_cast(this), die.GetOffset(), DW_TAG_value_to_name(tag), attrs.name.GetCString()); } return TypeSP(); } clang::ClassTemplateSpecializationDecl *class_specialization_decl = m_ast.CreateClassTemplateSpecializationDecl( decl_ctx, class_template_decl, tag_decl_kind, template_param_infos); clang_type = m_ast.CreateClassTemplateSpecializationType( class_specialization_decl); clang_type_was_created = true; m_ast.SetMetadata(class_template_decl, metadata); m_ast.SetMetadata(class_specialization_decl, metadata); } } if (!clang_type_was_created) { clang_type_was_created = true; clang_type = m_ast.CreateRecordType( decl_ctx, attrs.accessibility, attrs.name.GetCString(), tag_decl_kind, attrs.class_language, &metadata, attrs.exports_symbols); } } // Store a forward declaration to this class type in case any // parameters in any class methods need it for the clang types for // function prototypes. LinkDeclContextToDIE(m_ast.GetDeclContextForType(clang_type), die); type_sp = std::make_shared(die.GetID(), dwarf, attrs.name, attrs.byte_size, nullptr, LLDB_INVALID_UID, Type::eEncodingIsUID, &attrs.decl, clang_type, Type::ResolveState::Forward); type_sp->SetIsCompleteObjCClass(attrs.is_complete_objc_class); // Add our type to the unique type map so we don't end up creating many // copies of the same type over and over in the ASTContext for our // module unique_ast_entry_up->m_type_sp = type_sp; unique_ast_entry_up->m_die = die; unique_ast_entry_up->m_declaration = unique_decl; unique_ast_entry_up->m_byte_size = attrs.byte_size.getValueOr(0); dwarf->GetUniqueDWARFASTTypeMap().Insert(unique_typename, *unique_ast_entry_up); if (attrs.is_forward_declaration && die.HasChildren()) { // Check to see if the DIE actually has a definition, some version of // GCC will // emit DIEs with DW_AT_declaration set to true, but yet still have // subprogram, members, or inheritance, so we can't trust it DWARFDIE child_die = die.GetFirstChild(); while (child_die) { switch (child_die.Tag()) { case DW_TAG_inheritance: case DW_TAG_subprogram: case DW_TAG_member: case DW_TAG_APPLE_property: case DW_TAG_class_type: case DW_TAG_structure_type: case DW_TAG_enumeration_type: case DW_TAG_typedef: case DW_TAG_union_type: child_die.Clear(); attrs.is_forward_declaration = false; break; default: child_die = child_die.GetSibling(); break; } } } if (!attrs.is_forward_declaration) { // Always start the definition for a class type so that if the class // has child classes or types that require the class to be created // for use as their decl contexts the class will be ready to accept // these child definitions. if (!die.HasChildren()) { // No children for this struct/union/class, lets finish it if (ClangASTContext::StartTagDeclarationDefinition(clang_type)) { ClangASTContext::CompleteTagDeclarationDefinition(clang_type); } else { dwarf->GetObjectFile()->GetModule()->ReportError( "DWARF DIE at 0x%8.8x named \"%s\" was not able to start its " "definition.\nPlease file a bug and attach the file at the " "start of this error message", die.GetOffset(), attrs.name.GetCString()); } if (tag == DW_TAG_structure_type) // this only applies in C { clang::RecordDecl *record_decl = ClangASTContext::GetAsRecordDecl(clang_type); if (record_decl) { GetClangASTImporter().InsertRecordDecl( record_decl, ClangASTImporter::LayoutInfo()); } } } else if (clang_type_was_created) { // Start the definition if the class is not objective C since the // underlying decls respond to isCompleteDefinition(). Objective // C decls don't respond to isCompleteDefinition() so we can't // start the declaration definition right away. For C++ // class/union/structs we want to start the definition in case the // class is needed as the declaration context for a contained class // or type without the need to complete that type.. if (attrs.class_language != eLanguageTypeObjC && attrs.class_language != eLanguageTypeObjC_plus_plus) ClangASTContext::StartTagDeclarationDefinition(clang_type); // Leave this as a forward declaration until we need to know the // details of the type. lldb_private::Type will automatically call // the SymbolFile virtual function // "SymbolFileDWARF::CompleteType(Type *)" When the definition // needs to be defined. assert(!dwarf->GetForwardDeclClangTypeToDie().count( ClangUtil::RemoveFastQualifiers(clang_type) .GetOpaqueQualType()) && "Type already in the forward declaration map!"); // Can't assume m_ast.GetSymbolFile() is actually a // SymbolFileDWARF, it can be a SymbolFileDWARFDebugMap for Apple // binaries. dwarf->GetForwardDeclDieToClangType()[die.GetDIE()] = clang_type.GetOpaqueQualType(); dwarf->GetForwardDeclClangTypeToDie() [ClangUtil::RemoveFastQualifiers(clang_type).GetOpaqueQualType()] = die.GetID(); m_ast.SetHasExternalStorage(clang_type.GetOpaqueQualType(), true); } } // If we made a clang type, set the trivial abi if applicable: We only // do this for pass by value - which implies the Trivial ABI. There // isn't a way to assert that something that would normally be pass by // value is pass by reference, so we ignore that attribute if set. if (attrs.calling_convention == llvm::dwarf::DW_CC_pass_by_value) { clang::CXXRecordDecl *record_decl = m_ast.GetAsCXXRecordDecl(clang_type.GetOpaqueQualType()); if (record_decl && record_decl->getDefinition()) { record_decl->setHasTrivialSpecialMemberForCall(); } } if (attrs.calling_convention == llvm::dwarf::DW_CC_pass_by_reference) { clang::CXXRecordDecl *record_decl = m_ast.GetAsCXXRecordDecl(clang_type.GetOpaqueQualType()); if (record_decl) record_decl->setArgPassingRestrictions( clang::RecordDecl::APK_CannotPassInRegs); } return type_sp; } // DWARF parsing functions class DWARFASTParserClang::DelayedAddObjCClassProperty { public: DelayedAddObjCClassProperty( const CompilerType &class_opaque_type, const char *property_name, const CompilerType &property_opaque_type, // The property type is only // required if you don't have an // ivar decl clang::ObjCIvarDecl *ivar_decl, const char *property_setter_name, const char *property_getter_name, uint32_t property_attributes, const ClangASTMetadata *metadata) : m_class_opaque_type(class_opaque_type), m_property_name(property_name), m_property_opaque_type(property_opaque_type), m_ivar_decl(ivar_decl), m_property_setter_name(property_setter_name), m_property_getter_name(property_getter_name), m_property_attributes(property_attributes) { if (metadata != nullptr) { m_metadata_up.reset(new ClangASTMetadata()); *m_metadata_up = *metadata; } } DelayedAddObjCClassProperty(const DelayedAddObjCClassProperty &rhs) { *this = rhs; } DelayedAddObjCClassProperty & operator=(const DelayedAddObjCClassProperty &rhs) { m_class_opaque_type = rhs.m_class_opaque_type; m_property_name = rhs.m_property_name; m_property_opaque_type = rhs.m_property_opaque_type; m_ivar_decl = rhs.m_ivar_decl; m_property_setter_name = rhs.m_property_setter_name; m_property_getter_name = rhs.m_property_getter_name; m_property_attributes = rhs.m_property_attributes; if (rhs.m_metadata_up) { m_metadata_up.reset(new ClangASTMetadata()); *m_metadata_up = *rhs.m_metadata_up; } return *this; } bool Finalize() { return ClangASTContext::AddObjCClassProperty( m_class_opaque_type, m_property_name, m_property_opaque_type, m_ivar_decl, m_property_setter_name, m_property_getter_name, m_property_attributes, m_metadata_up.get()); } private: CompilerType m_class_opaque_type; const char *m_property_name; CompilerType m_property_opaque_type; clang::ObjCIvarDecl *m_ivar_decl; const char *m_property_setter_name; const char *m_property_getter_name; uint32_t m_property_attributes; std::unique_ptr m_metadata_up; }; bool DWARFASTParserClang::ParseTemplateDIE( const DWARFDIE &die, ClangASTContext::TemplateParameterInfos &template_param_infos) { const dw_tag_t tag = die.Tag(); bool is_template_template_argument = false; switch (tag) { case DW_TAG_GNU_template_parameter_pack: { template_param_infos.packed_args.reset( new ClangASTContext::TemplateParameterInfos); for (DWARFDIE child_die = die.GetFirstChild(); child_die.IsValid(); child_die = child_die.GetSibling()) { if (!ParseTemplateDIE(child_die, *template_param_infos.packed_args)) return false; } if (const char *name = die.GetName()) { template_param_infos.pack_name = name; } return true; } case DW_TAG_GNU_template_template_param: is_template_template_argument = true; LLVM_FALLTHROUGH; case DW_TAG_template_type_parameter: case DW_TAG_template_value_parameter: { DWARFAttributes attributes; const size_t num_attributes = die.GetAttributes(attributes); const char *name = nullptr; const char *template_name = nullptr; CompilerType clang_type; uint64_t uval64 = 0; bool uval64_valid = false; if (num_attributes > 0) { DWARFFormValue form_value; for (size_t i = 0; i < num_attributes; ++i) { const dw_attr_t attr = attributes.AttributeAtIndex(i); switch (attr) { case DW_AT_name: if (attributes.ExtractFormValueAtIndex(i, form_value)) name = form_value.AsCString(); break; case DW_AT_GNU_template_name: if (attributes.ExtractFormValueAtIndex(i, form_value)) template_name = form_value.AsCString(); break; case DW_AT_type: if (attributes.ExtractFormValueAtIndex(i, form_value)) { Type *lldb_type = die.ResolveTypeUID(form_value.Reference()); if (lldb_type) clang_type = lldb_type->GetForwardCompilerType(); } break; case DW_AT_const_value: if (attributes.ExtractFormValueAtIndex(i, form_value)) { uval64_valid = true; uval64 = form_value.Unsigned(); } break; default: break; } } clang::ASTContext *ast = m_ast.getASTContext(); if (!clang_type) clang_type = m_ast.GetBasicType(eBasicTypeVoid); if (!is_template_template_argument) { bool is_signed = false; if (name && name[0]) template_param_infos.names.push_back(name); else template_param_infos.names.push_back(NULL); // Get the signed value for any integer or enumeration if available clang_type.IsIntegerOrEnumerationType(is_signed); if (tag == DW_TAG_template_value_parameter && uval64_valid) { llvm::Optional size = clang_type.GetBitSize(nullptr); if (!size) return false; llvm::APInt apint(*size, uval64, is_signed); template_param_infos.args.push_back( clang::TemplateArgument(*ast, llvm::APSInt(apint, !is_signed), ClangUtil::GetQualType(clang_type))); } else { template_param_infos.args.push_back( clang::TemplateArgument(ClangUtil::GetQualType(clang_type))); } } else { auto *tplt_type = m_ast.CreateTemplateTemplateParmDecl(template_name); template_param_infos.names.push_back(name); template_param_infos.args.push_back( clang::TemplateArgument(clang::TemplateName(tplt_type))); } } } return true; default: break; } return false; } bool DWARFASTParserClang::ParseTemplateParameterInfos( const DWARFDIE &parent_die, ClangASTContext::TemplateParameterInfos &template_param_infos) { if (!parent_die) return false; for (DWARFDIE die = parent_die.GetFirstChild(); die.IsValid(); die = die.GetSibling()) { const dw_tag_t tag = die.Tag(); switch (tag) { case DW_TAG_template_type_parameter: case DW_TAG_template_value_parameter: case DW_TAG_GNU_template_parameter_pack: case DW_TAG_GNU_template_template_param: ParseTemplateDIE(die, template_param_infos); break; default: break; } } if (template_param_infos.args.empty()) return false; return template_param_infos.args.size() == template_param_infos.names.size(); } bool DWARFASTParserClang::CompleteRecordType(const DWARFDIE &die, lldb_private::Type *type, CompilerType &clang_type) { const dw_tag_t tag = die.Tag(); SymbolFileDWARF *dwarf = die.GetDWARF(); ClangASTImporter::LayoutInfo layout_info; { if (die.HasChildren()) { LanguageType class_language = eLanguageTypeUnknown; if (ClangASTContext::IsObjCObjectOrInterfaceType(clang_type)) { class_language = eLanguageTypeObjC; // For objective C we don't start the definition when the class is // created. ClangASTContext::StartTagDeclarationDefinition(clang_type); } int tag_decl_kind = -1; AccessType default_accessibility = eAccessNone; if (tag == DW_TAG_structure_type) { tag_decl_kind = clang::TTK_Struct; default_accessibility = eAccessPublic; } else if (tag == DW_TAG_union_type) { tag_decl_kind = clang::TTK_Union; default_accessibility = eAccessPublic; } else if (tag == DW_TAG_class_type) { tag_decl_kind = clang::TTK_Class; default_accessibility = eAccessPrivate; } std::vector> bases; std::vector member_accessibilities; bool is_a_class = false; // Parse members and base classes first std::vector member_function_dies; DelayedPropertyList delayed_properties; ParseChildMembers(die, clang_type, class_language, bases, member_accessibilities, member_function_dies, delayed_properties, default_accessibility, is_a_class, layout_info); // Now parse any methods if there were any... for (const DWARFDIE &die : member_function_dies) dwarf->ResolveType(die); if (class_language == eLanguageTypeObjC) { ConstString class_name(clang_type.GetTypeName()); if (class_name) { DIEArray method_die_offsets; dwarf->GetObjCMethodDIEOffsets(class_name, method_die_offsets); if (!method_die_offsets.empty()) { DWARFDebugInfo *debug_info = dwarf->DebugInfo(); const size_t num_matches = method_die_offsets.size(); for (size_t i = 0; i < num_matches; ++i) { const DIERef &die_ref = method_die_offsets[i]; DWARFDIE method_die = debug_info->GetDIE(die_ref); if (method_die) method_die.ResolveType(); } } for (DelayedPropertyList::iterator pi = delayed_properties.begin(), pe = delayed_properties.end(); pi != pe; ++pi) pi->Finalize(); } } // If we have a DW_TAG_structure_type instead of a DW_TAG_class_type we // need to tell the clang type it is actually a class. if (class_language != eLanguageTypeObjC) { if (is_a_class && tag_decl_kind != clang::TTK_Class) m_ast.SetTagTypeKind(ClangUtil::GetQualType(clang_type), clang::TTK_Class); } // Since DW_TAG_structure_type gets used for both classes and // structures, we may need to set any DW_TAG_member fields to have a // "private" access if none was specified. When we parsed the child // members we tracked that actual accessibility value for each // DW_TAG_member in the "member_accessibilities" array. If the value // for the member is zero, then it was set to the // "default_accessibility" which for structs was "public". Below we // correct this by setting any fields to "private" that weren't // correctly set. if (is_a_class && !member_accessibilities.empty()) { // This is a class and all members that didn't have their access // specified are private. m_ast.SetDefaultAccessForRecordFields( m_ast.GetAsRecordDecl(clang_type), eAccessPrivate, &member_accessibilities.front(), member_accessibilities.size()); } if (!bases.empty()) { // Make sure all base classes refer to complete types and not forward // declarations. If we don't do this, clang will crash with an // assertion in the call to clang_type.TransferBaseClasses() for (const auto &base_class : bases) { clang::TypeSourceInfo *type_source_info = base_class->getTypeSourceInfo(); if (type_source_info) { CompilerType base_class_type( &m_ast, type_source_info->getType().getAsOpaquePtr()); if (!base_class_type.GetCompleteType()) { auto module = dwarf->GetObjectFile()->GetModule(); module->ReportError(":: Class '%s' has a base class '%s' which " "does not have a complete definition.", die.GetName(), base_class_type.GetTypeName().GetCString()); if (die.GetCU()->GetProducer() == eProducerClang) module->ReportError(":: Try compiling the source file with " "-fstandalone-debug."); // We have no choice other than to pretend that the base class // is complete. If we don't do this, clang will crash when we // call setBases() inside of // "clang_type.TransferBaseClasses()" below. Since we // provide layout assistance, all ivars in this class and other // classes will be fine, this is the best we can do short of // crashing. if (ClangASTContext::StartTagDeclarationDefinition( base_class_type)) { ClangASTContext::CompleteTagDeclarationDefinition( base_class_type); } } } } m_ast.TransferBaseClasses(clang_type.GetOpaqueQualType(), std::move(bases)); } } } m_ast.AddMethodOverridesForCXXRecordType(clang_type.GetOpaqueQualType()); ClangASTContext::BuildIndirectFields(clang_type); ClangASTContext::CompleteTagDeclarationDefinition(clang_type); if (!layout_info.field_offsets.empty() || !layout_info.base_offsets.empty() || !layout_info.vbase_offsets.empty()) { if (type) layout_info.bit_size = type->GetByteSize().getValueOr(0) * 8; if (layout_info.bit_size == 0) layout_info.bit_size = die.GetAttributeValueAsUnsigned(DW_AT_byte_size, 0) * 8; clang::CXXRecordDecl *record_decl = m_ast.GetAsCXXRecordDecl(clang_type.GetOpaqueQualType()); if (record_decl) GetClangASTImporter().InsertRecordDecl(record_decl, layout_info); } return (bool)clang_type; } bool DWARFASTParserClang::CompleteEnumType(const DWARFDIE &die, lldb_private::Type *type, CompilerType &clang_type) { if (ClangASTContext::StartTagDeclarationDefinition(clang_type)) { if (die.HasChildren()) { bool is_signed = false; clang_type.IsIntegerType(is_signed); ParseChildEnumerators(clang_type, is_signed, type->GetByteSize().getValueOr(0), die); } ClangASTContext::CompleteTagDeclarationDefinition(clang_type); } return (bool)clang_type; } bool DWARFASTParserClang::CompleteTypeFromDWARF(const DWARFDIE &die, lldb_private::Type *type, CompilerType &clang_type) { SymbolFileDWARF *dwarf = die.GetDWARF(); std::lock_guard guard( dwarf->GetObjectFile()->GetModule()->GetMutex()); // Disable external storage for this type so we don't get anymore // clang::ExternalASTSource queries for this type. m_ast.SetHasExternalStorage(clang_type.GetOpaqueQualType(), false); if (!die) return false; const dw_tag_t tag = die.Tag(); Log *log = nullptr; // (LogChannelDWARF::GetLogIfAny(DWARF_LOG_DEBUG_INFO|DWARF_LOG_TYPE_COMPLETION)); if (log) dwarf->GetObjectFile()->GetModule()->LogMessageVerboseBacktrace( log, "0x%8.8" PRIx64 ": %s '%s' resolving forward declaration...", die.GetID(), die.GetTagAsCString(), type->GetName().AsCString()); assert(clang_type); DWARFAttributes attributes; switch (tag) { case DW_TAG_structure_type: case DW_TAG_union_type: case DW_TAG_class_type: return CompleteRecordType(die, type, clang_type); case DW_TAG_enumeration_type: return CompleteEnumType(die, type, clang_type); default: assert(false && "not a forward clang type decl!"); break; } return false; } void DWARFASTParserClang::EnsureAllDIEsInDeclContextHaveBeenParsed( lldb_private::CompilerDeclContext decl_context) { auto opaque_decl_ctx = (clang::DeclContext *)decl_context.GetOpaqueDeclContext(); for (auto it = m_decl_ctx_to_die.find(opaque_decl_ctx); it != m_decl_ctx_to_die.end() && it->first == opaque_decl_ctx; it = m_decl_ctx_to_die.erase(it)) for (DWARFDIE decl = it->second.GetFirstChild(); decl; decl = decl.GetSibling()) GetClangDeclForDIE(decl); } CompilerDecl DWARFASTParserClang::GetDeclForUIDFromDWARF(const DWARFDIE &die) { clang::Decl *clang_decl = GetClangDeclForDIE(die); if (clang_decl != nullptr) return CompilerDecl(&m_ast, clang_decl); return CompilerDecl(); } CompilerDeclContext DWARFASTParserClang::GetDeclContextForUIDFromDWARF(const DWARFDIE &die) { clang::DeclContext *clang_decl_ctx = GetClangDeclContextForDIE(die); if (clang_decl_ctx) return CompilerDeclContext(&m_ast, clang_decl_ctx); return CompilerDeclContext(); } CompilerDeclContext DWARFASTParserClang::GetDeclContextContainingUIDFromDWARF(const DWARFDIE &die) { clang::DeclContext *clang_decl_ctx = GetClangDeclContextContainingDIE(die, nullptr); if (clang_decl_ctx) return CompilerDeclContext(&m_ast, clang_decl_ctx); return CompilerDeclContext(); } size_t DWARFASTParserClang::ParseChildEnumerators( lldb_private::CompilerType &clang_type, bool is_signed, uint32_t enumerator_byte_size, const DWARFDIE &parent_die) { if (!parent_die) return 0; size_t enumerators_added = 0; for (DWARFDIE die = parent_die.GetFirstChild(); die.IsValid(); die = die.GetSibling()) { const dw_tag_t tag = die.Tag(); if (tag == DW_TAG_enumerator) { DWARFAttributes attributes; const size_t num_child_attributes = die.GetAttributes(attributes); if (num_child_attributes > 0) { const char *name = nullptr; bool got_value = false; int64_t enum_value = 0; Declaration decl; uint32_t i; for (i = 0; i < num_child_attributes; ++i) { const dw_attr_t attr = attributes.AttributeAtIndex(i); DWARFFormValue form_value; if (attributes.ExtractFormValueAtIndex(i, form_value)) { switch (attr) { case DW_AT_const_value: got_value = true; if (is_signed) enum_value = form_value.Signed(); else enum_value = form_value.Unsigned(); break; case DW_AT_name: name = form_value.AsCString(); break; case DW_AT_description: default: case DW_AT_decl_file: decl.SetFile(die.GetCU()->GetFile(form_value.Unsigned())); break; case DW_AT_decl_line: decl.SetLine(form_value.Unsigned()); break; case DW_AT_decl_column: decl.SetColumn(form_value.Unsigned()); break; case DW_AT_sibling: break; } } } if (name && name[0] && got_value) { m_ast.AddEnumerationValueToEnumerationType( clang_type, decl, name, enum_value, enumerator_byte_size * 8); ++enumerators_added; } } } } return enumerators_added; } #if defined(LLDB_CONFIGURATION_DEBUG) || defined(LLDB_CONFIGURATION_RELEASE) class DIEStack { public: void Push(const DWARFDIE &die) { m_dies.push_back(die); } void LogDIEs(Log *log) { StreamString log_strm; const size_t n = m_dies.size(); log_strm.Printf("DIEStack[%" PRIu64 "]:\n", (uint64_t)n); for (size_t i = 0; i < n; i++) { std::string qualified_name; const DWARFDIE &die = m_dies[i]; die.GetQualifiedName(qualified_name); log_strm.Printf("[%" PRIu64 "] 0x%8.8x: %s name='%s'\n", (uint64_t)i, die.GetOffset(), die.GetTagAsCString(), qualified_name.c_str()); } log->PutCString(log_strm.GetData()); } void Pop() { m_dies.pop_back(); } class ScopedPopper { public: ScopedPopper(DIEStack &die_stack) : m_die_stack(die_stack), m_valid(false) {} void Push(const DWARFDIE &die) { m_valid = true; m_die_stack.Push(die); } ~ScopedPopper() { if (m_valid) m_die_stack.Pop(); } protected: DIEStack &m_die_stack; bool m_valid; }; protected: typedef std::vector Stack; Stack m_dies; }; #endif Function *DWARFASTParserClang::ParseFunctionFromDWARF(CompileUnit &comp_unit, const DWARFDIE &die) { DWARFRangeList func_ranges; const char *name = nullptr; const char *mangled = nullptr; int decl_file = 0; int decl_line = 0; int decl_column = 0; int call_file = 0; int call_line = 0; int call_column = 0; DWARFExpression frame_base; const dw_tag_t tag = die.Tag(); if (tag != DW_TAG_subprogram) return nullptr; if (die.GetDIENamesAndRanges(name, mangled, func_ranges, decl_file, decl_line, decl_column, call_file, call_line, call_column, &frame_base)) { // Union of all ranges in the function DIE (if the function is // discontiguous) AddressRange func_range; lldb::addr_t lowest_func_addr = func_ranges.GetMinRangeBase(0); lldb::addr_t highest_func_addr = func_ranges.GetMaxRangeEnd(0); if (lowest_func_addr != LLDB_INVALID_ADDRESS && lowest_func_addr <= highest_func_addr) { ModuleSP module_sp(die.GetModule()); func_range.GetBaseAddress().ResolveAddressUsingFileSections( lowest_func_addr, module_sp->GetSectionList()); if (func_range.GetBaseAddress().IsValid()) func_range.SetByteSize(highest_func_addr - lowest_func_addr); } if (func_range.GetBaseAddress().IsValid()) { Mangled func_name; if (mangled) func_name.SetValue(ConstString(mangled), true); else if ((die.GetParent().Tag() == DW_TAG_compile_unit || die.GetParent().Tag() == DW_TAG_partial_unit) && Language::LanguageIsCPlusPlus(die.GetLanguage()) && !Language::LanguageIsObjC(die.GetLanguage()) && name && strcmp(name, "main") != 0) { // If the mangled name is not present in the DWARF, generate the // demangled name using the decl context. We skip if the function is // "main" as its name is never mangled. bool is_static = false; bool is_variadic = false; bool has_template_params = false; unsigned type_quals = 0; std::vector param_types; std::vector param_decls; DWARFDeclContext decl_ctx; StreamString sstr; die.GetDWARFDeclContext(decl_ctx); sstr << decl_ctx.GetQualifiedName(); clang::DeclContext *containing_decl_ctx = GetClangDeclContextContainingDIE(die, nullptr); ParseChildParameters(containing_decl_ctx, die, true, is_static, is_variadic, has_template_params, param_types, param_decls, type_quals); sstr << "("; for (size_t i = 0; i < param_types.size(); i++) { if (i > 0) sstr << ", "; sstr << param_types[i].GetTypeName(); } if (is_variadic) sstr << ", ..."; sstr << ")"; if (type_quals & clang::Qualifiers::Const) sstr << " const"; func_name.SetValue(ConstString(sstr.GetString()), false); } else func_name.SetValue(ConstString(name), false); FunctionSP func_sp; std::unique_ptr decl_up; if (decl_file != 0 || decl_line != 0 || decl_column != 0) decl_up.reset(new Declaration(die.GetCU()->GetFile(decl_file), decl_line, decl_column)); SymbolFileDWARF *dwarf = die.GetDWARF(); // Supply the type _only_ if it has already been parsed Type *func_type = dwarf->GetDIEToType().lookup(die.GetDIE()); assert(func_type == nullptr || func_type != DIE_IS_BEING_PARSED); if (dwarf->FixupAddress(func_range.GetBaseAddress())) { const user_id_t func_user_id = die.GetID(); func_sp = std::make_shared(&comp_unit, func_user_id, // UserID is the DIE offset func_user_id, func_name, func_type, func_range); // first address range if (func_sp.get() != nullptr) { if (frame_base.IsValid()) func_sp->GetFrameBaseExpression() = frame_base; comp_unit.AddFunction(func_sp); return func_sp.get(); } } } } return nullptr; } void DWARFASTParserClang::ParseSingleMember( const DWARFDIE &die, const DWARFDIE &parent_die, lldb_private::CompilerType &class_clang_type, const lldb::LanguageType class_language, std::vector &member_accessibilities, lldb::AccessType &default_accessibility, DelayedPropertyList &delayed_properties, lldb_private::ClangASTImporter::LayoutInfo &layout_info, BitfieldInfo &last_field_info) { ModuleSP module_sp = parent_die.GetDWARF()->GetObjectFile()->GetModule(); const dw_tag_t tag = die.Tag(); // Get the parent byte size so we can verify any members will fit const uint64_t parent_byte_size = parent_die.GetAttributeValueAsUnsigned(DW_AT_byte_size, UINT64_MAX); const uint64_t parent_bit_size = parent_byte_size == UINT64_MAX ? UINT64_MAX : parent_byte_size * 8; DWARFAttributes attributes; const size_t num_attributes = die.GetAttributes(attributes); if (num_attributes > 0) { const char *name = nullptr; const char *prop_name = nullptr; const char *prop_getter_name = nullptr; const char *prop_setter_name = nullptr; uint32_t prop_attributes = 0; bool is_artificial = false; DWARFFormValue encoding_form; AccessType accessibility = eAccessNone; uint32_t member_byte_offset = (parent_die.Tag() == DW_TAG_union_type) ? 0 : UINT32_MAX; llvm::Optional byte_size; int64_t bit_offset = 0; uint64_t data_bit_offset = UINT64_MAX; size_t bit_size = 0; bool is_external = false; // On DW_TAG_members, this means the member is static uint32_t i; for (i = 0; i < num_attributes && !is_artificial; ++i) { const dw_attr_t attr = attributes.AttributeAtIndex(i); DWARFFormValue form_value; if (attributes.ExtractFormValueAtIndex(i, form_value)) { switch (attr) { case DW_AT_name: name = form_value.AsCString(); break; case DW_AT_type: encoding_form = form_value; break; case DW_AT_bit_offset: bit_offset = form_value.Signed(); break; case DW_AT_bit_size: bit_size = form_value.Unsigned(); break; case DW_AT_byte_size: byte_size = form_value.Unsigned(); break; case DW_AT_data_bit_offset: data_bit_offset = form_value.Unsigned(); break; case DW_AT_data_member_location: if (form_value.BlockData()) { Value initialValue(0); Value memberOffset(0); const DWARFDataExtractor &debug_info_data = die.GetData(); uint32_t block_length = form_value.Unsigned(); uint32_t block_offset = form_value.BlockData() - debug_info_data.GetDataStart(); if (DWARFExpression::Evaluate( nullptr, // ExecutionContext * nullptr, // RegisterContext * module_sp, DataExtractor(debug_info_data, block_offset, block_length), die.GetCU(), eRegisterKindDWARF, &initialValue, nullptr, memberOffset, nullptr)) { member_byte_offset = memberOffset.ResolveValue(nullptr).UInt(); } } else { // With DWARF 3 and later, if the value is an integer constant, // this form value is the offset in bytes from the beginning of // the containing entity. member_byte_offset = form_value.Unsigned(); } break; case DW_AT_accessibility: accessibility = DW_ACCESS_to_AccessType(form_value.Unsigned()); break; case DW_AT_artificial: is_artificial = form_value.Boolean(); break; case DW_AT_APPLE_property_name: prop_name = form_value.AsCString(); break; case DW_AT_APPLE_property_getter: prop_getter_name = form_value.AsCString(); break; case DW_AT_APPLE_property_setter: prop_setter_name = form_value.AsCString(); break; case DW_AT_APPLE_property_attribute: prop_attributes = form_value.Unsigned(); break; case DW_AT_external: is_external = form_value.Boolean(); break; default: case DW_AT_declaration: case DW_AT_description: case DW_AT_mutable: case DW_AT_visibility: case DW_AT_sibling: break; } } } if (prop_name) { ConstString fixed_getter; ConstString fixed_setter; // Check if the property getter/setter were provided as full names. // We want basenames, so we extract them. if (prop_getter_name && prop_getter_name[0] == '-') { ObjCLanguage::MethodName prop_getter_method(prop_getter_name, true); prop_getter_name = prop_getter_method.GetSelector().GetCString(); } if (prop_setter_name && prop_setter_name[0] == '-') { ObjCLanguage::MethodName prop_setter_method(prop_setter_name, true); prop_setter_name = prop_setter_method.GetSelector().GetCString(); } // If the names haven't been provided, they need to be filled in. if (!prop_getter_name) { prop_getter_name = prop_name; } if (!prop_setter_name && prop_name[0] && !(prop_attributes & DW_APPLE_PROPERTY_readonly)) { StreamString ss; ss.Printf("set%c%s:", toupper(prop_name[0]), &prop_name[1]); fixed_setter.SetString(ss.GetString()); prop_setter_name = fixed_setter.GetCString(); } } // Clang has a DWARF generation bug where sometimes it represents // fields that are references with bad byte size and bit size/offset // information such as: // // DW_AT_byte_size( 0x00 ) // DW_AT_bit_size( 0x40 ) // DW_AT_bit_offset( 0xffffffffffffffc0 ) // // So check the bit offset to make sure it is sane, and if the values // are not sane, remove them. If we don't do this then we will end up // with a crash if we try to use this type in an expression when clang // becomes unhappy with its recycled debug info. if (byte_size.getValueOr(0) == 0 && bit_offset < 0) { bit_size = 0; bit_offset = 0; } // FIXME: Make Clang ignore Objective-C accessibility for expressions if (class_language == eLanguageTypeObjC || class_language == eLanguageTypeObjC_plus_plus) accessibility = eAccessNone; // Handle static members if (is_external && member_byte_offset == UINT32_MAX) { Type *var_type = die.ResolveTypeUID(encoding_form.Reference()); if (var_type) { if (accessibility == eAccessNone) accessibility = eAccessPublic; ClangASTContext::AddVariableToRecordType( class_clang_type, name, var_type->GetLayoutCompilerType(), accessibility); } return; } if (!is_artificial) { Type *member_type = die.ResolveTypeUID(encoding_form.Reference()); clang::FieldDecl *field_decl = nullptr; if (tag == DW_TAG_member) { if (member_type) { if (accessibility == eAccessNone) accessibility = default_accessibility; member_accessibilities.push_back(accessibility); uint64_t field_bit_offset = (member_byte_offset == UINT32_MAX ? 0 : (member_byte_offset * 8)); if (bit_size > 0) { BitfieldInfo this_field_info; this_field_info.bit_offset = field_bit_offset; this_field_info.bit_size = bit_size; ///////////////////////////////////////////////////////////// // How to locate a field given the DWARF debug information // // AT_byte_size indicates the size of the word in which the bit // offset must be interpreted. // // AT_data_member_location indicates the byte offset of the // word from the base address of the structure. // // AT_bit_offset indicates how many bits into the word // (according to the host endianness) the low-order bit of the // field starts. AT_bit_offset can be negative. // // AT_bit_size indicates the size of the field in bits. ///////////////////////////////////////////////////////////// if (data_bit_offset != UINT64_MAX) { this_field_info.bit_offset = data_bit_offset; } else { if (!byte_size) byte_size = member_type->GetByteSize(); ObjectFile *objfile = die.GetDWARF()->GetObjectFile(); if (objfile->GetByteOrder() == eByteOrderLittle) { this_field_info.bit_offset += byte_size.getValueOr(0) * 8; this_field_info.bit_offset -= (bit_offset + bit_size); } else { this_field_info.bit_offset += bit_offset; } } if ((this_field_info.bit_offset >= parent_bit_size) || !last_field_info.NextBitfieldOffsetIsValid( this_field_info.bit_offset)) { ObjectFile *objfile = die.GetDWARF()->GetObjectFile(); objfile->GetModule()->ReportWarning( "0x%8.8" PRIx64 ": %s bitfield named \"%s\" has invalid " "bit offset (0x%8.8" PRIx64 ") member will be ignored. Please file a bug against the " "compiler and include the preprocessed output for %s\n", die.GetID(), DW_TAG_value_to_name(tag), name, this_field_info.bit_offset, GetUnitName(parent_die).c_str()); this_field_info.Clear(); return; } // Update the field bit offset we will report for layout field_bit_offset = this_field_info.bit_offset; // If the member to be emitted did not start on a character // boundary and there is empty space between the last field and // this one, then we need to emit an anonymous member filling // up the space up to its start. There are three cases here: // // 1 If the previous member ended on a character boundary, then // we can emit an // anonymous member starting at the most recent character // boundary. // // 2 If the previous member did not end on a character boundary // and the distance // from the end of the previous member to the current member // is less than a // word width, then we can emit an anonymous member starting // right after the // previous member and right before this member. // // 3 If the previous member did not end on a character boundary // and the distance // from the end of the previous member to the current member // is greater than // or equal a word width, then we act as in Case 1. const uint64_t character_width = 8; const uint64_t word_width = 32; // Objective-C has invalid DW_AT_bit_offset values in older // versions of clang, so we have to be careful and only insert // unnamed bitfields if we have a new enough clang. bool detect_unnamed_bitfields = true; if (class_language == eLanguageTypeObjC || class_language == eLanguageTypeObjC_plus_plus) detect_unnamed_bitfields = die.GetCU()->Supports_unnamed_objc_bitfields(); if (detect_unnamed_bitfields) { BitfieldInfo anon_field_info; if ((this_field_info.bit_offset % character_width) != 0) // not char aligned { uint64_t last_field_end = 0; if (last_field_info.IsValid()) last_field_end = last_field_info.bit_offset + last_field_info.bit_size; if (this_field_info.bit_offset != last_field_end) { if (((last_field_end % character_width) == 0) || // case 1 (this_field_info.bit_offset - last_field_end >= word_width)) // case 3 { anon_field_info.bit_size = this_field_info.bit_offset % character_width; anon_field_info.bit_offset = this_field_info.bit_offset - anon_field_info.bit_size; } else // case 2 { anon_field_info.bit_size = this_field_info.bit_offset - last_field_end; anon_field_info.bit_offset = last_field_end; } } } if (anon_field_info.IsValid()) { clang::FieldDecl *unnamed_bitfield_decl = ClangASTContext::AddFieldToRecordType( class_clang_type, llvm::StringRef(), m_ast.GetBuiltinTypeForEncodingAndBitSize(eEncodingSint, word_width), accessibility, anon_field_info.bit_size); layout_info.field_offsets.insert(std::make_pair( unnamed_bitfield_decl, anon_field_info.bit_offset)); } } last_field_info = this_field_info; } else { last_field_info.Clear(); } CompilerType member_clang_type = member_type->GetLayoutCompilerType(); if (!member_clang_type.IsCompleteType()) member_clang_type.GetCompleteType(); { // Older versions of clang emit array[0] and array[1] in the // same way (). If the current field // is at the end of the structure, then there is definitely no // room for extra elements and we override the type to // array[0]. CompilerType member_array_element_type; uint64_t member_array_size; bool member_array_is_incomplete; if (member_clang_type.IsArrayType(&member_array_element_type, &member_array_size, &member_array_is_incomplete) && !member_array_is_incomplete) { uint64_t parent_byte_size = parent_die.GetAttributeValueAsUnsigned(DW_AT_byte_size, UINT64_MAX); if (member_byte_offset >= parent_byte_size) { if (member_array_size != 1 && (member_array_size != 0 || member_byte_offset > parent_byte_size)) { module_sp->ReportError( "0x%8.8" PRIx64 ": DW_TAG_member '%s' refers to type 0x%8.8x" " which extends beyond the bounds of 0x%8.8" PRIx64, die.GetID(), name, encoding_form.Reference().GetOffset(), parent_die.GetID()); } member_clang_type = m_ast.CreateArrayType(member_array_element_type, 0, false); } } } if (ClangASTContext::IsCXXClassType(member_clang_type) && !member_clang_type.GetCompleteType()) { if (die.GetCU()->GetProducer() == eProducerClang) module_sp->ReportError( "DWARF DIE at 0x%8.8x (class %s) has a member variable " "0x%8.8x (%s) whose type is a forward declaration, not a " "complete definition.\nTry compiling the source file " "with -fstandalone-debug", parent_die.GetOffset(), parent_die.GetName(), die.GetOffset(), name); else module_sp->ReportError( "DWARF DIE at 0x%8.8x (class %s) has a member variable " "0x%8.8x (%s) whose type is a forward declaration, not a " "complete definition.\nPlease file a bug against the " "compiler and include the preprocessed output for %s", parent_die.GetOffset(), parent_die.GetName(), die.GetOffset(), name, GetUnitName(parent_die).c_str()); // We have no choice other than to pretend that the member // class is complete. If we don't do this, clang will crash // when trying to layout the class. Since we provide layout // assistance, all ivars in this class and other classes will // be fine, this is the best we can do short of crashing. if (ClangASTContext::StartTagDeclarationDefinition( member_clang_type)) { ClangASTContext::CompleteTagDeclarationDefinition( member_clang_type); } else { module_sp->ReportError( "DWARF DIE at 0x%8.8x (class %s) has a member variable " "0x%8.8x (%s) whose type claims to be a C++ class but we " "were not able to start its definition.\nPlease file a " "bug and attach the file at the start of this error " "message", parent_die.GetOffset(), parent_die.GetName(), die.GetOffset(), name); } } field_decl = ClangASTContext::AddFieldToRecordType( class_clang_type, name, member_clang_type, accessibility, bit_size); m_ast.SetMetadataAsUserID(field_decl, die.GetID()); layout_info.field_offsets.insert( std::make_pair(field_decl, field_bit_offset)); } else { if (name) module_sp->ReportError( "0x%8.8" PRIx64 ": DW_TAG_member '%s' refers to type 0x%8.8x" " which was unable to be parsed", die.GetID(), name, encoding_form.Reference().GetOffset()); else module_sp->ReportError( "0x%8.8" PRIx64 ": DW_TAG_member refers to type 0x%8.8x" " which was unable to be parsed", die.GetID(), encoding_form.Reference().GetOffset()); } } if (prop_name != nullptr && member_type) { clang::ObjCIvarDecl *ivar_decl = nullptr; if (field_decl) { ivar_decl = clang::dyn_cast(field_decl); assert(ivar_decl != nullptr); } ClangASTMetadata metadata; metadata.SetUserID(die.GetID()); delayed_properties.push_back(DelayedAddObjCClassProperty( class_clang_type, prop_name, member_type->GetLayoutCompilerType(), ivar_decl, prop_setter_name, prop_getter_name, prop_attributes, &metadata)); if (ivar_decl) m_ast.SetMetadataAsUserID(ivar_decl, die.GetID()); } } } } bool DWARFASTParserClang::ParseChildMembers( const DWARFDIE &parent_die, CompilerType &class_clang_type, const LanguageType class_language, std::vector> &base_classes, std::vector &member_accessibilities, std::vector &member_function_dies, DelayedPropertyList &delayed_properties, AccessType &default_accessibility, bool &is_a_class, ClangASTImporter::LayoutInfo &layout_info) { if (!parent_die) return false; BitfieldInfo last_field_info; ModuleSP module_sp = parent_die.GetDWARF()->GetObjectFile()->GetModule(); ClangASTContext *ast = llvm::dyn_cast_or_null(class_clang_type.GetTypeSystem()); if (ast == nullptr) return false; for (DWARFDIE die = parent_die.GetFirstChild(); die.IsValid(); die = die.GetSibling()) { dw_tag_t tag = die.Tag(); switch (tag) { case DW_TAG_member: case DW_TAG_APPLE_property: ParseSingleMember(die, parent_die, class_clang_type, class_language, member_accessibilities, default_accessibility, delayed_properties, layout_info, last_field_info); break; case DW_TAG_subprogram: // Let the type parsing code handle this one for us. member_function_dies.push_back(die); break; case DW_TAG_inheritance: { is_a_class = true; if (default_accessibility == eAccessNone) default_accessibility = eAccessPrivate; // TODO: implement DW_TAG_inheritance type parsing DWARFAttributes attributes; const size_t num_attributes = die.GetAttributes(attributes); if (num_attributes > 0) { DWARFFormValue encoding_form; AccessType accessibility = default_accessibility; bool is_virtual = false; bool is_base_of_class = true; off_t member_byte_offset = 0; uint32_t i; for (i = 0; i < num_attributes; ++i) { const dw_attr_t attr = attributes.AttributeAtIndex(i); DWARFFormValue form_value; if (attributes.ExtractFormValueAtIndex(i, form_value)) { switch (attr) { case DW_AT_type: encoding_form = form_value; break; case DW_AT_data_member_location: if (form_value.BlockData()) { Value initialValue(0); Value memberOffset(0); const DWARFDataExtractor &debug_info_data = die.GetData(); uint32_t block_length = form_value.Unsigned(); uint32_t block_offset = form_value.BlockData() - debug_info_data.GetDataStart(); if (DWARFExpression::Evaluate( nullptr, nullptr, module_sp, DataExtractor(debug_info_data, block_offset, block_length), die.GetCU(), eRegisterKindDWARF, &initialValue, nullptr, memberOffset, nullptr)) { member_byte_offset = memberOffset.ResolveValue(nullptr).UInt(); } } else { // With DWARF 3 and later, if the value is an integer constant, // this form value is the offset in bytes from the beginning of // the containing entity. member_byte_offset = form_value.Unsigned(); } break; case DW_AT_accessibility: accessibility = DW_ACCESS_to_AccessType(form_value.Unsigned()); break; case DW_AT_virtuality: is_virtual = form_value.Boolean(); break; case DW_AT_sibling: break; default: break; } } } Type *base_class_type = die.ResolveTypeUID(encoding_form.Reference()); if (base_class_type == nullptr) { module_sp->ReportError("0x%8.8x: DW_TAG_inheritance failed to " "resolve the base class at 0x%8.8x" " from enclosing type 0x%8.8x. \nPlease file " "a bug and attach the file at the start of " "this error message", die.GetOffset(), encoding_form.Reference().GetOffset(), parent_die.GetOffset()); break; } CompilerType base_class_clang_type = base_class_type->GetFullCompilerType(); assert(base_class_clang_type); if (class_language == eLanguageTypeObjC) { ast->SetObjCSuperClass(class_clang_type, base_class_clang_type); } else { std::unique_ptr result = ast->CreateBaseClassSpecifier( base_class_clang_type.GetOpaqueQualType(), accessibility, is_virtual, is_base_of_class); if (!result) break; base_classes.push_back(std::move(result)); if (is_virtual) { // Do not specify any offset for virtual inheritance. The DWARF // produced by clang doesn't give us a constant offset, but gives // us a DWARF expressions that requires an actual object in memory. // the DW_AT_data_member_location for a virtual base class looks // like: // DW_AT_data_member_location( DW_OP_dup, DW_OP_deref, // DW_OP_constu(0x00000018), DW_OP_minus, DW_OP_deref, // DW_OP_plus ) // Given this, there is really no valid response we can give to // clang for virtual base class offsets, and this should eventually // be removed from LayoutRecordType() in the external // AST source in clang. } else { layout_info.base_offsets.insert(std::make_pair( ast->GetAsCXXRecordDecl( base_class_clang_type.GetOpaqueQualType()), clang::CharUnits::fromQuantity(member_byte_offset))); } } } } break; default: break; } } return true; } size_t DWARFASTParserClang::ParseChildParameters( clang::DeclContext *containing_decl_ctx, const DWARFDIE &parent_die, bool skip_artificial, bool &is_static, bool &is_variadic, bool &has_template_params, std::vector &function_param_types, std::vector &function_param_decls, unsigned &type_quals) { if (!parent_die) return 0; size_t arg_idx = 0; for (DWARFDIE die = parent_die.GetFirstChild(); die.IsValid(); die = die.GetSibling()) { const dw_tag_t tag = die.Tag(); switch (tag) { case DW_TAG_formal_parameter: { DWARFAttributes attributes; const size_t num_attributes = die.GetAttributes(attributes); if (num_attributes > 0) { const char *name = nullptr; DWARFFormValue param_type_die_form; bool is_artificial = false; // one of None, Auto, Register, Extern, Static, PrivateExtern clang::StorageClass storage = clang::SC_None; uint32_t i; for (i = 0; i < num_attributes; ++i) { const dw_attr_t attr = attributes.AttributeAtIndex(i); DWARFFormValue form_value; if (attributes.ExtractFormValueAtIndex(i, form_value)) { switch (attr) { case DW_AT_name: name = form_value.AsCString(); break; case DW_AT_type: param_type_die_form = form_value; break; case DW_AT_artificial: is_artificial = form_value.Boolean(); break; case DW_AT_location: case DW_AT_const_value: case DW_AT_default_value: case DW_AT_description: case DW_AT_endianity: case DW_AT_is_optional: case DW_AT_segment: case DW_AT_variable_parameter: default: case DW_AT_abstract_origin: case DW_AT_sibling: break; } } } bool skip = false; if (skip_artificial && is_artificial) { // In order to determine if a C++ member function is "const" we // have to look at the const-ness of "this"... if (arg_idx == 0 && DeclKindIsCXXClass(containing_decl_ctx->getDeclKind()) && // Often times compilers omit the "this" name for the // specification DIEs, so we can't rely upon the name being in // the formal parameter DIE... (name == nullptr || ::strcmp(name, "this") == 0)) { Type *this_type = die.ResolveTypeUID(param_type_die_form.Reference()); if (this_type) { uint32_t encoding_mask = this_type->GetEncodingMask(); if (encoding_mask & Type::eEncodingIsPointerUID) { is_static = false; if (encoding_mask & (1u << Type::eEncodingIsConstUID)) type_quals |= clang::Qualifiers::Const; if (encoding_mask & (1u << Type::eEncodingIsVolatileUID)) type_quals |= clang::Qualifiers::Volatile; } } } skip = true; } if (!skip) { Type *type = die.ResolveTypeUID(param_type_die_form.Reference()); if (type) { function_param_types.push_back(type->GetForwardCompilerType()); clang::ParmVarDecl *param_var_decl = m_ast.CreateParameterDeclaration(containing_decl_ctx, name, type->GetForwardCompilerType(), storage); assert(param_var_decl); function_param_decls.push_back(param_var_decl); m_ast.SetMetadataAsUserID(param_var_decl, die.GetID()); } } } arg_idx++; } break; case DW_TAG_unspecified_parameters: is_variadic = true; break; case DW_TAG_template_type_parameter: case DW_TAG_template_value_parameter: case DW_TAG_GNU_template_parameter_pack: // The one caller of this was never using the template_param_infos, and // the local variable was taking up a large amount of stack space in // SymbolFileDWARF::ParseType() so this was removed. If we ever need the // template params back, we can add them back. // ParseTemplateDIE (dwarf_cu, die, template_param_infos); has_template_params = true; break; default: break; } } return arg_idx; } llvm::Optional DWARFASTParser::ParseChildArrayInfo(const DWARFDIE &parent_die, const ExecutionContext *exe_ctx) { SymbolFile::ArrayInfo array_info; if (!parent_die) return llvm::None; for (DWARFDIE die = parent_die.GetFirstChild(); die.IsValid(); die = die.GetSibling()) { const dw_tag_t tag = die.Tag(); switch (tag) { case DW_TAG_subrange_type: { DWARFAttributes attributes; const size_t num_child_attributes = die.GetAttributes(attributes); if (num_child_attributes > 0) { uint64_t num_elements = 0; uint64_t lower_bound = 0; uint64_t upper_bound = 0; bool upper_bound_valid = false; uint32_t i; for (i = 0; i < num_child_attributes; ++i) { const dw_attr_t attr = attributes.AttributeAtIndex(i); DWARFFormValue form_value; if (attributes.ExtractFormValueAtIndex(i, form_value)) { switch (attr) { case DW_AT_name: break; case DW_AT_count: if (DWARFDIE var_die = die.GetReferencedDIE(DW_AT_count)) { if (var_die.Tag() == DW_TAG_variable) if (exe_ctx) { if (auto frame = exe_ctx->GetFrameSP()) { Status error; lldb::VariableSP var_sp; auto valobj_sp = frame->GetValueForVariableExpressionPath( var_die.GetName(), eNoDynamicValues, 0, var_sp, error); if (valobj_sp) { num_elements = valobj_sp->GetValueAsUnsigned(0); break; } } } } else num_elements = form_value.Unsigned(); break; case DW_AT_bit_stride: array_info.bit_stride = form_value.Unsigned(); break; case DW_AT_byte_stride: array_info.byte_stride = form_value.Unsigned(); break; case DW_AT_lower_bound: lower_bound = form_value.Unsigned(); break; case DW_AT_upper_bound: upper_bound_valid = true; upper_bound = form_value.Unsigned(); break; default: case DW_AT_abstract_origin: case DW_AT_accessibility: case DW_AT_allocated: case DW_AT_associated: case DW_AT_data_location: case DW_AT_declaration: case DW_AT_description: case DW_AT_sibling: case DW_AT_threads_scaled: case DW_AT_type: case DW_AT_visibility: break; } } } if (num_elements == 0) { if (upper_bound_valid && upper_bound >= lower_bound) num_elements = upper_bound - lower_bound + 1; } array_info.element_orders.push_back(num_elements); } } break; default: break; } } return array_info; } Type *DWARFASTParserClang::GetTypeForDIE(const DWARFDIE &die) { if (die) { SymbolFileDWARF *dwarf = die.GetDWARF(); DWARFAttributes attributes; const size_t num_attributes = die.GetAttributes(attributes); if (num_attributes > 0) { DWARFFormValue type_die_form; for (size_t i = 0; i < num_attributes; ++i) { dw_attr_t attr = attributes.AttributeAtIndex(i); DWARFFormValue form_value; if (attr == DW_AT_type && attributes.ExtractFormValueAtIndex(i, form_value)) return dwarf->ResolveTypeUID(form_value.Reference(), true); } } } return nullptr; } clang::Decl *DWARFASTParserClang::GetClangDeclForDIE(const DWARFDIE &die) { if (!die) return nullptr; switch (die.Tag()) { case DW_TAG_variable: case DW_TAG_constant: case DW_TAG_formal_parameter: case DW_TAG_imported_declaration: case DW_TAG_imported_module: break; default: return nullptr; } DIEToDeclMap::iterator cache_pos = m_die_to_decl.find(die.GetDIE()); if (cache_pos != m_die_to_decl.end()) return cache_pos->second; if (DWARFDIE spec_die = die.GetReferencedDIE(DW_AT_specification)) { clang::Decl *decl = GetClangDeclForDIE(spec_die); m_die_to_decl[die.GetDIE()] = decl; m_decl_to_die[decl].insert(die.GetDIE()); return decl; } if (DWARFDIE abstract_origin_die = die.GetReferencedDIE(DW_AT_abstract_origin)) { clang::Decl *decl = GetClangDeclForDIE(abstract_origin_die); m_die_to_decl[die.GetDIE()] = decl; m_decl_to_die[decl].insert(die.GetDIE()); return decl; } clang::Decl *decl = nullptr; switch (die.Tag()) { case DW_TAG_variable: case DW_TAG_constant: case DW_TAG_formal_parameter: { SymbolFileDWARF *dwarf = die.GetDWARF(); Type *type = GetTypeForDIE(die); if (dwarf && type) { const char *name = die.GetName(); clang::DeclContext *decl_context = ClangASTContext::DeclContextGetAsDeclContext( dwarf->GetDeclContextContainingUID(die.GetID())); decl = m_ast.CreateVariableDeclaration( decl_context, name, ClangUtil::GetQualType(type->GetForwardCompilerType())); } break; } case DW_TAG_imported_declaration: { SymbolFileDWARF *dwarf = die.GetDWARF(); DWARFDIE imported_uid = die.GetAttributeValueAsReferenceDIE(DW_AT_import); if (imported_uid) { CompilerDecl imported_decl = imported_uid.GetDecl(); if (imported_decl) { clang::DeclContext *decl_context = ClangASTContext::DeclContextGetAsDeclContext( dwarf->GetDeclContextContainingUID(die.GetID())); if (clang::NamedDecl *clang_imported_decl = llvm::dyn_cast( (clang::Decl *)imported_decl.GetOpaqueDecl())) decl = m_ast.CreateUsingDeclaration(decl_context, clang_imported_decl); } } break; } case DW_TAG_imported_module: { SymbolFileDWARF *dwarf = die.GetDWARF(); DWARFDIE imported_uid = die.GetAttributeValueAsReferenceDIE(DW_AT_import); if (imported_uid) { CompilerDeclContext imported_decl_ctx = imported_uid.GetDeclContext(); if (imported_decl_ctx) { clang::DeclContext *decl_context = ClangASTContext::DeclContextGetAsDeclContext( dwarf->GetDeclContextContainingUID(die.GetID())); if (clang::NamespaceDecl *ns_decl = ClangASTContext::DeclContextGetAsNamespaceDecl( imported_decl_ctx)) decl = m_ast.CreateUsingDirectiveDeclaration(decl_context, ns_decl); } } break; } default: break; } m_die_to_decl[die.GetDIE()] = decl; m_decl_to_die[decl].insert(die.GetDIE()); return decl; } clang::DeclContext * DWARFASTParserClang::GetClangDeclContextForDIE(const DWARFDIE &die) { if (die) { clang::DeclContext *decl_ctx = GetCachedClangDeclContextForDIE(die); if (decl_ctx) return decl_ctx; bool try_parsing_type = true; switch (die.Tag()) { case DW_TAG_compile_unit: case DW_TAG_partial_unit: decl_ctx = m_ast.GetTranslationUnitDecl(); try_parsing_type = false; break; case DW_TAG_namespace: decl_ctx = ResolveNamespaceDIE(die); try_parsing_type = false; break; case DW_TAG_lexical_block: decl_ctx = GetDeclContextForBlock(die); try_parsing_type = false; break; default: break; } if (decl_ctx == nullptr && try_parsing_type) { Type *type = die.GetDWARF()->ResolveType(die); if (type) decl_ctx = GetCachedClangDeclContextForDIE(die); } if (decl_ctx) { LinkDeclContextToDIE(decl_ctx, die); return decl_ctx; } } return nullptr; } static bool IsSubroutine(const DWARFDIE &die) { switch (die.Tag()) { case DW_TAG_subprogram: case DW_TAG_inlined_subroutine: return true; default: return false; } } static DWARFDIE GetContainingFunctionWithAbstractOrigin(const DWARFDIE &die) { for (DWARFDIE candidate = die; candidate; candidate = candidate.GetParent()) { if (IsSubroutine(candidate)) { if (candidate.GetReferencedDIE(DW_AT_abstract_origin)) { return candidate; } else { return DWARFDIE(); } } } assert(0 && "Shouldn't call GetContainingFunctionWithAbstractOrigin on " "something not in a function"); return DWARFDIE(); } static DWARFDIE FindAnyChildWithAbstractOrigin(const DWARFDIE &context) { for (DWARFDIE candidate = context.GetFirstChild(); candidate.IsValid(); candidate = candidate.GetSibling()) { if (candidate.GetReferencedDIE(DW_AT_abstract_origin)) { return candidate; } } return DWARFDIE(); } static DWARFDIE FindFirstChildWithAbstractOrigin(const DWARFDIE &block, const DWARFDIE &function) { assert(IsSubroutine(function)); for (DWARFDIE context = block; context != function.GetParent(); context = context.GetParent()) { assert(!IsSubroutine(context) || context == function); if (DWARFDIE child = FindAnyChildWithAbstractOrigin(context)) { return child; } } return DWARFDIE(); } clang::DeclContext * DWARFASTParserClang::GetDeclContextForBlock(const DWARFDIE &die) { assert(die.Tag() == DW_TAG_lexical_block); DWARFDIE containing_function_with_abstract_origin = GetContainingFunctionWithAbstractOrigin(die); if (!containing_function_with_abstract_origin) { return (clang::DeclContext *)ResolveBlockDIE(die); } DWARFDIE child = FindFirstChildWithAbstractOrigin( die, containing_function_with_abstract_origin); CompilerDeclContext decl_context = GetDeclContextContainingUIDFromDWARF(child); return (clang::DeclContext *)decl_context.GetOpaqueDeclContext(); } clang::BlockDecl *DWARFASTParserClang::ResolveBlockDIE(const DWARFDIE &die) { if (die && die.Tag() == DW_TAG_lexical_block) { clang::BlockDecl *decl = llvm::cast_or_null(m_die_to_decl_ctx[die.GetDIE()]); if (!decl) { DWARFDIE decl_context_die; clang::DeclContext *decl_context = GetClangDeclContextContainingDIE(die, &decl_context_die); decl = m_ast.CreateBlockDeclaration(decl_context); if (decl) LinkDeclContextToDIE((clang::DeclContext *)decl, die); } return decl; } return nullptr; } clang::NamespaceDecl * DWARFASTParserClang::ResolveNamespaceDIE(const DWARFDIE &die) { if (die && die.Tag() == DW_TAG_namespace) { // See if we already parsed this namespace DIE and associated it with a // uniqued namespace declaration clang::NamespaceDecl *namespace_decl = static_cast(m_die_to_decl_ctx[die.GetDIE()]); if (namespace_decl) return namespace_decl; else { const char *namespace_name = die.GetName(); clang::DeclContext *containing_decl_ctx = GetClangDeclContextContainingDIE(die, nullptr); bool is_inline = die.GetAttributeValueAsUnsigned(DW_AT_export_symbols, 0) != 0; namespace_decl = m_ast.GetUniqueNamespaceDeclaration( namespace_name, containing_decl_ctx, is_inline); Log *log = nullptr; // (LogChannelDWARF::GetLogIfAll(DWARF_LOG_DEBUG_INFO)); if (log) { SymbolFileDWARF *dwarf = die.GetDWARF(); if (namespace_name) { dwarf->GetObjectFile()->GetModule()->LogMessage( log, "ASTContext => %p: 0x%8.8" PRIx64 ": DW_TAG_namespace with DW_AT_name(\"%s\") => " "clang::NamespaceDecl *%p (original = %p)", static_cast(m_ast.getASTContext()), die.GetID(), namespace_name, static_cast(namespace_decl), static_cast(namespace_decl->getOriginalNamespace())); } else { dwarf->GetObjectFile()->GetModule()->LogMessage( log, "ASTContext => %p: 0x%8.8" PRIx64 ": DW_TAG_namespace (anonymous) => clang::NamespaceDecl *%p " "(original = %p)", static_cast(m_ast.getASTContext()), die.GetID(), static_cast(namespace_decl), static_cast(namespace_decl->getOriginalNamespace())); } } if (namespace_decl) LinkDeclContextToDIE((clang::DeclContext *)namespace_decl, die); return namespace_decl; } } return nullptr; } clang::DeclContext *DWARFASTParserClang::GetClangDeclContextContainingDIE( const DWARFDIE &die, DWARFDIE *decl_ctx_die_copy) { SymbolFileDWARF *dwarf = die.GetDWARF(); DWARFDIE decl_ctx_die = dwarf->GetDeclContextDIEContainingDIE(die); if (decl_ctx_die_copy) *decl_ctx_die_copy = decl_ctx_die; if (decl_ctx_die) { clang::DeclContext *clang_decl_ctx = GetClangDeclContextForDIE(decl_ctx_die); if (clang_decl_ctx) return clang_decl_ctx; } return m_ast.GetTranslationUnitDecl(); } clang::DeclContext * DWARFASTParserClang::GetCachedClangDeclContextForDIE(const DWARFDIE &die) { if (die) { DIEToDeclContextMap::iterator pos = m_die_to_decl_ctx.find(die.GetDIE()); if (pos != m_die_to_decl_ctx.end()) return pos->second; } return nullptr; } void DWARFASTParserClang::LinkDeclContextToDIE(clang::DeclContext *decl_ctx, const DWARFDIE &die) { m_die_to_decl_ctx[die.GetDIE()] = decl_ctx; // There can be many DIEs for a single decl context // m_decl_ctx_to_die[decl_ctx].insert(die.GetDIE()); m_decl_ctx_to_die.insert(std::make_pair(decl_ctx, die)); } bool DWARFASTParserClang::CopyUniqueClassMethodTypes( const DWARFDIE &src_class_die, const DWARFDIE &dst_class_die, lldb_private::Type *class_type, std::vector &failures) { if (!class_type || !src_class_die || !dst_class_die) return false; if (src_class_die.Tag() != dst_class_die.Tag()) return false; // We need to complete the class type so we can get all of the method types // parsed so we can then unique those types to their equivalent counterparts // in "dst_cu" and "dst_class_die" class_type->GetFullCompilerType(); DWARFDIE src_die; DWARFDIE dst_die; UniqueCStringMap src_name_to_die; UniqueCStringMap dst_name_to_die; UniqueCStringMap src_name_to_die_artificial; UniqueCStringMap dst_name_to_die_artificial; for (src_die = src_class_die.GetFirstChild(); src_die.IsValid(); src_die = src_die.GetSibling()) { if (src_die.Tag() == DW_TAG_subprogram) { // Make sure this is a declaration and not a concrete instance by looking // for DW_AT_declaration set to 1. Sometimes concrete function instances // are placed inside the class definitions and shouldn't be included in // the list of things are are tracking here. if (src_die.GetAttributeValueAsUnsigned(DW_AT_declaration, 0) == 1) { const char *src_name = src_die.GetMangledName(); if (src_name) { ConstString src_const_name(src_name); if (src_die.GetAttributeValueAsUnsigned(DW_AT_artificial, 0)) src_name_to_die_artificial.Append(src_const_name, src_die); else src_name_to_die.Append(src_const_name, src_die); } } } } for (dst_die = dst_class_die.GetFirstChild(); dst_die.IsValid(); dst_die = dst_die.GetSibling()) { if (dst_die.Tag() == DW_TAG_subprogram) { // Make sure this is a declaration and not a concrete instance by looking // for DW_AT_declaration set to 1. Sometimes concrete function instances // are placed inside the class definitions and shouldn't be included in // the list of things are are tracking here. if (dst_die.GetAttributeValueAsUnsigned(DW_AT_declaration, 0) == 1) { const char *dst_name = dst_die.GetMangledName(); if (dst_name) { ConstString dst_const_name(dst_name); if (dst_die.GetAttributeValueAsUnsigned(DW_AT_artificial, 0)) dst_name_to_die_artificial.Append(dst_const_name, dst_die); else dst_name_to_die.Append(dst_const_name, dst_die); } } } } const uint32_t src_size = src_name_to_die.GetSize(); const uint32_t dst_size = dst_name_to_die.GetSize(); Log *log = nullptr; // (LogChannelDWARF::GetLogIfAny(DWARF_LOG_DEBUG_INFO | // DWARF_LOG_TYPE_COMPLETION)); // Is everything kosher so we can go through the members at top speed? bool fast_path = true; if (src_size != dst_size) { if (src_size != 0 && dst_size != 0) { LLDB_LOGF(log, "warning: trying to unique class DIE 0x%8.8x to 0x%8.8x, " "but they didn't have the same size (src=%d, dst=%d)", src_class_die.GetOffset(), dst_class_die.GetOffset(), src_size, dst_size); } fast_path = false; } uint32_t idx; if (fast_path) { for (idx = 0; idx < src_size; ++idx) { src_die = src_name_to_die.GetValueAtIndexUnchecked(idx); dst_die = dst_name_to_die.GetValueAtIndexUnchecked(idx); if (src_die.Tag() != dst_die.Tag()) { LLDB_LOGF(log, "warning: tried to unique class DIE 0x%8.8x to 0x%8.8x, " "but 0x%8.8x (%s) tags didn't match 0x%8.8x (%s)", src_class_die.GetOffset(), dst_class_die.GetOffset(), src_die.GetOffset(), src_die.GetTagAsCString(), dst_die.GetOffset(), dst_die.GetTagAsCString()); fast_path = false; } const char *src_name = src_die.GetMangledName(); const char *dst_name = dst_die.GetMangledName(); // Make sure the names match if (src_name == dst_name || (strcmp(src_name, dst_name) == 0)) continue; LLDB_LOGF(log, "warning: tried to unique class DIE 0x%8.8x to 0x%8.8x, " "but 0x%8.8x (%s) names didn't match 0x%8.8x (%s)", src_class_die.GetOffset(), dst_class_die.GetOffset(), src_die.GetOffset(), src_name, dst_die.GetOffset(), dst_name); fast_path = false; } } DWARFASTParserClang *src_dwarf_ast_parser = (DWARFASTParserClang *)src_die.GetDWARFParser(); DWARFASTParserClang *dst_dwarf_ast_parser = (DWARFASTParserClang *)dst_die.GetDWARFParser(); // Now do the work of linking the DeclContexts and Types. if (fast_path) { // We can do this quickly. Just run across the tables index-for-index // since we know each node has matching names and tags. for (idx = 0; idx < src_size; ++idx) { src_die = src_name_to_die.GetValueAtIndexUnchecked(idx); dst_die = dst_name_to_die.GetValueAtIndexUnchecked(idx); clang::DeclContext *src_decl_ctx = src_dwarf_ast_parser->m_die_to_decl_ctx[src_die.GetDIE()]; if (src_decl_ctx) { LLDB_LOGF(log, "uniquing decl context %p from 0x%8.8x for 0x%8.8x", static_cast(src_decl_ctx), src_die.GetOffset(), dst_die.GetOffset()); dst_dwarf_ast_parser->LinkDeclContextToDIE(src_decl_ctx, dst_die); } else { LLDB_LOGF(log, "warning: tried to unique decl context from 0x%8.8x for " "0x%8.8x, but none was found", src_die.GetOffset(), dst_die.GetOffset()); } Type *src_child_type = dst_die.GetDWARF()->GetDIEToType()[src_die.GetDIE()]; if (src_child_type) { LLDB_LOGF(log, "uniquing type %p (uid=0x%" PRIx64 ") from 0x%8.8x for 0x%8.8x", static_cast(src_child_type), src_child_type->GetID(), src_die.GetOffset(), dst_die.GetOffset()); dst_die.GetDWARF()->GetDIEToType()[dst_die.GetDIE()] = src_child_type; } else { LLDB_LOGF(log, "warning: tried to unique lldb_private::Type from " "0x%8.8x for 0x%8.8x, but none was found", src_die.GetOffset(), dst_die.GetOffset()); } } } else { // We must do this slowly. For each member of the destination, look up a // member in the source with the same name, check its tag, and unique them // if everything matches up. Report failures. if (!src_name_to_die.IsEmpty() && !dst_name_to_die.IsEmpty()) { src_name_to_die.Sort(); for (idx = 0; idx < dst_size; ++idx) { ConstString dst_name = dst_name_to_die.GetCStringAtIndex(idx); dst_die = dst_name_to_die.GetValueAtIndexUnchecked(idx); src_die = src_name_to_die.Find(dst_name, DWARFDIE()); if (src_die && (src_die.Tag() == dst_die.Tag())) { clang::DeclContext *src_decl_ctx = src_dwarf_ast_parser->m_die_to_decl_ctx[src_die.GetDIE()]; if (src_decl_ctx) { LLDB_LOGF(log, "uniquing decl context %p from 0x%8.8x for 0x%8.8x", static_cast(src_decl_ctx), src_die.GetOffset(), dst_die.GetOffset()); dst_dwarf_ast_parser->LinkDeclContextToDIE(src_decl_ctx, dst_die); } else { LLDB_LOGF(log, "warning: tried to unique decl context from 0x%8.8x " "for 0x%8.8x, but none was found", src_die.GetOffset(), dst_die.GetOffset()); } Type *src_child_type = dst_die.GetDWARF()->GetDIEToType()[src_die.GetDIE()]; if (src_child_type) { LLDB_LOGF( log, "uniquing type %p (uid=0x%" PRIx64 ") from 0x%8.8x for 0x%8.8x", static_cast(src_child_type), src_child_type->GetID(), src_die.GetOffset(), dst_die.GetOffset()); dst_die.GetDWARF()->GetDIEToType()[dst_die.GetDIE()] = src_child_type; } else { LLDB_LOGF(log, "warning: tried to unique lldb_private::Type from " "0x%8.8x for 0x%8.8x, but none was found", src_die.GetOffset(), dst_die.GetOffset()); } } else { LLDB_LOGF(log, "warning: couldn't find a match for 0x%8.8x", dst_die.GetOffset()); failures.push_back(dst_die); } } } } const uint32_t src_size_artificial = src_name_to_die_artificial.GetSize(); const uint32_t dst_size_artificial = dst_name_to_die_artificial.GetSize(); if (src_size_artificial && dst_size_artificial) { dst_name_to_die_artificial.Sort(); for (idx = 0; idx < src_size_artificial; ++idx) { ConstString src_name_artificial = src_name_to_die_artificial.GetCStringAtIndex(idx); src_die = src_name_to_die_artificial.GetValueAtIndexUnchecked(idx); dst_die = dst_name_to_die_artificial.Find(src_name_artificial, DWARFDIE()); if (dst_die) { // Both classes have the artificial types, link them clang::DeclContext *src_decl_ctx = src_dwarf_ast_parser->m_die_to_decl_ctx[src_die.GetDIE()]; if (src_decl_ctx) { LLDB_LOGF(log, "uniquing decl context %p from 0x%8.8x for 0x%8.8x", static_cast(src_decl_ctx), src_die.GetOffset(), dst_die.GetOffset()); dst_dwarf_ast_parser->LinkDeclContextToDIE(src_decl_ctx, dst_die); } else { LLDB_LOGF(log, "warning: tried to unique decl context from 0x%8.8x " "for 0x%8.8x, but none was found", src_die.GetOffset(), dst_die.GetOffset()); } Type *src_child_type = dst_die.GetDWARF()->GetDIEToType()[src_die.GetDIE()]; if (src_child_type) { LLDB_LOGF( log, "uniquing type %p (uid=0x%" PRIx64 ") from 0x%8.8x for 0x%8.8x", static_cast(src_child_type), src_child_type->GetID(), src_die.GetOffset(), dst_die.GetOffset()); dst_die.GetDWARF()->GetDIEToType()[dst_die.GetDIE()] = src_child_type; } else { LLDB_LOGF(log, "warning: tried to unique lldb_private::Type from " "0x%8.8x for 0x%8.8x, but none was found", src_die.GetOffset(), dst_die.GetOffset()); } } } } if (dst_size_artificial) { for (idx = 0; idx < dst_size_artificial; ++idx) { ConstString dst_name_artificial = dst_name_to_die_artificial.GetCStringAtIndex(idx); dst_die = dst_name_to_die_artificial.GetValueAtIndexUnchecked(idx); LLDB_LOGF(log, "warning: need to create artificial method for 0x%8.8x for " "method '%s'", dst_die.GetOffset(), dst_name_artificial.GetCString()); failures.push_back(dst_die); } } return !failures.empty(); }