/* * Copyright (C) 2017 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ // This file is a standalone one-header-file library using only C++03. // // It assumes that the program is compiled for the "Itanium" C++ ABI // (http://itanium-cxx-abi.github.io/cxx-abi/), a common C++ ABI used on many // CPU architectures and operating systems. // #ifndef RTTI_DUMP #define RTTI_DUMP #include #include #include #include #include #include #include #include #include #if defined( __ANDROID__ ) && !defined( RTTI_DUMP_USE_PRINTF ) #include #define RTTI_DUMP_LOG( fmt, ... ) \ __android_log_print( ANDROID_LOG_INFO, "rtti_dump", fmt, ##__VA_ARGS__ ) #else #define RTTI_DUMP_LOG( fmt, ... ) printf( fmt "\n", ##__VA_ARGS__ ) #endif // Avoid compiler warnings. #define RTTI_DUMP_UNUSED __attribute__( ( unused ) ) // Use an anonymous namespace so this header file can be included at the top of // multiple C++ source files without breaking the One Definition Rule. namespace rtti_dump { namespace { // Returns the type of the current exception object or NULL if the thread is // not currently in a catch block. extern "C" const std::type_info* __cxa_current_exception_type(); // Using run-time type information, returns an std::type_info* corresponding to // the most-derived class of a pointer to an object. The pointed-to type must // be a polymorphic class. (i.e. The class must have a virtual function or a // base class with a virtual function.) // // The function can return NULL if the object's vtable comes from an object // file compiled without -frtti. template RTTI_DUMP_UNUSED const std::type_info* runtime_typeid( const volatile T* dynptr ) { T* dynptr_unqual = const_cast( dynptr ); // Use dynamic_cast to ensure that T is polymorphic. The result is // discarded just in case the most-derived object vtable and the subobject // vtable point to different typeinfo objects. (XXX: I *think* that's // impossible, though.) (void) sizeof( dynamic_cast( dynptr_unqual ) ); void* vptr = *reinterpret_cast( dynptr_unqual ); void* typeid_void = reinterpret_cast( vptr )[-1]; return reinterpret_cast( typeid_void ); } // Returns the name of the DSO or binary containing the given address. RTTI_DUMP_UNUSED std::string dladdr_fname( const void* ptr ) { Dl_info info = { 0 }; if( !dladdr( const_cast( ptr ), &info ) ) { char buf[64]; snprintf( buf, sizeof( buf ), "[error: dladdr failed - %d]", errno ); return buf; } else { return std::string( info.dli_fname ); } } // Dump the address of the std::type_info object, its name, and the shared // object where the type_info object is defined. RTTI_DUMP_UNUSED void dump_type( const std::type_info* type, const char* label = "dump_type", int indent = 0 ) { const std::string prefix = label + std::string( ": " ) + std::string( indent, ' ' ); if( type == NULL ) { RTTI_DUMP_LOG( "%sERROR: dump_type called with type==NULL!", prefix.c_str() ); } else { struct type_info { virtual ~type_info() {} const char* type_name; }; assert( sizeof( type_info ) == sizeof( std::type_info ) ); const char* const name = type->name(); const char* const raw_name = reinterpret_cast( type )->type_name; if( name == raw_name ) { RTTI_DUMP_LOG( "%stype %s:", prefix.c_str(), name ); } else if( raw_name + 1 == name ) { RTTI_DUMP_LOG( "%stype %s (raw name == '%s' @ %p):", prefix.c_str(), name, raw_name, raw_name ); } else { RTTI_DUMP_LOG( "%stype %s (raw name == %p):", prefix.c_str(), name, raw_name ); } RTTI_DUMP_LOG( "%s type_info obj: %p (in %s)", prefix.c_str(), type, dladdr_fname( type ).c_str() ); RTTI_DUMP_LOG( "%s type_info name: %p (in %s)", prefix.c_str(), name, dladdr_fname( name ).c_str() ); } } // Call from a catch block to dump the type of the current exception. RTTI_DUMP_UNUSED void dump_current_exception( const char* label = "dump_current_exception" ) { const std::type_info* type = __cxa_current_exception_type(); if( type != NULL ) { dump_type( type, label ); } else { RTTI_DUMP_LOG( "%s: ERROR: dump_current_exception called outside a catch block!", label ); } } namespace hierarchy_dumper_internals { // std::type_info has virtual member functions, so the most-derived type of // a pointer to a std::type_info object can be determined at run-time by // looking for the std::type_info's own std::type_info. We rely upon this // property to walk a class's RTTI graph at run-time. struct __class_type_info : std::type_info { }; struct __si_class_type_info : __class_type_info { const __class_type_info* __base_type; }; struct __base_class_type_info { const __class_type_info* __base_type; long __offset_flags; }; struct __vmi_class_type_info : __class_type_info { unsigned int __flags; unsigned int __base_count; __base_class_type_info __base_info[1]; }; class Dumper { const char* label_; std::set seen_; public: Dumper( const char* label ) : label_( label ) {} void dump_type( const std::type_info* info, int indent ); }; const int kIndent = 4; void Dumper::dump_type( const std::type_info* info, int indent ) { ::rtti_dump::dump_type( info, label_, indent * kIndent ); if( info == NULL ) { return; } const std::type_info* info_type = runtime_typeid( info ); __base_class_type_info lone_base = { 0 }; const __base_class_type_info* base_table = NULL; unsigned int base_count = 0; // Determine type equality using a string comparison, because this dumping // system doesn't trust std::type_info::operator== to work with multiple // shared objects. const int sub_indent_sp = ( indent + 1 ) * kIndent; if( info_type == NULL ) { // I don't think info_type can ever be NULL here. RTTI_DUMP_LOG( "%s: %*sERROR: runtime_typeid(info) was NULL!", label_, sub_indent_sp, "" ); } else if( !strcmp( info_type->name(), "N10__cxxabiv120__si_class_type_infoE" ) ) { const __si_class_type_info& infox = *reinterpret_cast( info ); lone_base.__base_type = infox.__base_type; base_count = 1; base_table = &lone_base; } else if( !strcmp( info_type->name(), "N10__cxxabiv121__vmi_class_type_infoE" ) ) { const __vmi_class_type_info& infox = *reinterpret_cast( info ); base_count = infox.__base_count; base_table = infox.__base_info; } if( base_count > 0 ) { if( seen_.find( info ) != seen_.end() ) { RTTI_DUMP_LOG( "%s: %*sbase classes: ...elided...", label_, sub_indent_sp, "" ); } else { RTTI_DUMP_LOG( "%s: %*sbase classes:", label_, sub_indent_sp, "" ); seen_.insert( info ); for( unsigned int i = 0; i < base_count; ++i ) { dump_type( base_table[i].__base_type, indent + 2 ); } } } } } // namespace hierarchy_dumper_internals // Dump the std::type_info object, and if it represents a class with base // classes, then dumps the class hierarchy. RTTI_DUMP_UNUSED void dump_class_hierarchy( const std::type_info* info, const char* label = "dump_class_hierarchy" ) { hierarchy_dumper_internals::Dumper dumper( label ); dumper.dump_type( info, 0 ); } } // anonymous namespace } // namespace rtti_dump #endif // RTTI_DUMP