//===-- Symbol.cpp ----------------------------------------------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "lldb/Symbol/Symbol.h" #include "lldb/Core/Module.h" #include "lldb/Core/Section.h" #include "lldb/Core/Stream.h" #include "lldb/Symbol/ObjectFile.h" #include "lldb/Symbol/Symtab.h" #include "lldb/Symbol/Function.h" #include "lldb/Target/Process.h" #include "lldb/Target/Target.h" #include "lldb/Symbol/SymbolVendor.h" using namespace lldb; using namespace lldb_private; Symbol::Symbol() : SymbolContextScope (), m_uid (UINT32_MAX), m_type_data (0), m_type_data_resolved (false), m_is_synthetic (false), m_is_debug (false), m_is_external (false), m_size_is_sibling (false), m_size_is_synthesized (false), m_size_is_valid (false), m_demangled_is_synthesized (false), m_type (eSymbolTypeInvalid), m_mangled (), m_addr_range (), m_flags () { } Symbol::Symbol ( uint32_t symID, const char *name, bool name_is_mangled, SymbolType type, bool external, bool is_debug, bool is_trampoline, bool is_artificial, const lldb::SectionSP §ion_sp, addr_t offset, addr_t size, bool size_is_valid, uint32_t flags ) : SymbolContextScope (), m_uid (symID), m_type_data (0), m_type_data_resolved (false), m_is_synthetic (is_artificial), m_is_debug (is_debug), m_is_external (external), m_size_is_sibling (false), m_size_is_synthesized (false), m_size_is_valid (size_is_valid || size > 0), m_demangled_is_synthesized (false), m_type (type), m_mangled (ConstString(name), name_is_mangled), m_addr_range (section_sp, offset, size), m_flags (flags) { } Symbol::Symbol ( uint32_t symID, const char *name, bool name_is_mangled, SymbolType type, bool external, bool is_debug, bool is_trampoline, bool is_artificial, const AddressRange &range, bool size_is_valid, uint32_t flags ) : SymbolContextScope (), m_uid (symID), m_type_data (0), m_type_data_resolved (false), m_is_synthetic (is_artificial), m_is_debug (is_debug), m_is_external (external), m_size_is_sibling (false), m_size_is_synthesized (false), m_size_is_valid (size_is_valid || range.GetByteSize() > 0), m_demangled_is_synthesized (false), m_type (type), m_mangled (ConstString(name), name_is_mangled), m_addr_range (range), m_flags (flags) { } Symbol::Symbol(const Symbol& rhs): SymbolContextScope (rhs), m_uid (rhs.m_uid), m_type_data (rhs.m_type_data), m_type_data_resolved (rhs.m_type_data_resolved), m_is_synthetic (rhs.m_is_synthetic), m_is_debug (rhs.m_is_debug), m_is_external (rhs.m_is_external), m_size_is_sibling (rhs.m_size_is_sibling), m_size_is_synthesized (false), m_size_is_valid (rhs.m_size_is_valid), m_demangled_is_synthesized (rhs.m_demangled_is_synthesized), m_type (rhs.m_type), m_mangled (rhs.m_mangled), m_addr_range (rhs.m_addr_range), m_flags (rhs.m_flags) { } const Symbol& Symbol::operator= (const Symbol& rhs) { if (this != &rhs) { SymbolContextScope::operator= (rhs); m_uid = rhs.m_uid; m_type_data = rhs.m_type_data; m_type_data_resolved = rhs.m_type_data_resolved; m_is_synthetic = rhs.m_is_synthetic; m_is_debug = rhs.m_is_debug; m_is_external = rhs.m_is_external; m_size_is_sibling = rhs.m_size_is_sibling; m_size_is_synthesized = rhs.m_size_is_sibling; m_size_is_valid = rhs.m_size_is_valid; m_demangled_is_synthesized = rhs.m_demangled_is_synthesized; m_type = rhs.m_type; m_mangled = rhs.m_mangled; m_addr_range = rhs.m_addr_range; m_flags = rhs.m_flags; } return *this; } void Symbol::Clear() { m_uid = UINT32_MAX; m_mangled.Clear(); m_type_data = 0; m_type_data_resolved = false; m_is_synthetic = false; m_is_debug = false; m_is_external = false; m_size_is_sibling = false; m_size_is_synthesized = false; m_size_is_valid = false; m_demangled_is_synthesized = false; m_type = eSymbolTypeInvalid; m_flags = 0; m_addr_range.Clear(); } bool Symbol::ValueIsAddress() const { return m_addr_range.GetBaseAddress().GetSection().get() != NULL; } uint32_t Symbol::GetSiblingIndex() const { return m_size_is_sibling ? m_addr_range.GetByteSize() : 0; } bool Symbol::IsTrampoline () const { return m_type == eSymbolTypeTrampoline; } bool Symbol::IsIndirect () const { return m_type == eSymbolTypeResolver; } void Symbol::GetDescription (Stream *s, lldb::DescriptionLevel level, Target *target) const { s->Printf("id = {0x%8.8x}", m_uid); if (m_addr_range.GetBaseAddress().GetSection()) { if (ValueIsAddress()) { const lldb::addr_t byte_size = GetByteSize(); if (byte_size > 0) { s->PutCString (", range = "); m_addr_range.Dump(s, target, Address::DumpStyleLoadAddress, Address::DumpStyleFileAddress); } else { s->PutCString (", address = "); m_addr_range.GetBaseAddress().Dump(s, target, Address::DumpStyleLoadAddress, Address::DumpStyleFileAddress); } } else s->Printf (", value = 0x%16.16" PRIx64, m_addr_range.GetBaseAddress().GetOffset()); } else { if (m_size_is_sibling) s->Printf (", sibling = %5" PRIu64, m_addr_range.GetBaseAddress().GetOffset()); else s->Printf (", value = 0x%16.16" PRIx64, m_addr_range.GetBaseAddress().GetOffset()); } if (m_mangled.GetDemangledName()) s->Printf(", name=\"%s\"", m_mangled.GetDemangledName().AsCString()); if (m_mangled.GetMangledName()) s->Printf(", mangled=\"%s\"", m_mangled.GetMangledName().AsCString()); } void Symbol::Dump(Stream *s, Target *target, uint32_t index) const { // s->Printf("%.*p: ", (int)sizeof(void*) * 2, this); // s->Indent(); // s->Printf("Symbol[%5u] %6u %c%c %-12s ", s->Printf("[%5u] %6u %c%c%c %-12s ", index, GetID(), m_is_debug ? 'D' : ' ', m_is_synthetic ? 'S' : ' ', m_is_external ? 'X' : ' ', GetTypeAsString()); // Make sure the size of the symbol is up to date before dumping GetByteSize(); if (ValueIsAddress()) { if (!m_addr_range.GetBaseAddress().Dump(s, NULL, Address::DumpStyleFileAddress)) s->Printf("%*s", 18, ""); s->PutChar(' '); if (!m_addr_range.GetBaseAddress().Dump(s, target, Address::DumpStyleLoadAddress)) s->Printf("%*s", 18, ""); const char *format = m_size_is_sibling ? " Sibling -> [%5llu] 0x%8.8x %s\n": " 0x%16.16" PRIx64 " 0x%8.8x %s\n"; s->Printf( format, GetByteSize(), m_flags, m_mangled.GetName().AsCString("")); } else { const char *format = m_size_is_sibling ? "0x%16.16" PRIx64 " Sibling -> [%5llu] 0x%8.8x %s\n": "0x%16.16" PRIx64 " 0x%16.16" PRIx64 " 0x%8.8x %s\n"; s->Printf( format, m_addr_range.GetBaseAddress().GetOffset(), GetByteSize(), m_flags, m_mangled.GetName().AsCString("")); } } uint32_t Symbol::GetPrologueByteSize () { if (m_type == eSymbolTypeCode || m_type == eSymbolTypeResolver) { if (!m_type_data_resolved) { m_type_data_resolved = true; const Address &base_address = m_addr_range.GetBaseAddress(); Function *function = base_address.CalculateSymbolContextFunction(); if (function) { // Functions have line entries which can also potentially have end of prologue information. // So if this symbol points to a function, use the prologue information from there. m_type_data = function->GetPrologueByteSize(); } else { ModuleSP module_sp (base_address.GetModule()); SymbolContext sc; if (module_sp) { uint32_t resolved_flags = module_sp->ResolveSymbolContextForAddress (base_address, eSymbolContextLineEntry, sc); if (resolved_flags & eSymbolContextLineEntry) { // Default to the end of the first line entry. m_type_data = sc.line_entry.range.GetByteSize(); // Set address for next line. Address addr (base_address); addr.Slide (m_type_data); // Check the first few instructions and look for one that has a line number that is // different than the first entry. This is also done in Function::GetPrologueByteSize(). uint16_t total_offset = m_type_data; for (int idx = 0; idx < 6; ++idx) { SymbolContext sc_temp; resolved_flags = module_sp->ResolveSymbolContextForAddress (addr, eSymbolContextLineEntry, sc_temp); // Make sure we got line number information... if (!(resolved_flags & eSymbolContextLineEntry)) break; // If this line number is different than our first one, use it and we're done. if (sc_temp.line_entry.line != sc.line_entry.line) { m_type_data = total_offset; break; } // Slide addr up to the next line address. addr.Slide (sc_temp.line_entry.range.GetByteSize()); total_offset += sc_temp.line_entry.range.GetByteSize(); // If we've gone too far, bail out. if (total_offset >= m_addr_range.GetByteSize()) break; } // Sanity check - this may be a function in the middle of code that has debug information, but // not for this symbol. So the line entries surrounding us won't lie inside our function. // In that case, the line entry will be bigger than we are, so we do that quick check and // if that is true, we just return 0. if (m_type_data >= m_addr_range.GetByteSize()) m_type_data = 0; } else { // TODO: expose something in Process to figure out the // size of a function prologue. m_type_data = 0; } } } } return m_type_data; } return 0; } bool Symbol::Compare(const ConstString& name, SymbolType type) const { if (type == eSymbolTypeAny || m_type == type) return m_mangled.GetMangledName() == name || m_mangled.GetDemangledName() == name; return false; } #define ENUM_TO_CSTRING(x) case eSymbolType##x: return #x; const char * Symbol::GetTypeAsString() const { switch (m_type) { ENUM_TO_CSTRING(Invalid); ENUM_TO_CSTRING(Absolute); ENUM_TO_CSTRING(Code); ENUM_TO_CSTRING(Data); ENUM_TO_CSTRING(Trampoline); ENUM_TO_CSTRING(Runtime); ENUM_TO_CSTRING(Exception); ENUM_TO_CSTRING(SourceFile); ENUM_TO_CSTRING(HeaderFile); ENUM_TO_CSTRING(ObjectFile); ENUM_TO_CSTRING(CommonBlock); ENUM_TO_CSTRING(Block); ENUM_TO_CSTRING(Local); ENUM_TO_CSTRING(Param); ENUM_TO_CSTRING(Variable); ENUM_TO_CSTRING(VariableType); ENUM_TO_CSTRING(LineEntry); ENUM_TO_CSTRING(LineHeader); ENUM_TO_CSTRING(ScopeBegin); ENUM_TO_CSTRING(ScopeEnd); ENUM_TO_CSTRING(Additional); ENUM_TO_CSTRING(Compiler); ENUM_TO_CSTRING(Instrumentation); ENUM_TO_CSTRING(Undefined); ENUM_TO_CSTRING(ObjCClass); ENUM_TO_CSTRING(ObjCMetaClass); ENUM_TO_CSTRING(ObjCIVar); default: break; } return "<unknown SymbolType>"; } void Symbol::CalculateSymbolContext (SymbolContext *sc) { // Symbols can reconstruct the symbol and the module in the symbol context sc->symbol = this; if (ValueIsAddress()) sc->module_sp = GetAddress().GetModule(); else sc->module_sp.reset(); } ModuleSP Symbol::CalculateSymbolContextModule () { if (ValueIsAddress()) return GetAddress().GetModule(); return ModuleSP(); } Symbol * Symbol::CalculateSymbolContextSymbol () { return this; } void Symbol::DumpSymbolContext (Stream *s) { bool dumped_module = false; if (ValueIsAddress()) { ModuleSP module_sp (GetAddress().GetModule()); if (module_sp) { dumped_module = true; module_sp->DumpSymbolContext(s); } } if (dumped_module) s->PutCString(", "); s->Printf("Symbol{0x%8.8x}", GetID()); } lldb::addr_t Symbol::GetByteSize () const { return m_addr_range.GetByteSize(); }