//===-- LLVMSymbolize.cpp -------------------------------------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // Implementation for LLVM symbolization library. // //===----------------------------------------------------------------------===// #include "LLVMSymbolize.h" #include "llvm/ADT/STLExtras.h" #include "llvm/Config/config.h" #include "llvm/Object/ELFObjectFile.h" #include "llvm/Object/MachO.h" #include "llvm/Support/Casting.h" #include "llvm/Support/Compression.h" #include "llvm/Support/DataExtractor.h" #include "llvm/Support/Errc.h" #include "llvm/Support/FileSystem.h" #include "llvm/Support/MemoryBuffer.h" #include "llvm/Support/Path.h" #include #include namespace llvm { namespace symbolize { static bool error(std::error_code ec) { if (!ec) return false; errs() << "LLVMSymbolizer: error reading file: " << ec.message() << ".\n"; return true; } static DILineInfoSpecifier getDILineInfoSpecifier(const LLVMSymbolizer::Options &Opts) { return DILineInfoSpecifier( DILineInfoSpecifier::FileLineInfoKind::AbsoluteFilePath, Opts.PrintFunctions); } ModuleInfo::ModuleInfo(ObjectFile *Obj, DIContext *DICtx) : Module(Obj), DebugInfoContext(DICtx) { for (const SymbolRef &Symbol : Module->symbols()) { addSymbol(Symbol); } bool NoSymbolTable = (Module->symbol_begin() == Module->symbol_end()); if (NoSymbolTable && Module->isELF()) { // Fallback to dynamic symbol table, if regular symbol table is stripped. std::pair IDyn = getELFDynamicSymbolIterators(Module); for (symbol_iterator si = IDyn.first, se = IDyn.second; si != se; ++si) { addSymbol(*si); } } } void ModuleInfo::addSymbol(const SymbolRef &Symbol) { SymbolRef::Type SymbolType; if (error(Symbol.getType(SymbolType))) return; if (SymbolType != SymbolRef::ST_Function && SymbolType != SymbolRef::ST_Data) return; uint64_t SymbolAddress; if (error(Symbol.getAddress(SymbolAddress)) || SymbolAddress == UnknownAddressOrSize) return; uint64_t SymbolSize; // Getting symbol size is linear for Mach-O files, so assume that symbol // occupies the memory range up to the following symbol. if (isa(Module)) SymbolSize = 0; else if (error(Symbol.getSize(SymbolSize)) || SymbolSize == UnknownAddressOrSize) return; StringRef SymbolName; if (error(Symbol.getName(SymbolName))) return; // Mach-O symbol table names have leading underscore, skip it. if (Module->isMachO() && SymbolName.size() > 0 && SymbolName[0] == '_') SymbolName = SymbolName.drop_front(); // FIXME: If a function has alias, there are two entries in symbol table // with same address size. Make sure we choose the correct one. SymbolMapTy &M = SymbolType == SymbolRef::ST_Function ? Functions : Objects; SymbolDesc SD = { SymbolAddress, SymbolSize }; M.insert(std::make_pair(SD, SymbolName)); } bool ModuleInfo::getNameFromSymbolTable(SymbolRef::Type Type, uint64_t Address, std::string &Name, uint64_t &Addr, uint64_t &Size) const { const SymbolMapTy &M = Type == SymbolRef::ST_Function ? Functions : Objects; if (M.empty()) return false; SymbolDesc SD = { Address, Address }; SymbolMapTy::const_iterator it = M.upper_bound(SD); if (it == M.begin()) return false; --it; if (it->first.Size != 0 && it->first.Addr + it->first.Size <= Address) return false; Name = it->second.str(); Addr = it->first.Addr; Size = it->first.Size; return true; } DILineInfo ModuleInfo::symbolizeCode( uint64_t ModuleOffset, const LLVMSymbolizer::Options &Opts) const { DILineInfo LineInfo; if (DebugInfoContext) { LineInfo = DebugInfoContext->getLineInfoForAddress( ModuleOffset, getDILineInfoSpecifier(Opts)); } // Override function name from symbol table if necessary. if (Opts.PrintFunctions != FunctionNameKind::None && Opts.UseSymbolTable) { std::string FunctionName; uint64_t Start, Size; if (getNameFromSymbolTable(SymbolRef::ST_Function, ModuleOffset, FunctionName, Start, Size)) { LineInfo.FunctionName = FunctionName; } } return LineInfo; } DIInliningInfo ModuleInfo::symbolizeInlinedCode( uint64_t ModuleOffset, const LLVMSymbolizer::Options &Opts) const { DIInliningInfo InlinedContext; if (DebugInfoContext) { InlinedContext = DebugInfoContext->getInliningInfoForAddress( ModuleOffset, getDILineInfoSpecifier(Opts)); } // Make sure there is at least one frame in context. if (InlinedContext.getNumberOfFrames() == 0) { InlinedContext.addFrame(DILineInfo()); } // Override the function name in lower frame with name from symbol table. if (Opts.PrintFunctions != FunctionNameKind::None && Opts.UseSymbolTable) { DIInliningInfo PatchedInlinedContext; for (uint32_t i = 0, n = InlinedContext.getNumberOfFrames(); i < n; i++) { DILineInfo LineInfo = InlinedContext.getFrame(i); if (i == n - 1) { std::string FunctionName; uint64_t Start, Size; if (getNameFromSymbolTable(SymbolRef::ST_Function, ModuleOffset, FunctionName, Start, Size)) { LineInfo.FunctionName = FunctionName; } } PatchedInlinedContext.addFrame(LineInfo); } InlinedContext = PatchedInlinedContext; } return InlinedContext; } bool ModuleInfo::symbolizeData(uint64_t ModuleOffset, std::string &Name, uint64_t &Start, uint64_t &Size) const { return getNameFromSymbolTable(SymbolRef::ST_Data, ModuleOffset, Name, Start, Size); } const char LLVMSymbolizer::kBadString[] = "??"; std::string LLVMSymbolizer::symbolizeCode(const std::string &ModuleName, uint64_t ModuleOffset) { ModuleInfo *Info = getOrCreateModuleInfo(ModuleName); if (!Info) return printDILineInfo(DILineInfo()); if (Opts.PrintInlining) { DIInliningInfo InlinedContext = Info->symbolizeInlinedCode(ModuleOffset, Opts); uint32_t FramesNum = InlinedContext.getNumberOfFrames(); assert(FramesNum > 0); std::string Result; for (uint32_t i = 0; i < FramesNum; i++) { DILineInfo LineInfo = InlinedContext.getFrame(i); Result += printDILineInfo(LineInfo); } return Result; } DILineInfo LineInfo = Info->symbolizeCode(ModuleOffset, Opts); return printDILineInfo(LineInfo); } std::string LLVMSymbolizer::symbolizeData(const std::string &ModuleName, uint64_t ModuleOffset) { std::string Name = kBadString; uint64_t Start = 0; uint64_t Size = 0; if (Opts.UseSymbolTable) { if (ModuleInfo *Info = getOrCreateModuleInfo(ModuleName)) { if (Info->symbolizeData(ModuleOffset, Name, Start, Size) && Opts.Demangle) Name = DemangleName(Name); } } std::stringstream ss; ss << Name << "\n" << Start << " " << Size << "\n"; return ss.str(); } void LLVMSymbolizer::flush() { DeleteContainerSeconds(Modules); BinaryForPath.clear(); ObjectFileForArch.clear(); } static std::string getDarwinDWARFResourceForPath(const std::string &Path) { StringRef Basename = sys::path::filename(Path); const std::string &DSymDirectory = Path + ".dSYM"; SmallString<16> ResourceName = StringRef(DSymDirectory); sys::path::append(ResourceName, "Contents", "Resources", "DWARF"); sys::path::append(ResourceName, Basename); return ResourceName.str(); } static bool checkFileCRC(StringRef Path, uint32_t CRCHash) { ErrorOr> MB = MemoryBuffer::getFileOrSTDIN(Path); if (!MB) return false; return !zlib::isAvailable() || CRCHash == zlib::crc32(MB.get()->getBuffer()); } static bool findDebugBinary(const std::string &OrigPath, const std::string &DebuglinkName, uint32_t CRCHash, std::string &Result) { std::string OrigRealPath = OrigPath; #if defined(HAVE_REALPATH) if (char *RP = realpath(OrigPath.c_str(), nullptr)) { OrigRealPath = RP; free(RP); } #endif SmallString<16> OrigDir(OrigRealPath); llvm::sys::path::remove_filename(OrigDir); SmallString<16> DebugPath = OrigDir; // Try /path/to/original_binary/debuglink_name llvm::sys::path::append(DebugPath, DebuglinkName); if (checkFileCRC(DebugPath, CRCHash)) { Result = DebugPath.str(); return true; } // Try /path/to/original_binary/.debug/debuglink_name DebugPath = OrigRealPath; llvm::sys::path::append(DebugPath, ".debug", DebuglinkName); if (checkFileCRC(DebugPath, CRCHash)) { Result = DebugPath.str(); return true; } // Try /usr/lib/debug/path/to/original_binary/debuglink_name DebugPath = "/usr/lib/debug"; llvm::sys::path::append(DebugPath, llvm::sys::path::relative_path(OrigDir), DebuglinkName); if (checkFileCRC(DebugPath, CRCHash)) { Result = DebugPath.str(); return true; } return false; } static bool getGNUDebuglinkContents(const Binary *Bin, std::string &DebugName, uint32_t &CRCHash) { const ObjectFile *Obj = dyn_cast(Bin); if (!Obj) return false; for (const SectionRef &Section : Obj->sections()) { StringRef Name; Section.getName(Name); Name = Name.substr(Name.find_first_not_of("._")); if (Name == "gnu_debuglink") { StringRef Data; Section.getContents(Data); DataExtractor DE(Data, Obj->isLittleEndian(), 0); uint32_t Offset = 0; if (const char *DebugNameStr = DE.getCStr(&Offset)) { // 4-byte align the offset. Offset = (Offset + 3) & ~0x3; if (DE.isValidOffsetForDataOfSize(Offset, 4)) { DebugName = DebugNameStr; CRCHash = DE.getU32(&Offset); return true; } } break; } } return false; } LLVMSymbolizer::BinaryPair LLVMSymbolizer::getOrCreateBinary(const std::string &Path) { BinaryMapTy::iterator I = BinaryForPath.find(Path); if (I != BinaryForPath.end()) return I->second; Binary *Bin = nullptr; Binary *DbgBin = nullptr; ErrorOr> BinaryOrErr = createBinary(Path); if (!error(BinaryOrErr.getError())) { OwningBinary &ParsedBinary = BinaryOrErr.get(); // Check if it's a universal binary. Bin = ParsedBinary.getBinary().get(); addOwningBinary(std::move(ParsedBinary)); if (Bin->isMachO() || Bin->isMachOUniversalBinary()) { // On Darwin we may find DWARF in separate object file in // resource directory. const std::string &ResourcePath = getDarwinDWARFResourceForPath(Path); BinaryOrErr = createBinary(ResourcePath); std::error_code EC = BinaryOrErr.getError(); if (EC != errc::no_such_file_or_directory && !error(EC)) { OwningBinary B = std::move(BinaryOrErr.get()); DbgBin = B.getBinary().get(); addOwningBinary(std::move(B)); } } // Try to locate the debug binary using .gnu_debuglink section. if (!DbgBin) { std::string DebuglinkName; uint32_t CRCHash; std::string DebugBinaryPath; if (getGNUDebuglinkContents(Bin, DebuglinkName, CRCHash) && findDebugBinary(Path, DebuglinkName, CRCHash, DebugBinaryPath)) { BinaryOrErr = createBinary(DebugBinaryPath); if (!error(BinaryOrErr.getError())) { OwningBinary B = std::move(BinaryOrErr.get()); DbgBin = B.getBinary().get(); addOwningBinary(std::move(B)); } } } } if (!DbgBin) DbgBin = Bin; BinaryPair Res = std::make_pair(Bin, DbgBin); BinaryForPath[Path] = Res; return Res; } ObjectFile * LLVMSymbolizer::getObjectFileFromBinary(Binary *Bin, const std::string &ArchName) { if (!Bin) return nullptr; ObjectFile *Res = nullptr; if (MachOUniversalBinary *UB = dyn_cast(Bin)) { ObjectFileForArchMapTy::iterator I = ObjectFileForArch.find( std::make_pair(UB, ArchName)); if (I != ObjectFileForArch.end()) return I->second; ErrorOr> ParsedObj = UB->getObjectForArch(Triple(ArchName).getArch()); if (ParsedObj) { Res = ParsedObj.get().get(); ParsedBinariesAndObjects.push_back(std::move(ParsedObj.get())); } ObjectFileForArch[std::make_pair(UB, ArchName)] = Res; } else if (Bin->isObject()) { Res = cast(Bin); } return Res; } ModuleInfo * LLVMSymbolizer::getOrCreateModuleInfo(const std::string &ModuleName) { ModuleMapTy::iterator I = Modules.find(ModuleName); if (I != Modules.end()) return I->second; std::string BinaryName = ModuleName; std::string ArchName = Opts.DefaultArch; size_t ColonPos = ModuleName.find_last_of(':'); // Verify that substring after colon form a valid arch name. if (ColonPos != std::string::npos) { std::string ArchStr = ModuleName.substr(ColonPos + 1); if (Triple(ArchStr).getArch() != Triple::UnknownArch) { BinaryName = ModuleName.substr(0, ColonPos); ArchName = ArchStr; } } BinaryPair Binaries = getOrCreateBinary(BinaryName); ObjectFile *Obj = getObjectFileFromBinary(Binaries.first, ArchName); ObjectFile *DbgObj = getObjectFileFromBinary(Binaries.second, ArchName); if (!Obj) { // Failed to find valid object file. Modules.insert(make_pair(ModuleName, (ModuleInfo *)nullptr)); return nullptr; } DIContext *Context = DIContext::getDWARFContext(*DbgObj); assert(Context); ModuleInfo *Info = new ModuleInfo(Obj, Context); Modules.insert(make_pair(ModuleName, Info)); return Info; } std::string LLVMSymbolizer::printDILineInfo(DILineInfo LineInfo) const { // By default, DILineInfo contains "" for function/filename it // cannot fetch. We replace it to "??" to make our output closer to addr2line. static const std::string kDILineInfoBadString = ""; std::stringstream Result; if (Opts.PrintFunctions != FunctionNameKind::None) { std::string FunctionName = LineInfo.FunctionName; if (FunctionName == kDILineInfoBadString) FunctionName = kBadString; else if (Opts.Demangle) FunctionName = DemangleName(FunctionName); Result << FunctionName << "\n"; } std::string Filename = LineInfo.FileName; if (Filename == kDILineInfoBadString) Filename = kBadString; Result << Filename << ":" << LineInfo.Line << ":" << LineInfo.Column << "\n"; return Result.str(); } #if !defined(_MSC_VER) // Assume that __cxa_demangle is provided by libcxxabi (except for Windows). extern "C" char *__cxa_demangle(const char *mangled_name, char *output_buffer, size_t *length, int *status); #endif std::string LLVMSymbolizer::DemangleName(const std::string &Name) { #if !defined(_MSC_VER) // We can spoil names of symbols with C linkage, so use an heuristic // approach to check if the name should be demangled. if (Name.substr(0, 2) != "_Z") return Name; int status = 0; char *DemangledName = __cxa_demangle(Name.c_str(), nullptr, nullptr, &status); if (status != 0) return Name; std::string Result = DemangledName; free(DemangledName); return Result; #else return Name; #endif } } // namespace symbolize } // namespace llvm