//===-- LLVMSymbolize.cpp -------------------------------------------------===// // // 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 // //===----------------------------------------------------------------------===// // // Implementation for LLVM symbolization library. // //===----------------------------------------------------------------------===// #include "llvm/DebugInfo/Symbolize/Symbolize.h" #include "llvm/ADT/STLExtras.h" #include "llvm/DebugInfo/BTF/BTFContext.h" #include "llvm/DebugInfo/DWARF/DWARFContext.h" #include "llvm/DebugInfo/PDB/PDB.h" #include "llvm/DebugInfo/PDB/PDBContext.h" #include "llvm/DebugInfo/Symbolize/SymbolizableObjectFile.h" #include "llvm/Demangle/Demangle.h" #include "llvm/Object/BuildID.h" #include "llvm/Object/COFF.h" #include "llvm/Object/ELFObjectFile.h" #include "llvm/Object/MachO.h" #include "llvm/Object/MachOUniversal.h" #include "llvm/Support/CRC.h" #include "llvm/Support/Casting.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 #include namespace llvm { namespace codeview { union DebugInfo; } namespace symbolize { LLVMSymbolizer::LLVMSymbolizer() = default; LLVMSymbolizer::LLVMSymbolizer(const Options &Opts) : Opts(Opts), BIDFetcher(std::make_unique(Opts.DebugFileDirectory)) {} LLVMSymbolizer::~LLVMSymbolizer() = default; template Expected LLVMSymbolizer::symbolizeCodeCommon(const T &ModuleSpecifier, object::SectionedAddress ModuleOffset) { auto InfoOrErr = getOrCreateModuleInfo(ModuleSpecifier); if (!InfoOrErr) return InfoOrErr.takeError(); SymbolizableModule *Info = *InfoOrErr; // A null module means an error has already been reported. Return an empty // result. if (!Info) return DILineInfo(); // If the user is giving us relative addresses, add the preferred base of the // object to the offset before we do the query. It's what DIContext expects. if (Opts.RelativeAddresses) ModuleOffset.Address += Info->getModulePreferredBase(); DILineInfo LineInfo = Info->symbolizeCode( ModuleOffset, DILineInfoSpecifier(Opts.PathStyle, Opts.PrintFunctions), Opts.UseSymbolTable); if (Opts.Demangle) LineInfo.FunctionName = DemangleName(LineInfo.FunctionName, Info); return LineInfo; } Expected LLVMSymbolizer::symbolizeCode(const ObjectFile &Obj, object::SectionedAddress ModuleOffset) { return symbolizeCodeCommon(Obj, ModuleOffset); } Expected LLVMSymbolizer::symbolizeCode(const std::string &ModuleName, object::SectionedAddress ModuleOffset) { return symbolizeCodeCommon(ModuleName, ModuleOffset); } Expected LLVMSymbolizer::symbolizeCode(ArrayRef BuildID, object::SectionedAddress ModuleOffset) { return symbolizeCodeCommon(BuildID, ModuleOffset); } template Expected LLVMSymbolizer::symbolizeInlinedCodeCommon( const T &ModuleSpecifier, object::SectionedAddress ModuleOffset) { auto InfoOrErr = getOrCreateModuleInfo(ModuleSpecifier); if (!InfoOrErr) return InfoOrErr.takeError(); SymbolizableModule *Info = *InfoOrErr; // A null module means an error has already been reported. Return an empty // result. if (!Info) return DIInliningInfo(); // If the user is giving us relative addresses, add the preferred base of the // object to the offset before we do the query. It's what DIContext expects. if (Opts.RelativeAddresses) ModuleOffset.Address += Info->getModulePreferredBase(); DIInliningInfo InlinedContext = Info->symbolizeInlinedCode( ModuleOffset, DILineInfoSpecifier(Opts.PathStyle, Opts.PrintFunctions), Opts.UseSymbolTable); if (Opts.Demangle) { for (int i = 0, n = InlinedContext.getNumberOfFrames(); i < n; i++) { auto *Frame = InlinedContext.getMutableFrame(i); Frame->FunctionName = DemangleName(Frame->FunctionName, Info); } } return InlinedContext; } Expected LLVMSymbolizer::symbolizeInlinedCode(const ObjectFile &Obj, object::SectionedAddress ModuleOffset) { return symbolizeInlinedCodeCommon(Obj, ModuleOffset); } Expected LLVMSymbolizer::symbolizeInlinedCode(const std::string &ModuleName, object::SectionedAddress ModuleOffset) { return symbolizeInlinedCodeCommon(ModuleName, ModuleOffset); } Expected LLVMSymbolizer::symbolizeInlinedCode(ArrayRef BuildID, object::SectionedAddress ModuleOffset) { return symbolizeInlinedCodeCommon(BuildID, ModuleOffset); } template Expected LLVMSymbolizer::symbolizeDataCommon(const T &ModuleSpecifier, object::SectionedAddress ModuleOffset) { auto InfoOrErr = getOrCreateModuleInfo(ModuleSpecifier); if (!InfoOrErr) return InfoOrErr.takeError(); SymbolizableModule *Info = *InfoOrErr; // A null module means an error has already been reported. Return an empty // result. if (!Info) return DIGlobal(); // If the user is giving us relative addresses, add the preferred base of // the object to the offset before we do the query. It's what DIContext // expects. if (Opts.RelativeAddresses) ModuleOffset.Address += Info->getModulePreferredBase(); DIGlobal Global = Info->symbolizeData(ModuleOffset); if (Opts.Demangle) Global.Name = DemangleName(Global.Name, Info); return Global; } Expected LLVMSymbolizer::symbolizeData(const ObjectFile &Obj, object::SectionedAddress ModuleOffset) { return symbolizeDataCommon(Obj, ModuleOffset); } Expected LLVMSymbolizer::symbolizeData(const std::string &ModuleName, object::SectionedAddress ModuleOffset) { return symbolizeDataCommon(ModuleName, ModuleOffset); } Expected LLVMSymbolizer::symbolizeData(ArrayRef BuildID, object::SectionedAddress ModuleOffset) { return symbolizeDataCommon(BuildID, ModuleOffset); } template Expected> LLVMSymbolizer::symbolizeFrameCommon(const T &ModuleSpecifier, object::SectionedAddress ModuleOffset) { auto InfoOrErr = getOrCreateModuleInfo(ModuleSpecifier); if (!InfoOrErr) return InfoOrErr.takeError(); SymbolizableModule *Info = *InfoOrErr; // A null module means an error has already been reported. Return an empty // result. if (!Info) return std::vector(); // If the user is giving us relative addresses, add the preferred base of // the object to the offset before we do the query. It's what DIContext // expects. if (Opts.RelativeAddresses) ModuleOffset.Address += Info->getModulePreferredBase(); return Info->symbolizeFrame(ModuleOffset); } Expected> LLVMSymbolizer::symbolizeFrame(const ObjectFile &Obj, object::SectionedAddress ModuleOffset) { return symbolizeFrameCommon(Obj, ModuleOffset); } Expected> LLVMSymbolizer::symbolizeFrame(const std::string &ModuleName, object::SectionedAddress ModuleOffset) { return symbolizeFrameCommon(ModuleName, ModuleOffset); } Expected> LLVMSymbolizer::symbolizeFrame(ArrayRef BuildID, object::SectionedAddress ModuleOffset) { return symbolizeFrameCommon(BuildID, ModuleOffset); } template Expected> LLVMSymbolizer::findSymbolCommon(const T &ModuleSpecifier, StringRef Symbol, uint64_t Offset) { auto InfoOrErr = getOrCreateModuleInfo(ModuleSpecifier); if (!InfoOrErr) return InfoOrErr.takeError(); SymbolizableModule *Info = *InfoOrErr; std::vector Result; // A null module means an error has already been reported. Return an empty // result. if (!Info) return Result; for (object::SectionedAddress A : Info->findSymbol(Symbol, Offset)) { DILineInfo LineInfo = Info->symbolizeCode( A, DILineInfoSpecifier(Opts.PathStyle, Opts.PrintFunctions), Opts.UseSymbolTable); if (LineInfo.FileName != DILineInfo::BadString) { if (Opts.Demangle) LineInfo.FunctionName = DemangleName(LineInfo.FunctionName, Info); Result.push_back(LineInfo); } } return Result; } Expected> LLVMSymbolizer::findSymbol(const ObjectFile &Obj, StringRef Symbol, uint64_t Offset) { return findSymbolCommon(Obj, Symbol, Offset); } Expected> LLVMSymbolizer::findSymbol(const std::string &ModuleName, StringRef Symbol, uint64_t Offset) { return findSymbolCommon(ModuleName, Symbol, Offset); } Expected> LLVMSymbolizer::findSymbol(ArrayRef BuildID, StringRef Symbol, uint64_t Offset) { return findSymbolCommon(BuildID, Symbol, Offset); } void LLVMSymbolizer::flush() { ObjectForUBPathAndArch.clear(); LRUBinaries.clear(); CacheSize = 0; BinaryForPath.clear(); ObjectPairForPathArch.clear(); Modules.clear(); BuildIDPaths.clear(); } namespace { // For Path="/path/to/foo" and Basename="foo" assume that debug info is in // /path/to/foo.dSYM/Contents/Resources/DWARF/foo. // For Path="/path/to/bar.dSYM" and Basename="foo" assume that debug info is in // /path/to/bar.dSYM/Contents/Resources/DWARF/foo. std::string getDarwinDWARFResourceForPath(const std::string &Path, const std::string &Basename) { SmallString<16> ResourceName = StringRef(Path); if (sys::path::extension(Path) != ".dSYM") { ResourceName += ".dSYM"; } sys::path::append(ResourceName, "Contents", "Resources", "DWARF"); sys::path::append(ResourceName, Basename); return std::string(ResourceName); } bool checkFileCRC(StringRef Path, uint32_t CRCHash) { ErrorOr> MB = MemoryBuffer::getFileOrSTDIN(Path); if (!MB) return false; return CRCHash == llvm::crc32(arrayRefFromStringRef(MB.get()->getBuffer())); } bool getGNUDebuglinkContents(const ObjectFile *Obj, std::string &DebugName, uint32_t &CRCHash) { if (!Obj) return false; for (const SectionRef &Section : Obj->sections()) { StringRef Name; consumeError(Section.getName().moveInto(Name)); Name = Name.substr(Name.find_first_not_of("._")); if (Name == "gnu_debuglink") { Expected ContentsOrErr = Section.getContents(); if (!ContentsOrErr) { consumeError(ContentsOrErr.takeError()); return false; } DataExtractor DE(*ContentsOrErr, Obj->isLittleEndian(), 0); uint64_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; } bool darwinDsymMatchesBinary(const MachOObjectFile *DbgObj, const MachOObjectFile *Obj) { ArrayRef dbg_uuid = DbgObj->getUuid(); ArrayRef bin_uuid = Obj->getUuid(); if (dbg_uuid.empty() || bin_uuid.empty()) return false; return !memcmp(dbg_uuid.data(), bin_uuid.data(), dbg_uuid.size()); } } // end anonymous namespace ObjectFile *LLVMSymbolizer::lookUpDsymFile(const std::string &ExePath, const MachOObjectFile *MachExeObj, const std::string &ArchName) { // On Darwin we may find DWARF in separate object file in // resource directory. std::vector DsymPaths; StringRef Filename = sys::path::filename(ExePath); DsymPaths.push_back( getDarwinDWARFResourceForPath(ExePath, std::string(Filename))); for (const auto &Path : Opts.DsymHints) { DsymPaths.push_back( getDarwinDWARFResourceForPath(Path, std::string(Filename))); } for (const auto &Path : DsymPaths) { auto DbgObjOrErr = getOrCreateObject(Path, ArchName); if (!DbgObjOrErr) { // Ignore errors, the file might not exist. consumeError(DbgObjOrErr.takeError()); continue; } ObjectFile *DbgObj = DbgObjOrErr.get(); if (!DbgObj) continue; const MachOObjectFile *MachDbgObj = dyn_cast(DbgObj); if (!MachDbgObj) continue; if (darwinDsymMatchesBinary(MachDbgObj, MachExeObj)) return DbgObj; } return nullptr; } ObjectFile *LLVMSymbolizer::lookUpDebuglinkObject(const std::string &Path, const ObjectFile *Obj, const std::string &ArchName) { std::string DebuglinkName; uint32_t CRCHash; std::string DebugBinaryPath; if (!getGNUDebuglinkContents(Obj, DebuglinkName, CRCHash)) return nullptr; if (!findDebugBinary(Path, DebuglinkName, CRCHash, DebugBinaryPath)) return nullptr; auto DbgObjOrErr = getOrCreateObject(DebugBinaryPath, ArchName); if (!DbgObjOrErr) { // Ignore errors, the file might not exist. consumeError(DbgObjOrErr.takeError()); return nullptr; } return DbgObjOrErr.get(); } ObjectFile *LLVMSymbolizer::lookUpBuildIDObject(const std::string &Path, const ELFObjectFileBase *Obj, const std::string &ArchName) { auto BuildID = getBuildID(Obj); if (BuildID.size() < 2) return nullptr; std::string DebugBinaryPath; if (!getOrFindDebugBinary(BuildID, DebugBinaryPath)) return nullptr; auto DbgObjOrErr = getOrCreateObject(DebugBinaryPath, ArchName); if (!DbgObjOrErr) { consumeError(DbgObjOrErr.takeError()); return nullptr; } return DbgObjOrErr.get(); } bool LLVMSymbolizer::findDebugBinary(const std::string &OrigPath, const std::string &DebuglinkName, uint32_t CRCHash, std::string &Result) { SmallString<16> OrigDir(OrigPath); llvm::sys::path::remove_filename(OrigDir); SmallString<16> DebugPath = OrigDir; // Try relative/path/to/original_binary/debuglink_name llvm::sys::path::append(DebugPath, DebuglinkName); if (checkFileCRC(DebugPath, CRCHash)) { Result = std::string(DebugPath); return true; } // Try relative/path/to/original_binary/.debug/debuglink_name DebugPath = OrigDir; llvm::sys::path::append(DebugPath, ".debug", DebuglinkName); if (checkFileCRC(DebugPath, CRCHash)) { Result = std::string(DebugPath); return true; } // Make the path absolute so that lookups will go to // "/usr/lib/debug/full/path/to/debug", not // "/usr/lib/debug/to/debug" llvm::sys::fs::make_absolute(OrigDir); if (!Opts.FallbackDebugPath.empty()) { // Try /absolute/path/to/original_binary/debuglink_name DebugPath = Opts.FallbackDebugPath; } else { #if defined(__NetBSD__) // Try /usr/libdata/debug/absolute/path/to/original_binary/debuglink_name DebugPath = "/usr/libdata/debug"; #else // Try /usr/lib/debug/absolute/path/to/original_binary/debuglink_name DebugPath = "/usr/lib/debug"; #endif } llvm::sys::path::append(DebugPath, llvm::sys::path::relative_path(OrigDir), DebuglinkName); if (checkFileCRC(DebugPath, CRCHash)) { Result = std::string(DebugPath); return true; } return false; } static StringRef getBuildIDStr(ArrayRef BuildID) { return StringRef(reinterpret_cast(BuildID.data()), BuildID.size()); } bool LLVMSymbolizer::getOrFindDebugBinary(const ArrayRef BuildID, std::string &Result) { StringRef BuildIDStr = getBuildIDStr(BuildID); auto I = BuildIDPaths.find(BuildIDStr); if (I != BuildIDPaths.end()) { Result = I->second; return true; } if (!BIDFetcher) return false; if (std::optional Path = BIDFetcher->fetch(BuildID)) { Result = *Path; auto InsertResult = BuildIDPaths.insert({BuildIDStr, Result}); assert(InsertResult.second); (void)InsertResult; return true; } return false; } Expected LLVMSymbolizer::getOrCreateObjectPair(const std::string &Path, const std::string &ArchName) { auto I = ObjectPairForPathArch.find(std::make_pair(Path, ArchName)); if (I != ObjectPairForPathArch.end()) { recordAccess(BinaryForPath.find(Path)->second); return I->second; } auto ObjOrErr = getOrCreateObject(Path, ArchName); if (!ObjOrErr) { ObjectPairForPathArch.emplace(std::make_pair(Path, ArchName), ObjectPair(nullptr, nullptr)); return ObjOrErr.takeError(); } ObjectFile *Obj = ObjOrErr.get(); assert(Obj != nullptr); ObjectFile *DbgObj = nullptr; if (auto MachObj = dyn_cast(Obj)) DbgObj = lookUpDsymFile(Path, MachObj, ArchName); else if (auto ELFObj = dyn_cast(Obj)) DbgObj = lookUpBuildIDObject(Path, ELFObj, ArchName); if (!DbgObj) DbgObj = lookUpDebuglinkObject(Path, Obj, ArchName); if (!DbgObj) DbgObj = Obj; ObjectPair Res = std::make_pair(Obj, DbgObj); std::string DbgObjPath = DbgObj->getFileName().str(); auto Pair = ObjectPairForPathArch.emplace(std::make_pair(Path, ArchName), Res); BinaryForPath.find(DbgObjPath)->second.pushEvictor([this, I = Pair.first]() { ObjectPairForPathArch.erase(I); }); return Res; } Expected LLVMSymbolizer::getOrCreateObject(const std::string &Path, const std::string &ArchName) { Binary *Bin; auto Pair = BinaryForPath.emplace(Path, OwningBinary()); if (!Pair.second) { Bin = Pair.first->second->getBinary(); recordAccess(Pair.first->second); } else { Expected> BinOrErr = createBinary(Path); if (!BinOrErr) return BinOrErr.takeError(); CachedBinary &CachedBin = Pair.first->second; CachedBin = std::move(BinOrErr.get()); CachedBin.pushEvictor([this, I = Pair.first]() { BinaryForPath.erase(I); }); LRUBinaries.push_back(CachedBin); CacheSize += CachedBin.size(); Bin = CachedBin->getBinary(); } if (!Bin) return static_cast(nullptr); if (MachOUniversalBinary *UB = dyn_cast_or_null(Bin)) { auto I = ObjectForUBPathAndArch.find(std::make_pair(Path, ArchName)); if (I != ObjectForUBPathAndArch.end()) return I->second.get(); Expected> ObjOrErr = UB->getMachOObjectForArch(ArchName); if (!ObjOrErr) { ObjectForUBPathAndArch.emplace(std::make_pair(Path, ArchName), std::unique_ptr()); return ObjOrErr.takeError(); } ObjectFile *Res = ObjOrErr->get(); auto Pair = ObjectForUBPathAndArch.emplace(std::make_pair(Path, ArchName), std::move(ObjOrErr.get())); BinaryForPath.find(Path)->second.pushEvictor( [this, Iter = Pair.first]() { ObjectForUBPathAndArch.erase(Iter); }); return Res; } if (Bin->isObject()) { return cast(Bin); } return errorCodeToError(object_error::arch_not_found); } Expected LLVMSymbolizer::createModuleInfo(const ObjectFile *Obj, std::unique_ptr Context, StringRef ModuleName) { auto InfoOrErr = SymbolizableObjectFile::create(Obj, std::move(Context), Opts.UntagAddresses); std::unique_ptr SymMod; if (InfoOrErr) SymMod = std::move(*InfoOrErr); auto InsertResult = Modules.insert( std::make_pair(std::string(ModuleName), std::move(SymMod))); assert(InsertResult.second); if (!InfoOrErr) return InfoOrErr.takeError(); return InsertResult.first->second.get(); } Expected LLVMSymbolizer::getOrCreateModuleInfo(const std::string &ModuleName) { 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; } } auto I = Modules.find(ModuleName); if (I != Modules.end()) { recordAccess(BinaryForPath.find(BinaryName)->second); return I->second.get(); } auto ObjectsOrErr = getOrCreateObjectPair(BinaryName, ArchName); if (!ObjectsOrErr) { // Failed to find valid object file. Modules.emplace(ModuleName, std::unique_ptr()); return ObjectsOrErr.takeError(); } ObjectPair Objects = ObjectsOrErr.get(); std::unique_ptr Context; // If this is a COFF object containing PDB info, use a PDBContext to // symbolize. Otherwise, use DWARF. if (auto CoffObject = dyn_cast(Objects.first)) { const codeview::DebugInfo *DebugInfo; StringRef PDBFileName; auto EC = CoffObject->getDebugPDBInfo(DebugInfo, PDBFileName); if (!EC && DebugInfo != nullptr && !PDBFileName.empty()) { #if 0 using namespace pdb; std::unique_ptr Session; PDB_ReaderType ReaderType = Opts.UseDIA ? PDB_ReaderType::DIA : PDB_ReaderType::Native; if (auto Err = loadDataForEXE(ReaderType, Objects.first->getFileName(), Session)) { Modules.emplace(ModuleName, std::unique_ptr()); // Return along the PDB filename to provide more context return createFileError(PDBFileName, std::move(Err)); } Context.reset(new PDBContext(*CoffObject, std::move(Session))); #else return make_error( "PDB support not compiled in", std::make_error_code(std::errc::not_supported)); #endif } } if (!Context) Context = DWARFContext::create( *Objects.second, DWARFContext::ProcessDebugRelocations::Process, nullptr, Opts.DWPName); auto ModuleOrErr = createModuleInfo(Objects.first, std::move(Context), ModuleName); if (ModuleOrErr) { auto I = Modules.find(ModuleName); BinaryForPath.find(BinaryName)->second.pushEvictor([this, I]() { Modules.erase(I); }); } return ModuleOrErr; } // For BPF programs .BTF.ext section contains line numbers information, // use it if regular DWARF is not available (e.g. for stripped binary). static bool useBTFContext(const ObjectFile &Obj) { return Obj.makeTriple().isBPF() && !Obj.hasDebugInfo() && BTFParser::hasBTFSections(Obj); } Expected LLVMSymbolizer::getOrCreateModuleInfo(const ObjectFile &Obj) { StringRef ObjName = Obj.getFileName(); auto I = Modules.find(ObjName); if (I != Modules.end()) return I->second.get(); std::unique_ptr Context; if (useBTFContext(Obj)) Context = BTFContext::create(Obj); else Context = DWARFContext::create(Obj); // FIXME: handle COFF object with PDB info to use PDBContext return createModuleInfo(&Obj, std::move(Context), ObjName); } Expected LLVMSymbolizer::getOrCreateModuleInfo(ArrayRef BuildID) { std::string Path; if (!getOrFindDebugBinary(BuildID, Path)) { return createStringError(errc::no_such_file_or_directory, "could not find build ID"); } return getOrCreateModuleInfo(Path); } namespace { // Undo these various manglings for Win32 extern "C" functions: // cdecl - _foo // stdcall - _foo@12 // fastcall - @foo@12 // vectorcall - foo@@12 // These are all different linkage names for 'foo'. StringRef demanglePE32ExternCFunc(StringRef SymbolName) { char Front = SymbolName.empty() ? '\0' : SymbolName[0]; // Remove any '@[0-9]+' suffix. bool HasAtNumSuffix = false; if (Front != '?') { size_t AtPos = SymbolName.rfind('@'); if (AtPos != StringRef::npos && all_of(drop_begin(SymbolName, AtPos + 1), isDigit)) { SymbolName = SymbolName.substr(0, AtPos); HasAtNumSuffix = true; } } // Remove any ending '@' for vectorcall. bool IsVectorCall = false; if (HasAtNumSuffix && SymbolName.ends_with("@")) { SymbolName = SymbolName.drop_back(); IsVectorCall = true; } // If not vectorcall, remove any '_' or '@' prefix. if (!IsVectorCall && (Front == '_' || Front == '@')) SymbolName = SymbolName.drop_front(); return SymbolName; } } // end anonymous namespace std::string LLVMSymbolizer::DemangleName(const std::string &Name, const SymbolizableModule *DbiModuleDescriptor) { std::string Result; if (nonMicrosoftDemangle(Name, Result)) return Result; if (!Name.empty() && Name.front() == '?') { // Only do MSVC C++ demangling on symbols starting with '?'. int status = 0; char *DemangledName = microsoftDemangle( Name, nullptr, &status, MSDemangleFlags(MSDF_NoAccessSpecifier | MSDF_NoCallingConvention | MSDF_NoMemberType | MSDF_NoReturnType)); if (status != 0) return Name; Result = DemangledName; free(DemangledName); return Result; } if (DbiModuleDescriptor && DbiModuleDescriptor->isWin32Module()) { std::string DemangledCName(demanglePE32ExternCFunc(Name)); // On i386 Windows, the C name mangling for different calling conventions // may also be applied on top of the Itanium or Rust name mangling. if (nonMicrosoftDemangle(DemangledCName, Result)) return Result; return DemangledCName; } return Name; } void LLVMSymbolizer::recordAccess(CachedBinary &Bin) { if (Bin->getBinary()) LRUBinaries.splice(LRUBinaries.end(), LRUBinaries, Bin.getIterator()); } void LLVMSymbolizer::pruneCache() { // Evict the LRU binary until the max cache size is reached or there's <= 1 // item in the cache. The MRU binary is always kept to avoid thrashing if it's // larger than the cache size. while (CacheSize > Opts.MaxCacheSize && !LRUBinaries.empty() && std::next(LRUBinaries.begin()) != LRUBinaries.end()) { CachedBinary &Bin = LRUBinaries.front(); CacheSize -= Bin.size(); LRUBinaries.pop_front(); Bin.evict(); } } void CachedBinary::pushEvictor(std::function NewEvictor) { if (Evictor) { this->Evictor = [OldEvictor = std::move(this->Evictor), NewEvictor = std::move(NewEvictor)]() { NewEvictor(); OldEvictor(); }; } else { this->Evictor = std::move(NewEvictor); } } } // namespace symbolize } // namespace llvm