//===-- llvm-dwp.cpp - Split DWARF merging tool for llvm ------------------===// // // 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 // //===----------------------------------------------------------------------===// // // A utility for merging DWARF 5 Split DWARF .dwo files into .dwp (DWARF // package files). // //===----------------------------------------------------------------------===// #include "DWPError.h" #include "DWPStringPool.h" #include "llvm/ADT/MapVector.h" #include "llvm/ADT/Optional.h" #include "llvm/ADT/STLExtras.h" #include "llvm/DebugInfo/DWARF/DWARFContext.h" #include "llvm/DebugInfo/DWARF/DWARFDataExtractor.h" #include "llvm/DebugInfo/DWARF/DWARFFormValue.h" #include "llvm/DebugInfo/DWARF/DWARFUnitIndex.h" #include "llvm/MC/MCAsmBackend.h" #include "llvm/MC/MCAsmInfo.h" #include "llvm/MC/MCCodeEmitter.h" #include "llvm/MC/MCContext.h" #include "llvm/MC/MCInstrInfo.h" #include "llvm/MC/MCObjectFileInfo.h" #include "llvm/MC/MCObjectWriter.h" #include "llvm/MC/MCRegisterInfo.h" #include "llvm/MC/MCStreamer.h" #include "llvm/MC/MCTargetOptionsCommandFlags.h" #include "llvm/Object/Decompressor.h" #include "llvm/Object/ObjectFile.h" #include "llvm/Support/CommandLine.h" #include "llvm/Support/DataExtractor.h" #include "llvm/Support/Error.h" #include "llvm/Support/FileSystem.h" #include "llvm/Support/InitLLVM.h" #include "llvm/Support/MathExtras.h" #include "llvm/Support/MemoryBuffer.h" #include "llvm/Support/Path.h" #include "llvm/Support/TargetRegistry.h" #include "llvm/Support/TargetSelect.h" #include "llvm/Support/ToolOutputFile.h" #include "llvm/Support/WithColor.h" #include "llvm/Support/raw_ostream.h" using namespace llvm; using namespace llvm::object; static mc::RegisterMCTargetOptionsFlags MCTargetOptionsFlags; cl::OptionCategory DwpCategory("Specific Options"); static cl::list InputFiles(cl::Positional, cl::ZeroOrMore, cl::desc(""), cl::cat(DwpCategory)); static cl::list ExecFilenames( "e", cl::ZeroOrMore, cl::desc("Specify the executable/library files to get the list of *.dwo from"), cl::value_desc("filename"), cl::cat(DwpCategory)); static cl::opt OutputFilename(cl::Required, "o", cl::desc("Specify the output file."), cl::value_desc("filename"), cl::cat(DwpCategory)); // Returns the size of debug_str_offsets section headers in bytes. static uint64_t debugStrOffsetsHeaderSize(DataExtractor StrOffsetsData, uint16_t DwarfVersion) { if (DwarfVersion <= 4) return 0; // There is no header before dwarf 5. uint64_t Offset = 0; uint64_t Length = StrOffsetsData.getU32(&Offset); if (Length == llvm::dwarf::DW_LENGTH_DWARF64) return 16; // unit length: 12 bytes, version: 2 bytes, padding: 2 bytes. return 8; // unit length: 4 bytes, version: 2 bytes, padding: 2 bytes. } // Holds data for Skeleton and Split Compilation Unit Headers as defined in // Dwarf 5 specification, 7.5.1.2 and Dwarf 4 specification 7.5.1.1. struct CompileUnitHeader { // unit_length field. Note that the type is uint64_t even in 32-bit dwarf. uint64_t Length = 0; // version field. uint16_t Version = 0; // unit_type field. Initialized only if Version >= 5. uint8_t UnitType = 0; // address_size field. uint8_t AddrSize = 0; // debug_abbrev_offset field. Note that the type is uint64_t even in 32-bit // dwarf. It is assumed to be 0. uint64_t DebugAbbrevOffset = 0; // dwo_id field. This resides in the header only if Version >= 5. // In earlier versions, it is read from DW_AT_GNU_dwo_id. Optional Signature = None; // Derived from the length of Length field. dwarf::DwarfFormat Format = dwarf::DwarfFormat::DWARF32; // The size of the Header in bytes. This is derived while parsing the header, // and is stored as a convenience. uint8_t HeaderSize = 0; }; // Parse and return the header of the compile unit. static Expected parseCompileUnitHeader(StringRef Info) { CompileUnitHeader Header; Error Err = Error::success(); uint64_t Offset = 0; DWARFDataExtractor InfoData(Info, true, 0); std::tie(Header.Length, Header.Format) = InfoData.getInitialLength(&Offset, &Err); if (Err) return make_error("cannot parse compile unit length: " + llvm::toString(std::move(Err))); if (!InfoData.isValidOffset(Offset + (Header.Length - 1))) { return make_error( "compile unit exceeds .debug_info section range: " + utostr(Offset + Header.Length) + " >= " + utostr(InfoData.size())); } Header.Version = InfoData.getU16(&Offset, &Err); if (Err) return make_error("cannot parse compile unit version: " + llvm::toString(std::move(Err))); uint64_t MinHeaderLength; if (Header.Version >= 5) { // Size: Version (2), UnitType (1), AddrSize (1), DebugAbbrevOffset (4), // Signature (8) MinHeaderLength = 16; } else { // Size: Version (2), DebugAbbrevOffset (4), AddrSize (1) MinHeaderLength = 7; } if (Header.Length < MinHeaderLength) { return make_error( "compile unit length is too small: expected at least " + utostr(MinHeaderLength) + " got " + utostr(Header.Length) + "."); } if (Header.Version >= 5) { Header.UnitType = InfoData.getU8(&Offset); Header.AddrSize = InfoData.getU8(&Offset); Header.DebugAbbrevOffset = InfoData.getU32(&Offset); Header.Signature = InfoData.getU64(&Offset); } else { // Note that, address_size and debug_abbrev_offset fields have switched // places between dwarf version 4 and 5. Header.DebugAbbrevOffset = InfoData.getU32(&Offset); Header.AddrSize = InfoData.getU8(&Offset); } Header.HeaderSize = Offset; return Header; } static void writeStringsAndOffsets(MCStreamer &Out, DWPStringPool &Strings, MCSection *StrOffsetSection, StringRef CurStrSection, StringRef CurStrOffsetSection, const CompileUnitHeader &Header) { // Could possibly produce an error or warning if one of these was non-null but // the other was null. if (CurStrSection.empty() || CurStrOffsetSection.empty()) return; DenseMap OffsetRemapping; DataExtractor Data(CurStrSection, true, 0); uint64_t LocalOffset = 0; uint64_t PrevOffset = 0; while (const char *s = Data.getCStr(&LocalOffset)) { OffsetRemapping[PrevOffset] = Strings.getOffset(s, LocalOffset - PrevOffset); PrevOffset = LocalOffset; } Data = DataExtractor(CurStrOffsetSection, true, 0); Out.SwitchSection(StrOffsetSection); uint64_t HeaderSize = debugStrOffsetsHeaderSize(Data, Header.Version); uint64_t Offset = 0; uint64_t Size = CurStrOffsetSection.size(); // FIXME: This can be caused by bad input and should be handled as such. assert(HeaderSize <= Size && "StrOffsetSection size is less than its header"); // Copy the header to the output. Out.emitBytes(Data.getBytes(&Offset, HeaderSize)); while (Offset < Size) { auto OldOffset = Data.getU32(&Offset); auto NewOffset = OffsetRemapping[OldOffset]; Out.emitIntValue(NewOffset, 4); } } static uint64_t getCUAbbrev(StringRef Abbrev, uint64_t AbbrCode) { uint64_t Offset = 0; DataExtractor AbbrevData(Abbrev, true, 0); while (AbbrevData.getULEB128(&Offset) != AbbrCode) { // Tag AbbrevData.getULEB128(&Offset); // DW_CHILDREN AbbrevData.getU8(&Offset); // Attributes while (AbbrevData.getULEB128(&Offset) | AbbrevData.getULEB128(&Offset)) ; } return Offset; } struct CompileUnitIdentifiers { uint64_t Signature = 0; const char *Name = ""; const char *DWOName = ""; }; static Expected getIndexedString(dwarf::Form Form, DataExtractor InfoData, uint64_t &InfoOffset, StringRef StrOffsets, StringRef Str, uint16_t Version) { if (Form == dwarf::DW_FORM_string) return InfoData.getCStr(&InfoOffset); uint64_t StrIndex; switch (Form) { case dwarf::DW_FORM_strx1: StrIndex = InfoData.getU8(&InfoOffset); break; case dwarf::DW_FORM_strx2: StrIndex = InfoData.getU16(&InfoOffset); break; case dwarf::DW_FORM_strx3: StrIndex = InfoData.getU24(&InfoOffset); break; case dwarf::DW_FORM_strx4: StrIndex = InfoData.getU32(&InfoOffset); break; case dwarf::DW_FORM_strx: case dwarf::DW_FORM_GNU_str_index: StrIndex = InfoData.getULEB128(&InfoOffset); break; default: return make_error( "string field must be encoded with one of the following: " "DW_FORM_string, DW_FORM_strx, DW_FORM_strx1, DW_FORM_strx2, " "DW_FORM_strx3, DW_FORM_strx4, or DW_FORM_GNU_str_index."); } DataExtractor StrOffsetsData(StrOffsets, true, 0); uint64_t StrOffsetsOffset = 4 * StrIndex; StrOffsetsOffset += debugStrOffsetsHeaderSize(StrOffsetsData, Version); uint64_t StrOffset = StrOffsetsData.getU32(&StrOffsetsOffset); DataExtractor StrData(Str, true, 0); return StrData.getCStr(&StrOffset); } static Expected getCUIdentifiers(StringRef Abbrev, StringRef Info, StringRef StrOffsets, StringRef Str) { Expected HeaderOrError = parseCompileUnitHeader(Info); if (!HeaderOrError) return HeaderOrError.takeError(); CompileUnitHeader &Header = *HeaderOrError; DataExtractor InfoData(Info, true, 0); uint64_t Offset = Header.HeaderSize; if (Header.Version >= 5 && Header.UnitType != dwarf::DW_UT_split_compile) return make_error( std::string("unit type DW_UT_split_compile type not found in " "debug_info header. Unexpected unit type 0x" + utostr(Header.UnitType) + " found")); CompileUnitIdentifiers ID; uint32_t AbbrCode = InfoData.getULEB128(&Offset); DataExtractor AbbrevData(Abbrev, true, 0); uint64_t AbbrevOffset = getCUAbbrev(Abbrev, AbbrCode); auto Tag = static_cast(AbbrevData.getULEB128(&AbbrevOffset)); if (Tag != dwarf::DW_TAG_compile_unit) return make_error("top level DIE is not a compile unit"); // DW_CHILDREN AbbrevData.getU8(&AbbrevOffset); uint32_t Name; dwarf::Form Form; while ((Name = AbbrevData.getULEB128(&AbbrevOffset)) | (Form = static_cast(AbbrevData.getULEB128(&AbbrevOffset))) && (Name != 0 || Form != 0)) { switch (Name) { case dwarf::DW_AT_name: { Expected EName = getIndexedString( Form, InfoData, Offset, StrOffsets, Str, Header.Version); if (!EName) return EName.takeError(); ID.Name = *EName; break; } case dwarf::DW_AT_GNU_dwo_name: case dwarf::DW_AT_dwo_name: { Expected EName = getIndexedString( Form, InfoData, Offset, StrOffsets, Str, Header.Version); if (!EName) return EName.takeError(); ID.DWOName = *EName; break; } case dwarf::DW_AT_GNU_dwo_id: Header.Signature = InfoData.getU64(&Offset); break; default: DWARFFormValue::skipValue( Form, InfoData, &Offset, dwarf::FormParams({Header.Version, Header.AddrSize, Header.Format})); } } if (!Header.Signature) return make_error("compile unit missing dwo_id"); ID.Signature = *Header.Signature; return ID; } struct UnitIndexEntry { DWARFUnitIndex::Entry::SectionContribution Contributions[8]; std::string Name; std::string DWOName; StringRef DWPName; }; static bool isSupportedSectionKind(DWARFSectionKind Kind) { return Kind != DW_SECT_EXT_unknown; } // Convert an internal section identifier into the index to use with // UnitIndexEntry::Contributions. static unsigned getContributionIndex(DWARFSectionKind Kind) { // Assuming the pre-standard DWP format. assert(serializeSectionKind(Kind, 2) >= DW_SECT_INFO); return serializeSectionKind(Kind, 2) - DW_SECT_INFO; } // Convert a UnitIndexEntry::Contributions index to the corresponding on-disk // value of the section identifier. static unsigned getOnDiskSectionId(unsigned Index) { return Index + DW_SECT_INFO; } static StringRef getSubsection(StringRef Section, const DWARFUnitIndex::Entry &Entry, DWARFSectionKind Kind) { const auto *Off = Entry.getContribution(Kind); if (!Off) return StringRef(); return Section.substr(Off->Offset, Off->Length); } static void addAllTypesFromDWP( MCStreamer &Out, MapVector &TypeIndexEntries, const DWARFUnitIndex &TUIndex, MCSection *OutputTypes, StringRef Types, const UnitIndexEntry &TUEntry, uint32_t &TypesOffset) { Out.SwitchSection(OutputTypes); for (const DWARFUnitIndex::Entry &E : TUIndex.getRows()) { auto *I = E.getContributions(); if (!I) continue; auto P = TypeIndexEntries.insert(std::make_pair(E.getSignature(), TUEntry)); if (!P.second) continue; auto &Entry = P.first->second; // Zero out the debug_info contribution Entry.Contributions[0] = {}; for (auto Kind : TUIndex.getColumnKinds()) { if (!isSupportedSectionKind(Kind)) continue; auto &C = Entry.Contributions[getContributionIndex(Kind)]; C.Offset += I->Offset; C.Length = I->Length; ++I; } unsigned TypesIndex = getContributionIndex(DW_SECT_EXT_TYPES); auto &C = Entry.Contributions[TypesIndex]; Out.emitBytes(Types.substr( C.Offset - TUEntry.Contributions[TypesIndex].Offset, C.Length)); C.Offset = TypesOffset; TypesOffset += C.Length; } } static void addAllTypes(MCStreamer &Out, MapVector &TypeIndexEntries, MCSection *OutputTypes, const std::vector &TypesSections, const UnitIndexEntry &CUEntry, uint32_t &TypesOffset) { for (StringRef Types : TypesSections) { Out.SwitchSection(OutputTypes); uint64_t Offset = 0; DataExtractor Data(Types, true, 0); while (Data.isValidOffset(Offset)) { UnitIndexEntry Entry = CUEntry; // Zero out the debug_info contribution Entry.Contributions[0] = {}; auto &C = Entry.Contributions[getContributionIndex(DW_SECT_EXT_TYPES)]; C.Offset = TypesOffset; auto PrevOffset = Offset; // Length of the unit, including the 4 byte length field. C.Length = Data.getU32(&Offset) + 4; Data.getU16(&Offset); // Version Data.getU32(&Offset); // Abbrev offset Data.getU8(&Offset); // Address size auto Signature = Data.getU64(&Offset); Offset = PrevOffset + C.Length; auto P = TypeIndexEntries.insert(std::make_pair(Signature, Entry)); if (!P.second) continue; Out.emitBytes(Types.substr(PrevOffset, C.Length)); TypesOffset += C.Length; } } } static void writeIndexTable(MCStreamer &Out, ArrayRef ContributionOffsets, const MapVector &IndexEntries, uint32_t DWARFUnitIndex::Entry::SectionContribution::*Field) { for (const auto &E : IndexEntries) for (size_t i = 0; i != array_lengthof(E.second.Contributions); ++i) if (ContributionOffsets[i]) Out.emitIntValue(E.second.Contributions[i].*Field, 4); } static void writeIndex(MCStreamer &Out, MCSection *Section, ArrayRef ContributionOffsets, const MapVector &IndexEntries) { if (IndexEntries.empty()) return; unsigned Columns = 0; for (auto &C : ContributionOffsets) if (C) ++Columns; std::vector Buckets(NextPowerOf2(3 * IndexEntries.size() / 2)); uint64_t Mask = Buckets.size() - 1; size_t i = 0; for (const auto &P : IndexEntries) { auto S = P.first; auto H = S & Mask; auto HP = ((S >> 32) & Mask) | 1; while (Buckets[H]) { assert(S != IndexEntries.begin()[Buckets[H] - 1].first && "Duplicate unit"); H = (H + HP) & Mask; } Buckets[H] = i + 1; ++i; } Out.SwitchSection(Section); Out.emitIntValue(2, 4); // Version Out.emitIntValue(Columns, 4); // Columns Out.emitIntValue(IndexEntries.size(), 4); // Num Units Out.emitIntValue(Buckets.size(), 4); // Num Buckets // Write the signatures. for (const auto &I : Buckets) Out.emitIntValue(I ? IndexEntries.begin()[I - 1].first : 0, 8); // Write the indexes. for (const auto &I : Buckets) Out.emitIntValue(I, 4); // Write the column headers (which sections will appear in the table) for (size_t i = 0; i != ContributionOffsets.size(); ++i) if (ContributionOffsets[i]) Out.emitIntValue(getOnDiskSectionId(i), 4); // Write the offsets. writeIndexTable(Out, ContributionOffsets, IndexEntries, &DWARFUnitIndex::Entry::SectionContribution::Offset); // Write the lengths. writeIndexTable(Out, ContributionOffsets, IndexEntries, &DWARFUnitIndex::Entry::SectionContribution::Length); } static std::string buildDWODescription(StringRef Name, StringRef DWPName, StringRef DWOName) { std::string Text = "\'"; Text += Name; Text += '\''; if (!DWPName.empty()) { Text += " (from "; if (!DWOName.empty()) { Text += '\''; Text += DWOName; Text += "' in "; } Text += '\''; Text += DWPName; Text += "')"; } return Text; } static Error createError(StringRef Name, Error E) { return make_error( ("failure while decompressing compressed section: '" + Name + "', " + llvm::toString(std::move(E))) .str()); } static Error handleCompressedSection(std::deque> &UncompressedSections, StringRef &Name, StringRef &Contents) { if (!Decompressor::isGnuStyle(Name)) return Error::success(); Expected Dec = Decompressor::create(Name, Contents, false /*IsLE*/, false /*Is64Bit*/); if (!Dec) return createError(Name, Dec.takeError()); UncompressedSections.emplace_back(); if (Error E = Dec->resizeAndDecompress(UncompressedSections.back())) return createError(Name, std::move(E)); Name = Name.substr(2); // Drop ".z" Contents = UncompressedSections.back(); return Error::success(); } static Error handleSection( const StringMap> &KnownSections, const MCSection *StrSection, const MCSection *StrOffsetSection, const MCSection *TypesSection, const MCSection *CUIndexSection, const MCSection *TUIndexSection, const SectionRef &Section, MCStreamer &Out, std::deque> &UncompressedSections, uint32_t (&ContributionOffsets)[8], UnitIndexEntry &CurEntry, StringRef &CurStrSection, StringRef &CurStrOffsetSection, std::vector &CurTypesSection, StringRef &InfoSection, StringRef &AbbrevSection, StringRef &CurCUIndexSection, StringRef &CurTUIndexSection) { if (Section.isBSS()) return Error::success(); if (Section.isVirtual()) return Error::success(); Expected NameOrErr = Section.getName(); if (!NameOrErr) return NameOrErr.takeError(); StringRef Name = *NameOrErr; Expected ContentsOrErr = Section.getContents(); if (!ContentsOrErr) return ContentsOrErr.takeError(); StringRef Contents = *ContentsOrErr; if (auto Err = handleCompressedSection(UncompressedSections, Name, Contents)) return Err; Name = Name.substr(Name.find_first_not_of("._")); auto SectionPair = KnownSections.find(Name); if (SectionPair == KnownSections.end()) return Error::success(); if (DWARFSectionKind Kind = SectionPair->second.second) { auto Index = getContributionIndex(Kind); if (Kind != DW_SECT_EXT_TYPES) { CurEntry.Contributions[Index].Offset = ContributionOffsets[Index]; ContributionOffsets[Index] += (CurEntry.Contributions[Index].Length = Contents.size()); } switch (Kind) { case DW_SECT_INFO: InfoSection = Contents; break; case DW_SECT_ABBREV: AbbrevSection = Contents; break; default: break; } } MCSection *OutSection = SectionPair->second.first; if (OutSection == StrOffsetSection) CurStrOffsetSection = Contents; else if (OutSection == StrSection) CurStrSection = Contents; else if (OutSection == TypesSection) CurTypesSection.push_back(Contents); else if (OutSection == CUIndexSection) CurCUIndexSection = Contents; else if (OutSection == TUIndexSection) CurTUIndexSection = Contents; else { Out.SwitchSection(OutSection); Out.emitBytes(Contents); } return Error::success(); } static Error buildDuplicateError(const std::pair &PrevE, const CompileUnitIdentifiers &ID, StringRef DWPName) { return make_error( std::string("duplicate DWO ID (") + utohexstr(PrevE.first) + ") in " + buildDWODescription(PrevE.second.Name, PrevE.second.DWPName, PrevE.second.DWOName) + " and " + buildDWODescription(ID.Name, DWPName, ID.DWOName)); } static Expected> getDWOFilenames(StringRef ExecFilename) { auto ErrOrObj = object::ObjectFile::createObjectFile(ExecFilename); if (!ErrOrObj) return ErrOrObj.takeError(); const ObjectFile &Obj = *ErrOrObj.get().getBinary(); std::unique_ptr DWARFCtx = DWARFContext::create(Obj); SmallVector DWOPaths; for (const auto &CU : DWARFCtx->compile_units()) { const DWARFDie &Die = CU->getUnitDIE(); std::string DWOName = dwarf::toString( Die.find({dwarf::DW_AT_dwo_name, dwarf::DW_AT_GNU_dwo_name}), ""); if (DWOName.empty()) continue; std::string DWOCompDir = dwarf::toString(Die.find(dwarf::DW_AT_comp_dir), ""); if (!DWOCompDir.empty()) { SmallString<16> DWOPath(std::move(DWOName)); sys::fs::make_absolute(DWOCompDir, DWOPath); DWOPaths.emplace_back(DWOPath.data(), DWOPath.size()); } else { DWOPaths.push_back(std::move(DWOName)); } } return std::move(DWOPaths); } static Error write(MCStreamer &Out, ArrayRef Inputs) { const auto &MCOFI = *Out.getContext().getObjectFileInfo(); MCSection *const StrSection = MCOFI.getDwarfStrDWOSection(); MCSection *const StrOffsetSection = MCOFI.getDwarfStrOffDWOSection(); MCSection *const TypesSection = MCOFI.getDwarfTypesDWOSection(); MCSection *const CUIndexSection = MCOFI.getDwarfCUIndexSection(); MCSection *const TUIndexSection = MCOFI.getDwarfTUIndexSection(); const StringMap> KnownSections = { {"debug_info.dwo", {MCOFI.getDwarfInfoDWOSection(), DW_SECT_INFO}}, {"debug_types.dwo", {MCOFI.getDwarfTypesDWOSection(), DW_SECT_EXT_TYPES}}, {"debug_str_offsets.dwo", {StrOffsetSection, DW_SECT_STR_OFFSETS}}, {"debug_str.dwo", {StrSection, static_cast(0)}}, {"debug_loc.dwo", {MCOFI.getDwarfLocDWOSection(), DW_SECT_EXT_LOC}}, {"debug_line.dwo", {MCOFI.getDwarfLineDWOSection(), DW_SECT_LINE}}, {"debug_abbrev.dwo", {MCOFI.getDwarfAbbrevDWOSection(), DW_SECT_ABBREV}}, {"debug_cu_index", {CUIndexSection, static_cast(0)}}, {"debug_tu_index", {TUIndexSection, static_cast(0)}}}; MapVector IndexEntries; MapVector TypeIndexEntries; uint32_t ContributionOffsets[8] = {}; DWPStringPool Strings(Out, StrSection); SmallVector, 128> Objects; Objects.reserve(Inputs.size()); std::deque> UncompressedSections; for (const auto &Input : Inputs) { auto ErrOrObj = object::ObjectFile::createObjectFile(Input); if (!ErrOrObj) return ErrOrObj.takeError(); auto &Obj = *ErrOrObj->getBinary(); Objects.push_back(std::move(*ErrOrObj)); UnitIndexEntry CurEntry = {}; StringRef CurStrSection; StringRef CurStrOffsetSection; std::vector CurTypesSection; StringRef InfoSection; StringRef AbbrevSection; StringRef CurCUIndexSection; StringRef CurTUIndexSection; for (const auto &Section : Obj.sections()) if (auto Err = handleSection( KnownSections, StrSection, StrOffsetSection, TypesSection, CUIndexSection, TUIndexSection, Section, Out, UncompressedSections, ContributionOffsets, CurEntry, CurStrSection, CurStrOffsetSection, CurTypesSection, InfoSection, AbbrevSection, CurCUIndexSection, CurTUIndexSection)) return Err; if (InfoSection.empty()) continue; Expected CompileUnitHeaderOrErr = parseCompileUnitHeader(InfoSection); if (!CompileUnitHeaderOrErr) return CompileUnitHeaderOrErr.takeError(); CompileUnitHeader &CompileUnitHeader = *CompileUnitHeaderOrErr; writeStringsAndOffsets(Out, Strings, StrOffsetSection, CurStrSection, CurStrOffsetSection, CompileUnitHeader); if (CurCUIndexSection.empty()) { Expected EID = getCUIdentifiers( AbbrevSection, InfoSection, CurStrOffsetSection, CurStrSection); if (!EID) return createFileError(Input, EID.takeError()); const auto &ID = *EID; auto P = IndexEntries.insert(std::make_pair(ID.Signature, CurEntry)); if (!P.second) return buildDuplicateError(*P.first, ID, ""); P.first->second.Name = ID.Name; P.first->second.DWOName = ID.DWOName; addAllTypes(Out, TypeIndexEntries, TypesSection, CurTypesSection, CurEntry, ContributionOffsets[getContributionIndex(DW_SECT_EXT_TYPES)]); continue; } DWARFUnitIndex CUIndex(DW_SECT_INFO); DataExtractor CUIndexData(CurCUIndexSection, Obj.isLittleEndian(), 0); if (!CUIndex.parse(CUIndexData)) return make_error("failed to parse cu_index"); if (CUIndex.getVersion() != 2) return make_error( "unsupported cu_index version: " + utostr(CUIndex.getVersion()) + " (only version 2 is supported)"); for (const DWARFUnitIndex::Entry &E : CUIndex.getRows()) { auto *I = E.getContributions(); if (!I) continue; auto P = IndexEntries.insert(std::make_pair(E.getSignature(), CurEntry)); Expected EID = getCUIdentifiers( getSubsection(AbbrevSection, E, DW_SECT_ABBREV), getSubsection(InfoSection, E, DW_SECT_INFO), getSubsection(CurStrOffsetSection, E, DW_SECT_STR_OFFSETS), CurStrSection); if (!EID) return createFileError(Input, EID.takeError()); const auto &ID = *EID; if (!P.second) return buildDuplicateError(*P.first, ID, Input); auto &NewEntry = P.first->second; NewEntry.Name = ID.Name; NewEntry.DWOName = ID.DWOName; NewEntry.DWPName = Input; for (auto Kind : CUIndex.getColumnKinds()) { if (!isSupportedSectionKind(Kind)) continue; auto &C = NewEntry.Contributions[getContributionIndex(Kind)]; C.Offset += I->Offset; C.Length = I->Length; ++I; } } if (!CurTypesSection.empty()) { if (CurTypesSection.size() != 1) return make_error("multiple type unit sections in .dwp file"); DWARFUnitIndex TUIndex(DW_SECT_EXT_TYPES); DataExtractor TUIndexData(CurTUIndexSection, Obj.isLittleEndian(), 0); if (!TUIndex.parse(TUIndexData)) return make_error("failed to parse tu_index"); if (TUIndex.getVersion() != 2) return make_error( "unsupported tu_index version: " + utostr(TUIndex.getVersion()) + " (only version 2 is supported)"); addAllTypesFromDWP( Out, TypeIndexEntries, TUIndex, TypesSection, CurTypesSection.front(), CurEntry, ContributionOffsets[getContributionIndex(DW_SECT_EXT_TYPES)]); } } // Lie about there being no info contributions so the TU index only includes // the type unit contribution ContributionOffsets[0] = 0; writeIndex(Out, MCOFI.getDwarfTUIndexSection(), ContributionOffsets, TypeIndexEntries); // Lie about the type contribution ContributionOffsets[getContributionIndex(DW_SECT_EXT_TYPES)] = 0; // Unlie about the info contribution ContributionOffsets[0] = 1; writeIndex(Out, MCOFI.getDwarfCUIndexSection(), ContributionOffsets, IndexEntries); return Error::success(); } static int error(const Twine &Error, const Twine &Context) { errs() << Twine("while processing ") + Context + ":\n"; errs() << Twine("error: ") + Error + "\n"; return 1; } static Expected readTargetTriple(StringRef FileName) { auto ErrOrObj = object::ObjectFile::createObjectFile(FileName); if (!ErrOrObj) return ErrOrObj.takeError(); return ErrOrObj->getBinary()->makeTriple(); } int main(int argc, char **argv) { InitLLVM X(argc, argv); cl::ParseCommandLineOptions(argc, argv, "merge split dwarf (.dwo) files\n"); llvm::InitializeAllTargetInfos(); llvm::InitializeAllTargetMCs(); llvm::InitializeAllTargets(); llvm::InitializeAllAsmPrinters(); std::vector DWOFilenames = InputFiles; for (const auto &ExecFilename : ExecFilenames) { auto DWOs = getDWOFilenames(ExecFilename); if (!DWOs) { logAllUnhandledErrors(DWOs.takeError(), WithColor::error()); return 1; } DWOFilenames.insert(DWOFilenames.end(), std::make_move_iterator(DWOs->begin()), std::make_move_iterator(DWOs->end())); } if (DWOFilenames.empty()) return 0; std::string ErrorStr; StringRef Context = "dwarf streamer init"; auto ErrOrTriple = readTargetTriple(DWOFilenames.front()); if (!ErrOrTriple) { logAllUnhandledErrors(ErrOrTriple.takeError(), WithColor::error()); return 1; } // Get the target. const Target *TheTarget = TargetRegistry::lookupTarget("", *ErrOrTriple, ErrorStr); if (!TheTarget) return error(ErrorStr, Context); std::string TripleName = ErrOrTriple->getTriple(); // Create all the MC Objects. std::unique_ptr MRI(TheTarget->createMCRegInfo(TripleName)); if (!MRI) return error(Twine("no register info for target ") + TripleName, Context); MCTargetOptions MCOptions = llvm::mc::InitMCTargetOptionsFromFlags(); std::unique_ptr MAI( TheTarget->createMCAsmInfo(*MRI, TripleName, MCOptions)); if (!MAI) return error("no asm info for target " + TripleName, Context); std::unique_ptr MSTI( TheTarget->createMCSubtargetInfo(TripleName, "", "")); if (!MSTI) return error("no subtarget info for target " + TripleName, Context); MCContext MC(*ErrOrTriple, MAI.get(), MRI.get(), MSTI.get()); std::unique_ptr MOFI( TheTarget->createMCObjectFileInfo(MC, /*PIC=*/false)); MC.setObjectFileInfo(MOFI.get()); MCTargetOptions Options; auto MAB = TheTarget->createMCAsmBackend(*MSTI, *MRI, Options); if (!MAB) return error("no asm backend for target " + TripleName, Context); std::unique_ptr MII(TheTarget->createMCInstrInfo()); if (!MII) return error("no instr info info for target " + TripleName, Context); MCCodeEmitter *MCE = TheTarget->createMCCodeEmitter(*MII, *MRI, MC); if (!MCE) return error("no code emitter for target " + TripleName, Context); // Create the output file. std::error_code EC; ToolOutputFile OutFile(OutputFilename, EC, sys::fs::OF_None); Optional BOS; raw_pwrite_stream *OS; if (EC) return error(Twine(OutputFilename) + ": " + EC.message(), Context); if (OutFile.os().supportsSeeking()) { OS = &OutFile.os(); } else { BOS.emplace(OutFile.os()); OS = BOS.getPointer(); } std::unique_ptr MS(TheTarget->createMCObjectStreamer( *ErrOrTriple, MC, std::unique_ptr(MAB), MAB->createObjectWriter(*OS), std::unique_ptr(MCE), *MSTI, MCOptions.MCRelaxAll, MCOptions.MCIncrementalLinkerCompatible, /*DWARFMustBeAtTheEnd*/ false)); if (!MS) return error("no object streamer for target " + TripleName, Context); if (auto Err = write(*MS, DWOFilenames)) { logAllUnhandledErrors(std::move(Err), WithColor::error()); return 1; } MS->Finish(); OutFile.keep(); return 0; }