//===- Object.h -------------------------------------------------*- C++ -*-===// // // 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 // //===----------------------------------------------------------------------===// #ifndef LLVM_TOOLS_OBJCOPY_OBJECT_H #define LLVM_TOOLS_OBJCOPY_OBJECT_H #include "Buffer.h" #include "CopyConfig.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/StringRef.h" #include "llvm/ADT/Twine.h" #include "llvm/BinaryFormat/ELF.h" #include "llvm/MC/StringTableBuilder.h" #include "llvm/Object/ELFObjectFile.h" #include "llvm/Support/Errc.h" #include "llvm/Support/FileOutputBuffer.h" #include #include #include #include #include #include namespace llvm { enum class DebugCompressionType; namespace objcopy { namespace elf { class SectionBase; class Section; class OwnedDataSection; class StringTableSection; class SymbolTableSection; class RelocationSection; class DynamicRelocationSection; class GnuDebugLinkSection; class GroupSection; class SectionIndexSection; class CompressedSection; class DecompressedSection; class Segment; class Object; struct Symbol; class SectionTableRef { MutableArrayRef> Sections; public: using iterator = pointee_iterator *>; explicit SectionTableRef(MutableArrayRef> Secs) : Sections(Secs) {} SectionTableRef(const SectionTableRef &) = default; iterator begin() const { return iterator(Sections.data()); } iterator end() const { return iterator(Sections.data() + Sections.size()); } size_t size() const { return Sections.size(); } Expected getSection(uint32_t Index, Twine ErrMsg); template Expected getSectionOfType(uint32_t Index, Twine IndexErrMsg, Twine TypeErrMsg); }; enum ElfType { ELFT_ELF32LE, ELFT_ELF64LE, ELFT_ELF32BE, ELFT_ELF64BE }; class SectionVisitor { public: virtual ~SectionVisitor() = default; virtual Error visit(const Section &Sec) = 0; virtual Error visit(const OwnedDataSection &Sec) = 0; virtual Error visit(const StringTableSection &Sec) = 0; virtual Error visit(const SymbolTableSection &Sec) = 0; virtual Error visit(const RelocationSection &Sec) = 0; virtual Error visit(const DynamicRelocationSection &Sec) = 0; virtual Error visit(const GnuDebugLinkSection &Sec) = 0; virtual Error visit(const GroupSection &Sec) = 0; virtual Error visit(const SectionIndexSection &Sec) = 0; virtual Error visit(const CompressedSection &Sec) = 0; virtual Error visit(const DecompressedSection &Sec) = 0; }; class MutableSectionVisitor { public: virtual ~MutableSectionVisitor() = default; virtual Error visit(Section &Sec) = 0; virtual Error visit(OwnedDataSection &Sec) = 0; virtual Error visit(StringTableSection &Sec) = 0; virtual Error visit(SymbolTableSection &Sec) = 0; virtual Error visit(RelocationSection &Sec) = 0; virtual Error visit(DynamicRelocationSection &Sec) = 0; virtual Error visit(GnuDebugLinkSection &Sec) = 0; virtual Error visit(GroupSection &Sec) = 0; virtual Error visit(SectionIndexSection &Sec) = 0; virtual Error visit(CompressedSection &Sec) = 0; virtual Error visit(DecompressedSection &Sec) = 0; }; class SectionWriter : public SectionVisitor { protected: Buffer &Out; public: virtual ~SectionWriter() = default; Error visit(const Section &Sec) override; Error visit(const OwnedDataSection &Sec) override; Error visit(const StringTableSection &Sec) override; Error visit(const DynamicRelocationSection &Sec) override; virtual Error visit(const SymbolTableSection &Sec) override = 0; virtual Error visit(const RelocationSection &Sec) override = 0; virtual Error visit(const GnuDebugLinkSection &Sec) override = 0; virtual Error visit(const GroupSection &Sec) override = 0; virtual Error visit(const SectionIndexSection &Sec) override = 0; virtual Error visit(const CompressedSection &Sec) override = 0; virtual Error visit(const DecompressedSection &Sec) override = 0; explicit SectionWriter(Buffer &Buf) : Out(Buf) {} }; template class ELFSectionWriter : public SectionWriter { private: using Elf_Word = typename ELFT::Word; using Elf_Rel = typename ELFT::Rel; using Elf_Rela = typename ELFT::Rela; using Elf_Sym = typename ELFT::Sym; public: virtual ~ELFSectionWriter() {} Error visit(const SymbolTableSection &Sec) override; Error visit(const RelocationSection &Sec) override; Error visit(const GnuDebugLinkSection &Sec) override; Error visit(const GroupSection &Sec) override; Error visit(const SectionIndexSection &Sec) override; Error visit(const CompressedSection &Sec) override; Error visit(const DecompressedSection &Sec) override; explicit ELFSectionWriter(Buffer &Buf) : SectionWriter(Buf) {} }; template class ELFSectionSizer : public MutableSectionVisitor { private: using Elf_Rel = typename ELFT::Rel; using Elf_Rela = typename ELFT::Rela; using Elf_Sym = typename ELFT::Sym; using Elf_Word = typename ELFT::Word; using Elf_Xword = typename ELFT::Xword; public: Error visit(Section &Sec) override; Error visit(OwnedDataSection &Sec) override; Error visit(StringTableSection &Sec) override; Error visit(DynamicRelocationSection &Sec) override; Error visit(SymbolTableSection &Sec) override; Error visit(RelocationSection &Sec) override; Error visit(GnuDebugLinkSection &Sec) override; Error visit(GroupSection &Sec) override; Error visit(SectionIndexSection &Sec) override; Error visit(CompressedSection &Sec) override; Error visit(DecompressedSection &Sec) override; }; #define MAKE_SEC_WRITER_FRIEND \ friend class SectionWriter; \ friend class IHexSectionWriterBase; \ friend class IHexSectionWriter; \ template friend class ELFSectionWriter; \ template friend class ELFSectionSizer; class BinarySectionWriter : public SectionWriter { public: virtual ~BinarySectionWriter() {} Error visit(const SymbolTableSection &Sec) override; Error visit(const RelocationSection &Sec) override; Error visit(const GnuDebugLinkSection &Sec) override; Error visit(const GroupSection &Sec) override; Error visit(const SectionIndexSection &Sec) override; Error visit(const CompressedSection &Sec) override; Error visit(const DecompressedSection &Sec) override; explicit BinarySectionWriter(Buffer &Buf) : SectionWriter(Buf) {} }; using IHexLineData = SmallVector; struct IHexRecord { // Memory address of the record. uint16_t Addr; // Record type (see below). uint16_t Type; // Record data in hexadecimal form. StringRef HexData; // Helper method to get file length of the record // including newline character static size_t getLength(size_t DataSize) { // :LLAAAATT[DD...DD]CC' return DataSize * 2 + 11; } // Gets length of line in a file (getLength + CRLF). static size_t getLineLength(size_t DataSize) { return getLength(DataSize) + 2; } // Given type, address and data returns line which can // be written to output file. static IHexLineData getLine(uint8_t Type, uint16_t Addr, ArrayRef Data); // Parses the line and returns record if possible. // Line should be trimmed from whitespace characters. static Expected parse(StringRef Line); // Calculates checksum of stringified record representation // S must NOT contain leading ':' and trailing whitespace // characters static uint8_t getChecksum(StringRef S); enum Type { // Contains data and a 16-bit starting address for the data. // The byte count specifies number of data bytes in the record. Data = 0, // Must occur exactly once per file in the last line of the file. // The data field is empty (thus byte count is 00) and the address // field is typically 0000. EndOfFile = 1, // The data field contains a 16-bit segment base address (thus byte // count is always 02) compatible with 80x86 real mode addressing. // The address field (typically 0000) is ignored. The segment address // from the most recent 02 record is multiplied by 16 and added to each // subsequent data record address to form the physical starting address // for the data. This allows addressing up to one megabyte of address // space. SegmentAddr = 2, // or 80x86 processors, specifies the initial content of the CS:IP // registers. The address field is 0000, the byte count is always 04, // the first two data bytes are the CS value, the latter two are the // IP value. StartAddr80x86 = 3, // Allows for 32 bit addressing (up to 4GiB). The record's address field // is ignored (typically 0000) and its byte count is always 02. The two // data bytes (big endian) specify the upper 16 bits of the 32 bit // absolute address for all subsequent type 00 records ExtendedAddr = 4, // The address field is 0000 (not used) and the byte count is always 04. // The four data bytes represent a 32-bit address value. In the case of // 80386 and higher CPUs, this address is loaded into the EIP register. StartAddr = 5, // We have no other valid types InvalidType = 6 }; }; // Base class for IHexSectionWriter. This class implements writing algorithm, // but doesn't actually write records. It is used for output buffer size // calculation in IHexWriter::finalize. class IHexSectionWriterBase : public BinarySectionWriter { // 20-bit segment address uint32_t SegmentAddr = 0; // Extended linear address uint32_t BaseAddr = 0; // Write segment address corresponding to 'Addr' uint64_t writeSegmentAddr(uint64_t Addr); // Write extended linear (base) address corresponding to 'Addr' uint64_t writeBaseAddr(uint64_t Addr); protected: // Offset in the output buffer uint64_t Offset = 0; void writeSection(const SectionBase *Sec, ArrayRef Data); virtual void writeData(uint8_t Type, uint16_t Addr, ArrayRef Data); public: explicit IHexSectionWriterBase(Buffer &Buf) : BinarySectionWriter(Buf) {} uint64_t getBufferOffset() const { return Offset; } Error visit(const Section &Sec) final; Error visit(const OwnedDataSection &Sec) final; Error visit(const StringTableSection &Sec) override; Error visit(const DynamicRelocationSection &Sec) final; using BinarySectionWriter::visit; }; // Real IHEX section writer class IHexSectionWriter : public IHexSectionWriterBase { public: IHexSectionWriter(Buffer &Buf) : IHexSectionWriterBase(Buf) {} void writeData(uint8_t Type, uint16_t Addr, ArrayRef Data) override; Error visit(const StringTableSection &Sec) override; }; class Writer { protected: Object &Obj; Buffer &Buf; public: virtual ~Writer(); virtual Error finalize() = 0; virtual Error write() = 0; Writer(Object &O, Buffer &B) : Obj(O), Buf(B) {} }; template class ELFWriter : public Writer { private: using Elf_Addr = typename ELFT::Addr; using Elf_Shdr = typename ELFT::Shdr; using Elf_Phdr = typename ELFT::Phdr; using Elf_Ehdr = typename ELFT::Ehdr; void initEhdrSegment(); void writeEhdr(); void writePhdr(const Segment &Seg); void writeShdr(const SectionBase &Sec); void writePhdrs(); void writeShdrs(); Error writeSectionData(); void writeSegmentData(); void assignOffsets(); std::unique_ptr> SecWriter; size_t totalSize() const; public: virtual ~ELFWriter() {} bool WriteSectionHeaders; // For --only-keep-debug, select an alternative section/segment layout // algorithm. bool OnlyKeepDebug; Error finalize() override; Error write() override; ELFWriter(Object &Obj, Buffer &Buf, bool WSH, bool OnlyKeepDebug); }; class BinaryWriter : public Writer { private: std::unique_ptr SecWriter; uint64_t TotalSize = 0; public: ~BinaryWriter() {} Error finalize() override; Error write() override; BinaryWriter(Object &Obj, Buffer &Buf) : Writer(Obj, Buf) {} }; class IHexWriter : public Writer { struct SectionCompare { bool operator()(const SectionBase *Lhs, const SectionBase *Rhs) const; }; std::set Sections; size_t TotalSize = 0; Error checkSection(const SectionBase &Sec); uint64_t writeEntryPointRecord(uint8_t *Buf); uint64_t writeEndOfFileRecord(uint8_t *Buf); public: ~IHexWriter() {} Error finalize() override; Error write() override; IHexWriter(Object &Obj, Buffer &Buf) : Writer(Obj, Buf) {} }; class SectionBase { public: std::string Name; Segment *ParentSegment = nullptr; uint64_t HeaderOffset = 0; uint32_t Index = 0; uint32_t OriginalIndex = 0; uint64_t OriginalFlags = 0; uint64_t OriginalType = ELF::SHT_NULL; uint64_t OriginalOffset = std::numeric_limits::max(); uint64_t Addr = 0; uint64_t Align = 1; uint32_t EntrySize = 0; uint64_t Flags = 0; uint64_t Info = 0; uint64_t Link = ELF::SHN_UNDEF; uint64_t NameIndex = 0; uint64_t Offset = 0; uint64_t Size = 0; uint64_t Type = ELF::SHT_NULL; ArrayRef OriginalData; bool HasSymbol = false; SectionBase() = default; SectionBase(const SectionBase &) = default; virtual ~SectionBase() = default; virtual Error initialize(SectionTableRef SecTable); virtual void finalize(); // Remove references to these sections. The list of sections must be sorted. virtual Error removeSectionReferences(bool AllowBrokenLinks, function_ref ToRemove); virtual Error removeSymbols(function_ref ToRemove); virtual Error accept(SectionVisitor &Visitor) const = 0; virtual Error accept(MutableSectionVisitor &Visitor) = 0; virtual void markSymbols(); virtual void replaceSectionReferences(const DenseMap &); // Notify the section that it is subject to removal. virtual void onRemove(); }; class Segment { private: struct SectionCompare { bool operator()(const SectionBase *Lhs, const SectionBase *Rhs) const { // Some sections might have the same address if one of them is empty. To // fix this we can use the lexicographic ordering on ->Addr and the // original index. if (Lhs->OriginalOffset == Rhs->OriginalOffset) return Lhs->OriginalIndex < Rhs->OriginalIndex; return Lhs->OriginalOffset < Rhs->OriginalOffset; } }; public: uint32_t Type = 0; uint32_t Flags = 0; uint64_t Offset = 0; uint64_t VAddr = 0; uint64_t PAddr = 0; uint64_t FileSize = 0; uint64_t MemSize = 0; uint64_t Align = 0; uint32_t Index = 0; uint64_t OriginalOffset = 0; Segment *ParentSegment = nullptr; ArrayRef Contents; std::set Sections; explicit Segment(ArrayRef Data) : Contents(Data) {} Segment() = default; const SectionBase *firstSection() const { if (!Sections.empty()) return *Sections.begin(); return nullptr; } void removeSection(const SectionBase *Sec) { Sections.erase(Sec); } void addSection(const SectionBase *Sec) { Sections.insert(Sec); } ArrayRef getContents() const { return Contents; } }; class Section : public SectionBase { MAKE_SEC_WRITER_FRIEND ArrayRef Contents; SectionBase *LinkSection = nullptr; public: explicit Section(ArrayRef Data) : Contents(Data) {} Error accept(SectionVisitor &Visitor) const override; Error accept(MutableSectionVisitor &Visitor) override; Error removeSectionReferences( bool AllowBrokenLinks, function_ref ToRemove) override; Error initialize(SectionTableRef SecTable) override; void finalize() override; }; class OwnedDataSection : public SectionBase { MAKE_SEC_WRITER_FRIEND std::vector Data; public: OwnedDataSection(StringRef SecName, ArrayRef Data) : Data(std::begin(Data), std::end(Data)) { Name = SecName.str(); Type = OriginalType = ELF::SHT_PROGBITS; Size = Data.size(); OriginalOffset = std::numeric_limits::max(); } OwnedDataSection(const Twine &SecName, uint64_t SecAddr, uint64_t SecFlags, uint64_t SecOff) { Name = SecName.str(); Type = OriginalType = ELF::SHT_PROGBITS; Addr = SecAddr; Flags = OriginalFlags = SecFlags; OriginalOffset = SecOff; } void appendHexData(StringRef HexData); Error accept(SectionVisitor &Sec) const override; Error accept(MutableSectionVisitor &Visitor) override; }; class CompressedSection : public SectionBase { MAKE_SEC_WRITER_FRIEND DebugCompressionType CompressionType; uint64_t DecompressedSize; uint64_t DecompressedAlign; SmallVector CompressedData; public: static Expected create(const SectionBase &Sec, DebugCompressionType CompressionType); static Expected create(ArrayRef CompressedData, uint64_t DecompressedSize, uint64_t DecompressedAlign); uint64_t getDecompressedSize() const { return DecompressedSize; } uint64_t getDecompressedAlign() const { return DecompressedAlign; } Error accept(SectionVisitor &Visitor) const override; Error accept(MutableSectionVisitor &Visitor) override; static bool classof(const SectionBase *S) { return (S->OriginalFlags & ELF::SHF_COMPRESSED) || (StringRef(S->Name).startswith(".zdebug")); } private: CompressedSection(const SectionBase &Sec, DebugCompressionType CompressionType, Error &Err); CompressedSection(ArrayRef CompressedData, uint64_t DecompressedSize, uint64_t DecompressedAlign); }; class DecompressedSection : public SectionBase { MAKE_SEC_WRITER_FRIEND public: explicit DecompressedSection(const CompressedSection &Sec) : SectionBase(Sec) { Size = Sec.getDecompressedSize(); Align = Sec.getDecompressedAlign(); Flags = OriginalFlags = (Flags & ~ELF::SHF_COMPRESSED); if (StringRef(Name).startswith(".zdebug")) Name = "." + Name.substr(2); } Error accept(SectionVisitor &Visitor) const override; Error accept(MutableSectionVisitor &Visitor) override; }; // There are two types of string tables that can exist, dynamic and not dynamic. // In the dynamic case the string table is allocated. Changing a dynamic string // table would mean altering virtual addresses and thus the memory image. So // dynamic string tables should not have an interface to modify them or // reconstruct them. This type lets us reconstruct a string table. To avoid // this class being used for dynamic string tables (which has happened) the // classof method checks that the particular instance is not allocated. This // then agrees with the makeSection method used to construct most sections. class StringTableSection : public SectionBase { MAKE_SEC_WRITER_FRIEND StringTableBuilder StrTabBuilder; public: StringTableSection() : StrTabBuilder(StringTableBuilder::ELF) { Type = OriginalType = ELF::SHT_STRTAB; } void addString(StringRef Name); uint32_t findIndex(StringRef Name) const; void prepareForLayout(); Error accept(SectionVisitor &Visitor) const override; Error accept(MutableSectionVisitor &Visitor) override; static bool classof(const SectionBase *S) { if (S->OriginalFlags & ELF::SHF_ALLOC) return false; return S->OriginalType == ELF::SHT_STRTAB; } }; // Symbols have a st_shndx field that normally stores an index but occasionally // stores a different special value. This enum keeps track of what the st_shndx // field means. Most of the values are just copies of the special SHN_* values. // SYMBOL_SIMPLE_INDEX means that the st_shndx is just an index of a section. enum SymbolShndxType { SYMBOL_SIMPLE_INDEX = 0, SYMBOL_ABS = ELF::SHN_ABS, SYMBOL_COMMON = ELF::SHN_COMMON, SYMBOL_LOPROC = ELF::SHN_LOPROC, SYMBOL_AMDGPU_LDS = ELF::SHN_AMDGPU_LDS, SYMBOL_HEXAGON_SCOMMON = ELF::SHN_HEXAGON_SCOMMON, SYMBOL_HEXAGON_SCOMMON_2 = ELF::SHN_HEXAGON_SCOMMON_2, SYMBOL_HEXAGON_SCOMMON_4 = ELF::SHN_HEXAGON_SCOMMON_4, SYMBOL_HEXAGON_SCOMMON_8 = ELF::SHN_HEXAGON_SCOMMON_8, SYMBOL_HIPROC = ELF::SHN_HIPROC, SYMBOL_LOOS = ELF::SHN_LOOS, SYMBOL_HIOS = ELF::SHN_HIOS, SYMBOL_XINDEX = ELF::SHN_XINDEX, }; struct Symbol { uint8_t Binding; SectionBase *DefinedIn = nullptr; SymbolShndxType ShndxType; uint32_t Index; std::string Name; uint32_t NameIndex; uint64_t Size; uint8_t Type; uint64_t Value; uint8_t Visibility; bool Referenced = false; uint16_t getShndx() const; bool isCommon() const; }; class SectionIndexSection : public SectionBase { MAKE_SEC_WRITER_FRIEND private: std::vector Indexes; SymbolTableSection *Symbols = nullptr; public: virtual ~SectionIndexSection() {} void addIndex(uint32_t Index) { assert(Size > 0); Indexes.push_back(Index); } void reserve(size_t NumSymbols) { Indexes.reserve(NumSymbols); Size = NumSymbols * 4; } void setSymTab(SymbolTableSection *SymTab) { Symbols = SymTab; } Error initialize(SectionTableRef SecTable) override; void finalize() override; Error accept(SectionVisitor &Visitor) const override; Error accept(MutableSectionVisitor &Visitor) override; SectionIndexSection() { Name = ".symtab_shndx"; Align = 4; EntrySize = 4; Type = OriginalType = ELF::SHT_SYMTAB_SHNDX; } }; class SymbolTableSection : public SectionBase { MAKE_SEC_WRITER_FRIEND void setStrTab(StringTableSection *StrTab) { SymbolNames = StrTab; } void assignIndices(); protected: std::vector> Symbols; StringTableSection *SymbolNames = nullptr; SectionIndexSection *SectionIndexTable = nullptr; using SymPtr = std::unique_ptr; public: SymbolTableSection() { Type = OriginalType = ELF::SHT_SYMTAB; } void addSymbol(Twine Name, uint8_t Bind, uint8_t Type, SectionBase *DefinedIn, uint64_t Value, uint8_t Visibility, uint16_t Shndx, uint64_t SymbolSize); void prepareForLayout(); // An 'empty' symbol table still contains a null symbol. bool empty() const { return Symbols.size() == 1; } void setShndxTable(SectionIndexSection *ShndxTable) { SectionIndexTable = ShndxTable; } const SectionIndexSection *getShndxTable() const { return SectionIndexTable; } void fillShndxTable(); const SectionBase *getStrTab() const { return SymbolNames; } Expected getSymbolByIndex(uint32_t Index) const; Expected getSymbolByIndex(uint32_t Index); void updateSymbols(function_ref Callable); Error removeSectionReferences( bool AllowBrokenLinks, function_ref ToRemove) override; Error initialize(SectionTableRef SecTable) override; void finalize() override; Error accept(SectionVisitor &Visitor) const override; Error accept(MutableSectionVisitor &Visitor) override; Error removeSymbols(function_ref ToRemove) override; void replaceSectionReferences( const DenseMap &FromTo) override; static bool classof(const SectionBase *S) { return S->OriginalType == ELF::SHT_SYMTAB; } }; struct Relocation { Symbol *RelocSymbol = nullptr; uint64_t Offset; uint64_t Addend; uint32_t Type; }; // All relocation sections denote relocations to apply to another section. // However, some relocation sections use a dynamic symbol table and others use // a regular symbol table. Because the types of the two symbol tables differ in // our system (because they should behave differently) we can't uniformly // represent all relocations with the same base class if we expose an interface // that mentions the symbol table type. So we split the two base types into two // different classes, one which handles the section the relocation is applied to // and another which handles the symbol table type. The symbol table type is // taken as a type parameter to the class (see RelocSectionWithSymtabBase). class RelocationSectionBase : public SectionBase { protected: SectionBase *SecToApplyRel = nullptr; public: const SectionBase *getSection() const { return SecToApplyRel; } void setSection(SectionBase *Sec) { SecToApplyRel = Sec; } static bool classof(const SectionBase *S) { return S->OriginalType == ELF::SHT_REL || S->OriginalType == ELF::SHT_RELA; } }; // Takes the symbol table type to use as a parameter so that we can deduplicate // that code between the two symbol table types. template class RelocSectionWithSymtabBase : public RelocationSectionBase { void setSymTab(SymTabType *SymTab) { Symbols = SymTab; } protected: RelocSectionWithSymtabBase() = default; SymTabType *Symbols = nullptr; public: Error initialize(SectionTableRef SecTable) override; void finalize() override; }; class RelocationSection : public RelocSectionWithSymtabBase { MAKE_SEC_WRITER_FRIEND std::vector Relocations; public: void addRelocation(Relocation Rel) { Relocations.push_back(Rel); } Error accept(SectionVisitor &Visitor) const override; Error accept(MutableSectionVisitor &Visitor) override; Error removeSectionReferences( bool AllowBrokenLinks, function_ref ToRemove) override; Error removeSymbols(function_ref ToRemove) override; void markSymbols() override; void replaceSectionReferences( const DenseMap &FromTo) override; static bool classof(const SectionBase *S) { if (S->OriginalFlags & ELF::SHF_ALLOC) return false; return S->OriginalType == ELF::SHT_REL || S->OriginalType == ELF::SHT_RELA; } }; // TODO: The way stripping and groups interact is complicated // and still needs to be worked on. class GroupSection : public SectionBase { MAKE_SEC_WRITER_FRIEND const SymbolTableSection *SymTab = nullptr; Symbol *Sym = nullptr; ELF::Elf32_Word FlagWord; SmallVector GroupMembers; public: // TODO: Contents is present in several classes of the hierarchy. // This needs to be refactored to avoid duplication. ArrayRef Contents; explicit GroupSection(ArrayRef Data) : Contents(Data) {} void setSymTab(const SymbolTableSection *SymTabSec) { SymTab = SymTabSec; } void setSymbol(Symbol *S) { Sym = S; } void setFlagWord(ELF::Elf32_Word W) { FlagWord = W; } void addMember(SectionBase *Sec) { GroupMembers.push_back(Sec); } Error accept(SectionVisitor &) const override; Error accept(MutableSectionVisitor &Visitor) override; void finalize() override; Error removeSectionReferences( bool AllowBrokenLinks, function_ref ToRemove) override; Error removeSymbols(function_ref ToRemove) override; void markSymbols() override; void replaceSectionReferences( const DenseMap &FromTo) override; void onRemove() override; static bool classof(const SectionBase *S) { return S->OriginalType == ELF::SHT_GROUP; } }; class DynamicSymbolTableSection : public Section { public: explicit DynamicSymbolTableSection(ArrayRef Data) : Section(Data) {} static bool classof(const SectionBase *S) { return S->OriginalType == ELF::SHT_DYNSYM; } }; class DynamicSection : public Section { public: explicit DynamicSection(ArrayRef Data) : Section(Data) {} static bool classof(const SectionBase *S) { return S->OriginalType == ELF::SHT_DYNAMIC; } }; class DynamicRelocationSection : public RelocSectionWithSymtabBase { MAKE_SEC_WRITER_FRIEND private: ArrayRef Contents; public: explicit DynamicRelocationSection(ArrayRef Data) : Contents(Data) {} Error accept(SectionVisitor &) const override; Error accept(MutableSectionVisitor &Visitor) override; Error removeSectionReferences( bool AllowBrokenLinks, function_ref ToRemove) override; static bool classof(const SectionBase *S) { if (!(S->OriginalFlags & ELF::SHF_ALLOC)) return false; return S->OriginalType == ELF::SHT_REL || S->OriginalType == ELF::SHT_RELA; } }; class GnuDebugLinkSection : public SectionBase { MAKE_SEC_WRITER_FRIEND private: StringRef FileName; uint32_t CRC32; void init(StringRef File); public: // If we add this section from an external source we can use this ctor. explicit GnuDebugLinkSection(StringRef File, uint32_t PrecomputedCRC); Error accept(SectionVisitor &Visitor) const override; Error accept(MutableSectionVisitor &Visitor) override; }; class Reader { public: virtual ~Reader(); virtual Expected> create(bool EnsureSymtab) const = 0; }; using object::Binary; using object::ELFFile; using object::ELFObjectFile; using object::OwningBinary; class BasicELFBuilder { protected: std::unique_ptr Obj; void initFileHeader(); void initHeaderSegment(); StringTableSection *addStrTab(); SymbolTableSection *addSymTab(StringTableSection *StrTab); Error initSections(); public: BasicELFBuilder() : Obj(std::make_unique()) {} }; class BinaryELFBuilder : public BasicELFBuilder { MemoryBuffer *MemBuf; uint8_t NewSymbolVisibility; void addData(SymbolTableSection *SymTab); public: BinaryELFBuilder(MemoryBuffer *MB, uint8_t NewSymbolVisibility) : BasicELFBuilder(), MemBuf(MB), NewSymbolVisibility(NewSymbolVisibility) {} Expected> build(); }; class IHexELFBuilder : public BasicELFBuilder { const std::vector &Records; void addDataSections(); public: IHexELFBuilder(const std::vector &Records) : BasicELFBuilder(), Records(Records) {} Expected> build(); }; template class ELFBuilder { private: using Elf_Addr = typename ELFT::Addr; using Elf_Shdr = typename ELFT::Shdr; using Elf_Word = typename ELFT::Word; const ELFFile &ElfFile; Object &Obj; size_t EhdrOffset = 0; Optional ExtractPartition; void setParentSegment(Segment &Child); Error readProgramHeaders(const ELFFile &HeadersFile); Error initGroupSection(GroupSection *GroupSec); Error initSymbolTable(SymbolTableSection *SymTab); Error readSectionHeaders(); Error readSections(bool EnsureSymtab); Error findEhdrOffset(); Expected makeSection(const Elf_Shdr &Shdr); public: ELFBuilder(const ELFObjectFile &ElfObj, Object &Obj, Optional ExtractPartition) : ElfFile(ElfObj.getELFFile()), Obj(Obj), ExtractPartition(ExtractPartition) {} Error build(bool EnsureSymtab); }; class BinaryReader : public Reader { MemoryBuffer *MemBuf; uint8_t NewSymbolVisibility; public: BinaryReader(MemoryBuffer *MB, const uint8_t NewSymbolVisibility) : MemBuf(MB), NewSymbolVisibility(NewSymbolVisibility) {} Expected> create(bool EnsureSymtab) const override; }; class IHexReader : public Reader { MemoryBuffer *MemBuf; Expected> parse() const; Error parseError(size_t LineNo, Error E) const { return LineNo == -1U ? createFileError(MemBuf->getBufferIdentifier(), std::move(E)) : createFileError(MemBuf->getBufferIdentifier(), LineNo, std::move(E)); } template Error parseError(size_t LineNo, char const *Fmt, const Ts &... Vals) const { Error E = createStringError(errc::invalid_argument, Fmt, Vals...); return parseError(LineNo, std::move(E)); } public: IHexReader(MemoryBuffer *MB) : MemBuf(MB) {} Expected> create(bool EnsureSymtab) const override; }; class ELFReader : public Reader { Binary *Bin; Optional ExtractPartition; public: Expected> create(bool EnsureSymtab) const override; explicit ELFReader(Binary *B, Optional ExtractPartition) : Bin(B), ExtractPartition(ExtractPartition) {} }; class Object { private: using SecPtr = std::unique_ptr; using SegPtr = std::unique_ptr; std::vector Sections; std::vector Segments; std::vector RemovedSections; static bool sectionIsAlloc(const SectionBase &Sec) { return Sec.Flags & ELF::SHF_ALLOC; }; public: template using Range = iterator_range< pointee_iterator>::iterator>>; template using ConstRange = iterator_range>::const_iterator>>; // It is often the case that the ELF header and the program header table are // not present in any segment. This could be a problem during file layout, // because other segments may get assigned an offset where either of the // two should reside, which will effectively corrupt the resulting binary. // Other than that we use these segments to track program header offsets // when they may not follow the ELF header. Segment ElfHdrSegment; Segment ProgramHdrSegment; uint8_t OSABI; uint8_t ABIVersion; uint64_t Entry; uint64_t SHOff; uint32_t Type; uint32_t Machine; uint32_t Version; uint32_t Flags; bool HadShdrs = true; bool MustBeRelocatable = false; StringTableSection *SectionNames = nullptr; SymbolTableSection *SymbolTable = nullptr; SectionIndexSection *SectionIndexTable = nullptr; void sortSections(); SectionTableRef sections() { return SectionTableRef(Sections); } ConstRange sections() const { return make_pointee_range(Sections); } iterator_range< filter_iterator::const_iterator>, decltype(§ionIsAlloc)>> allocSections() const { return make_filter_range(make_pointee_range(Sections), sectionIsAlloc); } SectionBase *findSection(StringRef Name) { auto SecIt = find_if(Sections, [&](const SecPtr &Sec) { return Sec->Name == Name; }); return SecIt == Sections.end() ? nullptr : SecIt->get(); } SectionTableRef removedSections() { return SectionTableRef(RemovedSections); } Range segments() { return make_pointee_range(Segments); } ConstRange segments() const { return make_pointee_range(Segments); } Error removeSections(bool AllowBrokenLinks, std::function ToRemove); Error removeSymbols(function_ref ToRemove); template T &addSection(Ts &&... Args) { auto Sec = std::make_unique(std::forward(Args)...); auto Ptr = Sec.get(); MustBeRelocatable |= isa(*Ptr); Sections.emplace_back(std::move(Sec)); Ptr->Index = Sections.size(); return *Ptr; } Error addNewSymbolTable(); Segment &addSegment(ArrayRef Data) { Segments.emplace_back(std::make_unique(Data)); return *Segments.back(); } bool isRelocatable() const { return (Type != ELF::ET_DYN && Type != ELF::ET_EXEC) || MustBeRelocatable; } }; } // end namespace elf } // end namespace objcopy } // end namespace llvm #endif // LLVM_TOOLS_OBJCOPY_OBJECT_H