src/third_party/llvm-project/lld/ELF/Symbols.h - cobalt - Git at Google

 //===- Symbols.h ------------------------------------------------*- C++ -*-===//
 //
 //                             The LLVM Linker
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file defines various types of Symbols.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLD_ELF_SYMBOLS_H
 #define LLD_ELF_SYMBOLS_H

 #include "InputSection.h"
 #include "lld/Common/LLVM.h"
 #include "lld/Common/Strings.h"
 #include "llvm/Object/Archive.h"
 #include "llvm/Object/ELF.h"

 namespace lld {
 namespace elf {

 class ArchiveFile;
 class BitcodeFile;
 class BssSection;
 class InputFile;
 class LazyObjFile;
 template <class ELFT> class ObjFile;
 class OutputSection;
 template <class ELFT> class SharedFile;

 // This is a StringRef-like container that doesn't run strlen().
 //
 // ELF string tables contain a lot of null-terminated strings. Most of them
 // are not necessary for the linker because they are names of local symbols,
 // and the linker doesn't use local symbol names for name resolution. So, we
 // use this class to represents strings read from string tables.
 struct StringRefZ {
   StringRefZ(const char *S) : Data(S), Size(-1) {}
   StringRefZ(StringRef S) : Data(S.data()), Size(S.size()) {}

   const char *Data;
   const uint32_t Size;
 };

 // The base class for real symbol classes.
 class Symbol {
 public:
   enum Kind {
     DefinedKind,
     SharedKind,
     UndefinedKind,
     LazyArchiveKind,
     LazyObjectKind,
   };

   Kind kind() const { return static_cast<Kind>(SymbolKind); }

   // The file from which this symbol was created.
   InputFile *File;

 protected:
   const char *NameData;
   mutable uint32_t NameSize;

 public:
   uint32_t DynsymIndex = 0;
   uint32_t GotIndex = -1;
   uint32_t PltIndex = -1;
   uint32_t GlobalDynIndex = -1;

   // This field is a index to the symbol's version definition.
   uint32_t VerdefIndex = -1;

   // Version definition index.
   uint16_t VersionId;

   // Symbol binding. This is not overwritten by replaceSymbol to track
   // changes during resolution. In particular:
   //  - An undefined weak is still weak when it resolves to a shared library.
   //  - An undefined weak will not fetch archive members, but we have to
   //    remember it is weak.
   uint8_t Binding;

   // The following fields have the same meaning as the ELF symbol attributes.
   uint8_t Type;    // symbol type
   uint8_t StOther; // st_other field value

   const uint8_t SymbolKind;

   // Symbol visibility. This is the computed minimum visibility of all
   // observed non-DSO symbols.
   unsigned Visibility : 2;

   // True if the symbol was used for linking and thus need to be added to the
   // output file's symbol table. This is true for all symbols except for
   // unreferenced DSO symbols and bitcode symbols that are unreferenced except
   // by other bitcode objects.
   unsigned IsUsedInRegularObj : 1;

   // If this flag is true and the symbol has protected or default visibility, it
   // will appear in .dynsym. This flag is set by interposable DSO symbols in
   // executables, by most symbols in DSOs and executables built with
   // --export-dynamic, and by dynamic lists.
   unsigned ExportDynamic : 1;

   // False if LTO shouldn't inline whatever this symbol points to. If a symbol
   // is overwritten after LTO, LTO shouldn't inline the symbol because it
   // doesn't know the final contents of the symbol.
   unsigned CanInline : 1;

   // True if this symbol is specified by --trace-symbol option.
   unsigned Traced : 1;

   bool includeInDynsym() const;
   uint8_t computeBinding() const;
   bool isWeak() const { return Binding == llvm::ELF::STB_WEAK; }

   bool isUndefined() const { return SymbolKind == UndefinedKind; }
   bool isDefined() const { return SymbolKind == DefinedKind; }
   bool isShared() const { return SymbolKind == SharedKind; }
   bool isLocal() const { return Binding == llvm::ELF::STB_LOCAL; }

   bool isLazy() const {
     return SymbolKind == LazyArchiveKind || SymbolKind == LazyObjectKind;
   }

   // True if this is an undefined weak symbol.
   bool isUndefWeak() const { return isWeak() && isUndefined(); }

   StringRef getName() const {
     if (NameSize == (uint32_t)-1)
       NameSize = strlen(NameData);
     return {NameData, NameSize};
   }

   void parseSymbolVersion();

   bool isInGot() const { return GotIndex != -1U; }
   bool isInPlt() const { return PltIndex != -1U; }

   uint64_t getVA(int64_t Addend = 0) const;

   uint64_t getGotOffset() const;
   uint64_t getGotVA() const;
   uint64_t getGotPltOffset() const;
   uint64_t getGotPltVA() const;
   uint64_t getPltVA() const;
   uint64_t getPltOffset() const;
   uint64_t getSize() const;
   OutputSection *getOutputSection() const;

 protected:
   Symbol(Kind K, InputFile *File, StringRefZ Name, uint8_t Binding,
          uint8_t StOther, uint8_t Type)
       : File(File), NameData(Name.Data), NameSize(Name.Size), Binding(Binding),
         Type(Type), StOther(StOther), SymbolKind(K), NeedsPltAddr(false),
         IsInIplt(false), IsInIgot(false), IsPreemptible(false),
         Used(!Config->GcSections), NeedsTocRestore(false) {}

 public:
   // True the symbol should point to its PLT entry.
   // For SharedSymbol only.
   unsigned NeedsPltAddr : 1;

   // True if this symbol is in the Iplt sub-section of the Plt.
   unsigned IsInIplt : 1;

   // True if this symbol is in the Igot sub-section of the .got.plt or .got.
   unsigned IsInIgot : 1;

   // True if this symbol is preemptible at load time.
   unsigned IsPreemptible : 1;

   // True if an undefined or shared symbol is used from a live section.
   unsigned Used : 1;

   // True if a call to this symbol needs to be followed by a restore of the
   // PPC64 toc pointer.
   unsigned NeedsTocRestore : 1;

   // The Type field may also have this value. It means that we have not yet seen
   // a non-Lazy symbol with this name, so we don't know what its type is. The
   // Type field is normally set to this value for Lazy symbols unless we saw a
   // weak undefined symbol first, in which case we need to remember the original
   // symbol's type in order to check for TLS mismatches.
   enum { UnknownType = 255 };

   bool isSection() const { return Type == llvm::ELF::STT_SECTION; }
   bool isTls() const { return Type == llvm::ELF::STT_TLS; }
   bool isFunc() const { return Type == llvm::ELF::STT_FUNC; }
   bool isGnuIFunc() const { return Type == llvm::ELF::STT_GNU_IFUNC; }
   bool isObject() const { return Type == llvm::ELF::STT_OBJECT; }
   bool isFile() const { return Type == llvm::ELF::STT_FILE; }
 };

 // Represents a symbol that is defined in the current output file.
 class Defined : public Symbol {
 public:
   Defined(InputFile *File, StringRefZ Name, uint8_t Binding, uint8_t StOther,
           uint8_t Type, uint64_t Value, uint64_t Size, SectionBase *Section)
       : Symbol(DefinedKind, File, Name, Binding, StOther, Type), Value(Value),
         Size(Size), Section(Section) {}

   static bool classof(const Symbol *S) { return S->isDefined(); }

   uint64_t Value;
   uint64_t Size;
   SectionBase *Section;
 };

 class Undefined : public Symbol {
 public:
   Undefined(InputFile *File, StringRefZ Name, uint8_t Binding, uint8_t StOther,
             uint8_t Type)
       : Symbol(UndefinedKind, File, Name, Binding, StOther, Type) {}

   static bool classof(const Symbol *S) { return S->kind() == UndefinedKind; }
 };

 class SharedSymbol : public Symbol {
 public:
   static bool classof(const Symbol *S) { return S->kind() == SharedKind; }

   SharedSymbol(InputFile &File, StringRef Name, uint8_t Binding,
                uint8_t StOther, uint8_t Type, uint64_t Value, uint64_t Size,
                uint32_t Alignment, uint32_t VerdefIndex)
       : Symbol(SharedKind, &File, Name, Binding, StOther, Type),
         Alignment(Alignment), Value(Value), Size(Size) {
     this->VerdefIndex = VerdefIndex;
     // GNU ifunc is a mechanism to allow user-supplied functions to
     // resolve PLT slot values at load-time. This is contrary to the
     // regular symbol resolution scheme in which symbols are resolved just
     // by name. Using this hook, you can program how symbols are solved
     // for you program. For example, you can make "memcpy" to be resolved
     // to a SSE-enabled version of memcpy only when a machine running the
     // program supports the SSE instruction set.
     //
     // Naturally, such symbols should always be called through their PLT
     // slots. What GNU ifunc symbols point to are resolver functions, and
     // calling them directly doesn't make sense (unless you are writing a
     // loader).
     //
     // For DSO symbols, we always call them through PLT slots anyway.
     // So there's no difference between GNU ifunc and regular function
     // symbols if they are in DSOs. So we can handle GNU_IFUNC as FUNC.
     if (this->Type == llvm::ELF::STT_GNU_IFUNC)
       this->Type = llvm::ELF::STT_FUNC;
   }

   template <class ELFT> SharedFile<ELFT> &getFile() const {
     return *cast<SharedFile<ELFT>>(File);
   }

   uint32_t Alignment;

   uint64_t Value; // st_value
   uint64_t Size;  // st_size
 };

 // LazyArchive and LazyObject represent a symbols that is not yet in the link,
 // but we know where to find it if needed. If the resolver finds both Undefined
 // and Lazy for the same name, it will ask the Lazy to load a file.
 //
 // A special complication is the handling of weak undefined symbols. They should
 // not load a file, but we have to remember we have seen both the weak undefined
 // and the lazy. We represent that with a lazy symbol with a weak binding. This
 // means that code looking for undefined symbols normally also has to take lazy
 // symbols into consideration.

 // This class represents a symbol defined in an archive file. It is
 // created from an archive file header, and it knows how to load an
 // object file from an archive to replace itself with a defined
 // symbol.
 class LazyArchive : public Symbol {
 public:
   LazyArchive(InputFile &File, uint8_t Type,
               const llvm::object::Archive::Symbol S)
       : Symbol(LazyArchiveKind, &File, S.getName(), llvm::ELF::STB_GLOBAL,
                llvm::ELF::STV_DEFAULT, Type),
         Sym(S) {}

   static bool classof(const Symbol *S) { return S->kind() == LazyArchiveKind; }

   InputFile *fetch();

 private:
   const llvm::object::Archive::Symbol Sym;
 };

 // LazyObject symbols represents symbols in object files between
 // --start-lib and --end-lib options.
 class LazyObject : public Symbol {
 public:
   LazyObject(InputFile &File, uint8_t Type, StringRef Name)
       : Symbol(LazyObjectKind, &File, Name, llvm::ELF::STB_GLOBAL,
                llvm::ELF::STV_DEFAULT, Type) {}

   static bool classof(const Symbol *S) { return S->kind() == LazyObjectKind; }
 };

 // Some linker-generated symbols need to be created as
 // Defined symbols.
 struct ElfSym {
   // __bss_start
   static Defined *Bss;

   // etext and _etext
   static Defined *Etext1;
   static Defined *Etext2;

   // edata and _edata
   static Defined *Edata1;
   static Defined *Edata2;

   // end and _end
   static Defined *End1;
   static Defined *End2;

   // The _GLOBAL_OFFSET_TABLE_ symbol is defined by target convention to
   // be at some offset from the base of the .got section, usually 0 or
   // the end of the .got.
   static Defined *GlobalOffsetTable;

   // _gp, _gp_disp and __gnu_local_gp symbols. Only for MIPS.
   static Defined *MipsGp;
   static Defined *MipsGpDisp;
   static Defined *MipsLocalGp;

   // __rela_iplt_end or __rel_iplt_end
   static Defined *RelaIpltEnd;
 };

 // A buffer class that is large enough to hold any Symbol-derived
 // object. We allocate memory using this class and instantiate a symbol
 // using the placement new.
 union SymbolUnion {
   alignas(Defined) char A[sizeof(Defined)];
   alignas(Undefined) char C[sizeof(Undefined)];
   alignas(SharedSymbol) char D[sizeof(SharedSymbol)];
   alignas(LazyArchive) char E[sizeof(LazyArchive)];
   alignas(LazyObject) char F[sizeof(LazyObject)];
 };

 void printTraceSymbol(Symbol *Sym);

 template <typename T, typename... ArgT>
 void replaceSymbol(Symbol *S, ArgT &&... Arg) {
   static_assert(std::is_trivially_destructible<T>(),
                 "Symbol types must be trivially destructible");
   static_assert(sizeof(T) <= sizeof(SymbolUnion), "SymbolUnion too small");
   static_assert(alignof(T) <= alignof(SymbolUnion),
                 "SymbolUnion not aligned enough");
   assert(static_cast<Symbol *>(static_cast<T *>(nullptr)) == nullptr &&
          "Not a Symbol");

   Symbol Sym = *S;

   new (S) T(std::forward<ArgT>(Arg)...);

   S->VersionId = Sym.VersionId;
   S->Visibility = Sym.Visibility;
   S->IsUsedInRegularObj = Sym.IsUsedInRegularObj;
   S->ExportDynamic = Sym.ExportDynamic;
   S->CanInline = Sym.CanInline;
   S->Traced = Sym.Traced;

   // Print out a log message if --trace-symbol was specified.
   // This is for debugging.
   if (S->Traced)
     printTraceSymbol(S);
 }

 void warnUnorderableSymbol(const Symbol *Sym);
 } // namespace elf

 std::string toString(const elf::Symbol &B);
 } // namespace lld

 #endif
	//===- Symbols.h ------------------------------------------------- C++ --===//
	//
	// The LLVM Linker
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defines various types of Symbols.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLD_ELF_SYMBOLS_H
	#define LLD_ELF_SYMBOLS_H

	#include "InputSection.h"
	#include "lld/Common/LLVM.h"
	#include "lld/Common/Strings.h"
	#include "llvm/Object/Archive.h"
	#include "llvm/Object/ELF.h"

	namespace lld {
	namespace elf {

	class ArchiveFile;
	class BitcodeFile;
	class BssSection;
	class InputFile;
	class LazyObjFile;
	template <class ELFT> class ObjFile;
	class OutputSection;
	template <class ELFT> class SharedFile;

	// This is a StringRef-like container that doesn't run strlen().
	//
	// ELF string tables contain a lot of null-terminated strings. Most of them
	// are not necessary for the linker because they are names of local symbols,
	// and the linker doesn't use local symbol names for name resolution. So, we
	// use this class to represents strings read from string tables.
	struct StringRefZ {
	StringRefZ(const char *S) : Data(S), Size(-1) {}
	StringRefZ(StringRef S) : Data(S.data()), Size(S.size()) {}

	const char *Data;
	const uint32_t Size;
	};

	// The base class for real symbol classes.
	class Symbol {
	public:
	enum Kind {
	DefinedKind,
	SharedKind,
	UndefinedKind,
	LazyArchiveKind,
	LazyObjectKind,
	};

	Kind kind() const { return static_cast<Kind>(SymbolKind); }

	// The file from which this symbol was created.
	InputFile *File;

	protected:
	const char *NameData;
	mutable uint32_t NameSize;

	public:
	uint32_t DynsymIndex = 0;
	uint32_t GotIndex = -1;
	uint32_t PltIndex = -1;
	uint32_t GlobalDynIndex = -1;

	// This field is a index to the symbol's version definition.
	uint32_t VerdefIndex = -1;

	// Version definition index.
	uint16_t VersionId;

	// Symbol binding. This is not overwritten by replaceSymbol to track
	// changes during resolution. In particular:
	// - An undefined weak is still weak when it resolves to a shared library.
	// - An undefined weak will not fetch archive members, but we have to
	// remember it is weak.
	uint8_t Binding;

	// The following fields have the same meaning as the ELF symbol attributes.
	uint8_t Type; // symbol type
	uint8_t StOther; // st_other field value

	const uint8_t SymbolKind;

	// Symbol visibility. This is the computed minimum visibility of all
	// observed non-DSO symbols.
	unsigned Visibility : 2;

	// True if the symbol was used for linking and thus need to be added to the
	// output file's symbol table. This is true for all symbols except for
	// unreferenced DSO symbols and bitcode symbols that are unreferenced except
	// by other bitcode objects.
	unsigned IsUsedInRegularObj : 1;

	// If this flag is true and the symbol has protected or default visibility, it
	// will appear in .dynsym. This flag is set by interposable DSO symbols in
	// executables, by most symbols in DSOs and executables built with
	// --export-dynamic, and by dynamic lists.
	unsigned ExportDynamic : 1;

	// False if LTO shouldn't inline whatever this symbol points to. If a symbol
	// is overwritten after LTO, LTO shouldn't inline the symbol because it
	// doesn't know the final contents of the symbol.
	unsigned CanInline : 1;

	// True if this symbol is specified by --trace-symbol option.
	unsigned Traced : 1;

	bool includeInDynsym() const;
	uint8_t computeBinding() const;
	bool isWeak() const { return Binding == llvm::ELF::STB_WEAK; }

	bool isUndefined() const { return SymbolKind == UndefinedKind; }
	bool isDefined() const { return SymbolKind == DefinedKind; }
	bool isShared() const { return SymbolKind == SharedKind; }
	bool isLocal() const { return Binding == llvm::ELF::STB_LOCAL; }

	bool isLazy() const {
	return SymbolKind == LazyArchiveKind \|\| SymbolKind == LazyObjectKind;
	}

	// True if this is an undefined weak symbol.
	bool isUndefWeak() const { return isWeak() && isUndefined(); }

	StringRef getName() const {
	if (NameSize == (uint32_t)-1)
	NameSize = strlen(NameData);
	return {NameData, NameSize};
	}

	void parseSymbolVersion();

	bool isInGot() const { return GotIndex != -1U; }
	bool isInPlt() const { return PltIndex != -1U; }

	uint64_t getVA(int64_t Addend = 0) const;

	uint64_t getGotOffset() const;
	uint64_t getGotVA() const;
	uint64_t getGotPltOffset() const;
	uint64_t getGotPltVA() const;
	uint64_t getPltVA() const;
	uint64_t getPltOffset() const;
	uint64_t getSize() const;
	OutputSection *getOutputSection() const;

	protected:
	Symbol(Kind K, InputFile *File, StringRefZ Name, uint8_t Binding,
	uint8_t StOther, uint8_t Type)
	: File(File), NameData(Name.Data), NameSize(Name.Size), Binding(Binding),
	Type(Type), StOther(StOther), SymbolKind(K), NeedsPltAddr(false),
	IsInIplt(false), IsInIgot(false), IsPreemptible(false),
	Used(!Config->GcSections), NeedsTocRestore(false) {}

	public:
	// True the symbol should point to its PLT entry.
	// For SharedSymbol only.
	unsigned NeedsPltAddr : 1;

	// True if this symbol is in the Iplt sub-section of the Plt.
	unsigned IsInIplt : 1;

	// True if this symbol is in the Igot sub-section of the .got.plt or .got.
	unsigned IsInIgot : 1;

	// True if this symbol is preemptible at load time.
	unsigned IsPreemptible : 1;

	// True if an undefined or shared symbol is used from a live section.
	unsigned Used : 1;

	// True if a call to this symbol needs to be followed by a restore of the
	// PPC64 toc pointer.
	unsigned NeedsTocRestore : 1;

	// The Type field may also have this value. It means that we have not yet seen
	// a non-Lazy symbol with this name, so we don't know what its type is. The
	// Type field is normally set to this value for Lazy symbols unless we saw a
	// weak undefined symbol first, in which case we need to remember the original
	// symbol's type in order to check for TLS mismatches.
	enum { UnknownType = 255 };

	bool isSection() const { return Type == llvm::ELF::STT_SECTION; }
	bool isTls() const { return Type == llvm::ELF::STT_TLS; }
	bool isFunc() const { return Type == llvm::ELF::STT_FUNC; }
	bool isGnuIFunc() const { return Type == llvm::ELF::STT_GNU_IFUNC; }
	bool isObject() const { return Type == llvm::ELF::STT_OBJECT; }
	bool isFile() const { return Type == llvm::ELF::STT_FILE; }
	};

	// Represents a symbol that is defined in the current output file.
	class Defined : public Symbol {
	public:
	Defined(InputFile *File, StringRefZ Name, uint8_t Binding, uint8_t StOther,
	uint8_t Type, uint64_t Value, uint64_t Size, SectionBase *Section)
	: Symbol(DefinedKind, File, Name, Binding, StOther, Type), Value(Value),
	Size(Size), Section(Section) {}

	static bool classof(const Symbol *S) { return S->isDefined(); }

	uint64_t Value;
	uint64_t Size;
	SectionBase *Section;
	};

	class Undefined : public Symbol {
	public:
	Undefined(InputFile *File, StringRefZ Name, uint8_t Binding, uint8_t StOther,
	uint8_t Type)
	: Symbol(UndefinedKind, File, Name, Binding, StOther, Type) {}

	static bool classof(const Symbol *S) { return S->kind() == UndefinedKind; }
	};

	class SharedSymbol : public Symbol {
	public:
	static bool classof(const Symbol *S) { return S->kind() == SharedKind; }

	SharedSymbol(InputFile &File, StringRef Name, uint8_t Binding,
	uint8_t StOther, uint8_t Type, uint64_t Value, uint64_t Size,
	uint32_t Alignment, uint32_t VerdefIndex)
	: Symbol(SharedKind, &File, Name, Binding, StOther, Type),
	Alignment(Alignment), Value(Value), Size(Size) {
	this->VerdefIndex = VerdefIndex;
	// GNU ifunc is a mechanism to allow user-supplied functions to
	// resolve PLT slot values at load-time. This is contrary to the
	// regular symbol resolution scheme in which symbols are resolved just
	// by name. Using this hook, you can program how symbols are solved
	// for you program. For example, you can make "memcpy" to be resolved
	// to a SSE-enabled version of memcpy only when a machine running the
	// program supports the SSE instruction set.
	//
	// Naturally, such symbols should always be called through their PLT
	// slots. What GNU ifunc symbols point to are resolver functions, and
	// calling them directly doesn't make sense (unless you are writing a
	// loader).
	//
	// For DSO symbols, we always call them through PLT slots anyway.
	// So there's no difference between GNU ifunc and regular function
	// symbols if they are in DSOs. So we can handle GNU_IFUNC as FUNC.
	if (this->Type == llvm::ELF::STT_GNU_IFUNC)
	this->Type = llvm::ELF::STT_FUNC;
	}

	template <class ELFT> SharedFile<ELFT> &getFile() const {
	return *cast<SharedFile<ELFT>>(File);
	}

	uint32_t Alignment;

	uint64_t Value; // st_value
	uint64_t Size; // st_size
	};

	// LazyArchive and LazyObject represent a symbols that is not yet in the link,
	// but we know where to find it if needed. If the resolver finds both Undefined
	// and Lazy for the same name, it will ask the Lazy to load a file.
	//
	// A special complication is the handling of weak undefined symbols. They should
	// not load a file, but we have to remember we have seen both the weak undefined
	// and the lazy. We represent that with a lazy symbol with a weak binding. This
	// means that code looking for undefined symbols normally also has to take lazy
	// symbols into consideration.

	// This class represents a symbol defined in an archive file. It is
	// created from an archive file header, and it knows how to load an
	// object file from an archive to replace itself with a defined
	// symbol.
	class LazyArchive : public Symbol {
	public:
	LazyArchive(InputFile &File, uint8_t Type,
	const llvm::object::Archive::Symbol S)
	: Symbol(LazyArchiveKind, &File, S.getName(), llvm::ELF::STB_GLOBAL,
	llvm::ELF::STV_DEFAULT, Type),
	Sym(S) {}

	static bool classof(const Symbol *S) { return S->kind() == LazyArchiveKind; }

	InputFile *fetch();

	private:
	const llvm::object::Archive::Symbol Sym;
	};

	// LazyObject symbols represents symbols in object files between
	// --start-lib and --end-lib options.
	class LazyObject : public Symbol {
	public:
	LazyObject(InputFile &File, uint8_t Type, StringRef Name)
	: Symbol(LazyObjectKind, &File, Name, llvm::ELF::STB_GLOBAL,
	llvm::ELF::STV_DEFAULT, Type) {}

	static bool classof(const Symbol *S) { return S->kind() == LazyObjectKind; }
	};

	// Some linker-generated symbols need to be created as
	// Defined symbols.
	struct ElfSym {
	// __bss_start
	static Defined *Bss;

	// etext and _etext
	static Defined *Etext1;
	static Defined *Etext2;

	// edata and _edata
	static Defined *Edata1;
	static Defined *Edata2;

	// end and _end
	static Defined *End1;
	static Defined *End2;

	// The _GLOBAL_OFFSET_TABLE_ symbol is defined by target convention to
	// be at some offset from the base of the .got section, usually 0 or
	// the end of the .got.
	static Defined *GlobalOffsetTable;

	// _gp, _gp_disp and __gnu_local_gp symbols. Only for MIPS.
	static Defined *MipsGp;
	static Defined *MipsGpDisp;
	static Defined *MipsLocalGp;

	// __rela_iplt_end or __rel_iplt_end
	static Defined *RelaIpltEnd;
	};

	// A buffer class that is large enough to hold any Symbol-derived
	// object. We allocate memory using this class and instantiate a symbol
	// using the placement new.
	union SymbolUnion {
	alignas(Defined) char A[sizeof(Defined)];
	alignas(Undefined) char C[sizeof(Undefined)];
	alignas(SharedSymbol) char D[sizeof(SharedSymbol)];
	alignas(LazyArchive) char E[sizeof(LazyArchive)];
	alignas(LazyObject) char F[sizeof(LazyObject)];
	};

	void printTraceSymbol(Symbol *Sym);

	template <typename T, typename... ArgT>
	void replaceSymbol(Symbol *S, ArgT &&... Arg) {
	static_assert(std::is_trivially_destructible<T>(),
	"Symbol types must be trivially destructible");
	static_assert(sizeof(T) <= sizeof(SymbolUnion), "SymbolUnion too small");
	static_assert(alignof(T) <= alignof(SymbolUnion),
	"SymbolUnion not aligned enough");
	assert(static_cast<Symbol >(static_cast<T >(nullptr)) == nullptr &&
	"Not a Symbol");

	Symbol Sym = *S;

	new (S) T(std::forward<ArgT>(Arg)...);

	S->VersionId = Sym.VersionId;
	S->Visibility = Sym.Visibility;
	S->IsUsedInRegularObj = Sym.IsUsedInRegularObj;
	S->ExportDynamic = Sym.ExportDynamic;
	S->CanInline = Sym.CanInline;
	S->Traced = Sym.Traced;

	// Print out a log message if --trace-symbol was specified.
	// This is for debugging.
	if (S->Traced)
	printTraceSymbol(S);
	}

	void warnUnorderableSymbol(const Symbol *Sym);
	} // namespace elf

	std::string toString(const elf::Symbol &B);
	} // namespace lld

	#endif