lld/ELF/Writer.cpp

//===- Writer.cpp ---------------------------------------------------------===//
//
//                             The LLVM Linker
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//

#include "Writer.h"
#include "Config.h"
#include "LinkerScript.h"
#include "OutputSections.h"
#include "SymbolTable.h"
#include "Target.h"

#include "llvm/ADT/SmallPtrSet.h"
#include "llvm/ADT/StringMap.h"
#include "llvm/ADT/StringSwitch.h"
#include "llvm/Support/Endian.h"
#include "llvm/Support/FileOutputBuffer.h"
#include "llvm/Support/StringSaver.h"
#include "llvm/Support/raw_ostream.h"

using namespace llvm;
using namespace llvm::ELF;
using namespace llvm::object;
using namespace llvm::support::endian;

using namespace lld;
using namespace lld::elf;

namespace {
// The writer writes a SymbolTable result to a file.
template <class ELFT> class Writer {
public:
  typedef typename ELFT::uint uintX_t;
  typedef typename ELFT::Shdr Elf_Shdr;
  typedef typename ELFT::Ehdr Elf_Ehdr;
  typedef typename ELFT::Phdr Elf_Phdr;
  typedef typename ELFT::Sym Elf_Sym;
  typedef typename ELFT::SymRange Elf_Sym_Range;
  typedef typename ELFT::Rela Elf_Rela;
  Writer(SymbolTable<ELFT> &S) : Symtab(S) {}
  void run();

private:
  // This describes a program header entry.
  // Each contains type, access flags and range of output sections that will be
  // placed in it.
  struct Phdr {
    Phdr(unsigned Type, unsigned Flags) {
      H.p_type = Type;
      H.p_flags = Flags;
    }
    Elf_Phdr H = {};
    OutputSectionBase<ELFT> *First = nullptr;
    OutputSectionBase<ELFT> *Last = nullptr;
  };

  void copyLocalSymbols();
  void addReservedSymbols();
  void createSections();
  void addPredefinedSections();
  bool needsGot();

  template <class RelTy>
  void scanRelocs(InputSectionBase<ELFT> &C, ArrayRef<RelTy> Rels);

  void scanRelocs(InputSection<ELFT> &C);
  void scanRelocs(InputSectionBase<ELFT> &S, const Elf_Shdr &RelSec);
  void createPhdrs();
  void assignAddresses();
  void assignFileOffsets();
  void setPhdrs();
  void fixHeaders();
  void fixSectionAlignments();
  void fixAbsoluteSymbols();
  void openFile();
  void writeHeader();
  void writeSections();
  void writeBuildId();
  bool isDiscarded(InputSectionBase<ELFT> *IS) const;
  StringRef getOutputSectionName(InputSectionBase<ELFT> *S) const;
  bool needsInterpSection() const {
    return !Symtab.getSharedFiles().empty() && !Config->DynamicLinker.empty();
  }
  bool isOutputDynamic() const {
    return !Symtab.getSharedFiles().empty() || Config->Pic;
  }
  template <class RelTy>
  void scanRelocsForThunks(const elf::ObjectFile<ELFT> &File,
                           ArrayRef<RelTy> Rels);

  void ensureBss();
  void addCommonSymbols(std::vector<DefinedCommon *> &Syms);
  void addCopyRelSymbol(SharedSymbol<ELFT> *Sym);

  std::unique_ptr<llvm::FileOutputBuffer> Buffer;

  BumpPtrAllocator Alloc;
  std::vector<OutputSectionBase<ELFT> *> OutputSections;
  std::vector<std::unique_ptr<OutputSectionBase<ELFT>>> OwningSections;

  void addRelIpltSymbols();
  void addStartEndSymbols();
  void addStartStopSymbols(OutputSectionBase<ELFT> *Sec);

  SymbolTable<ELFT> &Symtab;
  std::vector<Phdr> Phdrs;

  uintX_t FileSize;
  uintX_t SectionHeaderOff;

  // Flag to force GOT to be in output if we have relocations
  // that relies on its address.
  bool HasGotOffRel = false;
};
} // anonymous namespace

template <class ELFT> void elf::writeResult(SymbolTable<ELFT> *Symtab) {
  typedef typename ELFT::uint uintX_t;
  typedef typename ELFT::Ehdr Elf_Ehdr;

  // Create singleton output sections.
  DynamicSection<ELFT> Dynamic(*Symtab);
  EhFrameHeader<ELFT> EhFrameHdr;
  GotSection<ELFT> Got;
  InterpSection<ELFT> Interp;
  PltSection<ELFT> Plt;
  RelocationSection<ELFT> RelaDyn(Config->Rela ? ".rela.dyn" : ".rel.dyn");
  StringTableSection<ELFT> DynStrTab(".dynstr", true);
  StringTableSection<ELFT> ShStrTab(".shstrtab", false);
  SymbolTableSection<ELFT> DynSymTab(*Symtab, DynStrTab);

  OutputSectionBase<ELFT> ElfHeader("", 0, SHF_ALLOC);
  ElfHeader.setSize(sizeof(Elf_Ehdr));
  OutputSectionBase<ELFT> ProgramHeaders("", 0, SHF_ALLOC);
  ProgramHeaders.updateAlign(sizeof(uintX_t));

  // Instantiate optional output sections if they are needed.
  std::unique_ptr<BuildIdSection<ELFT>> BuildId;
  std::unique_ptr<GnuHashTableSection<ELFT>> GnuHashTab;
  std::unique_ptr<GotPltSection<ELFT>> GotPlt;
  std::unique_ptr<HashTableSection<ELFT>> HashTab;
  std::unique_ptr<RelocationSection<ELFT>> RelaPlt;
  std::unique_ptr<StringTableSection<ELFT>> StrTab;
  std::unique_ptr<SymbolTableSection<ELFT>> SymTabSec;
  std::unique_ptr<OutputSection<ELFT>> MipsRldMap;

  if (Config->BuildId == BuildIdKind::Fnv1)
    BuildId.reset(new BuildIdFnv1<ELFT>);
  else if (Config->BuildId == BuildIdKind::Md5)
    BuildId.reset(new BuildIdMd5<ELFT>);
  else if (Config->BuildId == BuildIdKind::Sha1)
    BuildId.reset(new BuildIdSha1<ELFT>);

  if (Config->GnuHash)
    GnuHashTab.reset(new GnuHashTableSection<ELFT>);
  if (Config->SysvHash)
    HashTab.reset(new HashTableSection<ELFT>);
  if (Target->UseLazyBinding) {
    StringRef S = Config->Rela ? ".rela.plt" : ".rel.plt";
    GotPlt.reset(new GotPltSection<ELFT>);
    RelaPlt.reset(new RelocationSection<ELFT>(S));
  }
  if (!Config->StripAll) {
    StrTab.reset(new StringTableSection<ELFT>(".strtab", false));
    SymTabSec.reset(new SymbolTableSection<ELFT>(*Symtab, *StrTab));
  }
  if (Config->EMachine == EM_MIPS && !Config->Shared) {
    // This is a MIPS specific section to hold a space within the data segment
    // of executable file which is pointed to by the DT_MIPS_RLD_MAP entry.
    // See "Dynamic section" in Chapter 5 in the following document:
    // ftp://www.linux-mips.org/pub/linux/mips/doc/ABI/mipsabi.pdf
    MipsRldMap.reset(new OutputSection<ELFT>(".rld_map", SHT_PROGBITS,
                                             SHF_ALLOC | SHF_WRITE));
    MipsRldMap->setSize(sizeof(uintX_t));
    MipsRldMap->updateAlign(sizeof(uintX_t));
  }

  Out<ELFT>::BuildId = BuildId.get();
  Out<ELFT>::DynStrTab = &DynStrTab;
  Out<ELFT>::DynSymTab = &DynSymTab;
  Out<ELFT>::Dynamic = &Dynamic;
  Out<ELFT>::EhFrameHdr = &EhFrameHdr;
  Out<ELFT>::GnuHashTab = GnuHashTab.get();
  Out<ELFT>::Got = &Got;
  Out<ELFT>::GotPlt = GotPlt.get();
  Out<ELFT>::HashTab = HashTab.get();
  Out<ELFT>::Interp = &Interp;
  Out<ELFT>::Plt = &Plt;
  Out<ELFT>::RelaDyn = &RelaDyn;
  Out<ELFT>::RelaPlt = RelaPlt.get();
  Out<ELFT>::ShStrTab = &ShStrTab;
  Out<ELFT>::StrTab = StrTab.get();
  Out<ELFT>::SymTab = SymTabSec.get();
  Out<ELFT>::Bss = nullptr;
  Out<ELFT>::MipsRldMap = MipsRldMap.get();
  Out<ELFT>::Opd = nullptr;
  Out<ELFT>::OpdBuf = nullptr;
  Out<ELFT>::TlsPhdr = nullptr;
  Out<ELFT>::ElfHeader = &ElfHeader;
  Out<ELFT>::ProgramHeaders = &ProgramHeaders;

  Writer<ELFT>(*Symtab).run();
}

// The main function of the writer.
template <class ELFT> void Writer<ELFT>::run() {
  if (!Config->DiscardAll)
    copyLocalSymbols();
  addReservedSymbols();
  createSections();
  if (HasError)
    return;

  if (Config->Relocatable) {
    assignFileOffsets();
  } else {
    createPhdrs();
    fixHeaders();
    if (ScriptConfig->DoLayout) {
      Script<ELFT>::X->assignAddresses(OutputSections);
    } else {
      fixSectionAlignments();
      assignAddresses();
    }
    assignFileOffsets();
    setPhdrs();
    fixAbsoluteSymbols();
  }

  openFile();
  if (HasError)
    return;
  writeHeader();
  writeSections();
  writeBuildId();
  if (HasError)
    return;
  check(Buffer->commit());
}

namespace {
template <bool Is64Bits> struct SectionKey {
  typedef typename std::conditional<Is64Bits, uint64_t, uint32_t>::type uintX_t;
  StringRef Name;
  uint32_t Type;
  uintX_t Flags;
  uintX_t Alignment;
};
}
namespace llvm {
template <bool Is64Bits> struct DenseMapInfo<SectionKey<Is64Bits>> {
  static SectionKey<Is64Bits> getEmptyKey() {
    return SectionKey<Is64Bits>{DenseMapInfo<StringRef>::getEmptyKey(), 0, 0,
                                0};
  }
  static SectionKey<Is64Bits> getTombstoneKey() {
    return SectionKey<Is64Bits>{DenseMapInfo<StringRef>::getTombstoneKey(), 0,
                                0, 0};
  }
  static unsigned getHashValue(const SectionKey<Is64Bits> &Val) {
    return hash_combine(Val.Name, Val.Type, Val.Flags, Val.Alignment);
  }
  static bool isEqual(const SectionKey<Is64Bits> &LHS,
                      const SectionKey<Is64Bits> &RHS) {
    return DenseMapInfo<StringRef>::isEqual(LHS.Name, RHS.Name) &&
           LHS.Type == RHS.Type && LHS.Flags == RHS.Flags &&
           LHS.Alignment == RHS.Alignment;
  }
};
}

// Returns the number of relocations processed.
template <class ELFT>
static unsigned handleTlsRelocation(uint32_t Type, SymbolBody &Body,
                                    InputSectionBase<ELFT> &C,
                                    typename ELFT::uint Offset,
                                    typename ELFT::uint Addend, RelExpr Expr) {
  if (!(C.getSectionHdr()->sh_flags & SHF_ALLOC))
    return 0;

  if (!Body.isTls())
    return 0;

  typedef typename ELFT::uint uintX_t;
  if (Expr == R_TLSLD_PC || Expr == R_TLSLD) {
    // Local-Dynamic relocs can be relaxed to Local-Exec.
    if (!Config->Shared) {
      C.Relocations.push_back(
          {R_RELAX_TLS_LD_TO_LE, Type, Offset, Addend, &Body});
      return 2;
    }
    if (Out<ELFT>::Got->addTlsIndex())
      Out<ELFT>::RelaDyn->addReloc({Target->TlsModuleIndexRel, Out<ELFT>::Got,
                                    Out<ELFT>::Got->getTlsIndexOff(), false,
                                    nullptr, 0});
    C.Relocations.push_back({Expr, Type, Offset, Addend, &Body});
    return 1;
  }

  // Local-Dynamic relocs can be relaxed to Local-Exec.
  if (Target->isTlsLocalDynamicRel(Type) && !Config->Shared) {
    C.Relocations.push_back(
        {R_RELAX_TLS_LD_TO_LE, Type, Offset, Addend, &Body});
    return 1;
  }

  if (Target->isTlsGlobalDynamicRel(Type)) {
    if (Config->Shared) {
      if (Out<ELFT>::Got->addDynTlsEntry(Body)) {
        uintX_t Off = Out<ELFT>::Got->getGlobalDynOffset(Body);
        Out<ELFT>::RelaDyn->addReloc(
            {Target->TlsModuleIndexRel, Out<ELFT>::Got, Off, false, &Body, 0});
        Out<ELFT>::RelaDyn->addReloc({Target->TlsOffsetRel, Out<ELFT>::Got,
                                      Off + (uintX_t)sizeof(uintX_t), false,
                                      &Body, 0});
      }
      C.Relocations.push_back({Expr, Type, Offset, Addend, &Body});
      return 1;
    }

    // Global-Dynamic relocs can be relaxed to Initial-Exec or Local-Exec
    // depending on the symbol being locally defined or not.
    if (Body.isPreemptible()) {
      Expr =
          Expr == R_TLSGD_PC ? R_RELAX_TLS_GD_TO_IE_PC : R_RELAX_TLS_GD_TO_IE;
      C.Relocations.push_back({Expr, Type, Offset, Addend, &Body});
      if (!Body.isInGot()) {
        Out<ELFT>::Got->addEntry(Body);
        Out<ELFT>::RelaDyn->addReloc({Target->TlsGotRel, Out<ELFT>::Got,
                                      Body.getGotOffset<ELFT>(), false, &Body,
                                      0});
      }
      return 2;
    }
    C.Relocations.push_back(
        {R_RELAX_TLS_GD_TO_LE, Type, Offset, Addend, &Body});
    return Target->TlsGdToLeSkip;
  }

  // Initial-Exec relocs can be relaxed to Local-Exec if the symbol is locally
  // defined.
  if (Target->isTlsInitialExecRel(Type) && !Config->Shared &&
      !Body.isPreemptible()) {
    C.Relocations.push_back(
        {R_RELAX_TLS_IE_TO_LE, Type, Offset, Addend, &Body});
    return 1;
  }
  return 0;
}

// Some targets might require creation of thunks for relocations. Now we
// support only MIPS which requires LA25 thunk to call PIC code from non-PIC
// one. Scan relocations to find each one requires thunk.
template <class ELFT>
template <class RelTy>
void Writer<ELFT>::scanRelocsForThunks(const elf::ObjectFile<ELFT> &File,
                                       ArrayRef<RelTy> Rels) {
  for (const RelTy &RI : Rels) {
    uint32_t Type = RI.getType(Config->Mips64EL);
    uint32_t SymIndex = RI.getSymbol(Config->Mips64EL);
    SymbolBody &Body = File.getSymbolBody(SymIndex).repl();
    if (Body.hasThunk() || !Target->needsThunk(Type, File, Body))
      continue;
    auto *D = cast<DefinedRegular<ELFT>>(&Body);
    auto *S = cast<InputSection<ELFT>>(D->Section);
    S->addThunk(Body);
  }
}

template <endianness E> static int16_t readSignedLo16(const uint8_t *Loc) {
  return read32<E>(Loc) & 0xffff;
}

template <class RelTy>
static uint32_t getMipsPairType(const RelTy *Rel, const SymbolBody &Sym) {
  switch (Rel->getType(Config->Mips64EL)) {
  case R_MIPS_HI16:
    return R_MIPS_LO16;
  case R_MIPS_GOT16:
    return Sym.isLocal() ? R_MIPS_LO16 : R_MIPS_NONE;
  case R_MIPS_PCHI16:
    return R_MIPS_PCLO16;
  case R_MICROMIPS_HI16:
    return R_MICROMIPS_LO16;
  default:
    return R_MIPS_NONE;
  }
}

template <class ELFT, class RelTy>
static int32_t findMipsPairedAddend(const uint8_t *Buf, const uint8_t *BufLoc,
                                    SymbolBody &Sym, const RelTy *Rel,
                                    const RelTy *End) {
  uint32_t SymIndex = Rel->getSymbol(Config->Mips64EL);
  uint32_t Type = getMipsPairType(Rel, Sym);

  // Some MIPS relocations use addend calculated from addend of the relocation
  // itself and addend of paired relocation. ABI requires to compute such
  // combined addend in case of REL relocation record format only.
  // See p. 4-17 at ftp://www.linux-mips.org/pub/linux/mips/doc/ABI/mipsabi.pdf
  if (RelTy::IsRela || Type == R_MIPS_NONE)
    return 0;

  for (const RelTy *RI = Rel; RI != End; ++RI) {
    if (RI->getType(Config->Mips64EL) != Type)
      continue;
    if (RI->getSymbol(Config->Mips64EL) != SymIndex)
      continue;
    const endianness E = ELFT::TargetEndianness;
    return ((read32<E>(BufLoc) & 0xffff) << 16) +
           readSignedLo16<E>(Buf + RI->r_offset);
  }
  unsigned OldType = Rel->getType(Config->Mips64EL);
  StringRef OldName = getELFRelocationTypeName(Config->EMachine, OldType);
  StringRef NewName = getELFRelocationTypeName(Config->EMachine, Type);
  warning("can't find matching " + NewName + " relocation for " + OldName);
  return 0;
}

// True if non-preemptable symbol always has the same value regardless of where
// the DSO is loaded.
template <class ELFT> static bool isAbsolute(const SymbolBody &Body) {
  Symbol *Sym = Body.Backref;
  if (Body.isUndefined() && Sym->isWeak())
    return true; // always 0
  if (const auto *DR = dyn_cast<DefinedRegular<ELFT>>(&Body))
    return DR->Section == nullptr; // Absolute symbol.
  return false;
}

namespace {
enum PltNeed { Plt_No, Plt_Explicit, Plt_Implicit };
}

static bool needsPlt(RelExpr Expr) {
  return Expr == R_PLT_PC || Expr == R_PPC_PLT_OPD || Expr == R_PLT;
}

static PltNeed needsPlt(RelExpr Expr, uint32_t Type, const SymbolBody &S) {
  if (S.isGnuIFunc())
    return Plt_Explicit;
  if (S.isPreemptible() && needsPlt(Expr))
    return Plt_Explicit;

  // This handles a non PIC program call to function in a shared library.
  // In an ideal world, we could just report an error saying the relocation
  // can overflow at runtime.
  // In the real world with glibc, crt1.o has a R_X86_64_PC32 pointing to
  // libc.so.
  //
  // The general idea on how to handle such cases is to create a PLT entry
  // and use that as the function value.
  //
  // For the static linking part, we just return true and everything else
  // will use the the PLT entry as the address.
  //
  // The remaining problem is making sure pointer equality still works. We
  // need the help of the dynamic linker for that. We let it know that we have
  // a direct reference to a so symbol by creating an undefined symbol with a
  // non zero st_value. Seeing that, the dynamic linker resolves the symbol to
  // the value of the symbol we created. This is true even for got entries, so
  // pointer equality is maintained. To avoid an infinite loop, the only entry
  // that points to the real function is a dedicated got entry used by the
  // plt. That is identified by special relocation types (R_X86_64_JUMP_SLOT,
  // R_386_JMP_SLOT, etc).
  if (S.isShared() && !Config->Pic && S.isFunc())
    if (!refersToGotEntry(Expr))
      return Plt_Implicit;

  return Plt_No;
}

static bool needsCopyRel(RelExpr E, const SymbolBody &S) {
  if (Config->Shared)
    return false;
  if (!S.isShared())
    return false;
  if (!S.isObject())
    return false;
  if (refersToGotEntry(E))
    return false;
  if (needsPlt(E))
    return false;
  if (E == R_SIZE)
    return false;
  return true;
}

// The reason we have to do this early scan is as follows
// * To mmap the output file, we need to know the size
// * For that, we need to know how many dynamic relocs we will have.
// It might be possible to avoid this by outputting the file with write:
// * Write the allocated output sections, computing addresses.
// * Apply relocations, recording which ones require a dynamic reloc.
// * Write the dynamic relocations.
// * Write the rest of the file.
// This would have some drawbacks. For example, we would only know if .rela.dyn
// is needed after applying relocations. If it is, it will go after rw and rx
// sections. Given that it is ro, we will need an extra PT_LOAD. This
// complicates things for the dynamic linker and means we would have to reserve
// space for the extra PT_LOAD even if we end up not using it.
template <class ELFT>
template <class RelTy>
void Writer<ELFT>::scanRelocs(InputSectionBase<ELFT> &C, ArrayRef<RelTy> Rels) {
  uintX_t Flags = C.getSectionHdr()->sh_flags;
  bool IsAlloc = Flags & SHF_ALLOC;
  bool IsWrite = Flags & SHF_WRITE;

  auto AddDyn = [=](const DynamicReloc<ELFT> &Reloc) {
    if (IsAlloc)
      Out<ELFT>::RelaDyn->addReloc(Reloc);
  };

  const elf::ObjectFile<ELFT> &File = *C.getFile();
  ArrayRef<uint8_t> SectionData = C.getSectionData();
  const uint8_t *Buf = SectionData.begin();
  for (auto I = Rels.begin(), E = Rels.end(); I != E; ++I) {
    const RelTy &RI = *I;
    uint32_t SymIndex = RI.getSymbol(Config->Mips64EL);
    SymbolBody &OrigBody = File.getSymbolBody(SymIndex);
    Symbol *Sym = OrigBody.Backref;
    SymbolBody &Body = Sym ? *Sym->Body : OrigBody;
    uint32_t Type = RI.getType(Config->Mips64EL);

    // Ignore "hint" relocation because it is for optional code optimization.
    if (Target->isHintRel(Type))
      continue;

    uintX_t Offset = C.getOffset(RI.r_offset);
    if (Offset == (uintX_t)-1)
      continue;

    // Set "used" bit for --as-needed.
    if (OrigBody.isUndefined() && Sym && !Sym->isWeak())
      if (auto *S = dyn_cast<SharedSymbol<ELFT>>(&Body))
        S->File->IsUsed = true;

    RelExpr Expr = Target->getRelExpr(Type, Body);

    // This relocation does not require got entry, but it is relative to got and
    // needs it to be created. Here we request for that.
    if (Expr == R_GOTONLY_PC || Expr == R_GOTREL)
      HasGotOffRel = true;

    uintX_t Addend = getAddend<ELFT>(RI);
    const uint8_t *BufLoc = Buf + RI.r_offset;
    if (!RelTy::IsRela)
      Addend += Target->getImplicitAddend(BufLoc, Type);
    if (Config->EMachine == EM_MIPS) {
      Addend += findMipsPairedAddend<ELFT>(Buf, BufLoc, Body, &RI, E);
      if (Type == R_MIPS_LO16 && Expr == R_PC)
        // R_MIPS_LO16 expression has R_PC type iif the target is _gp_disp
        // symbol. In that case we should use the following formula for
        // calculation "AHL + GP – P + 4". Let's add 4 right here.
        // For details see p. 4-19 at
        // ftp://www.linux-mips.org/pub/linux/mips/doc/ABI/mipsabi.pdf
        Addend += 4;
    }

    if (unsigned Processed =
            handleTlsRelocation<ELFT>(Type, Body, C, Offset, Addend, Expr)) {
      I += (Processed - 1);
      continue;
    }

    if (Expr == R_GOT && !Target->isRelRelative(Type) && Config->Shared)
      AddDyn({Target->RelativeRel, C.OutSec, Offset, true, &Body,
              getAddend<ELFT>(RI)});

    // If a symbol in a DSO is referenced directly instead of through GOT
    // in a read-only section, we need to create a copy relocation for the
    // symbol.
    if (auto *B = dyn_cast<SharedSymbol<ELFT>>(&Body)) {
      if (IsAlloc && !IsWrite && needsCopyRel(Expr, *B)) {
        if (!B->needsCopy())
          addCopyRelSymbol(B);
        C.Relocations.push_back({Expr, Type, Offset, Addend, &Body});
        continue;
      }
    }

    bool Preemptible = Body.isPreemptible();

    // If a relocation needs PLT, we create a PLT and a GOT slot
    // for the symbol.
    PltNeed NeedPlt = needsPlt(Expr, Type, Body);
    if (NeedPlt) {
      if (NeedPlt == Plt_Implicit)
        Body.NeedsCopyOrPltAddr = true;
      RelExpr E = Expr;
      if (Expr == R_PPC_OPD)
        E = R_PPC_PLT_OPD;
      else if (Expr == R_PC)
        E = R_PLT_PC;
      else if (Expr == R_ABS)
        E = R_PLT;
      C.Relocations.push_back({E, Type, Offset, Addend, &Body});

      if (Body.isInPlt())
        continue;
      Out<ELFT>::Plt->addEntry(Body);

      uint32_t Rel;
      if (Body.isGnuIFunc())
        Rel = Preemptible ? Target->PltRel : Target->IRelativeRel;
      else
        Rel = Target->UseLazyBinding ? Target->PltRel : Target->GotRel;

      if (Target->UseLazyBinding) {
        Out<ELFT>::GotPlt->addEntry(Body);
        if (IsAlloc)
          Out<ELFT>::RelaPlt->addReloc({Rel, Out<ELFT>::GotPlt,
                                        Body.getGotPltOffset<ELFT>(),
                                        !Preemptible, &Body, 0});
      } else {
        if (Body.isInGot())
          continue;
        Out<ELFT>::Got->addEntry(Body);
        AddDyn({Rel, Out<ELFT>::Got, Body.getGotOffset<ELFT>(), !Preemptible,
                &Body, 0});
      }
      continue;
    }

    // We decided not to use a plt. Optimize a reference to the plt to a
    // reference to the symbol itself.
    if (Expr == R_PLT_PC)
      Expr = R_PC;
    if (Expr == R_PPC_PLT_OPD)
      Expr = R_PPC_OPD;
    if (Expr == R_PLT)
      Expr = R_ABS;

    if (Target->needsThunk(Type, File, Body)) {
      C.Relocations.push_back({R_THUNK, Type, Offset, Addend, &Body});
      continue;
    }

    // If a relocation needs GOT, we create a GOT slot for the symbol.
    if (refersToGotEntry(Expr)) {
      uint32_t T = Body.isTls() ? Target->getTlsGotRel(Type) : Type;
      if (Config->EMachine == EM_MIPS && Expr == R_GOT_OFF)
        Addend -= MipsGPOffset;
      C.Relocations.push_back({Expr, T, Offset, Addend, &Body});
      if (Body.isInGot())
        continue;
      Out<ELFT>::Got->addEntry(Body);

      if (Config->EMachine == EM_MIPS)
        // MIPS ABI has special rules to process GOT entries
        // and doesn't require relocation entries for them.
        // See "Global Offset Table" in Chapter 5 in the following document
        // for detailed description:
        // ftp://www.linux-mips.org/pub/linux/mips/doc/ABI/mipsabi.pdf
        continue;

      if (Preemptible || (Config->Pic && !isAbsolute<ELFT>(Body))) {
        uint32_t DynType;
        if (Body.isTls())
          DynType = Target->TlsGotRel;
        else if (Preemptible)
          DynType = Target->GotRel;
        else
          DynType = Target->RelativeRel;
        AddDyn({DynType, Out<ELFT>::Got, Body.getGotOffset<ELFT>(),
                !Preemptible, &Body, 0});
      }
      continue;
    }

    if (Preemptible) {
      // We don't know anything about the finaly symbol. Just ask the dynamic
      // linker to handle the relocation for us.
      AddDyn({Target->getDynRel(Type), C.OutSec, Offset, false, &Body, Addend});
      // MIPS ABI turns using of GOT and dynamic relocations inside out.
      // While regular ABI uses dynamic relocations to fill up GOT entries
      // MIPS ABI requires dynamic linker to fills up GOT entries using
      // specially sorted dynamic symbol table. This affects even dynamic
      // relocations against symbols which do not require GOT entries
      // creation explicitly, i.e. do not have any GOT-relocations. So if
      // a preemptible symbol has a dynamic relocation we anyway have
      // to create a GOT entry for it.
      // If a non-preemptible symbol has a dynamic relocation against it,
      // dynamic linker takes it st_value, adds offset and writes down
      // result of the dynamic relocation. In case of preemptible symbol
      // dynamic linker performs symbol resolution, writes the symbol value
      // to the GOT entry and reads the GOT entry when it needs to perform
      // a dynamic relocation.
      // ftp://www.linux-mips.org/pub/linux/mips/doc/ABI/mipsabi.pdf p.4-19
      if (Config->EMachine == EM_MIPS && !Body.isInGot())
        Out<ELFT>::Got->addEntry(Body);
      continue;
    }

    if (Config->EMachine == EM_PPC64 && RI.getType(false) == R_PPC64_TOC) {
      C.Relocations.push_back({R_PPC_TOC, Type, Offset, Addend, &Body});
      AddDyn({R_PPC64_RELATIVE, C.OutSec, Offset, false, nullptr,
              (uintX_t)getPPC64TocBase() + Addend});
      continue;
    }

    // We know that this is the final symbol. If the program being produced
    // is position independent, the final value is still not known.
    // If the relocation depends on the symbol value (not the size or distances
    // in the output), we still need some help from the dynamic linker.
    // We can however do better than just copying the incoming relocation. We
    // can process some of it and and just ask the dynamic linker to add the
    // load address.
    if (!Config->Pic || Target->isRelRelative(Type) || Expr == R_PC ||
        Expr == R_SIZE || isAbsolute<ELFT>(Body)) {
      if (Config->EMachine == EM_MIPS && Body.isLocal() &&
          (Type == R_MIPS_GPREL16 || Type == R_MIPS_GPREL32)) {
        Expr = R_ABS;
        Addend += File.getMipsGp0();
      }
      C.Relocations.push_back({Expr, Type, Offset, Addend, &Body});
      continue;
    }

    AddDyn({Target->RelativeRel, C.OutSec, Offset, true, &Body, Addend});
    C.Relocations.push_back({R_ABS, Type, Offset, Addend, &Body});
  }

  // Scan relocations for necessary thunks.
  if (Config->EMachine == EM_MIPS)
    scanRelocsForThunks(File, Rels);
}

template <class ELFT> void Writer<ELFT>::scanRelocs(InputSection<ELFT> &C) {
  for (const Elf_Shdr *RelSec : C.RelocSections)
    scanRelocs(C, *RelSec);
}

template <class ELFT>
void Writer<ELFT>::scanRelocs(InputSectionBase<ELFT> &S,
                              const Elf_Shdr &RelSec) {
  ELFFile<ELFT> &EObj = S.getFile()->getObj();
  if (RelSec.sh_type == SHT_RELA)
    scanRelocs(S, EObj.relas(&RelSec));
  else
    scanRelocs(S, EObj.rels(&RelSec));
}

template <class ELFT>
static void reportUndefined(SymbolTable<ELFT> &Symtab, SymbolBody *Sym) {
  if (!Config->NoUndefined) {
    if (Config->Relocatable)
      return;
    if (Config->Shared)
      if (Sym->Backref->Visibility == STV_DEFAULT)
        return;
  }

  std::string Msg = "undefined symbol: " + Sym->getName().str();
  if (InputFile *File = Symtab.findFile(Sym))
    Msg += " in " + File->getName().str();
  if (Config->NoinhibitExec)
    warning(Msg);
  else
    error(Msg);
}

template <class ELFT>
static bool shouldKeepInSymtab(InputSectionBase<ELFT> *Sec, StringRef SymName,
                               const SymbolBody &B) {
  if (B.isFile())
    return false;

  // We keep sections in symtab for relocatable output.
  if (B.isSection())
    return Config->Relocatable;

  // If sym references a section in a discarded group, don't keep it.
  if (Sec == &InputSection<ELFT>::Discarded)
    return false;

  if (Config->DiscardNone)
    return true;

  // In ELF assembly .L symbols are normally discarded by the assembler.
  // If the assembler fails to do so, the linker discards them if
  // * --discard-locals is used.
  // * The symbol is in a SHF_MERGE section, which is normally the reason for
  //   the assembler keeping the .L symbol.
  if (!SymName.startswith(".L") && !SymName.empty())
    return true;

  if (Config->DiscardLocals)
    return false;

  return !(Sec->getSectionHdr()->sh_flags & SHF_MERGE);
}

// Local symbols are not in the linker's symbol table. This function scans
// each object file's symbol table to copy local symbols to the output.
template <class ELFT> void Writer<ELFT>::copyLocalSymbols() {
  if (!Out<ELFT>::SymTab)
    return;
  for (const std::unique_ptr<elf::ObjectFile<ELFT>> &F :
       Symtab.getObjectFiles()) {
    const char *StrTab = F->getStringTable().data();
    for (SymbolBody *B : F->getLocalSymbols()) {
      auto *DR = dyn_cast<DefinedRegular<ELFT>>(B);
      // No reason to keep local undefined symbol in symtab.
      if (!DR)
        continue;
      StringRef SymName(StrTab + B->getNameOffset());
      InputSectionBase<ELFT> *Sec = DR->Section;
      if (!shouldKeepInSymtab<ELFT>(Sec, SymName, *B))
        continue;
      if (Sec) {
        if (!Sec->Live)
          continue;

        // Garbage collection is normally able to remove local symbols if they
        // point to gced sections. In the case of SHF_MERGE sections, we want it
        // to also be able to drop them if part of the section is gced.
        // We could look at the section offset map to keep some of these
        // symbols, but almost all local symbols are .L* symbols, so it
        // is probably not worth the complexity.
        if (Config->GcSections && isa<MergeInputSection<ELFT>>(Sec))
          continue;
      }
      ++Out<ELFT>::SymTab->NumLocals;
      if (Config->Relocatable)
        B->DynsymIndex = Out<ELFT>::SymTab->NumLocals;
      F->KeptLocalSyms.push_back(
          std::make_pair(DR, Out<ELFT>::SymTab->StrTabSec.addString(SymName)));
    }
  }
}

// PPC64 has a number of special SHT_PROGBITS+SHF_ALLOC+SHF_WRITE sections that
// we would like to make sure appear is a specific order to maximize their
// coverage by a single signed 16-bit offset from the TOC base pointer.
// Conversely, the special .tocbss section should be first among all SHT_NOBITS
// sections. This will put it next to the loaded special PPC64 sections (and,
// thus, within reach of the TOC base pointer).
static int getPPC64SectionRank(StringRef SectionName) {
  return StringSwitch<int>(SectionName)
      .Case(".tocbss", 0)
      .Case(".branch_lt", 2)
      .Case(".toc", 3)
      .Case(".toc1", 4)
      .Case(".opd", 5)
      .Default(1);
}

template <class ELFT> static bool isRelroSection(OutputSectionBase<ELFT> *Sec) {
  if (!Config->ZRelro)
    return false;
  typename OutputSectionBase<ELFT>::uintX_t Flags = Sec->getFlags();
  if (!(Flags & SHF_ALLOC) || !(Flags & SHF_WRITE))
    return false;
  if (Flags & SHF_TLS)
    return true;
  uint32_t Type = Sec->getType();
  if (Type == SHT_INIT_ARRAY || Type == SHT_FINI_ARRAY ||
      Type == SHT_PREINIT_ARRAY)
    return true;
  if (Sec == Out<ELFT>::GotPlt)
    return Config->ZNow;
  if (Sec == Out<ELFT>::Dynamic || Sec == Out<ELFT>::Got)
    return true;
  StringRef S = Sec->getName();
  return S == ".data.rel.ro" || S == ".ctors" || S == ".dtors" || S == ".jcr" ||
         S == ".eh_frame";
}

// Output section ordering is determined by this function.
template <class ELFT>
static bool compareSections(OutputSectionBase<ELFT> *A,
                            OutputSectionBase<ELFT> *B) {
  typedef typename ELFT::uint uintX_t;

  int Comp = Script<ELFT>::X->compareSections(A->getName(), B->getName());
  if (Comp != 0)
    return Comp < 0;

  uintX_t AFlags = A->getFlags();
  uintX_t BFlags = B->getFlags();

  // Allocatable sections go first to reduce the total PT_LOAD size and
  // so debug info doesn't change addresses in actual code.
  bool AIsAlloc = AFlags & SHF_ALLOC;
  bool BIsAlloc = BFlags & SHF_ALLOC;
  if (AIsAlloc != BIsAlloc)
    return AIsAlloc;

  // We don't have any special requirements for the relative order of
  // two non allocatable sections.
  if (!AIsAlloc)
    return false;

  // We want the read only sections first so that they go in the PT_LOAD
  // covering the program headers at the start of the file.
  bool AIsWritable = AFlags & SHF_WRITE;
  bool BIsWritable = BFlags & SHF_WRITE;
  if (AIsWritable != BIsWritable)
    return BIsWritable;

  // For a corresponding reason, put non exec sections first (the program
  // header PT_LOAD is not executable).
  bool AIsExec = AFlags & SHF_EXECINSTR;
  bool BIsExec = BFlags & SHF_EXECINSTR;
  if (AIsExec != BIsExec)
    return BIsExec;

  // If we got here we know that both A and B are in the same PT_LOAD.

  // The TLS initialization block needs to be a single contiguous block in a R/W
  // PT_LOAD, so stick TLS sections directly before R/W sections. The TLS NOBITS
  // sections are placed here as they don't take up virtual address space in the
  // PT_LOAD.
  bool AIsTls = AFlags & SHF_TLS;
  bool BIsTls = BFlags & SHF_TLS;
  if (AIsTls != BIsTls)
    return AIsTls;

  // The next requirement we have is to put nobits sections last. The
  // reason is that the only thing the dynamic linker will see about
  // them is a p_memsz that is larger than p_filesz. Seeing that it
  // zeros the end of the PT_LOAD, so that has to correspond to the
  // nobits sections.
  bool AIsNoBits = A->getType() == SHT_NOBITS;
  bool BIsNoBits = B->getType() == SHT_NOBITS;
  if (AIsNoBits != BIsNoBits)
    return BIsNoBits;

  // We place RelRo section before plain r/w ones.
  bool AIsRelRo = isRelroSection(A);
  bool BIsRelRo = isRelroSection(B);
  if (AIsRelRo != BIsRelRo)
    return AIsRelRo;

  // Some architectures have additional ordering restrictions for sections
  // within the same PT_LOAD.
  if (Config->EMachine == EM_PPC64)
    return getPPC64SectionRank(A->getName()) <
           getPPC64SectionRank(B->getName());

  return false;
}

// The .bss section does not exist if no input file has a .bss section.
// This function creates one if that's the case.
template <class ELFT> void Writer<ELFT>::ensureBss() {
  if (Out<ELFT>::Bss)
    return;
  Out<ELFT>::Bss =
      new OutputSection<ELFT>(".bss", SHT_NOBITS, SHF_ALLOC | SHF_WRITE);
  OwningSections.emplace_back(Out<ELFT>::Bss);
  OutputSections.push_back(Out<ELFT>::Bss);
}

// Until this function is called, common symbols do not belong to any section.
// This function adds them to end of BSS section.
template <class ELFT>
void Writer<ELFT>::addCommonSymbols(std::vector<DefinedCommon *> &Syms) {
  if (Syms.empty())
    return;

  // Sort the common symbols by alignment as an heuristic to pack them better.
  std::stable_sort(Syms.begin(), Syms.end(),
                   [](const DefinedCommon *A, const DefinedCommon *B) {
                     return A->Alignment > B->Alignment;
                   });

  ensureBss();
  uintX_t Off = Out<ELFT>::Bss->getSize();
  for (DefinedCommon *C : Syms) {
    Off = alignTo(Off, C->Alignment);
    Out<ELFT>::Bss->updateAlign(C->Alignment);
    C->OffsetInBss = Off;
    Off += C->Size;
  }

  Out<ELFT>::Bss->setSize(Off);
}

template <class ELFT> static uint32_t getAlignment(SharedSymbol<ELFT> *SS) {
  typedef typename ELFFile<ELFT>::uintX_t uintX_t;

  uintX_t SecAlign = SS->File->getSection(SS->Sym)->sh_addralign;
  uintX_t SymValue = SS->Sym.st_value;
  int TrailingZeros =
      std::min(countTrailingZeros(SecAlign), countTrailingZeros(SymValue));
  return 1 << TrailingZeros;
}

// Reserve space in .bss for copy relocation.
template <class ELFT>
void Writer<ELFT>::addCopyRelSymbol(SharedSymbol<ELFT> *SS) {
  ensureBss();
  uintX_t Align = getAlignment(SS);
  uintX_t Off = alignTo(Out<ELFT>::Bss->getSize(), Align);
  Out<ELFT>::Bss->setSize(Off + SS->template getSize<ELFT>());
  Out<ELFT>::Bss->updateAlign(Align);
  uintX_t Shndx = SS->Sym.st_shndx;
  uintX_t Value = SS->Sym.st_value;
  // Look through the DSO's dynamic symbol for aliases and create a dynamic
  // symbol for each one. This causes the copy relocation to correctly interpose
  // any aliases.
  for (SharedSymbol<ELFT> &S : SS->File->getSharedSymbols()) {
    if (S.Sym.st_shndx != Shndx || S.Sym.st_value != Value)
      continue;
    S.OffsetInBss = Off;
    S.NeedsCopyOrPltAddr = true;
    S.Backref->IsUsedInRegularObj = true;
  }
  Out<ELFT>::RelaDyn->addReloc(
      {Target->CopyRel, Out<ELFT>::Bss, SS->OffsetInBss, false, SS, 0});
}

template <class ELFT>
StringRef Writer<ELFT>::getOutputSectionName(InputSectionBase<ELFT> *S) const {
  StringRef Dest = Script<ELFT>::X->getOutputSection(S);
  if (!Dest.empty())
    return Dest;

  StringRef Name = S->getSectionName();
  for (StringRef V : {".text.", ".rodata.", ".data.rel.ro.", ".data.", ".bss.",
                      ".init_array.", ".fini_array.", ".ctors.", ".dtors.",
                      ".tbss.", ".gcc_except_table.", ".tdata."})
    if (Name.startswith(V))
      return V.drop_back();
  return Name;
}

template <class ELFT>
void reportDiscarded(InputSectionBase<ELFT> *IS,
                     const std::unique_ptr<elf::ObjectFile<ELFT>> &File) {
  if (!Config->PrintGcSections || !IS || IS->Live)
    return;
  llvm::errs() << "removing unused section from '" << IS->getSectionName()
               << "' in file '" << File->getName() << "'\n";
}

template <class ELFT>
bool Writer<ELFT>::isDiscarded(InputSectionBase<ELFT> *S) const {
  return !S || S == &InputSection<ELFT>::Discarded || !S->Live ||
         Script<ELFT>::X->isDiscarded(S);
}

template <class ELFT>
static SymbolBody *
addOptionalSynthetic(SymbolTable<ELFT> &Table, StringRef Name,
                     OutputSectionBase<ELFT> &Sec, typename ELFT::uint Val) {
  if (!Table.find(Name))
    return nullptr;
  return Table.addSynthetic(Name, Sec, Val);
}

// The beginning and the ending of .rel[a].plt section are marked
// with __rel[a]_iplt_{start,end} symbols if it is a statically linked
// executable. The runtime needs these symbols in order to resolve
// all IRELATIVE relocs on startup. For dynamic executables, we don't
// need these symbols, since IRELATIVE relocs are resolved through GOT
// and PLT. For details, see http://www.airs.com/blog/archives/403.
template <class ELFT> void Writer<ELFT>::addRelIpltSymbols() {
  if (isOutputDynamic() || !Out<ELFT>::RelaPlt)
    return;
  StringRef S = Config->Rela ? "__rela_iplt_start" : "__rel_iplt_start";
  ElfSym<ELFT>::RelaIpltStart =
      addOptionalSynthetic(Symtab, S, *Out<ELFT>::RelaPlt, 0);

  S = Config->Rela ? "__rela_iplt_end" : "__rel_iplt_end";
  ElfSym<ELFT>::RelaIpltEnd = addOptionalSynthetic(
      Symtab, S, *Out<ELFT>::RelaPlt, DefinedSynthetic<ELFT>::SectionEnd);
}

template <class ELFT> static bool includeInSymtab(const SymbolBody &B) {
  if (!B.Backref->IsUsedInRegularObj)
    return false;

  if (auto *D = dyn_cast<DefinedRegular<ELFT>>(&B)) {
    // Exclude symbols pointing to garbage-collected sections.
    if (D->Section && !D->Section->Live)
      return false;
  }
  return true;
}

// This class knows how to create an output section for a given
// input section. Output section type is determined by various
// factors, including input section's sh_flags, sh_type and
// linker scripts.
namespace {
template <class ELFT> class OutputSectionFactory {
  typedef typename ELFT::Shdr Elf_Shdr;
  typedef typename ELFT::uint uintX_t;

public:
  std::pair<OutputSectionBase<ELFT> *, bool> create(InputSectionBase<ELFT> *C,
                                                    StringRef OutsecName);

  OutputSectionBase<ELFT> *lookup(StringRef Name, uint32_t Type,
                                  uintX_t Flags) {
    return Map.lookup({Name, Type, Flags, 0});
  }

private:
  SectionKey<ELFT::Is64Bits> createKey(InputSectionBase<ELFT> *C,
                                       StringRef OutsecName);

  SmallDenseMap<SectionKey<ELFT::Is64Bits>, OutputSectionBase<ELFT> *> Map;
};
}

template <class ELFT>
std::pair<OutputSectionBase<ELFT> *, bool>
OutputSectionFactory<ELFT>::create(InputSectionBase<ELFT> *C,
                                   StringRef OutsecName) {
  SectionKey<ELFT::Is64Bits> Key = createKey(C, OutsecName);
  OutputSectionBase<ELFT> *&Sec = Map[Key];
  if (Sec)
    return {Sec, false};

  switch (C->SectionKind) {
  case InputSectionBase<ELFT>::Regular:
    Sec = new OutputSection<ELFT>(Key.Name, Key.Type, Key.Flags);
    break;
  case InputSectionBase<ELFT>::EHFrame:
    Sec = new EHOutputSection<ELFT>(Key.Name, Key.Type, Key.Flags);
    break;
  case InputSectionBase<ELFT>::Merge:
    Sec = new MergeOutputSection<ELFT>(Key.Name, Key.Type, Key.Flags,
                                       Key.Alignment);
    break;
  case InputSectionBase<ELFT>::MipsReginfo:
    Sec = new MipsReginfoOutputSection<ELFT>();
    break;
  }
  return {Sec, true};
}

template <class ELFT>
SectionKey<ELFT::Is64Bits>
OutputSectionFactory<ELFT>::createKey(InputSectionBase<ELFT> *C,
                                      StringRef OutsecName) {
  const Elf_Shdr *H = C->getSectionHdr();
  uintX_t Flags = H->sh_flags & ~SHF_GROUP;

  // For SHF_MERGE we create different output sections for each alignment.
  // This makes each output section simple and keeps a single level mapping from
  // input to output.
  uintX_t Alignment = 0;
  if (isa<MergeInputSection<ELFT>>(C))
    Alignment = std::max(H->sh_addralign, H->sh_entsize);

  // GNU as can give .eh_frame secion type SHT_PROGBITS or SHT_X86_64_UNWIND
  // depending on the construct. We want to canonicalize it so that
  // there is only one .eh_frame in the end.
  uint32_t Type = H->sh_type;
  if (Type == SHT_PROGBITS && Config->EMachine == EM_X86_64 &&
      isa<EHInputSection<ELFT>>(C))
    Type = SHT_X86_64_UNWIND;

  return SectionKey<ELFT::Is64Bits>{OutsecName, Type, Flags, Alignment};
}

// The linker is expected to define some symbols depending on
// the linking result. This function defines such symbols.
template <class ELFT> void Writer<ELFT>::addReservedSymbols() {
  if (Config->EMachine == EM_MIPS) {
    // Define _gp for MIPS. st_value of _gp symbol will be updated by Writer
    // so that it points to an absolute address which is relative to GOT.
    // See "Global Data Symbols" in Chapter 6 in the following document:
    // ftp://www.linux-mips.org/pub/linux/mips/doc/ABI/mipsabi.pdf
    ElfSym<ELFT>::MipsGp =
        Symtab.addSynthetic("_gp", *Out<ELFT>::Got, MipsGPOffset);

    // On MIPS O32 ABI, _gp_disp is a magic symbol designates offset between
    // start of function and 'gp' pointer into GOT.
    ElfSym<ELFT>::MipsGpDisp =
        addOptionalSynthetic(Symtab, "_gp_disp", *Out<ELFT>::Got, MipsGPOffset);
    // The __gnu_local_gp is a magic symbol equal to the current value of 'gp'
    // pointer. This symbol is used in the code generated by .cpload pseudo-op
    // in case of using -mno-shared option.
    // https://sourceware.org/ml/binutils/2004-12/msg00094.html
    ElfSym<ELFT>::MipsLocalGp = addOptionalSynthetic(
        Symtab, "__gnu_local_gp", *Out<ELFT>::Got, MipsGPOffset);
  }

  // In the assembly for 32 bit x86 the _GLOBAL_OFFSET_TABLE_ symbol
  // is magical and is used to produce a R_386_GOTPC relocation.
  // The R_386_GOTPC relocation value doesn't actually depend on the
  // symbol value, so it could use an index of STN_UNDEF which, according
  // to the spec, means the symbol value is 0.
  // Unfortunately both gas and MC keep the _GLOBAL_OFFSET_TABLE_ symbol in
  // the object file.
  // The situation is even stranger on x86_64 where the assembly doesn't
  // need the magical symbol, but gas still puts _GLOBAL_OFFSET_TABLE_ as
  // an undefined symbol in the .o files.
  // Given that the symbol is effectively unused, we just create a dummy
  // hidden one to avoid the undefined symbol error.
  if (!Config->Relocatable)
    Symtab.addIgnored("_GLOBAL_OFFSET_TABLE_");

  // __tls_get_addr is defined by the dynamic linker for dynamic ELFs. For
  // static linking the linker is required to optimize away any references to
  // __tls_get_addr, so it's not defined anywhere. Create a hidden definition
  // to avoid the undefined symbol error.
  if (!isOutputDynamic())
    Symtab.addIgnored("__tls_get_addr");

  auto Define = [this](StringRef S, DefinedRegular<ELFT> *&Sym1,
                       DefinedRegular<ELFT> *&Sym2) {
    Sym1 = Symtab.addIgnored(S, STV_DEFAULT);

    // The name without the underscore is not a reserved name,
    // so it is defined only when there is a reference against it.
    assert(S.startswith("_"));
    S = S.substr(1);
    if (SymbolBody *B = Symtab.find(S))
      if (B->isUndefined())
        Sym2 = Symtab.addAbsolute(S, STV_DEFAULT);
  };

  Define("_end", ElfSym<ELFT>::End, ElfSym<ELFT>::End2);
  Define("_etext", ElfSym<ELFT>::Etext, ElfSym<ELFT>::Etext2);
  Define("_edata", ElfSym<ELFT>::Edata, ElfSym<ELFT>::Edata2);
}

// Sort input sections by section name suffixes for
// __attribute__((init_priority(N))).
template <class ELFT> static void sortInitFini(OutputSectionBase<ELFT> *S) {
  if (S)
    reinterpret_cast<OutputSection<ELFT> *>(S)->sortInitFini();
}

// Sort input sections by the special rule for .ctors and .dtors.
template <class ELFT> static void sortCtorsDtors(OutputSectionBase<ELFT> *S) {
  if (S)
    reinterpret_cast<OutputSection<ELFT> *>(S)->sortCtorsDtors();
}

// Create output section objects and add them to OutputSections.
template <class ELFT> void Writer<ELFT>::createSections() {
  // Add .interp first because some loaders want to see that section
  // on the first page of the executable file when loaded into memory.
  if (needsInterpSection())
    OutputSections.push_back(Out<ELFT>::Interp);

  // A core file does not usually contain unmodified segments except
  // the first page of the executable. Add the build ID section now
  // so that the section is included in the first page.
  if (Out<ELFT>::BuildId)
    OutputSections.push_back(Out<ELFT>::BuildId);

  // Create output sections for input object file sections.
  std::vector<OutputSectionBase<ELFT> *> RegularSections;
  OutputSectionFactory<ELFT> Factory;
  for (const std::unique_ptr<elf::ObjectFile<ELFT>> &F :
       Symtab.getObjectFiles()) {
    for (InputSectionBase<ELFT> *C : F->getSections()) {
      if (isDiscarded(C)) {
        reportDiscarded(C, F);
        continue;
      }
      OutputSectionBase<ELFT> *Sec;
      bool IsNew;
      std::tie(Sec, IsNew) = Factory.create(C, getOutputSectionName(C));
      if (IsNew) {
        OwningSections.emplace_back(Sec);
        OutputSections.push_back(Sec);
        RegularSections.push_back(Sec);
      }
      Sec->addSection(C);
    }
  }

  Out<ELFT>::Bss = static_cast<OutputSection<ELFT> *>(
      Factory.lookup(".bss", SHT_NOBITS, SHF_ALLOC | SHF_WRITE));

  // If we have a .opd section (used under PPC64 for function descriptors),
  // store a pointer to it here so that we can use it later when processing
  // relocations.
  Out<ELFT>::Opd = Factory.lookup(".opd", SHT_PROGBITS, SHF_WRITE | SHF_ALLOC);

  Out<ELFT>::Dynamic->PreInitArraySec = Factory.lookup(
      ".preinit_array", SHT_PREINIT_ARRAY, SHF_WRITE | SHF_ALLOC);
  Out<ELFT>::Dynamic->InitArraySec =
      Factory.lookup(".init_array", SHT_INIT_ARRAY, SHF_WRITE | SHF_ALLOC);
  Out<ELFT>::Dynamic->FiniArraySec =
      Factory.lookup(".fini_array", SHT_FINI_ARRAY, SHF_WRITE | SHF_ALLOC);

  // Sort section contents for __attribute__((init_priority(N)).
  sortInitFini(Out<ELFT>::Dynamic->InitArraySec);
  sortInitFini(Out<ELFT>::Dynamic->FiniArraySec);
  sortCtorsDtors(Factory.lookup(".ctors", SHT_PROGBITS, SHF_WRITE | SHF_ALLOC));
  sortCtorsDtors(Factory.lookup(".dtors", SHT_PROGBITS, SHF_WRITE | SHF_ALLOC));

  // The linker needs to define SECNAME_start, SECNAME_end and SECNAME_stop
  // symbols for sections, so that the runtime can get the start and end
  // addresses of each section by section name. Add such symbols.
  if (!Config->Relocatable) {
    addStartEndSymbols();
    for (OutputSectionBase<ELFT> *Sec : RegularSections)
      addStartStopSymbols(Sec);
  }

  // Add _DYNAMIC symbol. Unlike GNU gold, our _DYNAMIC symbol has no type.
  // It should be okay as no one seems to care about the type.
  // Even the author of gold doesn't remember why gold behaves that way.
  // https://sourceware.org/ml/binutils/2002-03/msg00360.html
  if (isOutputDynamic())
    Symtab.addSynthetic("_DYNAMIC", *Out<ELFT>::Dynamic, 0);

  // Define __rel[a]_iplt_{start,end} symbols if needed.
  addRelIpltSymbols();

  if (Out<ELFT>::EhFrameHdr->Sec)
    Out<ELFT>::EhFrameHdr->Sec->finalize();

  // Scan relocations. This must be done after every symbol is declared so that
  // we can correctly decide if a dynamic relocation is needed.
  // Check size() each time to guard against .bss being created.
  for (unsigned I = 0; I < OutputSections.size(); ++I) {
    OutputSectionBase<ELFT> *Sec = OutputSections[I];
    Sec->forEachInputSection([&](InputSectionBase<ELFT> *S) {
      if (auto *IS = dyn_cast<InputSection<ELFT>>(S)) {
        // Set OutSecOff so that scanRelocs can use it.
        uintX_t Off = alignTo(Sec->getSize(), S->Align);
        IS->OutSecOff = Off;

        scanRelocs(*IS);

        // Now that scan relocs possibly changed the size, update the offset.
        Sec->setSize(Off + S->getSize());
      } else if (auto *EH = dyn_cast<EHInputSection<ELFT>>(S)) {
        if (EH->RelocSection)
          scanRelocs(*EH, *EH->RelocSection);
      }
    });
  }

  // Now that we have defined all possible symbols including linker-
  // synthesized ones. Visit all symbols to give the finishing touches.
  std::vector<DefinedCommon *> CommonSymbols;
  for (Symbol *S : Symtab.getSymbols()) {
    SymbolBody *Body = S->Body;
    if (Body->isUndefined() && !S->isWeak()) {
      auto *U = dyn_cast<UndefinedElf<ELFT>>(Body);
      if (!U || !U->canKeepUndefined())
        reportUndefined<ELFT>(Symtab, Body);
    }

    if (auto *C = dyn_cast<DefinedCommon>(Body))
      CommonSymbols.push_back(C);

    if (!includeInSymtab<ELFT>(*Body))
      continue;
    if (Out<ELFT>::SymTab)
      Out<ELFT>::SymTab->addSymbol(Body);

    if (isOutputDynamic() && S->includeInDynsym())
      Out<ELFT>::DynSymTab->addSymbol(Body);
  }

  // Do not proceed if there was an undefined symbol.
  if (HasError)
    return;

  addCommonSymbols(CommonSymbols);

  // So far we have added sections from input object files.
  // This function adds linker-created Out<ELFT>::* sections.
  addPredefinedSections();

  std::stable_sort(OutputSections.begin(), OutputSections.end(),
                   compareSections<ELFT>);

  unsigned I = 1;
  for (OutputSectionBase<ELFT> *Sec : OutputSections) {
    Sec->SectionIndex = I++;
    Sec->setSHName(Out<ELFT>::ShStrTab->addString(Sec->getName()));
  }

  // Finalizers fix each section's size.
  // .dynsym is finalized early since that may fill up .gnu.hash.
  if (isOutputDynamic())
    Out<ELFT>::DynSymTab->finalize();

  // Fill other section headers. The dynamic table is finalized
  // at the end because some tags like RELSZ depend on result
  // of finalizing other sections. The dynamic string table is
  // finalized once the .dynamic finalizer has added a few last
  // strings. See DynamicSection::finalize()
  for (OutputSectionBase<ELFT> *Sec : OutputSections)
    if (Sec != Out<ELFT>::DynStrTab && Sec != Out<ELFT>::Dynamic)
      Sec->finalize();

  if (isOutputDynamic())
    Out<ELFT>::Dynamic->finalize();
}

template <class ELFT> bool Writer<ELFT>::needsGot() {
  if (!Out<ELFT>::Got->empty())
    return true;

  // We add the .got section to the result for dynamic MIPS target because
  // its address and properties are mentioned in the .dynamic section.
  if (Config->EMachine == EM_MIPS)
    return true;

  // If we have a relocation that is relative to GOT (such as GOTOFFREL),
  // we need to emit a GOT even if it's empty.
  return HasGotOffRel;
}

// This function add Out<ELFT>::* sections to OutputSections.
template <class ELFT> void Writer<ELFT>::addPredefinedSections() {
  auto Add = [&](OutputSectionBase<ELFT> *C) {
    if (C)
      OutputSections.push_back(C);
  };

  // This order is not the same as the final output order
  // because we sort the sections using their attributes below.
  Add(Out<ELFT>::SymTab);
  Add(Out<ELFT>::ShStrTab);
  Add(Out<ELFT>::StrTab);
  if (isOutputDynamic()) {
    Add(Out<ELFT>::DynSymTab);
    Add(Out<ELFT>::GnuHashTab);
    Add(Out<ELFT>::HashTab);
    Add(Out<ELFT>::Dynamic);
    Add(Out<ELFT>::DynStrTab);
    if (Out<ELFT>::RelaDyn->hasRelocs())
      Add(Out<ELFT>::RelaDyn);
    Add(Out<ELFT>::MipsRldMap);
  }

  // We always need to add rel[a].plt to output if it has entries.
  // Even during static linking it can contain R_[*]_IRELATIVE relocations.
  if (Out<ELFT>::RelaPlt && Out<ELFT>::RelaPlt->hasRelocs()) {
    Add(Out<ELFT>::RelaPlt);
    Out<ELFT>::RelaPlt->Static = !isOutputDynamic();
  }

  if (needsGot())
    Add(Out<ELFT>::Got);
  if (Out<ELFT>::GotPlt && !Out<ELFT>::GotPlt->empty())
    Add(Out<ELFT>::GotPlt);
  if (!Out<ELFT>::Plt->empty())
    Add(Out<ELFT>::Plt);
  if (Out<ELFT>::EhFrameHdr->Live)
    Add(Out<ELFT>::EhFrameHdr);
}

// The linker is expected to define SECNAME_start and SECNAME_end
// symbols for a few sections. This function defines them.
template <class ELFT> void Writer<ELFT>::addStartEndSymbols() {
  auto Define = [&](StringRef Start, StringRef End,
                    OutputSectionBase<ELFT> *OS) {
    if (OS) {
      Symtab.addSynthetic(Start, *OS, 0);
      Symtab.addSynthetic(End, *OS, DefinedSynthetic<ELFT>::SectionEnd);
    } else {
      Symtab.addIgnored(Start);
      Symtab.addIgnored(End);
    }
  };

  Define("__preinit_array_start", "__preinit_array_end",
         Out<ELFT>::Dynamic->PreInitArraySec);
  Define("__init_array_start", "__init_array_end",
         Out<ELFT>::Dynamic->InitArraySec);
  Define("__fini_array_start", "__fini_array_end",
         Out<ELFT>::Dynamic->FiniArraySec);
}

// If a section name is valid as a C identifier (which is rare because of
// the leading '.'), linkers are expected to define __start_<secname> and
// __stop_<secname> symbols. They are at beginning and end of the section,
// respectively. This is not requested by the ELF standard, but GNU ld and
// gold provide the feature, and used by many programs.
template <class ELFT>
void Writer<ELFT>::addStartStopSymbols(OutputSectionBase<ELFT> *Sec) {
  StringRef S = Sec->getName();
  if (!isValidCIdentifier(S))
    return;
  StringSaver Saver(Alloc);
  StringRef Start = Saver.save("__start_" + S);
  StringRef Stop = Saver.save("__stop_" + S);
  if (SymbolBody *B = Symtab.find(Start))
    if (B->isUndefined())
      Symtab.addSynthetic(Start, *Sec, 0);
  if (SymbolBody *B = Symtab.find(Stop))
    if (B->isUndefined())
      Symtab.addSynthetic(Stop, *Sec, DefinedSynthetic<ELFT>::SectionEnd);
}

template <class ELFT> static bool needsPtLoad(OutputSectionBase<ELFT> *Sec) {
  if (!(Sec->getFlags() & SHF_ALLOC))
    return false;

  // Don't allocate VA space for TLS NOBITS sections. The PT_TLS PHDR is
  // responsible for allocating space for them, not the PT_LOAD that
  // contains the TLS initialization image.
  if (Sec->getFlags() & SHF_TLS && Sec->getType() == SHT_NOBITS)
    return false;
  return true;
}

static uint32_t toPhdrFlags(uint64_t Flags) {
  uint32_t Ret = PF_R;
  if (Flags & SHF_WRITE)
    Ret |= PF_W;
  if (Flags & SHF_EXECINSTR)
    Ret |= PF_X;
  return Ret;
}

// Decide which program headers to create and which sections to include in each
// one.
template <class ELFT> void Writer<ELFT>::createPhdrs() {
  auto AddHdr = [this](unsigned Type, unsigned Flags) {
    return &*Phdrs.emplace(Phdrs.end(), Type, Flags);
  };

  auto AddSec = [](Phdr &Hdr, OutputSectionBase<ELFT> *Sec) {
    Hdr.Last = Sec;
    if (!Hdr.First)
      Hdr.First = Sec;
    Hdr.H.p_align = std::max<uintX_t>(Hdr.H.p_align, Sec->getAlign());
  };

  // The first phdr entry is PT_PHDR which describes the program header itself.
  Phdr &Hdr = *AddHdr(PT_PHDR, PF_R);
  AddSec(Hdr, Out<ELFT>::ProgramHeaders);

  // PT_INTERP must be the second entry if exists.
  if (needsInterpSection()) {
    Phdr &Hdr = *AddHdr(PT_INTERP, toPhdrFlags(Out<ELFT>::Interp->getFlags()));
    AddSec(Hdr, Out<ELFT>::Interp);
  }

  // Add the first PT_LOAD segment for regular output sections.
  uintX_t Flags = PF_R;
  Phdr *Load = AddHdr(PT_LOAD, Flags);
  AddSec(*Load, Out<ELFT>::ElfHeader);
  AddSec(*Load, Out<ELFT>::ProgramHeaders);

  Phdr TlsHdr(PT_TLS, PF_R);
  Phdr RelRo(PT_GNU_RELRO, PF_R);
  Phdr Note(PT_NOTE, PF_R);
  for (OutputSectionBase<ELFT> *Sec : OutputSections) {
    if (!(Sec->getFlags() & SHF_ALLOC))
      break;

    // If we meet TLS section then we create TLS header
    // and put all TLS sections inside for futher use when
    // assign addresses.
    if (Sec->getFlags() & SHF_TLS)
      AddSec(TlsHdr, Sec);

    if (!needsPtLoad<ELFT>(Sec))
      continue;

    // If flags changed then we want new load segment.
    uintX_t NewFlags = toPhdrFlags(Sec->getFlags());
    if (Flags != NewFlags) {
      Load = AddHdr(PT_LOAD, NewFlags);
      Flags = NewFlags;
    }

    AddSec(*Load, Sec);

    if (isRelroSection(Sec))
      AddSec(RelRo, Sec);
    if (Sec->getType() == SHT_NOTE)
      AddSec(Note, Sec);
  }

  // Add the TLS segment unless it's empty.
  if (TlsHdr.First)
    Phdrs.push_back(std::move(TlsHdr));

  // Add an entry for .dynamic.
  if (isOutputDynamic()) {
    Phdr &H = *AddHdr(PT_DYNAMIC, toPhdrFlags(Out<ELFT>::Dynamic->getFlags()));
    AddSec(H, Out<ELFT>::Dynamic);
  }

  // PT_GNU_RELRO includes all sections that should be marked as
  // read-only by dynamic linker after proccessing relocations.
  if (RelRo.First)
    Phdrs.push_back(std::move(RelRo));

  // PT_GNU_EH_FRAME is a special section pointing on .eh_frame_hdr.
  if (Out<ELFT>::EhFrameHdr->Live) {
    Phdr &Hdr = *AddHdr(PT_GNU_EH_FRAME,
                        toPhdrFlags(Out<ELFT>::EhFrameHdr->getFlags()));
    AddSec(Hdr, Out<ELFT>::EhFrameHdr);
  }

  // PT_GNU_STACK is a special section to tell the loader to make the
  // pages for the stack non-executable.
  if (!Config->ZExecStack)
    AddHdr(PT_GNU_STACK, PF_R | PF_W);

  if (Note.First)
    Phdrs.push_back(std::move(Note));

  Out<ELFT>::ProgramHeaders->setSize(sizeof(Elf_Phdr) * Phdrs.size());
}

// The first section of each PT_LOAD and the first section after PT_GNU_RELRO
// have to be page aligned so that the dynamic linker can set the permissions.
template <class ELFT> void Writer<ELFT>::fixSectionAlignments() {
  for (const Phdr &P : Phdrs)
    if (P.H.p_type == PT_LOAD)
      P.First->PageAlign = true;

  for (const Phdr &P : Phdrs) {
    if (P.H.p_type != PT_GNU_RELRO)
      continue;
    // Find the first section after PT_GNU_RELRO. If it is in a PT_LOAD we
    // have to align it to a page.
    auto End = OutputSections.end();
    auto I = std::find(OutputSections.begin(), End, P.Last);
    if (I == End || (I + 1) == End)
      continue;
    OutputSectionBase<ELFT> *Sec = *(I + 1);
    if (needsPtLoad(Sec))
      Sec->PageAlign = true;
  }
}

// We should set file offsets and VAs for elf header and program headers
// sections. These are special, we do not include them into output sections
// list, but have them to simplify the code.
template <class ELFT> void Writer<ELFT>::fixHeaders() {
  uintX_t BaseVA = ScriptConfig->DoLayout ? 0 : Target->getVAStart();
  Out<ELFT>::ElfHeader->setVA(BaseVA);
  Out<ELFT>::ElfHeader->setFileOffset(0);
  uintX_t Off = Out<ELFT>::ElfHeader->getSize();
  Out<ELFT>::ProgramHeaders->setVA(Off + BaseVA);
  Out<ELFT>::ProgramHeaders->setFileOffset(Off);
}

// Assign VAs (addresses at run-time) to output sections.
template <class ELFT> void Writer<ELFT>::assignAddresses() {
  uintX_t VA = Target->getVAStart() + Out<ELFT>::ElfHeader->getSize() +
               Out<ELFT>::ProgramHeaders->getSize();

  uintX_t ThreadBssOffset = 0;
  for (OutputSectionBase<ELFT> *Sec : OutputSections) {
    uintX_t Align = Sec->getAlign();
    if (Sec->PageAlign)
      Align = std::max<uintX_t>(Align, Target->PageSize);

    // We only assign VAs to allocated sections.
    if (needsPtLoad<ELFT>(Sec)) {
      VA = alignTo(VA, Align);
      Sec->setVA(VA);
      VA += Sec->getSize();
    } else if (Sec->getFlags() & SHF_TLS && Sec->getType() == SHT_NOBITS) {
      uintX_t TVA = VA + ThreadBssOffset;
      TVA = alignTo(TVA, Align);
      Sec->setVA(TVA);
      ThreadBssOffset = TVA - VA + Sec->getSize();
    }
  }
}

// Assign file offsets to output sections.
template <class ELFT> void Writer<ELFT>::assignFileOffsets() {
  uintX_t Off =
      Out<ELFT>::ElfHeader->getSize() + Out<ELFT>::ProgramHeaders->getSize();

  for (OutputSectionBase<ELFT> *Sec : OutputSections) {
    if (Sec->getType() == SHT_NOBITS) {
      Sec->setFileOffset(Off);
      continue;
    }
    uintX_t Align = Sec->getAlign();
    if (Sec->PageAlign)
      Align = std::max<uintX_t>(Align, Target->PageSize);
    Off = alignTo(Off, Align);
    Sec->setFileOffset(Off);
    Off += Sec->getSize();
  }
  SectionHeaderOff = alignTo(Off, sizeof(uintX_t));
  FileSize = SectionHeaderOff + (OutputSections.size() + 1) * sizeof(Elf_Shdr);
}

// Finalize the program headers. We call this function after we assign
// file offsets and VAs to all sections.
template <class ELFT> void Writer<ELFT>::setPhdrs() {
  for (Phdr &P : Phdrs) {
    Elf_Phdr &H = P.H;
    OutputSectionBase<ELFT> *First = P.First;
    OutputSectionBase<ELFT> *Last = P.Last;
    if (First) {
      H.p_filesz = Last->getFileOff() - First->getFileOff();
      if (Last->getType() != SHT_NOBITS)
        H.p_filesz += Last->getSize();
      H.p_memsz = Last->getVA() + Last->getSize() - First->getVA();
      H.p_offset = First->getFileOff();
      H.p_vaddr = First->getVA();
    }
    if (H.p_type == PT_LOAD)
      H.p_align = Target->PageSize;
    else if (H.p_type == PT_GNU_RELRO)
      H.p_align = 1;
    H.p_paddr = H.p_vaddr;

    // The TLS pointer goes after PT_TLS. At least glibc will align it,
    // so round up the size to make sure the offsets are correct.
    if (H.p_type == PT_TLS) {
      Out<ELFT>::TlsPhdr = &H;
      H.p_memsz = alignTo(H.p_memsz, H.p_align);
    }
  }
}

static uint32_t getMipsEFlags() {
  // FIXME: In fact ELF flags depends on ELF flags of input object files
  // and selected emulation. For now just use hard coded values.
  uint32_t V = EF_MIPS_ABI_O32 | EF_MIPS_CPIC | EF_MIPS_ARCH_32R2;
  if (Config->Shared)
    V |= EF_MIPS_PIC;
  return V;
}

template <class ELFT> static typename ELFT::uint getEntryAddr() {
  if (Symbol *S = Config->EntrySym)
    return S->Body->getVA<ELFT>();
  if (Config->EntryAddr != uint64_t(-1))
    return Config->EntryAddr;
  return 0;
}

template <class ELFT> static uint8_t getELFEncoding() {
  if (ELFT::TargetEndianness == llvm::support::little)
    return ELFDATA2LSB;
  return ELFDATA2MSB;
}

static uint16_t getELFType() {
  if (Config->Pic)
    return ET_DYN;
  if (Config->Relocatable)
    return ET_REL;
  return ET_EXEC;
}

// This function is called after we have assigned address and size
// to each section. This function fixes some predefined absolute
// symbol values that depend on section address and size.
template <class ELFT> void Writer<ELFT>::fixAbsoluteSymbols() {
  auto Set = [](DefinedRegular<ELFT> *&S1, DefinedRegular<ELFT> *&S2,
                uintX_t V) {
    if (S1)
      S1->Value = V;
    if (S2)
      S2->Value = V;
  };

  // _etext is the first location after the last read-only loadable segment.
  // _edata is the first location after the last read-write loadable segment.
  // _end is the first location after the uninitialized data region.
  for (Phdr &P : Phdrs) {
    Elf_Phdr &H = P.H;
    if (H.p_type != PT_LOAD)
      continue;
    Set(ElfSym<ELFT>::End, ElfSym<ELFT>::End2, H.p_vaddr + H.p_memsz);

    uintX_t Val = H.p_vaddr + H.p_filesz;
    if (H.p_flags & PF_W)
      Set(ElfSym<ELFT>::Edata, ElfSym<ELFT>::Edata2, Val);
    else
      Set(ElfSym<ELFT>::Etext, ElfSym<ELFT>::Etext2, Val);
  }
}

template <class ELFT> void Writer<ELFT>::writeHeader() {
  uint8_t *Buf = Buffer->getBufferStart();
  memcpy(Buf, "\177ELF", 4);

  auto &FirstObj = cast<ELFFileBase<ELFT>>(*Config->FirstElf);

  // Write the ELF header.
  auto *EHdr = reinterpret_cast<Elf_Ehdr *>(Buf);
  EHdr->e_ident[EI_CLASS] = ELFT::Is64Bits ? ELFCLASS64 : ELFCLASS32;
  EHdr->e_ident[EI_DATA] = getELFEncoding<ELFT>();
  EHdr->e_ident[EI_VERSION] = EV_CURRENT;
  EHdr->e_ident[EI_OSABI] = FirstObj.getOSABI();
  EHdr->e_type = getELFType();
  EHdr->e_machine = FirstObj.getEMachine();
  EHdr->e_version = EV_CURRENT;
  EHdr->e_entry = getEntryAddr<ELFT>();
  EHdr->e_shoff = SectionHeaderOff;
  EHdr->e_ehsize = sizeof(Elf_Ehdr);
  EHdr->e_phnum = Phdrs.size();
  EHdr->e_shentsize = sizeof(Elf_Shdr);
  EHdr->e_shnum = OutputSections.size() + 1;
  EHdr->e_shstrndx = Out<ELFT>::ShStrTab->SectionIndex;

  if (Config->EMachine == EM_MIPS)
    EHdr->e_flags = getMipsEFlags();

  if (!Config->Relocatable) {
    EHdr->e_phoff = sizeof(Elf_Ehdr);
    EHdr->e_phentsize = sizeof(Elf_Phdr);
  }

  // Write the program header table.
  auto *HBuf = reinterpret_cast<Elf_Phdr *>(Buf + EHdr->e_phoff);
  for (Phdr &P : Phdrs)
    *HBuf++ = P.H;

  // Write the section header table. Note that the first table entry is null.
  auto *SHdrs = reinterpret_cast<Elf_Shdr *>(Buf + EHdr->e_shoff);
  for (OutputSectionBase<ELFT> *Sec : OutputSections)
    Sec->writeHeaderTo(++SHdrs);
}

template <class ELFT> void Writer<ELFT>::openFile() {
  ErrorOr<std::unique_ptr<FileOutputBuffer>> BufferOrErr =
      FileOutputBuffer::create(Config->OutputFile, FileSize,
                               FileOutputBuffer::F_executable);
  if (BufferOrErr)
    Buffer = std::move(*BufferOrErr);
  else
    error(BufferOrErr, "failed to open " + Config->OutputFile);
}

// Write section contents to a mmap'ed file.
template <class ELFT> void Writer<ELFT>::writeSections() {
  uint8_t *Buf = Buffer->getBufferStart();

  // PPC64 needs to process relocations in the .opd section before processing
  // relocations in code-containing sections.
  if (OutputSectionBase<ELFT> *Sec = Out<ELFT>::Opd) {
    Out<ELFT>::OpdBuf = Buf + Sec->getFileOff();
    Sec->writeTo(Buf + Sec->getFileOff());
  }

  for (OutputSectionBase<ELFT> *Sec : OutputSections)
    if (Sec != Out<ELFT>::Opd)
      Sec->writeTo(Buf + Sec->getFileOff());
}

template <class ELFT> void Writer<ELFT>::writeBuildId() {
  BuildIdSection<ELFT> *S = Out<ELFT>::BuildId;
  if (!S)
    return;

  // Compute a hash of all sections except .debug_* sections.
  // We skip debug sections because they tend to be very large
  // and their contents are very likely to be the same as long as
  // other sections are the same.
  uint8_t *Start = Buffer->getBufferStart();
  uint8_t *Last = Start;
  for (OutputSectionBase<ELFT> *Sec : OutputSections) {
    uint8_t *End = Start + Sec->getFileOff();
    if (!Sec->getName().startswith(".debug_"))
      S->update({Last, End});
    Last = End;
  }
  S->update({Last, Start + FileSize});

  // Fill the hash value field in the .note.gnu.build-id section.
  S->writeBuildId();
}

template void elf::writeResult<ELF32LE>(SymbolTable<ELF32LE> *Symtab);
template void elf::writeResult<ELF32BE>(SymbolTable<ELF32BE> *Symtab);
template void elf::writeResult<ELF64LE>(SymbolTable<ELF64LE> *Symtab);
template void elf::writeResult<ELF64BE>(SymbolTable<ELF64BE> *Symtab);