lld/ELF/InputSection.h - llvm-project - Git at Google

 //===- InputSection.h -------------------------------------------*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLD_ELF_INPUT_SECTION_H
 #define LLD_ELF_INPUT_SECTION_H

 #include "Config.h"
 #include "Relocations.h"
 #include "Thunks.h"
 #include "lld/Common/LLVM.h"
 #include "llvm/ADT/CachedHashString.h"
 #include "llvm/ADT/DenseSet.h"
 #include "llvm/ADT/TinyPtrVector.h"
 #include "llvm/Object/ELF.h"

 namespace lld {
 namespace elf {

 class Symbol;
 struct SectionPiece;

 class Defined;
 struct Partition;
 class SyntheticSection;
 class MergeSyntheticSection;
 template <class ELFT> class ObjFile;
 class OutputSection;

 extern std::vector<Partition> partitions;

 // Returned by InputSectionBase::relsOrRelas. At least one member is empty.
 template <class ELFT> struct RelsOrRelas {
   ArrayRef<typename ELFT::Rel> rels;
   ArrayRef<typename ELFT::Rela> relas;
   bool areRelocsRel() const { return rels.size(); }
 };

 // This is the base class of all sections that lld handles. Some are sections in
 // input files, some are sections in the produced output file and some exist
 // just as a convenience for implementing special ways of combining some
 // sections.
 class SectionBase {
 public:
   enum Kind { Regular, EHFrame, Merge, Synthetic, Output };

   Kind kind() const { return (Kind)sectionKind; }

   StringRef name;

   // This pointer points to the "real" instance of this instance.
   // Usually Repl == this. However, if ICF merges two sections,
   // Repl pointer of one section points to another section. So,
   // if you need to get a pointer to this instance, do not use
   // this but instead this->Repl.
   SectionBase *repl;

   uint8_t sectionKind : 3;

   // The next two bit fields are only used by InputSectionBase, but we
   // put them here so the struct packs better.

   uint8_t bss : 1;

   // Set for sections that should not be folded by ICF.
   uint8_t keepUnique : 1;

   // The 1-indexed partition that this section is assigned to by the garbage
   // collector, or 0 if this section is dead. Normally there is only one
   // partition, so this will either be 0 or 1.
   uint8_t partition;
   elf::Partition &getPartition() const;

   // These corresponds to the fields in Elf_Shdr.
   uint32_t alignment;
   uint64_t flags;
   uint32_t entsize;
   uint32_t type;
   uint32_t link;
   uint32_t info;

   OutputSection *getOutputSection();
   const OutputSection *getOutputSection() const {
     return const_cast<SectionBase *>(this)->getOutputSection();
   }

   // Translate an offset in the input section to an offset in the output
   // section.
   uint64_t getOffset(uint64_t offset) const;

   uint64_t getVA(uint64_t offset = 0) const;

   bool isLive() const { return partition != 0; }
   void markLive() { partition = 1; }
   void markDead() { partition = 0; }

 protected:
   constexpr SectionBase(Kind sectionKind, StringRef name, uint64_t flags,
                         uint32_t entsize, uint32_t alignment, uint32_t type,
                         uint32_t info, uint32_t link)
       : name(name), repl(this), sectionKind(sectionKind), bss(false),
         keepUnique(false), partition(0), alignment(alignment), flags(flags),
         entsize(entsize), type(type), link(link), info(info) {}
 };

 // This corresponds to a section of an input file.
 class InputSectionBase : public SectionBase {
 public:
   template <class ELFT>
   InputSectionBase(ObjFile<ELFT> &file, const typename ELFT::Shdr &header,
                    StringRef name, Kind sectionKind);

   InputSectionBase(InputFile *file, uint64_t flags, uint32_t type,
                    uint64_t entsize, uint32_t link, uint32_t info,
                    uint32_t alignment, ArrayRef<uint8_t> data, StringRef name,
                    Kind sectionKind);

   static bool classof(const SectionBase *s) { return s->kind() != Output; }

   // The file which contains this section. Its dynamic type is always
   // ObjFile<ELFT>, but in order to avoid ELFT, we use InputFile as
   // its static type.
   InputFile *file;

   // Section index of the relocation section if exists.
   uint32_t relSecIdx = 0;

   template <class ELFT> ObjFile<ELFT> *getFile() const {
     return cast_or_null<ObjFile<ELFT>>(file);
   }

   // If basic block sections are enabled, many code sections could end up with
   // one or two jump instructions at the end that could be relaxed to a smaller
   // instruction. The members below help trimming the trailing jump instruction
   // and shrinking a section.
   unsigned bytesDropped = 0;

   // Whether the section needs to be padded with a NOP filler due to
   // deleteFallThruJmpInsn.
   bool nopFiller = false;

   void drop_back(uint64_t num) { bytesDropped += num; }

   void push_back(uint64_t num) {
     assert(bytesDropped >= num);
     bytesDropped -= num;
   }

   void trim() {
     if (bytesDropped) {
       rawData = rawData.drop_back(bytesDropped);
       bytesDropped = 0;
     }
   }

   ArrayRef<uint8_t> data() const {
     if (uncompressedSize >= 0)
       uncompress();
     return rawData;
   }

   uint64_t getOffsetInFile() const;

   // Input sections are part of an output section. Special sections
   // like .eh_frame and merge sections are first combined into a
   // synthetic section that is then added to an output section. In all
   // cases this points one level up.
   SectionBase *parent = nullptr;

   // The next member in the section group if this section is in a group. This is
   // used by --gc-sections.
   InputSectionBase *nextInSectionGroup = nullptr;

   template <class ELFT> RelsOrRelas<ELFT> relsOrRelas() const;

   // InputSections that are dependent on us (reverse dependency for GC)
   llvm::TinyPtrVector<InputSection *> dependentSections;

   // Returns the size of this section (even if this is a common or BSS.)
   size_t getSize() const;

   InputSection *getLinkOrderDep() const;

   // Get the function symbol that encloses this offset from within the
   // section.
   template <class ELFT>
   Defined *getEnclosingFunction(uint64_t offset);

   // Returns a source location string. Used to construct an error message.
   template <class ELFT> std::string getLocation(uint64_t offset);
   std::string getSrcMsg(const Symbol &sym, uint64_t offset);
   std::string getObjMsg(uint64_t offset);

   // Each section knows how to relocate itself. These functions apply
   // relocations, assuming that Buf points to this section's copy in
   // the mmap'ed output buffer.
   template <class ELFT> void relocate(uint8_t *buf, uint8_t *bufEnd);
   void relocateAlloc(uint8_t *buf, uint8_t *bufEnd);
   static uint64_t getRelocTargetVA(const InputFile *File, RelType Type,
                                    int64_t A, uint64_t P, const Symbol &Sym,
                                    RelExpr Expr);

   // The native ELF reloc data type is not very convenient to handle.
   // So we convert ELF reloc records to our own records in Relocations.cpp.
   // This vector contains such "cooked" relocations.
   SmallVector<Relocation, 0> relocations;

   // These are modifiers to jump instructions that are necessary when basic
   // block sections are enabled.  Basic block sections creates opportunities to
   // relax jump instructions at basic block boundaries after reordering the
   // basic blocks.
   SmallVector<JumpInstrMod, 0> jumpInstrMods;

   // A function compiled with -fsplit-stack calling a function
   // compiled without -fsplit-stack needs its prologue adjusted. Find
   // such functions and adjust their prologues.  This is very similar
   // to relocation. See https://gcc.gnu.org/wiki/SplitStacks for more
   // information.
   template <typename ELFT>
   void adjustSplitStackFunctionPrologues(uint8_t *buf, uint8_t *end);


   template <typename T> llvm::ArrayRef<T> getDataAs() const {
     size_t s = data().size();
     assert(s % sizeof(T) == 0);
     return llvm::makeArrayRef<T>((const T *)data().data(), s / sizeof(T));
   }

 protected:
   template <typename ELFT>
   void parseCompressedHeader();
   void uncompress() const;

   mutable ArrayRef<uint8_t> rawData;

   // This field stores the uncompressed size of the compressed data in rawData,
   // or -1 if rawData is not compressed (either because the section wasn't
   // compressed in the first place, or because we ended up uncompressing it).
   // Since the feature is not used often, this is usually -1.
   mutable int64_t uncompressedSize = -1;
 };

 // SectionPiece represents a piece of splittable section contents.
 // We allocate a lot of these and binary search on them. This means that they
 // have to be as compact as possible, which is why we don't store the size (can
 // be found by looking at the next one).
 struct SectionPiece {
   SectionPiece(size_t off, uint32_t hash, bool live)
       : inputOff(off), live(live || !config->gcSections), hash(hash >> 1) {}

   uint32_t inputOff;
   uint32_t live : 1;
   uint32_t hash : 31;
   uint64_t outputOff = 0;
 };

 static_assert(sizeof(SectionPiece) == 16, "SectionPiece is too big");

 // This corresponds to a SHF_MERGE section of an input file.
 class MergeInputSection : public InputSectionBase {
 public:
   template <class ELFT>
   MergeInputSection(ObjFile<ELFT> &f, const typename ELFT::Shdr &header,
                     StringRef name);
   MergeInputSection(uint64_t flags, uint32_t type, uint64_t entsize,
                     ArrayRef<uint8_t> data, StringRef name);

   static bool classof(const SectionBase *s) { return s->kind() == Merge; }
   void splitIntoPieces();

   // Translate an offset in the input section to an offset in the parent
   // MergeSyntheticSection.
   uint64_t getParentOffset(uint64_t offset) const;

   // Splittable sections are handled as a sequence of data
   // rather than a single large blob of data.
   std::vector<SectionPiece> pieces;

   // Returns I'th piece's data. This function is very hot when
   // string merging is enabled, so we want to inline.
   LLVM_ATTRIBUTE_ALWAYS_INLINE
   llvm::CachedHashStringRef getData(size_t i) const {
     size_t begin = pieces[i].inputOff;
     size_t end =
         (pieces.size() - 1 == i) ? data().size() : pieces[i + 1].inputOff;
     return {toStringRef(data().slice(begin, end - begin)), pieces[i].hash};
   }

   // Returns the SectionPiece at a given input section offset.
   SectionPiece *getSectionPiece(uint64_t offset);
   const SectionPiece *getSectionPiece(uint64_t offset) const {
     return const_cast<MergeInputSection *>(this)->getSectionPiece(offset);
   }

   SyntheticSection *getParent() const;

 private:
   void splitStrings(ArrayRef<uint8_t> a, size_t size);
   void splitNonStrings(ArrayRef<uint8_t> a, size_t size);
 };

 struct EhSectionPiece {
   EhSectionPiece(size_t off, InputSectionBase *sec, uint32_t size,
                  unsigned firstRelocation)
       : inputOff(off), sec(sec), size(size), firstRelocation(firstRelocation) {}

   ArrayRef<uint8_t> data() const {
     return {sec->data().data() + this->inputOff, size};
   }

   size_t inputOff;
   ssize_t outputOff = -1;
   InputSectionBase *sec;
   uint32_t size;
   unsigned firstRelocation;
 };

 // This corresponds to a .eh_frame section of an input file.
 class EhInputSection : public InputSectionBase {
 public:
   template <class ELFT>
   EhInputSection(ObjFile<ELFT> &f, const typename ELFT::Shdr &header,
                  StringRef name);
   static bool classof(const SectionBase *s) { return s->kind() == EHFrame; }
   template <class ELFT> void split();
   template <class ELFT, class RelTy> void split(ArrayRef<RelTy> rels);

   // Splittable sections are handled as a sequence of data
   // rather than a single large blob of data.
   std::vector<EhSectionPiece> pieces;

   SyntheticSection *getParent() const;
 };

 // This is a section that is added directly to an output section
 // instead of needing special combination via a synthetic section. This
 // includes all input sections with the exceptions of SHF_MERGE and
 // .eh_frame. It also includes the synthetic sections themselves.
 class InputSection : public InputSectionBase {
 public:
   InputSection(InputFile *f, uint64_t flags, uint32_t type, uint32_t alignment,
                ArrayRef<uint8_t> data, StringRef name, Kind k = Regular);
   template <class ELFT>
   InputSection(ObjFile<ELFT> &f, const typename ELFT::Shdr &header,
                StringRef name);

   // Write this section to a mmap'ed file, assuming Buf is pointing to
   // beginning of the output section.
   template <class ELFT> void writeTo(uint8_t *buf);

   OutputSection *getParent() const;

   // This variable has two usages. Initially, it represents an index in the
   // OutputSection's InputSection list, and is used when ordering SHF_LINK_ORDER
   // sections. After assignAddresses is called, it represents the offset from
   // the beginning of the output section this section was assigned to.
   uint64_t outSecOff = 0;

   static bool classof(const SectionBase *s);

   InputSectionBase *getRelocatedSection() const;

   template <class ELFT, class RelTy>
   void relocateNonAlloc(uint8_t *buf, llvm::ArrayRef<RelTy> rels);

   // Used by ICF.
   uint32_t eqClass[2] = {0, 0};

   // Called by ICF to merge two input sections.
   void replace(InputSection *other);

   static InputSection discarded;

 private:
   template <class ELFT, class RelTy>
   void copyRelocations(uint8_t *buf, llvm::ArrayRef<RelTy> rels);

   template <class ELFT> void copyShtGroup(uint8_t *buf);
 };

 #ifdef _WIN32
 static_assert(sizeof(InputSection) <= 184, "InputSection is too big");
 #else
 static_assert(sizeof(InputSection) <= 176, "InputSection is too big");
 #endif

 inline bool isDebugSection(const InputSectionBase &sec) {
   return (sec.flags & llvm::ELF::SHF_ALLOC) == 0 &&
          (sec.name.startswith(".debug") || sec.name.startswith(".zdebug"));
 }

 // The list of all input sections.
 extern std::vector<InputSectionBase *> inputSections;

 // The set of TOC entries (.toc + addend) for which we should not apply
 // toc-indirect to toc-relative relaxation. const Symbol * refers to the
 // STT_SECTION symbol associated to the .toc input section.
 extern llvm::DenseSet<std::pair<const Symbol *, uint64_t>> ppc64noTocRelax;

 } // namespace elf

 std::string toString(const elf::InputSectionBase *);
 } // namespace lld

 #endif
	//===- InputSection.h -------------------------------------------- C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLD_ELF_INPUT_SECTION_H
	#define LLD_ELF_INPUT_SECTION_H

	#include "Config.h"
	#include "Relocations.h"
	#include "Thunks.h"
	#include "lld/Common/LLVM.h"
	#include "llvm/ADT/CachedHashString.h"
	#include "llvm/ADT/DenseSet.h"
	#include "llvm/ADT/TinyPtrVector.h"
	#include "llvm/Object/ELF.h"

	namespace lld {
	namespace elf {

	class Symbol;
	struct SectionPiece;

	class Defined;
	struct Partition;
	class SyntheticSection;
	class MergeSyntheticSection;
	template <class ELFT> class ObjFile;
	class OutputSection;

	extern std::vector<Partition> partitions;

	// Returned by InputSectionBase::relsOrRelas. At least one member is empty.
	template <class ELFT> struct RelsOrRelas {
	ArrayRef<typename ELFT::Rel> rels;
	ArrayRef<typename ELFT::Rela> relas;
	bool areRelocsRel() const { return rels.size(); }
	};

	// This is the base class of all sections that lld handles. Some are sections in
	// input files, some are sections in the produced output file and some exist
	// just as a convenience for implementing special ways of combining some
	// sections.
	class SectionBase {
	public:
	enum Kind { Regular, EHFrame, Merge, Synthetic, Output };

	Kind kind() const { return (Kind)sectionKind; }

	StringRef name;

	// This pointer points to the "real" instance of this instance.
	// Usually Repl == this. However, if ICF merges two sections,
	// Repl pointer of one section points to another section. So,
	// if you need to get a pointer to this instance, do not use
	// this but instead this->Repl.
	SectionBase *repl;

	uint8_t sectionKind : 3;

	// The next two bit fields are only used by InputSectionBase, but we
	// put them here so the struct packs better.

	uint8_t bss : 1;

	// Set for sections that should not be folded by ICF.
	uint8_t keepUnique : 1;

	// The 1-indexed partition that this section is assigned to by the garbage
	// collector, or 0 if this section is dead. Normally there is only one
	// partition, so this will either be 0 or 1.
	uint8_t partition;
	elf::Partition &getPartition() const;

	// These corresponds to the fields in Elf_Shdr.
	uint32_t alignment;
	uint64_t flags;
	uint32_t entsize;
	uint32_t type;
	uint32_t link;
	uint32_t info;

	OutputSection *getOutputSection();
	const OutputSection *getOutputSection() const {
	return const_cast<SectionBase *>(this)->getOutputSection();
	}

	// Translate an offset in the input section to an offset in the output
	// section.
	uint64_t getOffset(uint64_t offset) const;

	uint64_t getVA(uint64_t offset = 0) const;

	bool isLive() const { return partition != 0; }
	void markLive() { partition = 1; }
	void markDead() { partition = 0; }

	protected:
	constexpr SectionBase(Kind sectionKind, StringRef name, uint64_t flags,
	uint32_t entsize, uint32_t alignment, uint32_t type,
	uint32_t info, uint32_t link)
	: name(name), repl(this), sectionKind(sectionKind), bss(false),
	keepUnique(false), partition(0), alignment(alignment), flags(flags),
	entsize(entsize), type(type), link(link), info(info) {}
	};

	// This corresponds to a section of an input file.
	class InputSectionBase : public SectionBase {
	public:
	template <class ELFT>
	InputSectionBase(ObjFile<ELFT> &file, const typename ELFT::Shdr &header,
	StringRef name, Kind sectionKind);

	InputSectionBase(InputFile *file, uint64_t flags, uint32_t type,
	uint64_t entsize, uint32_t link, uint32_t info,
	uint32_t alignment, ArrayRef<uint8_t> data, StringRef name,
	Kind sectionKind);

	static bool classof(const SectionBase *s) { return s->kind() != Output; }

	// The file which contains this section. Its dynamic type is always
	// ObjFile<ELFT>, but in order to avoid ELFT, we use InputFile as
	// its static type.
	InputFile *file;

	// Section index of the relocation section if exists.
	uint32_t relSecIdx = 0;

	template <class ELFT> ObjFile<ELFT> *getFile() const {
	return cast_or_null<ObjFile<ELFT>>(file);
	}

	// If basic block sections are enabled, many code sections could end up with
	// one or two jump instructions at the end that could be relaxed to a smaller
	// instruction. The members below help trimming the trailing jump instruction
	// and shrinking a section.
	unsigned bytesDropped = 0;

	// Whether the section needs to be padded with a NOP filler due to
	// deleteFallThruJmpInsn.
	bool nopFiller = false;

	void drop_back(uint64_t num) { bytesDropped += num; }

	void push_back(uint64_t num) {
	assert(bytesDropped >= num);
	bytesDropped -= num;
	}

	void trim() {
	if (bytesDropped) {
	rawData = rawData.drop_back(bytesDropped);
	bytesDropped = 0;
	}
	}

	ArrayRef<uint8_t> data() const {
	if (uncompressedSize >= 0)
	uncompress();
	return rawData;
	}

	uint64_t getOffsetInFile() const;

	// Input sections are part of an output section. Special sections
	// like .eh_frame and merge sections are first combined into a
	// synthetic section that is then added to an output section. In all
	// cases this points one level up.
	SectionBase *parent = nullptr;

	// The next member in the section group if this section is in a group. This is
	// used by --gc-sections.
	InputSectionBase *nextInSectionGroup = nullptr;

	template <class ELFT> RelsOrRelas<ELFT> relsOrRelas() const;

	// InputSections that are dependent on us (reverse dependency for GC)
	llvm::TinyPtrVector<InputSection *> dependentSections;

	// Returns the size of this section (even if this is a common or BSS.)
	size_t getSize() const;

	InputSection *getLinkOrderDep() const;

	// Get the function symbol that encloses this offset from within the
	// section.
	template <class ELFT>
	Defined *getEnclosingFunction(uint64_t offset);

	// Returns a source location string. Used to construct an error message.
	template <class ELFT> std::string getLocation(uint64_t offset);
	std::string getSrcMsg(const Symbol &sym, uint64_t offset);
	std::string getObjMsg(uint64_t offset);

	// Each section knows how to relocate itself. These functions apply
	// relocations, assuming that Buf points to this section's copy in
	// the mmap'ed output buffer.
	template <class ELFT> void relocate(uint8_t buf, uint8_t bufEnd);
	void relocateAlloc(uint8_t buf, uint8_t bufEnd);
	static uint64_t getRelocTargetVA(const InputFile *File, RelType Type,
	int64_t A, uint64_t P, const Symbol &Sym,
	RelExpr Expr);

	// The native ELF reloc data type is not very convenient to handle.
	// So we convert ELF reloc records to our own records in Relocations.cpp.
	// This vector contains such "cooked" relocations.
	SmallVector<Relocation, 0> relocations;

	// These are modifiers to jump instructions that are necessary when basic
	// block sections are enabled. Basic block sections creates opportunities to
	// relax jump instructions at basic block boundaries after reordering the
	// basic blocks.
	SmallVector<JumpInstrMod, 0> jumpInstrMods;

	// A function compiled with -fsplit-stack calling a function
	// compiled without -fsplit-stack needs its prologue adjusted. Find
	// such functions and adjust their prologues. This is very similar
	// to relocation. See https://gcc.gnu.org/wiki/SplitStacks for more
	// information.
	template <typename ELFT>
	void adjustSplitStackFunctionPrologues(uint8_t buf, uint8_t end);


	template <typename T> llvm::ArrayRef<T> getDataAs() const {
	size_t s = data().size();
	assert(s % sizeof(T) == 0);
	return llvm::makeArrayRef<T>((const T *)data().data(), s / sizeof(T));
	}

	protected:
	template <typename ELFT>
	void parseCompressedHeader();
	void uncompress() const;

	mutable ArrayRef<uint8_t> rawData;

	// This field stores the uncompressed size of the compressed data in rawData,
	// or -1 if rawData is not compressed (either because the section wasn't
	// compressed in the first place, or because we ended up uncompressing it).
	// Since the feature is not used often, this is usually -1.
	mutable int64_t uncompressedSize = -1;
	};

	// SectionPiece represents a piece of splittable section contents.
	// We allocate a lot of these and binary search on them. This means that they
	// have to be as compact as possible, which is why we don't store the size (can
	// be found by looking at the next one).
	struct SectionPiece {
	SectionPiece(size_t off, uint32_t hash, bool live)
	: inputOff(off), live(live \|\| !config->gcSections), hash(hash >> 1) {}

	uint32_t inputOff;
	uint32_t live : 1;
	uint32_t hash : 31;
	uint64_t outputOff = 0;
	};

	static_assert(sizeof(SectionPiece) == 16, "SectionPiece is too big");

	// This corresponds to a SHF_MERGE section of an input file.
	class MergeInputSection : public InputSectionBase {
	public:
	template <class ELFT>
	MergeInputSection(ObjFile<ELFT> &f, const typename ELFT::Shdr &header,
	StringRef name);
	MergeInputSection(uint64_t flags, uint32_t type, uint64_t entsize,
	ArrayRef<uint8_t> data, StringRef name);

	static bool classof(const SectionBase *s) { return s->kind() == Merge; }
	void splitIntoPieces();

	// Translate an offset in the input section to an offset in the parent
	// MergeSyntheticSection.
	uint64_t getParentOffset(uint64_t offset) const;

	// Splittable sections are handled as a sequence of data
	// rather than a single large blob of data.
	std::vector<SectionPiece> pieces;

	// Returns I'th piece's data. This function is very hot when
	// string merging is enabled, so we want to inline.
	LLVM_ATTRIBUTE_ALWAYS_INLINE
	llvm::CachedHashStringRef getData(size_t i) const {
	size_t begin = pieces[i].inputOff;
	size_t end =
	(pieces.size() - 1 == i) ? data().size() : pieces[i + 1].inputOff;
	return {toStringRef(data().slice(begin, end - begin)), pieces[i].hash};
	}

	// Returns the SectionPiece at a given input section offset.
	SectionPiece *getSectionPiece(uint64_t offset);
	const SectionPiece *getSectionPiece(uint64_t offset) const {
	return const_cast<MergeInputSection *>(this)->getSectionPiece(offset);
	}

	SyntheticSection *getParent() const;

	private:
	void splitStrings(ArrayRef<uint8_t> a, size_t size);
	void splitNonStrings(ArrayRef<uint8_t> a, size_t size);
	};

	struct EhSectionPiece {
	EhSectionPiece(size_t off, InputSectionBase *sec, uint32_t size,
	unsigned firstRelocation)
	: inputOff(off), sec(sec), size(size), firstRelocation(firstRelocation) {}

	ArrayRef<uint8_t> data() const {
	return {sec->data().data() + this->inputOff, size};
	}

	size_t inputOff;
	ssize_t outputOff = -1;
	InputSectionBase *sec;
	uint32_t size;
	unsigned firstRelocation;
	};

	// This corresponds to a .eh_frame section of an input file.
	class EhInputSection : public InputSectionBase {
	public:
	template <class ELFT>
	EhInputSection(ObjFile<ELFT> &f, const typename ELFT::Shdr &header,
	StringRef name);
	static bool classof(const SectionBase *s) { return s->kind() == EHFrame; }
	template <class ELFT> void split();
	template <class ELFT, class RelTy> void split(ArrayRef<RelTy> rels);

	// Splittable sections are handled as a sequence of data
	// rather than a single large blob of data.
	std::vector<EhSectionPiece> pieces;

	SyntheticSection *getParent() const;
	};

	// This is a section that is added directly to an output section
	// instead of needing special combination via a synthetic section. This
	// includes all input sections with the exceptions of SHF_MERGE and
	// .eh_frame. It also includes the synthetic sections themselves.
	class InputSection : public InputSectionBase {
	public:
	InputSection(InputFile *f, uint64_t flags, uint32_t type, uint32_t alignment,
	ArrayRef<uint8_t> data, StringRef name, Kind k = Regular);
	template <class ELFT>
	InputSection(ObjFile<ELFT> &f, const typename ELFT::Shdr &header,
	StringRef name);

	// Write this section to a mmap'ed file, assuming Buf is pointing to
	// beginning of the output section.
	template <class ELFT> void writeTo(uint8_t *buf);

	OutputSection *getParent() const;

	// This variable has two usages. Initially, it represents an index in the
	// OutputSection's InputSection list, and is used when ordering SHF_LINK_ORDER
	// sections. After assignAddresses is called, it represents the offset from
	// the beginning of the output section this section was assigned to.
	uint64_t outSecOff = 0;

	static bool classof(const SectionBase *s);

	InputSectionBase *getRelocatedSection() const;

	template <class ELFT, class RelTy>
	void relocateNonAlloc(uint8_t *buf, llvm::ArrayRef<RelTy> rels);

	// Used by ICF.
	uint32_t eqClass[2] = {0, 0};

	// Called by ICF to merge two input sections.
	void replace(InputSection *other);

	static InputSection discarded;

	private:
	template <class ELFT, class RelTy>
	void copyRelocations(uint8_t *buf, llvm::ArrayRef<RelTy> rels);

	template <class ELFT> void copyShtGroup(uint8_t *buf);
	};

	#ifdef _WIN32
	static_assert(sizeof(InputSection) <= 184, "InputSection is too big");
	#else
	static_assert(sizeof(InputSection) <= 176, "InputSection is too big");
	#endif

	inline bool isDebugSection(const InputSectionBase &sec) {
	return (sec.flags & llvm::ELF::SHF_ALLOC) == 0 &&
	(sec.name.startswith(".debug") \|\| sec.name.startswith(".zdebug"));
	}

	// The list of all input sections.
	extern std::vector<InputSectionBase *> inputSections;

	// The set of TOC entries (.toc + addend) for which we should not apply
	// toc-indirect to toc-relative relaxation. const Symbol * refers to the
	// STT_SECTION symbol associated to the .toc input section.
	extern llvm::DenseSet<std::pair<const Symbol *, uint64_t>> ppc64noTocRelax;

	} // namespace elf

	std::string toString(const elf::InputSectionBase *);
	} // namespace lld

	#endif