linux-x64/clang/include/llvm/Object/ObjectFile.h - hafnium/prebuilts - Git at Google

 //===- ObjectFile.h - File format independent object file -------*- 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
 //
 //===----------------------------------------------------------------------===//
 //
 // This file declares a file format independent ObjectFile class.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_OBJECT_OBJECTFILE_H
 #define LLVM_OBJECT_OBJECTFILE_H

 #include "llvm/ADT/StringRef.h"
 #include "llvm/ADT/Triple.h"
 #include "llvm/ADT/iterator_range.h"
 #include "llvm/BinaryFormat/Magic.h"
 #include "llvm/MC/SubtargetFeature.h"
 #include "llvm/Object/Binary.h"
 #include "llvm/Object/Error.h"
 #include "llvm/Object/SymbolicFile.h"
 #include "llvm/Support/Casting.h"
 #include "llvm/Support/Error.h"
 #include "llvm/Support/FileSystem.h"
 #include "llvm/Support/MemoryBuffer.h"
 #include <cassert>
 #include <cstdint>
 #include <memory>
 #include <system_error>

 namespace llvm {

 class ARMAttributeParser;

 namespace object {

 class COFFObjectFile;
 class MachOObjectFile;
 class ObjectFile;
 class SectionRef;
 class SymbolRef;
 class symbol_iterator;
 class WasmObjectFile;

 using section_iterator = content_iterator<SectionRef>;

 /// This is a value type class that represents a single relocation in the list
 /// of relocations in the object file.
 class RelocationRef {
   DataRefImpl RelocationPimpl;
   const ObjectFile *OwningObject = nullptr;

 public:
   RelocationRef() = default;
   RelocationRef(DataRefImpl RelocationP, const ObjectFile *Owner);

   bool operator==(const RelocationRef &Other) const;

   void moveNext();

   uint64_t getOffset() const;
   symbol_iterator getSymbol() const;
   uint64_t getType() const;

   /// Get a string that represents the type of this relocation.
   ///
   /// This is for display purposes only.
   void getTypeName(SmallVectorImpl<char> &Result) const;

   DataRefImpl getRawDataRefImpl() const;
   const ObjectFile *getObject() const;
 };

 using relocation_iterator = content_iterator<RelocationRef>;

 /// This is a value type class that represents a single section in the list of
 /// sections in the object file.
 class SectionRef {
   friend class SymbolRef;

   DataRefImpl SectionPimpl;
   const ObjectFile *OwningObject = nullptr;

 public:
   SectionRef() = default;
   SectionRef(DataRefImpl SectionP, const ObjectFile *Owner);

   bool operator==(const SectionRef &Other) const;
   bool operator!=(const SectionRef &Other) const;
   bool operator<(const SectionRef &Other) const;

   void moveNext();

   std::error_code getName(StringRef &Result) const;
   uint64_t getAddress() const;
   uint64_t getIndex() const;
   uint64_t getSize() const;
   std::error_code getContents(StringRef &Result) const;

   /// Get the alignment of this section as the actual value (not log 2).
   uint64_t getAlignment() const;

   bool isCompressed() const;
   /// Whether this section contains instructions.
   bool isText() const;
   /// Whether this section contains data, not instructions.
   bool isData() const;
   /// Whether this section contains BSS uninitialized data.
   bool isBSS() const;
   bool isVirtual() const;
   bool isBitcode() const;
   bool isStripped() const;

   /// Whether this section will be placed in the text segment, according to the
   /// Berkeley size format. This is true if the section is allocatable, and
   /// contains either code or readonly data.
   bool isBerkeleyText() const;
   /// Whether this section will be placed in the data segment, according to the
   /// Berkeley size format. This is true if the section is allocatable and
   /// contains data (e.g. PROGBITS), but is not text.
   bool isBerkeleyData() const;

   bool containsSymbol(SymbolRef S) const;

   relocation_iterator relocation_begin() const;
   relocation_iterator relocation_end() const;
   iterator_range<relocation_iterator> relocations() const {
     return make_range(relocation_begin(), relocation_end());
   }
   section_iterator getRelocatedSection() const;

   DataRefImpl getRawDataRefImpl() const;
   const ObjectFile *getObject() const;
 };

 /// This is a value type class that represents a single symbol in the list of
 /// symbols in the object file.
 class SymbolRef : public BasicSymbolRef {
   friend class SectionRef;

 public:
   enum Type {
     ST_Unknown, // Type not specified
     ST_Data,
     ST_Debug,
     ST_File,
     ST_Function,
     ST_Other
   };

   SymbolRef() = default;
   SymbolRef(DataRefImpl SymbolP, const ObjectFile *Owner);
   SymbolRef(const BasicSymbolRef &B) : BasicSymbolRef(B) {
     assert(isa<ObjectFile>(BasicSymbolRef::getObject()));
   }

   Expected<StringRef> getName() const;
   /// Returns the symbol virtual address (i.e. address at which it will be
   /// mapped).
   Expected<uint64_t> getAddress() const;

   /// Return the value of the symbol depending on the object this can be an
   /// offset or a virtual address.
   uint64_t getValue() const;

   /// Get the alignment of this symbol as the actual value (not log 2).
   uint32_t getAlignment() const;
   uint64_t getCommonSize() const;
   Expected<SymbolRef::Type> getType() const;

   /// Get section this symbol is defined in reference to. Result is
   /// end_sections() if it is undefined or is an absolute symbol.
   Expected<section_iterator> getSection() const;

   const ObjectFile *getObject() const;
 };

 class symbol_iterator : public basic_symbol_iterator {
 public:
   symbol_iterator(SymbolRef Sym) : basic_symbol_iterator(Sym) {}
   symbol_iterator(const basic_symbol_iterator &B)
       : basic_symbol_iterator(SymbolRef(B->getRawDataRefImpl(),
                                         cast<ObjectFile>(B->getObject()))) {}

   const SymbolRef *operator->() const {
     const BasicSymbolRef &P = basic_symbol_iterator::operator *();
     return static_cast<const SymbolRef*>(&P);
   }

   const SymbolRef &operator*() const {
     const BasicSymbolRef &P = basic_symbol_iterator::operator *();
     return static_cast<const SymbolRef&>(P);
   }
 };

 /// This class is the base class for all object file types. Concrete instances
 /// of this object are created by createObjectFile, which figures out which type
 /// to create.
 class ObjectFile : public SymbolicFile {
   virtual void anchor();

 protected:
   ObjectFile(unsigned int Type, MemoryBufferRef Source);

   const uint8_t *base() const {
     return reinterpret_cast<const uint8_t *>(Data.getBufferStart());
   }

   // These functions are for SymbolRef to call internally. The main goal of
   // this is to allow SymbolRef::SymbolPimpl to point directly to the symbol
   // entry in the memory mapped object file. SymbolPimpl cannot contain any
   // virtual functions because then it could not point into the memory mapped
   // file.
   //
   // Implementations assume that the DataRefImpl is valid and has not been
   // modified externally. It's UB otherwise.
   friend class SymbolRef;

   virtual Expected<StringRef> getSymbolName(DataRefImpl Symb) const = 0;
   std::error_code printSymbolName(raw_ostream &OS,
                                   DataRefImpl Symb) const override;
   virtual Expected<uint64_t> getSymbolAddress(DataRefImpl Symb) const = 0;
   virtual uint64_t getSymbolValueImpl(DataRefImpl Symb) const = 0;
   virtual uint32_t getSymbolAlignment(DataRefImpl Symb) const;
   virtual uint64_t getCommonSymbolSizeImpl(DataRefImpl Symb) const = 0;
   virtual Expected<SymbolRef::Type> getSymbolType(DataRefImpl Symb) const = 0;
   virtual Expected<section_iterator>
   getSymbolSection(DataRefImpl Symb) const = 0;

   // Same as above for SectionRef.
   friend class SectionRef;

   virtual void moveSectionNext(DataRefImpl &Sec) const = 0;
   virtual std::error_code getSectionName(DataRefImpl Sec,
                                          StringRef &Res) const = 0;
   virtual uint64_t getSectionAddress(DataRefImpl Sec) const = 0;
   virtual uint64_t getSectionIndex(DataRefImpl Sec) const = 0;
   virtual uint64_t getSectionSize(DataRefImpl Sec) const = 0;
   virtual std::error_code getSectionContents(DataRefImpl Sec,
                                              StringRef &Res) const = 0;
   virtual uint64_t getSectionAlignment(DataRefImpl Sec) const = 0;
   virtual bool isSectionCompressed(DataRefImpl Sec) const = 0;
   virtual bool isSectionText(DataRefImpl Sec) const = 0;
   virtual bool isSectionData(DataRefImpl Sec) const = 0;
   virtual bool isSectionBSS(DataRefImpl Sec) const = 0;
   // A section is 'virtual' if its contents aren't present in the object image.
   virtual bool isSectionVirtual(DataRefImpl Sec) const = 0;
   virtual bool isSectionBitcode(DataRefImpl Sec) const;
   virtual bool isSectionStripped(DataRefImpl Sec) const;
   virtual bool isBerkeleyText(DataRefImpl Sec) const;
   virtual bool isBerkeleyData(DataRefImpl Sec) const;
   virtual relocation_iterator section_rel_begin(DataRefImpl Sec) const = 0;
   virtual relocation_iterator section_rel_end(DataRefImpl Sec) const = 0;
   virtual section_iterator getRelocatedSection(DataRefImpl Sec) const;

   // Same as above for RelocationRef.
   friend class RelocationRef;
   virtual void moveRelocationNext(DataRefImpl &Rel) const = 0;
   virtual uint64_t getRelocationOffset(DataRefImpl Rel) const = 0;
   virtual symbol_iterator getRelocationSymbol(DataRefImpl Rel) const = 0;
   virtual uint64_t getRelocationType(DataRefImpl Rel) const = 0;
   virtual void getRelocationTypeName(DataRefImpl Rel,
                                      SmallVectorImpl<char> &Result) const = 0;

   uint64_t getSymbolValue(DataRefImpl Symb) const;

 public:
   ObjectFile() = delete;
   ObjectFile(const ObjectFile &other) = delete;

   uint64_t getCommonSymbolSize(DataRefImpl Symb) const {
     assert(getSymbolFlags(Symb) & SymbolRef::SF_Common);
     return getCommonSymbolSizeImpl(Symb);
   }

   virtual std::vector<SectionRef> dynamic_relocation_sections() const {
     return std::vector<SectionRef>();
   }

   using symbol_iterator_range = iterator_range<symbol_iterator>;
   symbol_iterator_range symbols() const {
     return symbol_iterator_range(symbol_begin(), symbol_end());
   }

   virtual section_iterator section_begin() const = 0;
   virtual section_iterator section_end() const = 0;

   using section_iterator_range = iterator_range<section_iterator>;
   section_iterator_range sections() const {
     return section_iterator_range(section_begin(), section_end());
   }

   /// The number of bytes used to represent an address in this object
   ///        file format.
   virtual uint8_t getBytesInAddress() const = 0;

   virtual StringRef getFileFormatName() const = 0;
   virtual Triple::ArchType getArch() const = 0;
   virtual SubtargetFeatures getFeatures() const = 0;
   virtual void setARMSubArch(Triple &TheTriple) const { }
   virtual Expected<uint64_t> getStartAddress() const {
     return errorCodeToError(object_error::parse_failed);
   };

   /// Create a triple from the data in this object file.
   Triple makeTriple() const;

   virtual std::error_code
     getBuildAttributes(ARMAttributeParser &Attributes) const {
       return std::error_code();
     }

   /// Maps a debug section name to a standard DWARF section name.
   virtual StringRef mapDebugSectionName(StringRef Name) const { return Name; }

   /// True if this is a relocatable object (.o/.obj).
   virtual bool isRelocatableObject() const = 0;

   /// @returns Pointer to ObjectFile subclass to handle this type of object.
   /// @param ObjectPath The path to the object file. ObjectPath.isObject must
   ///        return true.
   /// Create ObjectFile from path.
   static Expected<OwningBinary<ObjectFile>>
   createObjectFile(StringRef ObjectPath);

   static Expected<std::unique_ptr<ObjectFile>>
   createObjectFile(MemoryBufferRef Object, llvm::file_magic Type);
   static Expected<std::unique_ptr<ObjectFile>>
   createObjectFile(MemoryBufferRef Object) {
     return createObjectFile(Object, llvm::file_magic::unknown);
   }

   static bool classof(const Binary *v) {
     return v->isObject();
   }

   static Expected<std::unique_ptr<COFFObjectFile>>
   createCOFFObjectFile(MemoryBufferRef Object);

   static Expected<std::unique_ptr<ObjectFile>>
   createELFObjectFile(MemoryBufferRef Object);

   static Expected<std::unique_ptr<MachOObjectFile>>
   createMachOObjectFile(MemoryBufferRef Object,
                         uint32_t UniversalCputype = 0,
                         uint32_t UniversalIndex = 0);

   static Expected<std::unique_ptr<WasmObjectFile>>
   createWasmObjectFile(MemoryBufferRef Object);
 };

 // Inline function definitions.
 inline SymbolRef::SymbolRef(DataRefImpl SymbolP, const ObjectFile *Owner)
     : BasicSymbolRef(SymbolP, Owner) {}

 inline Expected<StringRef> SymbolRef::getName() const {
   return getObject()->getSymbolName(getRawDataRefImpl());
 }

 inline Expected<uint64_t> SymbolRef::getAddress() const {
   return getObject()->getSymbolAddress(getRawDataRefImpl());
 }

 inline uint64_t SymbolRef::getValue() const {
   return getObject()->getSymbolValue(getRawDataRefImpl());
 }

 inline uint32_t SymbolRef::getAlignment() const {
   return getObject()->getSymbolAlignment(getRawDataRefImpl());
 }

 inline uint64_t SymbolRef::getCommonSize() const {
   return getObject()->getCommonSymbolSize(getRawDataRefImpl());
 }

 inline Expected<section_iterator> SymbolRef::getSection() const {
   return getObject()->getSymbolSection(getRawDataRefImpl());
 }

 inline Expected<SymbolRef::Type> SymbolRef::getType() const {
   return getObject()->getSymbolType(getRawDataRefImpl());
 }

 inline const ObjectFile *SymbolRef::getObject() const {
   const SymbolicFile *O = BasicSymbolRef::getObject();
   return cast<ObjectFile>(O);
 }

 /// SectionRef
 inline SectionRef::SectionRef(DataRefImpl SectionP,
                               const ObjectFile *Owner)
   : SectionPimpl(SectionP)
   , OwningObject(Owner) {}

 inline bool SectionRef::operator==(const SectionRef &Other) const {
   return SectionPimpl == Other.SectionPimpl;
 }

 inline bool SectionRef::operator!=(const SectionRef &Other) const {
   return SectionPimpl != Other.SectionPimpl;
 }

 inline bool SectionRef::operator<(const SectionRef &Other) const {
   return SectionPimpl < Other.SectionPimpl;
 }

 inline void SectionRef::moveNext() {
   return OwningObject->moveSectionNext(SectionPimpl);
 }

 inline std::error_code SectionRef::getName(StringRef &Result) const {
   return OwningObject->getSectionName(SectionPimpl, Result);
 }

 inline uint64_t SectionRef::getAddress() const {
   return OwningObject->getSectionAddress(SectionPimpl);
 }

 inline uint64_t SectionRef::getIndex() const {
   return OwningObject->getSectionIndex(SectionPimpl);
 }

 inline uint64_t SectionRef::getSize() const {
   return OwningObject->getSectionSize(SectionPimpl);
 }

 inline std::error_code SectionRef::getContents(StringRef &Result) const {
   return OwningObject->getSectionContents(SectionPimpl, Result);
 }

 inline uint64_t SectionRef::getAlignment() const {
   return OwningObject->getSectionAlignment(SectionPimpl);
 }

 inline bool SectionRef::isCompressed() const {
   return OwningObject->isSectionCompressed(SectionPimpl);
 }

 inline bool SectionRef::isText() const {
   return OwningObject->isSectionText(SectionPimpl);
 }

 inline bool SectionRef::isData() const {
   return OwningObject->isSectionData(SectionPimpl);
 }

 inline bool SectionRef::isBSS() const {
   return OwningObject->isSectionBSS(SectionPimpl);
 }

 inline bool SectionRef::isVirtual() const {
   return OwningObject->isSectionVirtual(SectionPimpl);
 }

 inline bool SectionRef::isBitcode() const {
   return OwningObject->isSectionBitcode(SectionPimpl);
 }

 inline bool SectionRef::isStripped() const {
   return OwningObject->isSectionStripped(SectionPimpl);
 }

 inline bool SectionRef::isBerkeleyText() const {
   return OwningObject->isBerkeleyText(SectionPimpl);
 }

 inline bool SectionRef::isBerkeleyData() const {
   return OwningObject->isBerkeleyData(SectionPimpl);
 }

 inline relocation_iterator SectionRef::relocation_begin() const {
   return OwningObject->section_rel_begin(SectionPimpl);
 }

 inline relocation_iterator SectionRef::relocation_end() const {
   return OwningObject->section_rel_end(SectionPimpl);
 }

 inline section_iterator SectionRef::getRelocatedSection() const {
   return OwningObject->getRelocatedSection(SectionPimpl);
 }

 inline DataRefImpl SectionRef::getRawDataRefImpl() const {
   return SectionPimpl;
 }

 inline const ObjectFile *SectionRef::getObject() const {
   return OwningObject;
 }

 /// RelocationRef
 inline RelocationRef::RelocationRef(DataRefImpl RelocationP,
                               const ObjectFile *Owner)
   : RelocationPimpl(RelocationP)
   , OwningObject(Owner) {}

 inline bool RelocationRef::operator==(const RelocationRef &Other) const {
   return RelocationPimpl == Other.RelocationPimpl;
 }

 inline void RelocationRef::moveNext() {
   return OwningObject->moveRelocationNext(RelocationPimpl);
 }

 inline uint64_t RelocationRef::getOffset() const {
   return OwningObject->getRelocationOffset(RelocationPimpl);
 }

 inline symbol_iterator RelocationRef::getSymbol() const {
   return OwningObject->getRelocationSymbol(RelocationPimpl);
 }

 inline uint64_t RelocationRef::getType() const {
   return OwningObject->getRelocationType(RelocationPimpl);
 }

 inline void RelocationRef::getTypeName(SmallVectorImpl<char> &Result) const {
   return OwningObject->getRelocationTypeName(RelocationPimpl, Result);
 }

 inline DataRefImpl RelocationRef::getRawDataRefImpl() const {
   return RelocationPimpl;
 }

 inline const ObjectFile *RelocationRef::getObject() const {
   return OwningObject;
 }

 } // end namespace object

 } // end namespace llvm

 #endif // LLVM_OBJECT_OBJECTFILE_H
	//===- ObjectFile.h - File format independent object file -------- 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
	//
	//===----------------------------------------------------------------------===//
	//
	// This file declares a file format independent ObjectFile class.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_OBJECT_OBJECTFILE_H
	#define LLVM_OBJECT_OBJECTFILE_H

	#include "llvm/ADT/StringRef.h"
	#include "llvm/ADT/Triple.h"
	#include "llvm/ADT/iterator_range.h"
	#include "llvm/BinaryFormat/Magic.h"
	#include "llvm/MC/SubtargetFeature.h"
	#include "llvm/Object/Binary.h"
	#include "llvm/Object/Error.h"
	#include "llvm/Object/SymbolicFile.h"
	#include "llvm/Support/Casting.h"
	#include "llvm/Support/Error.h"
	#include "llvm/Support/FileSystem.h"
	#include "llvm/Support/MemoryBuffer.h"
	#include <cassert>
	#include <cstdint>
	#include <memory>
	#include <system_error>

	namespace llvm {

	class ARMAttributeParser;

	namespace object {

	class COFFObjectFile;
	class MachOObjectFile;
	class ObjectFile;
	class SectionRef;
	class SymbolRef;
	class symbol_iterator;
	class WasmObjectFile;

	using section_iterator = content_iterator<SectionRef>;

	/// This is a value type class that represents a single relocation in the list
	/// of relocations in the object file.
	class RelocationRef {
	DataRefImpl RelocationPimpl;
	const ObjectFile *OwningObject = nullptr;

	public:
	RelocationRef() = default;
	RelocationRef(DataRefImpl RelocationP, const ObjectFile *Owner);

	bool operator==(const RelocationRef &Other) const;

	void moveNext();

	uint64_t getOffset() const;
	symbol_iterator getSymbol() const;
	uint64_t getType() const;

	/// Get a string that represents the type of this relocation.
	///
	/// This is for display purposes only.
	void getTypeName(SmallVectorImpl<char> &Result) const;

	DataRefImpl getRawDataRefImpl() const;
	const ObjectFile *getObject() const;
	};

	using relocation_iterator = content_iterator<RelocationRef>;

	/// This is a value type class that represents a single section in the list of
	/// sections in the object file.
	class SectionRef {
	friend class SymbolRef;

	DataRefImpl SectionPimpl;
	const ObjectFile *OwningObject = nullptr;

	public:
	SectionRef() = default;
	SectionRef(DataRefImpl SectionP, const ObjectFile *Owner);

	bool operator==(const SectionRef &Other) const;
	bool operator!=(const SectionRef &Other) const;
	bool operator<(const SectionRef &Other) const;

	void moveNext();

	std::error_code getName(StringRef &Result) const;
	uint64_t getAddress() const;
	uint64_t getIndex() const;
	uint64_t getSize() const;
	std::error_code getContents(StringRef &Result) const;

	/// Get the alignment of this section as the actual value (not log 2).
	uint64_t getAlignment() const;

	bool isCompressed() const;
	/// Whether this section contains instructions.
	bool isText() const;
	/// Whether this section contains data, not instructions.
	bool isData() const;
	/// Whether this section contains BSS uninitialized data.
	bool isBSS() const;
	bool isVirtual() const;
	bool isBitcode() const;
	bool isStripped() const;

	/// Whether this section will be placed in the text segment, according to the
	/// Berkeley size format. This is true if the section is allocatable, and
	/// contains either code or readonly data.
	bool isBerkeleyText() const;
	/// Whether this section will be placed in the data segment, according to the
	/// Berkeley size format. This is true if the section is allocatable and
	/// contains data (e.g. PROGBITS), but is not text.
	bool isBerkeleyData() const;

	bool containsSymbol(SymbolRef S) const;

	relocation_iterator relocation_begin() const;
	relocation_iterator relocation_end() const;
	iterator_range<relocation_iterator> relocations() const {
	return make_range(relocation_begin(), relocation_end());
	}
	section_iterator getRelocatedSection() const;

	DataRefImpl getRawDataRefImpl() const;
	const ObjectFile *getObject() const;
	};

	/// This is a value type class that represents a single symbol in the list of
	/// symbols in the object file.
	class SymbolRef : public BasicSymbolRef {
	friend class SectionRef;

	public:
	enum Type {
	ST_Unknown, // Type not specified
	ST_Data,
	ST_Debug,
	ST_File,
	ST_Function,
	ST_Other
	};

	SymbolRef() = default;
	SymbolRef(DataRefImpl SymbolP, const ObjectFile *Owner);
	SymbolRef(const BasicSymbolRef &B) : BasicSymbolRef(B) {
	assert(isa<ObjectFile>(BasicSymbolRef::getObject()));
	}

	Expected<StringRef> getName() const;
	/// Returns the symbol virtual address (i.e. address at which it will be
	/// mapped).
	Expected<uint64_t> getAddress() const;

	/// Return the value of the symbol depending on the object this can be an
	/// offset or a virtual address.
	uint64_t getValue() const;

	/// Get the alignment of this symbol as the actual value (not log 2).
	uint32_t getAlignment() const;
	uint64_t getCommonSize() const;
	Expected<SymbolRef::Type> getType() const;

	/// Get section this symbol is defined in reference to. Result is
	/// end_sections() if it is undefined or is an absolute symbol.
	Expected<section_iterator> getSection() const;

	const ObjectFile *getObject() const;
	};

	class symbol_iterator : public basic_symbol_iterator {
	public:
	symbol_iterator(SymbolRef Sym) : basic_symbol_iterator(Sym) {}
	symbol_iterator(const basic_symbol_iterator &B)
	: basic_symbol_iterator(SymbolRef(B->getRawDataRefImpl(),
	cast<ObjectFile>(B->getObject()))) {}

	const SymbolRef *operator->() const {
	const BasicSymbolRef &P = basic_symbol_iterator::operator *();
	return static_cast<const SymbolRef*>(&P);
	}

	const SymbolRef &operator*() const {
	const BasicSymbolRef &P = basic_symbol_iterator::operator *();
	return static_cast<const SymbolRef&>(P);
	}
	};

	/// This class is the base class for all object file types. Concrete instances
	/// of this object are created by createObjectFile, which figures out which type
	/// to create.
	class ObjectFile : public SymbolicFile {
	virtual void anchor();

	protected:
	ObjectFile(unsigned int Type, MemoryBufferRef Source);

	const uint8_t *base() const {
	return reinterpret_cast<const uint8_t *>(Data.getBufferStart());
	}

	// These functions are for SymbolRef to call internally. The main goal of
	// this is to allow SymbolRef::SymbolPimpl to point directly to the symbol
	// entry in the memory mapped object file. SymbolPimpl cannot contain any
	// virtual functions because then it could not point into the memory mapped
	// file.
	//
	// Implementations assume that the DataRefImpl is valid and has not been
	// modified externally. It's UB otherwise.
	friend class SymbolRef;

	virtual Expected<StringRef> getSymbolName(DataRefImpl Symb) const = 0;
	std::error_code printSymbolName(raw_ostream &OS,
	DataRefImpl Symb) const override;
	virtual Expected<uint64_t> getSymbolAddress(DataRefImpl Symb) const = 0;
	virtual uint64_t getSymbolValueImpl(DataRefImpl Symb) const = 0;
	virtual uint32_t getSymbolAlignment(DataRefImpl Symb) const;
	virtual uint64_t getCommonSymbolSizeImpl(DataRefImpl Symb) const = 0;
	virtual Expected<SymbolRef::Type> getSymbolType(DataRefImpl Symb) const = 0;
	virtual Expected<section_iterator>
	getSymbolSection(DataRefImpl Symb) const = 0;

	// Same as above for SectionRef.
	friend class SectionRef;

	virtual void moveSectionNext(DataRefImpl &Sec) const = 0;
	virtual std::error_code getSectionName(DataRefImpl Sec,
	StringRef &Res) const = 0;
	virtual uint64_t getSectionAddress(DataRefImpl Sec) const = 0;
	virtual uint64_t getSectionIndex(DataRefImpl Sec) const = 0;
	virtual uint64_t getSectionSize(DataRefImpl Sec) const = 0;
	virtual std::error_code getSectionContents(DataRefImpl Sec,
	StringRef &Res) const = 0;
	virtual uint64_t getSectionAlignment(DataRefImpl Sec) const = 0;
	virtual bool isSectionCompressed(DataRefImpl Sec) const = 0;
	virtual bool isSectionText(DataRefImpl Sec) const = 0;
	virtual bool isSectionData(DataRefImpl Sec) const = 0;
	virtual bool isSectionBSS(DataRefImpl Sec) const = 0;
	// A section is 'virtual' if its contents aren't present in the object image.
	virtual bool isSectionVirtual(DataRefImpl Sec) const = 0;
	virtual bool isSectionBitcode(DataRefImpl Sec) const;
	virtual bool isSectionStripped(DataRefImpl Sec) const;
	virtual bool isBerkeleyText(DataRefImpl Sec) const;
	virtual bool isBerkeleyData(DataRefImpl Sec) const;
	virtual relocation_iterator section_rel_begin(DataRefImpl Sec) const = 0;
	virtual relocation_iterator section_rel_end(DataRefImpl Sec) const = 0;
	virtual section_iterator getRelocatedSection(DataRefImpl Sec) const;

	// Same as above for RelocationRef.
	friend class RelocationRef;
	virtual void moveRelocationNext(DataRefImpl &Rel) const = 0;
	virtual uint64_t getRelocationOffset(DataRefImpl Rel) const = 0;
	virtual symbol_iterator getRelocationSymbol(DataRefImpl Rel) const = 0;
	virtual uint64_t getRelocationType(DataRefImpl Rel) const = 0;
	virtual void getRelocationTypeName(DataRefImpl Rel,
	SmallVectorImpl<char> &Result) const = 0;

	uint64_t getSymbolValue(DataRefImpl Symb) const;

	public:
	ObjectFile() = delete;
	ObjectFile(const ObjectFile &other) = delete;

	uint64_t getCommonSymbolSize(DataRefImpl Symb) const {
	assert(getSymbolFlags(Symb) & SymbolRef::SF_Common);
	return getCommonSymbolSizeImpl(Symb);
	}

	virtual std::vector<SectionRef> dynamic_relocation_sections() const {
	return std::vector<SectionRef>();
	}

	using symbol_iterator_range = iterator_range<symbol_iterator>;
	symbol_iterator_range symbols() const {
	return symbol_iterator_range(symbol_begin(), symbol_end());
	}

	virtual section_iterator section_begin() const = 0;
	virtual section_iterator section_end() const = 0;

	using section_iterator_range = iterator_range<section_iterator>;
	section_iterator_range sections() const {
	return section_iterator_range(section_begin(), section_end());
	}

	/// The number of bytes used to represent an address in this object
	/// file format.
	virtual uint8_t getBytesInAddress() const = 0;

	virtual StringRef getFileFormatName() const = 0;
	virtual Triple::ArchType getArch() const = 0;
	virtual SubtargetFeatures getFeatures() const = 0;
	virtual void setARMSubArch(Triple &TheTriple) const { }
	virtual Expected<uint64_t> getStartAddress() const {
	return errorCodeToError(object_error::parse_failed);
	};

	/// Create a triple from the data in this object file.
	Triple makeTriple() const;

	virtual std::error_code
	getBuildAttributes(ARMAttributeParser &Attributes) const {
	return std::error_code();
	}

	/// Maps a debug section name to a standard DWARF section name.
	virtual StringRef mapDebugSectionName(StringRef Name) const { return Name; }

	/// True if this is a relocatable object (.o/.obj).
	virtual bool isRelocatableObject() const = 0;

	/// @returns Pointer to ObjectFile subclass to handle this type of object.
	/// @param ObjectPath The path to the object file. ObjectPath.isObject must
	/// return true.
	/// Create ObjectFile from path.
	static Expected<OwningBinary<ObjectFile>>
	createObjectFile(StringRef ObjectPath);

	static Expected<std::unique_ptr<ObjectFile>>
	createObjectFile(MemoryBufferRef Object, llvm::file_magic Type);
	static Expected<std::unique_ptr<ObjectFile>>
	createObjectFile(MemoryBufferRef Object) {
	return createObjectFile(Object, llvm::file_magic::unknown);
	}

	static bool classof(const Binary *v) {
	return v->isObject();
	}

	static Expected<std::unique_ptr<COFFObjectFile>>
	createCOFFObjectFile(MemoryBufferRef Object);

	static Expected<std::unique_ptr<ObjectFile>>
	createELFObjectFile(MemoryBufferRef Object);

	static Expected<std::unique_ptr<MachOObjectFile>>
	createMachOObjectFile(MemoryBufferRef Object,
	uint32_t UniversalCputype = 0,
	uint32_t UniversalIndex = 0);

	static Expected<std::unique_ptr<WasmObjectFile>>
	createWasmObjectFile(MemoryBufferRef Object);
	};

	// Inline function definitions.
	inline SymbolRef::SymbolRef(DataRefImpl SymbolP, const ObjectFile *Owner)
	: BasicSymbolRef(SymbolP, Owner) {}

	inline Expected<StringRef> SymbolRef::getName() const {
	return getObject()->getSymbolName(getRawDataRefImpl());
	}

	inline Expected<uint64_t> SymbolRef::getAddress() const {
	return getObject()->getSymbolAddress(getRawDataRefImpl());
	}

	inline uint64_t SymbolRef::getValue() const {
	return getObject()->getSymbolValue(getRawDataRefImpl());
	}

	inline uint32_t SymbolRef::getAlignment() const {
	return getObject()->getSymbolAlignment(getRawDataRefImpl());
	}

	inline uint64_t SymbolRef::getCommonSize() const {
	return getObject()->getCommonSymbolSize(getRawDataRefImpl());
	}

	inline Expected<section_iterator> SymbolRef::getSection() const {
	return getObject()->getSymbolSection(getRawDataRefImpl());
	}

	inline Expected<SymbolRef::Type> SymbolRef::getType() const {
	return getObject()->getSymbolType(getRawDataRefImpl());
	}

	inline const ObjectFile *SymbolRef::getObject() const {
	const SymbolicFile *O = BasicSymbolRef::getObject();
	return cast<ObjectFile>(O);
	}

	/// SectionRef
	inline SectionRef::SectionRef(DataRefImpl SectionP,
	const ObjectFile *Owner)
	: SectionPimpl(SectionP)
	, OwningObject(Owner) {}

	inline bool SectionRef::operator==(const SectionRef &Other) const {
	return SectionPimpl == Other.SectionPimpl;
	}

	inline bool SectionRef::operator!=(const SectionRef &Other) const {
	return SectionPimpl != Other.SectionPimpl;
	}

	inline bool SectionRef::operator<(const SectionRef &Other) const {
	return SectionPimpl < Other.SectionPimpl;
	}

	inline void SectionRef::moveNext() {
	return OwningObject->moveSectionNext(SectionPimpl);
	}

	inline std::error_code SectionRef::getName(StringRef &Result) const {
	return OwningObject->getSectionName(SectionPimpl, Result);
	}

	inline uint64_t SectionRef::getAddress() const {
	return OwningObject->getSectionAddress(SectionPimpl);
	}

	inline uint64_t SectionRef::getIndex() const {
	return OwningObject->getSectionIndex(SectionPimpl);
	}

	inline uint64_t SectionRef::getSize() const {
	return OwningObject->getSectionSize(SectionPimpl);
	}

	inline std::error_code SectionRef::getContents(StringRef &Result) const {
	return OwningObject->getSectionContents(SectionPimpl, Result);
	}

	inline uint64_t SectionRef::getAlignment() const {
	return OwningObject->getSectionAlignment(SectionPimpl);
	}

	inline bool SectionRef::isCompressed() const {
	return OwningObject->isSectionCompressed(SectionPimpl);
	}

	inline bool SectionRef::isText() const {
	return OwningObject->isSectionText(SectionPimpl);
	}

	inline bool SectionRef::isData() const {
	return OwningObject->isSectionData(SectionPimpl);
	}

	inline bool SectionRef::isBSS() const {
	return OwningObject->isSectionBSS(SectionPimpl);
	}

	inline bool SectionRef::isVirtual() const {
	return OwningObject->isSectionVirtual(SectionPimpl);
	}

	inline bool SectionRef::isBitcode() const {
	return OwningObject->isSectionBitcode(SectionPimpl);
	}

	inline bool SectionRef::isStripped() const {
	return OwningObject->isSectionStripped(SectionPimpl);
	}

	inline bool SectionRef::isBerkeleyText() const {
	return OwningObject->isBerkeleyText(SectionPimpl);
	}

	inline bool SectionRef::isBerkeleyData() const {
	return OwningObject->isBerkeleyData(SectionPimpl);
	}

	inline relocation_iterator SectionRef::relocation_begin() const {
	return OwningObject->section_rel_begin(SectionPimpl);
	}

	inline relocation_iterator SectionRef::relocation_end() const {
	return OwningObject->section_rel_end(SectionPimpl);
	}

	inline section_iterator SectionRef::getRelocatedSection() const {
	return OwningObject->getRelocatedSection(SectionPimpl);
	}

	inline DataRefImpl SectionRef::getRawDataRefImpl() const {
	return SectionPimpl;
	}

	inline const ObjectFile *SectionRef::getObject() const {
	return OwningObject;
	}

	/// RelocationRef
	inline RelocationRef::RelocationRef(DataRefImpl RelocationP,
	const ObjectFile *Owner)
	: RelocationPimpl(RelocationP)
	, OwningObject(Owner) {}

	inline bool RelocationRef::operator==(const RelocationRef &Other) const {
	return RelocationPimpl == Other.RelocationPimpl;
	}

	inline void RelocationRef::moveNext() {
	return OwningObject->moveRelocationNext(RelocationPimpl);
	}

	inline uint64_t RelocationRef::getOffset() const {
	return OwningObject->getRelocationOffset(RelocationPimpl);
	}

	inline symbol_iterator RelocationRef::getSymbol() const {
	return OwningObject->getRelocationSymbol(RelocationPimpl);
	}

	inline uint64_t RelocationRef::getType() const {
	return OwningObject->getRelocationType(RelocationPimpl);
	}

	inline void RelocationRef::getTypeName(SmallVectorImpl<char> &Result) const {
	return OwningObject->getRelocationTypeName(RelocationPimpl, Result);
	}

	inline DataRefImpl RelocationRef::getRawDataRefImpl() const {
	return RelocationPimpl;
	}

	inline const ObjectFile *RelocationRef::getObject() const {
	return OwningObject;
	}

	} // end namespace object

	} // end namespace llvm

	#endif // LLVM_OBJECT_OBJECTFILE_H