tools/llvm-pdbutil/InputFile.cpp - llvm - Git at Google

 //===- InputFile.cpp ------------------------------------------ *- C++ --*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 #include "InputFile.h"

 #include "FormatUtil.h"
 #include "LinePrinter.h"

 #include "llvm/BinaryFormat/Magic.h"
 #include "llvm/DebugInfo/CodeView/CodeView.h"
 #include "llvm/DebugInfo/CodeView/LazyRandomTypeCollection.h"
 #include "llvm/DebugInfo/CodeView/StringsAndChecksums.h"
 #include "llvm/DebugInfo/PDB/Native/DbiStream.h"
 #include "llvm/DebugInfo/PDB/Native/NativeSession.h"
 #include "llvm/DebugInfo/PDB/Native/PDBFile.h"
 #include "llvm/DebugInfo/PDB/Native/PDBStringTable.h"
 #include "llvm/DebugInfo/PDB/Native/RawError.h"
 #include "llvm/DebugInfo/PDB/Native/TpiStream.h"
 #include "llvm/DebugInfo/PDB/PDB.h"
 #include "llvm/Object/COFF.h"
 #include "llvm/Support/FileSystem.h"
 #include "llvm/Support/FormatVariadic.h"

 using namespace llvm;
 using namespace llvm::codeview;
 using namespace llvm::object;
 using namespace llvm::pdb;

 InputFile::InputFile() {}
 InputFile::~InputFile() {}

 static Expected<ModuleDebugStreamRef>
 getModuleDebugStream(PDBFile &File, StringRef &ModuleName, uint32_t Index) {
   ExitOnError Err("Unexpected error: ");

   auto &Dbi = Err(File.getPDBDbiStream());
   const auto &Modules = Dbi.modules();
   if (Index >= Modules.getModuleCount())
     return make_error<RawError>(raw_error_code::index_out_of_bounds,
                                 "Invalid module index");

   auto Modi = Modules.getModuleDescriptor(Index);

   ModuleName = Modi.getModuleName();

   uint16_t ModiStream = Modi.getModuleStreamIndex();
   if (ModiStream == kInvalidStreamIndex)
     return make_error<RawError>(raw_error_code::no_stream,
                                 "Module stream not present");

   auto ModStreamData = File.createIndexedStream(ModiStream);

   ModuleDebugStreamRef ModS(Modi, std::move(ModStreamData));
   if (auto EC = ModS.reload())
     return make_error<RawError>(raw_error_code::corrupt_file,
                                 "Invalid module stream");

   return std::move(ModS);
 }

 static inline bool isCodeViewDebugSubsection(object::SectionRef Section,
                                              StringRef Name,
                                              BinaryStreamReader &Reader) {
   StringRef SectionName, Contents;
   if (Section.getName(SectionName))
     return false;

   if (SectionName != Name)
     return false;

   if (Section.getContents(Contents))
     return false;

   Reader = BinaryStreamReader(Contents, support::little);
   uint32_t Magic;
   if (Reader.bytesRemaining() < sizeof(uint32_t))
     return false;
   cantFail(Reader.readInteger(Magic));
   if (Magic != COFF::DEBUG_SECTION_MAGIC)
     return false;
   return true;
 }

 static inline bool isDebugSSection(object::SectionRef Section,
                                    DebugSubsectionArray &Subsections) {
   BinaryStreamReader Reader;
   if (!isCodeViewDebugSubsection(Section, ".debug$S", Reader))
     return false;

   cantFail(Reader.readArray(Subsections, Reader.bytesRemaining()));
   return true;
 }

 static bool isDebugTSection(SectionRef Section, CVTypeArray &Types) {
   BinaryStreamReader Reader;
   if (!isCodeViewDebugSubsection(Section, ".debug$T", Reader) &&
       !isCodeViewDebugSubsection(Section, ".debug$P", Reader))
     return false;
   cantFail(Reader.readArray(Types, Reader.bytesRemaining()));
   return true;
 }

 static std::string formatChecksumKind(FileChecksumKind Kind) {
   switch (Kind) {
     RETURN_CASE(FileChecksumKind, None, "None");
     RETURN_CASE(FileChecksumKind, MD5, "MD5");
     RETURN_CASE(FileChecksumKind, SHA1, "SHA-1");
     RETURN_CASE(FileChecksumKind, SHA256, "SHA-256");
   }
   return formatUnknownEnum(Kind);
 }

 template <typename... Args>
 static void formatInternal(LinePrinter &Printer, bool Append, Args &&... args) {
   if (Append)
     Printer.format(std::forward<Args>(args)...);
   else
     Printer.formatLine(std::forward<Args>(args)...);
 }

 SymbolGroup::SymbolGroup(InputFile *File, uint32_t GroupIndex) : File(File) {
   if (!File)
     return;

   if (File->isPdb())
     initializeForPdb(GroupIndex);
   else {
     Name = ".debug$S";
     uint32_t I = 0;
     for (const auto &S : File->obj().sections()) {
       DebugSubsectionArray SS;
       if (!isDebugSSection(S, SS))
         continue;

       if (!SC.hasChecksums() || !SC.hasStrings())
         SC.initialize(SS);

       if (I == GroupIndex)
         Subsections = SS;

       if (SC.hasChecksums() && SC.hasStrings())
         break;
     }
     rebuildChecksumMap();
   }
 }

 StringRef SymbolGroup::name() const { return Name; }

 void SymbolGroup::updateDebugS(const codeview::DebugSubsectionArray &SS) {
   Subsections = SS;
 }

 void SymbolGroup::updatePdbModi(uint32_t Modi) { initializeForPdb(Modi); }

 void SymbolGroup::initializeForPdb(uint32_t Modi) {
   assert(File && File->isPdb());

   // PDB always uses the same string table, but each module has its own
   // checksums.  So we only set the strings if they're not already set.
   if (!SC.hasStrings()) {
     auto StringTable = File->pdb().getStringTable();
     if (StringTable)
       SC.setStrings(StringTable->getStringTable());
     else
       consumeError(StringTable.takeError());
   }

   SC.resetChecksums();
   auto MDS = getModuleDebugStream(File->pdb(), Name, Modi);
   if (!MDS) {
     consumeError(MDS.takeError());
     return;
   }

   DebugStream = std::make_shared<ModuleDebugStreamRef>(std::move(*MDS));
   Subsections = DebugStream->getSubsectionsArray();
   SC.initialize(Subsections);
   rebuildChecksumMap();
 }

 void SymbolGroup::rebuildChecksumMap() {
   if (!SC.hasChecksums())
     return;

   for (const auto &Entry : SC.checksums()) {
     auto S = SC.strings().getString(Entry.FileNameOffset);
     if (!S)
       continue;
     ChecksumsByFile[*S] = Entry;
   }
 }

 const ModuleDebugStreamRef &SymbolGroup::getPdbModuleStream() const {
   assert(File && File->isPdb() && DebugStream);
   return *DebugStream;
 }

 Expected<StringRef> SymbolGroup::getNameFromStringTable(uint32_t Offset) const {
   return SC.strings().getString(Offset);
 }

 void SymbolGroup::formatFromFileName(LinePrinter &Printer, StringRef File,
                                      bool Append) const {
   auto FC = ChecksumsByFile.find(File);
   if (FC == ChecksumsByFile.end()) {
     formatInternal(Printer, Append, "- (no checksum) {0}", File);
     return;
   }

   formatInternal(Printer, Append, "- ({0}: {1}) {2}",
                  formatChecksumKind(FC->getValue().Kind),
                  toHex(FC->getValue().Checksum), File);
 }

 void SymbolGroup::formatFromChecksumsOffset(LinePrinter &Printer,
                                             uint32_t Offset,
                                             bool Append) const {
   if (!SC.hasChecksums()) {
     formatInternal(Printer, Append, "(unknown file name offset {0})", Offset);
     return;
   }

   auto Iter = SC.checksums().getArray().at(Offset);
   if (Iter == SC.checksums().getArray().end()) {
     formatInternal(Printer, Append, "(unknown file name offset {0})", Offset);
     return;
   }

   uint32_t FO = Iter->FileNameOffset;
   auto ExpectedFile = getNameFromStringTable(FO);
   if (!ExpectedFile) {
     formatInternal(Printer, Append, "(unknown file name offset {0})", Offset);
     consumeError(ExpectedFile.takeError());
     return;
   }
   if (Iter->Kind == FileChecksumKind::None) {
     formatInternal(Printer, Append, "{0} (no checksum)", *ExpectedFile);
   } else {
     formatInternal(Printer, Append, "{0} ({1}: {2})", *ExpectedFile,
                    formatChecksumKind(Iter->Kind), toHex(Iter->Checksum));
   }
 }

 Expected<InputFile> InputFile::open(StringRef Path, bool AllowUnknownFile) {
   InputFile IF;
   if (!llvm::sys::fs::exists(Path))
     return make_error<StringError>(formatv("File {0} not found", Path),
                                    inconvertibleErrorCode());

   file_magic Magic;
   if (auto EC = identify_magic(Path, Magic))
     return make_error<StringError>(
         formatv("Unable to identify file type for file {0}", Path), EC);

   if (Magic == file_magic::coff_object) {
     Expected<OwningBinary<Binary>> BinaryOrErr = createBinary(Path);
     if (!BinaryOrErr)
       return BinaryOrErr.takeError();

     IF.CoffObject = std::move(*BinaryOrErr);
     IF.PdbOrObj = llvm::cast<COFFObjectFile>(IF.CoffObject.getBinary());
     return std::move(IF);
   }

   if (Magic == file_magic::pdb) {
     std::unique_ptr<IPDBSession> Session;
     if (auto Err = loadDataForPDB(PDB_ReaderType::Native, Path, Session))
       return std::move(Err);

     IF.PdbSession.reset(static_cast<NativeSession *>(Session.release()));
     IF.PdbOrObj = &IF.PdbSession->getPDBFile();

     return std::move(IF);
   }

   if (!AllowUnknownFile)
     return make_error<StringError>(
         formatv("File {0} is not a supported file type", Path),
         inconvertibleErrorCode());

   auto Result = MemoryBuffer::getFile(Path, -1LL, false);
   if (!Result)
     return make_error<StringError>(
         formatv("File {0} could not be opened", Path), Result.getError());

   IF.UnknownFile = std::move(*Result);
   IF.PdbOrObj = IF.UnknownFile.get();
   return std::move(IF);
 }

 PDBFile &InputFile::pdb() {
   assert(isPdb());
   return *PdbOrObj.get<PDBFile *>();
 }

 const PDBFile &InputFile::pdb() const {
   assert(isPdb());
   return *PdbOrObj.get<PDBFile *>();
 }

 object::COFFObjectFile &InputFile::obj() {
   assert(isObj());
   return *PdbOrObj.get<object::COFFObjectFile *>();
 }

 const object::COFFObjectFile &InputFile::obj() const {
   assert(isObj());
   return *PdbOrObj.get<object::COFFObjectFile *>();
 }

 MemoryBuffer &InputFile::unknown() {
   assert(isUnknown());
   return *PdbOrObj.get<MemoryBuffer *>();
 }

 const MemoryBuffer &InputFile::unknown() const {
   assert(isUnknown());
   return *PdbOrObj.get<MemoryBuffer *>();
 }

 StringRef InputFile::getFilePath() const {
   if (isPdb())
     return pdb().getFilePath();
   if (isObj())
     return obj().getFileName();
   assert(isUnknown());
   return unknown().getBufferIdentifier();
 }

 bool InputFile::hasTypes() const {
   if (isPdb())
     return pdb().hasPDBTpiStream();

   for (const auto &Section : obj().sections()) {
     CVTypeArray Types;
     if (isDebugTSection(Section, Types))
       return true;
   }
   return false;
 }

 bool InputFile::hasIds() const {
   if (isObj())
     return false;
   return pdb().hasPDBIpiStream();
 }

 bool InputFile::isPdb() const { return PdbOrObj.is<PDBFile *>(); }

 bool InputFile::isObj() const {
   return PdbOrObj.is<object::COFFObjectFile *>();
 }

 bool InputFile::isUnknown() const { return PdbOrObj.is<MemoryBuffer *>(); }

 codeview::LazyRandomTypeCollection &
 InputFile::getOrCreateTypeCollection(TypeCollectionKind Kind) {
   if (Types && Kind == kTypes)
     return *Types;
   if (Ids && Kind == kIds)
     return *Ids;

   if (Kind == kIds) {
     assert(isPdb() && pdb().hasPDBIpiStream());
   }

   // If the collection was already initialized, we should have just returned it
   // in step 1.
   if (isPdb()) {
     TypeCollectionPtr &Collection = (Kind == kIds) ? Ids : Types;
     auto &Stream = cantFail((Kind == kIds) ? pdb().getPDBIpiStream()
                                            : pdb().getPDBTpiStream());

     auto &Array = Stream.typeArray();
     uint32_t Count = Stream.getNumTypeRecords();
     auto Offsets = Stream.getTypeIndexOffsets();
     Collection =
         llvm::make_unique<LazyRandomTypeCollection>(Array, Count, Offsets);
     return *Collection;
   }

   assert(isObj());
   assert(Kind == kTypes);
   assert(!Types);

   for (const auto &Section : obj().sections()) {
     CVTypeArray Records;
     if (!isDebugTSection(Section, Records))
       continue;

     Types = llvm::make_unique<LazyRandomTypeCollection>(Records, 100);
     return *Types;
   }

   Types = llvm::make_unique<LazyRandomTypeCollection>(100);
   return *Types;
 }

 codeview::LazyRandomTypeCollection &InputFile::types() {
   return getOrCreateTypeCollection(kTypes);
 }

 codeview::LazyRandomTypeCollection &InputFile::ids() {
   // Object files have only one type stream that contains both types and ids.
   // Similarly, some PDBs don't contain an IPI stream, and for those both types
   // and IDs are in the same stream.
   if (isObj() || !pdb().hasPDBIpiStream())
     return types();

   return getOrCreateTypeCollection(kIds);
 }

 iterator_range<SymbolGroupIterator> InputFile::symbol_groups() {
   return make_range<SymbolGroupIterator>(symbol_groups_begin(),
                                          symbol_groups_end());
 }

 SymbolGroupIterator InputFile::symbol_groups_begin() {
   return SymbolGroupIterator(*this);
 }

 SymbolGroupIterator InputFile::symbol_groups_end() {
   return SymbolGroupIterator();
 }

 SymbolGroupIterator::SymbolGroupIterator() : Value(nullptr) {}

 SymbolGroupIterator::SymbolGroupIterator(InputFile &File) : Value(&File) {
   if (File.isObj()) {
     SectionIter = File.obj().section_begin();
     scanToNextDebugS();
   }
 }

 bool SymbolGroupIterator::operator==(const SymbolGroupIterator &R) const {
   bool E = isEnd();
   bool RE = R.isEnd();
   if (E || RE)
     return E == RE;

   if (Value.File != R.Value.File)
     return false;
   return Index == R.Index;
 }

 const SymbolGroup &SymbolGroupIterator::operator*() const {
   assert(!isEnd());
   return Value;
 }
 SymbolGroup &SymbolGroupIterator::operator*() {
   assert(!isEnd());
   return Value;
 }

 SymbolGroupIterator &SymbolGroupIterator::operator++() {
   assert(Value.File && !isEnd());
   ++Index;
   if (isEnd())
     return *this;

   if (Value.File->isPdb()) {
     Value.updatePdbModi(Index);
     return *this;
   }

   scanToNextDebugS();
   return *this;
 }

 void SymbolGroupIterator::scanToNextDebugS() {
   assert(SectionIter.hasValue());
   auto End = Value.File->obj().section_end();
   auto &Iter = *SectionIter;
   assert(!isEnd());

   while (++Iter != End) {
     DebugSubsectionArray SS;
     SectionRef SR = *Iter;
     if (!isDebugSSection(SR, SS))
       continue;

     Value.updateDebugS(SS);
     return;
   }
 }

 bool SymbolGroupIterator::isEnd() const {
   if (!Value.File)
     return true;
   if (Value.File->isPdb()) {
     auto &Dbi = cantFail(Value.File->pdb().getPDBDbiStream());
     uint32_t Count = Dbi.modules().getModuleCount();
     assert(Index <= Count);
     return Index == Count;
   }

   assert(SectionIter.hasValue());
   return *SectionIter == Value.File->obj().section_end();
 }
	//===- InputFile.cpp ------------------------------------------ - C++ ---===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	#include "InputFile.h"

	#include "FormatUtil.h"
	#include "LinePrinter.h"

	#include "llvm/BinaryFormat/Magic.h"
	#include "llvm/DebugInfo/CodeView/CodeView.h"
	#include "llvm/DebugInfo/CodeView/LazyRandomTypeCollection.h"
	#include "llvm/DebugInfo/CodeView/StringsAndChecksums.h"
	#include "llvm/DebugInfo/PDB/Native/DbiStream.h"
	#include "llvm/DebugInfo/PDB/Native/NativeSession.h"
	#include "llvm/DebugInfo/PDB/Native/PDBFile.h"
	#include "llvm/DebugInfo/PDB/Native/PDBStringTable.h"
	#include "llvm/DebugInfo/PDB/Native/RawError.h"
	#include "llvm/DebugInfo/PDB/Native/TpiStream.h"
	#include "llvm/DebugInfo/PDB/PDB.h"
	#include "llvm/Object/COFF.h"
	#include "llvm/Support/FileSystem.h"
	#include "llvm/Support/FormatVariadic.h"

	using namespace llvm;
	using namespace llvm::codeview;
	using namespace llvm::object;
	using namespace llvm::pdb;

	InputFile::InputFile() {}
	InputFile::~InputFile() {}

	static Expected<ModuleDebugStreamRef>
	getModuleDebugStream(PDBFile &File, StringRef &ModuleName, uint32_t Index) {
	ExitOnError Err("Unexpected error: ");

	auto &Dbi = Err(File.getPDBDbiStream());
	const auto &Modules = Dbi.modules();
	if (Index >= Modules.getModuleCount())
	return make_error<RawError>(raw_error_code::index_out_of_bounds,
	"Invalid module index");

	auto Modi = Modules.getModuleDescriptor(Index);

	ModuleName = Modi.getModuleName();

	uint16_t ModiStream = Modi.getModuleStreamIndex();
	if (ModiStream == kInvalidStreamIndex)
	return make_error<RawError>(raw_error_code::no_stream,
	"Module stream not present");

	auto ModStreamData = File.createIndexedStream(ModiStream);

	ModuleDebugStreamRef ModS(Modi, std::move(ModStreamData));
	if (auto EC = ModS.reload())
	return make_error<RawError>(raw_error_code::corrupt_file,
	"Invalid module stream");

	return std::move(ModS);
	}

	static inline bool isCodeViewDebugSubsection(object::SectionRef Section,
	StringRef Name,
	BinaryStreamReader &Reader) {
	StringRef SectionName, Contents;
	if (Section.getName(SectionName))
	return false;

	if (SectionName != Name)
	return false;

	if (Section.getContents(Contents))
	return false;

	Reader = BinaryStreamReader(Contents, support::little);
	uint32_t Magic;
	if (Reader.bytesRemaining() < sizeof(uint32_t))
	return false;
	cantFail(Reader.readInteger(Magic));
	if (Magic != COFF::DEBUG_SECTION_MAGIC)
	return false;
	return true;
	}

	static inline bool isDebugSSection(object::SectionRef Section,
	DebugSubsectionArray &Subsections) {
	BinaryStreamReader Reader;
	if (!isCodeViewDebugSubsection(Section, ".debug$S", Reader))
	return false;

	cantFail(Reader.readArray(Subsections, Reader.bytesRemaining()));
	return true;
	}

	static bool isDebugTSection(SectionRef Section, CVTypeArray &Types) {
	BinaryStreamReader Reader;
	if (!isCodeViewDebugSubsection(Section, ".debug$T", Reader) &&
	!isCodeViewDebugSubsection(Section, ".debug$P", Reader))
	return false;
	cantFail(Reader.readArray(Types, Reader.bytesRemaining()));
	return true;
	}

	static std::string formatChecksumKind(FileChecksumKind Kind) {
	switch (Kind) {
	RETURN_CASE(FileChecksumKind, None, "None");
	RETURN_CASE(FileChecksumKind, MD5, "MD5");
	RETURN_CASE(FileChecksumKind, SHA1, "SHA-1");
	RETURN_CASE(FileChecksumKind, SHA256, "SHA-256");
	}
	return formatUnknownEnum(Kind);
	}

	template <typename... Args>
	static void formatInternal(LinePrinter &Printer, bool Append, Args &&... args) {
	if (Append)
	Printer.format(std::forward<Args>(args)...);
	else
	Printer.formatLine(std::forward<Args>(args)...);
	}

	SymbolGroup::SymbolGroup(InputFile *File, uint32_t GroupIndex) : File(File) {
	if (!File)
	return;

	if (File->isPdb())
	initializeForPdb(GroupIndex);
	else {
	Name = ".debug$S";
	uint32_t I = 0;
	for (const auto &S : File->obj().sections()) {
	DebugSubsectionArray SS;
	if (!isDebugSSection(S, SS))
	continue;

	if (!SC.hasChecksums() \|\| !SC.hasStrings())
	SC.initialize(SS);

	if (I == GroupIndex)
	Subsections = SS;

	if (SC.hasChecksums() && SC.hasStrings())
	break;
	}
	rebuildChecksumMap();
	}
	}

	StringRef SymbolGroup::name() const { return Name; }

	void SymbolGroup::updateDebugS(const codeview::DebugSubsectionArray &SS) {
	Subsections = SS;
	}

	void SymbolGroup::updatePdbModi(uint32_t Modi) { initializeForPdb(Modi); }

	void SymbolGroup::initializeForPdb(uint32_t Modi) {
	assert(File && File->isPdb());

	// PDB always uses the same string table, but each module has its own
	// checksums. So we only set the strings if they're not already set.
	if (!SC.hasStrings()) {
	auto StringTable = File->pdb().getStringTable();
	if (StringTable)
	SC.setStrings(StringTable->getStringTable());
	else
	consumeError(StringTable.takeError());
	}

	SC.resetChecksums();
	auto MDS = getModuleDebugStream(File->pdb(), Name, Modi);
	if (!MDS) {
	consumeError(MDS.takeError());
	return;
	}

	DebugStream = std::make_shared<ModuleDebugStreamRef>(std::move(*MDS));
	Subsections = DebugStream->getSubsectionsArray();
	SC.initialize(Subsections);
	rebuildChecksumMap();
	}

	void SymbolGroup::rebuildChecksumMap() {
	if (!SC.hasChecksums())
	return;

	for (const auto &Entry : SC.checksums()) {
	auto S = SC.strings().getString(Entry.FileNameOffset);
	if (!S)
	continue;
	ChecksumsByFile[*S] = Entry;
	}
	}

	const ModuleDebugStreamRef &SymbolGroup::getPdbModuleStream() const {
	assert(File && File->isPdb() && DebugStream);
	return *DebugStream;
	}

	Expected<StringRef> SymbolGroup::getNameFromStringTable(uint32_t Offset) const {
	return SC.strings().getString(Offset);
	}

	void SymbolGroup::formatFromFileName(LinePrinter &Printer, StringRef File,
	bool Append) const {
	auto FC = ChecksumsByFile.find(File);
	if (FC == ChecksumsByFile.end()) {
	formatInternal(Printer, Append, "- (no checksum) {0}", File);
	return;
	}

	formatInternal(Printer, Append, "- ({0}: {1}) {2}",
	formatChecksumKind(FC->getValue().Kind),
	toHex(FC->getValue().Checksum), File);
	}

	void SymbolGroup::formatFromChecksumsOffset(LinePrinter &Printer,
	uint32_t Offset,
	bool Append) const {
	if (!SC.hasChecksums()) {
	formatInternal(Printer, Append, "(unknown file name offset {0})", Offset);
	return;
	}

	auto Iter = SC.checksums().getArray().at(Offset);
	if (Iter == SC.checksums().getArray().end()) {
	formatInternal(Printer, Append, "(unknown file name offset {0})", Offset);
	return;
	}

	uint32_t FO = Iter->FileNameOffset;
	auto ExpectedFile = getNameFromStringTable(FO);
	if (!ExpectedFile) {
	formatInternal(Printer, Append, "(unknown file name offset {0})", Offset);
	consumeError(ExpectedFile.takeError());
	return;
	}
	if (Iter->Kind == FileChecksumKind::None) {
	formatInternal(Printer, Append, "{0} (no checksum)", *ExpectedFile);
	} else {
	formatInternal(Printer, Append, "{0} ({1}: {2})", *ExpectedFile,
	formatChecksumKind(Iter->Kind), toHex(Iter->Checksum));
	}
	}

	Expected<InputFile> InputFile::open(StringRef Path, bool AllowUnknownFile) {
	InputFile IF;
	if (!llvm::sys::fs::exists(Path))
	return make_error<StringError>(formatv("File {0} not found", Path),
	inconvertibleErrorCode());

	file_magic Magic;
	if (auto EC = identify_magic(Path, Magic))
	return make_error<StringError>(
	formatv("Unable to identify file type for file {0}", Path), EC);

	if (Magic == file_magic::coff_object) {
	Expected<OwningBinary<Binary>> BinaryOrErr = createBinary(Path);
	if (!BinaryOrErr)
	return BinaryOrErr.takeError();

	IF.CoffObject = std::move(*BinaryOrErr);
	IF.PdbOrObj = llvm::cast<COFFObjectFile>(IF.CoffObject.getBinary());
	return std::move(IF);
	}

	if (Magic == file_magic::pdb) {
	std::unique_ptr<IPDBSession> Session;
	if (auto Err = loadDataForPDB(PDB_ReaderType::Native, Path, Session))
	return std::move(Err);

	IF.PdbSession.reset(static_cast<NativeSession *>(Session.release()));
	IF.PdbOrObj = &IF.PdbSession->getPDBFile();

	return std::move(IF);
	}

	if (!AllowUnknownFile)
	return make_error<StringError>(
	formatv("File {0} is not a supported file type", Path),
	inconvertibleErrorCode());

	auto Result = MemoryBuffer::getFile(Path, -1LL, false);
	if (!Result)
	return make_error<StringError>(
	formatv("File {0} could not be opened", Path), Result.getError());

	IF.UnknownFile = std::move(*Result);
	IF.PdbOrObj = IF.UnknownFile.get();
	return std::move(IF);
	}

	PDBFile &InputFile::pdb() {
	assert(isPdb());
	return PdbOrObj.get<PDBFile >();
	}

	const PDBFile &InputFile::pdb() const {
	assert(isPdb());
	return PdbOrObj.get<PDBFile >();
	}

	object::COFFObjectFile &InputFile::obj() {
	assert(isObj());
	return PdbOrObj.get<object::COFFObjectFile >();
	}

	const object::COFFObjectFile &InputFile::obj() const {
	assert(isObj());
	return PdbOrObj.get<object::COFFObjectFile >();
	}

	MemoryBuffer &InputFile::unknown() {
	assert(isUnknown());
	return PdbOrObj.get<MemoryBuffer >();
	}

	const MemoryBuffer &InputFile::unknown() const {
	assert(isUnknown());
	return PdbOrObj.get<MemoryBuffer >();
	}

	StringRef InputFile::getFilePath() const {
	if (isPdb())
	return pdb().getFilePath();
	if (isObj())
	return obj().getFileName();
	assert(isUnknown());
	return unknown().getBufferIdentifier();
	}

	bool InputFile::hasTypes() const {
	if (isPdb())
	return pdb().hasPDBTpiStream();

	for (const auto &Section : obj().sections()) {
	CVTypeArray Types;
	if (isDebugTSection(Section, Types))
	return true;
	}
	return false;
	}

	bool InputFile::hasIds() const {
	if (isObj())
	return false;
	return pdb().hasPDBIpiStream();
	}

	bool InputFile::isPdb() const { return PdbOrObj.is<PDBFile *>(); }

	bool InputFile::isObj() const {
	return PdbOrObj.is<object::COFFObjectFile *>();
	}

	bool InputFile::isUnknown() const { return PdbOrObj.is<MemoryBuffer *>(); }

	codeview::LazyRandomTypeCollection &
	InputFile::getOrCreateTypeCollection(TypeCollectionKind Kind) {
	if (Types && Kind == kTypes)
	return *Types;
	if (Ids && Kind == kIds)
	return *Ids;

	if (Kind == kIds) {
	assert(isPdb() && pdb().hasPDBIpiStream());
	}

	// If the collection was already initialized, we should have just returned it
	// in step 1.
	if (isPdb()) {
	TypeCollectionPtr &Collection = (Kind == kIds) ? Ids : Types;
	auto &Stream = cantFail((Kind == kIds) ? pdb().getPDBIpiStream()
	: pdb().getPDBTpiStream());

	auto &Array = Stream.typeArray();
	uint32_t Count = Stream.getNumTypeRecords();
	auto Offsets = Stream.getTypeIndexOffsets();
	Collection =
	llvm::make_unique<LazyRandomTypeCollection>(Array, Count, Offsets);
	return *Collection;
	}

	assert(isObj());
	assert(Kind == kTypes);
	assert(!Types);

	for (const auto &Section : obj().sections()) {
	CVTypeArray Records;
	if (!isDebugTSection(Section, Records))
	continue;

	Types = llvm::make_unique<LazyRandomTypeCollection>(Records, 100);
	return *Types;
	}

	Types = llvm::make_unique<LazyRandomTypeCollection>(100);
	return *Types;
	}

	codeview::LazyRandomTypeCollection &InputFile::types() {
	return getOrCreateTypeCollection(kTypes);
	}

	codeview::LazyRandomTypeCollection &InputFile::ids() {
	// Object files have only one type stream that contains both types and ids.
	// Similarly, some PDBs don't contain an IPI stream, and for those both types
	// and IDs are in the same stream.
	if (isObj() \|\| !pdb().hasPDBIpiStream())
	return types();

	return getOrCreateTypeCollection(kIds);
	}

	iterator_range<SymbolGroupIterator> InputFile::symbol_groups() {
	return make_range<SymbolGroupIterator>(symbol_groups_begin(),
	symbol_groups_end());
	}

	SymbolGroupIterator InputFile::symbol_groups_begin() {
	return SymbolGroupIterator(*this);
	}

	SymbolGroupIterator InputFile::symbol_groups_end() {
	return SymbolGroupIterator();
	}

	SymbolGroupIterator::SymbolGroupIterator() : Value(nullptr) {}

	SymbolGroupIterator::SymbolGroupIterator(InputFile &File) : Value(&File) {
	if (File.isObj()) {
	SectionIter = File.obj().section_begin();
	scanToNextDebugS();
	}
	}

	bool SymbolGroupIterator::operator==(const SymbolGroupIterator &R) const {
	bool E = isEnd();
	bool RE = R.isEnd();
	if (E \|\| RE)
	return E == RE;

	if (Value.File != R.Value.File)
	return false;
	return Index == R.Index;
	}

	const SymbolGroup &SymbolGroupIterator::operator*() const {
	assert(!isEnd());
	return Value;
	}
	SymbolGroup &SymbolGroupIterator::operator*() {
	assert(!isEnd());
	return Value;
	}

	SymbolGroupIterator &SymbolGroupIterator::operator++() {
	assert(Value.File && !isEnd());
	++Index;
	if (isEnd())
	return *this;

	if (Value.File->isPdb()) {
	Value.updatePdbModi(Index);
	return *this;
	}

	scanToNextDebugS();
	return *this;
	}

	void SymbolGroupIterator::scanToNextDebugS() {
	assert(SectionIter.hasValue());
	auto End = Value.File->obj().section_end();
	auto &Iter = *SectionIter;
	assert(!isEnd());

	while (++Iter != End) {
	DebugSubsectionArray SS;
	SectionRef SR = *Iter;
	if (!isDebugSSection(SR, SS))
	continue;

	Value.updateDebugS(SS);
	return;
	}
	}

	bool SymbolGroupIterator::isEnd() const {
	if (!Value.File)
	return true;
	if (Value.File->isPdb()) {
	auto &Dbi = cantFail(Value.File->pdb().getPDBDbiStream());
	uint32_t Count = Dbi.modules().getModuleCount();
	assert(Index <= Count);
	return Index == Count;
	}

	assert(SectionIter.hasValue());
	return *SectionIter == Value.File->obj().section_end();
	}