BitcodeReader.cpp

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//===- BitcodeReader.cpp - Internal BitcodeReader implementation ----------===//
//
// 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
//
//===----------------------------------------------------------------------===//
 
#include "llvm/Bitcode/BitcodeReader.h"
#include "MetadataLoader.h"
#include "ValueList.h"
#include "llvm/ADT/APFloat.h"
#include "llvm/ADT/APInt.h"
#include "llvm/ADT/ArrayRef.h"
#include "llvm/ADT/DenseMap.h"
#include "llvm/ADT/STLExtras.h"
#include "llvm/ADT/SmallString.h"
#include "llvm/ADT/SmallVector.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/ADT/Twine.h"
#include "llvm/Bitcode/BitcodeCommon.h"
#include "llvm/Bitcode/LLVMBitCodes.h"
#include "llvm/Bitstream/BitstreamReader.h"
#include "llvm/Config/llvm-config.h"
#include "llvm/IR/Argument.h"
#include "llvm/IR/AttributeMask.h"
#include "llvm/IR/Attributes.h"
#include "llvm/IR/AutoUpgrade.h"
#include "llvm/IR/BasicBlock.h"
#include "llvm/IR/CallingConv.h"
#include "llvm/IR/Comdat.h"
#include "llvm/IR/Constant.h"
#include "llvm/IR/ConstantRangeList.h"
#include "llvm/IR/Constants.h"
#include "llvm/IR/DataLayout.h"
#include "llvm/IR/DebugInfo.h"
#include "llvm/IR/DebugInfoMetadata.h"
#include "llvm/IR/DebugLoc.h"
#include "llvm/IR/DerivedTypes.h"
#include "llvm/IR/Function.h"
#include "llvm/IR/GVMaterializer.h"
#include "llvm/IR/GetElementPtrTypeIterator.h"
#include "llvm/IR/GlobalAlias.h"
#include "llvm/IR/GlobalIFunc.h"
#include "llvm/IR/GlobalObject.h"
#include "llvm/IR/GlobalValue.h"
#include "llvm/IR/GlobalVariable.h"
#include "llvm/IR/InlineAsm.h"
#include "llvm/IR/InstIterator.h"
#include "llvm/IR/InstrTypes.h"
#include "llvm/IR/Instruction.h"
#include "llvm/IR/Instructions.h"
#include "llvm/IR/Intrinsics.h"
#include "llvm/IR/IntrinsicsAArch64.h"
#include "llvm/IR/IntrinsicsARM.h"
#include "llvm/IR/LLVMContext.h"
#include "llvm/IR/Metadata.h"
#include "llvm/IR/Module.h"
#include "llvm/IR/ModuleSummaryIndex.h"
#include "llvm/IR/Operator.h"
#include "llvm/IR/ProfDataUtils.h"
#include "llvm/IR/Type.h"
#include "llvm/IR/Value.h"
#include "llvm/IR/Verifier.h"
#include "llvm/Support/AtomicOrdering.h"
#include "llvm/Support/Casting.h"
#include "llvm/Support/CommandLine.h"
#include "llvm/Support/Compiler.h"
#include "llvm/Support/Debug.h"
#include "llvm/Support/Error.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/Support/ErrorOr.h"
#include "llvm/Support/MathExtras.h"
#include "llvm/Support/MemoryBuffer.h"
#include "llvm/Support/ModRef.h"
#include "llvm/Support/raw_ostream.h"
#include "llvm/TargetParser/Triple.h"
#include <algorithm>
#include <cassert>
#include <cstddef>
#include <cstdint>
#include <deque>
#include <map>
#include <memory>
#include <optional>
#include <string>
#include <system_error>
#include <tuple>
#include <utility>
#include <vector>
 
using namespace llvm;
 
static cl::opt<bool> PrintSummaryGUIDs(
    "print-summary-global-ids", cl::init(false), cl::Hidden,
    cl::desc(
        "Print the global id for each value when reading the module summary"));
 
static cl::opt<bool> ExpandConstantExprs(
    "expand-constant-exprs", cl::Hidden,
    cl::desc(
        "Expand constant expressions to instructions for testing purposes"));
 
namespace {
 
enum {
  SWITCH_INST_MAGIC = 0x4B5 // May 2012 => 1205 => Hex
};
 
} // end anonymous namespace
 
static Error error(const Twine &Message) {
  return make_error<StringError>(
      Message, make_error_code(BitcodeError::CorruptedBitcode));
}
 
static Error hasInvalidBitcodeHeader(BitstreamCursor &Stream) {
  if (!Stream.canSkipToPos(4))
    return createStringError(std::errc::illegal_byte_sequence,
                             "file too small to contain bitcode header");
  for (unsigned C : {'B', 'C'})
    if (Expected<SimpleBitstreamCursor::word_t> Res = Stream.Read(8)) {
      if (Res.get() != C)
        return createStringError(std::errc::illegal_byte_sequence,
                                 "file doesn't start with bitcode header");
    } else
      return Res.takeError();
  for (unsigned C : {0x0, 0xC, 0xE, 0xD})
    if (Expected<SimpleBitstreamCursor::word_t> Res = Stream.Read(4)) {
      if (Res.get() != C)
        return createStringError(std::errc::illegal_byte_sequence,
                                 "file doesn't start with bitcode header");
    } else
      return Res.takeError();
  return Error::success();
}
 
static Expected<BitstreamCursor> initStream(MemoryBufferRef Buffer) {
  const unsigned char *BufPtr = (const unsigned char *)Buffer.getBufferStart();
  const unsigned char *BufEnd = BufPtr + Buffer.getBufferSize();
 
  if (Buffer.getBufferSize() & 3)
    return error("Invalid bitcode signature");
 
  // If we have a wrapper header, parse it and ignore the non-bc file contents.
  // The magic number is 0x0B17C0DE stored in little endian.
  if (isBitcodeWrapper(BufPtr, BufEnd))
    if (SkipBitcodeWrapperHeader(BufPtr, BufEnd, true))
      return error("Invalid bitcode wrapper header");
 
  BitstreamCursor Stream(ArrayRef<uint8_t>(BufPtr, BufEnd));
  if (Error Err = hasInvalidBitcodeHeader(Stream))
    return std::move(Err);
 
  return std::move(Stream);
}
 
/// Convert a string from a record into an std::string, return true on failure.
template <typename StrTy>
static bool convertToString(ArrayRef<uint64_t> Record, unsigned Idx,
                            StrTy &Result) {
  if (Idx > Record.size())
    return true;
 
  Result.append(Record.begin() + Idx, Record.end());
  return false;
}
 
// Strip all the TBAA attachment for the module.
static void stripTBAA(Module *M) {
  for (auto &F : *M) {
    if (F.isMaterializable())
      continue;
    for (auto &I : instructions(F))
      I.setMetadata(LLVMContext::MD_tbaa, nullptr);
  }
}
 
/// Read the "IDENTIFICATION_BLOCK_ID" block, do some basic enforcement on the
/// "epoch" encoded in the bitcode, and return the producer name if any.
static Expected<std::string> readIdentificationBlock(BitstreamCursor &Stream) {
  if (Error Err = Stream.EnterSubBlock(bitc::IDENTIFICATION_BLOCK_ID))
    return std::move(Err);
 
  // Read all the records.
  SmallVector<uint64_t, 64> Record;
 
  std::string ProducerIdentification;
 
  while (true) {
    BitstreamEntry Entry;
    if (Error E = Stream.advance().moveInto(Entry))
      return std::move(E);
 
    switch (Entry.Kind) {
    default:
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock:
      return ProducerIdentification;
    case BitstreamEntry::Record:
      // The interesting case.
      break;
    }
 
    // Read a record.
    Record.clear();
    Expected<unsigned> MaybeBitCode = Stream.readRecord(Entry.ID, Record);
    if (!MaybeBitCode)
      return MaybeBitCode.takeError();
    switch (MaybeBitCode.get()) {
    default: // Default behavior: reject
      return error("Invalid value");
    case bitc::IDENTIFICATION_CODE_STRING: // IDENTIFICATION: [strchr x N]
      convertToString(Record, 0, ProducerIdentification);
      break;
    case bitc::IDENTIFICATION_CODE_EPOCH: { // EPOCH: [epoch#]
      unsigned epoch = (unsigned)Record[0];
      if (epoch != bitc::BITCODE_CURRENT_EPOCH) {
        return error(
          Twine("Incompatible epoch: Bitcode '") + Twine(epoch) +
          "' vs current: '" + Twine(bitc::BITCODE_CURRENT_EPOCH) + "'");
      }
    }
    }
  }
}
 
static Expected<std::string> readIdentificationCode(BitstreamCursor &Stream) {
  // We expect a number of well-defined blocks, though we don't necessarily
  // need to understand them all.
  while (true) {
    if (Stream.AtEndOfStream())
      return "";
 
    BitstreamEntry Entry;
    if (Error E = Stream.advance().moveInto(Entry))
      return std::move(E);
 
    switch (Entry.Kind) {
    case BitstreamEntry::EndBlock:
    case BitstreamEntry::Error:
      return error("Malformed block");
 
    case BitstreamEntry::SubBlock:
      if (Entry.ID == bitc::IDENTIFICATION_BLOCK_ID)
        return readIdentificationBlock(Stream);
 
      // Ignore other sub-blocks.
      if (Error Err = Stream.SkipBlock())
        return std::move(Err);
      continue;
    case BitstreamEntry::Record:
      if (Error E = Stream.skipRecord(Entry.ID).takeError())
        return std::move(E);
      continue;
    }
  }
}
 
static Expected<bool> hasObjCCategoryInModule(BitstreamCursor &Stream) {
  if (Error Err = Stream.EnterSubBlock(bitc::MODULE_BLOCK_ID))
    return std::move(Err);
 
  SmallVector<uint64_t, 64> Record;
  // Read all the records for this module.
 
  while (true) {
    Expected<BitstreamEntry> MaybeEntry = Stream.advanceSkippingSubblocks();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    BitstreamEntry Entry = MaybeEntry.get();
 
    switch (Entry.Kind) {
    case BitstreamEntry::SubBlock: // Handled for us already.
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock:
      return false;
    case BitstreamEntry::Record:
      // The interesting case.
      break;
    }
 
    // Read a record.
    Expected<unsigned> MaybeRecord = Stream.readRecord(Entry.ID, Record);
    if (!MaybeRecord)
      return MaybeRecord.takeError();
    switch (MaybeRecord.get()) {
    default:
      break; // Default behavior, ignore unknown content.
    case bitc::MODULE_CODE_SECTIONNAME: { // SECTIONNAME: [strchr x N]
      std::string S;
      if (convertToString(Record, 0, S))
        return error("Invalid section name record");
 
      // Check for the i386 and other (x86_64, ARM) conventions
 
      auto [Segment, Section] = StringRef(S).split(",");
      Segment = Segment.trim();
      Section = Section.trim();
 
      if (Segment == "__DATA" && Section.starts_with("__objc_catlist"))
        return true;
      if (Segment == "__OBJC" && Section.starts_with("__category"))
        return true;
      if (Segment == "__TEXT" && Section.starts_with("__swift"))
        return true;
      break;
    }
    }
    Record.clear();
  }
  llvm_unreachable("Exit infinite loop");
}
 
static Expected<bool> hasObjCCategory(BitstreamCursor &Stream) {
  // We expect a number of well-defined blocks, though we don't necessarily
  // need to understand them all.
  while (true) {
    BitstreamEntry Entry;
    if (Error E = Stream.advance().moveInto(Entry))
      return std::move(E);
 
    switch (Entry.Kind) {
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock:
      return false;
 
    case BitstreamEntry::SubBlock:
      if (Entry.ID == bitc::MODULE_BLOCK_ID)
        return hasObjCCategoryInModule(Stream);
 
      // Ignore other sub-blocks.
      if (Error Err = Stream.SkipBlock())
        return std::move(Err);
      continue;
 
    case BitstreamEntry::Record:
      if (Error E = Stream.skipRecord(Entry.ID).takeError())
        return std::move(E);
      continue;
    }
  }
}
 
static Expected<std::string> readModuleTriple(BitstreamCursor &Stream) {
  if (Error Err = Stream.EnterSubBlock(bitc::MODULE_BLOCK_ID))
    return std::move(Err);
 
  SmallVector<uint64_t, 64> Record;
 
  std::string Triple;
 
  // Read all the records for this module.
  while (true) {
    Expected<BitstreamEntry> MaybeEntry = Stream.advanceSkippingSubblocks();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    BitstreamEntry Entry = MaybeEntry.get();
 
    switch (Entry.Kind) {
    case BitstreamEntry::SubBlock: // Handled for us already.
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock:
      return Triple;
    case BitstreamEntry::Record:
      // The interesting case.
      break;
    }
 
    // Read a record.
    Expected<unsigned> MaybeRecord = Stream.readRecord(Entry.ID, Record);
    if (!MaybeRecord)
      return MaybeRecord.takeError();
    switch (MaybeRecord.get()) {
    default: break;  // Default behavior, ignore unknown content.
    case bitc::MODULE_CODE_TRIPLE: {  // TRIPLE: [strchr x N]
      std::string S;
      if (convertToString(Record, 0, S))
        return error("Invalid triple record");
      Triple = S;
      break;
    }
    }
    Record.clear();
  }
  llvm_unreachable("Exit infinite loop");
}
 
static Expected<std::string> readTriple(BitstreamCursor &Stream) {
  // We expect a number of well-defined blocks, though we don't necessarily
  // need to understand them all.
  while (true) {
    Expected<BitstreamEntry> MaybeEntry = Stream.advance();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    BitstreamEntry Entry = MaybeEntry.get();
 
    switch (Entry.Kind) {
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock:
      return "";
 
    case BitstreamEntry::SubBlock:
      if (Entry.ID == bitc::MODULE_BLOCK_ID)
        return readModuleTriple(Stream);
 
      // Ignore other sub-blocks.
      if (Error Err = Stream.SkipBlock())
        return std::move(Err);
      continue;
 
    case BitstreamEntry::Record:
      if (llvm::Expected<unsigned> Skipped = Stream.skipRecord(Entry.ID))
        continue;
      else
        return Skipped.takeError();
    }
  }
}
 
namespace {
 
class BitcodeReaderBase {
protected:
  BitcodeReaderBase(BitstreamCursor Stream, StringRef Strtab)
      : Stream(std::move(Stream)), Strtab(Strtab) {
    this->Stream.setBlockInfo(&BlockInfo);
  }
 
  BitstreamBlockInfo BlockInfo;
  BitstreamCursor Stream;
  StringRef Strtab;
 
  /// In version 2 of the bitcode we store names of global values and comdats in
  /// a string table rather than in the VST.
  bool UseStrtab = false;
 
  Expected<unsigned> parseVersionRecord(ArrayRef<uint64_t> Record);
 
  /// If this module uses a string table, pop the reference to the string table
  /// and return the referenced string and the rest of the record. Otherwise
  /// just return the record itself.
  std::pair<StringRef, ArrayRef<uint64_t>>
  readNameFromStrtab(ArrayRef<uint64_t> Record);
 
  Error readBlockInfo();
 
  // Contains an arbitrary and optional string identifying the bitcode producer
  std::string ProducerIdentification;
 
  Error error(const Twine &Message);
};
 
} // end anonymous namespace
 
Error BitcodeReaderBase::error(const Twine &Message) {
  std::string FullMsg = Message.str();
  if (!ProducerIdentification.empty())
    FullMsg += " (Producer: '" + ProducerIdentification + "' Reader: 'LLVM " +
               LLVM_VERSION_STRING "')";
  return ::error(FullMsg);
}
 
Expected<unsigned>
BitcodeReaderBase::parseVersionRecord(ArrayRef<uint64_t> Record) {
  if (Record.empty())
    return error("Invalid version record");
  unsigned ModuleVersion = Record[0];
  if (ModuleVersion > 2)
    return error("Invalid value");
  UseStrtab = ModuleVersion >= 2;
  return ModuleVersion;
}
 
std::pair<StringRef, ArrayRef<uint64_t>>
BitcodeReaderBase::readNameFromStrtab(ArrayRef<uint64_t> Record) {
  if (!UseStrtab)
    return {"", Record};
  // Invalid reference. Let the caller complain about the record being empty.
  if (Record[0] + Record[1] > Strtab.size())
    return {"", {}};
  return {StringRef(Strtab.data() + Record[0], Record[1]), Record.slice(2)};
}
 
namespace {
 
/// This represents a constant expression or constant aggregate using a custom
/// structure internal to the bitcode reader. Later, this structure will be
/// expanded by materializeValue() either into a constant expression/aggregate,
/// or into an instruction sequence at the point of use. This allows us to
/// upgrade bitcode using constant expressions even if this kind of constant
/// expression is no longer supported.
class BitcodeConstant final : public Value,
                              TrailingObjects<BitcodeConstant, unsigned> {
  friend TrailingObjects;
 
  // Value subclass ID: Pick largest possible value to avoid any clashes.
  static constexpr uint8_t SubclassID = 255;
 
public:
  // Opcodes used for non-expressions. This includes constant aggregates
  // (struct, array, vector) that might need expansion, as well as non-leaf
  // constants that don't need expansion (no_cfi, dso_local, blockaddress),
  // but still go through BitcodeConstant to avoid different uselist orders
  // between the two cases.
  static constexpr uint8_t ConstantStructOpcode = 255;
  static constexpr uint8_t ConstantArrayOpcode = 254;
  static constexpr uint8_t ConstantVectorOpcode = 253;
  static constexpr uint8_t NoCFIOpcode = 252;
  static constexpr uint8_t DSOLocalEquivalentOpcode = 251;
  static constexpr uint8_t BlockAddressOpcode = 250;
  static constexpr uint8_t ConstantPtrAuthOpcode = 249;
  static constexpr uint8_t FirstSpecialOpcode = ConstantPtrAuthOpcode;
 
  // Separate struct to make passing different number of parameters to
  // BitcodeConstant::create() more convenient.
  struct ExtraInfo {
    uint8_t Opcode;
    uint8_t Flags;
    unsigned BlockAddressBB = 0;
    Type *SrcElemTy = nullptr;
    std::optional<ConstantRange> InRange;
 
    ExtraInfo(uint8_t Opcode, uint8_t Flags = 0, Type *SrcElemTy = nullptr,
              std::optional<ConstantRange> InRange = std::nullopt)
        : Opcode(Opcode), Flags(Flags), SrcElemTy(SrcElemTy),
          InRange(std::move(InRange)) {}
 
    ExtraInfo(uint8_t Opcode, uint8_t Flags, unsigned BlockAddressBB)
        : Opcode(Opcode), Flags(Flags), BlockAddressBB(BlockAddressBB) {}
  };
 
  uint8_t Opcode;
  uint8_t Flags;
  unsigned NumOperands;
  unsigned BlockAddressBB;
  Type *SrcElemTy; // GEP source element type.
  std::optional<ConstantRange> InRange; // GEP inrange attribute.
 
private:
  BitcodeConstant(Type *Ty, const ExtraInfo &Info, ArrayRef<unsigned> OpIDs)
      : Value(Ty, SubclassID), Opcode(Info.Opcode), Flags(Info.Flags),
        NumOperands(OpIDs.size()), BlockAddressBB(Info.BlockAddressBB),
        SrcElemTy(Info.SrcElemTy), InRange(Info.InRange) {
    llvm::uninitialized_copy(OpIDs, getTrailingObjects());
  }
 
  BitcodeConstant &operator=(const BitcodeConstant &) = delete;
 
public:
  static BitcodeConstant *create(BumpPtrAllocator &A, Type *Ty,
                                 const ExtraInfo &Info,
                                 ArrayRef<unsigned> OpIDs) {
    void *Mem = A.Allocate(totalSizeToAlloc<unsigned>(OpIDs.size()),
                           alignof(BitcodeConstant));
    return new (Mem) BitcodeConstant(Ty, Info, OpIDs);
  }
 
  static bool classof(const Value *V) { return V->getValueID() == SubclassID; }
 
  ArrayRef<unsigned> getOperandIDs() const {
    return ArrayRef(getTrailingObjects(), NumOperands);
  }
 
  std::optional<ConstantRange> getInRange() const {
    assert(Opcode == Instruction::GetElementPtr);
    return InRange;
  }
 
  const char *getOpcodeName() const {
    return Instruction::getOpcodeName(Opcode);
  }
};
 
class BitcodeReader : public BitcodeReaderBase, public GVMaterializer {
  LLVMContext &Context;
  Module *TheModule = nullptr;
  // Next offset to start scanning for lazy parsing of function bodies.
  uint64_t NextUnreadBit = 0;
  // Last function offset found in the VST.
  uint64_t LastFunctionBlockBit = 0;
  bool SeenValueSymbolTable = false;
  uint64_t VSTOffset = 0;
 
  std::vector<std::string> SectionTable;
  std::vector<std::string> GCTable;
 
  std::vector<Type *> TypeList;
  /// Track type IDs of contained types. Order is the same as the contained
  /// types of a Type*. This is used during upgrades of typed pointer IR in
  /// opaque pointer mode.
  DenseMap<unsigned, SmallVector<unsigned, 1>> ContainedTypeIDs;
  /// In some cases, we need to create a type ID for a type that was not
  /// explicitly encoded in the bitcode, or we don't know about at the current
  /// point. For example, a global may explicitly encode the value type ID, but
  /// not have a type ID for the pointer to value type, for which we create a
  /// virtual type ID instead. This map stores the new type ID that was created
  /// for the given pair of Type and contained type ID.
  DenseMap<std::pair<Type *, unsigned>, unsigned> VirtualTypeIDs;
  DenseMap<Function *, unsigned> FunctionTypeIDs;
  /// Allocator for BitcodeConstants. This should come before ValueList,
  /// because the ValueList might hold ValueHandles to these constants, so
  /// ValueList must be destroyed before Alloc.
  BumpPtrAllocator Alloc;
  BitcodeReaderValueList ValueList;
  std::optional<MetadataLoader> MDLoader;
  std::vector<Comdat *> ComdatList;
  DenseSet<GlobalObject *> ImplicitComdatObjects;
  SmallVector<Instruction *, 64> InstructionList;
 
  std::vector<std::pair<GlobalVariable *, unsigned>> GlobalInits;
  std::vector<std::pair<GlobalValue *, unsigned>> IndirectSymbolInits;
 
  struct FunctionOperandInfo {
    Function *F;
    unsigned PersonalityFn;
    unsigned Prefix;
    unsigned Prologue;
  };
  std::vector<FunctionOperandInfo> FunctionOperands;
 
  /// The set of attributes by index.  Index zero in the file is for null, and
  /// is thus not represented here.  As such all indices are off by one.
  std::vector<AttributeList> MAttributes;
 
  /// The set of attribute groups.
  std::map<unsigned, AttributeList> MAttributeGroups;
 
  /// While parsing a function body, this is a list of the basic blocks for the
  /// function.
  std::vector<BasicBlock*> FunctionBBs;
 
  // When reading the module header, this list is populated with functions that
  // have bodies later in the file.
  std::vector<Function*> FunctionsWithBodies;
 
  // When intrinsic functions are encountered which require upgrading they are
  // stored here with their replacement function.
  using UpdatedIntrinsicMap = DenseMap<Function *, Function *>;
  UpdatedIntrinsicMap UpgradedIntrinsics;
 
  // Several operations happen after the module header has been read, but
  // before function bodies are processed. This keeps track of whether
  // we've done this yet.
  bool SeenFirstFunctionBody = false;
 
  /// When function bodies are initially scanned, this map contains info about
  /// where to find deferred function body in the stream.
  DenseMap<Function*, uint64_t> DeferredFunctionInfo;
 
  /// When Metadata block is initially scanned when parsing the module, we may
  /// choose to defer parsing of the metadata. This vector contains info about
  /// which Metadata blocks are deferred.
  std::vector<uint64_t> DeferredMetadataInfo;
 
  /// These are basic blocks forward-referenced by block addresses.  They are
  /// inserted lazily into functions when they're loaded.  The basic block ID is
  /// its index into the vector.
  DenseMap<Function *, std::vector<BasicBlock *>> BasicBlockFwdRefs;
  std::deque<Function *> BasicBlockFwdRefQueue;
 
  /// These are Functions that contain BlockAddresses which refer a different
  /// Function. When parsing the different Function, queue Functions that refer
  /// to the different Function. Those Functions must be materialized in order
  /// to resolve their BlockAddress constants before the different Function
  /// gets moved into another Module.
  std::vector<Function *> BackwardRefFunctions;
 
  /// Indicates that we are using a new encoding for instruction operands where
  /// most operands in the current FUNCTION_BLOCK are encoded relative to the
  /// instruction number, for a more compact encoding.  Some instruction
  /// operands are not relative to the instruction ID: basic block numbers, and
  /// types. Once the old style function blocks have been phased out, we would
  /// not need this flag.
  bool UseRelativeIDs = false;
 
  /// True if all functions will be materialized, negating the need to process
  /// (e.g.) blockaddress forward references.
  bool WillMaterializeAllForwardRefs = false;
 
  /// Tracks whether we have seen debug intrinsics or records in this bitcode;
  /// seeing both in a single module is currently a fatal error.
  bool SeenDebugIntrinsic = false;
  bool SeenDebugRecord = false;
 
  bool StripDebugInfo = false;
  TBAAVerifier TBAAVerifyHelper;
 
  std::vector<std::string> BundleTags;
  SmallVector<SyncScope::ID, 8> SSIDs;
 
  std::optional<ValueTypeCallbackTy> ValueTypeCallback;
 
public:
  BitcodeReader(BitstreamCursor Stream, StringRef Strtab,
                StringRef ProducerIdentification, LLVMContext &Context);
 
  Error materializeForwardReferencedFunctions();
 
  Error materialize(GlobalValue *GV) override;
  Error materializeModule() override;
  std::vector<StructType *> getIdentifiedStructTypes() const override;
 
  /// Main interface to parsing a bitcode buffer.
  /// \returns true if an error occurred.
  Error parseBitcodeInto(Module *M, bool ShouldLazyLoadMetadata,
                         bool IsImporting, ParserCallbacks Callbacks = {});
 
  static uint64_t decodeSignRotatedValue(uint64_t V);
 
  /// Materialize any deferred Metadata block.
  Error materializeMetadata() override;
 
  void setStripDebugInfo() override;
 
private:
  std::vector<StructType *> IdentifiedStructTypes;
  StructType *createIdentifiedStructType(LLVMContext &Context, StringRef Name);
  StructType *createIdentifiedStructType(LLVMContext &Context);
 
  static constexpr unsigned InvalidTypeID = ~0u;
 
  Type *getTypeByID(unsigned ID);
  Type *getPtrElementTypeByID(unsigned ID);
  unsigned getContainedTypeID(unsigned ID, unsigned Idx = 0);
  unsigned getVirtualTypeID(Type *Ty, ArrayRef<unsigned> ContainedTypeIDs = {});
 
  void callValueTypeCallback(Value *F, unsigned TypeID);
  Expected<Value *> materializeValue(unsigned ValID, BasicBlock *InsertBB);
  Expected<Constant *> getValueForInitializer(unsigned ID);
 
  Value *getFnValueByID(unsigned ID, Type *Ty, unsigned TyID,
                        BasicBlock *ConstExprInsertBB) {
    if (Ty && Ty->isMetadataTy())
      return MetadataAsValue::get(Ty->getContext(), getFnMetadataByID(ID));
    return ValueList.getValueFwdRef(ID, Ty, TyID, ConstExprInsertBB);
  }
 
  Metadata *getFnMetadataByID(unsigned ID) {
    return MDLoader->getMetadataFwdRefOrLoad(ID);
  }
 
  BasicBlock *getBasicBlock(unsigned ID) const {
    if (ID >= FunctionBBs.size()) return nullptr; // Invalid ID
    return FunctionBBs[ID];
  }
 
  AttributeList getAttributes(unsigned i) const {
    if (i-1 < MAttributes.size())
      return MAttributes[i-1];
    return AttributeList();
  }
 
  /// Read a value/type pair out of the specified record from slot 'Slot'.
  /// Increment Slot past the number of slots used in the record. Return true on
  /// failure.
  bool getValueTypePair(const SmallVectorImpl<uint64_t> &Record, unsigned &Slot,
                        unsigned InstNum, Value *&ResVal, unsigned &TypeID,
                        BasicBlock *ConstExprInsertBB) {
    if (Slot == Record.size()) return true;
    unsigned ValNo = (unsigned)Record[Slot++];
    // Adjust the ValNo, if it was encoded relative to the InstNum.
    if (UseRelativeIDs)
      ValNo = InstNum - ValNo;
    if (ValNo < InstNum) {
      // If this is not a forward reference, just return the value we already
      // have.
      TypeID = ValueList.getTypeID(ValNo);
      ResVal = getFnValueByID(ValNo, nullptr, TypeID, ConstExprInsertBB);
      assert((!ResVal || ResVal->getType() == getTypeByID(TypeID)) &&
             "Incorrect type ID stored for value");
      return ResVal == nullptr;
    }
    if (Slot == Record.size())
      return true;
 
    TypeID = (unsigned)Record[Slot++];
    ResVal = getFnValueByID(ValNo, getTypeByID(TypeID), TypeID,
                            ConstExprInsertBB);
    return ResVal == nullptr;
  }
 
  bool getValueOrMetadata(const SmallVectorImpl<uint64_t> &Record,
                          unsigned &Slot, unsigned InstNum, Value *&ResVal,
                          BasicBlock *ConstExprInsertBB) {
    if (Slot == Record.size())
      return true;
    unsigned ValID = Record[Slot++];
    if (ValID != static_cast<unsigned>(bitc::OB_METADATA)) {
      unsigned TypeId;
      return getValueTypePair(Record, --Slot, InstNum, ResVal, TypeId,
                              ConstExprInsertBB);
    }
    if (Slot == Record.size())
      return true;
    unsigned ValNo = InstNum - (unsigned)Record[Slot++];
    ResVal = MetadataAsValue::get(Context, getFnMetadataByID(ValNo));
    return false;
  }
 
  /// Read a value out of the specified record from slot 'Slot'. Increment Slot
  /// past the number of slots used by the value in the record. Return true if
  /// there is an error.
  bool popValue(const SmallVectorImpl<uint64_t> &Record, unsigned &Slot,
                unsigned InstNum, Type *Ty, unsigned TyID, Value *&ResVal,
                BasicBlock *ConstExprInsertBB) {
    if (getValue(Record, Slot, InstNum, Ty, TyID, ResVal, ConstExprInsertBB))
      return true;
    // All values currently take a single record slot.
    ++Slot;
    return false;
  }
 
  /// Like popValue, but does not increment the Slot number.
  bool getValue(const SmallVectorImpl<uint64_t> &Record, unsigned Slot,
                unsigned InstNum, Type *Ty, unsigned TyID, Value *&ResVal,
                BasicBlock *ConstExprInsertBB) {
    ResVal = getValue(Record, Slot, InstNum, Ty, TyID, ConstExprInsertBB);
    return ResVal == nullptr;
  }
 
  /// Version of getValue that returns ResVal directly, or 0 if there is an
  /// error.
  Value *getValue(const SmallVectorImpl<uint64_t> &Record, unsigned Slot,
                  unsigned InstNum, Type *Ty, unsigned TyID,
                  BasicBlock *ConstExprInsertBB) {
    if (Slot == Record.size()) return nullptr;
    unsigned ValNo = (unsigned)Record[Slot];
    // Adjust the ValNo, if it was encoded relative to the InstNum.
    if (UseRelativeIDs)
      ValNo = InstNum - ValNo;
    return getFnValueByID(ValNo, Ty, TyID, ConstExprInsertBB);
  }
 
  /// Like getValue, but decodes signed VBRs.
  Value *getValueSigned(const SmallVectorImpl<uint64_t> &Record, unsigned Slot,
                        unsigned InstNum, Type *Ty, unsigned TyID,
                        BasicBlock *ConstExprInsertBB) {
    if (Slot == Record.size()) return nullptr;
    unsigned ValNo = (unsigned)decodeSignRotatedValue(Record[Slot]);
    // Adjust the ValNo, if it was encoded relative to the InstNum.
    if (UseRelativeIDs)
      ValNo = InstNum - ValNo;
    return getFnValueByID(ValNo, Ty, TyID, ConstExprInsertBB);
  }
 
  Expected<ConstantRange> readConstantRange(ArrayRef<uint64_t> Record,
                                            unsigned &OpNum,
                                            unsigned BitWidth) {
    if (Record.size() - OpNum < 2)
      return error("Too few records for range");
    if (BitWidth > 64) {
      unsigned LowerActiveWords = Record[OpNum];
      unsigned UpperActiveWords = Record[OpNum++] >> 32;
      if (Record.size() - OpNum < LowerActiveWords + UpperActiveWords)
        return error("Too few records for range");
      APInt Lower =
          readWideAPInt(ArrayRef(&Record[OpNum], LowerActiveWords), BitWidth);
      OpNum += LowerActiveWords;
      APInt Upper =
          readWideAPInt(ArrayRef(&Record[OpNum], UpperActiveWords), BitWidth);
      OpNum += UpperActiveWords;
      return ConstantRange(Lower, Upper);
    } else {
      int64_t Start = BitcodeReader::decodeSignRotatedValue(Record[OpNum++]);
      int64_t End = BitcodeReader::decodeSignRotatedValue(Record[OpNum++]);
      return ConstantRange(APInt(BitWidth, Start, true),
                           APInt(BitWidth, End, true));
    }
  }
 
  Expected<ConstantRange>
  readBitWidthAndConstantRange(ArrayRef<uint64_t> Record, unsigned &OpNum) {
    if (Record.size() - OpNum < 1)
      return error("Too few records for range");
    unsigned BitWidth = Record[OpNum++];
    return readConstantRange(Record, OpNum, BitWidth);
  }
 
  /// Upgrades old-style typeless byval/sret/inalloca attributes by adding the
  /// corresponding argument's pointee type. Also upgrades intrinsics that now
  /// require an elementtype attribute.
  Error propagateAttributeTypes(CallBase *CB, ArrayRef<unsigned> ArgsTys);
 
  /// Converts alignment exponent (i.e. power of two (or zero)) to the
  /// corresponding alignment to use. If alignment is too large, returns
  /// a corresponding error code.
  Error parseAlignmentValue(uint64_t Exponent, MaybeAlign &Alignment);
  Error parseAttrKind(uint64_t Code, Attribute::AttrKind *Kind);
  Error parseModule(uint64_t ResumeBit, bool ShouldLazyLoadMetadata = false,
                    ParserCallbacks Callbacks = {});
 
  Error parseComdatRecord(ArrayRef<uint64_t> Record);
  Error parseGlobalVarRecord(ArrayRef<uint64_t> Record);
  Error parseFunctionRecord(ArrayRef<uint64_t> Record);
  Error parseGlobalIndirectSymbolRecord(unsigned BitCode,
                                        ArrayRef<uint64_t> Record);
 
  Error parseAttributeBlock();
  Error parseAttributeGroupBlock();
  Error parseTypeTable();
  Error parseTypeTableBody();
  Error parseOperandBundleTags();
  Error parseSyncScopeNames();
 
  Expected<Value *> recordValue(SmallVectorImpl<uint64_t> &Record,
                                unsigned NameIndex, Triple &TT);
  void setDeferredFunctionInfo(unsigned FuncBitcodeOffsetDelta, Function *F,
                               ArrayRef<uint64_t> Record);
  Error parseValueSymbolTable(uint64_t Offset = 0);
  Error parseGlobalValueSymbolTable();
  Error parseConstants();
  Error rememberAndSkipFunctionBodies();
  Error rememberAndSkipFunctionBody();
  /// Save the positions of the Metadata blocks and skip parsing the blocks.
  Error rememberAndSkipMetadata();
  Error typeCheckLoadStoreInst(Type *ValType, Type *PtrType);
  Error parseFunctionBody(Function *F);
  Error globalCleanup();
  Error resolveGlobalAndIndirectSymbolInits();
  Error parseUseLists();
  Error findFunctionInStream(
      Function *F,
      DenseMap<Function *, uint64_t>::iterator DeferredFunctionInfoIterator);
 
  SyncScope::ID getDecodedSyncScopeID(unsigned Val);
};
 
/// Class to manage reading and parsing function summary index bitcode
/// files/sections.
class ModuleSummaryIndexBitcodeReader : public BitcodeReaderBase {
  /// The module index built during parsing.
  ModuleSummaryIndex &TheIndex;
 
  /// Indicates whether we have encountered a global value summary section
  /// yet during parsing.
  bool SeenGlobalValSummary = false;
 
  /// Indicates whether we have already parsed the VST, used for error checking.
  bool SeenValueSymbolTable = false;
 
  /// Set to the offset of the VST recorded in the MODULE_CODE_VSTOFFSET record.
  /// Used to enable on-demand parsing of the VST.
  uint64_t VSTOffset = 0;
 
  // Map to save ValueId to ValueInfo association that was recorded in the
  // ValueSymbolTable. It is used after the VST is parsed to convert
  // call graph edges read from the function summary from referencing
  // callees by their ValueId to using the ValueInfo instead, which is how
  // they are recorded in the summary index being built.
  // We save a GUID which refers to the same global as the ValueInfo, but
  // ignoring the linkage, i.e. for values other than local linkage they are
  // identical (this is the second member). ValueInfo has the real GUID.
  DenseMap<unsigned, std::pair<ValueInfo, GlobalValue::GUID>>
      ValueIdToValueInfoMap;
 
  /// Map populated during module path string table parsing, from the
  /// module ID to a string reference owned by the index's module
  /// path string table, used to correlate with combined index
  /// summary records.
  DenseMap<uint64_t, StringRef> ModuleIdMap;
 
  /// Original source file name recorded in a bitcode record.
  std::string SourceFileName;
 
  /// The string identifier given to this module by the client, normally the
  /// path to the bitcode file.
  StringRef ModulePath;
 
  /// Callback to ask whether a symbol is the prevailing copy when invoked
  /// during combined index building.
  std::function<bool(GlobalValue::GUID)> IsPrevailing;
 
  /// Saves the stack ids from the STACK_IDS record to consult when adding stack
  /// ids from the lists in the callsite and alloc entries to the index.
  std::vector<uint64_t> StackIds;
 
  /// Linearized radix tree of allocation contexts. See the description above
  /// the CallStackRadixTreeBuilder class in ProfileData/MemProf.h for format.
  std::vector<uint64_t> RadixArray;
 
  /// Map from the module's stack id index to the index in the
  /// ModuleSummaryIndex's StackIds vector. Populated lazily from the StackIds
  /// list and used to avoid repeated hash lookups.
  std::vector<unsigned> StackIdToIndex;
 
public:
  ModuleSummaryIndexBitcodeReader(
      BitstreamCursor Stream, StringRef Strtab, ModuleSummaryIndex &TheIndex,
      StringRef ModulePath,
      std::function<bool(GlobalValue::GUID)> IsPrevailing = nullptr);
 
  Error parseModule();
 
private:
  void setValueGUID(uint64_t ValueID, StringRef ValueName,
                    GlobalValue::LinkageTypes Linkage,
                    StringRef SourceFileName);
  Error parseValueSymbolTable(
      uint64_t Offset,
      DenseMap<unsigned, GlobalValue::LinkageTypes> &ValueIdToLinkageMap);
  SmallVector<ValueInfo, 0> makeRefList(ArrayRef<uint64_t> Record);
  SmallVector<FunctionSummary::EdgeTy, 0>
  makeCallList(ArrayRef<uint64_t> Record, bool IsOldProfileFormat,
               bool HasProfile, bool HasRelBF);
  Error parseEntireSummary(unsigned ID);
  Error parseModuleStringTable();
  void parseTypeIdCompatibleVtableSummaryRecord(ArrayRef<uint64_t> Record);
  void parseTypeIdCompatibleVtableInfo(ArrayRef<uint64_t> Record, size_t &Slot,
                                       TypeIdCompatibleVtableInfo &TypeId);
  std::vector<FunctionSummary::ParamAccess>
  parseParamAccesses(ArrayRef<uint64_t> Record);
  SmallVector<unsigned> parseAllocInfoContext(ArrayRef<uint64_t> Record,
                                              unsigned &I);
 
  // Mark uninitialized stack ID mappings for lazy population.
  static constexpr unsigned UninitializedStackIdIndex =
      std::numeric_limits<unsigned>::max();
 
  unsigned getStackIdIndex(unsigned LocalIndex) {
    unsigned &Index = StackIdToIndex[LocalIndex];
    // Add the stack id to the ModuleSummaryIndex map only when first requested
    // and cache the result in the local StackIdToIndex map.
    if (Index == UninitializedStackIdIndex)
      Index = TheIndex.addOrGetStackIdIndex(StackIds[LocalIndex]);
    return Index;
  }
 
  template <bool AllowNullValueInfo = false>
  std::pair<ValueInfo, GlobalValue::GUID>
  getValueInfoFromValueId(unsigned ValueId);
 
  void addThisModule();
  ModuleSummaryIndex::ModuleInfo *getThisModule();
};
 
} // end anonymous namespace
 
std::error_code llvm::errorToErrorCodeAndEmitErrors(LLVMContext &Ctx,
                                                    Error Err) {
  if (Err) {
    std::error_code EC;
    handleAllErrors(std::move(Err), [&](ErrorInfoBase &EIB) {
      EC = EIB.convertToErrorCode();
      Ctx.emitError(EIB.message());
    });
    return EC;
  }
  return std::error_code();
}
 
BitcodeReader::BitcodeReader(BitstreamCursor Stream, StringRef Strtab,
                             StringRef ProducerIdentification,
                             LLVMContext &Context)
    : BitcodeReaderBase(std::move(Stream), Strtab), Context(Context),
      ValueList(this->Stream.SizeInBytes(),
                [this](unsigned ValID, BasicBlock *InsertBB) {
                  return materializeValue(ValID, InsertBB);
                }) {
  this->ProducerIdentification = std::string(ProducerIdentification);
}
 
Error BitcodeReader::materializeForwardReferencedFunctions() {
  if (WillMaterializeAllForwardRefs)
    return Error::success();
 
  // Prevent recursion.
  WillMaterializeAllForwardRefs = true;
 
  while (!BasicBlockFwdRefQueue.empty()) {
    Function *F = BasicBlockFwdRefQueue.front();
    BasicBlockFwdRefQueue.pop_front();
    assert(F && "Expected valid function");
    if (!BasicBlockFwdRefs.count(F))
      // Already materialized.
      continue;
 
    // Check for a function that isn't materializable to prevent an infinite
    // loop.  When parsing a blockaddress stored in a global variable, there
    // isn't a trivial way to check if a function will have a body without a
    // linear search through FunctionsWithBodies, so just check it here.
    if (!F->isMaterializable())
      return error("Never resolved function from blockaddress");
 
    // Try to materialize F.
    if (Error Err = materialize(F))
      return Err;
  }
  assert(BasicBlockFwdRefs.empty() && "Function missing from queue");
 
  for (Function *F : BackwardRefFunctions)
    if (Error Err = materialize(F))
      return Err;
  BackwardRefFunctions.clear();
 
  // Reset state.
  WillMaterializeAllForwardRefs = false;
  return Error::success();
}
 
//===----------------------------------------------------------------------===//
//  Helper functions to implement forward reference resolution, etc.
//===----------------------------------------------------------------------===//
 
static bool hasImplicitComdat(size_t Val) {
  switch (Val) {
  default:
    return false;
  case 1:  // Old WeakAnyLinkage
  case 4:  // Old LinkOnceAnyLinkage
  case 10: // Old WeakODRLinkage
  case 11: // Old LinkOnceODRLinkage
    return true;
  }
}
 
static GlobalValue::LinkageTypes getDecodedLinkage(unsigned Val) {
  switch (Val) {
  default: // Map unknown/new linkages to external
  case 0:
    return GlobalValue::ExternalLinkage;
  case 2:
    return GlobalValue::AppendingLinkage;
  case 3:
    return GlobalValue::InternalLinkage;
  case 5:
    return GlobalValue::ExternalLinkage; // Obsolete DLLImportLinkage
  case 6:
    return GlobalValue::ExternalLinkage; // Obsolete DLLExportLinkage
  case 7:
    return GlobalValue::ExternalWeakLinkage;
  case 8:
    return GlobalValue::CommonLinkage;
  case 9:
    return GlobalValue::PrivateLinkage;
  case 12:
    return GlobalValue::AvailableExternallyLinkage;
  case 13:
    return GlobalValue::PrivateLinkage; // Obsolete LinkerPrivateLinkage
  case 14:
    return GlobalValue::PrivateLinkage; // Obsolete LinkerPrivateWeakLinkage
  case 15:
    return GlobalValue::ExternalLinkage; // Obsolete LinkOnceODRAutoHideLinkage
  case 1: // Old value with implicit comdat.
  case 16:
    return GlobalValue::WeakAnyLinkage;
  case 10: // Old value with implicit comdat.
  case 17:
    return GlobalValue::WeakODRLinkage;
  case 4: // Old value with implicit comdat.
  case 18:
    return GlobalValue::LinkOnceAnyLinkage;
  case 11: // Old value with implicit comdat.
  case 19:
    return GlobalValue::LinkOnceODRLinkage;
  }
}
 
static FunctionSummary::FFlags getDecodedFFlags(uint64_t RawFlags) {
  FunctionSummary::FFlags Flags;
  Flags.ReadNone = RawFlags & 0x1;
  Flags.ReadOnly = (RawFlags >> 1) & 0x1;
  Flags.NoRecurse = (RawFlags >> 2) & 0x1;
  Flags.ReturnDoesNotAlias = (RawFlags >> 3) & 0x1;
  Flags.NoInline = (RawFlags >> 4) & 0x1;
  Flags.AlwaysInline = (RawFlags >> 5) & 0x1;
  Flags.NoUnwind = (RawFlags >> 6) & 0x1;
  Flags.MayThrow = (RawFlags >> 7) & 0x1;
  Flags.HasUnknownCall = (RawFlags >> 8) & 0x1;
  Flags.MustBeUnreachable = (RawFlags >> 9) & 0x1;
  return Flags;
}
 
// Decode the flags for GlobalValue in the summary. The bits for each attribute:
//
// linkage: [0,4), notEligibleToImport: 4, live: 5, local: 6, canAutoHide: 7,
// visibility: [8, 10).
static GlobalValueSummary::GVFlags getDecodedGVSummaryFlags(uint64_t RawFlags,
                                                            uint64_t Version) {
  // Summary were not emitted before LLVM 3.9, we don't need to upgrade Linkage
  // like getDecodedLinkage() above. Any future change to the linkage enum and
  // to getDecodedLinkage() will need to be taken into account here as above.
  auto Linkage = GlobalValue::LinkageTypes(RawFlags & 0xF); // 4 bits
  auto Visibility = GlobalValue::VisibilityTypes((RawFlags >> 8) & 3); // 2 bits
  auto IK = GlobalValueSummary::ImportKind((RawFlags >> 10) & 1);      // 1 bit
  bool NoRenameOnPromotion = ((RawFlags >> 11) & 1);                   // 1 bit
  RawFlags = RawFlags >> 4;
  bool NotEligibleToImport = (RawFlags & 0x1) || Version < 3;
  // The Live flag wasn't introduced until version 3. For dead stripping
  // to work correctly on earlier versions, we must conservatively treat all
  // values as live.
  bool Live = (RawFlags & 0x2) || Version < 3;
  bool Local = (RawFlags & 0x4);
  bool AutoHide = (RawFlags & 0x8);
 
  return GlobalValueSummary::GVFlags(Linkage, Visibility, NotEligibleToImport,
                                     Live, Local, AutoHide, IK,
                                     NoRenameOnPromotion);
}
 
// Decode the flags for GlobalVariable in the summary
static GlobalVarSummary::GVarFlags getDecodedGVarFlags(uint64_t RawFlags) {
  return GlobalVarSummary::GVarFlags(
      (RawFlags & 0x1) ? true : false, (RawFlags & 0x2) ? true : false,
      (RawFlags & 0x4) ? true : false,
      (GlobalObject::VCallVisibility)(RawFlags >> 3));
}
 
static std::pair<CalleeInfo::HotnessType, bool>
getDecodedHotnessCallEdgeInfo(uint64_t RawFlags) {
  CalleeInfo::HotnessType Hotness =
      static_cast<CalleeInfo::HotnessType>(RawFlags & 0x7); // 3 bits
  bool HasTailCall = (RawFlags & 0x8);                      // 1 bit
  return {Hotness, HasTailCall};
}
 
// Deprecated, but still needed to read old bitcode files.
static void getDecodedRelBFCallEdgeInfo(uint64_t RawFlags, uint64_t &RelBF,
                                        bool &HasTailCall) {
  static constexpr unsigned RelBlockFreqBits = 28;
  static constexpr uint64_t RelBlockFreqMask = (1 << RelBlockFreqBits) - 1;
  RelBF = RawFlags & RelBlockFreqMask; // RelBlockFreqBits bits
  HasTailCall = (RawFlags & (1 << RelBlockFreqBits)); // 1 bit
}
 
static GlobalValue::VisibilityTypes getDecodedVisibility(unsigned Val) {
  switch (Val) {
  default: // Map unknown visibilities to default.
  case 0: return GlobalValue::DefaultVisibility;
  case 1: return GlobalValue::HiddenVisibility;
  case 2: return GlobalValue::ProtectedVisibility;
  }
}
 
static GlobalValue::DLLStorageClassTypes
getDecodedDLLStorageClass(unsigned Val) {
  switch (Val) {
  default: // Map unknown values to default.
  case 0: return GlobalValue::DefaultStorageClass;
  case 1: return GlobalValue::DLLImportStorageClass;
  case 2: return GlobalValue::DLLExportStorageClass;
  }
}
 
static bool getDecodedDSOLocal(unsigned Val) {
  switch(Val) {
  default: // Map unknown values to preemptable.
  case 0:  return false;
  case 1:  return true;
  }
}
 
static std::optional<CodeModel::Model> getDecodedCodeModel(unsigned Val) {
  switch (Val) {
  case 1:
    return CodeModel::Tiny;
  case 2:
    return CodeModel::Small;
  case 3:
    return CodeModel::Kernel;
  case 4:
    return CodeModel::Medium;
  case 5:
    return CodeModel::Large;
  }
 
  return {};
}
 
static GlobalVariable::ThreadLocalMode getDecodedThreadLocalMode(unsigned Val) {
  switch (Val) {
    case 0: return GlobalVariable::NotThreadLocal;
    default: // Map unknown non-zero value to general dynamic.
    case 1: return GlobalVariable::GeneralDynamicTLSModel;
    case 2: return GlobalVariable::LocalDynamicTLSModel;
    case 3: return GlobalVariable::InitialExecTLSModel;
    case 4: return GlobalVariable::LocalExecTLSModel;
  }
}
 
static GlobalVariable::UnnamedAddr getDecodedUnnamedAddrType(unsigned Val) {
  switch (Val) {
    default: // Map unknown to UnnamedAddr::None.
    case 0: return GlobalVariable::UnnamedAddr::None;
    case 1: return GlobalVariable::UnnamedAddr::Global;
    case 2: return GlobalVariable::UnnamedAddr::Local;
  }
}
 
static int getDecodedCastOpcode(unsigned Val) {
  switch (Val) {
  default: return -1;
  case bitc::CAST_TRUNC   : return Instruction::Trunc;
  case bitc::CAST_ZEXT    : return Instruction::ZExt;
  case bitc::CAST_SEXT    : return Instruction::SExt;
  case bitc::CAST_FPTOUI  : return Instruction::FPToUI;
  case bitc::CAST_FPTOSI  : return Instruction::FPToSI;
  case bitc::CAST_UITOFP  : return Instruction::UIToFP;
  case bitc::CAST_SITOFP  : return Instruction::SIToFP;
  case bitc::CAST_FPTRUNC : return Instruction::FPTrunc;
  case bitc::CAST_FPEXT   : return Instruction::FPExt;
  case bitc::CAST_PTRTOADDR: return Instruction::PtrToAddr;
  case bitc::CAST_PTRTOINT: return Instruction::PtrToInt;
  case bitc::CAST_INTTOPTR: return Instruction::IntToPtr;
  case bitc::CAST_BITCAST : return Instruction::BitCast;
  case bitc::CAST_ADDRSPACECAST: return Instruction::AddrSpaceCast;
  }
}
 
static int getDecodedUnaryOpcode(unsigned Val, Type *Ty) {
  bool IsFP = Ty->isFPOrFPVectorTy();
  // UnOps are only valid for int/fp or vector of int/fp types
  if (!IsFP && !Ty->isIntOrIntVectorTy())
    return -1;
 
  switch (Val) {
  default:
    return -1;
  case bitc::UNOP_FNEG:
    return IsFP ? Instruction::FNeg : -1;
  }
}
 
static int getDecodedBinaryOpcode(unsigned Val, Type *Ty) {
  bool IsFP = Ty->isFPOrFPVectorTy();
  // BinOps are only valid for int/fp or vector of int/fp types
  if (!IsFP && !Ty->isIntOrIntVectorTy())
    return -1;
 
  switch (Val) {
  default:
    return -1;
  case bitc::BINOP_ADD:
    return IsFP ? Instruction::FAdd : Instruction::Add;
  case bitc::BINOP_SUB:
    return IsFP ? Instruction::FSub : Instruction::Sub;
  case bitc::BINOP_MUL:
    return IsFP ? Instruction::FMul : Instruction::Mul;
  case bitc::BINOP_UDIV:
    return IsFP ? -1 : Instruction::UDiv;
  case bitc::BINOP_SDIV:
    return IsFP ? Instruction::FDiv : Instruction::SDiv;
  case bitc::BINOP_UREM:
    return IsFP ? -1 : Instruction::URem;
  case bitc::BINOP_SREM:
    return IsFP ? Instruction::FRem : Instruction::SRem;
  case bitc::BINOP_SHL:
    return IsFP ? -1 : Instruction::Shl;
  case bitc::BINOP_LSHR:
    return IsFP ? -1 : Instruction::LShr;
  case bitc::BINOP_ASHR:
    return IsFP ? -1 : Instruction::AShr;
  case bitc::BINOP_AND:
    return IsFP ? -1 : Instruction::And;
  case bitc::BINOP_OR:
    return IsFP ? -1 : Instruction::Or;
  case bitc::BINOP_XOR:
    return IsFP ? -1 : Instruction::Xor;
  }
}
 
static AtomicRMWInst::BinOp getDecodedRMWOperation(unsigned Val) {
  switch (Val) {
  default: return AtomicRMWInst::BAD_BINOP;
  case bitc::RMW_XCHG: return AtomicRMWInst::Xchg;
  case bitc::RMW_ADD: return AtomicRMWInst::Add;
  case bitc::RMW_SUB: return AtomicRMWInst::Sub;
  case bitc::RMW_AND: return AtomicRMWInst::And;
  case bitc::RMW_NAND: return AtomicRMWInst::Nand;
  case bitc::RMW_OR: return AtomicRMWInst::Or;
  case bitc::RMW_XOR: return AtomicRMWInst::Xor;
  case bitc::RMW_MAX: return AtomicRMWInst::Max;
  case bitc::RMW_MIN: return AtomicRMWInst::Min;
  case bitc::RMW_UMAX: return AtomicRMWInst::UMax;
  case bitc::RMW_UMIN: return AtomicRMWInst::UMin;
  case bitc::RMW_FADD: return AtomicRMWInst::FAdd;
  case bitc::RMW_FSUB: return AtomicRMWInst::FSub;
  case bitc::RMW_FMAX: return AtomicRMWInst::FMax;
  case bitc::RMW_FMIN: return AtomicRMWInst::FMin;
  case bitc::RMW_FMAXIMUM:
    return AtomicRMWInst::FMaximum;
  case bitc::RMW_FMINIMUM:
    return AtomicRMWInst::FMinimum;
  case bitc::RMW_UINC_WRAP:
    return AtomicRMWInst::UIncWrap;
  case bitc::RMW_UDEC_WRAP:
    return AtomicRMWInst::UDecWrap;
  case bitc::RMW_USUB_COND:
    return AtomicRMWInst::USubCond;
  case bitc::RMW_USUB_SAT:
    return AtomicRMWInst::USubSat;
  }
}
 
static AtomicOrdering getDecodedOrdering(unsigned Val) {
  switch (Val) {
  case bitc::ORDERING_NOTATOMIC: return AtomicOrdering::NotAtomic;
  case bitc::ORDERING_UNORDERED: return AtomicOrdering::Unordered;
  case bitc::ORDERING_MONOTONIC: return AtomicOrdering::Monotonic;
  case bitc::ORDERING_ACQUIRE: return AtomicOrdering::Acquire;
  case bitc::ORDERING_RELEASE: return AtomicOrdering::Release;
  case bitc::ORDERING_ACQREL: return AtomicOrdering::AcquireRelease;
  default: // Map unknown orderings to sequentially-consistent.
  case bitc::ORDERING_SEQCST: return AtomicOrdering::SequentiallyConsistent;
  }
}
 
static Comdat::SelectionKind getDecodedComdatSelectionKind(unsigned Val) {
  switch (Val) {
  default: // Map unknown selection kinds to any.
  case bitc::COMDAT_SELECTION_KIND_ANY:
    return Comdat::Any;
  case bitc::COMDAT_SELECTION_KIND_EXACT_MATCH:
    return Comdat::ExactMatch;
  case bitc::COMDAT_SELECTION_KIND_LARGEST:
    return Comdat::Largest;
  case bitc::COMDAT_SELECTION_KIND_NO_DUPLICATES:
    return Comdat::NoDeduplicate;
  case bitc::COMDAT_SELECTION_KIND_SAME_SIZE:
    return Comdat::SameSize;
  }
}
 
static FastMathFlags getDecodedFastMathFlags(unsigned Val) {
  FastMathFlags FMF;
  if (0 != (Val & bitc::UnsafeAlgebra))
    FMF.setFast();
  if (0 != (Val & bitc::AllowReassoc))
    FMF.setAllowReassoc();
  if (0 != (Val & bitc::NoNaNs))
    FMF.setNoNaNs();
  if (0 != (Val & bitc::NoInfs))
    FMF.setNoInfs();
  if (0 != (Val & bitc::NoSignedZeros))
    FMF.setNoSignedZeros();
  if (0 != (Val & bitc::AllowReciprocal))
    FMF.setAllowReciprocal();
  if (0 != (Val & bitc::AllowContract))
    FMF.setAllowContract(true);
  if (0 != (Val & bitc::ApproxFunc))
    FMF.setApproxFunc();
  return FMF;
}
 
static void upgradeDLLImportExportLinkage(GlobalValue *GV, unsigned Val) {
  // A GlobalValue with local linkage cannot have a DLL storage class.
  if (GV->hasLocalLinkage())
    return;
  switch (Val) {
  case 5: GV->setDLLStorageClass(GlobalValue::DLLImportStorageClass); break;
  case 6: GV->setDLLStorageClass(GlobalValue::DLLExportStorageClass); break;
  }
}
 
Type *BitcodeReader::getTypeByID(unsigned ID) {
  // The type table size is always specified correctly.
  if (ID >= TypeList.size())
    return nullptr;
 
  if (Type *Ty = TypeList[ID])
    return Ty;
 
  // If we have a forward reference, the only possible case is when it is to a
  // named struct.  Just create a placeholder for now.
  return TypeList[ID] = createIdentifiedStructType(Context);
}
 
unsigned BitcodeReader::getContainedTypeID(unsigned ID, unsigned Idx) {
  auto It = ContainedTypeIDs.find(ID);
  if (It == ContainedTypeIDs.end())
    return InvalidTypeID;
 
  if (Idx >= It->second.size())
    return InvalidTypeID;
 
  return It->second[Idx];
}
 
Type *BitcodeReader::getPtrElementTypeByID(unsigned ID) {
  if (ID >= TypeList.size())
    return nullptr;
 
  Type *Ty = TypeList[ID];
  if (!Ty->isPointerTy())
    return nullptr;
 
  return getTypeByID(getContainedTypeID(ID, 0));
}
 
unsigned BitcodeReader::getVirtualTypeID(Type *Ty,
                                         ArrayRef<unsigned> ChildTypeIDs) {
  unsigned ChildTypeID = ChildTypeIDs.empty() ? InvalidTypeID : ChildTypeIDs[0];
  auto CacheKey = std::make_pair(Ty, ChildTypeID);
  auto It = VirtualTypeIDs.find(CacheKey);
  if (It != VirtualTypeIDs.end()) {
    // The cmpxchg return value is the only place we need more than one
    // contained type ID, however the second one will always be the same (i1),
    // so we don't need to include it in the cache key. This asserts that the
    // contained types are indeed as expected and there are no collisions.
    assert((ChildTypeIDs.empty() ||
            ContainedTypeIDs[It->second] == ChildTypeIDs) &&
           "Incorrect cached contained type IDs");
    return It->second;
  }
 
  unsigned TypeID = TypeList.size();
  TypeList.push_back(Ty);
  if (!ChildTypeIDs.empty())
    append_range(ContainedTypeIDs[TypeID], ChildTypeIDs);
  VirtualTypeIDs.insert({CacheKey, TypeID});
  return TypeID;
}
 
static GEPNoWrapFlags toGEPNoWrapFlags(uint64_t Flags) {
  GEPNoWrapFlags NW;
  if (Flags & (1 << bitc::GEP_INBOUNDS))
    NW |= GEPNoWrapFlags::inBounds();
  if (Flags & (1 << bitc::GEP_NUSW))
    NW |= GEPNoWrapFlags::noUnsignedSignedWrap();
  if (Flags & (1 << bitc::GEP_NUW))
    NW |= GEPNoWrapFlags::noUnsignedWrap();
  return NW;
}
 
static bool isConstExprSupported(const BitcodeConstant *BC) {
  uint8_t Opcode = BC->Opcode;
 
  // These are not real constant expressions, always consider them supported.
  if (Opcode >= BitcodeConstant::FirstSpecialOpcode)
    return true;
 
  // If -expand-constant-exprs is set, we want to consider all expressions
  // as unsupported.
  if (ExpandConstantExprs)
    return false;
 
  if (Instruction::isBinaryOp(Opcode))
    return ConstantExpr::isSupportedBinOp(Opcode);
 
  if (Instruction::isCast(Opcode))
    return ConstantExpr::isSupportedCastOp(Opcode);
 
  if (Opcode == Instruction::GetElementPtr)
    return ConstantExpr::isSupportedGetElementPtr(BC->SrcElemTy);
 
  switch (Opcode) {
  case Instruction::FNeg:
  case Instruction::Select:
  case Instruction::ICmp:
  case Instruction::FCmp:
    return false;
  default:
    return true;
  }
}
 
Expected<Value *> BitcodeReader::materializeValue(unsigned StartValID,
                                                  BasicBlock *InsertBB) {
  // Quickly handle the case where there is no BitcodeConstant to resolve.
  if (StartValID < ValueList.size() && ValueList[StartValID] &&
      !isa<BitcodeConstant>(ValueList[StartValID]))
    return ValueList[StartValID];
 
  SmallDenseMap<unsigned, Value *> MaterializedValues;
  SmallVector<unsigned> Worklist;
  Worklist.push_back(StartValID);
  while (!Worklist.empty()) {
    unsigned ValID = Worklist.back();
    if (MaterializedValues.count(ValID)) {
      // Duplicate expression that was already handled.
      Worklist.pop_back();
      continue;
    }
 
    if (ValID >= ValueList.size() || !ValueList[ValID])
      return error("Invalid value ID");
 
    Value *V = ValueList[ValID];
    auto *BC = dyn_cast<BitcodeConstant>(V);
    if (!BC) {
      MaterializedValues.insert({ValID, V});
      Worklist.pop_back();
      continue;
    }
 
    // Iterate in reverse, so values will get popped from the worklist in
    // expected order.
    SmallVector<Value *> Ops;
    for (unsigned OpID : reverse(BC->getOperandIDs())) {
      auto It = MaterializedValues.find(OpID);
      if (It != MaterializedValues.end())
        Ops.push_back(It->second);
      else
        Worklist.push_back(OpID);
    }
 
    // Some expressions have not been resolved yet, handle them first and then
    // revisit this one.
    if (Ops.size() != BC->getOperandIDs().size())
      continue;
    std::reverse(Ops.begin(), Ops.end());
 
    SmallVector<Constant *> ConstOps;
    for (Value *Op : Ops)
      if (auto *C = dyn_cast<Constant>(Op))
        ConstOps.push_back(C);
 
    // Materialize as constant expression if possible.
    if (isConstExprSupported(BC) && ConstOps.size() == Ops.size()) {
      Constant *C;
      if (Instruction::isCast(BC->Opcode)) {
        C = UpgradeBitCastExpr(BC->Opcode, ConstOps[0], BC->getType());
        if (!C)
          C = ConstantExpr::getCast(BC->Opcode, ConstOps[0], BC->getType());
      } else if (Instruction::isBinaryOp(BC->Opcode)) {
        C = ConstantExpr::get(BC->Opcode, ConstOps[0], ConstOps[1], BC->Flags);
      } else {
        switch (BC->Opcode) {
        case BitcodeConstant::ConstantPtrAuthOpcode: {
          auto *Key = dyn_cast<ConstantInt>(ConstOps[1]);
          if (!Key)
            return error("ptrauth key operand must be ConstantInt");
 
          auto *Disc = dyn_cast<ConstantInt>(ConstOps[2]);
          if (!Disc)
            return error("ptrauth disc operand must be ConstantInt");
 
          Constant *DeactivationSymbol =
              ConstOps.size() > 4 ? ConstOps[4]
                                  : ConstantPointerNull::get(cast<PointerType>(
                                        ConstOps[3]->getType()));
          if (!DeactivationSymbol->getType()->isPointerTy())
            return error(
                "ptrauth deactivation symbol operand must be a pointer");
 
          C = ConstantPtrAuth::get(ConstOps[0], Key, Disc, ConstOps[3],
                                   DeactivationSymbol);
          break;
        }
        case BitcodeConstant::NoCFIOpcode: {
          auto *GV = dyn_cast<GlobalValue>(ConstOps[0]);
          if (!GV)
            return error("no_cfi operand must be GlobalValue");
          C = NoCFIValue::get(GV);
          break;
        }
        case BitcodeConstant::DSOLocalEquivalentOpcode: {
          auto *GV = dyn_cast<GlobalValue>(ConstOps[0]);
          if (!GV)
            return error("dso_local operand must be GlobalValue");
          C = DSOLocalEquivalent::get(GV);
          break;
        }
        case BitcodeConstant::BlockAddressOpcode: {
          Function *Fn = dyn_cast<Function>(ConstOps[0]);
          if (!Fn)
            return error("blockaddress operand must be a function");
 
          // If the function is already parsed we can insert the block address
          // right away.
          BasicBlock *BB;
          unsigned BBID = BC->BlockAddressBB;
          if (!BBID)
            // Invalid reference to entry block.
            return error("Invalid ID");
          if (!Fn->empty()) {
            Function::iterator BBI = Fn->begin(), BBE = Fn->end();
            for (size_t I = 0, E = BBID; I != E; ++I) {
              if (BBI == BBE)
                return error("Invalid ID");
              ++BBI;
            }
            BB = &*BBI;
          } else {
            // Otherwise insert a placeholder and remember it so it can be
            // inserted when the function is parsed.
            auto &FwdBBs = BasicBlockFwdRefs[Fn];
            if (FwdBBs.empty())
              BasicBlockFwdRefQueue.push_back(Fn);
            if (FwdBBs.size() < BBID + 1)
              FwdBBs.resize(BBID + 1);
            if (!FwdBBs[BBID])
              FwdBBs[BBID] = BasicBlock::Create(Context);
            BB = FwdBBs[BBID];
          }
          C = BlockAddress::get(Fn->getType(), BB);
          break;
        }
        case BitcodeConstant::ConstantStructOpcode: {
          auto *ST = cast<StructType>(BC->getType());
          if (ST->getNumElements() != ConstOps.size())
            return error("Invalid number of elements in struct initializer");
 
          for (const auto [Ty, Op] : zip(ST->elements(), ConstOps))
            if (Op->getType() != Ty)
              return error("Incorrect type in struct initializer");
 
          C = ConstantStruct::get(ST, ConstOps);
          break;
        }
        case BitcodeConstant::ConstantArrayOpcode: {
          auto *AT = cast<ArrayType>(BC->getType());
          if (AT->getNumElements() != ConstOps.size())
            return error("Invalid number of elements in array initializer");
 
          for (Constant *Op : ConstOps)
            if (Op->getType() != AT->getElementType())
              return error("Incorrect type in array initializer");
 
          C = ConstantArray::get(AT, ConstOps);
          break;
        }
        case BitcodeConstant::ConstantVectorOpcode: {
          auto *VT = cast<FixedVectorType>(BC->getType());
          if (VT->getNumElements() != ConstOps.size())
            return error("Invalid number of elements in vector initializer");
 
          for (Constant *Op : ConstOps)
            if (Op->getType() != VT->getElementType())
              return error("Incorrect type in vector initializer");
 
          C = ConstantVector::get(ConstOps);
          break;
        }
        case Instruction::GetElementPtr:
          C = ConstantExpr::getGetElementPtr(
              BC->SrcElemTy, ConstOps[0], ArrayRef(ConstOps).drop_front(),
              toGEPNoWrapFlags(BC->Flags), BC->getInRange());
          break;
        case Instruction::ExtractElement:
          C = ConstantExpr::getExtractElement(ConstOps[0], ConstOps[1]);
          break;
        case Instruction::InsertElement:
          C = ConstantExpr::getInsertElement(ConstOps[0], ConstOps[1],
                                             ConstOps[2]);
          break;
        case Instruction::ShuffleVector: {
          SmallVector<int, 16> Mask;
          ShuffleVectorInst::getShuffleMask(ConstOps[2], Mask);
          C = ConstantExpr::getShuffleVector(ConstOps[0], ConstOps[1], Mask);
          break;
        }
        default:
          llvm_unreachable("Unhandled bitcode constant");
        }
      }
 
      // Cache resolved constant.
      ValueList.replaceValueWithoutRAUW(ValID, C);
      MaterializedValues.insert({ValID, C});
      Worklist.pop_back();
      continue;
    }
 
    if (!InsertBB)
      return error(Twine("Value referenced by initializer is an unsupported "
                         "constant expression of type ") +
                   BC->getOpcodeName());
 
    // Materialize as instructions if necessary.
    Instruction *I;
    if (Instruction::isCast(BC->Opcode)) {
      I = CastInst::Create((Instruction::CastOps)BC->Opcode, Ops[0],
                           BC->getType(), "constexpr", InsertBB);
    } else if (Instruction::isUnaryOp(BC->Opcode)) {
      I = UnaryOperator::Create((Instruction::UnaryOps)BC->Opcode, Ops[0],
                                "constexpr", InsertBB);
    } else if (Instruction::isBinaryOp(BC->Opcode)) {
      I = BinaryOperator::Create((Instruction::BinaryOps)BC->Opcode, Ops[0],
                                 Ops[1], "constexpr", InsertBB);
      if (isa<OverflowingBinaryOperator>(I)) {
        if (BC->Flags & OverflowingBinaryOperator::NoSignedWrap)
          I->setHasNoSignedWrap();
        if (BC->Flags & OverflowingBinaryOperator::NoUnsignedWrap)
          I->setHasNoUnsignedWrap();
      }
      if (isa<PossiblyExactOperator>(I) &&
          (BC->Flags & PossiblyExactOperator::IsExact))
        I->setIsExact();
    } else {
      switch (BC->Opcode) {
      case BitcodeConstant::ConstantVectorOpcode: {
        Type *IdxTy = Type::getInt32Ty(BC->getContext());
        Value *V = PoisonValue::get(BC->getType());
        for (auto Pair : enumerate(Ops)) {
          Value *Idx = ConstantInt::get(IdxTy, Pair.index());
          V = InsertElementInst::Create(V, Pair.value(), Idx, "constexpr.ins",
                                        InsertBB);
        }
        I = cast<Instruction>(V);
        break;
      }
      case BitcodeConstant::ConstantStructOpcode:
      case BitcodeConstant::ConstantArrayOpcode: {
        Value *V = PoisonValue::get(BC->getType());
        for (auto Pair : enumerate(Ops))
          V = InsertValueInst::Create(V, Pair.value(), Pair.index(),
                                      "constexpr.ins", InsertBB);
        I = cast<Instruction>(V);
        break;
      }
      case Instruction::ICmp:
      case Instruction::FCmp:
        I = CmpInst::Create((Instruction::OtherOps)BC->Opcode,
                            (CmpInst::Predicate)BC->Flags, Ops[0], Ops[1],
                            "constexpr", InsertBB);
        break;
      case Instruction::GetElementPtr:
        I = GetElementPtrInst::Create(BC->SrcElemTy, Ops[0],
                                      ArrayRef(Ops).drop_front(), "constexpr",
                                      InsertBB);
        cast<GetElementPtrInst>(I)->setNoWrapFlags(toGEPNoWrapFlags(BC->Flags));
        break;
      case Instruction::Select:
        I = SelectInst::Create(Ops[0], Ops[1], Ops[2], "constexpr", InsertBB);
        break;
      case Instruction::ExtractElement:
        I = ExtractElementInst::Create(Ops[0], Ops[1], "constexpr", InsertBB);
        break;
      case Instruction::InsertElement:
        I = InsertElementInst::Create(Ops[0], Ops[1], Ops[2], "constexpr",
                                      InsertBB);
        break;
      case Instruction::ShuffleVector:
        I = new ShuffleVectorInst(Ops[0], Ops[1], Ops[2], "constexpr",
                                  InsertBB);
        break;
      default:
        llvm_unreachable("Unhandled bitcode constant");
      }
    }
 
    MaterializedValues.insert({ValID, I});
    Worklist.pop_back();
  }
 
  return MaterializedValues[StartValID];
}
 
Expected<Constant *> BitcodeReader::getValueForInitializer(unsigned ID) {
  Expected<Value *> MaybeV = materializeValue(ID, /* InsertBB */ nullptr);
  if (!MaybeV)
    return MaybeV.takeError();
 
  // Result must be Constant if InsertBB is nullptr.
  return cast<Constant>(MaybeV.get());
}
 
StructType *BitcodeReader::createIdentifiedStructType(LLVMContext &Context,
                                                      StringRef Name) {
  auto *Ret = StructType::create(Context, Name);
  IdentifiedStructTypes.push_back(Ret);
  return Ret;
}
 
StructType *BitcodeReader::createIdentifiedStructType(LLVMContext &Context) {
  auto *Ret = StructType::create(Context);
  IdentifiedStructTypes.push_back(Ret);
  return Ret;
}
 
//===----------------------------------------------------------------------===//
//  Functions for parsing blocks from the bitcode file
//===----------------------------------------------------------------------===//
 
static uint64_t getRawAttributeMask(Attribute::AttrKind Val) {
  switch (Val) {
  case Attribute::EndAttrKinds:
  case Attribute::EmptyKey:
  case Attribute::TombstoneKey:
    llvm_unreachable("Synthetic enumerators which should never get here");
 
  case Attribute::None:            return 0;
  case Attribute::ZExt:            return 1 << 0;
  case Attribute::SExt:            return 1 << 1;
  case Attribute::NoReturn:        return 1 << 2;
  case Attribute::InReg:           return 1 << 3;
  case Attribute::StructRet:       return 1 << 4;
  case Attribute::NoUnwind:        return 1 << 5;
  case Attribute::NoAlias:         return 1 << 6;
  case Attribute::ByVal:           return 1 << 7;
  case Attribute::Nest:            return 1 << 8;
  case Attribute::ReadNone:        return 1 << 9;
  case Attribute::ReadOnly:        return 1 << 10;
  case Attribute::NoInline:        return 1 << 11;
  case Attribute::AlwaysInline:    return 1 << 12;
  case Attribute::OptimizeForSize: return 1 << 13;
  case Attribute::StackProtect:    return 1 << 14;
  case Attribute::StackProtectReq: return 1 << 15;
  case Attribute::Alignment:       return 31 << 16;
  // 1ULL << 21 is NoCapture, which is upgraded separately.
  case Attribute::NoRedZone:       return 1 << 22;
  case Attribute::NoImplicitFloat: return 1 << 23;
  case Attribute::Naked:           return 1 << 24;
  case Attribute::InlineHint:      return 1 << 25;
  case Attribute::StackAlignment:  return 7 << 26;
  case Attribute::ReturnsTwice:    return 1 << 29;
  case Attribute::UWTable:         return 1 << 30;
  case Attribute::NonLazyBind:     return 1U << 31;
  case Attribute::SanitizeAddress: return 1ULL << 32;
  case Attribute::MinSize:         return 1ULL << 33;
  case Attribute::NoDuplicate:     return 1ULL << 34;
  case Attribute::StackProtectStrong: return 1ULL << 35;
  case Attribute::SanitizeThread:  return 1ULL << 36;
  case Attribute::SanitizeMemory:  return 1ULL << 37;
  case Attribute::NoBuiltin:       return 1ULL << 38;
  case Attribute::Returned:        return 1ULL << 39;
  case Attribute::Cold:            return 1ULL << 40;
  case Attribute::Builtin:         return 1ULL << 41;
  case Attribute::OptimizeNone:    return 1ULL << 42;
  case Attribute::InAlloca:        return 1ULL << 43;
  case Attribute::NonNull:         return 1ULL << 44;
  case Attribute::JumpTable:       return 1ULL << 45;
  case Attribute::Convergent:      return 1ULL << 46;
  case Attribute::SafeStack:       return 1ULL << 47;
  case Attribute::NoRecurse:       return 1ULL << 48;
  // 1ULL << 49 is InaccessibleMemOnly, which is upgraded separately.
  // 1ULL << 50 is InaccessibleMemOrArgMemOnly, which is upgraded separately.
  case Attribute::SwiftSelf:       return 1ULL << 51;
  case Attribute::SwiftError:      return 1ULL << 52;
  case Attribute::WriteOnly:       return 1ULL << 53;
  case Attribute::Speculatable:    return 1ULL << 54;
  case Attribute::StrictFP:        return 1ULL << 55;
  case Attribute::SanitizeHWAddress: return 1ULL << 56;
  case Attribute::NoCfCheck:       return 1ULL << 57;
  case Attribute::OptForFuzzing:   return 1ULL << 58;
  case Attribute::ShadowCallStack: return 1ULL << 59;
  case Attribute::SpeculativeLoadHardening:
    return 1ULL << 60;
  case Attribute::ImmArg:
    return 1ULL << 61;
  case Attribute::WillReturn:
    return 1ULL << 62;
  case Attribute::NoFree:
    return 1ULL << 63;
  default:
    // Other attributes are not supported in the raw format,
    // as we ran out of space.
    return 0;
  }
  llvm_unreachable("Unsupported attribute type");
}
 
static void addRawAttributeValue(AttrBuilder &B, uint64_t Val) {
  if (!Val) return;
 
  for (Attribute::AttrKind I = Attribute::None; I != Attribute::EndAttrKinds;
       I = Attribute::AttrKind(I + 1)) {
    if (uint64_t A = (Val & getRawAttributeMask(I))) {
      if (I == Attribute::Alignment)
        B.addAlignmentAttr(1ULL << ((A >> 16) - 1));
      else if (I == Attribute::StackAlignment)
        B.addStackAlignmentAttr(1ULL << ((A >> 26)-1));
      else if (Attribute::isTypeAttrKind(I))
        B.addTypeAttr(I, nullptr); // Type will be auto-upgraded.
      else
        B.addAttribute(I);
    }
  }
}
 
/// This fills an AttrBuilder object with the LLVM attributes that have
/// been decoded from the given integer.
static void decodeLLVMAttributesForBitcode(AttrBuilder &B,
                                           uint64_t EncodedAttrs,
                                           uint64_t AttrIdx) {
  // The alignment is stored as a 16-bit raw value from bits 31--16.  We shift
  // the bits above 31 down by 11 bits.
  unsigned Alignment = (EncodedAttrs & (0xffffULL << 16)) >> 16;
  assert((!Alignment || isPowerOf2_32(Alignment)) &&
         "Alignment must be a power of two.");
 
  if (Alignment)
    B.addAlignmentAttr(Alignment);
 
  uint64_t Attrs = ((EncodedAttrs & (0xfffffULL << 32)) >> 11) |
                   (EncodedAttrs & 0xffff);
 
  if (AttrIdx == AttributeList::FunctionIndex) {
    // Upgrade old memory attributes.
    MemoryEffects ME = MemoryEffects::unknown();
    if (Attrs & (1ULL << 9)) {
      // ReadNone
      Attrs &= ~(1ULL << 9);
      ME &= MemoryEffects::none();
    }
    if (Attrs & (1ULL << 10)) {
      // ReadOnly
      Attrs &= ~(1ULL << 10);
      ME &= MemoryEffects::readOnly();
    }
    if (Attrs & (1ULL << 49)) {
      // InaccessibleMemOnly
      Attrs &= ~(1ULL << 49);
      ME &= MemoryEffects::inaccessibleMemOnly();
    }
    if (Attrs & (1ULL << 50)) {
      // InaccessibleMemOrArgMemOnly
      Attrs &= ~(1ULL << 50);
      ME &= MemoryEffects::inaccessibleOrArgMemOnly();
    }
    if (Attrs & (1ULL << 53)) {
      // WriteOnly
      Attrs &= ~(1ULL << 53);
      ME &= MemoryEffects::writeOnly();
    }
    if (ME != MemoryEffects::unknown())
      B.addMemoryAttr(ME);
  }
 
  // Upgrade nocapture to captures(none).
  if (Attrs & (1ULL << 21)) {
    Attrs &= ~(1ULL << 21);
    B.addCapturesAttr(CaptureInfo::none());
  }
 
  addRawAttributeValue(B, Attrs);
}
 
Error BitcodeReader::parseAttributeBlock() {
  if (Error Err = Stream.EnterSubBlock(bitc::PARAMATTR_BLOCK_ID))
    return Err;
 
  if (!MAttributes.empty())
    return error("Invalid multiple blocks");
 
  SmallVector<uint64_t, 64> Record;
 
  SmallVector<AttributeList, 8> Attrs;
 
  // Read all the records.
  while (true) {
    Expected<BitstreamEntry> MaybeEntry = Stream.advanceSkippingSubblocks();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    BitstreamEntry Entry = MaybeEntry.get();
 
    switch (Entry.Kind) {
    case BitstreamEntry::SubBlock: // Handled for us already.
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock:
      return Error::success();
    case BitstreamEntry::Record:
      // The interesting case.
      break;
    }
 
    // Read a record.
    Record.clear();
    Expected<unsigned> MaybeRecord = Stream.readRecord(Entry.ID, Record);
    if (!MaybeRecord)
      return MaybeRecord.takeError();
    switch (MaybeRecord.get()) {
    default:  // Default behavior: ignore.
      break;
    case bitc::PARAMATTR_CODE_ENTRY_OLD: // ENTRY: [paramidx0, attr0, ...]
      // Deprecated, but still needed to read old bitcode files.
      if (Record.size() & 1)
        return error("Invalid parameter attribute record");
 
      for (unsigned i = 0, e = Record.size(); i != e; i += 2) {
        AttrBuilder B(Context);
        decodeLLVMAttributesForBitcode(B, Record[i+1], Record[i]);
        Attrs.push_back(AttributeList::get(Context, Record[i], B));
      }
 
      MAttributes.push_back(AttributeList::get(Context, Attrs));
      Attrs.clear();
      break;
    case bitc::PARAMATTR_CODE_ENTRY: // ENTRY: [attrgrp0, attrgrp1, ...]
      for (uint64_t Val : Record)
        Attrs.push_back(MAttributeGroups[Val]);
 
      MAttributes.push_back(AttributeList::get(Context, Attrs));
      Attrs.clear();
      break;
    }
  }
}
 
// Returns Attribute::None on unrecognized codes.
static Attribute::AttrKind getAttrFromCode(uint64_t Code) {
  switch (Code) {
  default:
    return Attribute::None;
  case bitc::ATTR_KIND_ALIGNMENT:
    return Attribute::Alignment;
  case bitc::ATTR_KIND_ALWAYS_INLINE:
    return Attribute::AlwaysInline;
  case bitc::ATTR_KIND_BUILTIN:
    return Attribute::Builtin;
  case bitc::ATTR_KIND_BY_VAL:
    return Attribute::ByVal;
  case bitc::ATTR_KIND_IN_ALLOCA:
    return Attribute::InAlloca;
  case bitc::ATTR_KIND_COLD:
    return Attribute::Cold;
  case bitc::ATTR_KIND_CONVERGENT:
    return Attribute::Convergent;
  case bitc::ATTR_KIND_DISABLE_SANITIZER_INSTRUMENTATION:
    return Attribute::DisableSanitizerInstrumentation;
  case bitc::ATTR_KIND_ELEMENTTYPE:
    return Attribute::ElementType;
  case bitc::ATTR_KIND_FNRETTHUNK_EXTERN:
    return Attribute::FnRetThunkExtern;
  case bitc::ATTR_KIND_INLINE_HINT:
    return Attribute::InlineHint;
  case bitc::ATTR_KIND_IN_REG:
    return Attribute::InReg;
  case bitc::ATTR_KIND_JUMP_TABLE:
    return Attribute::JumpTable;
  case bitc::ATTR_KIND_MEMORY:
    return Attribute::Memory;
  case bitc::ATTR_KIND_NOFPCLASS:
    return Attribute::NoFPClass;
  case bitc::ATTR_KIND_MIN_SIZE:
    return Attribute::MinSize;
  case bitc::ATTR_KIND_NAKED:
    return Attribute::Naked;
  case bitc::ATTR_KIND_NEST:
    return Attribute::Nest;
  case bitc::ATTR_KIND_NO_ALIAS:
    return Attribute::NoAlias;
  case bitc::ATTR_KIND_NO_BUILTIN:
    return Attribute::NoBuiltin;
  case bitc::ATTR_KIND_NO_CALLBACK:
    return Attribute::NoCallback;
  case bitc::ATTR_KIND_NO_DIVERGENCE_SOURCE:
    return Attribute::NoDivergenceSource;
  case bitc::ATTR_KIND_NO_DUPLICATE:
    return Attribute::NoDuplicate;
  case bitc::ATTR_KIND_NOFREE:
    return Attribute::NoFree;
  case bitc::ATTR_KIND_NO_IMPLICIT_FLOAT:
    return Attribute::NoImplicitFloat;
  case bitc::ATTR_KIND_NO_INLINE:
    return Attribute::NoInline;
  case bitc::ATTR_KIND_NO_RECURSE:
    return Attribute::NoRecurse;
  case bitc::ATTR_KIND_NO_MERGE:
    return Attribute::NoMerge;
  case bitc::ATTR_KIND_NON_LAZY_BIND:
    return Attribute::NonLazyBind;
  case bitc::ATTR_KIND_NON_NULL:
    return Attribute::NonNull;
  case bitc::ATTR_KIND_DEREFERENCEABLE:
    return Attribute::Dereferenceable;
  case bitc::ATTR_KIND_DEREFERENCEABLE_OR_NULL:
    return Attribute::DereferenceableOrNull;
  case bitc::ATTR_KIND_ALLOC_ALIGN:
    return Attribute::AllocAlign;
  case bitc::ATTR_KIND_ALLOC_KIND:
    return Attribute::AllocKind;
  case bitc::ATTR_KIND_ALLOC_SIZE:
    return Attribute::AllocSize;
  case bitc::ATTR_KIND_ALLOCATED_POINTER:
    return Attribute::AllocatedPointer;
  case bitc::ATTR_KIND_NO_RED_ZONE:
    return Attribute::NoRedZone;
  case bitc::ATTR_KIND_NO_RETURN:
    return Attribute::NoReturn;
  case bitc::ATTR_KIND_NOSYNC:
    return Attribute::NoSync;
  case bitc::ATTR_KIND_NOCF_CHECK:
    return Attribute::NoCfCheck;
  case bitc::ATTR_KIND_NO_PROFILE:
    return Attribute::NoProfile;
  case bitc::ATTR_KIND_SKIP_PROFILE:
    return Attribute::SkipProfile;
  case bitc::ATTR_KIND_NO_UNWIND:
    return Attribute::NoUnwind;
  case bitc::ATTR_KIND_NO_SANITIZE_BOUNDS:
    return Attribute::NoSanitizeBounds;
  case bitc::ATTR_KIND_NO_SANITIZE_COVERAGE:
    return Attribute::NoSanitizeCoverage;
  case bitc::ATTR_KIND_NULL_POINTER_IS_VALID:
    return Attribute::NullPointerIsValid;
  case bitc::ATTR_KIND_OPTIMIZE_FOR_DEBUGGING:
    return Attribute::OptimizeForDebugging;
  case bitc::ATTR_KIND_OPT_FOR_FUZZING:
    return Attribute::OptForFuzzing;
  case bitc::ATTR_KIND_OPTIMIZE_FOR_SIZE:
    return Attribute::OptimizeForSize;
  case bitc::ATTR_KIND_OPTIMIZE_NONE:
    return Attribute::OptimizeNone;
  case bitc::ATTR_KIND_READ_NONE:
    return Attribute::ReadNone;
  case bitc::ATTR_KIND_READ_ONLY:
    return Attribute::ReadOnly;
  case bitc::ATTR_KIND_RETURNED:
    return Attribute::Returned;
  case bitc::ATTR_KIND_RETURNS_TWICE:
    return Attribute::ReturnsTwice;
  case bitc::ATTR_KIND_S_EXT:
    return Attribute::SExt;
  case bitc::ATTR_KIND_SPECULATABLE:
    return Attribute::Speculatable;
  case bitc::ATTR_KIND_STACK_ALIGNMENT:
    return Attribute::StackAlignment;
  case bitc::ATTR_KIND_STACK_PROTECT:
    return Attribute::StackProtect;
  case bitc::ATTR_KIND_STACK_PROTECT_REQ:
    return Attribute::StackProtectReq;
  case bitc::ATTR_KIND_STACK_PROTECT_STRONG:
    return Attribute::StackProtectStrong;
  case bitc::ATTR_KIND_SAFESTACK:
    return Attribute::SafeStack;
  case bitc::ATTR_KIND_SHADOWCALLSTACK:
    return Attribute::ShadowCallStack;
  case bitc::ATTR_KIND_STRICT_FP:
    return Attribute::StrictFP;
  case bitc::ATTR_KIND_STRUCT_RET:
    return Attribute::StructRet;
  case bitc::ATTR_KIND_SANITIZE_ADDRESS:
    return Attribute::SanitizeAddress;
  case bitc::ATTR_KIND_SANITIZE_HWADDRESS:
    return Attribute::SanitizeHWAddress;
  case bitc::ATTR_KIND_SANITIZE_THREAD:
    return Attribute::SanitizeThread;
  case bitc::ATTR_KIND_SANITIZE_TYPE:
    return Attribute::SanitizeType;
  case bitc::ATTR_KIND_SANITIZE_MEMORY:
    return Attribute::SanitizeMemory;
  case bitc::ATTR_KIND_SANITIZE_NUMERICAL_STABILITY:
    return Attribute::SanitizeNumericalStability;
  case bitc::ATTR_KIND_SANITIZE_REALTIME:
    return Attribute::SanitizeRealtime;
  case bitc::ATTR_KIND_SANITIZE_REALTIME_BLOCKING:
    return Attribute::SanitizeRealtimeBlocking;
  case bitc::ATTR_KIND_SANITIZE_ALLOC_TOKEN:
    return Attribute::SanitizeAllocToken;
  case bitc::ATTR_KIND_SPECULATIVE_LOAD_HARDENING:
    return Attribute::SpeculativeLoadHardening;
  case bitc::ATTR_KIND_SWIFT_ERROR:
    return Attribute::SwiftError;
  case bitc::ATTR_KIND_SWIFT_SELF:
    return Attribute::SwiftSelf;
  case bitc::ATTR_KIND_SWIFT_ASYNC:
    return Attribute::SwiftAsync;
  case bitc::ATTR_KIND_UW_TABLE:
    return Attribute::UWTable;
  case bitc::ATTR_KIND_VSCALE_RANGE:
    return Attribute::VScaleRange;
  case bitc::ATTR_KIND_WILLRETURN:
    return Attribute::WillReturn;
  case bitc::ATTR_KIND_WRITEONLY:
    return Attribute::WriteOnly;
  case bitc::ATTR_KIND_Z_EXT:
    return Attribute::ZExt;
  case bitc::ATTR_KIND_IMMARG:
    return Attribute::ImmArg;
  case bitc::ATTR_KIND_SANITIZE_MEMTAG:
    return Attribute::SanitizeMemTag;
  case bitc::ATTR_KIND_PREALLOCATED:
    return Attribute::Preallocated;
  case bitc::ATTR_KIND_NOUNDEF:
    return Attribute::NoUndef;
  case bitc::ATTR_KIND_BYREF:
    return Attribute::ByRef;
  case bitc::ATTR_KIND_MUSTPROGRESS:
    return Attribute::MustProgress;
  case bitc::ATTR_KIND_HOT:
    return Attribute::Hot;
  case bitc::ATTR_KIND_PRESPLIT_COROUTINE:
    return Attribute::PresplitCoroutine;
  case bitc::ATTR_KIND_WRITABLE:
    return Attribute::Writable;
  case bitc::ATTR_KIND_CORO_ONLY_DESTROY_WHEN_COMPLETE:
    return Attribute::CoroDestroyOnlyWhenComplete;
  case bitc::ATTR_KIND_DEAD_ON_UNWIND:
    return Attribute::DeadOnUnwind;
  case bitc::ATTR_KIND_RANGE:
    return Attribute::Range;
  case bitc::ATTR_KIND_INITIALIZES:
    return Attribute::Initializes;
  case bitc::ATTR_KIND_CORO_ELIDE_SAFE:
    return Attribute::CoroElideSafe;
  case bitc::ATTR_KIND_NO_EXT:
    return Attribute::NoExt;
  case bitc::ATTR_KIND_CAPTURES:
    return Attribute::Captures;
  case bitc::ATTR_KIND_DEAD_ON_RETURN:
    return Attribute::DeadOnReturn;
  case bitc::ATTR_KIND_NO_CREATE_UNDEF_OR_POISON:
    return Attribute::NoCreateUndefOrPoison;
  case bitc::ATTR_KIND_DENORMAL_FPENV:
    return Attribute::DenormalFPEnv;
  case bitc::ATTR_KIND_NOOUTLINE:
    return Attribute::NoOutline;
  }
}
 
Error BitcodeReader::parseAlignmentValue(uint64_t Exponent,
                                         MaybeAlign &Alignment) {
  // Note: Alignment in bitcode files is incremented by 1, so that zero
  // can be used for default alignment.
  if (Exponent > Value::MaxAlignmentExponent + 1)
    return error("Invalid alignment value");
  Alignment = decodeMaybeAlign(Exponent);
  return Error::success();
}
 
Error BitcodeReader::parseAttrKind(uint64_t Code, Attribute::AttrKind *Kind) {
  *Kind = getAttrFromCode(Code);
  if (*Kind == Attribute::None)
    return error("Unknown attribute kind (" + Twine(Code) + ")");
  return Error::success();
}
 
static bool upgradeOldMemoryAttribute(MemoryEffects &ME, uint64_t EncodedKind) {
  switch (EncodedKind) {
  case bitc::ATTR_KIND_READ_NONE:
    ME &= MemoryEffects::none();
    return true;
  case bitc::ATTR_KIND_READ_ONLY:
    ME &= MemoryEffects::readOnly();
    return true;
  case bitc::ATTR_KIND_WRITEONLY:
    ME &= MemoryEffects::writeOnly();
    return true;
  case bitc::ATTR_KIND_ARGMEMONLY:
    ME &= MemoryEffects::argMemOnly();
    return true;
  case bitc::ATTR_KIND_INACCESSIBLEMEM_ONLY:
    ME &= MemoryEffects::inaccessibleMemOnly();
    return true;
  case bitc::ATTR_KIND_INACCESSIBLEMEM_OR_ARGMEMONLY:
    ME &= MemoryEffects::inaccessibleOrArgMemOnly();
    return true;
  default:
    return false;
  }
}
 
Error BitcodeReader::parseAttributeGroupBlock() {
  if (Error Err = Stream.EnterSubBlock(bitc::PARAMATTR_GROUP_BLOCK_ID))
    return Err;
 
  if (!MAttributeGroups.empty())
    return error("Invalid multiple blocks");
 
  SmallVector<uint64_t, 64> Record;
 
  // Read all the records.
  while (true) {
    Expected<BitstreamEntry> MaybeEntry = Stream.advanceSkippingSubblocks();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    BitstreamEntry Entry = MaybeEntry.get();
 
    switch (Entry.Kind) {
    case BitstreamEntry::SubBlock: // Handled for us already.
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock:
      return Error::success();
    case BitstreamEntry::Record:
      // The interesting case.
      break;
    }
 
    // Read a record.
    Record.clear();
    Expected<unsigned> MaybeRecord = Stream.readRecord(Entry.ID, Record);
    if (!MaybeRecord)
      return MaybeRecord.takeError();
    switch (MaybeRecord.get()) {
    default:  // Default behavior: ignore.
      break;
    case bitc::PARAMATTR_GRP_CODE_ENTRY: { // ENTRY: [grpid, idx, a0, a1, ...]
      if (Record.size() < 3)
        return error("Invalid grp record");
 
      uint64_t GrpID = Record[0];
      uint64_t Idx = Record[1]; // Index of the object this attribute refers to.
 
      AttrBuilder B(Context);
      MemoryEffects ME = MemoryEffects::unknown();
      for (unsigned i = 2, e = Record.size(); i != e; ++i) {
        if (Record[i] == 0) {        // Enum attribute
          Attribute::AttrKind Kind;
          uint64_t EncodedKind = Record[++i];
          if (Idx == AttributeList::FunctionIndex &&
              upgradeOldMemoryAttribute(ME, EncodedKind))
            continue;
 
          if (EncodedKind == bitc::ATTR_KIND_NO_CAPTURE) {
            B.addCapturesAttr(CaptureInfo::none());
            continue;
          }
 
          if (Error Err = parseAttrKind(EncodedKind, &Kind))
            return Err;
 
          // Upgrade old-style byval attribute to one with a type, even if it's
          // nullptr. We will have to insert the real type when we associate
          // this AttributeList with a function.
          if (Kind == Attribute::ByVal)
            B.addByValAttr(nullptr);
          else if (Kind == Attribute::StructRet)
            B.addStructRetAttr(nullptr);
          else if (Kind == Attribute::InAlloca)
            B.addInAllocaAttr(nullptr);
          else if (Kind == Attribute::UWTable)
            B.addUWTableAttr(UWTableKind::Default);
          else if (Kind == Attribute::DeadOnReturn)
            B.addDeadOnReturnAttr(DeadOnReturnInfo());
          else if (Attribute::isEnumAttrKind(Kind))
            B.addAttribute(Kind);
          else
            return error("Not an enum attribute");
        } else if (Record[i] == 1) { // Integer attribute
          Attribute::AttrKind Kind;
          if (Error Err = parseAttrKind(Record[++i], &Kind))
            return Err;
          if (!Attribute::isIntAttrKind(Kind))
            return error("Not an int attribute");
          if (Kind == Attribute::Alignment)
            B.addAlignmentAttr(Record[++i]);
          else if (Kind == Attribute::StackAlignment)
            B.addStackAlignmentAttr(Record[++i]);
          else if (Kind == Attribute::Dereferenceable)
            B.addDereferenceableAttr(Record[++i]);
          else if (Kind == Attribute::DereferenceableOrNull)
            B.addDereferenceableOrNullAttr(Record[++i]);
          else if (Kind == Attribute::DeadOnReturn)
            B.addDeadOnReturnAttr(
                DeadOnReturnInfo::createFromIntValue(Record[++i]));
          else if (Kind == Attribute::AllocSize)
            B.addAllocSizeAttrFromRawRepr(Record[++i]);
          else if (Kind == Attribute::VScaleRange)
            B.addVScaleRangeAttrFromRawRepr(Record[++i]);
          else if (Kind == Attribute::UWTable)
            B.addUWTableAttr(UWTableKind(Record[++i]));
          else if (Kind == Attribute::AllocKind)
            B.addAllocKindAttr(static_cast<AllocFnKind>(Record[++i]));
          else if (Kind == Attribute::Memory) {
            uint64_t EncodedME = Record[++i];
            const uint8_t Version = (EncodedME >> 56);
            if (Version == 0) {
              // Errno memory location was previously encompassed into default
              // memory. Ensure this is taken into account while reconstructing
              // the memory attribute prior to its introduction.
              ModRefInfo ArgMem = ModRefInfo((EncodedME >> 0) & 3);
              ModRefInfo InaccessibleMem = ModRefInfo((EncodedME >> 2) & 3);
              ModRefInfo OtherMem = ModRefInfo((EncodedME >> 4) & 3);
              auto ME = MemoryEffects::inaccessibleMemOnly(InaccessibleMem) |
                        MemoryEffects::argMemOnly(ArgMem) |
                        MemoryEffects::errnoMemOnly(OtherMem) |
                        MemoryEffects::otherMemOnly(OtherMem);
              B.addMemoryAttr(ME);
            } else {
              // Construct the memory attribute directly from the encoded base
              // on newer versions.
              B.addMemoryAttr(MemoryEffects::createFromIntValue(
                  EncodedME & 0x00FFFFFFFFFFFFFFULL));
            }
          } else if (Kind == Attribute::Captures)
            B.addCapturesAttr(CaptureInfo::createFromIntValue(Record[++i]));
          else if (Kind == Attribute::NoFPClass)
            B.addNoFPClassAttr(
                static_cast<FPClassTest>(Record[++i] & fcAllFlags));
          else if (Kind == Attribute::DenormalFPEnv) {
            B.addDenormalFPEnvAttr(
                DenormalFPEnv::createFromIntValue(Record[++i]));
          }
        } else if (Record[i] == 3 || Record[i] == 4) { // String attribute
          bool HasValue = (Record[i++] == 4);
          SmallString<64> KindStr;
          SmallString<64> ValStr;
 
          while (Record[i] != 0 && i != e)
            KindStr += Record[i++];
          assert(Record[i] == 0 && "Kind string not null terminated");
 
          if (HasValue) {
            // Has a value associated with it.
            ++i; // Skip the '0' that terminates the "kind" string.
            while (Record[i] != 0 && i != e)
              ValStr += Record[i++];
            assert(Record[i] == 0 && "Value string not null terminated");
          }
 
          B.addAttribute(KindStr.str(), ValStr.str());
        } else if (Record[i] == 5 || Record[i] == 6) {
          bool HasType = Record[i] == 6;
          Attribute::AttrKind Kind;
          if (Error Err = parseAttrKind(Record[++i], &Kind))
            return Err;
          if (!Attribute::isTypeAttrKind(Kind))
            return error("Not a type attribute");
 
          B.addTypeAttr(Kind, HasType ? getTypeByID(Record[++i]) : nullptr);
        } else if (Record[i] == 7) {
          Attribute::AttrKind Kind;
 
          i++;
          if (Error Err = parseAttrKind(Record[i++], &Kind))
            return Err;
          if (!Attribute::isConstantRangeAttrKind(Kind))
            return error("Not a ConstantRange attribute");
 
          Expected<ConstantRange> MaybeCR =
              readBitWidthAndConstantRange(Record, i);
          if (!MaybeCR)
            return MaybeCR.takeError();
          i--;
 
          B.addConstantRangeAttr(Kind, MaybeCR.get());
        } else if (Record[i] == 8) {
          Attribute::AttrKind Kind;
 
          i++;
          if (Error Err = parseAttrKind(Record[i++], &Kind))
            return Err;
          if (!Attribute::isConstantRangeListAttrKind(Kind))
            return error("Not a constant range list attribute");
 
          SmallVector<ConstantRange, 2> Val;
          if (i + 2 > e)
            return error("Too few records for constant range list");
          unsigned RangeSize = Record[i++];
          unsigned BitWidth = Record[i++];
          for (unsigned Idx = 0; Idx < RangeSize; ++Idx) {
            Expected<ConstantRange> MaybeCR =
                readConstantRange(Record, i, BitWidth);
            if (!MaybeCR)
              return MaybeCR.takeError();
            Val.push_back(MaybeCR.get());
          }
          i--;
 
          if (!ConstantRangeList::isOrderedRanges(Val))
            return error("Invalid (unordered or overlapping) range list");
          B.addConstantRangeListAttr(Kind, Val);
        } else {
          return error("Invalid attribute group entry");
        }
      }
 
      if (ME != MemoryEffects::unknown())
        B.addMemoryAttr(ME);
 
      UpgradeAttributes(B);
      MAttributeGroups[GrpID] = AttributeList::get(Context, Idx, B);
      break;
    }
    }
  }
}
 
Error BitcodeReader::parseTypeTable() {
  if (Error Err = Stream.EnterSubBlock(bitc::TYPE_BLOCK_ID_NEW))
    return Err;
 
  return parseTypeTableBody();
}
 
Error BitcodeReader::parseTypeTableBody() {
  if (!TypeList.empty())
    return error("Invalid multiple blocks");
 
  SmallVector<uint64_t, 64> Record;
  unsigned NumRecords = 0;
 
  SmallString<64> TypeName;
 
  // Read all the records for this type table.
  while (true) {
    Expected<BitstreamEntry> MaybeEntry = Stream.advanceSkippingSubblocks();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    BitstreamEntry Entry = MaybeEntry.get();
 
    switch (Entry.Kind) {
    case BitstreamEntry::SubBlock: // Handled for us already.
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock:
      if (NumRecords != TypeList.size())
        return error("Malformed block");
      return Error::success();
    case BitstreamEntry::Record:
      // The interesting case.
      break;
    }
 
    // Read a record.
    Record.clear();
    Type *ResultTy = nullptr;
    SmallVector<unsigned> ContainedIDs;
    Expected<unsigned> MaybeRecord = Stream.readRecord(Entry.ID, Record);
    if (!MaybeRecord)
      return MaybeRecord.takeError();
    switch (MaybeRecord.get()) {
    default:
      return error("Invalid value");
    case bitc::TYPE_CODE_NUMENTRY: // TYPE_CODE_NUMENTRY: [numentries]
      // TYPE_CODE_NUMENTRY contains a count of the number of types in the
      // type list.  This allows us to reserve space.
      if (Record.empty())
        return error("Invalid numentry record");
      TypeList.resize(Record[0]);
      continue;
    case bitc::TYPE_CODE_VOID:      // VOID
      ResultTy = Type::getVoidTy(Context);
      break;
    case bitc::TYPE_CODE_HALF:     // HALF
      ResultTy = Type::getHalfTy(Context);
      break;
    case bitc::TYPE_CODE_BFLOAT:    // BFLOAT
      ResultTy = Type::getBFloatTy(Context);
      break;
    case bitc::TYPE_CODE_FLOAT:     // FLOAT
      ResultTy = Type::getFloatTy(Context);
      break;
    case bitc::TYPE_CODE_DOUBLE:    // DOUBLE
      ResultTy = Type::getDoubleTy(Context);
      break;
    case bitc::TYPE_CODE_X86_FP80:  // X86_FP80
      ResultTy = Type::getX86_FP80Ty(Context);
      break;
    case bitc::TYPE_CODE_FP128:     // FP128
      ResultTy = Type::getFP128Ty(Context);
      break;
    case bitc::TYPE_CODE_PPC_FP128: // PPC_FP128
      ResultTy = Type::getPPC_FP128Ty(Context);
      break;
    case bitc::TYPE_CODE_LABEL:     // LABEL
      ResultTy = Type::getLabelTy(Context);
      break;
    case bitc::TYPE_CODE_METADATA:  // METADATA
      ResultTy = Type::getMetadataTy(Context);
      break;
    case bitc::TYPE_CODE_X86_MMX:   // X86_MMX
      // Deprecated: decodes as <1 x i64>
      ResultTy =
          llvm::FixedVectorType::get(llvm::IntegerType::get(Context, 64), 1);
      break;
    case bitc::TYPE_CODE_X86_AMX:   // X86_AMX
      ResultTy = Type::getX86_AMXTy(Context);
      break;
    case bitc::TYPE_CODE_TOKEN:     // TOKEN
      ResultTy = Type::getTokenTy(Context);
      break;
    case bitc::TYPE_CODE_INTEGER: { // INTEGER: [width]
      if (Record.empty())
        return error("Invalid integer record");
 
      uint64_t NumBits = Record[0];
      if (NumBits < IntegerType::MIN_INT_BITS ||
          NumBits > IntegerType::MAX_INT_BITS)
        return error("Bitwidth for integer type out of range");
      ResultTy = IntegerType::get(Context, NumBits);
      break;
    }
    case bitc::TYPE_CODE_POINTER: { // POINTER: [pointee type] or
                                    //          [pointee type, address space]
      if (Record.empty())
        return error("Invalid pointer record");
      unsigned AddressSpace = 0;
      if (Record.size() == 2)
        AddressSpace = Record[1];
      ResultTy = getTypeByID(Record[0]);
      if (!ResultTy ||
          !PointerType::isValidElementType(ResultTy))
        return error("Invalid type");
      ContainedIDs.push_back(Record[0]);
      ResultTy = PointerType::get(ResultTy->getContext(), AddressSpace);
      break;
    }
    case bitc::TYPE_CODE_OPAQUE_POINTER: { // OPAQUE_POINTER: [addrspace]
      if (Record.size() != 1)
        return error("Invalid opaque pointer record");
      unsigned AddressSpace = Record[0];
      ResultTy = PointerType::get(Context, AddressSpace);
      break;
    }
    case bitc::TYPE_CODE_FUNCTION_OLD: {
      // Deprecated, but still needed to read old bitcode files.
      // FUNCTION: [vararg, attrid, retty, paramty x N]
      if (Record.size() < 3)
        return error("Invalid function record");
      SmallVector<Type*, 8> ArgTys;
      for (unsigned i = 3, e = Record.size(); i != e; ++i) {
        if (Type *T = getTypeByID(Record[i]))
          ArgTys.push_back(T);
        else
          break;
      }
 
      ResultTy = getTypeByID(Record[2]);
      if (!ResultTy || ArgTys.size() < Record.size()-3)
        return error("Invalid type");
 
      ContainedIDs.append(Record.begin() + 2, Record.end());
      ResultTy = FunctionType::get(ResultTy, ArgTys, Record[0]);
      break;
    }
    case bitc::TYPE_CODE_FUNCTION: {
      // FUNCTION: [vararg, retty, paramty x N]
      if (Record.size() < 2)
        return error("Invalid function record");
      SmallVector<Type*, 8> ArgTys;
      for (unsigned i = 2, e = Record.size(); i != e; ++i) {
        if (Type *T = getTypeByID(Record[i])) {
          if (!FunctionType::isValidArgumentType(T))
            return error("Invalid function argument type");
          ArgTys.push_back(T);
        }
        else
          break;
      }
 
      ResultTy = getTypeByID(Record[1]);
      if (!ResultTy || ArgTys.size() < Record.size()-2)
        return error("Invalid type");
 
      ContainedIDs.append(Record.begin() + 1, Record.end());
      ResultTy = FunctionType::get(ResultTy, ArgTys, Record[0]);
      break;
    }
    case bitc::TYPE_CODE_STRUCT_ANON: {  // STRUCT: [ispacked, eltty x N]
      if (Record.empty())
        return error("Invalid anon struct record");
      SmallVector<Type*, 8> EltTys;
      for (unsigned i = 1, e = Record.size(); i != e; ++i) {
        if (Type *T = getTypeByID(Record[i]))
          EltTys.push_back(T);
        else
          break;
      }
      if (EltTys.size() != Record.size()-1)
        return error("Invalid type");
      ContainedIDs.append(Record.begin() + 1, Record.end());
      ResultTy = StructType::get(Context, EltTys, Record[0]);
      break;
    }
    case bitc::TYPE_CODE_STRUCT_NAME:   // STRUCT_NAME: [strchr x N]
      if (convertToString(Record, 0, TypeName))
        return error("Invalid struct name record");
      continue;
 
    case bitc::TYPE_CODE_STRUCT_NAMED: { // STRUCT: [ispacked, eltty x N]
      if (Record.empty())
        return error("Invalid named struct record");
 
      if (NumRecords >= TypeList.size())
        return error("Invalid TYPE table");
 
      // Check to see if this was forward referenced, if so fill in the temp.
      StructType *Res = cast_or_null<StructType>(TypeList[NumRecords]);
      if (Res) {
        Res->setName(TypeName);
        TypeList[NumRecords] = nullptr;
      } else  // Otherwise, create a new struct.
        Res = createIdentifiedStructType(Context, TypeName);
      TypeName.clear();
 
      SmallVector<Type*, 8> EltTys;
      for (unsigned i = 1, e = Record.size(); i != e; ++i) {
        if (Type *T = getTypeByID(Record[i]))
          EltTys.push_back(T);
        else
          break;
      }
      if (EltTys.size() != Record.size()-1)
        return error("Invalid named struct record");
      if (auto E = Res->setBodyOrError(EltTys, Record[0]))
        return E;
      ContainedIDs.append(Record.begin() + 1, Record.end());
      ResultTy = Res;
      break;
    }
    case bitc::TYPE_CODE_OPAQUE: {       // OPAQUE: []
      if (Record.size() != 1)
        return error("Invalid opaque type record");
 
      if (NumRecords >= TypeList.size())
        return error("Invalid TYPE table");
 
      // Check to see if this was forward referenced, if so fill in the temp.
      StructType *Res = cast_or_null<StructType>(TypeList[NumRecords]);
      if (Res) {
        Res->setName(TypeName);
        TypeList[NumRecords] = nullptr;
      } else  // Otherwise, create a new struct with no body.
        Res = createIdentifiedStructType(Context, TypeName);
      TypeName.clear();
      ResultTy = Res;
      break;
    }
    case bitc::TYPE_CODE_TARGET_TYPE: { // TARGET_TYPE: [NumTy, Tys..., Ints...]
      if (Record.size() < 1)
        return error("Invalid target extension type record");
 
      if (NumRecords >= TypeList.size())
        return error("Invalid TYPE table");
 
      if (Record[0] >= Record.size())
        return error("Too many type parameters");
 
      unsigned NumTys = Record[0];
      SmallVector<Type *, 4> TypeParams;
      SmallVector<unsigned, 8> IntParams;
      for (unsigned i = 0; i < NumTys; i++) {
        if (Type *T = getTypeByID(Record[i + 1]))
          TypeParams.push_back(T);
        else
          return error("Invalid type");
      }
 
      for (unsigned i = NumTys + 1, e = Record.size(); i < e; i++) {
        if (Record[i] > UINT_MAX)
          return error("Integer parameter too large");
        IntParams.push_back(Record[i]);
      }
      auto TTy =
          TargetExtType::getOrError(Context, TypeName, TypeParams, IntParams);
      if (auto E = TTy.takeError())
        return E;
      ResultTy = *TTy;
      TypeName.clear();
      break;
    }
    case bitc::TYPE_CODE_ARRAY:     // ARRAY: [numelts, eltty]
      if (Record.size() < 2)
        return error("Invalid array type record");
      ResultTy = getTypeByID(Record[1]);
      if (!ResultTy || !ArrayType::isValidElementType(ResultTy))
        return error("Invalid type");
      ContainedIDs.push_back(Record[1]);
      ResultTy = ArrayType::get(ResultTy, Record[0]);
      break;
    case bitc::TYPE_CODE_VECTOR:    // VECTOR: [numelts, eltty] or
                                    //         [numelts, eltty, scalable]
      if (Record.size() < 2)
        return error("Invalid vector type record");
      if (Record[0] == 0)
        return error("Invalid vector length");
      ResultTy = getTypeByID(Record[1]);
      if (!ResultTy || !VectorType::isValidElementType(ResultTy))
        return error("Invalid type");
      bool Scalable = Record.size() > 2 ? Record[2] : false;
      ContainedIDs.push_back(Record[1]);
      ResultTy = VectorType::get(ResultTy, Record[0], Scalable);
      break;
    }
 
    if (NumRecords >= TypeList.size())
      return error("Invalid TYPE table");
    if (TypeList[NumRecords])
      return error(
          "Invalid TYPE table: Only named structs can be forward referenced");
    assert(ResultTy && "Didn't read a type?");
    TypeList[NumRecords] = ResultTy;
    if (!ContainedIDs.empty())
      ContainedTypeIDs[NumRecords] = std::move(ContainedIDs);
    ++NumRecords;
  }
}
 
Error BitcodeReader::parseOperandBundleTags() {
  if (Error Err = Stream.EnterSubBlock(bitc::OPERAND_BUNDLE_TAGS_BLOCK_ID))
    return Err;
 
  if (!BundleTags.empty())
    return error("Invalid multiple blocks");
 
  SmallVector<uint64_t, 64> Record;
 
  while (true) {
    Expected<BitstreamEntry> MaybeEntry = Stream.advanceSkippingSubblocks();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    BitstreamEntry Entry = MaybeEntry.get();
 
    switch (Entry.Kind) {
    case BitstreamEntry::SubBlock: // Handled for us already.
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock:
      return Error::success();
    case BitstreamEntry::Record:
      // The interesting case.
      break;
    }
 
    // Tags are implicitly mapped to integers by their order.
 
    Expected<unsigned> MaybeRecord = Stream.readRecord(Entry.ID, Record);
    if (!MaybeRecord)
      return MaybeRecord.takeError();
    if (MaybeRecord.get() != bitc::OPERAND_BUNDLE_TAG)
      return error("Invalid operand bundle record");
 
    // OPERAND_BUNDLE_TAG: [strchr x N]
    BundleTags.emplace_back();
    if (convertToString(Record, 0, BundleTags.back()))
      return error("Invalid operand bundle record");
    Record.clear();
  }
}
 
Error BitcodeReader::parseSyncScopeNames() {
  if (Error Err = Stream.EnterSubBlock(bitc::SYNC_SCOPE_NAMES_BLOCK_ID))
    return Err;
 
  if (!SSIDs.empty())
    return error("Invalid multiple synchronization scope names blocks");
 
  SmallVector<uint64_t, 64> Record;
  while (true) {
    Expected<BitstreamEntry> MaybeEntry = Stream.advanceSkippingSubblocks();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    BitstreamEntry Entry = MaybeEntry.get();
 
    switch (Entry.Kind) {
    case BitstreamEntry::SubBlock: // Handled for us already.
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock:
      if (SSIDs.empty())
        return error("Invalid empty synchronization scope names block");
      return Error::success();
    case BitstreamEntry::Record:
      // The interesting case.
      break;
    }
 
    // Synchronization scope names are implicitly mapped to synchronization
    // scope IDs by their order.
 
    Expected<unsigned> MaybeRecord = Stream.readRecord(Entry.ID, Record);
    if (!MaybeRecord)
      return MaybeRecord.takeError();
    if (MaybeRecord.get() != bitc::SYNC_SCOPE_NAME)
      return error("Invalid sync scope record");
 
    SmallString<16> SSN;
    if (convertToString(Record, 0, SSN))
      return error("Invalid sync scope record");
 
    SSIDs.push_back(Context.getOrInsertSyncScopeID(SSN));
    Record.clear();
  }
}
 
/// Associate a value with its name from the given index in the provided record.
Expected<Value *> BitcodeReader::recordValue(SmallVectorImpl<uint64_t> &Record,
                                             unsigned NameIndex, Triple &TT) {
  SmallString<128> ValueName;
  if (convertToString(Record, NameIndex, ValueName))
    return error("Invalid record");
  unsigned ValueID = Record[0];
  if (ValueID >= ValueList.size() || !ValueList[ValueID])
    return error("Invalid record");
  Value *V = ValueList[ValueID];
 
  StringRef NameStr(ValueName.data(), ValueName.size());
  if (NameStr.contains(0))
    return error("Invalid value name");
  V->setName(NameStr);
  auto *GO = dyn_cast<GlobalObject>(V);
  if (GO && ImplicitComdatObjects.contains(GO) && TT.supportsCOMDAT())
    GO->setComdat(TheModule->getOrInsertComdat(V->getName()));
  return V;
}
 
/// Helper to note and return the current location, and jump to the given
/// offset.
static Expected<uint64_t> jumpToValueSymbolTable(uint64_t Offset,
                                                 BitstreamCursor &Stream) {
  // Save the current parsing location so we can jump back at the end
  // of the VST read.
  uint64_t CurrentBit = Stream.GetCurrentBitNo();
  if (Error JumpFailed = Stream.JumpToBit(Offset * 32))
    return std::move(JumpFailed);
  Expected<BitstreamEntry> MaybeEntry = Stream.advance();
  if (!MaybeEntry)
    return MaybeEntry.takeError();
  if (MaybeEntry.get().Kind != BitstreamEntry::SubBlock ||
      MaybeEntry.get().ID != bitc::VALUE_SYMTAB_BLOCK_ID)
    return error("Expected value symbol table subblock");
  return CurrentBit;
}
 
void BitcodeReader::setDeferredFunctionInfo(unsigned FuncBitcodeOffsetDelta,
                                            Function *F,
                                            ArrayRef<uint64_t> Record) {
  // Note that we subtract 1 here because the offset is relative to one word
  // before the start of the identification or module block, which was
  // historically always the start of the regular bitcode header.
  uint64_t FuncWordOffset = Record[1] - 1;
  uint64_t FuncBitOffset = FuncWordOffset * 32;
  DeferredFunctionInfo[F] = FuncBitOffset + FuncBitcodeOffsetDelta;
  // Set the LastFunctionBlockBit to point to the last function block.
  // Later when parsing is resumed after function materialization,
  // we can simply skip that last function block.
  if (FuncBitOffset > LastFunctionBlockBit)
    LastFunctionBlockBit = FuncBitOffset;
}
 
/// Read a new-style GlobalValue symbol table.
Error BitcodeReader::parseGlobalValueSymbolTable() {
  unsigned FuncBitcodeOffsetDelta =
      Stream.getAbbrevIDWidth() + bitc::BlockIDWidth;
 
  if (Error Err = Stream.EnterSubBlock(bitc::VALUE_SYMTAB_BLOCK_ID))
    return Err;
 
  SmallVector<uint64_t, 64> Record;
  while (true) {
    Expected<BitstreamEntry> MaybeEntry = Stream.advanceSkippingSubblocks();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    BitstreamEntry Entry = MaybeEntry.get();
 
    switch (Entry.Kind) {
    case BitstreamEntry::SubBlock:
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock:
      return Error::success();
    case BitstreamEntry::Record:
      break;
    }
 
    Record.clear();
    Expected<unsigned> MaybeRecord = Stream.readRecord(Entry.ID, Record);
    if (!MaybeRecord)
      return MaybeRecord.takeError();
    switch (MaybeRecord.get()) {
    case bitc::VST_CODE_FNENTRY: { // [valueid, offset]
      unsigned ValueID = Record[0];
      if (ValueID >= ValueList.size() || !ValueList[ValueID])
        return error("Invalid value reference in symbol table");
      setDeferredFunctionInfo(FuncBitcodeOffsetDelta,
                              cast<Function>(ValueList[ValueID]), Record);
      break;
    }
    }
  }
}
 
/// Parse the value symbol table at either the current parsing location or
/// at the given bit offset if provided.
Error BitcodeReader::parseValueSymbolTable(uint64_t Offset) {
  uint64_t CurrentBit;
  // Pass in the Offset to distinguish between calling for the module-level
  // VST (where we want to jump to the VST offset) and the function-level
  // VST (where we don't).
  if (Offset > 0) {
    Expected<uint64_t> MaybeCurrentBit = jumpToValueSymbolTable(Offset, Stream);
    if (!MaybeCurrentBit)
      return MaybeCurrentBit.takeError();
    CurrentBit = MaybeCurrentBit.get();
    // If this module uses a string table, read this as a module-level VST.
    if (UseStrtab) {
      if (Error Err = parseGlobalValueSymbolTable())
        return Err;
      if (Error JumpFailed = Stream.JumpToBit(CurrentBit))
        return JumpFailed;
      return Error::success();
    }
    // Otherwise, the VST will be in a similar format to a function-level VST,
    // and will contain symbol names.
  }
 
  // Compute the delta between the bitcode indices in the VST (the word offset
  // to the word-aligned ENTER_SUBBLOCK for the function block, and that
  // expected by the lazy reader. The reader's EnterSubBlock expects to have
  // already read the ENTER_SUBBLOCK code (size getAbbrevIDWidth) and BlockID
  // (size BlockIDWidth). Note that we access the stream's AbbrevID width here
  // just before entering the VST subblock because: 1) the EnterSubBlock
  // changes the AbbrevID width; 2) the VST block is nested within the same
  // outer MODULE_BLOCK as the FUNCTION_BLOCKs and therefore have the same
  // AbbrevID width before calling EnterSubBlock; and 3) when we want to
  // jump to the FUNCTION_BLOCK using this offset later, we don't want
  // to rely on the stream's AbbrevID width being that of the MODULE_BLOCK.
  unsigned FuncBitcodeOffsetDelta =
      Stream.getAbbrevIDWidth() + bitc::BlockIDWidth;
 
  if (Error Err = Stream.EnterSubBlock(bitc::VALUE_SYMTAB_BLOCK_ID))
    return Err;
 
  SmallVector<uint64_t, 64> Record;
 
  Triple TT(TheModule->getTargetTriple());
 
  // Read all the records for this value table.
  SmallString<128> ValueName;
 
  while (true) {
    Expected<BitstreamEntry> MaybeEntry = Stream.advanceSkippingSubblocks();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    BitstreamEntry Entry = MaybeEntry.get();
 
    switch (Entry.Kind) {
    case BitstreamEntry::SubBlock: // Handled for us already.
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock:
      if (Offset > 0)
        if (Error JumpFailed = Stream.JumpToBit(CurrentBit))
          return JumpFailed;
      return Error::success();
    case BitstreamEntry::Record:
      // The interesting case.
      break;
    }
 
    // Read a record.
    Record.clear();
    Expected<unsigned> MaybeRecord = Stream.readRecord(Entry.ID, Record);
    if (!MaybeRecord)
      return MaybeRecord.takeError();
    switch (MaybeRecord.get()) {
    default:  // Default behavior: unknown type.
      break;
    case bitc::VST_CODE_ENTRY: {  // VST_CODE_ENTRY: [valueid, namechar x N]
      Expected<Value *> ValOrErr = recordValue(Record, 1, TT);
      if (Error Err = ValOrErr.takeError())
        return Err;
      ValOrErr.get();
      break;
    }
    case bitc::VST_CODE_FNENTRY: {
      // VST_CODE_FNENTRY: [valueid, offset, namechar x N]
      Expected<Value *> ValOrErr = recordValue(Record, 2, TT);
      if (Error Err = ValOrErr.takeError())
        return Err;
      Value *V = ValOrErr.get();
 
      // Ignore function offsets emitted for aliases of functions in older
      // versions of LLVM.
      if (auto *F = dyn_cast<Function>(V))
        setDeferredFunctionInfo(FuncBitcodeOffsetDelta, F, Record);
      break;
    }
    case bitc::VST_CODE_BBENTRY: {
      if (convertToString(Record, 1, ValueName))
        return error("Invalid bbentry record");
      BasicBlock *BB = getBasicBlock(Record[0]);
      if (!BB)
        return error("Invalid bbentry record");
 
      BB->setName(ValueName.str());
      ValueName.clear();
      break;
    }
    }
  }
}
 
/// Decode a signed value stored with the sign bit in the LSB for dense VBR
/// encoding.
uint64_t BitcodeReader::decodeSignRotatedValue(uint64_t V) {
  if ((V & 1) == 0)
    return V >> 1;
  if (V != 1)
    return -(V >> 1);
  // There is no such thing as -0 with integers.  "-0" really means MININT.
  return 1ULL << 63;
}
 
/// Resolve all of the initializers for global values and aliases that we can.
Error BitcodeReader::resolveGlobalAndIndirectSymbolInits() {
  std::vector<std::pair<GlobalVariable *, unsigned>> GlobalInitWorklist;
  std::vector<std::pair<GlobalValue *, unsigned>> IndirectSymbolInitWorklist;
  std::vector<FunctionOperandInfo> FunctionOperandWorklist;
 
  GlobalInitWorklist.swap(GlobalInits);
  IndirectSymbolInitWorklist.swap(IndirectSymbolInits);
  FunctionOperandWorklist.swap(FunctionOperands);
 
  while (!GlobalInitWorklist.empty()) {
    unsigned ValID = GlobalInitWorklist.back().second;
    if (ValID >= ValueList.size()) {
      // Not ready to resolve this yet, it requires something later in the file.
      GlobalInits.push_back(GlobalInitWorklist.back());
    } else {
      Expected<Constant *> MaybeC = getValueForInitializer(ValID);
      if (!MaybeC)
        return MaybeC.takeError();
      GlobalInitWorklist.back().first->setInitializer(MaybeC.get());
    }
    GlobalInitWorklist.pop_back();
  }
 
  while (!IndirectSymbolInitWorklist.empty()) {
    unsigned ValID = IndirectSymbolInitWorklist.back().second;
    if (ValID >= ValueList.size()) {
      IndirectSymbolInits.push_back(IndirectSymbolInitWorklist.back());
    } else {
      Expected<Constant *> MaybeC = getValueForInitializer(ValID);
      if (!MaybeC)
        return MaybeC.takeError();
      Constant *C = MaybeC.get();
      GlobalValue *GV = IndirectSymbolInitWorklist.back().first;
      if (auto *GA = dyn_cast<GlobalAlias>(GV)) {
        if (C->getType() != GV->getType())
          return error("Alias and aliasee types don't match");
        GA->setAliasee(C);
      } else if (auto *GI = dyn_cast<GlobalIFunc>(GV)) {
        GI->setResolver(C);
      } else {
        return error("Expected an alias or an ifunc");
      }
    }
    IndirectSymbolInitWorklist.pop_back();
  }
 
  while (!FunctionOperandWorklist.empty()) {
    FunctionOperandInfo &Info = FunctionOperandWorklist.back();
    if (Info.PersonalityFn) {
      unsigned ValID = Info.PersonalityFn - 1;
      if (ValID < ValueList.size()) {
        Expected<Constant *> MaybeC = getValueForInitializer(ValID);
        if (!MaybeC)
          return MaybeC.takeError();
        Info.F->setPersonalityFn(MaybeC.get());
        Info.PersonalityFn = 0;
      }
    }
    if (Info.Prefix) {
      unsigned ValID = Info.Prefix - 1;
      if (ValID < ValueList.size()) {
        Expected<Constant *> MaybeC = getValueForInitializer(ValID);
        if (!MaybeC)
          return MaybeC.takeError();
        Info.F->setPrefixData(MaybeC.get());
        Info.Prefix = 0;
      }
    }
    if (Info.Prologue) {
      unsigned ValID = Info.Prologue - 1;
      if (ValID < ValueList.size()) {
        Expected<Constant *> MaybeC = getValueForInitializer(ValID);
        if (!MaybeC)
          return MaybeC.takeError();
        Info.F->setPrologueData(MaybeC.get());
        Info.Prologue = 0;
      }
    }
    if (Info.PersonalityFn || Info.Prefix || Info.Prologue)
      FunctionOperands.push_back(Info);
    FunctionOperandWorklist.pop_back();
  }
 
  return Error::success();
}
 
APInt llvm::readWideAPInt(ArrayRef<uint64_t> Vals, unsigned TypeBits) {
  SmallVector<uint64_t, 8> Words(Vals.size());
  transform(Vals, Words.begin(),
                 BitcodeReader::decodeSignRotatedValue);
 
  return APInt(TypeBits, Words);
}
 
Error BitcodeReader::parseConstants() {
  if (Error Err = Stream.EnterSubBlock(bitc::CONSTANTS_BLOCK_ID))
    return Err;
 
  SmallVector<uint64_t, 64> Record;
 
  // Read all the records for this value table.
  Type *CurTy = Type::getInt32Ty(Context);
  unsigned Int32TyID = getVirtualTypeID(CurTy);
  unsigned CurTyID = Int32TyID;
  Type *CurElemTy = nullptr;
  unsigned NextCstNo = ValueList.size();
 
  while (true) {
    Expected<BitstreamEntry> MaybeEntry = Stream.advanceSkippingSubblocks();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    BitstreamEntry Entry = MaybeEntry.get();
 
    switch (Entry.Kind) {
    case BitstreamEntry::SubBlock: // Handled for us already.
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock:
      if (NextCstNo != ValueList.size())
        return error("Invalid constant reference");
      return Error::success();
    case BitstreamEntry::Record:
      // The interesting case.
      break;
    }
 
    // Read a record.
    Record.clear();
    Type *VoidType = Type::getVoidTy(Context);
    Value *V = nullptr;
    Expected<unsigned> MaybeBitCode = Stream.readRecord(Entry.ID, Record);
    if (!MaybeBitCode)
      return MaybeBitCode.takeError();
    switch (unsigned BitCode = MaybeBitCode.get()) {
    default:  // Default behavior: unknown constant
    case bitc::CST_CODE_UNDEF:     // UNDEF
      V = UndefValue::get(CurTy);
      break;
    case bitc::CST_CODE_POISON:    // POISON
      V = PoisonValue::get(CurTy);
      break;
    case bitc::CST_CODE_SETTYPE:   // SETTYPE: [typeid]
      if (Record.empty())
        return error("Invalid settype record");
      if (Record[0] >= TypeList.size() || !TypeList[Record[0]])
        return error("Invalid settype record");
      if (TypeList[Record[0]] == VoidType)
        return error("Invalid constant type");
      CurTyID = Record[0];
      CurTy = TypeList[CurTyID];
      CurElemTy = getPtrElementTypeByID(CurTyID);
      continue;  // Skip the ValueList manipulation.
    case bitc::CST_CODE_NULL:      // NULL
      if (CurTy->isVoidTy() || CurTy->isFunctionTy() || CurTy->isLabelTy())
        return error("Invalid type for a constant null value");
      if (auto *TETy = dyn_cast<TargetExtType>(CurTy))
        if (!TETy->hasProperty(TargetExtType::HasZeroInit))
          return error("Invalid type for a constant null value");
      V = Constant::getNullValue(CurTy);
      break;
    case bitc::CST_CODE_INTEGER:   // INTEGER: [intval]
      if (!CurTy->isIntOrIntVectorTy() || Record.empty())
        return error("Invalid integer const record");
      V = ConstantInt::getSigned(CurTy, decodeSignRotatedValue(Record[0]));
      break;
    case bitc::CST_CODE_WIDE_INTEGER: {// WIDE_INTEGER: [n x intval]
      if (!CurTy->isIntOrIntVectorTy() || Record.empty())
        return error("Invalid wide integer const record");
 
      auto *ScalarTy = cast<IntegerType>(CurTy->getScalarType());
      APInt VInt = readWideAPInt(Record, ScalarTy->getBitWidth());
      V = ConstantInt::get(CurTy, VInt);
      break;
    }
    case bitc::CST_CODE_FLOAT: {    // FLOAT: [fpval]
      if (Record.empty())
        return error("Invalid float const record");
 
      auto *ScalarTy = CurTy->getScalarType();
      if (ScalarTy->isHalfTy())
        V = ConstantFP::get(CurTy, APFloat(APFloat::IEEEhalf(),
                                           APInt(16, (uint16_t)Record[0])));
      else if (ScalarTy->isBFloatTy())
        V = ConstantFP::get(
            CurTy, APFloat(APFloat::BFloat(), APInt(16, (uint32_t)Record[0])));
      else if (ScalarTy->isFloatTy())
        V = ConstantFP::get(CurTy, APFloat(APFloat::IEEEsingle(),
                                           APInt(32, (uint32_t)Record[0])));
      else if (ScalarTy->isDoubleTy())
        V = ConstantFP::get(
            CurTy, APFloat(APFloat::IEEEdouble(), APInt(64, Record[0])));
      else if (ScalarTy->isX86_FP80Ty()) {
        // Bits are not stored the same way as a normal i80 APInt, compensate.
        uint64_t Rearrange[2];
        Rearrange[0] = (Record[1] & 0xffffLL) | (Record[0] << 16);
        Rearrange[1] = Record[0] >> 48;
        V = ConstantFP::get(
            CurTy, APFloat(APFloat::x87DoubleExtended(), APInt(80, Rearrange)));
      } else if (ScalarTy->isFP128Ty())
        V = ConstantFP::get(CurTy,
                            APFloat(APFloat::IEEEquad(), APInt(128, Record)));
      else if (ScalarTy->isPPC_FP128Ty())
        V = ConstantFP::get(
            CurTy, APFloat(APFloat::PPCDoubleDouble(), APInt(128, Record)));
      else
        V = PoisonValue::get(CurTy);
      break;
    }
 
    case bitc::CST_CODE_AGGREGATE: {// AGGREGATE: [n x value number]
      if (Record.empty())
        return error("Invalid aggregate record");
 
      SmallVector<unsigned, 16> Elts;
      llvm::append_range(Elts, Record);
 
      if (isa<StructType>(CurTy)) {
        V = BitcodeConstant::create(
            Alloc, CurTy, BitcodeConstant::ConstantStructOpcode, Elts);
      } else if (isa<ArrayType>(CurTy)) {
        V = BitcodeConstant::create(Alloc, CurTy,
                                    BitcodeConstant::ConstantArrayOpcode, Elts);
      } else if (isa<VectorType>(CurTy)) {
        V = BitcodeConstant::create(
            Alloc, CurTy, BitcodeConstant::ConstantVectorOpcode, Elts);
      } else {
        V = PoisonValue::get(CurTy);
      }
      break;
    }
    case bitc::CST_CODE_STRING:    // STRING: [values]
    case bitc::CST_CODE_CSTRING: { // CSTRING: [values]
      if (Record.empty())
        return error("Invalid string record");
 
      SmallString<16> Elts(Record.begin(), Record.end());
      V = ConstantDataArray::getString(Context, Elts,
                                       BitCode == bitc::CST_CODE_CSTRING);
      break;
    }
    case bitc::CST_CODE_DATA: {// DATA: [n x value]
      if (Record.empty())
        return error("Invalid data record");
 
      Type *EltTy;
      if (auto *Array = dyn_cast<ArrayType>(CurTy))
        EltTy = Array->getElementType();
      else
        EltTy = cast<VectorType>(CurTy)->getElementType();
      if (EltTy->isIntegerTy(8)) {
        SmallVector<uint8_t, 16> Elts(Record.begin(), Record.end());
        if (isa<VectorType>(CurTy))
          V = ConstantDataVector::get(Context, Elts);
        else
          V = ConstantDataArray::get(Context, Elts);
      } else if (EltTy->isIntegerTy(16)) {
        SmallVector<uint16_t, 16> Elts(Record.begin(), Record.end());
        if (isa<VectorType>(CurTy))
          V = ConstantDataVector::get(Context, Elts);
        else
          V = ConstantDataArray::get(Context, Elts);
      } else if (EltTy->isIntegerTy(32)) {
        SmallVector<uint32_t, 16> Elts(Record.begin(), Record.end());
        if (isa<VectorType>(CurTy))
          V = ConstantDataVector::get(Context, Elts);
        else
          V = ConstantDataArray::get(Context, Elts);
      } else if (EltTy->isIntegerTy(64)) {
        SmallVector<uint64_t, 16> Elts(Record.begin(), Record.end());
        if (isa<VectorType>(CurTy))
          V = ConstantDataVector::get(Context, Elts);
        else
          V = ConstantDataArray::get(Context, Elts);
      } else if (EltTy->isHalfTy()) {
        SmallVector<uint16_t, 16> Elts(Record.begin(), Record.end());
        if (isa<VectorType>(CurTy))
          V = ConstantDataVector::getFP(EltTy, Elts);
        else
          V = ConstantDataArray::getFP(EltTy, Elts);
      } else if (EltTy->isBFloatTy()) {
        SmallVector<uint16_t, 16> Elts(Record.begin(), Record.end());
        if (isa<VectorType>(CurTy))
          V = ConstantDataVector::getFP(EltTy, Elts);
        else
          V = ConstantDataArray::getFP(EltTy, Elts);
      } else if (EltTy->isFloatTy()) {
        SmallVector<uint32_t, 16> Elts(Record.begin(), Record.end());
        if (isa<VectorType>(CurTy))
          V = ConstantDataVector::getFP(EltTy, Elts);
        else
          V = ConstantDataArray::getFP(EltTy, Elts);
      } else if (EltTy->isDoubleTy()) {
        SmallVector<uint64_t, 16> Elts(Record.begin(), Record.end());
        if (isa<VectorType>(CurTy))
          V = ConstantDataVector::getFP(EltTy, Elts);
        else
          V = ConstantDataArray::getFP(EltTy, Elts);
      } else {
        return error("Invalid type for value");
      }
      break;
    }
    case bitc::CST_CODE_CE_UNOP: {  // CE_UNOP: [opcode, opval]
      if (Record.size() < 2)
        return error("Invalid unary op constexpr record");
      int Opc = getDecodedUnaryOpcode(Record[0], CurTy);
      if (Opc < 0) {
        V = PoisonValue::get(CurTy);  // Unknown unop.
      } else {
        V = BitcodeConstant::create(Alloc, CurTy, Opc, (unsigned)Record[1]);
      }
      break;
    }
    case bitc::CST_CODE_CE_BINOP: {  // CE_BINOP: [opcode, opval, opval]
      if (Record.size() < 3)
        return error("Invalid binary op constexpr record");
      int Opc = getDecodedBinaryOpcode(Record[0], CurTy);
      if (Opc < 0) {
        V = PoisonValue::get(CurTy);  // Unknown binop.
      } else {
        uint8_t Flags = 0;
        if (Record.size() >= 4) {
          if (Opc == Instruction::Add ||
              Opc == Instruction::Sub ||
              Opc == Instruction::Mul ||
              Opc == Instruction::Shl) {
            if (Record[3] & (1 << bitc::OBO_NO_SIGNED_WRAP))
              Flags |= OverflowingBinaryOperator::NoSignedWrap;
            if (Record[3] & (1 << bitc::OBO_NO_UNSIGNED_WRAP))
              Flags |= OverflowingBinaryOperator::NoUnsignedWrap;
          } else if (Opc == Instruction::SDiv ||
                     Opc == Instruction::UDiv ||
                     Opc == Instruction::LShr ||
                     Opc == Instruction::AShr) {
            if (Record[3] & (1 << bitc::PEO_EXACT))
              Flags |= PossiblyExactOperator::IsExact;
          }
        }
        V = BitcodeConstant::create(Alloc, CurTy, {(uint8_t)Opc, Flags},
                                    {(unsigned)Record[1], (unsigned)Record[2]});
      }
      break;
    }
    case bitc::CST_CODE_CE_CAST: {  // CE_CAST: [opcode, opty, opval]
      if (Record.size() < 3)
        return error("Invalid cast constexpr record");
      int Opc = getDecodedCastOpcode(Record[0]);
      if (Opc < 0) {
        V = PoisonValue::get(CurTy);  // Unknown cast.
      } else {
        unsigned OpTyID = Record[1];
        Type *OpTy = getTypeByID(OpTyID);
        if (!OpTy)
          return error("Invalid cast constexpr record");
        V = BitcodeConstant::create(Alloc, CurTy, Opc, (unsigned)Record[2]);
      }
      break;
    }
    case bitc::CST_CODE_CE_INBOUNDS_GEP: // [ty, n x operands]
    case bitc::CST_CODE_CE_GEP_OLD:      // [ty, n x operands]
    case bitc::CST_CODE_CE_GEP_WITH_INRANGE_INDEX_OLD: // [ty, flags, n x
                                                       // operands]
    case bitc::CST_CODE_CE_GEP:                // [ty, flags, n x operands]
    case bitc::CST_CODE_CE_GEP_WITH_INRANGE: { // [ty, flags, start, end, n x
                                               // operands]
      if (Record.size() < 2)
        return error("Constant GEP record must have at least two elements");
      unsigned OpNum = 0;
      Type *PointeeType = nullptr;
      if (BitCode == bitc::CST_CODE_CE_GEP_WITH_INRANGE_INDEX_OLD ||
          BitCode == bitc::CST_CODE_CE_GEP_WITH_INRANGE ||
          BitCode == bitc::CST_CODE_CE_GEP || Record.size() % 2)
        PointeeType = getTypeByID(Record[OpNum++]);
 
      uint64_t Flags = 0;
      std::optional<ConstantRange> InRange;
      if (BitCode == bitc::CST_CODE_CE_GEP_WITH_INRANGE_INDEX_OLD) {
        uint64_t Op = Record[OpNum++];
        Flags = Op & 1; // inbounds
        unsigned InRangeIndex = Op >> 1;
        // "Upgrade" inrange by dropping it. The feature is too niche to
        // bother.
        (void)InRangeIndex;
      } else if (BitCode == bitc::CST_CODE_CE_GEP_WITH_INRANGE) {
        Flags = Record[OpNum++];
        Expected<ConstantRange> MaybeInRange =
            readBitWidthAndConstantRange(Record, OpNum);
        if (!MaybeInRange)
          return MaybeInRange.takeError();
        InRange = MaybeInRange.get();
      } else if (BitCode == bitc::CST_CODE_CE_GEP) {
        Flags = Record[OpNum++];
      } else if (BitCode == bitc::CST_CODE_CE_INBOUNDS_GEP)
        Flags = (1 << bitc::GEP_INBOUNDS);
 
      SmallVector<unsigned, 16> Elts;
      unsigned BaseTypeID = Record[OpNum];
      while (OpNum != Record.size()) {
        unsigned ElTyID = Record[OpNum++];
        Type *ElTy = getTypeByID(ElTyID);
        if (!ElTy)
          return error("Invalid getelementptr constexpr record");
        Elts.push_back(Record[OpNum++]);
      }
 
      if (Elts.size() < 1)
        return error("Invalid gep with no operands");
 
      Type *BaseType = getTypeByID(BaseTypeID);
      if (isa<VectorType>(BaseType)) {
        BaseTypeID = getContainedTypeID(BaseTypeID, 0);
        BaseType = getTypeByID(BaseTypeID);
      }
 
      PointerType *OrigPtrTy = dyn_cast_or_null<PointerType>(BaseType);
      if (!OrigPtrTy)
        return error("GEP base operand must be pointer or vector of pointer");
 
      if (!PointeeType) {
        PointeeType = getPtrElementTypeByID(BaseTypeID);
        if (!PointeeType)
          return error("Missing element type for old-style constant GEP");
      }
 
      V = BitcodeConstant::create(
          Alloc, CurTy,
          {Instruction::GetElementPtr, uint8_t(Flags), PointeeType, InRange},
          Elts);
      break;
    }
    case bitc::CST_CODE_CE_SELECT: {  // CE_SELECT: [opval#, opval#, opval#]
      if (Record.size() < 3)
        return error("Invalid select constexpr record");
 
      V = BitcodeConstant::create(
          Alloc, CurTy, Instruction::Select,
          {(unsigned)Record[0], (unsigned)Record[1], (unsigned)Record[2]});
      break;
    }
    case bitc::CST_CODE_CE_EXTRACTELT
        : { // CE_EXTRACTELT: [opty, opval, opty, opval]
      if (Record.size() < 3)
        return error("Invalid extractelement constexpr record");
      unsigned OpTyID = Record[0];
      VectorType *OpTy =
        dyn_cast_or_null<VectorType>(getTypeByID(OpTyID));
      if (!OpTy)
        return error("Invalid extractelement constexpr record");
      unsigned IdxRecord;
      if (Record.size() == 4) {
        unsigned IdxTyID = Record[2];
        Type *IdxTy = getTypeByID(IdxTyID);
        if (!IdxTy)
          return error("Invalid extractelement constexpr record");
        IdxRecord = Record[3];
      } else {
        // Deprecated, but still needed to read old bitcode files.
        IdxRecord = Record[2];
      }
      V = BitcodeConstant::create(Alloc, CurTy, Instruction::ExtractElement,
                                  {(unsigned)Record[1], IdxRecord});
      break;
    }
    case bitc::CST_CODE_CE_INSERTELT
        : { // CE_INSERTELT: [opval, opval, opty, opval]
      VectorType *OpTy = dyn_cast<VectorType>(CurTy);
      if (Record.size() < 3 || !OpTy)
        return error("Invalid insertelement constexpr record");
      unsigned IdxRecord;
      if (Record.size() == 4) {
        unsigned IdxTyID = Record[2];
        Type *IdxTy = getTypeByID(IdxTyID);
        if (!IdxTy)
          return error("Invalid insertelement constexpr record");
        IdxRecord = Record[3];
      } else {
        // Deprecated, but still needed to read old bitcode files.
        IdxRecord = Record[2];
      }
      V = BitcodeConstant::create(
          Alloc, CurTy, Instruction::InsertElement,
          {(unsigned)Record[0], (unsigned)Record[1], IdxRecord});
      break;
    }
    case bitc::CST_CODE_CE_SHUFFLEVEC: { // CE_SHUFFLEVEC: [opval, opval, opval]
      VectorType *OpTy = dyn_cast<VectorType>(CurTy);
      if (Record.size() < 3 || !OpTy)
        return error("Invalid shufflevector constexpr record");
      V = BitcodeConstant::create(
          Alloc, CurTy, Instruction::ShuffleVector,
          {(unsigned)Record[0], (unsigned)Record[1], (unsigned)Record[2]});
      break;
    }
    case bitc::CST_CODE_CE_SHUFVEC_EX: { // [opty, opval, opval, opval]
      VectorType *RTy = dyn_cast<VectorType>(CurTy);
      VectorType *OpTy =
        dyn_cast_or_null<VectorType>(getTypeByID(Record[0]));
      if (Record.size() < 4 || !RTy || !OpTy)
        return error("Invalid shufflevector constexpr record");
      V = BitcodeConstant::create(
          Alloc, CurTy, Instruction::ShuffleVector,
          {(unsigned)Record[1], (unsigned)Record[2], (unsigned)Record[3]});
      break;
    }
    case bitc::CST_CODE_CE_CMP: {     // CE_CMP: [opty, opval, opval, pred]
      if (Record.size() < 4)
        return error("Invalid cmp constexpt record");
      unsigned OpTyID = Record[0];
      Type *OpTy = getTypeByID(OpTyID);
      if (!OpTy)
        return error("Invalid cmp constexpr record");
      V = BitcodeConstant::create(
          Alloc, CurTy,
          {(uint8_t)(OpTy->isFPOrFPVectorTy() ? Instruction::FCmp
                                              : Instruction::ICmp),
           (uint8_t)Record[3]},
          {(unsigned)Record[1], (unsigned)Record[2]});
      break;
    }
    // This maintains backward compatibility, pre-asm dialect keywords.
    // Deprecated, but still needed to read old bitcode files.
    case bitc::CST_CODE_INLINEASM_OLD: {
      if (Record.size() < 2)
        return error("Invalid inlineasm record");
      std::string AsmStr, ConstrStr;
      bool HasSideEffects = Record[0] & 1;
      bool IsAlignStack = Record[0] >> 1;
      unsigned AsmStrSize = Record[1];
      if (2+AsmStrSize >= Record.size())
        return error("Invalid inlineasm record");
      unsigned ConstStrSize = Record[2+AsmStrSize];
      if (3+AsmStrSize+ConstStrSize > Record.size())
        return error("Invalid inlineasm record");
 
      for (unsigned i = 0; i != AsmStrSize; ++i)
        AsmStr += (char)Record[2+i];
      for (unsigned i = 0; i != ConstStrSize; ++i)
        ConstrStr += (char)Record[3+AsmStrSize+i];
      UpgradeInlineAsmString(&AsmStr);
      if (!CurElemTy)
        return error("Missing element type for old-style inlineasm");
      V = InlineAsm::get(cast<FunctionType>(CurElemTy), AsmStr, ConstrStr,
                         HasSideEffects, IsAlignStack);
      break;
    }
    // This version adds support for the asm dialect keywords (e.g.,
    // inteldialect).
    case bitc::CST_CODE_INLINEASM_OLD2: {
      if (Record.size() < 2)
        return error("Invalid inlineasm record");
      std::string AsmStr, ConstrStr;
      bool HasSideEffects = Record[0] & 1;
      bool IsAlignStack = (Record[0] >> 1) & 1;
      unsigned AsmDialect = Record[0] >> 2;
      unsigned AsmStrSize = Record[1];
      if (2+AsmStrSize >= Record.size())
        return error("Invalid inlineasm record");
      unsigned ConstStrSize = Record[2+AsmStrSize];
      if (3+AsmStrSize+ConstStrSize > Record.size())
        return error("Invalid inlineasm record");
 
      for (unsigned i = 0; i != AsmStrSize; ++i)
        AsmStr += (char)Record[2+i];
      for (unsigned i = 0; i != ConstStrSize; ++i)
        ConstrStr += (char)Record[3+AsmStrSize+i];
      UpgradeInlineAsmString(&AsmStr);
      if (!CurElemTy)
        return error("Missing element type for old-style inlineasm");
      V = InlineAsm::get(cast<FunctionType>(CurElemTy), AsmStr, ConstrStr,
                         HasSideEffects, IsAlignStack,
                         InlineAsm::AsmDialect(AsmDialect));
      break;
    }
    // This version adds support for the unwind keyword.
    case bitc::CST_CODE_INLINEASM_OLD3: {
      if (Record.size() < 2)
        return error("Invalid inlineasm record");
      unsigned OpNum = 0;
      std::string AsmStr, ConstrStr;
      bool HasSideEffects = Record[OpNum] & 1;
      bool IsAlignStack = (Record[OpNum] >> 1) & 1;
      unsigned AsmDialect = (Record[OpNum] >> 2) & 1;
      bool CanThrow = (Record[OpNum] >> 3) & 1;
      ++OpNum;
      unsigned AsmStrSize = Record[OpNum];
      ++OpNum;
      if (OpNum + AsmStrSize >= Record.size())
        return error("Invalid inlineasm record");
      unsigned ConstStrSize = Record[OpNum + AsmStrSize];
      if (OpNum + 1 + AsmStrSize + ConstStrSize > Record.size())
        return error("Invalid inlineasm record");
 
      for (unsigned i = 0; i != AsmStrSize; ++i)
        AsmStr += (char)Record[OpNum + i];
      ++OpNum;
      for (unsigned i = 0; i != ConstStrSize; ++i)
        ConstrStr += (char)Record[OpNum + AsmStrSize + i];
      UpgradeInlineAsmString(&AsmStr);
      if (!CurElemTy)
        return error("Missing element type for old-style inlineasm");
      V = InlineAsm::get(cast<FunctionType>(CurElemTy), AsmStr, ConstrStr,
                         HasSideEffects, IsAlignStack,
                         InlineAsm::AsmDialect(AsmDialect), CanThrow);
      break;
    }
    // This version adds explicit function type.
    case bitc::CST_CODE_INLINEASM: {
      if (Record.size() < 3)
        return error("Invalid inlineasm record");
      unsigned OpNum = 0;
      auto *FnTy = dyn_cast_or_null<FunctionType>(getTypeByID(Record[OpNum]));
      ++OpNum;
      if (!FnTy)
        return error("Invalid inlineasm record");
      std::string AsmStr, ConstrStr;
      bool HasSideEffects = Record[OpNum] & 1;
      bool IsAlignStack = (Record[OpNum] >> 1) & 1;
      unsigned AsmDialect = (Record[OpNum] >> 2) & 1;
      bool CanThrow = (Record[OpNum] >> 3) & 1;
      ++OpNum;
      unsigned AsmStrSize = Record[OpNum];
      ++OpNum;
      if (OpNum + AsmStrSize >= Record.size())
        return error("Invalid inlineasm record");
      unsigned ConstStrSize = Record[OpNum + AsmStrSize];
      if (OpNum + 1 + AsmStrSize + ConstStrSize > Record.size())
        return error("Invalid inlineasm record");
 
      for (unsigned i = 0; i != AsmStrSize; ++i)
        AsmStr += (char)Record[OpNum + i];
      ++OpNum;
      for (unsigned i = 0; i != ConstStrSize; ++i)
        ConstrStr += (char)Record[OpNum + AsmStrSize + i];
      UpgradeInlineAsmString(&AsmStr);
      V = InlineAsm::get(FnTy, AsmStr, ConstrStr, HasSideEffects, IsAlignStack,
                         InlineAsm::AsmDialect(AsmDialect), CanThrow);
      break;
    }
    case bitc::CST_CODE_BLOCKADDRESS:{
      if (Record.size() < 3)
        return error("Invalid blockaddress record");
      unsigned FnTyID = Record[0];
      Type *FnTy = getTypeByID(FnTyID);
      if (!FnTy)
        return error("Invalid blockaddress record");
      V = BitcodeConstant::create(
          Alloc, CurTy,
          {BitcodeConstant::BlockAddressOpcode, 0, (unsigned)Record[2]},
          Record[1]);
      break;
    }
    case bitc::CST_CODE_DSO_LOCAL_EQUIVALENT: {
      if (Record.size() < 2)
        return error("Invalid dso_local record");
      unsigned GVTyID = Record[0];
      Type *GVTy = getTypeByID(GVTyID);
      if (!GVTy)
        return error("Invalid dso_local record");
      V = BitcodeConstant::create(
          Alloc, CurTy, BitcodeConstant::DSOLocalEquivalentOpcode, Record[1]);
      break;
    }
    case bitc::CST_CODE_NO_CFI_VALUE: {
      if (Record.size() < 2)
        return error("Invalid no_cfi record");
      unsigned GVTyID = Record[0];
      Type *GVTy = getTypeByID(GVTyID);
      if (!GVTy)
        return error("Invalid no_cfi record");
      V = BitcodeConstant::create(Alloc, CurTy, BitcodeConstant::NoCFIOpcode,
                                  Record[1]);
      break;
    }
    case bitc::CST_CODE_PTRAUTH: {
      if (Record.size() < 4)
        return error("Invalid ptrauth record");
      // Ptr, Key, Disc, AddrDisc
      V = BitcodeConstant::create(Alloc, CurTy,
                                  BitcodeConstant::ConstantPtrAuthOpcode,
                                  {(unsigned)Record[0], (unsigned)Record[1],
                                   (unsigned)Record[2], (unsigned)Record[3]});
      break;
    }
    case bitc::CST_CODE_PTRAUTH2: {
      if (Record.size() < 5)
        return error("Invalid ptrauth record");
      // Ptr, Key, Disc, AddrDisc, DeactivationSymbol
      V = BitcodeConstant::create(
          Alloc, CurTy, BitcodeConstant::ConstantPtrAuthOpcode,
          {(unsigned)Record[0], (unsigned)Record[1], (unsigned)Record[2],
           (unsigned)Record[3], (unsigned)Record[4]});
      break;
    }
    }
 
    assert(V->getType() == getTypeByID(CurTyID) && "Incorrect result type ID");
    if (Error Err = ValueList.assignValue(NextCstNo, V, CurTyID))
      return Err;
    ++NextCstNo;
  }
}
 
Error BitcodeReader::parseUseLists() {
  if (Error Err = Stream.EnterSubBlock(bitc::USELIST_BLOCK_ID))
    return Err;
 
  // Read all the records.
  SmallVector<uint64_t, 64> Record;
 
  while (true) {
    Expected<BitstreamEntry> MaybeEntry = Stream.advanceSkippingSubblocks();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    BitstreamEntry Entry = MaybeEntry.get();
 
    switch (Entry.Kind) {
    case BitstreamEntry::SubBlock: // Handled for us already.
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock:
      return Error::success();
    case BitstreamEntry::Record:
      // The interesting case.
      break;
    }
 
    // Read a use list record.
    Record.clear();
    bool IsBB = false;
    Expected<unsigned> MaybeRecord = Stream.readRecord(Entry.ID, Record);
    if (!MaybeRecord)
      return MaybeRecord.takeError();
    switch (MaybeRecord.get()) {
    default:  // Default behavior: unknown type.
      break;
    case bitc::USELIST_CODE_BB:
      IsBB = true;
      [[fallthrough]];
    case bitc::USELIST_CODE_DEFAULT: {
      unsigned RecordLength = Record.size();
      if (RecordLength < 3)
        // Records should have at least an ID and two indexes.
        return error("Invalid uselist record");
      unsigned ID = Record.pop_back_val();
 
      Value *V;
      if (IsBB) {
        assert(ID < FunctionBBs.size() && "Basic block not found");
        V = FunctionBBs[ID];
      } else
        V = ValueList[ID];
 
      if (!V->hasUseList())
        break;
 
      unsigned NumUses = 0;
      SmallDenseMap<const Use *, unsigned, 16> Order;
      for (const Use &U : V->materialized_uses()) {
        if (++NumUses > Record.size())
          break;
        Order[&U] = Record[NumUses - 1];
      }
      if (Order.size() != Record.size() || NumUses > Record.size())
        // Mismatches can happen if the functions are being materialized lazily
        // (out-of-order), or a value has been upgraded.
        break;
 
      V->sortUseList([&](const Use &L, const Use &R) {
        return Order.lookup(&L) < Order.lookup(&R);
      });
      break;
    }
    }
  }
}
 
/// When we see the block for metadata, remember where it is and then skip it.
/// This lets us lazily deserialize the metadata.
Error BitcodeReader::rememberAndSkipMetadata() {
  // Save the current stream state.
  uint64_t CurBit = Stream.GetCurrentBitNo();
  DeferredMetadataInfo.push_back(CurBit);
 
  // Skip over the block for now.
  if (Error Err = Stream.SkipBlock())
    return Err;
  return Error::success();
}
 
Error BitcodeReader::materializeMetadata() {
  for (uint64_t BitPos : DeferredMetadataInfo) {
    // Move the bit stream to the saved position.
    if (Error JumpFailed = Stream.JumpToBit(BitPos))
      return JumpFailed;
    if (Error Err = MDLoader->parseModuleMetadata())
      return Err;
  }
 
  // Upgrade "Linker Options" module flag to "llvm.linker.options" module-level
  // metadata. Only upgrade if the new option doesn't exist to avoid upgrade
  // multiple times.
  if (!TheModule->getNamedMetadata("llvm.linker.options")) {
    if (Metadata *Val = TheModule->getModuleFlag("Linker Options")) {
      NamedMDNode *LinkerOpts =
          TheModule->getOrInsertNamedMetadata("llvm.linker.options");
      for (const MDOperand &MDOptions : cast<MDNode>(Val)->operands())
        LinkerOpts->addOperand(cast<MDNode>(MDOptions));
    }
  }
 
  DeferredMetadataInfo.clear();
  return Error::success();
}
 
void BitcodeReader::setStripDebugInfo() { StripDebugInfo = true; }
 
/// When we see the block for a function body, remember where it is and then
/// skip it.  This lets us lazily deserialize the functions.
Error BitcodeReader::rememberAndSkipFunctionBody() {
  // Get the function we are talking about.
  if (FunctionsWithBodies.empty())
    return error("Insufficient function protos");
 
  Function *Fn = FunctionsWithBodies.back();
  FunctionsWithBodies.pop_back();
 
  // Save the current stream state.
  uint64_t CurBit = Stream.GetCurrentBitNo();
  assert(
      (DeferredFunctionInfo[Fn] == 0 || DeferredFunctionInfo[Fn] == CurBit) &&
      "Mismatch between VST and scanned function offsets");
  DeferredFunctionInfo[Fn] = CurBit;
 
  // Skip over the function block for now.
  if (Error Err = Stream.SkipBlock())
    return Err;
  return Error::success();
}
 
Error BitcodeReader::globalCleanup() {
  // Patch the initializers for globals and aliases up.
  if (Error Err = resolveGlobalAndIndirectSymbolInits())
    return Err;
  if (!GlobalInits.empty() || !IndirectSymbolInits.empty())
    return error("Malformed global initializer set");
 
  // Look for intrinsic functions which need to be upgraded at some point
  // and functions that need to have their function attributes upgraded.
  for (Function &F : *TheModule) {
    MDLoader->upgradeDebugIntrinsics(F);
    Function *NewFn;
    if (UpgradeIntrinsicFunction(&F, NewFn))
      UpgradedIntrinsics[&F] = NewFn;
    // Look for functions that rely on old function attribute behavior.
    UpgradeFunctionAttributes(F);
  }
 
  // Look for global variables which need to be renamed.
  std::vector<std::pair<GlobalVariable *, GlobalVariable *>> UpgradedVariables;
  for (GlobalVariable &GV : TheModule->globals())
    if (GlobalVariable *Upgraded = UpgradeGlobalVariable(&GV))
      UpgradedVariables.emplace_back(&GV, Upgraded);
  for (auto &Pair : UpgradedVariables) {
    Pair.first->eraseFromParent();
    TheModule->insertGlobalVariable(Pair.second);
  }
 
  // Force deallocation of memory for these vectors to favor the client that
  // want lazy deserialization.
  std::vector<std::pair<GlobalVariable *, unsigned>>().swap(GlobalInits);
  std::vector<std::pair<GlobalValue *, unsigned>>().swap(IndirectSymbolInits);
  return Error::success();
}
 
/// Support for lazy parsing of function bodies. This is required if we
/// either have an old bitcode file without a VST forward declaration record,
/// or if we have an anonymous function being materialized, since anonymous
/// functions do not have a name and are therefore not in the VST.
Error BitcodeReader::rememberAndSkipFunctionBodies() {
  if (Error JumpFailed = Stream.JumpToBit(NextUnreadBit))
    return JumpFailed;
 
  if (Stream.AtEndOfStream())
    return error("Could not find function in stream");
 
  if (!SeenFirstFunctionBody)
    return error("Trying to materialize functions before seeing function blocks");
 
  // An old bitcode file with the symbol table at the end would have
  // finished the parse greedily.
  assert(SeenValueSymbolTable);
 
  while (true) {
    Expected<llvm::BitstreamEntry> MaybeEntry = Stream.advance();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    llvm::BitstreamEntry Entry = MaybeEntry.get();
 
    switch (Entry.Kind) {
    default:
      return error("Expect SubBlock");
    case BitstreamEntry::SubBlock:
      switch (Entry.ID) {
      default:
        return error("Expect function block");
      case bitc::FUNCTION_BLOCK_ID:
        if (Error Err = rememberAndSkipFunctionBody())
          return Err;
        NextUnreadBit = Stream.GetCurrentBitNo();
        return Error::success();
      }
    }
  }
}
 
Error BitcodeReaderBase::readBlockInfo() {
  Expected<std::optional<BitstreamBlockInfo>> MaybeNewBlockInfo =
      Stream.ReadBlockInfoBlock();
  if (!MaybeNewBlockInfo)
    return MaybeNewBlockInfo.takeError();
  std::optional<BitstreamBlockInfo> NewBlockInfo =
      std::move(MaybeNewBlockInfo.get());
  if (!NewBlockInfo)
    return error("Malformed block");
  BlockInfo = std::move(*NewBlockInfo);
  return Error::success();
}
 
Error BitcodeReader::parseComdatRecord(ArrayRef<uint64_t> Record) {
  // v1: [selection_kind, name]
  // v2: [strtab_offset, strtab_size, selection_kind]
  StringRef Name;
  std::tie(Name, Record) = readNameFromStrtab(Record);
 
  if (Record.empty())
    return error("Invalid comdat record");
  Comdat::SelectionKind SK = getDecodedComdatSelectionKind(Record[0]);
  std::string OldFormatName;
  if (!UseStrtab) {
    if (Record.size() < 2)
      return error("Invalid comdat record");
    unsigned ComdatNameSize = Record[1];
    if (ComdatNameSize > Record.size() - 2)
      return error("Comdat name size too large");
    OldFormatName.reserve(ComdatNameSize);
    for (unsigned i = 0; i != ComdatNameSize; ++i)
      OldFormatName += (char)Record[2 + i];
    Name = OldFormatName;
  }
  Comdat *C = TheModule->getOrInsertComdat(Name);
  C->setSelectionKind(SK);
  ComdatList.push_back(C);
  return Error::success();
}
 
static void inferDSOLocal(GlobalValue *GV) {
  // infer dso_local from linkage and visibility if it is not encoded.
  if (GV->hasLocalLinkage() ||
      (!GV->hasDefaultVisibility() && !GV->hasExternalWeakLinkage()))
    GV->setDSOLocal(true);
}
 
GlobalValue::SanitizerMetadata deserializeSanitizerMetadata(unsigned V) {
  GlobalValue::SanitizerMetadata Meta;
  if (V & (1 << 0))
    Meta.NoAddress = true;
  if (V & (1 << 1))
    Meta.NoHWAddress = true;
  if (V & (1 << 2))
    Meta.Memtag = true;
  if (V & (1 << 3))
    Meta.IsDynInit = true;
  return Meta;
}
 
Error BitcodeReader::parseGlobalVarRecord(ArrayRef<uint64_t> Record) {
  // v1: [pointer type, isconst, initid, linkage, alignment, section,
  // visibility, threadlocal, unnamed_addr, externally_initialized,
  // dllstorageclass, comdat, attributes, preemption specifier,
  // partition strtab offset, partition strtab size] (name in VST)
  // v2: [strtab_offset, strtab_size, v1]
  // v3: [v2, code_model]
  StringRef Name;
  std::tie(Name, Record) = readNameFromStrtab(Record);
 
  if (Record.size() < 6)
    return error("Invalid global variable record");
  unsigned TyID = Record[0];
  Type *Ty = getTypeByID(TyID);
  if (!Ty)
    return error("Invalid global variable record");
  bool isConstant = Record[1] & 1;
  bool explicitType = Record[1] & 2;
  unsigned AddressSpace;
  if (explicitType) {
    AddressSpace = Record[1] >> 2;
  } else {
    if (!Ty->isPointerTy())
      return error("Invalid type for value");
    AddressSpace = cast<PointerType>(Ty)->getAddressSpace();
    TyID = getContainedTypeID(TyID);
    Ty = getTypeByID(TyID);
    if (!Ty)
      return error("Missing element type for old-style global");
  }
 
  uint64_t RawLinkage = Record[3];
  GlobalValue::LinkageTypes Linkage = getDecodedLinkage(RawLinkage);
  MaybeAlign Alignment;
  if (Error Err = parseAlignmentValue(Record[4], Alignment))
    return Err;
  std::string Section;
  if (Record[5]) {
    if (Record[5] - 1 >= SectionTable.size())
      return error("Invalid ID");
    Section = SectionTable[Record[5] - 1];
  }
  GlobalValue::VisibilityTypes Visibility = GlobalValue::DefaultVisibility;
  // Local linkage must have default visibility.
  // auto-upgrade `hidden` and `protected` for old bitcode.
  if (Record.size() > 6 && !GlobalValue::isLocalLinkage(Linkage))
    Visibility = getDecodedVisibility(Record[6]);
 
  GlobalVariable::ThreadLocalMode TLM = GlobalVariable::NotThreadLocal;
  if (Record.size() > 7)
    TLM = getDecodedThreadLocalMode(Record[7]);
 
  GlobalValue::UnnamedAddr UnnamedAddr = GlobalValue::UnnamedAddr::None;
  if (Record.size() > 8)
    UnnamedAddr = getDecodedUnnamedAddrType(Record[8]);
 
  bool ExternallyInitialized = false;
  if (Record.size() > 9)
    ExternallyInitialized = Record[9];
 
  GlobalVariable *NewGV =
      new GlobalVariable(*TheModule, Ty, isConstant, Linkage, nullptr, Name,
                         nullptr, TLM, AddressSpace, ExternallyInitialized);
  if (Alignment)
    NewGV->setAlignment(*Alignment);
  if (!Section.empty())
    NewGV->setSection(Section);
  NewGV->setVisibility(Visibility);
  NewGV->setUnnamedAddr(UnnamedAddr);
 
  if (Record.size() > 10) {
    // A GlobalValue with local linkage cannot have a DLL storage class.
    if (!NewGV->hasLocalLinkage()) {
      NewGV->setDLLStorageClass(getDecodedDLLStorageClass(Record[10]));
    }
  } else {
    upgradeDLLImportExportLinkage(NewGV, RawLinkage);
  }
 
  ValueList.push_back(NewGV, getVirtualTypeID(NewGV->getType(), TyID));
 
  // Remember which value to use for the global initializer.
  if (unsigned InitID = Record[2])
    GlobalInits.push_back(std::make_pair(NewGV, InitID - 1));
 
  if (Record.size() > 11) {
    if (unsigned ComdatID = Record[11]) {
      if (ComdatID > ComdatList.size())
        return error("Invalid global variable comdat ID");
      NewGV->setComdat(ComdatList[ComdatID - 1]);
    }
  } else if (hasImplicitComdat(RawLinkage)) {
    ImplicitComdatObjects.insert(NewGV);
  }
 
  if (Record.size() > 12) {
    auto AS = getAttributes(Record[12]).getFnAttrs();
    NewGV->setAttributes(AS);
  }
 
  if (Record.size() > 13) {
    NewGV->setDSOLocal(getDecodedDSOLocal(Record[13]));
  }
  inferDSOLocal(NewGV);
 
  // Check whether we have enough values to read a partition name.
  if (Record.size() > 15)
    NewGV->setPartition(StringRef(Strtab.data() + Record[14], Record[15]));
 
  if (Record.size() > 16 && Record[16]) {
    llvm::GlobalValue::SanitizerMetadata Meta =
        deserializeSanitizerMetadata(Record[16]);
    NewGV->setSanitizerMetadata(Meta);
  }
 
  if (Record.size() > 17 && Record[17]) {
    if (auto CM = getDecodedCodeModel(Record[17]))
      NewGV->setCodeModel(*CM);
    else
      return error("Invalid global variable code model");
  }
 
  return Error::success();
}
 
void BitcodeReader::callValueTypeCallback(Value *F, unsigned TypeID) {
  if (ValueTypeCallback) {
    (*ValueTypeCallback)(
        F, TypeID, [this](unsigned I) { return getTypeByID(I); },
        [this](unsigned I, unsigned J) { return getContainedTypeID(I, J); });
  }
}
 
Error BitcodeReader::parseFunctionRecord(ArrayRef<uint64_t> Record) {
  // v1: [type, callingconv, isproto, linkage, paramattr, alignment, section,
  // visibility, gc, unnamed_addr, prologuedata, dllstorageclass, comdat,
  // prefixdata,  personalityfn, preemption specifier, addrspace] (name in VST)
  // v2: [strtab_offset, strtab_size, v1]
  StringRef Name;
  std::tie(Name, Record) = readNameFromStrtab(Record);
 
  if (Record.size() < 8)
    return error("Invalid function record");
  unsigned FTyID = Record[0];
  Type *FTy = getTypeByID(FTyID);
  if (!FTy)
    return error("Invalid function record");
  if (isa<PointerType>(FTy)) {
    FTyID = getContainedTypeID(FTyID, 0);
    FTy = getTypeByID(FTyID);
    if (!FTy)
      return error("Missing element type for old-style function");
  }
 
  if (!isa<FunctionType>(FTy))
    return error("Invalid type for value");
  auto CC = static_cast<CallingConv::ID>(Record[1]);
  if (CC & ~CallingConv::MaxID)
    return error("Invalid calling convention ID");
 
  unsigned AddrSpace = TheModule->getDataLayout().getProgramAddressSpace();
  if (Record.size() > 16)
    AddrSpace = Record[16];
 
  Function *Func =
      Function::Create(cast<FunctionType>(FTy), GlobalValue::ExternalLinkage,
                       AddrSpace, Name, TheModule);
 
  assert(Func->getFunctionType() == FTy &&
         "Incorrect fully specified type provided for function");
  FunctionTypeIDs[Func] = FTyID;
 
  Func->setCallingConv(CC);
  bool isProto = Record[2];
  uint64_t RawLinkage = Record[3];
  Func->setLinkage(getDecodedLinkage(RawLinkage));
  Func->setAttributes(getAttributes(Record[4]));
  callValueTypeCallback(Func, FTyID);
 
  // Upgrade any old-style byval or sret without a type by propagating the
  // argument's pointee type. There should be no opaque pointers where the byval
  // type is implicit.
  for (unsigned i = 0; i != Func->arg_size(); ++i) {
    for (Attribute::AttrKind Kind : {Attribute::ByVal, Attribute::StructRet,
                                     Attribute::InAlloca}) {
      if (!Func->hasParamAttribute(i, Kind))
        continue;
 
      if (Func->getParamAttribute(i, Kind).getValueAsType())
        continue;
 
      Func->removeParamAttr(i, Kind);
 
      unsigned ParamTypeID = getContainedTypeID(FTyID, i + 1);
      Type *PtrEltTy = getPtrElementTypeByID(ParamTypeID);
      if (!PtrEltTy)
        return error("Missing param element type for attribute upgrade");
 
      Attribute NewAttr;
      switch (Kind) {
      case Attribute::ByVal:
        NewAttr = Attribute::getWithByValType(Context, PtrEltTy);
        break;
      case Attribute::StructRet:
        NewAttr = Attribute::getWithStructRetType(Context, PtrEltTy);
        break;
      case Attribute::InAlloca:
        NewAttr = Attribute::getWithInAllocaType(Context, PtrEltTy);
        break;
      default:
        llvm_unreachable("not an upgraded type attribute");
      }
 
      Func->addParamAttr(i, NewAttr);
    }
  }
 
  if (Func->getCallingConv() == CallingConv::X86_INTR &&
      !Func->arg_empty() && !Func->hasParamAttribute(0, Attribute::ByVal)) {
    unsigned ParamTypeID = getContainedTypeID(FTyID, 1);
    Type *ByValTy = getPtrElementTypeByID(ParamTypeID);
    if (!ByValTy)
      return error("Missing param element type for x86_intrcc upgrade");
    Attribute NewAttr = Attribute::getWithByValType(Context, ByValTy);
    Func->addParamAttr(0, NewAttr);
  }
 
  MaybeAlign Alignment;
  if (Error Err = parseAlignmentValue(Record[5], Alignment))
    return Err;
  if (Alignment)
    Func->setAlignment(*Alignment);
  if (Record[6]) {
    if (Record[6] - 1 >= SectionTable.size())
      return error("Invalid ID");
    Func->setSection(SectionTable[Record[6] - 1]);
  }
  // Local linkage must have default visibility.
  // auto-upgrade `hidden` and `protected` for old bitcode.
  if (!Func->hasLocalLinkage())
    Func->setVisibility(getDecodedVisibility(Record[7]));
  if (Record.size() > 8 && Record[8]) {
    if (Record[8] - 1 >= GCTable.size())
      return error("Invalid ID");
    Func->setGC(GCTable[Record[8] - 1]);
  }
  GlobalValue::UnnamedAddr UnnamedAddr = GlobalValue::UnnamedAddr::None;
  if (Record.size() > 9)
    UnnamedAddr = getDecodedUnnamedAddrType(Record[9]);
  Func->setUnnamedAddr(UnnamedAddr);
 
  FunctionOperandInfo OperandInfo = {Func, 0, 0, 0};
  if (Record.size() > 10)
    OperandInfo.Prologue = Record[10];
 
  if (Record.size() > 11) {
    // A GlobalValue with local linkage cannot have a DLL storage class.
    if (!Func->hasLocalLinkage()) {
      Func->setDLLStorageClass(getDecodedDLLStorageClass(Record[11]));
    }
  } else {
    upgradeDLLImportExportLinkage(Func, RawLinkage);
  }
 
  if (Record.size() > 12) {
    if (unsigned ComdatID = Record[12]) {
      if (ComdatID > ComdatList.size())
        return error("Invalid function comdat ID");
      Func->setComdat(ComdatList[ComdatID - 1]);
    }
  } else if (hasImplicitComdat(RawLinkage)) {
    ImplicitComdatObjects.insert(Func);
  }
 
  if (Record.size() > 13)
    OperandInfo.Prefix = Record[13];
 
  if (Record.size() > 14)
    OperandInfo.PersonalityFn = Record[14];
 
  if (Record.size() > 15) {
    Func->setDSOLocal(getDecodedDSOLocal(Record[15]));
  }
  inferDSOLocal(Func);
 
  // Record[16] is the address space number.
 
  // Check whether we have enough values to read a partition name. Also make
  // sure Strtab has enough values.
  if (Record.size() > 18 && Strtab.data() &&
      Record[17] + Record[18] <= Strtab.size()) {
    Func->setPartition(StringRef(Strtab.data() + Record[17], Record[18]));
  }
 
  if (Record.size() > 19) {
    MaybeAlign PrefAlignment;
    if (Error Err = parseAlignmentValue(Record[19], PrefAlignment))
      return Err;
    Func->setPreferredAlignment(PrefAlignment);
  }
 
  ValueList.push_back(Func, getVirtualTypeID(Func->getType(), FTyID));
 
  if (OperandInfo.PersonalityFn || OperandInfo.Prefix || OperandInfo.Prologue)
    FunctionOperands.push_back(OperandInfo);
 
  // If this is a function with a body, remember the prototype we are
  // creating now, so that we can match up the body with them later.
  if (!isProto) {
    Func->setIsMaterializable(true);
    FunctionsWithBodies.push_back(Func);
    DeferredFunctionInfo[Func] = 0;
  }
  return Error::success();
}
 
Error BitcodeReader::parseGlobalIndirectSymbolRecord(
    unsigned BitCode, ArrayRef<uint64_t> Record) {
  // v1 ALIAS_OLD: [alias type, aliasee val#, linkage] (name in VST)
  // v1 ALIAS: [alias type, addrspace, aliasee val#, linkage, visibility,
  // dllstorageclass, threadlocal, unnamed_addr,
  // preemption specifier] (name in VST)
  // v1 IFUNC: [alias type, addrspace, aliasee val#, linkage,
  // visibility, dllstorageclass, threadlocal, unnamed_addr,
  // preemption specifier] (name in VST)
  // v2: [strtab_offset, strtab_size, v1]
  StringRef Name;
  std::tie(Name, Record) = readNameFromStrtab(Record);
 
  bool NewRecord = BitCode != bitc::MODULE_CODE_ALIAS_OLD;
  if (Record.size() < (3 + (unsigned)NewRecord))
    return error("Invalid global indirect symbol record");
  unsigned OpNum = 0;
  unsigned TypeID = Record[OpNum++];
  Type *Ty = getTypeByID(TypeID);
  if (!Ty)
    return error("Invalid global indirect symbol record");
 
  unsigned AddrSpace;
  if (!NewRecord) {
    auto *PTy = dyn_cast<PointerType>(Ty);
    if (!PTy)
      return error("Invalid type for value");
    AddrSpace = PTy->getAddressSpace();
    TypeID = getContainedTypeID(TypeID);
    Ty = getTypeByID(TypeID);
    if (!Ty)
      return error("Missing element type for old-style indirect symbol");
  } else {
    AddrSpace = Record[OpNum++];
  }
 
  auto Val = Record[OpNum++];
  auto Linkage = Record[OpNum++];
  GlobalValue *NewGA;
  if (BitCode == bitc::MODULE_CODE_ALIAS ||
      BitCode == bitc::MODULE_CODE_ALIAS_OLD)
    NewGA = GlobalAlias::create(Ty, AddrSpace, getDecodedLinkage(Linkage), Name,
                                TheModule);
  else
    NewGA = GlobalIFunc::create(Ty, AddrSpace, getDecodedLinkage(Linkage), Name,
                                nullptr, TheModule);
 
  // Local linkage must have default visibility.
  // auto-upgrade `hidden` and `protected` for old bitcode.
  if (OpNum != Record.size()) {
    auto VisInd = OpNum++;
    if (!NewGA->hasLocalLinkage())
      NewGA->setVisibility(getDecodedVisibility(Record[VisInd]));
  }
  if (BitCode == bitc::MODULE_CODE_ALIAS ||
      BitCode == bitc::MODULE_CODE_ALIAS_OLD) {
    if (OpNum != Record.size()) {
      auto S = Record[OpNum++];
      // A GlobalValue with local linkage cannot have a DLL storage class.
      if (!NewGA->hasLocalLinkage())
        NewGA->setDLLStorageClass(getDecodedDLLStorageClass(S));
    }
    else
      upgradeDLLImportExportLinkage(NewGA, Linkage);
    if (OpNum != Record.size())
      NewGA->setThreadLocalMode(getDecodedThreadLocalMode(Record[OpNum++]));
    if (OpNum != Record.size())
      NewGA->setUnnamedAddr(getDecodedUnnamedAddrType(Record[OpNum++]));
  }
  if (OpNum != Record.size())
    NewGA->setDSOLocal(getDecodedDSOLocal(Record[OpNum++]));
  inferDSOLocal(NewGA);
 
  // Check whether we have enough values to read a partition name.
  if (OpNum + 1 < Record.size()) {
    // Check Strtab has enough values for the partition.
    if (Record[OpNum] + Record[OpNum + 1] > Strtab.size())
      return error("Malformed partition, too large.");
    NewGA->setPartition(
        StringRef(Strtab.data() + Record[OpNum], Record[OpNum + 1]));
  }
 
  ValueList.push_back(NewGA, getVirtualTypeID(NewGA->getType(), TypeID));
  IndirectSymbolInits.push_back(std::make_pair(NewGA, Val));
  return Error::success();
}
 
Error BitcodeReader::parseModule(uint64_t ResumeBit,
                                 bool ShouldLazyLoadMetadata,
                                 ParserCallbacks Callbacks) {
  this->ValueTypeCallback = std::move(Callbacks.ValueType);
  if (ResumeBit) {
    if (Error JumpFailed = Stream.JumpToBit(ResumeBit))
      return JumpFailed;
  } else if (Error Err = Stream.EnterSubBlock(bitc::MODULE_BLOCK_ID))
    return Err;
 
  SmallVector<uint64_t, 64> Record;
 
  // Parts of bitcode parsing depend on the datalayout.  Make sure we
  // finalize the datalayout before we run any of that code.
  bool ResolvedDataLayout = false;
  // In order to support importing modules with illegal data layout strings,
  // delay parsing the data layout string until after upgrades and overrides
  // have been applied, allowing to fix illegal data layout strings.
  // Initialize to the current module's layout string in case none is specified.
  std::string TentativeDataLayoutStr = TheModule->getDataLayoutStr();
 
  auto ResolveDataLayout = [&]() -> Error {
    if (ResolvedDataLayout)
      return Error::success();
 
    // Datalayout and triple can't be parsed after this point.
    ResolvedDataLayout = true;
 
    // Auto-upgrade the layout string
    TentativeDataLayoutStr = llvm::UpgradeDataLayoutString(
        TentativeDataLayoutStr, TheModule->getTargetTriple().str());
 
    // Apply override
    if (Callbacks.DataLayout) {
      if (auto LayoutOverride = (*Callbacks.DataLayout)(
              TheModule->getTargetTriple().str(), TentativeDataLayoutStr))
        TentativeDataLayoutStr = *LayoutOverride;
    }
 
    // Now the layout string is finalized in TentativeDataLayoutStr. Parse it.
    Expected<DataLayout> MaybeDL = DataLayout::parse(TentativeDataLayoutStr);
    if (!MaybeDL)
      return MaybeDL.takeError();
 
    TheModule->setDataLayout(MaybeDL.get());
    return Error::success();
  };
 
  // Read all the records for this module.
  while (true) {
    Expected<llvm::BitstreamEntry> MaybeEntry = Stream.advance();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    llvm::BitstreamEntry Entry = MaybeEntry.get();
 
    switch (Entry.Kind) {
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock:
      if (Error Err = ResolveDataLayout())
        return Err;
      return globalCleanup();
 
    case BitstreamEntry::SubBlock:
      switch (Entry.ID) {
      default:  // Skip unknown content.
        if (Error Err = Stream.SkipBlock())
          return Err;
        break;
      case bitc::BLOCKINFO_BLOCK_ID:
        if (Error Err = readBlockInfo())
          return Err;
        break;
      case bitc::PARAMATTR_BLOCK_ID:
        if (Error Err = parseAttributeBlock())
          return Err;
        break;
      case bitc::PARAMATTR_GROUP_BLOCK_ID:
        if (Error Err = parseAttributeGroupBlock())
          return Err;
        break;
      case bitc::TYPE_BLOCK_ID_NEW:
        if (Error Err = parseTypeTable())
          return Err;
        break;
      case bitc::VALUE_SYMTAB_BLOCK_ID:
        if (!SeenValueSymbolTable) {
          // Either this is an old form VST without function index and an
          // associated VST forward declaration record (which would have caused
          // the VST to be jumped to and parsed before it was encountered
          // normally in the stream), or there were no function blocks to
          // trigger an earlier parsing of the VST.
          assert(VSTOffset == 0 || FunctionsWithBodies.empty());
          if (Error Err = parseValueSymbolTable())
            return Err;
          SeenValueSymbolTable = true;
        } else {
          // We must have had a VST forward declaration record, which caused
          // the parser to jump to and parse the VST earlier.
          assert(VSTOffset > 0);
          if (Error Err = Stream.SkipBlock())
            return Err;
        }
        break;
      case bitc::CONSTANTS_BLOCK_ID:
        if (Error Err = parseConstants())
          return Err;
        if (Error Err = resolveGlobalAndIndirectSymbolInits())
          return Err;
        break;
      case bitc::METADATA_BLOCK_ID:
        if (ShouldLazyLoadMetadata) {
          if (Error Err = rememberAndSkipMetadata())
            return Err;
          break;
        }
        assert(DeferredMetadataInfo.empty() && "Unexpected deferred metadata");
        if (Error Err = MDLoader->parseModuleMetadata())
          return Err;
        break;
      case bitc::METADATA_KIND_BLOCK_ID:
        if (Error Err = MDLoader->parseMetadataKinds())
          return Err;
        break;
      case bitc::FUNCTION_BLOCK_ID:
        if (Error Err = ResolveDataLayout())
          return Err;
 
        // If this is the first function body we've seen, reverse the
        // FunctionsWithBodies list.
        if (!SeenFirstFunctionBody) {
          std::reverse(FunctionsWithBodies.begin(), FunctionsWithBodies.end());
          if (Error Err = globalCleanup())
            return Err;
          SeenFirstFunctionBody = true;
        }
 
        if (VSTOffset > 0) {
          // If we have a VST forward declaration record, make sure we
          // parse the VST now if we haven't already. It is needed to
          // set up the DeferredFunctionInfo vector for lazy reading.
          if (!SeenValueSymbolTable) {
            if (Error Err = BitcodeReader::parseValueSymbolTable(VSTOffset))
              return Err;
            SeenValueSymbolTable = true;
            // Fall through so that we record the NextUnreadBit below.
            // This is necessary in case we have an anonymous function that
            // is later materialized. Since it will not have a VST entry we
            // need to fall back to the lazy parse to find its offset.
          } else {
            // If we have a VST forward declaration record, but have already
            // parsed the VST (just above, when the first function body was
            // encountered here), then we are resuming the parse after
            // materializing functions. The ResumeBit points to the
            // start of the last function block recorded in the
            // DeferredFunctionInfo map. Skip it.
            if (Error Err = Stream.SkipBlock())
              return Err;
            continue;
          }
        }
 
        // Support older bitcode files that did not have the function
        // index in the VST, nor a VST forward declaration record, as
        // well as anonymous functions that do not have VST entries.
        // Build the DeferredFunctionInfo vector on the fly.
        if (Error Err = rememberAndSkipFunctionBody())
          return Err;
 
        // Suspend parsing when we reach the function bodies. Subsequent
        // materialization calls will resume it when necessary. If the bitcode
        // file is old, the symbol table will be at the end instead and will not
        // have been seen yet. In this case, just finish the parse now.
        if (SeenValueSymbolTable) {
          NextUnreadBit = Stream.GetCurrentBitNo();
          // After the VST has been parsed, we need to make sure intrinsic name
          // are auto-upgraded.
          return globalCleanup();
        }
        break;
      case bitc::USELIST_BLOCK_ID:
        if (Error Err = parseUseLists())
          return Err;
        break;
      case bitc::OPERAND_BUNDLE_TAGS_BLOCK_ID:
        if (Error Err = parseOperandBundleTags())
          return Err;
        break;
      case bitc::SYNC_SCOPE_NAMES_BLOCK_ID:
        if (Error Err = parseSyncScopeNames())
          return Err;
        break;
      }
      continue;
 
    case BitstreamEntry::Record:
      // The interesting case.
      break;
    }
 
    // Read a record.
    Expected<unsigned> MaybeBitCode = Stream.readRecord(Entry.ID, Record);
    if (!MaybeBitCode)
      return MaybeBitCode.takeError();
    switch (unsigned BitCode = MaybeBitCode.get()) {
    default: break;  // Default behavior, ignore unknown content.
    case bitc::MODULE_CODE_VERSION: {
      Expected<unsigned> VersionOrErr = parseVersionRecord(Record);
      if (!VersionOrErr)
        return VersionOrErr.takeError();
      UseRelativeIDs = *VersionOrErr >= 1;
      break;
    }
    case bitc::MODULE_CODE_TRIPLE: {  // TRIPLE: [strchr x N]
      if (ResolvedDataLayout)
        return error("target triple too late in module");
      std::string S;
      if (convertToString(Record, 0, S))
        return error("Invalid triple record");
      TheModule->setTargetTriple(Triple(std::move(S)));
      break;
    }
    case bitc::MODULE_CODE_DATALAYOUT: {  // DATALAYOUT: [strchr x N]
      if (ResolvedDataLayout)
        return error("datalayout too late in module");
      if (convertToString(Record, 0, TentativeDataLayoutStr))
        return error("Invalid data layout record");
      break;
    }
    case bitc::MODULE_CODE_ASM: {  // ASM: [strchr x N]
      std::string S;
      if (convertToString(Record, 0, S))
        return error("Invalid asm record");
      TheModule->setModuleInlineAsm(S);
      break;
    }
    case bitc::MODULE_CODE_DEPLIB: {  // DEPLIB: [strchr x N]
      // Deprecated, but still needed to read old bitcode files.
      std::string S;
      if (convertToString(Record, 0, S))
        return error("Invalid deplib record");
      // Ignore value.
      break;
    }
    case bitc::MODULE_CODE_SECTIONNAME: {  // SECTIONNAME: [strchr x N]
      std::string S;
      if (convertToString(Record, 0, S))
        return error("Invalid section name record");
      SectionTable.push_back(S);
      break;
    }
    case bitc::MODULE_CODE_GCNAME: {  // SECTIONNAME: [strchr x N]
      std::string S;
      if (convertToString(Record, 0, S))
        return error("Invalid gcname record");
      GCTable.push_back(S);
      break;
    }
    case bitc::MODULE_CODE_COMDAT:
      if (Error Err = parseComdatRecord(Record))
        return Err;
      break;
    // FIXME: BitcodeReader should handle {GLOBALVAR, FUNCTION, ALIAS, IFUNC}
    // written by ThinLinkBitcodeWriter. See
    // `ThinLinkBitcodeWriter::writeSimplifiedModuleInfo` for the format of each
    // record
    // (https://github.com/llvm/llvm-project/blob/b6a93967d9c11e79802b5e75cec1584d6c8aa472/llvm/lib/Bitcode/Writer/BitcodeWriter.cpp#L4714)
    case bitc::MODULE_CODE_GLOBALVAR:
      if (Error Err = parseGlobalVarRecord(Record))
        return Err;
      break;
    case bitc::MODULE_CODE_FUNCTION:
      if (Error Err = ResolveDataLayout())
        return Err;
      if (Error Err = parseFunctionRecord(Record))
        return Err;
      break;
    case bitc::MODULE_CODE_IFUNC:
    case bitc::MODULE_CODE_ALIAS:
    case bitc::MODULE_CODE_ALIAS_OLD:
      if (Error Err = parseGlobalIndirectSymbolRecord(BitCode, Record))
        return Err;
      break;
    /// MODULE_CODE_VSTOFFSET: [offset]
    case bitc::MODULE_CODE_VSTOFFSET:
      if (Record.empty())
        return error("Invalid vstoffset record");
      // Note that we subtract 1 here because the offset is relative to one word
      // before the start of the identification or module block, which was
      // historically always the start of the regular bitcode header.
      VSTOffset = Record[0] - 1;
      break;
    /// MODULE_CODE_SOURCE_FILENAME: [namechar x N]
    case bitc::MODULE_CODE_SOURCE_FILENAME:
      SmallString<128> ValueName;
      if (convertToString(Record, 0, ValueName))
        return error("Invalid source filename record");
      TheModule->setSourceFileName(ValueName);
      break;
    }
    Record.clear();
  }
  this->ValueTypeCallback = std::nullopt;
  return Error::success();
}
 
Error BitcodeReader::parseBitcodeInto(Module *M, bool ShouldLazyLoadMetadata,
                                      bool IsImporting,
                                      ParserCallbacks Callbacks) {
  TheModule = M;
  MetadataLoaderCallbacks MDCallbacks;
  MDCallbacks.GetTypeByID = [&](unsigned ID) { return getTypeByID(ID); };
  MDCallbacks.GetContainedTypeID = [&](unsigned I, unsigned J) {
    return getContainedTypeID(I, J);
  };
  MDCallbacks.MDType = Callbacks.MDType;
  MDLoader = MetadataLoader(Stream, *M, ValueList, IsImporting, MDCallbacks);
  return parseModule(0, ShouldLazyLoadMetadata, Callbacks);
}
 
Error BitcodeReader::typeCheckLoadStoreInst(Type *ValType, Type *PtrType) {
  if (!isa<PointerType>(PtrType))
    return error("Load/Store operand is not a pointer type");
  if (!PointerType::isLoadableOrStorableType(ValType))
    return error("Cannot load/store from pointer");
  return Error::success();
}
 
Error BitcodeReader::propagateAttributeTypes(CallBase *CB,
                                             ArrayRef<unsigned> ArgTyIDs) {
  AttributeList Attrs = CB->getAttributes();
  for (unsigned i = 0; i != CB->arg_size(); ++i) {
    for (Attribute::AttrKind Kind : {Attribute::ByVal, Attribute::StructRet,
                                     Attribute::InAlloca}) {
      if (!Attrs.hasParamAttr(i, Kind) ||
          Attrs.getParamAttr(i, Kind).getValueAsType())
        continue;
 
      Type *PtrEltTy = getPtrElementTypeByID(ArgTyIDs[i]);
      if (!PtrEltTy)
        return error("Missing element type for typed attribute upgrade");
 
      Attribute NewAttr;
      switch (Kind) {
      case Attribute::ByVal:
        NewAttr = Attribute::getWithByValType(Context, PtrEltTy);
        break;
      case Attribute::StructRet:
        NewAttr = Attribute::getWithStructRetType(Context, PtrEltTy);
        break;
      case Attribute::InAlloca:
        NewAttr = Attribute::getWithInAllocaType(Context, PtrEltTy);
        break;
      default:
        llvm_unreachable("not an upgraded type attribute");
      }
 
      Attrs = Attrs.addParamAttribute(Context, i, NewAttr);
    }
  }
 
  if (CB->isInlineAsm()) {
    const InlineAsm *IA = cast<InlineAsm>(CB->getCalledOperand());
    unsigned ArgNo = 0;
    for (const InlineAsm::ConstraintInfo &CI : IA->ParseConstraints()) {
      if (!CI.hasArg())
        continue;
 
      if (CI.isIndirect && !Attrs.getParamElementType(ArgNo)) {
        Type *ElemTy = getPtrElementTypeByID(ArgTyIDs[ArgNo]);
        if (!ElemTy)
          return error("Missing element type for inline asm upgrade");
        Attrs = Attrs.addParamAttribute(
            Context, ArgNo,
            Attribute::get(Context, Attribute::ElementType, ElemTy));
      }
 
      ArgNo++;
    }
  }
 
  switch (CB->getIntrinsicID()) {
  case Intrinsic::preserve_array_access_index:
  case Intrinsic::preserve_struct_access_index:
  case Intrinsic::aarch64_ldaxr:
  case Intrinsic::aarch64_ldxr:
  case Intrinsic::aarch64_stlxr:
  case Intrinsic::aarch64_stxr:
  case Intrinsic::arm_ldaex:
  case Intrinsic::arm_ldrex:
  case Intrinsic::arm_stlex:
  case Intrinsic::arm_strex: {
    unsigned ArgNo;
    switch (CB->getIntrinsicID()) {
    case Intrinsic::aarch64_stlxr:
    case Intrinsic::aarch64_stxr:
    case Intrinsic::arm_stlex:
    case Intrinsic::arm_strex:
      ArgNo = 1;
      break;
    default:
      ArgNo = 0;
      break;
    }
    if (!Attrs.getParamElementType(ArgNo)) {
      Type *ElTy = getPtrElementTypeByID(ArgTyIDs[ArgNo]);
      if (!ElTy)
        return error("Missing element type for elementtype upgrade");
      Attribute NewAttr = Attribute::get(Context, Attribute::ElementType, ElTy);
      Attrs = Attrs.addParamAttribute(Context, ArgNo, NewAttr);
    }
    break;
  }
  default:
    break;
  }
 
  CB->setAttributes(Attrs);
  return Error::success();
}
 
/// Lazily parse the specified function body block.
Error BitcodeReader::parseFunctionBody(Function *F) {
  if (Error Err = Stream.EnterSubBlock(bitc::FUNCTION_BLOCK_ID))
    return Err;
 
  // Unexpected unresolved metadata when parsing function.
  if (MDLoader->hasFwdRefs())
    return error("Invalid function metadata: incoming forward references");
 
  InstructionList.clear();
  unsigned ModuleValueListSize = ValueList.size();
  unsigned ModuleMDLoaderSize = MDLoader->size();
 
  // Add all the function arguments to the value table.
  unsigned ArgNo = 0;
  unsigned FTyID = FunctionTypeIDs[F];
  for (Argument &I : F->args()) {
    unsigned ArgTyID = getContainedTypeID(FTyID, ArgNo + 1);
    assert(I.getType() == getTypeByID(ArgTyID) &&
           "Incorrect fully specified type for Function Argument");
    ValueList.push_back(&I, ArgTyID);
    ++ArgNo;
  }
  unsigned NextValueNo = ValueList.size();
  BasicBlock *CurBB = nullptr;
  unsigned CurBBNo = 0;
  // Block into which constant expressions from phi nodes are materialized.
  BasicBlock *PhiConstExprBB = nullptr;
  // Edge blocks for phi nodes into which constant expressions have been
  // expanded.
  SmallMapVector<std::pair<BasicBlock *, BasicBlock *>, BasicBlock *, 4>
    ConstExprEdgeBBs;
 
  DebugLoc LastLoc;
  auto getLastInstruction = [&]() -> Instruction * {
    if (CurBB && !CurBB->empty())
      return &CurBB->back();
    else if (CurBBNo && FunctionBBs[CurBBNo - 1] &&
             !FunctionBBs[CurBBNo - 1]->empty())
      return &FunctionBBs[CurBBNo - 1]->back();
    return nullptr;
  };
 
  std::vector<OperandBundleDef> OperandBundles;
 
  // Read all the records.
  SmallVector<uint64_t, 64> Record;
 
  while (true) {
    Expected<llvm::BitstreamEntry> MaybeEntry = Stream.advance();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    llvm::BitstreamEntry Entry = MaybeEntry.get();
 
    switch (Entry.Kind) {
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock:
      goto OutOfRecordLoop;
 
    case BitstreamEntry::SubBlock:
      switch (Entry.ID) {
      default:  // Skip unknown content.
        if (Error Err = Stream.SkipBlock())
          return Err;
        break;
      case bitc::CONSTANTS_BLOCK_ID:
        if (Error Err = parseConstants())
          return Err;
        NextValueNo = ValueList.size();
        break;
      case bitc::VALUE_SYMTAB_BLOCK_ID:
        if (Error Err = parseValueSymbolTable())
          return Err;
        break;
      case bitc::METADATA_ATTACHMENT_ID:
        if (Error Err = MDLoader->parseMetadataAttachment(*F, InstructionList))
          return Err;
        break;
      case bitc::METADATA_BLOCK_ID:
        assert(DeferredMetadataInfo.empty() &&
               "Must read all module-level metadata before function-level");
        if (Error Err = MDLoader->parseFunctionMetadata())
          return Err;
        break;
      case bitc::USELIST_BLOCK_ID:
        if (Error Err = parseUseLists())
          return Err;
        break;
      }
      continue;
 
    case BitstreamEntry::Record:
      // The interesting case.
      break;
    }
 
    // Read a record.
    Record.clear();
    Instruction *I = nullptr;
    unsigned ResTypeID = InvalidTypeID;
    Expected<unsigned> MaybeBitCode = Stream.readRecord(Entry.ID, Record);
    if (!MaybeBitCode)
      return MaybeBitCode.takeError();
    switch (unsigned BitCode = MaybeBitCode.get()) {
    default: // Default behavior: reject
      return error("Invalid value");
    case bitc::FUNC_CODE_DECLAREBLOCKS: {   // DECLAREBLOCKS: [nblocks]
      if (Record.empty() || Record[0] == 0)
        return error("Invalid declareblocks record");
      // Create all the basic blocks for the function.
      FunctionBBs.resize(Record[0]);
 
      // See if anything took the address of blocks in this function.
      auto BBFRI = BasicBlockFwdRefs.find(F);
      if (BBFRI == BasicBlockFwdRefs.end()) {
        for (BasicBlock *&BB : FunctionBBs)
          BB = BasicBlock::Create(Context, "", F);
      } else {
        auto &BBRefs = BBFRI->second;
        // Check for invalid basic block references.
        if (BBRefs.size() > FunctionBBs.size())
          return error("Invalid ID");
        assert(!BBRefs.empty() && "Unexpected empty array");
        assert(!BBRefs.front() && "Invalid reference to entry block");
        for (unsigned I = 0, E = FunctionBBs.size(), RE = BBRefs.size(); I != E;
             ++I)
          if (I < RE && BBRefs[I]) {
            BBRefs[I]->insertInto(F);
            FunctionBBs[I] = BBRefs[I];
          } else {
            FunctionBBs[I] = BasicBlock::Create(Context, "", F);
          }
 
        // Erase from the table.
        BasicBlockFwdRefs.erase(BBFRI);
      }
 
      CurBB = FunctionBBs[0];
      continue;
    }
 
    case bitc::FUNC_CODE_BLOCKADDR_USERS: // BLOCKADDR_USERS: [vals...]
      // The record should not be emitted if it's an empty list.
      if (Record.empty())
        return error("Invalid blockaddr users record");
      // When we have the RARE case of a BlockAddress Constant that is not
      // scoped to the Function it refers to, we need to conservatively
      // materialize the referred to Function, regardless of whether or not
      // that Function will ultimately be linked, otherwise users of
      // BitcodeReader might start splicing out Function bodies such that we
      // might no longer be able to materialize the BlockAddress since the
      // BasicBlock (and entire body of the Function) the BlockAddress refers
      // to may have been moved. In the case that the user of BitcodeReader
      // decides ultimately not to link the Function body, materializing here
      // could be considered wasteful, but it's better than a deserialization
      // failure as described. This keeps BitcodeReader unaware of complex
      // linkage policy decisions such as those use by LTO, leaving those
      // decisions "one layer up."
      for (uint64_t ValID : Record)
        if (auto *F = dyn_cast<Function>(ValueList[ValID]))
          BackwardRefFunctions.push_back(F);
        else
          return error("Invalid blockaddr users record");
 
      continue;
 
    case bitc::FUNC_CODE_DEBUG_LOC_AGAIN:  // DEBUG_LOC_AGAIN
      // This record indicates that the last instruction is at the same
      // location as the previous instruction with a location.
      I = getLastInstruction();
 
      if (!I)
        return error("Invalid debug_loc_again record");
      I->setDebugLoc(LastLoc);
      I = nullptr;
      continue;
 
    case bitc::FUNC_CODE_DEBUG_LOC: {      // DEBUG_LOC: [line, col, scope, ia]
      I = getLastInstruction();
      if (!I || Record.size() < 4)
        return error("Invalid debug loc record");
 
      unsigned Line = Record[0], Col = Record[1];
      unsigned ScopeID = Record[2], IAID = Record[3];
      bool isImplicitCode = Record.size() >= 5 && Record[4];
      uint64_t AtomGroup = Record.size() == 7 ? Record[5] : 0;
      uint8_t AtomRank = Record.size() == 7 ? Record[6] : 0;
 
      MDNode *Scope = nullptr, *IA = nullptr;
      if (ScopeID) {
        Scope = dyn_cast_or_null<MDNode>(
            MDLoader->getMetadataFwdRefOrLoad(ScopeID - 1));
        if (!Scope)
          return error("Invalid debug loc record");
      }
      if (IAID) {
        IA = dyn_cast_or_null<MDNode>(
            MDLoader->getMetadataFwdRefOrLoad(IAID - 1));
        if (!IA)
          return error("Invalid debug loc record");
      }
 
      LastLoc = DILocation::get(Scope->getContext(), Line, Col, Scope, IA,
                                isImplicitCode, AtomGroup, AtomRank);
      I->setDebugLoc(LastLoc);
      I = nullptr;
      continue;
    }
    case bitc::FUNC_CODE_INST_UNOP: {    // UNOP: [opval, ty, opcode]
      unsigned OpNum = 0;
      Value *LHS;
      unsigned TypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, LHS, TypeID, CurBB) ||
          OpNum+1 > Record.size())
        return error("Invalid unary operator record");
 
      int Opc = getDecodedUnaryOpcode(Record[OpNum++], LHS->getType());
      if (Opc == -1)
        return error("Invalid unary operator record");
      I = UnaryOperator::Create((Instruction::UnaryOps)Opc, LHS);
      ResTypeID = TypeID;
      InstructionList.push_back(I);
      if (OpNum < Record.size()) {
        if (isa<FPMathOperator>(I)) {
          FastMathFlags FMF = getDecodedFastMathFlags(Record[OpNum]);
          if (FMF.any())
            I->setFastMathFlags(FMF);
        }
      }
      break;
    }
    case bitc::FUNC_CODE_INST_BINOP: {    // BINOP: [opval, ty, opval, opcode]
      unsigned OpNum = 0;
      Value *LHS, *RHS;
      unsigned TypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, LHS, TypeID, CurBB) ||
          popValue(Record, OpNum, NextValueNo, LHS->getType(), TypeID, RHS,
                   CurBB) ||
          OpNum+1 > Record.size())
        return error("Invalid binary operator record");
 
      int Opc = getDecodedBinaryOpcode(Record[OpNum++], LHS->getType());
      if (Opc == -1)
        return error("Invalid binary operator record");
      I = BinaryOperator::Create((Instruction::BinaryOps)Opc, LHS, RHS);
      ResTypeID = TypeID;
      InstructionList.push_back(I);
      if (OpNum < Record.size()) {
        if (Opc == Instruction::Add ||
            Opc == Instruction::Sub ||
            Opc == Instruction::Mul ||
            Opc == Instruction::Shl) {
          if (Record[OpNum] & (1 << bitc::OBO_NO_SIGNED_WRAP))
            cast<BinaryOperator>(I)->setHasNoSignedWrap(true);
          if (Record[OpNum] & (1 << bitc::OBO_NO_UNSIGNED_WRAP))
            cast<BinaryOperator>(I)->setHasNoUnsignedWrap(true);
        } else if (Opc == Instruction::SDiv ||
                   Opc == Instruction::UDiv ||
                   Opc == Instruction::LShr ||
                   Opc == Instruction::AShr) {
          if (Record[OpNum] & (1 << bitc::PEO_EXACT))
            cast<BinaryOperator>(I)->setIsExact(true);
        } else if (Opc == Instruction::Or) {
          if (Record[OpNum] & (1 << bitc::PDI_DISJOINT))
            cast<PossiblyDisjointInst>(I)->setIsDisjoint(true);
        } else if (isa<FPMathOperator>(I)) {
          FastMathFlags FMF = getDecodedFastMathFlags(Record[OpNum]);
          if (FMF.any())
            I->setFastMathFlags(FMF);
        }
      }
      break;
    }
    case bitc::FUNC_CODE_INST_CAST: {    // CAST: [opval, opty, destty, castopc]
      unsigned OpNum = 0;
      Value *Op;
      unsigned OpTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, Op, OpTypeID, CurBB) ||
          OpNum + 1 > Record.size())
        return error("Invalid cast record");
 
      ResTypeID = Record[OpNum++];
      Type *ResTy = getTypeByID(ResTypeID);
      int Opc = getDecodedCastOpcode(Record[OpNum++]);
 
      if (Opc == -1 || !ResTy)
        return error("Invalid cast record");
      Instruction *Temp = nullptr;
      if ((I = UpgradeBitCastInst(Opc, Op, ResTy, Temp))) {
        if (Temp) {
          InstructionList.push_back(Temp);
          assert(CurBB && "No current BB?");
          Temp->insertInto(CurBB, CurBB->end());
        }
      } else {
        auto CastOp = (Instruction::CastOps)Opc;
        if (!CastInst::castIsValid(CastOp, Op, ResTy))
          return error("Invalid cast");
        I = CastInst::Create(CastOp, Op, ResTy);
      }
 
      if (OpNum < Record.size()) {
        if (Opc == Instruction::ZExt || Opc == Instruction::UIToFP) {
          if (Record[OpNum] & (1 << bitc::PNNI_NON_NEG))
            cast<PossiblyNonNegInst>(I)->setNonNeg(true);
        } else if (Opc == Instruction::Trunc) {
          if (Record[OpNum] & (1 << bitc::TIO_NO_UNSIGNED_WRAP))
            cast<TruncInst>(I)->setHasNoUnsignedWrap(true);
          if (Record[OpNum] & (1 << bitc::TIO_NO_SIGNED_WRAP))
            cast<TruncInst>(I)->setHasNoSignedWrap(true);
        }
        if (isa<FPMathOperator>(I)) {
          FastMathFlags FMF = getDecodedFastMathFlags(Record[OpNum]);
          if (FMF.any())
            I->setFastMathFlags(FMF);
        }
      }
 
      InstructionList.push_back(I);
      break;
    }
    case bitc::FUNC_CODE_INST_INBOUNDS_GEP_OLD:
    case bitc::FUNC_CODE_INST_GEP_OLD:
    case bitc::FUNC_CODE_INST_GEP: { // GEP: type, [n x operands]
      unsigned OpNum = 0;
 
      unsigned TyID;
      Type *Ty;
      GEPNoWrapFlags NW;
 
      if (BitCode == bitc::FUNC_CODE_INST_GEP) {
        NW = toGEPNoWrapFlags(Record[OpNum++]);
        TyID = Record[OpNum++];
        Ty = getTypeByID(TyID);
      } else {
        if (BitCode == bitc::FUNC_CODE_INST_INBOUNDS_GEP_OLD)
          NW = GEPNoWrapFlags::inBounds();
        TyID = InvalidTypeID;
        Ty = nullptr;
      }
 
      Value *BasePtr;
      unsigned BasePtrTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, BasePtr, BasePtrTypeID,
                           CurBB))
        return error("Invalid gep record");
 
      if (!Ty) {
        TyID = getContainedTypeID(BasePtrTypeID);
        if (BasePtr->getType()->isVectorTy())
          TyID = getContainedTypeID(TyID);
        Ty = getTypeByID(TyID);
      }
 
      SmallVector<Value*, 16> GEPIdx;
      while (OpNum != Record.size()) {
        Value *Op;
        unsigned OpTypeID;
        if (getValueTypePair(Record, OpNum, NextValueNo, Op, OpTypeID, CurBB))
          return error("Invalid gep record");
        GEPIdx.push_back(Op);
      }
 
      auto *GEP = GetElementPtrInst::Create(Ty, BasePtr, GEPIdx);
      I = GEP;
 
      ResTypeID = TyID;
      if (cast<GEPOperator>(I)->getNumIndices() != 0) {
        auto GTI = std::next(gep_type_begin(I));
        for (Value *Idx : drop_begin(cast<GEPOperator>(I)->indices())) {
          unsigned SubType = 0;
          if (GTI.isStruct()) {
            ConstantInt *IdxC =
                Idx->getType()->isVectorTy()
                    ? cast<ConstantInt>(cast<Constant>(Idx)->getSplatValue())
                    : cast<ConstantInt>(Idx);
            SubType = IdxC->getZExtValue();
          }
          ResTypeID = getContainedTypeID(ResTypeID, SubType);
          ++GTI;
        }
      }
 
      // At this point ResTypeID is the result element type. We need a pointer
      // or vector of pointer to it.
      ResTypeID = getVirtualTypeID(I->getType()->getScalarType(), ResTypeID);
      if (I->getType()->isVectorTy())
        ResTypeID = getVirtualTypeID(I->getType(), ResTypeID);
 
      InstructionList.push_back(I);
      GEP->setNoWrapFlags(NW);
      break;
    }
 
    case bitc::FUNC_CODE_INST_EXTRACTVAL: {
                                       // EXTRACTVAL: [opty, opval, n x indices]
      unsigned OpNum = 0;
      Value *Agg;
      unsigned AggTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, Agg, AggTypeID, CurBB))
        return error("Invalid extractvalue record");
      Type *Ty = Agg->getType();
 
      unsigned RecSize = Record.size();
      if (OpNum == RecSize)
        return error("EXTRACTVAL: Invalid instruction with 0 indices");
 
      SmallVector<unsigned, 4> EXTRACTVALIdx;
      ResTypeID = AggTypeID;
      for (; OpNum != RecSize; ++OpNum) {
        bool IsArray = Ty->isArrayTy();
        bool IsStruct = Ty->isStructTy();
        uint64_t Index = Record[OpNum];
 
        if (!IsStruct && !IsArray)
          return error("EXTRACTVAL: Invalid type");
        if ((unsigned)Index != Index)
          return error("Invalid value");
        if (IsStruct && Index >= Ty->getStructNumElements())
          return error("EXTRACTVAL: Invalid struct index");
        if (IsArray && Index >= Ty->getArrayNumElements())
          return error("EXTRACTVAL: Invalid array index");
        EXTRACTVALIdx.push_back((unsigned)Index);
 
        if (IsStruct) {
          Ty = Ty->getStructElementType(Index);
          ResTypeID = getContainedTypeID(ResTypeID, Index);
        } else {
          Ty = Ty->getArrayElementType();
          ResTypeID = getContainedTypeID(ResTypeID);
        }
      }
 
      I = ExtractValueInst::Create(Agg, EXTRACTVALIdx);
      InstructionList.push_back(I);
      break;
    }
 
    case bitc::FUNC_CODE_INST_INSERTVAL: {
                           // INSERTVAL: [opty, opval, opty, opval, n x indices]
      unsigned OpNum = 0;
      Value *Agg;
      unsigned AggTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, Agg, AggTypeID, CurBB))
        return error("Invalid insertvalue record");
      Value *Val;
      unsigned ValTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, Val, ValTypeID, CurBB))
        return error("Invalid insertvalue record");
 
      unsigned RecSize = Record.size();
      if (OpNum == RecSize)
        return error("INSERTVAL: Invalid instruction with 0 indices");
 
      SmallVector<unsigned, 4> INSERTVALIdx;
      Type *CurTy = Agg->getType();
      for (; OpNum != RecSize; ++OpNum) {
        bool IsArray = CurTy->isArrayTy();
        bool IsStruct = CurTy->isStructTy();
        uint64_t Index = Record[OpNum];
 
        if (!IsStruct && !IsArray)
          return error("INSERTVAL: Invalid type");
        if ((unsigned)Index != Index)
          return error("Invalid value");
        if (IsStruct && Index >= CurTy->getStructNumElements())
          return error("INSERTVAL: Invalid struct index");
        if (IsArray && Index >= CurTy->getArrayNumElements())
          return error("INSERTVAL: Invalid array index");
 
        INSERTVALIdx.push_back((unsigned)Index);
        if (IsStruct)
          CurTy = CurTy->getStructElementType(Index);
        else
          CurTy = CurTy->getArrayElementType();
      }
 
      if (CurTy != Val->getType())
        return error("Inserted value type doesn't match aggregate type");
 
      I = InsertValueInst::Create(Agg, Val, INSERTVALIdx);
      ResTypeID = AggTypeID;
      InstructionList.push_back(I);
      break;
    }
 
    case bitc::FUNC_CODE_INST_SELECT: { // SELECT: [opval, ty, opval, opval]
      // obsolete form of select
      // handles select i1 ... in old bitcode
      unsigned OpNum = 0;
      Value *TrueVal, *FalseVal, *Cond;
      unsigned TypeID;
      Type *CondType = Type::getInt1Ty(Context);
      if (getValueTypePair(Record, OpNum, NextValueNo, TrueVal, TypeID,
                           CurBB) ||
          popValue(Record, OpNum, NextValueNo, TrueVal->getType(), TypeID,
                   FalseVal, CurBB) ||
          popValue(Record, OpNum, NextValueNo, CondType,
                   getVirtualTypeID(CondType), Cond, CurBB))
        return error("Invalid select record");
 
      I = SelectInst::Create(Cond, TrueVal, FalseVal);
      ResTypeID = TypeID;
      InstructionList.push_back(I);
      break;
    }
 
    case bitc::FUNC_CODE_INST_VSELECT: {// VSELECT: [ty,opval,opval,predty,pred]
      // new form of select
      // handles select i1 or select [N x i1]
      unsigned OpNum = 0;
      Value *TrueVal, *FalseVal, *Cond;
      unsigned ValTypeID, CondTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, TrueVal, ValTypeID,
                           CurBB) ||
          popValue(Record, OpNum, NextValueNo, TrueVal->getType(), ValTypeID,
                   FalseVal, CurBB) ||
          getValueTypePair(Record, OpNum, NextValueNo, Cond, CondTypeID, CurBB))
        return error("Invalid vector select record");
 
      // select condition can be either i1 or [N x i1]
      if (VectorType* vector_type =
          dyn_cast<VectorType>(Cond->getType())) {
        // expect <n x i1>
        if (vector_type->getElementType() != Type::getInt1Ty(Context))
          return error("Invalid type for value");
      } else {
        // expect i1
        if (Cond->getType() != Type::getInt1Ty(Context))
          return error("Invalid type for value");
      }
 
      I = SelectInst::Create(Cond, TrueVal, FalseVal);
      ResTypeID = ValTypeID;
      InstructionList.push_back(I);
      if (OpNum < Record.size() && isa<FPMathOperator>(I)) {
        FastMathFlags FMF = getDecodedFastMathFlags(Record[OpNum]);
        if (FMF.any())
          I->setFastMathFlags(FMF);
      }
      break;
    }
 
    case bitc::FUNC_CODE_INST_EXTRACTELT: { // EXTRACTELT: [opty, opval, opval]
      unsigned OpNum = 0;
      Value *Vec, *Idx;
      unsigned VecTypeID, IdxTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, Vec, VecTypeID, CurBB) ||
          getValueTypePair(Record, OpNum, NextValueNo, Idx, IdxTypeID, CurBB))
        return error("Invalid extractelement record");
      if (!Vec->getType()->isVectorTy())
        return error("Invalid type for value");
      I = ExtractElementInst::Create(Vec, Idx);
      ResTypeID = getContainedTypeID(VecTypeID);
      InstructionList.push_back(I);
      break;
    }
 
    case bitc::FUNC_CODE_INST_INSERTELT: { // INSERTELT: [ty, opval,opval,opval]
      unsigned OpNum = 0;
      Value *Vec, *Elt, *Idx;
      unsigned VecTypeID, IdxTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, Vec, VecTypeID, CurBB))
        return error("Invalid insertelement record");
      if (!Vec->getType()->isVectorTy())
        return error("Invalid type for value");
      if (popValue(Record, OpNum, NextValueNo,
                   cast<VectorType>(Vec->getType())->getElementType(),
                   getContainedTypeID(VecTypeID), Elt, CurBB) ||
          getValueTypePair(Record, OpNum, NextValueNo, Idx, IdxTypeID, CurBB))
        return error("Invalid insert element record");
      I = InsertElementInst::Create(Vec, Elt, Idx);
      ResTypeID = VecTypeID;
      InstructionList.push_back(I);
      break;
    }
 
    case bitc::FUNC_CODE_INST_SHUFFLEVEC: {// SHUFFLEVEC: [opval,ty,opval,opval]
      unsigned OpNum = 0;
      Value *Vec1, *Vec2, *Mask;
      unsigned Vec1TypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, Vec1, Vec1TypeID,
                           CurBB) ||
          popValue(Record, OpNum, NextValueNo, Vec1->getType(), Vec1TypeID,
                   Vec2, CurBB))
        return error("Invalid shufflevector record");
 
      unsigned MaskTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, Mask, MaskTypeID, CurBB))
        return error("Invalid shufflevector record");
      if (!Vec1->getType()->isVectorTy() || !Vec2->getType()->isVectorTy())
        return error("Invalid type for value");
 
      I = new ShuffleVectorInst(Vec1, Vec2, Mask);
      ResTypeID =
          getVirtualTypeID(I->getType(), getContainedTypeID(Vec1TypeID));
      InstructionList.push_back(I);
      break;
    }
 
    case bitc::FUNC_CODE_INST_CMP:   // CMP: [opty, opval, opval, pred]
      // Old form of ICmp/FCmp returning bool
      // Existed to differentiate between icmp/fcmp and vicmp/vfcmp which were
      // both legal on vectors but had different behaviour.
    case bitc::FUNC_CODE_INST_CMP2: { // CMP2: [opty, opval, opval, pred]
      // FCmp/ICmp returning bool or vector of bool
 
      unsigned OpNum = 0;
      Value *LHS, *RHS;
      unsigned LHSTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, LHS, LHSTypeID, CurBB) ||
          popValue(Record, OpNum, NextValueNo, LHS->getType(), LHSTypeID, RHS,
                   CurBB))
        return error("Invalid comparison record");
 
      if (OpNum >= Record.size())
        return error(
            "Invalid record: operand number exceeded available operands");
 
      CmpInst::Predicate PredVal = CmpInst::Predicate(Record[OpNum]);
      bool IsFP = LHS->getType()->isFPOrFPVectorTy();
      FastMathFlags FMF;
      if (IsFP && Record.size() > OpNum+1)
        FMF = getDecodedFastMathFlags(Record[++OpNum]);
 
      if (IsFP) {
        if (!CmpInst::isFPPredicate(PredVal))
          return error("Invalid fcmp predicate");
        I = new FCmpInst(PredVal, LHS, RHS);
      } else {
        if (!CmpInst::isIntPredicate(PredVal))
          return error("Invalid icmp predicate");
        I = new ICmpInst(PredVal, LHS, RHS);
        if (Record.size() > OpNum + 1 &&
            (Record[++OpNum] & (1 << bitc::ICMP_SAME_SIGN)))
          cast<ICmpInst>(I)->setSameSign();
      }
 
      if (OpNum + 1 != Record.size())
        return error("Invalid comparison record");
 
      ResTypeID = getVirtualTypeID(I->getType()->getScalarType());
      if (LHS->getType()->isVectorTy())
        ResTypeID = getVirtualTypeID(I->getType(), ResTypeID);
 
      if (FMF.any())
        I->setFastMathFlags(FMF);
      InstructionList.push_back(I);
      break;
    }
 
    case bitc::FUNC_CODE_INST_RET: // RET: [opty,opval<optional>]
      {
        unsigned Size = Record.size();
        if (Size == 0) {
          I = ReturnInst::Create(Context);
          InstructionList.push_back(I);
          break;
        }
 
        unsigned OpNum = 0;
        Value *Op = nullptr;
        unsigned OpTypeID;
        if (getValueTypePair(Record, OpNum, NextValueNo, Op, OpTypeID, CurBB))
          return error("Invalid ret record");
        if (OpNum != Record.size())
          return error("Invalid ret record");
 
        I = ReturnInst::Create(Context, Op);
        InstructionList.push_back(I);
        break;
      }
    case bitc::FUNC_CODE_INST_BR: { // BR: [bb#, bb#, opval] or [bb#]
      if (Record.size() != 1 && Record.size() != 3)
        return error("Invalid br record");
      BasicBlock *TrueDest = getBasicBlock(Record[0]);
      if (!TrueDest)
        return error("Invalid br record");
 
      if (Record.size() == 1) {
        I = UncondBrInst::Create(TrueDest);
        InstructionList.push_back(I);
      }
      else {
        BasicBlock *FalseDest = getBasicBlock(Record[1]);
        Type *CondType = Type::getInt1Ty(Context);
        Value *Cond = getValue(Record, 2, NextValueNo, CondType,
                               getVirtualTypeID(CondType), CurBB);
        if (!FalseDest || !Cond)
          return error("Invalid br record");
        I = CondBrInst::Create(Cond, TrueDest, FalseDest);
        InstructionList.push_back(I);
      }
      break;
    }
    case bitc::FUNC_CODE_INST_CLEANUPRET: { // CLEANUPRET: [val] or [val,bb#]
      if (Record.size() != 1 && Record.size() != 2)
        return error("Invalid cleanupret record");
      unsigned Idx = 0;
      Type *TokenTy = Type::getTokenTy(Context);
      Value *CleanupPad = getValue(Record, Idx++, NextValueNo, TokenTy,
                                   getVirtualTypeID(TokenTy), CurBB);
      if (!CleanupPad)
        return error("Invalid cleanupret record");
      BasicBlock *UnwindDest = nullptr;
      if (Record.size() == 2) {
        UnwindDest = getBasicBlock(Record[Idx++]);
        if (!UnwindDest)
          return error("Invalid cleanupret record");
      }
 
      I = CleanupReturnInst::Create(CleanupPad, UnwindDest);
      InstructionList.push_back(I);
      break;
    }
    case bitc::FUNC_CODE_INST_CATCHRET: { // CATCHRET: [val,bb#]
      if (Record.size() != 2)
        return error("Invalid catchret record");
      unsigned Idx = 0;
      Type *TokenTy = Type::getTokenTy(Context);
      Value *CatchPad = getValue(Record, Idx++, NextValueNo, TokenTy,
                                 getVirtualTypeID(TokenTy), CurBB);
      if (!CatchPad)
        return error("Invalid catchret record");
      BasicBlock *BB = getBasicBlock(Record[Idx++]);
      if (!BB)
        return error("Invalid catchret record");
 
      I = CatchReturnInst::Create(CatchPad, BB);
      InstructionList.push_back(I);
      break;
    }
    case bitc::FUNC_CODE_INST_CATCHSWITCH: { // CATCHSWITCH: [tok,num,(bb)*,bb?]
      // We must have, at minimum, the outer scope and the number of arguments.
      if (Record.size() < 2)
        return error("Invalid catchswitch record");
 
      unsigned Idx = 0;
 
      Type *TokenTy = Type::getTokenTy(Context);
      Value *ParentPad = getValue(Record, Idx++, NextValueNo, TokenTy,
                                  getVirtualTypeID(TokenTy), CurBB);
      if (!ParentPad)
        return error("Invalid catchswitch record");
 
      unsigned NumHandlers = Record[Idx++];
 
      SmallVector<BasicBlock *, 2> Handlers;
      for (unsigned Op = 0; Op != NumHandlers; ++Op) {
        BasicBlock *BB = getBasicBlock(Record[Idx++]);
        if (!BB)
          return error("Invalid catchswitch record");
        Handlers.push_back(BB);
      }
 
      BasicBlock *UnwindDest = nullptr;
      if (Idx + 1 == Record.size()) {
        UnwindDest = getBasicBlock(Record[Idx++]);
        if (!UnwindDest)
          return error("Invalid catchswitch record");
      }
 
      if (Record.size() != Idx)
        return error("Invalid catchswitch record");
 
      auto *CatchSwitch =
          CatchSwitchInst::Create(ParentPad, UnwindDest, NumHandlers);
      for (BasicBlock *Handler : Handlers)
        CatchSwitch->addHandler(Handler);
      I = CatchSwitch;
      ResTypeID = getVirtualTypeID(I->getType());
      InstructionList.push_back(I);
      break;
    }
    case bitc::FUNC_CODE_INST_CATCHPAD:
    case bitc::FUNC_CODE_INST_CLEANUPPAD: { // [tok,num,(ty,val)*]
      // We must have, at minimum, the outer scope and the number of arguments.
      if (Record.size() < 2)
        return error("Invalid catchpad/cleanuppad record");
 
      unsigned Idx = 0;
 
      Type *TokenTy = Type::getTokenTy(Context);
      Value *ParentPad = getValue(Record, Idx++, NextValueNo, TokenTy,
                                  getVirtualTypeID(TokenTy), CurBB);
      if (!ParentPad)
        return error("Invalid catchpad/cleanuppad record");
 
      unsigned NumArgOperands = Record[Idx++];
 
      SmallVector<Value *, 2> Args;
      for (unsigned Op = 0; Op != NumArgOperands; ++Op) {
        Value *Val;
        unsigned ValTypeID;
        if (getValueTypePair(Record, Idx, NextValueNo, Val, ValTypeID, nullptr))
          return error("Invalid catchpad/cleanuppad record");
        Args.push_back(Val);
      }
 
      if (Record.size() != Idx)
        return error("Invalid catchpad/cleanuppad record");
 
      if (BitCode == bitc::FUNC_CODE_INST_CLEANUPPAD)
        I = CleanupPadInst::Create(ParentPad, Args);
      else
        I = CatchPadInst::Create(ParentPad, Args);
      ResTypeID = getVirtualTypeID(I->getType());
      InstructionList.push_back(I);
      break;
    }
    case bitc::FUNC_CODE_INST_SWITCH: { // SWITCH: [opty, op0, op1, ...]
      // Check magic
      if ((Record[0] >> 16) == SWITCH_INST_MAGIC) {
        // "New" SwitchInst format with case ranges. The changes to write this
        // format were reverted but we still recognize bitcode that uses it.
        // Hopefully someday we will have support for case ranges and can use
        // this format again.
 
        unsigned OpTyID = Record[1];
        Type *OpTy = getTypeByID(OpTyID);
        unsigned ValueBitWidth = cast<IntegerType>(OpTy)->getBitWidth();
 
        Value *Cond = getValue(Record, 2, NextValueNo, OpTy, OpTyID, CurBB);
        BasicBlock *Default = getBasicBlock(Record[3]);
        if (!OpTy || !Cond || !Default)
          return error("Invalid switch record");
 
        unsigned NumCases = Record[4];
 
        SwitchInst *SI = SwitchInst::Create(Cond, Default, NumCases);
        InstructionList.push_back(SI);
 
        unsigned CurIdx = 5;
        for (unsigned i = 0; i != NumCases; ++i) {
          SmallVector<ConstantInt*, 1> CaseVals;
          unsigned NumItems = Record[CurIdx++];
          for (unsigned ci = 0; ci != NumItems; ++ci) {
            bool isSingleNumber = Record[CurIdx++];
 
            APInt Low;
            unsigned ActiveWords = 1;
            if (ValueBitWidth > 64)
              ActiveWords = Record[CurIdx++];
            Low = readWideAPInt(ArrayRef(&Record[CurIdx], ActiveWords),
                                ValueBitWidth);
            CurIdx += ActiveWords;
 
            if (!isSingleNumber) {
              ActiveWords = 1;
              if (ValueBitWidth > 64)
                ActiveWords = Record[CurIdx++];
              APInt High = readWideAPInt(ArrayRef(&Record[CurIdx], ActiveWords),
                                         ValueBitWidth);
              CurIdx += ActiveWords;
 
              // FIXME: It is not clear whether values in the range should be
              // compared as signed or unsigned values. The partially
              // implemented changes that used this format in the past used
              // unsigned comparisons.
              for ( ; Low.ule(High); ++Low)
                CaseVals.push_back(ConstantInt::get(Context, Low));
            } else
              CaseVals.push_back(ConstantInt::get(Context, Low));
          }
          BasicBlock *DestBB = getBasicBlock(Record[CurIdx++]);
          for (ConstantInt *Cst : CaseVals)
            SI->addCase(Cst, DestBB);
        }
        I = SI;
        break;
      }
 
      // Old SwitchInst format without case ranges.
 
      if (Record.size() < 3 || (Record.size() & 1) == 0)
        return error("Invalid switch record");
      unsigned OpTyID = Record[0];
      Type *OpTy = getTypeByID(OpTyID);
      Value *Cond = getValue(Record, 1, NextValueNo, OpTy, OpTyID, CurBB);
      BasicBlock *Default = getBasicBlock(Record[2]);
      if (!OpTy || !Cond || !Default)
        return error("Invalid switch record");
      unsigned NumCases = (Record.size()-3)/2;
      SwitchInst *SI = SwitchInst::Create(Cond, Default, NumCases);
      InstructionList.push_back(SI);
      for (unsigned i = 0, e = NumCases; i != e; ++i) {
        ConstantInt *CaseVal = dyn_cast_or_null<ConstantInt>(
            getFnValueByID(Record[3+i*2], OpTy, OpTyID, nullptr));
        BasicBlock *DestBB = getBasicBlock(Record[1+3+i*2]);
        if (!CaseVal || !DestBB) {
          delete SI;
          return error("Invalid switch record");
        }
        SI->addCase(CaseVal, DestBB);
      }
      I = SI;
      break;
    }
    case bitc::FUNC_CODE_INST_INDIRECTBR: { // INDIRECTBR: [opty, op0, op1, ...]
      if (Record.size() < 2)
        return error("Invalid indirectbr record");
      unsigned OpTyID = Record[0];
      Type *OpTy = getTypeByID(OpTyID);
      Value *Address = getValue(Record, 1, NextValueNo, OpTy, OpTyID, CurBB);
      if (!OpTy || !Address)
        return error("Invalid indirectbr record");
      unsigned NumDests = Record.size()-2;
      IndirectBrInst *IBI = IndirectBrInst::Create(Address, NumDests);
      InstructionList.push_back(IBI);
      for (unsigned i = 0, e = NumDests; i != e; ++i) {
        if (BasicBlock *DestBB = getBasicBlock(Record[2+i])) {
          IBI->addDestination(DestBB);
        } else {
          delete IBI;
          return error("Invalid indirectbr record");
        }
      }
      I = IBI;
      break;
    }
 
    case bitc::FUNC_CODE_INST_INVOKE: {
      // INVOKE: [attrs, cc, normBB, unwindBB, fnty, op0,op1,op2, ...]
      if (Record.size() < 4)
        return error("Invalid invoke record");
      unsigned OpNum = 0;
      AttributeList PAL = getAttributes(Record[OpNum++]);
      unsigned CCInfo = Record[OpNum++];
      BasicBlock *NormalBB = getBasicBlock(Record[OpNum++]);
      BasicBlock *UnwindBB = getBasicBlock(Record[OpNum++]);
 
      unsigned FTyID = InvalidTypeID;
      FunctionType *FTy = nullptr;
      if ((CCInfo >> 13) & 1) {
        FTyID = Record[OpNum++];
        FTy = dyn_cast<FunctionType>(getTypeByID(FTyID));
        if (!FTy)
          return error("Explicit invoke type is not a function type");
      }
 
      Value *Callee;
      unsigned CalleeTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, Callee, CalleeTypeID,
                           CurBB))
        return error("Invalid invoke record");
 
      PointerType *CalleeTy = dyn_cast<PointerType>(Callee->getType());
      if (!CalleeTy)
        return error("Callee is not a pointer");
      if (!FTy) {
        FTyID = getContainedTypeID(CalleeTypeID);
        FTy = dyn_cast_or_null<FunctionType>(getTypeByID(FTyID));
        if (!FTy)
          return error("Callee is not of pointer to function type");
      }
      if (Record.size() < FTy->getNumParams() + OpNum)
        return error("Insufficient operands to call");
 
      SmallVector<Value*, 16> Ops;
      SmallVector<unsigned, 16> ArgTyIDs;
      for (unsigned i = 0, e = FTy->getNumParams(); i != e; ++i, ++OpNum) {
        unsigned ArgTyID = getContainedTypeID(FTyID, i + 1);
        Ops.push_back(getValue(Record, OpNum, NextValueNo, FTy->getParamType(i),
                               ArgTyID, CurBB));
        ArgTyIDs.push_back(ArgTyID);
        if (!Ops.back())
          return error("Invalid invoke record");
      }
 
      if (!FTy->isVarArg()) {
        if (Record.size() != OpNum)
          return error("Invalid invoke record");
      } else {
        // Read type/value pairs for varargs params.
        while (OpNum != Record.size()) {
          Value *Op;
          unsigned OpTypeID;
          if (getValueTypePair(Record, OpNum, NextValueNo, Op, OpTypeID, CurBB))
            return error("Invalid invoke record");
          Ops.push_back(Op);
          ArgTyIDs.push_back(OpTypeID);
        }
      }
 
      // Upgrade the bundles if needed.
      if (!OperandBundles.empty())
        UpgradeOperandBundles(OperandBundles);
 
      I = InvokeInst::Create(FTy, Callee, NormalBB, UnwindBB, Ops,
                             OperandBundles);
      ResTypeID = getContainedTypeID(FTyID);
      OperandBundles.clear();
      InstructionList.push_back(I);
      cast<InvokeInst>(I)->setCallingConv(
          static_cast<CallingConv::ID>(CallingConv::MaxID & CCInfo));
      cast<InvokeInst>(I)->setAttributes(PAL);
      if (Error Err = propagateAttributeTypes(cast<CallBase>(I), ArgTyIDs)) {
        I->deleteValue();
        return Err;
      }
 
      break;
    }
    case bitc::FUNC_CODE_INST_RESUME: { // RESUME: [opval]
      unsigned Idx = 0;
      Value *Val = nullptr;
      unsigned ValTypeID;
      if (getValueTypePair(Record, Idx, NextValueNo, Val, ValTypeID, CurBB))
        return error("Invalid resume record");
      I = ResumeInst::Create(Val);
      InstructionList.push_back(I);
      break;
    }
    case bitc::FUNC_CODE_INST_CALLBR: {
      // CALLBR: [attr, cc, norm, transfs, fty, fnid, args]
      unsigned OpNum = 0;
      AttributeList PAL = getAttributes(Record[OpNum++]);
      unsigned CCInfo = Record[OpNum++];
 
      BasicBlock *DefaultDest = getBasicBlock(Record[OpNum++]);
      unsigned NumIndirectDests = Record[OpNum++];
      SmallVector<BasicBlock *, 16> IndirectDests;
      for (unsigned i = 0, e = NumIndirectDests; i != e; ++i)
        IndirectDests.push_back(getBasicBlock(Record[OpNum++]));
 
      unsigned FTyID = InvalidTypeID;
      FunctionType *FTy = nullptr;
      if ((CCInfo >> bitc::CALL_EXPLICIT_TYPE) & 1) {
        FTyID = Record[OpNum++];
        FTy = dyn_cast_or_null<FunctionType>(getTypeByID(FTyID));
        if (!FTy)
          return error("Explicit call type is not a function type");
      }
 
      Value *Callee;
      unsigned CalleeTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, Callee, CalleeTypeID,
                           CurBB))
        return error("Invalid callbr record");
 
      PointerType *OpTy = dyn_cast<PointerType>(Callee->getType());
      if (!OpTy)
        return error("Callee is not a pointer type");
      if (!FTy) {
        FTyID = getContainedTypeID(CalleeTypeID);
        FTy = dyn_cast_or_null<FunctionType>(getTypeByID(FTyID));
        if (!FTy)
          return error("Callee is not of pointer to function type");
      }
      if (Record.size() < FTy->getNumParams() + OpNum)
        return error("Insufficient operands to call");
 
      SmallVector<Value*, 16> Args;
      SmallVector<unsigned, 16> ArgTyIDs;
      // Read the fixed params.
      for (unsigned i = 0, e = FTy->getNumParams(); i != e; ++i, ++OpNum) {
        Value *Arg;
        unsigned ArgTyID = getContainedTypeID(FTyID, i + 1);
        if (FTy->getParamType(i)->isLabelTy())
          Arg = getBasicBlock(Record[OpNum]);
        else
          Arg = getValue(Record, OpNum, NextValueNo, FTy->getParamType(i),
                         ArgTyID, CurBB);
        if (!Arg)
          return error("Invalid callbr record");
        Args.push_back(Arg);
        ArgTyIDs.push_back(ArgTyID);
      }
 
      // Read type/value pairs for varargs params.
      if (!FTy->isVarArg()) {
        if (OpNum != Record.size())
          return error("Invalid callbr record");
      } else {
        while (OpNum != Record.size()) {
          Value *Op;
          unsigned OpTypeID;
          if (getValueTypePair(Record, OpNum, NextValueNo, Op, OpTypeID, CurBB))
            return error("Invalid callbr record");
          Args.push_back(Op);
          ArgTyIDs.push_back(OpTypeID);
        }
      }
 
      // Upgrade the bundles if needed.
      if (!OperandBundles.empty())
        UpgradeOperandBundles(OperandBundles);
 
      if (auto *IA = dyn_cast<InlineAsm>(Callee)) {
        InlineAsm::ConstraintInfoVector ConstraintInfo = IA->ParseConstraints();
        auto IsLabelConstraint = [](const InlineAsm::ConstraintInfo &CI) {
          return CI.Type == InlineAsm::isLabel;
        };
        if (none_of(ConstraintInfo, IsLabelConstraint)) {
          // Upgrade explicit blockaddress arguments to label constraints.
          // Verify that the last arguments are blockaddress arguments that
          // match the indirect destinations. Clang always generates callbr
          // in this form. We could support reordering with more effort.
          unsigned FirstBlockArg = Args.size() - IndirectDests.size();
          for (unsigned ArgNo = FirstBlockArg; ArgNo < Args.size(); ++ArgNo) {
            unsigned LabelNo = ArgNo - FirstBlockArg;
            auto *BA = dyn_cast<BlockAddress>(Args[ArgNo]);
            if (!BA || BA->getFunction() != F ||
                LabelNo > IndirectDests.size() ||
                BA->getBasicBlock() != IndirectDests[LabelNo])
              return error("callbr argument does not match indirect dest");
          }
 
          // Remove blockaddress arguments.
          Args.erase(Args.begin() + FirstBlockArg, Args.end());
          ArgTyIDs.erase(ArgTyIDs.begin() + FirstBlockArg, ArgTyIDs.end());
 
          // Recreate the function type with less arguments.
          SmallVector<Type *> ArgTys;
          for (Value *Arg : Args)
            ArgTys.push_back(Arg->getType());
          FTy =
              FunctionType::get(FTy->getReturnType(), ArgTys, FTy->isVarArg());
 
          // Update constraint string to use label constraints.
          std::string Constraints = IA->getConstraintString().str();
          unsigned ArgNo = 0;
          size_t Pos = 0;
          for (const auto &CI : ConstraintInfo) {
            if (CI.hasArg()) {
              if (ArgNo >= FirstBlockArg)
                Constraints.insert(Pos, "!");
              ++ArgNo;
            }
 
            // Go to next constraint in string.
            Pos = Constraints.find(',', Pos);
            if (Pos == std::string::npos)
              break;
            ++Pos;
          }
 
          Callee = InlineAsm::get(FTy, IA->getAsmString(), Constraints,
                                  IA->hasSideEffects(), IA->isAlignStack(),
                                  IA->getDialect(), IA->canThrow());
        }
      }
 
      I = CallBrInst::Create(FTy, Callee, DefaultDest, IndirectDests, Args,
                             OperandBundles);
      ResTypeID = getContainedTypeID(FTyID);
      OperandBundles.clear();
      InstructionList.push_back(I);
      cast<CallBrInst>(I)->setCallingConv(
          static_cast<CallingConv::ID>((0x7ff & CCInfo) >> bitc::CALL_CCONV));
      cast<CallBrInst>(I)->setAttributes(PAL);
      if (Error Err = propagateAttributeTypes(cast<CallBase>(I), ArgTyIDs)) {
        I->deleteValue();
        return Err;
      }
      break;
    }
    case bitc::FUNC_CODE_INST_UNREACHABLE: // UNREACHABLE
      I = new UnreachableInst(Context);
      InstructionList.push_back(I);
      break;
    case bitc::FUNC_CODE_INST_PHI: { // PHI: [ty, val0,bb0, ...]
      if (Record.empty())
        return error("Invalid phi record");
      // The first record specifies the type.
      unsigned TyID = Record[0];
      Type *Ty = getTypeByID(TyID);
      if (!Ty)
        return error("Invalid phi record");
 
      // Phi arguments are pairs of records of [value, basic block].
      // There is an optional final record for fast-math-flags if this phi has a
      // floating-point type.
      size_t NumArgs = (Record.size() - 1) / 2;
      PHINode *PN = PHINode::Create(Ty, NumArgs);
      if ((Record.size() - 1) % 2 == 1 && !isa<FPMathOperator>(PN)) {
        PN->deleteValue();
        return error("Invalid phi record");
      }
      InstructionList.push_back(PN);
 
      SmallDenseMap<BasicBlock *, Value *> Args;
      for (unsigned i = 0; i != NumArgs; i++) {
        BasicBlock *BB = getBasicBlock(Record[i * 2 + 2]);
        if (!BB) {
          PN->deleteValue();
          return error("Invalid phi BB");
        }
 
        // Phi nodes may contain the same predecessor multiple times, in which
        // case the incoming value must be identical. Directly reuse the already
        // seen value here, to avoid expanding a constant expression multiple
        // times.
        auto It = Args.find(BB);
        BasicBlock *EdgeBB = ConstExprEdgeBBs.lookup({BB, CurBB});
        if (It != Args.end()) {
          // If this predecessor was also replaced with a constexpr basic
          // block, it must be de-duplicated.
          if (!EdgeBB) {
            PN->addIncoming(It->second, BB);
          }
          continue;
        }
 
        // If there already is a block for this edge (from a different phi),
        // use it.
        if (!EdgeBB) {
          // Otherwise, use a temporary block (that we will discard if it
          // turns out to be unnecessary).
          if (!PhiConstExprBB)
            PhiConstExprBB = BasicBlock::Create(Context, "phi.constexpr", F);
          EdgeBB = PhiConstExprBB;
        }
 
        // With the new function encoding, it is possible that operands have
        // negative IDs (for forward references).  Use a signed VBR
        // representation to keep the encoding small.
        Value *V;
        if (UseRelativeIDs)
          V = getValueSigned(Record, i * 2 + 1, NextValueNo, Ty, TyID, EdgeBB);
        else
          V = getValue(Record, i * 2 + 1, NextValueNo, Ty, TyID, EdgeBB);
        if (!V) {
          PN->deleteValue();
          PhiConstExprBB->eraseFromParent();
          return error("Invalid phi record");
        }
 
        if (EdgeBB == PhiConstExprBB && !EdgeBB->empty()) {
          ConstExprEdgeBBs.insert({{BB, CurBB}, EdgeBB});
          PhiConstExprBB = nullptr;
        }
        PN->addIncoming(V, BB);
        Args.insert({BB, V});
      }
      I = PN;
      ResTypeID = TyID;
 
      // If there are an even number of records, the final record must be FMF.
      if (Record.size() % 2 == 0) {
        assert(isa<FPMathOperator>(I) && "Unexpected phi type");
        FastMathFlags FMF = getDecodedFastMathFlags(Record[Record.size() - 1]);
        if (FMF.any())
          I->setFastMathFlags(FMF);
      }
 
      break;
    }
 
    case bitc::FUNC_CODE_INST_LANDINGPAD:
    case bitc::FUNC_CODE_INST_LANDINGPAD_OLD: {
      // LANDINGPAD: [ty, val, val, num, (id0,val0 ...)?]
      unsigned Idx = 0;
      if (BitCode == bitc::FUNC_CODE_INST_LANDINGPAD) {
        if (Record.size() < 3)
          return error("Invalid landingpad record");
      } else {
        assert(BitCode == bitc::FUNC_CODE_INST_LANDINGPAD_OLD);
        if (Record.size() < 4)
          return error("Invalid landingpad record");
      }
      ResTypeID = Record[Idx++];
      Type *Ty = getTypeByID(ResTypeID);
      if (!Ty)
        return error("Invalid landingpad record");
      if (BitCode == bitc::FUNC_CODE_INST_LANDINGPAD_OLD) {
        Value *PersFn = nullptr;
        unsigned PersFnTypeID;
        if (getValueTypePair(Record, Idx, NextValueNo, PersFn, PersFnTypeID,
                             nullptr))
          return error("Invalid landingpad record");
 
        if (!F->hasPersonalityFn())
          F->setPersonalityFn(cast<Constant>(PersFn));
        else if (F->getPersonalityFn() != cast<Constant>(PersFn))
          return error("Personality function mismatch");
      }
 
      bool IsCleanup = !!Record[Idx++];
      unsigned NumClauses = Record[Idx++];
      LandingPadInst *LP = LandingPadInst::Create(Ty, NumClauses);
      LP->setCleanup(IsCleanup);
      for (unsigned J = 0; J != NumClauses; ++J) {
        LandingPadInst::ClauseType CT =
          LandingPadInst::ClauseType(Record[Idx++]); (void)CT;
        Value *Val;
        unsigned ValTypeID;
 
        if (getValueTypePair(Record, Idx, NextValueNo, Val, ValTypeID,
                             nullptr)) {
          delete LP;
          return error("Invalid landingpad record");
        }
 
        assert((CT != LandingPadInst::Catch ||
                !isa<ArrayType>(Val->getType())) &&
               "Catch clause has a invalid type!");
        assert((CT != LandingPadInst::Filter ||
                isa<ArrayType>(Val->getType())) &&
               "Filter clause has invalid type!");
        LP->addClause(cast<Constant>(Val));
      }
 
      I = LP;
      InstructionList.push_back(I);
      break;
    }
 
    case bitc::FUNC_CODE_INST_ALLOCA: { // ALLOCA: [instty, opty, op, align]
      if (Record.size() != 4 && Record.size() != 5)
        return error("Invalid alloca record");
      using APV = AllocaPackedValues;
      const uint64_t Rec = Record[3];
      const bool InAlloca = Bitfield::get<APV::UsedWithInAlloca>(Rec);
      const bool SwiftError = Bitfield::get<APV::SwiftError>(Rec);
      unsigned TyID = Record[0];
      Type *Ty = getTypeByID(TyID);
      if (!Bitfield::get<APV::ExplicitType>(Rec)) {
        TyID = getContainedTypeID(TyID);
        Ty = getTypeByID(TyID);
        if (!Ty)
          return error("Missing element type for old-style alloca");
      }
      unsigned OpTyID = Record[1];
      Type *OpTy = getTypeByID(OpTyID);
      Value *Size = getFnValueByID(Record[2], OpTy, OpTyID, CurBB);
      MaybeAlign Align;
      uint64_t AlignExp =
          Bitfield::get<APV::AlignLower>(Rec) |
          (Bitfield::get<APV::AlignUpper>(Rec) << APV::AlignLower::Bits);
      if (Error Err = parseAlignmentValue(AlignExp, Align)) {
        return Err;
      }
      if (!Ty || !Size)
        return error("Invalid alloca record");
 
      const DataLayout &DL = TheModule->getDataLayout();
      unsigned AS = Record.size() == 5 ? Record[4] : DL.getAllocaAddrSpace();
 
      SmallPtrSet<Type *, 4> Visited;
      if (!Align && !Ty->isSized(&Visited))
        return error("alloca of unsized type");
      if (!Align)
        Align = DL.getPrefTypeAlign(Ty);
 
      if (!Size->getType()->isIntegerTy())
        return error("alloca element count must have integer type");
 
      AllocaInst *AI = new AllocaInst(Ty, AS, Size, *Align);
      AI->setUsedWithInAlloca(InAlloca);
      AI->setSwiftError(SwiftError);
      I = AI;
      ResTypeID = getVirtualTypeID(AI->getType(), TyID);
      InstructionList.push_back(I);
      break;
    }
    case bitc::FUNC_CODE_INST_LOAD: { // LOAD: [opty, op, align, vol]
      unsigned OpNum = 0;
      Value *Op;
      unsigned OpTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, Op, OpTypeID, CurBB) ||
          (OpNum + 2 != Record.size() && OpNum + 3 != Record.size()))
        return error("Invalid load record");
 
      if (!isa<PointerType>(Op->getType()))
        return error("Load operand is not a pointer type");
 
      Type *Ty = nullptr;
      if (OpNum + 3 == Record.size()) {
        ResTypeID = Record[OpNum++];
        Ty = getTypeByID(ResTypeID);
      } else {
        ResTypeID = getContainedTypeID(OpTypeID);
        Ty = getTypeByID(ResTypeID);
      }
 
      if (!Ty)
        return error("Missing load type");
 
      if (Error Err = typeCheckLoadStoreInst(Ty, Op->getType()))
        return Err;
 
      MaybeAlign Align;
      if (Error Err = parseAlignmentValue(Record[OpNum], Align))
        return Err;
      SmallPtrSet<Type *, 4> Visited;
      if (!Align && !Ty->isSized(&Visited))
        return error("load of unsized type");
      if (!Align)
        Align = TheModule->getDataLayout().getABITypeAlign(Ty);
      I = new LoadInst(Ty, Op, "", Record[OpNum + 1], *Align);
      InstructionList.push_back(I);
      break;
    }
    case bitc::FUNC_CODE_INST_LOADATOMIC: {
       // LOADATOMIC: [opty, op, align, vol, ordering, ssid]
      unsigned OpNum = 0;
      Value *Op;
      unsigned OpTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, Op, OpTypeID, CurBB) ||
          (OpNum + 4 != Record.size() && OpNum + 5 != Record.size()))
        return error("Invalid load atomic record");
 
      if (!isa<PointerType>(Op->getType()))
        return error("Load operand is not a pointer type");
 
      Type *Ty = nullptr;
      if (OpNum + 5 == Record.size()) {
        ResTypeID = Record[OpNum++];
        Ty = getTypeByID(ResTypeID);
      } else {
        ResTypeID = getContainedTypeID(OpTypeID);
        Ty = getTypeByID(ResTypeID);
      }
 
      if (!Ty)
        return error("Missing atomic load type");
 
      if (Error Err = typeCheckLoadStoreInst(Ty, Op->getType()))
        return Err;
 
      AtomicOrdering Ordering = getDecodedOrdering(Record[OpNum + 2]);
      if (Ordering == AtomicOrdering::NotAtomic ||
          Ordering == AtomicOrdering::Release ||
          Ordering == AtomicOrdering::AcquireRelease)
        return error("Invalid load atomic record");
      if (Ordering != AtomicOrdering::NotAtomic && Record[OpNum] == 0)
        return error("Invalid load atomic record");
      SyncScope::ID SSID = getDecodedSyncScopeID(Record[OpNum + 3]);
 
      MaybeAlign Align;
      if (Error Err = parseAlignmentValue(Record[OpNum], Align))
        return Err;
      if (!Align)
        return error("Alignment missing from atomic load");
      I = new LoadInst(Ty, Op, "", Record[OpNum + 1], *Align, Ordering, SSID);
      InstructionList.push_back(I);
      break;
    }
    case bitc::FUNC_CODE_INST_STORE:
    case bitc::FUNC_CODE_INST_STORE_OLD: { // STORE2:[ptrty, ptr, val, align, vol]
      unsigned OpNum = 0;
      Value *Val, *Ptr;
      unsigned PtrTypeID, ValTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, Ptr, PtrTypeID, CurBB))
        return error("Invalid store record");
 
      if (BitCode == bitc::FUNC_CODE_INST_STORE) {
        if (getValueTypePair(Record, OpNum, NextValueNo, Val, ValTypeID, CurBB))
          return error("Invalid store record");
      } else {
        ValTypeID = getContainedTypeID(PtrTypeID);
        if (popValue(Record, OpNum, NextValueNo, getTypeByID(ValTypeID),
                     ValTypeID, Val, CurBB))
          return error("Invalid store record");
      }
 
      if (OpNum + 2 != Record.size())
        return error("Invalid store record");
 
      if (Error Err = typeCheckLoadStoreInst(Val->getType(), Ptr->getType()))
        return Err;
      MaybeAlign Align;
      if (Error Err = parseAlignmentValue(Record[OpNum], Align))
        return Err;
      SmallPtrSet<Type *, 4> Visited;
      if (!Align && !Val->getType()->isSized(&Visited))
        return error("store of unsized type");
      if (!Align)
        Align = TheModule->getDataLayout().getABITypeAlign(Val->getType());
      I = new StoreInst(Val, Ptr, Record[OpNum + 1], *Align);
      InstructionList.push_back(I);
      break;
    }
    case bitc::FUNC_CODE_INST_STOREATOMIC:
    case bitc::FUNC_CODE_INST_STOREATOMIC_OLD: {
      // STOREATOMIC: [ptrty, ptr, val, align, vol, ordering, ssid]
      unsigned OpNum = 0;
      Value *Val, *Ptr;
      unsigned PtrTypeID, ValTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, Ptr, PtrTypeID, CurBB) ||
          !isa<PointerType>(Ptr->getType()))
        return error("Invalid store atomic record");
      if (BitCode == bitc::FUNC_CODE_INST_STOREATOMIC) {
        if (getValueTypePair(Record, OpNum, NextValueNo, Val, ValTypeID, CurBB))
          return error("Invalid store atomic record");
      } else {
        ValTypeID = getContainedTypeID(PtrTypeID);
        if (popValue(Record, OpNum, NextValueNo, getTypeByID(ValTypeID),
                     ValTypeID, Val, CurBB))
          return error("Invalid store atomic record");
      }
 
      if (OpNum + 4 != Record.size())
        return error("Invalid store atomic record");
 
      if (Error Err = typeCheckLoadStoreInst(Val->getType(), Ptr->getType()))
        return Err;
      AtomicOrdering Ordering = getDecodedOrdering(Record[OpNum + 2]);
      if (Ordering == AtomicOrdering::NotAtomic ||
          Ordering == AtomicOrdering::Acquire ||
          Ordering == AtomicOrdering::AcquireRelease)
        return error("Invalid store atomic record");
      SyncScope::ID SSID = getDecodedSyncScopeID(Record[OpNum + 3]);
      if (Ordering != AtomicOrdering::NotAtomic && Record[OpNum] == 0)
        return error("Invalid store atomic record");
 
      MaybeAlign Align;
      if (Error Err = parseAlignmentValue(Record[OpNum], Align))
        return Err;
      if (!Align)
        return error("Alignment missing from atomic store");
      I = new StoreInst(Val, Ptr, Record[OpNum + 1], *Align, Ordering, SSID);
      InstructionList.push_back(I);
      break;
    }
    case bitc::FUNC_CODE_INST_CMPXCHG_OLD: {
      // CMPXCHG_OLD: [ptrty, ptr, cmp, val, vol, ordering, syncscope,
      // failure_ordering?, weak?]
      const size_t NumRecords = Record.size();
      unsigned OpNum = 0;
      Value *Ptr = nullptr;
      unsigned PtrTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, Ptr, PtrTypeID, CurBB))
        return error("Invalid cmpxchg record");
 
      if (!isa<PointerType>(Ptr->getType()))
        return error("Cmpxchg operand is not a pointer type");
 
      Value *Cmp = nullptr;
      unsigned CmpTypeID = getContainedTypeID(PtrTypeID);
      if (popValue(Record, OpNum, NextValueNo, getTypeByID(CmpTypeID),
                   CmpTypeID, Cmp, CurBB))
        return error("Invalid cmpxchg record");
 
      Value *New = nullptr;
      if (popValue(Record, OpNum, NextValueNo, Cmp->getType(), CmpTypeID,
                   New, CurBB) ||
          NumRecords < OpNum + 3 || NumRecords > OpNum + 5)
        return error("Invalid cmpxchg record");
 
      const AtomicOrdering SuccessOrdering =
          getDecodedOrdering(Record[OpNum + 1]);
      if (SuccessOrdering == AtomicOrdering::NotAtomic ||
          SuccessOrdering == AtomicOrdering::Unordered)
        return error("Invalid cmpxchg record");
 
      const SyncScope::ID SSID = getDecodedSyncScopeID(Record[OpNum + 2]);
 
      if (Error Err = typeCheckLoadStoreInst(Cmp->getType(), Ptr->getType()))
        return Err;
 
      const AtomicOrdering FailureOrdering =
          NumRecords < 7
              ? AtomicCmpXchgInst::getStrongestFailureOrdering(SuccessOrdering)
              : getDecodedOrdering(Record[OpNum + 3]);
 
      if (FailureOrdering == AtomicOrdering::NotAtomic ||
          FailureOrdering == AtomicOrdering::Unordered)
        return error("Invalid cmpxchg record");
 
      const Align Alignment(
          TheModule->getDataLayout().getTypeStoreSize(Cmp->getType()));
 
      I = new AtomicCmpXchgInst(Ptr, Cmp, New, Alignment, SuccessOrdering,
                                FailureOrdering, SSID);
      cast<AtomicCmpXchgInst>(I)->setVolatile(Record[OpNum]);
 
      if (NumRecords < 8) {
        // Before weak cmpxchgs existed, the instruction simply returned the
        // value loaded from memory, so bitcode files from that era will be
        // expecting the first component of a modern cmpxchg.
        I->insertInto(CurBB, CurBB->end());
        I = ExtractValueInst::Create(I, 0);
        ResTypeID = CmpTypeID;
      } else {
        cast<AtomicCmpXchgInst>(I)->setWeak(Record[OpNum + 4]);
        unsigned I1TypeID = getVirtualTypeID(Type::getInt1Ty(Context));
        ResTypeID = getVirtualTypeID(I->getType(), {CmpTypeID, I1TypeID});
      }
 
      InstructionList.push_back(I);
      break;
    }
    case bitc::FUNC_CODE_INST_CMPXCHG: {
      // CMPXCHG: [ptrty, ptr, cmp, val, vol, success_ordering, syncscope,
      // failure_ordering, weak, align?]
      const size_t NumRecords = Record.size();
      unsigned OpNum = 0;
      Value *Ptr = nullptr;
      unsigned PtrTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, Ptr, PtrTypeID, CurBB))
        return error("Invalid cmpxchg record");
 
      if (!isa<PointerType>(Ptr->getType()))
        return error("Cmpxchg operand is not a pointer type");
 
      Value *Cmp = nullptr;
      unsigned CmpTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, Cmp, CmpTypeID, CurBB))
        return error("Invalid cmpxchg record");
 
      Value *Val = nullptr;
      if (popValue(Record, OpNum, NextValueNo, Cmp->getType(), CmpTypeID, Val,
                   CurBB))
        return error("Invalid cmpxchg record");
 
      if (NumRecords < OpNum + 3 || NumRecords > OpNum + 6)
        return error("Invalid cmpxchg record");
 
      const bool IsVol = Record[OpNum];
 
      const AtomicOrdering SuccessOrdering =
          getDecodedOrdering(Record[OpNum + 1]);
      if (!AtomicCmpXchgInst::isValidSuccessOrdering(SuccessOrdering))
        return error("Invalid cmpxchg success ordering");
 
      const SyncScope::ID SSID = getDecodedSyncScopeID(Record[OpNum + 2]);
 
      if (Error Err = typeCheckLoadStoreInst(Cmp->getType(), Ptr->getType()))
        return Err;
 
      const AtomicOrdering FailureOrdering =
          getDecodedOrdering(Record[OpNum + 3]);
      if (!AtomicCmpXchgInst::isValidFailureOrdering(FailureOrdering))
        return error("Invalid cmpxchg failure ordering");
 
      const bool IsWeak = Record[OpNum + 4];
 
      MaybeAlign Alignment;
 
      if (NumRecords == (OpNum + 6)) {
        if (Error Err = parseAlignmentValue(Record[OpNum + 5], Alignment))
          return Err;
      }
      if (!Alignment)
        Alignment =
            Align(TheModule->getDataLayout().getTypeStoreSize(Cmp->getType()));
 
      I = new AtomicCmpXchgInst(Ptr, Cmp, Val, *Alignment, SuccessOrdering,
                                FailureOrdering, SSID);
      cast<AtomicCmpXchgInst>(I)->setVolatile(IsVol);
      cast<AtomicCmpXchgInst>(I)->setWeak(IsWeak);
 
      unsigned I1TypeID = getVirtualTypeID(Type::getInt1Ty(Context));
      ResTypeID = getVirtualTypeID(I->getType(), {CmpTypeID, I1TypeID});
 
      InstructionList.push_back(I);
      break;
    }
    case bitc::FUNC_CODE_INST_ATOMICRMW_OLD:
    case bitc::FUNC_CODE_INST_ATOMICRMW: {
      // ATOMICRMW_OLD: [ptrty, ptr, val, op, vol, ordering, ssid, align?]
      // ATOMICRMW: [ptrty, ptr, valty, val, op, vol, ordering, ssid, align?]
      const size_t NumRecords = Record.size();
      unsigned OpNum = 0;
 
      Value *Ptr = nullptr;
      unsigned PtrTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, Ptr, PtrTypeID, CurBB))
        return error("Invalid atomicrmw record");
 
      if (!isa<PointerType>(Ptr->getType()))
        return error("Invalid atomicrmw record");
 
      Value *Val = nullptr;
      unsigned ValTypeID = InvalidTypeID;
      if (BitCode == bitc::FUNC_CODE_INST_ATOMICRMW_OLD) {
        ValTypeID = getContainedTypeID(PtrTypeID);
        if (popValue(Record, OpNum, NextValueNo,
                     getTypeByID(ValTypeID), ValTypeID, Val, CurBB))
          return error("Invalid atomicrmw record");
      } else {
        if (getValueTypePair(Record, OpNum, NextValueNo, Val, ValTypeID, CurBB))
          return error("Invalid atomicrmw record");
      }
 
      if (!(NumRecords == (OpNum + 4) || NumRecords == (OpNum + 5)))
        return error("Invalid atomicrmw record");
 
      const AtomicRMWInst::BinOp Operation =
          getDecodedRMWOperation(Record[OpNum]);
      if (Operation < AtomicRMWInst::FIRST_BINOP ||
          Operation > AtomicRMWInst::LAST_BINOP)
        return error("Invalid atomicrmw record");
 
      const bool IsVol = Record[OpNum + 1];
 
      const AtomicOrdering Ordering = getDecodedOrdering(Record[OpNum + 2]);
      if (Ordering == AtomicOrdering::NotAtomic ||
          Ordering == AtomicOrdering::Unordered)
        return error("Invalid atomicrmw record");
 
      const SyncScope::ID SSID = getDecodedSyncScopeID(Record[OpNum + 3]);
 
      MaybeAlign Alignment;
 
      if (NumRecords == (OpNum + 5)) {
        if (Error Err = parseAlignmentValue(Record[OpNum + 4], Alignment))
          return Err;
      }
 
      if (!Alignment)
        Alignment =
            Align(TheModule->getDataLayout().getTypeStoreSize(Val->getType()));
 
      I = new AtomicRMWInst(Operation, Ptr, Val, *Alignment, Ordering, SSID);
      ResTypeID = ValTypeID;
      cast<AtomicRMWInst>(I)->setVolatile(IsVol);
 
      InstructionList.push_back(I);
      break;
    }
    case bitc::FUNC_CODE_INST_FENCE: { // FENCE:[ordering, ssid]
      if (2 != Record.size())
        return error("Invalid fence record");
      AtomicOrdering Ordering = getDecodedOrdering(Record[0]);
      if (Ordering == AtomicOrdering::NotAtomic ||
          Ordering == AtomicOrdering::Unordered ||
          Ordering == AtomicOrdering::Monotonic)
        return error("Invalid fence record");
      SyncScope::ID SSID = getDecodedSyncScopeID(Record[1]);
      I = new FenceInst(Context, Ordering, SSID);
      InstructionList.push_back(I);
      break;
    }
    case bitc::FUNC_CODE_DEBUG_RECORD_LABEL: {
      // DbgLabelRecords are placed after the Instructions that they are
      // attached to.
      SeenDebugRecord = true;
      Instruction *Inst = getLastInstruction();
      if (!Inst)
        return error("Invalid dbg record: missing instruction");
      DILocation *DIL = cast<DILocation>(getFnMetadataByID(Record[0]));
      DILabel *Label = cast<DILabel>(getFnMetadataByID(Record[1]));
      Inst->getParent()->insertDbgRecordBefore(
          new DbgLabelRecord(Label, DebugLoc(DIL)), Inst->getIterator());
      continue; // This isn't an instruction.
    }
    case bitc::FUNC_CODE_DEBUG_RECORD_VALUE_SIMPLE:
    case bitc::FUNC_CODE_DEBUG_RECORD_VALUE:
    case bitc::FUNC_CODE_DEBUG_RECORD_DECLARE:
    case bitc::FUNC_CODE_DEBUG_RECORD_DECLARE_VALUE:
    case bitc::FUNC_CODE_DEBUG_RECORD_ASSIGN: {
      // DbgVariableRecords are placed after the Instructions that they are
      // attached to.
      SeenDebugRecord = true;
      Instruction *Inst = getLastInstruction();
      if (!Inst)
        return error("Invalid dbg record: missing instruction");
 
      // First 3 fields are common to all kinds:
      //   DILocation, DILocalVariable, DIExpression
      // dbg_value (FUNC_CODE_DEBUG_RECORD_VALUE)
      //   ..., LocationMetadata
      // dbg_value (FUNC_CODE_DEBUG_RECORD_VALUE_SIMPLE - abbrev'd)
      //   ..., Value
      // dbg_declare (FUNC_CODE_DEBUG_RECORD_DECLARE)
      //   ..., LocationMetadata
      // dbg_declare_value (FUNC_CODE_DEBUG_RECORD_DECLARE_VALUE)
      //   ..., LocationMetadata
      // dbg_assign (FUNC_CODE_DEBUG_RECORD_ASSIGN)
      //   ..., LocationMetadata, DIAssignID, DIExpression, LocationMetadata
      unsigned Slot = 0;
      // Common fields (0-2).
      DILocation *DIL = cast<DILocation>(getFnMetadataByID(Record[Slot++]));
      DILocalVariable *Var =
          cast<DILocalVariable>(getFnMetadataByID(Record[Slot++]));
      DIExpression *Expr =
          cast<DIExpression>(getFnMetadataByID(Record[Slot++]));
 
      // Union field (3: LocationMetadata | Value).
      Metadata *RawLocation = nullptr;
      if (BitCode == bitc::FUNC_CODE_DEBUG_RECORD_VALUE_SIMPLE) {
        Value *V = nullptr;
        unsigned TyID = 0;
        // We never expect to see a fwd reference value here because
        // use-before-defs are encoded with the standard non-abbrev record
        // type (they'd require encoding the type too, and they're rare). As a
        // result, getValueTypePair only ever increments Slot by one here (once
        // for the value, never twice for value and type).
        unsigned SlotBefore = Slot;
        if (getValueTypePair(Record, Slot, NextValueNo, V, TyID, CurBB))
          return error("Invalid dbg record: invalid value");
        (void)SlotBefore;
        assert((SlotBefore == Slot - 1) && "unexpected fwd ref");
        RawLocation = ValueAsMetadata::get(V);
      } else {
        RawLocation = getFnMetadataByID(Record[Slot++]);
      }
 
      DbgVariableRecord *DVR = nullptr;
      switch (BitCode) {
      case bitc::FUNC_CODE_DEBUG_RECORD_VALUE:
      case bitc::FUNC_CODE_DEBUG_RECORD_VALUE_SIMPLE:
        DVR = new DbgVariableRecord(RawLocation, Var, Expr, DIL,
                                    DbgVariableRecord::LocationType::Value);
        break;
      case bitc::FUNC_CODE_DEBUG_RECORD_DECLARE:
        DVR = new DbgVariableRecord(RawLocation, Var, Expr, DIL,
                                    DbgVariableRecord::LocationType::Declare);
        break;
      case bitc::FUNC_CODE_DEBUG_RECORD_DECLARE_VALUE:
        DVR = new DbgVariableRecord(
            RawLocation, Var, Expr, DIL,
            DbgVariableRecord::LocationType::DeclareValue);
        break;
      case bitc::FUNC_CODE_DEBUG_RECORD_ASSIGN: {
        DIAssignID *ID = cast<DIAssignID>(getFnMetadataByID(Record[Slot++]));
        DIExpression *AddrExpr =
            cast<DIExpression>(getFnMetadataByID(Record[Slot++]));
        Metadata *Addr = getFnMetadataByID(Record[Slot++]);
        DVR = new DbgVariableRecord(RawLocation, Var, Expr, ID, Addr, AddrExpr,
                                    DIL);
        break;
      }
      default:
        llvm_unreachable("Unknown DbgVariableRecord bitcode");
      }
      Inst->getParent()->insertDbgRecordBefore(DVR, Inst->getIterator());
      continue; // This isn't an instruction.
    }
    case bitc::FUNC_CODE_INST_CALL: {
      // CALL: [paramattrs, cc, fmf, fnty, fnid, arg0, arg1...]
      if (Record.size() < 3)
        return error("Invalid call record");
 
      unsigned OpNum = 0;
      AttributeList PAL = getAttributes(Record[OpNum++]);
      unsigned CCInfo = Record[OpNum++];
 
      FastMathFlags FMF;
      if ((CCInfo >> bitc::CALL_FMF) & 1) {
        FMF = getDecodedFastMathFlags(Record[OpNum++]);
        if (!FMF.any())
          return error("Fast math flags indicator set for call with no FMF");
      }
 
      unsigned FTyID = InvalidTypeID;
      FunctionType *FTy = nullptr;
      if ((CCInfo >> bitc::CALL_EXPLICIT_TYPE) & 1) {
        FTyID = Record[OpNum++];
        FTy = dyn_cast_or_null<FunctionType>(getTypeByID(FTyID));
        if (!FTy)
          return error("Explicit call type is not a function type");
      }
 
      Value *Callee;
      unsigned CalleeTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, Callee, CalleeTypeID,
                           CurBB))
        return error("Invalid call record");
 
      PointerType *OpTy = dyn_cast<PointerType>(Callee->getType());
      if (!OpTy)
        return error("Callee is not a pointer type");
      if (!FTy) {
        FTyID = getContainedTypeID(CalleeTypeID);
        FTy = dyn_cast_or_null<FunctionType>(getTypeByID(FTyID));
        if (!FTy)
          return error("Callee is not of pointer to function type");
      }
      if (Record.size() < FTy->getNumParams() + OpNum)
        return error("Insufficient operands to call");
 
      SmallVector<Value*, 16> Args;
      SmallVector<unsigned, 16> ArgTyIDs;
      // Read the fixed params.
      for (unsigned i = 0, e = FTy->getNumParams(); i != e; ++i, ++OpNum) {
        unsigned ArgTyID = getContainedTypeID(FTyID, i + 1);
        if (FTy->getParamType(i)->isLabelTy())
          Args.push_back(getBasicBlock(Record[OpNum]));
        else
          Args.push_back(getValue(Record, OpNum, NextValueNo,
                                  FTy->getParamType(i), ArgTyID, CurBB));
        ArgTyIDs.push_back(ArgTyID);
        if (!Args.back())
          return error("Invalid call record");
      }
 
      // Read type/value pairs for varargs params.
      if (!FTy->isVarArg()) {
        if (OpNum != Record.size())
          return error("Invalid call record");
      } else {
        while (OpNum != Record.size()) {
          Value *Op;
          unsigned OpTypeID;
          if (getValueTypePair(Record, OpNum, NextValueNo, Op, OpTypeID, CurBB))
            return error("Invalid call record");
          Args.push_back(Op);
          ArgTyIDs.push_back(OpTypeID);
        }
      }
 
      // Upgrade the bundles if needed.
      if (!OperandBundles.empty())
        UpgradeOperandBundles(OperandBundles);
 
      I = CallInst::Create(FTy, Callee, Args, OperandBundles);
      ResTypeID = getContainedTypeID(FTyID);
      OperandBundles.clear();
      InstructionList.push_back(I);
      cast<CallInst>(I)->setCallingConv(
          static_cast<CallingConv::ID>((0x7ff & CCInfo) >> bitc::CALL_CCONV));
      CallInst::TailCallKind TCK = CallInst::TCK_None;
      if (CCInfo & (1 << bitc::CALL_TAIL))
        TCK = CallInst::TCK_Tail;
      if (CCInfo & (1 << bitc::CALL_MUSTTAIL))
        TCK = CallInst::TCK_MustTail;
      if (CCInfo & (1 << bitc::CALL_NOTAIL))
        TCK = CallInst::TCK_NoTail;
      cast<CallInst>(I)->setTailCallKind(TCK);
      cast<CallInst>(I)->setAttributes(PAL);
      if (isa<DbgInfoIntrinsic>(I))
        SeenDebugIntrinsic = true;
      if (Error Err = propagateAttributeTypes(cast<CallBase>(I), ArgTyIDs)) {
        I->deleteValue();
        return Err;
      }
      if (FMF.any()) {
        if (!isa<FPMathOperator>(I))
          return error("Fast-math-flags specified for call without "
                       "floating-point scalar or vector return type");
        I->setFastMathFlags(FMF);
      }
      break;
    }
    case bitc::FUNC_CODE_INST_VAARG: { // VAARG: [valistty, valist, instty]
      if (Record.size() < 3)
        return error("Invalid va_arg record");
      unsigned OpTyID = Record[0];
      Type *OpTy = getTypeByID(OpTyID);
      Value *Op = getValue(Record, 1, NextValueNo, OpTy, OpTyID, CurBB);
      ResTypeID = Record[2];
      Type *ResTy = getTypeByID(ResTypeID);
      if (!OpTy || !Op || !ResTy)
        return error("Invalid va_arg record");
      I = new VAArgInst(Op, ResTy);
      InstructionList.push_back(I);
      break;
    }
 
    case bitc::FUNC_CODE_OPERAND_BUNDLE: {
      // A call or an invoke can be optionally prefixed with some variable
      // number of operand bundle blocks.  These blocks are read into
      // OperandBundles and consumed at the next call or invoke instruction.
 
      if (Record.empty() || Record[0] >= BundleTags.size())
        return error("Invalid operand bundle record");
 
      std::vector<Value *> Inputs;
 
      unsigned OpNum = 1;
      while (OpNum != Record.size()) {
        Value *Op;
        if (getValueOrMetadata(Record, OpNum, NextValueNo, Op, CurBB))
          return error("Invalid operand bundle record");
        Inputs.push_back(Op);
      }
 
      OperandBundles.emplace_back(BundleTags[Record[0]], std::move(Inputs));
      continue;
    }
 
    case bitc::FUNC_CODE_INST_FREEZE: { // FREEZE: [opty,opval]
      unsigned OpNum = 0;
      Value *Op = nullptr;
      unsigned OpTypeID;
      if (getValueTypePair(Record, OpNum, NextValueNo, Op, OpTypeID, CurBB))
        return error("Invalid freeze record");
      if (OpNum != Record.size())
        return error("Invalid freeze record");
 
      I = new FreezeInst(Op);
      ResTypeID = OpTypeID;
      InstructionList.push_back(I);
      break;
    }
    }
 
    // Add instruction to end of current BB.  If there is no current BB, reject
    // this file.
    if (!CurBB) {
      I->deleteValue();
      return error("Invalid instruction with no BB");
    }
    if (!OperandBundles.empty()) {
      I->deleteValue();
      return error("Operand bundles found with no consumer");
    }
    I->insertInto(CurBB, CurBB->end());
 
    // If this was a terminator instruction, move to the next block.
    if (I->isTerminator()) {
      ++CurBBNo;
      CurBB = CurBBNo < FunctionBBs.size() ? FunctionBBs[CurBBNo] : nullptr;
    }
 
    // Non-void values get registered in the value table for future use.
    if (!I->getType()->isVoidTy()) {
      assert(I->getType() == getTypeByID(ResTypeID) &&
             "Incorrect result type ID");
      if (Error Err = ValueList.assignValue(NextValueNo++, I, ResTypeID))
        return Err;
    }
  }
 
OutOfRecordLoop:
 
  if (!OperandBundles.empty())
    return error("Operand bundles found with no consumer");
 
  // Check the function list for unresolved values.
  if (Argument *A = dyn_cast<Argument>(ValueList.back())) {
    if (!A->getParent()) {
      // We found at least one unresolved value.  Nuke them all to avoid leaks.
      for (unsigned i = ModuleValueListSize, e = ValueList.size(); i != e; ++i){
        if ((A = dyn_cast_or_null<Argument>(ValueList[i])) && !A->getParent()) {
          A->replaceAllUsesWith(PoisonValue::get(A->getType()));
          delete A;
        }
      }
      return error("Never resolved value found in function");
    }
  }
 
  // Unexpected unresolved metadata about to be dropped.
  if (MDLoader->hasFwdRefs())
    return error("Invalid function metadata: outgoing forward refs");
 
  if (PhiConstExprBB)
    PhiConstExprBB->eraseFromParent();
 
  for (const auto &Pair : ConstExprEdgeBBs) {
    BasicBlock *From = Pair.first.first;
    BasicBlock *To = Pair.first.second;
    BasicBlock *EdgeBB = Pair.second;
    UncondBrInst::Create(To, EdgeBB);
    From->getTerminator()->replaceSuccessorWith(To, EdgeBB);
    To->replacePhiUsesWith(From, EdgeBB);
    EdgeBB->moveBefore(To);
  }
 
  // Trim the value list down to the size it was before we parsed this function.
  ValueList.shrinkTo(ModuleValueListSize);
  MDLoader->shrinkTo(ModuleMDLoaderSize);
  std::vector<BasicBlock*>().swap(FunctionBBs);
  return Error::success();
}
 
/// Find the function body in the bitcode stream
Error BitcodeReader::findFunctionInStream(
    Function *F,
    DenseMap<Function *, uint64_t>::iterator DeferredFunctionInfoIterator) {
  while (DeferredFunctionInfoIterator->second == 0) {
    // This is the fallback handling for the old format bitcode that
    // didn't contain the function index in the VST, or when we have
    // an anonymous function which would not have a VST entry.
    // Assert that we have one of those two cases.
    assert(VSTOffset == 0 || !F->hasName());
    // Parse the next body in the stream and set its position in the
    // DeferredFunctionInfo map.
    if (Error Err = rememberAndSkipFunctionBodies())
      return Err;
  }
  return Error::success();
}
 
SyncScope::ID BitcodeReader::getDecodedSyncScopeID(unsigned Val) {
  if (Val == SyncScope::SingleThread || Val == SyncScope::System)
    return SyncScope::ID(Val);
  if (Val >= SSIDs.size())
    return SyncScope::System; // Map unknown synchronization scopes to system.
  return SSIDs[Val];
}
 
//===----------------------------------------------------------------------===//
// GVMaterializer implementation
//===----------------------------------------------------------------------===//
 
Error BitcodeReader::materialize(GlobalValue *GV) {
  Function *F = dyn_cast<Function>(GV);
  // If it's not a function or is already material, ignore the request.
  if (!F || !F->isMaterializable())
    return Error::success();
 
  DenseMap<Function*, uint64_t>::iterator DFII = DeferredFunctionInfo.find(F);
  assert(DFII != DeferredFunctionInfo.end() && "Deferred function not found!");
  // If its position is recorded as 0, its body is somewhere in the stream
  // but we haven't seen it yet.
  if (DFII->second == 0)
    if (Error Err = findFunctionInStream(F, DFII))
      return Err;
 
  // Materialize metadata before parsing any function bodies.
  if (Error Err = materializeMetadata())
    return Err;
 
  // Move the bit stream to the saved position of the deferred function body.
  if (Error JumpFailed = Stream.JumpToBit(DFII->second))
    return JumpFailed;
 
  if (Error Err = parseFunctionBody(F))
    return Err;
  F->setIsMaterializable(false);
 
  // All parsed Functions should load into the debug info format dictated by the
  // Module.
  if (SeenDebugIntrinsic && SeenDebugRecord)
    return error("Mixed debug intrinsics and debug records in bitcode module!");
 
  if (StripDebugInfo)
    stripDebugInfo(*F);
 
  // Finish fn->subprogram upgrade for materialized functions.
  if (DISubprogram *SP = MDLoader->lookupSubprogramForFunction(F))
    F->setSubprogram(SP);
 
  // Check if the TBAA Metadata are valid, otherwise we will need to strip them.
  if (!MDLoader->isStrippingTBAA()) {
    for (auto &I : instructions(F)) {
      MDNode *TBAA = I.getMetadata(LLVMContext::MD_tbaa);
      if (!TBAA || TBAAVerifyHelper.visitTBAAMetadata(&I, TBAA))
        continue;
      MDLoader->setStripTBAA(true);
      stripTBAA(F->getParent());
    }
  }
 
  for (auto &I : make_early_inc_range(instructions(F))) {
    // "Upgrade" older incorrect branch weights by dropping them.
    if (auto *MD = I.getMetadata(LLVMContext::MD_prof)) {
      if (MD->getOperand(0) != nullptr && isa<MDString>(MD->getOperand(0))) {
        MDString *MDS = cast<MDString>(MD->getOperand(0));
        StringRef ProfName = MDS->getString();
        // Check consistency of !prof branch_weights metadata.
        if (ProfName != MDProfLabels::BranchWeights)
          continue;
        unsigned ExpectedNumOperands = 0;
        if (isa<CondBrInst>(&I))
          ExpectedNumOperands = 2;
        else if (SwitchInst *SI = dyn_cast<SwitchInst>(&I))
          ExpectedNumOperands = SI->getNumSuccessors();
        else if (isa<CallInst>(&I))
          ExpectedNumOperands = 1;
        else if (IndirectBrInst *IBI = dyn_cast<IndirectBrInst>(&I))
          ExpectedNumOperands = IBI->getNumDestinations();
        else if (isa<SelectInst>(&I))
          ExpectedNumOperands = 2;
        else
          continue; // ignore and continue.
 
        unsigned Offset = getBranchWeightOffset(MD);
 
        // If branch weight doesn't match, just strip branch weight.
        if (MD->getNumOperands() != Offset + ExpectedNumOperands)
          I.setMetadata(LLVMContext::MD_prof, nullptr);
      }
    }
 
    if (auto *CI = dyn_cast<CallBase>(&I)) {
      // Remove incompatible attributes on function calls.
      CI->removeRetAttrs(AttributeFuncs::typeIncompatible(
          CI->getFunctionType()->getReturnType(), CI->getRetAttributes()));
 
      for (unsigned ArgNo = 0; ArgNo < CI->arg_size(); ++ArgNo)
        CI->removeParamAttrs(ArgNo, AttributeFuncs::typeIncompatible(
                                        CI->getArgOperand(ArgNo)->getType(),
                                        CI->getParamAttributes(ArgNo)));
 
      // Upgrade intrinsics.
      if (Function *OldFn = CI->getCalledFunction()) {
        auto It = UpgradedIntrinsics.find(OldFn);
        if (It != UpgradedIntrinsics.end())
          UpgradeIntrinsicCall(CI, It->second);
      }
    }
  }
 
  // Look for functions that rely on old function attribute behavior.
  UpgradeFunctionAttributes(*F);
 
  // Bring in any functions that this function forward-referenced via
  // blockaddresses.
  return materializeForwardReferencedFunctions();
}
 
Error BitcodeReader::materializeModule() {
  if (Error Err = materializeMetadata())
    return Err;
 
  // Promise to materialize all forward references.
  WillMaterializeAllForwardRefs = true;
 
  // Iterate over the module, deserializing any functions that are still on
  // disk.
  for (Function &F : *TheModule) {
    if (Error Err = materialize(&F))
      return Err;
  }
  // At this point, if there are any function bodies, parse the rest of
  // the bits in the module past the last function block we have recorded
  // through either lazy scanning or the VST.
  if (LastFunctionBlockBit || NextUnreadBit)
    if (Error Err = parseModule(LastFunctionBlockBit > NextUnreadBit
                                    ? LastFunctionBlockBit
                                    : NextUnreadBit))
      return Err;
 
  // Check that all block address forward references got resolved (as we
  // promised above).
  if (!BasicBlockFwdRefs.empty())
    return error("Never resolved function from blockaddress");
 
  // Upgrade any intrinsic calls that slipped through (should not happen!) and
  // delete the old functions to clean up. We can't do this unless the entire
  // module is materialized because there could always be another function body
  // with calls to the old function.
  for (auto &I : UpgradedIntrinsics) {
    for (auto *U : I.first->users()) {
      if (CallInst *CI = dyn_cast<CallInst>(U))
        UpgradeIntrinsicCall(CI, I.second);
    }
    if (I.first != I.second) {
      if (!I.first->use_empty())
        I.first->replaceAllUsesWith(I.second);
      I.first->eraseFromParent();
    }
  }
  UpgradedIntrinsics.clear();
 
  UpgradeDebugInfo(*TheModule);
 
  UpgradeModuleFlags(*TheModule);
 
  UpgradeNVVMAnnotations(*TheModule);
 
  UpgradeARCRuntime(*TheModule);
 
  copyModuleAttrToFunctions(*TheModule);
 
  return Error::success();
}
 
std::vector<StructType *> BitcodeReader::getIdentifiedStructTypes() const {
  return IdentifiedStructTypes;
}
 
ModuleSummaryIndexBitcodeReader::ModuleSummaryIndexBitcodeReader(
    BitstreamCursor Cursor, StringRef Strtab, ModuleSummaryIndex &TheIndex,
    StringRef ModulePath, std::function<bool(GlobalValue::GUID)> IsPrevailing)
    : BitcodeReaderBase(std::move(Cursor), Strtab), TheIndex(TheIndex),
      ModulePath(ModulePath), IsPrevailing(IsPrevailing) {}
 
void ModuleSummaryIndexBitcodeReader::addThisModule() {
  TheIndex.addModule(ModulePath);
}
 
ModuleSummaryIndex::ModuleInfo *
ModuleSummaryIndexBitcodeReader::getThisModule() {
  return TheIndex.getModule(ModulePath);
}
 
template <bool AllowNullValueInfo>
std::pair<ValueInfo, GlobalValue::GUID>
ModuleSummaryIndexBitcodeReader::getValueInfoFromValueId(unsigned ValueId) {
  auto VGI = ValueIdToValueInfoMap[ValueId];
  // We can have a null value info in distributed ThinLTO index files:
  // - For memprof callsite info records when the callee function summary is not
  //   included in the index.
  // - For alias summary when its aliasee summary is not included in the index.
  // The bitcode writer records 0 in these cases,
  // and the caller of this helper will set AllowNullValueInfo to true.
  assert(AllowNullValueInfo || std::get<0>(VGI));
  return VGI;
}
 
void ModuleSummaryIndexBitcodeReader::setValueGUID(
    uint64_t ValueID, StringRef ValueName, GlobalValue::LinkageTypes Linkage,
    StringRef SourceFileName) {
  std::string GlobalId =
      GlobalValue::getGlobalIdentifier(ValueName, Linkage, SourceFileName);
  auto ValueGUID = GlobalValue::getGUIDAssumingExternalLinkage(GlobalId);
  auto OriginalNameID = ValueGUID;
  if (GlobalValue::isLocalLinkage(Linkage))
    OriginalNameID = GlobalValue::getGUIDAssumingExternalLinkage(ValueName);
  if (PrintSummaryGUIDs)
    dbgs() << "GUID " << ValueGUID << "(" << OriginalNameID << ") is "
           << ValueName << "\n";
 
  // UseStrtab is false for legacy summary formats and value names are
  // created on stack. In that case we save the name in a string saver in
  // the index so that the value name can be recorded.
  ValueIdToValueInfoMap[ValueID] = std::make_pair(
      TheIndex.getOrInsertValueInfo(
          ValueGUID, UseStrtab ? ValueName : TheIndex.saveString(ValueName)),
      OriginalNameID);
}
 
// Specialized value symbol table parser used when reading module index
// blocks where we don't actually create global values. The parsed information
// is saved in the bitcode reader for use when later parsing summaries.
Error ModuleSummaryIndexBitcodeReader::parseValueSymbolTable(
    uint64_t Offset,
    DenseMap<unsigned, GlobalValue::LinkageTypes> &ValueIdToLinkageMap) {
  // With a strtab the VST is not required to parse the summary.
  if (UseStrtab)
    return Error::success();
 
  assert(Offset > 0 && "Expected non-zero VST offset");
  Expected<uint64_t> MaybeCurrentBit = jumpToValueSymbolTable(Offset, Stream);
  if (!MaybeCurrentBit)
    return MaybeCurrentBit.takeError();
  uint64_t CurrentBit = MaybeCurrentBit.get();
 
  if (Error Err = Stream.EnterSubBlock(bitc::VALUE_SYMTAB_BLOCK_ID))
    return Err;
 
  SmallVector<uint64_t, 64> Record;
 
  // Read all the records for this value table.
  SmallString<128> ValueName;
 
  while (true) {
    Expected<BitstreamEntry> MaybeEntry = Stream.advanceSkippingSubblocks();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    BitstreamEntry Entry = MaybeEntry.get();
 
    switch (Entry.Kind) {
    case BitstreamEntry::SubBlock: // Handled for us already.
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock:
      // Done parsing VST, jump back to wherever we came from.
      if (Error JumpFailed = Stream.JumpToBit(CurrentBit))
        return JumpFailed;
      return Error::success();
    case BitstreamEntry::Record:
      // The interesting case.
      break;
    }
 
    // Read a record.
    Record.clear();
    Expected<unsigned> MaybeRecord = Stream.readRecord(Entry.ID, Record);
    if (!MaybeRecord)
      return MaybeRecord.takeError();
    switch (MaybeRecord.get()) {
    default: // Default behavior: ignore (e.g. VST_CODE_BBENTRY records).
      break;
    case bitc::VST_CODE_ENTRY: { // VST_CODE_ENTRY: [valueid, namechar x N]
      if (convertToString(Record, 1, ValueName))
        return error("Invalid vst_code_entry record");
      unsigned ValueID = Record[0];
      assert(!SourceFileName.empty());
      auto VLI = ValueIdToLinkageMap.find(ValueID);
      assert(VLI != ValueIdToLinkageMap.end() &&
             "No linkage found for VST entry?");
      auto Linkage = VLI->second;
      setValueGUID(ValueID, ValueName, Linkage, SourceFileName);
      ValueName.clear();
      break;
    }
    case bitc::VST_CODE_FNENTRY: {
      // VST_CODE_FNENTRY: [valueid, offset, namechar x N]
      if (convertToString(Record, 2, ValueName))
        return error("Invalid vst_code_fnentry record");
      unsigned ValueID = Record[0];
      assert(!SourceFileName.empty());
      auto VLI = ValueIdToLinkageMap.find(ValueID);
      assert(VLI != ValueIdToLinkageMap.end() &&
             "No linkage found for VST entry?");
      auto Linkage = VLI->second;
      setValueGUID(ValueID, ValueName, Linkage, SourceFileName);
      ValueName.clear();
      break;
    }
    case bitc::VST_CODE_COMBINED_ENTRY: {
      // VST_CODE_COMBINED_ENTRY: [valueid, refguid]
      unsigned ValueID = Record[0];
      GlobalValue::GUID RefGUID = Record[1];
      // The "original name", which is the second value of the pair will be
      // overriden later by a FS_COMBINED_ORIGINAL_NAME in the combined index.
      ValueIdToValueInfoMap[ValueID] =
          std::make_pair(TheIndex.getOrInsertValueInfo(RefGUID), RefGUID);
      break;
    }
    }
  }
}
 
// Parse just the blocks needed for building the index out of the module.
// At the end of this routine the module Index is populated with a map
// from global value id to GlobalValueSummary objects.
Error ModuleSummaryIndexBitcodeReader::parseModule() {
  if (Error Err = Stream.EnterSubBlock(bitc::MODULE_BLOCK_ID))
    return Err;
 
  SmallVector<uint64_t, 64> Record;
  DenseMap<unsigned, GlobalValue::LinkageTypes> ValueIdToLinkageMap;
  unsigned ValueId = 0;
 
  // Read the index for this module.
  while (true) {
    Expected<llvm::BitstreamEntry> MaybeEntry = Stream.advance();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    llvm::BitstreamEntry Entry = MaybeEntry.get();
 
    switch (Entry.Kind) {
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock:
      return Error::success();
 
    case BitstreamEntry::SubBlock:
      switch (Entry.ID) {
      default: // Skip unknown content.
        if (Error Err = Stream.SkipBlock())
          return Err;
        break;
      case bitc::BLOCKINFO_BLOCK_ID:
        // Need to parse these to get abbrev ids (e.g. for VST)
        if (Error Err = readBlockInfo())
          return Err;
        break;
      case bitc::VALUE_SYMTAB_BLOCK_ID:
        // Should have been parsed earlier via VSTOffset, unless there
        // is no summary section.
        assert(((SeenValueSymbolTable && VSTOffset > 0) ||
                !SeenGlobalValSummary) &&
               "Expected early VST parse via VSTOffset record");
        if (Error Err = Stream.SkipBlock())
          return Err;
        break;
      case bitc::GLOBALVAL_SUMMARY_BLOCK_ID:
      case bitc::FULL_LTO_GLOBALVAL_SUMMARY_BLOCK_ID:
        // Add the module if it is a per-module index (has a source file name).
        if (!SourceFileName.empty())
          addThisModule();
        assert(!SeenValueSymbolTable &&
               "Already read VST when parsing summary block?");
        // We might not have a VST if there were no values in the
        // summary. An empty summary block generated when we are
        // performing ThinLTO compiles so we don't later invoke
        // the regular LTO process on them.
        if (VSTOffset > 0) {
          if (Error Err = parseValueSymbolTable(VSTOffset, ValueIdToLinkageMap))
            return Err;
          SeenValueSymbolTable = true;
        }
        SeenGlobalValSummary = true;
        if (Error Err = parseEntireSummary(Entry.ID))
          return Err;
        break;
      case bitc::MODULE_STRTAB_BLOCK_ID:
        if (Error Err = parseModuleStringTable())
          return Err;
        break;
      }
      continue;
 
    case BitstreamEntry::Record: {
        Record.clear();
        Expected<unsigned> MaybeBitCode = Stream.readRecord(Entry.ID, Record);
        if (!MaybeBitCode)
          return MaybeBitCode.takeError();
        switch (MaybeBitCode.get()) {
        default:
          break; // Default behavior, ignore unknown content.
        case bitc::MODULE_CODE_VERSION: {
          if (Error Err = parseVersionRecord(Record).takeError())
            return Err;
          break;
        }
        /// MODULE_CODE_SOURCE_FILENAME: [namechar x N]
        case bitc::MODULE_CODE_SOURCE_FILENAME: {
          SmallString<128> ValueName;
          if (convertToString(Record, 0, ValueName))
            return error("Invalid source filename record");
          SourceFileName = ValueName.c_str();
          break;
        }
        /// MODULE_CODE_HASH: [5*i32]
        case bitc::MODULE_CODE_HASH: {
          if (Record.size() != 5)
            return error("Invalid hash length " + Twine(Record.size()).str());
          auto &Hash = getThisModule()->second;
          int Pos = 0;
          for (auto &Val : Record) {
            assert(!(Val >> 32) && "Unexpected high bits set");
            Hash[Pos++] = Val;
          }
          break;
        }
        /// MODULE_CODE_VSTOFFSET: [offset]
        case bitc::MODULE_CODE_VSTOFFSET:
          if (Record.empty())
            return error("Invalid vstoffset record");
          // Note that we subtract 1 here because the offset is relative to one
          // word before the start of the identification or module block, which
          // was historically always the start of the regular bitcode header.
          VSTOffset = Record[0] - 1;
          break;
        // v1 GLOBALVAR: [pointer type, isconst,     initid,       linkage, ...]
        // v1 FUNCTION:  [type,         callingconv, isproto,      linkage, ...]
        // v1 ALIAS:     [alias type,   addrspace,   aliasee val#, linkage, ...]
        // v2: [strtab offset, strtab size, v1]
        case bitc::MODULE_CODE_GLOBALVAR:
        case bitc::MODULE_CODE_FUNCTION:
        case bitc::MODULE_CODE_ALIAS: {
          StringRef Name;
          ArrayRef<uint64_t> GVRecord;
          std::tie(Name, GVRecord) = readNameFromStrtab(Record);
          if (GVRecord.size() <= 3)
            return error("Invalid global record");
          uint64_t RawLinkage = GVRecord[3];
          GlobalValue::LinkageTypes Linkage = getDecodedLinkage(RawLinkage);
          if (!UseStrtab) {
            ValueIdToLinkageMap[ValueId++] = Linkage;
            break;
          }
 
          setValueGUID(ValueId++, Name, Linkage, SourceFileName);
          break;
        }
        }
      }
      continue;
    }
  }
}
 
SmallVector<ValueInfo, 0>
ModuleSummaryIndexBitcodeReader::makeRefList(ArrayRef<uint64_t> Record) {
  SmallVector<ValueInfo, 0> Ret;
  Ret.reserve(Record.size());
  for (uint64_t RefValueId : Record)
    Ret.push_back(std::get<0>(getValueInfoFromValueId(RefValueId)));
  return Ret;
}
 
SmallVector<FunctionSummary::EdgeTy, 0>
ModuleSummaryIndexBitcodeReader::makeCallList(ArrayRef<uint64_t> Record,
                                              bool IsOldProfileFormat,
                                              bool HasProfile, bool HasRelBF) {
  SmallVector<FunctionSummary::EdgeTy, 0> Ret;
  // In the case of new profile formats, there are two Record entries per
  // Edge. Otherwise, conservatively reserve up to Record.size.
  if (!IsOldProfileFormat && (HasProfile || HasRelBF))
    Ret.reserve(Record.size() / 2);
  else
    Ret.reserve(Record.size());
 
  for (unsigned I = 0, E = Record.size(); I != E; ++I) {
    CalleeInfo::HotnessType Hotness = CalleeInfo::HotnessType::Unknown;
    bool HasTailCall = false;
    uint64_t RelBF = 0;
    ValueInfo Callee = std::get<0>(getValueInfoFromValueId(Record[I]));
    if (IsOldProfileFormat) {
      I += 1; // Skip old callsitecount field
      if (HasProfile)
        I += 1; // Skip old profilecount field
    } else if (HasProfile)
      std::tie(Hotness, HasTailCall) =
          getDecodedHotnessCallEdgeInfo(Record[++I]);
    // Deprecated, but still needed to read old bitcode files.
    else if (HasRelBF)
      getDecodedRelBFCallEdgeInfo(Record[++I], RelBF, HasTailCall);
    Ret.push_back(
        FunctionSummary::EdgeTy{Callee, CalleeInfo(Hotness, HasTailCall)});
  }
  return Ret;
}
 
static void
parseWholeProgramDevirtResolutionByArg(ArrayRef<uint64_t> Record, size_t &Slot,
                                       WholeProgramDevirtResolution &Wpd) {
  uint64_t ArgNum = Record[Slot++];
  WholeProgramDevirtResolution::ByArg &B =
      Wpd.ResByArg[{Record.begin() + Slot, Record.begin() + Slot + ArgNum}];
  Slot += ArgNum;
 
  B.TheKind =
      static_cast<WholeProgramDevirtResolution::ByArg::Kind>(Record[Slot++]);
  B.Info = Record[Slot++];
  B.Byte = Record[Slot++];
  B.Bit = Record[Slot++];
}
 
static void parseWholeProgramDevirtResolution(ArrayRef<uint64_t> Record,
                                              StringRef Strtab, size_t &Slot,
                                              TypeIdSummary &TypeId) {
  uint64_t Id = Record[Slot++];
  WholeProgramDevirtResolution &Wpd = TypeId.WPDRes[Id];
 
  Wpd.TheKind = static_cast<WholeProgramDevirtResolution::Kind>(Record[Slot++]);
  Wpd.SingleImplName = {Strtab.data() + Record[Slot],
                        static_cast<size_t>(Record[Slot + 1])};
  Slot += 2;
 
  uint64_t ResByArgNum = Record[Slot++];
  for (uint64_t I = 0; I != ResByArgNum; ++I)
    parseWholeProgramDevirtResolutionByArg(Record, Slot, Wpd);
}
 
static void parseTypeIdSummaryRecord(ArrayRef<uint64_t> Record,
                                     StringRef Strtab,
                                     ModuleSummaryIndex &TheIndex) {
  size_t Slot = 0;
  TypeIdSummary &TypeId = TheIndex.getOrInsertTypeIdSummary(
      {Strtab.data() + Record[Slot], static_cast<size_t>(Record[Slot + 1])});
  Slot += 2;
 
  TypeId.TTRes.TheKind = static_cast<TypeTestResolution::Kind>(Record[Slot++]);
  TypeId.TTRes.SizeM1BitWidth = Record[Slot++];
  TypeId.TTRes.AlignLog2 = Record[Slot++];
  TypeId.TTRes.SizeM1 = Record[Slot++];
  TypeId.TTRes.BitMask = Record[Slot++];
  TypeId.TTRes.InlineBits = Record[Slot++];
 
  while (Slot < Record.size())
    parseWholeProgramDevirtResolution(Record, Strtab, Slot, TypeId);
}
 
std::vector<FunctionSummary::ParamAccess>
ModuleSummaryIndexBitcodeReader::parseParamAccesses(ArrayRef<uint64_t> Record) {
  auto ReadRange = [&]() {
    APInt Lower(FunctionSummary::ParamAccess::RangeWidth,
                BitcodeReader::decodeSignRotatedValue(Record.consume_front()));
    APInt Upper(FunctionSummary::ParamAccess::RangeWidth,
                BitcodeReader::decodeSignRotatedValue(Record.consume_front()));
    ConstantRange Range{Lower, Upper};
    assert(!Range.isFullSet());
    assert(!Range.isUpperSignWrapped());
    return Range;
  };
 
  std::vector<FunctionSummary::ParamAccess> PendingParamAccesses;
  while (!Record.empty()) {
    PendingParamAccesses.emplace_back();
    FunctionSummary::ParamAccess &ParamAccess = PendingParamAccesses.back();
    ParamAccess.ParamNo = Record.consume_front();
    ParamAccess.Use = ReadRange();
    ParamAccess.Calls.resize(Record.consume_front());
    for (auto &Call : ParamAccess.Calls) {
      Call.ParamNo = Record.consume_front();
      Call.Callee =
          std::get<0>(getValueInfoFromValueId(Record.consume_front()));
      Call.Offsets = ReadRange();
    }
  }
  return PendingParamAccesses;
}
 
void ModuleSummaryIndexBitcodeReader::parseTypeIdCompatibleVtableInfo(
    ArrayRef<uint64_t> Record, size_t &Slot,
    TypeIdCompatibleVtableInfo &TypeId) {
  uint64_t Offset = Record[Slot++];
  ValueInfo Callee = std::get<0>(getValueInfoFromValueId(Record[Slot++]));
  TypeId.push_back({Offset, Callee});
}
 
void ModuleSummaryIndexBitcodeReader::parseTypeIdCompatibleVtableSummaryRecord(
    ArrayRef<uint64_t> Record) {
  size_t Slot = 0;
  TypeIdCompatibleVtableInfo &TypeId =
      TheIndex.getOrInsertTypeIdCompatibleVtableSummary(
          {Strtab.data() + Record[Slot],
           static_cast<size_t>(Record[Slot + 1])});
  Slot += 2;
 
  while (Slot < Record.size())
    parseTypeIdCompatibleVtableInfo(Record, Slot, TypeId);
}
 
SmallVector<unsigned> ModuleSummaryIndexBitcodeReader::parseAllocInfoContext(
    ArrayRef<uint64_t> Record, unsigned &I) {
  SmallVector<unsigned> StackIdList;
  // For backwards compatibility with old format before radix tree was
  // used, simply see if we found a radix tree array record (and thus if
  // the RadixArray is non-empty).
  if (RadixArray.empty()) {
    unsigned NumStackEntries = Record[I++];
    assert(Record.size() - I >= NumStackEntries);
    StackIdList.reserve(NumStackEntries);
    for (unsigned J = 0; J < NumStackEntries; J++) {
      assert(Record[I] < StackIds.size());
      StackIdList.push_back(getStackIdIndex(Record[I++]));
    }
  } else {
    unsigned RadixIndex = Record[I++];
    // See the comments above CallStackRadixTreeBuilder in ProfileData/MemProf.h
    // for a detailed description of the radix tree array format. Briefly, the
    // first entry will be the number of frames, any negative values are the
    // negative of the offset of the next frame, and otherwise the frames are in
    // increasing linear order.
    assert(RadixIndex < RadixArray.size());
    unsigned NumStackIds = RadixArray[RadixIndex++];
    StackIdList.reserve(NumStackIds);
    while (NumStackIds--) {
      assert(RadixIndex < RadixArray.size());
      unsigned Elem = RadixArray[RadixIndex];
      if (static_cast<std::make_signed_t<unsigned>>(Elem) < 0) {
        RadixIndex = RadixIndex - Elem;
        assert(RadixIndex < RadixArray.size());
        Elem = RadixArray[RadixIndex];
        // We shouldn't encounter a second offset in a row.
        assert(static_cast<std::make_signed_t<unsigned>>(Elem) >= 0);
      }
      RadixIndex++;
      StackIdList.push_back(getStackIdIndex(Elem));
    }
  }
  return StackIdList;
}
 
static void setSpecialRefs(SmallVectorImpl<ValueInfo> &Refs, unsigned ROCnt,
                           unsigned WOCnt) {
  // Readonly and writeonly refs are in the end of the refs list.
  assert(ROCnt + WOCnt <= Refs.size());
  unsigned FirstWORef = Refs.size() - WOCnt;
  unsigned RefNo = FirstWORef - ROCnt;
  for (; RefNo < FirstWORef; ++RefNo)
    Refs[RefNo].setReadOnly();
  for (; RefNo < Refs.size(); ++RefNo)
    Refs[RefNo].setWriteOnly();
}
 
// Eagerly parse the entire summary block. This populates the GlobalValueSummary
// objects in the index.
Error ModuleSummaryIndexBitcodeReader::parseEntireSummary(unsigned ID) {
  if (Error Err = Stream.EnterSubBlock(ID))
    return Err;
  SmallVector<uint64_t, 64> Record;
 
  // Parse version
  {
    Expected<BitstreamEntry> MaybeEntry = Stream.advanceSkippingSubblocks();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    BitstreamEntry Entry = MaybeEntry.get();
 
    if (Entry.Kind != BitstreamEntry::Record)
      return error("Invalid Summary Block: record for version expected");
    Expected<unsigned> MaybeRecord = Stream.readRecord(Entry.ID, Record);
    if (!MaybeRecord)
      return MaybeRecord.takeError();
    if (MaybeRecord.get() != bitc::FS_VERSION)
      return error("Invalid Summary Block: version expected");
  }
  const uint64_t Version = Record[0];
  const bool IsOldProfileFormat = Version == 1;
  // Starting with bitcode summary version 13, MemProf records follow the
  // corresponding function summary.
  const bool MemProfAfterFunctionSummary = Version >= 13;
  if (Version < 1 || Version > ModuleSummaryIndex::BitcodeSummaryVersion)
    return error("Invalid summary version " + Twine(Version) +
                 ". Version should be in the range [1-" +
                 Twine(ModuleSummaryIndex::BitcodeSummaryVersion) +
                 "].");
  Record.clear();
 
  // Keep around the last seen summary to be used when we see an optional
  // "OriginalName" attachement.
  GlobalValueSummary *LastSeenSummary = nullptr;
  GlobalValue::GUID LastSeenGUID = 0;
 
  // Track the most recent function summary if it was prevailing, and while we
  // are not done processing any subsequent memprof records. Starting with
  // summary version 13 (tracked by MemProfAfterFunctionSummary), MemProf
  // records follow the function summary and we skip processing them when the
  // summary is not prevailing. Note that when reading a combined index we don't
  // know what is prevailing so this should always be set in the new format when
  // we encounter MemProf records.
  FunctionSummary *CurrentPrevailingFS = nullptr;
 
  // We can expect to see any number of type ID information records before
  // each function summary records; these variables store the information
  // collected so far so that it can be used to create the summary object.
  std::vector<GlobalValue::GUID> PendingTypeTests;
  std::vector<FunctionSummary::VFuncId> PendingTypeTestAssumeVCalls,
      PendingTypeCheckedLoadVCalls;
  std::vector<FunctionSummary::ConstVCall> PendingTypeTestAssumeConstVCalls,
      PendingTypeCheckedLoadConstVCalls;
  std::vector<FunctionSummary::ParamAccess> PendingParamAccesses;
 
  std::vector<CallsiteInfo> PendingCallsites;
  std::vector<AllocInfo> PendingAllocs;
  std::vector<uint64_t> PendingContextIds;
 
  while (true) {
    Expected<BitstreamEntry> MaybeEntry = Stream.advanceSkippingSubblocks();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    BitstreamEntry Entry = MaybeEntry.get();
 
    switch (Entry.Kind) {
    case BitstreamEntry::SubBlock: // Handled for us already.
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock:
      return Error::success();
    case BitstreamEntry::Record:
      // The interesting case.
      break;
    }
 
    // Read a record. The record format depends on whether this
    // is a per-module index or a combined index file. In the per-module
    // case the records contain the associated value's ID for correlation
    // with VST entries. In the combined index the correlation is done
    // via the bitcode offset of the summary records (which were saved
    // in the combined index VST entries). The records also contain
    // information used for ThinLTO renaming and importing.
    Record.clear();
    Expected<unsigned> MaybeBitCode = Stream.readRecord(Entry.ID, Record);
    if (!MaybeBitCode)
      return MaybeBitCode.takeError();
    unsigned BitCode = MaybeBitCode.get();
 
    switch (BitCode) {
    default: // Default behavior: ignore.
      break;
    case bitc::FS_FLAGS: {  // [flags]
      TheIndex.setFlags(Record[0]);
      break;
    }
    case bitc::FS_VALUE_GUID: { // [valueid, refguid_upper32, refguid_lower32]
      uint64_t ValueID = Record[0];
      GlobalValue::GUID RefGUID;
      if (Version >= 11) {
        RefGUID = Record[1] << 32 | Record[2];
      } else {
        RefGUID = Record[1];
      }
      ValueIdToValueInfoMap[ValueID] =
          std::make_pair(TheIndex.getOrInsertValueInfo(RefGUID), RefGUID);
      break;
    }
    // FS_PERMODULE is legacy and does not have support for the tail call flag.
    // FS_PERMODULE: [valueid, flags, instcount, fflags, numrefs,
    //                numrefs x valueid, n x (valueid)]
    // FS_PERMODULE_PROFILE: [valueid, flags, instcount, fflags, numrefs,
    //                        numrefs x valueid,
    //                        n x (valueid, hotness+tailcall flags)]
    // Deprecated, but still needed to read old bitcode files.
    // FS_PERMODULE_RELBF: [valueid, flags, instcount, fflags, numrefs,
    //                      numrefs x valueid,
    //                      n x (valueid, relblockfreq+tailcall)]
    case bitc::FS_PERMODULE:
    case bitc::FS_PERMODULE_PROFILE:
    // Deprecated, but still needed to read old bitcode files.
    case bitc::FS_PERMODULE_RELBF: {
      unsigned ValueID = Record[0];
      uint64_t RawFlags = Record[1];
      unsigned InstCount = Record[2];
      uint64_t RawFunFlags = 0;
      unsigned NumRefs = Record[3];
      unsigned NumRORefs = 0, NumWORefs = 0;
      int RefListStartIndex = 4;
      if (Version >= 4) {
        RawFunFlags = Record[3];
        NumRefs = Record[4];
        RefListStartIndex = 5;
        if (Version >= 5) {
          NumRORefs = Record[5];
          RefListStartIndex = 6;
          if (Version >= 7) {
            NumWORefs = Record[6];
            RefListStartIndex = 7;
          }
        }
      }
 
      auto Flags = getDecodedGVSummaryFlags(RawFlags, Version);
      // The module path string ref set in the summary must be owned by the
      // index's module string table. Since we don't have a module path
      // string table section in the per-module index, we create a single
      // module path string table entry with an empty (0) ID to take
      // ownership.
      int CallGraphEdgeStartIndex = RefListStartIndex + NumRefs;
      assert(Record.size() >= RefListStartIndex + NumRefs &&
             "Record size inconsistent with number of references");
      SmallVector<ValueInfo, 0> Refs = makeRefList(
          ArrayRef<uint64_t>(Record).slice(RefListStartIndex, NumRefs));
      bool HasProfile = (BitCode == bitc::FS_PERMODULE_PROFILE);
      // Deprecated, but still needed to read old bitcode files.
      bool HasRelBF = (BitCode == bitc::FS_PERMODULE_RELBF);
      SmallVector<FunctionSummary::EdgeTy, 0> Calls = makeCallList(
          ArrayRef<uint64_t>(Record).slice(CallGraphEdgeStartIndex),
          IsOldProfileFormat, HasProfile, HasRelBF);
      setSpecialRefs(Refs, NumRORefs, NumWORefs);
      auto [VI, GUID] = getValueInfoFromValueId(ValueID);
 
      // The linker doesn't resolve local linkage values so don't check whether
      // those are prevailing (set IsPrevailingSym so they are always processed
      // and kept).
      auto LT = (GlobalValue::LinkageTypes)Flags.Linkage;
      bool IsPrevailingSym = !IsPrevailing || GlobalValue::isLocalLinkage(LT) ||
                             IsPrevailing(VI.getGUID());
 
      // If this is not the prevailing copy, and the records are in the "old"
      // order (preceding), clear them now. They should already be empty in
      // the new order (following), as they are processed or skipped immediately
      // when they follow the summary.
      assert(!MemProfAfterFunctionSummary ||
             (PendingCallsites.empty() && PendingAllocs.empty()));
      if (!IsPrevailingSym && !MemProfAfterFunctionSummary) {
        PendingCallsites.clear();
        PendingAllocs.clear();
      }
 
      auto FS = std::make_unique<FunctionSummary>(
          Flags, InstCount, getDecodedFFlags(RawFunFlags), std::move(Refs),
          std::move(Calls), std::move(PendingTypeTests),
          std::move(PendingTypeTestAssumeVCalls),
          std::move(PendingTypeCheckedLoadVCalls),
          std::move(PendingTypeTestAssumeConstVCalls),
          std::move(PendingTypeCheckedLoadConstVCalls),
          std::move(PendingParamAccesses), std::move(PendingCallsites),
          std::move(PendingAllocs));
      FS->setModulePath(getThisModule()->first());
      FS->setOriginalName(GUID);
      // Set CurrentPrevailingFS only if prevailing, so subsequent MemProf
      // records are attached (new order) or skipped.
      if (MemProfAfterFunctionSummary) {
        if (IsPrevailingSym)
          CurrentPrevailingFS = FS.get();
        else
          CurrentPrevailingFS = nullptr;
      }
      TheIndex.addGlobalValueSummary(VI, std::move(FS));
      break;
    }
    // FS_ALIAS: [valueid, flags, valueid]
    // Aliases must be emitted (and parsed) after all FS_PERMODULE entries, as
    // they expect all aliasee summaries to be available.
    case bitc::FS_ALIAS: {
      unsigned ValueID = Record[0];
      uint64_t RawFlags = Record[1];
      unsigned AliaseeID = Record[2];
      auto Flags = getDecodedGVSummaryFlags(RawFlags, Version);
      auto AS = std::make_unique<AliasSummary>(Flags);
      // The module path string ref set in the summary must be owned by the
      // index's module string table. Since we don't have a module path
      // string table section in the per-module index, we create a single
      // module path string table entry with an empty (0) ID to take
      // ownership.
      AS->setModulePath(getThisModule()->first());
 
      auto AliaseeVI = std::get<0>(getValueInfoFromValueId(AliaseeID));
      auto AliaseeInModule = TheIndex.findSummaryInModule(AliaseeVI, ModulePath);
      if (!AliaseeInModule)
        return error("Alias expects aliasee summary to be parsed");
      AS->setAliasee(AliaseeVI, AliaseeInModule);
 
      auto GUID = getValueInfoFromValueId(ValueID);
      AS->setOriginalName(std::get<1>(GUID));
      TheIndex.addGlobalValueSummary(std::get<0>(GUID), std::move(AS));
      break;
    }
    // FS_PERMODULE_GLOBALVAR_INIT_REFS: [valueid, flags, varflags, n x valueid]
    case bitc::FS_PERMODULE_GLOBALVAR_INIT_REFS: {
      unsigned ValueID = Record[0];
      uint64_t RawFlags = Record[1];
      unsigned RefArrayStart = 2;
      GlobalVarSummary::GVarFlags GVF(/* ReadOnly */ false,
                                      /* WriteOnly */ false,
                                      /* Constant */ false,
                                      GlobalObject::VCallVisibilityPublic);
      auto Flags = getDecodedGVSummaryFlags(RawFlags, Version);
      if (Version >= 5) {
        GVF = getDecodedGVarFlags(Record[2]);
        RefArrayStart = 3;
      }
      SmallVector<ValueInfo, 0> Refs =
          makeRefList(ArrayRef<uint64_t>(Record).slice(RefArrayStart));
      auto FS =
          std::make_unique<GlobalVarSummary>(Flags, GVF, std::move(Refs));
      FS->setModulePath(getThisModule()->first());
      auto GUID = getValueInfoFromValueId(ValueID);
      FS->setOriginalName(std::get<1>(GUID));
      TheIndex.addGlobalValueSummary(std::get<0>(GUID), std::move(FS));
      break;
    }
    // FS_PERMODULE_VTABLE_GLOBALVAR_INIT_REFS: [valueid, flags, varflags,
    //                        numrefs, numrefs x valueid,
    //                        n x (valueid, offset)]
    case bitc::FS_PERMODULE_VTABLE_GLOBALVAR_INIT_REFS: {
      unsigned ValueID = Record[0];
      uint64_t RawFlags = Record[1];
      GlobalVarSummary::GVarFlags GVF = getDecodedGVarFlags(Record[2]);
      unsigned NumRefs = Record[3];
      unsigned RefListStartIndex = 4;
      unsigned VTableListStartIndex = RefListStartIndex + NumRefs;
      auto Flags = getDecodedGVSummaryFlags(RawFlags, Version);
      SmallVector<ValueInfo, 0> Refs = makeRefList(
          ArrayRef<uint64_t>(Record).slice(RefListStartIndex, NumRefs));
      VTableFuncList VTableFuncs;
      for (unsigned I = VTableListStartIndex, E = Record.size(); I != E; ++I) {
        ValueInfo Callee = std::get<0>(getValueInfoFromValueId(Record[I]));
        uint64_t Offset = Record[++I];
        VTableFuncs.push_back({Callee, Offset});
      }
      auto VS =
          std::make_unique<GlobalVarSummary>(Flags, GVF, std::move(Refs));
      VS->setModulePath(getThisModule()->first());
      VS->setVTableFuncs(VTableFuncs);
      auto GUID = getValueInfoFromValueId(ValueID);
      VS->setOriginalName(std::get<1>(GUID));
      TheIndex.addGlobalValueSummary(std::get<0>(GUID), std::move(VS));
      break;
    }
    // FS_COMBINED is legacy and does not have support for the tail call flag.
    // FS_COMBINED: [valueid, modid, flags, instcount, fflags, numrefs,
    //               numrefs x valueid, n x (valueid)]
    // FS_COMBINED_PROFILE: [valueid, modid, flags, instcount, fflags, numrefs,
    //                       numrefs x valueid,
    //                       n x (valueid, hotness+tailcall flags)]
    case bitc::FS_COMBINED:
    case bitc::FS_COMBINED_PROFILE: {
      unsigned ValueID = Record[0];
      uint64_t ModuleId = Record[1];
      uint64_t RawFlags = Record[2];
      unsigned InstCount = Record[3];
      uint64_t RawFunFlags = 0;
      unsigned NumRefs = Record[4];
      unsigned NumRORefs = 0, NumWORefs = 0;
      int RefListStartIndex = 5;
 
      if (Version >= 4) {
        RawFunFlags = Record[4];
        RefListStartIndex = 6;
        size_t NumRefsIndex = 5;
        if (Version >= 5) {
          unsigned NumRORefsOffset = 1;
          RefListStartIndex = 7;
          if (Version >= 6) {
            NumRefsIndex = 6;
            RefListStartIndex = 8;
            if (Version >= 7) {
              RefListStartIndex = 9;
              NumWORefs = Record[8];
              NumRORefsOffset = 2;
            }
          }
          NumRORefs = Record[RefListStartIndex - NumRORefsOffset];
        }
        NumRefs = Record[NumRefsIndex];
      }
 
      auto Flags = getDecodedGVSummaryFlags(RawFlags, Version);
      int CallGraphEdgeStartIndex = RefListStartIndex + NumRefs;
      assert(Record.size() >= RefListStartIndex + NumRefs &&
             "Record size inconsistent with number of references");
      SmallVector<ValueInfo, 0> Refs = makeRefList(
          ArrayRef<uint64_t>(Record).slice(RefListStartIndex, NumRefs));
      bool HasProfile = (BitCode == bitc::FS_COMBINED_PROFILE);
      SmallVector<FunctionSummary::EdgeTy, 0> Edges = makeCallList(
          ArrayRef<uint64_t>(Record).slice(CallGraphEdgeStartIndex),
          IsOldProfileFormat, HasProfile, false);
      ValueInfo VI = std::get<0>(getValueInfoFromValueId(ValueID));
      setSpecialRefs(Refs, NumRORefs, NumWORefs);
      auto FS = std::make_unique<FunctionSummary>(
          Flags, InstCount, getDecodedFFlags(RawFunFlags), std::move(Refs),
          std::move(Edges), std::move(PendingTypeTests),
          std::move(PendingTypeTestAssumeVCalls),
          std::move(PendingTypeCheckedLoadVCalls),
          std::move(PendingTypeTestAssumeConstVCalls),
          std::move(PendingTypeCheckedLoadConstVCalls),
          std::move(PendingParamAccesses), std::move(PendingCallsites),
          std::move(PendingAllocs));
      LastSeenSummary = FS.get();
      if (MemProfAfterFunctionSummary)
        CurrentPrevailingFS = FS.get();
      LastSeenGUID = VI.getGUID();
      FS->setModulePath(ModuleIdMap[ModuleId]);
      TheIndex.addGlobalValueSummary(VI, std::move(FS));
      break;
    }
    // FS_COMBINED_ALIAS: [valueid, modid, flags, valueid]
    // Aliases must be emitted (and parsed) after all FS_COMBINED entries, as
    // they expect all aliasee summaries to be available.
    case bitc::FS_COMBINED_ALIAS: {
      unsigned ValueID = Record[0];
      uint64_t ModuleId = Record[1];
      uint64_t RawFlags = Record[2];
      unsigned AliaseeValueId = Record[3];
      auto Flags = getDecodedGVSummaryFlags(RawFlags, Version);
      auto AS = std::make_unique<AliasSummary>(Flags);
      LastSeenSummary = AS.get();
      AS->setModulePath(ModuleIdMap[ModuleId]);
 
      auto AliaseeVI = std::get<0>(
          getValueInfoFromValueId</*AllowNullValueInfo*/ true>(AliaseeValueId));
      if (AliaseeVI) {
        auto AliaseeInModule =
            TheIndex.findSummaryInModule(AliaseeVI, AS->modulePath());
        AS->setAliasee(AliaseeVI, AliaseeInModule);
      }
      ValueInfo VI = std::get<0>(getValueInfoFromValueId(ValueID));
      LastSeenGUID = VI.getGUID();
      TheIndex.addGlobalValueSummary(VI, std::move(AS));
      break;
    }
    // FS_COMBINED_GLOBALVAR_INIT_REFS: [valueid, modid, flags, n x valueid]
    case bitc::FS_COMBINED_GLOBALVAR_INIT_REFS: {
      unsigned ValueID = Record[0];
      uint64_t ModuleId = Record[1];
      uint64_t RawFlags = Record[2];
      unsigned RefArrayStart = 3;
      GlobalVarSummary::GVarFlags GVF(/* ReadOnly */ false,
                                      /* WriteOnly */ false,
                                      /* Constant */ false,
                                      GlobalObject::VCallVisibilityPublic);
      auto Flags = getDecodedGVSummaryFlags(RawFlags, Version);
      if (Version >= 5) {
        GVF = getDecodedGVarFlags(Record[3]);
        RefArrayStart = 4;
      }
      SmallVector<ValueInfo, 0> Refs =
          makeRefList(ArrayRef<uint64_t>(Record).slice(RefArrayStart));
      auto FS =
          std::make_unique<GlobalVarSummary>(Flags, GVF, std::move(Refs));
      LastSeenSummary = FS.get();
      FS->setModulePath(ModuleIdMap[ModuleId]);
      ValueInfo VI = std::get<0>(getValueInfoFromValueId(ValueID));
      LastSeenGUID = VI.getGUID();
      TheIndex.addGlobalValueSummary(VI, std::move(FS));
      break;
    }
    // FS_COMBINED_ORIGINAL_NAME: [original_name]
    case bitc::FS_COMBINED_ORIGINAL_NAME: {
      uint64_t OriginalName = Record[0];
      if (!LastSeenSummary)
        return error("Name attachment that does not follow a combined record");
      LastSeenSummary->setOriginalName(OriginalName);
      TheIndex.addOriginalName(LastSeenGUID, OriginalName);
      // Reset the LastSeenSummary
      LastSeenSummary = nullptr;
      LastSeenGUID = 0;
      break;
    }
    case bitc::FS_TYPE_TESTS:
      assert(PendingTypeTests.empty());
      llvm::append_range(PendingTypeTests, Record);
      break;
 
    case bitc::FS_TYPE_TEST_ASSUME_VCALLS:
      assert(PendingTypeTestAssumeVCalls.empty());
      for (unsigned I = 0; I != Record.size(); I += 2)
        PendingTypeTestAssumeVCalls.push_back({Record[I], Record[I+1]});
      break;
 
    case bitc::FS_TYPE_CHECKED_LOAD_VCALLS:
      assert(PendingTypeCheckedLoadVCalls.empty());
      for (unsigned I = 0; I != Record.size(); I += 2)
        PendingTypeCheckedLoadVCalls.push_back({Record[I], Record[I+1]});
      break;
 
    case bitc::FS_TYPE_TEST_ASSUME_CONST_VCALL:
      PendingTypeTestAssumeConstVCalls.push_back(
          {{Record[0], Record[1]}, {Record.begin() + 2, Record.end()}});
      break;
 
    case bitc::FS_TYPE_CHECKED_LOAD_CONST_VCALL:
      PendingTypeCheckedLoadConstVCalls.push_back(
          {{Record[0], Record[1]}, {Record.begin() + 2, Record.end()}});
      break;
 
    case bitc::FS_CFI_FUNCTION_DEFS: {
      auto &CfiFunctionDefs = TheIndex.cfiFunctionDefs();
      for (unsigned I = 0; I != Record.size(); I += 2)
        CfiFunctionDefs.emplace(Strtab.data() + Record[I],
                                static_cast<size_t>(Record[I + 1]));
      break;
    }
 
    case bitc::FS_CFI_FUNCTION_DECLS: {
      auto &CfiFunctionDecls = TheIndex.cfiFunctionDecls();
      for (unsigned I = 0; I != Record.size(); I += 2)
        CfiFunctionDecls.emplace(Strtab.data() + Record[I],
                                 static_cast<size_t>(Record[I + 1]));
      break;
    }
 
    case bitc::FS_TYPE_ID:
      parseTypeIdSummaryRecord(Record, Strtab, TheIndex);
      break;
 
    case bitc::FS_TYPE_ID_METADATA:
      parseTypeIdCompatibleVtableSummaryRecord(Record);
      break;
 
    case bitc::FS_BLOCK_COUNT:
      TheIndex.addBlockCount(Record[0]);
      break;
 
    case bitc::FS_PARAM_ACCESS: {
      PendingParamAccesses = parseParamAccesses(Record);
      break;
    }
 
    case bitc::FS_STACK_IDS: { // [n x stackid]
      // Save stack ids in the reader to consult when adding stack ids from the
      // lists in the stack node and alloc node entries.
      assert(StackIds.empty());
      if (Version <= 11) {
        StackIds = ArrayRef<uint64_t>(Record);
      } else {
        // This is an array of 32-bit fixed-width values, holding each 64-bit
        // context id as a pair of adjacent (most significant first) 32-bit
        // words.
        assert(Record.size() % 2 == 0);
        StackIds.reserve(Record.size() / 2);
        for (auto R = Record.begin(); R != Record.end(); R += 2)
          StackIds.push_back(*R << 32 | *(R + 1));
      }
      assert(StackIdToIndex.empty());
      // Initialize with a marker to support lazy population.
      StackIdToIndex.resize(StackIds.size(), UninitializedStackIdIndex);
      break;
    }
 
    case bitc::FS_CONTEXT_RADIX_TREE_ARRAY: { // [n x entry]
      RadixArray = ArrayRef<uint64_t>(Record);
      break;
    }
 
    case bitc::FS_PERMODULE_CALLSITE_INFO: {
      // If they are in the new order (following), they are skipped when they
      // follow a non-prevailing summary (CurrentPrevailingFS will be null).
      if (MemProfAfterFunctionSummary && !CurrentPrevailingFS)
        break;
      unsigned ValueID = Record[0];
      SmallVector<unsigned> StackIdList;
      for (uint64_t R : drop_begin(Record)) {
        assert(R < StackIds.size());
        StackIdList.push_back(getStackIdIndex(R));
      }
      ValueInfo VI = std::get<0>(getValueInfoFromValueId(ValueID));
      if (MemProfAfterFunctionSummary)
        CurrentPrevailingFS->addCallsite(
            CallsiteInfo({VI, std::move(StackIdList)}));
      else
        PendingCallsites.push_back(CallsiteInfo({VI, std::move(StackIdList)}));
      break;
    }
 
    case bitc::FS_COMBINED_CALLSITE_INFO: {
      // In the combined index case we don't have a prevailing check,
      // so we should always have a CurrentPrevailingFS.
      assert(!MemProfAfterFunctionSummary || CurrentPrevailingFS);
      auto RecordIter = Record.begin();
      unsigned ValueID = *RecordIter++;
      unsigned NumStackIds = *RecordIter++;
      unsigned NumVersions = *RecordIter++;
      assert(Record.size() == 3 + NumStackIds + NumVersions);
      SmallVector<unsigned> StackIdList;
      for (unsigned J = 0; J < NumStackIds; J++) {
        assert(*RecordIter < StackIds.size());
        StackIdList.push_back(getStackIdIndex(*RecordIter++));
      }
      SmallVector<unsigned> Versions;
      for (unsigned J = 0; J < NumVersions; J++)
        Versions.push_back(*RecordIter++);
      ValueInfo VI = std::get<0>(
          getValueInfoFromValueId</*AllowNullValueInfo*/ true>(ValueID));
      if (MemProfAfterFunctionSummary)
        CurrentPrevailingFS->addCallsite(
            CallsiteInfo({VI, std::move(Versions), std::move(StackIdList)}));
      else
        PendingCallsites.push_back(
            CallsiteInfo({VI, std::move(Versions), std::move(StackIdList)}));
      break;
    }
 
    case bitc::FS_ALLOC_CONTEXT_IDS: {
      // If they are in the new order (following), they are skipped when they
      // follow a non-prevailing summary (CurrentPrevailingFS will be null).
      if (MemProfAfterFunctionSummary && !CurrentPrevailingFS)
        break;
      // This is an array of 32-bit fixed-width values, holding each 64-bit
      // context id as a pair of adjacent (most significant first) 32-bit words.
      assert(Record.size() % 2 == 0);
      PendingContextIds.reserve(Record.size() / 2);
      for (auto R = Record.begin(); R != Record.end(); R += 2)
        PendingContextIds.push_back(*R << 32 | *(R + 1));
      break;
    }
 
    case bitc::FS_PERMODULE_ALLOC_INFO: {
      // If they are in the new order (following), they are skipped when they
      // follow a non-prevailing summary (CurrentPrevailingFS will be null).
      if (MemProfAfterFunctionSummary && !CurrentPrevailingFS) {
        PendingContextIds.clear();
        break;
      }
      unsigned I = 0;
      std::vector<MIBInfo> MIBs;
      unsigned NumMIBs = 0;
      if (Version >= 10)
        NumMIBs = Record[I++];
      unsigned MIBsRead = 0;
      while ((Version >= 10 && MIBsRead++ < NumMIBs) ||
             (Version < 10 && I < Record.size())) {
        assert(Record.size() - I >= 2);
        AllocationType AllocType = (AllocationType)Record[I++];
        auto StackIdList = parseAllocInfoContext(Record, I);
        MIBs.push_back(MIBInfo(AllocType, std::move(StackIdList)));
      }
      // We either have nothing left or at least NumMIBs context size info
      // indices left (for the total sizes included when reporting of hinted
      // bytes is enabled).
      assert(I == Record.size() || Record.size() - I >= NumMIBs);
      std::vector<std::vector<ContextTotalSize>> AllContextSizes;
      if (I < Record.size()) {
        assert(!PendingContextIds.empty() &&
               "Missing context ids for alloc sizes");
        unsigned ContextIdIndex = 0;
        MIBsRead = 0;
        // The sizes are a linearized array of sizes, where for each MIB there
        // is 1 or more sizes (due to context trimming, each MIB in the metadata
        // and summarized here can correspond to more than one original context
        // from the profile).
        while (MIBsRead++ < NumMIBs) {
          // First read the number of contexts recorded for this MIB.
          unsigned NumContextSizeInfoEntries = Record[I++];
          assert(Record.size() - I >= NumContextSizeInfoEntries);
          std::vector<ContextTotalSize> ContextSizes;
          ContextSizes.reserve(NumContextSizeInfoEntries);
          for (unsigned J = 0; J < NumContextSizeInfoEntries; J++) {
            assert(ContextIdIndex < PendingContextIds.size());
            // Skip any 0 entries for MIBs without the context size info.
            if (PendingContextIds[ContextIdIndex] == 0) {
              // The size should also be 0 if the context was 0.
              assert(!Record[I]);
              ContextIdIndex++;
              I++;
              continue;
            }
            // PendingContextIds read from the preceding FS_ALLOC_CONTEXT_IDS
            // should be in the same order as the total sizes.
            ContextSizes.push_back(
                {PendingContextIds[ContextIdIndex++], Record[I++]});
          }
          AllContextSizes.push_back(std::move(ContextSizes));
        }
        PendingContextIds.clear();
      }
      AllocInfo AI(std::move(MIBs));
      if (!AllContextSizes.empty()) {
        assert(AI.MIBs.size() == AllContextSizes.size());
        AI.ContextSizeInfos = std::move(AllContextSizes);
      }
 
      if (MemProfAfterFunctionSummary)
        CurrentPrevailingFS->addAlloc(std::move(AI));
      else
        PendingAllocs.push_back(std::move(AI));
      break;
    }
 
    case bitc::FS_COMBINED_ALLOC_INFO:
    case bitc::FS_COMBINED_ALLOC_INFO_NO_CONTEXT: {
      // In the combined index case we don't have a prevailing check,
      // so we should always have a CurrentPrevailingFS.
      assert(!MemProfAfterFunctionSummary || CurrentPrevailingFS);
      unsigned I = 0;
      std::vector<MIBInfo> MIBs;
      unsigned NumMIBs = Record[I++];
      unsigned NumVersions = Record[I++];
      unsigned MIBsRead = 0;
      while (MIBsRead++ < NumMIBs) {
        assert(Record.size() - I >= 2);
        AllocationType AllocType = (AllocationType)Record[I++];
        SmallVector<unsigned> StackIdList;
        if (BitCode == bitc::FS_COMBINED_ALLOC_INFO)
          StackIdList = parseAllocInfoContext(Record, I);
        MIBs.push_back(MIBInfo(AllocType, std::move(StackIdList)));
      }
      assert(Record.size() - I >= NumVersions);
      SmallVector<uint8_t> Versions;
      for (unsigned J = 0; J < NumVersions; J++)
        Versions.push_back(Record[I++]);
      assert(I == Record.size());
      AllocInfo AI(std::move(Versions), std::move(MIBs));
      if (MemProfAfterFunctionSummary)
        CurrentPrevailingFS->addAlloc(std::move(AI));
      else
        PendingAllocs.push_back(std::move(AI));
      break;
    }
    }
  }
  llvm_unreachable("Exit infinite loop");
}
 
// Parse the  module string table block into the Index.
// This populates the ModulePathStringTable map in the index.
Error ModuleSummaryIndexBitcodeReader::parseModuleStringTable() {
  if (Error Err = Stream.EnterSubBlock(bitc::MODULE_STRTAB_BLOCK_ID))
    return Err;
 
  SmallVector<uint64_t, 64> Record;
 
  SmallString<128> ModulePath;
  ModuleSummaryIndex::ModuleInfo *LastSeenModule = nullptr;
 
  while (true) {
    Expected<BitstreamEntry> MaybeEntry = Stream.advanceSkippingSubblocks();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    BitstreamEntry Entry = MaybeEntry.get();
 
    switch (Entry.Kind) {
    case BitstreamEntry::SubBlock: // Handled for us already.
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock:
      return Error::success();
    case BitstreamEntry::Record:
      // The interesting case.
      break;
    }
 
    Record.clear();
    Expected<unsigned> MaybeRecord = Stream.readRecord(Entry.ID, Record);
    if (!MaybeRecord)
      return MaybeRecord.takeError();
    switch (MaybeRecord.get()) {
    default: // Default behavior: ignore.
      break;
    case bitc::MST_CODE_ENTRY: {
      // MST_ENTRY: [modid, namechar x N]
      uint64_t ModuleId = Record[0];
 
      if (convertToString(Record, 1, ModulePath))
        return error("Invalid code_entry record");
 
      LastSeenModule = TheIndex.addModule(ModulePath);
      ModuleIdMap[ModuleId] = LastSeenModule->first();
 
      ModulePath.clear();
      break;
    }
    /// MST_CODE_HASH: [5*i32]
    case bitc::MST_CODE_HASH: {
      if (Record.size() != 5)
        return error("Invalid hash length " + Twine(Record.size()).str());
      if (!LastSeenModule)
        return error("Invalid hash that does not follow a module path");
      int Pos = 0;
      for (auto &Val : Record) {
        assert(!(Val >> 32) && "Unexpected high bits set");
        LastSeenModule->second[Pos++] = Val;
      }
      // Reset LastSeenModule to avoid overriding the hash unexpectedly.
      LastSeenModule = nullptr;
      break;
    }
    }
  }
  llvm_unreachable("Exit infinite loop");
}
 
namespace {
 
// FIXME: This class is only here to support the transition to llvm::Error. It
// will be removed once this transition is complete. Clients should prefer to
// deal with the Error value directly, rather than converting to error_code.
class BitcodeErrorCategoryType : public std::error_category {
  const char *name() const noexcept override {
    return "llvm.bitcode";
  }
 
  std::string message(int IE) const override {
    BitcodeError E = static_cast<BitcodeError>(IE);
    switch (E) {
    case BitcodeError::CorruptedBitcode:
      return "Corrupted bitcode";
    }
    llvm_unreachable("Unknown error type!");
  }
};
 
} // end anonymous namespace
 
const std::error_category &llvm::BitcodeErrorCategory() {
  static BitcodeErrorCategoryType ErrorCategory;
  return ErrorCategory;
}
 
static Expected<StringRef> readBlobInRecord(BitstreamCursor &Stream,
                                            unsigned Block, unsigned RecordID) {
  if (Error Err = Stream.EnterSubBlock(Block))
    return std::move(Err);
 
  StringRef Strtab;
  while (true) {
    Expected<llvm::BitstreamEntry> MaybeEntry = Stream.advance();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    llvm::BitstreamEntry Entry = MaybeEntry.get();
 
    switch (Entry.Kind) {
    case BitstreamEntry::EndBlock:
      return Strtab;
 
    case BitstreamEntry::Error:
      return error("Malformed block");
 
    case BitstreamEntry::SubBlock:
      if (Error Err = Stream.SkipBlock())
        return std::move(Err);
      break;
 
    case BitstreamEntry::Record:
      StringRef Blob;
      SmallVector<uint64_t, 1> Record;
      Expected<unsigned> MaybeRecord =
          Stream.readRecord(Entry.ID, Record, &Blob);
      if (!MaybeRecord)
        return MaybeRecord.takeError();
      if (MaybeRecord.get() == RecordID)
        Strtab = Blob;
      break;
    }
  }
}
 
//===----------------------------------------------------------------------===//
// External interface
//===----------------------------------------------------------------------===//
 
Expected<std::vector<BitcodeModule>>
llvm::getBitcodeModuleList(MemoryBufferRef Buffer) {
  auto FOrErr = getBitcodeFileContents(Buffer);
  if (!FOrErr)
    return FOrErr.takeError();
  return std::move(FOrErr->Mods);
}
 
Expected<BitcodeFileContents>
llvm::getBitcodeFileContents(MemoryBufferRef Buffer) {
  Expected<BitstreamCursor> StreamOrErr = initStream(Buffer);
  if (!StreamOrErr)
    return StreamOrErr.takeError();
  BitstreamCursor &Stream = *StreamOrErr;
 
  BitcodeFileContents F;
  while (true) {
    uint64_t BCBegin = Stream.getCurrentByteNo();
 
    // We may be consuming bitcode from a client that leaves garbage at the end
    // of the bitcode stream (e.g. Apple's ar tool). If we are close enough to
    // the end that there cannot possibly be another module, stop looking.
    if (BCBegin + 8 >= Stream.getBitcodeBytes().size())
      return F;
 
    Expected<llvm::BitstreamEntry> MaybeEntry = Stream.advance();
    if (!MaybeEntry)
      return MaybeEntry.takeError();
    llvm::BitstreamEntry Entry = MaybeEntry.get();
 
    switch (Entry.Kind) {
    case BitstreamEntry::EndBlock:
    case BitstreamEntry::Error:
      return error("Malformed block");
 
    case BitstreamEntry::SubBlock: {
      uint64_t IdentificationBit = -1ull;
      if (Entry.ID == bitc::IDENTIFICATION_BLOCK_ID) {
        IdentificationBit = Stream.GetCurrentBitNo() - BCBegin * 8;
        if (Error Err = Stream.SkipBlock())
          return std::move(Err);
 
        {
          Expected<llvm::BitstreamEntry> MaybeEntry = Stream.advance();
          if (!MaybeEntry)
            return MaybeEntry.takeError();
          Entry = MaybeEntry.get();
        }
 
        if (Entry.Kind != BitstreamEntry::SubBlock ||
            Entry.ID != bitc::MODULE_BLOCK_ID)
          return error("Malformed block");
      }
 
      if (Entry.ID == bitc::MODULE_BLOCK_ID) {
        uint64_t ModuleBit = Stream.GetCurrentBitNo() - BCBegin * 8;
        if (Error Err = Stream.SkipBlock())
          return std::move(Err);
 
        F.Mods.push_back({Stream.getBitcodeBytes().slice(
                              BCBegin, Stream.getCurrentByteNo() - BCBegin),
                          Buffer.getBufferIdentifier(), IdentificationBit,
                          ModuleBit});
        continue;
      }
 
      if (Entry.ID == bitc::STRTAB_BLOCK_ID) {
        Expected<StringRef> Strtab =
            readBlobInRecord(Stream, bitc::STRTAB_BLOCK_ID, bitc::STRTAB_BLOB);
        if (!Strtab)
          return Strtab.takeError();
        // This string table is used by every preceding bitcode module that does
        // not have its own string table. A bitcode file may have multiple
        // string tables if it was created by binary concatenation, for example
        // with "llvm-cat -b".
        for (BitcodeModule &I : llvm::reverse(F.Mods)) {
          if (!I.Strtab.empty())
            break;
          I.Strtab = *Strtab;
        }
        // Similarly, the string table is used by every preceding symbol table;
        // normally there will be just one unless the bitcode file was created
        // by binary concatenation.
        if (!F.Symtab.empty() && F.StrtabForSymtab.empty())
          F.StrtabForSymtab = *Strtab;
        continue;
      }
 
      if (Entry.ID == bitc::SYMTAB_BLOCK_ID) {
        Expected<StringRef> SymtabOrErr =
            readBlobInRecord(Stream, bitc::SYMTAB_BLOCK_ID, bitc::SYMTAB_BLOB);
        if (!SymtabOrErr)
          return SymtabOrErr.takeError();
 
        // We can expect the bitcode file to have multiple symbol tables if it
        // was created by binary concatenation. In that case we silently
        // ignore any subsequent symbol tables, which is fine because this is a
        // low level function. The client is expected to notice that the number
        // of modules in the symbol table does not match the number of modules
        // in the input file and regenerate the symbol table.
        if (F.Symtab.empty())
          F.Symtab = *SymtabOrErr;
        continue;
      }
 
      if (Error Err = Stream.SkipBlock())
        return std::move(Err);
      continue;
    }
    case BitstreamEntry::Record:
      if (Error E = Stream.skipRecord(Entry.ID).takeError())
        return std::move(E);
      continue;
    }
  }
}
 
/// Get a lazy one-at-time loading module from bitcode.
///
/// This isn't always used in a lazy context.  In particular, it's also used by
/// \a parseModule().  If this is truly lazy, then we need to eagerly pull
/// in forward-referenced functions from block address references.
///
/// \param[in] MaterializeAll Set to \c true if we should materialize
/// everything.
Expected<std::unique_ptr<Module>>
BitcodeModule::getModuleImpl(LLVMContext &Context, bool MaterializeAll,
                             bool ShouldLazyLoadMetadata, bool IsImporting,
                             ParserCallbacks Callbacks) {
  BitstreamCursor Stream(Buffer);
 
  std::string ProducerIdentification;
  if (IdentificationBit != -1ull) {
    if (Error JumpFailed = Stream.JumpToBit(IdentificationBit))
      return std::move(JumpFailed);
    if (Error E =
            readIdentificationBlock(Stream).moveInto(ProducerIdentification))
      return std::move(E);
  }
 
  if (Error JumpFailed = Stream.JumpToBit(ModuleBit))
    return std::move(JumpFailed);
  auto *R = new BitcodeReader(std::move(Stream), Strtab, ProducerIdentification,
                              Context);
 
  std::unique_ptr<Module> M =
      std::make_unique<Module>(ModuleIdentifier, Context);
  M->setMaterializer(R);
 
  // Delay parsing Metadata if ShouldLazyLoadMetadata is true.
  if (Error Err = R->parseBitcodeInto(M.get(), ShouldLazyLoadMetadata,
                                      IsImporting, Callbacks))
    return std::move(Err);
 
  if (MaterializeAll) {
    // Read in the entire module, and destroy the BitcodeReader.
    if (Error Err = M->materializeAll())
      return std::move(Err);
  } else {
    // Resolve forward references from blockaddresses.
    if (Error Err = R->materializeForwardReferencedFunctions())
      return std::move(Err);
  }
 
  return std::move(M);
}
 
Expected<std::unique_ptr<Module>>
BitcodeModule::getLazyModule(LLVMContext &Context, bool ShouldLazyLoadMetadata,
                             bool IsImporting, ParserCallbacks Callbacks) {
  return getModuleImpl(Context, false, ShouldLazyLoadMetadata, IsImporting,
                       Callbacks);
}
 
// Parse the specified bitcode buffer and merge the index into CombinedIndex.
// We don't use ModuleIdentifier here because the client may need to control the
// module path used in the combined summary (e.g. when reading summaries for
// regular LTO modules).
Error BitcodeModule::readSummary(
    ModuleSummaryIndex &CombinedIndex, StringRef ModulePath,
    std::function<bool(GlobalValue::GUID)> IsPrevailing) {
  BitstreamCursor Stream(Buffer);
  if (Error JumpFailed = Stream.JumpToBit(ModuleBit))
    return JumpFailed;
 
  ModuleSummaryIndexBitcodeReader R(std::move(Stream), Strtab, CombinedIndex,
                                    ModulePath, IsPrevailing);
  return R.parseModule();
}
 
// Parse the specified bitcode buffer, returning the function info index.
Expected<std::unique_ptr<ModuleSummaryIndex>> BitcodeModule::getSummary() {
  BitstreamCursor Stream(Buffer);
  if (Error JumpFailed = Stream.JumpToBit(ModuleBit))
    return std::move(JumpFailed);
 
  auto Index = std::make_unique<ModuleSummaryIndex>(/*HaveGVs=*/false);
  ModuleSummaryIndexBitcodeReader R(std::move(Stream), Strtab, *Index,
                                    ModuleIdentifier, 0);
 
  if (Error Err = R.parseModule())
    return std::move(Err);
 
  return std::move(Index);
}
 
static Expected<std::pair<bool, bool>>
getEnableSplitLTOUnitAndUnifiedFlag(BitstreamCursor &Stream, unsigned ID) {
  if (Error Err = Stream.EnterSubBlock(ID))
    return std::move(Err);
 
  SmallVector<uint64_t, 64> Record;
  while (true) {
    BitstreamEntry Entry;
    if (Error E = Stream.advanceSkippingSubblocks().moveInto(Entry))
      return std::move(E);
 
    switch (Entry.Kind) {
    case BitstreamEntry::SubBlock: // Handled for us already.
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock: {
      // If no flags record found, return both flags as false.
      return std::make_pair(false, false);
    }
    case BitstreamEntry::Record:
      // The interesting case.
      break;
    }
 
    // Look for the FS_FLAGS record.
    Record.clear();
    Expected<unsigned> MaybeBitCode = Stream.readRecord(Entry.ID, Record);
    if (!MaybeBitCode)
      return MaybeBitCode.takeError();
    switch (MaybeBitCode.get()) {
    default: // Default behavior: ignore.
      break;
    case bitc::FS_FLAGS: { // [flags]
      uint64_t Flags = Record[0];
      // Scan flags.
      assert(Flags <= 0x7ff && "Unexpected bits in flag");
 
      bool EnableSplitLTOUnit = Flags & 0x8;
      bool UnifiedLTO = Flags & 0x200;
      return std::make_pair(EnableSplitLTOUnit, UnifiedLTO);
    }
    }
  }
  llvm_unreachable("Exit infinite loop");
}
 
// Check if the given bitcode buffer contains a global value summary block.
Expected<BitcodeLTOInfo> BitcodeModule::getLTOInfo() {
  BitstreamCursor Stream(Buffer);
  if (Error JumpFailed = Stream.JumpToBit(ModuleBit))
    return std::move(JumpFailed);
 
  if (Error Err = Stream.EnterSubBlock(bitc::MODULE_BLOCK_ID))
    return std::move(Err);
 
  while (true) {
    llvm::BitstreamEntry Entry;
    if (Error E = Stream.advance().moveInto(Entry))
      return std::move(E);
 
    switch (Entry.Kind) {
    case BitstreamEntry::Error:
      return error("Malformed block");
    case BitstreamEntry::EndBlock:
      return BitcodeLTOInfo{/*IsThinLTO=*/false, /*HasSummary=*/false,
                            /*EnableSplitLTOUnit=*/false, /*UnifiedLTO=*/false};
 
    case BitstreamEntry::SubBlock:
      if (Entry.ID == bitc::GLOBALVAL_SUMMARY_BLOCK_ID ||
          Entry.ID == bitc::FULL_LTO_GLOBALVAL_SUMMARY_BLOCK_ID) {
        Expected<std::pair<bool, bool>> Flags =
            getEnableSplitLTOUnitAndUnifiedFlag(Stream, Entry.ID);
        if (!Flags)
          return Flags.takeError();
        BitcodeLTOInfo LTOInfo;
        std::tie(LTOInfo.EnableSplitLTOUnit, LTOInfo.UnifiedLTO) = Flags.get();
        LTOInfo.IsThinLTO = (Entry.ID == bitc::GLOBALVAL_SUMMARY_BLOCK_ID);
        LTOInfo.HasSummary = true;
        return LTOInfo;
      }
 
      // Ignore other sub-blocks.
      if (Error Err = Stream.SkipBlock())
        return std::move(Err);
      continue;
 
    case BitstreamEntry::Record:
      if (Expected<unsigned> StreamFailed = Stream.skipRecord(Entry.ID))
        continue;
      else
        return StreamFailed.takeError();
    }
  }
}
 
static Expected<BitcodeModule> getSingleModule(MemoryBufferRef Buffer) {
  Expected<std::vector<BitcodeModule>> MsOrErr = getBitcodeModuleList(Buffer);
  if (!MsOrErr)
    return MsOrErr.takeError();
 
  if (MsOrErr->size() != 1)
    return error("Expected a single module");
 
  return (*MsOrErr)[0];
}
 
Expected<std::unique_ptr<Module>>
llvm::getLazyBitcodeModule(MemoryBufferRef Buffer, LLVMContext &Context,
                           bool ShouldLazyLoadMetadata, bool IsImporting,
                           ParserCallbacks Callbacks) {
  Expected<BitcodeModule> BM = getSingleModule(Buffer);
  if (!BM)
    return BM.takeError();
 
  return BM->getLazyModule(Context, ShouldLazyLoadMetadata, IsImporting,
                           Callbacks);
}
 
Expected<std::unique_ptr<Module>> llvm::getOwningLazyBitcodeModule(
    std::unique_ptr<MemoryBuffer> &&Buffer, LLVMContext &Context,
    bool ShouldLazyLoadMetadata, bool IsImporting, ParserCallbacks Callbacks) {
  auto MOrErr = getLazyBitcodeModule(*Buffer, Context, ShouldLazyLoadMetadata,
                                     IsImporting, Callbacks);
  if (MOrErr)
    (*MOrErr)->setOwnedMemoryBuffer(std::move(Buffer));
  return MOrErr;
}
 
Expected<std::unique_ptr<Module>>
BitcodeModule::parseModule(LLVMContext &Context, ParserCallbacks Callbacks) {
  return getModuleImpl(Context, true, false, false, Callbacks);
  // TODO: Restore the use-lists to the in-memory state when the bitcode was
  // written.  We must defer until the Module has been fully materialized.
}
 
Expected<std::unique_ptr<Module>>
llvm::parseBitcodeFile(MemoryBufferRef Buffer, LLVMContext &Context,
                       ParserCallbacks Callbacks) {
  Expected<BitcodeModule> BM = getSingleModule(Buffer);
  if (!BM)
    return BM.takeError();
 
  return BM->parseModule(Context, Callbacks);
}
 
Expected<std::string> llvm::getBitcodeTargetTriple(MemoryBufferRef Buffer) {
  Expected<BitstreamCursor> StreamOrErr = initStream(Buffer);
  if (!StreamOrErr)
    return StreamOrErr.takeError();
 
  return readTriple(*StreamOrErr);
}
 
Expected<bool> llvm::isBitcodeContainingObjCCategory(MemoryBufferRef Buffer) {
  Expected<BitstreamCursor> StreamOrErr = initStream(Buffer);
  if (!StreamOrErr)
    return StreamOrErr.takeError();
 
  return hasObjCCategory(*StreamOrErr);
}
 
Expected<std::string> llvm::getBitcodeProducerString(MemoryBufferRef Buffer) {
  Expected<BitstreamCursor> StreamOrErr = initStream(Buffer);
  if (!StreamOrErr)
    return StreamOrErr.takeError();
 
  return readIdentificationCode(*StreamOrErr);
}
 
Error llvm::readModuleSummaryIndex(MemoryBufferRef Buffer,
                                   ModuleSummaryIndex &CombinedIndex) {
  Expected<BitcodeModule> BM = getSingleModule(Buffer);
  if (!BM)
    return BM.takeError();
 
  return BM->readSummary(CombinedIndex, BM->getModuleIdentifier());
}
 
Expected<std::unique_ptr<ModuleSummaryIndex>>
llvm::getModuleSummaryIndex(MemoryBufferRef Buffer) {
  Expected<BitcodeModule> BM = getSingleModule(Buffer);
  if (!BM)
    return BM.takeError();
 
  return BM->getSummary();
}
 
Expected<BitcodeLTOInfo> llvm::getBitcodeLTOInfo(MemoryBufferRef Buffer) {
  Expected<BitcodeModule> BM = getSingleModule(Buffer);
  if (!BM)
    return BM.takeError();
 
  return BM->getLTOInfo();
}
 
Expected<std::unique_ptr<ModuleSummaryIndex>>
llvm::getModuleSummaryIndexForFile(StringRef Path,
                                   bool IgnoreEmptyThinLTOIndexFile) {
  ErrorOr<std::unique_ptr<MemoryBuffer>> FileOrErr =
      MemoryBuffer::getFileOrSTDIN(Path);
  if (!FileOrErr)
    return errorCodeToError(FileOrErr.getError());
  if (IgnoreEmptyThinLTOIndexFile && !(*FileOrErr)->getBufferSize())
    return nullptr;
  return getModuleSummaryIndex(**FileOrErr);
}