Type.cpp

Go to the documentation of this file.

//===- Type.cpp - Type representation and manipulation --------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
//  This file implements type-related functionality.
//
//===----------------------------------------------------------------------===//
 
#include "clang/AST/Type.h"
#include "Linkage.h"
#include "clang/AST/ASTContext.h"
#include "clang/AST/Attr.h"
#include "clang/AST/CharUnits.h"
#include "clang/AST/Decl.h"
#include "clang/AST/DeclBase.h"
#include "clang/AST/DeclCXX.h"
#include "clang/AST/DeclFriend.h"
#include "clang/AST/DeclObjC.h"
#include "clang/AST/DeclTemplate.h"
#include "clang/AST/DependenceFlags.h"
#include "clang/AST/Expr.h"
#include "clang/AST/NestedNameSpecifier.h"
#include "clang/AST/PrettyPrinter.h"
#include "clang/AST/TemplateBase.h"
#include "clang/AST/TemplateName.h"
#include "clang/AST/TypeVisitor.h"
#include "clang/Basic/AddressSpaces.h"
#include "clang/Basic/ExceptionSpecificationType.h"
#include "clang/Basic/IdentifierTable.h"
#include "clang/Basic/LLVM.h"
#include "clang/Basic/LangOptions.h"
#include "clang/Basic/Linkage.h"
#include "clang/Basic/Specifiers.h"
#include "clang/Basic/TargetCXXABI.h"
#include "clang/Basic/TargetInfo.h"
#include "clang/Basic/Visibility.h"
#include "llvm/ADT/APInt.h"
#include "llvm/ADT/APSInt.h"
#include "llvm/ADT/ArrayRef.h"
#include "llvm/ADT/FoldingSet.h"
#include "llvm/ADT/STLExtras.h"
#include "llvm/ADT/SmallVector.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/Support/MathExtras.h"
#include <algorithm>
#include <cassert>
#include <cstdint>
#include <cstring>
#include <optional>
 
using namespace clang;
 
bool Qualifiers::isStrictSupersetOf(Qualifiers Other) const {
  return (*this != Other) &&
         // CVR qualifiers superset
         (((Mask & CVRMask) | (Other.Mask & CVRMask)) == (Mask & CVRMask)) &&
         // ObjC GC qualifiers superset
         ((getObjCGCAttr() == Other.getObjCGCAttr()) ||
          (hasObjCGCAttr() && !Other.hasObjCGCAttr())) &&
         // Address space superset.
         ((getAddressSpace() == Other.getAddressSpace()) ||
          (hasAddressSpace() && !Other.hasAddressSpace())) &&
         // Lifetime qualifier superset.
         ((getObjCLifetime() == Other.getObjCLifetime()) ||
          (hasObjCLifetime() && !Other.hasObjCLifetime()));
}
 
bool Qualifiers::isTargetAddressSpaceSupersetOf(LangAS A, LangAS B,
                                                const ASTContext &Ctx) {
  // In OpenCLC v2.0 s6.5.5: every address space except for __constant can be
  // used as __generic.
  return (A == LangAS::opencl_generic && B != LangAS::opencl_constant) ||
         // We also define global_device and global_host address spaces,
         // to distinguish global pointers allocated on host from pointers
         // allocated on device, which are a subset of __global.
         (A == LangAS::opencl_global && (B == LangAS::opencl_global_device ||
                                         B == LangAS::opencl_global_host)) ||
         (A == LangAS::sycl_global &&
          (B == LangAS::sycl_global_device || B == LangAS::sycl_global_host)) ||
         // Consider pointer size address spaces to be equivalent to default.
         ((isPtrSizeAddressSpace(A) || A == LangAS::Default) &&
          (isPtrSizeAddressSpace(B) || B == LangAS::Default)) ||
         // Default is a superset of SYCL address spaces.
         (A == LangAS::Default &&
          (B == LangAS::sycl_private || B == LangAS::sycl_local ||
           B == LangAS::sycl_global || B == LangAS::sycl_global_device ||
           B == LangAS::sycl_global_host)) ||
         // In HIP device compilation, any cuda address space is allowed
         // to implicitly cast into the default address space.
         (A == LangAS::Default &&
          (B == LangAS::cuda_constant || B == LangAS::cuda_device ||
           B == LangAS::cuda_shared)) ||
         // In HLSL, the this pointer for member functions points to the default
         // address space. This causes a problem if the structure is in
         // a different address space. We want to allow casting from these
         // address spaces to default to work around this problem.
         (A == LangAS::Default && B == LangAS::hlsl_private) ||
         (A == LangAS::Default && B == LangAS::hlsl_device) ||
         (A == LangAS::Default && B == LangAS::hlsl_input) ||
         (A == LangAS::Default && B == LangAS::hlsl_output) ||
         (A == LangAS::Default && B == LangAS::hlsl_push_constant) ||
         // Conversions from target specific address spaces may be legal
         // depending on the target information.
         Ctx.getTargetInfo().isAddressSpaceSupersetOf(A, B);
}
 
const IdentifierInfo *QualType::getBaseTypeIdentifier() const {
  const Type *ty = getTypePtr();
  NamedDecl *ND = nullptr;
  if (const auto *DNT = ty->getAs<DependentNameType>())
    return DNT->getIdentifier();
  if (ty->isPointerOrReferenceType())
    return ty->getPointeeType().getBaseTypeIdentifier();
  if (const auto *TT = ty->getAs<TagType>())
    ND = TT->getDecl();
  else if (ty->getTypeClass() == Type::Typedef)
    ND = ty->castAs<TypedefType>()->getDecl();
  else if (ty->isArrayType())
    return ty->castAsArrayTypeUnsafe()
        ->getElementType()
        .getBaseTypeIdentifier();
 
  if (ND)
    return ND->getIdentifier();
  return nullptr;
}
 
bool QualType::hasPostfixDeclaratorSyntax() const {
  QualType QT = *this;
  while (true) {
    const Type *T = QT.getTypePtr();
    switch (T->getTypeClass()) {
    default:
      return false;
    case Type::Pointer:
      QT = cast<PointerType>(T)->getPointeeType();
      break;
    case Type::BlockPointer:
      QT = cast<BlockPointerType>(T)->getPointeeType();
      break;
    case Type::MemberPointer:
      QT = cast<MemberPointerType>(T)->getPointeeType();
      break;
    case Type::LValueReference:
    case Type::RValueReference:
      QT = cast<ReferenceType>(T)->getPointeeType();
      break;
    case Type::PackExpansion:
      QT = cast<PackExpansionType>(T)->getPattern();
      break;
    case Type::Paren:
    case Type::ConstantArray:
    case Type::DependentSizedArray:
    case Type::IncompleteArray:
    case Type::VariableArray:
    case Type::FunctionProto:
    case Type::FunctionNoProto:
      return true;
    }
  }
}
 
bool QualType::mayBeDynamicClass() const {
  const auto *ClassDecl = getTypePtr()->getPointeeCXXRecordDecl();
  return ClassDecl && ClassDecl->mayBeDynamicClass();
}
 
bool QualType::mayBeNotDynamicClass() const {
  const auto *ClassDecl = getTypePtr()->getPointeeCXXRecordDecl();
  return !ClassDecl || ClassDecl->mayBeNonDynamicClass();
}
 
bool QualType::isConstant(QualType T, const ASTContext &Ctx) {
  if (T.isConstQualified())
    return true;
 
  if (const ArrayType *AT = Ctx.getAsArrayType(T))
    return AT->getElementType().isConstant(Ctx);
 
  return T.getAddressSpace() == LangAS::opencl_constant;
}
 
std::optional<QualType::NonConstantStorageReason>
QualType::isNonConstantStorage(const ASTContext &Ctx, bool ExcludeCtor,
                               bool ExcludeDtor) {
  if (!isConstant(Ctx) && !(*this)->isReferenceType())
    return NonConstantStorageReason::NonConstNonReferenceType;
  if (!Ctx.getLangOpts().CPlusPlus)
    return std::nullopt;
  if (const CXXRecordDecl *Record =
          Ctx.getBaseElementType(*this)->getAsCXXRecordDecl()) {
    if (!ExcludeCtor)
      return NonConstantStorageReason::NonTrivialCtor;
    if (Record->hasMutableFields())
      return NonConstantStorageReason::MutableField;
    if (!Record->hasTrivialDestructor() && !ExcludeDtor)
      return NonConstantStorageReason::NonTrivialDtor;
  }
  return std::nullopt;
}
 
// C++ [temp.dep.type]p1:
//   A type is dependent if it is...
//     - an array type constructed from any dependent type or whose
//       size is specified by a constant expression that is
//       value-dependent,
ArrayType::ArrayType(TypeClass tc, QualType et, QualType can,
                     ArraySizeModifier sm, unsigned tq, const Expr *sz)
    // Note, we need to check for DependentSizedArrayType explicitly here
    // because we use a DependentSizedArrayType with no size expression as the
    // type of a dependent array of unknown bound with a dependent braced
    // initializer:
    //
    //   template<int ...N> int arr[] = {N...};
    : Type(tc, can,
           et->getDependence() |
               (sz ? toTypeDependence(
                         turnValueToTypeDependence(sz->getDependence()))
                   : TypeDependence::None) |
               (tc == VariableArray ? TypeDependence::VariablyModified
                                    : TypeDependence::None) |
               (tc == DependentSizedArray
                    ? TypeDependence::DependentInstantiation
                    : TypeDependence::None)),
      ElementType(et) {
  ArrayTypeBits.IndexTypeQuals = tq;
  ArrayTypeBits.SizeModifier = llvm::to_underlying(sm);
}
 
ConstantArrayType *
ConstantArrayType::Create(const ASTContext &Ctx, QualType ET, QualType Can,
                          const llvm::APInt &Sz, const Expr *SzExpr,
                          ArraySizeModifier SzMod, unsigned Qual) {
  bool NeedsExternalSize = SzExpr != nullptr || Sz.ugt(0x0FFFFFFFFFFFFFFF) ||
                           Sz.getBitWidth() > 0xFF;
  if (!NeedsExternalSize)
    return new (Ctx, alignof(ConstantArrayType)) ConstantArrayType(
        ET, Can, Sz.getBitWidth(), Sz.getZExtValue(), SzMod, Qual);
 
  auto *SzPtr = new (Ctx, alignof(ConstantArrayType::ExternalSize))
      ConstantArrayType::ExternalSize(Sz, SzExpr);
  return new (Ctx, alignof(ConstantArrayType))
      ConstantArrayType(ET, Can, SzPtr, SzMod, Qual);
}
 
unsigned
ConstantArrayType::getNumAddressingBits(const ASTContext &Context,
                                        QualType ElementType,
                                        const llvm::APInt &NumElements) {
  uint64_t ElementSize = Context.getTypeSizeInChars(ElementType).getQuantity();
 
  // Fast path the common cases so we can avoid the conservative computation
  // below, which in common cases allocates "large" APSInt values, which are
  // slow.
 
  // If the element size is a power of 2, we can directly compute the additional
  // number of addressing bits beyond those required for the element count.
  if (llvm::isPowerOf2_64(ElementSize)) {
    return NumElements.getActiveBits() + llvm::Log2_64(ElementSize);
  }
 
  // If both the element count and element size fit in 32-bits, we can do the
  // computation directly in 64-bits.
  if ((ElementSize >> 32) == 0 && NumElements.getBitWidth() <= 64 &&
      (NumElements.getZExtValue() >> 32) == 0) {
    uint64_t TotalSize = NumElements.getZExtValue() * ElementSize;
    return llvm::bit_width(TotalSize);
  }
 
  // Otherwise, use APSInt to handle arbitrary sized values.
  llvm::APSInt SizeExtended(NumElements, true);
  unsigned SizeTypeBits = Context.getTypeSize(Context.getSizeType());
  SizeExtended = SizeExtended.extend(
      std::max(SizeTypeBits, SizeExtended.getBitWidth()) * 2);
 
  llvm::APSInt TotalSize(llvm::APInt(SizeExtended.getBitWidth(), ElementSize));
  TotalSize *= SizeExtended;
 
  return TotalSize.getActiveBits();
}
 
unsigned
ConstantArrayType::getNumAddressingBits(const ASTContext &Context) const {
  return getNumAddressingBits(Context, getElementType(), getSize());
}
 
unsigned ConstantArrayType::getMaxSizeBits(const ASTContext &Context) {
  unsigned Bits = Context.getTypeSize(Context.getSizeType());
 
  // Limit the number of bits in size_t so that maximal bit size fits 64 bit
  // integer (see PR8256).  We can do this as currently there is no hardware
  // that supports full 64-bit virtual space.
  if (Bits > 61)
    Bits = 61;
 
  return Bits;
}
 
void ConstantArrayType::Profile(llvm::FoldingSetNodeID &ID,
                                const ASTContext &Context, QualType ET,
                                uint64_t ArraySize, const Expr *SizeExpr,
                                ArraySizeModifier SizeMod, unsigned TypeQuals) {
  ID.AddPointer(ET.getAsOpaquePtr());
  ID.AddInteger(ArraySize);
  ID.AddInteger(llvm::to_underlying(SizeMod));
  ID.AddInteger(TypeQuals);
  ID.AddBoolean(SizeExpr != nullptr);
  if (SizeExpr)
    SizeExpr->Profile(ID, Context, true);
}
 
QualType ArrayParameterType::getConstantArrayType(const ASTContext &Ctx) const {
  return Ctx.getConstantArrayType(getElementType(), getSize(), getSizeExpr(),
                                  getSizeModifier(),
                                  getIndexTypeQualifiers().getAsOpaqueValue());
}
 
DependentSizedArrayType::DependentSizedArrayType(QualType et, QualType can,
                                                 Expr *e, ArraySizeModifier sm,
                                                 unsigned tq)
    : ArrayType(DependentSizedArray, et, can, sm, tq, e), SizeExpr((Stmt *)e) {}
 
void DependentSizedArrayType::Profile(llvm::FoldingSetNodeID &ID,
                                      const ASTContext &Context, QualType ET,
                                      ArraySizeModifier SizeMod,
                                      unsigned TypeQuals, Expr *E) {
  ID.AddPointer(ET.getAsOpaquePtr());
  ID.AddInteger(llvm::to_underlying(SizeMod));
  ID.AddInteger(TypeQuals);
  if (E)
    E->Profile(ID, Context, true);
}
 
DependentVectorType::DependentVectorType(QualType ElementType,
                                         QualType CanonType, Expr *SizeExpr,
                                         SourceLocation Loc, VectorKind VecKind)
    : Type(DependentVector, CanonType,
           TypeDependence::DependentInstantiation |
               ElementType->getDependence() |
               (SizeExpr ? toTypeDependence(SizeExpr->getDependence())
                         : TypeDependence::None)),
      ElementType(ElementType), SizeExpr(SizeExpr), Loc(Loc) {
  VectorTypeBits.VecKind = llvm::to_underlying(VecKind);
}
 
void DependentVectorType::Profile(llvm::FoldingSetNodeID &ID,
                                  const ASTContext &Context,
                                  QualType ElementType, const Expr *SizeExpr,
                                  VectorKind VecKind) {
  ID.AddPointer(ElementType.getAsOpaquePtr());
  ID.AddInteger(llvm::to_underlying(VecKind));
  SizeExpr->Profile(ID, Context, true);
}
 
DependentSizedExtVectorType::DependentSizedExtVectorType(QualType ElementType,
                                                         QualType can,
                                                         Expr *SizeExpr,
                                                         SourceLocation loc)
    : Type(DependentSizedExtVector, can,
           TypeDependence::DependentInstantiation |
               ElementType->getDependence() |
               (SizeExpr ? toTypeDependence(SizeExpr->getDependence())
                         : TypeDependence::None)),
      SizeExpr(SizeExpr), ElementType(ElementType), loc(loc) {}
 
void DependentSizedExtVectorType::Profile(llvm::FoldingSetNodeID &ID,
                                          const ASTContext &Context,
                                          QualType ElementType,
                                          Expr *SizeExpr) {
  ID.AddPointer(ElementType.getAsOpaquePtr());
  SizeExpr->Profile(ID, Context, true);
}
 
DependentAddressSpaceType::DependentAddressSpaceType(QualType PointeeType,
                                                     QualType can,
                                                     Expr *AddrSpaceExpr,
                                                     SourceLocation loc)
    : Type(DependentAddressSpace, can,
           TypeDependence::DependentInstantiation |
               PointeeType->getDependence() |
               (AddrSpaceExpr ? toTypeDependence(AddrSpaceExpr->getDependence())
                              : TypeDependence::None)),
      AddrSpaceExpr(AddrSpaceExpr), PointeeType(PointeeType), loc(loc) {}
 
void DependentAddressSpaceType::Profile(llvm::FoldingSetNodeID &ID,
                                        const ASTContext &Context,
                                        QualType PointeeType,
                                        Expr *AddrSpaceExpr) {
  ID.AddPointer(PointeeType.getAsOpaquePtr());
  AddrSpaceExpr->Profile(ID, Context, true);
}
 
MatrixType::MatrixType(TypeClass tc, QualType matrixType, QualType canonType,
                       const Expr *RowExpr, const Expr *ColumnExpr)
    : Type(tc, canonType,
           (RowExpr ? (matrixType->getDependence() | TypeDependence::Dependent |
                       TypeDependence::Instantiation |
                       (matrixType->isVariablyModifiedType()
                            ? TypeDependence::VariablyModified
                            : TypeDependence::None) |
                       (matrixType->containsUnexpandedParameterPack() ||
                                (RowExpr &&
                                 RowExpr->containsUnexpandedParameterPack()) ||
                                (ColumnExpr &&
                                 ColumnExpr->containsUnexpandedParameterPack())
                            ? TypeDependence::UnexpandedPack
                            : TypeDependence::None))
                    : matrixType->getDependence())),
      ElementType(matrixType) {}
 
ConstantMatrixType::ConstantMatrixType(QualType matrixType, unsigned nRows,
                                       unsigned nColumns, QualType canonType)
    : ConstantMatrixType(ConstantMatrix, matrixType, nRows, nColumns,
                         canonType) {}
 
ConstantMatrixType::ConstantMatrixType(TypeClass tc, QualType matrixType,
                                       unsigned nRows, unsigned nColumns,
                                       QualType canonType)
    : MatrixType(tc, matrixType, canonType), NumRows(nRows),
      NumColumns(nColumns) {}
 
DependentSizedMatrixType::DependentSizedMatrixType(QualType ElementType,
                                                   QualType CanonicalType,
                                                   Expr *RowExpr,
                                                   Expr *ColumnExpr,
                                                   SourceLocation loc)
    : MatrixType(DependentSizedMatrix, ElementType, CanonicalType, RowExpr,
                 ColumnExpr),
      RowExpr(RowExpr), ColumnExpr(ColumnExpr), loc(loc) {}
 
void DependentSizedMatrixType::Profile(llvm::FoldingSetNodeID &ID,
                                       const ASTContext &CTX,
                                       QualType ElementType, Expr *RowExpr,
                                       Expr *ColumnExpr) {
  ID.AddPointer(ElementType.getAsOpaquePtr());
  RowExpr->Profile(ID, CTX, true);
  ColumnExpr->Profile(ID, CTX, true);
}
 
VectorType::VectorType(QualType vecType, unsigned nElements, QualType canonType,
                       VectorKind vecKind)
    : VectorType(Vector, vecType, nElements, canonType, vecKind) {}
 
VectorType::VectorType(TypeClass tc, QualType vecType, unsigned nElements,
                       QualType canonType, VectorKind vecKind)
    : Type(tc, canonType, vecType->getDependence()), ElementType(vecType) {
  VectorTypeBits.VecKind = llvm::to_underlying(vecKind);
  VectorTypeBits.NumElements = nElements;
}
 
bool Type::isPackedVectorBoolType(const ASTContext &ctx) const {
  if (ctx.getLangOpts().HLSL)
    return false;
  return isExtVectorBoolType();
}
 
BitIntType::BitIntType(bool IsUnsigned, unsigned NumBits)
    : Type(BitInt, QualType{}, TypeDependence::None), IsUnsigned(IsUnsigned),
      NumBits(NumBits) {}
 
DependentBitIntType::DependentBitIntType(bool IsUnsigned, Expr *NumBitsExpr)
    : Type(DependentBitInt, QualType{},
           toTypeDependence(NumBitsExpr->getDependence())),
      ExprAndUnsigned(NumBitsExpr, IsUnsigned) {}
 
bool DependentBitIntType::isUnsigned() const {
  return ExprAndUnsigned.getInt();
}
 
clang::Expr *DependentBitIntType::getNumBitsExpr() const {
  return ExprAndUnsigned.getPointer();
}
 
void DependentBitIntType::Profile(llvm::FoldingSetNodeID &ID,
                                  const ASTContext &Context, bool IsUnsigned,
                                  Expr *NumBitsExpr) {
  ID.AddBoolean(IsUnsigned);
  NumBitsExpr->Profile(ID, Context, true);
}
 
bool BoundsAttributedType::referencesFieldDecls() const {
  return llvm::any_of(dependent_decls(),
                      [](const TypeCoupledDeclRefInfo &Info) {
                        return isa<FieldDecl>(Info.getDecl());
                      });
}
 
void CountAttributedType::Profile(llvm::FoldingSetNodeID &ID,
                                  QualType WrappedTy, Expr *CountExpr,
                                  bool CountInBytes, bool OrNull) {
  ID.AddPointer(WrappedTy.getAsOpaquePtr());
  ID.AddBoolean(CountInBytes);
  ID.AddBoolean(OrNull);
  // We profile it as a pointer as the StmtProfiler considers parameter
  // expressions on function declaration and function definition as the
  // same, resulting in count expression being evaluated with ParamDecl
  // not in the function scope.
  ID.AddPointer(CountExpr);
}
 
/// getArrayElementTypeNoTypeQual - If this is an array type, return the
/// element type of the array, potentially with type qualifiers missing.
/// This method should never be used when type qualifiers are meaningful.
const Type *Type::getArrayElementTypeNoTypeQual() const {
  // If this is directly an array type, return it.
  if (const auto *ATy = dyn_cast<ArrayType>(this))
    return ATy->getElementType().getTypePtr();
 
  // If the canonical form of this type isn't the right kind, reject it.
  if (!isa<ArrayType>(CanonicalType))
    return nullptr;
 
  // If this is a typedef for an array type, strip the typedef off without
  // losing all typedef information.
  return cast<ArrayType>(getUnqualifiedDesugaredType())
      ->getElementType()
      .getTypePtr();
}
 
/// getDesugaredType - Return the specified type with any "sugar" removed from
/// the type.  This takes off typedefs, typeof's etc.  If the outer level of
/// the type is already concrete, it returns it unmodified.  This is similar
/// to getting the canonical type, but it doesn't remove *all* typedefs.  For
/// example, it returns "T*" as "T*", (not as "int*"), because the pointer is
/// concrete.
QualType QualType::getDesugaredType(QualType T, const ASTContext &Context) {
  SplitQualType split = getSplitDesugaredType(T);
  return Context.getQualifiedType(split.Ty, split.Quals);
}
 
QualType QualType::getSingleStepDesugaredTypeImpl(QualType type,
                                                  const ASTContext &Context) {
  SplitQualType split = type.split();
  QualType desugar = split.Ty->getLocallyUnqualifiedSingleStepDesugaredType();
  return Context.getQualifiedType(desugar, split.Quals);
}
 
// Check that no type class is polymorphic. LLVM style RTTI should be used
// instead. If absolutely needed an exception can still be added here by
// defining the appropriate macro (but please don't do this).
#define TYPE(CLASS, BASE)                                                      \
  static_assert(!std::is_polymorphic<CLASS##Type>::value,                      \
                #CLASS "Type should not be polymorphic!");
#include "clang/AST/TypeNodes.inc"
 
// Check that no type class has a non-trival destructor. Types are
// allocated with the BumpPtrAllocator from ASTContext and therefore
// their destructor is not executed.
#define TYPE(CLASS, BASE)                                                      \
  static_assert(std::is_trivially_destructible<CLASS##Type>::value,            \
                #CLASS "Type should be trivially destructible!");
#include "clang/AST/TypeNodes.inc"
 
QualType Type::getLocallyUnqualifiedSingleStepDesugaredType() const {
  switch (getTypeClass()) {
#define ABSTRACT_TYPE(Class, Parent)
#define TYPE(Class, Parent)                                                    \
  case Type::Class: {                                                          \
    const auto *ty = cast<Class##Type>(this);                                  \
    if (!ty->isSugared())                                                      \
      return QualType(ty, 0);                                                  \
    return ty->desugar();                                                      \
  }
#include "clang/AST/TypeNodes.inc"
  }
  llvm_unreachable("bad type kind!");
}
 
SplitQualType QualType::getSplitDesugaredType(QualType T) {
  QualifierCollector Qs;
 
  QualType Cur = T;
  while (true) {
    const Type *CurTy = Qs.strip(Cur);
    switch (CurTy->getTypeClass()) {
#define ABSTRACT_TYPE(Class, Parent)
#define TYPE(Class, Parent)                                                    \
  case Type::Class: {                                                          \
    const auto *Ty = cast<Class##Type>(CurTy);                                 \
    if (!Ty->isSugared())                                                      \
      return SplitQualType(Ty, Qs);                                            \
    Cur = Ty->desugar();                                                       \
    break;                                                                     \
  }
#include "clang/AST/TypeNodes.inc"
    }
  }
}
 
SplitQualType QualType::getSplitUnqualifiedTypeImpl(QualType type) {
  SplitQualType split = type.split();
 
  // All the qualifiers we've seen so far.
  Qualifiers quals = split.Quals;
 
  // The last type node we saw with any nodes inside it.
  const Type *lastTypeWithQuals = split.Ty;
 
  while (true) {
    QualType next;
 
    // Do a single-step desugar, aborting the loop if the type isn't
    // sugared.
    switch (split.Ty->getTypeClass()) {
#define ABSTRACT_TYPE(Class, Parent)
#define TYPE(Class, Parent)                                                    \
  case Type::Class: {                                                          \
    const auto *ty = cast<Class##Type>(split.Ty);                              \
    if (!ty->isSugared())                                                      \
      goto done;                                                               \
    next = ty->desugar();                                                      \
    break;                                                                     \
  }
#include "clang/AST/TypeNodes.inc"
    }
 
    // Otherwise, split the underlying type.  If that yields qualifiers,
    // update the information.
    split = next.split();
    if (!split.Quals.empty()) {
      lastTypeWithQuals = split.Ty;
      quals.addConsistentQualifiers(split.Quals);
    }
  }
 
done:
  return SplitQualType(lastTypeWithQuals, quals);
}
 
QualType QualType::IgnoreParens(QualType T) {
  // FIXME: this seems inherently un-qualifiers-safe.
  while (const auto *PT = T->getAs<ParenType>())
    T = PT->getInnerType();
  return T;
}
 
/// This will check for a T (which should be a Type which can act as
/// sugar, such as a TypedefType) by removing any existing sugar until it
/// reaches a T or a non-sugared type.
template <typename T> static const T *getAsSugar(const Type *Cur) {
  while (true) {
    if (const auto *Sugar = dyn_cast<T>(Cur))
      return Sugar;
    switch (Cur->getTypeClass()) {
#define ABSTRACT_TYPE(Class, Parent)
#define TYPE(Class, Parent)                                                    \
  case Type::Class: {                                                          \
    const auto *Ty = cast<Class##Type>(Cur);                                   \
    if (!Ty->isSugared())                                                      \
      return 0;                                                                \
    Cur = Ty->desugar().getTypePtr();                                          \
    break;                                                                     \
  }
#include "clang/AST/TypeNodes.inc"
    }
  }
}
 
template <> const TypedefType *Type::getAs() const {
  return getAsSugar<TypedefType>(this);
}
 
template <> const UsingType *Type::getAs() const {
  return getAsSugar<UsingType>(this);
}
 
template <> const TemplateSpecializationType *Type::getAs() const {
  return getAsSugar<TemplateSpecializationType>(this);
}
 
template <> const AttributedType *Type::getAs() const {
  return getAsSugar<AttributedType>(this);
}
 
template <> const BoundsAttributedType *Type::getAs() const {
  return getAsSugar<BoundsAttributedType>(this);
}
 
template <> const CountAttributedType *Type::getAs() const {
  return getAsSugar<CountAttributedType>(this);
}
 
/// getUnqualifiedDesugaredType - Pull any qualifiers and syntactic
/// sugar off the given type.  This should produce an object of the
/// same dynamic type as the canonical type.
const Type *Type::getUnqualifiedDesugaredType() const {
  const Type *Cur = this;
 
  while (true) {
    switch (Cur->getTypeClass()) {
#define ABSTRACT_TYPE(Class, Parent)
#define TYPE(Class, Parent)                                                    \
  case Class: {                                                                \
    const auto *Ty = cast<Class##Type>(Cur);                                   \
    if (!Ty->isSugared())                                                      \
      return Cur;                                                              \
    Cur = Ty->desugar().getTypePtr();                                          \
    break;                                                                     \
  }
#include "clang/AST/TypeNodes.inc"
    }
  }
}
 
bool Type::isClassType() const {
  if (const auto *RT = getAsCanonical<RecordType>())
    return RT->getDecl()->isClass();
  return false;
}
 
bool Type::isStructureType() const {
  if (const auto *RT = getAsCanonical<RecordType>())
    return RT->getDecl()->isStruct();
  return false;
}
 
bool Type::isStructureTypeWithFlexibleArrayMember() const {
  const auto *RT = getAsCanonical<RecordType>();
  if (!RT)
    return false;
  const auto *Decl = RT->getDecl();
  if (!Decl->isStruct())
    return false;
  return Decl->getDefinitionOrSelf()->hasFlexibleArrayMember();
}
 
bool Type::isObjCBoxableRecordType() const {
  if (const auto *RD = getAsRecordDecl())
    return RD->hasAttr<ObjCBoxableAttr>();
  return false;
}
 
bool Type::isInterfaceType() const {
  if (const auto *RT = getAsCanonical<RecordType>())
    return RT->getDecl()->isInterface();
  return false;
}
 
bool Type::isStructureOrClassType() const {
  if (const auto *RT = getAsCanonical<RecordType>())
    return RT->getDecl()->isStructureOrClass();
  return false;
}
 
bool Type::isVoidPointerType() const {
  if (const auto *PT = getAsCanonical<PointerType>())
    return PT->getPointeeType()->isVoidType();
  return false;
}
 
bool Type::isUnionType() const {
  if (const auto *RT = getAsCanonical<RecordType>())
    return RT->getDecl()->isUnion();
  return false;
}
 
bool Type::isComplexType() const {
  if (const auto *CT = getAsCanonical<ComplexType>())
    return CT->getElementType()->isFloatingType();
  return false;
}
 
bool Type::isComplexIntegerType() const {
  // Check for GCC complex integer extension.
  return getAsComplexIntegerType();
}
 
bool Type::isScopedEnumeralType() const {
  if (const auto *ET = getAsCanonical<EnumType>())
    return ET->getDecl()->isScoped();
  return false;
}
 
bool Type::isCountAttributedType() const {
  return getAs<CountAttributedType>();
}
 
const ComplexType *Type::getAsComplexIntegerType() const {
  if (const auto *Complex = getAs<ComplexType>())
    if (Complex->getElementType()->isIntegerType())
      return Complex;
  return nullptr;
}
 
QualType Type::getPointeeType() const {
  if (const auto *PT = getAs<PointerType>())
    return PT->getPointeeType();
  if (const auto *OPT = getAs<ObjCObjectPointerType>())
    return OPT->getPointeeType();
  if (const auto *BPT = getAs<BlockPointerType>())
    return BPT->getPointeeType();
  if (const auto *RT = getAs<ReferenceType>())
    return RT->getPointeeType();
  if (const auto *MPT = getAs<MemberPointerType>())
    return MPT->getPointeeType();
  if (const auto *DT = getAs<DecayedType>())
    return DT->getPointeeType();
  return {};
}
 
const RecordType *Type::getAsStructureType() const {
  // If this is directly a structure type, return it.
  if (const auto *RT = dyn_cast<RecordType>(this)) {
    if (RT->getDecl()->isStruct())
      return RT;
  }
 
  // If the canonical form of this type isn't the right kind, reject it.
  if (const auto *RT = dyn_cast<RecordType>(CanonicalType)) {
    if (!RT->getDecl()->isStruct())
      return nullptr;
 
    // If this is a typedef for a structure type, strip the typedef off without
    // losing all typedef information.
    return cast<RecordType>(getUnqualifiedDesugaredType());
  }
  return nullptr;
}
 
const RecordType *Type::getAsUnionType() const {
  // If this is directly a union type, return it.
  if (const auto *RT = dyn_cast<RecordType>(this)) {
    if (RT->getDecl()->isUnion())
      return RT;
  }
 
  // If the canonical form of this type isn't the right kind, reject it.
  if (const auto *RT = dyn_cast<RecordType>(CanonicalType)) {
    if (!RT->getDecl()->isUnion())
      return nullptr;
 
    // If this is a typedef for a union type, strip the typedef off without
    // losing all typedef information.
    return cast<RecordType>(getUnqualifiedDesugaredType());
  }
 
  return nullptr;
}
 
bool Type::isObjCIdOrObjectKindOfType(const ASTContext &ctx,
                                      const ObjCObjectType *&bound) const {
  bound = nullptr;
 
  const auto *OPT = getAs<ObjCObjectPointerType>();
  if (!OPT)
    return false;
 
  // Easy case: id.
  if (OPT->isObjCIdType())
    return true;
 
  // If it's not a __kindof type, reject it now.
  if (!OPT->isKindOfType())
    return false;
 
  // If it's Class or qualified Class, it's not an object type.
  if (OPT->isObjCClassType() || OPT->isObjCQualifiedClassType())
    return false;
 
  // Figure out the type bound for the __kindof type.
  bound = OPT->getObjectType()
              ->stripObjCKindOfTypeAndQuals(ctx)
              ->getAs<ObjCObjectType>();
  return true;
}
 
bool Type::isObjCClassOrClassKindOfType() const {
  const auto *OPT = getAs<ObjCObjectPointerType>();
  if (!OPT)
    return false;
 
  // Easy case: Class.
  if (OPT->isObjCClassType())
    return true;
 
  // If it's not a __kindof type, reject it now.
  if (!OPT->isKindOfType())
    return false;
 
  // If it's Class or qualified Class, it's a class __kindof type.
  return OPT->isObjCClassType() || OPT->isObjCQualifiedClassType();
}
 
ObjCTypeParamType::ObjCTypeParamType(const ObjCTypeParamDecl *D, QualType can,
                                     ArrayRef<ObjCProtocolDecl *> protocols)
    : Type(ObjCTypeParam, can, toSemanticDependence(can->getDependence())),
      OTPDecl(const_cast<ObjCTypeParamDecl *>(D)) {
  initialize(protocols);
}
 
ObjCObjectType::ObjCObjectType(QualType Canonical, QualType Base,
                               ArrayRef<QualType> typeArgs,
                               ArrayRef<ObjCProtocolDecl *> protocols,
                               bool isKindOf)
    : Type(ObjCObject, Canonical, Base->getDependence()), BaseType(Base) {
  ObjCObjectTypeBits.IsKindOf = isKindOf;
 
  ObjCObjectTypeBits.NumTypeArgs = typeArgs.size();
  assert(getTypeArgsAsWritten().size() == typeArgs.size() &&
         "bitfield overflow in type argument count");
  if (!typeArgs.empty())
    memcpy(getTypeArgStorage(), typeArgs.data(),
           typeArgs.size() * sizeof(QualType));
 
  for (auto typeArg : typeArgs) {
    addDependence(typeArg->getDependence() & ~TypeDependence::VariablyModified);
  }
  // Initialize the protocol qualifiers. The protocol storage is known
  // after we set number of type arguments.
  initialize(protocols);
}
 
bool ObjCObjectType::isSpecialized() const {
  // If we have type arguments written here, the type is specialized.
  if (ObjCObjectTypeBits.NumTypeArgs > 0)
    return true;
 
  // Otherwise, check whether the base type is specialized.
  if (const auto objcObject = getBaseType()->getAs<ObjCObjectType>()) {
    // Terminate when we reach an interface type.
    if (isa<ObjCInterfaceType>(objcObject))
      return false;
 
    return objcObject->isSpecialized();
  }
 
  // Not specialized.
  return false;
}
 
ArrayRef<QualType> ObjCObjectType::getTypeArgs() const {
  // We have type arguments written on this type.
  if (isSpecializedAsWritten())
    return getTypeArgsAsWritten();
 
  // Look at the base type, which might have type arguments.
  if (const auto objcObject = getBaseType()->getAs<ObjCObjectType>()) {
    // Terminate when we reach an interface type.
    if (isa<ObjCInterfaceType>(objcObject))
      return {};
 
    return objcObject->getTypeArgs();
  }
 
  // No type arguments.
  return {};
}
 
bool ObjCObjectType::isKindOfType() const {
  if (isKindOfTypeAsWritten())
    return true;
 
  // Look at the base type, which might have type arguments.
  if (const auto objcObject = getBaseType()->getAs<ObjCObjectType>()) {
    // Terminate when we reach an interface type.
    if (isa<ObjCInterfaceType>(objcObject))
      return false;
 
    return objcObject->isKindOfType();
  }
 
  // Not a "__kindof" type.
  return false;
}
 
QualType
ObjCObjectType::stripObjCKindOfTypeAndQuals(const ASTContext &ctx) const {
  if (!isKindOfType() && qual_empty())
    return QualType(this, 0);
 
  // Recursively strip __kindof.
  SplitQualType splitBaseType = getBaseType().split();
  QualType baseType(splitBaseType.Ty, 0);
  if (const auto *baseObj = splitBaseType.Ty->getAs<ObjCObjectType>())
    baseType = baseObj->stripObjCKindOfTypeAndQuals(ctx);
 
  return ctx.getObjCObjectType(
      ctx.getQualifiedType(baseType, splitBaseType.Quals),
      getTypeArgsAsWritten(),
      /*protocols=*/{},
      /*isKindOf=*/false);
}
 
ObjCInterfaceDecl *ObjCInterfaceType::getDecl() const {
  ObjCInterfaceDecl *Canon = Decl->getCanonicalDecl();
  if (ObjCInterfaceDecl *Def = Canon->getDefinition())
    return Def;
  return Canon;
}
 
const ObjCObjectPointerType *ObjCObjectPointerType::stripObjCKindOfTypeAndQuals(
    const ASTContext &ctx) const {
  if (!isKindOfType() && qual_empty())
    return this;
 
  QualType obj = getObjectType()->stripObjCKindOfTypeAndQuals(ctx);
  return ctx.getObjCObjectPointerType(obj)->castAs<ObjCObjectPointerType>();
}
 
namespace {
 
/// Visitor used to perform a simple type transformation that does not change
/// the semantics of the type.
template <typename Derived>
struct SimpleTransformVisitor : public TypeVisitor<Derived, QualType> {
  ASTContext &Ctx;
 
  QualType recurse(QualType type) {
    // Split out the qualifiers from the type.
    SplitQualType splitType = type.split();
 
    // Visit the type itself.
    QualType result = static_cast<Derived *>(this)->Visit(splitType.Ty);
    if (result.isNull())
      return result;
 
    // Reconstruct the transformed type by applying the local qualifiers
    // from the split type.
    return Ctx.getQualifiedType(result, splitType.Quals);
  }
 
public:
  explicit SimpleTransformVisitor(ASTContext &ctx) : Ctx(ctx) {}
 
  // None of the clients of this transformation can occur where
  // there are dependent types, so skip dependent types.
#define TYPE(Class, Base)
#define DEPENDENT_TYPE(Class, Base)                                            \
  QualType Visit##Class##Type(const Class##Type *T) { return QualType(T, 0); }
#include "clang/AST/TypeNodes.inc"
 
#define TRIVIAL_TYPE_CLASS(Class)                                              \
  QualType Visit##Class##Type(const Class##Type *T) { return QualType(T, 0); }
#define SUGARED_TYPE_CLASS(Class)                                              \
  QualType Visit##Class##Type(const Class##Type *T) {                          \
    if (!T->isSugared())                                                       \
      return QualType(T, 0);                                                   \
    QualType desugaredType = recurse(T->desugar());                            \
    if (desugaredType.isNull())                                                \
      return {};                                                               \
    if (desugaredType.getAsOpaquePtr() == T->desugar().getAsOpaquePtr())       \
      return QualType(T, 0);                                                   \
    return desugaredType;                                                      \
  }
 
  TRIVIAL_TYPE_CLASS(Builtin)
 
  QualType VisitComplexType(const ComplexType *T) {
    QualType elementType = recurse(T->getElementType());
    if (elementType.isNull())
      return {};
 
    if (elementType.getAsOpaquePtr() == T->getElementType().getAsOpaquePtr())
      return QualType(T, 0);
 
    return Ctx.getComplexType(elementType);
  }
 
  QualType VisitPointerType(const PointerType *T) {
    QualType pointeeType = recurse(T->getPointeeType());
    if (pointeeType.isNull())
      return {};
 
    if (pointeeType.getAsOpaquePtr() == T->getPointeeType().getAsOpaquePtr())
      return QualType(T, 0);
 
    return Ctx.getPointerType(pointeeType);
  }
 
  QualType VisitBlockPointerType(const BlockPointerType *T) {
    QualType pointeeType = recurse(T->getPointeeType());
    if (pointeeType.isNull())
      return {};
 
    if (pointeeType.getAsOpaquePtr() == T->getPointeeType().getAsOpaquePtr())
      return QualType(T, 0);
 
    return Ctx.getBlockPointerType(pointeeType);
  }
 
  QualType VisitLValueReferenceType(const LValueReferenceType *T) {
    QualType pointeeType = recurse(T->getPointeeTypeAsWritten());
    if (pointeeType.isNull())
      return {};
 
    if (pointeeType.getAsOpaquePtr() ==
        T->getPointeeTypeAsWritten().getAsOpaquePtr())
      return QualType(T, 0);
 
    return Ctx.getLValueReferenceType(pointeeType, T->isSpelledAsLValue());
  }
 
  QualType VisitRValueReferenceType(const RValueReferenceType *T) {
    QualType pointeeType = recurse(T->getPointeeTypeAsWritten());
    if (pointeeType.isNull())
      return {};
 
    if (pointeeType.getAsOpaquePtr() ==
        T->getPointeeTypeAsWritten().getAsOpaquePtr())
      return QualType(T, 0);
 
    return Ctx.getRValueReferenceType(pointeeType);
  }
 
  QualType VisitMemberPointerType(const MemberPointerType *T) {
    QualType pointeeType = recurse(T->getPointeeType());
    if (pointeeType.isNull())
      return {};
 
    if (pointeeType.getAsOpaquePtr() == T->getPointeeType().getAsOpaquePtr())
      return QualType(T, 0);
 
    return Ctx.getMemberPointerType(pointeeType, T->getQualifier(),
                                    T->getMostRecentCXXRecordDecl());
  }
 
  QualType VisitConstantArrayType(const ConstantArrayType *T) {
    QualType elementType = recurse(T->getElementType());
    if (elementType.isNull())
      return {};
 
    if (elementType.getAsOpaquePtr() == T->getElementType().getAsOpaquePtr())
      return QualType(T, 0);
 
    return Ctx.getConstantArrayType(elementType, T->getSize(), T->getSizeExpr(),
                                    T->getSizeModifier(),
                                    T->getIndexTypeCVRQualifiers());
  }
 
  QualType VisitVariableArrayType(const VariableArrayType *T) {
    QualType elementType = recurse(T->getElementType());
    if (elementType.isNull())
      return {};
 
    if (elementType.getAsOpaquePtr() == T->getElementType().getAsOpaquePtr())
      return QualType(T, 0);
 
    return Ctx.getVariableArrayType(elementType, T->getSizeExpr(),
                                    T->getSizeModifier(),
                                    T->getIndexTypeCVRQualifiers());
  }
 
  QualType VisitIncompleteArrayType(const IncompleteArrayType *T) {
    QualType elementType = recurse(T->getElementType());
    if (elementType.isNull())
      return {};
 
    if (elementType.getAsOpaquePtr() == T->getElementType().getAsOpaquePtr())
      return QualType(T, 0);
 
    return Ctx.getIncompleteArrayType(elementType, T->getSizeModifier(),
                                      T->getIndexTypeCVRQualifiers());
  }
 
  QualType VisitVectorType(const VectorType *T) {
    QualType elementType = recurse(T->getElementType());
    if (elementType.isNull())
      return {};
 
    if (elementType.getAsOpaquePtr() == T->getElementType().getAsOpaquePtr())
      return QualType(T, 0);
 
    return Ctx.getVectorType(elementType, T->getNumElements(),
                             T->getVectorKind());
  }
 
  QualType VisitExtVectorType(const ExtVectorType *T) {
    QualType elementType = recurse(T->getElementType());
    if (elementType.isNull())
      return {};
 
    if (elementType.getAsOpaquePtr() == T->getElementType().getAsOpaquePtr())
      return QualType(T, 0);
 
    return Ctx.getExtVectorType(elementType, T->getNumElements());
  }
 
  QualType VisitConstantMatrixType(const ConstantMatrixType *T) {
    QualType elementType = recurse(T->getElementType());
    if (elementType.isNull())
      return {};
    if (elementType.getAsOpaquePtr() == T->getElementType().getAsOpaquePtr())
      return QualType(T, 0);
 
    return Ctx.getConstantMatrixType(elementType, T->getNumRows(),
                                     T->getNumColumns());
  }
 
  QualType VisitOverflowBehaviorType(const OverflowBehaviorType *T) {
    QualType UnderlyingType = recurse(T->getUnderlyingType());
    if (UnderlyingType.isNull())
      return {};
 
    if (UnderlyingType.getAsOpaquePtr() ==
        T->getUnderlyingType().getAsOpaquePtr())
      return QualType(T, 0);
 
    return Ctx.getOverflowBehaviorType(T->getBehaviorKind(), UnderlyingType);
  }
 
  QualType VisitFunctionNoProtoType(const FunctionNoProtoType *T) {
    QualType returnType = recurse(T->getReturnType());
    if (returnType.isNull())
      return {};
 
    if (returnType.getAsOpaquePtr() == T->getReturnType().getAsOpaquePtr())
      return QualType(T, 0);
 
    return Ctx.getFunctionNoProtoType(returnType, T->getExtInfo());
  }
 
  QualType VisitFunctionProtoType(const FunctionProtoType *T) {
    QualType returnType = recurse(T->getReturnType());
    if (returnType.isNull())
      return {};
 
    // Transform parameter types.
    SmallVector<QualType, 4> paramTypes;
    bool paramChanged = false;
    for (auto paramType : T->getParamTypes()) {
      QualType newParamType = recurse(paramType);
      if (newParamType.isNull())
        return {};
 
      if (newParamType.getAsOpaquePtr() != paramType.getAsOpaquePtr())
        paramChanged = true;
 
      paramTypes.push_back(newParamType);
    }
 
    // Transform extended info.
    FunctionProtoType::ExtProtoInfo info = T->getExtProtoInfo();
    bool exceptionChanged = false;
    if (info.ExceptionSpec.Type == EST_Dynamic) {
      SmallVector<QualType, 4> exceptionTypes;
      for (auto exceptionType : info.ExceptionSpec.Exceptions) {
        QualType newExceptionType = recurse(exceptionType);
        if (newExceptionType.isNull())
          return {};
 
        if (newExceptionType.getAsOpaquePtr() != exceptionType.getAsOpaquePtr())
          exceptionChanged = true;
 
        exceptionTypes.push_back(newExceptionType);
      }
 
      if (exceptionChanged) {
        info.ExceptionSpec.Exceptions =
            llvm::ArrayRef(exceptionTypes).copy(Ctx);
      }
    }
 
    if (returnType.getAsOpaquePtr() == T->getReturnType().getAsOpaquePtr() &&
        !paramChanged && !exceptionChanged)
      return QualType(T, 0);
 
    return Ctx.getFunctionType(returnType, paramTypes, info);
  }
 
  QualType VisitParenType(const ParenType *T) {
    QualType innerType = recurse(T->getInnerType());
    if (innerType.isNull())
      return {};
 
    if (innerType.getAsOpaquePtr() == T->getInnerType().getAsOpaquePtr())
      return QualType(T, 0);
 
    return Ctx.getParenType(innerType);
  }
 
  SUGARED_TYPE_CLASS(Typedef)
  SUGARED_TYPE_CLASS(ObjCTypeParam)
  SUGARED_TYPE_CLASS(MacroQualified)
 
  QualType VisitAdjustedType(const AdjustedType *T) {
    QualType originalType = recurse(T->getOriginalType());
    if (originalType.isNull())
      return {};
 
    QualType adjustedType = recurse(T->getAdjustedType());
    if (adjustedType.isNull())
      return {};
 
    if (originalType.getAsOpaquePtr() ==
            T->getOriginalType().getAsOpaquePtr() &&
        adjustedType.getAsOpaquePtr() == T->getAdjustedType().getAsOpaquePtr())
      return QualType(T, 0);
 
    return Ctx.getAdjustedType(originalType, adjustedType);
  }
 
  QualType VisitDecayedType(const DecayedType *T) {
    QualType originalType = recurse(T->getOriginalType());
    if (originalType.isNull())
      return {};
 
    if (originalType.getAsOpaquePtr() == T->getOriginalType().getAsOpaquePtr())
      return QualType(T, 0);
 
    return Ctx.getDecayedType(originalType);
  }
 
  QualType VisitArrayParameterType(const ArrayParameterType *T) {
    QualType ArrTy = VisitConstantArrayType(T);
    if (ArrTy.isNull())
      return {};
 
    return Ctx.getArrayParameterType(ArrTy);
  }
 
  SUGARED_TYPE_CLASS(TypeOfExpr)
  SUGARED_TYPE_CLASS(TypeOf)
  SUGARED_TYPE_CLASS(Decltype)
  SUGARED_TYPE_CLASS(UnaryTransform)
  TRIVIAL_TYPE_CLASS(Record)
  TRIVIAL_TYPE_CLASS(Enum)
 
  QualType VisitAttributedType(const AttributedType *T) {
    QualType modifiedType = recurse(T->getModifiedType());
    if (modifiedType.isNull())
      return {};
 
    QualType equivalentType = recurse(T->getEquivalentType());
    if (equivalentType.isNull())
      return {};
 
    if (modifiedType.getAsOpaquePtr() ==
            T->getModifiedType().getAsOpaquePtr() &&
        equivalentType.getAsOpaquePtr() ==
            T->getEquivalentType().getAsOpaquePtr())
      return QualType(T, 0);
 
    return Ctx.getAttributedType(T->getAttrKind(), modifiedType, equivalentType,
                                 T->getAttr());
  }
 
  QualType VisitSubstTemplateTypeParmType(const SubstTemplateTypeParmType *T) {
    QualType replacementType = recurse(T->getReplacementType());
    if (replacementType.isNull())
      return {};
 
    if (replacementType.getAsOpaquePtr() ==
        T->getReplacementType().getAsOpaquePtr())
      return QualType(T, 0);
 
    return Ctx.getSubstTemplateTypeParmType(
        replacementType, T->getAssociatedDecl(), T->getIndex(),
        T->getPackIndex(), T->getFinal());
  }
 
  // FIXME: Non-trivial to implement, but important for C++
  SUGARED_TYPE_CLASS(TemplateSpecialization)
 
  QualType VisitAutoType(const AutoType *T) {
    if (!T->isDeduced())
      return QualType(T, 0);
 
    QualType deducedType = recurse(T->getDeducedType());
    if (deducedType.isNull())
      return {};
 
    if (deducedType == T->getDeducedType())
      return QualType(T, 0);
 
    return Ctx.getAutoType(T->getDeducedKind(), deducedType, T->getKeyword(),
                           T->getTypeConstraintConcept(),
                           T->getTypeConstraintArguments());
  }
 
  QualType VisitObjCObjectType(const ObjCObjectType *T) {
    QualType baseType = recurse(T->getBaseType());
    if (baseType.isNull())
      return {};
 
    // Transform type arguments.
    bool typeArgChanged = false;
    SmallVector<QualType, 4> typeArgs;
    for (auto typeArg : T->getTypeArgsAsWritten()) {
      QualType newTypeArg = recurse(typeArg);
      if (newTypeArg.isNull())
        return {};
 
      if (newTypeArg.getAsOpaquePtr() != typeArg.getAsOpaquePtr())
        typeArgChanged = true;
 
      typeArgs.push_back(newTypeArg);
    }
 
    if (baseType.getAsOpaquePtr() == T->getBaseType().getAsOpaquePtr() &&
        !typeArgChanged)
      return QualType(T, 0);
 
    return Ctx.getObjCObjectType(
        baseType, typeArgs,
        llvm::ArrayRef(T->qual_begin(), T->getNumProtocols()),
        T->isKindOfTypeAsWritten());
  }
 
  TRIVIAL_TYPE_CLASS(ObjCInterface)
 
  QualType VisitObjCObjectPointerType(const ObjCObjectPointerType *T) {
    QualType pointeeType = recurse(T->getPointeeType());
    if (pointeeType.isNull())
      return {};
 
    if (pointeeType.getAsOpaquePtr() == T->getPointeeType().getAsOpaquePtr())
      return QualType(T, 0);
 
    return Ctx.getObjCObjectPointerType(pointeeType);
  }
 
  QualType VisitAtomicType(const AtomicType *T) {
    QualType valueType = recurse(T->getValueType());
    if (valueType.isNull())
      return {};
 
    if (valueType.getAsOpaquePtr() == T->getValueType().getAsOpaquePtr())
      return QualType(T, 0);
 
    return Ctx.getAtomicType(valueType);
  }
 
#undef TRIVIAL_TYPE_CLASS
#undef SUGARED_TYPE_CLASS
};
 
struct SubstObjCTypeArgsVisitor
    : public SimpleTransformVisitor<SubstObjCTypeArgsVisitor> {
  using BaseType = SimpleTransformVisitor<SubstObjCTypeArgsVisitor>;
 
  ArrayRef<QualType> TypeArgs;
  ObjCSubstitutionContext SubstContext;
 
  SubstObjCTypeArgsVisitor(ASTContext &ctx, ArrayRef<QualType> typeArgs,
                           ObjCSubstitutionContext context)
      : BaseType(ctx), TypeArgs(typeArgs), SubstContext(context) {}
 
  QualType VisitObjCTypeParamType(const ObjCTypeParamType *OTPTy) {
    // Replace an Objective-C type parameter reference with the corresponding
    // type argument.
    ObjCTypeParamDecl *typeParam = OTPTy->getDecl();
    // If we have type arguments, use them.
    if (!TypeArgs.empty()) {
      QualType argType = TypeArgs[typeParam->getIndex()];
      if (OTPTy->qual_empty())
        return argType;
 
      // Apply protocol lists if exists.
      bool hasError;
      SmallVector<ObjCProtocolDecl *, 8> protocolsVec;
      protocolsVec.append(OTPTy->qual_begin(), OTPTy->qual_end());
      ArrayRef<ObjCProtocolDecl *> protocolsToApply = protocolsVec;
      return Ctx.applyObjCProtocolQualifiers(
          argType, protocolsToApply, hasError, true /*allowOnPointerType*/);
    }
 
    switch (SubstContext) {
    case ObjCSubstitutionContext::Ordinary:
    case ObjCSubstitutionContext::Parameter:
    case ObjCSubstitutionContext::Superclass:
      // Substitute the bound.
      return typeParam->getUnderlyingType();
 
    case ObjCSubstitutionContext::Result:
    case ObjCSubstitutionContext::Property: {
      // Substitute the __kindof form of the underlying type.
      const auto *objPtr =
          typeParam->getUnderlyingType()->castAs<ObjCObjectPointerType>();
 
      // __kindof types, id, and Class don't need an additional
      // __kindof.
      if (objPtr->isKindOfType() || objPtr->isObjCIdOrClassType())
        return typeParam->getUnderlyingType();
 
      // Add __kindof.
      const auto *obj = objPtr->getObjectType();
      QualType resultTy = Ctx.getObjCObjectType(
          obj->getBaseType(), obj->getTypeArgsAsWritten(), obj->getProtocols(),
          /*isKindOf=*/true);
 
      // Rebuild object pointer type.
      return Ctx.getObjCObjectPointerType(resultTy);
    }
    }
    llvm_unreachable("Unexpected ObjCSubstitutionContext!");
  }
 
  QualType VisitFunctionType(const FunctionType *funcType) {
    // If we have a function type, update the substitution context
    // appropriately.
 
    // Substitute result type.
    QualType returnType = funcType->getReturnType().substObjCTypeArgs(
        Ctx, TypeArgs, ObjCSubstitutionContext::Result);
    if (returnType.isNull())
      return {};
 
    // Handle non-prototyped functions, which only substitute into the result
    // type.
    if (isa<FunctionNoProtoType>(funcType)) {
      // If the return type was unchanged, do nothing.
      if (returnType.getAsOpaquePtr() ==
          funcType->getReturnType().getAsOpaquePtr())
        return BaseType::VisitFunctionType(funcType);
 
      // Otherwise, build a new type.
      return Ctx.getFunctionNoProtoType(returnType, funcType->getExtInfo());
    }
 
    const auto *funcProtoType = cast<FunctionProtoType>(funcType);
 
    // Transform parameter types.
    SmallVector<QualType, 4> paramTypes;
    bool paramChanged = false;
    for (auto paramType : funcProtoType->getParamTypes()) {
      QualType newParamType = paramType.substObjCTypeArgs(
          Ctx, TypeArgs, ObjCSubstitutionContext::Parameter);
      if (newParamType.isNull())
        return {};
 
      if (newParamType.getAsOpaquePtr() != paramType.getAsOpaquePtr())
        paramChanged = true;
 
      paramTypes.push_back(newParamType);
    }
 
    // Transform extended info.
    FunctionProtoType::ExtProtoInfo info = funcProtoType->getExtProtoInfo();
    bool exceptionChanged = false;
    if (info.ExceptionSpec.Type == EST_Dynamic) {
      SmallVector<QualType, 4> exceptionTypes;
      for (auto exceptionType : info.ExceptionSpec.Exceptions) {
        QualType newExceptionType = exceptionType.substObjCTypeArgs(
            Ctx, TypeArgs, ObjCSubstitutionContext::Ordinary);
        if (newExceptionType.isNull())
          return {};
 
        if (newExceptionType.getAsOpaquePtr() != exceptionType.getAsOpaquePtr())
          exceptionChanged = true;
 
        exceptionTypes.push_back(newExceptionType);
      }
 
      if (exceptionChanged) {
        info.ExceptionSpec.Exceptions =
            llvm::ArrayRef(exceptionTypes).copy(Ctx);
      }
    }
 
    if (returnType.getAsOpaquePtr() ==
            funcProtoType->getReturnType().getAsOpaquePtr() &&
        !paramChanged && !exceptionChanged)
      return BaseType::VisitFunctionType(funcType);
 
    return Ctx.getFunctionType(returnType, paramTypes, info);
  }
 
  QualType VisitObjCObjectType(const ObjCObjectType *objcObjectType) {
    // Substitute into the type arguments of a specialized Objective-C object
    // type.
    if (objcObjectType->isSpecializedAsWritten()) {
      SmallVector<QualType, 4> newTypeArgs;
      bool anyChanged = false;
      for (auto typeArg : objcObjectType->getTypeArgsAsWritten()) {
        QualType newTypeArg = typeArg.substObjCTypeArgs(
            Ctx, TypeArgs, ObjCSubstitutionContext::Ordinary);
        if (newTypeArg.isNull())
          return {};
 
        if (newTypeArg.getAsOpaquePtr() != typeArg.getAsOpaquePtr()) {
          // If we're substituting based on an unspecialized context type,
          // produce an unspecialized type.
          ArrayRef<ObjCProtocolDecl *> protocols(
              objcObjectType->qual_begin(), objcObjectType->getNumProtocols());
          if (TypeArgs.empty() &&
              SubstContext != ObjCSubstitutionContext::Superclass) {
            return Ctx.getObjCObjectType(
                objcObjectType->getBaseType(), {}, protocols,
                objcObjectType->isKindOfTypeAsWritten());
          }
 
          anyChanged = true;
        }
 
        newTypeArgs.push_back(newTypeArg);
      }
 
      if (anyChanged) {
        ArrayRef<ObjCProtocolDecl *> protocols(
            objcObjectType->qual_begin(), objcObjectType->getNumProtocols());
        return Ctx.getObjCObjectType(objcObjectType->getBaseType(), newTypeArgs,
                                     protocols,
                                     objcObjectType->isKindOfTypeAsWritten());
      }
    }
 
    return BaseType::VisitObjCObjectType(objcObjectType);
  }
 
  QualType VisitAttributedType(const AttributedType *attrType) {
    QualType newType = BaseType::VisitAttributedType(attrType);
    if (newType.isNull())
      return {};
 
    const auto *newAttrType = dyn_cast<AttributedType>(newType.getTypePtr());
    if (!newAttrType || newAttrType->getAttrKind() != attr::ObjCKindOf)
      return newType;
 
    // Find out if it's an Objective-C object or object pointer type;
    QualType newEquivType = newAttrType->getEquivalentType();
    const ObjCObjectPointerType *ptrType =
        newEquivType->getAs<ObjCObjectPointerType>();
    const ObjCObjectType *objType = ptrType
                                        ? ptrType->getObjectType()
                                        : newEquivType->getAs<ObjCObjectType>();
    if (!objType)
      return newType;
 
    // Rebuild the "equivalent" type, which pushes __kindof down into
    // the object type.
    newEquivType = Ctx.getObjCObjectType(
        objType->getBaseType(), objType->getTypeArgsAsWritten(),
        objType->getProtocols(),
        // There is no need to apply kindof on an unqualified id type.
        /*isKindOf=*/objType->isObjCUnqualifiedId() ? false : true);
 
    // If we started with an object pointer type, rebuild it.
    if (ptrType)
      newEquivType = Ctx.getObjCObjectPointerType(newEquivType);
 
    // Rebuild the attributed type.
    return Ctx.getAttributedType(newAttrType->getAttrKind(),
                                 newAttrType->getModifiedType(), newEquivType,
                                 newAttrType->getAttr());
  }
};
 
struct StripObjCKindOfTypeVisitor
    : public SimpleTransformVisitor<StripObjCKindOfTypeVisitor> {
  using BaseType = SimpleTransformVisitor<StripObjCKindOfTypeVisitor>;
 
  explicit StripObjCKindOfTypeVisitor(ASTContext &ctx) : BaseType(ctx) {}
 
  QualType VisitObjCObjectType(const ObjCObjectType *objType) {
    if (!objType->isKindOfType())
      return BaseType::VisitObjCObjectType(objType);
 
    QualType baseType = objType->getBaseType().stripObjCKindOfType(Ctx);
    return Ctx.getObjCObjectType(baseType, objType->getTypeArgsAsWritten(),
                                 objType->getProtocols(),
                                 /*isKindOf=*/false);
  }
};
 
} // namespace
 
bool QualType::UseExcessPrecision(const ASTContext &Ctx) {
  const BuiltinType *BT = getTypePtr()->getAs<BuiltinType>();
  if (!BT) {
    const VectorType *VT = getTypePtr()->getAs<VectorType>();
    if (VT) {
      QualType ElementType = VT->getElementType();
      return ElementType.UseExcessPrecision(Ctx);
    }
  } else {
    switch (BT->getKind()) {
    case BuiltinType::Kind::Float16: {
      const TargetInfo &TI = Ctx.getTargetInfo();
      if (TI.hasFloat16Type() && !TI.hasFastHalfType() &&
          Ctx.getLangOpts().getFloat16ExcessPrecision() !=
              Ctx.getLangOpts().ExcessPrecisionKind::FPP_None)
        return true;
      break;
    }
    case BuiltinType::Kind::BFloat16: {
      const TargetInfo &TI = Ctx.getTargetInfo();
      if (TI.hasBFloat16Type() && !TI.hasFullBFloat16Type() &&
          Ctx.getLangOpts().getBFloat16ExcessPrecision() !=
              Ctx.getLangOpts().ExcessPrecisionKind::FPP_None)
        return true;
      break;
    }
    default:
      return false;
    }
  }
  return false;
}
 
/// Substitute the given type arguments for Objective-C type
/// parameters within the given type, recursively.
QualType QualType::substObjCTypeArgs(ASTContext &ctx,
                                     ArrayRef<QualType> typeArgs,
                                     ObjCSubstitutionContext context) const {
  SubstObjCTypeArgsVisitor visitor(ctx, typeArgs, context);
  return visitor.recurse(*this);
}
 
QualType QualType::substObjCMemberType(QualType objectType,
                                       const DeclContext *dc,
                                       ObjCSubstitutionContext context) const {
  if (auto subs = objectType->getObjCSubstitutions(dc))
    return substObjCTypeArgs(dc->getParentASTContext(), *subs, context);
 
  return *this;
}
 
QualType QualType::stripObjCKindOfType(const ASTContext &constCtx) const {
  // FIXME: Because ASTContext::getAttributedType() is non-const.
  auto &ctx = const_cast<ASTContext &>(constCtx);
  StripObjCKindOfTypeVisitor visitor(ctx);
  return visitor.recurse(*this);
}
 
QualType QualType::getAtomicUnqualifiedType() const {
  QualType T = *this;
  if (const auto AT = T.getTypePtr()->getAs<AtomicType>())
    T = AT->getValueType();
  return T.getUnqualifiedType();
}
 
std::optional<ArrayRef<QualType>>
Type::getObjCSubstitutions(const DeclContext *dc) const {
  // Look through method scopes.
  if (const auto method = dyn_cast<ObjCMethodDecl>(dc))
    dc = method->getDeclContext();
 
  // Find the class or category in which the type we're substituting
  // was declared.
  const auto *dcClassDecl = dyn_cast<ObjCInterfaceDecl>(dc);
  const ObjCCategoryDecl *dcCategoryDecl = nullptr;
  ObjCTypeParamList *dcTypeParams = nullptr;
  if (dcClassDecl) {
    // If the class does not have any type parameters, there's no
    // substitution to do.
    dcTypeParams = dcClassDecl->getTypeParamList();
    if (!dcTypeParams)
      return std::nullopt;
  } else {
    // If we are in neither a class nor a category, there's no
    // substitution to perform.
    dcCategoryDecl = dyn_cast<ObjCCategoryDecl>(dc);
    if (!dcCategoryDecl)
      return std::nullopt;
 
    // If the category does not have any type parameters, there's no
    // substitution to do.
    dcTypeParams = dcCategoryDecl->getTypeParamList();
    if (!dcTypeParams)
      return std::nullopt;
 
    dcClassDecl = dcCategoryDecl->getClassInterface();
    if (!dcClassDecl)
      return std::nullopt;
  }
  assert(dcTypeParams && "No substitutions to perform");
  assert(dcClassDecl && "No class context");
 
  // Find the underlying object type.
  const ObjCObjectType *objectType;
  if (const auto *objectPointerType = getAs<ObjCObjectPointerType>()) {
    objectType = objectPointerType->getObjectType();
  } else if (getAs<BlockPointerType>()) {
    ASTContext &ctx = dc->getParentASTContext();
    objectType = ctx.getObjCObjectType(ctx.ObjCBuiltinIdTy, {}, {})
                     ->castAs<ObjCObjectType>();
  } else {
    objectType = getAs<ObjCObjectType>();
  }
 
  /// Extract the class from the receiver object type.
  ObjCInterfaceDecl *curClassDecl =
      objectType ? objectType->getInterface() : nullptr;
  if (!curClassDecl) {
    // If we don't have a context type (e.g., this is "id" or some
    // variant thereof), substitute the bounds.
    return llvm::ArrayRef<QualType>();
  }
 
  // Follow the superclass chain until we've mapped the receiver type
  // to the same class as the context.
  while (curClassDecl != dcClassDecl) {
    // Map to the superclass type.
    QualType superType = objectType->getSuperClassType();
    if (superType.isNull()) {
      objectType = nullptr;
      break;
    }
 
    objectType = superType->castAs<ObjCObjectType>();
    curClassDecl = objectType->getInterface();
  }
 
  // If we don't have a receiver type, or the receiver type does not
  // have type arguments, substitute in the defaults.
  if (!objectType || objectType->isUnspecialized()) {
    return llvm::ArrayRef<QualType>();
  }
 
  // The receiver type has the type arguments we want.
  return objectType->getTypeArgs();
}
 
bool Type::acceptsObjCTypeParams() const {
  if (auto *IfaceT = getAsObjCInterfaceType()) {
    if (auto *ID = IfaceT->getInterface()) {
      if (ID->getTypeParamList())
        return true;
    }
  }
 
  return false;
}
 
void ObjCObjectType::computeSuperClassTypeSlow() const {
  // Retrieve the class declaration for this type. If there isn't one
  // (e.g., this is some variant of "id" or "Class"), then there is no
  // superclass type.
  ObjCInterfaceDecl *classDecl = getInterface();
  if (!classDecl) {
    CachedSuperClassType.setInt(true);
    return;
  }
 
  // Extract the superclass type.
  const ObjCObjectType *superClassObjTy = classDecl->getSuperClassType();
  if (!superClassObjTy) {
    CachedSuperClassType.setInt(true);
    return;
  }
 
  ObjCInterfaceDecl *superClassDecl = superClassObjTy->getInterface();
  if (!superClassDecl) {
    CachedSuperClassType.setInt(true);
    return;
  }
 
  // If the superclass doesn't have type parameters, then there is no
  // substitution to perform.
  QualType superClassType(superClassObjTy, 0);
  ObjCTypeParamList *superClassTypeParams = superClassDecl->getTypeParamList();
  if (!superClassTypeParams) {
    CachedSuperClassType.setPointerAndInt(
        superClassType->castAs<ObjCObjectType>(), true);
    return;
  }
 
  // If the superclass reference is unspecialized, return it.
  if (superClassObjTy->isUnspecialized()) {
    CachedSuperClassType.setPointerAndInt(superClassObjTy, true);
    return;
  }
 
  // If the subclass is not parameterized, there aren't any type
  // parameters in the superclass reference to substitute.
  ObjCTypeParamList *typeParams = classDecl->getTypeParamList();
  if (!typeParams) {
    CachedSuperClassType.setPointerAndInt(
        superClassType->castAs<ObjCObjectType>(), true);
    return;
  }
 
  // If the subclass type isn't specialized, return the unspecialized
  // superclass.
  if (isUnspecialized()) {
    QualType unspecializedSuper =
        classDecl->getASTContext().getObjCInterfaceType(
            superClassObjTy->getInterface());
    CachedSuperClassType.setPointerAndInt(
        unspecializedSuper->castAs<ObjCObjectType>(), true);
    return;
  }
 
  // Substitute the provided type arguments into the superclass type.
  ArrayRef<QualType> typeArgs = getTypeArgs();
  assert(typeArgs.size() == typeParams->size());
  CachedSuperClassType.setPointerAndInt(
      superClassType
          .substObjCTypeArgs(classDecl->getASTContext(), typeArgs,
                             ObjCSubstitutionContext::Superclass)
          ->castAs<ObjCObjectType>(),
      true);
}
 
const ObjCInterfaceType *ObjCObjectPointerType::getInterfaceType() const {
  if (auto interfaceDecl = getObjectType()->getInterface()) {
    return interfaceDecl->getASTContext()
        .getObjCInterfaceType(interfaceDecl)
        ->castAs<ObjCInterfaceType>();
  }
 
  return nullptr;
}
 
QualType ObjCObjectPointerType::getSuperClassType() const {
  QualType superObjectType = getObjectType()->getSuperClassType();
  if (superObjectType.isNull())
    return superObjectType;
 
  ASTContext &ctx = getInterfaceDecl()->getASTContext();
  return ctx.getObjCObjectPointerType(superObjectType);
}
 
const ObjCObjectType *Type::getAsObjCQualifiedInterfaceType() const {
  // There is no sugar for ObjCObjectType's, just return the canonical
  // type pointer if it is the right class.  There is no typedef information to
  // return and these cannot be Address-space qualified.
  if (const auto *T = getAs<ObjCObjectType>())
    if (T->getNumProtocols() && T->getInterface())
      return T;
  return nullptr;
}
 
bool Type::isObjCQualifiedInterfaceType() const {
  return getAsObjCQualifiedInterfaceType() != nullptr;
}
 
const ObjCObjectPointerType *Type::getAsObjCQualifiedIdType() const {
  // There is no sugar for ObjCQualifiedIdType's, just return the canonical
  // type pointer if it is the right class.
  if (const auto *OPT = getAs<ObjCObjectPointerType>()) {
    if (OPT->isObjCQualifiedIdType())
      return OPT;
  }
  return nullptr;
}
 
const ObjCObjectPointerType *Type::getAsObjCQualifiedClassType() const {
  // There is no sugar for ObjCQualifiedClassType's, just return the canonical
  // type pointer if it is the right class.
  if (const auto *OPT = getAs<ObjCObjectPointerType>()) {
    if (OPT->isObjCQualifiedClassType())
      return OPT;
  }
  return nullptr;
}
 
const ObjCObjectType *Type::getAsObjCInterfaceType() const {
  if (const auto *OT = getAs<ObjCObjectType>()) {
    if (OT->getInterface())
      return OT;
  }
  return nullptr;
}
 
const ObjCObjectPointerType *Type::getAsObjCInterfacePointerType() const {
  if (const auto *OPT = getAs<ObjCObjectPointerType>()) {
    if (OPT->getInterfaceType())
      return OPT;
  }
  return nullptr;
}
 
const CXXRecordDecl *Type::getPointeeCXXRecordDecl() const {
  QualType PointeeType;
  if (const auto *PT = getAsCanonical<PointerType>())
    PointeeType = PT->getPointeeType();
  else if (const auto *RT = getAsCanonical<ReferenceType>())
    PointeeType = RT->getPointeeType();
  else
    return nullptr;
  return PointeeType->getAsCXXRecordDecl();
}
 
const TemplateSpecializationType *
Type::getAsNonAliasTemplateSpecializationType() const {
  const auto *TST = getAs<TemplateSpecializationType>();
  while (TST && TST->isTypeAlias())
    TST = TST->desugar()->getAs<TemplateSpecializationType>();
  return TST;
}
 
NestedNameSpecifier Type::getPrefix() const {
  switch (getTypeClass()) {
  case Type::DependentName:
    return cast<DependentNameType>(this)->getQualifier();
  case Type::TemplateSpecialization:
    return cast<TemplateSpecializationType>(this)
        ->getTemplateName()
        .getQualifier();
  case Type::Enum:
  case Type::Record:
  case Type::InjectedClassName:
    return cast<TagType>(this)->getQualifier();
  case Type::Typedef:
    return cast<TypedefType>(this)->getQualifier();
  case Type::UnresolvedUsing:
    return cast<UnresolvedUsingType>(this)->getQualifier();
  case Type::Using:
    return cast<UsingType>(this)->getQualifier();
  default:
    return std::nullopt;
  }
}
 
bool Type::hasAttr(attr::Kind AK) const {
  const Type *Cur = this;
  while (const auto *AT = Cur->getAs<AttributedType>()) {
    if (AT->getAttrKind() == AK)
      return true;
    Cur = AT->getEquivalentType().getTypePtr();
  }
  return false;
}
 
namespace {
 
class GetContainedDeducedTypeVisitor
    : public TypeVisitor<GetContainedDeducedTypeVisitor, Type *> {
  bool Syntactic;
 
public:
  GetContainedDeducedTypeVisitor(bool Syntactic = false)
      : Syntactic(Syntactic) {}
 
  using TypeVisitor<GetContainedDeducedTypeVisitor, Type *>::Visit;
 
  Type *Visit(QualType T) {
    if (T.isNull())
      return nullptr;
    return Visit(T.getTypePtr());
  }
 
  // The deduced type itself.
  Type *VisitDeducedType(const DeducedType *AT) {
    return const_cast<DeducedType *>(AT);
  }
 
  // Only these types can contain the desired 'auto' type.
  Type *VisitSubstTemplateTypeParmType(const SubstTemplateTypeParmType *T) {
    return Visit(T->getReplacementType());
  }
 
  Type *VisitPointerType(const PointerType *T) {
    return Visit(T->getPointeeType());
  }
 
  Type *VisitBlockPointerType(const BlockPointerType *T) {
    return Visit(T->getPointeeType());
  }
 
  Type *VisitReferenceType(const ReferenceType *T) {
    return Visit(T->getPointeeTypeAsWritten());
  }
 
  Type *VisitMemberPointerType(const MemberPointerType *T) {
    return Visit(T->getPointeeType());
  }
 
  Type *VisitArrayType(const ArrayType *T) {
    return Visit(T->getElementType());
  }
 
  Type *VisitDependentSizedExtVectorType(const DependentSizedExtVectorType *T) {
    return Visit(T->getElementType());
  }
 
  Type *VisitVectorType(const VectorType *T) {
    return Visit(T->getElementType());
  }
 
  Type *VisitDependentSizedMatrixType(const DependentSizedMatrixType *T) {
    return Visit(T->getElementType());
  }
 
  Type *VisitConstantMatrixType(const ConstantMatrixType *T) {
    return Visit(T->getElementType());
  }
 
  Type *VisitFunctionProtoType(const FunctionProtoType *T) {
    if (Syntactic && T->hasTrailingReturn())
      return const_cast<FunctionProtoType *>(T);
    return VisitFunctionType(T);
  }
 
  Type *VisitFunctionType(const FunctionType *T) {
    return Visit(T->getReturnType());
  }
 
  Type *VisitParenType(const ParenType *T) { return Visit(T->getInnerType()); }
 
  Type *VisitAttributedType(const AttributedType *T) {
    return Visit(T->getModifiedType());
  }
 
  Type *VisitMacroQualifiedType(const MacroQualifiedType *T) {
    return Visit(T->getUnderlyingType());
  }
 
  Type *VisitOverflowBehaviorType(const OverflowBehaviorType *T) {
    return Visit(T->getUnderlyingType());
  }
 
  Type *VisitAdjustedType(const AdjustedType *T) {
    return Visit(T->getOriginalType());
  }
 
  Type *VisitPackExpansionType(const PackExpansionType *T) {
    return Visit(T->getPattern());
  }
};
 
} // namespace
 
DeducedType *Type::getContainedDeducedType() const {
  return cast_or_null<DeducedType>(
      GetContainedDeducedTypeVisitor().Visit(this));
}
 
bool Type::hasAutoForTrailingReturnType() const {
  return isa_and_nonnull<FunctionType>(
      GetContainedDeducedTypeVisitor(true).Visit(this));
}
 
bool Type::hasIntegerRepresentation() const {
  if (const auto *VT = dyn_cast<VectorType>(CanonicalType))
    return VT->getElementType()->isIntegerType();
  if (CanonicalType->isSveVLSBuiltinType()) {
    const auto *VT = cast<BuiltinType>(CanonicalType);
    return VT->getKind() == BuiltinType::SveBool ||
           (VT->getKind() >= BuiltinType::SveInt8 &&
            VT->getKind() <= BuiltinType::SveUint64);
  }
  if (CanonicalType->isRVVVLSBuiltinType()) {
    const auto *VT = cast<BuiltinType>(CanonicalType);
    return (VT->getKind() >= BuiltinType::RvvInt8mf8 &&
            VT->getKind() <= BuiltinType::RvvUint64m8);
  }
 
  return isIntegerType();
}
 
/// Determine whether this type is an integral type.
///
/// This routine determines whether the given type is an integral type per
/// C++ [basic.fundamental]p7. Although the C standard does not define the
/// term "integral type", it has a similar term "integer type", and in C++
/// the two terms are equivalent. However, C's "integer type" includes
/// enumeration types, while C++'s "integer type" does not. The \c ASTContext
/// parameter is used to determine whether we should be following the C or
/// C++ rules when determining whether this type is an integral/integer type.
///
/// For cases where C permits "an integer type" and C++ permits "an integral
/// type", use this routine.
///
/// For cases where C permits "an integer type" and C++ permits "an integral
/// or enumeration type", use \c isIntegralOrEnumerationType() instead.
///
/// \param Ctx The context in which this type occurs.
///
/// \returns true if the type is considered an integral type, false otherwise.
bool Type::isIntegralType(const ASTContext &Ctx) const {
  if (const auto *BT = dyn_cast<BuiltinType>(CanonicalType))
    return BT->isInteger();
 
  // Complete enum types are integral in C.
  if (!Ctx.getLangOpts().CPlusPlus) {
    if (const auto *ET = dyn_cast<EnumType>(CanonicalType))
      return IsEnumDeclComplete(ET->getDecl());
 
    if (const OverflowBehaviorType *OBT =
            dyn_cast<OverflowBehaviorType>(CanonicalType))
      return OBT->getUnderlyingType()->isIntegralOrEnumerationType();
  }
 
  return isBitIntType();
}
 
bool Type::isIntegralOrUnscopedEnumerationType() const {
  if (const auto *BT = dyn_cast<BuiltinType>(CanonicalType))
    return BT->isInteger();
 
  if (const auto *OBT = dyn_cast<OverflowBehaviorType>(CanonicalType))
    return OBT->getUnderlyingType()->isIntegerType();
 
  if (isBitIntType())
    return true;
 
  return isUnscopedEnumerationType();
}
 
bool Type::isUnscopedEnumerationType() const {
  if (const auto *ET = dyn_cast<EnumType>(CanonicalType))
    return !ET->getDecl()->isScoped();
 
  return false;
}
 
bool Type::isCharType() const {
  if (const auto *BT = dyn_cast<BuiltinType>(CanonicalType))
    return BT->getKind() == BuiltinType::Char_U ||
           BT->getKind() == BuiltinType::UChar ||
           BT->getKind() == BuiltinType::Char_S ||
           BT->getKind() == BuiltinType::SChar;
  return false;
}
 
bool Type::isWideCharType() const {
  if (const auto *BT = dyn_cast<BuiltinType>(CanonicalType))
    return BT->getKind() == BuiltinType::WChar_S ||
           BT->getKind() == BuiltinType::WChar_U;
  return false;
}
 
bool Type::isChar8Type() const {
  if (const BuiltinType *BT = dyn_cast<BuiltinType>(CanonicalType))
    return BT->getKind() == BuiltinType::Char8;
  return false;
}
 
bool Type::isChar16Type() const {
  if (const auto *BT = dyn_cast<BuiltinType>(CanonicalType))
    return BT->getKind() == BuiltinType::Char16;
  return false;
}
 
bool Type::isChar32Type() const {
  if (const auto *BT = dyn_cast<BuiltinType>(CanonicalType))
    return BT->getKind() == BuiltinType::Char32;
  return false;
}
 
/// Determine whether this type is any of the built-in character
/// types.
bool Type::isAnyCharacterType() const {
  const auto *BT = dyn_cast<BuiltinType>(CanonicalType);
  if (!BT)
    return false;
  switch (BT->getKind()) {
  default:
    return false;
  case BuiltinType::Char_U:
  case BuiltinType::UChar:
  case BuiltinType::WChar_U:
  case BuiltinType::Char8:
  case BuiltinType::Char16:
  case BuiltinType::Char32:
  case BuiltinType::Char_S:
  case BuiltinType::SChar:
  case BuiltinType::WChar_S:
    return true;
  }
}
 
bool Type::isUnicodeCharacterType() const {
  const auto *BT = dyn_cast<BuiltinType>(CanonicalType);
  if (!BT)
    return false;
  switch (BT->getKind()) {
  default:
    return false;
  case BuiltinType::Char8:
  case BuiltinType::Char16:
  case BuiltinType::Char32:
    return true;
  }
}
 
/// isSignedIntegerType - Return true if this is an integer type that is
/// signed, according to C99 6.2.5p4 [char, signed char, short, int, long..],
/// an enum decl which has a signed representation
bool Type::isSignedIntegerType() const {
  if (const auto *BT = dyn_cast<BuiltinType>(CanonicalType))
    return BT->isSignedInteger();
 
  if (const auto *ED = getAsEnumDecl()) {
    // Incomplete enum types are not treated as integer types.
    // FIXME: In C++, enum types are never integer types.
    if (!ED->isComplete() || ED->isScoped())
      return false;
    return ED->getIntegerType()->isSignedIntegerType();
  }
 
  if (const auto *IT = dyn_cast<BitIntType>(CanonicalType))
    return IT->isSigned();
  if (const auto *IT = dyn_cast<DependentBitIntType>(CanonicalType))
    return IT->isSigned();
 
  if (const auto *OBT = dyn_cast<OverflowBehaviorType>(CanonicalType))
    return OBT->getUnderlyingType()->isSignedIntegerType();
 
  return false;
}
 
bool Type::isSignedIntegerOrEnumerationType() const {
  if (const auto *BT = dyn_cast<BuiltinType>(CanonicalType))
    return BT->isSignedInteger();
 
  if (const auto *ED = getAsEnumDecl()) {
    if (!ED->isComplete())
      return false;
    return ED->getIntegerType()->isSignedIntegerType();
  }
 
  if (const auto *IT = dyn_cast<BitIntType>(CanonicalType))
    return IT->isSigned();
  if (const auto *IT = dyn_cast<DependentBitIntType>(CanonicalType))
    return IT->isSigned();
 
  if (const auto *OBT = dyn_cast<OverflowBehaviorType>(CanonicalType))
    return OBT->getUnderlyingType()->isSignedIntegerOrEnumerationType();
 
  return false;
}
 
bool Type::hasSignedIntegerRepresentation() const {
  if (const auto *VT = dyn_cast<VectorType>(CanonicalType))
    return VT->getElementType()->isSignedIntegerOrEnumerationType();
 
  if (const auto *BT = dyn_cast<BuiltinType>(CanonicalType)) {
    switch (BT->getKind()) {
#define SVE_VECTOR_TYPE_INT(Name, MangledName, Id, SingletonId, NumEls,        \
                            ElBits, NF, IsSigned)                              \
  case BuiltinType::Id:                                                        \
    return IsSigned;
#include "clang/Basic/AArch64ACLETypes.def"
    default:
      break;
    }
  }
 
  return isSignedIntegerOrEnumerationType();
}
 
/// isUnsignedIntegerType - Return true if this is an integer type that is
/// unsigned, according to C99 6.2.5p6 [which returns true for _Bool], an enum
/// decl which has an unsigned representation
bool Type::isUnsignedIntegerType() const {
  if (const auto *BT = dyn_cast<BuiltinType>(CanonicalType))
    return BT->isUnsignedInteger();
 
  if (const auto *ED = getAsEnumDecl()) {
    // Incomplete enum types are not treated as integer types.
    // FIXME: In C++, enum types are never integer types.
    if (!ED->isComplete() || ED->isScoped())
      return false;
    return ED->getIntegerType()->isUnsignedIntegerType();
  }
 
  if (const auto *IT = dyn_cast<BitIntType>(CanonicalType))
    return IT->isUnsigned();
  if (const auto *IT = dyn_cast<DependentBitIntType>(CanonicalType))
    return IT->isUnsigned();
 
  if (const auto *OBT = dyn_cast<OverflowBehaviorType>(CanonicalType))
    return OBT->getUnderlyingType()->isUnsignedIntegerType();
 
  return false;
}
 
bool Type::isUnsignedIntegerOrEnumerationType() const {
  if (const auto *BT = dyn_cast<BuiltinType>(CanonicalType))
    return BT->isUnsignedInteger();
 
  if (const auto *ED = getAsEnumDecl()) {
    if (!ED->isComplete())
      return false;
    return ED->getIntegerType()->isUnsignedIntegerType();
  }
 
  if (const auto *IT = dyn_cast<BitIntType>(CanonicalType))
    return IT->isUnsigned();
  if (const auto *IT = dyn_cast<DependentBitIntType>(CanonicalType))
    return IT->isUnsigned();
 
  if (const auto *OBT = dyn_cast<OverflowBehaviorType>(CanonicalType))
    return OBT->getUnderlyingType()->isUnsignedIntegerOrEnumerationType();
 
  return false;
}
 
bool Type::hasUnsignedIntegerRepresentation() const {
  if (const auto *VT = dyn_cast<VectorType>(CanonicalType))
    return VT->getElementType()->isUnsignedIntegerOrEnumerationType();
  if (const auto *VT = dyn_cast<MatrixType>(CanonicalType))
    return VT->getElementType()->isUnsignedIntegerOrEnumerationType();
  if (CanonicalType->isSveVLSBuiltinType()) {
    const auto *VT = cast<BuiltinType>(CanonicalType);
    return VT->getKind() >= BuiltinType::SveUint8 &&
           VT->getKind() <= BuiltinType::SveUint64;
  }
  return isUnsignedIntegerOrEnumerationType();
}
 
bool Type::isFloatingType() const {
  if (const auto *BT = dyn_cast<BuiltinType>(CanonicalType))
    return BT->isFloatingPoint();
  if (const auto *CT = dyn_cast<ComplexType>(CanonicalType))
    return CT->getElementType()->isFloatingType();
  return false;
}
 
bool Type::hasFloatingRepresentation() const {
  if (const auto *VT = dyn_cast<VectorType>(CanonicalType))
    return VT->getElementType()->isFloatingType();
  if (const auto *MT = dyn_cast<MatrixType>(CanonicalType))
    return MT->getElementType()->isFloatingType();
  return isFloatingType();
}
 
bool Type::isRealFloatingType() const {
  if (const auto *BT = dyn_cast<BuiltinType>(CanonicalType))
    return BT->isFloatingPoint();
  return false;
}
 
bool Type::isRealType() const {
  if (const auto *BT = dyn_cast<BuiltinType>(CanonicalType))
    return BT->getKind() >= BuiltinType::Bool &&
           BT->getKind() <= BuiltinType::Ibm128;
  if (const auto *ET = dyn_cast<EnumType>(CanonicalType)) {
    const auto *ED = ET->getDecl();
    return !ED->isScoped() && ED->getDefinitionOrSelf()->isComplete();
  }
  return isBitIntType();
}
 
bool Type::isArithmeticType() const {
  if (const auto *BT = dyn_cast<BuiltinType>(CanonicalType))
    return BT->getKind() >= BuiltinType::Bool &&
           BT->getKind() <= BuiltinType::Ibm128;
  if (const auto *ET = dyn_cast<EnumType>(CanonicalType)) {
    // GCC allows forward declaration of enum types (forbid by C99 6.7.2.3p2).
    // If a body isn't seen by the time we get here, return false.
    //
    // C++0x: Enumerations are not arithmetic types. For now, just return
    // false for scoped enumerations since that will disable any
    // unwanted implicit conversions.
    const auto *ED = ET->getDecl();
    return !ED->isScoped() && ED->getDefinitionOrSelf()->isComplete();
  }
 
  if (isOverflowBehaviorType() &&
      getAs<OverflowBehaviorType>()->getUnderlyingType()->isArithmeticType())
    return true;
 
  return isa<ComplexType>(CanonicalType) || isBitIntType();
}
 
bool Type::hasBooleanRepresentation() const {
  if (const auto *VT = dyn_cast<VectorType>(CanonicalType))
    return VT->getElementType()->isBooleanType();
  if (const auto *ED = getAsEnumDecl())
    return ED->isComplete() && ED->getIntegerType()->isBooleanType();
  if (const auto *IT = dyn_cast<BitIntType>(CanonicalType))
    return IT->getNumBits() == 1;
  return isBooleanType();
}
 
Type::ScalarTypeKind Type::getScalarTypeKind() const {
  assert(isScalarType());
 
  const Type *T = CanonicalType.getTypePtr();
  if (const auto *BT = dyn_cast<BuiltinType>(T)) {
    if (BT->getKind() == BuiltinType::Bool)
      return STK_Bool;
    if (BT->getKind() == BuiltinType::NullPtr)
      return STK_CPointer;
    if (BT->isInteger())
      return STK_Integral;
    if (BT->isFloatingPoint())
      return STK_Floating;
    if (BT->isFixedPointType())
      return STK_FixedPoint;
    llvm_unreachable("unknown scalar builtin type");
  } else if (isa<PointerType>(T)) {
    return STK_CPointer;
  } else if (isa<BlockPointerType>(T)) {
    return STK_BlockPointer;
  } else if (isa<ObjCObjectPointerType>(T)) {
    return STK_ObjCObjectPointer;
  } else if (isa<MemberPointerType>(T)) {
    return STK_MemberPointer;
  } else if (isa<EnumType>(T)) {
    assert(T->castAsEnumDecl()->isComplete());
    return STK_Integral;
  } else if (const auto *CT = dyn_cast<ComplexType>(T)) {
    if (CT->getElementType()->isRealFloatingType())
      return STK_FloatingComplex;
    return STK_IntegralComplex;
  } else if (isBitIntType()) {
    return STK_Integral;
  } else if (isa<OverflowBehaviorType>(T)) {
    return STK_Integral;
  }
 
  llvm_unreachable("unknown scalar type");
}
 
/// Determines whether the type is a C++ aggregate type or C
/// aggregate or union type.
///
/// An aggregate type is an array or a class type (struct, union, or
/// class) that has no user-declared constructors, no private or
/// protected non-static data members, no base classes, and no virtual
/// functions (C++ [dcl.init.aggr]p1). The notion of an aggregate type
/// subsumes the notion of C aggregates (C99 6.2.5p21) because it also
/// includes union types.
bool Type::isAggregateType() const {
  if (const auto *Record = dyn_cast<RecordType>(CanonicalType)) {
    if (const auto *ClassDecl = dyn_cast<CXXRecordDecl>(Record->getDecl()))
      return ClassDecl->isAggregate();
 
    return true;
  }
 
  return isa<ArrayType>(CanonicalType);
}
 
/// isConstantSizeType - Return true if this is not a variable sized type,
/// according to the rules of C99 6.7.5p3.  It is not legal to call this on
/// incomplete types or dependent types.
bool Type::isConstantSizeType() const {
  assert(!isIncompleteType() && "This doesn't make sense for incomplete types");
  assert(!isDependentType() && "This doesn't make sense for dependent types");
  // The VAT must have a size, as it is known to be complete.
  return !isa<VariableArrayType>(CanonicalType);
}
 
/// isIncompleteType - Return true if this is an incomplete type (C99 6.2.5p1)
/// - a type that can describe objects, but which lacks information needed to
/// determine its size.
bool Type::isIncompleteType(NamedDecl **Def) const {
  if (Def)
    *Def = nullptr;
 
  switch (CanonicalType->getTypeClass()) {
  default:
    return false;
  case Builtin:
    // Void is the only incomplete builtin type.  Per C99 6.2.5p19, it can never
    // be completed.
    return isVoidType();
  case Enum: {
    auto *EnumD = castAsEnumDecl();
    if (Def)
      *Def = EnumD;
    return !EnumD->isComplete();
  }
  case Record: {
    // A tagged type (struct/union/enum/class) is incomplete if the decl is a
    // forward declaration, but not a full definition (C99 6.2.5p22).
    auto *Rec = castAsRecordDecl();
    if (Def)
      *Def = Rec;
    return !Rec->isCompleteDefinition();
  }
  case InjectedClassName: {
    auto *Rec = castAsCXXRecordDecl();
    if (!Rec->isBeingDefined())
      return false;
    if (Def)
      *Def = Rec;
    return true;
  }
  case ConstantArray:
  case VariableArray:
    // An array is incomplete if its element type is incomplete
    // (C++ [dcl.array]p1).
    // We don't handle dependent-sized arrays (dependent types are never treated
    // as incomplete).
    return cast<ArrayType>(CanonicalType)
        ->getElementType()
        ->isIncompleteType(Def);
  case IncompleteArray:
    // An array of unknown size is an incomplete type (C99 6.2.5p22).
    return true;
  case MemberPointer: {
    // Member pointers in the MS ABI have special behavior in
    // RequireCompleteType: they attach a MSInheritanceAttr to the CXXRecordDecl
    // to indicate which inheritance model to use.
    // The inheritance attribute might only be present on the most recent
    // CXXRecordDecl.
    const CXXRecordDecl *RD =
        cast<MemberPointerType>(CanonicalType)->getMostRecentCXXRecordDecl();
    // Member pointers with dependent class types don't get special treatment.
    if (!RD || RD->isDependentType())
      return false;
    ASTContext &Context = RD->getASTContext();
    // Member pointers not in the MS ABI don't get special treatment.
    if (!Context.getTargetInfo().getCXXABI().isMicrosoft())
      return false;
    // Nothing interesting to do if the inheritance attribute is already set.
    if (RD->hasAttr<MSInheritanceAttr>())
      return false;
    return true;
  }
  case ObjCObject:
    return cast<ObjCObjectType>(CanonicalType)
        ->getBaseType()
        ->isIncompleteType(Def);
  case ObjCInterface: {
    // ObjC interfaces are incomplete if they are @class, not @interface.
    ObjCInterfaceDecl *Interface =
        cast<ObjCInterfaceType>(CanonicalType)->getDecl();
    if (Def)
      *Def = Interface;
    return !Interface->hasDefinition();
  }
  }
}
 
bool Type::isAlwaysIncompleteType() const {
  if (!isIncompleteType())
    return false;
 
  // Forward declarations of structs, classes, enums, and unions could be later
  // completed in a compilation unit by providing a type definition.
  if (isa<TagType>(CanonicalType))
    return false;
 
  // Other types are incompletable.
  //
  // E.g. `char[]` and `void`. The type is incomplete and no future
  // type declarations can make the type complete.
  return true;
}
 
bool Type::isSizelessBuiltinType() const {
  if (isSizelessVectorType())
    return true;
 
  if (const BuiltinType *BT = getAs<BuiltinType>()) {
    switch (BT->getKind()) {
      // WebAssembly reference types
#define WASM_TYPE(Name, Id, SingletonId) case BuiltinType::Id:
#include "clang/Basic/WebAssemblyReferenceTypes.def"
      // HLSL intangible types
#define HLSL_INTANGIBLE_TYPE(Name, Id, SingletonId) case BuiltinType::Id:
#include "clang/Basic/HLSLIntangibleTypes.def"
      // AMDGPU feature predicate type
    case BuiltinType::AMDGPUFeaturePredicate:
      return true;
    default:
      return false;
    }
  }
  return false;
}
 
bool Type::isWebAssemblyExternrefType() const {
  if (const auto *BT = getAs<BuiltinType>())
    return BT->getKind() == BuiltinType::WasmExternRef;
  return false;
}
 
bool Type::isWebAssemblyTableType() const {
  if (const auto *ATy = dyn_cast<ArrayType>(this))
    return ATy->getElementType().isWebAssemblyReferenceType();
 
  if (const auto *PTy = dyn_cast<PointerType>(this))
    return PTy->getPointeeType().isWebAssemblyReferenceType();
 
  return false;
}
 
bool Type::isSizelessType() const { return isSizelessBuiltinType(); }
 
bool Type::isSizelessVectorType() const {
  return isSVESizelessBuiltinType() || isRVVSizelessBuiltinType();
}
 
bool Type::isSVESizelessBuiltinType() const {
  if (const BuiltinType *BT = getAs<BuiltinType>()) {
    switch (BT->getKind()) {
      // SVE Types
#define SVE_VECTOR_TYPE(Name, MangledName, Id, SingletonId)                    \
  case BuiltinType::Id:                                                        \
    return true;
#define SVE_OPAQUE_TYPE(Name, MangledName, Id, SingletonId)                    \
  case BuiltinType::Id:                                                        \
    return true;
#define SVE_PREDICATE_TYPE(Name, MangledName, Id, SingletonId)                 \
  case BuiltinType::Id:                                                        \
    return true;
#include "clang/Basic/AArch64ACLETypes.def"
    default:
      return false;
    }
  }
  return false;
}
 
bool Type::isRVVSizelessBuiltinType() const {
  if (const BuiltinType *BT = getAs<BuiltinType>()) {
    switch (BT->getKind()) {
#define RVV_TYPE(Name, Id, SingletonId) case BuiltinType::Id:
#include "clang/Basic/RISCVVTypes.def"
      return true;
    default:
      return false;
    }
  }
  return false;
}
 
bool Type::isSveVLSBuiltinType() const {
  if (const BuiltinType *BT = getAs<BuiltinType>()) {
    switch (BT->getKind()) {
    case BuiltinType::SveInt8:
    case BuiltinType::SveInt16:
    case BuiltinType::SveInt32:
    case BuiltinType::SveInt64:
    case BuiltinType::SveUint8:
    case BuiltinType::SveUint16:
    case BuiltinType::SveUint32:
    case BuiltinType::SveUint64:
    case BuiltinType::SveFloat16:
    case BuiltinType::SveFloat32:
    case BuiltinType::SveFloat64:
    case BuiltinType::SveBFloat16:
    case BuiltinType::SveBool:
    case BuiltinType::SveBoolx2:
    case BuiltinType::SveBoolx4:
    case BuiltinType::SveMFloat8:
      return true;
    default:
      return false;
    }
  }
  return false;
}
 
QualType Type::getSizelessVectorEltType(const ASTContext &Ctx) const {
  assert(isSizelessVectorType() && "Must be sizeless vector type");
  // Currently supports SVE and RVV
  if (isSVESizelessBuiltinType())
    return getSveEltType(Ctx);
 
  if (isRVVSizelessBuiltinType())
    return getRVVEltType(Ctx);
 
  llvm_unreachable("Unhandled type");
}
 
QualType Type::getSveEltType(const ASTContext &Ctx) const {
  assert(isSveVLSBuiltinType() && "unsupported type!");
 
  const BuiltinType *BTy = castAs<BuiltinType>();
  if (BTy->getKind() == BuiltinType::SveBool)
    // Represent predicates as i8 rather than i1 to avoid any layout issues.
    // The type is bitcasted to a scalable predicate type when casting between
    // scalable and fixed-length vectors.
    return Ctx.UnsignedCharTy;
  else
    return Ctx.getBuiltinVectorTypeInfo(BTy).ElementType;
}
 
bool Type::isRVVVLSBuiltinType() const {
  if (const BuiltinType *BT = getAs<BuiltinType>()) {
    switch (BT->getKind()) {
#define RVV_VECTOR_TYPE(Name, Id, SingletonId, NumEls, ElBits, NF, IsSigned,   \
                        IsFP, IsBF)                                            \
  case BuiltinType::Id:                                                        \
    return NF == 1;
#define RVV_PREDICATE_TYPE(Name, Id, SingletonId, NumEls)                      \
  case BuiltinType::Id:                                                        \
    return true;
#include "clang/Basic/RISCVVTypes.def"
    default:
      return false;
    }
  }
  return false;
}
 
QualType Type::getRVVEltType(const ASTContext &Ctx) const {
  assert(isRVVVLSBuiltinType() && "unsupported type!");
 
  const BuiltinType *BTy = castAs<BuiltinType>();
 
  switch (BTy->getKind()) {
#define RVV_PREDICATE_TYPE(Name, Id, SingletonId, NumEls)                      \
  case BuiltinType::Id:                                                        \
    return Ctx.UnsignedCharTy;
  default:
    return Ctx.getBuiltinVectorTypeInfo(BTy).ElementType;
#include "clang/Basic/RISCVVTypes.def"
  }
 
  llvm_unreachable("Unhandled type");
}
 
bool QualType::isPODType(const ASTContext &Context) const {
  // C++11 has a more relaxed definition of POD.
  if (Context.getLangOpts().CPlusPlus11)
    return isCXX11PODType(Context);
 
  return isCXX98PODType(Context);
}
 
bool QualType::isCXX98PODType(const ASTContext &Context) const {
  // The compiler shouldn't query this for incomplete types, but the user might.
  // We return false for that case. Except for incomplete arrays of PODs, which
  // are PODs according to the standard.
  if (isNull())
    return false;
 
  if ((*this)->isIncompleteArrayType())
    return Context.getBaseElementType(*this).isCXX98PODType(Context);
 
  if ((*this)->isIncompleteType())
    return false;
 
  if (hasNonTrivialObjCLifetime())
    return false;
 
  QualType CanonicalType = getTypePtr()->CanonicalType;
 
  // Any type that is, or contains, address discriminated data is never POD.
  if (Context.containsAddressDiscriminatedPointerAuth(CanonicalType))
    return false;
 
  switch (CanonicalType->getTypeClass()) {
    // Everything not explicitly mentioned is not POD.
  default:
    return false;
  case Type::VariableArray:
  case Type::ConstantArray:
    // IncompleteArray is handled above.
    return Context.getBaseElementType(*this).isCXX98PODType(Context);
 
  case Type::ObjCObjectPointer:
  case Type::BlockPointer:
  case Type::Builtin:
  case Type::Complex:
  case Type::Pointer:
  case Type::MemberPointer:
  case Type::Vector:
  case Type::ExtVector:
  case Type::BitInt:
  case Type::OverflowBehavior:
    return true;
 
  case Type::Enum:
    return true;
 
  case Type::Record:
    if (const auto *ClassDecl =
            dyn_cast<CXXRecordDecl>(cast<RecordType>(CanonicalType)->getDecl()))
      return ClassDecl->isPOD();
 
    // C struct/union is POD.
    return true;
  }
}
 
bool QualType::isTrivialType(const ASTContext &Context) const {
  // The compiler shouldn't query this for incomplete types, but the user might.
  // We return false for that case. Except for incomplete arrays of PODs, which
  // are PODs according to the standard.
  if (isNull())
    return false;
 
  if ((*this)->isArrayType())
    return Context.getBaseElementType(*this).isTrivialType(Context);
 
  if ((*this)->isSizelessBuiltinType())
    return true;
 
  // Return false for incomplete types after skipping any incomplete array
  // types which are expressly allowed by the standard and thus our API.
  if ((*this)->isIncompleteType())
    return false;
 
  if (hasNonTrivialObjCLifetime())
    return false;
 
  QualType CanonicalType = getTypePtr()->CanonicalType;
  if (CanonicalType->isDependentType())
    return false;
 
  // Any type that is, or contains, address discriminated data is never a
  // trivial type.
  if (Context.containsAddressDiscriminatedPointerAuth(CanonicalType))
    return false;
 
  // C++0x [basic.types]p9:
  //   Scalar types, trivial class types, arrays of such types, and
  //   cv-qualified versions of these types are collectively called trivial
  //   types.
 
  // As an extension, Clang treats vector types as Scalar types.
  if (CanonicalType->isScalarType() || CanonicalType->isVectorType())
    return true;
 
  if (const auto *ClassDecl = CanonicalType->getAsCXXRecordDecl()) {
    // C++20 [class]p6:
    //   A trivial class is a class that is trivially copyable, and
    //     has one or more eligible default constructors such that each is
    //     trivial.
    // FIXME: We should merge this definition of triviality into
    // CXXRecordDecl::isTrivial. Currently it computes the wrong thing.
    return ClassDecl->hasTrivialDefaultConstructor() &&
           !ClassDecl->hasNonTrivialDefaultConstructor() &&
           ClassDecl->isTriviallyCopyable();
  }
 
  if (isa<RecordType>(CanonicalType))
    return true;
 
  // No other types can match.
  return false;
}
 
static bool isTriviallyCopyableTypeImpl(const QualType &type,
                                        const ASTContext &Context,
                                        bool IsCopyConstructible) {
  if (type->isArrayType())
    return isTriviallyCopyableTypeImpl(Context.getBaseElementType(type),
                                       Context, IsCopyConstructible);
 
  if (type.hasNonTrivialObjCLifetime())
    return false;
 
  // C++11 [basic.types]p9 - See Core 2094
  //   Scalar types, trivially copyable class types, arrays of such types, and
  //   cv-qualified versions of these types are collectively
  //   called trivially copy constructible types.
 
  QualType CanonicalType = type.getCanonicalType();
  if (CanonicalType->isDependentType())
    return false;
 
  if (CanonicalType->isSizelessBuiltinType())
    return true;
 
  // Return false for incomplete types after skipping any incomplete array types
  // which are expressly allowed by the standard and thus our API.
  if (CanonicalType->isIncompleteType())
    return false;
 
  if (CanonicalType.hasAddressDiscriminatedPointerAuth())
    return false;
 
  // As an extension, Clang treats vector and matrix types as Scalar types.
  if (CanonicalType->isScalarType() || CanonicalType->isVectorType() ||
      CanonicalType->isMatrixType())
    return true;
 
  // Mfloat8 type is a special case as it not scalar, but is still trivially
  // copyable.
  if (CanonicalType->isMFloat8Type())
    return true;
 
  if (const auto *RD = CanonicalType->getAsRecordDecl()) {
    if (const auto *ClassDecl = dyn_cast<CXXRecordDecl>(RD)) {
      if (IsCopyConstructible)
        return ClassDecl->isTriviallyCopyConstructible();
      return ClassDecl->isTriviallyCopyable();
    }
    return !RD->isNonTrivialToPrimitiveCopy();
  }
  // No other types can match.
  return false;
}
 
bool QualType::isTriviallyCopyableType(const ASTContext &Context) const {
  return isTriviallyCopyableTypeImpl(*this, Context,
                                     /*IsCopyConstructible=*/false);
}
 
// FIXME: each call will trigger a full computation, cache the result.
bool QualType::isBitwiseCloneableType(const ASTContext &Context) const {
  auto CanonicalType = getCanonicalType();
  if (CanonicalType.hasNonTrivialObjCLifetime())
    return false;
  if (CanonicalType->isArrayType())
    return Context.getBaseElementType(CanonicalType)
        .isBitwiseCloneableType(Context);
 
  if (CanonicalType->isIncompleteType())
    return false;
 
  // Any type that is, or contains, address discriminated data is never
  // bitwise clonable.
  if (Context.containsAddressDiscriminatedPointerAuth(CanonicalType))
    return false;
 
  const auto *RD = CanonicalType->getAsRecordDecl(); // struct/union/class
  if (!RD)
    return true;
 
  if (RD->isInvalidDecl())
    return false;
 
  // Never allow memcpy when we're adding poisoned padding bits to the struct.
  // Accessing these posioned bits will trigger false alarms on
  // SanitizeAddressFieldPadding etc.
  if (RD->mayInsertExtraPadding())
    return false;
 
  for (auto *const Field : RD->fields()) {
    if (!Field->getType().isBitwiseCloneableType(Context))
      return false;
  }
 
  if (const auto *CXXRD = dyn_cast<CXXRecordDecl>(RD)) {
    for (auto Base : CXXRD->bases())
      if (!Base.getType().isBitwiseCloneableType(Context))
        return false;
    for (auto VBase : CXXRD->vbases())
      if (!VBase.getType().isBitwiseCloneableType(Context))
        return false;
  }
  return true;
}
 
bool QualType::isTriviallyCopyConstructibleType(
    const ASTContext &Context) const {
  return isTriviallyCopyableTypeImpl(*this, Context,
                                     /*IsCopyConstructible=*/true);
}
 
bool QualType::isNonWeakInMRRWithObjCWeak(const ASTContext &Context) const {
  return !Context.getLangOpts().ObjCAutoRefCount &&
         Context.getLangOpts().ObjCWeak &&
         getObjCLifetime() != Qualifiers::OCL_Weak;
}
 
bool QualType::hasNonTrivialToPrimitiveDefaultInitializeCUnion(
    const RecordDecl *RD) {
  return RD->hasNonTrivialToPrimitiveDefaultInitializeCUnion();
}
 
bool QualType::hasNonTrivialToPrimitiveDestructCUnion(const RecordDecl *RD) {
  return RD->hasNonTrivialToPrimitiveDestructCUnion();
}
 
bool QualType::hasNonTrivialToPrimitiveCopyCUnion(const RecordDecl *RD) {
  return RD->hasNonTrivialToPrimitiveCopyCUnion();
}
 
bool QualType::isWebAssemblyReferenceType() const {
  return isWebAssemblyExternrefType() || isWebAssemblyFuncrefType();
}
 
bool QualType::isWebAssemblyExternrefType() const {
  return getTypePtr()->isWebAssemblyExternrefType();
}
 
bool QualType::isWebAssemblyFuncrefType() const {
  return getTypePtr()->isFunctionPointerType() &&
         (getTypePtr()->getPointeeType().getAddressSpace() ==
          LangAS::wasm_funcref);
}
 
bool QualType::isWrapType() const {
  if (const auto *OBT = getCanonicalType()->getAs<OverflowBehaviorType>())
    return OBT->getBehaviorKind() ==
           OverflowBehaviorType::OverflowBehaviorKind::Wrap;
 
  return false;
}
 
bool QualType::isTrapType() const {
  if (const auto *OBT = getCanonicalType()->getAs<OverflowBehaviorType>())
    return OBT->getBehaviorKind() ==
           OverflowBehaviorType::OverflowBehaviorKind::Trap;
 
  return false;
}
 
QualType::PrimitiveDefaultInitializeKind
QualType::isNonTrivialToPrimitiveDefaultInitialize() const {
  if (const auto *RD =
          getTypePtr()->getBaseElementTypeUnsafe()->getAsRecordDecl())
    if (RD->isNonTrivialToPrimitiveDefaultInitialize())
      return PDIK_Struct;
 
  switch (getQualifiers().getObjCLifetime()) {
  case Qualifiers::OCL_Strong:
    return PDIK_ARCStrong;
  case Qualifiers::OCL_Weak:
    return PDIK_ARCWeak;
  default:
    return PDIK_Trivial;
  }
}
 
QualType::PrimitiveCopyKind QualType::isNonTrivialToPrimitiveCopy() const {
  if (const auto *RD =
          getTypePtr()->getBaseElementTypeUnsafe()->getAsRecordDecl())
    if (RD->isNonTrivialToPrimitiveCopy())
      return PCK_Struct;
 
  Qualifiers Qs = getQualifiers();
  switch (Qs.getObjCLifetime()) {
  case Qualifiers::OCL_Strong:
    return PCK_ARCStrong;
  case Qualifiers::OCL_Weak:
    return PCK_ARCWeak;
  default:
    if (hasAddressDiscriminatedPointerAuth())
      return PCK_PtrAuth;
    return Qs.hasVolatile() ? PCK_VolatileTrivial : PCK_Trivial;
  }
}
 
QualType::PrimitiveCopyKind
QualType::isNonTrivialToPrimitiveDestructiveMove() const {
  return isNonTrivialToPrimitiveCopy();
}
 
bool Type::isLiteralType(const ASTContext &Ctx) const {
  if (isDependentType())
    return false;
 
  // C++1y [basic.types]p10:
  //   A type is a literal type if it is:
  //   -- cv void; or
  if (Ctx.getLangOpts().CPlusPlus14 && isVoidType())
    return true;
 
  // C++11 [basic.types]p10:
  //   A type is a literal type if it is:
  //   [...]
  //   -- an array of literal type other than an array of runtime bound; or
  if (isVariableArrayType())
    return false;
  const Type *BaseTy = getBaseElementTypeUnsafe();
  assert(BaseTy && "NULL element type");
 
  // Return false for incomplete types after skipping any incomplete array
  // types; those are expressly allowed by the standard and thus our API.
  if (BaseTy->isIncompleteType())
    return false;
 
  // C++11 [basic.types]p10:
  //   A type is a literal type if it is:
  //    -- a scalar type; or
  // As an extension, Clang treats vector types and complex types as
  // literal types.
  if (BaseTy->isScalarType() || BaseTy->isVectorType() ||
      BaseTy->isAnyComplexType())
    return true;
  // Matrices with constant numbers of rows and columns are also literal types
  // in HLSL.
  if (Ctx.getLangOpts().HLSL && BaseTy->isConstantMatrixType())
    return true;
  //    -- a reference type; or
  if (BaseTy->isReferenceType())
    return true;
  //    -- a class type that has all of the following properties:
  if (const auto *RD = BaseTy->getAsRecordDecl()) {
    //    -- a trivial destructor,
    //    -- every constructor call and full-expression in the
    //       brace-or-equal-initializers for non-static data members (if any)
    //       is a constant expression,
    //    -- it is an aggregate type or has at least one constexpr
    //       constructor or constructor template that is not a copy or move
    //       constructor, and
    //    -- all non-static data members and base classes of literal types
    //
    // We resolve DR1361 by ignoring the second bullet.
    if (const auto *ClassDecl = dyn_cast<CXXRecordDecl>(RD))
      return ClassDecl->isLiteral();
 
    return true;
  }
 
  // We treat _Atomic T as a literal type if T is a literal type.
  if (const auto *AT = BaseTy->getAs<AtomicType>())
    return AT->getValueType()->isLiteralType(Ctx);
 
  if (const auto *OBT = BaseTy->getAs<OverflowBehaviorType>())
    return OBT->getUnderlyingType()->isLiteralType(Ctx);
 
  // If this type hasn't been deduced yet, then conservatively assume that
  // it'll work out to be a literal type.
  if (isa<AutoType>(BaseTy->getCanonicalTypeInternal()))
    return true;
 
  return false;
}
 
bool Type::isStructuralType() const {
  // C++20 [temp.param]p6:
  //   A structural type is one of the following:
  //   -- a scalar type; or
  //   -- a vector type [Clang extension]; or
  if (isScalarType() || isVectorType())
    return true;
  //   -- an lvalue reference type; or
  if (isLValueReferenceType())
    return true;
  //  -- a literal class type [...under some conditions]
  if (const CXXRecordDecl *RD = getAsCXXRecordDecl())
    return RD->isStructural();
  return false;
}
 
bool Type::isStandardLayoutType() const {
  if (isDependentType())
    return false;
 
  // C++0x [basic.types]p9:
  //   Scalar types, standard-layout class types, arrays of such types, and
  //   cv-qualified versions of these types are collectively called
  //   standard-layout types.
  const Type *BaseTy = getBaseElementTypeUnsafe();
  assert(BaseTy && "NULL element type");
 
  // Return false for incomplete types after skipping any incomplete array
  // types which are expressly allowed by the standard and thus our API.
  if (BaseTy->isIncompleteType())
    return false;
 
  // As an extension, Clang treats vector types as Scalar types.
  if (BaseTy->isScalarType() || BaseTy->isVectorType())
    return true;
  if (const auto *RD = BaseTy->getAsRecordDecl()) {
    if (const auto *ClassDecl = dyn_cast<CXXRecordDecl>(RD);
        ClassDecl && !ClassDecl->isStandardLayout())
      return false;
 
    // Default to 'true' for non-C++ class types.
    // FIXME: This is a bit dubious, but plain C structs should trivially meet
    // all the requirements of standard layout classes.
    return true;
  }
 
  // No other types can match.
  return false;
}
 
// This is effectively the intersection of isTrivialType and
// isStandardLayoutType. We implement it directly to avoid redundant
// conversions from a type to a CXXRecordDecl.
bool QualType::isCXX11PODType(const ASTContext &Context) const {
  const Type *ty = getTypePtr();
  if (ty->isDependentType())
    return false;
 
  if (hasNonTrivialObjCLifetime())
    return false;
 
  // C++11 [basic.types]p9:
  //   Scalar types, POD classes, arrays of such types, and cv-qualified
  //   versions of these types are collectively called trivial types.
  const Type *BaseTy = ty->getBaseElementTypeUnsafe();
  assert(BaseTy && "NULL element type");
 
  if (BaseTy->isSizelessBuiltinType())
    return true;
 
  // Return false for incomplete types after skipping any incomplete array
  // types which are expressly allowed by the standard and thus our API.
  if (BaseTy->isIncompleteType())
    return false;
 
  // Any type that is, or contains, address discriminated data is non-POD.
  if (Context.containsAddressDiscriminatedPointerAuth(*this))
    return false;
 
  // As an extension, Clang treats vector types as Scalar types.
  if (BaseTy->isScalarType() || BaseTy->isVectorType())
    return true;
  if (const auto *RD = BaseTy->getAsRecordDecl()) {
    if (const auto *ClassDecl = dyn_cast<CXXRecordDecl>(RD)) {
      // C++11 [class]p10:
      //   A POD struct is a non-union class that is both a trivial class [...]
      if (!ClassDecl->isTrivial())
        return false;
 
      // C++11 [class]p10:
      //   A POD struct is a non-union class that is both a trivial class and
      //   a standard-layout class [...]
      if (!ClassDecl->isStandardLayout())
        return false;
 
      // C++11 [class]p10:
      //   A POD struct is a non-union class that is both a trivial class and
      //   a standard-layout class, and has no non-static data members of type
      //   non-POD struct, non-POD union (or array of such types). [...]
      //
      // We don't directly query the recursive aspect as the requirements for
      // both standard-layout classes and trivial classes apply recursively
      // already.
    }
 
    return true;
  }
 
  // No other types can match.
  return false;
}
 
bool Type::isNothrowT() const {
  if (const auto *RD = getAsCXXRecordDecl()) {
    IdentifierInfo *II = RD->getIdentifier();
    if (II && II->isStr("nothrow_t") && RD->isInStdNamespace())
      return true;
  }
  return false;
}
 
bool Type::isAlignValT() const {
  if (const auto *ET = getAsCanonical<EnumType>()) {
    const auto *ED = ET->getDecl();
    IdentifierInfo *II = ED->getIdentifier();
    if (II && II->isStr("align_val_t") && ED->isInStdNamespace())
      return true;
  }
  return false;
}
 
bool Type::isStdByteType() const {
  if (const auto *ET = getAsCanonical<EnumType>()) {
    const auto *ED = ET->getDecl();
    IdentifierInfo *II = ED->getIdentifier();
    if (II && II->isStr("byte") && ED->isInStdNamespace())
      return true;
  }
  return false;
}
 
bool Type::isSpecifierType() const {
  // Note that this intentionally does not use the canonical type.
  switch (getTypeClass()) {
  case Builtin:
  case Record:
  case Enum:
  case Typedef:
  case Complex:
  case TypeOfExpr:
  case TypeOf:
  case TemplateTypeParm:
  case SubstTemplateTypeParm:
  case TemplateSpecialization:
  case DependentName:
  case ObjCInterface:
  case ObjCObject:
    return true;
  default:
    return false;
  }
}
 
ElaboratedTypeKeyword KeywordHelpers::getKeywordForTypeSpec(unsigned TypeSpec) {
  switch (TypeSpec) {
  default:
    return ElaboratedTypeKeyword::None;
  case TST_typename:
    return ElaboratedTypeKeyword::Typename;
  case TST_class:
    return ElaboratedTypeKeyword::Class;
  case TST_struct:
    return ElaboratedTypeKeyword::Struct;
  case TST_interface:
    return ElaboratedTypeKeyword::Interface;
  case TST_union:
    return ElaboratedTypeKeyword::Union;
  case TST_enum:
    return ElaboratedTypeKeyword::Enum;
  }
}
 
TagTypeKind KeywordHelpers::getTagTypeKindForTypeSpec(unsigned TypeSpec) {
  switch (TypeSpec) {
  case TST_class:
    return TagTypeKind::Class;
  case TST_struct:
    return TagTypeKind::Struct;
  case TST_interface:
    return TagTypeKind::Interface;
  case TST_union:
    return TagTypeKind::Union;
  case TST_enum:
    return TagTypeKind::Enum;
  }
 
  llvm_unreachable("Type specifier is not a tag type kind.");
}
 
ElaboratedTypeKeyword
KeywordHelpers::getKeywordForTagTypeKind(TagTypeKind Kind) {
  switch (Kind) {
  case TagTypeKind::Class:
    return ElaboratedTypeKeyword::Class;
  case TagTypeKind::Struct:
    return ElaboratedTypeKeyword::Struct;
  case TagTypeKind::Interface:
    return ElaboratedTypeKeyword::Interface;
  case TagTypeKind::Union:
    return ElaboratedTypeKeyword::Union;
  case TagTypeKind::Enum:
    return ElaboratedTypeKeyword::Enum;
  }
  llvm_unreachable("Unknown tag type kind.");
}
 
TagTypeKind
KeywordHelpers::getTagTypeKindForKeyword(ElaboratedTypeKeyword Keyword) {
  switch (Keyword) {
  case ElaboratedTypeKeyword::Class:
    return TagTypeKind::Class;
  case ElaboratedTypeKeyword::Struct:
    return TagTypeKind::Struct;
  case ElaboratedTypeKeyword::Interface:
    return TagTypeKind::Interface;
  case ElaboratedTypeKeyword::Union:
    return TagTypeKind::Union;
  case ElaboratedTypeKeyword::Enum:
    return TagTypeKind::Enum;
  case ElaboratedTypeKeyword::None: // Fall through.
  case ElaboratedTypeKeyword::Typename:
    llvm_unreachable("Elaborated type keyword is not a tag type kind.");
  }
  llvm_unreachable("Unknown elaborated type keyword.");
}
 
bool KeywordHelpers::KeywordIsTagTypeKind(ElaboratedTypeKeyword Keyword) {
  switch (Keyword) {
  case ElaboratedTypeKeyword::None:
  case ElaboratedTypeKeyword::Typename:
    return false;
  case ElaboratedTypeKeyword::Class:
  case ElaboratedTypeKeyword::Struct:
  case ElaboratedTypeKeyword::Interface:
  case ElaboratedTypeKeyword::Union:
  case ElaboratedTypeKeyword::Enum:
    return true;
  }
  llvm_unreachable("Unknown elaborated type keyword.");
}
 
StringRef KeywordHelpers::getKeywordName(ElaboratedTypeKeyword Keyword) {
  switch (Keyword) {
  case ElaboratedTypeKeyword::None:
    return {};
  case ElaboratedTypeKeyword::Typename:
    return "typename";
  case ElaboratedTypeKeyword::Class:
    return "class";
  case ElaboratedTypeKeyword::Struct:
    return "struct";
  case ElaboratedTypeKeyword::Interface:
    return "__interface";
  case ElaboratedTypeKeyword::Union:
    return "union";
  case ElaboratedTypeKeyword::Enum:
    return "enum";
  }
 
  llvm_unreachable("Unknown elaborated type keyword.");
}
 
bool Type::isElaboratedTypeSpecifier() const {
  ElaboratedTypeKeyword Keyword;
  if (const auto *TST = dyn_cast<TemplateSpecializationType>(this))
    Keyword = TST->getKeyword();
  else if (const auto *DepName = dyn_cast<DependentNameType>(this))
    Keyword = DepName->getKeyword();
  else if (const auto *T = dyn_cast<TagType>(this))
    Keyword = T->getKeyword();
  else if (const auto *T = dyn_cast<TypedefType>(this))
    Keyword = T->getKeyword();
  else if (const auto *T = dyn_cast<UnresolvedUsingType>(this))
    Keyword = T->getKeyword();
  else if (const auto *T = dyn_cast<UsingType>(this))
    Keyword = T->getKeyword();
  else
    return false;
 
  return TypeWithKeyword::KeywordIsTagTypeKind(Keyword);
}
 
const char *Type::getTypeClassName() const {
  switch (TypeBits.TC) {
#define ABSTRACT_TYPE(Derived, Base)
#define TYPE(Derived, Base)                                                    \
  case Derived:                                                                \
    return #Derived;
#include "clang/AST/TypeNodes.inc"
  }
 
  llvm_unreachable("Invalid type class.");
}
 
StringRef BuiltinType::getName(const PrintingPolicy &Policy) const {
  switch (getKind()) {
  case Void:
    return "void";
  case Bool:
    return Policy.Bool ? "bool" : "_Bool";
  case Char_S:
    return "char";
  case Char_U:
    return "char";
  case SChar:
    return "signed char";
  case Short:
    return "short";
  case Int:
    return "int";
  case Long:
    return "long";
  case LongLong:
    return "long long";
  case Int128:
    return "__int128";
  case UChar:
    return "unsigned char";
  case UShort:
    return "unsigned short";
  case UInt:
    return "unsigned int";
  case ULong:
    return "unsigned long";
  case ULongLong:
    return "unsigned long long";
  case UInt128:
    return "unsigned __int128";
  case Half:
    return Policy.Half ? "half" : "__fp16";
  case BFloat16:
    return "__bf16";
  case Float:
    return "float";
  case Double:
    return "double";
  case LongDouble:
    return "long double";
  case ShortAccum:
    return "short _Accum";
  case Accum:
    return "_Accum";
  case LongAccum:
    return "long _Accum";
  case UShortAccum:
    return "unsigned short _Accum";
  case UAccum:
    return "unsigned _Accum";
  case ULongAccum:
    return "unsigned long _Accum";
  case BuiltinType::ShortFract:
    return "short _Fract";
  case BuiltinType::Fract:
    return "_Fract";
  case BuiltinType::LongFract:
    return "long _Fract";
  case BuiltinType::UShortFract:
    return "unsigned short _Fract";
  case BuiltinType::UFract:
    return "unsigned _Fract";
  case BuiltinType::ULongFract:
    return "unsigned long _Fract";
  case BuiltinType::SatShortAccum:
    return "_Sat short _Accum";
  case BuiltinType::SatAccum:
    return "_Sat _Accum";
  case BuiltinType::SatLongAccum:
    return "_Sat long _Accum";
  case BuiltinType::SatUShortAccum:
    return "_Sat unsigned short _Accum";
  case BuiltinType::SatUAccum:
    return "_Sat unsigned _Accum";
  case BuiltinType::SatULongAccum:
    return "_Sat unsigned long _Accum";
  case BuiltinType::SatShortFract:
    return "_Sat short _Fract";
  case BuiltinType::SatFract:
    return "_Sat _Fract";
  case BuiltinType::SatLongFract:
    return "_Sat long _Fract";
  case BuiltinType::SatUShortFract:
    return "_Sat unsigned short _Fract";
  case BuiltinType::SatUFract:
    return "_Sat unsigned _Fract";
  case BuiltinType::SatULongFract:
    return "_Sat unsigned long _Fract";
  case Float16:
    return "_Float16";
  case Float128:
    return "__float128";
  case Ibm128:
    return "__ibm128";
  case WChar_S:
  case WChar_U:
    return Policy.MSWChar ? "__wchar_t" : "wchar_t";
  case Char8:
    return "char8_t";
  case Char16:
    return "char16_t";
  case Char32:
    return "char32_t";
  case NullPtr:
    return Policy.NullptrTypeInNamespace ? "std::nullptr_t" : "nullptr_t";
  case Overload:
    return "<overloaded function type>";
  case BoundMember:
    return "<bound member function type>";
  case UnresolvedTemplate:
    return "<unresolved template type>";
  case PseudoObject:
    return "<pseudo-object type>";
  case Dependent:
    return "<dependent type>";
  case UnknownAny:
    return "<unknown type>";
  case ARCUnbridgedCast:
    return "<ARC unbridged cast type>";
  case BuiltinFn:
    return "<builtin fn type>";
  case ObjCId:
    return "id";
  case ObjCClass:
    return "Class";
  case ObjCSel:
    return "SEL";
#define IMAGE_TYPE(ImgType, Id, SingletonId, Access, Suffix)                   \
  case Id:                                                                     \
    return "__" #Access " " #ImgType "_t";
#include "clang/Basic/OpenCLImageTypes.def"
  case OCLSampler:
    return "sampler_t";
  case OCLEvent:
    return "event_t";
  case OCLClkEvent:
    return "clk_event_t";
  case OCLQueue:
    return "queue_t";
  case OCLReserveID:
    return "reserve_id_t";
  case IncompleteMatrixIdx:
    return "<incomplete matrix index type>";
  case ArraySection:
    return "<array section type>";
  case OMPArrayShaping:
    return "<OpenMP array shaping type>";
  case OMPIterator:
    return "<OpenMP iterator type>";
#define EXT_OPAQUE_TYPE(ExtType, Id, Ext)                                      \
  case Id:                                                                     \
    return #ExtType;
#include "clang/Basic/OpenCLExtensionTypes.def"
#define SVE_TYPE(Name, Id, SingletonId)                                        \
  case Id:                                                                     \
    return #Name;
#include "clang/Basic/AArch64ACLETypes.def"
#define PPC_VECTOR_TYPE(Name, Id, Size)                                        \
  case Id:                                                                     \
    return #Name;
#include "clang/Basic/PPCTypes.def"
#define RVV_TYPE(Name, Id, SingletonId)                                        \
  case Id:                                                                     \
    return Name;
#include "clang/Basic/RISCVVTypes.def"
#define WASM_TYPE(Name, Id, SingletonId)                                       \
  case Id:                                                                     \
    return Name;
#include "clang/Basic/WebAssemblyReferenceTypes.def"
#define AMDGPU_TYPE(Name, Id, SingletonId, Width, Align)                       \
  case Id:                                                                     \
    return Name;
#include "clang/Basic/AMDGPUTypes.def"
#define HLSL_INTANGIBLE_TYPE(Name, Id, SingletonId)                            \
  case Id:                                                                     \
    return #Name;
#include "clang/Basic/HLSLIntangibleTypes.def"
  }
 
  llvm_unreachable("Invalid builtin type.");
}
 
QualType QualType::getNonPackExpansionType() const {
  // We never wrap type sugar around a PackExpansionType.
  if (auto *PET = dyn_cast<PackExpansionType>(getTypePtr()))
    return PET->getPattern();
  return *this;
}
 
QualType QualType::getNonLValueExprType(const ASTContext &Context) const {
  if (const auto *RefType = getTypePtr()->getAs<ReferenceType>())
    return RefType->getPointeeType();
 
  // C++0x [basic.lval]:
  //   Class prvalues can have cv-qualified types; non-class prvalues always
  //   have cv-unqualified types.
  //
  // See also C99 6.3.2.1p2.
  if (!Context.getLangOpts().CPlusPlus ||
      (!getTypePtr()->isDependentType() && !getTypePtr()->isRecordType()))
    return getUnqualifiedType();
 
  return *this;
}
 
bool FunctionType::getCFIUncheckedCalleeAttr() const {
  if (const auto *FPT = getAs<FunctionProtoType>())
    return FPT->hasCFIUncheckedCallee();
  return false;
}
 
StringRef FunctionType::getNameForCallConv(CallingConv CC) {
  switch (CC) {
  case CC_C:
    return "cdecl";
  case CC_X86StdCall:
    return "stdcall";
  case CC_X86FastCall:
    return "fastcall";
  case CC_X86ThisCall:
    return "thiscall";
  case CC_X86Pascal:
    return "pascal";
  case CC_X86VectorCall:
    return "vectorcall";
  case CC_Win64:
    return "ms_abi";
  case CC_X86_64SysV:
    return "sysv_abi";
  case CC_X86RegCall:
    return "regcall";
  case CC_AAPCS:
    return "aapcs";
  case CC_AAPCS_VFP:
    return "aapcs-vfp";
  case CC_AArch64VectorCall:
    return "aarch64_vector_pcs";
  case CC_AArch64SVEPCS:
    return "aarch64_sve_pcs";
  case CC_IntelOclBicc:
    return "intel_ocl_bicc";
  case CC_SpirFunction:
    return "spir_function";
  case CC_DeviceKernel:
    return "device_kernel";
  case CC_Swift:
    return "swiftcall";
  case CC_SwiftAsync:
    return "swiftasynccall";
  case CC_PreserveMost:
    return "preserve_most";
  case CC_PreserveAll:
    return "preserve_all";
  case CC_M68kRTD:
    return "m68k_rtd";
  case CC_PreserveNone:
    return "preserve_none";
    // clang-format off
  case CC_RISCVVectorCall: return "riscv_vector_cc";
#define CC_VLS_CASE(ABI_VLEN) \
  case CC_RISCVVLSCall_##ABI_VLEN: return "riscv_vls_cc(" #ABI_VLEN ")";
  CC_VLS_CASE(32)
  CC_VLS_CASE(64)
  CC_VLS_CASE(128)
  CC_VLS_CASE(256)
  CC_VLS_CASE(512)
  CC_VLS_CASE(1024)
  CC_VLS_CASE(2048)
  CC_VLS_CASE(4096)
  CC_VLS_CASE(8192)
  CC_VLS_CASE(16384)
  CC_VLS_CASE(32768)
  CC_VLS_CASE(65536)
#undef CC_VLS_CASE
    // clang-format on
  }
 
  llvm_unreachable("Invalid calling convention.");
}
 
void FunctionProtoType::ExceptionSpecInfo::instantiate() {
  assert(Type == EST_Uninstantiated);
  NoexceptExpr =
      cast<FunctionProtoType>(SourceTemplate->getType())->getNoexceptExpr();
  Type = EST_DependentNoexcept;
}
 
FunctionProtoType::FunctionProtoType(QualType result, ArrayRef<QualType> params,
                                     QualType canonical,
                                     const ExtProtoInfo &epi)
    : FunctionType(FunctionProto, result, canonical, result->getDependence(),
                   epi.ExtInfo) {
  FunctionTypeBits.FastTypeQuals = epi.TypeQuals.getFastQualifiers();
  FunctionTypeBits.RefQualifier = epi.RefQualifier;
  FunctionTypeBits.NumParams = params.size();
  assert(getNumParams() == params.size() && "NumParams overflow!");
  FunctionTypeBits.ExceptionSpecType = epi.ExceptionSpec.Type;
  FunctionTypeBits.HasExtParameterInfos = !!epi.ExtParameterInfos;
  FunctionTypeBits.Variadic = epi.Variadic;
  FunctionTypeBits.HasTrailingReturn = epi.HasTrailingReturn;
  FunctionTypeBits.CFIUncheckedCallee = epi.CFIUncheckedCallee;
 
  if (epi.requiresFunctionProtoTypeExtraBitfields()) {
    FunctionTypeBits.HasExtraBitfields = true;
    auto &ExtraBits = *getTrailingObjects<FunctionTypeExtraBitfields>();
    ExtraBits = FunctionTypeExtraBitfields();
  } else {
    FunctionTypeBits.HasExtraBitfields = false;
  }
 
  // Propagate any extra attribute information.
  if (epi.requiresFunctionProtoTypeExtraAttributeInfo()) {
    auto &ExtraAttrInfo = *getTrailingObjects<FunctionTypeExtraAttributeInfo>();
    ExtraAttrInfo.CFISalt = epi.ExtraAttributeInfo.CFISalt;
 
    // Also set the bit in FunctionTypeExtraBitfields.
    auto &ExtraBits = *getTrailingObjects<FunctionTypeExtraBitfields>();
    ExtraBits.HasExtraAttributeInfo = true;
  }
 
  if (epi.requiresFunctionProtoTypeArmAttributes()) {
    auto &ArmTypeAttrs = *getTrailingObjects<FunctionTypeArmAttributes>();
    ArmTypeAttrs = FunctionTypeArmAttributes();
 
    // Also set the bit in FunctionTypeExtraBitfields
    auto &ExtraBits = *getTrailingObjects<FunctionTypeExtraBitfields>();
    ExtraBits.HasArmTypeAttributes = true;
  }
 
  // Fill in the trailing argument array.
  auto *argSlot = getTrailingObjects<QualType>();
  for (unsigned i = 0; i != getNumParams(); ++i) {
    addDependence(params[i]->getDependence() &
                  ~TypeDependence::VariablyModified);
    argSlot[i] = params[i];
  }
 
  // Propagate the SME ACLE attributes.
  if (epi.AArch64SMEAttributes != SME_NormalFunction) {
    auto &ArmTypeAttrs = *getTrailingObjects<FunctionTypeArmAttributes>();
    assert(epi.AArch64SMEAttributes <= SME_AttributeMask &&
           "Not enough bits to encode SME attributes");
    ArmTypeAttrs.AArch64SMEAttributes = epi.AArch64SMEAttributes;
  }
 
  // Fill in the exception type array if present.
  if (getExceptionSpecType() == EST_Dynamic) {
    auto &ExtraBits = *getTrailingObjects<FunctionTypeExtraBitfields>();
    size_t NumExceptions = epi.ExceptionSpec.Exceptions.size();
    assert(NumExceptions <= 1023 && "Not enough bits to encode exceptions");
    ExtraBits.NumExceptionType = NumExceptions;
 
    assert(hasExtraBitfields() && "missing trailing extra bitfields!");
    auto *exnSlot =
        reinterpret_cast<QualType *>(getTrailingObjects<ExceptionType>());
    unsigned I = 0;
    for (QualType ExceptionType : epi.ExceptionSpec.Exceptions) {
      // Note that, before C++17, a dependent exception specification does
      // *not* make a type dependent; it's not even part of the C++ type
      // system.
      addDependence(
          ExceptionType->getDependence() &
          (TypeDependence::Instantiation | TypeDependence::UnexpandedPack));
 
      exnSlot[I++] = ExceptionType;
    }
  }
  // Fill in the Expr * in the exception specification if present.
  else if (isComputedNoexcept(getExceptionSpecType())) {
    assert(epi.ExceptionSpec.NoexceptExpr && "computed noexcept with no expr");
    assert((getExceptionSpecType() == EST_DependentNoexcept) ==
           epi.ExceptionSpec.NoexceptExpr->isValueDependent());
 
    // Store the noexcept expression and context.
    *getTrailingObjects<Expr *>() = epi.ExceptionSpec.NoexceptExpr;
 
    addDependence(
        toTypeDependence(epi.ExceptionSpec.NoexceptExpr->getDependence()) &
        (TypeDependence::Instantiation | TypeDependence::UnexpandedPack));
  }
  // Fill in the FunctionDecl * in the exception specification if present.
  else if (getExceptionSpecType() == EST_Uninstantiated) {
    // Store the function decl from which we will resolve our
    // exception specification.
    auto **slot = getTrailingObjects<FunctionDecl *>();
    slot[0] = epi.ExceptionSpec.SourceDecl;
    slot[1] = epi.ExceptionSpec.SourceTemplate;
    // This exception specification doesn't make the type dependent, because
    // it's not instantiated as part of instantiating the type.
  } else if (getExceptionSpecType() == EST_Unevaluated) {
    // Store the function decl from which we will resolve our
    // exception specification.
    auto **slot = getTrailingObjects<FunctionDecl *>();
    slot[0] = epi.ExceptionSpec.SourceDecl;
  }
 
  // If this is a canonical type, and its exception specification is dependent,
  // then it's a dependent type. This only happens in C++17 onwards.
  if (isCanonicalUnqualified()) {
    if (getExceptionSpecType() == EST_Dynamic ||
        getExceptionSpecType() == EST_DependentNoexcept) {
      assert(hasDependentExceptionSpec() && "type should not be canonical");
      addDependence(TypeDependence::DependentInstantiation);
    }
  } else if (getCanonicalTypeInternal()->isDependentType()) {
    // Ask our canonical type whether our exception specification was dependent.
    addDependence(TypeDependence::DependentInstantiation);
  }
 
  // Fill in the extra parameter info if present.
  if (epi.ExtParameterInfos) {
    auto *extParamInfos = getTrailingObjects<ExtParameterInfo>();
    for (unsigned i = 0; i != getNumParams(); ++i)
      extParamInfos[i] = epi.ExtParameterInfos[i];
  }
 
  if (epi.TypeQuals.hasNonFastQualifiers()) {
    FunctionTypeBits.HasExtQuals = 1;
    *getTrailingObjects<Qualifiers>() = epi.TypeQuals;
  } else {
    FunctionTypeBits.HasExtQuals = 0;
  }
 
  // Fill in the Ellipsis location info if present.
  if (epi.Variadic) {
    auto &EllipsisLoc = *getTrailingObjects<SourceLocation>();
    EllipsisLoc = epi.EllipsisLoc;
  }
 
  if (!epi.FunctionEffects.empty()) {
    auto &ExtraBits = *getTrailingObjects<FunctionTypeExtraBitfields>();
    size_t EffectsCount = epi.FunctionEffects.size();
    ExtraBits.NumFunctionEffects = EffectsCount;
    assert(ExtraBits.NumFunctionEffects == EffectsCount &&
           "effect bitfield overflow");
 
    ArrayRef<FunctionEffect> SrcFX = epi.FunctionEffects.effects();
    auto *DestFX = getTrailingObjects<FunctionEffect>();
    llvm::uninitialized_copy(SrcFX, DestFX);
 
    ArrayRef<EffectConditionExpr> SrcConds = epi.FunctionEffects.conditions();
    if (!SrcConds.empty()) {
      ExtraBits.EffectsHaveConditions = true;
      auto *DestConds = getTrailingObjects<EffectConditionExpr>();
      llvm::uninitialized_copy(SrcConds, DestConds);
      assert(llvm::any_of(SrcConds,
                          [](const EffectConditionExpr &EC) {
                            if (const Expr *E = EC.getCondition())
                              return E->isTypeDependent() ||
                                     E->isValueDependent();
                            return false;
                          }) &&
             "expected a dependent expression among the conditions");
      addDependence(TypeDependence::DependentInstantiation);
    }
  }
}
 
bool FunctionProtoType::hasDependentExceptionSpec() const {
  if (Expr *NE = getNoexceptExpr())
    return NE->isValueDependent();
  for (QualType ET : exceptions())
    // A pack expansion with a non-dependent pattern is still dependent,
    // because we don't know whether the pattern is in the exception spec
    // or not (that depends on whether the pack has 0 expansions).
    if (ET->isDependentType() || ET->getAs<PackExpansionType>())
      return true;
  return false;
}
 
bool FunctionProtoType::hasInstantiationDependentExceptionSpec() const {
  if (Expr *NE = getNoexceptExpr())
    return NE->isInstantiationDependent();
  for (QualType ET : exceptions())
    if (ET->isInstantiationDependentType())
      return true;
  return false;
}
 
CanThrowResult FunctionProtoType::canThrow() const {
  switch (getExceptionSpecType()) {
  case EST_Unparsed:
  case EST_Unevaluated:
    llvm_unreachable("should not call this with unresolved exception specs");
 
  case EST_DynamicNone:
  case EST_BasicNoexcept:
  case EST_NoexceptTrue:
  case EST_NoThrow:
    return CT_Cannot;
 
  case EST_None:
  case EST_MSAny:
  case EST_NoexceptFalse:
    return CT_Can;
 
  case EST_Dynamic:
    // A dynamic exception specification is throwing unless every exception
    // type is an (unexpanded) pack expansion type.
    for (unsigned I = 0; I != getNumExceptions(); ++I)
      if (!getExceptionType(I)->getAs<PackExpansionType>())
        return CT_Can;
    return CT_Dependent;
 
  case EST_Uninstantiated:
  case EST_DependentNoexcept:
    return CT_Dependent;
  }
 
  llvm_unreachable("unexpected exception specification kind");
}
 
bool FunctionProtoType::isTemplateVariadic() const {
  for (unsigned ArgIdx = getNumParams(); ArgIdx; --ArgIdx)
    if (isa<PackExpansionType>(getParamType(ArgIdx - 1)))
      return true;
 
  return false;
}
 
void FunctionProtoType::Profile(llvm::FoldingSetNodeID &ID, QualType Result,
                                const QualType *ArgTys, unsigned NumParams,
                                const ExtProtoInfo &epi,
                                const ASTContext &Context, bool Canonical) {
  // We have to be careful not to get ambiguous profile encodings.
  // Note that valid type pointers are never ambiguous with anything else.
  //
  // The encoding grammar begins:
  //      type type* bool int bool
  // If that final bool is true, then there is a section for the EH spec:
  //      bool type*
  // This is followed by an optional "consumed argument" section of the
  // same length as the first type sequence:
  //      bool*
  // This is followed by the ext info:
  //      int
  // Finally we have a trailing return type flag (bool)
  // combined with AArch64 SME Attributes and extra attribute info, to save
  // space:
  //      int
  // combined with any FunctionEffects
  //
  // There is no ambiguity between the consumed arguments and an empty EH
  // spec because of the leading 'bool' which unambiguously indicates
  // whether the following bool is the EH spec or part of the arguments.
 
  ID.AddPointer(Result.getAsOpaquePtr());
  for (unsigned i = 0; i != NumParams; ++i)
    ID.AddPointer(ArgTys[i].getAsOpaquePtr());
  // This method is relatively performance sensitive, so as a performance
  // shortcut, use one AddInteger call instead of four for the next four
  // fields.
  assert(!(unsigned(epi.Variadic) & ~1) && !(unsigned(epi.RefQualifier) & ~3) &&
         !(unsigned(epi.ExceptionSpec.Type) & ~15) &&
         "Values larger than expected.");
  ID.AddInteger(unsigned(epi.Variadic) + (epi.RefQualifier << 1) +
                (epi.ExceptionSpec.Type << 3));
  ID.Add(epi.TypeQuals);
  if (epi.ExceptionSpec.Type == EST_Dynamic) {
    for (QualType Ex : epi.ExceptionSpec.Exceptions)
      ID.AddPointer(Ex.getAsOpaquePtr());
  } else if (isComputedNoexcept(epi.ExceptionSpec.Type)) {
    epi.ExceptionSpec.NoexceptExpr->Profile(ID, Context, Canonical);
  } else if (epi.ExceptionSpec.Type == EST_Uninstantiated ||
             epi.ExceptionSpec.Type == EST_Unevaluated) {
    ID.AddPointer(epi.ExceptionSpec.SourceDecl->getCanonicalDecl());
  }
  if (epi.ExtParameterInfos) {
    for (unsigned i = 0; i != NumParams; ++i)
      ID.AddInteger(epi.ExtParameterInfos[i].getOpaqueValue());
  }
 
  epi.ExtInfo.Profile(ID);
  epi.ExtraAttributeInfo.Profile(ID);
 
  unsigned EffectCount = epi.FunctionEffects.size();
  bool HasConds = !epi.FunctionEffects.Conditions.empty();
 
  ID.AddInteger((EffectCount << 3) | (HasConds << 2) |
                (epi.AArch64SMEAttributes << 1) | epi.HasTrailingReturn);
  ID.AddInteger(epi.CFIUncheckedCallee);
 
  for (unsigned Idx = 0; Idx != EffectCount; ++Idx) {
    ID.AddInteger(epi.FunctionEffects.Effects[Idx].toOpaqueInt32());
    if (HasConds)
      ID.AddPointer(epi.FunctionEffects.Conditions[Idx].getCondition());
  }
}
 
void FunctionProtoType::Profile(llvm::FoldingSetNodeID &ID,
                                const ASTContext &Ctx) {
  Profile(ID, getReturnType(), param_type_begin(), getNumParams(),
          getExtProtoInfo(), Ctx, isCanonicalUnqualified());
}
 
TypeCoupledDeclRefInfo::TypeCoupledDeclRefInfo(ValueDecl *D, bool Deref)
    : Data(D, Deref << DerefShift) {}
 
bool TypeCoupledDeclRefInfo::isDeref() const {
  return Data.getInt() & DerefMask;
}
ValueDecl *TypeCoupledDeclRefInfo::getDecl() const { return Data.getPointer(); }
unsigned TypeCoupledDeclRefInfo::getInt() const { return Data.getInt(); }
void *TypeCoupledDeclRefInfo::getOpaqueValue() const {
  return Data.getOpaqueValue();
}
bool TypeCoupledDeclRefInfo::operator==(
    const TypeCoupledDeclRefInfo &Other) const {
  return getOpaqueValue() == Other.getOpaqueValue();
}
void TypeCoupledDeclRefInfo::setFromOpaqueValue(void *V) {
  Data.setFromOpaqueValue(V);
}
 
OverflowBehaviorType::OverflowBehaviorType(
    QualType Canon, QualType Underlying,
    OverflowBehaviorType::OverflowBehaviorKind Kind)
    : Type(OverflowBehavior, Canon, Underlying->getDependence()),
      UnderlyingType(Underlying), BehaviorKind(Kind) {}
 
BoundsAttributedType::BoundsAttributedType(TypeClass TC, QualType Wrapped,
                                           QualType Canon)
    : Type(TC, Canon, Wrapped->getDependence()), WrappedTy(Wrapped) {}
 
CountAttributedType::CountAttributedType(
    QualType Wrapped, QualType Canon, Expr *CountExpr, bool CountInBytes,
    bool OrNull, ArrayRef<TypeCoupledDeclRefInfo> CoupledDecls)
    : BoundsAttributedType(CountAttributed, Wrapped, Canon),
      CountExpr(CountExpr) {
  CountAttributedTypeBits.NumCoupledDecls = CoupledDecls.size();
  CountAttributedTypeBits.CountInBytes = CountInBytes;
  CountAttributedTypeBits.OrNull = OrNull;
  auto *DeclSlot = getTrailingObjects();
  llvm::copy(CoupledDecls, DeclSlot);
  Decls = llvm::ArrayRef(DeclSlot, CoupledDecls.size());
}
 
StringRef CountAttributedType::getAttributeName(bool WithMacroPrefix) const {
// TODO: This method isn't really ideal because it doesn't return the spelling
// of the attribute that was used in the user's code. This method is used for
// diagnostics so the fact it doesn't use the spelling of the attribute in
// the user's code could be confusing (#113585).
#define ENUMERATE_ATTRS(PREFIX)                                                \
  do {                                                                         \
    if (isCountInBytes()) {                                                    \
      if (isOrNull())                                                          \
        return PREFIX "sized_by_or_null";                                      \
      return PREFIX "sized_by";                                                \
    }                                                                          \
    if (isOrNull())                                                            \
      return PREFIX "counted_by_or_null";                                      \
    return PREFIX "counted_by";                                                \
  } while (0)
 
  if (WithMacroPrefix)
    ENUMERATE_ATTRS("__");
  else
    ENUMERATE_ATTRS("");
 
#undef ENUMERATE_ATTRS
}
 
TypedefType::TypedefType(TypeClass TC, ElaboratedTypeKeyword Keyword,
                         NestedNameSpecifier Qualifier,
                         const TypedefNameDecl *D, QualType UnderlyingType,
                         bool HasTypeDifferentFromDecl)
    : TypeWithKeyword(
          Keyword, TC, UnderlyingType.getCanonicalType(),
          toSemanticDependence(UnderlyingType->getDependence()) |
              (Qualifier
                   ? toTypeDependence(Qualifier.getDependence() &
                                      ~NestedNameSpecifierDependence::Dependent)
                   : TypeDependence{})),
      Decl(const_cast<TypedefNameDecl *>(D)) {
  if ((TypedefBits.hasQualifier = !!Qualifier))
    *getTrailingObjects<NestedNameSpecifier>() = Qualifier;
  if ((TypedefBits.hasTypeDifferentFromDecl = HasTypeDifferentFromDecl))
    *getTrailingObjects<QualType>() = UnderlyingType;
}
 
QualType TypedefType::desugar() const {
  return typeMatchesDecl() ? Decl->getUnderlyingType()
                           : *getTrailingObjects<QualType>();
}
 
UnresolvedUsingType::UnresolvedUsingType(ElaboratedTypeKeyword Keyword,
                                         NestedNameSpecifier Qualifier,
                                         const UnresolvedUsingTypenameDecl *D,
                                         const Type *CanonicalType)
    : TypeWithKeyword(
          Keyword, UnresolvedUsing, QualType(CanonicalType, 0),
          TypeDependence::DependentInstantiation |
              (Qualifier
                   ? toTypeDependence(Qualifier.getDependence() &
                                      ~NestedNameSpecifierDependence::Dependent)
                   : TypeDependence{})),
      Decl(const_cast<UnresolvedUsingTypenameDecl *>(D)) {
  if ((UnresolvedUsingBits.hasQualifier = !!Qualifier))
    *getTrailingObjects<NestedNameSpecifier>() = Qualifier;
}
 
UsingType::UsingType(ElaboratedTypeKeyword Keyword,
                     NestedNameSpecifier Qualifier, const UsingShadowDecl *D,
                     QualType UnderlyingType)
    : TypeWithKeyword(Keyword, Using, UnderlyingType.getCanonicalType(),
                      toSemanticDependence(UnderlyingType->getDependence())),
      D(const_cast<UsingShadowDecl *>(D)), UnderlyingType(UnderlyingType) {
  if ((UsingBits.hasQualifier = !!Qualifier))
    *getTrailingObjects() = Qualifier;
}
 
QualType MacroQualifiedType::desugar() const { return getUnderlyingType(); }
 
QualType MacroQualifiedType::getModifiedType() const {
  // Step over MacroQualifiedTypes from the same macro to find the type
  // ultimately qualified by the macro qualifier.
  QualType Inner = cast<AttributedType>(getUnderlyingType())->getModifiedType();
  while (auto *InnerMQT = dyn_cast<MacroQualifiedType>(Inner)) {
    if (InnerMQT->getMacroIdentifier() != getMacroIdentifier())
      break;
    Inner = InnerMQT->getModifiedType();
  }
  return Inner;
}
 
TypeOfExprType::TypeOfExprType(const ASTContext &Context, Expr *E,
                               TypeOfKind Kind, QualType Can)
    : Type(TypeOfExpr,
           // We have to protect against 'Can' being invalid through its
           // default argument.
           Kind == TypeOfKind::Unqualified && !Can.isNull()
               ? Context.getUnqualifiedArrayType(Can).getAtomicUnqualifiedType()
               : Can,
           toTypeDependence(E->getDependence()) |
               (E->getType()->getDependence() &
                TypeDependence::VariablyModified)),
      TOExpr(E), Context(Context) {
  TypeOfBits.Kind = static_cast<unsigned>(Kind);
}
 
bool TypeOfExprType::isSugared() const { return !TOExpr->isTypeDependent(); }
 
QualType TypeOfExprType::desugar() const {
  if (isSugared()) {
    QualType QT = getUnderlyingExpr()->getType();
    return getKind() == TypeOfKind::Unqualified
               ? Context.getUnqualifiedArrayType(QT).getAtomicUnqualifiedType()
               : QT;
  }
  return QualType(this, 0);
}
 
void DependentTypeOfExprType::Profile(llvm::FoldingSetNodeID &ID,
                                      const ASTContext &Context, Expr *E,
                                      bool IsUnqual) {
  E->Profile(ID, Context, true);
  ID.AddBoolean(IsUnqual);
}
 
TypeOfType::TypeOfType(const ASTContext &Context, QualType T, QualType Can,
                       TypeOfKind Kind)
    : Type(TypeOf,
           Kind == TypeOfKind::Unqualified
               ? Context.getUnqualifiedArrayType(Can).getAtomicUnqualifiedType()
               : Can,
           T->getDependence()),
      TOType(T), Context(Context) {
  TypeOfBits.Kind = static_cast<unsigned>(Kind);
}
 
QualType TypeOfType::desugar() const {
  QualType QT = getUnmodifiedType();
  return getKind() == TypeOfKind::Unqualified
             ? Context.getUnqualifiedArrayType(QT).getAtomicUnqualifiedType()
             : QT;
}
 
DecltypeType::DecltypeType(Expr *E, QualType underlyingType, QualType can)
    // C++11 [temp.type]p2: "If an expression e involves a template parameter,
    // decltype(e) denotes a unique dependent type." Hence a decltype type is
    // type-dependent even if its expression is only instantiation-dependent.
    : Type(Decltype, can,
           toTypeDependence(E->getDependence()) |
               (E->isInstantiationDependent() ? TypeDependence::Dependent
                                              : TypeDependence::None) |
               (E->getType()->getDependence() &
                TypeDependence::VariablyModified)),
      E(E), UnderlyingType(underlyingType) {}
 
bool DecltypeType::isSugared() const { return !E->isInstantiationDependent(); }
 
QualType DecltypeType::desugar() const {
  if (isSugared())
    return getUnderlyingType();
 
  return QualType(this, 0);
}
 
DependentDecltypeType::DependentDecltypeType(Expr *E)
    : DecltypeType(E, QualType()) {}
 
void DependentDecltypeType::Profile(llvm::FoldingSetNodeID &ID,
                                    const ASTContext &Context, Expr *E) {
  E->Profile(ID, Context, true);
}
 
PackIndexingType::PackIndexingType(QualType Canonical, QualType Pattern,
                                   Expr *IndexExpr, bool FullySubstituted,
                                   ArrayRef<QualType> Expansions)
    : Type(PackIndexing, Canonical,
           computeDependence(Pattern, IndexExpr, Expansions)),
      Pattern(Pattern), IndexExpr(IndexExpr), Size(Expansions.size()),
      FullySubstituted(FullySubstituted) {
 
  llvm::uninitialized_copy(Expansions, getTrailingObjects());
}
 
UnsignedOrNone PackIndexingType::getSelectedIndex() const {
  if (isInstantiationDependentType())
    return std::nullopt;
  // Should only be not a constant for error recovery.
  ConstantExpr *CE = dyn_cast<ConstantExpr>(getIndexExpr());
  if (!CE)
    return std::nullopt;
  auto Index = CE->getResultAsAPSInt();
  assert(Index.isNonNegative() && "Invalid index");
  return static_cast<unsigned>(Index.getExtValue());
}
 
TypeDependence
PackIndexingType::computeDependence(QualType Pattern, Expr *IndexExpr,
                                    ArrayRef<QualType> Expansions) {
  TypeDependence IndexD = toTypeDependence(IndexExpr->getDependence());
 
  TypeDependence TD = IndexD | (IndexExpr->isInstantiationDependent()
                                    ? TypeDependence::DependentInstantiation
                                    : TypeDependence::None);
  if (Expansions.empty())
    TD |= Pattern->getDependence() & TypeDependence::DependentInstantiation;
  else
    for (const QualType &T : Expansions)
      TD |= T->getDependence();
 
  if (!(IndexD & TypeDependence::UnexpandedPack))
    TD &= ~TypeDependence::UnexpandedPack;
 
  // If the pattern does not contain an unexpended pack,
  // the type is still dependent, and invalid
  if (!Pattern->containsUnexpandedParameterPack())
    TD |= TypeDependence::Error | TypeDependence::DependentInstantiation;
 
  return TD;
}
 
void PackIndexingType::Profile(llvm::FoldingSetNodeID &ID,
                               const ASTContext &Context) {
  Profile(ID, Context, getPattern(), getIndexExpr(), isFullySubstituted(),
          getExpansions());
}
 
void PackIndexingType::Profile(llvm::FoldingSetNodeID &ID,
                               const ASTContext &Context, QualType Pattern,
                               Expr *E, bool FullySubstituted,
                               ArrayRef<QualType> Expansions) {
 
  E->Profile(ID, Context, true);
  ID.AddBoolean(FullySubstituted);
  if (!Expansions.empty()) {
    ID.AddInteger(Expansions.size());
    for (QualType T : Expansions)
      T.getCanonicalType().Profile(ID);
  } else {
    Pattern.Profile(ID);
  }
}
 
UnaryTransformType::UnaryTransformType(QualType BaseType,
                                       QualType UnderlyingType, UTTKind UKind,
                                       QualType CanonicalType)
    : Type(UnaryTransform, CanonicalType, BaseType->getDependence()),
      BaseType(BaseType), UnderlyingType(UnderlyingType), UKind(UKind) {}
 
TagType::TagType(TypeClass TC, ElaboratedTypeKeyword Keyword,
                 NestedNameSpecifier Qualifier, const TagDecl *Tag,
                 bool OwnsTag, bool ISInjected, const Type *CanonicalType)
    : TypeWithKeyword(
          Keyword, TC, QualType(CanonicalType, 0),
          (Tag->isDependentType() ? TypeDependence::DependentInstantiation
                                  : TypeDependence::None) |
              (Qualifier
                   ? toTypeDependence(Qualifier.getDependence() &
                                      ~NestedNameSpecifierDependence::Dependent)
                   : TypeDependence{})),
      decl(const_cast<TagDecl *>(Tag)) {
  if ((TagTypeBits.HasQualifier = !!Qualifier))
    getTrailingQualifier() = Qualifier;
  TagTypeBits.OwnsTag = !!OwnsTag;
  TagTypeBits.IsInjected = ISInjected;
}
 
void *TagType::getTrailingPointer() const {
  switch (getTypeClass()) {
  case Type::Enum:
    return const_cast<EnumType *>(cast<EnumType>(this) + 1);
  case Type::Record:
    return const_cast<RecordType *>(cast<RecordType>(this) + 1);
  case Type::InjectedClassName:
    return const_cast<InjectedClassNameType *>(
        cast<InjectedClassNameType>(this) + 1);
  default:
    llvm_unreachable("unexpected type class");
  }
}
 
NestedNameSpecifier &TagType::getTrailingQualifier() const {
  assert(TagTypeBits.HasQualifier);
  return *reinterpret_cast<NestedNameSpecifier *>(llvm::alignAddr(
      getTrailingPointer(), llvm::Align::Of<NestedNameSpecifier *>()));
}
 
NestedNameSpecifier TagType::getQualifier() const {
  return TagTypeBits.HasQualifier ? getTrailingQualifier() : std::nullopt;
}
 
ClassTemplateDecl *TagType::getTemplateDecl() const {
  auto *Decl = dyn_cast<CXXRecordDecl>(decl);
  if (!Decl)
    return nullptr;
  if (auto *RD = dyn_cast<ClassTemplateSpecializationDecl>(Decl))
    return RD->getSpecializedTemplate();
  return Decl->getDescribedClassTemplate();
}
 
TemplateName TagType::getTemplateName(const ASTContext &Ctx) const {
  auto *TD = getTemplateDecl();
  if (!TD)
    return TemplateName();
  if (isCanonicalUnqualified())
    return TemplateName(TD);
  return Ctx.getQualifiedTemplateName(getQualifier(), /*TemplateKeyword=*/false,
                                      TemplateName(TD));
}
 
ArrayRef<TemplateArgument>
TagType::getTemplateArgs(const ASTContext &Ctx) const {
  auto *Decl = dyn_cast<CXXRecordDecl>(decl);
  if (!Decl)
    return {};
 
  if (auto *RD = dyn_cast<ClassTemplateSpecializationDecl>(Decl))
    return RD->getTemplateArgs().asArray();
  if (ClassTemplateDecl *TD = Decl->getDescribedClassTemplate())
    return TD->getTemplateParameters()->getInjectedTemplateArgs(Ctx);
  return {};
}
 
bool RecordType::hasConstFields() const {
  std::vector<const RecordType *> RecordTypeList;
  RecordTypeList.push_back(this);
  unsigned NextToCheckIndex = 0;
 
  while (RecordTypeList.size() > NextToCheckIndex) {
    for (FieldDecl *FD : RecordTypeList[NextToCheckIndex]
                             ->getDecl()
                             ->getDefinitionOrSelf()
                             ->fields()) {
      QualType FieldTy = FD->getType();
      if (FieldTy.isConstQualified())
        return true;
      FieldTy = FieldTy.getCanonicalType();
      if (const auto *FieldRecTy = FieldTy->getAsCanonical<RecordType>()) {
        if (!llvm::is_contained(RecordTypeList, FieldRecTy))
          RecordTypeList.push_back(FieldRecTy);
      }
    }
    ++NextToCheckIndex;
  }
  return false;
}
 
InjectedClassNameType::InjectedClassNameType(ElaboratedTypeKeyword Keyword,
                                             NestedNameSpecifier Qualifier,
                                             const TagDecl *TD, bool IsInjected,
                                             const Type *CanonicalType)
    : TagType(TypeClass::InjectedClassName, Keyword, Qualifier, TD,
              /*OwnsTag=*/false, IsInjected, CanonicalType) {}
 
AttributedType::AttributedType(QualType canon, const Attr *attr,
                               QualType modified, QualType equivalent)
    : AttributedType(canon, attr->getKind(), attr, modified, equivalent) {}
 
AttributedType::AttributedType(QualType canon, attr::Kind attrKind,
                               const Attr *attr, QualType modified,
                               QualType equivalent)
    : Type(Attributed, canon, equivalent->getDependence()), Attribute(attr),
      ModifiedType(modified), EquivalentType(equivalent) {
  AttributedTypeBits.AttrKind = attrKind;
  assert(!attr || attr->getKind() == attrKind);
}
 
bool AttributedType::isQualifier() const {
  // FIXME: Generate this with TableGen.
  switch (getAttrKind()) {
  // These are type qualifiers in the traditional C sense: they annotate
  // something about a specific value/variable of a type.  (They aren't
  // always part of the canonical type, though.)
  case attr::ObjCGC:
  case attr::ObjCOwnership:
  case attr::ObjCInertUnsafeUnretained:
  case attr::TypeNonNull:
  case attr::TypeNullable:
  case attr::TypeNullableResult:
  case attr::TypeNullUnspecified:
  case attr::LifetimeBound:
  case attr::AddressSpace:
    return true;
 
  // All other type attributes aren't qualifiers; they rewrite the modified
  // type to be a semantically different type.
  default:
    return false;
  }
}
 
bool AttributedType::isMSTypeSpec() const {
  // FIXME: Generate this with TableGen?
  switch (getAttrKind()) {
  default:
    return false;
  case attr::Ptr32:
  case attr::Ptr64:
  case attr::SPtr:
  case attr::UPtr:
    return true;
  }
  llvm_unreachable("invalid attr kind");
}
 
bool AttributedType::isWebAssemblyFuncrefSpec() const {
  return getAttrKind() == attr::WebAssemblyFuncref;
}
 
bool AttributedType::isCallingConv() const {
  // FIXME: Generate this with TableGen.
  switch (getAttrKind()) {
  default:
    return false;
  case attr::Pcs:
  case attr::CDecl:
  case attr::FastCall:
  case attr::StdCall:
  case attr::ThisCall:
  case attr::RegCall:
  case attr::SwiftCall:
  case attr::SwiftAsyncCall:
  case attr::VectorCall:
  case attr::AArch64VectorPcs:
  case attr::AArch64SVEPcs:
  case attr::DeviceKernel:
  case attr::Pascal:
  case attr::MSABI:
  case attr::SysVABI:
  case attr::IntelOclBicc:
  case attr::PreserveMost:
  case attr::PreserveAll:
  case attr::M68kRTD:
  case attr::PreserveNone:
  case attr::RISCVVectorCC:
  case attr::RISCVVLSCC:
    return true;
  }
  llvm_unreachable("invalid attr kind");
}
 
IdentifierInfo *TemplateTypeParmType::getIdentifier() const {
  return isCanonicalUnqualified() ? nullptr : getDecl()->getIdentifier();
}
 
SubstTemplateTypeParmType::SubstTemplateTypeParmType(QualType Replacement,
                                                     Decl *AssociatedDecl,
                                                     unsigned Index,
                                                     UnsignedOrNone PackIndex,
                                                     bool Final)
    : Type(SubstTemplateTypeParm, Replacement.getCanonicalType(),
           Replacement->getDependence()),
      AssociatedDecl(AssociatedDecl) {
  SubstTemplateTypeParmTypeBits.HasNonCanonicalUnderlyingType =
      Replacement != getCanonicalTypeInternal();
  if (SubstTemplateTypeParmTypeBits.HasNonCanonicalUnderlyingType)
    *getTrailingObjects() = Replacement;
 
  SubstTemplateTypeParmTypeBits.Index = Index;
  SubstTemplateTypeParmTypeBits.Final = Final;
  SubstTemplateTypeParmTypeBits.PackIndex =
      PackIndex.toInternalRepresentation();
  assert(AssociatedDecl != nullptr);
}
 
const TemplateTypeParmDecl *
SubstTemplateTypeParmType::getReplacedParameter() const {
  return cast<TemplateTypeParmDecl>(std::get<0>(
      getReplacedTemplateParameter(getAssociatedDecl(), getIndex())));
}
 
void SubstTemplateTypeParmType::Profile(llvm::FoldingSetNodeID &ID,
                                        QualType Replacement,
                                        const Decl *AssociatedDecl,
                                        unsigned Index,
                                        UnsignedOrNone PackIndex, bool Final) {
  Replacement.Profile(ID);
  ID.AddPointer(AssociatedDecl);
  ID.AddInteger(Index);
  ID.AddInteger(PackIndex.toInternalRepresentation());
  ID.AddBoolean(Final);
}
 
SubstPackType::SubstPackType(TypeClass Derived, QualType Canon,
                             const TemplateArgument &ArgPack)
    : Type(Derived, Canon,
           TypeDependence::DependentInstantiation |
               TypeDependence::UnexpandedPack),
      Arguments(ArgPack.pack_begin()) {
  assert(llvm::all_of(
             ArgPack.pack_elements(),
             [](auto &P) { return P.getKind() == TemplateArgument::Type; }) &&
         "non-type argument to SubstPackType?");
  SubstPackTypeBits.NumArgs = ArgPack.pack_size();
}
 
TemplateArgument SubstPackType::getArgumentPack() const {
  return TemplateArgument(llvm::ArrayRef(Arguments, getNumArgs()));
}
 
void SubstPackType::Profile(llvm::FoldingSetNodeID &ID) {
  Profile(ID, getArgumentPack());
}
 
void SubstPackType::Profile(llvm::FoldingSetNodeID &ID,
                            const TemplateArgument &ArgPack) {
  ID.AddInteger(ArgPack.pack_size());
  for (const auto &P : ArgPack.pack_elements())
    ID.AddPointer(P.getAsType().getAsOpaquePtr());
}
 
SubstTemplateTypeParmPackType::SubstTemplateTypeParmPackType(
    QualType Canon, Decl *AssociatedDecl, unsigned Index, bool Final,
    const TemplateArgument &ArgPack)
    : SubstPackType(SubstTemplateTypeParmPack, Canon, ArgPack),
      AssociatedDeclAndFinal(AssociatedDecl, Final) {
  assert(AssociatedDecl != nullptr);
 
  SubstPackTypeBits.SubstTemplTypeParmPackIndex = Index;
  assert(getNumArgs() == ArgPack.pack_size() &&
         "Parent bitfields in SubstPackType were overwritten."
         "Check NumSubstPackTypeBits.");
}
 
Decl *SubstTemplateTypeParmPackType::getAssociatedDecl() const {
  return AssociatedDeclAndFinal.getPointer();
}
 
bool SubstTemplateTypeParmPackType::getFinal() const {
  return AssociatedDeclAndFinal.getInt();
}
 
const TemplateTypeParmDecl *
SubstTemplateTypeParmPackType::getReplacedParameter() const {
  return cast<TemplateTypeParmDecl>(std::get<0>(
      getReplacedTemplateParameter(getAssociatedDecl(), getIndex())));
}
 
IdentifierInfo *SubstTemplateTypeParmPackType::getIdentifier() const {
  return getReplacedParameter()->getIdentifier();
}
 
void SubstTemplateTypeParmPackType::Profile(llvm::FoldingSetNodeID &ID) {
  Profile(ID, getAssociatedDecl(), getIndex(), getFinal(), getArgumentPack());
}
 
void SubstTemplateTypeParmPackType::Profile(llvm::FoldingSetNodeID &ID,
                                            const Decl *AssociatedDecl,
                                            unsigned Index, bool Final,
                                            const TemplateArgument &ArgPack) {
  ID.AddPointer(AssociatedDecl);
  ID.AddInteger(Index);
  ID.AddBoolean(Final);
  SubstPackType::Profile(ID, ArgPack);
}
 
SubstBuiltinTemplatePackType::SubstBuiltinTemplatePackType(
    QualType Canon, const TemplateArgument &ArgPack)
    : SubstPackType(SubstBuiltinTemplatePack, Canon, ArgPack) {}
 
bool TemplateSpecializationType::anyDependentTemplateArguments(
    const TemplateArgumentListInfo &Args,
    ArrayRef<TemplateArgument> Converted) {
  return anyDependentTemplateArguments(Args.arguments(), Converted);
}
 
bool TemplateSpecializationType::anyDependentTemplateArguments(
    ArrayRef<TemplateArgumentLoc> Args, ArrayRef<TemplateArgument> Converted) {
  for (const TemplateArgument &Arg : Converted)
    if (Arg.isDependent())
      return true;
  return false;
}
 
bool TemplateSpecializationType::anyInstantiationDependentTemplateArguments(
    ArrayRef<TemplateArgumentLoc> Args) {
  for (const TemplateArgumentLoc &ArgLoc : Args) {
    if (ArgLoc.getArgument().isInstantiationDependent())
      return true;
  }
  return false;
}
 
static TypeDependence
getTemplateSpecializationTypeDependence(QualType Underlying, TemplateName T) {
  TypeDependence D = Underlying.isNull()
                         ? TypeDependence::DependentInstantiation
                         : toSemanticDependence(Underlying->getDependence());
  D |= toTypeDependence(T.getDependence()) & TypeDependence::UnexpandedPack;
  if (isPackProducingBuiltinTemplateName(T)) {
    if (Underlying.isNull()) // Dependent, will produce a pack on substitution.
      D |= TypeDependence::UnexpandedPack;
    else
      D |= (Underlying->getDependence() & TypeDependence::UnexpandedPack);
  }
  return D;
}
 
TemplateSpecializationType::TemplateSpecializationType(
    ElaboratedTypeKeyword Keyword, TemplateName T, bool IsAlias,
    ArrayRef<TemplateArgument> Args, QualType Underlying)
    : TypeWithKeyword(Keyword, TemplateSpecialization,
                      Underlying.isNull() ? QualType(this, 0)
                                          : Underlying.getCanonicalType(),
                      getTemplateSpecializationTypeDependence(Underlying, T)),
      Template(T) {
  TemplateSpecializationTypeBits.NumArgs = Args.size();
  TemplateSpecializationTypeBits.TypeAlias = IsAlias;
 
  auto *TemplateArgs =
      const_cast<TemplateArgument *>(template_arguments().data());
  for (const TemplateArgument &Arg : Args) {
    // Update instantiation-dependent, variably-modified, and error bits.
    // If the canonical type exists and is non-dependent, the template
    // specialization type can be non-dependent even if one of the type
    // arguments is. Given:
    //   template<typename T> using U = int;
    // U<T> is always non-dependent, irrespective of the type T.
    // However, U<Ts> contains an unexpanded parameter pack, even though
    // its expansion (and thus its desugared type) doesn't.
    addDependence(toTypeDependence(Arg.getDependence()) &
                  ~TypeDependence::Dependent);
    if (Arg.getKind() == TemplateArgument::Type)
      addDependence(Arg.getAsType()->getDependence() &
                    TypeDependence::VariablyModified);
    new (TemplateArgs++) TemplateArgument(Arg);
  }
 
  // Store the aliased type after the template arguments, if this is a type
  // alias template specialization.
  if (IsAlias)
    *reinterpret_cast<QualType *>(TemplateArgs) = Underlying;
}
 
QualType TemplateSpecializationType::getAliasedType() const {
  assert(isTypeAlias() && "not a type alias template specialization");
  return *reinterpret_cast<const QualType *>(template_arguments().end());
}
 
bool clang::TemplateSpecializationType::isSugared() const {
  return !isDependentType() || isCurrentInstantiation() || isTypeAlias() ||
         (isPackProducingBuiltinTemplateName(Template) &&
          isa<SubstBuiltinTemplatePackType>(*getCanonicalTypeInternal()));
}
 
void TemplateSpecializationType::Profile(llvm::FoldingSetNodeID &ID,
                                         const ASTContext &Ctx) {
  Profile(ID, getKeyword(), Template, template_arguments(),
          isSugared() ? desugar() : QualType(), Ctx);
}
 
void TemplateSpecializationType::Profile(llvm::FoldingSetNodeID &ID,
                                         ElaboratedTypeKeyword Keyword,
                                         TemplateName T,
                                         ArrayRef<TemplateArgument> Args,
                                         QualType Underlying,
                                         const ASTContext &Context) {
  ID.AddInteger(llvm::to_underlying(Keyword));
  T.Profile(ID);
  Underlying.Profile(ID);
 
  ID.AddInteger(Args.size());
  for (const TemplateArgument &Arg : Args)
    Arg.Profile(ID, Context);
}
 
QualType QualifierCollector::apply(const ASTContext &Context,
                                   QualType QT) const {
  if (!hasNonFastQualifiers())
    return QT.withFastQualifiers(getFastQualifiers());
 
  return Context.getQualifiedType(QT, *this);
}
 
QualType QualifierCollector::apply(const ASTContext &Context,
                                   const Type *T) const {
  if (!hasNonFastQualifiers())
    return QualType(T, getFastQualifiers());
 
  return Context.getQualifiedType(T, *this);
}
 
void ObjCObjectTypeImpl::Profile(llvm::FoldingSetNodeID &ID, QualType BaseType,
                                 ArrayRef<QualType> typeArgs,
                                 ArrayRef<ObjCProtocolDecl *> protocols,
                                 bool isKindOf) {
  ID.AddPointer(BaseType.getAsOpaquePtr());
  ID.AddInteger(typeArgs.size());
  for (auto typeArg : typeArgs)
    ID.AddPointer(typeArg.getAsOpaquePtr());
  ID.AddInteger(protocols.size());
  for (auto *proto : protocols)
    ID.AddPointer(proto);
  ID.AddBoolean(isKindOf);
}
 
void ObjCObjectTypeImpl::Profile(llvm::FoldingSetNodeID &ID) {
  Profile(ID, getBaseType(), getTypeArgsAsWritten(),
          llvm::ArrayRef(qual_begin(), getNumProtocols()),
          isKindOfTypeAsWritten());
}
 
void ObjCTypeParamType::Profile(llvm::FoldingSetNodeID &ID,
                                const ObjCTypeParamDecl *OTPDecl,
                                QualType CanonicalType,
                                ArrayRef<ObjCProtocolDecl *> protocols) {
  ID.AddPointer(OTPDecl);
  ID.AddPointer(CanonicalType.getAsOpaquePtr());
  ID.AddInteger(protocols.size());
  for (auto *proto : protocols)
    ID.AddPointer(proto);
}
 
void ObjCTypeParamType::Profile(llvm::FoldingSetNodeID &ID) {
  Profile(ID, getDecl(), getCanonicalTypeInternal(),
          llvm::ArrayRef(qual_begin(), getNumProtocols()));
}
 
namespace {
 
/// The cached properties of a type.
class CachedProperties {
  Linkage L;
  bool local;
 
public:
  CachedProperties(Linkage L, bool local) : L(L), local(local) {}
 
  Linkage getLinkage() const { return L; }
  bool hasLocalOrUnnamedType() const { return local; }
 
  friend CachedProperties merge(CachedProperties L, CachedProperties R) {
    Linkage MergedLinkage = minLinkage(L.L, R.L);
    return CachedProperties(MergedLinkage, L.hasLocalOrUnnamedType() ||
                                               R.hasLocalOrUnnamedType());
  }
};
 
} // namespace
 
static CachedProperties computeCachedProperties(const Type *T);
 
namespace clang {
 
/// The type-property cache.  This is templated so as to be
/// instantiated at an internal type to prevent unnecessary symbol
/// leakage.
template <class Private> class TypePropertyCache {
public:
  static CachedProperties get(QualType T) { return get(T.getTypePtr()); }
 
  static CachedProperties get(const Type *T) {
    ensure(T);
    return CachedProperties(T->TypeBits.getLinkage(),
                            T->TypeBits.hasLocalOrUnnamedType());
  }
 
  static void ensure(const Type *T) {
    // If the cache is valid, we're okay.
    if (T->TypeBits.isCacheValid())
      return;
 
    // If this type is non-canonical, ask its canonical type for the
    // relevant information.
    if (!T->isCanonicalUnqualified()) {
      const Type *CT = T->getCanonicalTypeInternal().getTypePtr();
      ensure(CT);
      T->TypeBits.CacheValid = true;
      T->TypeBits.CachedLinkage = CT->TypeBits.CachedLinkage;
      T->TypeBits.CachedLocalOrUnnamed = CT->TypeBits.CachedLocalOrUnnamed;
      return;
    }
 
    // Compute the cached properties and then set the cache.
    CachedProperties Result = computeCachedProperties(T);
    T->TypeBits.CacheValid = true;
    T->TypeBits.CachedLinkage = llvm::to_underlying(Result.getLinkage());
    T->TypeBits.CachedLocalOrUnnamed = Result.hasLocalOrUnnamedType();
  }
};
 
} // namespace clang
 
// Instantiate the friend template at a private class.  In a
// reasonable implementation, these symbols will be internal.
// It is terrible that this is the best way to accomplish this.
namespace {
 
class Private {};
 
} // namespace
 
using Cache = TypePropertyCache<Private>;
 
static CachedProperties computeCachedProperties(const Type *T) {
  switch (T->getTypeClass()) {
#define TYPE(Class, Base)
#define NON_CANONICAL_TYPE(Class, Base) case Type::Class:
#include "clang/AST/TypeNodes.inc"
    llvm_unreachable("didn't expect a non-canonical type here");
 
#define TYPE(Class, Base)
#define DEPENDENT_TYPE(Class, Base) case Type::Class:
#define NON_CANONICAL_UNLESS_DEPENDENT_TYPE(Class, Base) case Type::Class:
#include "clang/AST/TypeNodes.inc"
    // Treat instantiation-dependent types as external.
    assert(T->isInstantiationDependentType());
    return CachedProperties(Linkage::External, false);
 
  case Type::Auto:
  case Type::DeducedTemplateSpecialization:
    // Give non-deduced 'auto' types external linkage. We should only see them
    // here in error recovery.
    return CachedProperties(Linkage::External, false);
 
  case Type::BitInt:
  case Type::Builtin:
    // C++ [basic.link]p8:
    //   A type is said to have linkage if and only if:
    //     - it is a fundamental type (3.9.1); or
    return CachedProperties(Linkage::External, false);
 
  case Type::Record:
  case Type::Enum: {
    const auto *Tag = cast<TagType>(T)->getDecl()->getDefinitionOrSelf();
 
    // C++ [basic.link]p8:
    //     - it is a class or enumeration type that is named (or has a name
    //       for linkage purposes (7.1.3)) and the name has linkage; or
    //     -  it is a specialization of a class template (14); or
    Linkage L = Tag->getLinkageInternal();
    bool IsLocalOrUnnamed = Tag->getDeclContext()->isFunctionOrMethod() ||
                            !Tag->hasNameForLinkage();
    return CachedProperties(L, IsLocalOrUnnamed);
  }
 
    // C++ [basic.link]p8:
    //   - it is a compound type (3.9.2) other than a class or enumeration,
    //     compounded exclusively from types that have linkage; or
  case Type::Complex:
    return Cache::get(cast<ComplexType>(T)->getElementType());
  case Type::Pointer:
    return Cache::get(cast<PointerType>(T)->getPointeeType());
  case Type::BlockPointer:
    return Cache::get(cast<BlockPointerType>(T)->getPointeeType());
  case Type::LValueReference:
  case Type::RValueReference:
    return Cache::get(cast<ReferenceType>(T)->getPointeeType());
  case Type::MemberPointer: {
    const auto *MPT = cast<MemberPointerType>(T);
    CachedProperties Cls = [&] {
      if (MPT->isSugared())
        MPT = cast<MemberPointerType>(MPT->getCanonicalTypeInternal());
      return Cache::get(MPT->getQualifier().getAsType());
    }();
    return merge(Cls, Cache::get(MPT->getPointeeType()));
  }
  case Type::ConstantArray:
  case Type::IncompleteArray:
  case Type::VariableArray:
  case Type::ArrayParameter:
    return Cache::get(cast<ArrayType>(T)->getElementType());
  case Type::Vector:
  case Type::ExtVector:
    return Cache::get(cast<VectorType>(T)->getElementType());
  case Type::ConstantMatrix:
    return Cache::get(cast<ConstantMatrixType>(T)->getElementType());
  case Type::FunctionNoProto:
    return Cache::get(cast<FunctionType>(T)->getReturnType());
  case Type::FunctionProto: {
    const auto *FPT = cast<FunctionProtoType>(T);
    CachedProperties result = Cache::get(FPT->getReturnType());
    for (const auto &ai : FPT->param_types())
      result = merge(result, Cache::get(ai));
    return result;
  }
  case Type::ObjCInterface: {
    Linkage L = cast<ObjCInterfaceType>(T)->getDecl()->getLinkageInternal();
    return CachedProperties(L, false);
  }
  case Type::ObjCObject:
    return Cache::get(cast<ObjCObjectType>(T)->getBaseType());
  case Type::ObjCObjectPointer:
    return Cache::get(cast<ObjCObjectPointerType>(T)->getPointeeType());
  case Type::Atomic:
    return Cache::get(cast<AtomicType>(T)->getValueType());
  case Type::Pipe:
    return Cache::get(cast<PipeType>(T)->getElementType());
  case Type::HLSLAttributedResource:
    return Cache::get(cast<HLSLAttributedResourceType>(T)->getWrappedType());
  case Type::HLSLInlineSpirv:
    return CachedProperties(Linkage::External, false);
  case Type::OverflowBehavior:
    return Cache::get(cast<OverflowBehaviorType>(T)->getUnderlyingType());
  }
 
  llvm_unreachable("unhandled type class");
}
 
/// Determine the linkage of this type.
Linkage Type::getLinkage() const {
  Cache::ensure(this);
  return TypeBits.getLinkage();
}
 
bool Type::hasUnnamedOrLocalType() const {
  Cache::ensure(this);
  return TypeBits.hasLocalOrUnnamedType();
}
 
LinkageInfo LinkageComputer::computeTypeLinkageInfo(const Type *T) {
  switch (T->getTypeClass()) {
#define TYPE(Class, Base)
#define NON_CANONICAL_TYPE(Class, Base) case Type::Class:
#include "clang/AST/TypeNodes.inc"
    llvm_unreachable("didn't expect a non-canonical type here");
 
#define TYPE(Class, Base)
#define DEPENDENT_TYPE(Class, Base) case Type::Class:
#define NON_CANONICAL_UNLESS_DEPENDENT_TYPE(Class, Base) case Type::Class:
#include "clang/AST/TypeNodes.inc"
    // Treat instantiation-dependent types as external.
    assert(T->isInstantiationDependentType());
    return LinkageInfo::external();
 
  case Type::BitInt:
  case Type::Builtin:
    return LinkageInfo::external();
 
  case Type::Auto:
  case Type::DeducedTemplateSpecialization:
    return LinkageInfo::external();
 
  case Type::Record:
  case Type::Enum:
    return getDeclLinkageAndVisibility(
        cast<TagType>(T)->getDecl()->getDefinitionOrSelf());
 
  case Type::Complex:
    return computeTypeLinkageInfo(cast<ComplexType>(T)->getElementType());
  case Type::Pointer:
    return computeTypeLinkageInfo(cast<PointerType>(T)->getPointeeType());
  case Type::BlockPointer:
    return computeTypeLinkageInfo(cast<BlockPointerType>(T)->getPointeeType());
  case Type::LValueReference:
  case Type::RValueReference:
    return computeTypeLinkageInfo(cast<ReferenceType>(T)->getPointeeType());
  case Type::MemberPointer: {
    const auto *MPT = cast<MemberPointerType>(T);
    LinkageInfo LV;
    if (auto *D = MPT->getMostRecentCXXRecordDecl()) {
      LV.merge(getDeclLinkageAndVisibility(D));
    } else {
      LV.merge(computeTypeLinkageInfo(MPT->getQualifier().getAsType()));
    }
    LV.merge(computeTypeLinkageInfo(MPT->getPointeeType()));
    return LV;
  }
  case Type::ConstantArray:
  case Type::IncompleteArray:
  case Type::VariableArray:
  case Type::ArrayParameter:
    return computeTypeLinkageInfo(cast<ArrayType>(T)->getElementType());
  case Type::Vector:
  case Type::ExtVector:
    return computeTypeLinkageInfo(cast<VectorType>(T)->getElementType());
  case Type::ConstantMatrix:
    return computeTypeLinkageInfo(
        cast<ConstantMatrixType>(T)->getElementType());
  case Type::FunctionNoProto:
    return computeTypeLinkageInfo(cast<FunctionType>(T)->getReturnType());
  case Type::FunctionProto: {
    const auto *FPT = cast<FunctionProtoType>(T);
    LinkageInfo LV = computeTypeLinkageInfo(FPT->getReturnType());
    for (const auto &ai : FPT->param_types())
      LV.merge(computeTypeLinkageInfo(ai));
    return LV;
  }
  case Type::ObjCInterface:
    return getDeclLinkageAndVisibility(cast<ObjCInterfaceType>(T)->getDecl());
  case Type::ObjCObject:
    return computeTypeLinkageInfo(cast<ObjCObjectType>(T)->getBaseType());
  case Type::ObjCObjectPointer:
    return computeTypeLinkageInfo(
        cast<ObjCObjectPointerType>(T)->getPointeeType());
  case Type::Atomic:
    return computeTypeLinkageInfo(cast<AtomicType>(T)->getValueType());
  case Type::Pipe:
    return computeTypeLinkageInfo(cast<PipeType>(T)->getElementType());
  case Type::OverflowBehavior:
    return computeTypeLinkageInfo(
        cast<OverflowBehaviorType>(T)->getUnderlyingType());
  case Type::HLSLAttributedResource:
    return computeTypeLinkageInfo(cast<HLSLAttributedResourceType>(T)
                                      ->getContainedType()
                                      ->getCanonicalTypeInternal());
  case Type::HLSLInlineSpirv:
    return LinkageInfo::external();
  }
 
  llvm_unreachable("unhandled type class");
}
 
bool Type::isLinkageValid() const {
  if (!TypeBits.isCacheValid())
    return true;
 
  Linkage L = LinkageComputer{}
                  .computeTypeLinkageInfo(getCanonicalTypeInternal())
                  .getLinkage();
  return L == TypeBits.getLinkage();
}
 
LinkageInfo LinkageComputer::getTypeLinkageAndVisibility(const Type *T) {
  if (!T->isCanonicalUnqualified())
    return computeTypeLinkageInfo(T->getCanonicalTypeInternal());
 
  LinkageInfo LV = computeTypeLinkageInfo(T);
  assert(LV.getLinkage() == T->getLinkage());
  return LV;
}
 
LinkageInfo Type::getLinkageAndVisibility() const {
  return LinkageComputer{}.getTypeLinkageAndVisibility(this);
}
 
NullabilityKindOrNone Type::getNullability() const {
  QualType Type(this, 0);
  while (const auto *AT = Type->getAs<AttributedType>()) {
    // Check whether this is an attributed type with nullability
    // information.
    if (auto Nullability = AT->getImmediateNullability())
      return Nullability;
 
    Type = AT->getEquivalentType();
  }
  return std::nullopt;
}
 
bool Type::canHaveNullability(bool ResultIfUnknown) const {
  QualType type = getCanonicalTypeInternal();
 
  switch (type->getTypeClass()) {
#define NON_CANONICAL_TYPE(Class, Parent)                                      \
  /* We'll only see canonical types here. */                                   \
  case Type::Class:                                                            \
    llvm_unreachable("non-canonical type");
#define TYPE(Class, Parent)
#include "clang/AST/TypeNodes.inc"
 
  // Pointer types.
  case Type::Pointer:
  case Type::BlockPointer:
  case Type::MemberPointer:
  case Type::ObjCObjectPointer:
    return true;
 
  // Dependent types that could instantiate to pointer types.
  case Type::UnresolvedUsing:
  case Type::TypeOfExpr:
  case Type::TypeOf:
  case Type::Decltype:
  case Type::PackIndexing:
  case Type::UnaryTransform:
  case Type::TemplateTypeParm:
  case Type::SubstTemplateTypeParmPack:
  case Type::SubstBuiltinTemplatePack:
  case Type::DependentName:
  case Type::Auto:
    return ResultIfUnknown;
 
  // Dependent template specializations could instantiate to pointer types.
  case Type::TemplateSpecialization:
    // If it's a known class template, we can already check if it's nullable.
    if (TemplateDecl *templateDecl =
            cast<TemplateSpecializationType>(type.getTypePtr())
                ->getTemplateName()
                .getAsTemplateDecl())
      if (auto *CTD = dyn_cast<ClassTemplateDecl>(templateDecl))
        return llvm::any_of(
            CTD->redecls(), [](const RedeclarableTemplateDecl *RTD) {
              return RTD->getTemplatedDecl()->hasAttr<TypeNullableAttr>();
            });
    return ResultIfUnknown;
 
  case Type::Builtin:
    switch (cast<BuiltinType>(type.getTypePtr())->getKind()) {
      // Signed, unsigned, and floating-point types cannot have nullability.
#define SIGNED_TYPE(Id, SingletonId) case BuiltinType::Id:
#define UNSIGNED_TYPE(Id, SingletonId) case BuiltinType::Id:
#define FLOATING_TYPE(Id, SingletonId) case BuiltinType::Id:
#define BUILTIN_TYPE(Id, SingletonId)
#include "clang/AST/BuiltinTypes.def"
      return false;
 
    case BuiltinType::UnresolvedTemplate:
    // Dependent types that could instantiate to a pointer type.
    case BuiltinType::Dependent:
    case BuiltinType::Overload:
    case BuiltinType::BoundMember:
    case BuiltinType::PseudoObject:
    case BuiltinType::UnknownAny:
    case BuiltinType::ARCUnbridgedCast:
      return ResultIfUnknown;
 
    case BuiltinType::Void:
    case BuiltinType::ObjCId:
    case BuiltinType::ObjCClass:
    case BuiltinType::ObjCSel:
#define IMAGE_TYPE(ImgType, Id, SingletonId, Access, Suffix)                   \
  case BuiltinType::Id:
#include "clang/Basic/OpenCLImageTypes.def"
#define EXT_OPAQUE_TYPE(ExtType, Id, Ext) case BuiltinType::Id:
#include "clang/Basic/OpenCLExtensionTypes.def"
    case BuiltinType::OCLSampler:
    case BuiltinType::OCLEvent:
    case BuiltinType::OCLClkEvent:
    case BuiltinType::OCLQueue:
    case BuiltinType::OCLReserveID:
#define SVE_TYPE(Name, Id, SingletonId) case BuiltinType::Id:
#include "clang/Basic/AArch64ACLETypes.def"
#define PPC_VECTOR_TYPE(Name, Id, Size) case BuiltinType::Id:
#include "clang/Basic/PPCTypes.def"
#define RVV_TYPE(Name, Id, SingletonId) case BuiltinType::Id:
#include "clang/Basic/RISCVVTypes.def"
#define WASM_TYPE(Name, Id, SingletonId) case BuiltinType::Id:
#include "clang/Basic/WebAssemblyReferenceTypes.def"
#define AMDGPU_TYPE(Name, Id, SingletonId, Width, Align) case BuiltinType::Id:
#include "clang/Basic/AMDGPUTypes.def"
#define HLSL_INTANGIBLE_TYPE(Name, Id, SingletonId) case BuiltinType::Id:
#include "clang/Basic/HLSLIntangibleTypes.def"
    case BuiltinType::BuiltinFn:
    case BuiltinType::NullPtr:
    case BuiltinType::IncompleteMatrixIdx:
    case BuiltinType::ArraySection:
    case BuiltinType::OMPArrayShaping:
    case BuiltinType::OMPIterator:
      return false;
    }
    llvm_unreachable("unknown builtin type");
 
  case Type::Record: {
    const auto *RD = cast<RecordType>(type)->getDecl();
    // For template specializations, look only at primary template attributes.
    // This is a consistent regardless of whether the instantiation is known.
    if (const auto *CTSD = dyn_cast<ClassTemplateSpecializationDecl>(RD))
      return llvm::any_of(
          CTSD->getSpecializedTemplate()->redecls(),
          [](const RedeclarableTemplateDecl *RTD) {
            return RTD->getTemplatedDecl()->hasAttr<TypeNullableAttr>();
          });
    return llvm::any_of(RD->redecls(), [](const TagDecl *RD) {
      return RD->hasAttr<TypeNullableAttr>();
    });
  }
 
  // Non-pointer types.
  case Type::Complex:
  case Type::LValueReference:
  case Type::RValueReference:
  case Type::ConstantArray:
  case Type::IncompleteArray:
  case Type::VariableArray:
  case Type::DependentSizedArray:
  case Type::DependentVector:
  case Type::DependentSizedExtVector:
  case Type::Vector:
  case Type::ExtVector:
  case Type::ConstantMatrix:
  case Type::DependentSizedMatrix:
  case Type::DependentAddressSpace:
  case Type::FunctionProto:
  case Type::FunctionNoProto:
  case Type::DeducedTemplateSpecialization:
  case Type::Enum:
  case Type::InjectedClassName:
  case Type::PackExpansion:
  case Type::ObjCObject:
  case Type::ObjCInterface:
  case Type::Atomic:
  case Type::Pipe:
  case Type::BitInt:
  case Type::DependentBitInt:
  case Type::ArrayParameter:
  case Type::HLSLAttributedResource:
  case Type::HLSLInlineSpirv:
  case Type::OverflowBehavior:
    return false;
  }
  llvm_unreachable("bad type kind!");
}
 
NullabilityKindOrNone AttributedType::getImmediateNullability() const {
  if (getAttrKind() == attr::TypeNonNull)
    return NullabilityKind::NonNull;
  if (getAttrKind() == attr::TypeNullable)
    return NullabilityKind::Nullable;
  if (getAttrKind() == attr::TypeNullUnspecified)
    return NullabilityKind::Unspecified;
  if (getAttrKind() == attr::TypeNullableResult)
    return NullabilityKind::NullableResult;
  return std::nullopt;
}
 
NullabilityKindOrNone AttributedType::stripOuterNullability(QualType &T) {
  QualType AttrTy = T;
  if (auto MacroTy = dyn_cast<MacroQualifiedType>(T))
    AttrTy = MacroTy->getUnderlyingType();
 
  if (auto attributed = dyn_cast<AttributedType>(AttrTy)) {
    if (auto nullability = attributed->getImmediateNullability()) {
      T = attributed->getModifiedType();
      return nullability;
    }
  }
 
  return std::nullopt;
}
 
bool Type::isSignableIntegerType(const ASTContext &Ctx) const {
  if (!isIntegralType(Ctx) || isEnumeralType())
    return false;
  return Ctx.getTypeSize(this) == Ctx.getTypeSize(Ctx.VoidPtrTy);
}
 
bool Type::isBlockCompatibleObjCPointerType(ASTContext &ctx) const {
  const auto *objcPtr = getAs<ObjCObjectPointerType>();
  if (!objcPtr)
    return false;
 
  if (objcPtr->isObjCIdType()) {
    // id is always okay.
    return true;
  }
 
  // Blocks are NSObjects.
  if (ObjCInterfaceDecl *iface = objcPtr->getInterfaceDecl()) {
    if (iface->getIdentifier() != ctx.getNSObjectName())
      return false;
 
    // Continue to check qualifiers, below.
  } else if (objcPtr->isObjCQualifiedIdType()) {
    // Continue to check qualifiers, below.
  } else {
    return false;
  }
 
  // Check protocol qualifiers.
  for (ObjCProtocolDecl *proto : objcPtr->quals()) {
    // Blocks conform to NSObject and NSCopying.
    if (proto->getIdentifier() != ctx.getNSObjectName() &&
        proto->getIdentifier() != ctx.getNSCopyingName())
      return false;
  }
 
  return true;
}
 
Qualifiers::ObjCLifetime Type::getObjCARCImplicitLifetime() const {
  if (isObjCARCImplicitlyUnretainedType())
    return Qualifiers::OCL_ExplicitNone;
  return Qualifiers::OCL_Strong;
}
 
bool Type::isObjCARCImplicitlyUnretainedType() const {
  assert(isObjCLifetimeType() &&
         "cannot query implicit lifetime for non-inferrable type");
 
  const Type *canon = getCanonicalTypeInternal().getTypePtr();
 
  // Walk down to the base type.  We don't care about qualifiers for this.
  while (const auto *array = dyn_cast<ArrayType>(canon))
    canon = array->getElementType().getTypePtr();
 
  if (const auto *opt = dyn_cast<ObjCObjectPointerType>(canon)) {
    // Class and Class<Protocol> don't require retention.
    if (opt->getObjectType()->isObjCClass())
      return true;
  }
 
  return false;
}
 
bool Type::isObjCNSObjectType() const {
  if (const auto *typedefType = getAs<TypedefType>())
    return typedefType->getDecl()->hasAttr<ObjCNSObjectAttr>();
  return false;
}
 
bool Type::isObjCIndependentClassType() const {
  if (const auto *typedefType = getAs<TypedefType>())
    return typedefType->getDecl()->hasAttr<ObjCIndependentClassAttr>();
  return false;
}
 
bool Type::isObjCRetainableType() const {
  return isObjCObjectPointerType() || isBlockPointerType() ||
         isObjCNSObjectType();
}
 
bool Type::isObjCIndirectLifetimeType() const {
  if (isObjCLifetimeType())
    return true;
  if (const auto *OPT = getAs<PointerType>())
    return OPT->getPointeeType()->isObjCIndirectLifetimeType();
  if (const auto *Ref = getAs<ReferenceType>())
    return Ref->getPointeeType()->isObjCIndirectLifetimeType();
  if (const auto *MemPtr = getAs<MemberPointerType>())
    return MemPtr->getPointeeType()->isObjCIndirectLifetimeType();
  return false;
}
 
/// Returns true if objects of this type have lifetime semantics under
/// ARC.
bool Type::isObjCLifetimeType() const {
  const Type *type = this;
  while (const ArrayType *array = type->getAsArrayTypeUnsafe())
    type = array->getElementType().getTypePtr();
  return type->isObjCRetainableType();
}
 
/// Determine whether the given type T is a "bridgable" Objective-C type,
/// which is either an Objective-C object pointer type or an
bool Type::isObjCARCBridgableType() const {
  return isObjCObjectPointerType() || isBlockPointerType();
}
 
/// Determine whether the given type T is a "bridgeable" C type.
bool Type::isCARCBridgableType() const {
  const auto *Pointer = getAsCanonical<PointerType>();
  if (!Pointer)
    return false;
 
  QualType Pointee = Pointer->getPointeeType();
  return Pointee->isVoidType() || Pointee->isRecordType();
}
 
/// Check if the specified type is the CUDA device builtin surface type.
bool Type::isCUDADeviceBuiltinSurfaceType() const {
  if (const auto *RT = getAsCanonical<RecordType>())
    return RT->getDecl()
        ->getMostRecentDecl()
        ->hasAttr<CUDADeviceBuiltinSurfaceTypeAttr>();
  return false;
}
 
/// Check if the specified type is the CUDA device builtin texture type.
bool Type::isCUDADeviceBuiltinTextureType() const {
  if (const auto *RT = getAsCanonical<RecordType>())
    return RT->getDecl()
        ->getMostRecentDecl()
        ->hasAttr<CUDADeviceBuiltinTextureTypeAttr>();
  return false;
}
 
bool Type::hasSizedVLAType() const {
  if (!isVariablyModifiedType())
    return false;
 
  if (const auto *ptr = getAs<PointerType>())
    return ptr->getPointeeType()->hasSizedVLAType();
  if (const auto *ref = getAs<ReferenceType>())
    return ref->getPointeeType()->hasSizedVLAType();
  if (const ArrayType *arr = getAsArrayTypeUnsafe()) {
    if (isa<VariableArrayType>(arr) &&
        cast<VariableArrayType>(arr)->getSizeExpr())
      return true;
 
    return arr->getElementType()->hasSizedVLAType();
  }
 
  return false;
}
 
bool Type::isHLSLResourceRecord() const {
  return HLSLAttributedResourceType::findHandleTypeOnResource(this) != nullptr;
}
 
bool Type::isHLSLResourceRecordArray() const {
  const Type *Ty = getUnqualifiedDesugaredType();
  if (!Ty->isArrayType())
    return false;
  while (isa<ArrayType>(Ty))
    Ty = Ty->getArrayElementTypeNoTypeQual();
  return Ty->isHLSLResourceRecord();
}
 
bool Type::isHLSLIntangibleType() const {
  const Type *Ty = getUnqualifiedDesugaredType();
 
  // check if it's a builtin type first
  if (Ty->isBuiltinType())
    return Ty->isHLSLBuiltinIntangibleType();
 
  // unwrap arrays
  while (isa<ArrayType>(Ty))
    Ty = Ty->getArrayElementTypeNoTypeQual();
 
  const RecordType *RT =
      dyn_cast<RecordType>(Ty->getUnqualifiedDesugaredType());
  if (!RT)
    return false;
 
  CXXRecordDecl *RD = RT->getAsCXXRecordDecl();
  assert(RD != nullptr &&
         "all HLSL structs and classes should be CXXRecordDecl");
  assert(RD->isCompleteDefinition() && "expecting complete type");
  return RD->isHLSLIntangible();
}
 
QualType::DestructionKind QualType::isDestructedTypeImpl(QualType type) {
  switch (type.getObjCLifetime()) {
  case Qualifiers::OCL_None:
  case Qualifiers::OCL_ExplicitNone:
  case Qualifiers::OCL_Autoreleasing:
    break;
 
  case Qualifiers::OCL_Strong:
    return DK_objc_strong_lifetime;
  case Qualifiers::OCL_Weak:
    return DK_objc_weak_lifetime;
  }
 
  if (const auto *RD = type->getBaseElementTypeUnsafe()->getAsRecordDecl()) {
    if (const auto *CXXRD = dyn_cast<CXXRecordDecl>(RD)) {
      /// Check if this is a C++ object with a non-trivial destructor.
      if (CXXRD->hasDefinition() && !CXXRD->hasTrivialDestructor())
        return DK_cxx_destructor;
    } else {
      /// Check if this is a C struct that is non-trivial to destroy or an array
      /// that contains such a struct.
      if (RD->isNonTrivialToPrimitiveDestroy())
        return DK_nontrivial_c_struct;
    }
  }
 
  return DK_none;
}
 
bool MemberPointerType::isSugared() const {
  CXXRecordDecl *D1 = getMostRecentCXXRecordDecl(),
                *D2 = getQualifier().getAsRecordDecl();
  assert(!D1 == !D2);
  return D1 != D2 && D1->getCanonicalDecl() != D2->getCanonicalDecl();
}
 
void MemberPointerType::Profile(llvm::FoldingSetNodeID &ID, QualType Pointee,
                                const NestedNameSpecifier Qualifier,
                                const CXXRecordDecl *Cls) {
  ID.AddPointer(Pointee.getAsOpaquePtr());
  Qualifier.Profile(ID);
  if (Cls)
    ID.AddPointer(Cls->getCanonicalDecl());
}
 
CXXRecordDecl *MemberPointerType::getCXXRecordDecl() const {
  return dyn_cast<MemberPointerType>(getCanonicalTypeInternal())
      ->getQualifier()
      .getAsRecordDecl();
}
 
CXXRecordDecl *MemberPointerType::getMostRecentCXXRecordDecl() const {
  auto *RD = getCXXRecordDecl();
  if (!RD)
    return nullptr;
  return RD->getMostRecentDecl();
}
 
void clang::FixedPointValueToString(SmallVectorImpl<char> &Str,
                                    llvm::APSInt Val, unsigned Scale) {
  llvm::FixedPointSemantics FXSema(Val.getBitWidth(), Scale, Val.isSigned(),
                                   /*IsSaturated=*/false,
                                   /*HasUnsignedPadding=*/false);
  llvm::APFixedPoint(Val, FXSema).toString(Str);
}
 
DeducedType::DeducedType(TypeClass TC, DeducedKind DK,
                         QualType DeducedAsTypeOrCanon)
    : Type(TC, /*canon=*/DK == DeducedKind::Deduced
                   ? DeducedAsTypeOrCanon.getCanonicalType()
                   : DeducedAsTypeOrCanon,
           TypeDependence::None) {
  DeducedTypeBits.Kind = llvm::to_underlying(DK);
  switch (DK) {
  case DeducedKind::Undeduced:
    break;
  case DeducedKind::Deduced:
    assert(!DeducedAsTypeOrCanon.isNull() && "Deduced type cannot be null");
    addDependence(DeducedAsTypeOrCanon->getDependence() &
                  ~TypeDependence::VariablyModified);
    DeducedAsType = DeducedAsTypeOrCanon;
    break;
  case DeducedKind::DeducedAsPack:
    addDependence(TypeDependence::UnexpandedPack);
    [[fallthrough]];
  case DeducedKind::DeducedAsDependent:
    addDependence(TypeDependence::DependentInstantiation);
    break;
  }
  assert(getDeducedKind() == DK && "DeducedKind does not match the type state");
}
 
AutoType::AutoType(DeducedKind DK, QualType DeducedAsTypeOrCanon,
                   AutoTypeKeyword Keyword, TemplateDecl *TypeConstraintConcept,
                   ArrayRef<TemplateArgument> TypeConstraintArgs)
    : DeducedType(Auto, DK, DeducedAsTypeOrCanon) {
  AutoTypeBits.Keyword = llvm::to_underlying(Keyword);
  AutoTypeBits.NumArgs = TypeConstraintArgs.size();
  this->TypeConstraintConcept = TypeConstraintConcept;
  assert(TypeConstraintConcept || AutoTypeBits.NumArgs == 0);
  if (TypeConstraintConcept) {
    auto Dep = TypeDependence::None;
    if (const auto *TTP =
            dyn_cast<TemplateTemplateParmDecl>(TypeConstraintConcept))
      Dep = TypeDependence::DependentInstantiation |
            (TTP->isParameterPack() ? TypeDependence::UnexpandedPack
                                    : TypeDependence::None);
 
    auto *ArgBuffer =
        const_cast<TemplateArgument *>(getTypeConstraintArguments().data());
    for (const TemplateArgument &Arg : TypeConstraintArgs) {
      Dep |= toTypeDependence(Arg.getDependence());
      new (ArgBuffer++) TemplateArgument(Arg);
    }
    // A deduced AutoType only syntactically depends on its constraints.
    if (DK == DeducedKind::Deduced)
      Dep = toSyntacticDependence(Dep);
    addDependence(Dep);
  }
}
 
void AutoType::Profile(llvm::FoldingSetNodeID &ID, const ASTContext &Context,
                       DeducedKind DK, QualType Deduced,
                       AutoTypeKeyword Keyword, TemplateDecl *CD,
                       ArrayRef<TemplateArgument> Arguments) {
  DeducedType::Profile(ID, DK, Deduced);
  ID.AddInteger(llvm::to_underlying(Keyword));
  ID.AddPointer(CD);
  for (const TemplateArgument &Arg : Arguments)
    Arg.Profile(ID, Context);
}
 
void AutoType::Profile(llvm::FoldingSetNodeID &ID, const ASTContext &Context) {
  Profile(ID, Context, getDeducedKind(), getDeducedType(), getKeyword(),
          getTypeConstraintConcept(), getTypeConstraintArguments());
}
 
FunctionEffect::Kind FunctionEffect::oppositeKind() const {
  switch (kind()) {
  case Kind::NonBlocking:
    return Kind::Blocking;
  case Kind::Blocking:
    return Kind::NonBlocking;
  case Kind::NonAllocating:
    return Kind::Allocating;
  case Kind::Allocating:
    return Kind::NonAllocating;
  }
  llvm_unreachable("unknown effect kind");
}
 
StringRef FunctionEffect::name() const {
  switch (kind()) {
  case Kind::NonBlocking:
    return "nonblocking";
  case Kind::NonAllocating:
    return "nonallocating";
  case Kind::Blocking:
    return "blocking";
  case Kind::Allocating:
    return "allocating";
  }
  llvm_unreachable("unknown effect kind");
}
 
std::optional<FunctionEffect> FunctionEffect::effectProhibitingInference(
    const Decl &Callee, FunctionEffectKindSet CalleeFX) const {
  switch (kind()) {
  case Kind::NonAllocating:
  case Kind::NonBlocking: {
    for (FunctionEffect Effect : CalleeFX) {
      // nonblocking/nonallocating cannot call allocating.
      if (Effect.kind() == Kind::Allocating)
        return Effect;
      // nonblocking cannot call blocking.
      if (kind() == Kind::NonBlocking && Effect.kind() == Kind::Blocking)
        return Effect;
    }
    return std::nullopt;
  }
 
  case Kind::Allocating:
  case Kind::Blocking:
    assert(0 && "effectProhibitingInference with non-inferable effect kind");
    break;
  }
  llvm_unreachable("unknown effect kind");
}
 
bool FunctionEffect::shouldDiagnoseFunctionCall(
    bool Direct, FunctionEffectKindSet CalleeFX) const {
  switch (kind()) {
  case Kind::NonAllocating:
  case Kind::NonBlocking: {
    const Kind CallerKind = kind();
    for (FunctionEffect Effect : CalleeFX) {
      const Kind EK = Effect.kind();
      // Does callee have same or stronger constraint?
      if (EK == CallerKind ||
          (CallerKind == Kind::NonAllocating && EK == Kind::NonBlocking)) {
        return false; // no diagnostic
      }
    }
    return true; // warning
  }
  case Kind::Allocating:
  case Kind::Blocking:
    return false;
  }
  llvm_unreachable("unknown effect kind");
}
 
// =====
 
bool FunctionEffectSet::insert(const FunctionEffectWithCondition &NewEC,
                               Conflicts &Errs) {
  FunctionEffect::Kind NewOppositeKind = NewEC.Effect.oppositeKind();
  Expr *NewCondition = NewEC.Cond.getCondition();
 
  // The index at which insertion will take place; default is at end
  // but we might find an earlier insertion point.
  unsigned InsertIdx = Effects.size();
  unsigned Idx = 0;
  for (const FunctionEffectWithCondition &EC : *this) {
    // Note about effects with conditions: They are considered distinct from
    // those without conditions; they are potentially unique, redundant, or
    // in conflict, but we can't tell which until the condition is evaluated.
    if (EC.Cond.getCondition() == nullptr && NewCondition == nullptr) {
      if (EC.Effect.kind() == NewEC.Effect.kind()) {
        // There is no condition, and the effect kind is already present,
        // so just fail to insert the new one (creating a duplicate),
        // and return success.
        return true;
      }
 
      if (EC.Effect.kind() == NewOppositeKind) {
        Errs.push_back({EC, NewEC});
        return false;
      }
    }
 
    if (NewEC.Effect.kind() < EC.Effect.kind() && InsertIdx > Idx)
      InsertIdx = Idx;
 
    ++Idx;
  }
 
  if (NewCondition || !Conditions.empty()) {
    if (Conditions.empty() && !Effects.empty())
      Conditions.resize(Effects.size());
    Conditions.insert(Conditions.begin() + InsertIdx,
                      NewEC.Cond.getCondition());
  }
  Effects.insert(Effects.begin() + InsertIdx, NewEC.Effect);
  return true;
}
 
bool FunctionEffectSet::insert(const FunctionEffectsRef &Set, Conflicts &Errs) {
  for (const auto &Item : Set)
    insert(Item, Errs);
  return Errs.empty();
}
 
FunctionEffectSet FunctionEffectSet::getIntersection(FunctionEffectsRef LHS,
                                                     FunctionEffectsRef RHS) {
  FunctionEffectSet Result;
  FunctionEffectSet::Conflicts Errs;
 
  // We could use std::set_intersection but that would require expanding the
  // container interface to include push_back, making it available to clients
  // who might fail to maintain invariants.
  auto IterA = LHS.begin(), EndA = LHS.end();
  auto IterB = RHS.begin(), EndB = RHS.end();
 
  auto FEWCLess = [](const FunctionEffectWithCondition &LHS,
                     const FunctionEffectWithCondition &RHS) {
    return std::tuple(LHS.Effect, uintptr_t(LHS.Cond.getCondition())) <
           std::tuple(RHS.Effect, uintptr_t(RHS.Cond.getCondition()));
  };
 
  while (IterA != EndA && IterB != EndB) {
    FunctionEffectWithCondition A = *IterA;
    FunctionEffectWithCondition B = *IterB;
    if (FEWCLess(A, B))
      ++IterA;
    else if (FEWCLess(B, A))
      ++IterB;
    else {
      Result.insert(A, Errs);
      ++IterA;
      ++IterB;
    }
  }
 
  // Insertion shouldn't be able to fail; that would mean both input
  // sets contained conflicts.
  assert(Errs.empty() && "conflict shouldn't be possible in getIntersection");
 
  return Result;
}
 
FunctionEffectSet FunctionEffectSet::getUnion(FunctionEffectsRef LHS,
                                              FunctionEffectsRef RHS,
                                              Conflicts &Errs) {
  // Optimize for either of the two sets being empty (very common).
  if (LHS.empty())
    return FunctionEffectSet(RHS);
 
  FunctionEffectSet Combined(LHS);
  Combined.insert(RHS, Errs);
  return Combined;
}
 
namespace clang {
 
raw_ostream &operator<<(raw_ostream &OS,
                        const FunctionEffectWithCondition &CFE) {
  OS << CFE.Effect.name();
  if (Expr *E = CFE.Cond.getCondition()) {
    OS << '(';
    E->dump();
    OS << ')';
  }
  return OS;
}
 
} // namespace clang
 
LLVM_DUMP_METHOD void FunctionEffectsRef::dump(llvm::raw_ostream &OS) const {
  OS << "Effects{";
  llvm::interleaveComma(*this, OS);
  OS << "}";
}
 
LLVM_DUMP_METHOD void FunctionEffectSet::dump(llvm::raw_ostream &OS) const {
  FunctionEffectsRef(*this).dump(OS);
}
 
LLVM_DUMP_METHOD void FunctionEffectKindSet::dump(llvm::raw_ostream &OS) const {
  OS << "Effects{";
  llvm::interleaveComma(*this, OS);
  OS << "}";
}
 
FunctionEffectsRef
FunctionEffectsRef::create(ArrayRef<FunctionEffect> FX,
                           ArrayRef<EffectConditionExpr> Conds) {
  assert(llvm::is_sorted(FX) && "effects should be sorted");
  assert((Conds.empty() || Conds.size() == FX.size()) &&
         "effects size should match conditions size");
  return FunctionEffectsRef(FX, Conds);
}
 
std::string FunctionEffectWithCondition::description() const {
  std::string Result(Effect.name().str());
  if (Cond.getCondition() != nullptr)
    Result += "(expr)";
  return Result;
}
 
const HLSLAttributedResourceType *
HLSLAttributedResourceType::findHandleTypeOnResource(const Type *RT) {
  // If the type RT is an HLSL resource class, the first field must
  // be the resource handle of type HLSLAttributedResourceType
  const clang::Type *Ty = RT->getUnqualifiedDesugaredType();
  if (const RecordDecl *RD = Ty->getAsCXXRecordDecl()) {
    if (!RD->fields().empty()) {
      const auto &FirstFD = RD->fields().begin();
      return dyn_cast<HLSLAttributedResourceType>(
          FirstFD->getType().getTypePtr());
    }
  }
  return nullptr;
}
 
StringRef PredefinedSugarType::getName(Kind KD) {
  switch (KD) {
  case Kind::SizeT:
    return "__size_t";
  case Kind::SignedSizeT:
    return "__signed_size_t";
  case Kind::PtrdiffT:
    return "__ptrdiff_t";
  }
  llvm_unreachable("unexpected kind");
}