Mercurial > hg > CbC > CbC_llvm
view tools/clang/lib/AST/Type.cpp @ 110:0ba6fe025c14
minor fix
| author | Kaito Tokumori <e105711@ie.u-ryukyu.ac.jp> |
|---|---|
| date | Tue, 02 Feb 2016 19:26:30 +0900 |
| parents | 57be027de0f4 |
| children | 36195a0db682 |
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line source
//===--- Type.cpp - Type representation and manipulation ------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file implements type-related functionality. // //===----------------------------------------------------------------------===// #include "clang/AST/ASTContext.h" #include "clang/AST/Attr.h" #include "clang/AST/CharUnits.h" #include "clang/AST/DeclCXX.h" #include "clang/AST/DeclObjC.h" #include "clang/AST/DeclTemplate.h" #include "clang/AST/Expr.h" #include "clang/AST/PrettyPrinter.h" #include "clang/AST/Type.h" #include "clang/AST/TypeVisitor.h" #include "clang/Basic/Specifiers.h" #include "clang/Basic/TargetInfo.h" #include "llvm/ADT/APSInt.h" #include "llvm/ADT/StringExtras.h" #include "llvm/Support/raw_ostream.h" #include <algorithm> 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())); } const IdentifierInfo* QualType::getBaseTypeIdentifier() const { const Type* ty = getTypePtr(); NamedDecl *ND = nullptr; if (ty->isPointerType() || ty->isReferenceType()) return ty->getPointeeType().getBaseTypeIdentifier(); else if (ty->isRecordType()) ND = ty->getAs<RecordType>()->getDecl(); else if (ty->isEnumeralType()) ND = ty->getAs<EnumType>()->getDecl(); else if (ty->getTypeClass() == Type::Typedef) ND = ty->getAs<TypedefType>()->getDecl(); else if (ty->isArrayType()) return ty->castAsArrayTypeUnsafe()-> getElementType().getBaseTypeIdentifier(); if (ND) return ND->getIdentifier(); return nullptr; } bool QualType::isConstant(QualType T, 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; } unsigned ConstantArrayType::getNumAddressingBits(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 64 - llvm::countLeadingZeros(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::getMaxSizeBits(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; } DependentSizedArrayType::DependentSizedArrayType(const ASTContext &Context, QualType et, QualType can, Expr *e, ArraySizeModifier sm, unsigned tq, SourceRange brackets) : ArrayType(DependentSizedArray, et, can, sm, tq, (et->containsUnexpandedParameterPack() || (e && e->containsUnexpandedParameterPack()))), Context(Context), SizeExpr((Stmt*) e), Brackets(brackets) { } void DependentSizedArrayType::Profile(llvm::FoldingSetNodeID &ID, const ASTContext &Context, QualType ET, ArraySizeModifier SizeMod, unsigned TypeQuals, Expr *E) { ID.AddPointer(ET.getAsOpaquePtr()); ID.AddInteger(SizeMod); ID.AddInteger(TypeQuals); E->Profile(ID, Context, true); } DependentSizedExtVectorType::DependentSizedExtVectorType(const ASTContext &Context, QualType ElementType, QualType can, Expr *SizeExpr, SourceLocation loc) : Type(DependentSizedExtVector, can, /*Dependent=*/true, /*InstantiationDependent=*/true, ElementType->isVariablyModifiedType(), (ElementType->containsUnexpandedParameterPack() || (SizeExpr && SizeExpr->containsUnexpandedParameterPack()))), Context(Context), 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); } 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->isDependentType(), vecType->isInstantiationDependentType(), vecType->isVariablyModifiedType(), vecType->containsUnexpandedParameterPack()), ElementType(vecType) { VectorTypeBits.VecKind = vecKind; VectorTypeBits.NumElements = nElements; } /// 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 ArrayType *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); } QualType Type::getLocallyUnqualifiedSingleStepDesugaredType() const { switch (getTypeClass()) { #define ABSTRACT_TYPE(Class, Parent) #define TYPE(Class, Parent) \ case Type::Class: { \ const Class##Type *ty = cast<Class##Type>(this); \ if (!ty->isSugared()) return QualType(ty, 0); \ return ty->desugar(); \ } #include "clang/AST/TypeNodes.def" } 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 Class##Type *Ty = cast<Class##Type>(CurTy); \ if (!Ty->isSugared()) \ return SplitQualType(Ty, Qs); \ Cur = Ty->desugar(); \ break; \ } #include "clang/AST/TypeNodes.def" } } } 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 Class##Type *ty = cast<Class##Type>(split.Ty); \ if (!ty->isSugared()) goto done; \ next = ty->desugar(); \ break; \ } #include "clang/AST/TypeNodes.def" } // 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 ParenType *PT = T->getAs<ParenType>()) T = PT->getInnerType(); return T; } /// \brief 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 T *Sugar = dyn_cast<T>(Cur)) return Sugar; switch (Cur->getTypeClass()) { #define ABSTRACT_TYPE(Class, Parent) #define TYPE(Class, Parent) \ case Type::Class: { \ const Class##Type *Ty = cast<Class##Type>(Cur); \ if (!Ty->isSugared()) return 0; \ Cur = Ty->desugar().getTypePtr(); \ break; \ } #include "clang/AST/TypeNodes.def" } } } template <> const TypedefType *Type::getAs() const { return getAsSugar<TypedefType>(this); } template <> const TemplateSpecializationType *Type::getAs() const { return getAsSugar<TemplateSpecializationType>(this); } template <> const AttributedType *Type::getAs() const { return getAsSugar<AttributedType>(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 Class##Type *Ty = cast<Class##Type>(Cur); \ if (!Ty->isSugared()) return Cur; \ Cur = Ty->desugar().getTypePtr(); \ break; \ } #include "clang/AST/TypeNodes.def" } } } bool Type::isClassType() const { if (const RecordType *RT = getAs<RecordType>()) return RT->getDecl()->isClass(); return false; } bool Type::isStructureType() const { if (const RecordType *RT = getAs<RecordType>()) return RT->getDecl()->isStruct(); return false; } bool Type::isObjCBoxableRecordType() const { if (const RecordType *RT = getAs<RecordType>()) return RT->getDecl()->hasAttr<ObjCBoxableAttr>(); return false; } bool Type::isInterfaceType() const { if (const RecordType *RT = getAs<RecordType>()) return RT->getDecl()->isInterface(); return false; } bool Type::isStructureOrClassType() const { if (const RecordType *RT = getAs<RecordType>()) { RecordDecl *RD = RT->getDecl(); return RD->isStruct() || RD->isClass() || RD->isInterface(); } return false; } bool Type::isVoidPointerType() const { if (const PointerType *PT = getAs<PointerType>()) return PT->getPointeeType()->isVoidType(); return false; } bool Type::isUnionType() const { if (const RecordType *RT = getAs<RecordType>()) return RT->getDecl()->isUnion(); return false; } bool Type::isComplexType() const { if (const ComplexType *CT = dyn_cast<ComplexType>(CanonicalType)) return CT->getElementType()->isFloatingType(); return false; } bool Type::isComplexIntegerType() const { // Check for GCC complex integer extension. return getAsComplexIntegerType(); } const ComplexType *Type::getAsComplexIntegerType() const { if (const ComplexType *Complex = getAs<ComplexType>()) if (Complex->getElementType()->isIntegerType()) return Complex; return nullptr; } QualType Type::getPointeeType() const { if (const PointerType *PT = getAs<PointerType>()) return PT->getPointeeType(); if (const ObjCObjectPointerType *OPT = getAs<ObjCObjectPointerType>()) return OPT->getPointeeType(); if (const BlockPointerType *BPT = getAs<BlockPointerType>()) return BPT->getPointeeType(); if (const ReferenceType *RT = getAs<ReferenceType>()) return RT->getPointeeType(); if (const MemberPointerType *MPT = getAs<MemberPointerType>()) return MPT->getPointeeType(); if (const DecayedType *DT = getAs<DecayedType>()) return DT->getPointeeType(); return QualType(); } const RecordType *Type::getAsStructureType() const { // If this is directly a structure type, return it. if (const RecordType *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 RecordType *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 RecordType *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 RecordType *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 ObjCObjectPointerType *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 ObjCObjectPointerType *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(); } /// Was this type written with the special inert-in-MRC __unsafe_unretained /// qualifier? /// /// This approximates the answer to the following question: if this /// translation unit were compiled in ARC, would this type be qualified /// with __unsafe_unretained? bool Type::isObjCInertUnsafeUnretainedType() const { const Type *cur = this; while (true) { if (auto attributed = dyn_cast<AttributedType>(cur)) { if (attributed->getAttrKind() == AttributedType::attr_objc_inert_unsafe_unretained) return true; } // Single-step desugar until we run out of sugar. QualType next = cur->getLocallyUnqualifiedSingleStepDesugaredType(); if (next.getTypePtr() == cur) return false; cur = next.getTypePtr(); } } ObjCObjectType::ObjCObjectType(QualType Canonical, QualType Base, ArrayRef<QualType> typeArgs, ArrayRef<ObjCProtocolDecl *> protocols, bool isKindOf) : Type(ObjCObject, Canonical, Base->isDependentType(), Base->isInstantiationDependentType(), Base->isVariablyModifiedType(), Base->containsUnexpandedParameterPack()), BaseType(Base) { ObjCObjectTypeBits.IsKindOf = isKindOf; ObjCObjectTypeBits.NumTypeArgs = typeArgs.size(); assert(getTypeArgsAsWritten().size() == typeArgs.size() && "bitfield overflow in type argument count"); ObjCObjectTypeBits.NumProtocols = protocols.size(); assert(getNumProtocols() == protocols.size() && "bitfield overflow in protocol count"); if (!typeArgs.empty()) memcpy(getTypeArgStorage(), typeArgs.data(), typeArgs.size() * sizeof(QualType)); if (!protocols.empty()) memcpy(getProtocolStorage(), protocols.data(), protocols.size() * sizeof(ObjCProtocolDecl*)); for (auto typeArg : typeArgs) { if (typeArg->isDependentType()) setDependent(); else if (typeArg->isInstantiationDependentType()) setInstantiationDependent(); if (typeArg->containsUnexpandedParameterPack()) setContainsUnexpandedParameterPack(); } } 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 (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 (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 (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 ObjCObjectType *baseObj = splitBaseType.Ty->getAs<ObjCObjectType>()) { baseType = baseObj->stripObjCKindOfTypeAndQuals(ctx); } return ctx.getObjCObjectType(ctx.getQualifiedType(baseType, splitBaseType.Quals), getTypeArgsAsWritten(), /*protocols=*/{ }, /*isKindOf=*/false); } 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 { template<typename F> QualType simpleTransform(ASTContext &ctx, QualType type, F &&f); /// Visitor used by simpleTransform() to perform the transformation. template<typename F> struct SimpleTransformVisitor : public TypeVisitor<SimpleTransformVisitor<F>, QualType> { ASTContext &Ctx; F &&TheFunc; QualType recurse(QualType type) { return simpleTransform(Ctx, type, std::move(TheFunc)); } public: SimpleTransformVisitor(ASTContext &ctx, F &&f) : Ctx(ctx), TheFunc(std::move(f)) { } // 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.def" #define TRIVIAL_TYPE_CLASS(Class) \ QualType Visit##Class##Type(const Class##Type *T) { return QualType(T, 0); } TRIVIAL_TYPE_CLASS(Builtin) QualType VisitComplexType(const ComplexType *T) { QualType elementType = recurse(T->getElementType()); if (elementType.isNull()) return QualType(); 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 QualType(); 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 QualType(); 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 QualType(); 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 QualType(); 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 QualType(); if (pointeeType.getAsOpaquePtr() == T->getPointeeType().getAsOpaquePtr()) return QualType(T, 0); return Ctx.getMemberPointerType(pointeeType, T->getClass()); } QualType VisitConstantArrayType(const ConstantArrayType *T) { QualType elementType = recurse(T->getElementType()); if (elementType.isNull()) return QualType(); if (elementType.getAsOpaquePtr() == T->getElementType().getAsOpaquePtr()) return QualType(T, 0); return Ctx.getConstantArrayType(elementType, T->getSize(), T->getSizeModifier(), T->getIndexTypeCVRQualifiers()); } QualType VisitVariableArrayType(const VariableArrayType *T) { QualType elementType = recurse(T->getElementType()); if (elementType.isNull()) return QualType(); if (elementType.getAsOpaquePtr() == T->getElementType().getAsOpaquePtr()) return QualType(T, 0); return Ctx.getVariableArrayType(elementType, T->getSizeExpr(), T->getSizeModifier(), T->getIndexTypeCVRQualifiers(), T->getBracketsRange()); } QualType VisitIncompleteArrayType(const IncompleteArrayType *T) { QualType elementType = recurse(T->getElementType()); if (elementType.isNull()) return QualType(); 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 QualType(); 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 QualType(); if (elementType.getAsOpaquePtr() == T->getElementType().getAsOpaquePtr()) return QualType(T, 0); return Ctx.getExtVectorType(elementType, T->getNumElements()); } QualType VisitFunctionNoProtoType(const FunctionNoProtoType *T) { QualType returnType = recurse(T->getReturnType()); if (returnType.isNull()) return QualType(); 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 QualType(); // Transform parameter types. SmallVector<QualType, 4> paramTypes; bool paramChanged = false; for (auto paramType : T->getParamTypes()) { QualType newParamType = recurse(paramType); if (newParamType.isNull()) return QualType(); 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 QualType(); if (newExceptionType.getAsOpaquePtr() != exceptionType.getAsOpaquePtr()) exceptionChanged = true; exceptionTypes.push_back(newExceptionType); } if (exceptionChanged) { info.ExceptionSpec.Exceptions = llvm::makeArrayRef(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 QualType(); if (innerType.getAsOpaquePtr() == T->getInnerType().getAsOpaquePtr()) return QualType(T, 0); return Ctx.getParenType(innerType); } TRIVIAL_TYPE_CLASS(Typedef) QualType VisitAdjustedType(const AdjustedType *T) { QualType originalType = recurse(T->getOriginalType()); if (originalType.isNull()) return QualType(); QualType adjustedType = recurse(T->getAdjustedType()); if (adjustedType.isNull()) return QualType(); 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 QualType(); if (originalType.getAsOpaquePtr() == T->getOriginalType().getAsOpaquePtr()) return QualType(T, 0); return Ctx.getDecayedType(originalType); } TRIVIAL_TYPE_CLASS(TypeOfExpr) TRIVIAL_TYPE_CLASS(TypeOf) TRIVIAL_TYPE_CLASS(Decltype) TRIVIAL_TYPE_CLASS(UnaryTransform) TRIVIAL_TYPE_CLASS(Record) TRIVIAL_TYPE_CLASS(Enum) // FIXME: Non-trivial to implement, but important for C++ TRIVIAL_TYPE_CLASS(Elaborated) QualType VisitAttributedType(const AttributedType *T) { QualType modifiedType = recurse(T->getModifiedType()); if (modifiedType.isNull()) return QualType(); QualType equivalentType = recurse(T->getEquivalentType()); if (equivalentType.isNull()) return QualType(); if (modifiedType.getAsOpaquePtr() == T->getModifiedType().getAsOpaquePtr() && equivalentType.getAsOpaquePtr() == T->getEquivalentType().getAsOpaquePtr()) return QualType(T, 0); return Ctx.getAttributedType(T->getAttrKind(), modifiedType, equivalentType); } QualType VisitSubstTemplateTypeParmType(const SubstTemplateTypeParmType *T) { QualType replacementType = recurse(T->getReplacementType()); if (replacementType.isNull()) return QualType(); if (replacementType.getAsOpaquePtr() == T->getReplacementType().getAsOpaquePtr()) return QualType(T, 0); return Ctx.getSubstTemplateTypeParmType(T->getReplacedParameter(), replacementType); } // FIXME: Non-trivial to implement, but important for C++ TRIVIAL_TYPE_CLASS(TemplateSpecialization) QualType VisitAutoType(const AutoType *T) { if (!T->isDeduced()) return QualType(T, 0); QualType deducedType = recurse(T->getDeducedType()); if (deducedType.isNull()) return QualType(); if (deducedType.getAsOpaquePtr() == T->getDeducedType().getAsOpaquePtr()) return QualType(T, 0); return Ctx.getAutoType(deducedType, T->getKeyword(), T->isDependentType()); } // FIXME: Non-trivial to implement, but important for C++ TRIVIAL_TYPE_CLASS(PackExpansion) QualType VisitObjCObjectType(const ObjCObjectType *T) { QualType baseType = recurse(T->getBaseType()); if (baseType.isNull()) return QualType(); // Transform type arguments. bool typeArgChanged = false; SmallVector<QualType, 4> typeArgs; for (auto typeArg : T->getTypeArgsAsWritten()) { QualType newTypeArg = recurse(typeArg); if (newTypeArg.isNull()) return QualType(); 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::makeArrayRef(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 QualType(); 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 QualType(); if (valueType.getAsOpaquePtr() == T->getValueType().getAsOpaquePtr()) return QualType(T, 0); return Ctx.getAtomicType(valueType); } #undef TRIVIAL_TYPE_CLASS }; /// Perform a simple type transformation that does not change the /// semantics of the type. template<typename F> QualType simpleTransform(ASTContext &ctx, QualType type, F &&f) { // Transform the type. If it changed, return the transformed result. QualType transformed = f(type); if (transformed.getAsOpaquePtr() != type.getAsOpaquePtr()) return transformed; // Split out the qualifiers from the type. SplitQualType splitType = type.split(); // Visit the type itself. SimpleTransformVisitor<F> visitor(ctx, std::move(f)); QualType result = visitor.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); } } // end anonymous namespace /// 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 { return simpleTransform(ctx, *this, [&](QualType type) -> QualType { SplitQualType splitType = type.split(); // Replace an Objective-C type parameter reference with the corresponding // type argument. if (const auto *typedefTy = dyn_cast<TypedefType>(splitType.Ty)) { if (auto *typeParam = dyn_cast<ObjCTypeParamDecl>(typedefTy->getDecl())) { // If we have type arguments, use them. if (!typeArgs.empty()) { // FIXME: Introduce SubstObjCTypeParamType ? QualType argType = typeArgs[typeParam->getIndex()]; return ctx.getQualifiedType(argType, splitType.Quals); } switch (context) { case ObjCSubstitutionContext::Ordinary: case ObjCSubstitutionContext::Parameter: case ObjCSubstitutionContext::Superclass: // Substitute the bound. return ctx.getQualifiedType(typeParam->getUnderlyingType(), splitType.Quals); 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 ctx.getQualifiedType(typeParam->getUnderlyingType(), splitType.Quals); // Add __kindof. const auto *obj = objPtr->getObjectType(); QualType resultTy = ctx.getObjCObjectType(obj->getBaseType(), obj->getTypeArgsAsWritten(), obj->getProtocols(), /*isKindOf=*/true); // Rebuild object pointer type. resultTy = ctx.getObjCObjectPointerType(resultTy); return ctx.getQualifiedType(resultTy, splitType.Quals); } } } } // If we have a function type, update the context appropriately. if (const auto *funcType = dyn_cast<FunctionType>(splitType.Ty)) { // Substitute result type. QualType returnType = funcType->getReturnType().substObjCTypeArgs( ctx, typeArgs, ObjCSubstitutionContext::Result); if (returnType.isNull()) return QualType(); // 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 type; // 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 QualType(); 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 QualType(); if (newExceptionType.getAsOpaquePtr() != exceptionType.getAsOpaquePtr()) exceptionChanged = true; exceptionTypes.push_back(newExceptionType); } if (exceptionChanged) { info.ExceptionSpec.Exceptions = llvm::makeArrayRef(exceptionTypes).copy(ctx); } } if (returnType.getAsOpaquePtr() == funcProtoType->getReturnType().getAsOpaquePtr() && !paramChanged && !exceptionChanged) return type; return ctx.getFunctionType(returnType, paramTypes, info); } // Substitute into the type arguments of a specialized Objective-C object // type. if (const auto *objcObjectType = dyn_cast<ObjCObjectType>(splitType.Ty)) { 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 QualType(); 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() && context != 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 type; } return type; }); } 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); return simpleTransform(ctx, *this, [&](QualType type) -> QualType { SplitQualType splitType = type.split(); if (auto *objType = splitType.Ty->getAs<ObjCObjectType>()) { if (!objType->isKindOfType()) return type; QualType baseType = objType->getBaseType().stripObjCKindOfType(ctx); return ctx.getQualifiedType( ctx.getObjCObjectType(baseType, objType->getTypeArgsAsWritten(), objType->getProtocols(), /*isKindOf=*/false), splitType.Quals); } return type; }); } Optional<ArrayRef<QualType>> Type::getObjCSubstitutions( const DeclContext *dc) const { // Look through method scopes. if (auto method = dyn_cast<ObjCMethodDecl>(dc)) dc = method->getDeclContext(); // Find the class or category in which the type we're substituting // was declared. const ObjCInterfaceDecl *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 None; } 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 None; // If the category does not have any type parameters, there's no // substitution to do. dcTypeParams = dcCategoryDecl->getTypeParamList(); if (!dcTypeParams) return None; dcClassDecl = dcCategoryDecl->getClassInterface(); if (!dcClassDecl) return None; } 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 ObjCObjectType *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 ObjCObjectPointerType *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 ObjCObjectPointerType *OPT = getAs<ObjCObjectPointerType>()) { if (OPT->isObjCQualifiedClassType()) return OPT; } return nullptr; } const ObjCObjectType *Type::getAsObjCInterfaceType() const { if (const ObjCObjectType *OT = getAs<ObjCObjectType>()) { if (OT->getInterface()) return OT; } return nullptr; } const ObjCObjectPointerType *Type::getAsObjCInterfacePointerType() const { if (const ObjCObjectPointerType *OPT = getAs<ObjCObjectPointerType>()) { if (OPT->getInterfaceType()) return OPT; } return nullptr; } const CXXRecordDecl *Type::getPointeeCXXRecordDecl() const { QualType PointeeType; if (const PointerType *PT = getAs<PointerType>()) PointeeType = PT->getPointeeType(); else if (const ReferenceType *RT = getAs<ReferenceType>()) PointeeType = RT->getPointeeType(); else return nullptr; if (const RecordType *RT = PointeeType->getAs<RecordType>()) return dyn_cast<CXXRecordDecl>(RT->getDecl()); return nullptr; } CXXRecordDecl *Type::getAsCXXRecordDecl() const { return dyn_cast_or_null<CXXRecordDecl>(getAsTagDecl()); } TagDecl *Type::getAsTagDecl() const { if (const auto *TT = getAs<TagType>()) return cast<TagDecl>(TT->getDecl()); if (const auto *Injected = getAs<InjectedClassNameType>()) return Injected->getDecl(); return nullptr; } namespace { class GetContainedAutoVisitor : public TypeVisitor<GetContainedAutoVisitor, AutoType*> { public: using TypeVisitor<GetContainedAutoVisitor, AutoType*>::Visit; AutoType *Visit(QualType T) { if (T.isNull()) return nullptr; return Visit(T.getTypePtr()); } // The 'auto' type itself. AutoType *VisitAutoType(const AutoType *AT) { return const_cast<AutoType*>(AT); } // Only these types can contain the desired 'auto' type. AutoType *VisitPointerType(const PointerType *T) { return Visit(T->getPointeeType()); } AutoType *VisitBlockPointerType(const BlockPointerType *T) { return Visit(T->getPointeeType()); } AutoType *VisitReferenceType(const ReferenceType *T) { return Visit(T->getPointeeTypeAsWritten()); } AutoType *VisitMemberPointerType(const MemberPointerType *T) { return Visit(T->getPointeeType()); } AutoType *VisitArrayType(const ArrayType *T) { return Visit(T->getElementType()); } AutoType *VisitDependentSizedExtVectorType( const DependentSizedExtVectorType *T) { return Visit(T->getElementType()); } AutoType *VisitVectorType(const VectorType *T) { return Visit(T->getElementType()); } AutoType *VisitFunctionType(const FunctionType *T) { return Visit(T->getReturnType()); } AutoType *VisitParenType(const ParenType *T) { return Visit(T->getInnerType()); } AutoType *VisitAttributedType(const AttributedType *T) { return Visit(T->getModifiedType()); } AutoType *VisitAdjustedType(const AdjustedType *T) { return Visit(T->getOriginalType()); } }; } AutoType *Type::getContainedAutoType() const { return GetContainedAutoVisitor().Visit(this); } bool Type::hasIntegerRepresentation() const { if (const VectorType *VT = dyn_cast<VectorType>(CanonicalType)) return VT->getElementType()->isIntegerType(); else return isIntegerType(); } /// \brief 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(ASTContext &Ctx) const { if (const BuiltinType *BT = dyn_cast<BuiltinType>(CanonicalType)) return BT->getKind() >= BuiltinType::Bool && BT->getKind() <= BuiltinType::Int128; // Complete enum types are integral in C. if (!Ctx.getLangOpts().CPlusPlus) if (const EnumType *ET = dyn_cast<EnumType>(CanonicalType)) return ET->getDecl()->isComplete(); return false; } bool Type::isIntegralOrUnscopedEnumerationType() const { if (const BuiltinType *BT = dyn_cast<BuiltinType>(CanonicalType)) return BT->getKind() >= BuiltinType::Bool && BT->getKind() <= BuiltinType::Int128; // Check for a complete enum type; incomplete enum types are not properly an // enumeration type in the sense required here. // C++0x: However, if the underlying type of the enum is fixed, it is // considered complete. if (const EnumType *ET = dyn_cast<EnumType>(CanonicalType)) return ET->getDecl()->isComplete() && !ET->getDecl()->isScoped(); return false; } bool Type::isCharType() const { if (const BuiltinType *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 BuiltinType *BT = dyn_cast<BuiltinType>(CanonicalType)) return BT->getKind() == BuiltinType::WChar_S || BT->getKind() == BuiltinType::WChar_U; return false; } bool Type::isChar16Type() const { if (const BuiltinType *BT = dyn_cast<BuiltinType>(CanonicalType)) return BT->getKind() == BuiltinType::Char16; return false; } bool Type::isChar32Type() const { if (const BuiltinType *BT = dyn_cast<BuiltinType>(CanonicalType)) return BT->getKind() == BuiltinType::Char32; return false; } /// \brief Determine whether this type is any of the built-in character /// types. bool Type::isAnyCharacterType() const { const BuiltinType *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::Char16: case BuiltinType::Char32: case BuiltinType::Char_S: case BuiltinType::SChar: case BuiltinType::WChar_S: 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 BuiltinType *BT = dyn_cast<BuiltinType>(CanonicalType)) { return BT->getKind() >= BuiltinType::Char_S && BT->getKind() <= BuiltinType::Int128; } if (const EnumType *ET = dyn_cast<EnumType>(CanonicalType)) { // Incomplete enum types are not treated as integer types. // FIXME: In C++, enum types are never integer types. if (ET->getDecl()->isComplete() && !ET->getDecl()->isScoped()) return ET->getDecl()->getIntegerType()->isSignedIntegerType(); } return false; } bool Type::isSignedIntegerOrEnumerationType() const { if (const BuiltinType *BT = dyn_cast<BuiltinType>(CanonicalType)) { return BT->getKind() >= BuiltinType::Char_S && BT->getKind() <= BuiltinType::Int128; } if (const EnumType *ET = dyn_cast<EnumType>(CanonicalType)) { if (ET->getDecl()->isComplete()) return ET->getDecl()->getIntegerType()->isSignedIntegerType(); } return false; } bool Type::hasSignedIntegerRepresentation() const { if (const VectorType *VT = dyn_cast<VectorType>(CanonicalType)) return VT->getElementType()->isSignedIntegerOrEnumerationType(); else 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 BuiltinType *BT = dyn_cast<BuiltinType>(CanonicalType)) { return BT->getKind() >= BuiltinType::Bool && BT->getKind() <= BuiltinType::UInt128; } if (const EnumType *ET = dyn_cast<EnumType>(CanonicalType)) { // Incomplete enum types are not treated as integer types. // FIXME: In C++, enum types are never integer types. if (ET->getDecl()->isComplete() && !ET->getDecl()->isScoped()) return ET->getDecl()->getIntegerType()->isUnsignedIntegerType(); } return false; } bool Type::isUnsignedIntegerOrEnumerationType() const { if (const BuiltinType *BT = dyn_cast<BuiltinType>(CanonicalType)) { return BT->getKind() >= BuiltinType::Bool && BT->getKind() <= BuiltinType::UInt128; } if (const EnumType *ET = dyn_cast<EnumType>(CanonicalType)) { if (ET->getDecl()->isComplete()) return ET->getDecl()->getIntegerType()->isUnsignedIntegerType(); } return false; } bool Type::hasUnsignedIntegerRepresentation() const { if (const VectorType *VT = dyn_cast<VectorType>(CanonicalType)) return VT->getElementType()->isUnsignedIntegerOrEnumerationType(); else return isUnsignedIntegerOrEnumerationType(); } bool Type::isFloatingType() const { if (const BuiltinType *BT = dyn_cast<BuiltinType>(CanonicalType)) return BT->getKind() >= BuiltinType::Half && BT->getKind() <= BuiltinType::LongDouble; if (const ComplexType *CT = dyn_cast<ComplexType>(CanonicalType)) return CT->getElementType()->isFloatingType(); return false; } bool Type::hasFloatingRepresentation() const { if (const VectorType *VT = dyn_cast<VectorType>(CanonicalType)) return VT->getElementType()->isFloatingType(); else return isFloatingType(); } bool Type::isRealFloatingType() const { if (const BuiltinType *BT = dyn_cast<BuiltinType>(CanonicalType)) return BT->isFloatingPoint(); return false; } bool Type::isRealType() const { if (const BuiltinType *BT = dyn_cast<BuiltinType>(CanonicalType)) return BT->getKind() >= BuiltinType::Bool && BT->getKind() <= BuiltinType::LongDouble; if (const EnumType *ET = dyn_cast<EnumType>(CanonicalType)) return ET->getDecl()->isComplete() && !ET->getDecl()->isScoped(); return false; } bool Type::isArithmeticType() const { if (const BuiltinType *BT = dyn_cast<BuiltinType>(CanonicalType)) return BT->getKind() >= BuiltinType::Bool && BT->getKind() <= BuiltinType::LongDouble; if (const EnumType *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. return !ET->getDecl()->isScoped() && ET->getDecl()->isComplete(); return isa<ComplexType>(CanonicalType); } Type::ScalarTypeKind Type::getScalarTypeKind() const { assert(isScalarType()); const Type *T = CanonicalType.getTypePtr(); if (const BuiltinType *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; 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(cast<EnumType>(T)->getDecl()->isComplete()); return STK_Integral; } else if (const ComplexType *CT = dyn_cast<ComplexType>(T)) { if (CT->getElementType()->isRealFloatingType()) return STK_FloatingComplex; return STK_IntegralComplex; } llvm_unreachable("unknown scalar type"); } /// \brief 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 RecordType *Record = dyn_cast<RecordType>(CanonicalType)) { if (CXXRecordDecl *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: { EnumDecl *EnumD = cast<EnumType>(CanonicalType)->getDecl(); if (Def) *Def = EnumD; // An enumeration with fixed underlying type is complete (C++0x 7.2p3). if (EnumD->isFixed()) return false; return !EnumD->isCompleteDefinition(); } 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). RecordDecl *Rec = cast<RecordType>(CanonicalType)->getDecl(); if (Def) *Def = Rec; return !Rec->isCompleteDefinition(); } case ConstantArray: // An array is incomplete if its element type is incomplete // (C++ [dcl.array]p1). // We don't handle variable arrays (they're not allowed in C++) or // 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. auto *MPTy = cast<MemberPointerType>(CanonicalType); const Type *ClassTy = MPTy->getClass(); // Member pointers with dependent class types don't get special treatment. if (ClassTy->isDependentType()) return false; const CXXRecordDecl *RD = ClassTy->getAsCXXRecordDecl(); ASTContext &Context = RD->getASTContext(); // Member pointers not in the MS ABI don't get special treatment. if (!Context.getTargetInfo().getCXXABI().isMicrosoft()) return false; // The inheritance attribute might only be present on the most recent // CXXRecordDecl, use that one. RD = RD->getMostRecentDecl(); // 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 QualType::isPODType(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(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 0; if ((*this)->isIncompleteArrayType()) return Context.getBaseElementType(*this).isCXX98PODType(Context); if ((*this)->isIncompleteType()) return false; if (Context.getLangOpts().ObjCAutoRefCount) { switch (getObjCLifetime()) { case Qualifiers::OCL_ExplicitNone: return true; case Qualifiers::OCL_Strong: case Qualifiers::OCL_Weak: case Qualifiers::OCL_Autoreleasing: return false; case Qualifiers::OCL_None: break; } } QualType CanonicalType = getTypePtr()->CanonicalType; 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: return true; case Type::Enum: return true; case Type::Record: if (CXXRecordDecl *ClassDecl = dyn_cast<CXXRecordDecl>(cast<RecordType>(CanonicalType)->getDecl())) return ClassDecl->isPOD(); // C struct/union is POD. return true; } } bool QualType::isTrivialType(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 0; if ((*this)->isArrayType()) return Context.getBaseElementType(*this).isTrivialType(Context); // 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 (Context.getLangOpts().ObjCAutoRefCount) { switch (getObjCLifetime()) { case Qualifiers::OCL_ExplicitNone: return true; case Qualifiers::OCL_Strong: case Qualifiers::OCL_Weak: case Qualifiers::OCL_Autoreleasing: return false; case Qualifiers::OCL_None: if ((*this)->isObjCLifetimeType()) return false; break; } } QualType CanonicalType = getTypePtr()->CanonicalType; if (CanonicalType->isDependentType()) 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 RecordType *RT = CanonicalType->getAs<RecordType>()) { if (const CXXRecordDecl *ClassDecl = dyn_cast<CXXRecordDecl>(RT->getDecl())) { // C++11 [class]p6: // A trivial class is a class that has a default constructor, // has no non-trivial default constructors, and is trivially // copyable. return ClassDecl->hasDefaultConstructor() && !ClassDecl->hasNonTrivialDefaultConstructor() && ClassDecl->isTriviallyCopyable(); } return true; } // No other types can match. return false; } bool QualType::isTriviallyCopyableType(ASTContext &Context) const { if ((*this)->isArrayType()) return Context.getBaseElementType(*this).isTriviallyCopyableType(Context); if (Context.getLangOpts().ObjCAutoRefCount) { switch (getObjCLifetime()) { case Qualifiers::OCL_ExplicitNone: return true; case Qualifiers::OCL_Strong: case Qualifiers::OCL_Weak: case Qualifiers::OCL_Autoreleasing: return false; case Qualifiers::OCL_None: if ((*this)->isObjCLifetimeType()) return false; break; } } // C++11 [basic.types]p9 // Scalar types, trivially copyable class types, arrays of such types, and // non-volatile const-qualified versions of these types are collectively // called trivially copyable types. QualType CanonicalType = getCanonicalType(); if (CanonicalType->isDependentType()) return false; if (CanonicalType.isVolatileQualified()) return false; // 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; // As an extension, Clang treats vector types as Scalar types. if (CanonicalType->isScalarType() || CanonicalType->isVectorType()) return true; if (const RecordType *RT = CanonicalType->getAs<RecordType>()) { if (const CXXRecordDecl *ClassDecl = dyn_cast<CXXRecordDecl>(RT->getDecl())) { if (!ClassDecl->isTriviallyCopyable()) return false; } return true; } // No other types can match. return false; } 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; // -- a reference type; or if (BaseTy->isReferenceType()) return true; // -- a class type that has all of the following properties: if (const RecordType *RT = BaseTy->getAs<RecordType>()) { // -- 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 CXXRecordDecl *ClassDecl = dyn_cast<CXXRecordDecl>(RT->getDecl())) return ClassDecl->isLiteral(); return true; } // We treat _Atomic T as a literal type if T is a literal type. if (const AtomicType *AT = BaseTy->getAs<AtomicType>()) return AT->getValueType()->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::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 RecordType *RT = BaseTy->getAs<RecordType>()) { if (const CXXRecordDecl *ClassDecl = dyn_cast<CXXRecordDecl>(RT->getDecl())) if (!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(ASTContext &Context) const { const Type *ty = getTypePtr(); if (ty->isDependentType()) return false; if (Context.getLangOpts().ObjCAutoRefCount) { switch (getObjCLifetime()) { case Qualifiers::OCL_ExplicitNone: return true; case Qualifiers::OCL_Strong: case Qualifiers::OCL_Weak: case Qualifiers::OCL_Autoreleasing: return false; case Qualifiers::OCL_None: break; } } // 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"); // 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 RecordType *RT = BaseTy->getAs<RecordType>()) { if (const CXXRecordDecl *ClassDecl = dyn_cast<CXXRecordDecl>(RT->getDecl())) { // 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::isPromotableIntegerType() const { if (const BuiltinType *BT = getAs<BuiltinType>()) switch (BT->getKind()) { case BuiltinType::Bool: case BuiltinType::Char_S: case BuiltinType::Char_U: case BuiltinType::SChar: case BuiltinType::UChar: case BuiltinType::Short: case BuiltinType::UShort: case BuiltinType::WChar_S: case BuiltinType::WChar_U: case BuiltinType::Char16: case BuiltinType::Char32: return true; default: return false; } // Enumerated types are promotable to their compatible integer types // (C99 6.3.1.1) a.k.a. its underlying type (C++ [conv.prom]p2). if (const EnumType *ET = getAs<EnumType>()){ if (this->isDependentType() || ET->getDecl()->getPromotionType().isNull() || ET->getDecl()->isScoped()) return false; 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 Elaborated: case DependentName: case DependentTemplateSpecialization: case ObjCInterface: case ObjCObject: case ObjCObjectPointer: // FIXME: object pointers aren't really specifiers return true; default: return false; } } ElaboratedTypeKeyword TypeWithKeyword::getKeywordForTypeSpec(unsigned TypeSpec) { switch (TypeSpec) { default: return ETK_None; case TST_typename: return ETK_Typename; case TST_class: return ETK_Class; case TST_struct: return ETK_Struct; case TST_interface: return ETK_Interface; case TST_union: return ETK_Union; case TST_enum: return ETK_Enum; } } TagTypeKind TypeWithKeyword::getTagTypeKindForTypeSpec(unsigned TypeSpec) { switch(TypeSpec) { case TST_class: return TTK_Class; case TST_struct: return TTK_Struct; case TST_interface: return TTK_Interface; case TST_union: return TTK_Union; case TST_enum: return TTK_Enum; } llvm_unreachable("Type specifier is not a tag type kind."); } ElaboratedTypeKeyword TypeWithKeyword::getKeywordForTagTypeKind(TagTypeKind Kind) { switch (Kind) { case TTK_Class: return ETK_Class; case TTK_Struct: return ETK_Struct; case TTK_Interface: return ETK_Interface; case TTK_Union: return ETK_Union; case TTK_Enum: return ETK_Enum; } llvm_unreachable("Unknown tag type kind."); } TagTypeKind TypeWithKeyword::getTagTypeKindForKeyword(ElaboratedTypeKeyword Keyword) { switch (Keyword) { case ETK_Class: return TTK_Class; case ETK_Struct: return TTK_Struct; case ETK_Interface: return TTK_Interface; case ETK_Union: return TTK_Union; case ETK_Enum: return TTK_Enum; case ETK_None: // Fall through. case ETK_Typename: llvm_unreachable("Elaborated type keyword is not a tag type kind."); } llvm_unreachable("Unknown elaborated type keyword."); } bool TypeWithKeyword::KeywordIsTagTypeKind(ElaboratedTypeKeyword Keyword) { switch (Keyword) { case ETK_None: case ETK_Typename: return false; case ETK_Class: case ETK_Struct: case ETK_Interface: case ETK_Union: case ETK_Enum: return true; } llvm_unreachable("Unknown elaborated type keyword."); } StringRef TypeWithKeyword::getKeywordName(ElaboratedTypeKeyword Keyword) { switch (Keyword) { case ETK_None: return ""; case ETK_Typename: return "typename"; case ETK_Class: return "class"; case ETK_Struct: return "struct"; case ETK_Interface: return "__interface"; case ETK_Union: return "union"; case ETK_Enum: return "enum"; } llvm_unreachable("Unknown elaborated type keyword."); } DependentTemplateSpecializationType::DependentTemplateSpecializationType( ElaboratedTypeKeyword Keyword, NestedNameSpecifier *NNS, const IdentifierInfo *Name, unsigned NumArgs, const TemplateArgument *Args, QualType Canon) : TypeWithKeyword(Keyword, DependentTemplateSpecialization, Canon, true, true, /*VariablyModified=*/false, NNS && NNS->containsUnexpandedParameterPack()), NNS(NNS), Name(Name), NumArgs(NumArgs) { assert((!NNS || NNS->isDependent()) && "DependentTemplateSpecializatonType requires dependent qualifier"); for (unsigned I = 0; I != NumArgs; ++I) { if (Args[I].containsUnexpandedParameterPack()) setContainsUnexpandedParameterPack(); new (&getArgBuffer()[I]) TemplateArgument(Args[I]); } } void DependentTemplateSpecializationType::Profile(llvm::FoldingSetNodeID &ID, const ASTContext &Context, ElaboratedTypeKeyword Keyword, NestedNameSpecifier *Qualifier, const IdentifierInfo *Name, unsigned NumArgs, const TemplateArgument *Args) { ID.AddInteger(Keyword); ID.AddPointer(Qualifier); ID.AddPointer(Name); for (unsigned Idx = 0; Idx < NumArgs; ++Idx) Args[Idx].Profile(ID, Context); } bool Type::isElaboratedTypeSpecifier() const { ElaboratedTypeKeyword Keyword; if (const ElaboratedType *Elab = dyn_cast<ElaboratedType>(this)) Keyword = Elab->getKeyword(); else if (const DependentNameType *DepName = dyn_cast<DependentNameType>(this)) Keyword = DepName->getKeyword(); else if (const DependentTemplateSpecializationType *DepTST = dyn_cast<DependentTemplateSpecializationType>(this)) Keyword = DepTST->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.def" } llvm_unreachable("Invalid type class."); } StringRef BuiltinType::getName(const PrintingPolicy &Policy) const { switch (getKind()) { case Void: return "void"; #ifndef noCbC case __Code: return "__code"; #endif 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 Float: return "float"; case Double: return "double"; case LongDouble: return "long double"; case WChar_S: case WChar_U: return Policy.MSWChar ? "__wchar_t" : "wchar_t"; case Char16: return "char16_t"; case Char32: return "char32_t"; case NullPtr: return "nullptr_t"; case Overload: return "<overloaded function type>"; case BoundMember: return "<bound member function 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"; case OCLImage1d: return "image1d_t"; case OCLImage1dArray: return "image1d_array_t"; case OCLImage1dBuffer: return "image1d_buffer_t"; case OCLImage2d: return "image2d_t"; case OCLImage2dArray: return "image2d_array_t"; case OCLImage2dDepth: return "image2d_depth_t"; case OCLImage2dArrayDepth: return "image2d_array_depth_t"; case OCLImage2dMSAA: return "image2d_msaa_t"; case OCLImage2dArrayMSAA: return "image2d_array_msaa_t"; case OCLImage2dMSAADepth: return "image2d_msaa_depth_t"; case OCLImage2dArrayMSAADepth: return "image2d_array_msaa_depth_t"; case OCLImage3d: return "image3d_t"; case OCLSampler: return "sampler_t"; case OCLEvent: return "event_t"; case OCLClkEvent: return "clk_event_t"; case OCLQueue: return "queue_t"; case OCLNDRange: return "ndrange_t"; case OCLReserveID: return "reserve_id_t"; case OMPArraySection: return "<OpenMP array section type>"; } llvm_unreachable("Invalid builtin type."); } QualType QualType::getNonLValueExprType(const ASTContext &Context) const { if (const ReferenceType *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; } 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_X86_64Win64: return "ms_abi"; case CC_X86_64SysV: return "sysv_abi"; case CC_AAPCS: return "aapcs"; case CC_AAPCS_VFP: return "aapcs-vfp"; case CC_IntelOclBicc: return "intel_ocl_bicc"; case CC_SpirFunction: return "spir_function"; case CC_SpirKernel: return "spir_kernel"; } llvm_unreachable("Invalid calling convention."); } FunctionProtoType::FunctionProtoType(QualType result, ArrayRef<QualType> params, QualType canonical, const ExtProtoInfo &epi) : FunctionType(FunctionProto, result, canonical, result->isDependentType(), result->isInstantiationDependentType(), result->isVariablyModifiedType(), result->containsUnexpandedParameterPack(), epi.ExtInfo), NumParams(params.size()), NumExceptions(epi.ExceptionSpec.Exceptions.size()), ExceptionSpecType(epi.ExceptionSpec.Type), HasAnyConsumedParams(epi.ConsumedParameters != nullptr), Variadic(epi.Variadic), HasTrailingReturn(epi.HasTrailingReturn) { assert(NumParams == params.size() && "function has too many parameters"); FunctionTypeBits.TypeQuals = epi.TypeQuals; FunctionTypeBits.RefQualifier = epi.RefQualifier; // Fill in the trailing argument array. QualType *argSlot = reinterpret_cast<QualType*>(this+1); for (unsigned i = 0; i != NumParams; ++i) { if (params[i]->isDependentType()) setDependent(); else if (params[i]->isInstantiationDependentType()) setInstantiationDependent(); if (params[i]->containsUnexpandedParameterPack()) setContainsUnexpandedParameterPack(); argSlot[i] = params[i]; } if (getExceptionSpecType() == EST_Dynamic) { // Fill in the exception array. QualType *exnSlot = argSlot + NumParams; unsigned I = 0; for (QualType ExceptionType : epi.ExceptionSpec.Exceptions) { // Note that a dependent exception specification does *not* make // a type dependent; it's not even part of the C++ type system. if (ExceptionType->isInstantiationDependentType()) setInstantiationDependent(); if (ExceptionType->containsUnexpandedParameterPack()) setContainsUnexpandedParameterPack(); exnSlot[I++] = ExceptionType; } } else if (getExceptionSpecType() == EST_ComputedNoexcept) { // Store the noexcept expression and context. Expr **noexSlot = reinterpret_cast<Expr **>(argSlot + NumParams); *noexSlot = epi.ExceptionSpec.NoexceptExpr; if (epi.ExceptionSpec.NoexceptExpr) { if (epi.ExceptionSpec.NoexceptExpr->isValueDependent() || epi.ExceptionSpec.NoexceptExpr->isInstantiationDependent()) setInstantiationDependent(); if (epi.ExceptionSpec.NoexceptExpr->containsUnexpandedParameterPack()) setContainsUnexpandedParameterPack(); } } else if (getExceptionSpecType() == EST_Uninstantiated) { // Store the function decl from which we will resolve our // exception specification. FunctionDecl **slot = reinterpret_cast<FunctionDecl **>(argSlot + NumParams); 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. FunctionDecl **slot = reinterpret_cast<FunctionDecl **>(argSlot + NumParams); slot[0] = epi.ExceptionSpec.SourceDecl; } if (epi.ConsumedParameters) { bool *consumedParams = const_cast<bool *>(getConsumedParamsBuffer()); for (unsigned i = 0; i != NumParams; ++i) consumedParams[i] = epi.ConsumedParameters[i]; } } 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; } FunctionProtoType::NoexceptResult FunctionProtoType::getNoexceptSpec(const ASTContext &ctx) const { ExceptionSpecificationType est = getExceptionSpecType(); if (est == EST_BasicNoexcept) return NR_Nothrow; if (est != EST_ComputedNoexcept) return NR_NoNoexcept; Expr *noexceptExpr = getNoexceptExpr(); if (!noexceptExpr) return NR_BadNoexcept; if (noexceptExpr->isValueDependent()) return NR_Dependent; llvm::APSInt value; bool isICE = noexceptExpr->isIntegerConstantExpr(value, ctx, nullptr, /*evaluated*/false); (void)isICE; assert(isICE && "AST should not contain bad noexcept expressions."); return value.getBoolValue() ? NR_Nothrow : NR_Throw; } bool FunctionProtoType::isNothrow(const ASTContext &Ctx, bool ResultIfDependent) const { ExceptionSpecificationType EST = getExceptionSpecType(); assert(EST != EST_Unevaluated && EST != EST_Uninstantiated); if (EST == EST_DynamicNone || EST == EST_BasicNoexcept) return true; if (EST == EST_Dynamic && ResultIfDependent) { // A dynamic exception specification is throwing unless every exception // type is an (unexpanded) pack expansion type. for (unsigned I = 0, N = NumExceptions; I != N; ++I) if (!getExceptionType(I)->getAs<PackExpansionType>()) return false; return ResultIfDependent; } if (EST != EST_ComputedNoexcept) return false; NoexceptResult NR = getNoexceptSpec(Ctx); if (NR == NR_Dependent) return ResultIfDependent; return NR == NR_Nothrow; } 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) { // 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* // Finally, we have the ext info and trailing return type flag: // int bool // // 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.TypeQuals) & ~255) && !(unsigned(epi.RefQualifier) & ~3) && !(unsigned(epi.ExceptionSpec.Type) & ~15) && "Values larger than expected."); ID.AddInteger(unsigned(epi.Variadic) + (epi.TypeQuals << 1) + (epi.RefQualifier << 9) + (epi.ExceptionSpec.Type << 11)); if (epi.ExceptionSpec.Type == EST_Dynamic) { for (QualType Ex : epi.ExceptionSpec.Exceptions) ID.AddPointer(Ex.getAsOpaquePtr()); } else if (epi.ExceptionSpec.Type == EST_ComputedNoexcept && epi.ExceptionSpec.NoexceptExpr) { epi.ExceptionSpec.NoexceptExpr->Profile(ID, Context, false); } else if (epi.ExceptionSpec.Type == EST_Uninstantiated || epi.ExceptionSpec.Type == EST_Unevaluated) { ID.AddPointer(epi.ExceptionSpec.SourceDecl->getCanonicalDecl()); } if (epi.ConsumedParameters) { for (unsigned i = 0; i != NumParams; ++i) ID.AddBoolean(epi.ConsumedParameters[i]); } epi.ExtInfo.Profile(ID); ID.AddBoolean(epi.HasTrailingReturn); } void FunctionProtoType::Profile(llvm::FoldingSetNodeID &ID, const ASTContext &Ctx) { Profile(ID, getReturnType(), param_type_begin(), NumParams, getExtProtoInfo(), Ctx); } QualType TypedefType::desugar() const { return getDecl()->getUnderlyingType(); } TypeOfExprType::TypeOfExprType(Expr *E, QualType can) : Type(TypeOfExpr, can, E->isTypeDependent(), E->isInstantiationDependent(), E->getType()->isVariablyModifiedType(), E->containsUnexpandedParameterPack()), TOExpr(E) { } bool TypeOfExprType::isSugared() const { return !TOExpr->isTypeDependent(); } QualType TypeOfExprType::desugar() const { if (isSugared()) return getUnderlyingExpr()->getType(); return QualType(this, 0); } void DependentTypeOfExprType::Profile(llvm::FoldingSetNodeID &ID, const ASTContext &Context, Expr *E) { E->Profile(ID, Context, true); } 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, E->isInstantiationDependent(), E->isInstantiationDependent(), E->getType()->isVariablyModifiedType(), E->containsUnexpandedParameterPack()), 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(const ASTContext &Context, Expr *E) : DecltypeType(E, Context.DependentTy), Context(Context) { } void DependentDecltypeType::Profile(llvm::FoldingSetNodeID &ID, const ASTContext &Context, Expr *E) { E->Profile(ID, Context, true); } TagType::TagType(TypeClass TC, const TagDecl *D, QualType can) : Type(TC, can, D->isDependentType(), /*InstantiationDependent=*/D->isDependentType(), /*VariablyModified=*/false, /*ContainsUnexpandedParameterPack=*/false), decl(const_cast<TagDecl*>(D)) {} static TagDecl *getInterestingTagDecl(TagDecl *decl) { for (auto I : decl->redecls()) { if (I->isCompleteDefinition() || I->isBeingDefined()) return I; } // If there's no definition (not even in progress), return what we have. return decl; } UnaryTransformType::UnaryTransformType(QualType BaseType, QualType UnderlyingType, UTTKind UKind, QualType CanonicalType) : Type(UnaryTransform, CanonicalType, UnderlyingType->isDependentType(), UnderlyingType->isInstantiationDependentType(), UnderlyingType->isVariablyModifiedType(), BaseType->containsUnexpandedParameterPack()) , BaseType(BaseType), UnderlyingType(UnderlyingType), UKind(UKind) {} TagDecl *TagType::getDecl() const { return getInterestingTagDecl(decl); } bool TagType::isBeingDefined() const { return getDecl()->isBeingDefined(); } bool AttributedType::isQualifier() const { 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 AttributedType::attr_address_space: case AttributedType::attr_objc_gc: case AttributedType::attr_objc_ownership: case AttributedType::attr_objc_inert_unsafe_unretained: case AttributedType::attr_nonnull: case AttributedType::attr_nullable: case AttributedType::attr_null_unspecified: return true; // These aren't qualifiers; they rewrite the modified type to be a // semantically different type. case AttributedType::attr_regparm: case AttributedType::attr_vector_size: case AttributedType::attr_neon_vector_type: case AttributedType::attr_neon_polyvector_type: case AttributedType::attr_pcs: case AttributedType::attr_pcs_vfp: case AttributedType::attr_noreturn: case AttributedType::attr_cdecl: case AttributedType::attr_fastcall: case AttributedType::attr_stdcall: case AttributedType::attr_thiscall: case AttributedType::attr_pascal: case AttributedType::attr_vectorcall: case AttributedType::attr_inteloclbicc: case AttributedType::attr_ms_abi: case AttributedType::attr_sysv_abi: case AttributedType::attr_ptr32: case AttributedType::attr_ptr64: case AttributedType::attr_sptr: case AttributedType::attr_uptr: case AttributedType::attr_objc_kindof: return false; } llvm_unreachable("bad attributed type kind"); } bool AttributedType::isMSTypeSpec() const { 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::isCallingConv() const { switch (getAttrKind()) { case attr_ptr32: case attr_ptr64: case attr_sptr: case attr_uptr: case attr_address_space: case attr_regparm: case attr_vector_size: case attr_neon_vector_type: case attr_neon_polyvector_type: case attr_objc_gc: case attr_objc_ownership: case attr_objc_inert_unsafe_unretained: case attr_noreturn: case attr_nonnull: case attr_nullable: case attr_null_unspecified: case attr_objc_kindof: return false; case attr_pcs: case attr_pcs_vfp: case attr_cdecl: case attr_fastcall: case attr_stdcall: case attr_thiscall: case attr_vectorcall: case attr_pascal: case attr_ms_abi: case attr_sysv_abi: case attr_inteloclbicc: return true; } llvm_unreachable("invalid attr kind"); } CXXRecordDecl *InjectedClassNameType::getDecl() const { return cast<CXXRecordDecl>(getInterestingTagDecl(Decl)); } IdentifierInfo *TemplateTypeParmType::getIdentifier() const { return isCanonicalUnqualified() ? nullptr : getDecl()->getIdentifier(); } SubstTemplateTypeParmPackType:: SubstTemplateTypeParmPackType(const TemplateTypeParmType *Param, QualType Canon, const TemplateArgument &ArgPack) : Type(SubstTemplateTypeParmPack, Canon, true, true, false, true), Replaced(Param), Arguments(ArgPack.pack_begin()), NumArguments(ArgPack.pack_size()) { } TemplateArgument SubstTemplateTypeParmPackType::getArgumentPack() const { return TemplateArgument(llvm::makeArrayRef(Arguments, NumArguments)); } void SubstTemplateTypeParmPackType::Profile(llvm::FoldingSetNodeID &ID) { Profile(ID, getReplacedParameter(), getArgumentPack()); } void SubstTemplateTypeParmPackType::Profile(llvm::FoldingSetNodeID &ID, const TemplateTypeParmType *Replaced, const TemplateArgument &ArgPack) { ID.AddPointer(Replaced); ID.AddInteger(ArgPack.pack_size()); for (const auto &P : ArgPack.pack_elements()) ID.AddPointer(P.getAsType().getAsOpaquePtr()); } bool TemplateSpecializationType:: anyDependentTemplateArguments(const TemplateArgumentListInfo &Args, bool &InstantiationDependent) { return anyDependentTemplateArguments(Args.getArgumentArray(), Args.size(), InstantiationDependent); } bool TemplateSpecializationType:: anyDependentTemplateArguments(const TemplateArgumentLoc *Args, unsigned N, bool &InstantiationDependent) { for (unsigned i = 0; i != N; ++i) { if (Args[i].getArgument().isDependent()) { InstantiationDependent = true; return true; } if (Args[i].getArgument().isInstantiationDependent()) InstantiationDependent = true; } return false; } TemplateSpecializationType:: TemplateSpecializationType(TemplateName T, const TemplateArgument *Args, unsigned NumArgs, QualType Canon, QualType AliasedType) : Type(TemplateSpecialization, Canon.isNull()? QualType(this, 0) : Canon, Canon.isNull()? true : Canon->isDependentType(), Canon.isNull()? true : Canon->isInstantiationDependentType(), false, T.containsUnexpandedParameterPack()), Template(T), NumArgs(NumArgs), TypeAlias(!AliasedType.isNull()) { assert(!T.getAsDependentTemplateName() && "Use DependentTemplateSpecializationType for dependent template-name"); assert((T.getKind() == TemplateName::Template || T.getKind() == TemplateName::SubstTemplateTemplateParm || T.getKind() == TemplateName::SubstTemplateTemplateParmPack) && "Unexpected template name for TemplateSpecializationType"); TemplateArgument *TemplateArgs = reinterpret_cast<TemplateArgument *>(this + 1); for (unsigned Arg = 0; Arg < NumArgs; ++Arg) { // Update instantiation-dependent and variably-modified 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. if (Args[Arg].isInstantiationDependent()) setInstantiationDependent(); if (Args[Arg].getKind() == TemplateArgument::Type && Args[Arg].getAsType()->isVariablyModifiedType()) setVariablyModified(); if (Args[Arg].containsUnexpandedParameterPack()) setContainsUnexpandedParameterPack(); new (&TemplateArgs[Arg]) TemplateArgument(Args[Arg]); } // Store the aliased type if this is a type alias template specialization. if (TypeAlias) { TemplateArgument *Begin = reinterpret_cast<TemplateArgument *>(this + 1); *reinterpret_cast<QualType*>(Begin + getNumArgs()) = AliasedType; } } void TemplateSpecializationType::Profile(llvm::FoldingSetNodeID &ID, TemplateName T, const TemplateArgument *Args, unsigned NumArgs, const ASTContext &Context) { T.Profile(ID); for (unsigned Idx = 0; Idx < NumArgs; ++Idx) Args[Idx].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::makeArrayRef(qual_begin(), getNumProtocols()), isKindOfTypeAsWritten()); } namespace { /// \brief 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()); } }; } 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 = Result.getLinkage(); T->TypeBits.CachedLocalOrUnnamed = Result.hasLocalOrUnnamedType(); } }; } // 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 {}; } typedef TypePropertyCache<Private> Cache; 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.def" 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.def" // Treat instantiation-dependent types as external. assert(T->isInstantiationDependentType()); return CachedProperties(ExternalLinkage, false); case Type::Auto: // Give non-deduced 'auto' types external linkage. We should only see them // here in error recovery. return CachedProperties(ExternalLinkage, false); 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(ExternalLinkage, false); case Type::Record: case Type::Enum: { const TagDecl *Tag = cast<TagType>(T)->getDecl(); // 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 MemberPointerType *MPT = cast<MemberPointerType>(T); return merge(Cache::get(MPT->getClass()), Cache::get(MPT->getPointeeType())); } case Type::ConstantArray: case Type::IncompleteArray: case Type::VariableArray: return Cache::get(cast<ArrayType>(T)->getElementType()); case Type::Vector: case Type::ExtVector: return Cache::get(cast<VectorType>(T)->getElementType()); case Type::FunctionNoProto: return Cache::get(cast<FunctionType>(T)->getReturnType()); case Type::FunctionProto: { const FunctionProtoType *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()); } llvm_unreachable("unhandled type class"); } /// \brief 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(); } static LinkageInfo computeLinkageInfo(QualType T); static LinkageInfo computeLinkageInfo(const Type *T) { switch (T->getTypeClass()) { #define TYPE(Class,Base) #define NON_CANONICAL_TYPE(Class,Base) case Type::Class: #include "clang/AST/TypeNodes.def" 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.def" // Treat instantiation-dependent types as external. assert(T->isInstantiationDependentType()); return LinkageInfo::external(); case Type::Builtin: return LinkageInfo::external(); case Type::Auto: return LinkageInfo::external(); case Type::Record: case Type::Enum: return cast<TagType>(T)->getDecl()->getLinkageAndVisibility(); case Type::Complex: return computeLinkageInfo(cast<ComplexType>(T)->getElementType()); case Type::Pointer: return computeLinkageInfo(cast<PointerType>(T)->getPointeeType()); case Type::BlockPointer: return computeLinkageInfo(cast<BlockPointerType>(T)->getPointeeType()); case Type::LValueReference: case Type::RValueReference: return computeLinkageInfo(cast<ReferenceType>(T)->getPointeeType()); case Type::MemberPointer: { const MemberPointerType *MPT = cast<MemberPointerType>(T); LinkageInfo LV = computeLinkageInfo(MPT->getClass()); LV.merge(computeLinkageInfo(MPT->getPointeeType())); return LV; } case Type::ConstantArray: case Type::IncompleteArray: case Type::VariableArray: return computeLinkageInfo(cast<ArrayType>(T)->getElementType()); case Type::Vector: case Type::ExtVector: return computeLinkageInfo(cast<VectorType>(T)->getElementType()); case Type::FunctionNoProto: return computeLinkageInfo(cast<FunctionType>(T)->getReturnType()); case Type::FunctionProto: { const FunctionProtoType *FPT = cast<FunctionProtoType>(T); LinkageInfo LV = computeLinkageInfo(FPT->getReturnType()); for (const auto &ai : FPT->param_types()) LV.merge(computeLinkageInfo(ai)); return LV; } case Type::ObjCInterface: return cast<ObjCInterfaceType>(T)->getDecl()->getLinkageAndVisibility(); case Type::ObjCObject: return computeLinkageInfo(cast<ObjCObjectType>(T)->getBaseType()); case Type::ObjCObjectPointer: return computeLinkageInfo(cast<ObjCObjectPointerType>(T)->getPointeeType()); case Type::Atomic: return computeLinkageInfo(cast<AtomicType>(T)->getValueType()); case Type::Pipe: return computeLinkageInfo(cast<PipeType>(T)->getElementType()); } llvm_unreachable("unhandled type class"); } static LinkageInfo computeLinkageInfo(QualType T) { return computeLinkageInfo(T.getTypePtr()); } bool Type::isLinkageValid() const { if (!TypeBits.isCacheValid()) return true; return computeLinkageInfo(getCanonicalTypeInternal()).getLinkage() == TypeBits.getLinkage(); } LinkageInfo Type::getLinkageAndVisibility() const { if (!isCanonicalUnqualified()) return computeLinkageInfo(getCanonicalTypeInternal()); LinkageInfo LV = computeLinkageInfo(this); assert(LV.getLinkage() == getLinkage()); return LV; } Optional<NullabilityKind> Type::getNullability(const ASTContext &context) const { QualType type(this, 0); do { // Check whether this is an attributed type with nullability // information. if (auto attributed = dyn_cast<AttributedType>(type.getTypePtr())) { if (auto nullability = attributed->getImmediateNullability()) return nullability; } // Desugar the type. If desugaring does nothing, we're done. QualType desugared = type.getSingleStepDesugaredType(context); if (desugared.getTypePtr() == type.getTypePtr()) return None; type = desugared; } while (true); } bool Type::canHaveNullability() const { QualType type = getCanonicalTypeInternal(); switch (type->getTypeClass()) { // We'll only see canonical types here. #define NON_CANONICAL_TYPE(Class, Parent) \ case Type::Class: \ llvm_unreachable("non-canonical type"); #define TYPE(Class, Parent) #include "clang/AST/TypeNodes.def" // 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::UnaryTransform: case Type::TemplateTypeParm: case Type::SubstTemplateTypeParmPack: case Type::DependentName: case Type::DependentTemplateSpecialization: return true; // Dependent template specializations can instantiate to pointer // types unless they're known to be specializations of a class // template. case Type::TemplateSpecialization: if (TemplateDecl *templateDecl = cast<TemplateSpecializationType>(type.getTypePtr()) ->getTemplateName().getAsTemplateDecl()) { if (isa<ClassTemplateDecl>(templateDecl)) return false; } return true; // auto is considered dependent when it isn't deduced. case Type::Auto: return !cast<AutoType>(type.getTypePtr())->isDeduced(); 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; // 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 true; case BuiltinType::Void: #ifndef noCbC case BuiltinType::__Code: #endif case BuiltinType::ObjCId: case BuiltinType::ObjCClass: case BuiltinType::ObjCSel: case BuiltinType::OCLImage1d: case BuiltinType::OCLImage1dArray: case BuiltinType::OCLImage1dBuffer: case BuiltinType::OCLImage2d: case BuiltinType::OCLImage2dArray: case BuiltinType::OCLImage2dDepth: case BuiltinType::OCLImage2dArrayDepth: case BuiltinType::OCLImage2dMSAA: case BuiltinType::OCLImage2dArrayMSAA: case BuiltinType::OCLImage2dMSAADepth: case BuiltinType::OCLImage2dArrayMSAADepth: case BuiltinType::OCLImage3d: case BuiltinType::OCLSampler: case BuiltinType::OCLEvent: case BuiltinType::OCLClkEvent: case BuiltinType::OCLQueue: case BuiltinType::OCLNDRange: case BuiltinType::OCLReserveID: case BuiltinType::BuiltinFn: case BuiltinType::NullPtr: case BuiltinType::OMPArraySection: return false; } // 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::DependentSizedExtVector: case Type::Vector: case Type::ExtVector: case Type::FunctionProto: case Type::FunctionNoProto: case Type::Record: case Type::Enum: case Type::InjectedClassName: case Type::PackExpansion: case Type::ObjCObject: case Type::ObjCInterface: case Type::Atomic: case Type::Pipe: return false; } llvm_unreachable("bad type kind!"); } llvm::Optional<NullabilityKind> AttributedType::getImmediateNullability() const { if (getAttrKind() == AttributedType::attr_nonnull) return NullabilityKind::NonNull; if (getAttrKind() == AttributedType::attr_nullable) return NullabilityKind::Nullable; if (getAttrKind() == AttributedType::attr_null_unspecified) return NullabilityKind::Unspecified; return None; } Optional<NullabilityKind> AttributedType::stripOuterNullability(QualType &T) { if (auto attributed = dyn_cast<AttributedType>(T.getTypePtr())) { if (auto nullability = attributed->getImmediateNullability()) { T = attributed->getModifiedType(); return nullability; } } return None; } bool Type::isBlockCompatibleObjCPointerType(ASTContext &ctx) const { const ObjCObjectPointerType *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 ArrayType *array = dyn_cast<ArrayType>(canon)) canon = array->getElementType().getTypePtr(); if (const ObjCObjectPointerType *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 TypedefType *typedefType = dyn_cast<TypedefType>(this)) return typedefType->getDecl()->hasAttr<ObjCNSObjectAttr>(); return false; } bool Type::isObjCIndependentClassType() const { if (const TypedefType *typedefType = dyn_cast<TypedefType>(this)) 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 PointerType *OPT = getAs<PointerType>()) return OPT->getPointeeType()->isObjCIndirectLifetimeType(); if (const ReferenceType *Ref = getAs<ReferenceType>()) return Ref->getPointeeType()->isObjCIndirectLifetimeType(); if (const MemberPointerType *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(); } /// \brief 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(); } /// \brief Determine whether the given type T is a "bridgeable" C type. bool Type::isCARCBridgableType() const { const PointerType *Pointer = getAs<PointerType>(); if (!Pointer) return false; QualType Pointee = Pointer->getPointeeType(); return Pointee->isVoidType() || Pointee->isRecordType(); } bool Type::hasSizedVLAType() const { if (!isVariablyModifiedType()) return false; if (const PointerType *ptr = getAs<PointerType>()) return ptr->getPointeeType()->hasSizedVLAType(); if (const ReferenceType *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; } 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; } /// Currently, the only destruction kind we recognize is C++ objects /// with non-trivial destructors. const CXXRecordDecl *record = type->getBaseElementTypeUnsafe()->getAsCXXRecordDecl(); if (record && record->hasDefinition() && !record->hasTrivialDestructor()) return DK_cxx_destructor; return DK_none; } CXXRecordDecl *MemberPointerType::getMostRecentCXXRecordDecl() const { return getClass()->getAsCXXRecordDecl()->getMostRecentDecl(); }