//===-- CanonicalType.h - C Language Family Type Representation -*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file defines the CanQual class template, which provides access to // canonical types. // //===----------------------------------------------------------------------===// #ifndef LLVM_CLANG_AST_CANONICAL_TYPE_H #define LLVM_CLANG_AST_CANONICAL_TYPE_H #include "clang/AST/Type.h" #include "llvm/Support/Casting.h" #include "llvm/Support/type_traits.h" #include namespace clang { template class CanProxy; template struct CanProxyAdaptor; //----------------------------------------------------------------------------// // Canonical, qualified type template //----------------------------------------------------------------------------// /// \brief Represents a canonical, potentially-qualified type. /// /// The CanQual template is a lightweight smart pointer that provides access /// to the canonical representation of a type, where all typedefs and other /// syntactic sugar has been eliminated. A CanQualType may also have various /// qualifiers (const, volatile, restrict) attached to it. /// /// The template type parameter @p T is one of the Type classes (PointerType, /// BuiltinType, etc.). The type stored within @c CanQual will be of that /// type (or some subclass of that type). The typedef @c CanQualType is just /// a shorthand for @c CanQual. /// /// An instance of @c CanQual can be implicitly converted to a /// @c CanQual when T is derived from U, which essentially provides an /// implicit upcast. For example, @c CanQual can be /// converted to @c CanQual. Note that any @c CanQual type can /// be implicitly converted to a QualType, but the reverse operation requires /// a call to ASTContext::getCanonicalType(). /// /// template class CanQual { /// \brief The actual, canonical type. QualType Stored; public: /// \brief Constructs a NULL canonical type. CanQual() : Stored() { } /// \brief Converting constructor that permits implicit upcasting of /// canonical type pointers. template CanQual(const CanQual& Other, typename llvm::enable_if, int>::type = 0); /// \brief Retrieve the underlying type pointer, which refers to a /// canonical type. /// /// The underlying pointer must not be NULL. const T *getTypePtr() const { return cast(Stored.getTypePtr()); } /// \brief Retrieve the underlying type pointer, which refers to a /// canonical type, or NULL. /// const T *getTypePtrOrNull() const { return cast_or_null(Stored.getTypePtrOrNull()); } /// \brief Implicit conversion to a qualified type. operator QualType() const { return Stored; } /// \brief Implicit conversion to bool. operator bool() const { return !isNull(); } bool isNull() const { return Stored.isNull(); } SplitQualType split() const { return Stored.split(); } /// \brief Retrieve a canonical type pointer with a different static type, /// upcasting or downcasting as needed. /// /// The getAs() function is typically used to try to downcast to a /// more specific (canonical) type in the type system. For example: /// /// @code /// void f(CanQual T) { /// if (CanQual Ptr = T->getAs()) { /// // look at Ptr's pointee type /// } /// } /// @endcode /// /// \returns A proxy pointer to the same type, but with the specified /// static type (@p U). If the dynamic type is not the specified static type /// or a derived class thereof, a NULL canonical type. template CanProxy getAs() const; template CanProxy castAs() const; /// \brief Overloaded arrow operator that produces a canonical type /// proxy. CanProxy operator->() const; /// \brief Retrieve all qualifiers. Qualifiers getQualifiers() const { return Stored.getLocalQualifiers(); } /// \brief Retrieve the const/volatile/restrict qualifiers. unsigned getCVRQualifiers() const { return Stored.getLocalCVRQualifiers(); } /// \brief Determines whether this type has any qualifiers bool hasQualifiers() const { return Stored.hasLocalQualifiers(); } bool isConstQualified() const { return Stored.isLocalConstQualified(); } bool isVolatileQualified() const { return Stored.isLocalVolatileQualified(); } bool isRestrictQualified() const { return Stored.isLocalRestrictQualified(); } /// \brief Determines if this canonical type is furthermore /// canonical as a parameter. The parameter-canonicalization /// process decays arrays to pointers and drops top-level qualifiers. bool isCanonicalAsParam() const { return Stored.isCanonicalAsParam(); } /// \brief Retrieve the unqualified form of this type. CanQual getUnqualifiedType() const; /// \brief Retrieves a version of this type with const applied. /// Note that this does not always yield a canonical type. QualType withConst() const { return Stored.withConst(); } /// \brief Determines whether this canonical type is more qualified than /// the @p Other canonical type. bool isMoreQualifiedThan(CanQual Other) const { return Stored.isMoreQualifiedThan(Other.Stored); } /// \brief Determines whether this canonical type is at least as qualified as /// the @p Other canonical type. bool isAtLeastAsQualifiedAs(CanQual Other) const { return Stored.isAtLeastAsQualifiedAs(Other.Stored); } /// \brief If the canonical type is a reference type, returns the type that /// it refers to; otherwise, returns the type itself. CanQual getNonReferenceType() const; /// \brief Retrieve the internal representation of this canonical type. void *getAsOpaquePtr() const { return Stored.getAsOpaquePtr(); } /// \brief Construct a canonical type from its internal representation. static CanQual getFromOpaquePtr(void *Ptr); /// \brief Builds a canonical type from a QualType. /// /// This routine is inherently unsafe, because it requires the user to /// ensure that the given type is a canonical type with the correct // (dynamic) type. static CanQual CreateUnsafe(QualType Other); void dump() const { Stored.dump(); } void Profile(llvm::FoldingSetNodeID &ID) const { ID.AddPointer(getAsOpaquePtr()); } }; template inline bool operator==(CanQual x, CanQual y) { return x.getAsOpaquePtr() == y.getAsOpaquePtr(); } template inline bool operator!=(CanQual x, CanQual y) { return x.getAsOpaquePtr() != y.getAsOpaquePtr(); } /// \brief Represents a canonical, potentially-qualified type. typedef CanQual CanQualType; inline CanQualType Type::getCanonicalTypeUnqualified() const { return CanQualType::CreateUnsafe(getCanonicalTypeInternal()); } inline const DiagnosticBuilder &operator<<(const DiagnosticBuilder &DB, CanQualType T) { DB << static_cast(T); return DB; } //----------------------------------------------------------------------------// // Internal proxy classes used by canonical types //----------------------------------------------------------------------------// #define LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(Accessor) \ CanQualType Accessor() const { \ return CanQualType::CreateUnsafe(this->getTypePtr()->Accessor()); \ } #define LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(Type, Accessor) \ Type Accessor() const { return this->getTypePtr()->Accessor(); } /// \brief Base class of all canonical proxy types, which is responsible for /// storing the underlying canonical type and providing basic conversions. template class CanProxyBase { protected: CanQual Stored; public: /// \brief Retrieve the pointer to the underlying Type const T *getTypePtr() const { return Stored.getTypePtr(); } /// \brief Implicit conversion to the underlying pointer. /// /// Also provides the ability to use canonical type proxies in a Boolean // context,e.g., /// @code /// if (CanQual Ptr = T->getAs()) { ... } /// @endcode operator const T*() const { return this->Stored.getTypePtrOrNull(); } /// \brief Try to convert the given canonical type to a specific structural /// type. template CanProxy getAs() const { return this->Stored.template getAs(); } LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(Type::TypeClass, getTypeClass) // Type predicates LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isObjectType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isIncompleteType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isIncompleteOrObjectType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isVariablyModifiedType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isIntegerType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isEnumeralType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isBooleanType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isCharType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isWideCharType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isIntegralType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isIntegralOrEnumerationType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isRealFloatingType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isComplexType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isAnyComplexType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isFloatingType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isRealType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isArithmeticType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isVoidType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isDerivedType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isScalarType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isAggregateType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isAnyPointerType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isVoidPointerType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isFunctionPointerType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isMemberFunctionPointerType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isClassType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isStructureType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isInterfaceType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isStructureOrClassType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isUnionType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isComplexIntegerType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isNullPtrType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isDependentType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isOverloadableType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isArrayType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, hasPointerRepresentation) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, hasObjCPointerRepresentation) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, hasIntegerRepresentation) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, hasSignedIntegerRepresentation) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, hasUnsignedIntegerRepresentation) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, hasFloatingRepresentation) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isPromotableIntegerType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isSignedIntegerType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isUnsignedIntegerType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isSignedIntegerOrEnumerationType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isUnsignedIntegerOrEnumerationType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isConstantSizeType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isSpecifierType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(CXXRecordDecl*, getAsCXXRecordDecl) /// \brief Retrieve the proxy-adaptor type. /// /// This arrow operator is used when CanProxyAdaptor has been specialized /// for the given type T. In that case, we reference members of the /// CanProxyAdaptor specialization. Otherwise, this operator will be hidden /// by the arrow operator in the primary CanProxyAdaptor template. const CanProxyAdaptor *operator->() const { return static_cast *>(this); } }; /// \brief Replacable canonical proxy adaptor class that provides the link /// between a canonical type and the accessors of the type. /// /// The CanProxyAdaptor is a replaceable class template that is instantiated /// as part of each canonical proxy type. The primary template merely provides /// redirection to the underlying type (T), e.g., @c PointerType. One can /// provide specializations of this class template for each underlying type /// that provide accessors returning canonical types (@c CanQualType) rather /// than the more typical @c QualType, to propagate the notion of "canonical" /// through the system. template struct CanProxyAdaptor : CanProxyBase { }; /// \brief Canonical proxy type returned when retrieving the members of a /// canonical type or as the result of the @c CanQual::getAs member /// function. /// /// The CanProxy type mainly exists as a proxy through which operator-> will /// look to either map down to a raw T* (e.g., PointerType*) or to a proxy /// type that provides canonical-type access to the fields of the type. template class CanProxy : public CanProxyAdaptor { public: /// \brief Build a NULL proxy. CanProxy() { } /// \brief Build a proxy to the given canonical type. CanProxy(CanQual Stored) { this->Stored = Stored; } /// \brief Implicit conversion to the stored canonical type. operator CanQual() const { return this->Stored; } }; } // end namespace clang namespace llvm { /// Implement simplify_type for CanQual, so that we can dyn_cast from /// CanQual to a specific Type class. We're prefer isa/dyn_cast/cast/etc. /// to return smart pointer (proxies?). template struct simplify_type< ::clang::CanQual > { typedef const T *SimpleType; static SimpleType getSimplifiedValue(::clang::CanQual Val) { return Val.getTypePtr(); } }; // Teach SmallPtrSet that CanQual is "basically a pointer". template class PointerLikeTypeTraits > { public: static inline void *getAsVoidPointer(clang::CanQual P) { return P.getAsOpaquePtr(); } static inline clang::CanQual getFromVoidPointer(void *P) { return clang::CanQual::getFromOpaquePtr(P); } // qualifier information is encoded in the low bits. enum { NumLowBitsAvailable = 0 }; }; } // end namespace llvm namespace clang { //----------------------------------------------------------------------------// // Canonical proxy adaptors for canonical type nodes. //----------------------------------------------------------------------------// /// \brief Iterator adaptor that turns an iterator over canonical QualTypes /// into an iterator over CanQualTypes. template class CanTypeIterator { InputIterator Iter; public: typedef CanQualType value_type; typedef value_type reference; typedef CanProxy pointer; typedef typename std::iterator_traits::difference_type difference_type; typedef typename std::iterator_traits::iterator_category iterator_category; CanTypeIterator() : Iter() { } explicit CanTypeIterator(InputIterator Iter) : Iter(Iter) { } // Input iterator reference operator*() const { return CanQualType::CreateUnsafe(*Iter); } pointer operator->() const; CanTypeIterator &operator++() { ++Iter; return *this; } CanTypeIterator operator++(int) { CanTypeIterator Tmp(*this); ++Iter; return Tmp; } friend bool operator==(const CanTypeIterator& X, const CanTypeIterator &Y) { return X.Iter == Y.Iter; } friend bool operator!=(const CanTypeIterator& X, const CanTypeIterator &Y) { return X.Iter != Y.Iter; } // Bidirectional iterator CanTypeIterator &operator--() { --Iter; return *this; } CanTypeIterator operator--(int) { CanTypeIterator Tmp(*this); --Iter; return Tmp; } // Random access iterator reference operator[](difference_type n) const { return CanQualType::CreateUnsafe(Iter[n]); } CanTypeIterator &operator+=(difference_type n) { Iter += n; return *this; } CanTypeIterator &operator-=(difference_type n) { Iter -= n; return *this; } friend CanTypeIterator operator+(CanTypeIterator X, difference_type n) { X += n; return X; } friend CanTypeIterator operator+(difference_type n, CanTypeIterator X) { X += n; return X; } friend CanTypeIterator operator-(CanTypeIterator X, difference_type n) { X -= n; return X; } friend difference_type operator-(const CanTypeIterator &X, const CanTypeIterator &Y) { return X - Y; } }; template<> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getElementType) }; template<> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getPointeeType) }; template<> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getPointeeType) }; template<> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getPointeeType) }; template<> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getPointeeType) }; template<> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getPointeeType) }; template<> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getPointeeType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(const Type *, getClass) }; // CanProxyAdaptors for arrays are intentionally unimplemented because // they are not safe. template<> struct CanProxyAdaptor; template<> struct CanProxyAdaptor; template<> struct CanProxyAdaptor; template<> struct CanProxyAdaptor; template<> struct CanProxyAdaptor; template<> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getElementType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(const Expr *, getSizeExpr) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(SourceLocation, getAttributeLoc) }; template<> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getElementType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(unsigned, getNumElements) }; template<> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getElementType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(unsigned, getNumElements) }; template<> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getResultType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(FunctionType::ExtInfo, getExtInfo) }; template<> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getResultType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(FunctionType::ExtInfo, getExtInfo) }; template<> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getResultType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(FunctionType::ExtInfo, getExtInfo) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(unsigned, getNumArgs) CanQualType getArgType(unsigned i) const { return CanQualType::CreateUnsafe(this->getTypePtr()->getArgType(i)); } LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isVariadic) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(unsigned, getTypeQuals) typedef CanTypeIterator arg_type_iterator; arg_type_iterator arg_type_begin() const { return arg_type_iterator(this->getTypePtr()->arg_type_begin()); } arg_type_iterator arg_type_end() const { return arg_type_iterator(this->getTypePtr()->arg_type_end()); } // Note: canonical function types never have exception specifications }; template<> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getUnderlyingType) }; template<> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(Expr *, getUnderlyingExpr) LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getUnderlyingType) }; template <> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getBaseType) LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getUnderlyingType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(UnaryTransformType::UTTKind, getUTTKind) }; template<> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(TagDecl *, getDecl) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isBeingDefined) }; template<> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(RecordDecl *, getDecl) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isBeingDefined) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, hasConstFields) }; template<> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(EnumDecl *, getDecl) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isBeingDefined) }; template<> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(unsigned, getDepth) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(unsigned, getIndex) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isParameterPack) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(TemplateTypeParmDecl *, getDecl) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(IdentifierInfo *, getIdentifier) }; template<> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getBaseType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(const ObjCInterfaceDecl *, getInterface) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isObjCUnqualifiedId) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isObjCUnqualifiedClass) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isObjCQualifiedId) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isObjCQualifiedClass) typedef ObjCObjectPointerType::qual_iterator qual_iterator; LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(qual_iterator, qual_begin) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(qual_iterator, qual_end) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, qual_empty) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(unsigned, getNumProtocols) }; template<> struct CanProxyAdaptor : public CanProxyBase { LLVM_CLANG_CANPROXY_TYPE_ACCESSOR(getPointeeType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(const ObjCInterfaceType *, getInterfaceType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isObjCIdType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isObjCClassType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isObjCQualifiedIdType) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, isObjCQualifiedClassType) typedef ObjCObjectPointerType::qual_iterator qual_iterator; LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(qual_iterator, qual_begin) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(qual_iterator, qual_end) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(bool, qual_empty) LLVM_CLANG_CANPROXY_SIMPLE_ACCESSOR(unsigned, getNumProtocols) }; //----------------------------------------------------------------------------// // Method and function definitions //----------------------------------------------------------------------------// template inline CanQual CanQual::getUnqualifiedType() const { return CanQual::CreateUnsafe(Stored.getLocalUnqualifiedType()); } template inline CanQual CanQual::getNonReferenceType() const { if (CanQual RefType = getAs()) return RefType->getPointeeType(); else return *this; } template CanQual CanQual::getFromOpaquePtr(void *Ptr) { CanQual Result; Result.Stored = QualType::getFromOpaquePtr(Ptr); assert((!Result || Result.Stored.getAsOpaquePtr() == (void*)-1 || Result.Stored.isCanonical()) && "Type is not canonical!"); return Result; } template CanQual CanQual::CreateUnsafe(QualType Other) { assert((Other.isNull() || Other.isCanonical()) && "Type is not canonical!"); assert((Other.isNull() || isa(Other.getTypePtr())) && "Dynamic type does not meet the static type's requires"); CanQual Result; Result.Stored = Other; return Result; } template template CanProxy CanQual::getAs() const { ArrayType_cannot_be_used_with_getAs at; (void)at; if (Stored.isNull()) return CanProxy(); if (isa(Stored.getTypePtr())) return CanQual::CreateUnsafe(Stored); return CanProxy(); } template template CanProxy CanQual::castAs() const { ArrayType_cannot_be_used_with_getAs at; (void)at; assert(!Stored.isNull() && isa(Stored.getTypePtr())); return CanQual::CreateUnsafe(Stored); } template CanProxy CanQual::operator->() const { return CanProxy(*this); } template typename CanTypeIterator::pointer CanTypeIterator::operator->() const { return CanProxy(*this); } } #endif // LLVM_CLANG_AST_CANONICAL_TYPE_H