//===--- DeclObjC.h - Classes for representing declarations -----*- 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 DeclObjC interface and subclasses. // //===----------------------------------------------------------------------===// #ifndef LLVM_CLANG_AST_DECLOBJC_H #define LLVM_CLANG_AST_DECLOBJC_H #include "clang/AST/Decl.h" #include "clang/AST/SelectorLocationsKind.h" #include "llvm/ADT/STLExtras.h" #include "llvm/Support/Compiler.h" namespace clang { class Expr; class Stmt; class FunctionDecl; class RecordDecl; class ObjCIvarDecl; class ObjCMethodDecl; class ObjCProtocolDecl; class ObjCCategoryDecl; class ObjCPropertyDecl; class ObjCPropertyImplDecl; class CXXCtorInitializer; class ObjCListBase { ObjCListBase(const ObjCListBase &) = delete; void operator=(const ObjCListBase &) = delete; protected: /// List is an array of pointers to objects that are not owned by this object. void **List; unsigned NumElts; public: ObjCListBase() : List(nullptr), NumElts(0) {} unsigned size() const { return NumElts; } bool empty() const { return NumElts == 0; } protected: void set(void *const* InList, unsigned Elts, ASTContext &Ctx); }; /// ObjCList - This is a simple template class used to hold various lists of /// decls etc, which is heavily used by the ObjC front-end. This only use case /// this supports is setting the list all at once and then reading elements out /// of it. template class ObjCList : public ObjCListBase { public: void set(T* const* InList, unsigned Elts, ASTContext &Ctx) { ObjCListBase::set(reinterpret_cast(InList), Elts, Ctx); } typedef T* const * iterator; iterator begin() const { return (iterator)List; } iterator end() const { return (iterator)List+NumElts; } T* operator[](unsigned Idx) const { assert(Idx < NumElts && "Invalid access"); return (T*)List[Idx]; } }; /// \brief A list of Objective-C protocols, along with the source /// locations at which they were referenced. class ObjCProtocolList : public ObjCList { SourceLocation *Locations; using ObjCList::set; public: ObjCProtocolList() : ObjCList(), Locations(nullptr) { } typedef const SourceLocation *loc_iterator; loc_iterator loc_begin() const { return Locations; } loc_iterator loc_end() const { return Locations + size(); } void set(ObjCProtocolDecl* const* InList, unsigned Elts, const SourceLocation *Locs, ASTContext &Ctx); }; /// ObjCMethodDecl - Represents an instance or class method declaration. /// ObjC methods can be declared within 4 contexts: class interfaces, /// categories, protocols, and class implementations. While C++ member /// functions leverage C syntax, Objective-C method syntax is modeled after /// Smalltalk (using colons to specify argument types/expressions). /// Here are some brief examples: /// /// Setter/getter instance methods: /// - (void)setMenu:(NSMenu *)menu; /// - (NSMenu *)menu; /// /// Instance method that takes 2 NSView arguments: /// - (void)replaceSubview:(NSView *)oldView with:(NSView *)newView; /// /// Getter class method: /// + (NSMenu *)defaultMenu; /// /// A selector represents a unique name for a method. The selector names for /// the above methods are setMenu:, menu, replaceSubview:with:, and defaultMenu. /// class ObjCMethodDecl : public NamedDecl, public DeclContext { public: enum ImplementationControl { None, Required, Optional }; private: // The conventional meaning of this method; an ObjCMethodFamily. // This is not serialized; instead, it is computed on demand and // cached. mutable unsigned Family : ObjCMethodFamilyBitWidth; /// instance (true) or class (false) method. unsigned IsInstance : 1; unsigned IsVariadic : 1; /// True if this method is the getter or setter for an explicit property. unsigned IsPropertyAccessor : 1; // Method has a definition. unsigned IsDefined : 1; /// \brief Method redeclaration in the same interface. unsigned IsRedeclaration : 1; /// \brief Is redeclared in the same interface. mutable unsigned HasRedeclaration : 1; // NOTE: VC++ treats enums as signed, avoid using ImplementationControl enum /// \@required/\@optional unsigned DeclImplementation : 2; // NOTE: VC++ treats enums as signed, avoid using the ObjCDeclQualifier enum /// in, inout, etc. unsigned objcDeclQualifier : 7; /// \brief Indicates whether this method has a related result type. unsigned RelatedResultType : 1; /// \brief Whether the locations of the selector identifiers are in a /// "standard" position, a enum SelectorLocationsKind. unsigned SelLocsKind : 2; /// \brief Whether this method overrides any other in the class hierarchy. /// /// A method is said to override any method in the class's /// base classes, its protocols, or its categories' protocols, that has /// the same selector and is of the same kind (class or instance). /// A method in an implementation is not considered as overriding the same /// method in the interface or its categories. unsigned IsOverriding : 1; /// \brief Indicates if the method was a definition but its body was skipped. unsigned HasSkippedBody : 1; // Return type of this method. QualType MethodDeclType; // Type source information for the return type. TypeSourceInfo *ReturnTInfo; /// \brief Array of ParmVarDecls for the formal parameters of this method /// and optionally followed by selector locations. void *ParamsAndSelLocs; unsigned NumParams; /// List of attributes for this method declaration. SourceLocation DeclEndLoc; // the location of the ';' or '{'. // The following are only used for method definitions, null otherwise. LazyDeclStmtPtr Body; /// SelfDecl - Decl for the implicit self parameter. This is lazily /// constructed by createImplicitParams. ImplicitParamDecl *SelfDecl; /// CmdDecl - Decl for the implicit _cmd parameter. This is lazily /// constructed by createImplicitParams. ImplicitParamDecl *CmdDecl; SelectorLocationsKind getSelLocsKind() const { return (SelectorLocationsKind)SelLocsKind; } bool hasStandardSelLocs() const { return getSelLocsKind() != SelLoc_NonStandard; } /// \brief Get a pointer to the stored selector identifiers locations array. /// No locations will be stored if HasStandardSelLocs is true. SourceLocation *getStoredSelLocs() { return reinterpret_cast(getParams() + NumParams); } const SourceLocation *getStoredSelLocs() const { return reinterpret_cast(getParams() + NumParams); } /// \brief Get a pointer to the stored selector identifiers locations array. /// No locations will be stored if HasStandardSelLocs is true. ParmVarDecl **getParams() { return reinterpret_cast(ParamsAndSelLocs); } const ParmVarDecl *const *getParams() const { return reinterpret_cast(ParamsAndSelLocs); } /// \brief Get the number of stored selector identifiers locations. /// No locations will be stored if HasStandardSelLocs is true. unsigned getNumStoredSelLocs() const { if (hasStandardSelLocs()) return 0; return getNumSelectorLocs(); } void setParamsAndSelLocs(ASTContext &C, ArrayRef Params, ArrayRef SelLocs); ObjCMethodDecl(SourceLocation beginLoc, SourceLocation endLoc, Selector SelInfo, QualType T, TypeSourceInfo *ReturnTInfo, DeclContext *contextDecl, bool isInstance = true, bool isVariadic = false, bool isPropertyAccessor = false, bool isImplicitlyDeclared = false, bool isDefined = false, ImplementationControl impControl = None, bool HasRelatedResultType = false) : NamedDecl(ObjCMethod, contextDecl, beginLoc, SelInfo), DeclContext(ObjCMethod), Family(InvalidObjCMethodFamily), IsInstance(isInstance), IsVariadic(isVariadic), IsPropertyAccessor(isPropertyAccessor), IsDefined(isDefined), IsRedeclaration(0), HasRedeclaration(0), DeclImplementation(impControl), objcDeclQualifier(OBJC_TQ_None), RelatedResultType(HasRelatedResultType), SelLocsKind(SelLoc_StandardNoSpace), IsOverriding(0), HasSkippedBody(0), MethodDeclType(T), ReturnTInfo(ReturnTInfo), ParamsAndSelLocs(nullptr), NumParams(0), DeclEndLoc(endLoc), Body(), SelfDecl(nullptr), CmdDecl(nullptr) { setImplicit(isImplicitlyDeclared); } /// \brief A definition will return its interface declaration. /// An interface declaration will return its definition. /// Otherwise it will return itself. ObjCMethodDecl *getNextRedeclarationImpl() override; public: static ObjCMethodDecl * Create(ASTContext &C, SourceLocation beginLoc, SourceLocation endLoc, Selector SelInfo, QualType T, TypeSourceInfo *ReturnTInfo, DeclContext *contextDecl, bool isInstance = true, bool isVariadic = false, bool isPropertyAccessor = false, bool isImplicitlyDeclared = false, bool isDefined = false, ImplementationControl impControl = None, bool HasRelatedResultType = false); static ObjCMethodDecl *CreateDeserialized(ASTContext &C, unsigned ID); ObjCMethodDecl *getCanonicalDecl() override; const ObjCMethodDecl *getCanonicalDecl() const { return const_cast(this)->getCanonicalDecl(); } ObjCDeclQualifier getObjCDeclQualifier() const { return ObjCDeclQualifier(objcDeclQualifier); } void setObjCDeclQualifier(ObjCDeclQualifier QV) { objcDeclQualifier = QV; } /// \brief Determine whether this method has a result type that is related /// to the message receiver's type. bool hasRelatedResultType() const { return RelatedResultType; } /// \brief Note whether this method has a related result type. void SetRelatedResultType(bool RRT = true) { RelatedResultType = RRT; } /// \brief True if this is a method redeclaration in the same interface. bool isRedeclaration() const { return IsRedeclaration; } void setAsRedeclaration(const ObjCMethodDecl *PrevMethod); /// \brief Returns the location where the declarator ends. It will be /// the location of ';' for a method declaration and the location of '{' /// for a method definition. SourceLocation getDeclaratorEndLoc() const { return DeclEndLoc; } // Location information, modeled after the Stmt API. SourceLocation getLocStart() const LLVM_READONLY { return getLocation(); } SourceLocation getLocEnd() const LLVM_READONLY; SourceRange getSourceRange() const override LLVM_READONLY { return SourceRange(getLocation(), getLocEnd()); } SourceLocation getSelectorStartLoc() const { if (isImplicit()) return getLocStart(); return getSelectorLoc(0); } SourceLocation getSelectorLoc(unsigned Index) const { assert(Index < getNumSelectorLocs() && "Index out of range!"); if (hasStandardSelLocs()) return getStandardSelectorLoc(Index, getSelector(), getSelLocsKind() == SelLoc_StandardWithSpace, parameters(), DeclEndLoc); return getStoredSelLocs()[Index]; } void getSelectorLocs(SmallVectorImpl &SelLocs) const; unsigned getNumSelectorLocs() const { if (isImplicit()) return 0; Selector Sel = getSelector(); if (Sel.isUnarySelector()) return 1; return Sel.getNumArgs(); } ObjCInterfaceDecl *getClassInterface(); const ObjCInterfaceDecl *getClassInterface() const { return const_cast(this)->getClassInterface(); } Selector getSelector() const { return getDeclName().getObjCSelector(); } QualType getReturnType() const { return MethodDeclType; } void setReturnType(QualType T) { MethodDeclType = T; } SourceRange getReturnTypeSourceRange() const; /// \brief Determine the type of an expression that sends a message to this /// function. This replaces the type parameters with the types they would /// get if the receiver was parameterless (e.g. it may replace the type /// parameter with 'id'). QualType getSendResultType() const; /// Determine the type of an expression that sends a message to this /// function with the given receiver type. QualType getSendResultType(QualType receiverType) const; TypeSourceInfo *getReturnTypeSourceInfo() const { return ReturnTInfo; } void setReturnTypeSourceInfo(TypeSourceInfo *TInfo) { ReturnTInfo = TInfo; } // Iterator access to formal parameters. unsigned param_size() const { return NumParams; } typedef const ParmVarDecl *const *param_const_iterator; typedef ParmVarDecl *const *param_iterator; typedef llvm::iterator_range param_range; typedef llvm::iterator_range param_const_range; param_const_iterator param_begin() const { return param_const_iterator(getParams()); } param_const_iterator param_end() const { return param_const_iterator(getParams() + NumParams); } param_iterator param_begin() { return param_iterator(getParams()); } param_iterator param_end() { return param_iterator(getParams() + NumParams); } // This method returns and of the parameters which are part of the selector // name mangling requirements. param_const_iterator sel_param_end() const { return param_begin() + getSelector().getNumArgs(); } // ArrayRef access to formal parameters. This should eventually // replace the iterator interface above. ArrayRef parameters() const { return llvm::makeArrayRef(const_cast(getParams()), NumParams); } /// \brief Sets the method's parameters and selector source locations. /// If the method is implicit (not coming from source) \p SelLocs is /// ignored. void setMethodParams(ASTContext &C, ArrayRef Params, ArrayRef SelLocs = llvm::None); // Iterator access to parameter types. struct GetTypeFn { QualType operator()(const ParmVarDecl *PD) const { return PD->getType(); } }; typedef llvm::mapped_iterator param_type_iterator; param_type_iterator param_type_begin() const { return llvm::map_iterator(param_begin(), GetTypeFn()); } param_type_iterator param_type_end() const { return llvm::map_iterator(param_end(), GetTypeFn()); } /// createImplicitParams - Used to lazily create the self and cmd /// implict parameters. This must be called prior to using getSelfDecl() /// or getCmdDecl(). The call is ignored if the implicit parameters /// have already been created. void createImplicitParams(ASTContext &Context, const ObjCInterfaceDecl *ID); /// \return the type for \c self and set \arg selfIsPseudoStrong and /// \arg selfIsConsumed accordingly. QualType getSelfType(ASTContext &Context, const ObjCInterfaceDecl *OID, bool &selfIsPseudoStrong, bool &selfIsConsumed); ImplicitParamDecl * getSelfDecl() const { return SelfDecl; } void setSelfDecl(ImplicitParamDecl *SD) { SelfDecl = SD; } ImplicitParamDecl * getCmdDecl() const { return CmdDecl; } void setCmdDecl(ImplicitParamDecl *CD) { CmdDecl = CD; } /// Determines the family of this method. ObjCMethodFamily getMethodFamily() const; bool isInstanceMethod() const { return IsInstance; } void setInstanceMethod(bool isInst) { IsInstance = isInst; } bool isVariadic() const { return IsVariadic; } void setVariadic(bool isVar) { IsVariadic = isVar; } bool isClassMethod() const { return !IsInstance; } bool isPropertyAccessor() const { return IsPropertyAccessor; } void setPropertyAccessor(bool isAccessor) { IsPropertyAccessor = isAccessor; } bool isDefined() const { return IsDefined; } void setDefined(bool isDefined) { IsDefined = isDefined; } /// \brief Whether this method overrides any other in the class hierarchy. /// /// A method is said to override any method in the class's /// base classes, its protocols, or its categories' protocols, that has /// the same selector and is of the same kind (class or instance). /// A method in an implementation is not considered as overriding the same /// method in the interface or its categories. bool isOverriding() const { return IsOverriding; } void setOverriding(bool isOverriding) { IsOverriding = isOverriding; } /// \brief Return overridden methods for the given \p Method. /// /// An ObjC method is considered to override any method in the class's /// base classes (and base's categories), its protocols, or its categories' /// protocols, that has /// the same selector and is of the same kind (class or instance). /// A method in an implementation is not considered as overriding the same /// method in the interface or its categories. void getOverriddenMethods( SmallVectorImpl &Overridden) const; /// \brief True if the method was a definition but its body was skipped. bool hasSkippedBody() const { return HasSkippedBody; } void setHasSkippedBody(bool Skipped = true) { HasSkippedBody = Skipped; } /// \brief Returns the property associated with this method's selector. /// /// Note that even if this particular method is not marked as a property /// accessor, it is still possible for it to match a property declared in a /// superclass. Pass \c false if you only want to check the current class. const ObjCPropertyDecl *findPropertyDecl(bool CheckOverrides = true) const; // Related to protocols declared in \@protocol void setDeclImplementation(ImplementationControl ic) { DeclImplementation = ic; } ImplementationControl getImplementationControl() const { return ImplementationControl(DeclImplementation); } bool isOptional() const { return getImplementationControl() == Optional; } /// Returns true if this specific method declaration is marked with the /// designated initializer attribute. bool isThisDeclarationADesignatedInitializer() const; /// Returns true if the method selector resolves to a designated initializer /// in the class's interface. /// /// \param InitMethod if non-null and the function returns true, it receives /// the method declaration that was marked with the designated initializer /// attribute. bool isDesignatedInitializerForTheInterface( const ObjCMethodDecl **InitMethod = nullptr) const; /// \brief Determine whether this method has a body. bool hasBody() const override { return Body.isValid(); } /// \brief Retrieve the body of this method, if it has one. Stmt *getBody() const override; void setLazyBody(uint64_t Offset) { Body = Offset; } CompoundStmt *getCompoundBody() { return (CompoundStmt*)getBody(); } void setBody(Stmt *B) { Body = B; } /// \brief Returns whether this specific method is a definition. bool isThisDeclarationADefinition() const { return hasBody(); } // Implement isa/cast/dyncast/etc. static bool classof(const Decl *D) { return classofKind(D->getKind()); } static bool classofKind(Kind K) { return K == ObjCMethod; } static DeclContext *castToDeclContext(const ObjCMethodDecl *D) { return static_cast(const_cast(D)); } static ObjCMethodDecl *castFromDeclContext(const DeclContext *DC) { return static_cast(const_cast(DC)); } friend class ASTDeclReader; friend class ASTDeclWriter; }; /// Describes the variance of a given generic parameter. enum class ObjCTypeParamVariance : uint8_t { /// The parameter is invariant: must match exactly. Invariant, /// The parameter is covariant, e.g., X is a subtype of X when /// the type parameter is covariant and T is a subtype of U. Covariant, /// The parameter is contravariant, e.g., X is a subtype of X /// when the type parameter is covariant and U is a subtype of T. Contravariant, }; /// Represents the declaration of an Objective-C type parameter. /// /// \code /// @interface NSDictionary, Value> /// @end /// \endcode /// /// In the example above, both \c Key and \c Value are represented by /// \c ObjCTypeParamDecl. \c Key has an explicit bound of \c id, /// while \c Value gets an implicit bound of \c id. /// /// Objective-C type parameters are typedef-names in the grammar, class ObjCTypeParamDecl : public TypedefNameDecl { void anchor() override; /// Index of this type parameter in the type parameter list. unsigned Index : 14; /// The variance of the type parameter. unsigned Variance : 2; /// The location of the variance, if any. SourceLocation VarianceLoc; /// The location of the ':', which will be valid when the bound was /// explicitly specified. SourceLocation ColonLoc; ObjCTypeParamDecl(ASTContext &ctx, DeclContext *dc, ObjCTypeParamVariance variance, SourceLocation varianceLoc, unsigned index, SourceLocation nameLoc, IdentifierInfo *name, SourceLocation colonLoc, TypeSourceInfo *boundInfo) : TypedefNameDecl(ObjCTypeParam, ctx, dc, nameLoc, nameLoc, name, boundInfo), Index(index), Variance(static_cast(variance)), VarianceLoc(varianceLoc), ColonLoc(colonLoc) { } public: static ObjCTypeParamDecl *Create(ASTContext &ctx, DeclContext *dc, ObjCTypeParamVariance variance, SourceLocation varianceLoc, unsigned index, SourceLocation nameLoc, IdentifierInfo *name, SourceLocation colonLoc, TypeSourceInfo *boundInfo); static ObjCTypeParamDecl *CreateDeserialized(ASTContext &ctx, unsigned ID); SourceRange getSourceRange() const override LLVM_READONLY; /// Determine the variance of this type parameter. ObjCTypeParamVariance getVariance() const { return static_cast(Variance); } /// Set the variance of this type parameter. void setVariance(ObjCTypeParamVariance variance) { Variance = static_cast(variance); } /// Retrieve the location of the variance keyword. SourceLocation getVarianceLoc() const { return VarianceLoc; } /// Retrieve the index into its type parameter list. unsigned getIndex() const { return Index; } /// Whether this type parameter has an explicitly-written type bound, e.g., /// "T : NSView". bool hasExplicitBound() const { return ColonLoc.isValid(); } /// Retrieve the location of the ':' separating the type parameter name /// from the explicitly-specified bound. SourceLocation getColonLoc() const { return ColonLoc; } // Implement isa/cast/dyncast/etc. static bool classof(const Decl *D) { return classofKind(D->getKind()); } static bool classofKind(Kind K) { return K == ObjCTypeParam; } friend class ASTDeclReader; friend class ASTDeclWriter; }; /// Stores a list of Objective-C type parameters for a parameterized class /// or a category/extension thereof. /// /// \code /// @interface NSArray // stores the /// @end /// \endcode class ObjCTypeParamList final : private llvm::TrailingObjects { /// Stores the components of a SourceRange as a POD. struct PODSourceRange { unsigned Begin; unsigned End; }; union { /// Location of the left and right angle brackets. PODSourceRange Brackets; // Used only for alignment. ObjCTypeParamDecl *AlignmentHack; }; /// The number of parameters in the list, which are tail-allocated. unsigned NumParams; ObjCTypeParamList(SourceLocation lAngleLoc, ArrayRef typeParams, SourceLocation rAngleLoc); public: /// Create a new Objective-C type parameter list. static ObjCTypeParamList *create(ASTContext &ctx, SourceLocation lAngleLoc, ArrayRef typeParams, SourceLocation rAngleLoc); /// Iterate through the type parameters in the list. typedef ObjCTypeParamDecl **iterator; iterator begin() { return getTrailingObjects(); } iterator end() { return begin() + size(); } /// Determine the number of type parameters in this list. unsigned size() const { return NumParams; } // Iterate through the type parameters in the list. typedef ObjCTypeParamDecl * const *const_iterator; const_iterator begin() const { return getTrailingObjects(); } const_iterator end() const { return begin() + size(); } ObjCTypeParamDecl *front() const { assert(size() > 0 && "empty Objective-C type parameter list"); return *begin(); } ObjCTypeParamDecl *back() const { assert(size() > 0 && "empty Objective-C type parameter list"); return *(end() - 1); } SourceLocation getLAngleLoc() const { return SourceLocation::getFromRawEncoding(Brackets.Begin); } SourceLocation getRAngleLoc() const { return SourceLocation::getFromRawEncoding(Brackets.End); } SourceRange getSourceRange() const { return SourceRange(getLAngleLoc(), getRAngleLoc()); } /// Gather the default set of type arguments to be substituted for /// these type parameters when dealing with an unspecialized type. void gatherDefaultTypeArgs(SmallVectorImpl &typeArgs) const; friend TrailingObjects; }; enum class ObjCPropertyQueryKind : uint8_t { OBJC_PR_query_unknown = 0x00, OBJC_PR_query_instance, OBJC_PR_query_class }; /// \brief Represents one property declaration in an Objective-C interface. /// /// For example: /// \code{.mm} /// \@property (assign, readwrite) int MyProperty; /// \endcode class ObjCPropertyDecl : public NamedDecl { void anchor() override; public: enum PropertyAttributeKind { OBJC_PR_noattr = 0x00, OBJC_PR_readonly = 0x01, OBJC_PR_getter = 0x02, OBJC_PR_assign = 0x04, OBJC_PR_readwrite = 0x08, OBJC_PR_retain = 0x10, OBJC_PR_copy = 0x20, OBJC_PR_nonatomic = 0x40, OBJC_PR_setter = 0x80, OBJC_PR_atomic = 0x100, OBJC_PR_weak = 0x200, OBJC_PR_strong = 0x400, OBJC_PR_unsafe_unretained = 0x800, /// Indicates that the nullability of the type was spelled with a /// property attribute rather than a type qualifier. OBJC_PR_nullability = 0x1000, OBJC_PR_null_resettable = 0x2000, OBJC_PR_class = 0x4000 // Adding a property should change NumPropertyAttrsBits }; enum { /// \brief Number of bits fitting all the property attributes. NumPropertyAttrsBits = 15 }; enum SetterKind { Assign, Retain, Copy, Weak }; enum PropertyControl { None, Required, Optional }; private: SourceLocation AtLoc; // location of \@property SourceLocation LParenLoc; // location of '(' starting attribute list or null. QualType DeclType; TypeSourceInfo *DeclTypeSourceInfo; unsigned PropertyAttributes : NumPropertyAttrsBits; unsigned PropertyAttributesAsWritten : NumPropertyAttrsBits; // \@required/\@optional unsigned PropertyImplementation : 2; Selector GetterName; // getter name of NULL if no getter Selector SetterName; // setter name of NULL if no setter SourceLocation GetterNameLoc; // location of the getter attribute's value SourceLocation SetterNameLoc; // location of the setter attribute's value ObjCMethodDecl *GetterMethodDecl; // Declaration of getter instance method ObjCMethodDecl *SetterMethodDecl; // Declaration of setter instance method ObjCIvarDecl *PropertyIvarDecl; // Synthesize ivar for this property ObjCPropertyDecl(DeclContext *DC, SourceLocation L, IdentifierInfo *Id, SourceLocation AtLocation, SourceLocation LParenLocation, QualType T, TypeSourceInfo *TSI, PropertyControl propControl) : NamedDecl(ObjCProperty, DC, L, Id), AtLoc(AtLocation), LParenLoc(LParenLocation), DeclType(T), DeclTypeSourceInfo(TSI), PropertyAttributes(OBJC_PR_noattr), PropertyAttributesAsWritten(OBJC_PR_noattr), PropertyImplementation(propControl), GetterName(Selector()), SetterName(Selector()), GetterMethodDecl(nullptr), SetterMethodDecl(nullptr), PropertyIvarDecl(nullptr) {} public: static ObjCPropertyDecl *Create(ASTContext &C, DeclContext *DC, SourceLocation L, IdentifierInfo *Id, SourceLocation AtLocation, SourceLocation LParenLocation, QualType T, TypeSourceInfo *TSI, PropertyControl propControl = None); static ObjCPropertyDecl *CreateDeserialized(ASTContext &C, unsigned ID); SourceLocation getAtLoc() const { return AtLoc; } void setAtLoc(SourceLocation L) { AtLoc = L; } SourceLocation getLParenLoc() const { return LParenLoc; } void setLParenLoc(SourceLocation L) { LParenLoc = L; } TypeSourceInfo *getTypeSourceInfo() const { return DeclTypeSourceInfo; } QualType getType() const { return DeclType; } void setType(QualType T, TypeSourceInfo *TSI) { DeclType = T; DeclTypeSourceInfo = TSI; } /// Retrieve the type when this property is used with a specific base object /// type. QualType getUsageType(QualType objectType) const; PropertyAttributeKind getPropertyAttributes() const { return PropertyAttributeKind(PropertyAttributes); } void setPropertyAttributes(PropertyAttributeKind PRVal) { PropertyAttributes |= PRVal; } void overwritePropertyAttributes(unsigned PRVal) { PropertyAttributes = PRVal; } PropertyAttributeKind getPropertyAttributesAsWritten() const { return PropertyAttributeKind(PropertyAttributesAsWritten); } void setPropertyAttributesAsWritten(PropertyAttributeKind PRVal) { PropertyAttributesAsWritten = PRVal; } // Helper methods for accessing attributes. /// isReadOnly - Return true iff the property has a setter. bool isReadOnly() const { return (PropertyAttributes & OBJC_PR_readonly); } /// isAtomic - Return true if the property is atomic. bool isAtomic() const { return (PropertyAttributes & OBJC_PR_atomic); } /// isRetaining - Return true if the property retains its value. bool isRetaining() const { return (PropertyAttributes & (OBJC_PR_retain | OBJC_PR_strong | OBJC_PR_copy)); } bool isInstanceProperty() const { return !isClassProperty(); } bool isClassProperty() const { return PropertyAttributes & OBJC_PR_class; } ObjCPropertyQueryKind getQueryKind() const { return isClassProperty() ? ObjCPropertyQueryKind::OBJC_PR_query_class : ObjCPropertyQueryKind::OBJC_PR_query_instance; } static ObjCPropertyQueryKind getQueryKind(bool isClassProperty) { return isClassProperty ? ObjCPropertyQueryKind::OBJC_PR_query_class : ObjCPropertyQueryKind::OBJC_PR_query_instance; } /// getSetterKind - Return the method used for doing assignment in /// the property setter. This is only valid if the property has been /// defined to have a setter. SetterKind getSetterKind() const { if (PropertyAttributes & OBJC_PR_strong) return getType()->isBlockPointerType() ? Copy : Retain; if (PropertyAttributes & OBJC_PR_retain) return Retain; if (PropertyAttributes & OBJC_PR_copy) return Copy; if (PropertyAttributes & OBJC_PR_weak) return Weak; return Assign; } Selector getGetterName() const { return GetterName; } SourceLocation getGetterNameLoc() const { return GetterNameLoc; } void setGetterName(Selector Sel, SourceLocation Loc = SourceLocation()) { GetterName = Sel; GetterNameLoc = Loc; } Selector getSetterName() const { return SetterName; } SourceLocation getSetterNameLoc() const { return SetterNameLoc; } void setSetterName(Selector Sel, SourceLocation Loc = SourceLocation()) { SetterName = Sel; SetterNameLoc = Loc; } ObjCMethodDecl *getGetterMethodDecl() const { return GetterMethodDecl; } void setGetterMethodDecl(ObjCMethodDecl *gDecl) { GetterMethodDecl = gDecl; } ObjCMethodDecl *getSetterMethodDecl() const { return SetterMethodDecl; } void setSetterMethodDecl(ObjCMethodDecl *gDecl) { SetterMethodDecl = gDecl; } // Related to \@optional/\@required declared in \@protocol void setPropertyImplementation(PropertyControl pc) { PropertyImplementation = pc; } PropertyControl getPropertyImplementation() const { return PropertyControl(PropertyImplementation); } bool isOptional() const { return getPropertyImplementation() == PropertyControl::Optional; } void setPropertyIvarDecl(ObjCIvarDecl *Ivar) { PropertyIvarDecl = Ivar; } ObjCIvarDecl *getPropertyIvarDecl() const { return PropertyIvarDecl; } SourceRange getSourceRange() const override LLVM_READONLY { return SourceRange(AtLoc, getLocation()); } /// Get the default name of the synthesized ivar. IdentifierInfo *getDefaultSynthIvarName(ASTContext &Ctx) const; /// Lookup a property by name in the specified DeclContext. static ObjCPropertyDecl *findPropertyDecl(const DeclContext *DC, const IdentifierInfo *propertyID, ObjCPropertyQueryKind queryKind); static bool classof(const Decl *D) { return classofKind(D->getKind()); } static bool classofKind(Kind K) { return K == ObjCProperty; } }; /// ObjCContainerDecl - Represents a container for method declarations. /// Current sub-classes are ObjCInterfaceDecl, ObjCCategoryDecl, /// ObjCProtocolDecl, and ObjCImplDecl. /// class ObjCContainerDecl : public NamedDecl, public DeclContext { void anchor() override; SourceLocation AtStart; // These two locations in the range mark the end of the method container. // The first points to the '@' token, and the second to the 'end' token. SourceRange AtEnd; public: ObjCContainerDecl(Kind DK, DeclContext *DC, IdentifierInfo *Id, SourceLocation nameLoc, SourceLocation atStartLoc) : NamedDecl(DK, DC, nameLoc, Id), DeclContext(DK), AtStart(atStartLoc) {} // Iterator access to instance/class properties. typedef specific_decl_iterator prop_iterator; typedef llvm::iterator_range> prop_range; prop_range properties() const { return prop_range(prop_begin(), prop_end()); } prop_iterator prop_begin() const { return prop_iterator(decls_begin()); } prop_iterator prop_end() const { return prop_iterator(decls_end()); } typedef filtered_decl_iterator instprop_iterator; typedef llvm::iterator_range instprop_range; instprop_range instance_properties() const { return instprop_range(instprop_begin(), instprop_end()); } instprop_iterator instprop_begin() const { return instprop_iterator(decls_begin()); } instprop_iterator instprop_end() const { return instprop_iterator(decls_end()); } typedef filtered_decl_iterator classprop_iterator; typedef llvm::iterator_range classprop_range; classprop_range class_properties() const { return classprop_range(classprop_begin(), classprop_end()); } classprop_iterator classprop_begin() const { return classprop_iterator(decls_begin()); } classprop_iterator classprop_end() const { return classprop_iterator(decls_end()); } // Iterator access to instance/class methods. typedef specific_decl_iterator method_iterator; typedef llvm::iterator_range> method_range; method_range methods() const { return method_range(meth_begin(), meth_end()); } method_iterator meth_begin() const { return method_iterator(decls_begin()); } method_iterator meth_end() const { return method_iterator(decls_end()); } typedef filtered_decl_iterator instmeth_iterator; typedef llvm::iterator_range instmeth_range; instmeth_range instance_methods() const { return instmeth_range(instmeth_begin(), instmeth_end()); } instmeth_iterator instmeth_begin() const { return instmeth_iterator(decls_begin()); } instmeth_iterator instmeth_end() const { return instmeth_iterator(decls_end()); } typedef filtered_decl_iterator classmeth_iterator; typedef llvm::iterator_range classmeth_range; classmeth_range class_methods() const { return classmeth_range(classmeth_begin(), classmeth_end()); } classmeth_iterator classmeth_begin() const { return classmeth_iterator(decls_begin()); } classmeth_iterator classmeth_end() const { return classmeth_iterator(decls_end()); } // Get the local instance/class method declared in this interface. ObjCMethodDecl *getMethod(Selector Sel, bool isInstance, bool AllowHidden = false) const; ObjCMethodDecl *getInstanceMethod(Selector Sel, bool AllowHidden = false) const { return getMethod(Sel, true/*isInstance*/, AllowHidden); } ObjCMethodDecl *getClassMethod(Selector Sel, bool AllowHidden = false) const { return getMethod(Sel, false/*isInstance*/, AllowHidden); } bool HasUserDeclaredSetterMethod(const ObjCPropertyDecl *P) const; ObjCIvarDecl *getIvarDecl(IdentifierInfo *Id) const; ObjCPropertyDecl * FindPropertyDeclaration(const IdentifierInfo *PropertyId, ObjCPropertyQueryKind QueryKind) const; typedef llvm::DenseMap, ObjCPropertyDecl*> PropertyMap; typedef llvm::DenseMap ProtocolPropertyMap; typedef llvm::SmallVector PropertyDeclOrder; /// This routine collects list of properties to be implemented in the class. /// This includes, class's and its conforming protocols' properties. /// Note, the superclass's properties are not included in the list. virtual void collectPropertiesToImplement(PropertyMap &PM, PropertyDeclOrder &PO) const {} SourceLocation getAtStartLoc() const { return AtStart; } void setAtStartLoc(SourceLocation Loc) { AtStart = Loc; } // Marks the end of the container. SourceRange getAtEndRange() const { return AtEnd; } void setAtEndRange(SourceRange atEnd) { AtEnd = atEnd; } SourceRange getSourceRange() const override LLVM_READONLY { return SourceRange(AtStart, getAtEndRange().getEnd()); } // Implement isa/cast/dyncast/etc. static bool classof(const Decl *D) { return classofKind(D->getKind()); } static bool classofKind(Kind K) { return K >= firstObjCContainer && K <= lastObjCContainer; } static DeclContext *castToDeclContext(const ObjCContainerDecl *D) { return static_cast(const_cast(D)); } static ObjCContainerDecl *castFromDeclContext(const DeclContext *DC) { return static_cast(const_cast(DC)); } }; /// \brief Represents an ObjC class declaration. /// /// For example: /// /// \code /// // MostPrimitive declares no super class (not particularly useful). /// \@interface MostPrimitive /// // no instance variables or methods. /// \@end /// /// // NSResponder inherits from NSObject & implements NSCoding (a protocol). /// \@interface NSResponder : NSObject \ /// { // instance variables are represented by ObjCIvarDecl. /// id nextResponder; // nextResponder instance variable. /// } /// - (NSResponder *)nextResponder; // return a pointer to NSResponder. /// - (void)mouseMoved:(NSEvent *)theEvent; // return void, takes a pointer /// \@end // to an NSEvent. /// \endcode /// /// Unlike C/C++, forward class declarations are accomplished with \@class. /// Unlike C/C++, \@class allows for a list of classes to be forward declared. /// Unlike C++, ObjC is a single-rooted class model. In Cocoa, classes /// typically inherit from NSObject (an exception is NSProxy). /// class ObjCInterfaceDecl : public ObjCContainerDecl , public Redeclarable { void anchor() override; /// TypeForDecl - This indicates the Type object that represents this /// TypeDecl. It is a cache maintained by ASTContext::getObjCInterfaceType mutable const Type *TypeForDecl; friend class ASTContext; struct DefinitionData { /// \brief The definition of this class, for quick access from any /// declaration. ObjCInterfaceDecl *Definition; /// When non-null, this is always an ObjCObjectType. TypeSourceInfo *SuperClassTInfo; /// Protocols referenced in the \@interface declaration ObjCProtocolList ReferencedProtocols; /// Protocols reference in both the \@interface and class extensions. ObjCList AllReferencedProtocols; /// \brief List of categories and class extensions defined for this class. /// /// Categories are stored as a linked list in the AST, since the categories /// and class extensions come long after the initial interface declaration, /// and we avoid dynamically-resized arrays in the AST wherever possible. ObjCCategoryDecl *CategoryList; /// IvarList - List of all ivars defined by this class; including class /// extensions and implementation. This list is built lazily. ObjCIvarDecl *IvarList; /// \brief Indicates that the contents of this Objective-C class will be /// completed by the external AST source when required. mutable unsigned ExternallyCompleted : 1; /// \brief Indicates that the ivar cache does not yet include ivars /// declared in the implementation. mutable unsigned IvarListMissingImplementation : 1; /// Indicates that this interface decl contains at least one initializer /// marked with the 'objc_designated_initializer' attribute. unsigned HasDesignatedInitializers : 1; enum InheritedDesignatedInitializersState { /// We didn't calculate whether the designated initializers should be /// inherited or not. IDI_Unknown = 0, /// Designated initializers are inherited for the super class. IDI_Inherited = 1, /// The class does not inherit designated initializers. IDI_NotInherited = 2 }; /// One of the \c InheritedDesignatedInitializersState enumeratos. mutable unsigned InheritedDesignatedInitializers : 2; /// \brief The location of the last location in this declaration, before /// the properties/methods. For example, this will be the '>', '}', or /// identifier, SourceLocation EndLoc; DefinitionData() : Definition(), SuperClassTInfo(), CategoryList(), IvarList(), ExternallyCompleted(), IvarListMissingImplementation(true), HasDesignatedInitializers(), InheritedDesignatedInitializers(IDI_Unknown) { } }; ObjCInterfaceDecl(const ASTContext &C, DeclContext *DC, SourceLocation AtLoc, IdentifierInfo *Id, ObjCTypeParamList *typeParamList, SourceLocation CLoc, ObjCInterfaceDecl *PrevDecl, bool IsInternal); void LoadExternalDefinition() const; /// The type parameters associated with this class, if any. ObjCTypeParamList *TypeParamList; /// \brief Contains a pointer to the data associated with this class, /// which will be NULL if this class has not yet been defined. /// /// The bit indicates when we don't need to check for out-of-date /// declarations. It will be set unless modules are enabled. llvm::PointerIntPair Data; DefinitionData &data() const { assert(Data.getPointer() && "Declaration has no definition!"); return *Data.getPointer(); } /// \brief Allocate the definition data for this class. void allocateDefinitionData(); typedef Redeclarable redeclarable_base; ObjCInterfaceDecl *getNextRedeclarationImpl() override { return getNextRedeclaration(); } ObjCInterfaceDecl *getPreviousDeclImpl() override { return getPreviousDecl(); } ObjCInterfaceDecl *getMostRecentDeclImpl() override { return getMostRecentDecl(); } public: static ObjCInterfaceDecl *Create(const ASTContext &C, DeclContext *DC, SourceLocation atLoc, IdentifierInfo *Id, ObjCTypeParamList *typeParamList, ObjCInterfaceDecl *PrevDecl, SourceLocation ClassLoc = SourceLocation(), bool isInternal = false); static ObjCInterfaceDecl *CreateDeserialized(const ASTContext &C, unsigned ID); /// Retrieve the type parameters of this class. /// /// This function looks for a type parameter list for the given /// class; if the class has been declared (with \c \@class) but not /// defined (with \c \@interface), it will search for a declaration that /// has type parameters, skipping any declarations that do not. ObjCTypeParamList *getTypeParamList() const; /// Set the type parameters of this class. /// /// This function is used by the AST importer, which must import the type /// parameters after creating their DeclContext to avoid loops. void setTypeParamList(ObjCTypeParamList *TPL); /// Retrieve the type parameters written on this particular declaration of /// the class. ObjCTypeParamList *getTypeParamListAsWritten() const { return TypeParamList; } SourceRange getSourceRange() const override LLVM_READONLY { if (isThisDeclarationADefinition()) return ObjCContainerDecl::getSourceRange(); return SourceRange(getAtStartLoc(), getLocation()); } /// \brief Indicate that this Objective-C class is complete, but that /// the external AST source will be responsible for filling in its contents /// when a complete class is required. void setExternallyCompleted(); /// Indicate that this interface decl contains at least one initializer /// marked with the 'objc_designated_initializer' attribute. void setHasDesignatedInitializers(); /// Returns true if this interface decl contains at least one initializer /// marked with the 'objc_designated_initializer' attribute. bool hasDesignatedInitializers() const; /// Returns true if this interface decl declares a designated initializer /// or it inherites one from its super class. bool declaresOrInheritsDesignatedInitializers() const { return hasDesignatedInitializers() || inheritsDesignatedInitializers(); } const ObjCProtocolList &getReferencedProtocols() const { assert(hasDefinition() && "Caller did not check for forward reference!"); if (data().ExternallyCompleted) LoadExternalDefinition(); return data().ReferencedProtocols; } ObjCImplementationDecl *getImplementation() const; void setImplementation(ObjCImplementationDecl *ImplD); ObjCCategoryDecl *FindCategoryDeclaration(IdentifierInfo *CategoryId) const; // Get the local instance/class method declared in a category. ObjCMethodDecl *getCategoryInstanceMethod(Selector Sel) const; ObjCMethodDecl *getCategoryClassMethod(Selector Sel) const; ObjCMethodDecl *getCategoryMethod(Selector Sel, bool isInstance) const { return isInstance ? getCategoryInstanceMethod(Sel) : getCategoryClassMethod(Sel); } typedef ObjCProtocolList::iterator protocol_iterator; typedef llvm::iterator_range protocol_range; protocol_range protocols() const { return protocol_range(protocol_begin(), protocol_end()); } protocol_iterator protocol_begin() const { // FIXME: Should make sure no callers ever do this. if (!hasDefinition()) return protocol_iterator(); if (data().ExternallyCompleted) LoadExternalDefinition(); return data().ReferencedProtocols.begin(); } protocol_iterator protocol_end() const { // FIXME: Should make sure no callers ever do this. if (!hasDefinition()) return protocol_iterator(); if (data().ExternallyCompleted) LoadExternalDefinition(); return data().ReferencedProtocols.end(); } typedef ObjCProtocolList::loc_iterator protocol_loc_iterator; typedef llvm::iterator_range protocol_loc_range; protocol_loc_range protocol_locs() const { return protocol_loc_range(protocol_loc_begin(), protocol_loc_end()); } protocol_loc_iterator protocol_loc_begin() const { // FIXME: Should make sure no callers ever do this. if (!hasDefinition()) return protocol_loc_iterator(); if (data().ExternallyCompleted) LoadExternalDefinition(); return data().ReferencedProtocols.loc_begin(); } protocol_loc_iterator protocol_loc_end() const { // FIXME: Should make sure no callers ever do this. if (!hasDefinition()) return protocol_loc_iterator(); if (data().ExternallyCompleted) LoadExternalDefinition(); return data().ReferencedProtocols.loc_end(); } typedef ObjCList::iterator all_protocol_iterator; typedef llvm::iterator_range all_protocol_range; all_protocol_range all_referenced_protocols() const { return all_protocol_range(all_referenced_protocol_begin(), all_referenced_protocol_end()); } all_protocol_iterator all_referenced_protocol_begin() const { // FIXME: Should make sure no callers ever do this. if (!hasDefinition()) return all_protocol_iterator(); if (data().ExternallyCompleted) LoadExternalDefinition(); return data().AllReferencedProtocols.empty() ? protocol_begin() : data().AllReferencedProtocols.begin(); } all_protocol_iterator all_referenced_protocol_end() const { // FIXME: Should make sure no callers ever do this. if (!hasDefinition()) return all_protocol_iterator(); if (data().ExternallyCompleted) LoadExternalDefinition(); return data().AllReferencedProtocols.empty() ? protocol_end() : data().AllReferencedProtocols.end(); } typedef specific_decl_iterator ivar_iterator; typedef llvm::iterator_range> ivar_range; ivar_range ivars() const { return ivar_range(ivar_begin(), ivar_end()); } ivar_iterator ivar_begin() const { if (const ObjCInterfaceDecl *Def = getDefinition()) return ivar_iterator(Def->decls_begin()); // FIXME: Should make sure no callers ever do this. return ivar_iterator(); } ivar_iterator ivar_end() const { if (const ObjCInterfaceDecl *Def = getDefinition()) return ivar_iterator(Def->decls_end()); // FIXME: Should make sure no callers ever do this. return ivar_iterator(); } unsigned ivar_size() const { return std::distance(ivar_begin(), ivar_end()); } bool ivar_empty() const { return ivar_begin() == ivar_end(); } ObjCIvarDecl *all_declared_ivar_begin(); const ObjCIvarDecl *all_declared_ivar_begin() const { // Even though this modifies IvarList, it's conceptually const: // the ivar chain is essentially a cached property of ObjCInterfaceDecl. return const_cast(this)->all_declared_ivar_begin(); } void setIvarList(ObjCIvarDecl *ivar) { data().IvarList = ivar; } /// setProtocolList - Set the list of protocols that this interface /// implements. void setProtocolList(ObjCProtocolDecl *const* List, unsigned Num, const SourceLocation *Locs, ASTContext &C) { data().ReferencedProtocols.set(List, Num, Locs, C); } /// mergeClassExtensionProtocolList - Merge class extension's protocol list /// into the protocol list for this class. void mergeClassExtensionProtocolList(ObjCProtocolDecl *const* List, unsigned Num, ASTContext &C); /// Produce a name to be used for class's metadata. It comes either via /// objc_runtime_name attribute or class name. StringRef getObjCRuntimeNameAsString() const; /// Returns the designated initializers for the interface. /// /// If this declaration does not have methods marked as designated /// initializers then the interface inherits the designated initializers of /// its super class. void getDesignatedInitializers( llvm::SmallVectorImpl &Methods) const; /// Returns true if the given selector is a designated initializer for the /// interface. /// /// If this declaration does not have methods marked as designated /// initializers then the interface inherits the designated initializers of /// its super class. /// /// \param InitMethod if non-null and the function returns true, it receives /// the method that was marked as a designated initializer. bool isDesignatedInitializer(Selector Sel, const ObjCMethodDecl **InitMethod = nullptr) const; /// \brief Determine whether this particular declaration of this class is /// actually also a definition. bool isThisDeclarationADefinition() const { return getDefinition() == this; } /// \brief Determine whether this class has been defined. bool hasDefinition() const { // If the name of this class is out-of-date, bring it up-to-date, which // might bring in a definition. // Note: a null value indicates that we don't have a definition and that // modules are enabled. if (!Data.getOpaqueValue()) getMostRecentDecl(); return Data.getPointer(); } /// \brief Retrieve the definition of this class, or NULL if this class /// has been forward-declared (with \@class) but not yet defined (with /// \@interface). ObjCInterfaceDecl *getDefinition() { return hasDefinition()? Data.getPointer()->Definition : nullptr; } /// \brief Retrieve the definition of this class, or NULL if this class /// has been forward-declared (with \@class) but not yet defined (with /// \@interface). const ObjCInterfaceDecl *getDefinition() const { return hasDefinition()? Data.getPointer()->Definition : nullptr; } /// \brief Starts the definition of this Objective-C class, taking it from /// a forward declaration (\@class) to a definition (\@interface). void startDefinition(); /// Retrieve the superclass type. const ObjCObjectType *getSuperClassType() const { if (TypeSourceInfo *TInfo = getSuperClassTInfo()) return TInfo->getType()->castAs(); return nullptr; } // Retrieve the type source information for the superclass. TypeSourceInfo *getSuperClassTInfo() const { // FIXME: Should make sure no callers ever do this. if (!hasDefinition()) return nullptr; if (data().ExternallyCompleted) LoadExternalDefinition(); return data().SuperClassTInfo; } // Retrieve the declaration for the superclass of this class, which // does not include any type arguments that apply to the superclass. ObjCInterfaceDecl *getSuperClass() const; void setSuperClass(TypeSourceInfo *superClass) { data().SuperClassTInfo = superClass; } /// \brief Iterator that walks over the list of categories, filtering out /// those that do not meet specific criteria. /// /// This class template is used for the various permutations of category /// and extension iterators. template class filtered_category_iterator { ObjCCategoryDecl *Current; void findAcceptableCategory(); public: typedef ObjCCategoryDecl * value_type; typedef value_type reference; typedef value_type pointer; typedef std::ptrdiff_t difference_type; typedef std::input_iterator_tag iterator_category; filtered_category_iterator() : Current(nullptr) { } explicit filtered_category_iterator(ObjCCategoryDecl *Current) : Current(Current) { findAcceptableCategory(); } reference operator*() const { return Current; } pointer operator->() const { return Current; } filtered_category_iterator &operator++(); filtered_category_iterator operator++(int) { filtered_category_iterator Tmp = *this; ++(*this); return Tmp; } friend bool operator==(filtered_category_iterator X, filtered_category_iterator Y) { return X.Current == Y.Current; } friend bool operator!=(filtered_category_iterator X, filtered_category_iterator Y) { return X.Current != Y.Current; } }; private: /// \brief Test whether the given category is visible. /// /// Used in the \c visible_categories_iterator. static bool isVisibleCategory(ObjCCategoryDecl *Cat); public: /// \brief Iterator that walks over the list of categories and extensions /// that are visible, i.e., not hidden in a non-imported submodule. typedef filtered_category_iterator visible_categories_iterator; typedef llvm::iterator_range visible_categories_range; visible_categories_range visible_categories() const { return visible_categories_range(visible_categories_begin(), visible_categories_end()); } /// \brief Retrieve an iterator to the beginning of the visible-categories /// list. visible_categories_iterator visible_categories_begin() const { return visible_categories_iterator(getCategoryListRaw()); } /// \brief Retrieve an iterator to the end of the visible-categories list. visible_categories_iterator visible_categories_end() const { return visible_categories_iterator(); } /// \brief Determine whether the visible-categories list is empty. bool visible_categories_empty() const { return visible_categories_begin() == visible_categories_end(); } private: /// \brief Test whether the given category... is a category. /// /// Used in the \c known_categories_iterator. static bool isKnownCategory(ObjCCategoryDecl *) { return true; } public: /// \brief Iterator that walks over all of the known categories and /// extensions, including those that are hidden. typedef filtered_category_iterator known_categories_iterator; typedef llvm::iterator_range known_categories_range; known_categories_range known_categories() const { return known_categories_range(known_categories_begin(), known_categories_end()); } /// \brief Retrieve an iterator to the beginning of the known-categories /// list. known_categories_iterator known_categories_begin() const { return known_categories_iterator(getCategoryListRaw()); } /// \brief Retrieve an iterator to the end of the known-categories list. known_categories_iterator known_categories_end() const { return known_categories_iterator(); } /// \brief Determine whether the known-categories list is empty. bool known_categories_empty() const { return known_categories_begin() == known_categories_end(); } private: /// \brief Test whether the given category is a visible extension. /// /// Used in the \c visible_extensions_iterator. static bool isVisibleExtension(ObjCCategoryDecl *Cat); public: /// \brief Iterator that walks over all of the visible extensions, skipping /// any that are known but hidden. typedef filtered_category_iterator visible_extensions_iterator; typedef llvm::iterator_range visible_extensions_range; visible_extensions_range visible_extensions() const { return visible_extensions_range(visible_extensions_begin(), visible_extensions_end()); } /// \brief Retrieve an iterator to the beginning of the visible-extensions /// list. visible_extensions_iterator visible_extensions_begin() const { return visible_extensions_iterator(getCategoryListRaw()); } /// \brief Retrieve an iterator to the end of the visible-extensions list. visible_extensions_iterator visible_extensions_end() const { return visible_extensions_iterator(); } /// \brief Determine whether the visible-extensions list is empty. bool visible_extensions_empty() const { return visible_extensions_begin() == visible_extensions_end(); } private: /// \brief Test whether the given category is an extension. /// /// Used in the \c known_extensions_iterator. static bool isKnownExtension(ObjCCategoryDecl *Cat); public: /// \brief Iterator that walks over all of the known extensions. typedef filtered_category_iterator known_extensions_iterator; typedef llvm::iterator_range known_extensions_range; known_extensions_range known_extensions() const { return known_extensions_range(known_extensions_begin(), known_extensions_end()); } /// \brief Retrieve an iterator to the beginning of the known-extensions /// list. known_extensions_iterator known_extensions_begin() const { return known_extensions_iterator(getCategoryListRaw()); } /// \brief Retrieve an iterator to the end of the known-extensions list. known_extensions_iterator known_extensions_end() const { return known_extensions_iterator(); } /// \brief Determine whether the known-extensions list is empty. bool known_extensions_empty() const { return known_extensions_begin() == known_extensions_end(); } /// \brief Retrieve the raw pointer to the start of the category/extension /// list. ObjCCategoryDecl* getCategoryListRaw() const { // FIXME: Should make sure no callers ever do this. if (!hasDefinition()) return nullptr; if (data().ExternallyCompleted) LoadExternalDefinition(); return data().CategoryList; } /// \brief Set the raw pointer to the start of the category/extension /// list. void setCategoryListRaw(ObjCCategoryDecl *category) { data().CategoryList = category; } ObjCPropertyDecl *FindPropertyVisibleInPrimaryClass(IdentifierInfo *PropertyId, ObjCPropertyQueryKind QueryKind) const; void collectPropertiesToImplement(PropertyMap &PM, PropertyDeclOrder &PO) const override; /// isSuperClassOf - Return true if this class is the specified class or is a /// super class of the specified interface class. bool isSuperClassOf(const ObjCInterfaceDecl *I) const { // If RHS is derived from LHS it is OK; else it is not OK. while (I != nullptr) { if (declaresSameEntity(this, I)) return true; I = I->getSuperClass(); } return false; } /// isArcWeakrefUnavailable - Checks for a class or one of its super classes /// to be incompatible with __weak references. Returns true if it is. bool isArcWeakrefUnavailable() const; /// isObjCRequiresPropertyDefs - Checks that a class or one of its super /// classes must not be auto-synthesized. Returns class decl. if it must not /// be; 0, otherwise. const ObjCInterfaceDecl *isObjCRequiresPropertyDefs() const; ObjCIvarDecl *lookupInstanceVariable(IdentifierInfo *IVarName, ObjCInterfaceDecl *&ClassDeclared); ObjCIvarDecl *lookupInstanceVariable(IdentifierInfo *IVarName) { ObjCInterfaceDecl *ClassDeclared; return lookupInstanceVariable(IVarName, ClassDeclared); } ObjCProtocolDecl *lookupNestedProtocol(IdentifierInfo *Name); // Lookup a method. First, we search locally. If a method isn't // found, we search referenced protocols and class categories. ObjCMethodDecl *lookupMethod(Selector Sel, bool isInstance, bool shallowCategoryLookup = false, bool followSuper = true, const ObjCCategoryDecl *C = nullptr) const; /// Lookup an instance method for a given selector. ObjCMethodDecl *lookupInstanceMethod(Selector Sel) const { return lookupMethod(Sel, true/*isInstance*/); } /// Lookup a class method for a given selector. ObjCMethodDecl *lookupClassMethod(Selector Sel) const { return lookupMethod(Sel, false/*isInstance*/); } ObjCInterfaceDecl *lookupInheritedClass(const IdentifierInfo *ICName); /// \brief Lookup a method in the classes implementation hierarchy. ObjCMethodDecl *lookupPrivateMethod(const Selector &Sel, bool Instance=true) const; ObjCMethodDecl *lookupPrivateClassMethod(const Selector &Sel) { return lookupPrivateMethod(Sel, false); } /// \brief Lookup a setter or getter in the class hierarchy, /// including in all categories except for category passed /// as argument. ObjCMethodDecl *lookupPropertyAccessor(const Selector Sel, const ObjCCategoryDecl *Cat, bool IsClassProperty) const { return lookupMethod(Sel, !IsClassProperty/*isInstance*/, false/*shallowCategoryLookup*/, true /* followsSuper */, Cat); } SourceLocation getEndOfDefinitionLoc() const { if (!hasDefinition()) return getLocation(); return data().EndLoc; } void setEndOfDefinitionLoc(SourceLocation LE) { data().EndLoc = LE; } /// Retrieve the starting location of the superclass. SourceLocation getSuperClassLoc() const; /// isImplicitInterfaceDecl - check that this is an implicitly declared /// ObjCInterfaceDecl node. This is for legacy objective-c \@implementation /// declaration without an \@interface declaration. bool isImplicitInterfaceDecl() const { return hasDefinition() ? data().Definition->isImplicit() : isImplicit(); } /// ClassImplementsProtocol - Checks that 'lProto' protocol /// has been implemented in IDecl class, its super class or categories (if /// lookupCategory is true). bool ClassImplementsProtocol(ObjCProtocolDecl *lProto, bool lookupCategory, bool RHSIsQualifiedID = false); typedef redeclarable_base::redecl_range redecl_range; typedef redeclarable_base::redecl_iterator redecl_iterator; using redeclarable_base::redecls_begin; using redeclarable_base::redecls_end; using redeclarable_base::redecls; using redeclarable_base::getPreviousDecl; using redeclarable_base::getMostRecentDecl; using redeclarable_base::isFirstDecl; /// Retrieves the canonical declaration of this Objective-C class. ObjCInterfaceDecl *getCanonicalDecl() override { return getFirstDecl(); } const ObjCInterfaceDecl *getCanonicalDecl() const { return getFirstDecl(); } // Low-level accessor const Type *getTypeForDecl() const { return TypeForDecl; } void setTypeForDecl(const Type *TD) const { TypeForDecl = TD; } static bool classof(const Decl *D) { return classofKind(D->getKind()); } static bool classofKind(Kind K) { return K == ObjCInterface; } friend class ASTReader; friend class ASTDeclReader; friend class ASTDeclWriter; private: const ObjCInterfaceDecl *findInterfaceWithDesignatedInitializers() const; bool inheritsDesignatedInitializers() const; }; /// ObjCIvarDecl - Represents an ObjC instance variable. In general, ObjC /// instance variables are identical to C. The only exception is Objective-C /// supports C++ style access control. For example: /// /// \@interface IvarExample : NSObject /// { /// id defaultToProtected; /// \@public: /// id canBePublic; // same as C++. /// \@protected: /// id canBeProtected; // same as C++. /// \@package: /// id canBePackage; // framework visibility (not available in C++). /// } /// class ObjCIvarDecl : public FieldDecl { void anchor() override; public: enum AccessControl { None, Private, Protected, Public, Package }; private: ObjCIvarDecl(ObjCContainerDecl *DC, SourceLocation StartLoc, SourceLocation IdLoc, IdentifierInfo *Id, QualType T, TypeSourceInfo *TInfo, AccessControl ac, Expr *BW, bool synthesized) : FieldDecl(ObjCIvar, DC, StartLoc, IdLoc, Id, T, TInfo, BW, /*Mutable=*/false, /*HasInit=*/ICIS_NoInit), NextIvar(nullptr), DeclAccess(ac), Synthesized(synthesized) {} public: static ObjCIvarDecl *Create(ASTContext &C, ObjCContainerDecl *DC, SourceLocation StartLoc, SourceLocation IdLoc, IdentifierInfo *Id, QualType T, TypeSourceInfo *TInfo, AccessControl ac, Expr *BW = nullptr, bool synthesized=false); static ObjCIvarDecl *CreateDeserialized(ASTContext &C, unsigned ID); /// \brief Return the class interface that this ivar is logically contained /// in; this is either the interface where the ivar was declared, or the /// interface the ivar is conceptually a part of in the case of synthesized /// ivars. const ObjCInterfaceDecl *getContainingInterface() const; ObjCIvarDecl *getNextIvar() { return NextIvar; } const ObjCIvarDecl *getNextIvar() const { return NextIvar; } void setNextIvar(ObjCIvarDecl *ivar) { NextIvar = ivar; } void setAccessControl(AccessControl ac) { DeclAccess = ac; } AccessControl getAccessControl() const { return AccessControl(DeclAccess); } AccessControl getCanonicalAccessControl() const { return DeclAccess == None ? Protected : AccessControl(DeclAccess); } void setSynthesize(bool synth) { Synthesized = synth; } bool getSynthesize() const { return Synthesized; } /// Retrieve the type of this instance variable when viewed as a member of a /// specific object type. QualType getUsageType(QualType objectType) const; // Implement isa/cast/dyncast/etc. static bool classof(const Decl *D) { return classofKind(D->getKind()); } static bool classofKind(Kind K) { return K == ObjCIvar; } private: /// NextIvar - Next Ivar in the list of ivars declared in class; class's /// extensions and class's implementation ObjCIvarDecl *NextIvar; // NOTE: VC++ treats enums as signed, avoid using the AccessControl enum unsigned DeclAccess : 3; unsigned Synthesized : 1; }; /// \brief Represents a field declaration created by an \@defs(...). class ObjCAtDefsFieldDecl : public FieldDecl { void anchor() override; ObjCAtDefsFieldDecl(DeclContext *DC, SourceLocation StartLoc, SourceLocation IdLoc, IdentifierInfo *Id, QualType T, Expr *BW) : FieldDecl(ObjCAtDefsField, DC, StartLoc, IdLoc, Id, T, /*TInfo=*/nullptr, // FIXME: Do ObjCAtDefs have declarators ? BW, /*Mutable=*/false, /*HasInit=*/ICIS_NoInit) {} public: static ObjCAtDefsFieldDecl *Create(ASTContext &C, DeclContext *DC, SourceLocation StartLoc, SourceLocation IdLoc, IdentifierInfo *Id, QualType T, Expr *BW); static ObjCAtDefsFieldDecl *CreateDeserialized(ASTContext &C, unsigned ID); // Implement isa/cast/dyncast/etc. static bool classof(const Decl *D) { return classofKind(D->getKind()); } static bool classofKind(Kind K) { return K == ObjCAtDefsField; } }; /// \brief Represents an Objective-C protocol declaration. /// /// Objective-C protocols declare a pure abstract type (i.e., no instance /// variables are permitted). Protocols originally drew inspiration from /// C++ pure virtual functions (a C++ feature with nice semantics and lousy /// syntax:-). Here is an example: /// /// \code /// \@protocol NSDraggingInfo /// - (NSWindow *)draggingDestinationWindow; /// - (NSImage *)draggedImage; /// \@end /// \endcode /// /// This says that NSDraggingInfo requires two methods and requires everything /// that the two "referenced protocols" 'refproto1' and 'refproto2' require as /// well. /// /// \code /// \@interface ImplementsNSDraggingInfo : NSObject \ /// \@end /// \endcode /// /// ObjC protocols inspired Java interfaces. Unlike Java, ObjC classes and /// protocols are in distinct namespaces. For example, Cocoa defines both /// an NSObject protocol and class (which isn't allowed in Java). As a result, /// protocols are referenced using angle brackets as follows: /// /// id \ anyObjectThatImplementsNSDraggingInfo; /// class ObjCProtocolDecl : public ObjCContainerDecl, public Redeclarable { void anchor() override; struct DefinitionData { // \brief The declaration that defines this protocol. ObjCProtocolDecl *Definition; /// \brief Referenced protocols ObjCProtocolList ReferencedProtocols; }; /// \brief Contains a pointer to the data associated with this class, /// which will be NULL if this class has not yet been defined. /// /// The bit indicates when we don't need to check for out-of-date /// declarations. It will be set unless modules are enabled. llvm::PointerIntPair Data; DefinitionData &data() const { assert(Data.getPointer() && "Objective-C protocol has no definition!"); return *Data.getPointer(); } ObjCProtocolDecl(ASTContext &C, DeclContext *DC, IdentifierInfo *Id, SourceLocation nameLoc, SourceLocation atStartLoc, ObjCProtocolDecl *PrevDecl); void allocateDefinitionData(); typedef Redeclarable redeclarable_base; ObjCProtocolDecl *getNextRedeclarationImpl() override { return getNextRedeclaration(); } ObjCProtocolDecl *getPreviousDeclImpl() override { return getPreviousDecl(); } ObjCProtocolDecl *getMostRecentDeclImpl() override { return getMostRecentDecl(); } public: static ObjCProtocolDecl *Create(ASTContext &C, DeclContext *DC, IdentifierInfo *Id, SourceLocation nameLoc, SourceLocation atStartLoc, ObjCProtocolDecl *PrevDecl); static ObjCProtocolDecl *CreateDeserialized(ASTContext &C, unsigned ID); const ObjCProtocolList &getReferencedProtocols() const { assert(hasDefinition() && "No definition available!"); return data().ReferencedProtocols; } typedef ObjCProtocolList::iterator protocol_iterator; typedef llvm::iterator_range protocol_range; protocol_range protocols() const { return protocol_range(protocol_begin(), protocol_end()); } protocol_iterator protocol_begin() const { if (!hasDefinition()) return protocol_iterator(); return data().ReferencedProtocols.begin(); } protocol_iterator protocol_end() const { if (!hasDefinition()) return protocol_iterator(); return data().ReferencedProtocols.end(); } typedef ObjCProtocolList::loc_iterator protocol_loc_iterator; typedef llvm::iterator_range protocol_loc_range; protocol_loc_range protocol_locs() const { return protocol_loc_range(protocol_loc_begin(), protocol_loc_end()); } protocol_loc_iterator protocol_loc_begin() const { if (!hasDefinition()) return protocol_loc_iterator(); return data().ReferencedProtocols.loc_begin(); } protocol_loc_iterator protocol_loc_end() const { if (!hasDefinition()) return protocol_loc_iterator(); return data().ReferencedProtocols.loc_end(); } unsigned protocol_size() const { if (!hasDefinition()) return 0; return data().ReferencedProtocols.size(); } /// setProtocolList - Set the list of protocols that this interface /// implements. void setProtocolList(ObjCProtocolDecl *const*List, unsigned Num, const SourceLocation *Locs, ASTContext &C) { assert(hasDefinition() && "Protocol is not defined"); data().ReferencedProtocols.set(List, Num, Locs, C); } ObjCProtocolDecl *lookupProtocolNamed(IdentifierInfo *PName); // Lookup a method. First, we search locally. If a method isn't // found, we search referenced protocols and class categories. ObjCMethodDecl *lookupMethod(Selector Sel, bool isInstance) const; ObjCMethodDecl *lookupInstanceMethod(Selector Sel) const { return lookupMethod(Sel, true/*isInstance*/); } ObjCMethodDecl *lookupClassMethod(Selector Sel) const { return lookupMethod(Sel, false/*isInstance*/); } /// \brief Determine whether this protocol has a definition. bool hasDefinition() const { // If the name of this protocol is out-of-date, bring it up-to-date, which // might bring in a definition. // Note: a null value indicates that we don't have a definition and that // modules are enabled. if (!Data.getOpaqueValue()) getMostRecentDecl(); return Data.getPointer(); } /// \brief Retrieve the definition of this protocol, if any. ObjCProtocolDecl *getDefinition() { return hasDefinition()? Data.getPointer()->Definition : nullptr; } /// \brief Retrieve the definition of this protocol, if any. const ObjCProtocolDecl *getDefinition() const { return hasDefinition()? Data.getPointer()->Definition : nullptr; } /// \brief Determine whether this particular declaration is also the /// definition. bool isThisDeclarationADefinition() const { return getDefinition() == this; } /// \brief Starts the definition of this Objective-C protocol. void startDefinition(); /// Produce a name to be used for protocol's metadata. It comes either via /// objc_runtime_name attribute or protocol name. StringRef getObjCRuntimeNameAsString() const; SourceRange getSourceRange() const override LLVM_READONLY { if (isThisDeclarationADefinition()) return ObjCContainerDecl::getSourceRange(); return SourceRange(getAtStartLoc(), getLocation()); } typedef redeclarable_base::redecl_range redecl_range; typedef redeclarable_base::redecl_iterator redecl_iterator; using redeclarable_base::redecls_begin; using redeclarable_base::redecls_end; using redeclarable_base::redecls; using redeclarable_base::getPreviousDecl; using redeclarable_base::getMostRecentDecl; using redeclarable_base::isFirstDecl; /// Retrieves the canonical declaration of this Objective-C protocol. ObjCProtocolDecl *getCanonicalDecl() override { return getFirstDecl(); } const ObjCProtocolDecl *getCanonicalDecl() const { return getFirstDecl(); } void collectPropertiesToImplement(PropertyMap &PM, PropertyDeclOrder &PO) const override; void collectInheritedProtocolProperties(const ObjCPropertyDecl *Property, ProtocolPropertyMap &PM) const; static bool classof(const Decl *D) { return classofKind(D->getKind()); } static bool classofKind(Kind K) { return K == ObjCProtocol; } friend class ASTReader; friend class ASTDeclReader; friend class ASTDeclWriter; }; /// ObjCCategoryDecl - Represents a category declaration. A category allows /// you to add methods to an existing class (without subclassing or modifying /// the original class interface or implementation:-). Categories don't allow /// you to add instance data. The following example adds "myMethod" to all /// NSView's within a process: /// /// \@interface NSView (MyViewMethods) /// - myMethod; /// \@end /// /// Categories also allow you to split the implementation of a class across /// several files (a feature more naturally supported in C++). /// /// Categories were originally inspired by dynamic languages such as Common /// Lisp and Smalltalk. More traditional class-based languages (C++, Java) /// don't support this level of dynamism, which is both powerful and dangerous. /// class ObjCCategoryDecl : public ObjCContainerDecl { void anchor() override; /// Interface belonging to this category ObjCInterfaceDecl *ClassInterface; /// The type parameters associated with this category, if any. ObjCTypeParamList *TypeParamList; /// referenced protocols in this category. ObjCProtocolList ReferencedProtocols; /// Next category belonging to this class. /// FIXME: this should not be a singly-linked list. Move storage elsewhere. ObjCCategoryDecl *NextClassCategory; /// \brief The location of the category name in this declaration. SourceLocation CategoryNameLoc; /// class extension may have private ivars. SourceLocation IvarLBraceLoc; SourceLocation IvarRBraceLoc; ObjCCategoryDecl(DeclContext *DC, SourceLocation AtLoc, SourceLocation ClassNameLoc, SourceLocation CategoryNameLoc, IdentifierInfo *Id, ObjCInterfaceDecl *IDecl, ObjCTypeParamList *typeParamList, SourceLocation IvarLBraceLoc=SourceLocation(), SourceLocation IvarRBraceLoc=SourceLocation()); public: static ObjCCategoryDecl *Create(ASTContext &C, DeclContext *DC, SourceLocation AtLoc, SourceLocation ClassNameLoc, SourceLocation CategoryNameLoc, IdentifierInfo *Id, ObjCInterfaceDecl *IDecl, ObjCTypeParamList *typeParamList, SourceLocation IvarLBraceLoc=SourceLocation(), SourceLocation IvarRBraceLoc=SourceLocation()); static ObjCCategoryDecl *CreateDeserialized(ASTContext &C, unsigned ID); ObjCInterfaceDecl *getClassInterface() { return ClassInterface; } const ObjCInterfaceDecl *getClassInterface() const { return ClassInterface; } /// Retrieve the type parameter list associated with this category or /// extension. ObjCTypeParamList *getTypeParamList() const { return TypeParamList; } /// Set the type parameters of this category. /// /// This function is used by the AST importer, which must import the type /// parameters after creating their DeclContext to avoid loops. void setTypeParamList(ObjCTypeParamList *TPL); ObjCCategoryImplDecl *getImplementation() const; void setImplementation(ObjCCategoryImplDecl *ImplD); /// setProtocolList - Set the list of protocols that this interface /// implements. void setProtocolList(ObjCProtocolDecl *const*List, unsigned Num, const SourceLocation *Locs, ASTContext &C) { ReferencedProtocols.set(List, Num, Locs, C); } const ObjCProtocolList &getReferencedProtocols() const { return ReferencedProtocols; } typedef ObjCProtocolList::iterator protocol_iterator; typedef llvm::iterator_range protocol_range; protocol_range protocols() const { return protocol_range(protocol_begin(), protocol_end()); } protocol_iterator protocol_begin() const { return ReferencedProtocols.begin(); } protocol_iterator protocol_end() const { return ReferencedProtocols.end(); } unsigned protocol_size() const { return ReferencedProtocols.size(); } typedef ObjCProtocolList::loc_iterator protocol_loc_iterator; typedef llvm::iterator_range protocol_loc_range; protocol_loc_range protocol_locs() const { return protocol_loc_range(protocol_loc_begin(), protocol_loc_end()); } protocol_loc_iterator protocol_loc_begin() const { return ReferencedProtocols.loc_begin(); } protocol_loc_iterator protocol_loc_end() const { return ReferencedProtocols.loc_end(); } ObjCCategoryDecl *getNextClassCategory() const { return NextClassCategory; } /// \brief Retrieve the pointer to the next stored category (or extension), /// which may be hidden. ObjCCategoryDecl *getNextClassCategoryRaw() const { return NextClassCategory; } bool IsClassExtension() const { return getIdentifier() == nullptr; } typedef specific_decl_iterator ivar_iterator; typedef llvm::iterator_range> ivar_range; ivar_range ivars() const { return ivar_range(ivar_begin(), ivar_end()); } ivar_iterator ivar_begin() const { return ivar_iterator(decls_begin()); } ivar_iterator ivar_end() const { return ivar_iterator(decls_end()); } unsigned ivar_size() const { return std::distance(ivar_begin(), ivar_end()); } bool ivar_empty() const { return ivar_begin() == ivar_end(); } SourceLocation getCategoryNameLoc() const { return CategoryNameLoc; } void setCategoryNameLoc(SourceLocation Loc) { CategoryNameLoc = Loc; } void setIvarLBraceLoc(SourceLocation Loc) { IvarLBraceLoc = Loc; } SourceLocation getIvarLBraceLoc() const { return IvarLBraceLoc; } void setIvarRBraceLoc(SourceLocation Loc) { IvarRBraceLoc = Loc; } SourceLocation getIvarRBraceLoc() const { return IvarRBraceLoc; } static bool classof(const Decl *D) { return classofKind(D->getKind()); } static bool classofKind(Kind K) { return K == ObjCCategory; } friend class ASTDeclReader; friend class ASTDeclWriter; }; class ObjCImplDecl : public ObjCContainerDecl { void anchor() override; /// Class interface for this class/category implementation ObjCInterfaceDecl *ClassInterface; protected: ObjCImplDecl(Kind DK, DeclContext *DC, ObjCInterfaceDecl *classInterface, IdentifierInfo *Id, SourceLocation nameLoc, SourceLocation atStartLoc) : ObjCContainerDecl(DK, DC, Id, nameLoc, atStartLoc), ClassInterface(classInterface) {} public: const ObjCInterfaceDecl *getClassInterface() const { return ClassInterface; } ObjCInterfaceDecl *getClassInterface() { return ClassInterface; } void setClassInterface(ObjCInterfaceDecl *IFace); void addInstanceMethod(ObjCMethodDecl *method) { // FIXME: Context should be set correctly before we get here. method->setLexicalDeclContext(this); addDecl(method); } void addClassMethod(ObjCMethodDecl *method) { // FIXME: Context should be set correctly before we get here. method->setLexicalDeclContext(this); addDecl(method); } void addPropertyImplementation(ObjCPropertyImplDecl *property); ObjCPropertyImplDecl *FindPropertyImplDecl(IdentifierInfo *propertyId, ObjCPropertyQueryKind queryKind) const; ObjCPropertyImplDecl *FindPropertyImplIvarDecl(IdentifierInfo *ivarId) const; // Iterator access to properties. typedef specific_decl_iterator propimpl_iterator; typedef llvm::iterator_range> propimpl_range; propimpl_range property_impls() const { return propimpl_range(propimpl_begin(), propimpl_end()); } propimpl_iterator propimpl_begin() const { return propimpl_iterator(decls_begin()); } propimpl_iterator propimpl_end() const { return propimpl_iterator(decls_end()); } static bool classof(const Decl *D) { return classofKind(D->getKind()); } static bool classofKind(Kind K) { return K >= firstObjCImpl && K <= lastObjCImpl; } }; /// ObjCCategoryImplDecl - An object of this class encapsulates a category /// \@implementation declaration. If a category class has declaration of a /// property, its implementation must be specified in the category's /// \@implementation declaration. Example: /// \@interface I \@end /// \@interface I(CATEGORY) /// \@property int p1, d1; /// \@end /// \@implementation I(CATEGORY) /// \@dynamic p1,d1; /// \@end /// /// ObjCCategoryImplDecl class ObjCCategoryImplDecl : public ObjCImplDecl { void anchor() override; // Category name location SourceLocation CategoryNameLoc; ObjCCategoryImplDecl(DeclContext *DC, IdentifierInfo *Id, ObjCInterfaceDecl *classInterface, SourceLocation nameLoc, SourceLocation atStartLoc, SourceLocation CategoryNameLoc) : ObjCImplDecl(ObjCCategoryImpl, DC, classInterface, Id, nameLoc, atStartLoc), CategoryNameLoc(CategoryNameLoc) {} public: static ObjCCategoryImplDecl *Create(ASTContext &C, DeclContext *DC, IdentifierInfo *Id, ObjCInterfaceDecl *classInterface, SourceLocation nameLoc, SourceLocation atStartLoc, SourceLocation CategoryNameLoc); static ObjCCategoryImplDecl *CreateDeserialized(ASTContext &C, unsigned ID); ObjCCategoryDecl *getCategoryDecl() const; SourceLocation getCategoryNameLoc() const { return CategoryNameLoc; } static bool classof(const Decl *D) { return classofKind(D->getKind()); } static bool classofKind(Kind K) { return K == ObjCCategoryImpl;} friend class ASTDeclReader; friend class ASTDeclWriter; }; raw_ostream &operator<<(raw_ostream &OS, const ObjCCategoryImplDecl &CID); /// ObjCImplementationDecl - Represents a class definition - this is where /// method definitions are specified. For example: /// /// @code /// \@implementation MyClass /// - (void)myMethod { /* do something */ } /// \@end /// @endcode /// /// In a non-fragile runtime, instance variables can appear in the class /// interface, class extensions (nameless categories), and in the implementation /// itself, as well as being synthesized as backing storage for properties. /// /// In a fragile runtime, instance variables are specified in the class /// interface, \em not in the implementation. Nevertheless (for legacy reasons), /// we allow instance variables to be specified in the implementation. When /// specified, they need to be \em identical to the interface. class ObjCImplementationDecl : public ObjCImplDecl { void anchor() override; /// Implementation Class's super class. ObjCInterfaceDecl *SuperClass; SourceLocation SuperLoc; /// \@implementation may have private ivars. SourceLocation IvarLBraceLoc; SourceLocation IvarRBraceLoc; /// Support for ivar initialization. /// \brief The arguments used to initialize the ivars LazyCXXCtorInitializersPtr IvarInitializers; unsigned NumIvarInitializers; /// Do the ivars of this class require initialization other than /// zero-initialization? bool HasNonZeroConstructors : 1; /// Do the ivars of this class require non-trivial destruction? bool HasDestructors : 1; ObjCImplementationDecl(DeclContext *DC, ObjCInterfaceDecl *classInterface, ObjCInterfaceDecl *superDecl, SourceLocation nameLoc, SourceLocation atStartLoc, SourceLocation superLoc = SourceLocation(), SourceLocation IvarLBraceLoc=SourceLocation(), SourceLocation IvarRBraceLoc=SourceLocation()) : ObjCImplDecl(ObjCImplementation, DC, classInterface, classInterface ? classInterface->getIdentifier() : nullptr, nameLoc, atStartLoc), SuperClass(superDecl), SuperLoc(superLoc), IvarLBraceLoc(IvarLBraceLoc), IvarRBraceLoc(IvarRBraceLoc), IvarInitializers(nullptr), NumIvarInitializers(0), HasNonZeroConstructors(false), HasDestructors(false) {} public: static ObjCImplementationDecl *Create(ASTContext &C, DeclContext *DC, ObjCInterfaceDecl *classInterface, ObjCInterfaceDecl *superDecl, SourceLocation nameLoc, SourceLocation atStartLoc, SourceLocation superLoc = SourceLocation(), SourceLocation IvarLBraceLoc=SourceLocation(), SourceLocation IvarRBraceLoc=SourceLocation()); static ObjCImplementationDecl *CreateDeserialized(ASTContext &C, unsigned ID); /// init_iterator - Iterates through the ivar initializer list. typedef CXXCtorInitializer **init_iterator; /// init_const_iterator - Iterates through the ivar initializer list. typedef CXXCtorInitializer * const * init_const_iterator; typedef llvm::iterator_range init_range; typedef llvm::iterator_range init_const_range; init_range inits() { return init_range(init_begin(), init_end()); } init_const_range inits() const { return init_const_range(init_begin(), init_end()); } /// init_begin() - Retrieve an iterator to the first initializer. init_iterator init_begin() { const auto *ConstThis = this; return const_cast(ConstThis->init_begin()); } /// begin() - Retrieve an iterator to the first initializer. init_const_iterator init_begin() const; /// init_end() - Retrieve an iterator past the last initializer. init_iterator init_end() { return init_begin() + NumIvarInitializers; } /// end() - Retrieve an iterator past the last initializer. init_const_iterator init_end() const { return init_begin() + NumIvarInitializers; } /// getNumArgs - Number of ivars which must be initialized. unsigned getNumIvarInitializers() const { return NumIvarInitializers; } void setNumIvarInitializers(unsigned numNumIvarInitializers) { NumIvarInitializers = numNumIvarInitializers; } void setIvarInitializers(ASTContext &C, CXXCtorInitializer ** initializers, unsigned numInitializers); /// Do any of the ivars of this class (not counting its base classes) /// require construction other than zero-initialization? bool hasNonZeroConstructors() const { return HasNonZeroConstructors; } void setHasNonZeroConstructors(bool val) { HasNonZeroConstructors = val; } /// Do any of the ivars of this class (not counting its base classes) /// require non-trivial destruction? bool hasDestructors() const { return HasDestructors; } void setHasDestructors(bool val) { HasDestructors = val; } /// getIdentifier - Get the identifier that names the class /// interface associated with this implementation. IdentifierInfo *getIdentifier() const { return getClassInterface()->getIdentifier(); } /// getName - Get the name of identifier for the class interface associated /// with this implementation as a StringRef. // // FIXME: This is a bad API, we are hiding NamedDecl::getName with a different // meaning. StringRef getName() const { assert(getIdentifier() && "Name is not a simple identifier"); return getIdentifier()->getName(); } /// @brief Get the name of the class associated with this interface. // // FIXME: Move to StringRef API. std::string getNameAsString() const { return getName(); } /// Produce a name to be used for class's metadata. It comes either via /// class's objc_runtime_name attribute or class name. StringRef getObjCRuntimeNameAsString() const; const ObjCInterfaceDecl *getSuperClass() const { return SuperClass; } ObjCInterfaceDecl *getSuperClass() { return SuperClass; } SourceLocation getSuperClassLoc() const { return SuperLoc; } void setSuperClass(ObjCInterfaceDecl * superCls) { SuperClass = superCls; } void setIvarLBraceLoc(SourceLocation Loc) { IvarLBraceLoc = Loc; } SourceLocation getIvarLBraceLoc() const { return IvarLBraceLoc; } void setIvarRBraceLoc(SourceLocation Loc) { IvarRBraceLoc = Loc; } SourceLocation getIvarRBraceLoc() const { return IvarRBraceLoc; } typedef specific_decl_iterator ivar_iterator; typedef llvm::iterator_range> ivar_range; ivar_range ivars() const { return ivar_range(ivar_begin(), ivar_end()); } ivar_iterator ivar_begin() const { return ivar_iterator(decls_begin()); } ivar_iterator ivar_end() const { return ivar_iterator(decls_end()); } unsigned ivar_size() const { return std::distance(ivar_begin(), ivar_end()); } bool ivar_empty() const { return ivar_begin() == ivar_end(); } static bool classof(const Decl *D) { return classofKind(D->getKind()); } static bool classofKind(Kind K) { return K == ObjCImplementation; } friend class ASTDeclReader; friend class ASTDeclWriter; }; raw_ostream &operator<<(raw_ostream &OS, const ObjCImplementationDecl &ID); /// ObjCCompatibleAliasDecl - Represents alias of a class. This alias is /// declared as \@compatibility_alias alias class. class ObjCCompatibleAliasDecl : public NamedDecl { void anchor() override; /// Class that this is an alias of. ObjCInterfaceDecl *AliasedClass; ObjCCompatibleAliasDecl(DeclContext *DC, SourceLocation L, IdentifierInfo *Id, ObjCInterfaceDecl* aliasedClass) : NamedDecl(ObjCCompatibleAlias, DC, L, Id), AliasedClass(aliasedClass) {} public: static ObjCCompatibleAliasDecl *Create(ASTContext &C, DeclContext *DC, SourceLocation L, IdentifierInfo *Id, ObjCInterfaceDecl* aliasedClass); static ObjCCompatibleAliasDecl *CreateDeserialized(ASTContext &C, unsigned ID); const ObjCInterfaceDecl *getClassInterface() const { return AliasedClass; } ObjCInterfaceDecl *getClassInterface() { return AliasedClass; } void setClassInterface(ObjCInterfaceDecl *D) { AliasedClass = D; } static bool classof(const Decl *D) { return classofKind(D->getKind()); } static bool classofKind(Kind K) { return K == ObjCCompatibleAlias; } }; /// ObjCPropertyImplDecl - Represents implementation declaration of a property /// in a class or category implementation block. For example: /// \@synthesize prop1 = ivar1; /// class ObjCPropertyImplDecl : public Decl { public: enum Kind { Synthesize, Dynamic }; private: SourceLocation AtLoc; // location of \@synthesize or \@dynamic /// \brief For \@synthesize, the location of the ivar, if it was written in /// the source code. /// /// \code /// \@synthesize int a = b /// \endcode SourceLocation IvarLoc; /// Property declaration being implemented ObjCPropertyDecl *PropertyDecl; /// Null for \@dynamic. Required for \@synthesize. ObjCIvarDecl *PropertyIvarDecl; /// Null for \@dynamic. Non-null if property must be copy-constructed in /// getter. Expr *GetterCXXConstructor; /// Null for \@dynamic. Non-null if property has assignment operator to call /// in Setter synthesis. Expr *SetterCXXAssignment; ObjCPropertyImplDecl(DeclContext *DC, SourceLocation atLoc, SourceLocation L, ObjCPropertyDecl *property, Kind PK, ObjCIvarDecl *ivarDecl, SourceLocation ivarLoc) : Decl(ObjCPropertyImpl, DC, L), AtLoc(atLoc), IvarLoc(ivarLoc), PropertyDecl(property), PropertyIvarDecl(ivarDecl), GetterCXXConstructor(nullptr), SetterCXXAssignment(nullptr) { assert (PK == Dynamic || PropertyIvarDecl); } public: static ObjCPropertyImplDecl *Create(ASTContext &C, DeclContext *DC, SourceLocation atLoc, SourceLocation L, ObjCPropertyDecl *property, Kind PK, ObjCIvarDecl *ivarDecl, SourceLocation ivarLoc); static ObjCPropertyImplDecl *CreateDeserialized(ASTContext &C, unsigned ID); SourceRange getSourceRange() const override LLVM_READONLY; SourceLocation getLocStart() const LLVM_READONLY { return AtLoc; } void setAtLoc(SourceLocation Loc) { AtLoc = Loc; } ObjCPropertyDecl *getPropertyDecl() const { return PropertyDecl; } void setPropertyDecl(ObjCPropertyDecl *Prop) { PropertyDecl = Prop; } Kind getPropertyImplementation() const { return PropertyIvarDecl ? Synthesize : Dynamic; } ObjCIvarDecl *getPropertyIvarDecl() const { return PropertyIvarDecl; } SourceLocation getPropertyIvarDeclLoc() const { return IvarLoc; } void setPropertyIvarDecl(ObjCIvarDecl *Ivar, SourceLocation IvarLoc) { PropertyIvarDecl = Ivar; this->IvarLoc = IvarLoc; } /// \brief For \@synthesize, returns true if an ivar name was explicitly /// specified. /// /// \code /// \@synthesize int a = b; // true /// \@synthesize int a; // false /// \endcode bool isIvarNameSpecified() const { return IvarLoc.isValid() && IvarLoc != getLocation(); } Expr *getGetterCXXConstructor() const { return GetterCXXConstructor; } void setGetterCXXConstructor(Expr *getterCXXConstructor) { GetterCXXConstructor = getterCXXConstructor; } Expr *getSetterCXXAssignment() const { return SetterCXXAssignment; } void setSetterCXXAssignment(Expr *setterCXXAssignment) { SetterCXXAssignment = setterCXXAssignment; } static bool classof(const Decl *D) { return classofKind(D->getKind()); } static bool classofKind(Decl::Kind K) { return K == ObjCPropertyImpl; } friend class ASTDeclReader; }; template void ObjCInterfaceDecl::filtered_category_iterator:: findAcceptableCategory() { while (Current && !Filter(Current)) Current = Current->getNextClassCategoryRaw(); } template inline ObjCInterfaceDecl::filtered_category_iterator & ObjCInterfaceDecl::filtered_category_iterator::operator++() { Current = Current->getNextClassCategoryRaw(); findAcceptableCategory(); return *this; } inline bool ObjCInterfaceDecl::isVisibleCategory(ObjCCategoryDecl *Cat) { return !Cat->isHidden(); } inline bool ObjCInterfaceDecl::isVisibleExtension(ObjCCategoryDecl *Cat) { return Cat->IsClassExtension() && !Cat->isHidden(); } inline bool ObjCInterfaceDecl::isKnownExtension(ObjCCategoryDecl *Cat) { return Cat->IsClassExtension(); } } // end namespace clang #endif