//===--- Decl.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 Decl subclasses. // //===----------------------------------------------------------------------===// #ifndef LLVM_CLANG_AST_DECL_H #define LLVM_CLANG_AST_DECL_H #include "clang/AST/APValue.h" #include "clang/AST/DeclBase.h" #include "clang/AST/DeclarationName.h" #include "clang/AST/ExternalASTSource.h" namespace clang { class Expr; class FunctionTemplateDecl; class Stmt; class CompoundStmt; class StringLiteral; class TemplateArgumentList; /// TranslationUnitDecl - The top declaration context. class TranslationUnitDecl : public Decl, public DeclContext { TranslationUnitDecl() : Decl(TranslationUnit, 0, SourceLocation()), DeclContext(TranslationUnit) {} public: static TranslationUnitDecl *Create(ASTContext &C); // Implement isa/cast/dyncast/etc. static bool classof(const Decl *D) { return D->getKind() == TranslationUnit; } static bool classof(const TranslationUnitDecl *D) { return true; } static DeclContext *castToDeclContext(const TranslationUnitDecl *D) { return static_cast(const_cast(D)); } static TranslationUnitDecl *castFromDeclContext(const DeclContext *DC) { return static_cast(const_cast(DC)); } }; /// NamedDecl - This represents a decl with a name. Many decls have names such /// as ObjCMethodDecl, but not @class, etc. class NamedDecl : public Decl { /// Name - The name of this declaration, which is typically a normal /// identifier but may also be a special kind of name (C++ /// constructor, Objective-C selector, etc.) DeclarationName Name; protected: NamedDecl(Kind DK, DeclContext *DC, SourceLocation L, DeclarationName N) : Decl(DK, DC, L), Name(N) { } public: /// getIdentifier - Get the identifier that names this declaration, /// if there is one. This will return NULL if this declaration has /// no name (e.g., for an unnamed class) or if the name is a special /// name (C++ constructor, Objective-C selector, etc.). IdentifierInfo *getIdentifier() const { return Name.getAsIdentifierInfo(); } /// getNameAsCString - Get the name of identifier for this declaration as a /// C string (const char*). This requires that the declaration have a name /// and that it be a simple identifier. const char *getNameAsCString() const { assert(getIdentifier() && "Name is not a simple identifier"); return getIdentifier()->getName(); } /// getDeclName - Get the actual, stored name of the declaration, /// which may be a special name. DeclarationName getDeclName() const { return Name; } /// \brief Set the name of this declaration. void setDeclName(DeclarationName N) { Name = N; } /// getNameAsString - Get a human-readable name for the declaration, even if /// it is one of the special kinds of names (C++ constructor, Objective-C /// selector, etc). Creating this name requires expensive string /// manipulation, so it should be called only when performance doesn't matter. /// For simple declarations, getNameAsCString() should suffice. std::string getNameAsString() const { return Name.getAsString(); } /// getQualifiedNameAsString - Returns human-readable qualified name for /// declaration, like A::B::i, for i being member of namespace A::B. /// If declaration is not member of context which can be named (record, /// namespace), it will return same result as getNameAsString(). /// Creating this name is expensive, so it should be called only when /// performance doesn't matter. std::string getQualifiedNameAsString() const; /// declarationReplaces - Determine whether this declaration, if /// known to be well-formed within its context, will replace the /// declaration OldD if introduced into scope. A declaration will /// replace another declaration if, for example, it is a /// redeclaration of the same variable or function, but not if it is /// a declaration of a different kind (function vs. class) or an /// overloaded function. bool declarationReplaces(NamedDecl *OldD) const; /// \brief Determine whether this declaration has linkage. bool hasLinkage() const; /// \brief Looks through UsingDecls and ObjCCompatibleAliasDecls for /// the underlying named decl. NamedDecl *getUnderlyingDecl(); const NamedDecl *getUnderlyingDecl() const { return const_cast(this)->getUnderlyingDecl(); } static bool classof(const Decl *D) { return D->getKind() >= NamedFirst && D->getKind() <= NamedLast; } static bool classof(const NamedDecl *D) { return true; } }; /// NamespaceDecl - Represent a C++ namespace. class NamespaceDecl : public NamedDecl, public DeclContext { SourceLocation LBracLoc, RBracLoc; // For extended namespace definitions: // // namespace A { int x; } // namespace A { int y; } // // there will be one NamespaceDecl for each declaration. // NextNamespace points to the next extended declaration. // OrigNamespace points to the original namespace declaration. // OrigNamespace of the first namespace decl points to itself. NamespaceDecl *OrigNamespace, *NextNamespace; NamespaceDecl(DeclContext *DC, SourceLocation L, IdentifierInfo *Id) : NamedDecl(Namespace, DC, L, Id), DeclContext(Namespace) { OrigNamespace = this; NextNamespace = 0; } public: static NamespaceDecl *Create(ASTContext &C, DeclContext *DC, SourceLocation L, IdentifierInfo *Id); virtual void Destroy(ASTContext& C); NamespaceDecl *getNextNamespace() { return NextNamespace; } const NamespaceDecl *getNextNamespace() const { return NextNamespace; } void setNextNamespace(NamespaceDecl *ND) { NextNamespace = ND; } NamespaceDecl *getOriginalNamespace() const { return OrigNamespace; } void setOriginalNamespace(NamespaceDecl *ND) { OrigNamespace = ND; } virtual SourceRange getSourceRange() const { return SourceRange(getLocation(), RBracLoc); } SourceLocation getLBracLoc() const { return LBracLoc; } SourceLocation getRBracLoc() const { return RBracLoc; } void setLBracLoc(SourceLocation LBrace) { LBracLoc = LBrace; } void setRBracLoc(SourceLocation RBrace) { RBracLoc = RBrace; } // Implement isa/cast/dyncast/etc. static bool classof(const Decl *D) { return D->getKind() == Namespace; } static bool classof(const NamespaceDecl *D) { return true; } static DeclContext *castToDeclContext(const NamespaceDecl *D) { return static_cast(const_cast(D)); } static NamespaceDecl *castFromDeclContext(const DeclContext *DC) { return static_cast(const_cast(DC)); } }; /// ValueDecl - Represent the declaration of a variable (in which case it is /// an lvalue) a function (in which case it is a function designator) or /// an enum constant. class ValueDecl : public NamedDecl { QualType DeclType; protected: ValueDecl(Kind DK, DeclContext *DC, SourceLocation L, DeclarationName N, QualType T) : NamedDecl(DK, DC, L, N), DeclType(T) {} public: QualType getType() const { return DeclType; } void setType(QualType newType) { DeclType = newType; } // Implement isa/cast/dyncast/etc. static bool classof(const Decl *D) { return D->getKind() >= ValueFirst && D->getKind() <= ValueLast; } static bool classof(const ValueDecl *D) { return true; } }; /// \brief Structure used to store a statement, the constant value to /// which it was evaluated (if any), and whether or not the statement /// is an integral constant expression (if known). struct EvaluatedStmt { EvaluatedStmt() : WasEvaluated(false), CheckedICE(false), IsICE(false) { } /// \brief Whether this statement was already evaluated. bool WasEvaluated : 1; /// \brief Whether we already checked whether this statement was an /// integral constant expression. bool CheckedICE : 1; /// \brief Whether this statement is an integral constant /// expression. Only valid if CheckedICE is true. bool IsICE : 1; Stmt *Value; APValue Evaluated; }; /// VarDecl - An instance of this class is created to represent a variable /// declaration or definition. class VarDecl : public ValueDecl { public: enum StorageClass { None, Auto, Register, Extern, Static, PrivateExtern }; /// getStorageClassSpecifierString - Return the string used to /// specify the storage class \arg SC. /// /// It is illegal to call this function with SC == None. static const char *getStorageClassSpecifierString(StorageClass SC); private: mutable llvm::PointerUnion Init; // FIXME: This can be packed into the bitfields in Decl. unsigned SClass : 3; bool ThreadSpecified : 1; bool HasCXXDirectInit : 1; /// DeclaredInCondition - Whether this variable was declared in a /// condition, e.g., if (int x = foo()) { ... }. bool DeclaredInCondition : 1; /// \brief The previous declaration of this variable. VarDecl *PreviousDeclaration; // Move to DeclGroup when it is implemented. SourceLocation TypeSpecStartLoc; friend class StmtIteratorBase; protected: VarDecl(Kind DK, DeclContext *DC, SourceLocation L, IdentifierInfo *Id, QualType T, StorageClass SC, SourceLocation TSSL = SourceLocation()) : ValueDecl(DK, DC, L, Id, T), Init(), ThreadSpecified(false), HasCXXDirectInit(false), DeclaredInCondition(false), PreviousDeclaration(0), TypeSpecStartLoc(TSSL) { SClass = SC; } public: static VarDecl *Create(ASTContext &C, DeclContext *DC, SourceLocation L, IdentifierInfo *Id, QualType T, StorageClass S, SourceLocation TypeSpecStartLoc = SourceLocation()); virtual ~VarDecl(); virtual void Destroy(ASTContext& C); StorageClass getStorageClass() const { return (StorageClass)SClass; } void setStorageClass(StorageClass SC) { SClass = SC; } virtual SourceRange getSourceRange() const; SourceLocation getTypeSpecStartLoc() const { return TypeSpecStartLoc; } void setTypeSpecStartLoc(SourceLocation SL) { TypeSpecStartLoc = SL; } const Expr *getInit() const { if (Init.isNull()) return 0; const Stmt *S = Init.dyn_cast(); if (!S) S = Init.get()->Value; return (const Expr*) S; } Expr *getInit() { if (Init.isNull()) return 0; Stmt *S = Init.dyn_cast(); if (!S) S = Init.get()->Value; return (Expr*) S; } /// \brief Retrieve the address of the initializer expression. Stmt **getInitAddress() { if (Init.is()) return reinterpret_cast(&Init); // FIXME: ugly hack return &Init.get()->Value; } void setInit(ASTContext &C, Expr *I); /// \brief Note that constant evaluation has computed the given /// value for this variable's initializer. void setEvaluatedValue(ASTContext &C, const APValue &Value) const { EvaluatedStmt *Eval = Init.dyn_cast(); if (!Eval) { Stmt *S = Init.get(); Eval = new (C) EvaluatedStmt; Eval->Value = S; Init = Eval; } Eval->WasEvaluated = true; Eval->Evaluated = Value; } /// \brief Return the already-evaluated value of this variable's /// initializer, or NULL if the value is not yet known. APValue *getEvaluatedValue() const { if (EvaluatedStmt *Eval = Init.dyn_cast()) if (Eval->WasEvaluated) return &Eval->Evaluated; return 0; } /// \brief Determines whether it is already known whether the /// initializer is an integral constant expression or not. bool isInitKnownICE() const { if (EvaluatedStmt *Eval = Init.dyn_cast()) return Eval->CheckedICE; return false; } /// \brief Determines whether the initializer is an integral /// constant expression. /// /// \pre isInitKnownICE() bool isInitICE() const { assert(isInitKnownICE() && "Check whether we already know that the initializer is an ICE"); return Init.get()->IsICE; } /// \brief Note that we now know whether the initializer is an /// integral constant expression. void setInitKnownICE(ASTContext &C, bool IsICE) const { EvaluatedStmt *Eval = Init.dyn_cast(); if (!Eval) { Stmt *S = Init.get(); Eval = new (C) EvaluatedStmt; Eval->Value = S; Init = Eval; } Eval->CheckedICE = true; Eval->IsICE = IsICE; } /// \brief Retrieve the definition of this variable, which may come /// from a previous declaration. Def will be set to the VarDecl that /// contains the initializer, and the result will be that /// initializer. const Expr *getDefinition(const VarDecl *&Def) const; void setThreadSpecified(bool T) { ThreadSpecified = T; } bool isThreadSpecified() const { return ThreadSpecified; } void setCXXDirectInitializer(bool T) { HasCXXDirectInit = T; } /// hasCXXDirectInitializer - If true, the initializer was a direct /// initializer, e.g: "int x(1);". The Init expression will be the expression /// inside the parens or a "ClassType(a,b,c)" class constructor expression for /// class types. Clients can distinguish between "int x(1);" and "int x=1;" /// by checking hasCXXDirectInitializer. /// bool hasCXXDirectInitializer() const { return HasCXXDirectInit; } /// isDeclaredInCondition - Whether this variable was declared as /// part of a condition in an if/switch/while statement, e.g., /// @code /// if (int x = foo()) { ... } /// @endcode bool isDeclaredInCondition() const { return DeclaredInCondition; } void setDeclaredInCondition(bool InCondition) { DeclaredInCondition = InCondition; } /// getPreviousDeclaration - Return the previous declaration of this /// variable. const VarDecl *getPreviousDeclaration() const { return PreviousDeclaration; } void setPreviousDeclaration(VarDecl *PrevDecl) { PreviousDeclaration = PrevDecl; } /// hasLocalStorage - Returns true if a variable with function scope /// is a non-static local variable. bool hasLocalStorage() const { if (getStorageClass() == None) return !isFileVarDecl(); // Return true for: Auto, Register. // Return false for: Extern, Static, PrivateExtern. return getStorageClass() <= Register; } /// hasExternStorage - Returns true if a variable has extern or /// __private_extern__ storage. bool hasExternalStorage() const { return getStorageClass() == Extern || getStorageClass() == PrivateExtern; } /// hasGlobalStorage - Returns true for all variables that do not /// have local storage. This includs all global variables as well /// as static variables declared within a function. bool hasGlobalStorage() const { return !hasLocalStorage(); } /// isBlockVarDecl - Returns true for local variable declarations. Note that /// this includes static variables inside of functions. /// /// void foo() { int x; static int y; extern int z; } /// bool isBlockVarDecl() const { if (getKind() != Decl::Var) return false; if (const DeclContext *DC = getDeclContext()) return DC->getLookupContext()->isFunctionOrMethod(); return false; } /// \brief Determines whether this is a static data member. /// /// This will only be true in C++, and applies to, e.g., the /// variable 'x' in: /// \code /// struct S { /// static int x; /// }; /// \endcode bool isStaticDataMember() const { return getDeclContext()->isRecord(); } /// isFileVarDecl - Returns true for file scoped variable declaration. bool isFileVarDecl() const { if (getKind() != Decl::Var) return false; if (const DeclContext *Ctx = getDeclContext()) { Ctx = Ctx->getLookupContext(); if (isa(Ctx) || isa(Ctx) ) return true; } return false; } /// \brief Determine whether this is a tentative definition of a /// variable in C. bool isTentativeDefinition(ASTContext &Context) const; /// \brief Determines whether this variable is a variable with /// external, C linkage. bool isExternC(ASTContext &Context) const; // Implement isa/cast/dyncast/etc. static bool classof(const Decl *D) { return D->getKind() >= VarFirst && D->getKind() <= VarLast; } static bool classof(const VarDecl *D) { return true; } }; class ImplicitParamDecl : public VarDecl { protected: ImplicitParamDecl(Kind DK, DeclContext *DC, SourceLocation L, IdentifierInfo *Id, QualType Tw) : VarDecl(DK, DC, L, Id, Tw, VarDecl::None) {} public: static ImplicitParamDecl *Create(ASTContext &C, DeclContext *DC, SourceLocation L, IdentifierInfo *Id, QualType T); // Implement isa/cast/dyncast/etc. static bool classof(const ImplicitParamDecl *D) { return true; } static bool classof(const Decl *D) { return D->getKind() == ImplicitParam; } }; /// ParmVarDecl - Represent a parameter to a function. class ParmVarDecl : public VarDecl { // NOTE: VC++ treats enums as signed, avoid using the ObjCDeclQualifier enum /// FIXME: Also can be paced into the bitfields in Decl. /// in, inout, etc. unsigned objcDeclQualifier : 6; /// Default argument, if any. [C++ Only] Expr *DefaultArg; protected: ParmVarDecl(Kind DK, DeclContext *DC, SourceLocation L, IdentifierInfo *Id, QualType T, StorageClass S, Expr *DefArg) : VarDecl(DK, DC, L, Id, T, S), objcDeclQualifier(OBJC_TQ_None), DefaultArg(DefArg) {} public: static ParmVarDecl *Create(ASTContext &C, DeclContext *DC, SourceLocation L,IdentifierInfo *Id, QualType T, StorageClass S, Expr *DefArg); ObjCDeclQualifier getObjCDeclQualifier() const { return ObjCDeclQualifier(objcDeclQualifier); } void setObjCDeclQualifier(ObjCDeclQualifier QTVal) { objcDeclQualifier = QTVal; } const Expr *getDefaultArg() const { assert(!hasUnparsedDefaultArg() && "Default argument is not yet parsed!"); return DefaultArg; } Expr *getDefaultArg() { assert(!hasUnparsedDefaultArg() && "Default argument is not yet parsed!"); return DefaultArg; } void setDefaultArg(Expr *defarg) { DefaultArg = defarg; } /// hasDefaultArg - Determines whether this parameter has a default argument, /// either parsed or not. bool hasDefaultArg() const { return DefaultArg != 0; } /// hasUnparsedDefaultArg - Determines whether this parameter has a /// default argument that has not yet been parsed. This will occur /// during the processing of a C++ class whose member functions have /// default arguments, e.g., /// @code /// class X { /// public: /// void f(int x = 17); // x has an unparsed default argument now /// }; // x has a regular default argument now /// @endcode bool hasUnparsedDefaultArg() const { return DefaultArg == reinterpret_cast(-1); } /// setUnparsedDefaultArg - Specify that this parameter has an /// unparsed default argument. The argument will be replaced with a /// real default argument via setDefaultArg when the class /// definition enclosing the function declaration that owns this /// default argument is completed. void setUnparsedDefaultArg() { DefaultArg = reinterpret_cast(-1); } QualType getOriginalType() const; /// setOwningFunction - Sets the function declaration that owns this /// ParmVarDecl. Since ParmVarDecls are often created before the /// FunctionDecls that own them, this routine is required to update /// the DeclContext appropriately. void setOwningFunction(DeclContext *FD) { setDeclContext(FD); } // Implement isa/cast/dyncast/etc. static bool classof(const Decl *D) { return (D->getKind() == ParmVar || D->getKind() == OriginalParmVar); } static bool classof(const ParmVarDecl *D) { return true; } }; /// OriginalParmVarDecl - Represent a parameter to a function, when /// the type of the parameter has been promoted. This node represents the /// parameter to the function with its original type. /// class OriginalParmVarDecl : public ParmVarDecl { friend class ParmVarDecl; protected: QualType OriginalType; private: OriginalParmVarDecl(DeclContext *DC, SourceLocation L, IdentifierInfo *Id, QualType T, QualType OT, StorageClass S, Expr *DefArg) : ParmVarDecl(OriginalParmVar, DC, L, Id, T, S, DefArg), OriginalType(OT) {} public: static OriginalParmVarDecl *Create(ASTContext &C, DeclContext *DC, SourceLocation L,IdentifierInfo *Id, QualType T, QualType OT, StorageClass S, Expr *DefArg); void setOriginalType(QualType T) { OriginalType = T; } // Implement isa/cast/dyncast/etc. static bool classof(const Decl *D) { return D->getKind() == OriginalParmVar; } static bool classof(const OriginalParmVarDecl *D) { return true; } }; /// FunctionDecl - An instance of this class is created to represent a /// function declaration or definition. /// /// Since a given function can be declared several times in a program, /// there may be several FunctionDecls that correspond to that /// function. Only one of those FunctionDecls will be found when /// traversing the list of declarations in the context of the /// FunctionDecl (e.g., the translation unit); this FunctionDecl /// contains all of the information known about the function. Other, /// previous declarations of the function are available via the /// getPreviousDeclaration() chain. class FunctionDecl : public ValueDecl, public DeclContext { public: enum StorageClass { None, Extern, Static, PrivateExtern }; private: /// \brief Provides information about a function template specialization, /// which is a FunctionDecl that has been explicitly specialization or /// instantiated from a function template. struct TemplateSpecializationInfo { FunctionTemplateDecl *Template; const TemplateArgumentList *TemplateArguments; }; /// ParamInfo - new[]'d array of pointers to VarDecls for the formal /// parameters of this function. This is null if a prototype or if there are /// no formals. ParmVarDecl **ParamInfo; LazyDeclStmtPtr Body; /// PreviousDeclaration - A link to the previous declaration of this /// same function, NULL if this is the first declaration. For /// example, in the following code, the PreviousDeclaration can be /// traversed several times to see all three declarations of the /// function "f", the last of which is also a definition. /// /// int f(int x, int y = 1); /// int f(int x = 0, int y); /// int f(int x, int y) { return x + y; } FunctionDecl *PreviousDeclaration; // FIXME: This can be packed into the bitfields in Decl. // NOTE: VC++ treats enums as signed, avoid using the StorageClass enum unsigned SClass : 2; bool IsInline : 1; bool C99InlineDefinition : 1; bool IsVirtualAsWritten : 1; bool IsPure : 1; bool HasInheritedPrototype : 1; bool HasWrittenPrototype : 1; bool IsDeleted : 1; // Move to DeclGroup when it is implemented. SourceLocation TypeSpecStartLoc; /// \brief End part of this FunctionDecl's source range. /// /// We could compute the full range in getSourceRange(). However, when we're /// dealing with a function definition deserialized from a PCH/AST file, /// we can only compute the full range once the function body has been /// de-serialized, so it's far better to have the (sometimes-redundant) /// EndRangeLoc. SourceLocation EndRangeLoc; /// \brief The template or declaration that this declaration /// describes or was instantiated from, respectively. /// /// For non-templates, this value will be NULL. For function /// declarations that describe a function template, this will be a /// pointer to a FunctionTemplateDecl. For member functions /// of class template specializations, this will be the /// FunctionDecl from which the member function was instantiated. /// For function template specializations, this will be a /// FunctionTemplateSpecializationInfo, which contains information about /// the template being specialized and the template arguments involved in /// that specialization. llvm::PointerUnion3 TemplateOrSpecialization; protected: FunctionDecl(Kind DK, DeclContext *DC, SourceLocation L, DeclarationName N, QualType T, StorageClass S, bool isInline, SourceLocation TSSL = SourceLocation()) : ValueDecl(DK, DC, L, N, T), DeclContext(DK), ParamInfo(0), Body(), PreviousDeclaration(0), SClass(S), IsInline(isInline), C99InlineDefinition(false), IsVirtualAsWritten(false), IsPure(false), HasInheritedPrototype(false), HasWrittenPrototype(true), IsDeleted(false), TypeSpecStartLoc(TSSL), EndRangeLoc(L), TemplateOrSpecialization() {} virtual ~FunctionDecl() {} virtual void Destroy(ASTContext& C); public: static FunctionDecl *Create(ASTContext &C, DeclContext *DC, SourceLocation L, DeclarationName N, QualType T, StorageClass S = None, bool isInline = false, bool hasWrittenPrototype = true, SourceLocation TSStartLoc = SourceLocation()); virtual SourceRange getSourceRange() const { return SourceRange(getLocation(), EndRangeLoc); } void setLocEnd(SourceLocation E) { EndRangeLoc = E; } SourceLocation getTypeSpecStartLoc() const { return TypeSpecStartLoc; } void setTypeSpecStartLoc(SourceLocation TS) { TypeSpecStartLoc = TS; } /// getBody - Retrieve the body (definition) of the function. The /// function body might be in any of the (re-)declarations of this /// function. The variant that accepts a FunctionDecl pointer will /// set that function declaration to the actual declaration /// containing the body (if there is one). Stmt *getBody(ASTContext &Context, const FunctionDecl *&Definition) const; virtual Stmt *getBody(ASTContext &Context) const { const FunctionDecl* Definition; return getBody(Context, Definition); } /// \brief If the function has a body that is immediately available, /// return it. Stmt *getBodyIfAvailable() const; /// isThisDeclarationADefinition - Returns whether this specific /// declaration of the function is also a definition. This does not /// determine whether the function has been defined (e.g., in a /// previous definition); for that information, use getBody. /// FIXME: Should return true if function is deleted or defaulted. However, /// CodeGenModule.cpp uses it, and I don't know if this would break it. bool isThisDeclarationADefinition() const { return Body; } void setBody(Stmt *B); void setLazyBody(uint64_t Offset) { Body = Offset; } /// Whether this function is marked as virtual explicitly. bool isVirtualAsWritten() const { return IsVirtualAsWritten; } void setVirtualAsWritten(bool V) { IsVirtualAsWritten = V; } /// Whether this virtual function is pure, i.e. makes the containing class /// abstract. bool isPure() const { return IsPure; } void setPure(bool P = true) { IsPure = P; } /// \brief Whether this function has a prototype, either because one /// was explicitly written or because it was "inherited" by merging /// a declaration without a prototype with a declaration that has a /// prototype. bool hasPrototype() const { return HasWrittenPrototype || HasInheritedPrototype; } bool hasWrittenPrototype() const { return HasWrittenPrototype; } void setHasWrittenPrototype(bool P) { HasWrittenPrototype = P; } /// \brief Whether this function inherited its prototype from a /// previous declaration. bool hasInheritedPrototype() const { return HasInheritedPrototype; } void setHasInheritedPrototype(bool P = true) { HasInheritedPrototype = P; } /// \brief Whether this function has been deleted. /// /// A function that is "deleted" (via the C++0x "= delete" syntax) /// acts like a normal function, except that it cannot actually be /// called or have its address taken. Deleted functions are /// typically used in C++ overload resolution to attract arguments /// whose type or lvalue/rvalue-ness would permit the use of a /// different overload that would behave incorrectly. For example, /// one might use deleted functions to ban implicit conversion from /// a floating-point number to an Integer type: /// /// @code /// struct Integer { /// Integer(long); // construct from a long /// Integer(double) = delete; // no construction from float or double /// Integer(long double) = delete; // no construction from long double /// }; /// @endcode bool isDeleted() const { return IsDeleted; } void setDeleted(bool D = true) { IsDeleted = D; } /// \brief Determines whether this is a function "main", which is /// the entry point into an executable program. bool isMain() const; /// \brief Determines whether this function is a function with /// external, C linkage. bool isExternC(ASTContext &Context) const; /// \brief Determines whether this is a global function. bool isGlobal() const; /// getPreviousDeclaration - Return the previous declaration of this /// function. const FunctionDecl *getPreviousDeclaration() const { return PreviousDeclaration; } void setPreviousDeclaration(FunctionDecl * PrevDecl) { PreviousDeclaration = PrevDecl; } unsigned getBuiltinID(ASTContext &Context) const; unsigned getNumParmVarDeclsFromType() const; // Iterator access to formal parameters. unsigned param_size() const { return getNumParams(); } typedef ParmVarDecl **param_iterator; typedef ParmVarDecl * const *param_const_iterator; param_iterator param_begin() { return ParamInfo; } param_iterator param_end() { return ParamInfo+param_size(); } param_const_iterator param_begin() const { return ParamInfo; } param_const_iterator param_end() const { return ParamInfo+param_size(); } /// getNumParams - Return the number of parameters this function must have /// based on its functiontype. This is the length of the PararmInfo array /// after it has been created. unsigned getNumParams() const; const ParmVarDecl *getParamDecl(unsigned i) const { assert(i < getNumParams() && "Illegal param #"); return ParamInfo[i]; } ParmVarDecl *getParamDecl(unsigned i) { assert(i < getNumParams() && "Illegal param #"); return ParamInfo[i]; } void setParams(ASTContext& C, ParmVarDecl **NewParamInfo, unsigned NumParams); /// getMinRequiredArguments - Returns the minimum number of arguments /// needed to call this function. This may be fewer than the number of /// function parameters, if some of the parameters have default /// arguments (in C++). unsigned getMinRequiredArguments() const; QualType getResultType() const { return getType()->getAsFunctionType()->getResultType(); } StorageClass getStorageClass() const { return StorageClass(SClass); } void setStorageClass(StorageClass SC) { SClass = SC; } bool isInline() const { return IsInline; } void setInline(bool I) { IsInline = I; } /// \brief Whether this function is an "inline definition" as /// defined by C99. bool isC99InlineDefinition() const { return C99InlineDefinition; } void setC99InlineDefinition(bool I) { C99InlineDefinition = I; } /// \brief Determines whether this function has a gnu_inline /// attribute that affects its semantics. /// /// The gnu_inline attribute only introduces GNU inline semantics /// when all of the inline declarations of the function are marked /// gnu_inline. bool hasActiveGNUInlineAttribute(ASTContext &Context) const; /// \brief Determines whether this function is a GNU "extern /// inline", which is roughly the opposite of a C99 "extern inline" /// function. bool isExternGNUInline(ASTContext &Context) const; /// isOverloadedOperator - Whether this function declaration /// represents an C++ overloaded operator, e.g., "operator+". bool isOverloadedOperator() const { return getOverloadedOperator() != OO_None; }; OverloadedOperatorKind getOverloadedOperator() const; /// \brief If this function is an instantiation of a member function /// of a class template specialization, retrieves the function from /// which it was instantiated. /// /// This routine will return non-NULL for (non-templated) member /// functions of class templates and for instantiations of function /// templates. For example, given: /// /// \code /// template /// struct X { /// void f(T); /// }; /// \endcode /// /// The declaration for X::f is a (non-templated) FunctionDecl /// whose parent is the class template specialization X. For /// this declaration, getInstantiatedFromFunction() will return /// the FunctionDecl X::A. When a complete definition of /// X::A is required, it will be instantiated from the /// declaration returned by getInstantiatedFromMemberFunction(). FunctionDecl *getInstantiatedFromMemberFunction() const { return TemplateOrSpecialization.dyn_cast(); } /// \brief Specify that this record is an instantiation of the /// member function RD. void setInstantiationOfMemberFunction(FunctionDecl *RD) { TemplateOrSpecialization = RD; } /// \brief Retrieves the function template that is described by this /// function declaration. /// /// Every function template is represented as a FunctionTemplateDecl /// and a FunctionDecl (or something derived from FunctionDecl). The /// former contains template properties (such as the template /// parameter lists) while the latter contains the actual /// description of the template's /// contents. FunctionTemplateDecl::getTemplatedDecl() retrieves the /// FunctionDecl that describes the function template, /// getDescribedFunctionTemplate() retrieves the /// FunctionTemplateDecl from a FunctionDecl. FunctionTemplateDecl *getDescribedFunctionTemplate() const { return TemplateOrSpecialization.dyn_cast(); } void setDescribedFunctionTemplate(FunctionTemplateDecl *Template) { TemplateOrSpecialization = Template; } /// \brief Retrieve the primary template that this function template /// specialization either specializes or was instantiated from. /// /// If this function declaration is not a function template specialization, /// returns NULL. FunctionTemplateDecl *getPrimaryTemplate() const { if (TemplateSpecializationInfo *Info = TemplateOrSpecialization.dyn_cast()) { return Info->Template; } return 0; } /// \brief Retrieve the template arguments used to produce this function /// template specialization from the primary template. /// /// If this function declaration is not a function template specialization, /// returns NULL. const TemplateArgumentList *getTemplateSpecializationArgs() const { if (TemplateSpecializationInfo *Info = TemplateOrSpecialization.dyn_cast()) { return Info->TemplateArguments; } return 0; } /// \brief Specify that this function declaration is actually a function /// template specialization. /// /// \param Context the AST context in which this function resides. /// /// \param Template the function template that this function template /// specialization specializes. /// /// \param TemplateArgs the template arguments that produced this /// function template specialization from the template. void setFunctionTemplateSpecialization(ASTContext &Context, FunctionTemplateDecl *Template, const TemplateArgumentList *TemplateArgs); // Implement isa/cast/dyncast/etc. static bool classof(const Decl *D) { return D->getKind() >= FunctionFirst && D->getKind() <= FunctionLast; } static bool classof(const FunctionDecl *D) { return true; } static DeclContext *castToDeclContext(const FunctionDecl *D) { return static_cast(const_cast(D)); } static FunctionDecl *castFromDeclContext(const DeclContext *DC) { return static_cast(const_cast(DC)); } }; /// FieldDecl - An instance of this class is created by Sema::ActOnField to /// represent a member of a struct/union/class. class FieldDecl : public ValueDecl { // FIXME: This can be packed into the bitfields in Decl. bool Mutable : 1; Expr *BitWidth; protected: FieldDecl(Kind DK, DeclContext *DC, SourceLocation L, IdentifierInfo *Id, QualType T, Expr *BW, bool Mutable) : ValueDecl(DK, DC, L, Id, T), Mutable(Mutable), BitWidth(BW) { } public: static FieldDecl *Create(ASTContext &C, DeclContext *DC, SourceLocation L, IdentifierInfo *Id, QualType T, Expr *BW, bool Mutable); /// isMutable - Determines whether this field is mutable (C++ only). bool isMutable() const { return Mutable; } /// \brief Set whether this field is mutable (C++ only). void setMutable(bool M) { Mutable = M; } /// isBitfield - Determines whether this field is a bitfield. bool isBitField() const { return BitWidth != NULL; } /// @brief Determines whether this is an unnamed bitfield. bool isUnnamedBitfield() const { return BitWidth != NULL && !getDeclName(); } /// isAnonymousStructOrUnion - Determines whether this field is a /// representative for an anonymous struct or union. Such fields are /// unnamed and are implicitly generated by the implementation to /// store the data for the anonymous union or struct. bool isAnonymousStructOrUnion() const; Expr *getBitWidth() const { return BitWidth; } void setBitWidth(Expr *BW) { BitWidth = BW; } // Implement isa/cast/dyncast/etc. static bool classof(const Decl *D) { return D->getKind() >= FieldFirst && D->getKind() <= FieldLast; } static bool classof(const FieldDecl *D) { return true; } }; /// EnumConstantDecl - An instance of this object exists for each enum constant /// that is defined. For example, in "enum X {a,b}", each of a/b are /// EnumConstantDecl's, X is an instance of EnumDecl, and the type of a/b is a /// TagType for the X EnumDecl. class EnumConstantDecl : public ValueDecl { Stmt *Init; // an integer constant expression llvm::APSInt Val; // The value. protected: EnumConstantDecl(DeclContext *DC, SourceLocation L, IdentifierInfo *Id, QualType T, Expr *E, const llvm::APSInt &V) : ValueDecl(EnumConstant, DC, L, Id, T), Init((Stmt*)E), Val(V) {} virtual ~EnumConstantDecl() {} public: static EnumConstantDecl *Create(ASTContext &C, EnumDecl *DC, SourceLocation L, IdentifierInfo *Id, QualType T, Expr *E, const llvm::APSInt &V); virtual void Destroy(ASTContext& C); const Expr *getInitExpr() const { return (const Expr*) Init; } Expr *getInitExpr() { return (Expr*) Init; } const llvm::APSInt &getInitVal() const { return Val; } void setInitExpr(Expr *E) { Init = (Stmt*) E; } void setInitVal(const llvm::APSInt &V) { Val = V; } // Implement isa/cast/dyncast/etc. static bool classof(const Decl *D) { return D->getKind() == EnumConstant; } static bool classof(const EnumConstantDecl *D) { return true; } friend class StmtIteratorBase; }; /// TypeDecl - Represents a declaration of a type. /// class TypeDecl : public NamedDecl { /// TypeForDecl - This indicates the Type object that represents /// this TypeDecl. It is a cache maintained by /// ASTContext::getTypedefType, ASTContext::getTagDeclType, and /// ASTContext::getTemplateTypeParmType, and TemplateTypeParmDecl. mutable Type *TypeForDecl; friend class ASTContext; friend class DeclContext; friend class TagDecl; friend class TemplateTypeParmDecl; friend class ClassTemplateSpecializationDecl; friend class TagType; protected: TypeDecl(Kind DK, DeclContext *DC, SourceLocation L, IdentifierInfo *Id) : NamedDecl(DK, DC, L, Id), TypeForDecl(0) {} public: // Low-level accessor Type *getTypeForDecl() const { return TypeForDecl; } void setTypeForDecl(Type *TD) { TypeForDecl = TD; } // Implement isa/cast/dyncast/etc. static bool classof(const Decl *D) { return D->getKind() >= TypeFirst && D->getKind() <= TypeLast; } static bool classof(const TypeDecl *D) { return true; } }; class TypedefDecl : public TypeDecl { /// UnderlyingType - This is the type the typedef is set to. QualType UnderlyingType; TypedefDecl(DeclContext *DC, SourceLocation L, IdentifierInfo *Id, QualType T) : TypeDecl(Typedef, DC, L, Id), UnderlyingType(T) {} virtual ~TypedefDecl() {} public: static TypedefDecl *Create(ASTContext &C, DeclContext *DC, SourceLocation L,IdentifierInfo *Id, QualType T); QualType getUnderlyingType() const { return UnderlyingType; } void setUnderlyingType(QualType newType) { UnderlyingType = newType; } // Implement isa/cast/dyncast/etc. static bool classof(const Decl *D) { return D->getKind() == Typedef; } static bool classof(const TypedefDecl *D) { return true; } }; class TypedefDecl; /// TagDecl - Represents the declaration of a struct/union/class/enum. class TagDecl : public TypeDecl, public DeclContext { public: enum TagKind { TK_struct, TK_union, TK_class, TK_enum }; private: // FIXME: This can be packed into the bitfields in Decl. /// TagDeclKind - The TagKind enum. unsigned TagDeclKind : 2; /// IsDefinition - True if this is a definition ("struct foo {};"), false if /// it is a declaration ("struct foo;"). bool IsDefinition : 1; /// TypedefForAnonDecl - If a TagDecl is anonymous and part of a typedef, /// this points to the TypedefDecl. Used for mangling. TypedefDecl *TypedefForAnonDecl; protected: TagDecl(Kind DK, TagKind TK, DeclContext *DC, SourceLocation L, IdentifierInfo *Id) : TypeDecl(DK, DC, L, Id), DeclContext(DK), TypedefForAnonDecl(0) { assert((DK != Enum || TK == TK_enum) &&"EnumDecl not matched with TK_enum"); TagDeclKind = TK; IsDefinition = false; } public: /// isDefinition - Return true if this decl has its body specified. bool isDefinition() const { return IsDefinition; } /// \brief Whether this declaration declares a type that is /// dependent, i.e., a type that somehow depends on template /// parameters. bool isDependentType() const { return isDependentContext(); } /// @brief Starts the definition of this tag declaration. /// /// This method should be invoked at the beginning of the definition /// of this tag declaration. It will set the tag type into a state /// where it is in the process of being defined. void startDefinition(); /// @brief Completes the definition of this tag declaration. void completeDefinition(); /// getDefinition - Returns the TagDecl that actually defines this /// struct/union/class/enum. When determining whether or not a /// struct/union/class/enum is completely defined, one should use this method /// as opposed to 'isDefinition'. 'isDefinition' indicates whether or not a /// specific TagDecl is defining declaration, not whether or not the /// struct/union/class/enum type is defined. This method returns NULL if /// there is no TagDecl that defines the struct/union/class/enum. TagDecl* getDefinition(ASTContext& C) const; const char *getKindName() const { switch (getTagKind()) { default: assert(0 && "Unknown TagKind!"); case TK_struct: return "struct"; case TK_union: return "union"; case TK_class: return "class"; case TK_enum: return "enum"; } } TagKind getTagKind() const { return TagKind(TagDeclKind); } void setTagKind(TagKind TK) { TagDeclKind = TK; } bool isStruct() const { return getTagKind() == TK_struct; } bool isClass() const { return getTagKind() == TK_class; } bool isUnion() const { return getTagKind() == TK_union; } bool isEnum() const { return getTagKind() == TK_enum; } TypedefDecl *getTypedefForAnonDecl() const { return TypedefForAnonDecl; } void setTypedefForAnonDecl(TypedefDecl *TDD) { TypedefForAnonDecl = TDD; } // Implement isa/cast/dyncast/etc. static bool classof(const Decl *D) { return D->getKind() >= TagFirst && D->getKind() <= TagLast; } static bool classof(const TagDecl *D) { return true; } static DeclContext *castToDeclContext(const TagDecl *D) { return static_cast(const_cast(D)); } static TagDecl *castFromDeclContext(const DeclContext *DC) { return static_cast(const_cast(DC)); } void setDefinition(bool V) { IsDefinition = V; } }; /// EnumDecl - Represents an enum. As an extension, we allow forward-declared /// enums. class EnumDecl : public TagDecl { /// IntegerType - This represent the integer type that the enum corresponds /// to for code generation purposes. Note that the enumerator constants may /// have a different type than this does. QualType IntegerType; /// \brief If the enumeration was instantiated from an enumeration /// within a class or function template, this pointer refers to the /// enumeration declared within the template. EnumDecl *InstantiatedFrom; EnumDecl(DeclContext *DC, SourceLocation L, IdentifierInfo *Id) : TagDecl(Enum, TK_enum, DC, L, Id), InstantiatedFrom(0) { IntegerType = QualType(); } public: static EnumDecl *Create(ASTContext &C, DeclContext *DC, SourceLocation L, IdentifierInfo *Id, EnumDecl *PrevDecl); virtual void Destroy(ASTContext& C); /// completeDefinition - When created, the EnumDecl corresponds to a /// forward-declared enum. This method is used to mark the /// declaration as being defined; it's enumerators have already been /// added (via DeclContext::addDecl). NewType is the new underlying /// type of the enumeration type. void completeDefinition(ASTContext &C, QualType NewType); // enumerator_iterator - Iterates through the enumerators of this // enumeration. typedef specific_decl_iterator enumerator_iterator; enumerator_iterator enumerator_begin(ASTContext &Context) const { return enumerator_iterator(this->decls_begin(Context)); } enumerator_iterator enumerator_end(ASTContext &Context) const { return enumerator_iterator(this->decls_end(Context)); } /// getIntegerType - Return the integer type this enum decl corresponds to. /// This returns a null qualtype for an enum forward definition. QualType getIntegerType() const { return IntegerType; } /// \brief Set the underlying integer type. void setIntegerType(QualType T) { IntegerType = T; } /// \brief Returns the enumeration (declared within the template) /// from which this enumeration type was instantiated, or NULL if /// this enumeration was not instantiated from any template. EnumDecl *getInstantiatedFromMemberEnum() const { return InstantiatedFrom; } void setInstantiationOfMemberEnum(EnumDecl *IF) { InstantiatedFrom = IF; } static bool classof(const Decl *D) { return D->getKind() == Enum; } static bool classof(const EnumDecl *D) { return true; } }; /// RecordDecl - Represents a struct/union/class. For example: /// struct X; // Forward declaration, no "body". /// union Y { int A, B; }; // Has body with members A and B (FieldDecls). /// This decl will be marked invalid if *any* members are invalid. /// class RecordDecl : public TagDecl { // FIXME: This can be packed into the bitfields in Decl. /// HasFlexibleArrayMember - This is true if this struct ends with a flexible /// array member (e.g. int X[]) or if this union contains a struct that does. /// If so, this cannot be contained in arrays or other structs as a member. bool HasFlexibleArrayMember : 1; /// AnonymousStructOrUnion - Whether this is the type of an /// anonymous struct or union. bool AnonymousStructOrUnion : 1; protected: RecordDecl(Kind DK, TagKind TK, DeclContext *DC, SourceLocation L, IdentifierInfo *Id); virtual ~RecordDecl(); public: static RecordDecl *Create(ASTContext &C, TagKind TK, DeclContext *DC, SourceLocation L, IdentifierInfo *Id, RecordDecl* PrevDecl = 0); virtual void Destroy(ASTContext& C); bool hasFlexibleArrayMember() const { return HasFlexibleArrayMember; } void setHasFlexibleArrayMember(bool V) { HasFlexibleArrayMember = V; } /// isAnonymousStructOrUnion - Whether this is an anonymous struct /// or union. To be an anonymous struct or union, it must have been /// declared without a name and there must be no objects of this /// type declared, e.g., /// @code /// union { int i; float f; }; /// @endcode /// is an anonymous union but neither of the following are: /// @code /// union X { int i; float f; }; /// union { int i; float f; } obj; /// @endcode bool isAnonymousStructOrUnion() const { return AnonymousStructOrUnion; } void setAnonymousStructOrUnion(bool Anon) { AnonymousStructOrUnion = Anon; } /// \brief Determines whether this declaration represents the /// injected class name. /// /// The injected class name in C++ is the name of the class that /// appears inside the class itself. For example: /// /// \code /// struct C { /// // C is implicitly declared here as a synonym for the class name. /// }; /// /// C::C c; // same as "C c;" /// \endcode bool isInjectedClassName() const; /// getDefinition - Returns the RecordDecl that actually defines this /// struct/union/class. When determining whether or not a struct/union/class /// is completely defined, one should use this method as opposed to /// 'isDefinition'. 'isDefinition' indicates whether or not a specific /// RecordDecl is defining declaration, not whether or not the record /// type is defined. This method returns NULL if there is no RecordDecl /// that defines the struct/union/tag. RecordDecl* getDefinition(ASTContext& C) const { return cast_or_null(TagDecl::getDefinition(C)); } // Iterator access to field members. The field iterator only visits // the non-static data members of this class, ignoring any static // data members, functions, constructors, destructors, etc. typedef specific_decl_iterator field_iterator; field_iterator field_begin(ASTContext &Context) const { return field_iterator(decls_begin(Context)); } field_iterator field_end(ASTContext &Context) const { return field_iterator(decls_end(Context)); } // field_empty - Whether there are any fields (non-static data // members) in this record. bool field_empty(ASTContext &Context) const { return field_begin(Context) == field_end(Context); } /// completeDefinition - Notes that the definition of this type is /// now complete. void completeDefinition(ASTContext& C); static bool classof(const Decl *D) { return D->getKind() >= RecordFirst && D->getKind() <= RecordLast; } static bool classof(const RecordDecl *D) { return true; } }; class FileScopeAsmDecl : public Decl { StringLiteral *AsmString; FileScopeAsmDecl(DeclContext *DC, SourceLocation L, StringLiteral *asmstring) : Decl(FileScopeAsm, DC, L), AsmString(asmstring) {} public: static FileScopeAsmDecl *Create(ASTContext &C, DeclContext *DC, SourceLocation L, StringLiteral *Str); const StringLiteral *getAsmString() const { return AsmString; } StringLiteral *getAsmString() { return AsmString; } void setAsmString(StringLiteral *Asm) { AsmString = Asm; } static bool classof(const Decl *D) { return D->getKind() == FileScopeAsm; } static bool classof(const FileScopeAsmDecl *D) { return true; } }; /// BlockDecl - This represents a block literal declaration, which is like an /// unnamed FunctionDecl. For example: /// ^{ statement-body } or ^(int arg1, float arg2){ statement-body } /// class BlockDecl : public Decl, public DeclContext { // FIXME: This can be packed into the bitfields in Decl. bool isVariadic : 1; /// ParamInfo - new[]'d array of pointers to ParmVarDecls for the formal /// parameters of this function. This is null if a prototype or if there are /// no formals. ParmVarDecl **ParamInfo; unsigned NumParams; Stmt *Body; protected: BlockDecl(DeclContext *DC, SourceLocation CaretLoc) : Decl(Block, DC, CaretLoc), DeclContext(Block), isVariadic(false), ParamInfo(0), NumParams(0), Body(0) {} virtual ~BlockDecl(); virtual void Destroy(ASTContext& C); public: static BlockDecl *Create(ASTContext &C, DeclContext *DC, SourceLocation L); SourceLocation getCaretLocation() const { return getLocation(); } bool IsVariadic() const { return isVariadic; } void setIsVariadic(bool value) { isVariadic = value; } CompoundStmt *getBody() const { return (CompoundStmt*) Body; } Stmt *getBody(ASTContext &C) const { return (Stmt*) Body; } void setBody(CompoundStmt *B) { Body = (Stmt*) B; } // Iterator access to formal parameters. unsigned param_size() const { return getNumParams(); } typedef ParmVarDecl **param_iterator; typedef ParmVarDecl * const *param_const_iterator; bool param_empty() const { return NumParams == 0; } param_iterator param_begin() { return ParamInfo; } param_iterator param_end() { return ParamInfo+param_size(); } param_const_iterator param_begin() const { return ParamInfo; } param_const_iterator param_end() const { return ParamInfo+param_size(); } unsigned getNumParams() const; const ParmVarDecl *getParamDecl(unsigned i) const { assert(i < getNumParams() && "Illegal param #"); return ParamInfo[i]; } ParmVarDecl *getParamDecl(unsigned i) { assert(i < getNumParams() && "Illegal param #"); return ParamInfo[i]; } void setParams(ASTContext& C, ParmVarDecl **NewParamInfo, unsigned NumParams); // Implement isa/cast/dyncast/etc. static bool classof(const Decl *D) { return D->getKind() == Block; } static bool classof(const BlockDecl *D) { return true; } static DeclContext *castToDeclContext(const BlockDecl *D) { return static_cast(const_cast(D)); } static BlockDecl *castFromDeclContext(const DeclContext *DC) { return static_cast(const_cast(DC)); } }; /// Insertion operator for diagnostics. This allows sending NamedDecl's /// into a diagnostic with <<. inline const DiagnosticBuilder &operator<<(const DiagnosticBuilder &DB, NamedDecl* ND) { DB.AddTaggedVal(reinterpret_cast(ND), Diagnostic::ak_nameddecl); return DB; } } // end namespace clang #endif