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//===--- DeclSpec.h - Parsed declaration specifiers -------------*- 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 classes used to store parsed information about // declaration-specifiers and declarators. // // static const int volatile x, *y, *(*(*z)[10])(const void *x); // ------------------------- - -- --------------------------- // declaration-specifiers \ | / // declarators // //===----------------------------------------------------------------------===// #ifndef LLVM_CLANG_SEMA_DECLSPEC_H #define LLVM_CLANG_SEMA_DECLSPEC_H #include "clang/Sema/AttributeList.h" #include "clang/Sema/Ownership.h" #include "clang/AST/NestedNameSpecifier.h" #include "clang/Lex/Token.h" #include "clang/Basic/ExceptionSpecificationType.h" #include "clang/Basic/Lambda.h" #include "clang/Basic/OperatorKinds.h" #include "clang/Basic/Specifiers.h" #include "llvm/ADT/SmallVector.h" #include "llvm/Support/Compiler.h" #include "llvm/Support/ErrorHandling.h" namespace clang { class ASTContext; class TypeLoc; class LangOptions; class DiagnosticsEngine; class IdentifierInfo; class NamespaceAliasDecl; class NamespaceDecl; class NestedNameSpecifier; class NestedNameSpecifierLoc; class ObjCDeclSpec; class Preprocessor; class Sema; class Declarator; struct TemplateIdAnnotation; /// CXXScopeSpec - Represents a C++ nested-name-specifier or a global scope /// specifier. These can be in 3 states: /// 1) Not present, identified by isEmpty() /// 2) Present, identified by isNotEmpty() /// 2.a) Valid, idenified by isValid() /// 2.b) Invalid, identified by isInvalid(). /// /// isSet() is deprecated because it mostly corresponded to "valid" but was /// often used as if it meant "present". /// /// The actual scope is described by getScopeRep(). class CXXScopeSpec { SourceRange Range; NestedNameSpecifierLocBuilder Builder; public: const SourceRange &getRange() const { return Range; } void setRange(const SourceRange &R) { Range = R; } void setBeginLoc(SourceLocation Loc) { Range.setBegin(Loc); } void setEndLoc(SourceLocation Loc) { Range.setEnd(Loc); } SourceLocation getBeginLoc() const { return Range.getBegin(); } SourceLocation getEndLoc() const { return Range.getEnd(); } /// \brief Retrieve the representation of the nested-name-specifier. NestedNameSpecifier *getScopeRep() const { return Builder.getRepresentation(); } /// \brief Extend the current nested-name-specifier by another /// nested-name-specifier component of the form 'type::'. /// /// \param Context The AST context in which this nested-name-specifier /// resides. /// /// \param TemplateKWLoc The location of the 'template' keyword, if present. /// /// \param TL The TypeLoc that describes the type preceding the '::'. /// /// \param ColonColonLoc The location of the trailing '::'. void Extend(ASTContext &Context, SourceLocation TemplateKWLoc, TypeLoc TL, SourceLocation ColonColonLoc); /// \brief Extend the current nested-name-specifier by another /// nested-name-specifier component of the form 'identifier::'. /// /// \param Context The AST context in which this nested-name-specifier /// resides. /// /// \param Identifier The identifier. /// /// \param IdentifierLoc The location of the identifier. /// /// \param ColonColonLoc The location of the trailing '::'. void Extend(ASTContext &Context, IdentifierInfo *Identifier, SourceLocation IdentifierLoc, SourceLocation ColonColonLoc); /// \brief Extend the current nested-name-specifier by another /// nested-name-specifier component of the form 'namespace::'. /// /// \param Context The AST context in which this nested-name-specifier /// resides. /// /// \param Namespace The namespace. /// /// \param NamespaceLoc The location of the namespace name. /// /// \param ColonColonLoc The location of the trailing '::'. void Extend(ASTContext &Context, NamespaceDecl *Namespace, SourceLocation NamespaceLoc, SourceLocation ColonColonLoc); /// \brief Extend the current nested-name-specifier by another /// nested-name-specifier component of the form 'namespace-alias::'. /// /// \param Context The AST context in which this nested-name-specifier /// resides. /// /// \param Alias The namespace alias. /// /// \param AliasLoc The location of the namespace alias /// name. /// /// \param ColonColonLoc The location of the trailing '::'. void Extend(ASTContext &Context, NamespaceAliasDecl *Alias, SourceLocation AliasLoc, SourceLocation ColonColonLoc); /// \brief Turn this (empty) nested-name-specifier into the global /// nested-name-specifier '::'. void MakeGlobal(ASTContext &Context, SourceLocation ColonColonLoc); /// \brief Make a new nested-name-specifier from incomplete source-location /// information. /// /// FIXME: This routine should be used very, very rarely, in cases where we /// need to synthesize a nested-name-specifier. Most code should instead use /// \c Adopt() with a proper \c NestedNameSpecifierLoc. void MakeTrivial(ASTContext &Context, NestedNameSpecifier *Qualifier, SourceRange R); /// \brief Adopt an existing nested-name-specifier (with source-range /// information). void Adopt(NestedNameSpecifierLoc Other); /// \brief Retrieve a nested-name-specifier with location information, copied /// into the given AST context. /// /// \param Context The context into which this nested-name-specifier will be /// copied. NestedNameSpecifierLoc getWithLocInContext(ASTContext &Context) const; /// \brief Retrieve the location of the name in the last qualifier /// in this nested name specifier. For example: /// ::foo::bar<0>:: /// ^~~ SourceLocation getLastQualifierNameLoc() const; /// No scope specifier. bool isEmpty() const { return !Range.isValid(); } /// A scope specifier is present, but may be valid or invalid. bool isNotEmpty() const { return !isEmpty(); } /// An error occurred during parsing of the scope specifier. bool isInvalid() const { return isNotEmpty() && getScopeRep() == 0; } /// A scope specifier is present, and it refers to a real scope. bool isValid() const { return isNotEmpty() && getScopeRep() != 0; } /// \brief Indicate that this nested-name-specifier is invalid. void SetInvalid(SourceRange R) { assert(R.isValid() && "Must have a valid source range"); if (Range.getBegin().isInvalid()) Range.setBegin(R.getBegin()); Range.setEnd(R.getEnd()); Builder.Clear(); } /// Deprecated. Some call sites intend isNotEmpty() while others intend /// isValid(). bool isSet() const { return getScopeRep() != 0; } void clear() { Range = SourceRange(); Builder.Clear(); } /// \brief Retrieve the data associated with the source-location information. char *location_data() const { return Builder.getBuffer().first; } /// \brief Retrieve the size of the data associated with source-location /// information. unsigned location_size() const { return Builder.getBuffer().second; } }; /// DeclSpec - This class captures information about "declaration specifiers", /// which encompasses storage-class-specifiers, type-specifiers, /// type-qualifiers, and function-specifiers. class DeclSpec { public: // storage-class-specifier // Note: The order of these enumerators is important for diagnostics. enum SCS { SCS_unspecified = 0, SCS_typedef, SCS_extern, SCS_static, SCS_auto, SCS_register, SCS_private_extern, SCS_mutable }; // Import type specifier width enumeration and constants. typedef TypeSpecifierWidth TSW; static const TSW TSW_unspecified = clang::TSW_unspecified; static const TSW TSW_short = clang::TSW_short; static const TSW TSW_long = clang::TSW_long; static const TSW TSW_longlong = clang::TSW_longlong; enum TSC { TSC_unspecified, TSC_imaginary, TSC_complex }; // Import type specifier sign enumeration and constants. typedef TypeSpecifierSign TSS; static const TSS TSS_unspecified = clang::TSS_unspecified; static const TSS TSS_signed = clang::TSS_signed; static const TSS TSS_unsigned = clang::TSS_unsigned; // Import type specifier type enumeration and constants. typedef TypeSpecifierType TST; static const TST TST_unspecified = clang::TST_unspecified; static const TST TST_void = clang::TST_void; static const TST TST_char = clang::TST_char; static const TST TST_wchar = clang::TST_wchar; static const TST TST_char16 = clang::TST_char16; static const TST TST_char32 = clang::TST_char32; static const TST TST_int = clang::TST_int; static const TST TST_int128 = clang::TST_int128; static const TST TST_half = clang::TST_half; static const TST TST_float = clang::TST_float; static const TST TST_double = clang::TST_double; static const TST TST_bool = clang::TST_bool; static const TST TST_decimal32 = clang::TST_decimal32; static const TST TST_decimal64 = clang::TST_decimal64; static const TST TST_decimal128 = clang::TST_decimal128; static const TST TST_enum = clang::TST_enum; static const TST TST_union = clang::TST_union; static const TST TST_struct = clang::TST_struct; static const TST TST_class = clang::TST_class; static const TST TST_typename = clang::TST_typename; static const TST TST_typeofType = clang::TST_typeofType; static const TST TST_typeofExpr = clang::TST_typeofExpr; static const TST TST_decltype = clang::TST_decltype; static const TST TST_underlyingType = clang::TST_underlyingType; static const TST TST_auto = clang::TST_auto; static const TST TST_unknown_anytype = clang::TST_unknown_anytype; static const TST TST_atomic = clang::TST_atomic; static const TST TST_error = clang::TST_error; // type-qualifiers enum TQ { // NOTE: These flags must be kept in sync with Qualifiers::TQ. TQ_unspecified = 0, TQ_const = 1, TQ_restrict = 2, TQ_volatile = 4 }; /// ParsedSpecifiers - Flags to query which specifiers were applied. This is /// returned by getParsedSpecifiers. enum ParsedSpecifiers { PQ_None = 0, PQ_StorageClassSpecifier = 1, PQ_TypeSpecifier = 2, PQ_TypeQualifier = 4, PQ_FunctionSpecifier = 8 }; private: // storage-class-specifier /*SCS*/unsigned StorageClassSpec : 3; unsigned SCS_thread_specified : 1; unsigned SCS_extern_in_linkage_spec : 1; // type-specifier /*TSW*/unsigned TypeSpecWidth : 2; /*TSC*/unsigned TypeSpecComplex : 2; /*TSS*/unsigned TypeSpecSign : 2; /*TST*/unsigned TypeSpecType : 5; unsigned TypeAltiVecVector : 1; unsigned TypeAltiVecPixel : 1; unsigned TypeAltiVecBool : 1; unsigned TypeSpecOwned : 1; // type-qualifiers unsigned TypeQualifiers : 3; // Bitwise OR of TQ. // function-specifier unsigned FS_inline_specified : 1; unsigned FS_virtual_specified : 1; unsigned FS_explicit_specified : 1; // friend-specifier unsigned Friend_specified : 1; // constexpr-specifier unsigned Constexpr_specified : 1; /*SCS*/unsigned StorageClassSpecAsWritten : 3; union { UnionParsedType TypeRep; Decl *DeclRep; Expr *ExprRep; }; // attributes. ParsedAttributes Attrs; // Scope specifier for the type spec, if applicable. CXXScopeSpec TypeScope; // List of protocol qualifiers for objective-c classes. Used for // protocol-qualified interfaces "NString<foo>" and protocol-qualified id // "id<foo>". Decl * const *ProtocolQualifiers; unsigned NumProtocolQualifiers; SourceLocation ProtocolLAngleLoc; SourceLocation *ProtocolLocs; // SourceLocation info. These are null if the item wasn't specified or if // the setting was synthesized. SourceRange Range; SourceLocation StorageClassSpecLoc, SCS_threadLoc; SourceLocation TSWLoc, TSCLoc, TSSLoc, TSTLoc, AltiVecLoc; /// TSTNameLoc - If TypeSpecType is any of class, enum, struct, union, /// typename, then this is the location of the named type (if present); /// otherwise, it is the same as TSTLoc. Hence, the pair TSTLoc and /// TSTNameLoc provides source range info for tag types. SourceLocation TSTNameLoc; SourceRange TypeofParensRange; SourceLocation TQ_constLoc, TQ_restrictLoc, TQ_volatileLoc; SourceLocation FS_inlineLoc, FS_virtualLoc, FS_explicitLoc; SourceLocation FriendLoc, ModulePrivateLoc, ConstexprLoc; WrittenBuiltinSpecs writtenBS; void SaveWrittenBuiltinSpecs(); void SaveStorageSpecifierAsWritten(); ObjCDeclSpec *ObjCQualifiers; static bool isTypeRep(TST T) { return (T == TST_typename || T == TST_typeofType || T == TST_underlyingType || T == TST_atomic); } static bool isExprRep(TST T) { return (T == TST_typeofExpr || T == TST_decltype); } static bool isDeclRep(TST T) { return (T == TST_enum || T == TST_struct || T == TST_union || T == TST_class); } DeclSpec(const DeclSpec&); // DO NOT IMPLEMENT void operator=(const DeclSpec&); // DO NOT IMPLEMENT public: DeclSpec(AttributeFactory &attrFactory) : StorageClassSpec(SCS_unspecified), SCS_thread_specified(false), SCS_extern_in_linkage_spec(false), TypeSpecWidth(TSW_unspecified), TypeSpecComplex(TSC_unspecified), TypeSpecSign(TSS_unspecified), TypeSpecType(TST_unspecified), TypeAltiVecVector(false), TypeAltiVecPixel(false), TypeAltiVecBool(false), TypeSpecOwned(false), TypeQualifiers(TQ_unspecified), FS_inline_specified(false), FS_virtual_specified(false), FS_explicit_specified(false), Friend_specified(false), Constexpr_specified(false), StorageClassSpecAsWritten(SCS_unspecified), Attrs(attrFactory), ProtocolQualifiers(0), NumProtocolQualifiers(0), ProtocolLocs(0), writtenBS(), ObjCQualifiers(0) { } ~DeclSpec() { delete [] ProtocolQualifiers; delete [] ProtocolLocs; } // storage-class-specifier SCS getStorageClassSpec() const { return (SCS)StorageClassSpec; } bool isThreadSpecified() const { return SCS_thread_specified; } bool isExternInLinkageSpec() const { return SCS_extern_in_linkage_spec; } void setExternInLinkageSpec(bool Value) { SCS_extern_in_linkage_spec = Value; } SourceLocation getStorageClassSpecLoc() const { return StorageClassSpecLoc; } SourceLocation getThreadSpecLoc() const { return SCS_threadLoc; } void ClearStorageClassSpecs() { StorageClassSpec = DeclSpec::SCS_unspecified; SCS_thread_specified = false; SCS_extern_in_linkage_spec = false; StorageClassSpecLoc = SourceLocation(); SCS_threadLoc = SourceLocation(); } // type-specifier TSW getTypeSpecWidth() const { return (TSW)TypeSpecWidth; } TSC getTypeSpecComplex() const { return (TSC)TypeSpecComplex; } TSS getTypeSpecSign() const { return (TSS)TypeSpecSign; } TST getTypeSpecType() const { return (TST)TypeSpecType; } bool isTypeAltiVecVector() const { return TypeAltiVecVector; } bool isTypeAltiVecPixel() const { return TypeAltiVecPixel; } bool isTypeAltiVecBool() const { return TypeAltiVecBool; } bool isTypeSpecOwned() const { return TypeSpecOwned; } ParsedType getRepAsType() const { assert(isTypeRep((TST) TypeSpecType) && "DeclSpec does not store a type"); return TypeRep; } Decl *getRepAsDecl() const { assert(isDeclRep((TST) TypeSpecType) && "DeclSpec does not store a decl"); return DeclRep; } Expr *getRepAsExpr() const { assert(isExprRep((TST) TypeSpecType) && "DeclSpec does not store an expr"); return ExprRep; } CXXScopeSpec &getTypeSpecScope() { return TypeScope; } const CXXScopeSpec &getTypeSpecScope() const { return TypeScope; } const SourceRange &getSourceRange() const LLVM_READONLY { return Range; } SourceLocation getLocStart() const LLVM_READONLY { return Range.getBegin(); } SourceLocation getLocEnd() const LLVM_READONLY { return Range.getEnd(); } SourceLocation getTypeSpecWidthLoc() const { return TSWLoc; } SourceLocation getTypeSpecComplexLoc() const { return TSCLoc; } SourceLocation getTypeSpecSignLoc() const { return TSSLoc; } SourceLocation getTypeSpecTypeLoc() const { return TSTLoc; } SourceLocation getAltiVecLoc() const { return AltiVecLoc; } SourceLocation getTypeSpecTypeNameLoc() const { assert(isDeclRep((TST) TypeSpecType) || TypeSpecType == TST_typename); return TSTNameLoc; } SourceRange getTypeofParensRange() const { return TypeofParensRange; } void setTypeofParensRange(SourceRange range) { TypeofParensRange = range; } /// getSpecifierName - Turn a type-specifier-type into a string like "_Bool" /// or "union". static const char *getSpecifierName(DeclSpec::TST T); static const char *getSpecifierName(DeclSpec::TQ Q); static const char *getSpecifierName(DeclSpec::TSS S); static const char *getSpecifierName(DeclSpec::TSC C); static const char *getSpecifierName(DeclSpec::TSW W); static const char *getSpecifierName(DeclSpec::SCS S); // type-qualifiers /// getTypeQualifiers - Return a set of TQs. unsigned getTypeQualifiers() const { return TypeQualifiers; } SourceLocation getConstSpecLoc() const { return TQ_constLoc; } SourceLocation getRestrictSpecLoc() const { return TQ_restrictLoc; } SourceLocation getVolatileSpecLoc() const { return TQ_volatileLoc; } /// \brief Clear out all of the type qualifiers. void ClearTypeQualifiers() { TypeQualifiers = 0; TQ_constLoc = SourceLocation(); TQ_restrictLoc = SourceLocation(); TQ_volatileLoc = SourceLocation(); } // function-specifier bool isInlineSpecified() const { return FS_inline_specified; } SourceLocation getInlineSpecLoc() const { return FS_inlineLoc; } bool isVirtualSpecified() const { return FS_virtual_specified; } SourceLocation getVirtualSpecLoc() const { return FS_virtualLoc; } bool isExplicitSpecified() const { return FS_explicit_specified; } SourceLocation getExplicitSpecLoc() const { return FS_explicitLoc; } void ClearFunctionSpecs() { FS_inline_specified = false; FS_inlineLoc = SourceLocation(); FS_virtual_specified = false; FS_virtualLoc = SourceLocation(); FS_explicit_specified = false; FS_explicitLoc = SourceLocation(); } /// hasTypeSpecifier - Return true if any type-specifier has been found. bool hasTypeSpecifier() const { return getTypeSpecType() != DeclSpec::TST_unspecified || getTypeSpecWidth() != DeclSpec::TSW_unspecified || getTypeSpecComplex() != DeclSpec::TSC_unspecified || getTypeSpecSign() != DeclSpec::TSS_unspecified; } /// getParsedSpecifiers - Return a bitmask of which flavors of specifiers this /// DeclSpec includes. /// unsigned getParsedSpecifiers() const; SCS getStorageClassSpecAsWritten() const { return (SCS)StorageClassSpecAsWritten; } /// isEmpty - Return true if this declaration specifier is completely empty: /// no tokens were parsed in the production of it. bool isEmpty() const { return getParsedSpecifiers() == DeclSpec::PQ_None; } void SetRangeStart(SourceLocation Loc) { Range.setBegin(Loc); } void SetRangeEnd(SourceLocation Loc) { Range.setEnd(Loc); } /// These methods set the specified attribute of the DeclSpec and /// return false if there was no error. If an error occurs (for /// example, if we tried to set "auto" on a spec with "extern" /// already set), they return true and set PrevSpec and DiagID /// such that /// Diag(Loc, DiagID) << PrevSpec; /// will yield a useful result. /// /// TODO: use a more general approach that still allows these /// diagnostics to be ignored when desired. bool SetStorageClassSpec(Sema &S, SCS SC, SourceLocation Loc, const char *&PrevSpec, unsigned &DiagID); bool SetStorageClassSpecThread(SourceLocation Loc, const char *&PrevSpec, unsigned &DiagID); bool SetTypeSpecWidth(TSW W, SourceLocation Loc, const char *&PrevSpec, unsigned &DiagID); bool SetTypeSpecComplex(TSC C, SourceLocation Loc, const char *&PrevSpec, unsigned &DiagID); bool SetTypeSpecSign(TSS S, SourceLocation Loc, const char *&PrevSpec, unsigned &DiagID); bool SetTypeSpecType(TST T, SourceLocation Loc, const char *&PrevSpec, unsigned &DiagID); bool SetTypeSpecType(TST T, SourceLocation Loc, const char *&PrevSpec, unsigned &DiagID, ParsedType Rep); bool SetTypeSpecType(TST T, SourceLocation Loc, const char *&PrevSpec, unsigned &DiagID, Decl *Rep, bool Owned); bool SetTypeSpecType(TST T, SourceLocation TagKwLoc, SourceLocation TagNameLoc, const char *&PrevSpec, unsigned &DiagID, ParsedType Rep); bool SetTypeSpecType(TST T, SourceLocation TagKwLoc, SourceLocation TagNameLoc, const char *&PrevSpec, unsigned &DiagID, Decl *Rep, bool Owned); bool SetTypeSpecType(TST T, SourceLocation Loc, const char *&PrevSpec, unsigned &DiagID, Expr *Rep); bool SetTypeAltiVecVector(bool isAltiVecVector, SourceLocation Loc, const char *&PrevSpec, unsigned &DiagID); bool SetTypeAltiVecPixel(bool isAltiVecPixel, SourceLocation Loc, const char *&PrevSpec, unsigned &DiagID); bool SetTypeSpecError(); void UpdateDeclRep(Decl *Rep) { assert(isDeclRep((TST) TypeSpecType)); DeclRep = Rep; } void UpdateTypeRep(ParsedType Rep) { assert(isTypeRep((TST) TypeSpecType)); TypeRep = Rep; } void UpdateExprRep(Expr *Rep) { assert(isExprRep((TST) TypeSpecType)); ExprRep = Rep; } bool SetTypeQual(TQ T, SourceLocation Loc, const char *&PrevSpec, unsigned &DiagID, const LangOptions &Lang); bool SetFunctionSpecInline(SourceLocation Loc, const char *&PrevSpec, unsigned &DiagID); bool SetFunctionSpecVirtual(SourceLocation Loc, const char *&PrevSpec, unsigned &DiagID); bool SetFunctionSpecExplicit(SourceLocation Loc, const char *&PrevSpec, unsigned &DiagID); bool SetFriendSpec(SourceLocation Loc, const char *&PrevSpec, unsigned &DiagID); bool setModulePrivateSpec(SourceLocation Loc, const char *&PrevSpec, unsigned &DiagID); bool SetConstexprSpec(SourceLocation Loc, const char *&PrevSpec, unsigned &DiagID); bool isFriendSpecified() const { return Friend_specified; } SourceLocation getFriendSpecLoc() const { return FriendLoc; } bool isModulePrivateSpecified() const { return ModulePrivateLoc.isValid(); } SourceLocation getModulePrivateSpecLoc() const { return ModulePrivateLoc; } bool isConstexprSpecified() const { return Constexpr_specified; } SourceLocation getConstexprSpecLoc() const { return ConstexprLoc; } void ClearConstexprSpec() { Constexpr_specified = false; ConstexprLoc = SourceLocation(); } AttributePool &getAttributePool() const { return Attrs.getPool(); } /// AddAttributes - contatenates two attribute lists. /// The GCC attribute syntax allows for the following: /// /// short __attribute__(( unused, deprecated )) /// int __attribute__(( may_alias, aligned(16) )) var; /// /// This declares 4 attributes using 2 lists. The following syntax is /// also allowed and equivalent to the previous declaration. /// /// short __attribute__((unused)) __attribute__((deprecated)) /// int __attribute__((may_alias)) __attribute__((aligned(16))) var; /// void addAttributes(AttributeList *AL) { Attrs.addAll(AL); } void setAttributes(AttributeList *AL) { Attrs.set(AL); } bool hasAttributes() const { return !Attrs.empty(); } ParsedAttributes &getAttributes() { return Attrs; } const ParsedAttributes &getAttributes() const { return Attrs; } /// TakeAttributes - Return the current attribute list and remove them from /// the DeclSpec so that it doesn't own them. ParsedAttributes takeAttributes() { // The non-const "copy" constructor clears the operand automatically. return Attrs; } void takeAttributesFrom(ParsedAttributes &attrs) { Attrs.takeAllFrom(attrs); } typedef Decl * const *ProtocolQualifierListTy; ProtocolQualifierListTy getProtocolQualifiers() const { return ProtocolQualifiers; } SourceLocation *getProtocolLocs() const { return ProtocolLocs; } unsigned getNumProtocolQualifiers() const { return NumProtocolQualifiers; } SourceLocation getProtocolLAngleLoc() const { return ProtocolLAngleLoc; } void setProtocolQualifiers(Decl * const *Protos, unsigned NP, SourceLocation *ProtoLocs, SourceLocation LAngleLoc); /// Finish - This does final analysis of the declspec, issuing diagnostics for /// things like "_Imaginary" (lacking an FP type). After calling this method, /// DeclSpec is guaranteed self-consistent, even if an error occurred. void Finish(DiagnosticsEngine &D, Preprocessor &PP); const WrittenBuiltinSpecs& getWrittenBuiltinSpecs() const { return writtenBS; } ObjCDeclSpec *getObjCQualifiers() const { return ObjCQualifiers; } void setObjCQualifiers(ObjCDeclSpec *quals) { ObjCQualifiers = quals; } /// isMissingDeclaratorOk - This checks if this DeclSpec can stand alone, /// without a Declarator. Only tag declspecs can stand alone. bool isMissingDeclaratorOk(); }; /// ObjCDeclSpec - This class captures information about /// "declaration specifiers" specific to objective-c class ObjCDeclSpec { public: /// ObjCDeclQualifier - Qualifier used on types in method /// declarations. Not all combinations are sensible. Parameters /// can be one of { in, out, inout } with one of { bycopy, byref }. /// Returns can either be { oneway } or not. /// /// This should be kept in sync with Decl::ObjCDeclQualifier. enum ObjCDeclQualifier { DQ_None = 0x0, DQ_In = 0x1, DQ_Inout = 0x2, DQ_Out = 0x4, DQ_Bycopy = 0x8, DQ_Byref = 0x10, DQ_Oneway = 0x20 }; /// PropertyAttributeKind - list of property attributes. enum ObjCPropertyAttributeKind { DQ_PR_noattr = 0x0, DQ_PR_readonly = 0x01, DQ_PR_getter = 0x02, DQ_PR_assign = 0x04, DQ_PR_readwrite = 0x08, DQ_PR_retain = 0x10, DQ_PR_copy = 0x20, DQ_PR_nonatomic = 0x40, DQ_PR_setter = 0x80, DQ_PR_atomic = 0x100, DQ_PR_weak = 0x200, DQ_PR_strong = 0x400, DQ_PR_unsafe_unretained = 0x800 }; ObjCDeclSpec() : objcDeclQualifier(DQ_None), PropertyAttributes(DQ_PR_noattr), GetterName(0), SetterName(0) { } ObjCDeclQualifier getObjCDeclQualifier() const { return objcDeclQualifier; } void setObjCDeclQualifier(ObjCDeclQualifier DQVal) { objcDeclQualifier = (ObjCDeclQualifier) (objcDeclQualifier | DQVal); } ObjCPropertyAttributeKind getPropertyAttributes() const { return ObjCPropertyAttributeKind(PropertyAttributes); } void setPropertyAttributes(ObjCPropertyAttributeKind PRVal) { PropertyAttributes = (ObjCPropertyAttributeKind)(PropertyAttributes | PRVal); } const IdentifierInfo *getGetterName() const { return GetterName; } IdentifierInfo *getGetterName() { return GetterName; } void setGetterName(IdentifierInfo *name) { GetterName = name; } const IdentifierInfo *getSetterName() const { return SetterName; } IdentifierInfo *getSetterName() { return SetterName; } void setSetterName(IdentifierInfo *name) { SetterName = name; } private: // FIXME: These two are unrelated and mutially exclusive. So perhaps // we can put them in a union to reflect their mutual exclusiveness // (space saving is negligible). ObjCDeclQualifier objcDeclQualifier : 6; // NOTE: VC++ treats enums as signed, avoid using ObjCPropertyAttributeKind unsigned PropertyAttributes : 12; IdentifierInfo *GetterName; // getter name of NULL if no getter IdentifierInfo *SetterName; // setter name of NULL if no setter }; /// \brief Represents a C++ unqualified-id that has been parsed. class UnqualifiedId { private: const UnqualifiedId &operator=(const UnqualifiedId &); // DO NOT IMPLEMENT public: /// \brief Describes the kind of unqualified-id parsed. enum IdKind { /// \brief An identifier. IK_Identifier, /// \brief An overloaded operator name, e.g., operator+. IK_OperatorFunctionId, /// \brief A conversion function name, e.g., operator int. IK_ConversionFunctionId, /// \brief A user-defined literal name, e.g., operator "" _i. IK_LiteralOperatorId, /// \brief A constructor name. IK_ConstructorName, /// \brief A constructor named via a template-id. IK_ConstructorTemplateId, /// \brief A destructor name. IK_DestructorName, /// \brief A template-id, e.g., f<int>. IK_TemplateId, /// \brief An implicit 'self' parameter IK_ImplicitSelfParam } Kind; /// \brief Anonymous union that holds extra data associated with the /// parsed unqualified-id. union { /// \brief When Kind == IK_Identifier, the parsed identifier, or when Kind /// == IK_UserLiteralId, the identifier suffix. IdentifierInfo *Identifier; /// \brief When Kind == IK_OperatorFunctionId, the overloaded operator /// that we parsed. struct { /// \brief The kind of overloaded operator. OverloadedOperatorKind Operator; /// \brief The source locations of the individual tokens that name /// the operator, e.g., the "new", "[", and "]" tokens in /// operator new []. /// /// Different operators have different numbers of tokens in their name, /// up to three. Any remaining source locations in this array will be /// set to an invalid value for operators with fewer than three tokens. unsigned SymbolLocations[3]; } OperatorFunctionId; /// \brief When Kind == IK_ConversionFunctionId, the type that the /// conversion function names. UnionParsedType ConversionFunctionId; /// \brief When Kind == IK_ConstructorName, the class-name of the type /// whose constructor is being referenced. UnionParsedType ConstructorName; /// \brief When Kind == IK_DestructorName, the type referred to by the /// class-name. UnionParsedType DestructorName; /// \brief When Kind == IK_TemplateId or IK_ConstructorTemplateId, /// the template-id annotation that contains the template name and /// template arguments. TemplateIdAnnotation *TemplateId; }; /// \brief The location of the first token that describes this unqualified-id, /// which will be the location of the identifier, "operator" keyword, /// tilde (for a destructor), or the template name of a template-id. SourceLocation StartLocation; /// \brief The location of the last token that describes this unqualified-id. SourceLocation EndLocation; UnqualifiedId() : Kind(IK_Identifier), Identifier(0) { } /// \brief Do not use this copy constructor. It is temporary, and only /// exists because we are holding FieldDeclarators in a SmallVector when we /// don't actually need them. /// /// FIXME: Kill this copy constructor. UnqualifiedId(const UnqualifiedId &Other) : Kind(IK_Identifier), Identifier(Other.Identifier), StartLocation(Other.StartLocation), EndLocation(Other.EndLocation) { assert(Other.Kind == IK_Identifier && "Cannot copy non-identifiers"); } /// \brief Destroy this unqualified-id. ~UnqualifiedId() { clear(); } /// \brief Clear out this unqualified-id, setting it to default (invalid) /// state. void clear(); /// \brief Determine whether this unqualified-id refers to a valid name. bool isValid() const { return StartLocation.isValid(); } /// \brief Determine whether this unqualified-id refers to an invalid name. bool isInvalid() const { return !isValid(); } /// \brief Determine what kind of name we have. IdKind getKind() const { return Kind; } void setKind(IdKind kind) { Kind = kind; } /// \brief Specify that this unqualified-id was parsed as an identifier. /// /// \param Id the parsed identifier. /// \param IdLoc the location of the parsed identifier. void setIdentifier(const IdentifierInfo *Id, SourceLocation IdLoc) { Kind = IK_Identifier; Identifier = const_cast<IdentifierInfo *>(Id); StartLocation = EndLocation = IdLoc; } /// \brief Specify that this unqualified-id was parsed as an /// operator-function-id. /// /// \param OperatorLoc the location of the 'operator' keyword. /// /// \param Op the overloaded operator. /// /// \param SymbolLocations the locations of the individual operator symbols /// in the operator. void setOperatorFunctionId(SourceLocation OperatorLoc, OverloadedOperatorKind Op, SourceLocation SymbolLocations[3]); /// \brief Specify that this unqualified-id was parsed as a /// conversion-function-id. /// /// \param OperatorLoc the location of the 'operator' keyword. /// /// \param Ty the type to which this conversion function is converting. /// /// \param EndLoc the location of the last token that makes up the type name. void setConversionFunctionId(SourceLocation OperatorLoc, ParsedType Ty, SourceLocation EndLoc) { Kind = IK_ConversionFunctionId; StartLocation = OperatorLoc; EndLocation = EndLoc; ConversionFunctionId = Ty; } /// \brief Specific that this unqualified-id was parsed as a /// literal-operator-id. /// /// \param Id the parsed identifier. /// /// \param OpLoc the location of the 'operator' keyword. /// /// \param IdLoc the location of the identifier. void setLiteralOperatorId(const IdentifierInfo *Id, SourceLocation OpLoc, SourceLocation IdLoc) { Kind = IK_LiteralOperatorId; Identifier = const_cast<IdentifierInfo *>(Id); StartLocation = OpLoc; EndLocation = IdLoc; } /// \brief Specify that this unqualified-id was parsed as a constructor name. /// /// \param ClassType the class type referred to by the constructor name. /// /// \param ClassNameLoc the location of the class name. /// /// \param EndLoc the location of the last token that makes up the type name. void setConstructorName(ParsedType ClassType, SourceLocation ClassNameLoc, SourceLocation EndLoc) { Kind = IK_ConstructorName; StartLocation = ClassNameLoc; EndLocation = EndLoc; ConstructorName = ClassType; } /// \brief Specify that this unqualified-id was parsed as a /// template-id that names a constructor. /// /// \param TemplateId the template-id annotation that describes the parsed /// template-id. This UnqualifiedId instance will take ownership of the /// \p TemplateId and will free it on destruction. void setConstructorTemplateId(TemplateIdAnnotation *TemplateId); /// \brief Specify that this unqualified-id was parsed as a destructor name. /// /// \param TildeLoc the location of the '~' that introduces the destructor /// name. /// /// \param ClassType the name of the class referred to by the destructor name. void setDestructorName(SourceLocation TildeLoc, ParsedType ClassType, SourceLocation EndLoc) { Kind = IK_DestructorName; StartLocation = TildeLoc; EndLocation = EndLoc; DestructorName = ClassType; } /// \brief Specify that this unqualified-id was parsed as a template-id. /// /// \param TemplateId the template-id annotation that describes the parsed /// template-id. This UnqualifiedId instance will take ownership of the /// \p TemplateId and will free it on destruction. void setTemplateId(TemplateIdAnnotation *TemplateId); /// \brief Return the source range that covers this unqualified-id. SourceRange getSourceRange() const LLVM_READONLY { return SourceRange(StartLocation, EndLocation); } SourceLocation getLocStart() const LLVM_READONLY { return StartLocation; } SourceLocation getLocEnd() const LLVM_READONLY { return EndLocation; } }; /// CachedTokens - A set of tokens that has been cached for later /// parsing. typedef SmallVector<Token, 4> CachedTokens; /// DeclaratorChunk - One instance of this struct is used for each type in a /// declarator that is parsed. /// /// This is intended to be a small value object. struct DeclaratorChunk { enum { Pointer, Reference, Array, Function, BlockPointer, MemberPointer, Paren } Kind; /// Loc - The place where this type was defined. SourceLocation Loc; /// EndLoc - If valid, the place where this chunck ends. SourceLocation EndLoc; struct TypeInfoCommon { AttributeList *AttrList; }; struct PointerTypeInfo : TypeInfoCommon { /// The type qualifiers: const/volatile/restrict. unsigned TypeQuals : 3; /// The location of the const-qualifier, if any. unsigned ConstQualLoc; /// The location of the volatile-qualifier, if any. unsigned VolatileQualLoc; /// The location of the restrict-qualifier, if any. unsigned RestrictQualLoc; void destroy() { } }; struct ReferenceTypeInfo : TypeInfoCommon { /// The type qualifier: restrict. [GNU] C++ extension bool HasRestrict : 1; /// True if this is an lvalue reference, false if it's an rvalue reference. bool LValueRef : 1; void destroy() { } }; struct ArrayTypeInfo : TypeInfoCommon { /// The type qualifiers for the array: const/volatile/restrict. unsigned TypeQuals : 3; /// True if this dimension included the 'static' keyword. bool hasStatic : 1; /// True if this dimension was [*]. In this case, NumElts is null. bool isStar : 1; /// This is the size of the array, or null if [] or [*] was specified. /// Since the parser is multi-purpose, and we don't want to impose a root /// expression class on all clients, NumElts is untyped. Expr *NumElts; void destroy() {} }; /// ParamInfo - An array of paraminfo objects is allocated whenever a function /// declarator is parsed. There are two interesting styles of arguments here: /// K&R-style identifier lists and parameter type lists. K&R-style identifier /// lists will have information about the identifier, but no type information. /// Parameter type lists will have type info (if the actions module provides /// it), but may have null identifier info: e.g. for 'void foo(int X, int)'. struct ParamInfo { IdentifierInfo *Ident; SourceLocation IdentLoc; Decl *Param; /// DefaultArgTokens - When the parameter's default argument /// cannot be parsed immediately (because it occurs within the /// declaration of a member function), it will be stored here as a /// sequence of tokens to be parsed once the class definition is /// complete. Non-NULL indicates that there is a default argument. CachedTokens *DefaultArgTokens; ParamInfo() {} ParamInfo(IdentifierInfo *ident, SourceLocation iloc, Decl *param, CachedTokens *DefArgTokens = 0) : Ident(ident), IdentLoc(iloc), Param(param), DefaultArgTokens(DefArgTokens) {} }; struct TypeAndRange { ParsedType Ty; SourceRange Range; }; struct FunctionTypeInfo : TypeInfoCommon { /// hasPrototype - This is true if the function had at least one typed /// argument. If the function is () or (a,b,c), then it has no prototype, /// and is treated as a K&R-style function. unsigned hasPrototype : 1; /// isVariadic - If this function has a prototype, and if that /// proto ends with ',...)', this is true. When true, EllipsisLoc /// contains the location of the ellipsis. unsigned isVariadic : 1; /// \brief Whether the ref-qualifier (if any) is an lvalue reference. /// Otherwise, it's an rvalue reference. unsigned RefQualifierIsLValueRef : 1; /// The type qualifiers: const/volatile/restrict. /// The qualifier bitmask values are the same as in QualType. unsigned TypeQuals : 3; /// ExceptionSpecType - An ExceptionSpecificationType value. unsigned ExceptionSpecType : 3; /// DeleteArgInfo - If this is true, we need to delete[] ArgInfo. unsigned DeleteArgInfo : 1; /// When isVariadic is true, the location of the ellipsis in the source. unsigned EllipsisLoc; /// NumArgs - This is the number of formal arguments provided for the /// declarator. unsigned NumArgs; /// NumExceptions - This is the number of types in the dynamic-exception- /// decl, if the function has one. unsigned NumExceptions; /// \brief The location of the ref-qualifier, if any. /// /// If this is an invalid location, there is no ref-qualifier. unsigned RefQualifierLoc; /// \brief The location of the const-qualifier, if any. /// /// If this is an invalid location, there is no const-qualifier. unsigned ConstQualifierLoc; /// \brief The location of the volatile-qualifier, if any. /// /// If this is an invalid location, there is no volatile-qualifier. unsigned VolatileQualifierLoc; /// \brief The location of the 'mutable' qualifer in a lambda-declarator, if /// any. unsigned MutableLoc; /// \brief When ExceptionSpecType isn't EST_None or EST_Delayed, the /// location of the keyword introducing the spec. unsigned ExceptionSpecLoc; /// ArgInfo - This is a pointer to a new[]'d array of ParamInfo objects that /// describe the arguments for this function declarator. This is null if /// there are no arguments specified. ParamInfo *ArgInfo; union { /// \brief Pointer to a new[]'d array of TypeAndRange objects that /// contain the types in the function's dynamic exception specification /// and their locations, if there is one. TypeAndRange *Exceptions; /// \brief Pointer to the expression in the noexcept-specifier of this /// function, if it has one. Expr *NoexceptExpr; }; /// TrailingReturnType - If this isn't null, it's the trailing return type /// specified. This is actually a ParsedType, but stored as void* to /// allow union storage. void *TrailingReturnType; /// freeArgs - reset the argument list to having zero arguments. This is /// used in various places for error recovery. void freeArgs() { if (DeleteArgInfo) { delete[] ArgInfo; DeleteArgInfo = false; } NumArgs = 0; } void destroy() { if (DeleteArgInfo) delete[] ArgInfo; if (getExceptionSpecType() == EST_Dynamic) delete[] Exceptions; } /// isKNRPrototype - Return true if this is a K&R style identifier list, /// like "void foo(a,b,c)". In a function definition, this will be followed /// by the argument type definitions. bool isKNRPrototype() const { return !hasPrototype && NumArgs != 0; } SourceLocation getEllipsisLoc() const { return SourceLocation::getFromRawEncoding(EllipsisLoc); } SourceLocation getExceptionSpecLoc() const { return SourceLocation::getFromRawEncoding(ExceptionSpecLoc); } /// \brief Retrieve the location of the ref-qualifier, if any. SourceLocation getRefQualifierLoc() const { return SourceLocation::getFromRawEncoding(RefQualifierLoc); } /// \brief Retrieve the location of the ref-qualifier, if any. SourceLocation getConstQualifierLoc() const { return SourceLocation::getFromRawEncoding(ConstQualifierLoc); } /// \brief Retrieve the location of the ref-qualifier, if any. SourceLocation getVolatileQualifierLoc() const { return SourceLocation::getFromRawEncoding(VolatileQualifierLoc); } /// \brief Retrieve the location of the 'mutable' qualifier, if any. SourceLocation getMutableLoc() const { return SourceLocation::getFromRawEncoding(MutableLoc); } /// \brief Determine whether this function declaration contains a /// ref-qualifier. bool hasRefQualifier() const { return getRefQualifierLoc().isValid(); } /// \brief Determine whether this lambda-declarator contains a 'mutable' /// qualifier. bool hasMutableQualifier() const { return getMutableLoc().isValid(); } /// \brief Get the type of exception specification this function has. ExceptionSpecificationType getExceptionSpecType() const { return static_cast<ExceptionSpecificationType>(ExceptionSpecType); } }; struct BlockPointerTypeInfo : TypeInfoCommon { /// For now, sema will catch these as invalid. /// The type qualifiers: const/volatile/restrict. unsigned TypeQuals : 3; void destroy() { } }; struct MemberPointerTypeInfo : TypeInfoCommon { /// The type qualifiers: const/volatile/restrict. unsigned TypeQuals : 3; // CXXScopeSpec has a constructor, so it can't be a direct member. // So we need some pointer-aligned storage and a bit of trickery. union { void *Aligner; char Mem[sizeof(CXXScopeSpec)]; } ScopeMem; CXXScopeSpec &Scope() { return *reinterpret_cast<CXXScopeSpec*>(ScopeMem.Mem); } const CXXScopeSpec &Scope() const { return *reinterpret_cast<const CXXScopeSpec*>(ScopeMem.Mem); } void destroy() { Scope().~CXXScopeSpec(); } }; union { TypeInfoCommon Common; PointerTypeInfo Ptr; ReferenceTypeInfo Ref; ArrayTypeInfo Arr; FunctionTypeInfo Fun; BlockPointerTypeInfo Cls; MemberPointerTypeInfo Mem; }; void destroy() { switch (Kind) { case DeclaratorChunk::Function: return Fun.destroy(); case DeclaratorChunk::Pointer: return Ptr.destroy(); case DeclaratorChunk::BlockPointer: return Cls.destroy(); case DeclaratorChunk::Reference: return Ref.destroy(); case DeclaratorChunk::Array: return Arr.destroy(); case DeclaratorChunk::MemberPointer: return Mem.destroy(); case DeclaratorChunk::Paren: return; } } /// getAttrs - If there are attributes applied to this declaratorchunk, return /// them. const AttributeList *getAttrs() const { return Common.AttrList; } AttributeList *&getAttrListRef() { return Common.AttrList; } /// getPointer - Return a DeclaratorChunk for a pointer. /// static DeclaratorChunk getPointer(unsigned TypeQuals, SourceLocation Loc, SourceLocation ConstQualLoc, SourceLocation VolatileQualLoc, SourceLocation RestrictQualLoc) { DeclaratorChunk I; I.Kind = Pointer; I.Loc = Loc; I.Ptr.TypeQuals = TypeQuals; I.Ptr.ConstQualLoc = ConstQualLoc.getRawEncoding(); I.Ptr.VolatileQualLoc = VolatileQualLoc.getRawEncoding(); I.Ptr.RestrictQualLoc = RestrictQualLoc.getRawEncoding(); I.Ptr.AttrList = 0; return I; } /// getReference - Return a DeclaratorChunk for a reference. /// static DeclaratorChunk getReference(unsigned TypeQuals, SourceLocation Loc, bool lvalue) { DeclaratorChunk I; I.Kind = Reference; I.Loc = Loc; I.Ref.HasRestrict = (TypeQuals & DeclSpec::TQ_restrict) != 0; I.Ref.LValueRef = lvalue; I.Ref.AttrList = 0; return I; } /// getArray - Return a DeclaratorChunk for an array. /// static DeclaratorChunk getArray(unsigned TypeQuals, bool isStatic, bool isStar, Expr *NumElts, SourceLocation LBLoc, SourceLocation RBLoc) { DeclaratorChunk I; I.Kind = Array; I.Loc = LBLoc; I.EndLoc = RBLoc; I.Arr.AttrList = 0; I.Arr.TypeQuals = TypeQuals; I.Arr.hasStatic = isStatic; I.Arr.isStar = isStar; I.Arr.NumElts = NumElts; return I; } /// DeclaratorChunk::getFunction - Return a DeclaratorChunk for a function. /// "TheDeclarator" is the declarator that this will be added to. static DeclaratorChunk getFunction(bool hasProto, bool isVariadic, SourceLocation EllipsisLoc, ParamInfo *ArgInfo, unsigned NumArgs, unsigned TypeQuals, bool RefQualifierIsLvalueRef, SourceLocation RefQualifierLoc, SourceLocation ConstQualifierLoc, SourceLocation VolatileQualifierLoc, SourceLocation MutableLoc, ExceptionSpecificationType ESpecType, SourceLocation ESpecLoc, ParsedType *Exceptions, SourceRange *ExceptionRanges, unsigned NumExceptions, Expr *NoexceptExpr, SourceLocation LocalRangeBegin, SourceLocation LocalRangeEnd, Declarator &TheDeclarator, ParsedType TrailingReturnType = ParsedType()); /// getBlockPointer - Return a DeclaratorChunk for a block. /// static DeclaratorChunk getBlockPointer(unsigned TypeQuals, SourceLocation Loc) { DeclaratorChunk I; I.Kind = BlockPointer; I.Loc = Loc; I.Cls.TypeQuals = TypeQuals; I.Cls.AttrList = 0; return I; } static DeclaratorChunk getMemberPointer(const CXXScopeSpec &SS, unsigned TypeQuals, SourceLocation Loc) { DeclaratorChunk I; I.Kind = MemberPointer; I.Loc = Loc; I.Mem.TypeQuals = TypeQuals; I.Mem.AttrList = 0; new (I.Mem.ScopeMem.Mem) CXXScopeSpec(SS); return I; } /// getParen - Return a DeclaratorChunk for a paren. /// static DeclaratorChunk getParen(SourceLocation LParenLoc, SourceLocation RParenLoc) { DeclaratorChunk I; I.Kind = Paren; I.Loc = LParenLoc; I.EndLoc = RParenLoc; I.Common.AttrList = 0; return I; } }; /// \brief Described the kind of function definition (if any) provided for /// a function. enum FunctionDefinitionKind { FDK_Declaration, FDK_Definition, FDK_Defaulted, FDK_Deleted }; /// Declarator - Information about one declarator, including the parsed type /// information and the identifier. When the declarator is fully formed, this /// is turned into the appropriate Decl object. /// /// Declarators come in two types: normal declarators and abstract declarators. /// Abstract declarators are used when parsing types, and don't have an /// identifier. Normal declarators do have ID's. /// /// Instances of this class should be a transient object that lives on the /// stack, not objects that are allocated in large quantities on the heap. class Declarator { public: enum TheContext { FileContext, // File scope declaration. PrototypeContext, // Within a function prototype. ObjCResultContext, // An ObjC method result type. ObjCParameterContext,// An ObjC method parameter type. KNRTypeListContext, // K&R type definition list for formals. TypeNameContext, // Abstract declarator for types. MemberContext, // Struct/Union field. BlockContext, // Declaration within a block in a function. ForContext, // Declaration within first part of a for loop. ConditionContext, // Condition declaration in a C++ if/switch/while/for. TemplateParamContext,// Within a template parameter list. CXXNewContext, // C++ new-expression. CXXCatchContext, // C++ catch exception-declaration ObjCCatchContext, // Objective-C catch exception-declaration BlockLiteralContext, // Block literal declarator. LambdaExprContext, // Lambda-expression declarator. TrailingReturnContext, // C++11 trailing-type-specifier. TemplateTypeArgContext, // Template type argument. AliasDeclContext, // C++11 alias-declaration. AliasTemplateContext // C++11 alias-declaration template. }; private: const DeclSpec &DS; CXXScopeSpec SS; UnqualifiedId Name; SourceRange Range; /// Context - Where we are parsing this declarator. /// TheContext Context; /// DeclTypeInfo - This holds each type that the declarator includes as it is /// parsed. This is pushed from the identifier out, which means that element /// #0 will be the most closely bound to the identifier, and /// DeclTypeInfo.back() will be the least closely bound. SmallVector<DeclaratorChunk, 8> DeclTypeInfo; /// InvalidType - Set by Sema::GetTypeForDeclarator(). bool InvalidType : 1; /// GroupingParens - Set by Parser::ParseParenDeclarator(). bool GroupingParens : 1; /// FunctionDefinition - Is this Declarator for a function or member /// definition and, if so, what kind? /// /// Actually a FunctionDefinitionKind. unsigned FunctionDefinition : 2; // Redeclaration - Is this Declarator is a redeclaration. bool Redeclaration : 1; /// Attrs - Attributes. ParsedAttributes Attrs; /// AsmLabel - The asm label, if specified. Expr *AsmLabel; /// InlineParams - This is a local array used for the first function decl /// chunk to avoid going to the heap for the common case when we have one /// function chunk in the declarator. DeclaratorChunk::ParamInfo InlineParams[16]; bool InlineParamsUsed; /// Extension - true if the declaration is preceded by __extension__. bool Extension : 1; /// \brief If this is the second or subsequent declarator in this declaration, /// the location of the comma before this declarator. SourceLocation CommaLoc; /// \brief If provided, the source location of the ellipsis used to describe /// this declarator as a parameter pack. SourceLocation EllipsisLoc; friend struct DeclaratorChunk; public: Declarator(const DeclSpec &ds, TheContext C) : DS(ds), Range(ds.getSourceRange()), Context(C), InvalidType(DS.getTypeSpecType() == DeclSpec::TST_error), GroupingParens(false), FunctionDefinition(FDK_Declaration), Redeclaration(false), Attrs(ds.getAttributePool().getFactory()), AsmLabel(0), InlineParamsUsed(false), Extension(false) { } ~Declarator() { clear(); } /// getDeclSpec - Return the declaration-specifier that this declarator was /// declared with. const DeclSpec &getDeclSpec() const { return DS; } /// getMutableDeclSpec - Return a non-const version of the DeclSpec. This /// should be used with extreme care: declspecs can often be shared between /// multiple declarators, so mutating the DeclSpec affects all of the /// Declarators. This should only be done when the declspec is known to not /// be shared or when in error recovery etc. DeclSpec &getMutableDeclSpec() { return const_cast<DeclSpec &>(DS); } AttributePool &getAttributePool() const { return Attrs.getPool(); } /// getCXXScopeSpec - Return the C++ scope specifier (global scope or /// nested-name-specifier) that is part of the declarator-id. const CXXScopeSpec &getCXXScopeSpec() const { return SS; } CXXScopeSpec &getCXXScopeSpec() { return SS; } /// \brief Retrieve the name specified by this declarator. UnqualifiedId &getName() { return Name; } TheContext getContext() const { return Context; } bool isPrototypeContext() const { return (Context == PrototypeContext || Context == ObjCParameterContext || Context == ObjCResultContext); } /// getSourceRange - Get the source range that spans this declarator. const SourceRange &getSourceRange() const LLVM_READONLY { return Range; } SourceLocation getLocStart() const LLVM_READONLY { return Range.getBegin(); } SourceLocation getLocEnd() const LLVM_READONLY { return Range.getEnd(); } void SetSourceRange(SourceRange R) { Range = R; } /// SetRangeBegin - Set the start of the source range to Loc, unless it's /// invalid. void SetRangeBegin(SourceLocation Loc) { if (!Loc.isInvalid()) Range.setBegin(Loc); } /// SetRangeEnd - Set the end of the source range to Loc, unless it's invalid. void SetRangeEnd(SourceLocation Loc) { if (!Loc.isInvalid()) Range.setEnd(Loc); } /// ExtendWithDeclSpec - Extend the declarator source range to include the /// given declspec, unless its location is invalid. Adopts the range start if /// the current range start is invalid. void ExtendWithDeclSpec(const DeclSpec &DS) { const SourceRange &SR = DS.getSourceRange(); if (Range.getBegin().isInvalid()) Range.setBegin(SR.getBegin()); if (!SR.getEnd().isInvalid()) Range.setEnd(SR.getEnd()); } /// clear - Reset the contents of this Declarator. void clear() { SS.clear(); Name.clear(); Range = DS.getSourceRange(); for (unsigned i = 0, e = DeclTypeInfo.size(); i != e; ++i) DeclTypeInfo[i].destroy(); DeclTypeInfo.clear(); Attrs.clear(); AsmLabel = 0; InlineParamsUsed = false; CommaLoc = SourceLocation(); EllipsisLoc = SourceLocation(); } /// mayOmitIdentifier - Return true if the identifier is either optional or /// not allowed. This is true for typenames, prototypes, and template /// parameter lists. bool mayOmitIdentifier() const { switch (Context) { case FileContext: case KNRTypeListContext: case MemberContext: case BlockContext: case ForContext: case ConditionContext: return false; case TypeNameContext: case AliasDeclContext: case AliasTemplateContext: case PrototypeContext: case ObjCParameterContext: case ObjCResultContext: case TemplateParamContext: case CXXNewContext: case CXXCatchContext: case ObjCCatchContext: case BlockLiteralContext: case LambdaExprContext: case TemplateTypeArgContext: case TrailingReturnContext: return true; } llvm_unreachable("unknown context kind!"); } /// mayHaveIdentifier - Return true if the identifier is either optional or /// required. This is true for normal declarators and prototypes, but not /// typenames. bool mayHaveIdentifier() const { switch (Context) { case FileContext: case KNRTypeListContext: case MemberContext: case BlockContext: case ForContext: case ConditionContext: case PrototypeContext: case TemplateParamContext: case CXXCatchContext: case ObjCCatchContext: return true; case TypeNameContext: case CXXNewContext: case AliasDeclContext: case AliasTemplateContext: case ObjCParameterContext: case ObjCResultContext: case BlockLiteralContext: case LambdaExprContext: case TemplateTypeArgContext: case TrailingReturnContext: return false; } llvm_unreachable("unknown context kind!"); } /// mayBeFollowedByCXXDirectInit - Return true if the declarator can be /// followed by a C++ direct initializer, e.g. "int x(1);". bool mayBeFollowedByCXXDirectInit() const { if (hasGroupingParens()) return false; if (getDeclSpec().getStorageClassSpec() == DeclSpec::SCS_typedef) return false; if (getDeclSpec().getStorageClassSpec() == DeclSpec::SCS_extern && Context != FileContext) return false; // Special names can't have direct initializers. if (Name.getKind() != UnqualifiedId::IK_Identifier) return false; switch (Context) { case FileContext: case BlockContext: case ForContext: return true; case ConditionContext: // This may not be followed by a direct initializer, but it can't be a // function declaration either, and we'd prefer to perform a tentative // parse in order to produce the right diagnostic. return true; case KNRTypeListContext: case MemberContext: case PrototypeContext: case ObjCParameterContext: case ObjCResultContext: case TemplateParamContext: case CXXCatchContext: case ObjCCatchContext: case TypeNameContext: case CXXNewContext: case AliasDeclContext: case AliasTemplateContext: case BlockLiteralContext: case LambdaExprContext: case TemplateTypeArgContext: case TrailingReturnContext: return false; } llvm_unreachable("unknown context kind!"); } /// isPastIdentifier - Return true if we have parsed beyond the point where /// the bool isPastIdentifier() const { return Name.isValid(); } /// hasName - Whether this declarator has a name, which might be an /// identifier (accessible via getIdentifier()) or some kind of /// special C++ name (constructor, destructor, etc.). bool hasName() const { return Name.getKind() != UnqualifiedId::IK_Identifier || Name.Identifier; } IdentifierInfo *getIdentifier() const { if (Name.getKind() == UnqualifiedId::IK_Identifier) return Name.Identifier; return 0; } SourceLocation getIdentifierLoc() const { return Name.StartLocation; } /// \brief Set the name of this declarator to be the given identifier. void SetIdentifier(IdentifierInfo *Id, SourceLocation IdLoc) { Name.setIdentifier(Id, IdLoc); } /// AddTypeInfo - Add a chunk to this declarator. Also extend the range to /// EndLoc, which should be the last token of the chunk. void AddTypeInfo(const DeclaratorChunk &TI, ParsedAttributes &attrs, SourceLocation EndLoc) { DeclTypeInfo.push_back(TI); DeclTypeInfo.back().getAttrListRef() = attrs.getList(); getAttributePool().takeAllFrom(attrs.getPool()); if (!EndLoc.isInvalid()) SetRangeEnd(EndLoc); } /// AddInnermostTypeInfo - Add a new innermost chunk to this declarator. void AddInnermostTypeInfo(const DeclaratorChunk &TI) { DeclTypeInfo.insert(DeclTypeInfo.begin(), TI); } /// getNumTypeObjects() - Return the number of types applied to this /// declarator. unsigned getNumTypeObjects() const { return DeclTypeInfo.size(); } /// Return the specified TypeInfo from this declarator. TypeInfo #0 is /// closest to the identifier. const DeclaratorChunk &getTypeObject(unsigned i) const { assert(i < DeclTypeInfo.size() && "Invalid type chunk"); return DeclTypeInfo[i]; } DeclaratorChunk &getTypeObject(unsigned i) { assert(i < DeclTypeInfo.size() && "Invalid type chunk"); return DeclTypeInfo[i]; } void DropFirstTypeObject() { assert(!DeclTypeInfo.empty() && "No type chunks to drop."); DeclTypeInfo.front().destroy(); DeclTypeInfo.erase(DeclTypeInfo.begin()); } /// isArrayOfUnknownBound - This method returns true if the declarator /// is a declarator for an array of unknown bound (looking through /// parentheses). bool isArrayOfUnknownBound() const { for (unsigned i = 0, i_end = DeclTypeInfo.size(); i < i_end; ++i) { switch (DeclTypeInfo[i].Kind) { case DeclaratorChunk::Paren: continue; case DeclaratorChunk::Function: case DeclaratorChunk::Pointer: case DeclaratorChunk::Reference: case DeclaratorChunk::BlockPointer: case DeclaratorChunk::MemberPointer: return false; case DeclaratorChunk::Array: return !DeclTypeInfo[i].Arr.NumElts; } llvm_unreachable("Invalid type chunk"); } return false; } /// isFunctionDeclarator - This method returns true if the declarator /// is a function declarator (looking through parentheses). /// If true is returned, then the reference type parameter idx is /// assigned with the index of the declaration chunk. bool isFunctionDeclarator(unsigned& idx) const { for (unsigned i = 0, i_end = DeclTypeInfo.size(); i < i_end; ++i) { switch (DeclTypeInfo[i].Kind) { case DeclaratorChunk::Function: idx = i; return true; case DeclaratorChunk::Paren: continue; case DeclaratorChunk::Pointer: case DeclaratorChunk::Reference: case DeclaratorChunk::Array: case DeclaratorChunk::BlockPointer: case DeclaratorChunk::MemberPointer: return false; } llvm_unreachable("Invalid type chunk"); } return false; } /// isFunctionDeclarator - Once this declarator is fully parsed and formed, /// this method returns true if the identifier is a function declarator /// (looking through parentheses). bool isFunctionDeclarator() const { unsigned index; return isFunctionDeclarator(index); } /// getFunctionTypeInfo - Retrieves the function type info object /// (looking through parentheses). DeclaratorChunk::FunctionTypeInfo &getFunctionTypeInfo() { assert(isFunctionDeclarator() && "Not a function declarator!"); unsigned index = 0; isFunctionDeclarator(index); return DeclTypeInfo[index].Fun; } /// getFunctionTypeInfo - Retrieves the function type info object /// (looking through parentheses). const DeclaratorChunk::FunctionTypeInfo &getFunctionTypeInfo() const { return const_cast<Declarator*>(this)->getFunctionTypeInfo(); } /// \brief Determine whether the declaration that will be produced from /// this declaration will be a function. /// /// A declaration can declare a function even if the declarator itself /// isn't a function declarator, if the type specifier refers to a function /// type. This routine checks for both cases. bool isDeclarationOfFunction() const; /// takeAttributes - Takes attributes from the given parsed-attributes /// set and add them to this declarator. /// /// These examples both add 3 attributes to "var": /// short int var __attribute__((aligned(16),common,deprecated)); /// short int x, __attribute__((aligned(16)) var /// __attribute__((common,deprecated)); /// /// Also extends the range of the declarator. void takeAttributes(ParsedAttributes &attrs, SourceLocation lastLoc) { Attrs.takeAllFrom(attrs); if (!lastLoc.isInvalid()) SetRangeEnd(lastLoc); } const AttributeList *getAttributes() const { return Attrs.getList(); } AttributeList *getAttributes() { return Attrs.getList(); } AttributeList *&getAttrListRef() { return Attrs.getListRef(); } /// hasAttributes - do we contain any attributes? bool hasAttributes() const { if (getAttributes() || getDeclSpec().hasAttributes()) return true; for (unsigned i = 0, e = getNumTypeObjects(); i != e; ++i) if (getTypeObject(i).getAttrs()) return true; return false; } void setAsmLabel(Expr *E) { AsmLabel = E; } Expr *getAsmLabel() const { return AsmLabel; } void setExtension(bool Val = true) { Extension = Val; } bool getExtension() const { return Extension; } void setInvalidType(bool Val = true) { InvalidType = Val; } bool isInvalidType() const { return InvalidType || DS.getTypeSpecType() == DeclSpec::TST_error; } void setGroupingParens(bool flag) { GroupingParens = flag; } bool hasGroupingParens() const { return GroupingParens; } bool isFirstDeclarator() const { return !CommaLoc.isValid(); } SourceLocation getCommaLoc() const { return CommaLoc; } void setCommaLoc(SourceLocation CL) { CommaLoc = CL; } bool hasEllipsis() const { return EllipsisLoc.isValid(); } SourceLocation getEllipsisLoc() const { return EllipsisLoc; } void setEllipsisLoc(SourceLocation EL) { EllipsisLoc = EL; } void setFunctionDefinitionKind(FunctionDefinitionKind Val) { FunctionDefinition = Val; } bool isFunctionDefinition() const { return getFunctionDefinitionKind() != FDK_Declaration; } FunctionDefinitionKind getFunctionDefinitionKind() const { return (FunctionDefinitionKind)FunctionDefinition; } void setRedeclaration(bool Val) { Redeclaration = Val; } bool isRedeclaration() const { return Redeclaration; } }; /// FieldDeclarator - This little struct is used to capture information about /// structure field declarators, which is basically just a bitfield size. struct FieldDeclarator { Declarator D; Expr *BitfieldSize; explicit FieldDeclarator(DeclSpec &DS) : D(DS, Declarator::MemberContext) { BitfieldSize = 0; } }; /// VirtSpecifiers - Represents a C++0x virt-specifier-seq. class VirtSpecifiers { public: enum Specifier { VS_None = 0, VS_Override = 1, VS_Final = 2 }; VirtSpecifiers() : Specifiers(0) { } bool SetSpecifier(Specifier VS, SourceLocation Loc, const char *&PrevSpec); bool isOverrideSpecified() const { return Specifiers & VS_Override; } SourceLocation getOverrideLoc() const { return VS_overrideLoc; } bool isFinalSpecified() const { return Specifiers & VS_Final; } SourceLocation getFinalLoc() const { return VS_finalLoc; } void clear() { Specifiers = 0; } static const char *getSpecifierName(Specifier VS); SourceLocation getLastLocation() const { return LastLocation; } private: unsigned Specifiers; SourceLocation VS_overrideLoc, VS_finalLoc; SourceLocation LastLocation; }; /// LambdaCapture - An individual capture in a lambda introducer. struct LambdaCapture { LambdaCaptureKind Kind; SourceLocation Loc; IdentifierInfo* Id; SourceLocation EllipsisLoc; LambdaCapture(LambdaCaptureKind Kind, SourceLocation Loc, IdentifierInfo* Id = 0, SourceLocation EllipsisLoc = SourceLocation()) : Kind(Kind), Loc(Loc), Id(Id), EllipsisLoc(EllipsisLoc) {} }; /// LambdaIntroducer - Represents a complete lambda introducer. struct LambdaIntroducer { SourceRange Range; SourceLocation DefaultLoc; LambdaCaptureDefault Default; llvm::SmallVector<LambdaCapture, 4> Captures; LambdaIntroducer() : Default(LCD_None) {} /// addCapture - Append a capture in a lambda introducer. void addCapture(LambdaCaptureKind Kind, SourceLocation Loc, IdentifierInfo* Id = 0, SourceLocation EllipsisLoc = SourceLocation()) { Captures.push_back(LambdaCapture(Kind, Loc, Id, EllipsisLoc)); } }; } // end namespace clang #endif