//===--- ExprCXX.h - Classes for representing expressions -------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// /// /// \file /// \brief Defines the clang::Expr interface and subclasses for C++ expressions. /// //===----------------------------------------------------------------------===// #ifndef LLVM_CLANG_AST_EXPRCXX_H #define LLVM_CLANG_AST_EXPRCXX_H #include "clang/AST/Decl.h" #include "clang/AST/Expr.h" #include "clang/AST/TemplateBase.h" #include "clang/AST/UnresolvedSet.h" #include "clang/Basic/ExpressionTraits.h" #include "clang/Basic/Lambda.h" #include "clang/Basic/TypeTraits.h" #include "llvm/Support/Compiler.h" namespace clang { class CXXConstructorDecl; class CXXDestructorDecl; class CXXMethodDecl; class CXXTemporary; class MSPropertyDecl; class TemplateArgumentListInfo; class UuidAttr; //===--------------------------------------------------------------------===// // C++ Expressions. //===--------------------------------------------------------------------===// /// \brief A call to an overloaded operator written using operator /// syntax. /// /// Represents a call to an overloaded operator written using operator /// syntax, e.g., "x + y" or "*p". While semantically equivalent to a /// normal call, this AST node provides better information about the /// syntactic representation of the call. /// /// In a C++ template, this expression node kind will be used whenever /// any of the arguments are type-dependent. In this case, the /// function itself will be a (possibly empty) set of functions and /// function templates that were found by name lookup at template /// definition time. class CXXOperatorCallExpr : public CallExpr { /// \brief The overloaded operator. OverloadedOperatorKind Operator; SourceRange Range; // Record the FP_CONTRACT state that applies to this operator call. Only // meaningful for floating point types. For other types this value can be // set to false. unsigned FPContractable : 1; SourceRange getSourceRangeImpl() const LLVM_READONLY; public: CXXOperatorCallExpr(ASTContext& C, OverloadedOperatorKind Op, Expr *fn, ArrayRef args, QualType t, ExprValueKind VK, SourceLocation operatorloc, bool fpContractable) : CallExpr(C, CXXOperatorCallExprClass, fn, 0, args, t, VK, operatorloc), Operator(Op), FPContractable(fpContractable) { Range = getSourceRangeImpl(); } explicit CXXOperatorCallExpr(ASTContext& C, EmptyShell Empty) : CallExpr(C, CXXOperatorCallExprClass, Empty) { } /// \brief Returns the kind of overloaded operator that this /// expression refers to. OverloadedOperatorKind getOperator() const { return Operator; } /// \brief Returns the location of the operator symbol in the expression. /// /// When \c getOperator()==OO_Call, this is the location of the right /// parentheses; when \c getOperator()==OO_Subscript, this is the location /// of the right bracket. SourceLocation getOperatorLoc() const { return getRParenLoc(); } SourceLocation getLocStart() const LLVM_READONLY { return Range.getBegin(); } SourceLocation getLocEnd() const LLVM_READONLY { return Range.getEnd(); } SourceRange getSourceRange() const { return Range; } static bool classof(const Stmt *T) { return T->getStmtClass() == CXXOperatorCallExprClass; } // Set the FP contractability status of this operator. Only meaningful for // operations on floating point types. void setFPContractable(bool FPC) { FPContractable = FPC; } // Get the FP contractability status of this operator. Only meaningful for // operations on floating point types. bool isFPContractable() const { return FPContractable; } friend class ASTStmtReader; friend class ASTStmtWriter; }; /// Represents a call to a member function that /// may be written either with member call syntax (e.g., "obj.func()" /// or "objptr->func()") or with normal function-call syntax /// ("func()") within a member function that ends up calling a member /// function. The callee in either case is a MemberExpr that contains /// both the object argument and the member function, while the /// arguments are the arguments within the parentheses (not including /// the object argument). class CXXMemberCallExpr : public CallExpr { public: CXXMemberCallExpr(ASTContext &C, Expr *fn, ArrayRef args, QualType t, ExprValueKind VK, SourceLocation RP) : CallExpr(C, CXXMemberCallExprClass, fn, 0, args, t, VK, RP) {} CXXMemberCallExpr(ASTContext &C, EmptyShell Empty) : CallExpr(C, CXXMemberCallExprClass, Empty) { } /// \brief Retrieves the implicit object argument for the member call. /// /// For example, in "x.f(5)", this returns the sub-expression "x". Expr *getImplicitObjectArgument() const; /// \brief Retrieves the declaration of the called method. CXXMethodDecl *getMethodDecl() const; /// \brief Retrieves the CXXRecordDecl for the underlying type of /// the implicit object argument. /// /// Note that this is may not be the same declaration as that of the class /// context of the CXXMethodDecl which this function is calling. /// FIXME: Returns 0 for member pointer call exprs. CXXRecordDecl *getRecordDecl() const; static bool classof(const Stmt *T) { return T->getStmtClass() == CXXMemberCallExprClass; } }; /// \brief Represents a call to a CUDA kernel function. class CUDAKernelCallExpr : public CallExpr { private: enum { CONFIG, END_PREARG }; public: CUDAKernelCallExpr(ASTContext &C, Expr *fn, CallExpr *Config, ArrayRef args, QualType t, ExprValueKind VK, SourceLocation RP) : CallExpr(C, CUDAKernelCallExprClass, fn, END_PREARG, args, t, VK, RP) { setConfig(Config); } CUDAKernelCallExpr(ASTContext &C, EmptyShell Empty) : CallExpr(C, CUDAKernelCallExprClass, END_PREARG, Empty) { } const CallExpr *getConfig() const { return cast_or_null(getPreArg(CONFIG)); } CallExpr *getConfig() { return cast_or_null(getPreArg(CONFIG)); } void setConfig(CallExpr *E) { setPreArg(CONFIG, E); } static bool classof(const Stmt *T) { return T->getStmtClass() == CUDAKernelCallExprClass; } }; /// \brief Abstract class common to all of the C++ "named"/"keyword" casts. /// /// This abstract class is inherited by all of the classes /// representing "named" casts: CXXStaticCastExpr for \c static_cast, /// CXXDynamicCastExpr for \c dynamic_cast, CXXReinterpretCastExpr for /// reinterpret_cast, and CXXConstCastExpr for \c const_cast. class CXXNamedCastExpr : public ExplicitCastExpr { private: SourceLocation Loc; // the location of the casting op SourceLocation RParenLoc; // the location of the right parenthesis SourceRange AngleBrackets; // range for '<' '>' protected: CXXNamedCastExpr(StmtClass SC, QualType ty, ExprValueKind VK, CastKind kind, Expr *op, unsigned PathSize, TypeSourceInfo *writtenTy, SourceLocation l, SourceLocation RParenLoc, SourceRange AngleBrackets) : ExplicitCastExpr(SC, ty, VK, kind, op, PathSize, writtenTy), Loc(l), RParenLoc(RParenLoc), AngleBrackets(AngleBrackets) {} explicit CXXNamedCastExpr(StmtClass SC, EmptyShell Shell, unsigned PathSize) : ExplicitCastExpr(SC, Shell, PathSize) { } friend class ASTStmtReader; public: const char *getCastName() const; /// \brief Retrieve the location of the cast operator keyword, e.g., /// \c static_cast. SourceLocation getOperatorLoc() const { return Loc; } /// \brief Retrieve the location of the closing parenthesis. SourceLocation getRParenLoc() const { return RParenLoc; } SourceLocation getLocStart() const LLVM_READONLY { return Loc; } SourceLocation getLocEnd() const LLVM_READONLY { return RParenLoc; } SourceRange getAngleBrackets() const LLVM_READONLY { return AngleBrackets; } static bool classof(const Stmt *T) { switch (T->getStmtClass()) { case CXXStaticCastExprClass: case CXXDynamicCastExprClass: case CXXReinterpretCastExprClass: case CXXConstCastExprClass: return true; default: return false; } } }; /// \brief A C++ \c static_cast expression (C++ [expr.static.cast]). /// /// This expression node represents a C++ static cast, e.g., /// \c static_cast(1.0). class CXXStaticCastExpr : public CXXNamedCastExpr { CXXStaticCastExpr(QualType ty, ExprValueKind vk, CastKind kind, Expr *op, unsigned pathSize, TypeSourceInfo *writtenTy, SourceLocation l, SourceLocation RParenLoc, SourceRange AngleBrackets) : CXXNamedCastExpr(CXXStaticCastExprClass, ty, vk, kind, op, pathSize, writtenTy, l, RParenLoc, AngleBrackets) {} explicit CXXStaticCastExpr(EmptyShell Empty, unsigned PathSize) : CXXNamedCastExpr(CXXStaticCastExprClass, Empty, PathSize) { } public: static CXXStaticCastExpr *Create(const ASTContext &Context, QualType T, ExprValueKind VK, CastKind K, Expr *Op, const CXXCastPath *Path, TypeSourceInfo *Written, SourceLocation L, SourceLocation RParenLoc, SourceRange AngleBrackets); static CXXStaticCastExpr *CreateEmpty(const ASTContext &Context, unsigned PathSize); static bool classof(const Stmt *T) { return T->getStmtClass() == CXXStaticCastExprClass; } }; /// \brief A C++ @c dynamic_cast expression (C++ [expr.dynamic.cast]). /// /// This expression node represents a dynamic cast, e.g., /// \c dynamic_cast(BasePtr). Such a cast may perform a run-time /// check to determine how to perform the type conversion. class CXXDynamicCastExpr : public CXXNamedCastExpr { CXXDynamicCastExpr(QualType ty, ExprValueKind VK, CastKind kind, Expr *op, unsigned pathSize, TypeSourceInfo *writtenTy, SourceLocation l, SourceLocation RParenLoc, SourceRange AngleBrackets) : CXXNamedCastExpr(CXXDynamicCastExprClass, ty, VK, kind, op, pathSize, writtenTy, l, RParenLoc, AngleBrackets) {} explicit CXXDynamicCastExpr(EmptyShell Empty, unsigned pathSize) : CXXNamedCastExpr(CXXDynamicCastExprClass, Empty, pathSize) { } public: static CXXDynamicCastExpr *Create(const ASTContext &Context, QualType T, ExprValueKind VK, CastKind Kind, Expr *Op, const CXXCastPath *Path, TypeSourceInfo *Written, SourceLocation L, SourceLocation RParenLoc, SourceRange AngleBrackets); static CXXDynamicCastExpr *CreateEmpty(const ASTContext &Context, unsigned pathSize); bool isAlwaysNull() const; static bool classof(const Stmt *T) { return T->getStmtClass() == CXXDynamicCastExprClass; } }; /// \brief A C++ @c reinterpret_cast expression (C++ [expr.reinterpret.cast]). /// /// This expression node represents a reinterpret cast, e.g., /// @c reinterpret_cast(VoidPtr). /// /// A reinterpret_cast provides a differently-typed view of a value but /// (in Clang, as in most C++ implementations) performs no actual work at /// run time. class CXXReinterpretCastExpr : public CXXNamedCastExpr { CXXReinterpretCastExpr(QualType ty, ExprValueKind vk, CastKind kind, Expr *op, unsigned pathSize, TypeSourceInfo *writtenTy, SourceLocation l, SourceLocation RParenLoc, SourceRange AngleBrackets) : CXXNamedCastExpr(CXXReinterpretCastExprClass, ty, vk, kind, op, pathSize, writtenTy, l, RParenLoc, AngleBrackets) {} CXXReinterpretCastExpr(EmptyShell Empty, unsigned pathSize) : CXXNamedCastExpr(CXXReinterpretCastExprClass, Empty, pathSize) { } public: static CXXReinterpretCastExpr *Create(const ASTContext &Context, QualType T, ExprValueKind VK, CastKind Kind, Expr *Op, const CXXCastPath *Path, TypeSourceInfo *WrittenTy, SourceLocation L, SourceLocation RParenLoc, SourceRange AngleBrackets); static CXXReinterpretCastExpr *CreateEmpty(const ASTContext &Context, unsigned pathSize); static bool classof(const Stmt *T) { return T->getStmtClass() == CXXReinterpretCastExprClass; } }; /// \brief A C++ \c const_cast expression (C++ [expr.const.cast]). /// /// This expression node represents a const cast, e.g., /// \c const_cast(PtrToConstChar). /// /// A const_cast can remove type qualifiers but does not change the underlying /// value. class CXXConstCastExpr : public CXXNamedCastExpr { CXXConstCastExpr(QualType ty, ExprValueKind VK, Expr *op, TypeSourceInfo *writtenTy, SourceLocation l, SourceLocation RParenLoc, SourceRange AngleBrackets) : CXXNamedCastExpr(CXXConstCastExprClass, ty, VK, CK_NoOp, op, 0, writtenTy, l, RParenLoc, AngleBrackets) {} explicit CXXConstCastExpr(EmptyShell Empty) : CXXNamedCastExpr(CXXConstCastExprClass, Empty, 0) { } public: static CXXConstCastExpr *Create(const ASTContext &Context, QualType T, ExprValueKind VK, Expr *Op, TypeSourceInfo *WrittenTy, SourceLocation L, SourceLocation RParenLoc, SourceRange AngleBrackets); static CXXConstCastExpr *CreateEmpty(const ASTContext &Context); static bool classof(const Stmt *T) { return T->getStmtClass() == CXXConstCastExprClass; } }; /// \brief A call to a literal operator (C++11 [over.literal]) /// written as a user-defined literal (C++11 [lit.ext]). /// /// Represents a user-defined literal, e.g. "foo"_bar or 1.23_xyz. While this /// is semantically equivalent to a normal call, this AST node provides better /// information about the syntactic representation of the literal. /// /// Since literal operators are never found by ADL and can only be declared at /// namespace scope, a user-defined literal is never dependent. class UserDefinedLiteral : public CallExpr { /// \brief The location of a ud-suffix within the literal. SourceLocation UDSuffixLoc; public: UserDefinedLiteral(const ASTContext &C, Expr *Fn, ArrayRef Args, QualType T, ExprValueKind VK, SourceLocation LitEndLoc, SourceLocation SuffixLoc) : CallExpr(C, UserDefinedLiteralClass, Fn, 0, Args, T, VK, LitEndLoc), UDSuffixLoc(SuffixLoc) {} explicit UserDefinedLiteral(const ASTContext &C, EmptyShell Empty) : CallExpr(C, UserDefinedLiteralClass, Empty) {} /// The kind of literal operator which is invoked. enum LiteralOperatorKind { LOK_Raw, ///< Raw form: operator "" X (const char *) LOK_Template, ///< Raw form: operator "" X () LOK_Integer, ///< operator "" X (unsigned long long) LOK_Floating, ///< operator "" X (long double) LOK_String, ///< operator "" X (const CharT *, size_t) LOK_Character ///< operator "" X (CharT) }; /// \brief Returns the kind of literal operator invocation /// which this expression represents. LiteralOperatorKind getLiteralOperatorKind() const; /// \brief If this is not a raw user-defined literal, get the /// underlying cooked literal (representing the literal with the suffix /// removed). Expr *getCookedLiteral(); const Expr *getCookedLiteral() const { return const_cast(this)->getCookedLiteral(); } SourceLocation getLocStart() const { if (getLiteralOperatorKind() == LOK_Template) return getRParenLoc(); return getArg(0)->getLocStart(); } SourceLocation getLocEnd() const { return getRParenLoc(); } /// \brief Returns the location of a ud-suffix in the expression. /// /// For a string literal, there may be multiple identical suffixes. This /// returns the first. SourceLocation getUDSuffixLoc() const { return UDSuffixLoc; } /// \brief Returns the ud-suffix specified for this literal. const IdentifierInfo *getUDSuffix() const; static bool classof(const Stmt *S) { return S->getStmtClass() == UserDefinedLiteralClass; } friend class ASTStmtReader; friend class ASTStmtWriter; }; /// \brief A boolean literal, per ([C++ lex.bool] Boolean literals). /// class CXXBoolLiteralExpr : public Expr { bool Value; SourceLocation Loc; public: CXXBoolLiteralExpr(bool val, QualType Ty, SourceLocation l) : Expr(CXXBoolLiteralExprClass, Ty, VK_RValue, OK_Ordinary, false, false, false, false), Value(val), Loc(l) {} explicit CXXBoolLiteralExpr(EmptyShell Empty) : Expr(CXXBoolLiteralExprClass, Empty) { } bool getValue() const { return Value; } void setValue(bool V) { Value = V; } SourceLocation getLocStart() const LLVM_READONLY { return Loc; } SourceLocation getLocEnd() const LLVM_READONLY { return Loc; } SourceLocation getLocation() const { return Loc; } void setLocation(SourceLocation L) { Loc = L; } static bool classof(const Stmt *T) { return T->getStmtClass() == CXXBoolLiteralExprClass; } // Iterators child_range children() { return child_range(); } }; /// \brief The null pointer literal (C++11 [lex.nullptr]) /// /// Introduced in C++11, the only literal of type \c nullptr_t is \c nullptr. class CXXNullPtrLiteralExpr : public Expr { SourceLocation Loc; public: CXXNullPtrLiteralExpr(QualType Ty, SourceLocation l) : Expr(CXXNullPtrLiteralExprClass, Ty, VK_RValue, OK_Ordinary, false, false, false, false), Loc(l) {} explicit CXXNullPtrLiteralExpr(EmptyShell Empty) : Expr(CXXNullPtrLiteralExprClass, Empty) { } SourceLocation getLocStart() const LLVM_READONLY { return Loc; } SourceLocation getLocEnd() const LLVM_READONLY { return Loc; } SourceLocation getLocation() const { return Loc; } void setLocation(SourceLocation L) { Loc = L; } static bool classof(const Stmt *T) { return T->getStmtClass() == CXXNullPtrLiteralExprClass; } child_range children() { return child_range(); } }; /// \brief Implicit construction of a std::initializer_list object from an /// array temporary within list-initialization (C++11 [dcl.init.list]p5). class CXXStdInitializerListExpr : public Expr { Stmt *SubExpr; CXXStdInitializerListExpr(EmptyShell Empty) : Expr(CXXStdInitializerListExprClass, Empty), SubExpr(0) {} public: CXXStdInitializerListExpr(QualType Ty, Expr *SubExpr) : Expr(CXXStdInitializerListExprClass, Ty, VK_RValue, OK_Ordinary, Ty->isDependentType(), SubExpr->isValueDependent(), SubExpr->isInstantiationDependent(), SubExpr->containsUnexpandedParameterPack()), SubExpr(SubExpr) {} Expr *getSubExpr() { return static_cast(SubExpr); } const Expr *getSubExpr() const { return static_cast(SubExpr); } SourceLocation getLocStart() const LLVM_READONLY { return SubExpr->getLocStart(); } SourceLocation getLocEnd() const LLVM_READONLY { return SubExpr->getLocEnd(); } SourceRange getSourceRange() const LLVM_READONLY { return SubExpr->getSourceRange(); } static bool classof(const Stmt *S) { return S->getStmtClass() == CXXStdInitializerListExprClass; } child_range children() { return child_range(&SubExpr, &SubExpr + 1); } friend class ASTReader; friend class ASTStmtReader; }; /// A C++ \c typeid expression (C++ [expr.typeid]), which gets /// the \c type_info that corresponds to the supplied type, or the (possibly /// dynamic) type of the supplied expression. /// /// This represents code like \c typeid(int) or \c typeid(*objPtr) class CXXTypeidExpr : public Expr { private: llvm::PointerUnion Operand; SourceRange Range; public: CXXTypeidExpr(QualType Ty, TypeSourceInfo *Operand, SourceRange R) : Expr(CXXTypeidExprClass, Ty, VK_LValue, OK_Ordinary, // typeid is never type-dependent (C++ [temp.dep.expr]p4) false, // typeid is value-dependent if the type or expression are dependent Operand->getType()->isDependentType(), Operand->getType()->isInstantiationDependentType(), Operand->getType()->containsUnexpandedParameterPack()), Operand(Operand), Range(R) { } CXXTypeidExpr(QualType Ty, Expr *Operand, SourceRange R) : Expr(CXXTypeidExprClass, Ty, VK_LValue, OK_Ordinary, // typeid is never type-dependent (C++ [temp.dep.expr]p4) false, // typeid is value-dependent if the type or expression are dependent Operand->isTypeDependent() || Operand->isValueDependent(), Operand->isInstantiationDependent(), Operand->containsUnexpandedParameterPack()), Operand(Operand), Range(R) { } CXXTypeidExpr(EmptyShell Empty, bool isExpr) : Expr(CXXTypeidExprClass, Empty) { if (isExpr) Operand = (Expr*)0; else Operand = (TypeSourceInfo*)0; } /// Determine whether this typeid has a type operand which is potentially /// evaluated, per C++11 [expr.typeid]p3. bool isPotentiallyEvaluated() const; bool isTypeOperand() const { return Operand.is(); } /// \brief Retrieves the type operand of this typeid() expression after /// various required adjustments (removing reference types, cv-qualifiers). QualType getTypeOperand(ASTContext &Context) const; /// \brief Retrieve source information for the type operand. TypeSourceInfo *getTypeOperandSourceInfo() const { assert(isTypeOperand() && "Cannot call getTypeOperand for typeid(expr)"); return Operand.get(); } void setTypeOperandSourceInfo(TypeSourceInfo *TSI) { assert(isTypeOperand() && "Cannot call getTypeOperand for typeid(expr)"); Operand = TSI; } Expr *getExprOperand() const { assert(!isTypeOperand() && "Cannot call getExprOperand for typeid(type)"); return static_cast(Operand.get()); } void setExprOperand(Expr *E) { assert(!isTypeOperand() && "Cannot call getExprOperand for typeid(type)"); Operand = E; } SourceLocation getLocStart() const LLVM_READONLY { return Range.getBegin(); } SourceLocation getLocEnd() const LLVM_READONLY { return Range.getEnd(); } SourceRange getSourceRange() const LLVM_READONLY { return Range; } void setSourceRange(SourceRange R) { Range = R; } static bool classof(const Stmt *T) { return T->getStmtClass() == CXXTypeidExprClass; } // Iterators child_range children() { if (isTypeOperand()) return child_range(); Stmt **begin = reinterpret_cast(&Operand); return child_range(begin, begin + 1); } }; /// \brief A member reference to an MSPropertyDecl. /// /// This expression always has pseudo-object type, and therefore it is /// typically not encountered in a fully-typechecked expression except /// within the syntactic form of a PseudoObjectExpr. class MSPropertyRefExpr : public Expr { Expr *BaseExpr; MSPropertyDecl *TheDecl; SourceLocation MemberLoc; bool IsArrow; NestedNameSpecifierLoc QualifierLoc; public: MSPropertyRefExpr(Expr *baseExpr, MSPropertyDecl *decl, bool isArrow, QualType ty, ExprValueKind VK, NestedNameSpecifierLoc qualifierLoc, SourceLocation nameLoc) : Expr(MSPropertyRefExprClass, ty, VK, OK_Ordinary, /*type-dependent*/ false, baseExpr->isValueDependent(), baseExpr->isInstantiationDependent(), baseExpr->containsUnexpandedParameterPack()), BaseExpr(baseExpr), TheDecl(decl), MemberLoc(nameLoc), IsArrow(isArrow), QualifierLoc(qualifierLoc) {} MSPropertyRefExpr(EmptyShell Empty) : Expr(MSPropertyRefExprClass, Empty) {} SourceRange getSourceRange() const LLVM_READONLY { return SourceRange(getLocStart(), getLocEnd()); } bool isImplicitAccess() const { return getBaseExpr() && getBaseExpr()->isImplicitCXXThis(); } SourceLocation getLocStart() const { if (!isImplicitAccess()) return BaseExpr->getLocStart(); else if (QualifierLoc) return QualifierLoc.getBeginLoc(); else return MemberLoc; } SourceLocation getLocEnd() const { return getMemberLoc(); } child_range children() { return child_range((Stmt**)&BaseExpr, (Stmt**)&BaseExpr + 1); } static bool classof(const Stmt *T) { return T->getStmtClass() == MSPropertyRefExprClass; } Expr *getBaseExpr() const { return BaseExpr; } MSPropertyDecl *getPropertyDecl() const { return TheDecl; } bool isArrow() const { return IsArrow; } SourceLocation getMemberLoc() const { return MemberLoc; } NestedNameSpecifierLoc getQualifierLoc() const { return QualifierLoc; } friend class ASTStmtReader; }; /// A Microsoft C++ @c __uuidof expression, which gets /// the _GUID that corresponds to the supplied type or expression. /// /// This represents code like @c __uuidof(COMTYPE) or @c __uuidof(*comPtr) class CXXUuidofExpr : public Expr { private: llvm::PointerUnion Operand; SourceRange Range; public: CXXUuidofExpr(QualType Ty, TypeSourceInfo *Operand, SourceRange R) : Expr(CXXUuidofExprClass, Ty, VK_LValue, OK_Ordinary, false, Operand->getType()->isDependentType(), Operand->getType()->isInstantiationDependentType(), Operand->getType()->containsUnexpandedParameterPack()), Operand(Operand), Range(R) { } CXXUuidofExpr(QualType Ty, Expr *Operand, SourceRange R) : Expr(CXXUuidofExprClass, Ty, VK_LValue, OK_Ordinary, false, Operand->isTypeDependent(), Operand->isInstantiationDependent(), Operand->containsUnexpandedParameterPack()), Operand(Operand), Range(R) { } CXXUuidofExpr(EmptyShell Empty, bool isExpr) : Expr(CXXUuidofExprClass, Empty) { if (isExpr) Operand = (Expr*)0; else Operand = (TypeSourceInfo*)0; } bool isTypeOperand() const { return Operand.is(); } /// \brief Retrieves the type operand of this __uuidof() expression after /// various required adjustments (removing reference types, cv-qualifiers). QualType getTypeOperand(ASTContext &Context) const; /// \brief Retrieve source information for the type operand. TypeSourceInfo *getTypeOperandSourceInfo() const { assert(isTypeOperand() && "Cannot call getTypeOperand for __uuidof(expr)"); return Operand.get(); } void setTypeOperandSourceInfo(TypeSourceInfo *TSI) { assert(isTypeOperand() && "Cannot call getTypeOperand for __uuidof(expr)"); Operand = TSI; } Expr *getExprOperand() const { assert(!isTypeOperand() && "Cannot call getExprOperand for __uuidof(type)"); return static_cast(Operand.get()); } void setExprOperand(Expr *E) { assert(!isTypeOperand() && "Cannot call getExprOperand for __uuidof(type)"); Operand = E; } StringRef getUuidAsStringRef(ASTContext &Context) const; SourceLocation getLocStart() const LLVM_READONLY { return Range.getBegin(); } SourceLocation getLocEnd() const LLVM_READONLY { return Range.getEnd(); } SourceRange getSourceRange() const LLVM_READONLY { return Range; } void setSourceRange(SourceRange R) { Range = R; } static bool classof(const Stmt *T) { return T->getStmtClass() == CXXUuidofExprClass; } /// Grabs __declspec(uuid()) off a type, or returns 0 if we cannot resolve to /// a single GUID. static UuidAttr *GetUuidAttrOfType(QualType QT, bool *HasMultipleGUIDsPtr = 0); // Iterators child_range children() { if (isTypeOperand()) return child_range(); Stmt **begin = reinterpret_cast(&Operand); return child_range(begin, begin + 1); } }; /// \brief Represents the \c this expression in C++. /// /// This is a pointer to the object on which the current member function is /// executing (C++ [expr.prim]p3). Example: /// /// \code /// class Foo { /// public: /// void bar(); /// void test() { this->bar(); } /// }; /// \endcode class CXXThisExpr : public Expr { SourceLocation Loc; bool Implicit : 1; public: CXXThisExpr(SourceLocation L, QualType Type, bool isImplicit) : Expr(CXXThisExprClass, Type, VK_RValue, OK_Ordinary, // 'this' is type-dependent if the class type of the enclosing // member function is dependent (C++ [temp.dep.expr]p2) Type->isDependentType(), Type->isDependentType(), Type->isInstantiationDependentType(), /*ContainsUnexpandedParameterPack=*/false), Loc(L), Implicit(isImplicit) { } CXXThisExpr(EmptyShell Empty) : Expr(CXXThisExprClass, Empty) {} SourceLocation getLocation() const { return Loc; } void setLocation(SourceLocation L) { Loc = L; } SourceLocation getLocStart() const LLVM_READONLY { return Loc; } SourceLocation getLocEnd() const LLVM_READONLY { return Loc; } bool isImplicit() const { return Implicit; } void setImplicit(bool I) { Implicit = I; } static bool classof(const Stmt *T) { return T->getStmtClass() == CXXThisExprClass; } // Iterators child_range children() { return child_range(); } }; /// \brief A C++ throw-expression (C++ [except.throw]). /// /// This handles 'throw' (for re-throwing the current exception) and /// 'throw' assignment-expression. When assignment-expression isn't /// present, Op will be null. class CXXThrowExpr : public Expr { Stmt *Op; SourceLocation ThrowLoc; /// \brief Whether the thrown variable (if any) is in scope. unsigned IsThrownVariableInScope : 1; friend class ASTStmtReader; public: // \p Ty is the void type which is used as the result type of the // expression. The \p l is the location of the throw keyword. \p expr // can by null, if the optional expression to throw isn't present. CXXThrowExpr(Expr *expr, QualType Ty, SourceLocation l, bool IsThrownVariableInScope) : Expr(CXXThrowExprClass, Ty, VK_RValue, OK_Ordinary, false, false, expr && expr->isInstantiationDependent(), expr && expr->containsUnexpandedParameterPack()), Op(expr), ThrowLoc(l), IsThrownVariableInScope(IsThrownVariableInScope) {} CXXThrowExpr(EmptyShell Empty) : Expr(CXXThrowExprClass, Empty) {} const Expr *getSubExpr() const { return cast_or_null(Op); } Expr *getSubExpr() { return cast_or_null(Op); } SourceLocation getThrowLoc() const { return ThrowLoc; } /// \brief Determines whether the variable thrown by this expression (if any!) /// is within the innermost try block. /// /// This information is required to determine whether the NRVO can apply to /// this variable. bool isThrownVariableInScope() const { return IsThrownVariableInScope; } SourceLocation getLocStart() const LLVM_READONLY { return ThrowLoc; } SourceLocation getLocEnd() const LLVM_READONLY { if (getSubExpr() == 0) return ThrowLoc; return getSubExpr()->getLocEnd(); } static bool classof(const Stmt *T) { return T->getStmtClass() == CXXThrowExprClass; } // Iterators child_range children() { return child_range(&Op, Op ? &Op+1 : &Op); } }; /// \brief A default argument (C++ [dcl.fct.default]). /// /// This wraps up a function call argument that was created from the /// corresponding parameter's default argument, when the call did not /// explicitly supply arguments for all of the parameters. class CXXDefaultArgExpr : public Expr { /// \brief The parameter whose default is being used. /// /// When the bit is set, the subexpression is stored after the /// CXXDefaultArgExpr itself. When the bit is clear, the parameter's /// actual default expression is the subexpression. llvm::PointerIntPair Param; /// \brief The location where the default argument expression was used. SourceLocation Loc; CXXDefaultArgExpr(StmtClass SC, SourceLocation Loc, ParmVarDecl *param) : Expr(SC, param->hasUnparsedDefaultArg() ? param->getType().getNonReferenceType() : param->getDefaultArg()->getType(), param->getDefaultArg()->getValueKind(), param->getDefaultArg()->getObjectKind(), false, false, false, false), Param(param, false), Loc(Loc) { } CXXDefaultArgExpr(StmtClass SC, SourceLocation Loc, ParmVarDecl *param, Expr *SubExpr) : Expr(SC, SubExpr->getType(), SubExpr->getValueKind(), SubExpr->getObjectKind(), false, false, false, false), Param(param, true), Loc(Loc) { *reinterpret_cast(this + 1) = SubExpr; } public: CXXDefaultArgExpr(EmptyShell Empty) : Expr(CXXDefaultArgExprClass, Empty) {} // \p Param is the parameter whose default argument is used by this // expression. static CXXDefaultArgExpr *Create(const ASTContext &C, SourceLocation Loc, ParmVarDecl *Param) { return new (C) CXXDefaultArgExpr(CXXDefaultArgExprClass, Loc, Param); } // \p Param is the parameter whose default argument is used by this // expression, and \p SubExpr is the expression that will actually be used. static CXXDefaultArgExpr *Create(const ASTContext &C, SourceLocation Loc, ParmVarDecl *Param, Expr *SubExpr); // Retrieve the parameter that the argument was created from. const ParmVarDecl *getParam() const { return Param.getPointer(); } ParmVarDecl *getParam() { return Param.getPointer(); } // Retrieve the actual argument to the function call. const Expr *getExpr() const { if (Param.getInt()) return *reinterpret_cast (this + 1); return getParam()->getDefaultArg(); } Expr *getExpr() { if (Param.getInt()) return *reinterpret_cast (this + 1); return getParam()->getDefaultArg(); } /// \brief Retrieve the location where this default argument was actually /// used. SourceLocation getUsedLocation() const { return Loc; } /// Default argument expressions have no representation in the /// source, so they have an empty source range. SourceLocation getLocStart() const LLVM_READONLY { return SourceLocation(); } SourceLocation getLocEnd() const LLVM_READONLY { return SourceLocation(); } SourceLocation getExprLoc() const LLVM_READONLY { return Loc; } static bool classof(const Stmt *T) { return T->getStmtClass() == CXXDefaultArgExprClass; } // Iterators child_range children() { return child_range(); } friend class ASTStmtReader; friend class ASTStmtWriter; }; /// \brief A use of a default initializer in a constructor or in aggregate /// initialization. /// /// This wraps a use of a C++ default initializer (technically, /// a brace-or-equal-initializer for a non-static data member) when it /// is implicitly used in a mem-initializer-list in a constructor /// (C++11 [class.base.init]p8) or in aggregate initialization /// (C++1y [dcl.init.aggr]p7). class CXXDefaultInitExpr : public Expr { /// \brief The field whose default is being used. FieldDecl *Field; /// \brief The location where the default initializer expression was used. SourceLocation Loc; CXXDefaultInitExpr(const ASTContext &C, SourceLocation Loc, FieldDecl *Field, QualType T); CXXDefaultInitExpr(EmptyShell Empty) : Expr(CXXDefaultInitExprClass, Empty) {} public: /// \p Field is the non-static data member whose default initializer is used /// by this expression. static CXXDefaultInitExpr *Create(const ASTContext &C, SourceLocation Loc, FieldDecl *Field) { return new (C) CXXDefaultInitExpr(C, Loc, Field, Field->getType()); } /// \brief Get the field whose initializer will be used. FieldDecl *getField() { return Field; } const FieldDecl *getField() const { return Field; } /// \brief Get the initialization expression that will be used. const Expr *getExpr() const { return Field->getInClassInitializer(); } Expr *getExpr() { return Field->getInClassInitializer(); } SourceLocation getLocStart() const LLVM_READONLY { return Loc; } SourceLocation getLocEnd() const LLVM_READONLY { return Loc; } static bool classof(const Stmt *T) { return T->getStmtClass() == CXXDefaultInitExprClass; } // Iterators child_range children() { return child_range(); } friend class ASTReader; friend class ASTStmtReader; }; /// \brief Represents a C++ temporary. class CXXTemporary { /// \brief The destructor that needs to be called. const CXXDestructorDecl *Destructor; explicit CXXTemporary(const CXXDestructorDecl *destructor) : Destructor(destructor) { } public: static CXXTemporary *Create(const ASTContext &C, const CXXDestructorDecl *Destructor); const CXXDestructorDecl *getDestructor() const { return Destructor; } void setDestructor(const CXXDestructorDecl *Dtor) { Destructor = Dtor; } }; /// \brief Represents binding an expression to a temporary. /// /// This ensures the destructor is called for the temporary. It should only be /// needed for non-POD, non-trivially destructable class types. For example: /// /// \code /// struct S { /// S() { } // User defined constructor makes S non-POD. /// ~S() { } // User defined destructor makes it non-trivial. /// }; /// void test() { /// const S &s_ref = S(); // Requires a CXXBindTemporaryExpr. /// } /// \endcode class CXXBindTemporaryExpr : public Expr { CXXTemporary *Temp; Stmt *SubExpr; CXXBindTemporaryExpr(CXXTemporary *temp, Expr* SubExpr) : Expr(CXXBindTemporaryExprClass, SubExpr->getType(), VK_RValue, OK_Ordinary, SubExpr->isTypeDependent(), SubExpr->isValueDependent(), SubExpr->isInstantiationDependent(), SubExpr->containsUnexpandedParameterPack()), Temp(temp), SubExpr(SubExpr) { } public: CXXBindTemporaryExpr(EmptyShell Empty) : Expr(CXXBindTemporaryExprClass, Empty), Temp(0), SubExpr(0) {} static CXXBindTemporaryExpr *Create(const ASTContext &C, CXXTemporary *Temp, Expr* SubExpr); CXXTemporary *getTemporary() { return Temp; } const CXXTemporary *getTemporary() const { return Temp; } void setTemporary(CXXTemporary *T) { Temp = T; } const Expr *getSubExpr() const { return cast(SubExpr); } Expr *getSubExpr() { return cast(SubExpr); } void setSubExpr(Expr *E) { SubExpr = E; } SourceLocation getLocStart() const LLVM_READONLY { return SubExpr->getLocStart(); } SourceLocation getLocEnd() const LLVM_READONLY { return SubExpr->getLocEnd();} // Implement isa/cast/dyncast/etc. static bool classof(const Stmt *T) { return T->getStmtClass() == CXXBindTemporaryExprClass; } // Iterators child_range children() { return child_range(&SubExpr, &SubExpr + 1); } }; /// \brief Represents a call to a C++ constructor. class CXXConstructExpr : public Expr { public: enum ConstructionKind { CK_Complete, CK_NonVirtualBase, CK_VirtualBase, CK_Delegating }; private: CXXConstructorDecl *Constructor; SourceLocation Loc; SourceRange ParenOrBraceRange; unsigned NumArgs : 16; bool Elidable : 1; bool HadMultipleCandidates : 1; bool ListInitialization : 1; bool ZeroInitialization : 1; unsigned ConstructKind : 2; Stmt **Args; protected: CXXConstructExpr(const ASTContext &C, StmtClass SC, QualType T, SourceLocation Loc, CXXConstructorDecl *d, bool elidable, ArrayRef Args, bool HadMultipleCandidates, bool ListInitialization, bool ZeroInitialization, ConstructionKind ConstructKind, SourceRange ParenOrBraceRange); /// \brief Construct an empty C++ construction expression. CXXConstructExpr(StmtClass SC, EmptyShell Empty) : Expr(SC, Empty), Constructor(0), NumArgs(0), Elidable(false), HadMultipleCandidates(false), ListInitialization(false), ZeroInitialization(false), ConstructKind(0), Args(0) { } public: /// \brief Construct an empty C++ construction expression. explicit CXXConstructExpr(EmptyShell Empty) : Expr(CXXConstructExprClass, Empty), Constructor(0), NumArgs(0), Elidable(false), HadMultipleCandidates(false), ListInitialization(false), ZeroInitialization(false), ConstructKind(0), Args(0) { } static CXXConstructExpr *Create(const ASTContext &C, QualType T, SourceLocation Loc, CXXConstructorDecl *D, bool Elidable, ArrayRef Args, bool HadMultipleCandidates, bool ListInitialization, bool ZeroInitialization, ConstructionKind ConstructKind, SourceRange ParenOrBraceRange); CXXConstructorDecl* getConstructor() const { return Constructor; } void setConstructor(CXXConstructorDecl *C) { Constructor = C; } SourceLocation getLocation() const { return Loc; } void setLocation(SourceLocation Loc) { this->Loc = Loc; } /// \brief Whether this construction is elidable. bool isElidable() const { return Elidable; } void setElidable(bool E) { Elidable = E; } /// \brief Whether the referred constructor was resolved from /// an overloaded set having size greater than 1. bool hadMultipleCandidates() const { return HadMultipleCandidates; } void setHadMultipleCandidates(bool V) { HadMultipleCandidates = V; } /// \brief Whether this constructor call was written as list-initialization. bool isListInitialization() const { return ListInitialization; } void setListInitialization(bool V) { ListInitialization = V; } /// \brief Whether this construction first requires /// zero-initialization before the initializer is called. bool requiresZeroInitialization() const { return ZeroInitialization; } void setRequiresZeroInitialization(bool ZeroInit) { ZeroInitialization = ZeroInit; } /// \brief Determine whether this constructor is actually constructing /// a base class (rather than a complete object). ConstructionKind getConstructionKind() const { return (ConstructionKind)ConstructKind; } void setConstructionKind(ConstructionKind CK) { ConstructKind = CK; } typedef ExprIterator arg_iterator; typedef ConstExprIterator const_arg_iterator; arg_iterator arg_begin() { return Args; } arg_iterator arg_end() { return Args + NumArgs; } const_arg_iterator arg_begin() const { return Args; } const_arg_iterator arg_end() const { return Args + NumArgs; } Expr **getArgs() const { return reinterpret_cast(Args); } unsigned getNumArgs() const { return NumArgs; } /// \brief Return the specified argument. Expr *getArg(unsigned Arg) { assert(Arg < NumArgs && "Arg access out of range!"); return cast(Args[Arg]); } const Expr *getArg(unsigned Arg) const { assert(Arg < NumArgs && "Arg access out of range!"); return cast(Args[Arg]); } /// \brief Set the specified argument. void setArg(unsigned Arg, Expr *ArgExpr) { assert(Arg < NumArgs && "Arg access out of range!"); Args[Arg] = ArgExpr; } SourceLocation getLocStart() const LLVM_READONLY; SourceLocation getLocEnd() const LLVM_READONLY; SourceRange getParenOrBraceRange() const { return ParenOrBraceRange; } void setParenOrBraceRange(SourceRange Range) { ParenOrBraceRange = Range; } static bool classof(const Stmt *T) { return T->getStmtClass() == CXXConstructExprClass || T->getStmtClass() == CXXTemporaryObjectExprClass; } // Iterators child_range children() { return child_range(&Args[0], &Args[0]+NumArgs); } friend class ASTStmtReader; }; /// \brief Represents an explicit C++ type conversion that uses "functional" /// notation (C++ [expr.type.conv]). /// /// Example: /// \code /// x = int(0.5); /// \endcode class CXXFunctionalCastExpr : public ExplicitCastExpr { SourceLocation LParenLoc; SourceLocation RParenLoc; CXXFunctionalCastExpr(QualType ty, ExprValueKind VK, TypeSourceInfo *writtenTy, CastKind kind, Expr *castExpr, unsigned pathSize, SourceLocation lParenLoc, SourceLocation rParenLoc) : ExplicitCastExpr(CXXFunctionalCastExprClass, ty, VK, kind, castExpr, pathSize, writtenTy), LParenLoc(lParenLoc), RParenLoc(rParenLoc) {} explicit CXXFunctionalCastExpr(EmptyShell Shell, unsigned PathSize) : ExplicitCastExpr(CXXFunctionalCastExprClass, Shell, PathSize) { } public: static CXXFunctionalCastExpr *Create(const ASTContext &Context, QualType T, ExprValueKind VK, TypeSourceInfo *Written, CastKind Kind, Expr *Op, const CXXCastPath *Path, SourceLocation LPLoc, SourceLocation RPLoc); static CXXFunctionalCastExpr *CreateEmpty(const ASTContext &Context, unsigned PathSize); SourceLocation getLParenLoc() const { return LParenLoc; } void setLParenLoc(SourceLocation L) { LParenLoc = L; } SourceLocation getRParenLoc() const { return RParenLoc; } void setRParenLoc(SourceLocation L) { RParenLoc = L; } SourceLocation getLocStart() const LLVM_READONLY; SourceLocation getLocEnd() const LLVM_READONLY; static bool classof(const Stmt *T) { return T->getStmtClass() == CXXFunctionalCastExprClass; } }; /// @brief Represents a C++ functional cast expression that builds a /// temporary object. /// /// This expression type represents a C++ "functional" cast /// (C++[expr.type.conv]) with N != 1 arguments that invokes a /// constructor to build a temporary object. With N == 1 arguments the /// functional cast expression will be represented by CXXFunctionalCastExpr. /// Example: /// \code /// struct X { X(int, float); } /// /// X create_X() { /// return X(1, 3.14f); // creates a CXXTemporaryObjectExpr /// }; /// \endcode class CXXTemporaryObjectExpr : public CXXConstructExpr { TypeSourceInfo *Type; public: CXXTemporaryObjectExpr(const ASTContext &C, CXXConstructorDecl *Cons, TypeSourceInfo *Type, ArrayRef Args, SourceRange ParenOrBraceRange, bool HadMultipleCandidates, bool ListInitialization, bool ZeroInitialization); explicit CXXTemporaryObjectExpr(EmptyShell Empty) : CXXConstructExpr(CXXTemporaryObjectExprClass, Empty), Type() { } TypeSourceInfo *getTypeSourceInfo() const { return Type; } SourceLocation getLocStart() const LLVM_READONLY; SourceLocation getLocEnd() const LLVM_READONLY; static bool classof(const Stmt *T) { return T->getStmtClass() == CXXTemporaryObjectExprClass; } friend class ASTStmtReader; }; /// \brief A C++ lambda expression, which produces a function object /// (of unspecified type) that can be invoked later. /// /// Example: /// \code /// void low_pass_filter(std::vector &values, double cutoff) { /// values.erase(std::remove_if(values.begin(), values.end(), /// [=](double value) { return value > cutoff; }); /// } /// \endcode /// /// C++11 lambda expressions can capture local variables, either by copying /// the values of those local variables at the time the function /// object is constructed (not when it is called!) or by holding a /// reference to the local variable. These captures can occur either /// implicitly or can be written explicitly between the square /// brackets ([...]) that start the lambda expression. /// /// C++1y introduces a new form of "capture" called an init-capture that /// includes an initializing expression (rather than capturing a variable), /// and which can never occur implicitly. class LambdaExpr : public Expr { enum { /// \brief Flag used by the Capture class to indicate that the given /// capture was implicit. Capture_Implicit = 0x01, /// \brief Flag used by the Capture class to indicate that the /// given capture was by-copy. /// /// This includes the case of a non-reference init-capture. Capture_ByCopy = 0x02 }; /// \brief The source range that covers the lambda introducer ([...]). SourceRange IntroducerRange; /// \brief The source location of this lambda's capture-default ('=' or '&'). SourceLocation CaptureDefaultLoc; /// \brief The number of captures. unsigned NumCaptures : 16; /// \brief The default capture kind, which is a value of type /// LambdaCaptureDefault. unsigned CaptureDefault : 2; /// \brief Whether this lambda had an explicit parameter list vs. an /// implicit (and empty) parameter list. unsigned ExplicitParams : 1; /// \brief Whether this lambda had the result type explicitly specified. unsigned ExplicitResultType : 1; /// \brief Whether there are any array index variables stored at the end of /// this lambda expression. unsigned HasArrayIndexVars : 1; /// \brief The location of the closing brace ('}') that completes /// the lambda. /// /// The location of the brace is also available by looking up the /// function call operator in the lambda class. However, it is /// stored here to improve the performance of getSourceRange(), and /// to avoid having to deserialize the function call operator from a /// module file just to determine the source range. SourceLocation ClosingBrace; // Note: The capture initializers are stored directly after the lambda // expression, along with the index variables used to initialize by-copy // array captures. public: /// \brief Describes the capture of a variable or of \c this, or of a /// C++1y init-capture. class Capture { llvm::PointerIntPair DeclAndBits; SourceLocation Loc; SourceLocation EllipsisLoc; friend class ASTStmtReader; friend class ASTStmtWriter; public: /// \brief Create a new capture of a variable or of \c this. /// /// \param Loc The source location associated with this capture. /// /// \param Kind The kind of capture (this, byref, bycopy), which must /// not be init-capture. /// /// \param Implicit Whether the capture was implicit or explicit. /// /// \param Var The local variable being captured, or null if capturing /// \c this. /// /// \param EllipsisLoc The location of the ellipsis (...) for a /// capture that is a pack expansion, or an invalid source /// location to indicate that this is not a pack expansion. Capture(SourceLocation Loc, bool Implicit, LambdaCaptureKind Kind, VarDecl *Var = 0, SourceLocation EllipsisLoc = SourceLocation()); /// \brief Determine the kind of capture. LambdaCaptureKind getCaptureKind() const; /// \brief Determine whether this capture handles the C++ \c this /// pointer. bool capturesThis() const { return DeclAndBits.getPointer() == 0; } /// \brief Determine whether this capture handles a variable. bool capturesVariable() const { return dyn_cast_or_null(DeclAndBits.getPointer()); } /// \brief Determine whether this is an init-capture. bool isInitCapture() const { return capturesVariable() && getCapturedVar()->isInitCapture(); } /// \brief Retrieve the declaration of the local variable being /// captured. /// /// This operation is only valid if this capture is a variable capture /// (other than a capture of \c this). VarDecl *getCapturedVar() const { assert(capturesVariable() && "No variable available for 'this' capture"); return cast(DeclAndBits.getPointer()); } /// \brief Determine whether this was an implicit capture (not /// written between the square brackets introducing the lambda). bool isImplicit() const { return DeclAndBits.getInt() & Capture_Implicit; } /// \brief Determine whether this was an explicit capture (written /// between the square brackets introducing the lambda). bool isExplicit() const { return !isImplicit(); } /// \brief Retrieve the source location of the capture. /// /// For an explicit capture, this returns the location of the /// explicit capture in the source. For an implicit capture, this /// returns the location at which the variable or \c this was first /// used. SourceLocation getLocation() const { return Loc; } /// \brief Determine whether this capture is a pack expansion, /// which captures a function parameter pack. bool isPackExpansion() const { return EllipsisLoc.isValid(); } /// \brief Retrieve the location of the ellipsis for a capture /// that is a pack expansion. SourceLocation getEllipsisLoc() const { assert(isPackExpansion() && "No ellipsis location for a non-expansion"); return EllipsisLoc; } }; private: /// \brief Construct a lambda expression. LambdaExpr(QualType T, SourceRange IntroducerRange, LambdaCaptureDefault CaptureDefault, SourceLocation CaptureDefaultLoc, ArrayRef Captures, bool ExplicitParams, bool ExplicitResultType, ArrayRef CaptureInits, ArrayRef ArrayIndexVars, ArrayRef ArrayIndexStarts, SourceLocation ClosingBrace, bool ContainsUnexpandedParameterPack); /// \brief Construct an empty lambda expression. LambdaExpr(EmptyShell Empty, unsigned NumCaptures, bool HasArrayIndexVars) : Expr(LambdaExprClass, Empty), NumCaptures(NumCaptures), CaptureDefault(LCD_None), ExplicitParams(false), ExplicitResultType(false), HasArrayIndexVars(true) { getStoredStmts()[NumCaptures] = 0; } Stmt **getStoredStmts() const { return reinterpret_cast(const_cast(this) + 1); } /// \brief Retrieve the mapping from captures to the first array index /// variable. unsigned *getArrayIndexStarts() const { return reinterpret_cast(getStoredStmts() + NumCaptures + 1); } /// \brief Retrieve the complete set of array-index variables. VarDecl **getArrayIndexVars() const { unsigned ArrayIndexSize = llvm::RoundUpToAlignment(sizeof(unsigned) * (NumCaptures + 1), llvm::alignOf()); return reinterpret_cast( reinterpret_cast(getArrayIndexStarts()) + ArrayIndexSize); } public: /// \brief Construct a new lambda expression. static LambdaExpr *Create(const ASTContext &C, CXXRecordDecl *Class, SourceRange IntroducerRange, LambdaCaptureDefault CaptureDefault, SourceLocation CaptureDefaultLoc, ArrayRef Captures, bool ExplicitParams, bool ExplicitResultType, ArrayRef CaptureInits, ArrayRef ArrayIndexVars, ArrayRef ArrayIndexStarts, SourceLocation ClosingBrace, bool ContainsUnexpandedParameterPack); /// \brief Construct a new lambda expression that will be deserialized from /// an external source. static LambdaExpr *CreateDeserialized(const ASTContext &C, unsigned NumCaptures, unsigned NumArrayIndexVars); /// \brief Determine the default capture kind for this lambda. LambdaCaptureDefault getCaptureDefault() const { return static_cast(CaptureDefault); } /// \brief Retrieve the location of this lambda's capture-default, if any. SourceLocation getCaptureDefaultLoc() const { return CaptureDefaultLoc; } /// \brief An iterator that walks over the captures of the lambda, /// both implicit and explicit. typedef const Capture *capture_iterator; /// \brief Retrieve an iterator pointing to the first lambda capture. capture_iterator capture_begin() const; /// \brief Retrieve an iterator pointing past the end of the /// sequence of lambda captures. capture_iterator capture_end() const; /// \brief Determine the number of captures in this lambda. unsigned capture_size() const { return NumCaptures; } /// \brief Retrieve an iterator pointing to the first explicit /// lambda capture. capture_iterator explicit_capture_begin() const; /// \brief Retrieve an iterator pointing past the end of the sequence of /// explicit lambda captures. capture_iterator explicit_capture_end() const; /// \brief Retrieve an iterator pointing to the first implicit /// lambda capture. capture_iterator implicit_capture_begin() const; /// \brief Retrieve an iterator pointing past the end of the sequence of /// implicit lambda captures. capture_iterator implicit_capture_end() const; /// \brief Iterator that walks over the capture initialization /// arguments. typedef Expr **capture_init_iterator; /// \brief Retrieve the first initialization argument for this /// lambda expression (which initializes the first capture field). capture_init_iterator capture_init_begin() const { return reinterpret_cast(getStoredStmts()); } /// \brief Retrieve the iterator pointing one past the last /// initialization argument for this lambda expression. capture_init_iterator capture_init_end() const { return capture_init_begin() + NumCaptures; } /// \brief Retrieve the set of index variables used in the capture /// initializer of an array captured by copy. /// /// \param Iter The iterator that points at the capture initializer for /// which we are extracting the corresponding index variables. ArrayRef getCaptureInitIndexVars(capture_init_iterator Iter) const; /// \brief Retrieve the source range covering the lambda introducer, /// which contains the explicit capture list surrounded by square /// brackets ([...]). SourceRange getIntroducerRange() const { return IntroducerRange; } /// \brief Retrieve the class that corresponds to the lambda. /// /// This is the "closure type" (C++1y [expr.prim.lambda]), and stores the /// captures in its fields and provides the various operations permitted /// on a lambda (copying, calling). CXXRecordDecl *getLambdaClass() const; /// \brief Retrieve the function call operator associated with this /// lambda expression. CXXMethodDecl *getCallOperator() const; /// \brief If this is a generic lambda expression, retrieve the template /// parameter list associated with it, or else return null. TemplateParameterList *getTemplateParameterList() const; /// \brief Whether this is a generic lambda. bool isGenericLambda() const { return getTemplateParameterList(); } /// \brief Retrieve the body of the lambda. CompoundStmt *getBody() const; /// \brief Determine whether the lambda is mutable, meaning that any /// captures values can be modified. bool isMutable() const; /// \brief Determine whether this lambda has an explicit parameter /// list vs. an implicit (empty) parameter list. bool hasExplicitParameters() const { return ExplicitParams; } /// \brief Whether this lambda had its result type explicitly specified. bool hasExplicitResultType() const { return ExplicitResultType; } static bool classof(const Stmt *T) { return T->getStmtClass() == LambdaExprClass; } SourceLocation getLocStart() const LLVM_READONLY { return IntroducerRange.getBegin(); } SourceLocation getLocEnd() const LLVM_READONLY { return ClosingBrace; } child_range children() { return child_range(getStoredStmts(), getStoredStmts() + NumCaptures + 1); } friend class ASTStmtReader; friend class ASTStmtWriter; }; /// An expression "T()" which creates a value-initialized rvalue of type /// T, which is a non-class type. See (C++98 [5.2.3p2]). class CXXScalarValueInitExpr : public Expr { SourceLocation RParenLoc; TypeSourceInfo *TypeInfo; friend class ASTStmtReader; public: /// \brief Create an explicitly-written scalar-value initialization /// expression. CXXScalarValueInitExpr(QualType Type, TypeSourceInfo *TypeInfo, SourceLocation rParenLoc ) : Expr(CXXScalarValueInitExprClass, Type, VK_RValue, OK_Ordinary, false, false, Type->isInstantiationDependentType(), false), RParenLoc(rParenLoc), TypeInfo(TypeInfo) {} explicit CXXScalarValueInitExpr(EmptyShell Shell) : Expr(CXXScalarValueInitExprClass, Shell) { } TypeSourceInfo *getTypeSourceInfo() const { return TypeInfo; } SourceLocation getRParenLoc() const { return RParenLoc; } SourceLocation getLocStart() const LLVM_READONLY; SourceLocation getLocEnd() const LLVM_READONLY { return RParenLoc; } static bool classof(const Stmt *T) { return T->getStmtClass() == CXXScalarValueInitExprClass; } // Iterators child_range children() { return child_range(); } }; /// \brief Represents a new-expression for memory allocation and constructor /// calls, e.g: "new CXXNewExpr(foo)". class CXXNewExpr : public Expr { /// Contains an optional array size expression, an optional initialization /// expression, and any number of optional placement arguments, in that order. Stmt **SubExprs; /// \brief Points to the allocation function used. FunctionDecl *OperatorNew; /// \brief Points to the deallocation function used in case of error. May be /// null. FunctionDecl *OperatorDelete; /// \brief The allocated type-source information, as written in the source. TypeSourceInfo *AllocatedTypeInfo; /// \brief If the allocated type was expressed as a parenthesized type-id, /// the source range covering the parenthesized type-id. SourceRange TypeIdParens; /// \brief Range of the entire new expression. SourceRange Range; /// \brief Source-range of a paren-delimited initializer. SourceRange DirectInitRange; /// Was the usage ::new, i.e. is the global new to be used? bool GlobalNew : 1; /// Do we allocate an array? If so, the first SubExpr is the size expression. bool Array : 1; /// If this is an array allocation, does the usual deallocation /// function for the allocated type want to know the allocated size? bool UsualArrayDeleteWantsSize : 1; /// The number of placement new arguments. unsigned NumPlacementArgs : 13; /// What kind of initializer do we have? Could be none, parens, or braces. /// In storage, we distinguish between "none, and no initializer expr", and /// "none, but an implicit initializer expr". unsigned StoredInitializationStyle : 2; friend class ASTStmtReader; friend class ASTStmtWriter; public: enum InitializationStyle { NoInit, ///< New-expression has no initializer as written. CallInit, ///< New-expression has a C++98 paren-delimited initializer. ListInit ///< New-expression has a C++11 list-initializer. }; CXXNewExpr(const ASTContext &C, bool globalNew, FunctionDecl *operatorNew, FunctionDecl *operatorDelete, bool usualArrayDeleteWantsSize, ArrayRef placementArgs, SourceRange typeIdParens, Expr *arraySize, InitializationStyle initializationStyle, Expr *initializer, QualType ty, TypeSourceInfo *AllocatedTypeInfo, SourceRange Range, SourceRange directInitRange); explicit CXXNewExpr(EmptyShell Shell) : Expr(CXXNewExprClass, Shell), SubExprs(0) { } void AllocateArgsArray(const ASTContext &C, bool isArray, unsigned numPlaceArgs, bool hasInitializer); QualType getAllocatedType() const { assert(getType()->isPointerType()); return getType()->getAs()->getPointeeType(); } TypeSourceInfo *getAllocatedTypeSourceInfo() const { return AllocatedTypeInfo; } /// \brief True if the allocation result needs to be null-checked. /// /// C++11 [expr.new]p13: /// If the allocation function returns null, initialization shall /// not be done, the deallocation function shall not be called, /// and the value of the new-expression shall be null. /// /// An allocation function is not allowed to return null unless it /// has a non-throwing exception-specification. The '03 rule is /// identical except that the definition of a non-throwing /// exception specification is just "is it throw()?". bool shouldNullCheckAllocation(const ASTContext &Ctx) const; FunctionDecl *getOperatorNew() const { return OperatorNew; } void setOperatorNew(FunctionDecl *D) { OperatorNew = D; } FunctionDecl *getOperatorDelete() const { return OperatorDelete; } void setOperatorDelete(FunctionDecl *D) { OperatorDelete = D; } bool isArray() const { return Array; } Expr *getArraySize() { return Array ? cast(SubExprs[0]) : 0; } const Expr *getArraySize() const { return Array ? cast(SubExprs[0]) : 0; } unsigned getNumPlacementArgs() const { return NumPlacementArgs; } Expr **getPlacementArgs() { return reinterpret_cast(SubExprs + Array + hasInitializer()); } Expr *getPlacementArg(unsigned i) { assert(i < NumPlacementArgs && "Index out of range"); return getPlacementArgs()[i]; } const Expr *getPlacementArg(unsigned i) const { assert(i < NumPlacementArgs && "Index out of range"); return const_cast(this)->getPlacementArg(i); } bool isParenTypeId() const { return TypeIdParens.isValid(); } SourceRange getTypeIdParens() const { return TypeIdParens; } bool isGlobalNew() const { return GlobalNew; } /// \brief Whether this new-expression has any initializer at all. bool hasInitializer() const { return StoredInitializationStyle > 0; } /// \brief The kind of initializer this new-expression has. InitializationStyle getInitializationStyle() const { if (StoredInitializationStyle == 0) return NoInit; return static_cast(StoredInitializationStyle-1); } /// \brief The initializer of this new-expression. Expr *getInitializer() { return hasInitializer() ? cast(SubExprs[Array]) : 0; } const Expr *getInitializer() const { return hasInitializer() ? cast(SubExprs[Array]) : 0; } /// \brief Returns the CXXConstructExpr from this new-expression, or null. const CXXConstructExpr* getConstructExpr() const { return dyn_cast_or_null(getInitializer()); } /// Answers whether the usual array deallocation function for the /// allocated type expects the size of the allocation as a /// parameter. bool doesUsualArrayDeleteWantSize() const { return UsualArrayDeleteWantsSize; } typedef ExprIterator arg_iterator; typedef ConstExprIterator const_arg_iterator; arg_iterator placement_arg_begin() { return SubExprs + Array + hasInitializer(); } arg_iterator placement_arg_end() { return SubExprs + Array + hasInitializer() + getNumPlacementArgs(); } const_arg_iterator placement_arg_begin() const { return SubExprs + Array + hasInitializer(); } const_arg_iterator placement_arg_end() const { return SubExprs + Array + hasInitializer() + getNumPlacementArgs(); } typedef Stmt **raw_arg_iterator; raw_arg_iterator raw_arg_begin() { return SubExprs; } raw_arg_iterator raw_arg_end() { return SubExprs + Array + hasInitializer() + getNumPlacementArgs(); } const_arg_iterator raw_arg_begin() const { return SubExprs; } const_arg_iterator raw_arg_end() const { return SubExprs + Array + hasInitializer() + getNumPlacementArgs(); } SourceLocation getStartLoc() const { return Range.getBegin(); } SourceLocation getEndLoc() const { return Range.getEnd(); } SourceRange getDirectInitRange() const { return DirectInitRange; } SourceRange getSourceRange() const LLVM_READONLY { return Range; } SourceLocation getLocStart() const LLVM_READONLY { return getStartLoc(); } SourceLocation getLocEnd() const LLVM_READONLY { return getEndLoc(); } static bool classof(const Stmt *T) { return T->getStmtClass() == CXXNewExprClass; } // Iterators child_range children() { return child_range(raw_arg_begin(), raw_arg_end()); } }; /// \brief Represents a \c delete expression for memory deallocation and /// destructor calls, e.g. "delete[] pArray". class CXXDeleteExpr : public Expr { /// Points to the operator delete overload that is used. Could be a member. FunctionDecl *OperatorDelete; /// The pointer expression to be deleted. Stmt *Argument; /// Location of the expression. SourceLocation Loc; /// Is this a forced global delete, i.e. "::delete"? bool GlobalDelete : 1; /// Is this the array form of delete, i.e. "delete[]"? bool ArrayForm : 1; /// ArrayFormAsWritten can be different from ArrayForm if 'delete' is applied /// to pointer-to-array type (ArrayFormAsWritten will be false while ArrayForm /// will be true). bool ArrayFormAsWritten : 1; /// Does the usual deallocation function for the element type require /// a size_t argument? bool UsualArrayDeleteWantsSize : 1; public: CXXDeleteExpr(QualType ty, bool globalDelete, bool arrayForm, bool arrayFormAsWritten, bool usualArrayDeleteWantsSize, FunctionDecl *operatorDelete, Expr *arg, SourceLocation loc) : Expr(CXXDeleteExprClass, ty, VK_RValue, OK_Ordinary, false, false, arg->isInstantiationDependent(), arg->containsUnexpandedParameterPack()), OperatorDelete(operatorDelete), Argument(arg), Loc(loc), GlobalDelete(globalDelete), ArrayForm(arrayForm), ArrayFormAsWritten(arrayFormAsWritten), UsualArrayDeleteWantsSize(usualArrayDeleteWantsSize) { } explicit CXXDeleteExpr(EmptyShell Shell) : Expr(CXXDeleteExprClass, Shell), OperatorDelete(0), Argument(0) { } bool isGlobalDelete() const { return GlobalDelete; } bool isArrayForm() const { return ArrayForm; } bool isArrayFormAsWritten() const { return ArrayFormAsWritten; } /// Answers whether the usual array deallocation function for the /// allocated type expects the size of the allocation as a /// parameter. This can be true even if the actual deallocation /// function that we're using doesn't want a size. bool doesUsualArrayDeleteWantSize() const { return UsualArrayDeleteWantsSize; } FunctionDecl *getOperatorDelete() const { return OperatorDelete; } Expr *getArgument() { return cast(Argument); } const Expr *getArgument() const { return cast(Argument); } /// \brief Retrieve the type being destroyed. /// /// If the type being destroyed is a dependent type which may or may not /// be a pointer, return an invalid type. QualType getDestroyedType() const; SourceLocation getLocStart() const LLVM_READONLY { return Loc; } SourceLocation getLocEnd() const LLVM_READONLY {return Argument->getLocEnd();} static bool classof(const Stmt *T) { return T->getStmtClass() == CXXDeleteExprClass; } // Iterators child_range children() { return child_range(&Argument, &Argument+1); } friend class ASTStmtReader; }; /// \brief Stores the type being destroyed by a pseudo-destructor expression. class PseudoDestructorTypeStorage { /// \brief Either the type source information or the name of the type, if /// it couldn't be resolved due to type-dependence. llvm::PointerUnion Type; /// \brief The starting source location of the pseudo-destructor type. SourceLocation Location; public: PseudoDestructorTypeStorage() { } PseudoDestructorTypeStorage(IdentifierInfo *II, SourceLocation Loc) : Type(II), Location(Loc) { } PseudoDestructorTypeStorage(TypeSourceInfo *Info); TypeSourceInfo *getTypeSourceInfo() const { return Type.dyn_cast(); } IdentifierInfo *getIdentifier() const { return Type.dyn_cast(); } SourceLocation getLocation() const { return Location; } }; /// \brief Represents a C++ pseudo-destructor (C++ [expr.pseudo]). /// /// A pseudo-destructor is an expression that looks like a member access to a /// destructor of a scalar type, except that scalar types don't have /// destructors. For example: /// /// \code /// typedef int T; /// void f(int *p) { /// p->T::~T(); /// } /// \endcode /// /// Pseudo-destructors typically occur when instantiating templates such as: /// /// \code /// template /// void destroy(T* ptr) { /// ptr->T::~T(); /// } /// \endcode /// /// for scalar types. A pseudo-destructor expression has no run-time semantics /// beyond evaluating the base expression. class CXXPseudoDestructorExpr : public Expr { /// \brief The base expression (that is being destroyed). Stmt *Base; /// \brief Whether the operator was an arrow ('->'); otherwise, it was a /// period ('.'). bool IsArrow : 1; /// \brief The location of the '.' or '->' operator. SourceLocation OperatorLoc; /// \brief The nested-name-specifier that follows the operator, if present. NestedNameSpecifierLoc QualifierLoc; /// \brief The type that precedes the '::' in a qualified pseudo-destructor /// expression. TypeSourceInfo *ScopeType; /// \brief The location of the '::' in a qualified pseudo-destructor /// expression. SourceLocation ColonColonLoc; /// \brief The location of the '~'. SourceLocation TildeLoc; /// \brief The type being destroyed, or its name if we were unable to /// resolve the name. PseudoDestructorTypeStorage DestroyedType; friend class ASTStmtReader; public: CXXPseudoDestructorExpr(const ASTContext &Context, Expr *Base, bool isArrow, SourceLocation OperatorLoc, NestedNameSpecifierLoc QualifierLoc, TypeSourceInfo *ScopeType, SourceLocation ColonColonLoc, SourceLocation TildeLoc, PseudoDestructorTypeStorage DestroyedType); explicit CXXPseudoDestructorExpr(EmptyShell Shell) : Expr(CXXPseudoDestructorExprClass, Shell), Base(0), IsArrow(false), QualifierLoc(), ScopeType(0) { } Expr *getBase() const { return cast(Base); } /// \brief Determines whether this member expression actually had /// a C++ nested-name-specifier prior to the name of the member, e.g., /// x->Base::foo. bool hasQualifier() const { return QualifierLoc.hasQualifier(); } /// \brief Retrieves the nested-name-specifier that qualifies the type name, /// with source-location information. NestedNameSpecifierLoc getQualifierLoc() const { return QualifierLoc; } /// \brief If the member name was qualified, retrieves the /// nested-name-specifier that precedes the member name. Otherwise, returns /// null. NestedNameSpecifier *getQualifier() const { return QualifierLoc.getNestedNameSpecifier(); } /// \brief Determine whether this pseudo-destructor expression was written /// using an '->' (otherwise, it used a '.'). bool isArrow() const { return IsArrow; } /// \brief Retrieve the location of the '.' or '->' operator. SourceLocation getOperatorLoc() const { return OperatorLoc; } /// \brief Retrieve the scope type in a qualified pseudo-destructor /// expression. /// /// Pseudo-destructor expressions can have extra qualification within them /// that is not part of the nested-name-specifier, e.g., \c p->T::~T(). /// Here, if the object type of the expression is (or may be) a scalar type, /// \p T may also be a scalar type and, therefore, cannot be part of a /// nested-name-specifier. It is stored as the "scope type" of the pseudo- /// destructor expression. TypeSourceInfo *getScopeTypeInfo() const { return ScopeType; } /// \brief Retrieve the location of the '::' in a qualified pseudo-destructor /// expression. SourceLocation getColonColonLoc() const { return ColonColonLoc; } /// \brief Retrieve the location of the '~'. SourceLocation getTildeLoc() const { return TildeLoc; } /// \brief Retrieve the source location information for the type /// being destroyed. /// /// This type-source information is available for non-dependent /// pseudo-destructor expressions and some dependent pseudo-destructor /// expressions. Returns null if we only have the identifier for a /// dependent pseudo-destructor expression. TypeSourceInfo *getDestroyedTypeInfo() const { return DestroyedType.getTypeSourceInfo(); } /// \brief In a dependent pseudo-destructor expression for which we do not /// have full type information on the destroyed type, provides the name /// of the destroyed type. IdentifierInfo *getDestroyedTypeIdentifier() const { return DestroyedType.getIdentifier(); } /// \brief Retrieve the type being destroyed. QualType getDestroyedType() const; /// \brief Retrieve the starting location of the type being destroyed. SourceLocation getDestroyedTypeLoc() const { return DestroyedType.getLocation(); } /// \brief Set the name of destroyed type for a dependent pseudo-destructor /// expression. void setDestroyedType(IdentifierInfo *II, SourceLocation Loc) { DestroyedType = PseudoDestructorTypeStorage(II, Loc); } /// \brief Set the destroyed type. void setDestroyedType(TypeSourceInfo *Info) { DestroyedType = PseudoDestructorTypeStorage(Info); } SourceLocation getLocStart() const LLVM_READONLY {return Base->getLocStart();} SourceLocation getLocEnd() const LLVM_READONLY; static bool classof(const Stmt *T) { return T->getStmtClass() == CXXPseudoDestructorExprClass; } // Iterators child_range children() { return child_range(&Base, &Base + 1); } }; /// \brief Represents a GCC or MS unary type trait, as used in the /// implementation of TR1/C++11 type trait templates. /// /// Example: /// \code /// __is_pod(int) == true /// __is_enum(std::string) == false /// \endcode class UnaryTypeTraitExpr : public Expr { /// \brief The trait. A UnaryTypeTrait enum in MSVC compatible unsigned. unsigned UTT : 31; /// The value of the type trait. Unspecified if dependent. bool Value : 1; /// \brief The location of the type trait keyword. SourceLocation Loc; /// \brief The location of the closing paren. SourceLocation RParen; /// \brief The type being queried. TypeSourceInfo *QueriedType; public: UnaryTypeTraitExpr(SourceLocation loc, UnaryTypeTrait utt, TypeSourceInfo *queried, bool value, SourceLocation rparen, QualType ty) : Expr(UnaryTypeTraitExprClass, ty, VK_RValue, OK_Ordinary, false, queried->getType()->isDependentType(), queried->getType()->isInstantiationDependentType(), queried->getType()->containsUnexpandedParameterPack()), UTT(utt), Value(value), Loc(loc), RParen(rparen), QueriedType(queried) { } explicit UnaryTypeTraitExpr(EmptyShell Empty) : Expr(UnaryTypeTraitExprClass, Empty), UTT(0), Value(false), QueriedType() { } SourceLocation getLocStart() const LLVM_READONLY { return Loc; } SourceLocation getLocEnd() const LLVM_READONLY { return RParen; } UnaryTypeTrait getTrait() const { return static_cast(UTT); } QualType getQueriedType() const { return QueriedType->getType(); } TypeSourceInfo *getQueriedTypeSourceInfo() const { return QueriedType; } bool getValue() const { return Value; } static bool classof(const Stmt *T) { return T->getStmtClass() == UnaryTypeTraitExprClass; } // Iterators child_range children() { return child_range(); } friend class ASTStmtReader; }; /// \brief Represents a GCC or MS binary type trait, as used in the /// implementation of TR1/C++11 type trait templates. /// /// Example: /// \code /// __is_base_of(Base, Derived) == true /// \endcode class BinaryTypeTraitExpr : public Expr { /// \brief The trait. A BinaryTypeTrait enum in MSVC compatible unsigned. unsigned BTT : 8; /// The value of the type trait. Unspecified if dependent. bool Value : 1; /// \brief The location of the type trait keyword. SourceLocation Loc; /// \brief The location of the closing paren. SourceLocation RParen; /// \brief The lhs type being queried. TypeSourceInfo *LhsType; /// \brief The rhs type being queried. TypeSourceInfo *RhsType; public: BinaryTypeTraitExpr(SourceLocation loc, BinaryTypeTrait btt, TypeSourceInfo *lhsType, TypeSourceInfo *rhsType, bool value, SourceLocation rparen, QualType ty) : Expr(BinaryTypeTraitExprClass, ty, VK_RValue, OK_Ordinary, false, lhsType->getType()->isDependentType() || rhsType->getType()->isDependentType(), (lhsType->getType()->isInstantiationDependentType() || rhsType->getType()->isInstantiationDependentType()), (lhsType->getType()->containsUnexpandedParameterPack() || rhsType->getType()->containsUnexpandedParameterPack())), BTT(btt), Value(value), Loc(loc), RParen(rparen), LhsType(lhsType), RhsType(rhsType) { } explicit BinaryTypeTraitExpr(EmptyShell Empty) : Expr(BinaryTypeTraitExprClass, Empty), BTT(0), Value(false), LhsType(), RhsType() { } SourceLocation getLocStart() const LLVM_READONLY { return Loc; } SourceLocation getLocEnd() const LLVM_READONLY { return RParen; } BinaryTypeTrait getTrait() const { return static_cast(BTT); } QualType getLhsType() const { return LhsType->getType(); } QualType getRhsType() const { return RhsType->getType(); } TypeSourceInfo *getLhsTypeSourceInfo() const { return LhsType; } TypeSourceInfo *getRhsTypeSourceInfo() const { return RhsType; } bool getValue() const { assert(!isTypeDependent()); return Value; } static bool classof(const Stmt *T) { return T->getStmtClass() == BinaryTypeTraitExprClass; } // Iterators child_range children() { return child_range(); } friend class ASTStmtReader; }; /// \brief A type trait used in the implementation of various C++11 and /// Library TR1 trait templates. /// /// \code /// __is_trivially_constructible(vector, int*, int*) /// \endcode class TypeTraitExpr : public Expr { /// \brief The location of the type trait keyword. SourceLocation Loc; /// \brief The location of the closing parenthesis. SourceLocation RParenLoc; // Note: The TypeSourceInfos for the arguments are allocated after the // TypeTraitExpr. TypeTraitExpr(QualType T, SourceLocation Loc, TypeTrait Kind, ArrayRef Args, SourceLocation RParenLoc, bool Value); TypeTraitExpr(EmptyShell Empty) : Expr(TypeTraitExprClass, Empty) { } /// \brief Retrieve the argument types. TypeSourceInfo **getTypeSourceInfos() { return reinterpret_cast(this+1); } /// \brief Retrieve the argument types. TypeSourceInfo * const *getTypeSourceInfos() const { return reinterpret_cast(this+1); } public: /// \brief Create a new type trait expression. static TypeTraitExpr *Create(const ASTContext &C, QualType T, SourceLocation Loc, TypeTrait Kind, ArrayRef Args, SourceLocation RParenLoc, bool Value); static TypeTraitExpr *CreateDeserialized(const ASTContext &C, unsigned NumArgs); /// \brief Determine which type trait this expression uses. TypeTrait getTrait() const { return static_cast(TypeTraitExprBits.Kind); } bool getValue() const { assert(!isValueDependent()); return TypeTraitExprBits.Value; } /// \brief Determine the number of arguments to this type trait. unsigned getNumArgs() const { return TypeTraitExprBits.NumArgs; } /// \brief Retrieve the Ith argument. TypeSourceInfo *getArg(unsigned I) const { assert(I < getNumArgs() && "Argument out-of-range"); return getArgs()[I]; } /// \brief Retrieve the argument types. ArrayRef getArgs() const { return ArrayRef(getTypeSourceInfos(), getNumArgs()); } typedef TypeSourceInfo **arg_iterator; arg_iterator arg_begin() { return getTypeSourceInfos(); } arg_iterator arg_end() { return getTypeSourceInfos() + getNumArgs(); } typedef TypeSourceInfo const * const *arg_const_iterator; arg_const_iterator arg_begin() const { return getTypeSourceInfos(); } arg_const_iterator arg_end() const { return getTypeSourceInfos() + getNumArgs(); } SourceLocation getLocStart() const LLVM_READONLY { return Loc; } SourceLocation getLocEnd() const LLVM_READONLY { return RParenLoc; } static bool classof(const Stmt *T) { return T->getStmtClass() == TypeTraitExprClass; } // Iterators child_range children() { return child_range(); } friend class ASTStmtReader; friend class ASTStmtWriter; }; /// \brief An Embarcadero array type trait, as used in the implementation of /// __array_rank and __array_extent. /// /// Example: /// \code /// __array_rank(int[10][20]) == 2 /// __array_extent(int, 1) == 20 /// \endcode class ArrayTypeTraitExpr : public Expr { virtual void anchor(); /// \brief The trait. An ArrayTypeTrait enum in MSVC compat unsigned. unsigned ATT : 2; /// \brief The value of the type trait. Unspecified if dependent. uint64_t Value; /// \brief The array dimension being queried, or -1 if not used. Expr *Dimension; /// \brief The location of the type trait keyword. SourceLocation Loc; /// \brief The location of the closing paren. SourceLocation RParen; /// \brief The type being queried. TypeSourceInfo *QueriedType; public: ArrayTypeTraitExpr(SourceLocation loc, ArrayTypeTrait att, TypeSourceInfo *queried, uint64_t value, Expr *dimension, SourceLocation rparen, QualType ty) : Expr(ArrayTypeTraitExprClass, ty, VK_RValue, OK_Ordinary, false, queried->getType()->isDependentType(), (queried->getType()->isInstantiationDependentType() || (dimension && dimension->isInstantiationDependent())), queried->getType()->containsUnexpandedParameterPack()), ATT(att), Value(value), Dimension(dimension), Loc(loc), RParen(rparen), QueriedType(queried) { } explicit ArrayTypeTraitExpr(EmptyShell Empty) : Expr(ArrayTypeTraitExprClass, Empty), ATT(0), Value(false), QueriedType() { } virtual ~ArrayTypeTraitExpr() { } SourceLocation getLocStart() const LLVM_READONLY { return Loc; } SourceLocation getLocEnd() const LLVM_READONLY { return RParen; } ArrayTypeTrait getTrait() const { return static_cast(ATT); } QualType getQueriedType() const { return QueriedType->getType(); } TypeSourceInfo *getQueriedTypeSourceInfo() const { return QueriedType; } uint64_t getValue() const { assert(!isTypeDependent()); return Value; } Expr *getDimensionExpression() const { return Dimension; } static bool classof(const Stmt *T) { return T->getStmtClass() == ArrayTypeTraitExprClass; } // Iterators child_range children() { return child_range(); } friend class ASTStmtReader; }; /// \brief An expression trait intrinsic. /// /// Example: /// \code /// __is_lvalue_expr(std::cout) == true /// __is_lvalue_expr(1) == false /// \endcode class ExpressionTraitExpr : public Expr { /// \brief The trait. A ExpressionTrait enum in MSVC compatible unsigned. unsigned ET : 31; /// \brief The value of the type trait. Unspecified if dependent. bool Value : 1; /// \brief The location of the type trait keyword. SourceLocation Loc; /// \brief The location of the closing paren. SourceLocation RParen; /// \brief The expression being queried. Expr* QueriedExpression; public: ExpressionTraitExpr(SourceLocation loc, ExpressionTrait et, Expr *queried, bool value, SourceLocation rparen, QualType resultType) : Expr(ExpressionTraitExprClass, resultType, VK_RValue, OK_Ordinary, false, // Not type-dependent // Value-dependent if the argument is type-dependent. queried->isTypeDependent(), queried->isInstantiationDependent(), queried->containsUnexpandedParameterPack()), ET(et), Value(value), Loc(loc), RParen(rparen), QueriedExpression(queried) { } explicit ExpressionTraitExpr(EmptyShell Empty) : Expr(ExpressionTraitExprClass, Empty), ET(0), Value(false), QueriedExpression() { } SourceLocation getLocStart() const LLVM_READONLY { return Loc; } SourceLocation getLocEnd() const LLVM_READONLY { return RParen; } ExpressionTrait getTrait() const { return static_cast(ET); } Expr *getQueriedExpression() const { return QueriedExpression; } bool getValue() const { return Value; } static bool classof(const Stmt *T) { return T->getStmtClass() == ExpressionTraitExprClass; } // Iterators child_range children() { return child_range(); } friend class ASTStmtReader; }; /// \brief A reference to an overloaded function set, either an /// \c UnresolvedLookupExpr or an \c UnresolvedMemberExpr. class OverloadExpr : public Expr { /// \brief The common name of these declarations. DeclarationNameInfo NameInfo; /// \brief The nested-name-specifier that qualifies the name, if any. NestedNameSpecifierLoc QualifierLoc; /// The results. These are undesugared, which is to say, they may /// include UsingShadowDecls. Access is relative to the naming /// class. // FIXME: Allocate this data after the OverloadExpr subclass. DeclAccessPair *Results; unsigned NumResults; protected: /// \brief Whether the name includes info for explicit template /// keyword and arguments. bool HasTemplateKWAndArgsInfo; /// \brief Return the optional template keyword and arguments info. ASTTemplateKWAndArgsInfo *getTemplateKWAndArgsInfo(); // defined far below. /// \brief Return the optional template keyword and arguments info. const ASTTemplateKWAndArgsInfo *getTemplateKWAndArgsInfo() const { return const_cast(this)->getTemplateKWAndArgsInfo(); } OverloadExpr(StmtClass K, const ASTContext &C, NestedNameSpecifierLoc QualifierLoc, SourceLocation TemplateKWLoc, const DeclarationNameInfo &NameInfo, const TemplateArgumentListInfo *TemplateArgs, UnresolvedSetIterator Begin, UnresolvedSetIterator End, bool KnownDependent, bool KnownInstantiationDependent, bool KnownContainsUnexpandedParameterPack); OverloadExpr(StmtClass K, EmptyShell Empty) : Expr(K, Empty), QualifierLoc(), Results(0), NumResults(0), HasTemplateKWAndArgsInfo(false) { } void initializeResults(const ASTContext &C, UnresolvedSetIterator Begin, UnresolvedSetIterator End); public: struct FindResult { OverloadExpr *Expression; bool IsAddressOfOperand; bool HasFormOfMemberPointer; }; /// \brief Finds the overloaded expression in the given expression \p E of /// OverloadTy. /// /// \return the expression (which must be there) and true if it has /// the particular form of a member pointer expression static FindResult find(Expr *E) { assert(E->getType()->isSpecificBuiltinType(BuiltinType::Overload)); FindResult Result; E = E->IgnoreParens(); if (isa(E)) { assert(cast(E)->getOpcode() == UO_AddrOf); E = cast(E)->getSubExpr(); OverloadExpr *Ovl = cast(E->IgnoreParens()); Result.HasFormOfMemberPointer = (E == Ovl && Ovl->getQualifier()); Result.IsAddressOfOperand = true; Result.Expression = Ovl; } else { Result.HasFormOfMemberPointer = false; Result.IsAddressOfOperand = false; Result.Expression = cast(E); } return Result; } /// \brief Gets the naming class of this lookup, if any. CXXRecordDecl *getNamingClass() const; typedef UnresolvedSetImpl::iterator decls_iterator; decls_iterator decls_begin() const { return UnresolvedSetIterator(Results); } decls_iterator decls_end() const { return UnresolvedSetIterator(Results + NumResults); } /// \brief Gets the number of declarations in the unresolved set. unsigned getNumDecls() const { return NumResults; } /// \brief Gets the full name info. const DeclarationNameInfo &getNameInfo() const { return NameInfo; } /// \brief Gets the name looked up. DeclarationName getName() const { return NameInfo.getName(); } /// \brief Gets the location of the name. SourceLocation getNameLoc() const { return NameInfo.getLoc(); } /// \brief Fetches the nested-name qualifier, if one was given. NestedNameSpecifier *getQualifier() const { return QualifierLoc.getNestedNameSpecifier(); } /// \brief Fetches the nested-name qualifier with source-location /// information, if one was given. NestedNameSpecifierLoc getQualifierLoc() const { return QualifierLoc; } /// \brief Retrieve the location of the template keyword preceding /// this name, if any. SourceLocation getTemplateKeywordLoc() const { if (!HasTemplateKWAndArgsInfo) return SourceLocation(); return getTemplateKWAndArgsInfo()->getTemplateKeywordLoc(); } /// \brief Retrieve the location of the left angle bracket starting the /// explicit template argument list following the name, if any. SourceLocation getLAngleLoc() const { if (!HasTemplateKWAndArgsInfo) return SourceLocation(); return getTemplateKWAndArgsInfo()->LAngleLoc; } /// \brief Retrieve the location of the right angle bracket ending the /// explicit template argument list following the name, if any. SourceLocation getRAngleLoc() const { if (!HasTemplateKWAndArgsInfo) return SourceLocation(); return getTemplateKWAndArgsInfo()->RAngleLoc; } /// \brief Determines whether the name was preceded by the template keyword. bool hasTemplateKeyword() const { return getTemplateKeywordLoc().isValid(); } /// \brief Determines whether this expression had explicit template arguments. bool hasExplicitTemplateArgs() const { return getLAngleLoc().isValid(); } // Note that, inconsistently with the explicit-template-argument AST // nodes, users are *forbidden* from calling these methods on objects // without explicit template arguments. ASTTemplateArgumentListInfo &getExplicitTemplateArgs() { assert(hasExplicitTemplateArgs()); return *getTemplateKWAndArgsInfo(); } const ASTTemplateArgumentListInfo &getExplicitTemplateArgs() const { return const_cast(this)->getExplicitTemplateArgs(); } TemplateArgumentLoc const *getTemplateArgs() const { return getExplicitTemplateArgs().getTemplateArgs(); } unsigned getNumTemplateArgs() const { return getExplicitTemplateArgs().NumTemplateArgs; } /// \brief Copies the template arguments into the given structure. void copyTemplateArgumentsInto(TemplateArgumentListInfo &List) const { getExplicitTemplateArgs().copyInto(List); } /// \brief Retrieves the optional explicit template arguments. /// /// This points to the same data as getExplicitTemplateArgs(), but /// returns null if there are no explicit template arguments. const ASTTemplateArgumentListInfo *getOptionalExplicitTemplateArgs() const { if (!hasExplicitTemplateArgs()) return 0; return &getExplicitTemplateArgs(); } static bool classof(const Stmt *T) { return T->getStmtClass() == UnresolvedLookupExprClass || T->getStmtClass() == UnresolvedMemberExprClass; } friend class ASTStmtReader; friend class ASTStmtWriter; }; /// \brief A reference to a name which we were able to look up during /// parsing but could not resolve to a specific declaration. /// /// This arises in several ways: /// * we might be waiting for argument-dependent lookup; /// * the name might resolve to an overloaded function; /// and eventually: /// * the lookup might have included a function template. /// /// These never include UnresolvedUsingValueDecls, which are always class /// members and therefore appear only in UnresolvedMemberLookupExprs. class UnresolvedLookupExpr : public OverloadExpr { /// True if these lookup results should be extended by /// argument-dependent lookup if this is the operand of a function /// call. bool RequiresADL; /// True if these lookup results are overloaded. This is pretty /// trivially rederivable if we urgently need to kill this field. bool Overloaded; /// The naming class (C++ [class.access.base]p5) of the lookup, if /// any. This can generally be recalculated from the context chain, /// but that can be fairly expensive for unqualified lookups. If we /// want to improve memory use here, this could go in a union /// against the qualified-lookup bits. CXXRecordDecl *NamingClass; UnresolvedLookupExpr(const ASTContext &C, CXXRecordDecl *NamingClass, NestedNameSpecifierLoc QualifierLoc, SourceLocation TemplateKWLoc, const DeclarationNameInfo &NameInfo, bool RequiresADL, bool Overloaded, const TemplateArgumentListInfo *TemplateArgs, UnresolvedSetIterator Begin, UnresolvedSetIterator End) : OverloadExpr(UnresolvedLookupExprClass, C, QualifierLoc, TemplateKWLoc, NameInfo, TemplateArgs, Begin, End, false, false, false), RequiresADL(RequiresADL), Overloaded(Overloaded), NamingClass(NamingClass) {} UnresolvedLookupExpr(EmptyShell Empty) : OverloadExpr(UnresolvedLookupExprClass, Empty), RequiresADL(false), Overloaded(false), NamingClass(0) {} friend class ASTStmtReader; public: static UnresolvedLookupExpr *Create(const ASTContext &C, CXXRecordDecl *NamingClass, NestedNameSpecifierLoc QualifierLoc, const DeclarationNameInfo &NameInfo, bool ADL, bool Overloaded, UnresolvedSetIterator Begin, UnresolvedSetIterator End) { return new(C) UnresolvedLookupExpr(C, NamingClass, QualifierLoc, SourceLocation(), NameInfo, ADL, Overloaded, 0, Begin, End); } static UnresolvedLookupExpr *Create(const ASTContext &C, CXXRecordDecl *NamingClass, NestedNameSpecifierLoc QualifierLoc, SourceLocation TemplateKWLoc, const DeclarationNameInfo &NameInfo, bool ADL, const TemplateArgumentListInfo *Args, UnresolvedSetIterator Begin, UnresolvedSetIterator End); static UnresolvedLookupExpr *CreateEmpty(const ASTContext &C, bool HasTemplateKWAndArgsInfo, unsigned NumTemplateArgs); /// True if this declaration should be extended by /// argument-dependent lookup. bool requiresADL() const { return RequiresADL; } /// True if this lookup is overloaded. bool isOverloaded() const { return Overloaded; } /// Gets the 'naming class' (in the sense of C++0x /// [class.access.base]p5) of the lookup. This is the scope /// that was looked in to find these results. CXXRecordDecl *getNamingClass() const { return NamingClass; } SourceLocation getLocStart() const LLVM_READONLY { if (NestedNameSpecifierLoc l = getQualifierLoc()) return l.getBeginLoc(); return getNameInfo().getLocStart(); } SourceLocation getLocEnd() const LLVM_READONLY { if (hasExplicitTemplateArgs()) return getRAngleLoc(); return getNameInfo().getLocEnd(); } child_range children() { return child_range(); } static bool classof(const Stmt *T) { return T->getStmtClass() == UnresolvedLookupExprClass; } }; /// \brief A qualified reference to a name whose declaration cannot /// yet be resolved. /// /// DependentScopeDeclRefExpr is similar to DeclRefExpr in that /// it expresses a reference to a declaration such as /// X::value. The difference, however, is that an /// DependentScopeDeclRefExpr node is used only within C++ templates when /// the qualification (e.g., X::) refers to a dependent type. In /// this case, X::value cannot resolve to a declaration because the /// declaration will differ from one instantiation of X to the /// next. Therefore, DependentScopeDeclRefExpr keeps track of the /// qualifier (X::) and the name of the entity being referenced /// ("value"). Such expressions will instantiate to a DeclRefExpr once the /// declaration can be found. class DependentScopeDeclRefExpr : public Expr { /// \brief The nested-name-specifier that qualifies this unresolved /// declaration name. NestedNameSpecifierLoc QualifierLoc; /// \brief The name of the entity we will be referencing. DeclarationNameInfo NameInfo; /// \brief Whether the name includes info for explicit template /// keyword and arguments. bool HasTemplateKWAndArgsInfo; /// \brief Return the optional template keyword and arguments info. ASTTemplateKWAndArgsInfo *getTemplateKWAndArgsInfo() { if (!HasTemplateKWAndArgsInfo) return 0; return reinterpret_cast(this + 1); } /// \brief Return the optional template keyword and arguments info. const ASTTemplateKWAndArgsInfo *getTemplateKWAndArgsInfo() const { return const_cast(this) ->getTemplateKWAndArgsInfo(); } DependentScopeDeclRefExpr(QualType T, NestedNameSpecifierLoc QualifierLoc, SourceLocation TemplateKWLoc, const DeclarationNameInfo &NameInfo, const TemplateArgumentListInfo *Args); public: static DependentScopeDeclRefExpr *Create(const ASTContext &C, NestedNameSpecifierLoc QualifierLoc, SourceLocation TemplateKWLoc, const DeclarationNameInfo &NameInfo, const TemplateArgumentListInfo *TemplateArgs); static DependentScopeDeclRefExpr *CreateEmpty(const ASTContext &C, bool HasTemplateKWAndArgsInfo, unsigned NumTemplateArgs); /// \brief Retrieve the name that this expression refers to. const DeclarationNameInfo &getNameInfo() const { return NameInfo; } /// \brief Retrieve the name that this expression refers to. DeclarationName getDeclName() const { return NameInfo.getName(); } /// \brief Retrieve the location of the name within the expression. /// /// For example, in "X::value" this is the location of "value". SourceLocation getLocation() const { return NameInfo.getLoc(); } /// \brief Retrieve the nested-name-specifier that qualifies the /// name, with source location information. NestedNameSpecifierLoc getQualifierLoc() const { return QualifierLoc; } /// \brief Retrieve the nested-name-specifier that qualifies this /// declaration. NestedNameSpecifier *getQualifier() const { return QualifierLoc.getNestedNameSpecifier(); } /// \brief Retrieve the location of the template keyword preceding /// this name, if any. SourceLocation getTemplateKeywordLoc() const { if (!HasTemplateKWAndArgsInfo) return SourceLocation(); return getTemplateKWAndArgsInfo()->getTemplateKeywordLoc(); } /// \brief Retrieve the location of the left angle bracket starting the /// explicit template argument list following the name, if any. SourceLocation getLAngleLoc() const { if (!HasTemplateKWAndArgsInfo) return SourceLocation(); return getTemplateKWAndArgsInfo()->LAngleLoc; } /// \brief Retrieve the location of the right angle bracket ending the /// explicit template argument list following the name, if any. SourceLocation getRAngleLoc() const { if (!HasTemplateKWAndArgsInfo) return SourceLocation(); return getTemplateKWAndArgsInfo()->RAngleLoc; } /// Determines whether the name was preceded by the template keyword. bool hasTemplateKeyword() const { return getTemplateKeywordLoc().isValid(); } /// Determines whether this lookup had explicit template arguments. bool hasExplicitTemplateArgs() const { return getLAngleLoc().isValid(); } // Note that, inconsistently with the explicit-template-argument AST // nodes, users are *forbidden* from calling these methods on objects // without explicit template arguments. ASTTemplateArgumentListInfo &getExplicitTemplateArgs() { assert(hasExplicitTemplateArgs()); return *reinterpret_cast(this + 1); } /// Gets a reference to the explicit template argument list. const ASTTemplateArgumentListInfo &getExplicitTemplateArgs() const { assert(hasExplicitTemplateArgs()); return *reinterpret_cast(this + 1); } /// \brief Retrieves the optional explicit template arguments. /// /// This points to the same data as getExplicitTemplateArgs(), but /// returns null if there are no explicit template arguments. const ASTTemplateArgumentListInfo *getOptionalExplicitTemplateArgs() const { if (!hasExplicitTemplateArgs()) return 0; return &getExplicitTemplateArgs(); } /// \brief Copies the template arguments (if present) into the given /// structure. void copyTemplateArgumentsInto(TemplateArgumentListInfo &List) const { getExplicitTemplateArgs().copyInto(List); } TemplateArgumentLoc const *getTemplateArgs() const { return getExplicitTemplateArgs().getTemplateArgs(); } unsigned getNumTemplateArgs() const { return getExplicitTemplateArgs().NumTemplateArgs; } /// Note: getLocStart() is the start of the whole DependentScopeDeclRefExpr, /// and differs from getLocation().getStart(). SourceLocation getLocStart() const LLVM_READONLY { return QualifierLoc.getBeginLoc(); } SourceLocation getLocEnd() const LLVM_READONLY { if (hasExplicitTemplateArgs()) return getRAngleLoc(); return getLocation(); } static bool classof(const Stmt *T) { return T->getStmtClass() == DependentScopeDeclRefExprClass; } child_range children() { return child_range(); } friend class ASTStmtReader; friend class ASTStmtWriter; }; /// Represents an expression -- generally a full-expression -- that /// introduces cleanups to be run at the end of the sub-expression's /// evaluation. The most common source of expression-introduced /// cleanups is temporary objects in C++, but several other kinds of /// expressions can create cleanups, including basically every /// call in ARC that returns an Objective-C pointer. /// /// This expression also tracks whether the sub-expression contains a /// potentially-evaluated block literal. The lifetime of a block /// literal is the extent of the enclosing scope. class ExprWithCleanups : public Expr { public: /// The type of objects that are kept in the cleanup. /// It's useful to remember the set of blocks; we could also /// remember the set of temporaries, but there's currently /// no need. typedef BlockDecl *CleanupObject; private: Stmt *SubExpr; ExprWithCleanups(EmptyShell, unsigned NumObjects); ExprWithCleanups(Expr *SubExpr, ArrayRef Objects); CleanupObject *getObjectsBuffer() { return reinterpret_cast(this + 1); } const CleanupObject *getObjectsBuffer() const { return reinterpret_cast(this + 1); } friend class ASTStmtReader; public: static ExprWithCleanups *Create(const ASTContext &C, EmptyShell empty, unsigned numObjects); static ExprWithCleanups *Create(const ASTContext &C, Expr *subexpr, ArrayRef objects); ArrayRef getObjects() const { return ArrayRef(getObjectsBuffer(), getNumObjects()); } unsigned getNumObjects() const { return ExprWithCleanupsBits.NumObjects; } CleanupObject getObject(unsigned i) const { assert(i < getNumObjects() && "Index out of range"); return getObjects()[i]; } Expr *getSubExpr() { return cast(SubExpr); } const Expr *getSubExpr() const { return cast(SubExpr); } /// As with any mutator of the AST, be very careful /// when modifying an existing AST to preserve its invariants. void setSubExpr(Expr *E) { SubExpr = E; } SourceLocation getLocStart() const LLVM_READONLY { return SubExpr->getLocStart(); } SourceLocation getLocEnd() const LLVM_READONLY { return SubExpr->getLocEnd();} // Implement isa/cast/dyncast/etc. static bool classof(const Stmt *T) { return T->getStmtClass() == ExprWithCleanupsClass; } // Iterators child_range children() { return child_range(&SubExpr, &SubExpr + 1); } }; /// \brief Describes an explicit type conversion that uses functional /// notion but could not be resolved because one or more arguments are /// type-dependent. /// /// The explicit type conversions expressed by /// CXXUnresolvedConstructExpr have the form T(a1, a2, ..., aN), /// where \c T is some type and \c a1, \c a2, ..., \c aN are values, and /// either \c T is a dependent type or one or more of the a's is /// type-dependent. For example, this would occur in a template such /// as: /// /// \code /// template /// inline T make_a(const A1& a1) { /// return T(a1); /// } /// \endcode /// /// When the returned expression is instantiated, it may resolve to a /// constructor call, conversion function call, or some kind of type /// conversion. class CXXUnresolvedConstructExpr : public Expr { /// \brief The type being constructed. TypeSourceInfo *Type; /// \brief The location of the left parentheses ('('). SourceLocation LParenLoc; /// \brief The location of the right parentheses (')'). SourceLocation RParenLoc; /// \brief The number of arguments used to construct the type. unsigned NumArgs; CXXUnresolvedConstructExpr(TypeSourceInfo *Type, SourceLocation LParenLoc, ArrayRef Args, SourceLocation RParenLoc); CXXUnresolvedConstructExpr(EmptyShell Empty, unsigned NumArgs) : Expr(CXXUnresolvedConstructExprClass, Empty), Type(), NumArgs(NumArgs) { } friend class ASTStmtReader; public: static CXXUnresolvedConstructExpr *Create(const ASTContext &C, TypeSourceInfo *Type, SourceLocation LParenLoc, ArrayRef Args, SourceLocation RParenLoc); static CXXUnresolvedConstructExpr *CreateEmpty(const ASTContext &C, unsigned NumArgs); /// \brief Retrieve the type that is being constructed, as specified /// in the source code. QualType getTypeAsWritten() const { return Type->getType(); } /// \brief Retrieve the type source information for the type being /// constructed. TypeSourceInfo *getTypeSourceInfo() const { return Type; } /// \brief Retrieve the location of the left parentheses ('(') that /// precedes the argument list. SourceLocation getLParenLoc() const { return LParenLoc; } void setLParenLoc(SourceLocation L) { LParenLoc = L; } /// \brief Retrieve the location of the right parentheses (')') that /// follows the argument list. SourceLocation getRParenLoc() const { return RParenLoc; } void setRParenLoc(SourceLocation L) { RParenLoc = L; } /// \brief Retrieve the number of arguments. unsigned arg_size() const { return NumArgs; } typedef Expr** arg_iterator; arg_iterator arg_begin() { return reinterpret_cast(this + 1); } arg_iterator arg_end() { return arg_begin() + NumArgs; } typedef const Expr* const * const_arg_iterator; const_arg_iterator arg_begin() const { return reinterpret_cast(this + 1); } const_arg_iterator arg_end() const { return arg_begin() + NumArgs; } Expr *getArg(unsigned I) { assert(I < NumArgs && "Argument index out-of-range"); return *(arg_begin() + I); } const Expr *getArg(unsigned I) const { assert(I < NumArgs && "Argument index out-of-range"); return *(arg_begin() + I); } void setArg(unsigned I, Expr *E) { assert(I < NumArgs && "Argument index out-of-range"); *(arg_begin() + I) = E; } SourceLocation getLocStart() const LLVM_READONLY; SourceLocation getLocEnd() const LLVM_READONLY { assert(RParenLoc.isValid() || NumArgs == 1); return RParenLoc.isValid() ? RParenLoc : getArg(0)->getLocEnd(); } static bool classof(const Stmt *T) { return T->getStmtClass() == CXXUnresolvedConstructExprClass; } // Iterators child_range children() { Stmt **begin = reinterpret_cast(this+1); return child_range(begin, begin + NumArgs); } }; /// \brief Represents a C++ member access expression where the actual /// member referenced could not be resolved because the base /// expression or the member name was dependent. /// /// Like UnresolvedMemberExprs, these can be either implicit or /// explicit accesses. It is only possible to get one of these with /// an implicit access if a qualifier is provided. class CXXDependentScopeMemberExpr : public Expr { /// \brief The expression for the base pointer or class reference, /// e.g., the \c x in x.f. Can be null in implicit accesses. Stmt *Base; /// \brief The type of the base expression. Never null, even for /// implicit accesses. QualType BaseType; /// \brief Whether this member expression used the '->' operator or /// the '.' operator. bool IsArrow : 1; /// \brief Whether this member expression has info for explicit template /// keyword and arguments. bool HasTemplateKWAndArgsInfo : 1; /// \brief The location of the '->' or '.' operator. SourceLocation OperatorLoc; /// \brief The nested-name-specifier that precedes the member name, if any. NestedNameSpecifierLoc QualifierLoc; /// \brief In a qualified member access expression such as t->Base::f, this /// member stores the resolves of name lookup in the context of the member /// access expression, to be used at instantiation time. /// /// FIXME: This member, along with the QualifierLoc, could /// be stuck into a structure that is optionally allocated at the end of /// the CXXDependentScopeMemberExpr, to save space in the common case. NamedDecl *FirstQualifierFoundInScope; /// \brief The member to which this member expression refers, which /// can be name, overloaded operator, or destructor. /// /// FIXME: could also be a template-id DeclarationNameInfo MemberNameInfo; /// \brief Return the optional template keyword and arguments info. ASTTemplateKWAndArgsInfo *getTemplateKWAndArgsInfo() { if (!HasTemplateKWAndArgsInfo) return 0; return reinterpret_cast(this + 1); } /// \brief Return the optional template keyword and arguments info. const ASTTemplateKWAndArgsInfo *getTemplateKWAndArgsInfo() const { return const_cast(this) ->getTemplateKWAndArgsInfo(); } CXXDependentScopeMemberExpr(const ASTContext &C, Expr *Base, QualType BaseType, bool IsArrow, SourceLocation OperatorLoc, NestedNameSpecifierLoc QualifierLoc, SourceLocation TemplateKWLoc, NamedDecl *FirstQualifierFoundInScope, DeclarationNameInfo MemberNameInfo, const TemplateArgumentListInfo *TemplateArgs); public: CXXDependentScopeMemberExpr(const ASTContext &C, Expr *Base, QualType BaseType, bool IsArrow, SourceLocation OperatorLoc, NestedNameSpecifierLoc QualifierLoc, NamedDecl *FirstQualifierFoundInScope, DeclarationNameInfo MemberNameInfo); static CXXDependentScopeMemberExpr * Create(const ASTContext &C, Expr *Base, QualType BaseType, bool IsArrow, SourceLocation OperatorLoc, NestedNameSpecifierLoc QualifierLoc, SourceLocation TemplateKWLoc, NamedDecl *FirstQualifierFoundInScope, DeclarationNameInfo MemberNameInfo, const TemplateArgumentListInfo *TemplateArgs); static CXXDependentScopeMemberExpr * CreateEmpty(const ASTContext &C, bool HasTemplateKWAndArgsInfo, unsigned NumTemplateArgs); /// \brief True if this is an implicit access, i.e. one in which the /// member being accessed was not written in the source. The source /// location of the operator is invalid in this case. bool isImplicitAccess() const; /// \brief Retrieve the base object of this member expressions, /// e.g., the \c x in \c x.m. Expr *getBase() const { assert(!isImplicitAccess()); return cast(Base); } QualType getBaseType() const { return BaseType; } /// \brief Determine whether this member expression used the '->' /// operator; otherwise, it used the '.' operator. bool isArrow() const { return IsArrow; } /// \brief Retrieve the location of the '->' or '.' operator. SourceLocation getOperatorLoc() const { return OperatorLoc; } /// \brief Retrieve the nested-name-specifier that qualifies the member /// name. NestedNameSpecifier *getQualifier() const { return QualifierLoc.getNestedNameSpecifier(); } /// \brief Retrieve the nested-name-specifier that qualifies the member /// name, with source location information. NestedNameSpecifierLoc getQualifierLoc() const { return QualifierLoc; } /// \brief Retrieve the first part of the nested-name-specifier that was /// found in the scope of the member access expression when the member access /// was initially parsed. /// /// This function only returns a useful result when member access expression /// uses a qualified member name, e.g., "x.Base::f". Here, the declaration /// returned by this function describes what was found by unqualified name /// lookup for the identifier "Base" within the scope of the member access /// expression itself. At template instantiation time, this information is /// combined with the results of name lookup into the type of the object /// expression itself (the class type of x). NamedDecl *getFirstQualifierFoundInScope() const { return FirstQualifierFoundInScope; } /// \brief Retrieve the name of the member that this expression /// refers to. const DeclarationNameInfo &getMemberNameInfo() const { return MemberNameInfo; } /// \brief Retrieve the name of the member that this expression /// refers to. DeclarationName getMember() const { return MemberNameInfo.getName(); } // \brief Retrieve the location of the name of the member that this // expression refers to. SourceLocation getMemberLoc() const { return MemberNameInfo.getLoc(); } /// \brief Retrieve the location of the template keyword preceding the /// member name, if any. SourceLocation getTemplateKeywordLoc() const { if (!HasTemplateKWAndArgsInfo) return SourceLocation(); return getTemplateKWAndArgsInfo()->getTemplateKeywordLoc(); } /// \brief Retrieve the location of the left angle bracket starting the /// explicit template argument list following the member name, if any. SourceLocation getLAngleLoc() const { if (!HasTemplateKWAndArgsInfo) return SourceLocation(); return getTemplateKWAndArgsInfo()->LAngleLoc; } /// \brief Retrieve the location of the right angle bracket ending the /// explicit template argument list following the member name, if any. SourceLocation getRAngleLoc() const { if (!HasTemplateKWAndArgsInfo) return SourceLocation(); return getTemplateKWAndArgsInfo()->RAngleLoc; } /// Determines whether the member name was preceded by the template keyword. bool hasTemplateKeyword() const { return getTemplateKeywordLoc().isValid(); } /// \brief Determines whether this member expression actually had a C++ /// template argument list explicitly specified, e.g., x.f. bool hasExplicitTemplateArgs() const { return getLAngleLoc().isValid(); } /// \brief Retrieve the explicit template argument list that followed the /// member template name, if any. ASTTemplateArgumentListInfo &getExplicitTemplateArgs() { assert(hasExplicitTemplateArgs()); return *reinterpret_cast(this + 1); } /// \brief Retrieve the explicit template argument list that followed the /// member template name, if any. const ASTTemplateArgumentListInfo &getExplicitTemplateArgs() const { return const_cast(this) ->getExplicitTemplateArgs(); } /// \brief Retrieves the optional explicit template arguments. /// /// This points to the same data as getExplicitTemplateArgs(), but /// returns null if there are no explicit template arguments. const ASTTemplateArgumentListInfo *getOptionalExplicitTemplateArgs() const { if (!hasExplicitTemplateArgs()) return 0; return &getExplicitTemplateArgs(); } /// \brief Copies the template arguments (if present) into the given /// structure. void copyTemplateArgumentsInto(TemplateArgumentListInfo &List) const { getExplicitTemplateArgs().copyInto(List); } /// \brief Initializes the template arguments using the given structure. void initializeTemplateArgumentsFrom(const TemplateArgumentListInfo &List) { getExplicitTemplateArgs().initializeFrom(List); } /// \brief Retrieve the template arguments provided as part of this /// template-id. const TemplateArgumentLoc *getTemplateArgs() const { return getExplicitTemplateArgs().getTemplateArgs(); } /// \brief Retrieve the number of template arguments provided as part of this /// template-id. unsigned getNumTemplateArgs() const { return getExplicitTemplateArgs().NumTemplateArgs; } SourceLocation getLocStart() const LLVM_READONLY { if (!isImplicitAccess()) return Base->getLocStart(); if (getQualifier()) return getQualifierLoc().getBeginLoc(); return MemberNameInfo.getBeginLoc(); } SourceLocation getLocEnd() const LLVM_READONLY { if (hasExplicitTemplateArgs()) return getRAngleLoc(); return MemberNameInfo.getEndLoc(); } static bool classof(const Stmt *T) { return T->getStmtClass() == CXXDependentScopeMemberExprClass; } // Iterators child_range children() { if (isImplicitAccess()) return child_range(); return child_range(&Base, &Base + 1); } friend class ASTStmtReader; friend class ASTStmtWriter; }; /// \brief Represents a C++ member access expression for which lookup /// produced a set of overloaded functions. /// /// The member access may be explicit or implicit: /// \code /// struct A { /// int a, b; /// int explicitAccess() { return this->a + this->A::b; } /// int implicitAccess() { return a + A::b; } /// }; /// \endcode /// /// In the final AST, an explicit access always becomes a MemberExpr. /// An implicit access may become either a MemberExpr or a /// DeclRefExpr, depending on whether the member is static. class UnresolvedMemberExpr : public OverloadExpr { /// \brief Whether this member expression used the '->' operator or /// the '.' operator. bool IsArrow : 1; /// \brief Whether the lookup results contain an unresolved using /// declaration. bool HasUnresolvedUsing : 1; /// \brief The expression for the base pointer or class reference, /// e.g., the \c x in x.f. /// /// This can be null if this is an 'unbased' member expression. Stmt *Base; /// \brief The type of the base expression; never null. QualType BaseType; /// \brief The location of the '->' or '.' operator. SourceLocation OperatorLoc; UnresolvedMemberExpr(const ASTContext &C, bool HasUnresolvedUsing, Expr *Base, QualType BaseType, bool IsArrow, SourceLocation OperatorLoc, NestedNameSpecifierLoc QualifierLoc, SourceLocation TemplateKWLoc, const DeclarationNameInfo &MemberNameInfo, const TemplateArgumentListInfo *TemplateArgs, UnresolvedSetIterator Begin, UnresolvedSetIterator End); UnresolvedMemberExpr(EmptyShell Empty) : OverloadExpr(UnresolvedMemberExprClass, Empty), IsArrow(false), HasUnresolvedUsing(false), Base(0) { } friend class ASTStmtReader; public: static UnresolvedMemberExpr * Create(const ASTContext &C, bool HasUnresolvedUsing, Expr *Base, QualType BaseType, bool IsArrow, SourceLocation OperatorLoc, NestedNameSpecifierLoc QualifierLoc, SourceLocation TemplateKWLoc, const DeclarationNameInfo &MemberNameInfo, const TemplateArgumentListInfo *TemplateArgs, UnresolvedSetIterator Begin, UnresolvedSetIterator End); static UnresolvedMemberExpr * CreateEmpty(const ASTContext &C, bool HasTemplateKWAndArgsInfo, unsigned NumTemplateArgs); /// \brief True if this is an implicit access, i.e., one in which the /// member being accessed was not written in the source. /// /// The source location of the operator is invalid in this case. bool isImplicitAccess() const; /// \brief Retrieve the base object of this member expressions, /// e.g., the \c x in \c x.m. Expr *getBase() { assert(!isImplicitAccess()); return cast(Base); } const Expr *getBase() const { assert(!isImplicitAccess()); return cast(Base); } QualType getBaseType() const { return BaseType; } /// \brief Determine whether the lookup results contain an unresolved using /// declaration. bool hasUnresolvedUsing() const { return HasUnresolvedUsing; } /// \brief Determine whether this member expression used the '->' /// operator; otherwise, it used the '.' operator. bool isArrow() const { return IsArrow; } /// \brief Retrieve the location of the '->' or '.' operator. SourceLocation getOperatorLoc() const { return OperatorLoc; } /// \brief Retrieve the naming class of this lookup. CXXRecordDecl *getNamingClass() const; /// \brief Retrieve the full name info for the member that this expression /// refers to. const DeclarationNameInfo &getMemberNameInfo() const { return getNameInfo(); } /// \brief Retrieve the name of the member that this expression /// refers to. DeclarationName getMemberName() const { return getName(); } // \brief Retrieve the location of the name of the member that this // expression refers to. SourceLocation getMemberLoc() const { return getNameLoc(); } // \brief Return the preferred location (the member name) for the arrow when // diagnosing a problem with this expression. SourceLocation getExprLoc() const LLVM_READONLY { return getMemberLoc(); } SourceLocation getLocStart() const LLVM_READONLY { if (!isImplicitAccess()) return Base->getLocStart(); if (NestedNameSpecifierLoc l = getQualifierLoc()) return l.getBeginLoc(); return getMemberNameInfo().getLocStart(); } SourceLocation getLocEnd() const LLVM_READONLY { if (hasExplicitTemplateArgs()) return getRAngleLoc(); return getMemberNameInfo().getLocEnd(); } static bool classof(const Stmt *T) { return T->getStmtClass() == UnresolvedMemberExprClass; } // Iterators child_range children() { if (isImplicitAccess()) return child_range(); return child_range(&Base, &Base + 1); } }; /// \brief Represents a C++11 noexcept expression (C++ [expr.unary.noexcept]). /// /// The noexcept expression tests whether a given expression might throw. Its /// result is a boolean constant. class CXXNoexceptExpr : public Expr { bool Value : 1; Stmt *Operand; SourceRange Range; friend class ASTStmtReader; public: CXXNoexceptExpr(QualType Ty, Expr *Operand, CanThrowResult Val, SourceLocation Keyword, SourceLocation RParen) : Expr(CXXNoexceptExprClass, Ty, VK_RValue, OK_Ordinary, /*TypeDependent*/false, /*ValueDependent*/Val == CT_Dependent, Val == CT_Dependent || Operand->isInstantiationDependent(), Operand->containsUnexpandedParameterPack()), Value(Val == CT_Cannot), Operand(Operand), Range(Keyword, RParen) { } CXXNoexceptExpr(EmptyShell Empty) : Expr(CXXNoexceptExprClass, Empty) { } Expr *getOperand() const { return static_cast(Operand); } SourceLocation getLocStart() const LLVM_READONLY { return Range.getBegin(); } SourceLocation getLocEnd() const LLVM_READONLY { return Range.getEnd(); } SourceRange getSourceRange() const LLVM_READONLY { return Range; } bool getValue() const { return Value; } static bool classof(const Stmt *T) { return T->getStmtClass() == CXXNoexceptExprClass; } // Iterators child_range children() { return child_range(&Operand, &Operand + 1); } }; /// \brief Represents a C++11 pack expansion that produces a sequence of /// expressions. /// /// A pack expansion expression contains a pattern (which itself is an /// expression) followed by an ellipsis. For example: /// /// \code /// template /// void forward(F f, Types &&...args) { /// f(static_cast(args)...); /// } /// \endcode /// /// Here, the argument to the function object \c f is a pack expansion whose /// pattern is \c static_cast(args). When the \c forward function /// template is instantiated, the pack expansion will instantiate to zero or /// or more function arguments to the function object \c f. class PackExpansionExpr : public Expr { SourceLocation EllipsisLoc; /// \brief The number of expansions that will be produced by this pack /// expansion expression, if known. /// /// When zero, the number of expansions is not known. Otherwise, this value /// is the number of expansions + 1. unsigned NumExpansions; Stmt *Pattern; friend class ASTStmtReader; friend class ASTStmtWriter; public: PackExpansionExpr(QualType T, Expr *Pattern, SourceLocation EllipsisLoc, Optional NumExpansions) : Expr(PackExpansionExprClass, T, Pattern->getValueKind(), Pattern->getObjectKind(), /*TypeDependent=*/true, /*ValueDependent=*/true, /*InstantiationDependent=*/true, /*ContainsUnexpandedParameterPack=*/false), EllipsisLoc(EllipsisLoc), NumExpansions(NumExpansions? *NumExpansions + 1 : 0), Pattern(Pattern) { } PackExpansionExpr(EmptyShell Empty) : Expr(PackExpansionExprClass, Empty) { } /// \brief Retrieve the pattern of the pack expansion. Expr *getPattern() { return reinterpret_cast(Pattern); } /// \brief Retrieve the pattern of the pack expansion. const Expr *getPattern() const { return reinterpret_cast(Pattern); } /// \brief Retrieve the location of the ellipsis that describes this pack /// expansion. SourceLocation getEllipsisLoc() const { return EllipsisLoc; } /// \brief Determine the number of expansions that will be produced when /// this pack expansion is instantiated, if already known. Optional getNumExpansions() const { if (NumExpansions) return NumExpansions - 1; return None; } SourceLocation getLocStart() const LLVM_READONLY { return Pattern->getLocStart(); } SourceLocation getLocEnd() const LLVM_READONLY { return EllipsisLoc; } static bool classof(const Stmt *T) { return T->getStmtClass() == PackExpansionExprClass; } // Iterators child_range children() { return child_range(&Pattern, &Pattern + 1); } }; inline ASTTemplateKWAndArgsInfo *OverloadExpr::getTemplateKWAndArgsInfo() { if (!HasTemplateKWAndArgsInfo) return 0; if (isa(this)) return reinterpret_cast (cast(this) + 1); else return reinterpret_cast (cast(this) + 1); } /// \brief Represents an expression that computes the length of a parameter /// pack. /// /// \code /// template /// struct count { /// static const unsigned value = sizeof...(Types); /// }; /// \endcode class SizeOfPackExpr : public Expr { /// \brief The location of the \c sizeof keyword. SourceLocation OperatorLoc; /// \brief The location of the name of the parameter pack. SourceLocation PackLoc; /// \brief The location of the closing parenthesis. SourceLocation RParenLoc; /// \brief The length of the parameter pack, if known. /// /// When this expression is value-dependent, the length of the parameter pack /// is unknown. When this expression is not value-dependent, the length is /// known. unsigned Length; /// \brief The parameter pack itself. NamedDecl *Pack; friend class ASTStmtReader; friend class ASTStmtWriter; public: /// \brief Create a value-dependent expression that computes the length of /// the given parameter pack. SizeOfPackExpr(QualType SizeType, SourceLocation OperatorLoc, NamedDecl *Pack, SourceLocation PackLoc, SourceLocation RParenLoc) : Expr(SizeOfPackExprClass, SizeType, VK_RValue, OK_Ordinary, /*TypeDependent=*/false, /*ValueDependent=*/true, /*InstantiationDependent=*/true, /*ContainsUnexpandedParameterPack=*/false), OperatorLoc(OperatorLoc), PackLoc(PackLoc), RParenLoc(RParenLoc), Length(0), Pack(Pack) { } /// \brief Create an expression that computes the length of /// the given parameter pack, which is already known. SizeOfPackExpr(QualType SizeType, SourceLocation OperatorLoc, NamedDecl *Pack, SourceLocation PackLoc, SourceLocation RParenLoc, unsigned Length) : Expr(SizeOfPackExprClass, SizeType, VK_RValue, OK_Ordinary, /*TypeDependent=*/false, /*ValueDependent=*/false, /*InstantiationDependent=*/false, /*ContainsUnexpandedParameterPack=*/false), OperatorLoc(OperatorLoc), PackLoc(PackLoc), RParenLoc(RParenLoc), Length(Length), Pack(Pack) { } /// \brief Create an empty expression. SizeOfPackExpr(EmptyShell Empty) : Expr(SizeOfPackExprClass, Empty) { } /// \brief Determine the location of the 'sizeof' keyword. SourceLocation getOperatorLoc() const { return OperatorLoc; } /// \brief Determine the location of the parameter pack. SourceLocation getPackLoc() const { return PackLoc; } /// \brief Determine the location of the right parenthesis. SourceLocation getRParenLoc() const { return RParenLoc; } /// \brief Retrieve the parameter pack. NamedDecl *getPack() const { return Pack; } /// \brief Retrieve the length of the parameter pack. /// /// This routine may only be invoked when the expression is not /// value-dependent. unsigned getPackLength() const { assert(!isValueDependent() && "Cannot get the length of a value-dependent pack size expression"); return Length; } SourceLocation getLocStart() const LLVM_READONLY { return OperatorLoc; } SourceLocation getLocEnd() const LLVM_READONLY { return RParenLoc; } static bool classof(const Stmt *T) { return T->getStmtClass() == SizeOfPackExprClass; } // Iterators child_range children() { return child_range(); } }; /// \brief Represents a reference to a non-type template parameter /// that has been substituted with a template argument. class SubstNonTypeTemplateParmExpr : public Expr { /// \brief The replaced parameter. NonTypeTemplateParmDecl *Param; /// \brief The replacement expression. Stmt *Replacement; /// \brief The location of the non-type template parameter reference. SourceLocation NameLoc; friend class ASTReader; friend class ASTStmtReader; explicit SubstNonTypeTemplateParmExpr(EmptyShell Empty) : Expr(SubstNonTypeTemplateParmExprClass, Empty) { } public: SubstNonTypeTemplateParmExpr(QualType type, ExprValueKind valueKind, SourceLocation loc, NonTypeTemplateParmDecl *param, Expr *replacement) : Expr(SubstNonTypeTemplateParmExprClass, type, valueKind, OK_Ordinary, replacement->isTypeDependent(), replacement->isValueDependent(), replacement->isInstantiationDependent(), replacement->containsUnexpandedParameterPack()), Param(param), Replacement(replacement), NameLoc(loc) {} SourceLocation getNameLoc() const { return NameLoc; } SourceLocation getLocStart() const LLVM_READONLY { return NameLoc; } SourceLocation getLocEnd() const LLVM_READONLY { return NameLoc; } Expr *getReplacement() const { return cast(Replacement); } NonTypeTemplateParmDecl *getParameter() const { return Param; } static bool classof(const Stmt *s) { return s->getStmtClass() == SubstNonTypeTemplateParmExprClass; } // Iterators child_range children() { return child_range(&Replacement, &Replacement+1); } }; /// \brief Represents a reference to a non-type template parameter pack that /// has been substituted with a non-template argument pack. /// /// When a pack expansion in the source code contains multiple parameter packs /// and those parameter packs correspond to different levels of template /// parameter lists, this node is used to represent a non-type template /// parameter pack from an outer level, which has already had its argument pack /// substituted but that still lives within a pack expansion that itself /// could not be instantiated. When actually performing a substitution into /// that pack expansion (e.g., when all template parameters have corresponding /// arguments), this type will be replaced with the appropriate underlying /// expression at the current pack substitution index. class SubstNonTypeTemplateParmPackExpr : public Expr { /// \brief The non-type template parameter pack itself. NonTypeTemplateParmDecl *Param; /// \brief A pointer to the set of template arguments that this /// parameter pack is instantiated with. const TemplateArgument *Arguments; /// \brief The number of template arguments in \c Arguments. unsigned NumArguments; /// \brief The location of the non-type template parameter pack reference. SourceLocation NameLoc; friend class ASTReader; friend class ASTStmtReader; explicit SubstNonTypeTemplateParmPackExpr(EmptyShell Empty) : Expr(SubstNonTypeTemplateParmPackExprClass, Empty) { } public: SubstNonTypeTemplateParmPackExpr(QualType T, NonTypeTemplateParmDecl *Param, SourceLocation NameLoc, const TemplateArgument &ArgPack); /// \brief Retrieve the non-type template parameter pack being substituted. NonTypeTemplateParmDecl *getParameterPack() const { return Param; } /// \brief Retrieve the location of the parameter pack name. SourceLocation getParameterPackLocation() const { return NameLoc; } /// \brief Retrieve the template argument pack containing the substituted /// template arguments. TemplateArgument getArgumentPack() const; SourceLocation getLocStart() const LLVM_READONLY { return NameLoc; } SourceLocation getLocEnd() const LLVM_READONLY { return NameLoc; } static bool classof(const Stmt *T) { return T->getStmtClass() == SubstNonTypeTemplateParmPackExprClass; } // Iterators child_range children() { return child_range(); } }; /// \brief Represents a reference to a function parameter pack that has been /// substituted but not yet expanded. /// /// When a pack expansion contains multiple parameter packs at different levels, /// this node is used to represent a function parameter pack at an outer level /// which we have already substituted to refer to expanded parameters, but where /// the containing pack expansion cannot yet be expanded. /// /// \code /// template struct S { /// template auto f(Ts ...ts) -> decltype(g(Us(ts)...)); /// }; /// template struct S; /// \endcode class FunctionParmPackExpr : public Expr { /// \brief The function parameter pack which was referenced. ParmVarDecl *ParamPack; /// \brief The location of the function parameter pack reference. SourceLocation NameLoc; /// \brief The number of expansions of this pack. unsigned NumParameters; FunctionParmPackExpr(QualType T, ParmVarDecl *ParamPack, SourceLocation NameLoc, unsigned NumParams, Decl * const *Params); friend class ASTReader; friend class ASTStmtReader; public: static FunctionParmPackExpr *Create(const ASTContext &Context, QualType T, ParmVarDecl *ParamPack, SourceLocation NameLoc, ArrayRef Params); static FunctionParmPackExpr *CreateEmpty(const ASTContext &Context, unsigned NumParams); /// \brief Get the parameter pack which this expression refers to. ParmVarDecl *getParameterPack() const { return ParamPack; } /// \brief Get the location of the parameter pack. SourceLocation getParameterPackLocation() const { return NameLoc; } /// \brief Iterators over the parameters which the parameter pack expanded /// into. typedef ParmVarDecl * const *iterator; iterator begin() const { return reinterpret_cast(this+1); } iterator end() const { return begin() + NumParameters; } /// \brief Get the number of parameters in this parameter pack. unsigned getNumExpansions() const { return NumParameters; } /// \brief Get an expansion of the parameter pack by index. ParmVarDecl *getExpansion(unsigned I) const { return begin()[I]; } SourceLocation getLocStart() const LLVM_READONLY { return NameLoc; } SourceLocation getLocEnd() const LLVM_READONLY { return NameLoc; } static bool classof(const Stmt *T) { return T->getStmtClass() == FunctionParmPackExprClass; } child_range children() { return child_range(); } }; /// \brief Represents a prvalue temporary that is written into memory so that /// a reference can bind to it. /// /// Prvalue expressions are materialized when they need to have an address /// in memory for a reference to bind to. This happens when binding a /// reference to the result of a conversion, e.g., /// /// \code /// const int &r = 1.0; /// \endcode /// /// Here, 1.0 is implicitly converted to an \c int. That resulting \c int is /// then materialized via a \c MaterializeTemporaryExpr, and the reference /// binds to the temporary. \c MaterializeTemporaryExprs are always glvalues /// (either an lvalue or an xvalue, depending on the kind of reference binding /// to it), maintaining the invariant that references always bind to glvalues. /// /// Reference binding and copy-elision can both extend the lifetime of a /// temporary. When either happens, the expression will also track the /// declaration which is responsible for the lifetime extension. class MaterializeTemporaryExpr : public Expr { public: /// \brief The temporary-generating expression whose value will be /// materialized. Stmt *Temporary; /// \brief The declaration which lifetime-extended this reference, if any. /// Either a VarDecl, or (for a ctor-initializer) a FieldDecl. const ValueDecl *ExtendingDecl; friend class ASTStmtReader; friend class ASTStmtWriter; public: MaterializeTemporaryExpr(QualType T, Expr *Temporary, bool BoundToLvalueReference, const ValueDecl *ExtendedBy) : Expr(MaterializeTemporaryExprClass, T, BoundToLvalueReference? VK_LValue : VK_XValue, OK_Ordinary, Temporary->isTypeDependent(), Temporary->isValueDependent(), Temporary->isInstantiationDependent(), Temporary->containsUnexpandedParameterPack()), Temporary(Temporary), ExtendingDecl(ExtendedBy) { } MaterializeTemporaryExpr(EmptyShell Empty) : Expr(MaterializeTemporaryExprClass, Empty) { } /// \brief Retrieve the temporary-generating subexpression whose value will /// be materialized into a glvalue. Expr *GetTemporaryExpr() const { return static_cast(Temporary); } /// \brief Retrieve the storage duration for the materialized temporary. StorageDuration getStorageDuration() const { if (!ExtendingDecl) return SD_FullExpression; // FIXME: This is not necessarily correct for a temporary materialized // within a default initializer. if (isa(ExtendingDecl)) return SD_Automatic; return cast(ExtendingDecl)->getStorageDuration(); } /// \brief Get the declaration which triggered the lifetime-extension of this /// temporary, if any. const ValueDecl *getExtendingDecl() const { return ExtendingDecl; } void setExtendingDecl(const ValueDecl *ExtendedBy) { ExtendingDecl = ExtendedBy; } /// \brief Determine whether this materialized temporary is bound to an /// lvalue reference; otherwise, it's bound to an rvalue reference. bool isBoundToLvalueReference() const { return getValueKind() == VK_LValue; } SourceLocation getLocStart() const LLVM_READONLY { return Temporary->getLocStart(); } SourceLocation getLocEnd() const LLVM_READONLY { return Temporary->getLocEnd(); } static bool classof(const Stmt *T) { return T->getStmtClass() == MaterializeTemporaryExprClass; } // Iterators child_range children() { return child_range(&Temporary, &Temporary + 1); } }; } // end namespace clang #endif