//===--- Expr.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. // //===----------------------------------------------------------------------===// // // This file defines the Expr interface and subclasses. // //===----------------------------------------------------------------------===// #ifndef LLVM_CLANG_AST_EXPR_H #define LLVM_CLANG_AST_EXPR_H #include "clang/AST/APValue.h" #include "clang/AST/Stmt.h" #include "clang/AST/Type.h" #include "llvm/ADT/APSInt.h" #include "llvm/ADT/APFloat.h" #include "llvm/ADT/SmallVector.h" #include namespace clang { class ASTContext; class APValue; class Decl; class IdentifierInfo; class ParmVarDecl; class NamedDecl; class ValueDecl; class BlockDecl; class CXXOperatorCallExpr; class CXXMemberCallExpr; /// Expr - This represents one expression. Note that Expr's are subclasses of /// Stmt. This allows an expression to be transparently used any place a Stmt /// is required. /// class Expr : public Stmt { QualType TR; protected: /// TypeDependent - Whether this expression is type-dependent /// (C++ [temp.dep.expr]). bool TypeDependent : 1; /// ValueDependent - Whether this expression is value-dependent /// (C++ [temp.dep.constexpr]). bool ValueDependent : 1; // FIXME: Eventually, this constructor should go away and we should // require every subclass to provide type/value-dependence // information. Expr(StmtClass SC, QualType T) : Stmt(SC), TypeDependent(false), ValueDependent(false) { setType(T); } Expr(StmtClass SC, QualType T, bool TD, bool VD) : Stmt(SC), TypeDependent(TD), ValueDependent(VD) { setType(T); } /// \brief Construct an empty expression. explicit Expr(StmtClass SC, EmptyShell) : Stmt(SC) { } public: QualType getType() const { return TR; } void setType(QualType t) { // In C++, the type of an expression is always adjusted so that it // will not have reference type an expression will never have // reference type (C++ [expr]p6). Use // QualType::getNonReferenceType() to retrieve the non-reference // type. Additionally, inspect Expr::isLvalue to determine whether // an expression that is adjusted in this manner should be // considered an lvalue. assert((TR.isNull() || !TR->isReferenceType()) && "Expressions can't have reference type"); TR = t; } /// isValueDependent - Determines whether this expression is /// value-dependent (C++ [temp.dep.constexpr]). For example, the /// array bound of "Chars" in the following example is /// value-dependent. /// @code /// template struct meta_string; /// @endcode bool isValueDependent() const { return ValueDependent; } /// \brief Set whether this expression is value-dependent or not. void setValueDependent(bool VD) { ValueDependent = VD; } /// isTypeDependent - Determines whether this expression is /// type-dependent (C++ [temp.dep.expr]), which means that its type /// could change from one template instantiation to the next. For /// example, the expressions "x" and "x + y" are type-dependent in /// the following code, but "y" is not type-dependent: /// @code /// template /// void add(T x, int y) { /// x + y; /// } /// @endcode bool isTypeDependent() const { return TypeDependent; } /// \brief Set whether this expression is type-dependent or not. void setTypeDependent(bool TD) { TypeDependent = TD; } /// SourceLocation tokens are not useful in isolation - they are low level /// value objects created/interpreted by SourceManager. We assume AST /// clients will have a pointer to the respective SourceManager. virtual SourceRange getSourceRange() const = 0; /// getExprLoc - Return the preferred location for the arrow when diagnosing /// a problem with a generic expression. virtual SourceLocation getExprLoc() const { return getLocStart(); } /// isUnusedResultAWarning - Return true if this immediate expression should /// be warned about if the result is unused. If so, fill in Loc and Ranges /// with location to warn on and the source range[s] to report with the /// warning. bool isUnusedResultAWarning(SourceLocation &Loc, SourceRange &R1, SourceRange &R2) const; /// isLvalue - C99 6.3.2.1: an lvalue is an expression with an object type or /// incomplete type other than void. Nonarray expressions that can be lvalues: /// - name, where name must be a variable /// - e[i] /// - (e), where e must be an lvalue /// - e.name, where e must be an lvalue /// - e->name /// - *e, the type of e cannot be a function type /// - string-constant /// - reference type [C++ [expr]] /// - b ? x : y, where x and y are lvalues of suitable types [C++] /// enum isLvalueResult { LV_Valid, LV_NotObjectType, LV_IncompleteVoidType, LV_DuplicateVectorComponents, LV_InvalidExpression, LV_MemberFunction }; isLvalueResult isLvalue(ASTContext &Ctx) const; // Same as above, but excluding checks for non-object and void types in C isLvalueResult isLvalueInternal(ASTContext &Ctx) const; /// isModifiableLvalue - C99 6.3.2.1: an lvalue that does not have array type, /// does not have an incomplete type, does not have a const-qualified type, /// and if it is a structure or union, does not have any member (including, /// recursively, any member or element of all contained aggregates or unions) /// with a const-qualified type. /// /// \param Loc [in] [out] - A source location which *may* be filled /// in with the location of the expression making this a /// non-modifiable lvalue, if specified. enum isModifiableLvalueResult { MLV_Valid, MLV_NotObjectType, MLV_IncompleteVoidType, MLV_DuplicateVectorComponents, MLV_InvalidExpression, MLV_LValueCast, // Specialized form of MLV_InvalidExpression. MLV_IncompleteType, MLV_ConstQualified, MLV_ArrayType, MLV_NotBlockQualified, MLV_ReadonlyProperty, MLV_NoSetterProperty, MLV_MemberFunction }; isModifiableLvalueResult isModifiableLvalue(ASTContext &Ctx, SourceLocation *Loc = 0) const; /// \brief If this expression refers to a bit-field, retrieve the /// declaration of that bit-field. FieldDecl *getBitField(); const FieldDecl *getBitField() const { return const_cast(this)->getBitField(); } /// isIntegerConstantExpr - Return true if this expression is a valid integer /// constant expression, and, if so, return its value in Result. If not a /// valid i-c-e, return false and fill in Loc (if specified) with the location /// of the invalid expression. bool isIntegerConstantExpr(llvm::APSInt &Result, ASTContext &Ctx, SourceLocation *Loc = 0, bool isEvaluated = true) const; bool isIntegerConstantExpr(ASTContext &Ctx, SourceLocation *Loc = 0) const { llvm::APSInt X; return isIntegerConstantExpr(X, Ctx, Loc); } /// isConstantInitializer - Returns true if this expression is a constant /// initializer, which can be emitted at compile-time. bool isConstantInitializer(ASTContext &Ctx) const; /// EvalResult is a struct with detailed info about an evaluated expression. struct EvalResult { /// Val - This is the value the expression can be folded to. APValue Val; /// HasSideEffects - Whether the evaluated expression has side effects. /// For example, (f() && 0) can be folded, but it still has side effects. bool HasSideEffects; /// Diag - If the expression is unfoldable, then Diag contains a note /// diagnostic indicating why it's not foldable. DiagLoc indicates a caret /// position for the error, and DiagExpr is the expression that caused /// the error. /// If the expression is foldable, but not an integer constant expression, /// Diag contains a note diagnostic that describes why it isn't an integer /// constant expression. If the expression *is* an integer constant /// expression, then Diag will be zero. unsigned Diag; const Expr *DiagExpr; SourceLocation DiagLoc; EvalResult() : HasSideEffects(false), Diag(0), DiagExpr(0) {} }; /// Evaluate - Return true if this is a constant which we can fold using /// any crazy technique (that has nothing to do with language standards) that /// we want to. If this function returns true, it returns the folded constant /// in Result. bool Evaluate(EvalResult &Result, ASTContext &Ctx) const; /// isEvaluatable - Call Evaluate to see if this expression can be constant /// folded, but discard the result. bool isEvaluatable(ASTContext &Ctx) const; /// EvaluateAsInt - Call Evaluate and return the folded integer. This /// must be called on an expression that constant folds to an integer. llvm::APSInt EvaluateAsInt(ASTContext &Ctx) const; /// EvaluateAsLValue - Evaluate an expression to see if it's a valid LValue. bool EvaluateAsLValue(EvalResult &Result, ASTContext &Ctx) const; /// isNullPointerConstant - C99 6.3.2.3p3 - Return true if this is either an /// integer constant expression with the value zero, or if this is one that is /// cast to void*. bool isNullPointerConstant(ASTContext &Ctx) const; /// hasGlobalStorage - Return true if this expression has static storage /// duration. This means that the address of this expression is a link-time /// constant. bool hasGlobalStorage() const; /// isOBJCGCCandidate - Return true if this expression may be used in a read/ /// write barrier. bool isOBJCGCCandidate(ASTContext &Ctx) const; /// IgnoreParens - Ignore parentheses. If this Expr is a ParenExpr, return /// its subexpression. If that subexpression is also a ParenExpr, /// then this method recursively returns its subexpression, and so forth. /// Otherwise, the method returns the current Expr. Expr* IgnoreParens(); /// IgnoreParenCasts - Ignore parentheses and casts. Strip off any ParenExpr /// or CastExprs, returning their operand. Expr *IgnoreParenCasts(); /// IgnoreParenNoopCasts - Ignore parentheses and casts that do not change the /// value (including ptr->int casts of the same size). Strip off any /// ParenExpr or CastExprs, returning their operand. Expr *IgnoreParenNoopCasts(ASTContext &Ctx); const Expr* IgnoreParens() const { return const_cast(this)->IgnoreParens(); } const Expr *IgnoreParenCasts() const { return const_cast(this)->IgnoreParenCasts(); } const Expr *IgnoreParenNoopCasts(ASTContext &Ctx) const { return const_cast(this)->IgnoreParenNoopCasts(Ctx); } static bool hasAnyTypeDependentArguments(Expr** Exprs, unsigned NumExprs); static bool hasAnyValueDependentArguments(Expr** Exprs, unsigned NumExprs); static bool classof(const Stmt *T) { return T->getStmtClass() >= firstExprConstant && T->getStmtClass() <= lastExprConstant; } static bool classof(const Expr *) { return true; } }; //===----------------------------------------------------------------------===// // Primary Expressions. //===----------------------------------------------------------------------===// /// DeclRefExpr - [C99 6.5.1p2] - A reference to a declared variable, function, /// enum, etc. class DeclRefExpr : public Expr { NamedDecl *D; SourceLocation Loc; protected: // FIXME: Eventually, this constructor will go away and all subclasses // will have to provide the type- and value-dependent flags. DeclRefExpr(StmtClass SC, NamedDecl *d, QualType t, SourceLocation l) : Expr(SC, t), D(d), Loc(l) {} DeclRefExpr(StmtClass SC, NamedDecl *d, QualType t, SourceLocation l, bool TD, bool VD) : Expr(SC, t, TD, VD), D(d), Loc(l) {} public: // FIXME: Eventually, this constructor will go away and all clients // will have to provide the type- and value-dependent flags. DeclRefExpr(NamedDecl *d, QualType t, SourceLocation l) : Expr(DeclRefExprClass, t), D(d), Loc(l) {} DeclRefExpr(NamedDecl *d, QualType t, SourceLocation l, bool TD, bool VD) : Expr(DeclRefExprClass, t, TD, VD), D(d), Loc(l) {} /// \brief Construct an empty declaration reference expression. explicit DeclRefExpr(EmptyShell Empty) : Expr(DeclRefExprClass, Empty) { } NamedDecl *getDecl() { return D; } const NamedDecl *getDecl() const { return D; } void setDecl(NamedDecl *NewD) { D = NewD; } SourceLocation getLocation() const { return Loc; } void setLocation(SourceLocation L) { Loc = L; } virtual SourceRange getSourceRange() const { return SourceRange(Loc); } static bool classof(const Stmt *T) { return T->getStmtClass() == DeclRefExprClass || T->getStmtClass() == CXXConditionDeclExprClass || T->getStmtClass() == QualifiedDeclRefExprClass; } static bool classof(const DeclRefExpr *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// PredefinedExpr - [C99 6.4.2.2] - A predefined identifier such as __func__. class PredefinedExpr : public Expr { public: enum IdentType { Func, Function, PrettyFunction }; private: SourceLocation Loc; IdentType Type; public: PredefinedExpr(SourceLocation l, QualType type, IdentType IT) : Expr(PredefinedExprClass, type), Loc(l), Type(IT) {} /// \brief Construct an empty predefined expression. explicit PredefinedExpr(EmptyShell Empty) : Expr(PredefinedExprClass, Empty) { } PredefinedExpr* Clone(ASTContext &C) const; IdentType getIdentType() const { return Type; } void setIdentType(IdentType IT) { Type = IT; } SourceLocation getLocation() const { return Loc; } void setLocation(SourceLocation L) { Loc = L; } // FIXME: The logic for computing the value of a predefined expr should go // into a method here that takes the inner-most code decl (a block, function // or objc method) that the expr lives in. This would allow sema and codegen // to be consistent for things like sizeof(__func__) etc. virtual SourceRange getSourceRange() const { return SourceRange(Loc); } static bool classof(const Stmt *T) { return T->getStmtClass() == PredefinedExprClass; } static bool classof(const PredefinedExpr *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; class IntegerLiteral : public Expr { llvm::APInt Value; SourceLocation Loc; public: // type should be IntTy, LongTy, LongLongTy, UnsignedIntTy, UnsignedLongTy, // or UnsignedLongLongTy IntegerLiteral(const llvm::APInt &V, QualType type, SourceLocation l) : Expr(IntegerLiteralClass, type), Value(V), Loc(l) { assert(type->isIntegerType() && "Illegal type in IntegerLiteral"); } /// \brief Construct an empty integer literal. explicit IntegerLiteral(EmptyShell Empty) : Expr(IntegerLiteralClass, Empty) { } IntegerLiteral* Clone(ASTContext &C) const; const llvm::APInt &getValue() const { return Value; } virtual SourceRange getSourceRange() const { return SourceRange(Loc); } /// \brief Retrieve the location of the literal. SourceLocation getLocation() const { return Loc; } void setValue(const llvm::APInt &Val) { Value = Val; } void setLocation(SourceLocation Location) { Loc = Location; } static bool classof(const Stmt *T) { return T->getStmtClass() == IntegerLiteralClass; } static bool classof(const IntegerLiteral *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; class CharacterLiteral : public Expr { unsigned Value; SourceLocation Loc; bool IsWide; public: // type should be IntTy CharacterLiteral(unsigned value, bool iswide, QualType type, SourceLocation l) : Expr(CharacterLiteralClass, type), Value(value), Loc(l), IsWide(iswide) { } /// \brief Construct an empty character literal. CharacterLiteral(EmptyShell Empty) : Expr(CharacterLiteralClass, Empty) { } CharacterLiteral* Clone(ASTContext &C) const; SourceLocation getLoc() const { return Loc; } bool isWide() const { return IsWide; } virtual SourceRange getSourceRange() const { return SourceRange(Loc); } unsigned getValue() const { return Value; } void setLocation(SourceLocation Location) { Loc = Location; } void setWide(bool W) { IsWide = W; } void setValue(unsigned Val) { Value = Val; } static bool classof(const Stmt *T) { return T->getStmtClass() == CharacterLiteralClass; } static bool classof(const CharacterLiteral *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; class FloatingLiteral : public Expr { llvm::APFloat Value; bool IsExact : 1; SourceLocation Loc; public: FloatingLiteral(const llvm::APFloat &V, bool* isexact, QualType Type, SourceLocation L) : Expr(FloatingLiteralClass, Type), Value(V), IsExact(*isexact), Loc(L) {} /// \brief Construct an empty floating-point literal. explicit FloatingLiteral(EmptyShell Empty) : Expr(FloatingLiteralClass, Empty), Value(0.0) { } FloatingLiteral* Clone(ASTContext &C) const; const llvm::APFloat &getValue() const { return Value; } void setValue(const llvm::APFloat &Val) { Value = Val; } bool isExact() const { return IsExact; } void setExact(bool E) { IsExact = E; } /// getValueAsApproximateDouble - This returns the value as an inaccurate /// double. Note that this may cause loss of precision, but is useful for /// debugging dumps, etc. double getValueAsApproximateDouble() const; SourceLocation getLocation() const { return Loc; } void setLocation(SourceLocation L) { Loc = L; } // FIXME: The logic for computing the value of a predefined expr should go // into a method here that takes the inner-most code decl (a block, function // or objc method) that the expr lives in. This would allow sema and codegen // to be consistent for things like sizeof(__func__) etc. virtual SourceRange getSourceRange() const { return SourceRange(Loc); } static bool classof(const Stmt *T) { return T->getStmtClass() == FloatingLiteralClass; } static bool classof(const FloatingLiteral *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// ImaginaryLiteral - We support imaginary integer and floating point literals, /// like "1.0i". We represent these as a wrapper around FloatingLiteral and /// IntegerLiteral classes. Instances of this class always have a Complex type /// whose element type matches the subexpression. /// class ImaginaryLiteral : public Expr { Stmt *Val; public: ImaginaryLiteral(Expr *val, QualType Ty) : Expr(ImaginaryLiteralClass, Ty), Val(val) {} /// \brief Build an empty imaginary literal. explicit ImaginaryLiteral(EmptyShell Empty) : Expr(ImaginaryLiteralClass, Empty) { } const Expr *getSubExpr() const { return cast(Val); } Expr *getSubExpr() { return cast(Val); } void setSubExpr(Expr *E) { Val = E; } ImaginaryLiteral* Clone(ASTContext &C) const; virtual SourceRange getSourceRange() const { return Val->getSourceRange(); } static bool classof(const Stmt *T) { return T->getStmtClass() == ImaginaryLiteralClass; } static bool classof(const ImaginaryLiteral *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// StringLiteral - This represents a string literal expression, e.g. "foo" /// or L"bar" (wide strings). The actual string is returned by getStrData() /// is NOT null-terminated, and the length of the string is determined by /// calling getByteLength(). The C type for a string is always a /// ConstantArrayType. In C++, the char type is const qualified, in C it is /// not. /// /// Note that strings in C can be formed by concatenation of multiple string /// literal pptokens in translation phase #6. This keeps track of the locations /// of each of these pieces. /// /// Strings in C can also be truncated and extended by assigning into arrays, /// e.g. with constructs like: /// char X[2] = "foobar"; /// In this case, getByteLength() will return 6, but the string literal will /// have type "char[2]". class StringLiteral : public Expr { const char *StrData; unsigned ByteLength; bool IsWide; unsigned NumConcatenated; SourceLocation TokLocs[1]; StringLiteral(QualType Ty) : Expr(StringLiteralClass, Ty) {} public: /// This is the "fully general" constructor that allows representation of /// strings formed from multiple concatenated tokens. static StringLiteral *Create(ASTContext &C, const char *StrData, unsigned ByteLength, bool Wide, QualType Ty, const SourceLocation *Loc, unsigned NumStrs); /// Simple constructor for string literals made from one token. static StringLiteral *Create(ASTContext &C, const char *StrData, unsigned ByteLength, bool Wide, QualType Ty, SourceLocation Loc) { return Create(C, StrData, ByteLength, Wide, Ty, &Loc, 1); } /// \brief Construct an empty string literal. static StringLiteral *CreateEmpty(ASTContext &C, unsigned NumStrs); StringLiteral* Clone(ASTContext &C) const; void Destroy(ASTContext &C); const char *getStrData() const { return StrData; } unsigned getByteLength() const { return ByteLength; } /// \brief Sets the string data to the given string data. void setStrData(ASTContext &C, const char *Str, unsigned Len); bool isWide() const { return IsWide; } void setWide(bool W) { IsWide = W; } bool containsNonAsciiOrNull() const { for (unsigned i = 0; i < getByteLength(); ++i) if (!isascii(getStrData()[i]) || !getStrData()[i]) return true; return false; } /// getNumConcatenated - Get the number of string literal tokens that were /// concatenated in translation phase #6 to form this string literal. unsigned getNumConcatenated() const { return NumConcatenated; } SourceLocation getStrTokenLoc(unsigned TokNum) const { assert(TokNum < NumConcatenated && "Invalid tok number"); return TokLocs[TokNum]; } void setStrTokenLoc(unsigned TokNum, SourceLocation L) { assert(TokNum < NumConcatenated && "Invalid tok number"); TokLocs[TokNum] = L; } typedef const SourceLocation *tokloc_iterator; tokloc_iterator tokloc_begin() const { return TokLocs; } tokloc_iterator tokloc_end() const { return TokLocs+NumConcatenated; } virtual SourceRange getSourceRange() const { return SourceRange(TokLocs[0], TokLocs[NumConcatenated-1]); } static bool classof(const Stmt *T) { return T->getStmtClass() == StringLiteralClass; } static bool classof(const StringLiteral *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// ParenExpr - This represents a parethesized expression, e.g. "(1)". This /// AST node is only formed if full location information is requested. class ParenExpr : public Expr { SourceLocation L, R; Stmt *Val; public: ParenExpr(SourceLocation l, SourceLocation r, Expr *val) : Expr(ParenExprClass, val->getType(), val->isTypeDependent(), val->isValueDependent()), L(l), R(r), Val(val) {} /// \brief Construct an empty parenthesized expression. explicit ParenExpr(EmptyShell Empty) : Expr(ParenExprClass, Empty) { } const Expr *getSubExpr() const { return cast(Val); } Expr *getSubExpr() { return cast(Val); } void setSubExpr(Expr *E) { Val = E; } virtual SourceRange getSourceRange() const { return SourceRange(L, R); } /// \brief Get the location of the left parentheses '('. SourceLocation getLParen() const { return L; } void setLParen(SourceLocation Loc) { L = Loc; } /// \brief Get the location of the right parentheses ')'. SourceLocation getRParen() const { return R; } void setRParen(SourceLocation Loc) { R = Loc; } static bool classof(const Stmt *T) { return T->getStmtClass() == ParenExprClass; } static bool classof(const ParenExpr *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// UnaryOperator - This represents the unary-expression's (except sizeof and /// alignof), the postinc/postdec operators from postfix-expression, and various /// extensions. /// /// Notes on various nodes: /// /// Real/Imag - These return the real/imag part of a complex operand. If /// applied to a non-complex value, the former returns its operand and the /// later returns zero in the type of the operand. /// /// __builtin_offsetof(type, a.b[10]) is represented as a unary operator whose /// subexpression is a compound literal with the various MemberExpr and /// ArraySubscriptExpr's applied to it. /// class UnaryOperator : public Expr { public: // Note that additions to this should also update the StmtVisitor class. enum Opcode { PostInc, PostDec, // [C99 6.5.2.4] Postfix increment and decrement operators PreInc, PreDec, // [C99 6.5.3.1] Prefix increment and decrement operators. AddrOf, Deref, // [C99 6.5.3.2] Address and indirection operators. Plus, Minus, // [C99 6.5.3.3] Unary arithmetic operators. Not, LNot, // [C99 6.5.3.3] Unary arithmetic operators. Real, Imag, // "__real expr"/"__imag expr" Extension. Extension, // __extension__ marker. OffsetOf // __builtin_offsetof }; private: Stmt *Val; Opcode Opc; SourceLocation Loc; public: UnaryOperator(Expr *input, Opcode opc, QualType type, SourceLocation l) : Expr(UnaryOperatorClass, type, input->isTypeDependent() && opc != OffsetOf, input->isValueDependent()), Val(input), Opc(opc), Loc(l) {} /// \brief Build an empty unary operator. explicit UnaryOperator(EmptyShell Empty) : Expr(UnaryOperatorClass, Empty), Opc(AddrOf) { } Opcode getOpcode() const { return Opc; } void setOpcode(Opcode O) { Opc = O; } Expr *getSubExpr() const { return cast(Val); } void setSubExpr(Expr *E) { Val = E; } /// getOperatorLoc - Return the location of the operator. SourceLocation getOperatorLoc() const { return Loc; } void setOperatorLoc(SourceLocation L) { Loc = L; } /// isPostfix - Return true if this is a postfix operation, like x++. static bool isPostfix(Opcode Op) { return Op == PostInc || Op == PostDec; } /// isPostfix - Return true if this is a prefix operation, like --x. static bool isPrefix(Opcode Op) { return Op == PreInc || Op == PreDec; } bool isPrefix() const { return isPrefix(Opc); } bool isPostfix() const { return isPostfix(Opc); } bool isIncrementOp() const {return Opc==PreInc || Opc==PostInc; } bool isIncrementDecrementOp() const { return Opc>=PostInc && Opc<=PreDec; } bool isOffsetOfOp() const { return Opc == OffsetOf; } static bool isArithmeticOp(Opcode Op) { return Op >= Plus && Op <= LNot; } /// getOpcodeStr - Turn an Opcode enum value into the punctuation char it /// corresponds to, e.g. "sizeof" or "[pre]++" static const char *getOpcodeStr(Opcode Op); /// \brief Retrieve the unary opcode that corresponds to the given /// overloaded operator. static Opcode getOverloadedOpcode(OverloadedOperatorKind OO, bool Postfix); /// \brief Retrieve the overloaded operator kind that corresponds to /// the given unary opcode. static OverloadedOperatorKind getOverloadedOperator(Opcode Opc); virtual SourceRange getSourceRange() const { if (isPostfix()) return SourceRange(Val->getLocStart(), Loc); else return SourceRange(Loc, Val->getLocEnd()); } virtual SourceLocation getExprLoc() const { return Loc; } static bool classof(const Stmt *T) { return T->getStmtClass() == UnaryOperatorClass; } static bool classof(const UnaryOperator *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// SizeOfAlignOfExpr - [C99 6.5.3.4] - This is for sizeof/alignof, both of /// types and expressions. class SizeOfAlignOfExpr : public Expr { bool isSizeof : 1; // true if sizeof, false if alignof. bool isType : 1; // true if operand is a type, false if an expression union { void *Ty; Stmt *Ex; } Argument; SourceLocation OpLoc, RParenLoc; public: SizeOfAlignOfExpr(bool issizeof, QualType T, QualType resultType, SourceLocation op, SourceLocation rp) : Expr(SizeOfAlignOfExprClass, resultType, false, // Never type-dependent (C++ [temp.dep.expr]p3). // Value-dependent if the argument is type-dependent. T->isDependentType()), isSizeof(issizeof), isType(true), OpLoc(op), RParenLoc(rp) { Argument.Ty = T.getAsOpaquePtr(); } SizeOfAlignOfExpr(bool issizeof, Expr *E, QualType resultType, SourceLocation op, SourceLocation rp) : Expr(SizeOfAlignOfExprClass, resultType, false, // Never type-dependent (C++ [temp.dep.expr]p3). // Value-dependent if the argument is type-dependent. E->isTypeDependent()), isSizeof(issizeof), isType(false), OpLoc(op), RParenLoc(rp) { Argument.Ex = E; } /// \brief Construct an empty sizeof/alignof expression. explicit SizeOfAlignOfExpr(EmptyShell Empty) : Expr(SizeOfAlignOfExprClass, Empty) { } virtual void Destroy(ASTContext& C); bool isSizeOf() const { return isSizeof; } void setSizeof(bool S) { isSizeof = S; } bool isArgumentType() const { return isType; } QualType getArgumentType() const { assert(isArgumentType() && "calling getArgumentType() when arg is expr"); return QualType::getFromOpaquePtr(Argument.Ty); } Expr *getArgumentExpr() { assert(!isArgumentType() && "calling getArgumentExpr() when arg is type"); return static_cast(Argument.Ex); } const Expr *getArgumentExpr() const { return const_cast(this)->getArgumentExpr(); } void setArgument(Expr *E) { Argument.Ex = E; isType = false; } void setArgument(QualType T) { Argument.Ty = T.getAsOpaquePtr(); isType = true; } /// Gets the argument type, or the type of the argument expression, whichever /// is appropriate. QualType getTypeOfArgument() const { return isArgumentType() ? getArgumentType() : getArgumentExpr()->getType(); } SourceLocation getOperatorLoc() const { return OpLoc; } void setOperatorLoc(SourceLocation L) { OpLoc = L; } SourceLocation getRParenLoc() const { return RParenLoc; } void setRParenLoc(SourceLocation L) { RParenLoc = L; } virtual SourceRange getSourceRange() const { return SourceRange(OpLoc, RParenLoc); } static bool classof(const Stmt *T) { return T->getStmtClass() == SizeOfAlignOfExprClass; } static bool classof(const SizeOfAlignOfExpr *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; //===----------------------------------------------------------------------===// // Postfix Operators. //===----------------------------------------------------------------------===// /// ArraySubscriptExpr - [C99 6.5.2.1] Array Subscripting. class ArraySubscriptExpr : public Expr { enum { LHS, RHS, END_EXPR=2 }; Stmt* SubExprs[END_EXPR]; SourceLocation RBracketLoc; public: ArraySubscriptExpr(Expr *lhs, Expr *rhs, QualType t, SourceLocation rbracketloc) : Expr(ArraySubscriptExprClass, t, lhs->isTypeDependent() || rhs->isTypeDependent(), lhs->isValueDependent() || rhs->isValueDependent()), RBracketLoc(rbracketloc) { SubExprs[LHS] = lhs; SubExprs[RHS] = rhs; } /// \brief Create an empty array subscript expression. explicit ArraySubscriptExpr(EmptyShell Shell) : Expr(ArraySubscriptExprClass, Shell) { } /// An array access can be written A[4] or 4[A] (both are equivalent). /// - getBase() and getIdx() always present the normalized view: A[4]. /// In this case getBase() returns "A" and getIdx() returns "4". /// - getLHS() and getRHS() present the syntactic view. e.g. for /// 4[A] getLHS() returns "4". /// Note: Because vector element access is also written A[4] we must /// predicate the format conversion in getBase and getIdx only on the /// the type of the RHS, as it is possible for the LHS to be a vector of /// integer type Expr *getLHS() { return cast(SubExprs[LHS]); } const Expr *getLHS() const { return cast(SubExprs[LHS]); } void setLHS(Expr *E) { SubExprs[LHS] = E; } Expr *getRHS() { return cast(SubExprs[RHS]); } const Expr *getRHS() const { return cast(SubExprs[RHS]); } void setRHS(Expr *E) { SubExprs[RHS] = E; } Expr *getBase() { return cast(getRHS()->getType()->isIntegerType() ? getLHS():getRHS()); } const Expr *getBase() const { return cast(getRHS()->getType()->isIntegerType() ? getLHS():getRHS()); } Expr *getIdx() { return cast(getRHS()->getType()->isIntegerType() ? getRHS():getLHS()); } const Expr *getIdx() const { return cast(getRHS()->getType()->isIntegerType() ? getRHS():getLHS()); } virtual SourceRange getSourceRange() const { return SourceRange(getLHS()->getLocStart(), RBracketLoc); } SourceLocation getRBracketLoc() const { return RBracketLoc; } void setRBracketLoc(SourceLocation L) { RBracketLoc = L; } virtual SourceLocation getExprLoc() const { return getBase()->getExprLoc(); } static bool classof(const Stmt *T) { return T->getStmtClass() == ArraySubscriptExprClass; } static bool classof(const ArraySubscriptExpr *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// CallExpr - Represents a function call (C99 6.5.2.2, C++ [expr.call]). /// CallExpr itself represents a normal function call, e.g., "f(x, 2)", /// while its subclasses may represent alternative syntax that (semantically) /// results in a function call. For example, CXXOperatorCallExpr is /// a subclass for overloaded operator calls that use operator syntax, e.g., /// "str1 + str2" to resolve to a function call. class CallExpr : public Expr { enum { FN=0, ARGS_START=1 }; Stmt **SubExprs; unsigned NumArgs; SourceLocation RParenLoc; protected: // This version of the constructor is for derived classes. CallExpr(ASTContext& C, StmtClass SC, Expr *fn, Expr **args, unsigned numargs, QualType t, SourceLocation rparenloc); public: CallExpr(ASTContext& C, Expr *fn, Expr **args, unsigned numargs, QualType t, SourceLocation rparenloc); /// \brief Build an empty call expression. CallExpr(ASTContext &C, EmptyShell Empty); ~CallExpr() {} void Destroy(ASTContext& C); const Expr *getCallee() const { return cast(SubExprs[FN]); } Expr *getCallee() { return cast(SubExprs[FN]); } void setCallee(Expr *F) { SubExprs[FN] = F; } /// getNumArgs - Return the number of actual arguments to this call. /// unsigned getNumArgs() const { return NumArgs; } /// getArg - Return the specified argument. Expr *getArg(unsigned Arg) { assert(Arg < NumArgs && "Arg access out of range!"); return cast(SubExprs[Arg+ARGS_START]); } const Expr *getArg(unsigned Arg) const { assert(Arg < NumArgs && "Arg access out of range!"); return cast(SubExprs[Arg+ARGS_START]); } /// setArg - Set the specified argument. void setArg(unsigned Arg, Expr *ArgExpr) { assert(Arg < NumArgs && "Arg access out of range!"); SubExprs[Arg+ARGS_START] = ArgExpr; } /// setNumArgs - This changes the number of arguments present in this call. /// Any orphaned expressions are deleted by this, and any new operands are set /// to null. void setNumArgs(ASTContext& C, unsigned NumArgs); typedef ExprIterator arg_iterator; typedef ConstExprIterator const_arg_iterator; arg_iterator arg_begin() { return SubExprs+ARGS_START; } arg_iterator arg_end() { return SubExprs+ARGS_START+getNumArgs(); } const_arg_iterator arg_begin() const { return SubExprs+ARGS_START; } const_arg_iterator arg_end() const { return SubExprs+ARGS_START+getNumArgs();} /// getNumCommas - Return the number of commas that must have been present in /// this function call. unsigned getNumCommas() const { return NumArgs ? NumArgs - 1 : 0; } /// isBuiltinCall - If this is a call to a builtin, return the builtin ID. If /// not, return 0. unsigned isBuiltinCall(ASTContext &Context) const; /// getCallReturnType - Get the return type of the call expr. This is not /// always the type of the expr itself, if the return type is a reference /// type. QualType getCallReturnType() const; SourceLocation getRParenLoc() const { return RParenLoc; } void setRParenLoc(SourceLocation L) { RParenLoc = L; } virtual SourceRange getSourceRange() const { return SourceRange(getCallee()->getLocStart(), RParenLoc); } static bool classof(const Stmt *T) { return T->getStmtClass() == CallExprClass || T->getStmtClass() == CXXOperatorCallExprClass || T->getStmtClass() == CXXMemberCallExprClass; } static bool classof(const CallExpr *) { return true; } static bool classof(const CXXOperatorCallExpr *) { return true; } static bool classof(const CXXMemberCallExpr *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// MemberExpr - [C99 6.5.2.3] Structure and Union Members. X->F and X.F. /// class MemberExpr : public Expr { /// Base - the expression for the base pointer or structure references. In /// X.F, this is "X". Stmt *Base; /// MemberDecl - This is the decl being referenced by the field/member name. /// In X.F, this is the decl referenced by F. NamedDecl *MemberDecl; /// MemberLoc - This is the location of the member name. SourceLocation MemberLoc; /// IsArrow - True if this is "X->F", false if this is "X.F". bool IsArrow; public: MemberExpr(Expr *base, bool isarrow, NamedDecl *memberdecl, SourceLocation l, QualType ty) : Expr(MemberExprClass, ty, base->isTypeDependent(), base->isValueDependent()), Base(base), MemberDecl(memberdecl), MemberLoc(l), IsArrow(isarrow) {} /// \brief Build an empty member reference expression. explicit MemberExpr(EmptyShell Empty) : Expr(MemberExprClass, Empty) { } void setBase(Expr *E) { Base = E; } Expr *getBase() const { return cast(Base); } /// \brief Retrieve the member declaration to which this expression refers. /// /// The returned declaration will either be a FieldDecl or (in C++) /// a CXXMethodDecl. NamedDecl *getMemberDecl() const { return MemberDecl; } void setMemberDecl(NamedDecl *D) { MemberDecl = D; } bool isArrow() const { return IsArrow; } void setArrow(bool A) { IsArrow = A; } /// getMemberLoc - Return the location of the "member", in X->F, it is the /// location of 'F'. SourceLocation getMemberLoc() const { return MemberLoc; } void setMemberLoc(SourceLocation L) { MemberLoc = L; } virtual SourceRange getSourceRange() const { // If we have an implicit base (like a C++ implicit this), // make sure not to return its location SourceLocation BaseLoc = getBase()->getLocStart(); if (BaseLoc.isInvalid()) return SourceRange(MemberLoc, MemberLoc); return SourceRange(BaseLoc, MemberLoc); } virtual SourceLocation getExprLoc() const { return MemberLoc; } static bool classof(const Stmt *T) { return T->getStmtClass() == MemberExprClass; } static bool classof(const MemberExpr *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// CompoundLiteralExpr - [C99 6.5.2.5] /// class CompoundLiteralExpr : public Expr { /// LParenLoc - If non-null, this is the location of the left paren in a /// compound literal like "(int){4}". This can be null if this is a /// synthesized compound expression. SourceLocation LParenLoc; Stmt *Init; bool FileScope; public: CompoundLiteralExpr(SourceLocation lparenloc, QualType ty, Expr *init, bool fileScope) : Expr(CompoundLiteralExprClass, ty), LParenLoc(lparenloc), Init(init), FileScope(fileScope) {} /// \brief Construct an empty compound literal. explicit CompoundLiteralExpr(EmptyShell Empty) : Expr(CompoundLiteralExprClass, Empty) { } const Expr *getInitializer() const { return cast(Init); } Expr *getInitializer() { return cast(Init); } void setInitializer(Expr *E) { Init = E; } bool isFileScope() const { return FileScope; } void setFileScope(bool FS) { FileScope = FS; } SourceLocation getLParenLoc() const { return LParenLoc; } void setLParenLoc(SourceLocation L) { LParenLoc = L; } virtual SourceRange getSourceRange() const { // FIXME: Init should never be null. if (!Init) return SourceRange(); if (LParenLoc.isInvalid()) return Init->getSourceRange(); return SourceRange(LParenLoc, Init->getLocEnd()); } static bool classof(const Stmt *T) { return T->getStmtClass() == CompoundLiteralExprClass; } static bool classof(const CompoundLiteralExpr *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// CastExpr - Base class for type casts, including both implicit /// casts (ImplicitCastExpr) and explicit casts that have some /// representation in the source code (ExplicitCastExpr's derived /// classes). class CastExpr : public Expr { Stmt *Op; protected: CastExpr(StmtClass SC, QualType ty, Expr *op) : Expr(SC, ty, // Cast expressions are type-dependent if the type is // dependent (C++ [temp.dep.expr]p3). ty->isDependentType(), // Cast expressions are value-dependent if the type is // dependent or if the subexpression is value-dependent. ty->isDependentType() || (op && op->isValueDependent())), Op(op) {} /// \brief Construct an empty cast. CastExpr(StmtClass SC, EmptyShell Empty) : Expr(SC, Empty) { } public: Expr *getSubExpr() { return cast(Op); } const Expr *getSubExpr() const { return cast(Op); } void setSubExpr(Expr *E) { Op = E; } static bool classof(const Stmt *T) { StmtClass SC = T->getStmtClass(); if (SC >= CXXNamedCastExprClass && SC <= CXXFunctionalCastExprClass) return true; if (SC >= ImplicitCastExprClass && SC <= CStyleCastExprClass) return true; return false; } static bool classof(const CastExpr *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// ImplicitCastExpr - Allows us to explicitly represent implicit type /// conversions, which have no direct representation in the original /// source code. For example: converting T[]->T*, void f()->void /// (*f)(), float->double, short->int, etc. /// /// In C, implicit casts always produce rvalues. However, in C++, an /// implicit cast whose result is being bound to a reference will be /// an lvalue. For example: /// /// @code /// class Base { }; /// class Derived : public Base { }; /// void f(Derived d) { /// Base& b = d; // initializer is an ImplicitCastExpr to an lvalue of type Base /// } /// @endcode class ImplicitCastExpr : public CastExpr { /// LvalueCast - Whether this cast produces an lvalue. bool LvalueCast; public: ImplicitCastExpr(QualType ty, Expr *op, bool Lvalue) : CastExpr(ImplicitCastExprClass, ty, op), LvalueCast(Lvalue) { } /// \brief Construct an empty implicit cast. explicit ImplicitCastExpr(EmptyShell Shell) : CastExpr(ImplicitCastExprClass, Shell) { } virtual SourceRange getSourceRange() const { return getSubExpr()->getSourceRange(); } /// isLvalueCast - Whether this cast produces an lvalue. bool isLvalueCast() const { return LvalueCast; } /// setLvalueCast - Set whether this cast produces an lvalue. void setLvalueCast(bool Lvalue) { LvalueCast = Lvalue; } static bool classof(const Stmt *T) { return T->getStmtClass() == ImplicitCastExprClass; } static bool classof(const ImplicitCastExpr *) { return true; } }; /// ExplicitCastExpr - An explicit cast written in the source /// code. /// /// This class is effectively an abstract class, because it provides /// the basic representation of an explicitly-written cast without /// specifying which kind of cast (C cast, functional cast, static /// cast, etc.) was written; specific derived classes represent the /// particular style of cast and its location information. /// /// Unlike implicit casts, explicit cast nodes have two different /// types: the type that was written into the source code, and the /// actual type of the expression as determined by semantic /// analysis. These types may differ slightly. For example, in C++ one /// can cast to a reference type, which indicates that the resulting /// expression will be an lvalue. The reference type, however, will /// not be used as the type of the expression. class ExplicitCastExpr : public CastExpr { /// TypeAsWritten - The type that this expression is casting to, as /// written in the source code. QualType TypeAsWritten; protected: ExplicitCastExpr(StmtClass SC, QualType exprTy, Expr *op, QualType writtenTy) : CastExpr(SC, exprTy, op), TypeAsWritten(writtenTy) {} /// \brief Construct an empty explicit cast. ExplicitCastExpr(StmtClass SC, EmptyShell Shell) : CastExpr(SC, Shell) { } public: /// getTypeAsWritten - Returns the type that this expression is /// casting to, as written in the source code. QualType getTypeAsWritten() const { return TypeAsWritten; } void setTypeAsWritten(QualType T) { TypeAsWritten = T; } static bool classof(const Stmt *T) { StmtClass SC = T->getStmtClass(); if (SC >= ExplicitCastExprClass && SC <= CStyleCastExprClass) return true; if (SC >= CXXNamedCastExprClass && SC <= CXXFunctionalCastExprClass) return true; return false; } static bool classof(const ExplicitCastExpr *) { return true; } }; /// CStyleCastExpr - An explicit cast in C (C99 6.5.4) or a C-style /// cast in C++ (C++ [expr.cast]), which uses the syntax /// (Type)expr. For example: @c (int)f. class CStyleCastExpr : public ExplicitCastExpr { SourceLocation LPLoc; // the location of the left paren SourceLocation RPLoc; // the location of the right paren public: CStyleCastExpr(QualType exprTy, Expr *op, QualType writtenTy, SourceLocation l, SourceLocation r) : ExplicitCastExpr(CStyleCastExprClass, exprTy, op, writtenTy), LPLoc(l), RPLoc(r) {} /// \brief Construct an empty C-style explicit cast. explicit CStyleCastExpr(EmptyShell Shell) : ExplicitCastExpr(CStyleCastExprClass, Shell) { } SourceLocation getLParenLoc() const { return LPLoc; } void setLParenLoc(SourceLocation L) { LPLoc = L; } SourceLocation getRParenLoc() const { return RPLoc; } void setRParenLoc(SourceLocation L) { RPLoc = L; } virtual SourceRange getSourceRange() const { return SourceRange(LPLoc, getSubExpr()->getSourceRange().getEnd()); } static bool classof(const Stmt *T) { return T->getStmtClass() == CStyleCastExprClass; } static bool classof(const CStyleCastExpr *) { return true; } }; /// \brief A builtin binary operation expression such as "x + y" or "x <= y". /// /// This expression node kind describes a builtin binary operation, /// such as "x + y" for integer values "x" and "y". The operands will /// already have been converted to appropriate types (e.g., by /// performing promotions or conversions). /// /// In C++, where operators may be overloaded, a different kind of /// expression node (CXXOperatorCallExpr) is used to express the /// invocation of an overloaded operator with operator syntax. Within /// a C++ template, whether BinaryOperator or CXXOperatorCallExpr is /// used to store an expression "x + y" depends on the subexpressions /// for x and y. If neither x or y is type-dependent, and the "+" /// operator resolves to a built-in operation, BinaryOperator will be /// used to express the computation (x and y may still be /// value-dependent). If either x or y is type-dependent, or if the /// "+" resolves to an overloaded operator, CXXOperatorCallExpr will /// be used to express the computation. class BinaryOperator : public Expr { public: enum Opcode { // Operators listed in order of precedence. // Note that additions to this should also update the StmtVisitor class. PtrMemD, PtrMemI, // [C++ 5.5] Pointer-to-member operators. Mul, Div, Rem, // [C99 6.5.5] Multiplicative operators. Add, Sub, // [C99 6.5.6] Additive operators. Shl, Shr, // [C99 6.5.7] Bitwise shift operators. LT, GT, LE, GE, // [C99 6.5.8] Relational operators. EQ, NE, // [C99 6.5.9] Equality operators. And, // [C99 6.5.10] Bitwise AND operator. Xor, // [C99 6.5.11] Bitwise XOR operator. Or, // [C99 6.5.12] Bitwise OR operator. LAnd, // [C99 6.5.13] Logical AND operator. LOr, // [C99 6.5.14] Logical OR operator. Assign, MulAssign,// [C99 6.5.16] Assignment operators. DivAssign, RemAssign, AddAssign, SubAssign, ShlAssign, ShrAssign, AndAssign, XorAssign, OrAssign, Comma // [C99 6.5.17] Comma operator. }; private: enum { LHS, RHS, END_EXPR }; Stmt* SubExprs[END_EXPR]; Opcode Opc; SourceLocation OpLoc; public: BinaryOperator(Expr *lhs, Expr *rhs, Opcode opc, QualType ResTy, SourceLocation opLoc) : Expr(BinaryOperatorClass, ResTy, lhs->isTypeDependent() || rhs->isTypeDependent(), lhs->isValueDependent() || rhs->isValueDependent()), Opc(opc), OpLoc(opLoc) { SubExprs[LHS] = lhs; SubExprs[RHS] = rhs; assert(!isCompoundAssignmentOp() && "Use ArithAssignBinaryOperator for compound assignments"); } /// \brief Construct an empty binary operator. explicit BinaryOperator(EmptyShell Empty) : Expr(BinaryOperatorClass, Empty), Opc(Comma) { } SourceLocation getOperatorLoc() const { return OpLoc; } void setOperatorLoc(SourceLocation L) { OpLoc = L; } Opcode getOpcode() const { return Opc; } void setOpcode(Opcode O) { Opc = O; } Expr *getLHS() const { return cast(SubExprs[LHS]); } void setLHS(Expr *E) { SubExprs[LHS] = E; } Expr *getRHS() const { return cast(SubExprs[RHS]); } void setRHS(Expr *E) { SubExprs[RHS] = E; } virtual SourceRange getSourceRange() const { return SourceRange(getLHS()->getLocStart(), getRHS()->getLocEnd()); } /// getOpcodeStr - Turn an Opcode enum value into the punctuation char it /// corresponds to, e.g. "<<=". static const char *getOpcodeStr(Opcode Op); /// \brief Retrieve the binary opcode that corresponds to the given /// overloaded operator. static Opcode getOverloadedOpcode(OverloadedOperatorKind OO); /// \brief Retrieve the overloaded operator kind that corresponds to /// the given binary opcode. static OverloadedOperatorKind getOverloadedOperator(Opcode Opc); /// predicates to categorize the respective opcodes. bool isMultiplicativeOp() const { return Opc >= Mul && Opc <= Rem; } bool isAdditiveOp() const { return Opc == Add || Opc == Sub; } bool isShiftOp() const { return Opc == Shl || Opc == Shr; } bool isBitwiseOp() const { return Opc >= And && Opc <= Or; } static bool isRelationalOp(Opcode Opc) { return Opc >= LT && Opc <= GE; } bool isRelationalOp() const { return isRelationalOp(Opc); } static bool isEqualityOp(Opcode Opc) { return Opc == EQ || Opc == NE; } bool isEqualityOp() const { return isEqualityOp(Opc); } static bool isLogicalOp(Opcode Opc) { return Opc == LAnd || Opc == LOr; } bool isLogicalOp() const { return isLogicalOp(Opc); } bool isAssignmentOp() const { return Opc >= Assign && Opc <= OrAssign; } bool isCompoundAssignmentOp() const { return Opc > Assign && Opc <= OrAssign;} bool isShiftAssignOp() const { return Opc == ShlAssign || Opc == ShrAssign; } static bool classof(const Stmt *S) { return S->getStmtClass() == BinaryOperatorClass || S->getStmtClass() == CompoundAssignOperatorClass; } static bool classof(const BinaryOperator *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); protected: BinaryOperator(Expr *lhs, Expr *rhs, Opcode opc, QualType ResTy, SourceLocation oploc, bool dead) : Expr(CompoundAssignOperatorClass, ResTy), Opc(opc), OpLoc(oploc) { SubExprs[LHS] = lhs; SubExprs[RHS] = rhs; } BinaryOperator(StmtClass SC, EmptyShell Empty) : Expr(SC, Empty), Opc(MulAssign) { } }; /// CompoundAssignOperator - For compound assignments (e.g. +=), we keep /// track of the type the operation is performed in. Due to the semantics of /// these operators, the operands are promoted, the aritmetic performed, an /// implicit conversion back to the result type done, then the assignment takes /// place. This captures the intermediate type which the computation is done /// in. class CompoundAssignOperator : public BinaryOperator { QualType ComputationLHSType; QualType ComputationResultType; public: CompoundAssignOperator(Expr *lhs, Expr *rhs, Opcode opc, QualType ResType, QualType CompLHSType, QualType CompResultType, SourceLocation OpLoc) : BinaryOperator(lhs, rhs, opc, ResType, OpLoc, true), ComputationLHSType(CompLHSType), ComputationResultType(CompResultType) { assert(isCompoundAssignmentOp() && "Only should be used for compound assignments"); } /// \brief Build an empty compound assignment operator expression. explicit CompoundAssignOperator(EmptyShell Empty) : BinaryOperator(CompoundAssignOperatorClass, Empty) { } // The two computation types are the type the LHS is converted // to for the computation and the type of the result; the two are // distinct in a few cases (specifically, int+=ptr and ptr-=ptr). QualType getComputationLHSType() const { return ComputationLHSType; } void setComputationLHSType(QualType T) { ComputationLHSType = T; } QualType getComputationResultType() const { return ComputationResultType; } void setComputationResultType(QualType T) { ComputationResultType = T; } static bool classof(const CompoundAssignOperator *) { return true; } static bool classof(const Stmt *S) { return S->getStmtClass() == CompoundAssignOperatorClass; } }; /// ConditionalOperator - The ?: operator. Note that LHS may be null when the /// GNU "missing LHS" extension is in use. /// class ConditionalOperator : public Expr { enum { COND, LHS, RHS, END_EXPR }; Stmt* SubExprs[END_EXPR]; // Left/Middle/Right hand sides. public: ConditionalOperator(Expr *cond, Expr *lhs, Expr *rhs, QualType t) : Expr(ConditionalOperatorClass, t, // FIXME: the type of the conditional operator doesn't // depend on the type of the conditional, but the standard // seems to imply that it could. File a bug! ((lhs && lhs->isTypeDependent()) || (rhs && rhs->isTypeDependent())), (cond->isValueDependent() || (lhs && lhs->isValueDependent()) || (rhs && rhs->isValueDependent()))) { SubExprs[COND] = cond; SubExprs[LHS] = lhs; SubExprs[RHS] = rhs; } /// \brief Build an empty conditional operator. explicit ConditionalOperator(EmptyShell Empty) : Expr(ConditionalOperatorClass, Empty) { } // getCond - Return the expression representing the condition for // the ?: operator. Expr *getCond() const { return cast(SubExprs[COND]); } void setCond(Expr *E) { SubExprs[COND] = E; } // getTrueExpr - Return the subexpression representing the value of the ?: // expression if the condition evaluates to true. In most cases this value // will be the same as getLHS() except a GCC extension allows the left // subexpression to be omitted, and instead of the condition be returned. // e.g: x ?: y is shorthand for x ? x : y, except that the expression "x" // is only evaluated once. Expr *getTrueExpr() const { return cast(SubExprs[LHS] ? SubExprs[LHS] : SubExprs[COND]); } // getTrueExpr - Return the subexpression representing the value of the ?: // expression if the condition evaluates to false. This is the same as getRHS. Expr *getFalseExpr() const { return cast(SubExprs[RHS]); } Expr *getLHS() const { return cast_or_null(SubExprs[LHS]); } void setLHS(Expr *E) { SubExprs[LHS] = E; } Expr *getRHS() const { return cast(SubExprs[RHS]); } void setRHS(Expr *E) { SubExprs[RHS] = E; } virtual SourceRange getSourceRange() const { return SourceRange(getCond()->getLocStart(), getRHS()->getLocEnd()); } static bool classof(const Stmt *T) { return T->getStmtClass() == ConditionalOperatorClass; } static bool classof(const ConditionalOperator *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// AddrLabelExpr - The GNU address of label extension, representing &&label. class AddrLabelExpr : public Expr { SourceLocation AmpAmpLoc, LabelLoc; LabelStmt *Label; public: AddrLabelExpr(SourceLocation AALoc, SourceLocation LLoc, LabelStmt *L, QualType t) : Expr(AddrLabelExprClass, t), AmpAmpLoc(AALoc), LabelLoc(LLoc), Label(L) {} /// \brief Build an empty address of a label expression. explicit AddrLabelExpr(EmptyShell Empty) : Expr(AddrLabelExprClass, Empty) { } SourceLocation getAmpAmpLoc() const { return AmpAmpLoc; } void setAmpAmpLoc(SourceLocation L) { AmpAmpLoc = L; } SourceLocation getLabelLoc() const { return LabelLoc; } void setLabelLoc(SourceLocation L) { LabelLoc = L; } virtual SourceRange getSourceRange() const { return SourceRange(AmpAmpLoc, LabelLoc); } LabelStmt *getLabel() const { return Label; } void setLabel(LabelStmt *S) { Label = S; } static bool classof(const Stmt *T) { return T->getStmtClass() == AddrLabelExprClass; } static bool classof(const AddrLabelExpr *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// StmtExpr - This is the GNU Statement Expression extension: ({int X=4; X;}). /// The StmtExpr contains a single CompoundStmt node, which it evaluates and /// takes the value of the last subexpression. class StmtExpr : public Expr { Stmt *SubStmt; SourceLocation LParenLoc, RParenLoc; public: StmtExpr(CompoundStmt *substmt, QualType T, SourceLocation lp, SourceLocation rp) : Expr(StmtExprClass, T), SubStmt(substmt), LParenLoc(lp), RParenLoc(rp) { } /// \brief Build an empty statement expression. explicit StmtExpr(EmptyShell Empty) : Expr(StmtExprClass, Empty) { } CompoundStmt *getSubStmt() { return cast(SubStmt); } const CompoundStmt *getSubStmt() const { return cast(SubStmt); } void setSubStmt(CompoundStmt *S) { SubStmt = S; } virtual SourceRange getSourceRange() const { return SourceRange(LParenLoc, RParenLoc); } SourceLocation getLParenLoc() const { return LParenLoc; } void setLParenLoc(SourceLocation L) { LParenLoc = L; } SourceLocation getRParenLoc() const { return RParenLoc; } void setRParenLoc(SourceLocation L) { RParenLoc = L; } static bool classof(const Stmt *T) { return T->getStmtClass() == StmtExprClass; } static bool classof(const StmtExpr *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// TypesCompatibleExpr - GNU builtin-in function __builtin_types_compatible_p. /// This AST node represents a function that returns 1 if two *types* (not /// expressions) are compatible. The result of this built-in function can be /// used in integer constant expressions. class TypesCompatibleExpr : public Expr { QualType Type1; QualType Type2; SourceLocation BuiltinLoc, RParenLoc; public: TypesCompatibleExpr(QualType ReturnType, SourceLocation BLoc, QualType t1, QualType t2, SourceLocation RP) : Expr(TypesCompatibleExprClass, ReturnType), Type1(t1), Type2(t2), BuiltinLoc(BLoc), RParenLoc(RP) {} /// \brief Build an empty __builtin_type_compatible_p expression. explicit TypesCompatibleExpr(EmptyShell Empty) : Expr(TypesCompatibleExprClass, Empty) { } QualType getArgType1() const { return Type1; } void setArgType1(QualType T) { Type1 = T; } QualType getArgType2() const { return Type2; } void setArgType2(QualType T) { Type2 = T; } SourceLocation getBuiltinLoc() const { return BuiltinLoc; } void setBuiltinLoc(SourceLocation L) { BuiltinLoc = L; } SourceLocation getRParenLoc() const { return RParenLoc; } void setRParenLoc(SourceLocation L) { RParenLoc = L; } virtual SourceRange getSourceRange() const { return SourceRange(BuiltinLoc, RParenLoc); } static bool classof(const Stmt *T) { return T->getStmtClass() == TypesCompatibleExprClass; } static bool classof(const TypesCompatibleExpr *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// ShuffleVectorExpr - clang-specific builtin-in function /// __builtin_shufflevector. /// This AST node represents a operator that does a constant /// shuffle, similar to LLVM's shufflevector instruction. It takes /// two vectors and a variable number of constant indices, /// and returns the appropriately shuffled vector. class ShuffleVectorExpr : public Expr { SourceLocation BuiltinLoc, RParenLoc; // SubExprs - the list of values passed to the __builtin_shufflevector // function. The first two are vectors, and the rest are constant // indices. The number of values in this list is always // 2+the number of indices in the vector type. Stmt **SubExprs; unsigned NumExprs; public: ShuffleVectorExpr(Expr **args, unsigned nexpr, QualType Type, SourceLocation BLoc, SourceLocation RP) : Expr(ShuffleVectorExprClass, Type), BuiltinLoc(BLoc), RParenLoc(RP), NumExprs(nexpr) { SubExprs = new Stmt*[nexpr]; for (unsigned i = 0; i < nexpr; i++) SubExprs[i] = args[i]; } /// \brief Build an empty vector-shuffle expression. explicit ShuffleVectorExpr(EmptyShell Empty) : Expr(ShuffleVectorExprClass, Empty), SubExprs(0) { } SourceLocation getBuiltinLoc() const { return BuiltinLoc; } void setBuiltinLoc(SourceLocation L) { BuiltinLoc = L; } SourceLocation getRParenLoc() const { return RParenLoc; } void setRParenLoc(SourceLocation L) { RParenLoc = L; } virtual SourceRange getSourceRange() const { return SourceRange(BuiltinLoc, RParenLoc); } static bool classof(const Stmt *T) { return T->getStmtClass() == ShuffleVectorExprClass; } static bool classof(const ShuffleVectorExpr *) { return true; } ~ShuffleVectorExpr() { delete [] SubExprs; } /// getNumSubExprs - Return the size of the SubExprs array. This includes the /// constant expression, the actual arguments passed in, and the function /// pointers. unsigned getNumSubExprs() const { return NumExprs; } /// getExpr - Return the Expr at the specified index. Expr *getExpr(unsigned Index) { assert((Index < NumExprs) && "Arg access out of range!"); return cast(SubExprs[Index]); } const Expr *getExpr(unsigned Index) const { assert((Index < NumExprs) && "Arg access out of range!"); return cast(SubExprs[Index]); } void setExprs(Expr ** Exprs, unsigned NumExprs); unsigned getShuffleMaskIdx(ASTContext &Ctx, unsigned N) { assert((N < NumExprs - 2) && "Shuffle idx out of range!"); return getExpr(N+2)->EvaluateAsInt(Ctx).getZExtValue(); } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// ChooseExpr - GNU builtin-in function __builtin_choose_expr. /// This AST node is similar to the conditional operator (?:) in C, with /// the following exceptions: /// - the test expression must be a integer constant expression. /// - the expression returned acts like the chosen subexpression in every /// visible way: the type is the same as that of the chosen subexpression, /// and all predicates (whether it's an l-value, whether it's an integer /// constant expression, etc.) return the same result as for the chosen /// sub-expression. class ChooseExpr : public Expr { enum { COND, LHS, RHS, END_EXPR }; Stmt* SubExprs[END_EXPR]; // Left/Middle/Right hand sides. SourceLocation BuiltinLoc, RParenLoc; public: ChooseExpr(SourceLocation BLoc, Expr *cond, Expr *lhs, Expr *rhs, QualType t, SourceLocation RP) : Expr(ChooseExprClass, t), BuiltinLoc(BLoc), RParenLoc(RP) { SubExprs[COND] = cond; SubExprs[LHS] = lhs; SubExprs[RHS] = rhs; } /// \brief Build an empty __builtin_choose_expr. explicit ChooseExpr(EmptyShell Empty) : Expr(ChooseExprClass, Empty) { } /// isConditionTrue - Return whether the condition is true (i.e. not /// equal to zero). bool isConditionTrue(ASTContext &C) const; /// getChosenSubExpr - Return the subexpression chosen according to the /// condition. Expr *getChosenSubExpr(ASTContext &C) const { return isConditionTrue(C) ? getLHS() : getRHS(); } Expr *getCond() const { return cast(SubExprs[COND]); } void setCond(Expr *E) { SubExprs[COND] = E; } Expr *getLHS() const { return cast(SubExprs[LHS]); } void setLHS(Expr *E) { SubExprs[LHS] = E; } Expr *getRHS() const { return cast(SubExprs[RHS]); } void setRHS(Expr *E) { SubExprs[RHS] = E; } SourceLocation getBuiltinLoc() const { return BuiltinLoc; } void setBuiltinLoc(SourceLocation L) { BuiltinLoc = L; } SourceLocation getRParenLoc() const { return RParenLoc; } void setRParenLoc(SourceLocation L) { RParenLoc = L; } virtual SourceRange getSourceRange() const { return SourceRange(BuiltinLoc, RParenLoc); } static bool classof(const Stmt *T) { return T->getStmtClass() == ChooseExprClass; } static bool classof(const ChooseExpr *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// GNUNullExpr - Implements the GNU __null extension, which is a name /// for a null pointer constant that has integral type (e.g., int or /// long) and is the same size and alignment as a pointer. The __null /// extension is typically only used by system headers, which define /// NULL as __null in C++ rather than using 0 (which is an integer /// that may not match the size of a pointer). class GNUNullExpr : public Expr { /// TokenLoc - The location of the __null keyword. SourceLocation TokenLoc; public: GNUNullExpr(QualType Ty, SourceLocation Loc) : Expr(GNUNullExprClass, Ty), TokenLoc(Loc) { } /// \brief Build an empty GNU __null expression. explicit GNUNullExpr(EmptyShell Empty) : Expr(GNUNullExprClass, Empty) { } GNUNullExpr* Clone(ASTContext &C) const; /// getTokenLocation - The location of the __null token. SourceLocation getTokenLocation() const { return TokenLoc; } void setTokenLocation(SourceLocation L) { TokenLoc = L; } virtual SourceRange getSourceRange() const { return SourceRange(TokenLoc); } static bool classof(const Stmt *T) { return T->getStmtClass() == GNUNullExprClass; } static bool classof(const GNUNullExpr *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// VAArgExpr, used for the builtin function __builtin_va_start. class VAArgExpr : public Expr { Stmt *Val; SourceLocation BuiltinLoc, RParenLoc; public: VAArgExpr(SourceLocation BLoc, Expr* e, QualType t, SourceLocation RPLoc) : Expr(VAArgExprClass, t), Val(e), BuiltinLoc(BLoc), RParenLoc(RPLoc) { } /// \brief Create an empty __builtin_va_start expression. explicit VAArgExpr(EmptyShell Empty) : Expr(VAArgExprClass, Empty) { } const Expr *getSubExpr() const { return cast(Val); } Expr *getSubExpr() { return cast(Val); } void setSubExpr(Expr *E) { Val = E; } SourceLocation getBuiltinLoc() const { return BuiltinLoc; } void setBuiltinLoc(SourceLocation L) { BuiltinLoc = L; } SourceLocation getRParenLoc() const { return RParenLoc; } void setRParenLoc(SourceLocation L) { RParenLoc = L; } virtual SourceRange getSourceRange() const { return SourceRange(BuiltinLoc, RParenLoc); } static bool classof(const Stmt *T) { return T->getStmtClass() == VAArgExprClass; } static bool classof(const VAArgExpr *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// @brief Describes an C or C++ initializer list. /// /// InitListExpr describes an initializer list, which can be used to /// initialize objects of different types, including /// struct/class/union types, arrays, and vectors. For example: /// /// @code /// struct foo x = { 1, { 2, 3 } }; /// @endcode /// /// Prior to semantic analysis, an initializer list will represent the /// initializer list as written by the user, but will have the /// placeholder type "void". This initializer list is called the /// syntactic form of the initializer, and may contain C99 designated /// initializers (represented as DesignatedInitExprs), initializations /// of subobject members without explicit braces, and so on. Clients /// interested in the original syntax of the initializer list should /// use the syntactic form of the initializer list. /// /// After semantic analysis, the initializer list will represent the /// semantic form of the initializer, where the initializations of all /// subobjects are made explicit with nested InitListExpr nodes and /// C99 designators have been eliminated by placing the designated /// initializations into the subobject they initialize. Additionally, /// any "holes" in the initialization, where no initializer has been /// specified for a particular subobject, will be replaced with /// implicitly-generated ImplicitValueInitExpr expressions that /// value-initialize the subobjects. Note, however, that the /// initializer lists may still have fewer initializers than there are /// elements to initialize within the object. /// /// Given the semantic form of the initializer list, one can retrieve /// the original syntactic form of that initializer list (if it /// exists) using getSyntacticForm(). Since many initializer lists /// have the same syntactic and semantic forms, getSyntacticForm() may /// return NULL, indicating that the current initializer list also /// serves as its syntactic form. class InitListExpr : public Expr { std::vector InitExprs; SourceLocation LBraceLoc, RBraceLoc; /// Contains the initializer list that describes the syntactic form /// written in the source code. InitListExpr *SyntacticForm; /// If this initializer list initializes a union, specifies which /// field within the union will be initialized. FieldDecl *UnionFieldInit; /// Whether this initializer list originally had a GNU array-range /// designator in it. This is a temporary marker used by CodeGen. bool HadArrayRangeDesignator; public: InitListExpr(SourceLocation lbraceloc, Expr **initexprs, unsigned numinits, SourceLocation rbraceloc); /// \brief Build an empty initializer list. explicit InitListExpr(EmptyShell Empty) : Expr(InitListExprClass, Empty) { } unsigned getNumInits() const { return InitExprs.size(); } const Expr* getInit(unsigned Init) const { assert(Init < getNumInits() && "Initializer access out of range!"); return cast_or_null(InitExprs[Init]); } Expr* getInit(unsigned Init) { assert(Init < getNumInits() && "Initializer access out of range!"); return cast_or_null(InitExprs[Init]); } void setInit(unsigned Init, Expr *expr) { assert(Init < getNumInits() && "Initializer access out of range!"); InitExprs[Init] = expr; } /// \brief Reserve space for some number of initializers. void reserveInits(unsigned NumInits); /// @brief Specify the number of initializers /// /// If there are more than @p NumInits initializers, the remaining /// initializers will be destroyed. If there are fewer than @p /// NumInits initializers, NULL expressions will be added for the /// unknown initializers. void resizeInits(ASTContext &Context, unsigned NumInits); /// @brief Updates the initializer at index @p Init with the new /// expression @p expr, and returns the old expression at that /// location. /// /// When @p Init is out of range for this initializer list, the /// initializer list will be extended with NULL expressions to /// accomodate the new entry. Expr *updateInit(unsigned Init, Expr *expr); /// \brief If this initializes a union, specifies which field in the /// union to initialize. /// /// Typically, this field is the first named field within the /// union. However, a designated initializer can specify the /// initialization of a different field within the union. FieldDecl *getInitializedFieldInUnion() { return UnionFieldInit; } void setInitializedFieldInUnion(FieldDecl *FD) { UnionFieldInit = FD; } // Explicit InitListExpr's originate from source code (and have valid source // locations). Implicit InitListExpr's are created by the semantic analyzer. bool isExplicit() { return LBraceLoc.isValid() && RBraceLoc.isValid(); } SourceLocation getLBraceLoc() const { return LBraceLoc; } void setLBraceLoc(SourceLocation Loc) { LBraceLoc = Loc; } SourceLocation getRBraceLoc() const { return RBraceLoc; } void setRBraceLoc(SourceLocation Loc) { RBraceLoc = Loc; } /// @brief Retrieve the initializer list that describes the /// syntactic form of the initializer. /// /// InitListExpr *getSyntacticForm() const { return SyntacticForm; } void setSyntacticForm(InitListExpr *Init) { SyntacticForm = Init; } bool hadArrayRangeDesignator() const { return HadArrayRangeDesignator; } void sawArrayRangeDesignator(bool ARD = true) { HadArrayRangeDesignator = ARD; } virtual SourceRange getSourceRange() const { return SourceRange(LBraceLoc, RBraceLoc); } static bool classof(const Stmt *T) { return T->getStmtClass() == InitListExprClass; } static bool classof(const InitListExpr *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); typedef std::vector::iterator iterator; typedef std::vector::reverse_iterator reverse_iterator; iterator begin() { return InitExprs.begin(); } iterator end() { return InitExprs.end(); } reverse_iterator rbegin() { return InitExprs.rbegin(); } reverse_iterator rend() { return InitExprs.rend(); } }; /// @brief Represents a C99 designated initializer expression. /// /// A designated initializer expression (C99 6.7.8) contains one or /// more designators (which can be field designators, array /// designators, or GNU array-range designators) followed by an /// expression that initializes the field or element(s) that the /// designators refer to. For example, given: /// /// @code /// struct point { /// double x; /// double y; /// }; /// struct point ptarray[10] = { [2].y = 1.0, [2].x = 2.0, [0].x = 1.0 }; /// @endcode /// /// The InitListExpr contains three DesignatedInitExprs, the first of /// which covers @c [2].y=1.0. This DesignatedInitExpr will have two /// designators, one array designator for @c [2] followed by one field /// designator for @c .y. The initalization expression will be 1.0. class DesignatedInitExpr : public Expr { public: /// \brief Forward declaration of the Designator class. class Designator; private: /// The location of the '=' or ':' prior to the actual initializer /// expression. SourceLocation EqualOrColonLoc; /// Whether this designated initializer used the GNU deprecated /// syntax rather than the C99 '=' syntax. bool GNUSyntax : 1; /// The number of designators in this initializer expression. unsigned NumDesignators : 15; /// \brief The designators in this designated initialization /// expression. Designator *Designators; /// The number of subexpressions of this initializer expression, /// which contains both the initializer and any additional /// expressions used by array and array-range designators. unsigned NumSubExprs : 16; DesignatedInitExpr(QualType Ty, unsigned NumDesignators, const Designator *Designators, SourceLocation EqualOrColonLoc, bool GNUSyntax, Expr **IndexExprs, unsigned NumIndexExprs, Expr *Init); explicit DesignatedInitExpr(unsigned NumSubExprs) : Expr(DesignatedInitExprClass, EmptyShell()), NumDesignators(0), Designators(0), NumSubExprs(NumSubExprs) { } public: /// A field designator, e.g., ".x". struct FieldDesignator { /// Refers to the field that is being initialized. The low bit /// of this field determines whether this is actually a pointer /// to an IdentifierInfo (if 1) or a FieldDecl (if 0). When /// initially constructed, a field designator will store an /// IdentifierInfo*. After semantic analysis has resolved that /// name, the field designator will instead store a FieldDecl*. uintptr_t NameOrField; /// The location of the '.' in the designated initializer. unsigned DotLoc; /// The location of the field name in the designated initializer. unsigned FieldLoc; }; /// An array or GNU array-range designator, e.g., "[9]" or "[10..15]". struct ArrayOrRangeDesignator { /// Location of the first index expression within the designated /// initializer expression's list of subexpressions. unsigned Index; /// The location of the '[' starting the array range designator. unsigned LBracketLoc; /// The location of the ellipsis separating the start and end /// indices. Only valid for GNU array-range designators. unsigned EllipsisLoc; /// The location of the ']' terminating the array range designator. unsigned RBracketLoc; }; /// @brief Represents a single C99 designator. /// /// @todo This class is infuriatingly similar to clang::Designator, /// but minor differences (storing indices vs. storing pointers) /// keep us from reusing it. Try harder, later, to rectify these /// differences. class Designator { /// @brief The kind of designator this describes. enum { FieldDesignator, ArrayDesignator, ArrayRangeDesignator } Kind; union { /// A field designator, e.g., ".x". struct FieldDesignator Field; /// An array or GNU array-range designator, e.g., "[9]" or "[10..15]". struct ArrayOrRangeDesignator ArrayOrRange; }; friend class DesignatedInitExpr; public: Designator() {} /// @brief Initializes a field designator. Designator(const IdentifierInfo *FieldName, SourceLocation DotLoc, SourceLocation FieldLoc) : Kind(FieldDesignator) { Field.NameOrField = reinterpret_cast(FieldName) | 0x01; Field.DotLoc = DotLoc.getRawEncoding(); Field.FieldLoc = FieldLoc.getRawEncoding(); } /// @brief Initializes an array designator. Designator(unsigned Index, SourceLocation LBracketLoc, SourceLocation RBracketLoc) : Kind(ArrayDesignator) { ArrayOrRange.Index = Index; ArrayOrRange.LBracketLoc = LBracketLoc.getRawEncoding(); ArrayOrRange.EllipsisLoc = SourceLocation().getRawEncoding(); ArrayOrRange.RBracketLoc = RBracketLoc.getRawEncoding(); } /// @brief Initializes a GNU array-range designator. Designator(unsigned Index, SourceLocation LBracketLoc, SourceLocation EllipsisLoc, SourceLocation RBracketLoc) : Kind(ArrayRangeDesignator) { ArrayOrRange.Index = Index; ArrayOrRange.LBracketLoc = LBracketLoc.getRawEncoding(); ArrayOrRange.EllipsisLoc = EllipsisLoc.getRawEncoding(); ArrayOrRange.RBracketLoc = RBracketLoc.getRawEncoding(); } bool isFieldDesignator() const { return Kind == FieldDesignator; } bool isArrayDesignator() const { return Kind == ArrayDesignator; } bool isArrayRangeDesignator() const { return Kind == ArrayRangeDesignator; } IdentifierInfo * getFieldName(); FieldDecl *getField() { assert(Kind == FieldDesignator && "Only valid on a field designator"); if (Field.NameOrField & 0x01) return 0; else return reinterpret_cast(Field.NameOrField); } void setField(FieldDecl *FD) { assert(Kind == FieldDesignator && "Only valid on a field designator"); Field.NameOrField = reinterpret_cast(FD); } SourceLocation getDotLoc() const { assert(Kind == FieldDesignator && "Only valid on a field designator"); return SourceLocation::getFromRawEncoding(Field.DotLoc); } SourceLocation getFieldLoc() const { assert(Kind == FieldDesignator && "Only valid on a field designator"); return SourceLocation::getFromRawEncoding(Field.FieldLoc); } SourceLocation getLBracketLoc() const { assert((Kind == ArrayDesignator || Kind == ArrayRangeDesignator) && "Only valid on an array or array-range designator"); return SourceLocation::getFromRawEncoding(ArrayOrRange.LBracketLoc); } SourceLocation getRBracketLoc() const { assert((Kind == ArrayDesignator || Kind == ArrayRangeDesignator) && "Only valid on an array or array-range designator"); return SourceLocation::getFromRawEncoding(ArrayOrRange.RBracketLoc); } SourceLocation getEllipsisLoc() const { assert(Kind == ArrayRangeDesignator && "Only valid on an array-range designator"); return SourceLocation::getFromRawEncoding(ArrayOrRange.EllipsisLoc); } unsigned getFirstExprIndex() const { assert((Kind == ArrayDesignator || Kind == ArrayRangeDesignator) && "Only valid on an array or array-range designator"); return ArrayOrRange.Index; } SourceLocation getStartLocation() const { if (Kind == FieldDesignator) return getDotLoc().isInvalid()? getFieldLoc() : getDotLoc(); else return getLBracketLoc(); } }; static DesignatedInitExpr *Create(ASTContext &C, Designator *Designators, unsigned NumDesignators, Expr **IndexExprs, unsigned NumIndexExprs, SourceLocation EqualOrColonLoc, bool GNUSyntax, Expr *Init); static DesignatedInitExpr *CreateEmpty(ASTContext &C, unsigned NumIndexExprs); /// @brief Returns the number of designators in this initializer. unsigned size() const { return NumDesignators; } // Iterator access to the designators. typedef Designator* designators_iterator; designators_iterator designators_begin() { return Designators; } designators_iterator designators_end() { return Designators + NumDesignators; } Designator *getDesignator(unsigned Idx) { return &designators_begin()[Idx]; } void setDesignators(const Designator *Desigs, unsigned NumDesigs); Expr *getArrayIndex(const Designator& D); Expr *getArrayRangeStart(const Designator& D); Expr *getArrayRangeEnd(const Designator& D); /// @brief Retrieve the location of the '=' that precedes the /// initializer value itself, if present. SourceLocation getEqualOrColonLoc() const { return EqualOrColonLoc; } void setEqualOrColonLoc(SourceLocation L) { EqualOrColonLoc = L; } /// @brief Determines whether this designated initializer used the /// deprecated GNU syntax for designated initializers. bool usesGNUSyntax() const { return GNUSyntax; } void setGNUSyntax(bool GNU) { GNUSyntax = GNU; } /// @brief Retrieve the initializer value. Expr *getInit() const { return cast(*const_cast(this)->child_begin()); } void setInit(Expr *init) { *child_begin() = init; } /// \brief Retrieve the total number of subexpressions in this /// designated initializer expression, including the actual /// initialized value and any expressions that occur within array /// and array-range designators. unsigned getNumSubExprs() const { return NumSubExprs; } Expr *getSubExpr(unsigned Idx) { assert(Idx < NumSubExprs && "Subscript out of range"); char* Ptr = static_cast(static_cast(this)); Ptr += sizeof(DesignatedInitExpr); return reinterpret_cast(reinterpret_cast(Ptr))[Idx]; } void setSubExpr(unsigned Idx, Expr *E) { assert(Idx < NumSubExprs && "Subscript out of range"); char* Ptr = static_cast(static_cast(this)); Ptr += sizeof(DesignatedInitExpr); reinterpret_cast(reinterpret_cast(Ptr))[Idx] = E; } /// \brief Replaces the designator at index @p Idx with the series /// of designators in [First, Last). void ExpandDesignator(unsigned Idx, const Designator *First, const Designator *Last); virtual SourceRange getSourceRange() const; virtual void Destroy(ASTContext &C); static bool classof(const Stmt *T) { return T->getStmtClass() == DesignatedInitExprClass; } static bool classof(const DesignatedInitExpr *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// \brief Represents an implicitly-generated value initialization of /// an object of a given type. /// /// Implicit value initializations occur within semantic initializer /// list expressions (InitListExpr) as placeholders for subobject /// initializations not explicitly specified by the user. /// /// \see InitListExpr class ImplicitValueInitExpr : public Expr { public: explicit ImplicitValueInitExpr(QualType ty) : Expr(ImplicitValueInitExprClass, ty) { } /// \brief Construct an empty implicit value initialization. explicit ImplicitValueInitExpr(EmptyShell Empty) : Expr(ImplicitValueInitExprClass, Empty) { } static bool classof(const Stmt *T) { return T->getStmtClass() == ImplicitValueInitExprClass; } static bool classof(const ImplicitValueInitExpr *) { return true; } virtual SourceRange getSourceRange() const { return SourceRange(); } ImplicitValueInitExpr *Clone(ASTContext &C) const; // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; //===----------------------------------------------------------------------===// // Clang Extensions //===----------------------------------------------------------------------===// /// ExtVectorElementExpr - This represents access to specific elements of a /// vector, and may occur on the left hand side or right hand side. For example /// the following is legal: "V.xy = V.zw" if V is a 4 element extended vector. /// /// Note that the base may have either vector or pointer to vector type, just /// like a struct field reference. /// class ExtVectorElementExpr : public Expr { Stmt *Base; IdentifierInfo *Accessor; SourceLocation AccessorLoc; public: ExtVectorElementExpr(QualType ty, Expr *base, IdentifierInfo &accessor, SourceLocation loc) : Expr(ExtVectorElementExprClass, ty), Base(base), Accessor(&accessor), AccessorLoc(loc) {} /// \brief Build an empty vector element expression. explicit ExtVectorElementExpr(EmptyShell Empty) : Expr(ExtVectorElementExprClass, Empty) { } const Expr *getBase() const { return cast(Base); } Expr *getBase() { return cast(Base); } void setBase(Expr *E) { Base = E; } IdentifierInfo &getAccessor() const { return *Accessor; } void setAccessor(IdentifierInfo *II) { Accessor = II; } SourceLocation getAccessorLoc() const { return AccessorLoc; } void setAccessorLoc(SourceLocation L) { AccessorLoc = L; } /// getNumElements - Get the number of components being selected. unsigned getNumElements() const; /// containsDuplicateElements - Return true if any element access is /// repeated. bool containsDuplicateElements() const; /// getEncodedElementAccess - Encode the elements accessed into an llvm /// aggregate Constant of ConstantInt(s). void getEncodedElementAccess(llvm::SmallVectorImpl &Elts) const; virtual SourceRange getSourceRange() const { return SourceRange(getBase()->getLocStart(), AccessorLoc); } /// isArrow - Return true if the base expression is a pointer to vector, /// return false if the base expression is a vector. bool isArrow() const; static bool classof(const Stmt *T) { return T->getStmtClass() == ExtVectorElementExprClass; } static bool classof(const ExtVectorElementExpr *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// BlockExpr - Adaptor class for mixing a BlockDecl with expressions. /// ^{ statement-body } or ^(int arg1, float arg2){ statement-body } class BlockExpr : public Expr { protected: BlockDecl *TheBlock; bool HasBlockDeclRefExprs; public: BlockExpr(BlockDecl *BD, QualType ty, bool hasBlockDeclRefExprs) : Expr(BlockExprClass, ty), TheBlock(BD), HasBlockDeclRefExprs(hasBlockDeclRefExprs) {} /// \brief Build an empty block expression. explicit BlockExpr(EmptyShell Empty) : Expr(BlockExprClass, Empty) { } const BlockDecl *getBlockDecl() const { return TheBlock; } BlockDecl *getBlockDecl() { return TheBlock; } void setBlockDecl(BlockDecl *BD) { TheBlock = BD; } // Convenience functions for probing the underlying BlockDecl. SourceLocation getCaretLocation() const; const Stmt *getBody() const; Stmt *getBody(); const Stmt *getBody(ASTContext &C) const { return getBody(); } Stmt *getBody(ASTContext &C) { return getBody(); } virtual SourceRange getSourceRange() const { return SourceRange(getCaretLocation(), getBody()->getLocEnd()); } /// getFunctionType - Return the underlying function type for this block. const FunctionType *getFunctionType() const; /// hasBlockDeclRefExprs - Return true iff the block has BlockDeclRefExpr /// inside of the block that reference values outside the block. bool hasBlockDeclRefExprs() const { return HasBlockDeclRefExprs; } void setHasBlockDeclRefExprs(bool BDRE) { HasBlockDeclRefExprs = BDRE; } static bool classof(const Stmt *T) { return T->getStmtClass() == BlockExprClass; } static bool classof(const BlockExpr *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; /// BlockDeclRefExpr - A reference to a declared variable, function, /// enum, etc. class BlockDeclRefExpr : public Expr { ValueDecl *D; SourceLocation Loc; bool IsByRef; public: BlockDeclRefExpr(ValueDecl *d, QualType t, SourceLocation l, bool ByRef) : Expr(BlockDeclRefExprClass, t), D(d), Loc(l), IsByRef(ByRef) {} // \brief Build an empty reference to a declared variable in a // block. explicit BlockDeclRefExpr(EmptyShell Empty) : Expr(BlockDeclRefExprClass, Empty) { } ValueDecl *getDecl() { return D; } const ValueDecl *getDecl() const { return D; } void setDecl(ValueDecl *VD) { D = VD; } SourceLocation getLocation() const { return Loc; } void setLocation(SourceLocation L) { Loc = L; } virtual SourceRange getSourceRange() const { return SourceRange(Loc); } bool isByRef() const { return IsByRef; } void setByRef(bool BR) { IsByRef = BR; } static bool classof(const Stmt *T) { return T->getStmtClass() == BlockDeclRefExprClass; } static bool classof(const BlockDeclRefExpr *) { return true; } // Iterators virtual child_iterator child_begin(); virtual child_iterator child_end(); }; } // end namespace clang #endif