//===--- ASTMatchers.h - Structural query framework -------------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file implements matchers to be used together with the MatchFinder to // match AST nodes. // // Matchers are created by generator functions, which can be combined in // a functional in-language DSL to express queries over the C++ AST. // // For example, to match a class with a certain name, one would call: // record(hasName("MyClass")) // which returns a matcher that can be used to find all AST nodes that declare // a class named 'MyClass'. // // For more complicated match expressions we're often interested in accessing // multiple parts of the matched AST nodes once a match is found. In that case, // use the id(...) matcher around the match expressions that match the nodes // you want to access. // // For example, when we're interested in child classes of a certain class, we // would write: // record(hasName("MyClass"), hasChild(id("child", record()))) // When the match is found via the MatchFinder, a user provided callback will // be called with a BoundNodes instance that contains a mapping from the // strings that we provided for the id(...) calls to the nodes that were // matched. // In the given example, each time our matcher finds a match we get a callback // where "child" is bound to the CXXRecordDecl node of the matching child // class declaration. // // See ASTMatchersInternal.h for a more in-depth explanation of the // implementation details of the matcher framework. // // See ASTMatchFinder.h for how to use the generated matchers to run over // an AST. // //===----------------------------------------------------------------------===// #ifndef LLVM_CLANG_AST_MATCHERS_AST_MATCHERS_H #define LLVM_CLANG_AST_MATCHERS_AST_MATCHERS_H #include "clang/AST/DeclTemplate.h" #include "clang/ASTMatchers/ASTMatchersInternal.h" #include "clang/ASTMatchers/ASTMatchersMacros.h" #include "llvm/ADT/Twine.h" #include "llvm/Support/Regex.h" #include namespace clang { namespace ast_matchers { /// \brief Maps string IDs to AST nodes matched by parts of a matcher. /// /// The bound nodes are generated by adding id(...) matchers into the /// match expression around the matchers for the nodes we want to access later. /// /// The instances of BoundNodes are created by MatchFinder when the user's /// callbacks are executed every time a match is found. class BoundNodes { public: /// \brief Returns the AST node bound to 'ID'. /// Returns NULL if there was no node bound to 'ID' or if there is a node but /// it cannot be converted to the specified type. /// FIXME: We'll need one of those for every base type. /// @{ template const T *getDeclAs(StringRef ID) const { return getNodeAs(DeclBindings, ID); } template const T *getStmtAs(StringRef ID) const { return getNodeAs(StmtBindings, ID); } /// @} private: /// \brief Create BoundNodes from a pre-filled map of bindings. BoundNodes(const std::map &DeclBindings, const std::map &StmtBindings) : DeclBindings(DeclBindings), StmtBindings(StmtBindings) {} template const T *getNodeAs(const MapT &Bindings, StringRef ID) const { typename MapT::const_iterator It = Bindings.find(ID); if (It == Bindings.end()) { return NULL; } return llvm::dyn_cast(It->second); } std::map DeclBindings; std::map StmtBindings; friend class internal::BoundNodesTree; }; /// \brief If the provided matcher matches a node, binds the node to 'ID'. /// /// FIXME: Add example for accessing it. template internal::Matcher id(const std::string &ID, const internal::BindableMatcher &InnerMatcher) { return InnerMatcher.bind(ID); } /// \brief Types of matchers for the top-level classes in the AST class /// hierarchy. /// @{ typedef internal::Matcher DeclarationMatcher; typedef internal::Matcher TypeMatcher; typedef internal::Matcher StatementMatcher; /// @} /// \brief Matches any node. /// /// Useful when another matcher requires a child matcher, but there's no /// additional constraint. This will often be used with an explicit conversion /// to a internal::Matcher<> type such as TypeMatcher. /// /// Example: DeclarationMatcher(anything()) matches all declarations, e.g., /// "int* p" and "void f()" in /// int* p; /// void f(); inline internal::PolymorphicMatcherWithParam0 anything() { return internal::PolymorphicMatcherWithParam0(); } /// \brief Matches declarations. /// /// Examples matches \c X, \c C, and the friend declaration inside \c C; /// \code /// void X(); /// class C { /// friend X; /// }; /// \endcode const internal::VariadicDynCastAllOfMatcher decl; /// \brief Matches a declaration of anything that could have a name. /// /// Example matches X, S, the anonymous union type, i, and U; /// typedef int X; /// struct S { /// union { /// int i; /// } U; /// }; const internal::VariadicDynCastAllOfMatcher< Decl, NamedDecl> nameableDeclaration; /// \brief Matches C++ class declarations. /// /// Example matches X, Z /// class X; /// template class Z {}; const internal::VariadicDynCastAllOfMatcher< Decl, CXXRecordDecl> record; /// \brief Matches C++ class template specializations. /// /// Given /// template class A {}; /// template<> class A {}; /// A a; /// classTemplateSpecialization() /// matches the specializations \c A and \c A const internal::VariadicDynCastAllOfMatcher< Decl, ClassTemplateSpecializationDecl> classTemplateSpecialization; /// \brief Matches classTemplateSpecializations that have at least one /// TemplateArgument matching the given Matcher. /// /// Given /// template class A {}; /// template<> class A {}; /// A a; /// classTemplateSpecialization(hasAnyTemplateArgument( /// refersToType(asString("int")))) /// matches the specialization \c A AST_MATCHER_P(ClassTemplateSpecializationDecl, hasAnyTemplateArgument, internal::Matcher, Matcher) { const TemplateArgumentList &List = Node.getTemplateArgs(); for (unsigned i = 0; i < List.size(); ++i) { if (Matcher.matches(List.get(i), Finder, Builder)) return true; } return false; } /// \brief Matches expressions that match InnerMatcher after any implicit casts /// are stripped off. /// /// Parentheses and explicit casts are not discarded. /// Given /// int arr[5]; /// int a = 0; /// char b = 0; /// const int c = a; /// int *d = arr; /// long e = (long) 0l; /// The matchers /// variable(hasInitializer(ignoringImpCasts(integerLiteral()))) /// variable(hasInitializer(ignoringImpCasts(declarationReference()))) /// would match the declarations for a, b, c, and d, but not e. /// while /// variable(hasInitializer(integerLiteral())) /// variable(hasInitializer(declarationReference())) /// only match the declarations for b, c, and d. AST_MATCHER_P(Expr, ignoringImpCasts, internal::Matcher, InnerMatcher) { return InnerMatcher.matches(*Node.IgnoreImpCasts(), Finder, Builder); } /// \brief Matches expressions that match InnerMatcher after parentheses and /// casts are stripped off. /// /// Implicit and non-C Style casts are also discarded. /// Given /// int a = 0; /// char b = (0); /// void* c = reinterpret_cast(0); /// char d = char(0); /// The matcher /// variable(hasInitializer(ignoringParenCasts(integerLiteral()))) /// would match the declarations for a, b, c, and d. /// while /// variable(hasInitializer(integerLiteral())) /// only match the declaration for a. AST_MATCHER_P(Expr, ignoringParenCasts, internal::Matcher, InnerMatcher) { return InnerMatcher.matches(*Node.IgnoreParenCasts(), Finder, Builder); } /// \brief Matches expressions that match InnerMatcher after implicit casts and /// parentheses are stripped off. /// /// Explicit casts are not discarded. /// Given /// int arr[5]; /// int a = 0; /// char b = (0); /// const int c = a; /// int *d = (arr); /// long e = ((long) 0l); /// The matchers /// variable(hasInitializer(ignoringParenImpCasts( /// integerLiteral()))) /// variable(hasInitializer(ignoringParenImpCasts( /// declarationReference()))) /// would match the declarations for a, b, c, and d, but not e. /// while /// variable(hasInitializer(integerLiteral())) /// variable(hasInitializer(declarationReference())) /// would only match the declaration for a. AST_MATCHER_P(Expr, ignoringParenImpCasts, internal::Matcher, InnerMatcher) { return InnerMatcher.matches(*Node.IgnoreParenImpCasts(), Finder, Builder); } /// \brief Matches classTemplateSpecializations where the n'th TemplateArgument /// matches the given Matcher. /// /// Given /// template class A {}; /// A b; /// A c; /// classTemplateSpecialization(hasTemplateArgument( /// 1, refersToType(asString("int")))) /// matches the specialization \c A AST_MATCHER_P2(ClassTemplateSpecializationDecl, hasTemplateArgument, unsigned, N, internal::Matcher, Matcher) { const TemplateArgumentList &List = Node.getTemplateArgs(); if (List.size() <= N) return false; return Matcher.matches(List.get(N), Finder, Builder); } /// \brief Matches a TemplateArgument that refers to a certain type. /// /// Given /// struct X {}; /// template struct A {}; /// A a; /// classTemplateSpecialization(hasAnyTemplateArgument( /// refersToType(class(hasName("X"))))) /// matches the specialization \c A AST_MATCHER_P(TemplateArgument, refersToType, internal::Matcher, Matcher) { if (Node.getKind() != TemplateArgument::Type) return false; return Matcher.matches(Node.getAsType(), Finder, Builder); } /// \brief Matches a TemplateArgument that refers to a certain declaration. /// /// Given /// template struct A {}; /// struct B { B* next; }; /// A<&B::next> a; /// classTemplateSpecialization(hasAnyTemplateArgument( /// refersToDeclaration(field(hasName("next")))) /// matches the specialization \c A<&B::next> with \c field(...) matching /// \c B::next AST_MATCHER_P(TemplateArgument, refersToDeclaration, internal::Matcher, Matcher) { if (const Decl *Declaration = Node.getAsDecl()) return Matcher.matches(*Declaration, Finder, Builder); return false; } /// \brief Matches C++ constructor declarations. /// /// Example matches Foo::Foo() and Foo::Foo(int) /// class Foo { /// public: /// Foo(); /// Foo(int); /// int DoSomething(); /// }; const internal::VariadicDynCastAllOfMatcher< Decl, CXXConstructorDecl> constructor; /// \brief Matches explicit C++ destructor declarations. /// /// Example matches Foo::~Foo() /// class Foo { /// public: /// virtual ~Foo(); /// }; const internal::VariadicDynCastAllOfMatcher destructor; /// \brief Matches enum declarations. /// /// Example matches X /// enum X { /// A, B, C /// }; const internal::VariadicDynCastAllOfMatcher enumDecl; /// \brief Matches enum constants. /// /// Example matches A, B, C /// enum X { /// A, B, C /// }; const internal::VariadicDynCastAllOfMatcher< Decl, EnumConstantDecl> enumConstant; /// \brief Matches method declarations. /// /// Example matches y /// class X { void y() }; const internal::VariadicDynCastAllOfMatcher method; /// \brief Matches variable declarations. /// /// Note: this does not match declarations of member variables, which are /// "field" declarations in Clang parlance. /// /// Example matches a /// int a; const internal::VariadicDynCastAllOfMatcher variable; /// \brief Matches field declarations. /// /// Given /// class X { int m; }; /// field() /// matches 'm'. const internal::VariadicDynCastAllOfMatcher field; /// \brief Matches function declarations. /// /// Example matches f /// void f(); const internal::VariadicDynCastAllOfMatcher function; /// \brief Matches statements. /// /// Given /// { ++a; } /// statement() /// matches both the compound statement '{ ++a; }' and '++a'. const internal::VariadicDynCastAllOfMatcher statement; /// \brief Matches declaration statements. /// /// Given /// int a; /// declarationStatement() /// matches 'int a'. const internal::VariadicDynCastAllOfMatcher< Stmt, DeclStmt> declarationStatement; /// \brief Matches member expressions. /// /// Given /// class Y { /// void x() { this->x(); x(); Y y; y.x(); a; this->b; Y::b; } /// int a; static int b; /// }; /// memberExpression() /// matches this->x, x, y.x, a, this->b const internal::VariadicDynCastAllOfMatcher< Stmt, MemberExpr> memberExpression; /// \brief Matches call expressions. /// /// Example matches x.y() and y() /// X x; /// x.y(); /// y(); const internal::VariadicDynCastAllOfMatcher call; /// \brief Matches member call expressions. /// /// Example matches x.y() /// X x; /// x.y(); const internal::VariadicDynCastAllOfMatcher memberCall; /// \brief Matches init list expressions. /// /// Given /// int a[] = { 1, 2 }; /// struct B { int x, y; }; /// B b = { 5, 6 }; /// initList() /// matches "{ 1, 2 }" and "{ 5, 6 }" const internal::VariadicDynCastAllOfMatcher initListExpr; /// \brief Matches using declarations. /// /// Given /// namespace X { int x; } /// using X::x; /// usingDecl() /// matches \code using X::x \endcode const internal::VariadicDynCastAllOfMatcher usingDecl; /// \brief Matches constructor call expressions (including implicit ones). /// /// Example matches string(ptr, n) and ptr within arguments of f /// (matcher = constructorCall()) /// void f(const string &a, const string &b); /// char *ptr; /// int n; /// f(string(ptr, n), ptr); const internal::VariadicDynCastAllOfMatcher< Stmt, CXXConstructExpr> constructorCall; /// \brief Matches nodes where temporaries are created. /// /// Example matches FunctionTakesString(GetStringByValue()) /// (matcher = bindTemporaryExpression()) /// FunctionTakesString(GetStringByValue()); /// FunctionTakesStringByPointer(GetStringPointer()); const internal::VariadicDynCastAllOfMatcher< Stmt, CXXBindTemporaryExpr> bindTemporaryExpression; /// \brief Matches new expressions. /// /// Given /// new X; /// newExpression() /// matches 'new X'. const internal::VariadicDynCastAllOfMatcher< Stmt, CXXNewExpr> newExpression; /// \brief Matches delete expressions. /// /// Given /// delete X; /// deleteExpression() /// matches 'delete X'. const internal::VariadicDynCastAllOfMatcher< Stmt, CXXDeleteExpr> deleteExpression; /// \brief Matches array subscript expressions. /// /// Given /// int i = a[1]; /// arraySubscriptExpr() /// matches "a[1]" const internal::VariadicDynCastAllOfMatcher< Stmt, ArraySubscriptExpr> arraySubscriptExpr; /// \brief Matches the value of a default argument at the call site. /// /// Example matches the CXXDefaultArgExpr placeholder inserted for the /// default value of the second parameter in the call expression f(42) /// (matcher = defaultArgument()) /// void f(int x, int y = 0); /// f(42); const internal::VariadicDynCastAllOfMatcher< Stmt, CXXDefaultArgExpr> defaultArgument; /// \brief Matches overloaded operator calls. /// /// Note that if an operator isn't overloaded, it won't match. Instead, use /// binaryOperator matcher. /// Currently it does not match operators such as new delete. /// FIXME: figure out why these do not match? /// /// Example matches both operator<<((o << b), c) and operator<<(o, b) /// (matcher = overloadedOperatorCall()) /// ostream &operator<< (ostream &out, int i) { }; /// ostream &o; int b = 1, c = 1; /// o << b << c; const internal::VariadicDynCastAllOfMatcher< Stmt, CXXOperatorCallExpr> overloadedOperatorCall; /// \brief Matches expressions. /// /// Example matches x() /// void f() { x(); } const internal::VariadicDynCastAllOfMatcher< Stmt, Expr> expression; /// \brief Matches expressions that refer to declarations. /// /// Example matches x in if (x) /// bool x; /// if (x) {} const internal::VariadicDynCastAllOfMatcher< Stmt, DeclRefExpr> declarationReference; /// \brief Matches if statements. /// /// Example matches 'if (x) {}' /// if (x) {} const internal::VariadicDynCastAllOfMatcher ifStmt; /// \brief Matches for statements. /// /// Example matches 'for (;;) {}' /// for (;;) {} const internal::VariadicDynCastAllOfMatcher< Stmt, ForStmt> forStmt; /// \brief Matches the increment statement of a for loop. /// /// Example: /// forStmt(hasIncrement(unaryOperator(hasOperatorName("++")))) /// matches '++x' in /// for (x; x < N; ++x) { } AST_MATCHER_P(ForStmt, hasIncrement, internal::Matcher, InnerMatcher) { const Stmt *const Increment = Node.getInc(); return (Increment != NULL && InnerMatcher.matches(*Increment, Finder, Builder)); } /// \brief Matches the initialization statement of a for loop. /// /// Example: /// forStmt(hasLoopInit(declarationStatement())) /// matches 'int x = 0' in /// for (int x = 0; x < N; ++x) { } AST_MATCHER_P(ForStmt, hasLoopInit, internal::Matcher, InnerMatcher) { const Stmt *const Init = Node.getInit(); return (Init != NULL && InnerMatcher.matches(*Init, Finder, Builder)); } /// \brief Matches while statements. /// /// Given /// while (true) {} /// whileStmt() /// matches 'while (true) {}'. const internal::VariadicDynCastAllOfMatcher< Stmt, WhileStmt> whileStmt; /// \brief Matches do statements. /// /// Given /// do {} while (true); /// doStmt() /// matches 'do {} while(true)' const internal::VariadicDynCastAllOfMatcher doStmt; /// \brief Matches case and default statements inside switch statements. /// /// Given /// switch(a) { case 42: break; default: break; } /// switchCase() /// matches 'case 42: break;' and 'default: break;'. const internal::VariadicDynCastAllOfMatcher< Stmt, SwitchCase> switchCase; /// \brief Matches compound statements. /// /// Example matches '{}' and '{{}}'in 'for (;;) {{}}' /// for (;;) {{}} const internal::VariadicDynCastAllOfMatcher< Stmt, CompoundStmt> compoundStatement; /// \brief Matches bool literals. /// /// Example matches true /// true const internal::VariadicDynCastAllOfMatcher< Expr, CXXBoolLiteralExpr> boolLiteral; /// \brief Matches string literals (also matches wide string literals). /// /// Example matches "abcd", L"abcd" /// char *s = "abcd"; wchar_t *ws = L"abcd" const internal::VariadicDynCastAllOfMatcher< Expr, StringLiteral> stringLiteral; /// \brief Matches character literals (also matches wchar_t). /// /// Not matching Hex-encoded chars (e.g. 0x1234, which is a IntegerLiteral), /// though. /// /// Example matches 'a', L'a' /// char ch = 'a'; wchar_t chw = L'a'; const internal::VariadicDynCastAllOfMatcher< Expr, CharacterLiteral> characterLiteral; /// \brief Matches integer literals of all sizes / encodings. /// /// Not matching character-encoded integers such as L'a'. /// /// Example matches 1, 1L, 0x1, 1U const internal::VariadicDynCastAllOfMatcher< Expr, IntegerLiteral> integerLiteral; /// \brief Matches binary operator expressions. /// /// Example matches a || b /// !(a || b) const internal::VariadicDynCastAllOfMatcher< Stmt, BinaryOperator> binaryOperator; /// \brief Matches unary operator expressions. /// /// Example matches !a /// !a || b const internal::VariadicDynCastAllOfMatcher< Stmt, UnaryOperator> unaryOperator; /// \brief Matches conditional operator expressions. /// /// Example matches a ? b : c /// (a ? b : c) + 42 const internal::VariadicDynCastAllOfMatcher< Stmt, ConditionalOperator> conditionalOperator; /// \brief Matches a reinterpret_cast expression. /// /// Either the source expression or the destination type can be matched /// using has(), but hasDestinationType() is more specific and can be /// more readable. /// /// Example matches reinterpret_cast(&p) in /// void* p = reinterpret_cast(&p); const internal::VariadicDynCastAllOfMatcher< Expr, CXXReinterpretCastExpr> reinterpretCast; /// \brief Matches a C++ static_cast expression. /// /// \see hasDestinationType /// \see reinterpretCast /// /// Example: /// staticCast() /// matches /// static_cast(8) /// in /// long eight(static_cast(8)); const internal::VariadicDynCastAllOfMatcher< Expr, CXXStaticCastExpr> staticCast; /// \brief Matches a dynamic_cast expression. /// /// Example: /// dynamicCast() /// matches /// dynamic_cast(&b); /// in /// struct B { virtual ~B() {} }; struct D : B {}; /// B b; /// D* p = dynamic_cast(&b); const internal::VariadicDynCastAllOfMatcher< Expr, CXXDynamicCastExpr> dynamicCast; /// \brief Matches a const_cast expression. /// /// Example: Matches const_cast(&r) in /// int n = 42; /// const int& r(n); /// int* p = const_cast(&r); const internal::VariadicDynCastAllOfMatcher< Expr, CXXConstCastExpr> constCast; /// \brief Matches explicit cast expressions. /// /// Matches any cast expression written in user code, whether it be a /// C-style cast, a functional-style cast, or a keyword cast. /// /// Does not match implicit conversions. /// /// Note: the name "explicitCast" is chosen to match Clang's terminology, as /// Clang uses the term "cast" to apply to implicit conversions as well as to /// actual cast expressions. /// /// \see hasDestinationType. /// /// Example: matches all five of the casts in /// int((int)(reinterpret_cast(static_cast(const_cast(42))))) /// but does not match the implicit conversion in /// long ell = 42; const internal::VariadicDynCastAllOfMatcher< Expr, ExplicitCastExpr> explicitCast; /// \brief Matches the implicit cast nodes of Clang's AST. /// /// This matches many different places, including function call return value /// eliding, as well as any type conversions. const internal::VariadicDynCastAllOfMatcher< Expr, ImplicitCastExpr> implicitCast; /// \brief Matches any cast nodes of Clang's AST. /// /// Example: castExpr() matches each of the following: /// (int) 3; /// const_cast(SubExpr); /// char c = 0; /// but does not match /// int i = (0); /// int k = 0; const internal::VariadicDynCastAllOfMatcher< Expr, CastExpr> castExpr; /// \brief Matches functional cast expressions /// /// Example: Matches Foo(bar); /// Foo f = bar; /// Foo g = (Foo) bar; /// Foo h = Foo(bar); const internal::VariadicDynCastAllOfMatcher< Expr, CXXFunctionalCastExpr> functionalCast; /// \brief Various overloads for the anyOf matcher. /// @{ template internal::PolymorphicMatcherWithParam2 anyOf(const C1 &P1, const C2 &P2) { return internal::PolymorphicMatcherWithParam2(P1, P2); } template internal::PolymorphicMatcherWithParam2 > anyOf(const C1 &P1, const C2 &P2, const C3 &P3) { return anyOf(P1, anyOf(P2, P3)); } template internal::PolymorphicMatcherWithParam2 > > anyOf(const C1 &P1, const C2 &P2, const C3 &P3, const C4 &P4) { return anyOf(P1, anyOf(P2, anyOf(P3, P4))); } template internal::PolymorphicMatcherWithParam2 > > > anyOf(const C1& P1, const C2& P2, const C3& P3, const C4& P4, const C5& P5) { return anyOf(P1, anyOf(P2, anyOf(P3, anyOf(P4, P5)))); } /// @} /// \brief Various overloads for the allOf matcher. /// @{ template internal::PolymorphicMatcherWithParam2 allOf(const C1 &P1, const C2 &P2) { return internal::PolymorphicMatcherWithParam2(P1, P2); } template internal::PolymorphicMatcherWithParam2 > allOf(const C1& P1, const C2& P2, const C3& P3) { return allOf(P1, allOf(P2, P3)); } /// @} /// \brief Matches sizeof (C99), alignof (C++11) and vec_step (OpenCL) /// /// Given /// Foo x = bar; /// int y = sizeof(x) + alignof(x); /// unaryExprOrTypeTraitExpr() /// matches \c sizeof(x) and \c alignof(x) const internal::VariadicDynCastAllOfMatcher< Stmt, UnaryExprOrTypeTraitExpr> unaryExprOrTypeTraitExpr; /// \brief Matches unary expressions that have a specific type of argument. /// /// Given /// int a, c; float b; int s = sizeof(a) + sizeof(b) + alignof(c); /// unaryExprOrTypeTraitExpr(hasArgumentOfType(asString("int")) /// matches \c sizeof(a) and \c alignof(c) AST_MATCHER_P(UnaryExprOrTypeTraitExpr, hasArgumentOfType, internal::Matcher, Matcher) { const QualType ArgumentType = Node.getTypeOfArgument(); return Matcher.matches(ArgumentType, Finder, Builder); } /// \brief Matches unary expressions of a certain kind. /// /// Given /// int x; /// int s = sizeof(x) + alignof(x) /// unaryExprOrTypeTraitExpr(ofKind(UETT_SizeOf)) /// matches \c sizeof(x) AST_MATCHER_P(UnaryExprOrTypeTraitExpr, ofKind, UnaryExprOrTypeTrait, Kind) { return Node.getKind() == Kind; } /// \brief Same as unaryExprOrTypeTraitExpr, but only matching /// alignof. inline internal::Matcher alignOfExpr( const internal::Matcher &Matcher) { return internal::Matcher(unaryExprOrTypeTraitExpr(allOf( ofKind(UETT_AlignOf), Matcher))); } /// \brief Same as unaryExprOrTypeTraitExpr, but only matching /// sizeof. inline internal::Matcher sizeOfExpr( const internal::Matcher &Matcher) { return internal::Matcher(unaryExprOrTypeTraitExpr(allOf( ofKind(UETT_SizeOf), Matcher))); } /// \brief Matches NamedDecl nodes that have the specified name. /// /// Supports specifying enclosing namespaces or classes by prefixing the name /// with '::'. /// Does not match typedefs of an underlying type with the given name. /// /// Example matches X (Name == "X") /// class X; /// /// Example matches X (Name is one of "::a::b::X", "a::b::X", "b::X", "X") /// namespace a { namespace b { class X; } } AST_MATCHER_P(NamedDecl, hasName, std::string, Name) { assert(!Name.empty()); const std::string FullNameString = "::" + Node.getQualifiedNameAsString(); const llvm::StringRef FullName = FullNameString; const llvm::StringRef Pattern = Name; if (Pattern.startswith("::")) { return FullName == Pattern; } else { return FullName.endswith(("::" + Pattern).str()); } } /// \brief Matches NamedDecl nodes whose full names partially match the /// given RegExp. /// /// Supports specifying enclosing namespaces or classes by /// prefixing the name with '::'. Does not match typedefs /// of an underlying type with the given name. /// /// Example matches X (regexp == "::X") /// class X; /// /// Example matches X (regexp is one of "::X", "^foo::.*X", among others) /// namespace foo { namespace bar { class X; } } AST_MATCHER_P(NamedDecl, matchesName, std::string, RegExp) { assert(!RegExp.empty()); std::string FullNameString = "::" + Node.getQualifiedNameAsString(); llvm::Regex RE(RegExp); return RE.match(FullNameString); } /// \brief Matches overloaded operator names. /// /// Matches overloaded operator names specified in strings without the /// "operator" prefix, such as "<<", for OverloadedOperatorCall's. /// /// Example matches a << b /// (matcher == overloadedOperatorCall(hasOverloadedOperatorName("<<"))) /// a << b; /// c && d; // assuming both operator<< /// // and operator&& are overloaded somewhere. AST_MATCHER_P(CXXOperatorCallExpr, hasOverloadedOperatorName, std::string, Name) { return getOperatorSpelling(Node.getOperator()) == Name; } /// \brief Matches C++ classes that are directly or indirectly derived from /// a class matching \c Base. /// /// Note that a class is considered to be also derived from itself. /// /// Example matches X, Y, Z, C (Base == hasName("X")) /// class X; // A class is considered to be derived from itself /// class Y : public X {}; // directly derived /// class Z : public Y {}; // indirectly derived /// typedef X A; /// typedef A B; /// class C : public B {}; // derived from a typedef of X /// /// In the following example, Bar matches isDerivedFrom(hasName("X")): /// class Foo; /// typedef Foo X; /// class Bar : public Foo {}; // derived from a type that X is a typedef of AST_MATCHER_P(CXXRecordDecl, isDerivedFrom, internal::Matcher, Base) { return Finder->classIsDerivedFrom(&Node, Base, Builder); } /// \brief Overloaded method as shortcut for \c isDerivedFrom(hasName(...)). inline internal::Matcher isDerivedFrom(StringRef BaseName) { assert(!BaseName.empty()); return isDerivedFrom(hasName(BaseName)); } /// \brief Matches AST nodes that have child AST nodes that match the /// provided matcher. /// /// Example matches X, Y (matcher = record(has(record(hasName("X"))) /// class X {}; // Matches X, because X::X is a class of name X inside X. /// class Y { class X {}; }; /// class Z { class Y { class X {}; }; }; // Does not match Z. /// /// ChildT must be an AST base type. template internal::ArgumentAdaptingMatcher has( const internal::Matcher &ChildMatcher) { return internal::ArgumentAdaptingMatcher(ChildMatcher); } /// \brief Matches AST nodes that have descendant AST nodes that match the /// provided matcher. /// /// Example matches X, Y, Z /// (matcher = record(hasDescendant(record(hasName("X"))))) /// class X {}; // Matches X, because X::X is a class of name X inside X. /// class Y { class X {}; }; /// class Z { class Y { class X {}; }; }; /// /// DescendantT must be an AST base type. template internal::ArgumentAdaptingMatcher hasDescendant(const internal::Matcher &DescendantMatcher) { return internal::ArgumentAdaptingMatcher< internal::HasDescendantMatcher, DescendantT>(DescendantMatcher); } /// \brief Matches AST nodes that have child AST nodes that match the /// provided matcher. /// /// Example matches X, Y (matcher = record(forEach(record(hasName("X"))) /// class X {}; // Matches X, because X::X is a class of name X inside X. /// class Y { class X {}; }; /// class Z { class Y { class X {}; }; }; // Does not match Z. /// /// ChildT must be an AST base type. /// /// As opposed to 'has', 'forEach' will cause a match for each result that /// matches instead of only on the first one. template internal::ArgumentAdaptingMatcher forEach( const internal::Matcher& ChildMatcher) { return internal::ArgumentAdaptingMatcher< internal::ForEachMatcher, ChildT>(ChildMatcher); } /// \brief Matches AST nodes that have descendant AST nodes that match the /// provided matcher. /// /// Example matches X, A, B, C /// (matcher = record(forEachDescendant(record(hasName("X"))))) /// class X {}; // Matches X, because X::X is a class of name X inside X. /// class A { class X {}; }; /// class B { class C { class X {}; }; }; /// /// DescendantT must be an AST base type. /// /// As opposed to 'hasDescendant', 'forEachDescendant' will cause a match for /// each result that matches instead of only on the first one. /// /// Note: Recursively combined ForEachDescendant can cause many matches: /// record(forEachDescendant(record(forEachDescendant(record())))) /// will match 10 times (plus injected class name matches) on: /// class A { class B { class C { class D { class E {}; }; }; }; }; template internal::ArgumentAdaptingMatcher forEachDescendant( const internal::Matcher& DescendantMatcher) { return internal::ArgumentAdaptingMatcher< internal::ForEachDescendantMatcher, DescendantT>(DescendantMatcher); } /// \brief Matches if the provided matcher does not match. /// /// Example matches Y (matcher = record(unless(hasName("X")))) /// class X {}; /// class Y {}; template internal::PolymorphicMatcherWithParam1 unless(const M &InnerMatcher) { return internal::PolymorphicMatcherWithParam1< internal::NotMatcher, M>(InnerMatcher); } /// \brief Matches a type if the declaration of the type matches the given /// matcher. /// /// Usable as: Matcher, Matcher, Matcher inline internal::PolymorphicMatcherWithParam1< internal::HasDeclarationMatcher, internal::Matcher > hasDeclaration(const internal::Matcher &InnerMatcher) { return internal::PolymorphicMatcherWithParam1< internal::HasDeclarationMatcher, internal::Matcher >(InnerMatcher); } /// \brief Matches on the implicit object argument of a member call expression. /// /// Example matches y.x() (matcher = call(on(hasType(record(hasName("Y")))))) /// class Y { public: void x(); }; /// void z() { Y y; y.x(); }", /// /// FIXME: Overload to allow directly matching types? AST_MATCHER_P(CXXMemberCallExpr, on, internal::Matcher, InnerMatcher) { const Expr *ExprNode = const_cast(Node) .getImplicitObjectArgument() ->IgnoreParenImpCasts(); return (ExprNode != NULL && InnerMatcher.matches(*ExprNode, Finder, Builder)); } /// \brief Matches if the call expression's callee expression matches. /// /// Given /// class Y { void x() { this->x(); x(); Y y; y.x(); } }; /// void f() { f(); } /// call(callee(expression())) /// matches this->x(), x(), y.x(), f() /// with callee(...) /// matching this->x, x, y.x, f respectively /// /// Note: Callee cannot take the more general internal::Matcher /// because this introduces ambiguous overloads with calls to Callee taking a /// internal::Matcher, as the matcher hierarchy is purely /// implemented in terms of implicit casts. AST_MATCHER_P(CallExpr, callee, internal::Matcher, InnerMatcher) { const Expr *ExprNode = Node.getCallee(); return (ExprNode != NULL && InnerMatcher.matches(*ExprNode, Finder, Builder)); } /// \brief Matches if the call expression's callee's declaration matches the /// given matcher. /// /// Example matches y.x() (matcher = call(callee(method(hasName("x"))))) /// class Y { public: void x(); }; /// void z() { Y y; y.x(); inline internal::Matcher callee( const internal::Matcher &InnerMatcher) { return internal::Matcher(hasDeclaration(InnerMatcher)); } /// \brief Matches if the expression's or declaration's type matches a type /// matcher. /// /// Example matches x (matcher = expression(hasType( /// hasDeclaration(record(hasName("X")))))) /// and z (matcher = variable(hasType( /// hasDeclaration(record(hasName("X")))))) /// class X {}; /// void y(X &x) { x; X z; } AST_POLYMORPHIC_MATCHER_P(hasType, internal::Matcher, InnerMatcher) { TOOLING_COMPILE_ASSERT((llvm::is_base_of::value || llvm::is_base_of::value), instantiated_with_wrong_types); return InnerMatcher.matches(Node.getType(), Finder, Builder); } /// \brief Overloaded to match the declaration of the expression's or value /// declaration's type. /// /// In case of a value declaration (for example a variable declaration), /// this resolves one layer of indirection. For example, in the value /// declaration "X x;", record(hasName("X")) matches the declaration of X, /// while variable(hasType(record(hasName("X")))) matches the declaration /// of x." /// /// Example matches x (matcher = expression(hasType(record(hasName("X"))))) /// and z (matcher = variable(hasType(record(hasName("X"))))) /// class X {}; /// void y(X &x) { x; X z; } /// /// Usable as: Matcher, Matcher inline internal::PolymorphicMatcherWithParam1< internal::matcher_hasTypeMatcher, internal::Matcher > hasType(const internal::Matcher &InnerMatcher) { return hasType(internal::Matcher( hasDeclaration(InnerMatcher))); } /// \brief Matches if the matched type is represented by the given string. /// /// Given /// class Y { public: void x(); }; /// void z() { Y* y; y->x(); } /// call(on(hasType(asString("class Y *")))) /// matches y->x() AST_MATCHER_P(QualType, asString, std::string, Name) { return Name == Node.getAsString(); } /// \brief Matches if the matched type is a pointer type and the pointee type /// matches the specified matcher. /// /// Example matches y->x() /// (matcher = call(on(hasType(pointsTo(record(hasName("Y"))))))) /// class Y { public: void x(); }; /// void z() { Y *y; y->x(); } AST_MATCHER_P( QualType, pointsTo, internal::Matcher, InnerMatcher) { return (!Node.isNull() && Node->isPointerType() && InnerMatcher.matches(Node->getPointeeType(), Finder, Builder)); } /// \brief Overloaded to match the pointee type's declaration. inline internal::Matcher pointsTo( const internal::Matcher &InnerMatcher) { return pointsTo(internal::Matcher( hasDeclaration(InnerMatcher))); } /// \brief Matches if the matched type is a reference type and the referenced /// type matches the specified matcher. /// /// Example matches X &x and const X &y /// (matcher = variable(hasType(references(record(hasName("X")))))) /// class X { /// void a(X b) { /// X &x = b; /// const X &y = b; /// }; AST_MATCHER_P(QualType, references, internal::Matcher, InnerMatcher) { return (!Node.isNull() && Node->isReferenceType() && InnerMatcher.matches(Node->getPointeeType(), Finder, Builder)); } /// \brief Overloaded to match the referenced type's declaration. inline internal::Matcher references( const internal::Matcher &InnerMatcher) { return references(internal::Matcher( hasDeclaration(InnerMatcher))); } AST_MATCHER_P(CXXMemberCallExpr, onImplicitObjectArgument, internal::Matcher, InnerMatcher) { const Expr *ExprNode = const_cast(Node).getImplicitObjectArgument(); return (ExprNode != NULL && InnerMatcher.matches(*ExprNode, Finder, Builder)); } /// \brief Matches if the expression's type either matches the specified /// matcher, or is a pointer to a type that matches the InnerMatcher. inline internal::Matcher thisPointerType( const internal::Matcher &InnerMatcher) { return onImplicitObjectArgument( anyOf(hasType(InnerMatcher), hasType(pointsTo(InnerMatcher)))); } /// \brief Overloaded to match the type's declaration. inline internal::Matcher thisPointerType( const internal::Matcher &InnerMatcher) { return onImplicitObjectArgument( anyOf(hasType(InnerMatcher), hasType(pointsTo(InnerMatcher)))); } /// \brief Matches a DeclRefExpr that refers to a declaration that matches the /// specified matcher. /// /// Example matches x in if(x) /// (matcher = declarationReference(to(variable(hasName("x"))))) /// bool x; /// if (x) {} AST_MATCHER_P(DeclRefExpr, to, internal::Matcher, InnerMatcher) { const Decl *DeclNode = Node.getDecl(); return (DeclNode != NULL && InnerMatcher.matches(*DeclNode, Finder, Builder)); } /// \brief Matches a \c DeclRefExpr that refers to a declaration through a /// specific using shadow declaration. /// /// FIXME: This currently only works for functions. Fix. /// /// Given /// namespace a { void f() {} } /// using a::f; /// void g() { /// f(); // Matches this .. /// a::f(); // .. but not this. /// } /// declarationReference(throughUsingDeclaration(anything())) /// matches \c f() AST_MATCHER_P(DeclRefExpr, throughUsingDecl, internal::Matcher, Matcher) { const NamedDecl *FoundDecl = Node.getFoundDecl(); if (const UsingShadowDecl *UsingDecl = llvm::dyn_cast(FoundDecl)) return Matcher.matches(*UsingDecl, Finder, Builder); return false; } /// \brief Matches the Decl of a DeclStmt which has a single declaration. /// /// Given /// int a, b; /// int c; /// declarationStatement(hasSingleDecl(anything())) /// matches 'int c;' but not 'int a, b;'. AST_MATCHER_P(DeclStmt, hasSingleDecl, internal::Matcher, InnerMatcher) { if (Node.isSingleDecl()) { const Decl *FoundDecl = Node.getSingleDecl(); return InnerMatcher.matches(*FoundDecl, Finder, Builder); } return false; } /// \brief Matches a variable declaration that has an initializer expression /// that matches the given matcher. /// /// Example matches x (matcher = variable(hasInitializer(call()))) /// bool y() { return true; } /// bool x = y(); AST_MATCHER_P( VarDecl, hasInitializer, internal::Matcher, InnerMatcher) { const Expr *Initializer = Node.getAnyInitializer(); return (Initializer != NULL && InnerMatcher.matches(*Initializer, Finder, Builder)); } /// \brief Checks that a call expression or a constructor call expression has /// a specific number of arguments (including absent default arguments). /// /// Example matches f(0, 0) (matcher = call(argumentCountIs(2))) /// void f(int x, int y); /// f(0, 0); AST_POLYMORPHIC_MATCHER_P(argumentCountIs, unsigned, N) { TOOLING_COMPILE_ASSERT((llvm::is_base_of::value || llvm::is_base_of::value), instantiated_with_wrong_types); return Node.getNumArgs() == N; } /// \brief Matches the n'th argument of a call expression or a constructor /// call expression. /// /// Example matches y in x(y) /// (matcher = call(hasArgument(0, declarationReference()))) /// void x(int) { int y; x(y); } AST_POLYMORPHIC_MATCHER_P2( hasArgument, unsigned, N, internal::Matcher, InnerMatcher) { TOOLING_COMPILE_ASSERT((llvm::is_base_of::value || llvm::is_base_of::value), instantiated_with_wrong_types); return (N < Node.getNumArgs() && InnerMatcher.matches( *Node.getArg(N)->IgnoreParenImpCasts(), Finder, Builder)); } /// \brief Matches declaration statements that contain a specific number of /// declarations. /// /// Example: Given /// int a, b; /// int c; /// int d = 2, e; /// declCountIs(2) /// matches 'int a, b;' and 'int d = 2, e;', but not 'int c;'. AST_MATCHER_P(DeclStmt, declCountIs, unsigned, N) { return std::distance(Node.decl_begin(), Node.decl_end()) == N; } /// \brief Matches the n'th declaration of a declaration statement. /// /// Note that this does not work for global declarations because the AST /// breaks up multiple-declaration DeclStmt's into multiple single-declaration /// DeclStmt's. /// Example: Given non-global declarations /// int a, b = 0; /// int c; /// int d = 2, e; /// declarationStatement(containsDeclaration( /// 0, variable(hasInitializer(anything())))) /// matches only 'int d = 2, e;', and /// declarationStatement(containsDeclaration(1, variable())) /// matches 'int a, b = 0' as well as 'int d = 2, e;' /// but 'int c;' is not matched. AST_MATCHER_P2(DeclStmt, containsDeclaration, unsigned, N, internal::Matcher, InnerMatcher) { const unsigned NumDecls = std::distance(Node.decl_begin(), Node.decl_end()); if (N >= NumDecls) return false; DeclStmt::const_decl_iterator Iterator = Node.decl_begin(); std::advance(Iterator, N); return InnerMatcher.matches(**Iterator, Finder, Builder); } /// \brief Matches a constructor initializer. /// /// Given /// struct Foo { /// Foo() : foo_(1) { } /// int foo_; /// }; /// record(has(constructor(hasAnyConstructorInitializer(anything())))) /// record matches Foo, hasAnyConstructorInitializer matches foo_(1) AST_MATCHER_P(CXXConstructorDecl, hasAnyConstructorInitializer, internal::Matcher, InnerMatcher) { for (CXXConstructorDecl::init_const_iterator I = Node.init_begin(); I != Node.init_end(); ++I) { if (InnerMatcher.matches(**I, Finder, Builder)) { return true; } } return false; } /// \brief Matches the field declaration of a constructor initializer. /// /// Given /// struct Foo { /// Foo() : foo_(1) { } /// int foo_; /// }; /// record(has(constructor(hasAnyConstructorInitializer( /// forField(hasName("foo_")))))) /// matches Foo /// with forField matching foo_ AST_MATCHER_P(CXXCtorInitializer, forField, internal::Matcher, InnerMatcher) { const FieldDecl *NodeAsDecl = Node.getMember(); return (NodeAsDecl != NULL && InnerMatcher.matches(*NodeAsDecl, Finder, Builder)); } /// \brief Matches the initializer expression of a constructor initializer. /// /// Given /// struct Foo { /// Foo() : foo_(1) { } /// int foo_; /// }; /// record(has(constructor(hasAnyConstructorInitializer( /// withInitializer(integerLiteral(equals(1))))))) /// matches Foo /// with withInitializer matching (1) AST_MATCHER_P(CXXCtorInitializer, withInitializer, internal::Matcher, InnerMatcher) { const Expr* NodeAsExpr = Node.getInit(); return (NodeAsExpr != NULL && InnerMatcher.matches(*NodeAsExpr, Finder, Builder)); } /// \brief Matches a contructor initializer if it is explicitly written in /// code (as opposed to implicitly added by the compiler). /// /// Given /// struct Foo { /// Foo() { } /// Foo(int) : foo_("A") { } /// string foo_; /// }; /// constructor(hasAnyConstructorInitializer(isWritten())) /// will match Foo(int), but not Foo() AST_MATCHER(CXXCtorInitializer, isWritten) { return Node.isWritten(); } /// \brief Matches a constructor declaration that has been implicitly added /// by the compiler (eg. implicit default/copy constructors). AST_MATCHER(CXXConstructorDecl, isImplicit) { return Node.isImplicit(); } /// \brief Matches any argument of a call expression or a constructor call /// expression. /// /// Given /// void x(int, int, int) { int y; x(1, y, 42); } /// call(hasAnyArgument(declarationReference())) /// matches x(1, y, 42) /// with hasAnyArgument(...) /// matching y AST_POLYMORPHIC_MATCHER_P(hasAnyArgument, internal::Matcher, InnerMatcher) { TOOLING_COMPILE_ASSERT((llvm::is_base_of::value || llvm::is_base_of::value), instantiated_with_wrong_types); for (unsigned I = 0; I < Node.getNumArgs(); ++I) { if (InnerMatcher.matches(*Node.getArg(I)->IgnoreParenImpCasts(), Finder, Builder)) { return true; } } return false; } /// \brief Matches the n'th parameter of a function declaration. /// /// Given /// class X { void f(int x) {} }; /// method(hasParameter(0, hasType(variable()))) /// matches f(int x) {} /// with hasParameter(...) /// matching int x AST_MATCHER_P2(FunctionDecl, hasParameter, unsigned, N, internal::Matcher, InnerMatcher) { return (N < Node.getNumParams() && InnerMatcher.matches( *Node.getParamDecl(N), Finder, Builder)); } /// \brief Matches any parameter of a function declaration. /// /// Does not match the 'this' parameter of a method. /// /// Given /// class X { void f(int x, int y, int z) {} }; /// method(hasAnyParameter(hasName("y"))) /// matches f(int x, int y, int z) {} /// with hasAnyParameter(...) /// matching int y AST_MATCHER_P(FunctionDecl, hasAnyParameter, internal::Matcher, InnerMatcher) { for (unsigned I = 0; I < Node.getNumParams(); ++I) { if (InnerMatcher.matches(*Node.getParamDecl(I), Finder, Builder)) { return true; } } return false; } /// \brief Matches the return type of a function declaration. /// /// Given: /// class X { int f() { return 1; } }; /// method(returns(asString("int"))) /// matches int f() { return 1; } AST_MATCHER_P(FunctionDecl, returns, internal::Matcher, Matcher) { return Matcher.matches(Node.getResultType(), Finder, Builder); } /// \brief Matches extern "C" function declarations. /// /// Given: /// extern "C" void f() {} /// extern "C" { void g() {} } /// void h() {} /// function(isExternC()) /// matches the declaration of f and g, but not the declaration h AST_MATCHER(FunctionDecl, isExternC) { return Node.isExternC(); } /// \brief Matches the condition expression of an if statement, for loop, /// or conditional operator. /// /// Example matches true (matcher = hasCondition(boolLiteral(equals(true)))) /// if (true) {} AST_POLYMORPHIC_MATCHER_P(hasCondition, internal::Matcher, InnerMatcher) { TOOLING_COMPILE_ASSERT( (llvm::is_base_of::value) || (llvm::is_base_of::value) || (llvm::is_base_of::value) || (llvm::is_base_of::value) || (llvm::is_base_of::value), has_condition_requires_if_statement_conditional_operator_or_loop); const Expr *const Condition = Node.getCond(); return (Condition != NULL && InnerMatcher.matches(*Condition, Finder, Builder)); } /// \brief Matches the condition variable statement in an if statement. /// /// Given /// if (A* a = GetAPointer()) {} /// hasConditionVariableStatment(...) /// matches 'A* a = GetAPointer()'. AST_MATCHER_P(IfStmt, hasConditionVariableStatement, internal::Matcher, InnerMatcher) { const DeclStmt* const DeclarationStatement = Node.getConditionVariableDeclStmt(); return DeclarationStatement != NULL && InnerMatcher.matches(*DeclarationStatement, Finder, Builder); } /// \brief Matches the index expression of an array subscript expression. /// /// Given /// int i[5]; /// void f() { i[1] = 42; } /// arraySubscriptExpression(hasIndex(integerLiteral())) /// matches \c i[1] with the \c integerLiteral() matching \c 1 AST_MATCHER_P(ArraySubscriptExpr, hasIndex, internal::Matcher, matcher) { if (const Expr* Expression = Node.getIdx()) return matcher.matches(*Expression, Finder, Builder); return false; } /// \brief Matches the base expression of an array subscript expression. /// /// Given /// int i[5]; /// void f() { i[1] = 42; } /// arraySubscriptExpression(hasBase(implicitCast( /// hasSourceExpression(declarationReference())))) /// matches \c i[1] with the \c declarationReference() matching \c i AST_MATCHER_P(ArraySubscriptExpr, hasBase, internal::Matcher, matcher) { if (const Expr* Expression = Node.getBase()) return matcher.matches(*Expression, Finder, Builder); return false; } /// \brief Matches a 'for', 'while', or 'do while' statement that has /// a given body. /// /// Given /// for (;;) {} /// hasBody(compoundStatement()) /// matches 'for (;;) {}' /// with compoundStatement() /// matching '{}' AST_POLYMORPHIC_MATCHER_P(hasBody, internal::Matcher, InnerMatcher) { TOOLING_COMPILE_ASSERT( (llvm::is_base_of::value) || (llvm::is_base_of::value) || (llvm::is_base_of::value), has_body_requires_for_while_or_do_statement); const Stmt *const Statement = Node.getBody(); return (Statement != NULL && InnerMatcher.matches(*Statement, Finder, Builder)); } /// \brief Matches compound statements where at least one substatement matches /// a given matcher. /// /// Given /// { {}; 1+2; } /// hasAnySubstatement(compoundStatement()) /// matches '{ {}; 1+2; }' /// with compoundStatement() /// matching '{}' AST_MATCHER_P(CompoundStmt, hasAnySubstatement, internal::Matcher, InnerMatcher) { for (CompoundStmt::const_body_iterator It = Node.body_begin(); It != Node.body_end(); ++It) { if (InnerMatcher.matches(**It, Finder, Builder)) return true; } return false; } /// \brief Checks that a compound statement contains a specific number of /// child statements. /// /// Example: Given /// { for (;;) {} } /// compoundStatement(statementCountIs(0))) /// matches '{}' /// but does not match the outer compound statement. AST_MATCHER_P(CompoundStmt, statementCountIs, unsigned, N) { return Node.size() == N; } /// \brief Matches literals that are equal to the given value. /// /// Example matches true (matcher = boolLiteral(equals(true))) /// true /// /// Usable as: Matcher, Matcher, /// Matcher, Matcher template internal::PolymorphicMatcherWithParam1 equals(const ValueT &Value) { return internal::PolymorphicMatcherWithParam1< internal::ValueEqualsMatcher, ValueT>(Value); } /// \brief Matches the operator Name of operator expressions (binary or /// unary). /// /// Example matches a || b (matcher = binaryOperator(hasOperatorName("||"))) /// !(a || b) AST_POLYMORPHIC_MATCHER_P(hasOperatorName, std::string, Name) { TOOLING_COMPILE_ASSERT( (llvm::is_base_of::value) || (llvm::is_base_of::value), has_condition_requires_if_statement_or_conditional_operator); return Name == Node.getOpcodeStr(Node.getOpcode()); } /// \brief Matches the left hand side of binary operator expressions. /// /// Example matches a (matcher = binaryOperator(hasLHS())) /// a || b AST_MATCHER_P(BinaryOperator, hasLHS, internal::Matcher, InnerMatcher) { Expr *LeftHandSide = Node.getLHS(); return (LeftHandSide != NULL && InnerMatcher.matches(*LeftHandSide, Finder, Builder)); } /// \brief Matches the right hand side of binary operator expressions. /// /// Example matches b (matcher = binaryOperator(hasRHS())) /// a || b AST_MATCHER_P(BinaryOperator, hasRHS, internal::Matcher, InnerMatcher) { Expr *RightHandSide = Node.getRHS(); return (RightHandSide != NULL && InnerMatcher.matches(*RightHandSide, Finder, Builder)); } /// \brief Matches if either the left hand side or the right hand side of a /// binary operator matches. inline internal::Matcher hasEitherOperand( const internal::Matcher &InnerMatcher) { return anyOf(hasLHS(InnerMatcher), hasRHS(InnerMatcher)); } /// \brief Matches if the operand of a unary operator matches. /// /// Example matches true (matcher = hasOperand(boolLiteral(equals(true)))) /// !true AST_MATCHER_P(UnaryOperator, hasUnaryOperand, internal::Matcher, InnerMatcher) { const Expr * const Operand = Node.getSubExpr(); return (Operand != NULL && InnerMatcher.matches(*Operand, Finder, Builder)); } /// \brief Matches if the cast's source expression matches the given matcher. /// /// Example: matches "a string" (matcher = /// hasSourceExpression(constructorCall())) /// /// class URL { URL(string); }; /// URL url = "a string"; AST_MATCHER_P(CastExpr, hasSourceExpression, internal::Matcher, InnerMatcher) { const Expr* const SubExpression = Node.getSubExpr(); return (SubExpression != NULL && InnerMatcher.matches(*SubExpression, Finder, Builder)); } /// \brief Matches casts whose destination type matches a given matcher. /// /// (Note: Clang's AST refers to other conversions as "casts" too, and calls /// actual casts "explicit" casts.) AST_MATCHER_P(ExplicitCastExpr, hasDestinationType, internal::Matcher, InnerMatcher) { const QualType NodeType = Node.getTypeAsWritten(); return InnerMatcher.matches(NodeType, Finder, Builder); } /// \brief Matches implicit casts whose destination type matches a given /// matcher. /// /// FIXME: Unit test this matcher AST_MATCHER_P(ImplicitCastExpr, hasImplicitDestinationType, internal::Matcher, InnerMatcher) { return InnerMatcher.matches(Node.getType(), Finder, Builder); } /// \brief Matches the true branch expression of a conditional operator. /// /// Example matches a /// condition ? a : b AST_MATCHER_P(ConditionalOperator, hasTrueExpression, internal::Matcher, InnerMatcher) { Expr *Expression = Node.getTrueExpr(); return (Expression != NULL && InnerMatcher.matches(*Expression, Finder, Builder)); } /// \brief Matches the false branch expression of a conditional operator. /// /// Example matches b /// condition ? a : b AST_MATCHER_P(ConditionalOperator, hasFalseExpression, internal::Matcher, InnerMatcher) { Expr *Expression = Node.getFalseExpr(); return (Expression != NULL && InnerMatcher.matches(*Expression, Finder, Builder)); } /// \brief Matches if a declaration has a body attached. /// /// Example matches A, va, fa /// class A {}; /// class B; // Doesn't match, as it has no body. /// int va; /// extern int vb; // Doesn't match, as it doesn't define the variable. /// void fa() {} /// void fb(); // Doesn't match, as it has no body. /// /// Usable as: Matcher, Matcher, Matcher inline internal::PolymorphicMatcherWithParam0 isDefinition() { return internal::PolymorphicMatcherWithParam0< internal::IsDefinitionMatcher>(); } /// \brief Matches the class declaration that the given method declaration /// belongs to. /// /// FIXME: Generalize this for other kinds of declarations. /// FIXME: What other kind of declarations would we need to generalize /// this to? /// /// Example matches A() in the last line /// (matcher = constructorCall(hasDeclaration(method( /// ofClass(hasName("A")))))) /// class A { /// public: /// A(); /// }; /// A a = A(); AST_MATCHER_P(CXXMethodDecl, ofClass, internal::Matcher, InnerMatcher) { const CXXRecordDecl *Parent = Node.getParent(); return (Parent != NULL && InnerMatcher.matches(*Parent, Finder, Builder)); } /// \brief Matches member expressions that are called with '->' as opposed /// to '.'. /// /// Member calls on the implicit this pointer match as called with '->'. /// /// Given /// class Y { /// void x() { this->x(); x(); Y y; y.x(); a; this->b; Y::b; } /// int a; /// static int b; /// }; /// memberExpression(isArrow()) /// matches this->x, x, y.x, a, this->b inline internal::Matcher isArrow() { return makeMatcher(new internal::IsArrowMatcher()); } /// \brief Matches QualType nodes that are of integer type. /// /// Given /// void a(int); /// void b(long); /// void c(double); /// function(hasAnyParameter(hasType(isInteger()))) /// matches "a(int)", "b(long)", but not "c(double)". AST_MATCHER(QualType, isInteger) { return Node->isIntegerType(); } /// \brief Matches QualType nodes that are const-qualified, i.e., that /// include "top-level" const. /// /// Given /// void a(int); /// void b(int const); /// void c(const int); /// void d(const int*); /// void e(int const) {}; /// function(hasAnyParameter(hasType(isConstQualified()))) /// matches "void b(int const)", "void c(const int)" and /// "void e(int const) {}". It does not match d as there /// is no top-level const on the parameter type "const int *". inline internal::Matcher isConstQualified() { return makeMatcher(new internal::IsConstQualifiedMatcher()); } /// \brief Matches a member expression where the member is matched by a /// given matcher. /// /// Given /// struct { int first, second; } first, second; /// int i(second.first); /// int j(first.second); /// memberExpression(member(hasName("first"))) /// matches second.first /// but not first.second (because the member name there is "second"). AST_MATCHER_P(MemberExpr, member, internal::Matcher, InnerMatcher) { return InnerMatcher.matches(*Node.getMemberDecl(), Finder, Builder); } /// \brief Matches a member expression where the object expression is /// matched by a given matcher. /// /// Given /// struct X { int m; }; /// void f(X x) { x.m; m; } /// memberExpression(hasObjectExpression(hasType(record(hasName("X"))))))) /// matches "x.m" and "m" /// with hasObjectExpression(...) /// matching "x" and the implicit object expression of "m" which has type X*. AST_MATCHER_P(MemberExpr, hasObjectExpression, internal::Matcher, InnerMatcher) { return InnerMatcher.matches(*Node.getBase(), Finder, Builder); } /// \brief Matches any using shadow declaration. /// /// Given /// namespace X { void b(); } /// using X::b; /// usingDecl(hasAnyUsingShadowDecl(hasName("b")))) /// matches \code using X::b \endcode AST_MATCHER_P(UsingDecl, hasAnyUsingShadowDecl, internal::Matcher, Matcher) { for (UsingDecl::shadow_iterator II = Node.shadow_begin(); II != Node.shadow_end(); ++II) { if (Matcher.matches(**II, Finder, Builder)) return true; } return false; } /// \brief Matches a using shadow declaration where the target declaration is /// matched by the given matcher. /// /// Given /// namespace X { int a; void b(); } /// using X::a; /// using X::b; /// usingDecl(hasAnyUsingShadowDecl(hasTargetDecl(function()))) /// matches \code using X::b \endcode /// but not \code using X::a \endcode AST_MATCHER_P(UsingShadowDecl, hasTargetDecl, internal::Matcher, Matcher) { return Matcher.matches(*Node.getTargetDecl(), Finder, Builder); } /// \brief Matches template instantiations of function, class, or static /// member variable template instantiations. /// /// Given /// template class X {}; class A {}; X x; /// or /// template class X {}; class A {}; template class X ; /// record(hasName("::X"), isTemplateInstantiation()) /// matches the template instantiation of X . /// /// But given /// template class X {}; class A {}; /// template <> class X {}; X x; /// record(hasName("::X"), isTemplateInstantiation()) /// does not match, as X is an explicit template specialization. /// /// Usable as: Matcher, Matcher, Matcher inline internal::PolymorphicMatcherWithParam0< internal::IsTemplateInstantiationMatcher> isTemplateInstantiation() { return internal::PolymorphicMatcherWithParam0< internal::IsTemplateInstantiationMatcher>(); } } // end namespace ast_matchers } // end namespace clang #endif // LLVM_CLANG_AST_MATCHERS_AST_MATCHERS_H