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ASTMatchFinder.h
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ASTMatchers.h
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GtestMatchers.h
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Editing: ASTMatchersInternal.h
//===- ASTMatchersInternal.h - Structural query framework -------*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // Implements the base layer of the matcher framework. // // Matchers are methods that return a Matcher<T> which provides a method // Matches(...) which is a predicate on an AST node. The Matches method's // parameters define the context of the match, which allows matchers to recurse // or store the current node as bound to a specific string, so that it can be // retrieved later. // // In general, matchers have two parts: // 1. A function Matcher<T> MatcherName(<arguments>) which returns a Matcher<T> // based on the arguments and optionally on template type deduction based // on the arguments. Matcher<T>s form an implicit reverse hierarchy // to clang's AST class hierarchy, meaning that you can use a Matcher<Base> // everywhere a Matcher<Derived> is required. // 2. An implementation of a class derived from MatcherInterface<T>. // // The matcher functions are defined in ASTMatchers.h. To make it possible // to implement both the matcher function and the implementation of the matcher // interface in one place, ASTMatcherMacros.h defines macros that allow // implementing a matcher in a single place. // // This file contains the base classes needed to construct the actual matchers. // //===----------------------------------------------------------------------===// #ifndef LLVM_CLANG_ASTMATCHERS_ASTMATCHERSINTERNAL_H #define LLVM_CLANG_ASTMATCHERS_ASTMATCHERSINTERNAL_H #include "clang/AST/ASTTypeTraits.h" #include "clang/AST/Decl.h" #include "clang/AST/DeclCXX.h" #include "clang/AST/DeclFriend.h" #include "clang/AST/DeclTemplate.h" #include "clang/AST/Expr.h" #include "clang/AST/ExprCXX.h" #include "clang/AST/ExprObjC.h" #include "clang/AST/NestedNameSpecifier.h" #include "clang/AST/Stmt.h" #include "clang/AST/TemplateName.h" #include "clang/AST/Type.h" #include "clang/AST/TypeLoc.h" #include "clang/Basic/LLVM.h" #include "clang/Basic/OperatorKinds.h" #include "llvm/ADT/APFloat.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/IntrusiveRefCntPtr.h" #include "llvm/ADT/None.h" #include "llvm/ADT/Optional.h" #include "llvm/ADT/STLExtras.h" #include "llvm/ADT/SmallVector.h" #include "llvm/ADT/StringRef.h" #include "llvm/ADT/iterator.h" #include "llvm/Support/Casting.h" #include "llvm/Support/ManagedStatic.h" #include "llvm/Support/Regex.h" #include <algorithm> #include <cassert> #include <cstddef> #include <cstdint> #include <map> #include <memory> #include <string> #include <tuple> #include <type_traits> #include <utility> #include <vector> namespace clang { class ASTContext; namespace ast_matchers { class BoundNodes; namespace internal { /// Variadic function object. /// /// Most of the functions below that use VariadicFunction could be implemented /// using plain C++11 variadic functions, but the function object allows us to /// capture it on the dynamic matcher registry. template <typename ResultT, typename ArgT, ResultT (*Func)(ArrayRef<const ArgT *>)> struct VariadicFunction { ResultT operator()() const { return Func(None); } template <typename... ArgsT> ResultT operator()(const ArgT &Arg1, const ArgsT &... Args) const { return Execute(Arg1, static_cast<const ArgT &>(Args)...); } // We also allow calls with an already created array, in case the caller // already had it. ResultT operator()(ArrayRef<ArgT> Args) const { SmallVector<const ArgT*, 8> InnerArgs; for (const ArgT &Arg : Args) InnerArgs.push_back(&Arg); return Func(InnerArgs); } private: // Trampoline function to allow for implicit conversions to take place // before we make the array. template <typename... ArgsT> ResultT Execute(const ArgsT &... Args) const { const ArgT *const ArgsArray[] = {&Args...}; return Func(ArrayRef<const ArgT *>(ArgsArray, sizeof...(ArgsT))); } }; /// Unifies obtaining the underlying type of a regular node through /// `getType` and a TypedefNameDecl node through `getUnderlyingType`. inline QualType getUnderlyingType(const Expr &Node) { return Node.getType(); } inline QualType getUnderlyingType(const ValueDecl &Node) { return Node.getType(); } inline QualType getUnderlyingType(const TypedefNameDecl &Node) { return Node.getUnderlyingType(); } inline QualType getUnderlyingType(const FriendDecl &Node) { if (const TypeSourceInfo *TSI = Node.getFriendType()) return TSI->getType(); return QualType(); } inline QualType getUnderlyingType(const CXXBaseSpecifier &Node) { return Node.getType(); } /// Unifies obtaining the FunctionProtoType pointer from both /// FunctionProtoType and FunctionDecl nodes.. inline const FunctionProtoType * getFunctionProtoType(const FunctionProtoType &Node) { return &Node; } inline const FunctionProtoType *getFunctionProtoType(const FunctionDecl &Node) { return Node.getType()->getAs<FunctionProtoType>(); } /// Unifies obtaining the access specifier from Decl and CXXBaseSpecifier nodes. inline clang::AccessSpecifier getAccessSpecifier(const Decl &Node) { return Node.getAccess(); } inline clang::AccessSpecifier getAccessSpecifier(const CXXBaseSpecifier &Node) { return Node.getAccessSpecifier(); } /// Internal version of BoundNodes. Holds all the bound nodes. class BoundNodesMap { public: /// Adds \c Node to the map with key \c ID. /// /// The node's base type should be in NodeBaseType or it will be unaccessible. void addNode(StringRef ID, const DynTypedNode &DynNode) { NodeMap[std::string(ID)] = DynNode; } /// Returns the AST node bound to \c ID. /// /// Returns NULL if there was no node bound to \c ID or if there is a node but /// it cannot be converted to the specified type. template <typename T> const T *getNodeAs(StringRef ID) const { IDToNodeMap::const_iterator It = NodeMap.find(ID); if (It == NodeMap.end()) { return nullptr; } return It->second.get<T>(); } DynTypedNode getNode(StringRef ID) const { IDToNodeMap::const_iterator It = NodeMap.find(ID); if (It == NodeMap.end()) { return DynTypedNode(); } return It->second; } /// Imposes an order on BoundNodesMaps. bool operator<(const BoundNodesMap &Other) const { return NodeMap < Other.NodeMap; } /// A map from IDs to the bound nodes. /// /// Note that we're using std::map here, as for memoization: /// - we need a comparison operator /// - we need an assignment operator using IDToNodeMap = std::map<std::string, DynTypedNode, std::less<>>; const IDToNodeMap &getMap() const { return NodeMap; } /// Returns \c true if this \c BoundNodesMap can be compared, i.e. all /// stored nodes have memoization data. bool isComparable() const { for (const auto &IDAndNode : NodeMap) { if (!IDAndNode.second.getMemoizationData()) return false; } return true; } private: IDToNodeMap NodeMap; }; /// Creates BoundNodesTree objects. /// /// The tree builder is used during the matching process to insert the bound /// nodes from the Id matcher. class BoundNodesTreeBuilder { public: /// A visitor interface to visit all BoundNodes results for a /// BoundNodesTree. class Visitor { public: virtual ~Visitor() = default; /// Called multiple times during a single call to VisitMatches(...). /// /// 'BoundNodesView' contains the bound nodes for a single match. virtual void visitMatch(const BoundNodes& BoundNodesView) = 0; }; /// Add a binding from an id to a node. void setBinding(StringRef Id, const DynTypedNode &DynNode) { if (Bindings.empty()) Bindings.emplace_back(); for (BoundNodesMap &Binding : Bindings) Binding.addNode(Id, DynNode); } /// Adds a branch in the tree. void addMatch(const BoundNodesTreeBuilder &Bindings); /// Visits all matches that this BoundNodesTree represents. /// /// The ownership of 'ResultVisitor' remains at the caller. void visitMatches(Visitor* ResultVisitor); template <typename ExcludePredicate> bool removeBindings(const ExcludePredicate &Predicate) { Bindings.erase(std::remove_if(Bindings.begin(), Bindings.end(), Predicate), Bindings.end()); return !Bindings.empty(); } /// Imposes an order on BoundNodesTreeBuilders. bool operator<(const BoundNodesTreeBuilder &Other) const { return Bindings < Other.Bindings; } /// Returns \c true if this \c BoundNodesTreeBuilder can be compared, /// i.e. all stored node maps have memoization data. bool isComparable() const { for (const BoundNodesMap &NodesMap : Bindings) { if (!NodesMap.isComparable()) return false; } return true; } private: SmallVector<BoundNodesMap, 1> Bindings; }; class ASTMatchFinder; /// Generic interface for all matchers. /// /// Used by the implementation of Matcher<T> and DynTypedMatcher. /// In general, implement MatcherInterface<T> or SingleNodeMatcherInterface<T> /// instead. class DynMatcherInterface : public llvm::ThreadSafeRefCountedBase<DynMatcherInterface> { public: virtual ~DynMatcherInterface() = default; /// Returns true if \p DynNode can be matched. /// /// May bind \p DynNode to an ID via \p Builder, or recurse into /// the AST via \p Finder. virtual bool dynMatches(const DynTypedNode &DynNode, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const = 0; virtual llvm::Optional<clang::TraversalKind> TraversalKind() const { return llvm::None; } }; /// Generic interface for matchers on an AST node of type T. /// /// Implement this if your matcher may need to inspect the children or /// descendants of the node or bind matched nodes to names. If you are /// writing a simple matcher that only inspects properties of the /// current node and doesn't care about its children or descendants, /// implement SingleNodeMatcherInterface instead. template <typename T> class MatcherInterface : public DynMatcherInterface { public: /// Returns true if 'Node' can be matched. /// /// May bind 'Node' to an ID via 'Builder', or recurse into /// the AST via 'Finder'. virtual bool matches(const T &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const = 0; bool dynMatches(const DynTypedNode &DynNode, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const override { return matches(DynNode.getUnchecked<T>(), Finder, Builder); } }; /// Interface for matchers that only evaluate properties on a single /// node. template <typename T> class SingleNodeMatcherInterface : public MatcherInterface<T> { public: /// Returns true if the matcher matches the provided node. /// /// A subclass must implement this instead of Matches(). virtual bool matchesNode(const T &Node) const = 0; private: /// Implements MatcherInterface::Matches. bool matches(const T &Node, ASTMatchFinder * /* Finder */, BoundNodesTreeBuilder * /* Builder */) const override { return matchesNode(Node); } }; template <typename> class Matcher; /// Matcher that works on a \c DynTypedNode. /// /// It is constructed from a \c Matcher<T> object and redirects most calls to /// underlying matcher. /// It checks whether the \c DynTypedNode is convertible into the type of the /// underlying matcher and then do the actual match on the actual node, or /// return false if it is not convertible. class DynTypedMatcher { public: /// Takes ownership of the provided implementation pointer. template <typename T> DynTypedMatcher(MatcherInterface<T> *Implementation) : SupportedKind(ASTNodeKind::getFromNodeKind<T>()), RestrictKind(SupportedKind), Implementation(Implementation) {} /// Construct from a variadic function. enum VariadicOperator { /// Matches nodes for which all provided matchers match. VO_AllOf, /// Matches nodes for which at least one of the provided matchers /// matches. VO_AnyOf, /// Matches nodes for which at least one of the provided matchers /// matches, but doesn't stop at the first match. VO_EachOf, /// Matches any node but executes all inner matchers to find result /// bindings. VO_Optionally, /// Matches nodes that do not match the provided matcher. /// /// Uses the variadic matcher interface, but fails if /// InnerMatchers.size() != 1. VO_UnaryNot }; static DynTypedMatcher constructVariadic(VariadicOperator Op, ASTNodeKind SupportedKind, std::vector<DynTypedMatcher> InnerMatchers); static DynTypedMatcher constructRestrictedWrapper(const DynTypedMatcher &InnerMatcher, ASTNodeKind RestrictKind); /// Get a "true" matcher for \p NodeKind. /// /// It only checks that the node is of the right kind. static DynTypedMatcher trueMatcher(ASTNodeKind NodeKind); void setAllowBind(bool AB) { AllowBind = AB; } /// Check whether this matcher could ever match a node of kind \p Kind. /// \return \c false if this matcher will never match such a node. Otherwise, /// return \c true. bool canMatchNodesOfKind(ASTNodeKind Kind) const; /// Return a matcher that points to the same implementation, but /// restricts the node types for \p Kind. DynTypedMatcher dynCastTo(const ASTNodeKind Kind) const; /// Return a matcher that that points to the same implementation, but sets the /// traversal kind. /// /// If the traversal kind is already set, then \c TK overrides it. DynTypedMatcher withTraversalKind(TraversalKind TK); /// Returns true if the matcher matches the given \c DynNode. bool matches(const DynTypedNode &DynNode, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const; /// Same as matches(), but skips the kind check. /// /// It is faster, but the caller must ensure the node is valid for the /// kind of this matcher. bool matchesNoKindCheck(const DynTypedNode &DynNode, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const; /// Bind the specified \p ID to the matcher. /// \return A new matcher with the \p ID bound to it if this matcher supports /// binding. Otherwise, returns an empty \c Optional<>. llvm::Optional<DynTypedMatcher> tryBind(StringRef ID) const; /// Returns a unique \p ID for the matcher. /// /// Casting a Matcher<T> to Matcher<U> creates a matcher that has the /// same \c Implementation pointer, but different \c RestrictKind. We need to /// include both in the ID to make it unique. /// /// \c MatcherIDType supports operator< and provides strict weak ordering. using MatcherIDType = std::pair<ASTNodeKind, uint64_t>; MatcherIDType getID() const { /// FIXME: Document the requirements this imposes on matcher /// implementations (no new() implementation_ during a Matches()). return std::make_pair(RestrictKind, reinterpret_cast<uint64_t>(Implementation.get())); } /// Returns the type this matcher works on. /// /// \c matches() will always return false unless the node passed is of this /// or a derived type. ASTNodeKind getSupportedKind() const { return SupportedKind; } /// Returns \c true if the passed \c DynTypedMatcher can be converted /// to a \c Matcher<T>. /// /// This method verifies that the underlying matcher in \c Other can process /// nodes of types T. template <typename T> bool canConvertTo() const { return canConvertTo(ASTNodeKind::getFromNodeKind<T>()); } bool canConvertTo(ASTNodeKind To) const; /// Construct a \c Matcher<T> interface around the dynamic matcher. /// /// This method asserts that \c canConvertTo() is \c true. Callers /// should call \c canConvertTo() first to make sure that \c this is /// compatible with T. template <typename T> Matcher<T> convertTo() const { assert(canConvertTo<T>()); return unconditionalConvertTo<T>(); } /// Same as \c convertTo(), but does not check that the underlying /// matcher can handle a value of T. /// /// If it is not compatible, then this matcher will never match anything. template <typename T> Matcher<T> unconditionalConvertTo() const; /// Returns the \c TraversalKind respected by calls to `match()`, if any. /// /// Most matchers will not have a traversal kind set, instead relying on the /// surrounding context. For those, \c llvm::None is returned. llvm::Optional<clang::TraversalKind> getTraversalKind() const { return Implementation->TraversalKind(); } private: DynTypedMatcher(ASTNodeKind SupportedKind, ASTNodeKind RestrictKind, IntrusiveRefCntPtr<DynMatcherInterface> Implementation) : SupportedKind(SupportedKind), RestrictKind(RestrictKind), Implementation(std::move(Implementation)) {} bool AllowBind = false; ASTNodeKind SupportedKind; /// A potentially stricter node kind. /// /// It allows to perform implicit and dynamic cast of matchers without /// needing to change \c Implementation. ASTNodeKind RestrictKind; IntrusiveRefCntPtr<DynMatcherInterface> Implementation; }; /// Wrapper of a MatcherInterface<T> *that allows copying. /// /// A Matcher<Base> can be used anywhere a Matcher<Derived> is /// required. This establishes an is-a relationship which is reverse /// to the AST hierarchy. In other words, Matcher<T> is contravariant /// with respect to T. The relationship is built via a type conversion /// operator rather than a type hierarchy to be able to templatize the /// type hierarchy instead of spelling it out. template <typename T> class Matcher { public: /// Takes ownership of the provided implementation pointer. explicit Matcher(MatcherInterface<T> *Implementation) : Implementation(Implementation) {} /// Implicitly converts \c Other to a Matcher<T>. /// /// Requires \c T to be derived from \c From. template <typename From> Matcher(const Matcher<From> &Other, std::enable_if_t<std::is_base_of<From, T>::value && !std::is_same<From, T>::value> * = nullptr) : Implementation(restrictMatcher(Other.Implementation)) { assert(Implementation.getSupportedKind().isSame( ASTNodeKind::getFromNodeKind<T>())); } /// Implicitly converts \c Matcher<Type> to \c Matcher<QualType>. /// /// The resulting matcher is not strict, i.e. ignores qualifiers. template <typename TypeT> Matcher(const Matcher<TypeT> &Other, std::enable_if_t<std::is_same<T, QualType>::value && std::is_same<TypeT, Type>::value> * = nullptr) : Implementation(new TypeToQualType<TypeT>(Other)) {} /// Convert \c this into a \c Matcher<T> by applying dyn_cast<> to the /// argument. /// \c To must be a base class of \c T. template <typename To> Matcher<To> dynCastTo() const { static_assert(std::is_base_of<To, T>::value, "Invalid dynCast call."); return Matcher<To>(Implementation); } /// Forwards the call to the underlying MatcherInterface<T> pointer. bool matches(const T &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const { return Implementation.matches(DynTypedNode::create(Node), Finder, Builder); } /// Returns an ID that uniquely identifies the matcher. DynTypedMatcher::MatcherIDType getID() const { return Implementation.getID(); } /// Extract the dynamic matcher. /// /// The returned matcher keeps the same restrictions as \c this and remembers /// that it is meant to support nodes of type \c T. operator DynTypedMatcher() const { return Implementation; } /// Allows the conversion of a \c Matcher<Type> to a \c /// Matcher<QualType>. /// /// Depending on the constructor argument, the matcher is either strict, i.e. /// does only matches in the absence of qualifiers, or not, i.e. simply /// ignores any qualifiers. template <typename TypeT> class TypeToQualType : public MatcherInterface<QualType> { const DynTypedMatcher InnerMatcher; public: TypeToQualType(const Matcher<TypeT> &InnerMatcher) : InnerMatcher(InnerMatcher) {} bool matches(const QualType &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const override { if (Node.isNull()) return false; return this->InnerMatcher.matches(DynTypedNode::create(*Node), Finder, Builder); } }; private: // For Matcher<T> <=> Matcher<U> conversions. template <typename U> friend class Matcher; // For DynTypedMatcher::unconditionalConvertTo<T>. friend class DynTypedMatcher; static DynTypedMatcher restrictMatcher(const DynTypedMatcher &Other) { return Other.dynCastTo(ASTNodeKind::getFromNodeKind<T>()); } explicit Matcher(const DynTypedMatcher &Implementation) : Implementation(restrictMatcher(Implementation)) { assert(this->Implementation.getSupportedKind().isSame( ASTNodeKind::getFromNodeKind<T>())); } DynTypedMatcher Implementation; }; // class Matcher /// A convenient helper for creating a Matcher<T> without specifying /// the template type argument. template <typename T> inline Matcher<T> makeMatcher(MatcherInterface<T> *Implementation) { return Matcher<T>(Implementation); } /// Specialization of the conversion functions for QualType. /// /// This specialization provides the Matcher<Type>->Matcher<QualType> /// conversion that the static API does. template <> inline Matcher<QualType> DynTypedMatcher::convertTo<QualType>() const { assert(canConvertTo<QualType>()); const ASTNodeKind SourceKind = getSupportedKind(); if (SourceKind.isSame(ASTNodeKind::getFromNodeKind<Type>())) { // We support implicit conversion from Matcher<Type> to Matcher<QualType> return unconditionalConvertTo<Type>(); } return unconditionalConvertTo<QualType>(); } /// Finds the first node in a range that matches the given matcher. template <typename MatcherT, typename IteratorT> bool matchesFirstInRange(const MatcherT &Matcher, IteratorT Start, IteratorT End, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) { for (IteratorT I = Start; I != End; ++I) { BoundNodesTreeBuilder Result(*Builder); if (Matcher.matches(*I, Finder, &Result)) { *Builder = std::move(Result); return true; } } return false; } /// Finds the first node in a pointer range that matches the given /// matcher. template <typename MatcherT, typename IteratorT> bool matchesFirstInPointerRange(const MatcherT &Matcher, IteratorT Start, IteratorT End, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) { for (IteratorT I = Start; I != End; ++I) { BoundNodesTreeBuilder Result(*Builder); if (Matcher.matches(**I, Finder, &Result)) { *Builder = std::move(Result); return true; } } return false; } // Metafunction to determine if type T has a member called getDecl. template <typename Ty> class has_getDecl { using yes = char[1]; using no = char[2]; template <typename Inner> static yes& test(Inner *I, decltype(I->getDecl()) * = nullptr); template <typename> static no& test(...); public: static const bool value = sizeof(test<Ty>(nullptr)) == sizeof(yes); }; /// Matches overloaded operators with a specific name. /// /// The type argument ArgT is not used by this matcher but is used by /// PolymorphicMatcherWithParam1 and should be StringRef. template <typename T, typename ArgT> class HasOverloadedOperatorNameMatcher : public SingleNodeMatcherInterface<T> { static_assert(std::is_same<T, CXXOperatorCallExpr>::value || std::is_base_of<FunctionDecl, T>::value, "unsupported class for matcher"); static_assert(std::is_same<ArgT, std::vector<std::string>>::value, "argument type must be std::vector<std::string>"); public: explicit HasOverloadedOperatorNameMatcher(std::vector<std::string> Names) : SingleNodeMatcherInterface<T>(), Names(std::move(Names)) {} bool matchesNode(const T &Node) const override { return matchesSpecialized(Node); } private: /// CXXOperatorCallExpr exist only for calls to overloaded operators /// so this function returns true if the call is to an operator of the given /// name. bool matchesSpecialized(const CXXOperatorCallExpr &Node) const { return llvm::is_contained(Names, getOperatorSpelling(Node.getOperator())); } /// Returns true only if CXXMethodDecl represents an overloaded /// operator and has the given operator name. bool matchesSpecialized(const FunctionDecl &Node) const { return Node.isOverloadedOperator() && llvm::is_contained( Names, getOperatorSpelling(Node.getOverloadedOperator())); } const std::vector<std::string> Names; }; /// Matches named declarations with a specific name. /// /// See \c hasName() and \c hasAnyName() in ASTMatchers.h for details. class HasNameMatcher : public SingleNodeMatcherInterface<NamedDecl> { public: explicit HasNameMatcher(std::vector<std::string> Names); bool matchesNode(const NamedDecl &Node) const override; private: /// Unqualified match routine. /// /// It is much faster than the full match, but it only works for unqualified /// matches. bool matchesNodeUnqualified(const NamedDecl &Node) const; /// Full match routine /// /// Fast implementation for the simple case of a named declaration at /// namespace or RecordDecl scope. /// It is slower than matchesNodeUnqualified, but faster than /// matchesNodeFullSlow. bool matchesNodeFullFast(const NamedDecl &Node) const; /// Full match routine /// /// It generates the fully qualified name of the declaration (which is /// expensive) before trying to match. /// It is slower but simple and works on all cases. bool matchesNodeFullSlow(const NamedDecl &Node) const; const bool UseUnqualifiedMatch; const std::vector<std::string> Names; }; /// Trampoline function to use VariadicFunction<> to construct a /// HasNameMatcher. Matcher<NamedDecl> hasAnyNameFunc(ArrayRef<const StringRef *> NameRefs); /// Trampoline function to use VariadicFunction<> to construct a /// hasAnySelector matcher. Matcher<ObjCMessageExpr> hasAnySelectorFunc( ArrayRef<const StringRef *> NameRefs); /// Matches declarations for QualType and CallExpr. /// /// Type argument DeclMatcherT is required by PolymorphicMatcherWithParam1 but /// not actually used. template <typename T, typename DeclMatcherT> class HasDeclarationMatcher : public MatcherInterface<T> { static_assert(std::is_same<DeclMatcherT, Matcher<Decl>>::value, "instantiated with wrong types"); const DynTypedMatcher InnerMatcher; public: explicit HasDeclarationMatcher(const Matcher<Decl> &InnerMatcher) : InnerMatcher(InnerMatcher) {} bool matches(const T &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const override { return matchesSpecialized(Node, Finder, Builder); } private: /// Forwards to matching on the underlying type of the QualType. bool matchesSpecialized(const QualType &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const { if (Node.isNull()) return false; return matchesSpecialized(*Node, Finder, Builder); } /// Finds the best declaration for a type and returns whether the inner /// matcher matches on it. bool matchesSpecialized(const Type &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const { // DeducedType does not have declarations of its own, so // match the deduced type instead. const Type *EffectiveType = &Node; if (const auto *S = dyn_cast<DeducedType>(&Node)) { EffectiveType = S->getDeducedType().getTypePtrOrNull(); if (!EffectiveType) return false; } // First, for any types that have a declaration, extract the declaration and // match on it. if (const auto *S = dyn_cast<TagType>(EffectiveType)) { return matchesDecl(S->getDecl(), Finder, Builder); } if (const auto *S = dyn_cast<InjectedClassNameType>(EffectiveType)) { return matchesDecl(S->getDecl(), Finder, Builder); } if (const auto *S = dyn_cast<TemplateTypeParmType>(EffectiveType)) { return matchesDecl(S->getDecl(), Finder, Builder); } if (const auto *S = dyn_cast<TypedefType>(EffectiveType)) { return matchesDecl(S->getDecl(), Finder, Builder); } if (const auto *S = dyn_cast<UnresolvedUsingType>(EffectiveType)) { return matchesDecl(S->getDecl(), Finder, Builder); } if (const auto *S = dyn_cast<ObjCObjectType>(EffectiveType)) { return matchesDecl(S->getInterface(), Finder, Builder); } // A SubstTemplateTypeParmType exists solely to mark a type substitution // on the instantiated template. As users usually want to match the // template parameter on the uninitialized template, we can always desugar // one level without loss of expressivness. // For example, given: // template<typename T> struct X { T t; } class A {}; X<A> a; // The following matcher will match, which otherwise would not: // fieldDecl(hasType(pointerType())). if (const auto *S = dyn_cast<SubstTemplateTypeParmType>(EffectiveType)) { return matchesSpecialized(S->getReplacementType(), Finder, Builder); } // For template specialization types, we want to match the template // declaration, as long as the type is still dependent, and otherwise the // declaration of the instantiated tag type. if (const auto *S = dyn_cast<TemplateSpecializationType>(EffectiveType)) { if (!S->isTypeAlias() && S->isSugared()) { // If the template is non-dependent, we want to match the instantiated // tag type. // For example, given: // template<typename T> struct X {}; X<int> a; // The following matcher will match, which otherwise would not: // templateSpecializationType(hasDeclaration(cxxRecordDecl())). return matchesSpecialized(*S->desugar(), Finder, Builder); } // If the template is dependent or an alias, match the template // declaration. return matchesDecl(S->getTemplateName().getAsTemplateDecl(), Finder, Builder); } // FIXME: We desugar elaborated types. This makes the assumption that users // do never want to match on whether a type is elaborated - there are // arguments for both sides; for now, continue desugaring. if (const auto *S = dyn_cast<ElaboratedType>(EffectiveType)) { return matchesSpecialized(S->desugar(), Finder, Builder); } return false; } /// Extracts the Decl the DeclRefExpr references and returns whether /// the inner matcher matches on it. bool matchesSpecialized(const DeclRefExpr &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const { return matchesDecl(Node.getDecl(), Finder, Builder); } /// Extracts the Decl of the callee of a CallExpr and returns whether /// the inner matcher matches on it. bool matchesSpecialized(const CallExpr &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const { return matchesDecl(Node.getCalleeDecl(), Finder, Builder); } /// Extracts the Decl of the constructor call and returns whether the /// inner matcher matches on it. bool matchesSpecialized(const CXXConstructExpr &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const { return matchesDecl(Node.getConstructor(), Finder, Builder); } bool matchesSpecialized(const ObjCIvarRefExpr &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const { return matchesDecl(Node.getDecl(), Finder, Builder); } /// Extracts the operator new of the new call and returns whether the /// inner matcher matches on it. bool matchesSpecialized(const CXXNewExpr &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const { return matchesDecl(Node.getOperatorNew(), Finder, Builder); } /// Extracts the \c ValueDecl a \c MemberExpr refers to and returns /// whether the inner matcher matches on it. bool matchesSpecialized(const MemberExpr &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const { return matchesDecl(Node.getMemberDecl(), Finder, Builder); } /// Extracts the \c LabelDecl a \c AddrLabelExpr refers to and returns /// whether the inner matcher matches on it. bool matchesSpecialized(const AddrLabelExpr &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const { return matchesDecl(Node.getLabel(), Finder, Builder); } /// Extracts the declaration of a LabelStmt and returns whether the /// inner matcher matches on it. bool matchesSpecialized(const LabelStmt &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const { return matchesDecl(Node.getDecl(), Finder, Builder); } /// Returns whether the inner matcher \c Node. Returns false if \c Node /// is \c NULL. bool matchesDecl(const Decl *Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const { return Node != nullptr && this->InnerMatcher.matches( DynTypedNode::create(*Node), Finder, Builder); } }; /// IsBaseType<T>::value is true if T is a "base" type in the AST /// node class hierarchies. template <typename T> struct IsBaseType { static const bool value = std::is_same<T, Decl>::value || std::is_same<T, Stmt>::value || std::is_same<T, QualType>::value || std::is_same<T, Type>::value || std::is_same<T, TypeLoc>::value || std::is_same<T, NestedNameSpecifier>::value || std::is_same<T, NestedNameSpecifierLoc>::value || std::is_same<T, CXXCtorInitializer>::value; }; template <typename T> const bool IsBaseType<T>::value; /// Interface that allows matchers to traverse the AST. /// FIXME: Find a better name. /// /// This provides three entry methods for each base node type in the AST: /// - \c matchesChildOf: /// Matches a matcher on every child node of the given node. Returns true /// if at least one child node could be matched. /// - \c matchesDescendantOf: /// Matches a matcher on all descendant nodes of the given node. Returns true /// if at least one descendant matched. /// - \c matchesAncestorOf: /// Matches a matcher on all ancestors of the given node. Returns true if /// at least one ancestor matched. /// /// FIXME: Currently we only allow Stmt and Decl nodes to start a traversal. /// In the future, we want to implement this for all nodes for which it makes /// sense. In the case of matchesAncestorOf, we'll want to implement it for /// all nodes, as all nodes have ancestors. class ASTMatchFinder { public: /// Defines how bindings are processed on recursive matches. enum BindKind { /// Stop at the first match and only bind the first match. BK_First, /// Create results for all combinations of bindings that match. BK_All }; /// Defines which ancestors are considered for a match. enum AncestorMatchMode { /// All ancestors. AMM_All, /// Direct parent only. AMM_ParentOnly }; virtual ~ASTMatchFinder() = default; /// Returns true if the given C++ class is directly or indirectly derived /// from a base type matching \c base. /// /// A class is not considered to be derived from itself. virtual bool classIsDerivedFrom(const CXXRecordDecl *Declaration, const Matcher<NamedDecl> &Base, BoundNodesTreeBuilder *Builder, bool Directly) = 0; /// Returns true if the given Objective-C class is directly or indirectly /// derived from a base class matching \c base. /// /// A class is not considered to be derived from itself. virtual bool objcClassIsDerivedFrom(const ObjCInterfaceDecl *Declaration, const Matcher<NamedDecl> &Base, BoundNodesTreeBuilder *Builder, bool Directly) = 0; template <typename T> bool matchesChildOf(const T &Node, const DynTypedMatcher &Matcher, BoundNodesTreeBuilder *Builder, TraversalKind Traverse, BindKind Bind) { static_assert(std::is_base_of<Decl, T>::value || std::is_base_of<Stmt, T>::value || std::is_base_of<NestedNameSpecifier, T>::value || std::is_base_of<NestedNameSpecifierLoc, T>::value || std::is_base_of<TypeLoc, T>::value || std::is_base_of<QualType, T>::value, "unsupported type for recursive matching"); return matchesChildOf(DynTypedNode::create(Node), getASTContext(), Matcher, Builder, Traverse, Bind); } template <typename T> bool matchesDescendantOf(const T &Node, const DynTypedMatcher &Matcher, BoundNodesTreeBuilder *Builder, BindKind Bind) { static_assert(std::is_base_of<Decl, T>::value || std::is_base_of<Stmt, T>::value || std::is_base_of<NestedNameSpecifier, T>::value || std::is_base_of<NestedNameSpecifierLoc, T>::value || std::is_base_of<TypeLoc, T>::value || std::is_base_of<QualType, T>::value, "unsupported type for recursive matching"); return matchesDescendantOf(DynTypedNode::create(Node), getASTContext(), Matcher, Builder, Bind); } // FIXME: Implement support for BindKind. template <typename T> bool matchesAncestorOf(const T &Node, const DynTypedMatcher &Matcher, BoundNodesTreeBuilder *Builder, AncestorMatchMode MatchMode) { static_assert(std::is_base_of<Decl, T>::value || std::is_base_of<NestedNameSpecifierLoc, T>::value || std::is_base_of<Stmt, T>::value || std::is_base_of<TypeLoc, T>::value, "type not allowed for recursive matching"); return matchesAncestorOf(DynTypedNode::create(Node), getASTContext(), Matcher, Builder, MatchMode); } virtual ASTContext &getASTContext() const = 0; protected: virtual bool matchesChildOf(const DynTypedNode &Node, ASTContext &Ctx, const DynTypedMatcher &Matcher, BoundNodesTreeBuilder *Builder, TraversalKind Traverse, BindKind Bind) = 0; virtual bool matchesDescendantOf(const DynTypedNode &Node, ASTContext &Ctx, const DynTypedMatcher &Matcher, BoundNodesTreeBuilder *Builder, BindKind Bind) = 0; virtual bool matchesAncestorOf(const DynTypedNode &Node, ASTContext &Ctx, const DynTypedMatcher &Matcher, BoundNodesTreeBuilder *Builder, AncestorMatchMode MatchMode) = 0; }; /// A type-list implementation. /// /// A "linked list" of types, accessible by using the ::head and ::tail /// typedefs. template <typename... Ts> struct TypeList {}; // Empty sentinel type list. template <typename T1, typename... Ts> struct TypeList<T1, Ts...> { /// The first type on the list. using head = T1; /// A sublist with the tail. ie everything but the head. /// /// This type is used to do recursion. TypeList<>/EmptyTypeList indicates the /// end of the list. using tail = TypeList<Ts...>; }; /// The empty type list. using EmptyTypeList = TypeList<>; /// Helper meta-function to determine if some type \c T is present or /// a parent type in the list. template <typename AnyTypeList, typename T> struct TypeListContainsSuperOf { static const bool value = std::is_base_of<typename AnyTypeList::head, T>::value || TypeListContainsSuperOf<typename AnyTypeList::tail, T>::value; }; template <typename T> struct TypeListContainsSuperOf<EmptyTypeList, T> { static const bool value = false; }; /// A "type list" that contains all types. /// /// Useful for matchers like \c anything and \c unless. using AllNodeBaseTypes = TypeList<Decl, Stmt, NestedNameSpecifier, NestedNameSpecifierLoc, QualType, Type, TypeLoc, CXXCtorInitializer>; /// Helper meta-function to extract the argument out of a function of /// type void(Arg). /// /// See AST_POLYMORPHIC_SUPPORTED_TYPES for details. template <class T> struct ExtractFunctionArgMeta; template <class T> struct ExtractFunctionArgMeta<void(T)> { using type = T; }; /// Default type lists for ArgumentAdaptingMatcher matchers. using AdaptativeDefaultFromTypes = AllNodeBaseTypes; using AdaptativeDefaultToTypes = TypeList<Decl, Stmt, NestedNameSpecifier, NestedNameSpecifierLoc, TypeLoc, QualType>; /// All types that are supported by HasDeclarationMatcher above. using HasDeclarationSupportedTypes = TypeList<CallExpr, CXXConstructExpr, CXXNewExpr, DeclRefExpr, EnumType, ElaboratedType, InjectedClassNameType, LabelStmt, AddrLabelExpr, MemberExpr, QualType, RecordType, TagType, TemplateSpecializationType, TemplateTypeParmType, TypedefType, UnresolvedUsingType, ObjCIvarRefExpr>; template <template <typename ToArg, typename FromArg> class ArgumentAdapterT, typename T, typename ToTypes> class ArgumentAdaptingMatcherFuncAdaptor { public: explicit ArgumentAdaptingMatcherFuncAdaptor(const Matcher<T> &InnerMatcher) : InnerMatcher(InnerMatcher) {} using ReturnTypes = ToTypes; template <typename To> operator Matcher<To>() const { return Matcher<To>(new ArgumentAdapterT<To, T>(InnerMatcher)); } private: const Matcher<T> InnerMatcher; }; /// Converts a \c Matcher<T> to a matcher of desired type \c To by /// "adapting" a \c To into a \c T. /// /// The \c ArgumentAdapterT argument specifies how the adaptation is done. /// /// For example: /// \c ArgumentAdaptingMatcher<HasMatcher, T>(InnerMatcher); /// Given that \c InnerMatcher is of type \c Matcher<T>, this returns a matcher /// that is convertible into any matcher of type \c To by constructing /// \c HasMatcher<To, T>(InnerMatcher). /// /// If a matcher does not need knowledge about the inner type, prefer to use /// PolymorphicMatcherWithParam1. template <template <typename ToArg, typename FromArg> class ArgumentAdapterT, typename FromTypes = AdaptativeDefaultFromTypes, typename ToTypes = AdaptativeDefaultToTypes> struct ArgumentAdaptingMatcherFunc { template <typename T> static ArgumentAdaptingMatcherFuncAdaptor<ArgumentAdapterT, T, ToTypes> create(const Matcher<T> &InnerMatcher) { return ArgumentAdaptingMatcherFuncAdaptor<ArgumentAdapterT, T, ToTypes>( InnerMatcher); } template <typename T> ArgumentAdaptingMatcherFuncAdaptor<ArgumentAdapterT, T, ToTypes> operator()(const Matcher<T> &InnerMatcher) const { return create(InnerMatcher); } }; template <typename T> class TraversalMatcher : public MatcherInterface<T> { const DynTypedMatcher InnerMatcher; clang::TraversalKind Traversal; public: explicit TraversalMatcher(clang::TraversalKind TK, const Matcher<T> &InnerMatcher) : InnerMatcher(InnerMatcher), Traversal(TK) {} bool matches(const T &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const override { return this->InnerMatcher.matches(DynTypedNode::create(Node), Finder, Builder); } llvm::Optional<clang::TraversalKind> TraversalKind() const override { return Traversal; } }; template <typename MatcherType> class TraversalWrapper { public: TraversalWrapper(TraversalKind TK, const MatcherType &InnerMatcher) : TK(TK), InnerMatcher(InnerMatcher) {} template <typename T> operator Matcher<T>() const { return internal::DynTypedMatcher::constructRestrictedWrapper( new internal::TraversalMatcher<T>(TK, InnerMatcher), ASTNodeKind::getFromNodeKind<T>()) .template unconditionalConvertTo<T>(); } private: TraversalKind TK; MatcherType InnerMatcher; }; /// A PolymorphicMatcherWithParamN<MatcherT, P1, ..., PN> object can be /// created from N parameters p1, ..., pN (of type P1, ..., PN) and /// used as a Matcher<T> where a MatcherT<T, P1, ..., PN>(p1, ..., pN) /// can be constructed. /// /// For example: /// - PolymorphicMatcherWithParam0<IsDefinitionMatcher>() /// creates an object that can be used as a Matcher<T> for any type T /// where an IsDefinitionMatcher<T>() can be constructed. /// - PolymorphicMatcherWithParam1<ValueEqualsMatcher, int>(42) /// creates an object that can be used as a Matcher<T> for any type T /// where a ValueEqualsMatcher<T, int>(42) can be constructed. template <template <typename T> class MatcherT, typename ReturnTypesF = void(AllNodeBaseTypes)> class PolymorphicMatcherWithParam0 { public: using ReturnTypes = typename ExtractFunctionArgMeta<ReturnTypesF>::type; template <typename T> operator Matcher<T>() const { static_assert(TypeListContainsSuperOf<ReturnTypes, T>::value, "right polymorphic conversion"); return Matcher<T>(new MatcherT<T>()); } }; template <template <typename T, typename P1> class MatcherT, typename P1, typename ReturnTypesF = void(AllNodeBaseTypes)> class PolymorphicMatcherWithParam1 { public: explicit PolymorphicMatcherWithParam1(const P1 &Param1) : Param1(Param1) {} using ReturnTypes = typename ExtractFunctionArgMeta<ReturnTypesF>::type; template <typename T> operator Matcher<T>() const { static_assert(TypeListContainsSuperOf<ReturnTypes, T>::value, "right polymorphic conversion"); return Matcher<T>(new MatcherT<T, P1>(Param1)); } private: const P1 Param1; }; template <template <typename T, typename P1, typename P2> class MatcherT, typename P1, typename P2, typename ReturnTypesF = void(AllNodeBaseTypes)> class PolymorphicMatcherWithParam2 { public: PolymorphicMatcherWithParam2(const P1 &Param1, const P2 &Param2) : Param1(Param1), Param2(Param2) {} using ReturnTypes = typename ExtractFunctionArgMeta<ReturnTypesF>::type; template <typename T> operator Matcher<T>() const { static_assert(TypeListContainsSuperOf<ReturnTypes, T>::value, "right polymorphic conversion"); return Matcher<T>(new MatcherT<T, P1, P2>(Param1, Param2)); } private: const P1 Param1; const P2 Param2; }; /// Matches any instance of the given NodeType. /// /// This is useful when a matcher syntactically requires a child matcher, /// but the context doesn't care. See for example: anything(). class TrueMatcher { public: using ReturnTypes = AllNodeBaseTypes; template <typename T> operator Matcher<T>() const { return DynTypedMatcher::trueMatcher(ASTNodeKind::getFromNodeKind<T>()) .template unconditionalConvertTo<T>(); } }; /// A Matcher that allows binding the node it matches to an id. /// /// BindableMatcher provides a \a bind() method that allows binding the /// matched node to an id if the match was successful. template <typename T> class BindableMatcher : public Matcher<T> { public: explicit BindableMatcher(const Matcher<T> &M) : Matcher<T>(M) {} explicit BindableMatcher(MatcherInterface<T> *Implementation) : Matcher<T>(Implementation) {} /// Returns a matcher that will bind the matched node on a match. /// /// The returned matcher is equivalent to this matcher, but will /// bind the matched node on a match. Matcher<T> bind(StringRef ID) const { return DynTypedMatcher(*this) .tryBind(ID) ->template unconditionalConvertTo<T>(); } /// Same as Matcher<T>'s conversion operator, but enables binding on /// the returned matcher. operator DynTypedMatcher() const { DynTypedMatcher Result = static_cast<const Matcher<T>&>(*this); Result.setAllowBind(true); return Result; } }; /// Matches nodes of type T that have child nodes of type ChildT for /// which a specified child matcher matches. /// /// ChildT must be an AST base type. template <typename T, typename ChildT> class HasMatcher : public MatcherInterface<T> { const DynTypedMatcher InnerMatcher; public: explicit HasMatcher(const Matcher<ChildT> &InnerMatcher) : InnerMatcher(InnerMatcher) {} bool matches(const T &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const override { return Finder->matchesChildOf(Node, this->InnerMatcher, Builder, TraversalKind::TK_AsIs, ASTMatchFinder::BK_First); } }; /// Matches nodes of type T that have child nodes of type ChildT for /// which a specified child matcher matches. ChildT must be an AST base /// type. /// As opposed to the HasMatcher, the ForEachMatcher will produce a match /// for each child that matches. template <typename T, typename ChildT> class ForEachMatcher : public MatcherInterface<T> { static_assert(IsBaseType<ChildT>::value, "for each only accepts base type matcher"); const DynTypedMatcher InnerMatcher; public: explicit ForEachMatcher(const Matcher<ChildT> &InnerMatcher) : InnerMatcher(InnerMatcher) {} bool matches(const T &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const override { return Finder->matchesChildOf( Node, this->InnerMatcher, Builder, TraversalKind::TK_IgnoreImplicitCastsAndParentheses, ASTMatchFinder::BK_All); } }; /// VariadicOperatorMatcher related types. /// @{ /// Polymorphic matcher object that uses a \c /// DynTypedMatcher::VariadicOperator operator. /// /// Input matchers can have any type (including other polymorphic matcher /// types), and the actual Matcher<T> is generated on demand with an implicit /// conversion operator. template <typename... Ps> class VariadicOperatorMatcher { public: VariadicOperatorMatcher(DynTypedMatcher::VariadicOperator Op, Ps &&... Params) : Op(Op), Params(std::forward<Ps>(Params)...) {} template <typename T> operator Matcher<T>() const { return DynTypedMatcher::constructVariadic( Op, ASTNodeKind::getFromNodeKind<T>(), getMatchers<T>(std::index_sequence_for<Ps...>())) .template unconditionalConvertTo<T>(); } private: // Helper method to unpack the tuple into a vector. template <typename T, std::size_t... Is> std::vector<DynTypedMatcher> getMatchers(std::index_sequence<Is...>) const { return {Matcher<T>(std::get<Is>(Params))...}; } const DynTypedMatcher::VariadicOperator Op; std::tuple<Ps...> Params; }; /// Overloaded function object to generate VariadicOperatorMatcher /// objects from arbitrary matchers. template <unsigned MinCount, unsigned MaxCount> struct VariadicOperatorMatcherFunc { DynTypedMatcher::VariadicOperator Op; template <typename... Ms> VariadicOperatorMatcher<Ms...> operator()(Ms &&... Ps) const { static_assert(MinCount <= sizeof...(Ms) && sizeof...(Ms) <= MaxCount, "invalid number of parameters for variadic matcher"); return VariadicOperatorMatcher<Ms...>(Op, std::forward<Ms>(Ps)...); } }; /// @} template <typename T> inline Matcher<T> DynTypedMatcher::unconditionalConvertTo() const { return Matcher<T>(*this); } /// Creates a Matcher<T> that matches if all inner matchers match. template<typename T> BindableMatcher<T> makeAllOfComposite( ArrayRef<const Matcher<T> *> InnerMatchers) { // For the size() == 0 case, we return a "true" matcher. if (InnerMatchers.empty()) { return BindableMatcher<T>(TrueMatcher()); } // For the size() == 1 case, we simply return that one matcher. // No need to wrap it in a variadic operation. if (InnerMatchers.size() == 1) { return BindableMatcher<T>(*InnerMatchers[0]); } using PI = llvm::pointee_iterator<const Matcher<T> *const *>; std::vector<DynTypedMatcher> DynMatchers(PI(InnerMatchers.begin()), PI(InnerMatchers.end())); return BindableMatcher<T>( DynTypedMatcher::constructVariadic(DynTypedMatcher::VO_AllOf, ASTNodeKind::getFromNodeKind<T>(), std::move(DynMatchers)) .template unconditionalConvertTo<T>()); } /// Creates a Matcher<T> that matches if /// T is dyn_cast'able into InnerT and all inner matchers match. /// /// Returns BindableMatcher, as matchers that use dyn_cast have /// the same object both to match on and to run submatchers on, /// so there is no ambiguity with what gets bound. template<typename T, typename InnerT> BindableMatcher<T> makeDynCastAllOfComposite( ArrayRef<const Matcher<InnerT> *> InnerMatchers) { return BindableMatcher<T>( makeAllOfComposite(InnerMatchers).template dynCastTo<T>()); } /// Matches nodes of type T that have at least one descendant node of /// type DescendantT for which the given inner matcher matches. /// /// DescendantT must be an AST base type. template <typename T, typename DescendantT> class HasDescendantMatcher : public MatcherInterface<T> { static_assert(IsBaseType<DescendantT>::value, "has descendant only accepts base type matcher"); const DynTypedMatcher DescendantMatcher; public: explicit HasDescendantMatcher(const Matcher<DescendantT> &DescendantMatcher) : DescendantMatcher(DescendantMatcher) {} bool matches(const T &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const override { return Finder->matchesDescendantOf(Node, this->DescendantMatcher, Builder, ASTMatchFinder::BK_First); } }; /// Matches nodes of type \c T that have a parent node of type \c ParentT /// for which the given inner matcher matches. /// /// \c ParentT must be an AST base type. template <typename T, typename ParentT> class HasParentMatcher : public MatcherInterface<T> { static_assert(IsBaseType<ParentT>::value, "has parent only accepts base type matcher"); const DynTypedMatcher ParentMatcher; public: explicit HasParentMatcher(const Matcher<ParentT> &ParentMatcher) : ParentMatcher(ParentMatcher) {} bool matches(const T &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const override { return Finder->matchesAncestorOf(Node, this->ParentMatcher, Builder, ASTMatchFinder::AMM_ParentOnly); } }; /// Matches nodes of type \c T that have at least one ancestor node of /// type \c AncestorT for which the given inner matcher matches. /// /// \c AncestorT must be an AST base type. template <typename T, typename AncestorT> class HasAncestorMatcher : public MatcherInterface<T> { static_assert(IsBaseType<AncestorT>::value, "has ancestor only accepts base type matcher"); const DynTypedMatcher AncestorMatcher; public: explicit HasAncestorMatcher(const Matcher<AncestorT> &AncestorMatcher) : AncestorMatcher(AncestorMatcher) {} bool matches(const T &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const override { return Finder->matchesAncestorOf(Node, this->AncestorMatcher, Builder, ASTMatchFinder::AMM_All); } }; /// Matches nodes of type T that have at least one descendant node of /// type DescendantT for which the given inner matcher matches. /// /// DescendantT must be an AST base type. /// As opposed to HasDescendantMatcher, ForEachDescendantMatcher will match /// for each descendant node that matches instead of only for the first. template <typename T, typename DescendantT> class ForEachDescendantMatcher : public MatcherInterface<T> { static_assert(IsBaseType<DescendantT>::value, "for each descendant only accepts base type matcher"); const DynTypedMatcher DescendantMatcher; public: explicit ForEachDescendantMatcher( const Matcher<DescendantT> &DescendantMatcher) : DescendantMatcher(DescendantMatcher) {} bool matches(const T &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const override { return Finder->matchesDescendantOf(Node, this->DescendantMatcher, Builder, ASTMatchFinder::BK_All); } }; /// Matches on nodes that have a getValue() method if getValue() equals /// the value the ValueEqualsMatcher was constructed with. template <typename T, typename ValueT> class ValueEqualsMatcher : public SingleNodeMatcherInterface<T> { static_assert(std::is_base_of<CharacterLiteral, T>::value || std::is_base_of<CXXBoolLiteralExpr, T>::value || std::is_base_of<FloatingLiteral, T>::value || std::is_base_of<IntegerLiteral, T>::value, "the node must have a getValue method"); public: explicit ValueEqualsMatcher(const ValueT &ExpectedValue) : ExpectedValue(ExpectedValue) {} bool matchesNode(const T &Node) const override { return Node.getValue() == ExpectedValue; } private: const ValueT ExpectedValue; }; /// Template specializations to easily write matchers for floating point /// literals. template <> inline bool ValueEqualsMatcher<FloatingLiteral, double>::matchesNode( const FloatingLiteral &Node) const { if ((&Node.getSemantics()) == &llvm::APFloat::IEEEsingle()) return Node.getValue().convertToFloat() == ExpectedValue; if ((&Node.getSemantics()) == &llvm::APFloat::IEEEdouble()) return Node.getValue().convertToDouble() == ExpectedValue; return false; } template <> inline bool ValueEqualsMatcher<FloatingLiteral, float>::matchesNode( const FloatingLiteral &Node) const { if ((&Node.getSemantics()) == &llvm::APFloat::IEEEsingle()) return Node.getValue().convertToFloat() == ExpectedValue; if ((&Node.getSemantics()) == &llvm::APFloat::IEEEdouble()) return Node.getValue().convertToDouble() == ExpectedValue; return false; } template <> inline bool ValueEqualsMatcher<FloatingLiteral, llvm::APFloat>::matchesNode( const FloatingLiteral &Node) const { return ExpectedValue.compare(Node.getValue()) == llvm::APFloat::cmpEqual; } /// A VariadicDynCastAllOfMatcher<SourceT, TargetT> object is a /// variadic functor that takes a number of Matcher<TargetT> and returns a /// Matcher<SourceT> that matches TargetT nodes that are matched by all of the /// given matchers, if SourceT can be dynamically casted into TargetT. /// /// For example: /// const VariadicDynCastAllOfMatcher<Decl, CXXRecordDecl> record; /// Creates a functor record(...) that creates a Matcher<Decl> given /// a variable number of arguments of type Matcher<CXXRecordDecl>. /// The returned matcher matches if the given Decl can by dynamically /// casted to CXXRecordDecl and all given matchers match. template <typename SourceT, typename TargetT> class VariadicDynCastAllOfMatcher : public VariadicFunction<BindableMatcher<SourceT>, Matcher<TargetT>, makeDynCastAllOfComposite<SourceT, TargetT>> { public: VariadicDynCastAllOfMatcher() {} }; /// A \c VariadicAllOfMatcher<T> object is a variadic functor that takes /// a number of \c Matcher<T> and returns a \c Matcher<T> that matches \c T /// nodes that are matched by all of the given matchers. /// /// For example: /// const VariadicAllOfMatcher<NestedNameSpecifier> nestedNameSpecifier; /// Creates a functor nestedNameSpecifier(...) that creates a /// \c Matcher<NestedNameSpecifier> given a variable number of arguments of type /// \c Matcher<NestedNameSpecifier>. /// The returned matcher matches if all given matchers match. template <typename T> class VariadicAllOfMatcher : public VariadicFunction<BindableMatcher<T>, Matcher<T>, makeAllOfComposite<T>> { public: VariadicAllOfMatcher() {} }; /// Matches nodes of type \c TLoc for which the inner /// \c Matcher<T> matches. template <typename TLoc, typename T> class LocMatcher : public MatcherInterface<TLoc> { const DynTypedMatcher InnerMatcher; public: explicit LocMatcher(const Matcher<T> &InnerMatcher) : InnerMatcher(InnerMatcher) {} bool matches(const TLoc &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const override { if (!Node) return false; return this->InnerMatcher.matches(extract(Node), Finder, Builder); } private: static DynTypedNode extract(const NestedNameSpecifierLoc &Loc) { return DynTypedNode::create(*Loc.getNestedNameSpecifier()); } }; /// Matches \c TypeLocs based on an inner matcher matching a certain /// \c QualType. /// /// Used to implement the \c loc() matcher. class TypeLocTypeMatcher : public MatcherInterface<TypeLoc> { const DynTypedMatcher InnerMatcher; public: explicit TypeLocTypeMatcher(const Matcher<QualType> &InnerMatcher) : InnerMatcher(InnerMatcher) {} bool matches(const TypeLoc &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const override { if (!Node) return false; return this->InnerMatcher.matches(DynTypedNode::create(Node.getType()), Finder, Builder); } }; /// Matches nodes of type \c T for which the inner matcher matches on a /// another node of type \c T that can be reached using a given traverse /// function. template <typename T> class TypeTraverseMatcher : public MatcherInterface<T> { const DynTypedMatcher InnerMatcher; public: explicit TypeTraverseMatcher(const Matcher<QualType> &InnerMatcher, QualType (T::*TraverseFunction)() const) : InnerMatcher(InnerMatcher), TraverseFunction(TraverseFunction) {} bool matches(const T &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const override { QualType NextNode = (Node.*TraverseFunction)(); if (NextNode.isNull()) return false; return this->InnerMatcher.matches(DynTypedNode::create(NextNode), Finder, Builder); } private: QualType (T::*TraverseFunction)() const; }; /// Matches nodes of type \c T in a ..Loc hierarchy, for which the inner /// matcher matches on a another node of type \c T that can be reached using a /// given traverse function. template <typename T> class TypeLocTraverseMatcher : public MatcherInterface<T> { const DynTypedMatcher InnerMatcher; public: explicit TypeLocTraverseMatcher(const Matcher<TypeLoc> &InnerMatcher, TypeLoc (T::*TraverseFunction)() const) : InnerMatcher(InnerMatcher), TraverseFunction(TraverseFunction) {} bool matches(const T &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder) const override { TypeLoc NextNode = (Node.*TraverseFunction)(); if (!NextNode) return false; return this->InnerMatcher.matches(DynTypedNode::create(NextNode), Finder, Builder); } private: TypeLoc (T::*TraverseFunction)() const; }; /// Converts a \c Matcher<InnerT> to a \c Matcher<OuterT>, where /// \c OuterT is any type that is supported by \c Getter. /// /// \code Getter<OuterT>::value() \endcode returns a /// \code InnerTBase (OuterT::*)() \endcode, which is used to adapt a \c OuterT /// object into a \c InnerT template <typename InnerTBase, template <typename OuterT> class Getter, template <typename OuterT> class MatcherImpl, typename ReturnTypesF> class TypeTraversePolymorphicMatcher { private: using Self = TypeTraversePolymorphicMatcher<InnerTBase, Getter, MatcherImpl, ReturnTypesF>; static Self create(ArrayRef<const Matcher<InnerTBase> *> InnerMatchers); public: using ReturnTypes = typename ExtractFunctionArgMeta<ReturnTypesF>::type; explicit TypeTraversePolymorphicMatcher( ArrayRef<const Matcher<InnerTBase> *> InnerMatchers) : InnerMatcher(makeAllOfComposite(InnerMatchers)) {} template <typename OuterT> operator Matcher<OuterT>() const { return Matcher<OuterT>( new MatcherImpl<OuterT>(InnerMatcher, Getter<OuterT>::value())); } struct Func : public VariadicFunction<Self, Matcher<InnerTBase>, &Self::create> { Func() {} }; private: const Matcher<InnerTBase> InnerMatcher; }; /// A simple memoizer of T(*)() functions. /// /// It will call the passed 'Func' template parameter at most once. /// Used to support AST_MATCHER_FUNCTION() macro. template <typename Matcher, Matcher (*Func)()> class MemoizedMatcher { struct Wrapper { Wrapper() : M(Func()) {} Matcher M; }; public: static const Matcher &getInstance() { static llvm::ManagedStatic<Wrapper> Instance; return Instance->M; } }; // Define the create() method out of line to silence a GCC warning about // the struct "Func" having greater visibility than its base, which comes from // using the flag -fvisibility-inlines-hidden. template <typename InnerTBase, template <typename OuterT> class Getter, template <typename OuterT> class MatcherImpl, typename ReturnTypesF> TypeTraversePolymorphicMatcher<InnerTBase, Getter, MatcherImpl, ReturnTypesF> TypeTraversePolymorphicMatcher< InnerTBase, Getter, MatcherImpl, ReturnTypesF>::create(ArrayRef<const Matcher<InnerTBase> *> InnerMatchers) { return Self(InnerMatchers); } // FIXME: unify ClassTemplateSpecializationDecl and TemplateSpecializationType's // APIs for accessing the template argument list. inline ArrayRef<TemplateArgument> getTemplateSpecializationArgs(const ClassTemplateSpecializationDecl &D) { return D.getTemplateArgs().asArray(); } inline ArrayRef<TemplateArgument> getTemplateSpecializationArgs(const TemplateSpecializationType &T) { return llvm::makeArrayRef(T.getArgs(), T.getNumArgs()); } inline ArrayRef<TemplateArgument> getTemplateSpecializationArgs(const FunctionDecl &FD) { if (const auto* TemplateArgs = FD.getTemplateSpecializationArgs()) return TemplateArgs->asArray(); return ArrayRef<TemplateArgument>(); } struct NotEqualsBoundNodePredicate { bool operator()(const internal::BoundNodesMap &Nodes) const { return Nodes.getNode(ID) != Node; } std::string ID; DynTypedNode Node; }; template <typename Ty> struct GetBodyMatcher { static const Stmt *get(const Ty &Node) { return Node.getBody(); } }; template <> inline const Stmt *GetBodyMatcher<FunctionDecl>::get(const FunctionDecl &Node) { return Node.doesThisDeclarationHaveABody() ? Node.getBody() : nullptr; } template <typename Ty> struct HasSizeMatcher { static bool hasSize(const Ty &Node, unsigned int N) { return Node.getSize() == N; } }; template <> inline bool HasSizeMatcher<StringLiteral>::hasSize( const StringLiteral &Node, unsigned int N) { return Node.getLength() == N; } template <typename Ty> struct GetSourceExpressionMatcher { static const Expr *get(const Ty &Node) { return Node.getSubExpr(); } }; template <> inline const Expr *GetSourceExpressionMatcher<OpaqueValueExpr>::get( const OpaqueValueExpr &Node) { return Node.getSourceExpr(); } template <typename Ty> struct CompoundStmtMatcher { static const CompoundStmt *get(const Ty &Node) { return &Node; } }; template <> inline const CompoundStmt * CompoundStmtMatcher<StmtExpr>::get(const StmtExpr &Node) { return Node.getSubStmt(); } /// If \p Loc is (transitively) expanded from macro \p MacroName, returns the /// location (in the chain of expansions) at which \p MacroName was /// expanded. Since the macro may have been expanded inside a series of /// expansions, that location may itself be a MacroID. llvm::Optional<SourceLocation> getExpansionLocOfMacro(StringRef MacroName, SourceLocation Loc, const ASTContext &Context); /// Matches overloaded operators with a specific name. /// /// The type argument ArgT is not used by this matcher but is used by /// PolymorphicMatcherWithParam1 and should be std::vector<std::string>>. template <typename T, typename ArgT = std::vector<std::string>> class HasAnyOperatorNameMatcher : public SingleNodeMatcherInterface<T> { static_assert(std::is_same<T, BinaryOperator>::value || std::is_same<T, UnaryOperator>::value, "Matcher only supports `BinaryOperator` and `UnaryOperator`"); static_assert(std::is_same<ArgT, std::vector<std::string>>::value, "Matcher ArgT must be std::vector<std::string>"); public: explicit HasAnyOperatorNameMatcher(std::vector<std::string> Names) : SingleNodeMatcherInterface<T>(), Names(std::move(Names)) {} bool matchesNode(const T &Node) const override { StringRef OpName = getOpName(Node); return llvm::any_of( Names, [&](const std::string &Name) { return Name == OpName; }); } private: static StringRef getOpName(const UnaryOperator &Node) { return Node.getOpcodeStr(Node.getOpcode()); } static StringRef getOpName(const BinaryOperator &Node) { return Node.getOpcodeStr(); } const std::vector<std::string> Names; }; using HasOpNameMatcher = PolymorphicMatcherWithParam1<HasAnyOperatorNameMatcher, std::vector<std::string>, void(TypeList<BinaryOperator, UnaryOperator>)>; HasOpNameMatcher hasAnyOperatorNameFunc(ArrayRef<const StringRef *> NameRefs); using HasOverloadOpNameMatcher = PolymorphicMatcherWithParam1< HasOverloadedOperatorNameMatcher, std::vector<std::string>, void(TypeList<CXXOperatorCallExpr, FunctionDecl>)>; HasOverloadOpNameMatcher hasAnyOverloadedOperatorNameFunc(ArrayRef<const StringRef *> NameRefs); /// Returns true if \p Node has a base specifier matching \p BaseSpec. /// /// A class is not considered to be derived from itself. bool matchesAnyBase(const CXXRecordDecl &Node, const Matcher<CXXBaseSpecifier> &BaseSpecMatcher, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder); std::shared_ptr<llvm::Regex> createAndVerifyRegex(StringRef Regex, llvm::Regex::RegexFlags Flags, StringRef MatcherID); } // namespace internal } // namespace ast_matchers } // namespace clang #endif // LLVM_CLANG_ASTMATCHERS_ASTMATCHERSINTERNAL_H
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