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llvm / llvm-archive / 9ee4ded126524dc671b998a7c57f4d2433ee9d20 / . / safecode / tools / clang / include / clang / ASTMatchers / ASTMatchersInternal.h
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//===--- ASTMatchersInternal.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.
//
//===----------------------------------------------------------------------===//
//
// 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_AST_MATCHERS_AST_MATCHERS_INTERNAL_H
#define LLVM_CLANG_AST_MATCHERS_AST_MATCHERS_INTERNAL_H
#include "clang/AST/ASTTypeTraits.h"
#include "clang/AST/DeclCXX.h"
#include "clang/AST/Decl.h"
#include "clang/AST/ExprCXX.h"
#include "clang/AST/StmtCXX.h"
#include "clang/AST/Stmt.h"
#include "clang/AST/Type.h"
#include "llvm/ADT/VariadicFunction.h"
#include "llvm/Support/type_traits.h"
#include <map>
#include <string>
#include <vector>
namespace clang {
namespace ast_matchers {
/// FIXME: Move into the llvm support library.
template <bool> struct CompileAssert {};
#define TOOLING_COMPILE_ASSERT(Expr, Msg) \
typedef CompileAssert<(bool(Expr))> Msg[bool(Expr) ? 1 : -1]
class BoundNodes;
namespace internal {
class BoundNodesTreeBuilder;
/// \brief Internal version of BoundNodes. Holds all the bound nodes.
class BoundNodesMap {
public:
/// \brief Adds \c Node to the map with key \c ID.
///
/// The node's base type should be in NodeBaseType or it will be unaccessible.
template <typename T>
void addNode(StringRef ID, const T* Node) {
NodeMap[ID] = ast_type_traits::DynTypedNode::create(*Node);
}
void addNode(StringRef ID, ast_type_traits::DynTypedNode Node) {
NodeMap[ID] = Node;
}
/// \brief 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 NULL;
}
return It->second.get<T>();
}
/// \brief Copies all ID/Node pairs to BoundNodesTreeBuilder \c Builder.
void copyTo(BoundNodesTreeBuilder *Builder) const;
/// \brief Copies all ID/Node pairs to BoundNodesMap \c Other.
void copyTo(BoundNodesMap *Other) const;
private:
/// \brief A map from IDs to the bound nodes.
typedef std::map<std::string, ast_type_traits::DynTypedNode> IDToNodeMap;
IDToNodeMap NodeMap;
};
/// \brief A tree of bound nodes in match results.
///
/// If a match can contain multiple matches on the same node with different
/// matching subexpressions, BoundNodesTree contains a branch for each of
/// those matching subexpressions.
///
/// BoundNodesTree's are created during the matching process; when a match
/// is found, we iterate over the tree and create a BoundNodes object containing
/// the union of all bound nodes on the path from the root to a each leaf.
class BoundNodesTree {
public:
/// \brief A visitor interface to visit all BoundNodes results for a
/// BoundNodesTree.
class Visitor {
public:
virtual ~Visitor() {}
/// \brief 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;
};
BoundNodesTree();
/// \brief Create a BoundNodesTree from pre-filled maps of bindings.
BoundNodesTree(const BoundNodesMap& Bindings,
const std::vector<BoundNodesTree> RecursiveBindings);
/// \brief Adds all bound nodes to \c Builder.
void copyTo(BoundNodesTreeBuilder* Builder) const;
/// \brief Visits all matches that this BoundNodesTree represents.
///
/// The ownership of 'ResultVisitor' remains at the caller.
void visitMatches(Visitor* ResultVisitor);
private:
void visitMatchesRecursively(
Visitor* ResultVistior,
const BoundNodesMap& AggregatedBindings);
// FIXME: Find out whether we want to use different data structures here -
// first benchmarks indicate that it doesn't matter though.
BoundNodesMap Bindings;
std::vector<BoundNodesTree> RecursiveBindings;
};
/// \brief Creates BoundNodesTree objects.
///
/// The tree builder is used during the matching process to insert the bound
/// nodes from the Id matcher.
class BoundNodesTreeBuilder {
public:
BoundNodesTreeBuilder();
/// \brief Add a binding from an id to a node.
template <typename T>
void setBinding(const std::string &Id, const T *Node) {
Bindings.addNode(Id, Node);
}
void setBinding(const std::string &Id, ast_type_traits::DynTypedNode Node) {
Bindings.addNode(Id, Node);
}
/// \brief Adds a branch in the tree.
void addMatch(const BoundNodesTree& Bindings);
/// \brief Returns a BoundNodes object containing all current bindings.
BoundNodesTree build() const;
private:
BoundNodesTreeBuilder(const BoundNodesTreeBuilder &) LLVM_DELETED_FUNCTION;
void operator=(const BoundNodesTreeBuilder &) LLVM_DELETED_FUNCTION;
BoundNodesMap Bindings;
std::vector<BoundNodesTree> RecursiveBindings;
};
class ASTMatchFinder;
/// \brief 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 RefCountedBaseVPTR {
public:
virtual ~MatcherInterface() {}
/// \brief 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;
};
/// \brief Interface for matchers that only evaluate properties on a single
/// node.
template <typename T>
class SingleNodeMatcherInterface : public MatcherInterface<T> {
public:
/// \brief 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.
virtual bool matches(const T &Node,
ASTMatchFinder * /* Finder */,
BoundNodesTreeBuilder * /* Builder */) const {
return matchesNode(Node);
}
};
/// \brief Base class for all matchers that works on a \c DynTypedNode.
///
/// Matcher implementations will check whether the \c DynTypedNode is
/// convertible into the respecitve types and then do the actual match
/// on the actual node, or return false if it is not convertible.
class DynTypedMatcher {
public:
virtual ~DynTypedMatcher() {}
/// \brief Returns true if the matcher matches the given \c DynNode.
virtual bool matches(const ast_type_traits::DynTypedNode DynNode,
ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const = 0;
/// \brief Returns a unique ID for the matcher.
virtual uint64_t getID() const = 0;
};
/// \brief 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 DynTypedMatcher {
public:
/// \brief Takes ownership of the provided implementation pointer.
explicit Matcher(MatcherInterface<T> *Implementation)
: Implementation(Implementation) {}
/// \brief 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,
typename llvm::enable_if_c<
llvm::is_base_of<From, T>::value &&
!llvm::is_same<From, T>::value >::type* = 0)
: Implementation(new ImplicitCastMatcher<From>(Other)) {}
/// \brief 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,
typename llvm::enable_if_c<
llvm::is_same<T, QualType>::value &&
llvm::is_same<TypeT, Type>::value >::type* = 0)
: Implementation(new TypeToQualType<TypeT>(Other)) {}
/// \brief Forwards the call to the underlying MatcherInterface<T> pointer.
bool matches(const T &Node,
ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const {
return Implementation->matches(Node, Finder, Builder);
}
/// \brief Returns an ID that uniquely identifies the matcher.
uint64_t getID() const {
/// FIXME: Document the requirements this imposes on matcher
/// implementations (no new() implementation_ during a Matches()).
return reinterpret_cast<uint64_t>(Implementation.getPtr());
}
/// \brief Returns whether the matcher matches on the given \c DynNode.
virtual bool matches(const ast_type_traits::DynTypedNode DynNode,
ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const {
const T *Node = DynNode.get<T>();
if (!Node) return false;
return matches(*Node, Finder, Builder);
}
/// \brief 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> {
public:
TypeToQualType(const Matcher<TypeT> &InnerMatcher)
: InnerMatcher(InnerMatcher) {}
virtual bool matches(const QualType &Node,
ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const {
if (Node.isNull())
return false;
return InnerMatcher.matches(*Node, Finder, Builder);
}
private:
const Matcher<TypeT> InnerMatcher;
};
private:
/// \brief Allows conversion from Matcher<Base> to Matcher<T> if T
/// is derived from Base.
template <typename Base>
class ImplicitCastMatcher : public MatcherInterface<T> {
public:
explicit ImplicitCastMatcher(const Matcher<Base> &From)
: From(From) {}
virtual bool matches(const T &Node,
ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const {
return From.matches(Node, Finder, Builder);
}
private:
const Matcher<Base> From;
};
IntrusiveRefCntPtr< MatcherInterface<T> > Implementation;
}; // class Matcher
/// \brief 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);
}
/// \brief Metafunction to determine if type T has a member called getDecl.
template <typename T> struct has_getDecl {
struct Default { int getDecl; };
struct Derived : T, Default { };
template<typename C, C> struct CheckT;
// If T::getDecl exists, an ambiguity arises and CheckT will
// not be instantiable. This makes f(...) the only available
// overload.
template<typename C>
static char (&f(CheckT<int Default::*, &C::getDecl>*))[1];
template<typename C> static char (&f(...))[2];
static bool const value = sizeof(f<Derived>(0)) == 2;
};
/// \brief 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> {
TOOLING_COMPILE_ASSERT((llvm::is_same<T, CXXOperatorCallExpr>::value ||
llvm::is_same<T, CXXMethodDecl>::value),
unsupported_class_for_matcher);
TOOLING_COMPILE_ASSERT((llvm::is_same<ArgT, StringRef>::value),
argument_type_must_be_StringRef);
public:
explicit HasOverloadedOperatorNameMatcher(const StringRef Name)
: SingleNodeMatcherInterface<T>(), Name(Name) {}
virtual bool matchesNode(const T &Node) const LLVM_OVERRIDE {
return matchesSpecialized(Node);
}
private:
/// \brief 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 getOperatorSpelling(Node.getOperator()) == Name;
}
/// \brief Returns true only if CXXMethodDecl represents an overloaded
/// operator and has the given operator name.
bool matchesSpecialized(const CXXMethodDecl &Node) const {
return Node.isOverloadedOperator() &&
getOperatorSpelling(Node.getOverloadedOperator()) == Name;
}
std::string Name;
};
/// \brief 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> {
TOOLING_COMPILE_ASSERT((llvm::is_same< DeclMatcherT,
Matcher<Decl> >::value),
instantiated_with_wrong_types);
public:
explicit HasDeclarationMatcher(const Matcher<Decl> &InnerMatcher)
: InnerMatcher(InnerMatcher) {}
virtual bool matches(const T &Node,
ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const {
return matchesSpecialized(Node, Finder, Builder);
}
private:
/// \brief If getDecl exists as a member of U, returns whether the inner
/// matcher matches Node.getDecl().
template <typename U>
bool matchesSpecialized(
const U &Node, ASTMatchFinder *Finder, BoundNodesTreeBuilder *Builder,
typename llvm::enable_if<has_getDecl<U>, int>::type = 0) const {
return matchesDecl(Node.getDecl(), Finder, Builder);
}
/// \brief Extracts the CXXRecordDecl or EnumDecl of a QualType and returns
/// whether the inner matcher matches on it.
bool matchesSpecialized(const QualType &Node, ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const {
/// FIXME: Add other ways to convert...
if (Node.isNull())
return false;
if (const EnumType *AsEnum = dyn_cast<EnumType>(Node.getTypePtr()))
return matchesDecl(AsEnum->getDecl(), Finder, Builder);
return matchesDecl(Node->getAsCXXRecordDecl(), Finder, Builder);
}
/// \brief Gets the TemplateDecl from a TemplateSpecializationType
/// and returns whether the inner matches on it.
bool matchesSpecialized(const TemplateSpecializationType &Node,
ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const {
return matchesDecl(Node.getTemplateName().getAsTemplateDecl(),
Finder, Builder);
}
/// \brief 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);
}
/// \brief 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);
}
/// \brief 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);
}
/// \brief 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 != NULL && InnerMatcher.matches(*Node, Finder, Builder);
}
const Matcher<Decl> InnerMatcher;
};
/// \brief 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 =
(llvm::is_same<T, Decl>::value ||
llvm::is_same<T, Stmt>::value ||
llvm::is_same<T, QualType>::value ||
llvm::is_same<T, Type>::value ||
llvm::is_same<T, TypeLoc>::value ||
llvm::is_same<T, NestedNameSpecifier>::value ||
llvm::is_same<T, NestedNameSpecifierLoc>::value ||
llvm::is_same<T, CXXCtorInitializer>::value);
};
template <typename T>
const bool IsBaseType<T>::value;
/// \brief 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 wan 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:
/// \brief Defines how we descend a level in the AST when we pass
/// through expressions.
enum TraversalKind {
/// Will traverse any child nodes.
TK_AsIs,
/// Will not traverse implicit casts and parentheses.
TK_IgnoreImplicitCastsAndParentheses
};
/// \brief 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
};
/// \brief Defines which ancestors are considered for a match.
enum AncestorMatchMode {
/// All ancestors.
AMM_All,
/// Direct parent only.
AMM_ParentOnly
};
virtual ~ASTMatchFinder() {}
/// \brief Returns true if the given class is directly or indirectly derived
/// from a base type matching \c base.
///
/// A class is considered to be also derived from itself.
virtual bool classIsDerivedFrom(const CXXRecordDecl *Declaration,
const Matcher<NamedDecl> &Base,
BoundNodesTreeBuilder *Builder) = 0;
template <typename T>
bool matchesChildOf(const T &Node,
const DynTypedMatcher &Matcher,
BoundNodesTreeBuilder *Builder,
TraversalKind Traverse,
BindKind Bind) {
TOOLING_COMPILE_ASSERT(
(llvm::is_base_of<Decl, T>::value ||
llvm::is_base_of<Stmt, T>::value ||
llvm::is_base_of<NestedNameSpecifier, T>::value ||
llvm::is_base_of<NestedNameSpecifierLoc, T>::value ||
llvm::is_base_of<TypeLoc, T>::value ||
llvm::is_base_of<QualType, T>::value),
unsupported_type_for_recursive_matching);
return matchesChildOf(ast_type_traits::DynTypedNode::create(Node),
Matcher, Builder, Traverse, Bind);
}
template <typename T>
bool matchesDescendantOf(const T &Node,
const DynTypedMatcher &Matcher,
BoundNodesTreeBuilder *Builder,
BindKind Bind) {
TOOLING_COMPILE_ASSERT(
(llvm::is_base_of<Decl, T>::value ||
llvm::is_base_of<Stmt, T>::value ||
llvm::is_base_of<NestedNameSpecifier, T>::value ||
llvm::is_base_of<NestedNameSpecifierLoc, T>::value ||
llvm::is_base_of<TypeLoc, T>::value ||
llvm::is_base_of<QualType, T>::value),
unsupported_type_for_recursive_matching);
return matchesDescendantOf(ast_type_traits::DynTypedNode::create(Node),
Matcher, Builder, Bind);
}
// FIXME: Implement support for BindKind.
template <typename T>
bool matchesAncestorOf(const T &Node,
const DynTypedMatcher &Matcher,
BoundNodesTreeBuilder *Builder,
AncestorMatchMode MatchMode) {
TOOLING_COMPILE_ASSERT((llvm::is_base_of<Decl, T>::value ||
llvm::is_base_of<Stmt, T>::value),
only_Decl_or_Stmt_allowed_for_recursive_matching);
return matchesAncestorOf(ast_type_traits::DynTypedNode::create(Node),
Matcher, Builder, MatchMode);
}
virtual ASTContext &getASTContext() const = 0;
protected:
virtual bool matchesChildOf(const ast_type_traits::DynTypedNode &Node,
const DynTypedMatcher &Matcher,
BoundNodesTreeBuilder *Builder,
TraversalKind Traverse,
BindKind Bind) = 0;
virtual bool matchesDescendantOf(const ast_type_traits::DynTypedNode &Node,
const DynTypedMatcher &Matcher,
BoundNodesTreeBuilder *Builder,
BindKind Bind) = 0;
virtual bool matchesAncestorOf(const ast_type_traits::DynTypedNode &Node,
const DynTypedMatcher &Matcher,
BoundNodesTreeBuilder *Builder,
AncestorMatchMode MatchMode) = 0;
};
/// \brief 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 T>
class ArgumentAdaptingMatcher {
public:
explicit ArgumentAdaptingMatcher(const Matcher<T> &InnerMatcher)
: InnerMatcher(InnerMatcher) {}
template <typename To>
operator Matcher<To>() const {
return Matcher<To>(new ArgumentAdapterT<To, T>(InnerMatcher));
}
private:
const Matcher<T> InnerMatcher;
};
/// \brief 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>
class PolymorphicMatcherWithParam0 {
public:
template <typename T>
operator Matcher<T>() const {
return Matcher<T>(new MatcherT<T>());
}
};
template <template <typename T, typename P1> class MatcherT,
typename P1>
class PolymorphicMatcherWithParam1 {
public:
explicit PolymorphicMatcherWithParam1(const P1 &Param1)
: Param1(Param1) {}
template <typename T>
operator Matcher<T>() const {
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>
class PolymorphicMatcherWithParam2 {
public:
PolymorphicMatcherWithParam2(const P1 &Param1, const P2 &Param2)
: Param1(Param1), Param2(Param2) {}
template <typename T>
operator Matcher<T>() const {
return Matcher<T>(new MatcherT<T, P1, P2>(Param1, Param2));
}
private:
const P1 Param1;
const P2 Param2;
};
/// \brief 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().
///
/// FIXME: Alternatively we could also create a IsAMatcher or something
/// that checks that a dyn_cast is possible. This is purely needed for the
/// difference between calling for example:
/// record()
/// and
/// record(SomeMatcher)
/// In the second case we need the correct type we were dyn_cast'ed to in order
/// to get the right type for the inner matcher. In the first case we don't need
/// that, but we use the type conversion anyway and insert a TrueMatcher.
template <typename T>
class TrueMatcher : public SingleNodeMatcherInterface<T> {
public:
virtual bool matchesNode(const T &Node) const {
return true;
}
};
/// \brief Provides a MatcherInterface<T> for a Matcher<To> that matches if T is
/// dyn_cast'able into To and the given Matcher<To> matches on the dyn_cast'ed
/// node.
template <typename T, typename To>
class DynCastMatcher : public MatcherInterface<T> {
public:
explicit DynCastMatcher(const Matcher<To> &InnerMatcher)
: InnerMatcher(InnerMatcher) {}
virtual bool matches(const T &Node,
ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const {
const To *InnerMatchValue = dyn_cast<To>(&Node);
return InnerMatchValue != NULL &&
InnerMatcher.matches(*InnerMatchValue, Finder, Builder);
}
private:
const Matcher<To> InnerMatcher;
};
/// \brief Matcher<T> that wraps an inner Matcher<T> and binds the matched node
/// to an ID if the inner matcher matches on the node.
template <typename T>
class IdMatcher : public MatcherInterface<T> {
public:
/// \brief Creates an IdMatcher that binds to 'ID' if 'InnerMatcher' matches
/// the node.
IdMatcher(StringRef ID, const Matcher<T> &InnerMatcher)
: ID(ID), InnerMatcher(InnerMatcher) {}
virtual bool matches(const T &Node,
ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const {
bool Result = InnerMatcher.matches(Node, Finder, Builder);
if (Result) {
Builder->setBinding(ID, &Node);
}
return Result;
}
private:
const std::string ID;
const Matcher<T> InnerMatcher;
};
/// \brief 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:
BindableMatcher(MatcherInterface<T> *Implementation)
: Matcher<T>(Implementation) {}
/// \brief 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 Matcher<T>(new IdMatcher<T>(ID, *this));
}
};
/// \brief 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> {
TOOLING_COMPILE_ASSERT(IsBaseType<ChildT>::value,
has_only_accepts_base_type_matcher);
public:
explicit HasMatcher(const Matcher<ChildT> &ChildMatcher)
: ChildMatcher(ChildMatcher) {}
virtual bool matches(const T &Node,
ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const {
return Finder->matchesChildOf(
Node, ChildMatcher, Builder,
ASTMatchFinder::TK_IgnoreImplicitCastsAndParentheses,
ASTMatchFinder::BK_First);
}
private:
const Matcher<ChildT> ChildMatcher;
};
/// \brief 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> {
TOOLING_COMPILE_ASSERT(IsBaseType<ChildT>::value,
for_each_only_accepts_base_type_matcher);
public:
explicit ForEachMatcher(const Matcher<ChildT> &ChildMatcher)
: ChildMatcher(ChildMatcher) {}
virtual bool matches(const T& Node,
ASTMatchFinder* Finder,
BoundNodesTreeBuilder* Builder) const {
return Finder->matchesChildOf(
Node, ChildMatcher, Builder,
ASTMatchFinder::TK_IgnoreImplicitCastsAndParentheses,
ASTMatchFinder::BK_All);
}
private:
const Matcher<ChildT> ChildMatcher;
};
/// \brief Matches nodes of type T if the given Matcher<T> does not match.
///
/// Type argument MatcherT is required by PolymorphicMatcherWithParam1
/// but not actually used. It will always be instantiated with a type
/// convertible to Matcher<T>.
template <typename T, typename MatcherT>
class NotMatcher : public MatcherInterface<T> {
public:
explicit NotMatcher(const Matcher<T> &InnerMatcher)
: InnerMatcher(InnerMatcher) {}
virtual bool matches(const T &Node,
ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const {
return !InnerMatcher.matches(Node, Finder, Builder);
}
private:
const Matcher<T> InnerMatcher;
};
/// \brief Matches nodes of type T for which both provided matchers match.
///
/// Type arguments MatcherT1 and MatcherT2 are required by
/// PolymorphicMatcherWithParam2 but not actually used. They will
/// always be instantiated with types convertible to Matcher<T>.
template <typename T, typename MatcherT1, typename MatcherT2>
class AllOfMatcher : public MatcherInterface<T> {
public:
AllOfMatcher(const Matcher<T> &InnerMatcher1, const Matcher<T> &InnerMatcher2)
: InnerMatcher1(InnerMatcher1), InnerMatcher2(InnerMatcher2) {}
virtual bool matches(const T &Node,
ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const {
return InnerMatcher1.matches(Node, Finder, Builder) &&
InnerMatcher2.matches(Node, Finder, Builder);
}
private:
const Matcher<T> InnerMatcher1;
const Matcher<T> InnerMatcher2;
};
/// \brief Matches nodes of type T for which at least one of the two provided
/// matchers matches.
///
/// Type arguments MatcherT1 and MatcherT2 are
/// required by PolymorphicMatcherWithParam2 but not actually
/// used. They will always be instantiated with types convertible to
/// Matcher<T>.
template <typename T, typename MatcherT1, typename MatcherT2>
class EachOfMatcher : public MatcherInterface<T> {
public:
EachOfMatcher(const Matcher<T> &InnerMatcher1,
const Matcher<T> &InnerMatcher2)
: InnerMatcher1(InnerMatcher1), InnerMatcher2(InnerMatcher2) {
}
virtual bool matches(const T &Node, ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const {
BoundNodesTreeBuilder Builder1;
bool Matched1 = InnerMatcher1.matches(Node, Finder, &Builder1);
if (Matched1)
Builder->addMatch(Builder1.build());
BoundNodesTreeBuilder Builder2;
bool Matched2 = InnerMatcher2.matches(Node, Finder, &Builder2);
if (Matched2)
Builder->addMatch(Builder2.build());
return Matched1 || Matched2;
}
private:
const Matcher<T> InnerMatcher1;
const Matcher<T> InnerMatcher2;
};
/// \brief Matches nodes of type T for which at least one of the two provided
/// matchers matches.
///
/// Type arguments MatcherT1 and MatcherT2 are
/// required by PolymorphicMatcherWithParam2 but not actually
/// used. They will always be instantiated with types convertible to
/// Matcher<T>.
template <typename T, typename MatcherT1, typename MatcherT2>
class AnyOfMatcher : public MatcherInterface<T> {
public:
AnyOfMatcher(const Matcher<T> &InnerMatcher1, const Matcher<T> &InnerMatcher2)
: InnerMatcher1(InnerMatcher1), InnerMatcher2(InnerMatcher2) {}
virtual bool matches(const T &Node,
ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const {
return InnerMatcher1.matches(Node, Finder, Builder) ||
InnerMatcher2.matches(Node, Finder, Builder);
}
private:
const Matcher<T> InnerMatcher1;
const Matcher<T> InnerMatcher2;
};
/// \brief Creates a Matcher<T> that matches if all inner matchers match.
template<typename T>
BindableMatcher<T> makeAllOfComposite(
ArrayRef<const Matcher<T> *> InnerMatchers) {
if (InnerMatchers.empty())
return BindableMatcher<T>(new TrueMatcher<T>);
MatcherInterface<T> *InnerMatcher = new TrueMatcher<T>;
for (int i = InnerMatchers.size() - 1; i >= 0; --i) {
InnerMatcher = new AllOfMatcher<T, Matcher<T>, Matcher<T> >(
*InnerMatchers[i], makeMatcher(InnerMatcher));
}
return BindableMatcher<T>(InnerMatcher);
}
/// \brief 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>(new DynCastMatcher<T, InnerT>(
makeAllOfComposite(InnerMatchers)));
}
/// \brief 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> {
TOOLING_COMPILE_ASSERT(IsBaseType<DescendantT>::value,
has_descendant_only_accepts_base_type_matcher);
public:
explicit HasDescendantMatcher(const Matcher<DescendantT> &DescendantMatcher)
: DescendantMatcher(DescendantMatcher) {}
virtual bool matches(const T &Node,
ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const {
return Finder->matchesDescendantOf(
Node, DescendantMatcher, Builder, ASTMatchFinder::BK_First);
}
private:
const Matcher<DescendantT> DescendantMatcher;
};
/// \brief 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> {
TOOLING_COMPILE_ASSERT(IsBaseType<ParentT>::value,
has_parent_only_accepts_base_type_matcher);
public:
explicit HasParentMatcher(const Matcher<ParentT> &ParentMatcher)
: ParentMatcher(ParentMatcher) {}
virtual bool matches(const T &Node,
ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const {
return Finder->matchesAncestorOf(
Node, ParentMatcher, Builder, ASTMatchFinder::AMM_ParentOnly);
}
private:
const Matcher<ParentT> ParentMatcher;
};
/// \brief 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> {
TOOLING_COMPILE_ASSERT(IsBaseType<AncestorT>::value,
has_ancestor_only_accepts_base_type_matcher);
public:
explicit HasAncestorMatcher(const Matcher<AncestorT> &AncestorMatcher)
: AncestorMatcher(AncestorMatcher) {}
virtual bool matches(const T &Node,
ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const {
return Finder->matchesAncestorOf(
Node, AncestorMatcher, Builder, ASTMatchFinder::AMM_All);
}
private:
const Matcher<AncestorT> AncestorMatcher;
};
/// \brief 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> {
TOOLING_COMPILE_ASSERT(IsBaseType<DescendantT>::value,
for_each_descendant_only_accepts_base_type_matcher);
public:
explicit ForEachDescendantMatcher(
const Matcher<DescendantT>& DescendantMatcher)
: DescendantMatcher(DescendantMatcher) {}
virtual bool matches(const T& Node,
ASTMatchFinder* Finder,
BoundNodesTreeBuilder* Builder) const {
return Finder->matchesDescendantOf(Node, DescendantMatcher, Builder,
ASTMatchFinder::BK_All);
}
private:
const Matcher<DescendantT> DescendantMatcher;
};
/// \brief 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> {
TOOLING_COMPILE_ASSERT((llvm::is_base_of<CharacterLiteral, T>::value ||
llvm::is_base_of<CXXBoolLiteralExpr,
T>::value ||
llvm::is_base_of<FloatingLiteral, T>::value ||
llvm::is_base_of<IntegerLiteral, T>::value),
the_node_must_have_a_getValue_method);
public:
explicit ValueEqualsMatcher(const ValueT &ExpectedValue)
: ExpectedValue(ExpectedValue) {}
virtual bool matchesNode(const T &Node) const {
return Node.getValue() == ExpectedValue;
}
private:
const ValueT ExpectedValue;
};
/// \brief 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 llvm::VariadicFunction<
BindableMatcher<SourceT>, Matcher<TargetT>,
makeDynCastAllOfComposite<SourceT, TargetT> > {
public:
VariadicDynCastAllOfMatcher() {}
};
/// \brief 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 llvm::VariadicFunction<
BindableMatcher<T>, Matcher<T>,
makeAllOfComposite<T> > {
public:
VariadicAllOfMatcher() {}
};
/// \brief Matches nodes of type \c TLoc for which the inner
/// \c Matcher<T> matches.
template <typename TLoc, typename T>
class LocMatcher : public MatcherInterface<TLoc> {
public:
explicit LocMatcher(const Matcher<T> &InnerMatcher)
: InnerMatcher(InnerMatcher) {}
virtual bool matches(const TLoc &Node,
ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const {
if (!Node)
return false;
return InnerMatcher.matches(*extract(Node), Finder, Builder);
}
private:
const NestedNameSpecifier *extract(const NestedNameSpecifierLoc &Loc) const {
return Loc.getNestedNameSpecifier();
}
const Matcher<T> InnerMatcher;
};
/// \brief 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> {
public:
explicit TypeLocTypeMatcher(const Matcher<QualType> &InnerMatcher)
: InnerMatcher(InnerMatcher) {}
virtual bool matches(const TypeLoc &Node,
ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const {
if (!Node)
return false;
return InnerMatcher.matches(Node.getType(), Finder, Builder);
}
private:
const Matcher<QualType> InnerMatcher;
};
/// \brief 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> {
public:
explicit TypeTraverseMatcher(const Matcher<QualType> &InnerMatcher,
QualType (T::*TraverseFunction)() const)
: InnerMatcher(InnerMatcher), TraverseFunction(TraverseFunction) {}
virtual bool matches(const T &Node,
ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const {
QualType NextNode = (Node.*TraverseFunction)();
if (NextNode.isNull())
return false;
return InnerMatcher.matches(NextNode, Finder, Builder);
}
private:
const Matcher<QualType> InnerMatcher;
QualType (T::*TraverseFunction)() const;
};
/// \brief 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> {
public:
explicit TypeLocTraverseMatcher(const Matcher<TypeLoc> &InnerMatcher,
TypeLoc (T::*TraverseFunction)() const)
: InnerMatcher(InnerMatcher), TraverseFunction(TraverseFunction) {}
virtual bool matches(const T &Node,
ASTMatchFinder *Finder,
BoundNodesTreeBuilder *Builder) const {
TypeLoc NextNode = (Node.*TraverseFunction)();
if (!NextNode)
return false;
return InnerMatcher.matches(NextNode, Finder, Builder);
}
private:
const Matcher<TypeLoc> InnerMatcher;
TypeLoc (T::*TraverseFunction)() const;
};
template <typename T, typename InnerT>
T makeTypeAllOfComposite(ArrayRef<const Matcher<InnerT> *> InnerMatchers) {
return T(makeAllOfComposite<InnerT>(InnerMatchers));
}
} // end namespace internal
} // end namespace ast_matchers
} // end namespace clang
#endif // LLVM_CLANG_AST_MATCHERS_AST_MATCHERS_INTERNAL_H