lib/Sema/Lookup.h - clang - Git at Google

 //===--- Lookup.h - Classes for name lookup ---------------------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file defines the LookupResult class, which is integral to
 // Sema's name-lookup subsystem.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_CLANG_SEMA_LOOKUP_H
 #define LLVM_CLANG_SEMA_LOOKUP_H

 #include "Sema.h"

 namespace clang {

 /// @brief Represents the results of name lookup.
 ///
 /// An instance of the LookupResult class captures the results of a
 /// single name lookup, which can return no result (nothing found),
 /// a single declaration, a set of overloaded functions, or an
 /// ambiguity. Use the getKind() method to determine which of these
 /// results occurred for a given lookup.
 class LookupResult {
 public:
   enum LookupResultKind {
     /// @brief No entity found met the criteria.
     NotFound = 0,

     /// @brief No entity found met the criteria within the current
     /// instantiation,, but there were dependent base classes of the
     /// current instantiation that could not be searched.
     NotFoundInCurrentInstantiation,

     /// @brief Name lookup found a single declaration that met the
     /// criteria.  getFoundDecl() will return this declaration.
     Found,

     /// @brief Name lookup found a set of overloaded functions that
     /// met the criteria.
     FoundOverloaded,

     /// @brief Name lookup found an unresolvable value declaration
     /// and cannot yet complete.  This only happens in C++ dependent
     /// contexts with dependent using declarations.
     FoundUnresolvedValue,

     /// @brief Name lookup results in an ambiguity; use
     /// getAmbiguityKind to figure out what kind of ambiguity
     /// we have.
     Ambiguous
   };

   enum AmbiguityKind {
     /// Name lookup results in an ambiguity because multiple
     /// entities that meet the lookup criteria were found in
     /// subobjects of different types. For example:
     /// @code
     /// struct A { void f(int); }
     /// struct B { void f(double); }
     /// struct C : A, B { };
     /// void test(C c) {
     ///   c.f(0); // error: A::f and B::f come from subobjects of different
     ///           // types. overload resolution is not performed.
     /// }
     /// @endcode
     AmbiguousBaseSubobjectTypes,

     /// Name lookup results in an ambiguity because multiple
     /// nonstatic entities that meet the lookup criteria were found
     /// in different subobjects of the same type. For example:
     /// @code
     /// struct A { int x; };
     /// struct B : A { };
     /// struct C : A { };
     /// struct D : B, C { };
     /// int test(D d) {
     ///   return d.x; // error: 'x' is found in two A subobjects (of B and C)
     /// }
     /// @endcode
     AmbiguousBaseSubobjects,

     /// Name lookup results in an ambiguity because multiple definitions
     /// of entity that meet the lookup criteria were found in different
     /// declaration contexts.
     /// @code
     /// namespace A {
     ///   int i;
     ///   namespace B { int i; }
     ///   int test() {
     ///     using namespace B;
     ///     return i; // error 'i' is found in namespace A and A::B
     ///    }
     /// }
     /// @endcode
     AmbiguousReference,

     /// Name lookup results in an ambiguity because an entity with a
     /// tag name was hidden by an entity with an ordinary name from
     /// a different context.
     /// @code
     /// namespace A { struct Foo {}; }
     /// namespace B { void Foo(); }
     /// namespace C {
     ///   using namespace A;
     ///   using namespace B;
     /// }
     /// void test() {
     ///   C::Foo(); // error: tag 'A::Foo' is hidden by an object in a
     ///             // different namespace
     /// }
     /// @endcode
     AmbiguousTagHiding
   };

   /// A little identifier for flagging temporary lookup results.
   enum TemporaryToken {
     Temporary
   };

   typedef UnresolvedSetImpl::iterator iterator;
   typedef bool (*ResultFilter)(NamedDecl*, unsigned IDNS);

   LookupResult(Sema &SemaRef, DeclarationName Name, SourceLocation NameLoc,
                Sema::LookupNameKind LookupKind,
                Sema::RedeclarationKind Redecl = Sema::NotForRedeclaration)
     : ResultKind(NotFound),
       Paths(0),
       NamingClass(0),
       SemaRef(SemaRef),
       Name(Name),
       NameLoc(NameLoc),
       LookupKind(LookupKind),
       IsAcceptableFn(0),
       IDNS(0),
       Redecl(Redecl != Sema::NotForRedeclaration),
       HideTags(true),
       Diagnose(Redecl == Sema::NotForRedeclaration)
   {
     configure();
   }

   /// Creates a temporary lookup result, initializing its core data
   /// using the information from another result.  Diagnostics are always
   /// disabled.
   LookupResult(TemporaryToken _, const LookupResult &Other)
     : ResultKind(NotFound),
       Paths(0),
       NamingClass(0),
       SemaRef(Other.SemaRef),
       Name(Other.Name),
       NameLoc(Other.NameLoc),
       LookupKind(Other.LookupKind),
       IsAcceptableFn(Other.IsAcceptableFn),
       IDNS(Other.IDNS),
       Redecl(Other.Redecl),
       HideTags(Other.HideTags),
       Diagnose(false)
   {}

   ~LookupResult() {
     if (Diagnose) diagnose();
     if (Paths) deletePaths(Paths);
   }

   /// Gets the name to look up.
   DeclarationName getLookupName() const {
     return Name;
   }

   /// \brief Sets the name to look up.
   void setLookupName(DeclarationName Name) {
     this->Name = Name;
   }

   /// Gets the kind of lookup to perform.
   Sema::LookupNameKind getLookupKind() const {
     return LookupKind;
   }

   /// True if this lookup is just looking for an existing declaration.
   bool isForRedeclaration() const {
     return Redecl;
   }

   /// Sets whether tag declarations should be hidden by non-tag
   /// declarations during resolution.  The default is true.
   void setHideTags(bool Hide) {
     HideTags = Hide;
   }

   bool isAmbiguous() const {
     return getResultKind() == Ambiguous;
   }

   /// Determines if this names a single result which is not an
   /// unresolved value using decl.  If so, it is safe to call
   /// getFoundDecl().
   bool isSingleResult() const {
     return getResultKind() == Found;
   }

   /// Determines if the results are overloaded.
   bool isOverloadedResult() const {
     return getResultKind() == FoundOverloaded;
   }

   bool isUnresolvableResult() const {
     return getResultKind() == FoundUnresolvedValue;
   }

   LookupResultKind getResultKind() const {
     sanity();
     return ResultKind;
   }

   AmbiguityKind getAmbiguityKind() const {
     assert(isAmbiguous());
     return Ambiguity;
   }

   const UnresolvedSetImpl &asUnresolvedSet() const {
     return Decls;
   }

   iterator begin() const { return iterator(Decls.begin()); }
   iterator end() const { return iterator(Decls.end()); }

   /// \brief Return true if no decls were found
   bool empty() const { return Decls.empty(); }

   /// \brief Return the base paths structure that's associated with
   /// these results, or null if none is.
   CXXBasePaths *getBasePaths() const {
     return Paths;
   }

   /// \brief Tests whether the given declaration is acceptable.
   bool isAcceptableDecl(NamedDecl *D) const {
     assert(IsAcceptableFn);
     return IsAcceptableFn(D, IDNS);
   }

   /// \brief Returns the identifier namespace mask for this lookup.
   unsigned getIdentifierNamespace() const {
     return IDNS;
   }

   /// \brief Returns whether these results arose from performing a
   /// lookup into a class.
   bool isClassLookup() const {
     return NamingClass != 0;
   }

   /// \brief Returns the 'naming class' for this lookup, i.e. the
   /// class which was looked into to find these results.
   ///
   /// C++0x [class.access.base]p5:
   ///   The access to a member is affected by the class in which the
   ///   member is named. This naming class is the class in which the
   ///   member name was looked up and found. [Note: this class can be
   ///   explicit, e.g., when a qualified-id is used, or implicit,
   ///   e.g., when a class member access operator (5.2.5) is used
   ///   (including cases where an implicit "this->" is added). If both
   ///   a class member access operator and a qualified-id are used to
   ///   name the member (as in p->T::m), the class naming the member
   ///   is the class named by the nested-name-specifier of the
   ///   qualified-id (that is, T). -- end note ]
   ///
   /// This is set by the lookup routines when they find results in a class.
   CXXRecordDecl *getNamingClass() const {
     return NamingClass;
   }

   /// \brief Sets the 'naming class' for this lookup.
   void setNamingClass(CXXRecordDecl *Record) {
     NamingClass = Record;
   }

   /// \brief Add a declaration to these results with its natural access.
   /// Does not test the acceptance criteria.
   void addDecl(NamedDecl *D) {
     addDecl(D, D->getAccess());
   }

   /// \brief Add a declaration to these results with the given access.
   /// Does not test the acceptance criteria.
   void addDecl(NamedDecl *D, AccessSpecifier AS) {
     Decls.addDecl(D, AS);
     ResultKind = Found;
   }

   /// \brief Add all the declarations from another set of lookup
   /// results.
   void addAllDecls(const LookupResult &Other) {
     Decls.append(Other.Decls.begin(), Other.Decls.end());
     ResultKind = Found;
   }

   /// \brief Determine whether no result was found because we could not
   /// search into dependent base classes of the current instantiation.
   bool wasNotFoundInCurrentInstantiation() const {
     return ResultKind == NotFoundInCurrentInstantiation;
   }

   /// \brief Note that while no result was found in the current instantiation,
   /// there were dependent base classes that could not be searched.
   void setNotFoundInCurrentInstantiation() {
     assert(ResultKind == NotFound && Decls.empty());
     ResultKind = NotFoundInCurrentInstantiation;
   }

   /// \brief Resolves the result kind of the lookup, possibly hiding
   /// decls.
   ///
   /// This should be called in any environment where lookup might
   /// generate multiple lookup results.
   void resolveKind();

   /// \brief Re-resolves the result kind of the lookup after a set of
   /// removals has been performed.
   void resolveKindAfterFilter() {
     if (Decls.empty()) {
       if (ResultKind != NotFoundInCurrentInstantiation)
         ResultKind = NotFound;
     } else {
       ResultKind = Found;
       resolveKind();
     }
   }

   template <class DeclClass>
   DeclClass *getAsSingle() const {
     if (getResultKind() != Found) return 0;
     return dyn_cast<DeclClass>(getFoundDecl());
   }

   /// \brief Fetch the unique decl found by this lookup.  Asserts
   /// that one was found.
   ///
   /// This is intended for users who have examined the result kind
   /// and are certain that there is only one result.
   NamedDecl *getFoundDecl() const {
     assert(getResultKind() == Found
            && "getFoundDecl called on non-unique result");
     return (*begin())->getUnderlyingDecl();
   }

   /// Fetches a representative decl.  Useful for lazy diagnostics.
   NamedDecl *getRepresentativeDecl() const {
     assert(!Decls.empty() && "cannot get representative of empty set");
     return *begin();
   }

   /// \brief Asks if the result is a single tag decl.
   bool isSingleTagDecl() const {
     return getResultKind() == Found && isa<TagDecl>(getFoundDecl());
   }

   /// \brief Make these results show that the name was found in
   /// base classes of different types.
   ///
   /// The given paths object is copied and invalidated.
   void setAmbiguousBaseSubobjectTypes(CXXBasePaths &P);

   /// \brief Make these results show that the name was found in
   /// distinct base classes of the same type.
   ///
   /// The given paths object is copied and invalidated.
   void setAmbiguousBaseSubobjects(CXXBasePaths &P);

   /// \brief Make these results show that the name was found in
   /// different contexts and a tag decl was hidden by an ordinary
   /// decl in a different context.
   void setAmbiguousQualifiedTagHiding() {
     setAmbiguous(AmbiguousTagHiding);
   }

   /// \brief Clears out any current state.
   void clear() {
     ResultKind = NotFound;
     Decls.clear();
     if (Paths) deletePaths(Paths);
     Paths = NULL;
   }

   /// \brief Clears out any current state and re-initializes for a
   /// different kind of lookup.
   void clear(Sema::LookupNameKind Kind) {
     clear();
     LookupKind = Kind;
     configure();
   }

   void print(llvm::raw_ostream &);

   /// Suppress the diagnostics that would normally fire because of this
   /// lookup.  This happens during (e.g.) redeclaration lookups.
   void suppressDiagnostics() {
     Diagnose = false;
   }

   /// Sets a 'context' source range.
   void setContextRange(SourceRange SR) {
     NameContextRange = SR;
   }

   /// Gets the source range of the context of this name; for C++
   /// qualified lookups, this is the source range of the scope
   /// specifier.
   SourceRange getContextRange() const {
     return NameContextRange;
   }

   /// Gets the location of the identifier.  This isn't always defined:
   /// sometimes we're doing lookups on synthesized names.
   SourceLocation getNameLoc() const {
     return NameLoc;
   }

   /// \brief Get the Sema object that this lookup result is searching
   /// with.
   Sema &getSema() const { return SemaRef; }

   /// A class for iterating through a result set and possibly
   /// filtering out results.  The results returned are possibly
   /// sugared.
   class Filter {
     LookupResult &Results;
     LookupResult::iterator I;
     bool Changed;
 #ifndef NDEBUG
     bool CalledDone;
 #endif

     friend class LookupResult;
     Filter(LookupResult &Results)
       : Results(Results), I(Results.begin()), Changed(false)
 #ifndef NDEBUG
       , CalledDone(false)
 #endif
     {}

   public:
 #ifndef NDEBUG
     ~Filter() {
       assert(CalledDone &&
              "LookupResult::Filter destroyed without done() call");
     }
 #endif

     bool hasNext() const {
       return I != Results.end();
     }

     NamedDecl *next() {
       assert(I != Results.end() && "next() called on empty filter");
       return *I++;
     }

     /// Erase the last element returned from this iterator.
     void erase() {
       Results.Decls.erase(--I);
       Changed = true;
     }

     /// Replaces the current entry with the given one, preserving the
     /// access bits.
     void replace(NamedDecl *D) {
       Results.Decls.replace(I-1, D);
       Changed = true;
     }

     /// Replaces the current entry with the given one.
     void replace(NamedDecl *D, AccessSpecifier AS) {
       Results.Decls.replace(I-1, D, AS);
       Changed = true;
     }

     void done() {
 #ifndef NDEBUG
       assert(!CalledDone && "done() called twice");
       CalledDone = true;
 #endif

       if (Changed)
         Results.resolveKindAfterFilter();
     }
   };

   /// Create a filter for this result set.
   Filter makeFilter() {
     return Filter(*this);
   }

 private:
   void diagnose() {
     if (isAmbiguous())
       SemaRef.DiagnoseAmbiguousLookup(*this);
     else if (isClassLookup() && SemaRef.getLangOptions().AccessControl)
       SemaRef.CheckLookupAccess(*this);
   }

   void setAmbiguous(AmbiguityKind AK) {
     ResultKind = Ambiguous;
     Ambiguity = AK;
   }

   void addDeclsFromBasePaths(const CXXBasePaths &P);
   void configure();

   // Sanity checks.
   void sanity() const {
     assert(ResultKind != NotFound || Decls.size() == 0);
     assert(ResultKind != Found || Decls.size() == 1);
     assert(ResultKind != FoundOverloaded || Decls.size() > 1 ||
            (Decls.size() == 1 &&
             isa<FunctionTemplateDecl>((*begin())->getUnderlyingDecl())));
     assert(ResultKind != FoundUnresolvedValue || sanityCheckUnresolved());
     assert(ResultKind != Ambiguous || Decls.size() > 1 ||
            (Decls.size() == 1 && Ambiguity == AmbiguousBaseSubobjects));
     assert((Paths != NULL) == (ResultKind == Ambiguous &&
                                (Ambiguity == AmbiguousBaseSubobjectTypes ||
                                 Ambiguity == AmbiguousBaseSubobjects)));
   }

   bool sanityCheckUnresolved() const {
     for (iterator I = begin(), E = end(); I != E; ++I)
       if (isa<UnresolvedUsingValueDecl>(*I))
         return true;
     return false;
   }

   static void deletePaths(CXXBasePaths *);

   // Results.
   LookupResultKind ResultKind;
   AmbiguityKind Ambiguity; // ill-defined unless ambiguous
   UnresolvedSet<8> Decls;
   CXXBasePaths *Paths;
   CXXRecordDecl *NamingClass;

   // Parameters.
   Sema &SemaRef;
   DeclarationName Name;
   SourceLocation NameLoc;
   SourceRange NameContextRange;
   Sema::LookupNameKind LookupKind;
   ResultFilter IsAcceptableFn; // set by configure()
   unsigned IDNS; // set by configure()

   bool Redecl;

   /// \brief True if tag declarations should be hidden if non-tags
   ///   are present
   bool HideTags;

   bool Diagnose;
 };

   /// \brief Consumes visible declarations found when searching for
   /// all visible names within a given scope or context.
   ///
   /// This abstract class is meant to be subclassed by clients of \c
   /// Sema::LookupVisibleDecls(), each of which should override the \c
   /// FoundDecl() function to process declarations as they are found.
   class VisibleDeclConsumer {
   public:
     /// \brief Destroys the visible declaration consumer.
     virtual ~VisibleDeclConsumer();

     /// \brief Invoked each time \p Sema::LookupVisibleDecls() finds a
     /// declaration visible from the current scope or context.
     ///
     /// \param ND the declaration found.
     ///
     /// \param Hiding a declaration that hides the declaration \p ND,
     /// or NULL if no such declaration exists.
     ///
     /// \param InBaseClass whether this declaration was found in base
     /// class of the context we searched.
     virtual void FoundDecl(NamedDecl *ND, NamedDecl *Hiding,
                            bool InBaseClass) = 0;
   };

 /// \brief A class for storing results from argument-dependent lookup.
 class ADLResult {
 private:
   /// A map from canonical decls to the 'most recent' decl.
   llvm::DenseMap<NamedDecl*, NamedDecl*> Decls;

 public:
   /// Adds a new ADL candidate to this map.
   void insert(NamedDecl *D);

   /// Removes any data associated with a given decl.
   void erase(NamedDecl *D) {
     Decls.erase(cast<NamedDecl>(D->getCanonicalDecl()));
   }

   class iterator {
     typedef llvm::DenseMap<NamedDecl*,NamedDecl*>::iterator inner_iterator;
     inner_iterator iter;

     friend class ADLResult;
     iterator(const inner_iterator &iter) : iter(iter) {}
   public:
     iterator() {}

     iterator &operator++() { ++iter; return *this; }
     iterator operator++(int) { return iterator(iter++); }

     NamedDecl *operator*() const { return iter->second; }

     bool operator==(const iterator &other) const { return iter == other.iter; }
     bool operator!=(const iterator &other) const { return iter != other.iter; }
   };

   iterator begin() { return iterator(Decls.begin()); }
   iterator end() { return iterator(Decls.end()); }
 };

 }

 #endif
	//===--- Lookup.h - Classes for name lookup ---------------------- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defines the LookupResult class, which is integral to
	// Sema's name-lookup subsystem.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_CLANG_SEMA_LOOKUP_H
	#define LLVM_CLANG_SEMA_LOOKUP_H

	#include "Sema.h"

	namespace clang {

	/// @brief Represents the results of name lookup.
	///
	/// An instance of the LookupResult class captures the results of a
	/// single name lookup, which can return no result (nothing found),
	/// a single declaration, a set of overloaded functions, or an
	/// ambiguity. Use the getKind() method to determine which of these
	/// results occurred for a given lookup.
	class LookupResult {
	public:
	enum LookupResultKind {
	/// @brief No entity found met the criteria.
	NotFound = 0,

	/// @brief No entity found met the criteria within the current
	/// instantiation,, but there were dependent base classes of the
	/// current instantiation that could not be searched.
	NotFoundInCurrentInstantiation,

	/// @brief Name lookup found a single declaration that met the
	/// criteria. getFoundDecl() will return this declaration.
	Found,

	/// @brief Name lookup found a set of overloaded functions that
	/// met the criteria.
	FoundOverloaded,

	/// @brief Name lookup found an unresolvable value declaration
	/// and cannot yet complete. This only happens in C++ dependent
	/// contexts with dependent using declarations.
	FoundUnresolvedValue,

	/// @brief Name lookup results in an ambiguity; use
	/// getAmbiguityKind to figure out what kind of ambiguity
	/// we have.
	Ambiguous
	};

	enum AmbiguityKind {
	/// Name lookup results in an ambiguity because multiple
	/// entities that meet the lookup criteria were found in
	/// subobjects of different types. For example:
	/// @code
	/// struct A { void f(int); }
	/// struct B { void f(double); }
	/// struct C : A, B { };
	/// void test(C c) {
	/// c.f(0); // error: A::f and B::f come from subobjects of different
	/// // types. overload resolution is not performed.
	/// }
	/// @endcode
	AmbiguousBaseSubobjectTypes,

	/// Name lookup results in an ambiguity because multiple
	/// nonstatic entities that meet the lookup criteria were found
	/// in different subobjects of the same type. For example:
	/// @code
	/// struct A { int x; };
	/// struct B : A { };
	/// struct C : A { };
	/// struct D : B, C { };
	/// int test(D d) {
	/// return d.x; // error: 'x' is found in two A subobjects (of B and C)
	/// }
	/// @endcode
	AmbiguousBaseSubobjects,

	/// Name lookup results in an ambiguity because multiple definitions
	/// of entity that meet the lookup criteria were found in different
	/// declaration contexts.
	/// @code
	/// namespace A {
	/// int i;
	/// namespace B { int i; }
	/// int test() {
	/// using namespace B;
	/// return i; // error 'i' is found in namespace A and A::B
	/// }
	/// }
	/// @endcode
	AmbiguousReference,

	/// Name lookup results in an ambiguity because an entity with a
	/// tag name was hidden by an entity with an ordinary name from
	/// a different context.
	/// @code
	/// namespace A { struct Foo {}; }
	/// namespace B { void Foo(); }
	/// namespace C {
	/// using namespace A;
	/// using namespace B;
	/// }
	/// void test() {
	/// C::Foo(); // error: tag 'A::Foo' is hidden by an object in a
	/// // different namespace
	/// }
	/// @endcode
	AmbiguousTagHiding
	};

	/// A little identifier for flagging temporary lookup results.
	enum TemporaryToken {
	Temporary
	};

	typedef UnresolvedSetImpl::iterator iterator;
	typedef bool (ResultFilter)(NamedDecl, unsigned IDNS);

	LookupResult(Sema &SemaRef, DeclarationName Name, SourceLocation NameLoc,
	Sema::LookupNameKind LookupKind,
	Sema::RedeclarationKind Redecl = Sema::NotForRedeclaration)
	: ResultKind(NotFound),
	Paths(0),
	NamingClass(0),
	SemaRef(SemaRef),
	Name(Name),
	NameLoc(NameLoc),
	LookupKind(LookupKind),
	IsAcceptableFn(0),
	IDNS(0),
	Redecl(Redecl != Sema::NotForRedeclaration),
	HideTags(true),
	Diagnose(Redecl == Sema::NotForRedeclaration)
	{
	configure();
	}

	/// Creates a temporary lookup result, initializing its core data
	/// using the information from another result. Diagnostics are always
	/// disabled.
	LookupResult(TemporaryToken _, const LookupResult &Other)
	: ResultKind(NotFound),
	Paths(0),
	NamingClass(0),
	SemaRef(Other.SemaRef),
	Name(Other.Name),
	NameLoc(Other.NameLoc),
	LookupKind(Other.LookupKind),
	IsAcceptableFn(Other.IsAcceptableFn),
	IDNS(Other.IDNS),
	Redecl(Other.Redecl),
	HideTags(Other.HideTags),
	Diagnose(false)
	{}

	~LookupResult() {
	if (Diagnose) diagnose();
	if (Paths) deletePaths(Paths);
	}

	/// Gets the name to look up.
	DeclarationName getLookupName() const {
	return Name;
	}

	/// \brief Sets the name to look up.
	void setLookupName(DeclarationName Name) {
	this->Name = Name;
	}

	/// Gets the kind of lookup to perform.
	Sema::LookupNameKind getLookupKind() const {
	return LookupKind;
	}

	/// True if this lookup is just looking for an existing declaration.
	bool isForRedeclaration() const {
	return Redecl;
	}

	/// Sets whether tag declarations should be hidden by non-tag
	/// declarations during resolution. The default is true.
	void setHideTags(bool Hide) {
	HideTags = Hide;
	}

	bool isAmbiguous() const {
	return getResultKind() == Ambiguous;
	}

	/// Determines if this names a single result which is not an
	/// unresolved value using decl. If so, it is safe to call
	/// getFoundDecl().
	bool isSingleResult() const {
	return getResultKind() == Found;
	}

	/// Determines if the results are overloaded.
	bool isOverloadedResult() const {
	return getResultKind() == FoundOverloaded;
	}

	bool isUnresolvableResult() const {
	return getResultKind() == FoundUnresolvedValue;
	}

	LookupResultKind getResultKind() const {
	sanity();
	return ResultKind;
	}

	AmbiguityKind getAmbiguityKind() const {
	assert(isAmbiguous());
	return Ambiguity;
	}

	const UnresolvedSetImpl &asUnresolvedSet() const {
	return Decls;
	}

	iterator begin() const { return iterator(Decls.begin()); }
	iterator end() const { return iterator(Decls.end()); }

	/// \brief Return true if no decls were found
	bool empty() const { return Decls.empty(); }

	/// \brief Return the base paths structure that's associated with
	/// these results, or null if none is.
	CXXBasePaths *getBasePaths() const {
	return Paths;
	}

	/// \brief Tests whether the given declaration is acceptable.
	bool isAcceptableDecl(NamedDecl *D) const {
	assert(IsAcceptableFn);
	return IsAcceptableFn(D, IDNS);
	}

	/// \brief Returns the identifier namespace mask for this lookup.
	unsigned getIdentifierNamespace() const {
	return IDNS;
	}

	/// \brief Returns whether these results arose from performing a
	/// lookup into a class.
	bool isClassLookup() const {
	return NamingClass != 0;
	}

	/// \brief Returns the 'naming class' for this lookup, i.e. the
	/// class which was looked into to find these results.
	///
	/// C++0x [class.access.base]p5:
	/// The access to a member is affected by the class in which the
	/// member is named. This naming class is the class in which the
	/// member name was looked up and found. [Note: this class can be
	/// explicit, e.g., when a qualified-id is used, or implicit,
	/// e.g., when a class member access operator (5.2.5) is used
	/// (including cases where an implicit "this->" is added). If both
	/// a class member access operator and a qualified-id are used to
	/// name the member (as in p->T::m), the class naming the member
	/// is the class named by the nested-name-specifier of the
	/// qualified-id (that is, T). -- end note ]
	///
	/// This is set by the lookup routines when they find results in a class.
	CXXRecordDecl *getNamingClass() const {
	return NamingClass;
	}

	/// \brief Sets the 'naming class' for this lookup.
	void setNamingClass(CXXRecordDecl *Record) {
	NamingClass = Record;
	}

	/// \brief Add a declaration to these results with its natural access.
	/// Does not test the acceptance criteria.
	void addDecl(NamedDecl *D) {
	addDecl(D, D->getAccess());
	}

	/// \brief Add a declaration to these results with the given access.
	/// Does not test the acceptance criteria.
	void addDecl(NamedDecl *D, AccessSpecifier AS) {
	Decls.addDecl(D, AS);
	ResultKind = Found;
	}

	/// \brief Add all the declarations from another set of lookup
	/// results.
	void addAllDecls(const LookupResult &Other) {
	Decls.append(Other.Decls.begin(), Other.Decls.end());
	ResultKind = Found;
	}

	/// \brief Determine whether no result was found because we could not
	/// search into dependent base classes of the current instantiation.
	bool wasNotFoundInCurrentInstantiation() const {
	return ResultKind == NotFoundInCurrentInstantiation;
	}

	/// \brief Note that while no result was found in the current instantiation,
	/// there were dependent base classes that could not be searched.
	void setNotFoundInCurrentInstantiation() {
	assert(ResultKind == NotFound && Decls.empty());
	ResultKind = NotFoundInCurrentInstantiation;
	}

	/// \brief Resolves the result kind of the lookup, possibly hiding
	/// decls.
	///
	/// This should be called in any environment where lookup might
	/// generate multiple lookup results.
	void resolveKind();

	/// \brief Re-resolves the result kind of the lookup after a set of
	/// removals has been performed.
	void resolveKindAfterFilter() {
	if (Decls.empty()) {
	if (ResultKind != NotFoundInCurrentInstantiation)
	ResultKind = NotFound;
	} else {
	ResultKind = Found;
	resolveKind();
	}
	}

	template <class DeclClass>
	DeclClass *getAsSingle() const {
	if (getResultKind() != Found) return 0;
	return dyn_cast<DeclClass>(getFoundDecl());
	}

	/// \brief Fetch the unique decl found by this lookup. Asserts
	/// that one was found.
	///
	/// This is intended for users who have examined the result kind
	/// and are certain that there is only one result.
	NamedDecl *getFoundDecl() const {
	assert(getResultKind() == Found
	&& "getFoundDecl called on non-unique result");
	return (*begin())->getUnderlyingDecl();
	}

	/// Fetches a representative decl. Useful for lazy diagnostics.
	NamedDecl *getRepresentativeDecl() const {
	assert(!Decls.empty() && "cannot get representative of empty set");
	return *begin();
	}

	/// \brief Asks if the result is a single tag decl.
	bool isSingleTagDecl() const {
	return getResultKind() == Found && isa<TagDecl>(getFoundDecl());
	}

	/// \brief Make these results show that the name was found in
	/// base classes of different types.
	///
	/// The given paths object is copied and invalidated.
	void setAmbiguousBaseSubobjectTypes(CXXBasePaths &P);

	/// \brief Make these results show that the name was found in
	/// distinct base classes of the same type.
	///
	/// The given paths object is copied and invalidated.
	void setAmbiguousBaseSubobjects(CXXBasePaths &P);

	/// \brief Make these results show that the name was found in
	/// different contexts and a tag decl was hidden by an ordinary
	/// decl in a different context.
	void setAmbiguousQualifiedTagHiding() {
	setAmbiguous(AmbiguousTagHiding);
	}

	/// \brief Clears out any current state.
	void clear() {
	ResultKind = NotFound;
	Decls.clear();
	if (Paths) deletePaths(Paths);
	Paths = NULL;
	}

	/// \brief Clears out any current state and re-initializes for a
	/// different kind of lookup.
	void clear(Sema::LookupNameKind Kind) {
	clear();
	LookupKind = Kind;
	configure();
	}

	void print(llvm::raw_ostream &);

	/// Suppress the diagnostics that would normally fire because of this
	/// lookup. This happens during (e.g.) redeclaration lookups.
	void suppressDiagnostics() {
	Diagnose = false;
	}

	/// Sets a 'context' source range.
	void setContextRange(SourceRange SR) {
	NameContextRange = SR;
	}

	/// Gets the source range of the context of this name; for C++
	/// qualified lookups, this is the source range of the scope
	/// specifier.
	SourceRange getContextRange() const {
	return NameContextRange;
	}

	/// Gets the location of the identifier. This isn't always defined:
	/// sometimes we're doing lookups on synthesized names.
	SourceLocation getNameLoc() const {
	return NameLoc;
	}

	/// \brief Get the Sema object that this lookup result is searching
	/// with.
	Sema &getSema() const { return SemaRef; }

	/// A class for iterating through a result set and possibly
	/// filtering out results. The results returned are possibly
	/// sugared.
	class Filter {
	LookupResult &Results;
	LookupResult::iterator I;
	bool Changed;
	#ifndef NDEBUG
	bool CalledDone;
	#endif

	friend class LookupResult;
	Filter(LookupResult &Results)
	: Results(Results), I(Results.begin()), Changed(false)
	#ifndef NDEBUG
	, CalledDone(false)
	#endif
	{}

	public:
	#ifndef NDEBUG
	~Filter() {
	assert(CalledDone &&
	"LookupResult::Filter destroyed without done() call");
	}
	#endif

	bool hasNext() const {
	return I != Results.end();
	}

	NamedDecl *next() {
	assert(I != Results.end() && "next() called on empty filter");
	return *I++;
	}

	/// Erase the last element returned from this iterator.
	void erase() {
	Results.Decls.erase(--I);
	Changed = true;
	}

	/// Replaces the current entry with the given one, preserving the
	/// access bits.
	void replace(NamedDecl *D) {
	Results.Decls.replace(I-1, D);
	Changed = true;
	}

	/// Replaces the current entry with the given one.
	void replace(NamedDecl *D, AccessSpecifier AS) {
	Results.Decls.replace(I-1, D, AS);
	Changed = true;
	}

	void done() {
	#ifndef NDEBUG
	assert(!CalledDone && "done() called twice");
	CalledDone = true;
	#endif

	if (Changed)
	Results.resolveKindAfterFilter();
	}
	};

	/// Create a filter for this result set.
	Filter makeFilter() {
	return Filter(*this);
	}

	private:
	void diagnose() {
	if (isAmbiguous())
	SemaRef.DiagnoseAmbiguousLookup(*this);
	else if (isClassLookup() && SemaRef.getLangOptions().AccessControl)
	SemaRef.CheckLookupAccess(*this);
	}

	void setAmbiguous(AmbiguityKind AK) {
	ResultKind = Ambiguous;
	Ambiguity = AK;
	}

	void addDeclsFromBasePaths(const CXXBasePaths &P);
	void configure();

	// Sanity checks.
	void sanity() const {
	assert(ResultKind != NotFound \|\| Decls.size() == 0);
	assert(ResultKind != Found \|\| Decls.size() == 1);
	assert(ResultKind != FoundOverloaded \|\| Decls.size() > 1 \|\|
	(Decls.size() == 1 &&
	isa<FunctionTemplateDecl>((*begin())->getUnderlyingDecl())));
	assert(ResultKind != FoundUnresolvedValue \|\| sanityCheckUnresolved());
	assert(ResultKind != Ambiguous \|\| Decls.size() > 1 \|\|
	(Decls.size() == 1 && Ambiguity == AmbiguousBaseSubobjects));
	assert((Paths != NULL) == (ResultKind == Ambiguous &&
	(Ambiguity == AmbiguousBaseSubobjectTypes \|\|
	Ambiguity == AmbiguousBaseSubobjects)));
	}

	bool sanityCheckUnresolved() const {
	for (iterator I = begin(), E = end(); I != E; ++I)
	if (isa<UnresolvedUsingValueDecl>(*I))
	return true;
	return false;
	}

	static void deletePaths(CXXBasePaths *);

	// Results.
	LookupResultKind ResultKind;
	AmbiguityKind Ambiguity; // ill-defined unless ambiguous
	UnresolvedSet<8> Decls;
	CXXBasePaths *Paths;
	CXXRecordDecl *NamingClass;

	// Parameters.
	Sema &SemaRef;
	DeclarationName Name;
	SourceLocation NameLoc;
	SourceRange NameContextRange;
	Sema::LookupNameKind LookupKind;
	ResultFilter IsAcceptableFn; // set by configure()
	unsigned IDNS; // set by configure()

	bool Redecl;

	/// \brief True if tag declarations should be hidden if non-tags
	/// are present
	bool HideTags;

	bool Diagnose;
	};

	/// \brief Consumes visible declarations found when searching for
	/// all visible names within a given scope or context.
	///
	/// This abstract class is meant to be subclassed by clients of \c
	/// Sema::LookupVisibleDecls(), each of which should override the \c
	/// FoundDecl() function to process declarations as they are found.
	class VisibleDeclConsumer {
	public:
	/// \brief Destroys the visible declaration consumer.
	virtual ~VisibleDeclConsumer();

	/// \brief Invoked each time \p Sema::LookupVisibleDecls() finds a
	/// declaration visible from the current scope or context.
	///
	/// \param ND the declaration found.
	///
	/// \param Hiding a declaration that hides the declaration \p ND,
	/// or NULL if no such declaration exists.
	///
	/// \param InBaseClass whether this declaration was found in base
	/// class of the context we searched.
	virtual void FoundDecl(NamedDecl ND, NamedDecl Hiding,
	bool InBaseClass) = 0;
	};

	/// \brief A class for storing results from argument-dependent lookup.
	class ADLResult {
	private:
	/// A map from canonical decls to the 'most recent' decl.
	llvm::DenseMap<NamedDecl, NamedDecl> Decls;

	public:
	/// Adds a new ADL candidate to this map.
	void insert(NamedDecl *D);

	/// Removes any data associated with a given decl.
	void erase(NamedDecl *D) {
	Decls.erase(cast<NamedDecl>(D->getCanonicalDecl()));
	}

	class iterator {
	typedef llvm::DenseMap<NamedDecl,NamedDecl>::iterator inner_iterator;
	inner_iterator iter;

	friend class ADLResult;
	iterator(const inner_iterator &iter) : iter(iter) {}
	public:
	iterator() {}

	iterator &operator++() { ++iter; return *this; }
	iterator operator++(int) { return iterator(iter++); }

	NamedDecl operator() const { return iter->second; }

	bool operator==(const iterator &other) const { return iter == other.iter; }
	bool operator!=(const iterator &other) const { return iter != other.iter; }
	};

	iterator begin() { return iterator(Decls.begin()); }
	iterator end() { return iterator(Decls.end()); }
	};

	}

	#endif