include/clang/AST/ExternalASTSource.h - third_party/swift-clang - Git at Google

 //===--- ExternalASTSource.h - Abstract External AST Interface --*- 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 ExternalASTSource interface, which enables
 //  construction of AST nodes from some external source.
 //
 //===----------------------------------------------------------------------===//
 #ifndef LLVM_CLANG_AST_EXTERNALASTSOURCE_H
 #define LLVM_CLANG_AST_EXTERNALASTSOURCE_H

 #include "clang/AST/CharUnits.h"
 #include "clang/AST/DeclBase.h"
 #include "llvm/ADT/DenseMap.h"

 namespace clang {

 class ASTConsumer;
 class CXXBaseSpecifier;
 class CXXCtorInitializer;
 class DeclarationName;
 class ExternalSemaSource; // layering violation required for downcasting
 class FieldDecl;
 class Module;
 class NamedDecl;
 class RecordDecl;
 class Selector;
 class Stmt;
 class TagDecl;

 /// \brief Abstract interface for external sources of AST nodes.
 ///
 /// External AST sources provide AST nodes constructed from some
 /// external source, such as a precompiled header. External AST
 /// sources can resolve types and declarations from abstract IDs into
 /// actual type and declaration nodes, and read parts of declaration
 /// contexts.
 class ExternalASTSource : public RefCountedBase<ExternalASTSource> {
   /// Generation number for this external AST source. Must be increased
   /// whenever we might have added new redeclarations for existing decls.
   uint32_t CurrentGeneration;

   /// \brief Whether this AST source also provides information for
   /// semantic analysis.
   bool SemaSource;

   friend class ExternalSemaSource;

 public:
   ExternalASTSource() : CurrentGeneration(0), SemaSource(false) { }

   virtual ~ExternalASTSource();

   /// \brief RAII class for safely pairing a StartedDeserializing call
   /// with FinishedDeserializing.
   class Deserializing {
     ExternalASTSource *Source;
   public:
     explicit Deserializing(ExternalASTSource *source) : Source(source) {
       assert(Source);
       Source->StartedDeserializing();
     }
     ~Deserializing() {
       Source->FinishedDeserializing();
     }
   };

   /// \brief Get the current generation of this AST source. This number
   /// is incremented each time the AST source lazily extends an existing
   /// entity.
   uint32_t getGeneration() const { return CurrentGeneration; }

   /// \brief Resolve a declaration ID into a declaration, potentially
   /// building a new declaration.
   ///
   /// This method only needs to be implemented if the AST source ever
   /// passes back decl sets as VisibleDeclaration objects.
   ///
   /// The default implementation of this method is a no-op.
   virtual Decl *GetExternalDecl(uint32_t ID);

   /// \brief Resolve a selector ID into a selector.
   ///
   /// This operation only needs to be implemented if the AST source
   /// returns non-zero for GetNumKnownSelectors().
   ///
   /// The default implementation of this method is a no-op.
   virtual Selector GetExternalSelector(uint32_t ID);

   /// \brief Returns the number of selectors known to the external AST
   /// source.
   ///
   /// The default implementation of this method is a no-op.
   virtual uint32_t GetNumExternalSelectors();

   /// \brief Resolve the offset of a statement in the decl stream into
   /// a statement.
   ///
   /// This operation is meant to be used via a LazyOffsetPtr.  It only
   /// needs to be implemented if the AST source uses methods like
   /// FunctionDecl::setLazyBody when building decls.
   ///
   /// The default implementation of this method is a no-op.
   virtual Stmt *GetExternalDeclStmt(uint64_t Offset);

   /// \brief Resolve the offset of a set of C++ constructor initializers in
   /// the decl stream into an array of initializers.
   ///
   /// The default implementation of this method is a no-op.
   virtual CXXCtorInitializer **GetExternalCXXCtorInitializers(uint64_t Offset);

   /// \brief Resolve the offset of a set of C++ base specifiers in the decl
   /// stream into an array of specifiers.
   ///
   /// The default implementation of this method is a no-op.
   virtual CXXBaseSpecifier *GetExternalCXXBaseSpecifiers(uint64_t Offset);

   /// \brief Update an out-of-date identifier.
   virtual void updateOutOfDateIdentifier(IdentifierInfo &II) { }

   /// \brief Find all declarations with the given name in the given context,
   /// and add them to the context by calling SetExternalVisibleDeclsForName
   /// or SetNoExternalVisibleDeclsForName.
   /// \return \c true if any declarations might have been found, \c false if
   /// we definitely have no declarations with tbis name.
   ///
   /// The default implementation of this method is a no-op returning \c false.
   virtual bool
   FindExternalVisibleDeclsByName(const DeclContext *DC, DeclarationName Name);

   /// \brief Ensures that the table of all visible declarations inside this
   /// context is up to date.
   ///
   /// The default implementation of this function is a no-op.
   virtual void completeVisibleDeclsMap(const DeclContext *DC);

   /// \brief Retrieve the module that corresponds to the given module ID.
   virtual Module *getModule(unsigned ID) { return nullptr; }

   /// Abstracts clang modules and precompiled header files and holds
   /// everything needed to generate debug info for an imported module
   /// or PCH.
   class ASTSourceDescriptor {
     StringRef PCHModuleName;
     StringRef Path;
     StringRef ASTFile;
     uint64_t Signature = 0;
     const Module *ClangModule = nullptr;

   public:
     ASTSourceDescriptor(){};
     ASTSourceDescriptor(StringRef Name, StringRef Path, StringRef ASTFile,
                         uint64_t Signature)
         : PCHModuleName(std::move(Name)), Path(std::move(Path)),
           ASTFile(std::move(ASTFile)), Signature(Signature){};
     ASTSourceDescriptor(const Module &M);
     std::string getModuleName() const;
     StringRef getPath() const { return Path; }
     StringRef getASTFile() const { return ASTFile; }
     uint64_t getSignature() const { return Signature; }
     const Module *getModuleOrNull() const { return ClangModule; }
   };

   /// Return a descriptor for the corresponding module, if one exists.
   virtual llvm::Optional<ASTSourceDescriptor> getSourceDescriptor(unsigned ID);

   /// \brief Finds all declarations lexically contained within the given
   /// DeclContext, after applying an optional filter predicate.
   ///
   /// \param IsKindWeWant a predicate function that returns true if the passed
   /// declaration kind is one we are looking for.
   ///
   /// The default implementation of this method is a no-op.
   virtual void
   FindExternalLexicalDecls(const DeclContext *DC,
                            llvm::function_ref<bool(Decl::Kind)> IsKindWeWant,
                            SmallVectorImpl<Decl *> &Result);

   /// \brief Finds all declarations lexically contained within the given
   /// DeclContext.
   void FindExternalLexicalDecls(const DeclContext *DC,
                                 SmallVectorImpl<Decl *> &Result) {
     FindExternalLexicalDecls(DC, [](Decl::Kind) { return true; }, Result);
   }

   /// \brief Get the decls that are contained in a file in the Offset/Length
   /// range. \p Length can be 0 to indicate a point at \p Offset instead of
   /// a range.
   virtual void FindFileRegionDecls(FileID File, unsigned Offset,
                                    unsigned Length,
                                    SmallVectorImpl<Decl *> &Decls);

   /// \brief Gives the external AST source an opportunity to complete
   /// the redeclaration chain for a declaration. Called each time we
   /// need the most recent declaration of a declaration after the
   /// generation count is incremented.
   virtual void CompleteRedeclChain(const Decl *D);

   /// \brief Gives the external AST source an opportunity to complete
   /// an incomplete type.
   virtual void CompleteType(TagDecl *Tag);

   /// \brief Gives the external AST source an opportunity to complete an
   /// incomplete Objective-C class.
   ///
   /// This routine will only be invoked if the "externally completed" bit is
   /// set on the ObjCInterfaceDecl via the function
   /// \c ObjCInterfaceDecl::setExternallyCompleted().
   virtual void CompleteType(ObjCInterfaceDecl *Class);

   /// \brief Loads comment ranges.
   virtual void ReadComments();

   /// \brief Notify ExternalASTSource that we started deserialization of
   /// a decl or type so until FinishedDeserializing is called there may be
   /// decls that are initializing. Must be paired with FinishedDeserializing.
   ///
   /// The default implementation of this method is a no-op.
   virtual void StartedDeserializing();

   /// \brief Notify ExternalASTSource that we finished the deserialization of
   /// a decl or type. Must be paired with StartedDeserializing.
   ///
   /// The default implementation of this method is a no-op.
   virtual void FinishedDeserializing();

   /// \brief Function that will be invoked when we begin parsing a new
   /// translation unit involving this external AST source.
   ///
   /// The default implementation of this method is a no-op.
   virtual void StartTranslationUnit(ASTConsumer *Consumer);

   /// \brief Print any statistics that have been gathered regarding
   /// the external AST source.
   ///
   /// The default implementation of this method is a no-op.
   virtual void PrintStats();


   /// \brief Perform layout on the given record.
   ///
   /// This routine allows the external AST source to provide an specific
   /// layout for a record, overriding the layout that would normally be
   /// constructed. It is intended for clients who receive specific layout
   /// details rather than source code (such as LLDB). The client is expected
   /// to fill in the field offsets, base offsets, virtual base offsets, and
   /// complete object size.
   ///
   /// \param Record The record whose layout is being requested.
   ///
   /// \param Size The final size of the record, in bits.
   ///
   /// \param Alignment The final alignment of the record, in bits.
   ///
   /// \param FieldOffsets The offset of each of the fields within the record,
   /// expressed in bits. All of the fields must be provided with offsets.
   ///
   /// \param BaseOffsets The offset of each of the direct, non-virtual base
   /// classes. If any bases are not given offsets, the bases will be laid
   /// out according to the ABI.
   ///
   /// \param VirtualBaseOffsets The offset of each of the virtual base classes
   /// (either direct or not). If any bases are not given offsets, the bases will be laid
   /// out according to the ABI.
   ///
   /// \returns true if the record layout was provided, false otherwise.
   virtual bool layoutRecordType(
       const RecordDecl *Record, uint64_t &Size, uint64_t &Alignment,
       llvm::DenseMap<const FieldDecl *, uint64_t> &FieldOffsets,
       llvm::DenseMap<const CXXRecordDecl *, CharUnits> &BaseOffsets,
       llvm::DenseMap<const CXXRecordDecl *, CharUnits> &VirtualBaseOffsets);

   //===--------------------------------------------------------------------===//
   // Queries for performance analysis.
   //===--------------------------------------------------------------------===//

   struct MemoryBufferSizes {
     size_t malloc_bytes;
     size_t mmap_bytes;

     MemoryBufferSizes(size_t malloc_bytes, size_t mmap_bytes)
     : malloc_bytes(malloc_bytes), mmap_bytes(mmap_bytes) {}
   };

   /// Return the amount of memory used by memory buffers, breaking down
   /// by heap-backed versus mmap'ed memory.
   MemoryBufferSizes getMemoryBufferSizes() const {
     MemoryBufferSizes sizes(0, 0);
     getMemoryBufferSizes(sizes);
     return sizes;
   }

   virtual void getMemoryBufferSizes(MemoryBufferSizes &sizes) const;

 protected:
   static DeclContextLookupResult
   SetExternalVisibleDeclsForName(const DeclContext *DC,
                                  DeclarationName Name,
                                  ArrayRef<NamedDecl*> Decls);

   static DeclContextLookupResult
   SetNoExternalVisibleDeclsForName(const DeclContext *DC,
                                    DeclarationName Name);

   /// \brief Increment the current generation.
   uint32_t incrementGeneration(ASTContext &C);
 };

 /// \brief A lazy pointer to an AST node (of base type T) that resides
 /// within an external AST source.
 ///
 /// The AST node is identified within the external AST source by a
 /// 63-bit offset, and can be retrieved via an operation on the
 /// external AST source itself.
 template<typename T, typename OffsT, T* (ExternalASTSource::*Get)(OffsT Offset)>
 struct LazyOffsetPtr {
   /// \brief Either a pointer to an AST node or the offset within the
   /// external AST source where the AST node can be found.
   ///
   /// If the low bit is clear, a pointer to the AST node. If the low
   /// bit is set, the upper 63 bits are the offset.
   mutable uint64_t Ptr;

 public:
   LazyOffsetPtr() : Ptr(0) { }

   explicit LazyOffsetPtr(T *Ptr) : Ptr(reinterpret_cast<uint64_t>(Ptr)) { }
   explicit LazyOffsetPtr(uint64_t Offset) : Ptr((Offset << 1) | 0x01) {
     assert((Offset << 1 >> 1) == Offset && "Offsets must require < 63 bits");
     if (Offset == 0)
       Ptr = 0;
   }

   LazyOffsetPtr &operator=(T *Ptr) {
     this->Ptr = reinterpret_cast<uint64_t>(Ptr);
     return *this;
   }

   LazyOffsetPtr &operator=(uint64_t Offset) {
     assert((Offset << 1 >> 1) == Offset && "Offsets must require < 63 bits");
     if (Offset == 0)
       Ptr = 0;
     else
       Ptr = (Offset << 1) | 0x01;

     return *this;
   }

   /// \brief Whether this pointer is non-NULL.
   ///
   /// This operation does not require the AST node to be deserialized.
   explicit operator bool() const { return Ptr != 0; }

   /// \brief Whether this pointer is non-NULL.
   ///
   /// This operation does not require the AST node to be deserialized.
   bool isValid() const { return Ptr != 0; }

   /// \brief Whether this pointer is currently stored as an offset.
   bool isOffset() const { return Ptr & 0x01; }

   /// \brief Retrieve the pointer to the AST node that this lazy pointer
   ///
   /// \param Source the external AST source.
   ///
   /// \returns a pointer to the AST node.
   T* get(ExternalASTSource *Source) const {
     if (isOffset()) {
       assert(Source &&
              "Cannot deserialize a lazy pointer without an AST source");
       Ptr = reinterpret_cast<uint64_t>((Source->*Get)(Ptr >> 1));
     }
     return reinterpret_cast<T*>(Ptr);
   }
 };

 /// \brief A lazy value (of type T) that is within an AST node of type Owner,
 /// where the value might change in later generations of the external AST
 /// source.
 template<typename Owner, typename T, void (ExternalASTSource::*Update)(Owner)>
 struct LazyGenerationalUpdatePtr {
   /// A cache of the value of this pointer, in the most recent generation in
   /// which we queried it.
   struct LazyData {
     LazyData(ExternalASTSource *Source, T Value)
         : ExternalSource(Source), LastGeneration(0), LastValue(Value) {}
     ExternalASTSource *ExternalSource;
     uint32_t LastGeneration;
     T LastValue;
   };

   // Our value is represented as simply T if there is no external AST source.
   typedef llvm::PointerUnion<T, LazyData*> ValueType;
   ValueType Value;

   LazyGenerationalUpdatePtr(ValueType V) : Value(V) {}

   // Defined in ASTContext.h
   static ValueType makeValue(const ASTContext &Ctx, T Value);

 public:
   explicit LazyGenerationalUpdatePtr(const ASTContext &Ctx, T Value = T())
       : Value(makeValue(Ctx, Value)) {}

   /// Create a pointer that is not potentially updated by later generations of
   /// the external AST source.
   enum NotUpdatedTag { NotUpdated };
   LazyGenerationalUpdatePtr(NotUpdatedTag, T Value = T())
       : Value(Value) {}

   /// Forcibly set this pointer (which must be lazy) as needing updates.
   void markIncomplete() {
     Value.template get<LazyData *>()->LastGeneration = 0;
   }

   /// Set the value of this pointer, in the current generation.
   void set(T NewValue) {
     if (LazyData *LazyVal = Value.template dyn_cast<LazyData*>()) {
       LazyVal->LastValue = NewValue;
       return;
     }
     Value = NewValue;
   }

   /// Set the value of this pointer, for this and all future generations.
   void setNotUpdated(T NewValue) { Value = NewValue; }

   /// Get the value of this pointer, updating its owner if necessary.
   T get(Owner O) {
     if (LazyData *LazyVal = Value.template dyn_cast<LazyData*>()) {
       if (LazyVal->LastGeneration != LazyVal->ExternalSource->getGeneration()) {
         LazyVal->LastGeneration = LazyVal->ExternalSource->getGeneration();
         (LazyVal->ExternalSource->*Update)(O);
       }
       return LazyVal->LastValue;
     }
     return Value.template get<T>();
   }

   /// Get the most recently computed value of this pointer without updating it.
   T getNotUpdated() const {
     if (LazyData *LazyVal = Value.template dyn_cast<LazyData*>())
       return LazyVal->LastValue;
     return Value.template get<T>();
   }

   void *getOpaqueValue() { return Value.getOpaqueValue(); }
   static LazyGenerationalUpdatePtr getFromOpaqueValue(void *Ptr) {
     return LazyGenerationalUpdatePtr(ValueType::getFromOpaqueValue(Ptr));
   }
 };
 } // end namespace clang

 /// Specialize PointerLikeTypeTraits to allow LazyGenerationalUpdatePtr to be
 /// placed into a PointerUnion.
 namespace llvm {
 template<typename Owner, typename T,
          void (clang::ExternalASTSource::*Update)(Owner)>
 struct PointerLikeTypeTraits<
     clang::LazyGenerationalUpdatePtr<Owner, T, Update>> {
   typedef clang::LazyGenerationalUpdatePtr<Owner, T, Update> Ptr;
   static void *getAsVoidPointer(Ptr P) { return P.getOpaqueValue(); }
   static Ptr getFromVoidPointer(void *P) { return Ptr::getFromOpaqueValue(P); }
   enum {
     NumLowBitsAvailable = PointerLikeTypeTraits<T>::NumLowBitsAvailable - 1
   };
 };
 }

 namespace clang {
 /// \brief Represents a lazily-loaded vector of data.
 ///
 /// The lazily-loaded vector of data contains data that is partially loaded
 /// from an external source and partially added by local translation. The
 /// items loaded from the external source are loaded lazily, when needed for
 /// iteration over the complete vector.
 template<typename T, typename Source,
          void (Source::*Loader)(SmallVectorImpl<T>&),
          unsigned LoadedStorage = 2, unsigned LocalStorage = 4>
 class LazyVector {
   SmallVector<T, LoadedStorage> Loaded;
   SmallVector<T, LocalStorage> Local;

 public:
   /// Iteration over the elements in the vector.
   ///
   /// In a complete iteration, the iterator walks the range [-M, N),
   /// where negative values are used to indicate elements
   /// loaded from the external source while non-negative values are used to
   /// indicate elements added via \c push_back().
   /// However, to provide iteration in source order (for, e.g., chained
   /// precompiled headers), dereferencing the iterator flips the negative
   /// values (corresponding to loaded entities), so that position -M
   /// corresponds to element 0 in the loaded entities vector, position -M+1
   /// corresponds to element 1 in the loaded entities vector, etc. This
   /// gives us a reasonably efficient, source-order walk.
   ///
   /// We define this as a wrapping iterator around an int. The
   /// iterator_adaptor_base class forwards the iterator methods to basic integer
   /// arithmetic.
   class iterator
       : public llvm::iterator_adaptor_base<
             iterator, int, std::random_access_iterator_tag, T, int, T *, T &> {
     LazyVector *Self;

     iterator(LazyVector *Self, int Position)
         : iterator::iterator_adaptor_base(Position), Self(Self) {}

     bool isLoaded() const { return this->I < 0; }
     friend class LazyVector;

   public:
     iterator() : iterator(nullptr, 0) {}

     typename iterator::reference operator*() const {
       if (isLoaded())
         return Self->Loaded.end()[this->I];
       return Self->Local.begin()[this->I];
     }
   };

   iterator begin(Source *source, bool LocalOnly = false) {
     if (LocalOnly)
       return iterator(this, 0);

     if (source)
       (source->*Loader)(Loaded);
     return iterator(this, -(int)Loaded.size());
   }

   iterator end() {
     return iterator(this, Local.size());
   }

   void push_back(const T& LocalValue) {
     Local.push_back(LocalValue);
   }

   void erase(iterator From, iterator To) {
     if (From.isLoaded() && To.isLoaded()) {
       Loaded.erase(&*From, &*To);
       return;
     }

     if (From.isLoaded()) {
       Loaded.erase(&*From, Loaded.end());
       From = begin(nullptr, true);
     }

     Local.erase(&*From, &*To);
   }
 };

 /// \brief A lazy pointer to a statement.
 typedef LazyOffsetPtr<Stmt, uint64_t, &ExternalASTSource::GetExternalDeclStmt>
   LazyDeclStmtPtr;

 /// \brief A lazy pointer to a declaration.
 typedef LazyOffsetPtr<Decl, uint32_t, &ExternalASTSource::GetExternalDecl>
   LazyDeclPtr;

 /// \brief A lazy pointer to a set of CXXCtorInitializers.
 typedef LazyOffsetPtr<CXXCtorInitializer *, uint64_t,
                       &ExternalASTSource::GetExternalCXXCtorInitializers>
   LazyCXXCtorInitializersPtr;

 /// \brief A lazy pointer to a set of CXXBaseSpecifiers.
 typedef LazyOffsetPtr<CXXBaseSpecifier, uint64_t,
                       &ExternalASTSource::GetExternalCXXBaseSpecifiers>
   LazyCXXBaseSpecifiersPtr;

 } // end namespace clang

 #endif
	//===--- ExternalASTSource.h - Abstract External AST Interface --- 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 ExternalASTSource interface, which enables
	// construction of AST nodes from some external source.
	//
	//===----------------------------------------------------------------------===//
	#ifndef LLVM_CLANG_AST_EXTERNALASTSOURCE_H
	#define LLVM_CLANG_AST_EXTERNALASTSOURCE_H

	#include "clang/AST/CharUnits.h"
	#include "clang/AST/DeclBase.h"
	#include "llvm/ADT/DenseMap.h"

	namespace clang {

	class ASTConsumer;
	class CXXBaseSpecifier;
	class CXXCtorInitializer;
	class DeclarationName;
	class ExternalSemaSource; // layering violation required for downcasting
	class FieldDecl;
	class Module;
	class NamedDecl;
	class RecordDecl;
	class Selector;
	class Stmt;
	class TagDecl;

	/// \brief Abstract interface for external sources of AST nodes.
	///
	/// External AST sources provide AST nodes constructed from some
	/// external source, such as a precompiled header. External AST
	/// sources can resolve types and declarations from abstract IDs into
	/// actual type and declaration nodes, and read parts of declaration
	/// contexts.
	class ExternalASTSource : public RefCountedBase<ExternalASTSource> {
	/// Generation number for this external AST source. Must be increased
	/// whenever we might have added new redeclarations for existing decls.
	uint32_t CurrentGeneration;

	/// \brief Whether this AST source also provides information for
	/// semantic analysis.
	bool SemaSource;

	friend class ExternalSemaSource;

	public:
	ExternalASTSource() : CurrentGeneration(0), SemaSource(false) { }

	virtual ~ExternalASTSource();

	/// \brief RAII class for safely pairing a StartedDeserializing call
	/// with FinishedDeserializing.
	class Deserializing {
	ExternalASTSource *Source;
	public:
	explicit Deserializing(ExternalASTSource *source) : Source(source) {
	assert(Source);
	Source->StartedDeserializing();
	}
	~Deserializing() {
	Source->FinishedDeserializing();
	}
	};

	/// \brief Get the current generation of this AST source. This number
	/// is incremented each time the AST source lazily extends an existing
	/// entity.
	uint32_t getGeneration() const { return CurrentGeneration; }

	/// \brief Resolve a declaration ID into a declaration, potentially
	/// building a new declaration.
	///
	/// This method only needs to be implemented if the AST source ever
	/// passes back decl sets as VisibleDeclaration objects.
	///
	/// The default implementation of this method is a no-op.
	virtual Decl *GetExternalDecl(uint32_t ID);

	/// \brief Resolve a selector ID into a selector.
	///
	/// This operation only needs to be implemented if the AST source
	/// returns non-zero for GetNumKnownSelectors().
	///
	/// The default implementation of this method is a no-op.
	virtual Selector GetExternalSelector(uint32_t ID);

	/// \brief Returns the number of selectors known to the external AST
	/// source.
	///
	/// The default implementation of this method is a no-op.
	virtual uint32_t GetNumExternalSelectors();

	/// \brief Resolve the offset of a statement in the decl stream into
	/// a statement.
	///
	/// This operation is meant to be used via a LazyOffsetPtr. It only
	/// needs to be implemented if the AST source uses methods like
	/// FunctionDecl::setLazyBody when building decls.
	///
	/// The default implementation of this method is a no-op.
	virtual Stmt *GetExternalDeclStmt(uint64_t Offset);

	/// \brief Resolve the offset of a set of C++ constructor initializers in
	/// the decl stream into an array of initializers.
	///
	/// The default implementation of this method is a no-op.
	virtual CXXCtorInitializer **GetExternalCXXCtorInitializers(uint64_t Offset);

	/// \brief Resolve the offset of a set of C++ base specifiers in the decl
	/// stream into an array of specifiers.
	///
	/// The default implementation of this method is a no-op.
	virtual CXXBaseSpecifier *GetExternalCXXBaseSpecifiers(uint64_t Offset);

	/// \brief Update an out-of-date identifier.
	virtual void updateOutOfDateIdentifier(IdentifierInfo &II) { }

	/// \brief Find all declarations with the given name in the given context,
	/// and add them to the context by calling SetExternalVisibleDeclsForName
	/// or SetNoExternalVisibleDeclsForName.
	/// \return \c true if any declarations might have been found, \c false if
	/// we definitely have no declarations with tbis name.
	///
	/// The default implementation of this method is a no-op returning \c false.
	virtual bool
	FindExternalVisibleDeclsByName(const DeclContext *DC, DeclarationName Name);

	/// \brief Ensures that the table of all visible declarations inside this
	/// context is up to date.
	///
	/// The default implementation of this function is a no-op.
	virtual void completeVisibleDeclsMap(const DeclContext *DC);

	/// \brief Retrieve the module that corresponds to the given module ID.
	virtual Module *getModule(unsigned ID) { return nullptr; }

	/// Abstracts clang modules and precompiled header files and holds
	/// everything needed to generate debug info for an imported module
	/// or PCH.
	class ASTSourceDescriptor {
	StringRef PCHModuleName;
	StringRef Path;
	StringRef ASTFile;
	uint64_t Signature = 0;
	const Module *ClangModule = nullptr;

	public:
	ASTSourceDescriptor(){};
	ASTSourceDescriptor(StringRef Name, StringRef Path, StringRef ASTFile,
	uint64_t Signature)
	: PCHModuleName(std::move(Name)), Path(std::move(Path)),
	ASTFile(std::move(ASTFile)), Signature(Signature){};
	ASTSourceDescriptor(const Module &M);
	std::string getModuleName() const;
	StringRef getPath() const { return Path; }
	StringRef getASTFile() const { return ASTFile; }
	uint64_t getSignature() const { return Signature; }
	const Module *getModuleOrNull() const { return ClangModule; }
	};

	/// Return a descriptor for the corresponding module, if one exists.
	virtual llvm::Optional<ASTSourceDescriptor> getSourceDescriptor(unsigned ID);

	/// \brief Finds all declarations lexically contained within the given
	/// DeclContext, after applying an optional filter predicate.
	///
	/// \param IsKindWeWant a predicate function that returns true if the passed
	/// declaration kind is one we are looking for.
	///
	/// The default implementation of this method is a no-op.
	virtual void
	FindExternalLexicalDecls(const DeclContext *DC,
	llvm::function_ref<bool(Decl::Kind)> IsKindWeWant,
	SmallVectorImpl<Decl *> &Result);

	/// \brief Finds all declarations lexically contained within the given
	/// DeclContext.
	void FindExternalLexicalDecls(const DeclContext *DC,
	SmallVectorImpl<Decl *> &Result) {
	FindExternalLexicalDecls(DC, [](Decl::Kind) { return true; }, Result);
	}

	/// \brief Get the decls that are contained in a file in the Offset/Length
	/// range. \p Length can be 0 to indicate a point at \p Offset instead of
	/// a range.
	virtual void FindFileRegionDecls(FileID File, unsigned Offset,
	unsigned Length,
	SmallVectorImpl<Decl *> &Decls);

	/// \brief Gives the external AST source an opportunity to complete
	/// the redeclaration chain for a declaration. Called each time we
	/// need the most recent declaration of a declaration after the
	/// generation count is incremented.
	virtual void CompleteRedeclChain(const Decl *D);

	/// \brief Gives the external AST source an opportunity to complete
	/// an incomplete type.
	virtual void CompleteType(TagDecl *Tag);

	/// \brief Gives the external AST source an opportunity to complete an
	/// incomplete Objective-C class.
	///
	/// This routine will only be invoked if the "externally completed" bit is
	/// set on the ObjCInterfaceDecl via the function
	/// \c ObjCInterfaceDecl::setExternallyCompleted().
	virtual void CompleteType(ObjCInterfaceDecl *Class);

	/// \brief Loads comment ranges.
	virtual void ReadComments();

	/// \brief Notify ExternalASTSource that we started deserialization of
	/// a decl or type so until FinishedDeserializing is called there may be
	/// decls that are initializing. Must be paired with FinishedDeserializing.
	///
	/// The default implementation of this method is a no-op.
	virtual void StartedDeserializing();

	/// \brief Notify ExternalASTSource that we finished the deserialization of
	/// a decl or type. Must be paired with StartedDeserializing.
	///
	/// The default implementation of this method is a no-op.
	virtual void FinishedDeserializing();

	/// \brief Function that will be invoked when we begin parsing a new
	/// translation unit involving this external AST source.
	///
	/// The default implementation of this method is a no-op.
	virtual void StartTranslationUnit(ASTConsumer *Consumer);

	/// \brief Print any statistics that have been gathered regarding
	/// the external AST source.
	///
	/// The default implementation of this method is a no-op.
	virtual void PrintStats();


	/// \brief Perform layout on the given record.
	///
	/// This routine allows the external AST source to provide an specific
	/// layout for a record, overriding the layout that would normally be
	/// constructed. It is intended for clients who receive specific layout
	/// details rather than source code (such as LLDB). The client is expected
	/// to fill in the field offsets, base offsets, virtual base offsets, and
	/// complete object size.
	///
	/// \param Record The record whose layout is being requested.
	///
	/// \param Size The final size of the record, in bits.
	///
	/// \param Alignment The final alignment of the record, in bits.
	///
	/// \param FieldOffsets The offset of each of the fields within the record,
	/// expressed in bits. All of the fields must be provided with offsets.
	///
	/// \param BaseOffsets The offset of each of the direct, non-virtual base
	/// classes. If any bases are not given offsets, the bases will be laid
	/// out according to the ABI.
	///
	/// \param VirtualBaseOffsets The offset of each of the virtual base classes
	/// (either direct or not). If any bases are not given offsets, the bases will be laid
	/// out according to the ABI.
	///
	/// \returns true if the record layout was provided, false otherwise.
	virtual bool layoutRecordType(
	const RecordDecl *Record, uint64_t &Size, uint64_t &Alignment,
	llvm::DenseMap<const FieldDecl *, uint64_t> &FieldOffsets,
	llvm::DenseMap<const CXXRecordDecl *, CharUnits> &BaseOffsets,
	llvm::DenseMap<const CXXRecordDecl *, CharUnits> &VirtualBaseOffsets);

	//===--------------------------------------------------------------------===//
	// Queries for performance analysis.
	//===--------------------------------------------------------------------===//

	struct MemoryBufferSizes {
	size_t malloc_bytes;
	size_t mmap_bytes;

	MemoryBufferSizes(size_t malloc_bytes, size_t mmap_bytes)
	: malloc_bytes(malloc_bytes), mmap_bytes(mmap_bytes) {}
	};

	/// Return the amount of memory used by memory buffers, breaking down
	/// by heap-backed versus mmap'ed memory.
	MemoryBufferSizes getMemoryBufferSizes() const {
	MemoryBufferSizes sizes(0, 0);
	getMemoryBufferSizes(sizes);
	return sizes;
	}

	virtual void getMemoryBufferSizes(MemoryBufferSizes &sizes) const;

	protected:
	static DeclContextLookupResult
	SetExternalVisibleDeclsForName(const DeclContext *DC,
	DeclarationName Name,
	ArrayRef<NamedDecl*> Decls);

	static DeclContextLookupResult
	SetNoExternalVisibleDeclsForName(const DeclContext *DC,
	DeclarationName Name);

	/// \brief Increment the current generation.
	uint32_t incrementGeneration(ASTContext &C);
	};

	/// \brief A lazy pointer to an AST node (of base type T) that resides
	/// within an external AST source.
	///
	/// The AST node is identified within the external AST source by a
	/// 63-bit offset, and can be retrieved via an operation on the
	/// external AST source itself.
	template<typename T, typename OffsT, T* (ExternalASTSource::*Get)(OffsT Offset)>
	struct LazyOffsetPtr {
	/// \brief Either a pointer to an AST node or the offset within the
	/// external AST source where the AST node can be found.
	///
	/// If the low bit is clear, a pointer to the AST node. If the low
	/// bit is set, the upper 63 bits are the offset.
	mutable uint64_t Ptr;

	public:
	LazyOffsetPtr() : Ptr(0) { }

	explicit LazyOffsetPtr(T *Ptr) : Ptr(reinterpret_cast<uint64_t>(Ptr)) { }
	explicit LazyOffsetPtr(uint64_t Offset) : Ptr((Offset << 1) \| 0x01) {
	assert((Offset << 1 >> 1) == Offset && "Offsets must require < 63 bits");
	if (Offset == 0)
	Ptr = 0;
	}

	LazyOffsetPtr &operator=(T *Ptr) {
	this->Ptr = reinterpret_cast<uint64_t>(Ptr);
	return *this;
	}

	LazyOffsetPtr &operator=(uint64_t Offset) {
	assert((Offset << 1 >> 1) == Offset && "Offsets must require < 63 bits");
	if (Offset == 0)
	Ptr = 0;
	else
	Ptr = (Offset << 1) \| 0x01;

	return *this;
	}

	/// \brief Whether this pointer is non-NULL.
	///
	/// This operation does not require the AST node to be deserialized.
	explicit operator bool() const { return Ptr != 0; }

	/// \brief Whether this pointer is non-NULL.
	///
	/// This operation does not require the AST node to be deserialized.
	bool isValid() const { return Ptr != 0; }

	/// \brief Whether this pointer is currently stored as an offset.
	bool isOffset() const { return Ptr & 0x01; }

	/// \brief Retrieve the pointer to the AST node that this lazy pointer
	///
	/// \param Source the external AST source.
	///
	/// \returns a pointer to the AST node.
	T* get(ExternalASTSource *Source) const {
	if (isOffset()) {
	assert(Source &&
	"Cannot deserialize a lazy pointer without an AST source");
	Ptr = reinterpret_cast<uint64_t>((Source->*Get)(Ptr >> 1));
	}
	return reinterpret_cast<T*>(Ptr);
	}
	};

	/// \brief A lazy value (of type T) that is within an AST node of type Owner,
	/// where the value might change in later generations of the external AST
	/// source.
	template<typename Owner, typename T, void (ExternalASTSource::*Update)(Owner)>
	struct LazyGenerationalUpdatePtr {
	/// A cache of the value of this pointer, in the most recent generation in
	/// which we queried it.
	struct LazyData {
	LazyData(ExternalASTSource *Source, T Value)
	: ExternalSource(Source), LastGeneration(0), LastValue(Value) {}
	ExternalASTSource *ExternalSource;
	uint32_t LastGeneration;
	T LastValue;
	};

	// Our value is represented as simply T if there is no external AST source.
	typedef llvm::PointerUnion<T, LazyData*> ValueType;
	ValueType Value;

	LazyGenerationalUpdatePtr(ValueType V) : Value(V) {}

	// Defined in ASTContext.h
	static ValueType makeValue(const ASTContext &Ctx, T Value);

	public:
	explicit LazyGenerationalUpdatePtr(const ASTContext &Ctx, T Value = T())
	: Value(makeValue(Ctx, Value)) {}

	/// Create a pointer that is not potentially updated by later generations of
	/// the external AST source.
	enum NotUpdatedTag { NotUpdated };
	LazyGenerationalUpdatePtr(NotUpdatedTag, T Value = T())
	: Value(Value) {}

	/// Forcibly set this pointer (which must be lazy) as needing updates.
	void markIncomplete() {
	Value.template get<LazyData *>()->LastGeneration = 0;
	}

	/// Set the value of this pointer, in the current generation.
	void set(T NewValue) {
	if (LazyData LazyVal = Value.template dyn_cast<LazyData>()) {
	LazyVal->LastValue = NewValue;
	return;
	}
	Value = NewValue;
	}

	/// Set the value of this pointer, for this and all future generations.
	void setNotUpdated(T NewValue) { Value = NewValue; }

	/// Get the value of this pointer, updating its owner if necessary.
	T get(Owner O) {
	if (LazyData LazyVal = Value.template dyn_cast<LazyData>()) {
	if (LazyVal->LastGeneration != LazyVal->ExternalSource->getGeneration()) {
	LazyVal->LastGeneration = LazyVal->ExternalSource->getGeneration();
	(LazyVal->ExternalSource->*Update)(O);
	}
	return LazyVal->LastValue;
	}
	return Value.template get<T>();
	}

	/// Get the most recently computed value of this pointer without updating it.
	T getNotUpdated() const {
	if (LazyData LazyVal = Value.template dyn_cast<LazyData>())
	return LazyVal->LastValue;
	return Value.template get<T>();
	}

	void *getOpaqueValue() { return Value.getOpaqueValue(); }
	static LazyGenerationalUpdatePtr getFromOpaqueValue(void *Ptr) {
	return LazyGenerationalUpdatePtr(ValueType::getFromOpaqueValue(Ptr));
	}
	};
	} // end namespace clang

	/// Specialize PointerLikeTypeTraits to allow LazyGenerationalUpdatePtr to be
	/// placed into a PointerUnion.
	namespace llvm {
	template<typename Owner, typename T,
	void (clang::ExternalASTSource::*Update)(Owner)>
	struct PointerLikeTypeTraits<
	clang::LazyGenerationalUpdatePtr<Owner, T, Update>> {
	typedef clang::LazyGenerationalUpdatePtr<Owner, T, Update> Ptr;
	static void *getAsVoidPointer(Ptr P) { return P.getOpaqueValue(); }
	static Ptr getFromVoidPointer(void *P) { return Ptr::getFromOpaqueValue(P); }
	enum {
	NumLowBitsAvailable = PointerLikeTypeTraits<T>::NumLowBitsAvailable - 1
	};
	};
	}

	namespace clang {
	/// \brief Represents a lazily-loaded vector of data.
	///
	/// The lazily-loaded vector of data contains data that is partially loaded
	/// from an external source and partially added by local translation. The
	/// items loaded from the external source are loaded lazily, when needed for
	/// iteration over the complete vector.
	template<typename T, typename Source,
	void (Source::*Loader)(SmallVectorImpl<T>&),
	unsigned LoadedStorage = 2, unsigned LocalStorage = 4>
	class LazyVector {
	SmallVector<T, LoadedStorage> Loaded;
	SmallVector<T, LocalStorage> Local;

	public:
	/// Iteration over the elements in the vector.
	///
	/// In a complete iteration, the iterator walks the range [-M, N),
	/// where negative values are used to indicate elements
	/// loaded from the external source while non-negative values are used to
	/// indicate elements added via \c push_back().
	/// However, to provide iteration in source order (for, e.g., chained
	/// precompiled headers), dereferencing the iterator flips the negative
	/// values (corresponding to loaded entities), so that position -M
	/// corresponds to element 0 in the loaded entities vector, position -M+1
	/// corresponds to element 1 in the loaded entities vector, etc. This
	/// gives us a reasonably efficient, source-order walk.
	///
	/// We define this as a wrapping iterator around an int. The
	/// iterator_adaptor_base class forwards the iterator methods to basic integer
	/// arithmetic.
	class iterator
	: public llvm::iterator_adaptor_base<
	iterator, int, std::random_access_iterator_tag, T, int, T *, T &> {
	LazyVector *Self;

	iterator(LazyVector *Self, int Position)
	: iterator::iterator_adaptor_base(Position), Self(Self) {}

	bool isLoaded() const { return this->I < 0; }
	friend class LazyVector;

	public:
	iterator() : iterator(nullptr, 0) {}

	typename iterator::reference operator*() const {
	if (isLoaded())
	return Self->Loaded.end()[this->I];
	return Self->Local.begin()[this->I];
	}
	};

	iterator begin(Source *source, bool LocalOnly = false) {
	if (LocalOnly)
	return iterator(this, 0);

	if (source)
	(source->*Loader)(Loaded);
	return iterator(this, -(int)Loaded.size());
	}

	iterator end() {
	return iterator(this, Local.size());
	}

	void push_back(const T& LocalValue) {
	Local.push_back(LocalValue);
	}

	void erase(iterator From, iterator To) {
	if (From.isLoaded() && To.isLoaded()) {
	Loaded.erase(&From, &To);
	return;
	}

	if (From.isLoaded()) {
	Loaded.erase(&*From, Loaded.end());
	From = begin(nullptr, true);
	}

	Local.erase(&From, &To);
	}
	};

	/// \brief A lazy pointer to a statement.
	typedef LazyOffsetPtr<Stmt, uint64_t, &ExternalASTSource::GetExternalDeclStmt>
	LazyDeclStmtPtr;

	/// \brief A lazy pointer to a declaration.
	typedef LazyOffsetPtr<Decl, uint32_t, &ExternalASTSource::GetExternalDecl>
	LazyDeclPtr;

	/// \brief A lazy pointer to a set of CXXCtorInitializers.
	typedef LazyOffsetPtr<CXXCtorInitializer *, uint64_t,
	&ExternalASTSource::GetExternalCXXCtorInitializers>
	LazyCXXCtorInitializersPtr;

	/// \brief A lazy pointer to a set of CXXBaseSpecifiers.
	typedef LazyOffsetPtr<CXXBaseSpecifier, uint64_t,
	&ExternalASTSource::GetExternalCXXBaseSpecifiers>
	LazyCXXBaseSpecifiersPtr;

	} // end namespace clang

	#endif