//===--- PreprocessingRecord.h - Record of Preprocessing --------*- 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 PreprocessingRecord class, which maintains a record // of what occurred during preprocessing. // //===----------------------------------------------------------------------===// #ifndef LLVM_CLANG_LEX_PREPROCESSINGRECORD_H #define LLVM_CLANG_LEX_PREPROCESSINGRECORD_H #include "clang/Basic/IdentifierTable.h" #include "clang/Basic/SourceLocation.h" #include "clang/Lex/PPCallbacks.h" #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/Optional.h" #include "llvm/ADT/SmallVector.h" #include "llvm/Support/Allocator.h" #include "llvm/Support/Compiler.h" #include namespace clang { class IdentifierInfo; class MacroInfo; class PreprocessingRecord; } /// \brief Allocates memory within a Clang preprocessing record. void* operator new(size_t bytes, clang::PreprocessingRecord& PR, unsigned alignment = 8) throw(); /// \brief Frees memory allocated in a Clang preprocessing record. void operator delete(void* ptr, clang::PreprocessingRecord& PR, unsigned) throw(); namespace clang { class MacroDefinition; class FileEntry; /// \brief Base class that describes a preprocessed entity, which may be a /// preprocessor directive or macro expansion. class PreprocessedEntity { public: /// \brief The kind of preprocessed entity an object describes. enum EntityKind { /// \brief Indicates a problem trying to load the preprocessed entity. InvalidKind, /// \brief A macro expansion. MacroExpansionKind, /// \defgroup Preprocessing directives /// @{ /// \brief A macro definition. MacroDefinitionKind, /// \brief An inclusion directive, such as \c \#include, \c /// \#import, or \c \#include_next. InclusionDirectiveKind, /// @} FirstPreprocessingDirective = MacroDefinitionKind, LastPreprocessingDirective = InclusionDirectiveKind }; private: /// \brief The kind of preprocessed entity that this object describes. EntityKind Kind; /// \brief The source range that covers this preprocessed entity. SourceRange Range; protected: PreprocessedEntity(EntityKind Kind, SourceRange Range) : Kind(Kind), Range(Range) { } friend class PreprocessingRecord; public: /// \brief Retrieve the kind of preprocessed entity stored in this object. EntityKind getKind() const { return Kind; } /// \brief Retrieve the source range that covers this entire preprocessed /// entity. SourceRange getSourceRange() const LLVM_READONLY { return Range; } /// \brief Returns true if there was a problem loading the preprocessed /// entity. bool isInvalid() const { return Kind == InvalidKind; } // Only allow allocation of preprocessed entities using the allocator // in PreprocessingRecord or by doing a placement new. void* operator new(size_t bytes, PreprocessingRecord& PR, unsigned alignment = 8) throw() { return ::operator new(bytes, PR, alignment); } void* operator new(size_t bytes, void* mem) throw() { return mem; } void operator delete(void* ptr, PreprocessingRecord& PR, unsigned alignment) throw() { return ::operator delete(ptr, PR, alignment); } void operator delete(void*, std::size_t) throw() { } void operator delete(void*, void*) throw() { } private: // Make vanilla 'new' and 'delete' illegal for preprocessed entities. void* operator new(size_t bytes) throw(); void operator delete(void* data) throw(); }; /// \brief Records the presence of a preprocessor directive. class PreprocessingDirective : public PreprocessedEntity { public: PreprocessingDirective(EntityKind Kind, SourceRange Range) : PreprocessedEntity(Kind, Range) { } // Implement isa/cast/dyncast/etc. static bool classof(const PreprocessedEntity *PD) { return PD->getKind() >= FirstPreprocessingDirective && PD->getKind() <= LastPreprocessingDirective; } }; /// \brief Record the location of a macro definition. class MacroDefinition : public PreprocessingDirective { /// \brief The name of the macro being defined. const IdentifierInfo *Name; public: explicit MacroDefinition(const IdentifierInfo *Name, SourceRange Range) : PreprocessingDirective(MacroDefinitionKind, Range), Name(Name) { } /// \brief Retrieve the name of the macro being defined. const IdentifierInfo *getName() const { return Name; } /// \brief Retrieve the location of the macro name in the definition. SourceLocation getLocation() const { return getSourceRange().getBegin(); } // Implement isa/cast/dyncast/etc. static bool classof(const PreprocessedEntity *PE) { return PE->getKind() == MacroDefinitionKind; } }; /// \brief Records the location of a macro expansion. class MacroExpansion : public PreprocessedEntity { /// \brief The definition of this macro or the name of the macro if it is /// a builtin macro. llvm::PointerUnion NameOrDef; public: MacroExpansion(IdentifierInfo *BuiltinName, SourceRange Range) : PreprocessedEntity(MacroExpansionKind, Range), NameOrDef(BuiltinName) { } MacroExpansion(MacroDefinition *Definition, SourceRange Range) : PreprocessedEntity(MacroExpansionKind, Range), NameOrDef(Definition) { } /// \brief True if it is a builtin macro. bool isBuiltinMacro() const { return NameOrDef.is(); } /// \brief The name of the macro being expanded. const IdentifierInfo *getName() const { if (MacroDefinition *Def = getDefinition()) return Def->getName(); return NameOrDef.get(); } /// \brief The definition of the macro being expanded. May return null if /// this is a builtin macro. MacroDefinition *getDefinition() const { return NameOrDef.dyn_cast(); } // Implement isa/cast/dyncast/etc. static bool classof(const PreprocessedEntity *PE) { return PE->getKind() == MacroExpansionKind; } }; /// \brief Record the location of an inclusion directive, such as an /// \c \#include or \c \#import statement. class InclusionDirective : public PreprocessingDirective { public: /// \brief The kind of inclusion directives known to the /// preprocessor. enum InclusionKind { /// \brief An \c \#include directive. Include, /// \brief An Objective-C \c \#import directive. Import, /// \brief A GNU \c \#include_next directive. IncludeNext, /// \brief A Clang \c \#__include_macros directive. IncludeMacros }; private: /// \brief The name of the file that was included, as written in /// the source. StringRef FileName; /// \brief Whether the file name was in quotation marks; otherwise, it was /// in angle brackets. unsigned InQuotes : 1; /// \brief The kind of inclusion directive we have. /// /// This is a value of type InclusionKind. unsigned Kind : 2; /// \brief Whether the inclusion directive was automatically turned into /// a module import. unsigned ImportedModule : 1; /// \brief The file that was included. const FileEntry *File; public: InclusionDirective(PreprocessingRecord &PPRec, InclusionKind Kind, StringRef FileName, bool InQuotes, bool ImportedModule, const FileEntry *File, SourceRange Range); /// \brief Determine what kind of inclusion directive this is. InclusionKind getKind() const { return static_cast(Kind); } /// \brief Retrieve the included file name as it was written in the source. StringRef getFileName() const { return FileName; } /// \brief Determine whether the included file name was written in quotes; /// otherwise, it was written in angle brackets. bool wasInQuotes() const { return InQuotes; } /// \brief Determine whether the inclusion directive was automatically /// turned into a module import. bool importedModule() const { return ImportedModule; } /// \brief Retrieve the file entry for the actual file that was included /// by this directive. const FileEntry *getFile() const { return File; } // Implement isa/cast/dyncast/etc. static bool classof(const PreprocessedEntity *PE) { return PE->getKind() == InclusionDirectiveKind; } }; /// \brief An abstract class that should be subclassed by any external source /// of preprocessing record entries. class ExternalPreprocessingRecordSource { public: virtual ~ExternalPreprocessingRecordSource(); /// \brief Read a preallocated preprocessed entity from the external source. /// /// \returns null if an error occurred that prevented the preprocessed /// entity from being loaded. virtual PreprocessedEntity *ReadPreprocessedEntity(unsigned Index) = 0; /// \brief Returns a pair of [Begin, End) indices of preallocated /// preprocessed entities that \p Range encompasses. virtual std::pair findPreprocessedEntitiesInRange(SourceRange Range) = 0; /// \brief Optionally returns true or false if the preallocated preprocessed /// entity with index \p Index came from file \p FID. virtual Optional isPreprocessedEntityInFileID(unsigned Index, FileID FID) { return None; } }; /// \brief A record of the steps taken while preprocessing a source file, /// including the various preprocessing directives processed, macros /// expanded, etc. class PreprocessingRecord : public PPCallbacks { SourceManager &SourceMgr; /// \brief Allocator used to store preprocessing objects. llvm::BumpPtrAllocator BumpAlloc; /// \brief The set of preprocessed entities in this record, in order they /// were seen. std::vector PreprocessedEntities; /// \brief The set of preprocessed entities in this record that have been /// loaded from external sources. /// /// The entries in this vector are loaded lazily from the external source, /// and are referenced by the iterator using negative indices. std::vector LoadedPreprocessedEntities; /// \brief Global (loaded or local) ID for a preprocessed entity. /// Negative values are used to indicate preprocessed entities /// loaded from the external source while non-negative values are used to /// indicate preprocessed entities introduced by the current preprocessor. /// Value -1 corresponds to element 0 in the loaded entities vector, /// value -2 corresponds to element 1 in the loaded entities vector, etc. /// Value 0 is an invalid value, the index to local entities is 1-based, /// value 1 corresponds to element 0 in the local entities vector, /// value 2 corresponds to element 1 in the local entities vector, etc. class PPEntityID { int ID; explicit PPEntityID(int ID) : ID(ID) {} friend class PreprocessingRecord; public: PPEntityID() : ID(0) {} }; static PPEntityID getPPEntityID(unsigned Index, bool isLoaded) { return isLoaded ? PPEntityID(-int(Index)-1) : PPEntityID(Index+1); } /// \brief Mapping from MacroInfo structures to their definitions. llvm::DenseMap MacroDefinitions; /// \brief External source of preprocessed entities. ExternalPreprocessingRecordSource *ExternalSource; /// \brief Retrieve the preprocessed entity at the given ID. PreprocessedEntity *getPreprocessedEntity(PPEntityID PPID); /// \brief Retrieve the loaded preprocessed entity at the given index. PreprocessedEntity *getLoadedPreprocessedEntity(unsigned Index); /// \brief Determine the number of preprocessed entities that were /// loaded (or can be loaded) from an external source. unsigned getNumLoadedPreprocessedEntities() const { return LoadedPreprocessedEntities.size(); } /// \brief Returns a pair of [Begin, End) indices of local preprocessed /// entities that \p Range encompasses. std::pair findLocalPreprocessedEntitiesInRange(SourceRange Range) const; unsigned findBeginLocalPreprocessedEntity(SourceLocation Loc) const; unsigned findEndLocalPreprocessedEntity(SourceLocation Loc) const; /// \brief Allocate space for a new set of loaded preprocessed entities. /// /// \returns The index into the set of loaded preprocessed entities, which /// corresponds to the first newly-allocated entity. unsigned allocateLoadedEntities(unsigned NumEntities); /// \brief Register a new macro definition. void RegisterMacroDefinition(MacroInfo *Macro, MacroDefinition *Def); public: /// \brief Construct a new preprocessing record. explicit PreprocessingRecord(SourceManager &SM); /// \brief Allocate memory in the preprocessing record. void *Allocate(unsigned Size, unsigned Align = 8) { return BumpAlloc.Allocate(Size, Align); } /// \brief Deallocate memory in the preprocessing record. void Deallocate(void *Ptr) { } size_t getTotalMemory() const; SourceManager &getSourceManager() const { return SourceMgr; } // Iteration over the preprocessed entities. class iterator { PreprocessingRecord *Self; /// \brief Position within the preprocessed entity sequence. /// /// In a complete iteration, the Position field walks the range [-M, N), /// where negative values are used to indicate preprocessed entities /// loaded from the external source while non-negative values are used to /// indicate preprocessed entities introduced by the current preprocessor. /// 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. int Position; public: typedef PreprocessedEntity *value_type; typedef value_type& reference; typedef value_type* pointer; typedef std::random_access_iterator_tag iterator_category; typedef int difference_type; iterator() : Self(0), Position(0) { } iterator(PreprocessingRecord *Self, int Position) : Self(Self), Position(Position) { } value_type operator*() const { bool isLoaded = Position < 0; unsigned Index = isLoaded ? Self->LoadedPreprocessedEntities.size() + Position : Position; PPEntityID ID = Self->getPPEntityID(Index, isLoaded); return Self->getPreprocessedEntity(ID); } value_type operator[](difference_type D) { return *(*this + D); } iterator &operator++() { ++Position; return *this; } iterator operator++(int) { iterator Prev(*this); ++Position; return Prev; } iterator &operator--() { --Position; return *this; } iterator operator--(int) { iterator Prev(*this); --Position; return Prev; } friend bool operator==(const iterator &X, const iterator &Y) { return X.Position == Y.Position; } friend bool operator!=(const iterator &X, const iterator &Y) { return X.Position != Y.Position; } friend bool operator<(const iterator &X, const iterator &Y) { return X.Position < Y.Position; } friend bool operator>(const iterator &X, const iterator &Y) { return X.Position > Y.Position; } friend bool operator<=(const iterator &X, const iterator &Y) { return X.Position < Y.Position; } friend bool operator>=(const iterator &X, const iterator &Y) { return X.Position > Y.Position; } friend iterator& operator+=(iterator &X, difference_type D) { X.Position += D; return X; } friend iterator& operator-=(iterator &X, difference_type D) { X.Position -= D; return X; } friend iterator operator+(iterator X, difference_type D) { X.Position += D; return X; } friend iterator operator+(difference_type D, iterator X) { X.Position += D; return X; } friend difference_type operator-(const iterator &X, const iterator &Y) { return X.Position - Y.Position; } friend iterator operator-(iterator X, difference_type D) { X.Position -= D; return X; } friend class PreprocessingRecord; }; friend class iterator; /// \brief Begin iterator for all preprocessed entities. iterator begin() { return iterator(this, -(int)LoadedPreprocessedEntities.size()); } /// \brief End iterator for all preprocessed entities. iterator end() { return iterator(this, PreprocessedEntities.size()); } /// \brief Begin iterator for local, non-loaded, preprocessed entities. iterator local_begin() { return iterator(this, 0); } /// \brief End iterator for local, non-loaded, preprocessed entities. iterator local_end() { return iterator(this, PreprocessedEntities.size()); } /// \brief begin/end iterator pair for the given range of loaded /// preprocessed entities. std::pair getIteratorsForLoadedRange(unsigned start, unsigned count) { unsigned end = start + count; assert(end <= LoadedPreprocessedEntities.size()); return std::make_pair( iterator(this, int(start)-LoadedPreprocessedEntities.size()), iterator(this, int(end)-LoadedPreprocessedEntities.size())); } /// \brief Returns a pair of [Begin, End) iterators of preprocessed entities /// that source range \p R encompasses. /// /// \param R the range to look for preprocessed entities. /// std::pair getPreprocessedEntitiesInRange(SourceRange R); /// \brief Returns true if the preprocessed entity that \p PPEI iterator /// points to is coming from the file \p FID. /// /// Can be used to avoid implicit deserializations of preallocated /// preprocessed entities if we only care about entities of a specific file /// and not from files \#included in the range given at /// \see getPreprocessedEntitiesInRange. bool isEntityInFileID(iterator PPEI, FileID FID); /// \brief Add a new preprocessed entity to this record. PPEntityID addPreprocessedEntity(PreprocessedEntity *Entity); /// \brief Set the external source for preprocessed entities. void SetExternalSource(ExternalPreprocessingRecordSource &Source); /// \brief Retrieve the external source for preprocessed entities. ExternalPreprocessingRecordSource *getExternalSource() const { return ExternalSource; } /// \brief Retrieve the macro definition that corresponds to the given /// \c MacroInfo. MacroDefinition *findMacroDefinition(const MacroInfo *MI); private: virtual void MacroExpands(const Token &Id, const MacroDirective *MD, SourceRange Range, const MacroArgs *Args); virtual void MacroDefined(const Token &Id, const MacroDirective *MD); virtual void MacroUndefined(const Token &Id, const MacroDirective *MD); virtual void InclusionDirective(SourceLocation HashLoc, const Token &IncludeTok, StringRef FileName, bool IsAngled, CharSourceRange FilenameRange, const FileEntry *File, StringRef SearchPath, StringRef RelativePath, const Module *Imported); virtual void Ifdef(SourceLocation Loc, const Token &MacroNameTok, const MacroDirective *MD); virtual void Ifndef(SourceLocation Loc, const Token &MacroNameTok, const MacroDirective *MD); /// \brief Hook called whenever the 'defined' operator is seen. virtual void Defined(const Token &MacroNameTok, const MacroDirective *MD, SourceRange Range); void addMacroExpansion(const Token &Id, const MacroInfo *MI, SourceRange Range); /// \brief Cached result of the last \see getPreprocessedEntitiesInRange /// query. struct { SourceRange Range; std::pair Result; } CachedRangeQuery; std::pair getPreprocessedEntitiesInRangeSlow(SourceRange R); friend class ASTReader; friend class ASTWriter; }; } // end namespace clang inline void* operator new(size_t bytes, clang::PreprocessingRecord& PR, unsigned alignment) throw() { return PR.Allocate(bytes, alignment); } inline void operator delete(void* ptr, clang::PreprocessingRecord& PR, unsigned) throw() { PR.Deallocate(ptr); } #endif // LLVM_CLANG_LEX_PREPROCESSINGRECORD_H