//===--- Preprocessor.h - C Language Family Preprocessor --------*- 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 Preprocessor interface. // //===----------------------------------------------------------------------===// #ifndef LLVM_CLANG_LEX_PREPROCESSOR_H #define LLVM_CLANG_LEX_PREPROCESSOR_H #include "clang/Lex/Lexer.h" #include "clang/Lex/PTHLexer.h" #include "clang/Lex/PPCallbacks.h" #include "clang/Lex/TokenLexer.h" #include "clang/Lex/PTHManager.h" #include "clang/Basic/Builtins.h" #include "clang/Basic/Diagnostic.h" #include "clang/Basic/IdentifierTable.h" #include "clang/Basic/SourceLocation.h" #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/OwningPtr.h" #include "llvm/ADT/SmallVector.h" #include "llvm/Support/Allocator.h" #include namespace clang { class SourceManager; class ExternalPreprocessorSource; class FileManager; class FileEntry; class HeaderSearch; class PragmaNamespace; class PragmaHandler; class CommentHandler; class ScratchBuffer; class TargetInfo; class PPCallbacks; class DirectoryLookup; class PreprocessingRecord; /// Preprocessor - This object engages in a tight little dance with the lexer to /// efficiently preprocess tokens. Lexers know only about tokens within a /// single source file, and don't know anything about preprocessor-level issues /// like the #include stack, token expansion, etc. /// class Preprocessor { Diagnostic *Diags; LangOptions Features; const TargetInfo &Target; FileManager &FileMgr; SourceManager &SourceMgr; ScratchBuffer *ScratchBuf; HeaderSearch &HeaderInfo; /// \brief External source of macros. ExternalPreprocessorSource *ExternalSource; /// PTH - An optional PTHManager object used for getting tokens from /// a token cache rather than lexing the original source file. llvm::OwningPtr PTH; /// BP - A BumpPtrAllocator object used to quickly allocate and release /// objects internal to the Preprocessor. llvm::BumpPtrAllocator BP; /// Identifiers for builtin macros and other builtins. IdentifierInfo *Ident__LINE__, *Ident__FILE__; // __LINE__, __FILE__ IdentifierInfo *Ident__DATE__, *Ident__TIME__; // __DATE__, __TIME__ IdentifierInfo *Ident__INCLUDE_LEVEL__; // __INCLUDE_LEVEL__ IdentifierInfo *Ident__BASE_FILE__; // __BASE_FILE__ IdentifierInfo *Ident__TIMESTAMP__; // __TIMESTAMP__ IdentifierInfo *Ident__COUNTER__; // __COUNTER__ IdentifierInfo *Ident_Pragma, *Ident__VA_ARGS__; // _Pragma, __VA_ARGS__ IdentifierInfo *Ident__has_feature; // __has_feature IdentifierInfo *Ident__has_builtin; // __has_builtin IdentifierInfo *Ident__has_include; // __has_include IdentifierInfo *Ident__has_include_next; // __has_include_next SourceLocation DATELoc, TIMELoc; unsigned CounterValue; // Next __COUNTER__ value. enum { /// MaxIncludeStackDepth - Maximum depth of #includes. MaxAllowedIncludeStackDepth = 200 }; // State that is set before the preprocessor begins. bool KeepComments : 1; bool KeepMacroComments : 1; // State that changes while the preprocessor runs: bool InMacroArgs : 1; // True if parsing fn macro invocation args. /// Whether the preprocessor owns the header search object. bool OwnsHeaderSearch : 1; /// DisableMacroExpansion - True if macro expansion is disabled. bool DisableMacroExpansion : 1; /// \brief Whether we have already loaded macros from the external source. mutable bool ReadMacrosFromExternalSource : 1; /// Identifiers - This is mapping/lookup information for all identifiers in /// the program, including program keywords. mutable IdentifierTable Identifiers; /// Selectors - This table contains all the selectors in the program. Unlike /// IdentifierTable above, this table *isn't* populated by the preprocessor. /// It is declared/instantiated here because it's role/lifetime is /// conceptually similar the IdentifierTable. In addition, the current control /// flow (in clang::ParseAST()), make it convenient to put here. /// FIXME: Make sure the lifetime of Identifiers/Selectors *isn't* tied to /// the lifetime fo the preprocessor. SelectorTable Selectors; /// BuiltinInfo - Information about builtins. Builtin::Context BuiltinInfo; /// PragmaHandlers - This tracks all of the pragmas that the client registered /// with this preprocessor. PragmaNamespace *PragmaHandlers; /// \brief Tracks all of the comment handlers that the client registered /// with this preprocessor. std::vector CommentHandlers; /// \brief The file that we're performing code-completion for, if any. const FileEntry *CodeCompletionFile; /// CurLexer - This is the current top of the stack that we're lexing from if /// not expanding a macro and we are lexing directly from source code. /// Only one of CurLexer, CurPTHLexer, or CurTokenLexer will be non-null. llvm::OwningPtr CurLexer; /// CurPTHLexer - This is the current top of stack that we're lexing from if /// not expanding from a macro and we are lexing from a PTH cache. /// Only one of CurLexer, CurPTHLexer, or CurTokenLexer will be non-null. llvm::OwningPtr CurPTHLexer; /// CurPPLexer - This is the current top of the stack what we're lexing from /// if not expanding a macro. This is an alias for either CurLexer or /// CurPTHLexer. PreprocessorLexer *CurPPLexer; /// CurLookup - The DirectoryLookup structure used to find the current /// FileEntry, if CurLexer is non-null and if applicable. This allows us to /// implement #include_next and find directory-specific properties. const DirectoryLookup *CurDirLookup; /// CurTokenLexer - This is the current macro we are expanding, if we are /// expanding a macro. One of CurLexer and CurTokenLexer must be null. llvm::OwningPtr CurTokenLexer; /// IncludeMacroStack - This keeps track of the stack of files currently /// #included, and macros currently being expanded from, not counting /// CurLexer/CurTokenLexer. struct IncludeStackInfo { Lexer *TheLexer; PTHLexer *ThePTHLexer; PreprocessorLexer *ThePPLexer; TokenLexer *TheTokenLexer; const DirectoryLookup *TheDirLookup; IncludeStackInfo(Lexer *L, PTHLexer* P, PreprocessorLexer* PPL, TokenLexer* TL, const DirectoryLookup *D) : TheLexer(L), ThePTHLexer(P), ThePPLexer(PPL), TheTokenLexer(TL), TheDirLookup(D) {} }; std::vector IncludeMacroStack; /// Callbacks - These are actions invoked when some preprocessor activity is /// encountered (e.g. a file is #included, etc). PPCallbacks *Callbacks; /// Macros - For each IdentifierInfo with 'HasMacro' set, we keep a mapping /// to the actual definition of the macro. llvm::DenseMap Macros; /// MICache - A "freelist" of MacroInfo objects that can be reused for quick /// allocation. /// FIXME: why not use a singly linked list? std::vector MICache; /// MacroArgCache - This is a "freelist" of MacroArg objects that can be /// reused for quick allocation. MacroArgs *MacroArgCache; friend class MacroArgs; // Various statistics we track for performance analysis. unsigned NumDirectives, NumIncluded, NumDefined, NumUndefined, NumPragma; unsigned NumIf, NumElse, NumEndif; unsigned NumEnteredSourceFiles, MaxIncludeStackDepth; unsigned NumMacroExpanded, NumFnMacroExpanded, NumBuiltinMacroExpanded; unsigned NumFastMacroExpanded, NumTokenPaste, NumFastTokenPaste; unsigned NumSkipped; /// Predefines - This string is the predefined macros that preprocessor /// should use from the command line etc. std::string Predefines; /// TokenLexerCache - Cache macro expanders to reduce malloc traffic. enum { TokenLexerCacheSize = 8 }; unsigned NumCachedTokenLexers; TokenLexer *TokenLexerCache[TokenLexerCacheSize]; /// \brief A record of the macro definitions and instantiations that /// occurred during preprocessing. /// /// This is an optional side structure that can be enabled with /// \c createPreprocessingRecord() prior to preprocessing. PreprocessingRecord *Record; private: // Cached tokens state. typedef llvm::SmallVector CachedTokensTy; /// CachedTokens - Cached tokens are stored here when we do backtracking or /// lookahead. They are "lexed" by the CachingLex() method. CachedTokensTy CachedTokens; /// CachedLexPos - The position of the cached token that CachingLex() should /// "lex" next. If it points beyond the CachedTokens vector, it means that /// a normal Lex() should be invoked. CachedTokensTy::size_type CachedLexPos; /// BacktrackPositions - Stack of backtrack positions, allowing nested /// backtracks. The EnableBacktrackAtThisPos() method pushes a position to /// indicate where CachedLexPos should be set when the BackTrack() method is /// invoked (at which point the last position is popped). std::vector BacktrackPositions; public: Preprocessor(Diagnostic &diags, const LangOptions &opts, const TargetInfo &target, SourceManager &SM, HeaderSearch &Headers, IdentifierInfoLookup *IILookup = 0, bool OwnsHeaderSearch = false); ~Preprocessor(); Diagnostic &getDiagnostics() const { return *Diags; } void setDiagnostics(Diagnostic &D) { Diags = &D; } const LangOptions &getLangOptions() const { return Features; } const TargetInfo &getTargetInfo() const { return Target; } FileManager &getFileManager() const { return FileMgr; } SourceManager &getSourceManager() const { return SourceMgr; } HeaderSearch &getHeaderSearchInfo() const { return HeaderInfo; } IdentifierTable &getIdentifierTable() { return Identifiers; } SelectorTable &getSelectorTable() { return Selectors; } Builtin::Context &getBuiltinInfo() { return BuiltinInfo; } llvm::BumpPtrAllocator &getPreprocessorAllocator() { return BP; } void setPTHManager(PTHManager* pm); PTHManager *getPTHManager() { return PTH.get(); } void setExternalSource(ExternalPreprocessorSource *Source) { ExternalSource = Source; } ExternalPreprocessorSource *getExternalSource() const { return ExternalSource; } /// SetCommentRetentionState - Control whether or not the preprocessor retains /// comments in output. void SetCommentRetentionState(bool KeepComments, bool KeepMacroComments) { this->KeepComments = KeepComments | KeepMacroComments; this->KeepMacroComments = KeepMacroComments; } bool getCommentRetentionState() const { return KeepComments; } /// isCurrentLexer - Return true if we are lexing directly from the specified /// lexer. bool isCurrentLexer(const PreprocessorLexer *L) const { return CurPPLexer == L; } /// getCurrentLexer - Return the current lexer being lexed from. Note /// that this ignores any potentially active macro expansions and _Pragma /// expansions going on at the time. PreprocessorLexer *getCurrentLexer() const { return CurPPLexer; } /// getCurrentFileLexer - Return the current file lexer being lexed from. /// Note that this ignores any potentially active macro expansions and _Pragma /// expansions going on at the time. PreprocessorLexer *getCurrentFileLexer() const; /// getPPCallbacks/addPPCallbacks - Accessors for preprocessor callbacks. /// Note that this class takes ownership of any PPCallbacks object given to /// it. PPCallbacks *getPPCallbacks() const { return Callbacks; } void addPPCallbacks(PPCallbacks *C) { if (Callbacks) C = new PPChainedCallbacks(C, Callbacks); Callbacks = C; } /// getMacroInfo - Given an identifier, return the MacroInfo it is #defined to /// or null if it isn't #define'd. MacroInfo *getMacroInfo(IdentifierInfo *II) const { return II->hasMacroDefinition() ? Macros.find(II)->second : 0; } /// setMacroInfo - Specify a macro for this identifier. /// void setMacroInfo(IdentifierInfo *II, MacroInfo *MI); /// macro_iterator/macro_begin/macro_end - This allows you to walk the current /// state of the macro table. This visits every currently-defined macro. typedef llvm::DenseMap::const_iterator macro_iterator; macro_iterator macro_begin(bool IncludeExternalMacros = true) const; macro_iterator macro_end(bool IncludeExternalMacros = true) const; const std::string &getPredefines() const { return Predefines; } /// setPredefines - Set the predefines for this Preprocessor. These /// predefines are automatically injected when parsing the main file. void setPredefines(const char *P) { Predefines = P; } void setPredefines(const std::string &P) { Predefines = P; } /// getIdentifierInfo - Return information about the specified preprocessor /// identifier token. The version of this method that takes two character /// pointers is preferred unless the identifier is already available as a /// string (this avoids allocation and copying of memory to construct an /// std::string). IdentifierInfo *getIdentifierInfo(llvm::StringRef Name) const { return &Identifiers.get(Name); } /// AddPragmaHandler - Add the specified pragma handler to the preprocessor. /// If 'Namespace' is non-null, then it is a token required to exist on the /// pragma line before the pragma string starts, e.g. "STDC" or "GCC". void AddPragmaHandler(const char *Namespace, PragmaHandler *Handler); /// RemovePragmaHandler - Remove the specific pragma handler from /// the preprocessor. If \arg Namespace is non-null, then it should /// be the namespace that \arg Handler was added to. It is an error /// to remove a handler that has not been registered. void RemovePragmaHandler(const char *Namespace, PragmaHandler *Handler); /// \brief Add the specified comment handler to the preprocessor. void AddCommentHandler(CommentHandler *Handler); /// \brief Remove the specified comment handler. /// /// It is an error to remove a handler that has not been registered. void RemoveCommentHandler(CommentHandler *Handler); /// \brief Retrieve the preprocessing record, or NULL if there is no /// preprocessing record. PreprocessingRecord *getPreprocessingRecord() const { return Record; } /// \brief Create a new preprocessing record, which will keep track of /// all macro expansions, macro definitions, etc. void createPreprocessingRecord(); /// EnterMainSourceFile - Enter the specified FileID as the main source file, /// which implicitly adds the builtin defines etc. void EnterMainSourceFile(); /// EndSourceFile - Inform the preprocessor callbacks that processing is /// complete. void EndSourceFile(); /// EnterSourceFile - Add a source file to the top of the include stack and /// start lexing tokens from it instead of the current buffer. Emit an error /// and don't enter the file on error. void EnterSourceFile(FileID CurFileID, const DirectoryLookup *Dir, SourceLocation Loc); /// EnterMacro - Add a Macro to the top of the include stack and start lexing /// tokens from it instead of the current buffer. Args specifies the /// tokens input to a function-like macro. /// /// ILEnd specifies the location of the ')' for a function-like macro or the /// identifier for an object-like macro. void EnterMacro(Token &Identifier, SourceLocation ILEnd, MacroArgs *Args); /// EnterTokenStream - Add a "macro" context to the top of the include stack, /// which will cause the lexer to start returning the specified tokens. /// /// If DisableMacroExpansion is true, tokens lexed from the token stream will /// not be subject to further macro expansion. Otherwise, these tokens will /// be re-macro-expanded when/if expansion is enabled. /// /// If OwnsTokens is false, this method assumes that the specified stream of /// tokens has a permanent owner somewhere, so they do not need to be copied. /// If it is true, it assumes the array of tokens is allocated with new[] and /// must be freed. /// void EnterTokenStream(const Token *Toks, unsigned NumToks, bool DisableMacroExpansion, bool OwnsTokens); /// RemoveTopOfLexerStack - Pop the current lexer/macro exp off the top of the /// lexer stack. This should only be used in situations where the current /// state of the top-of-stack lexer is known. void RemoveTopOfLexerStack(); /// EnableBacktrackAtThisPos - From the point that this method is called, and /// until CommitBacktrackedTokens() or Backtrack() is called, the Preprocessor /// keeps track of the lexed tokens so that a subsequent Backtrack() call will /// make the Preprocessor re-lex the same tokens. /// /// Nested backtracks are allowed, meaning that EnableBacktrackAtThisPos can /// be called multiple times and CommitBacktrackedTokens/Backtrack calls will /// be combined with the EnableBacktrackAtThisPos calls in reverse order. /// /// NOTE: *DO NOT* forget to call either CommitBacktrackedTokens or Backtrack /// at some point after EnableBacktrackAtThisPos. If you don't, caching of /// tokens will continue indefinitely. /// void EnableBacktrackAtThisPos(); /// CommitBacktrackedTokens - Disable the last EnableBacktrackAtThisPos call. void CommitBacktrackedTokens(); /// Backtrack - Make Preprocessor re-lex the tokens that were lexed since /// EnableBacktrackAtThisPos() was previously called. void Backtrack(); /// isBacktrackEnabled - True if EnableBacktrackAtThisPos() was called and /// caching of tokens is on. bool isBacktrackEnabled() const { return !BacktrackPositions.empty(); } /// Lex - To lex a token from the preprocessor, just pull a token from the /// current lexer or macro object. void Lex(Token &Result) { if (CurLexer) CurLexer->Lex(Result); else if (CurPTHLexer) CurPTHLexer->Lex(Result); else if (CurTokenLexer) CurTokenLexer->Lex(Result); else CachingLex(Result); } /// LexNonComment - Lex a token. If it's a comment, keep lexing until we get /// something not a comment. This is useful in -E -C mode where comments /// would foul up preprocessor directive handling. void LexNonComment(Token &Result) { do Lex(Result); while (Result.getKind() == tok::comment); } /// LexUnexpandedToken - This is just like Lex, but this disables macro /// expansion of identifier tokens. void LexUnexpandedToken(Token &Result) { // Disable macro expansion. bool OldVal = DisableMacroExpansion; DisableMacroExpansion = true; // Lex the token. Lex(Result); // Reenable it. DisableMacroExpansion = OldVal; } /// LookAhead - This peeks ahead N tokens and returns that token without /// consuming any tokens. LookAhead(0) returns the next token that would be /// returned by Lex(), LookAhead(1) returns the token after it, etc. This /// returns normal tokens after phase 5. As such, it is equivalent to using /// 'Lex', not 'LexUnexpandedToken'. const Token &LookAhead(unsigned N) { if (CachedLexPos + N < CachedTokens.size()) return CachedTokens[CachedLexPos+N]; else return PeekAhead(N+1); } /// RevertCachedTokens - When backtracking is enabled and tokens are cached, /// this allows to revert a specific number of tokens. /// Note that the number of tokens being reverted should be up to the last /// backtrack position, not more. void RevertCachedTokens(unsigned N) { assert(isBacktrackEnabled() && "Should only be called when tokens are cached for backtracking"); assert(signed(CachedLexPos) - signed(N) >= signed(BacktrackPositions.back()) && "Should revert tokens up to the last backtrack position, not more"); assert(signed(CachedLexPos) - signed(N) >= 0 && "Corrupted backtrack positions ?"); CachedLexPos -= N; } /// EnterToken - Enters a token in the token stream to be lexed next. If /// BackTrack() is called afterwards, the token will remain at the insertion /// point. void EnterToken(const Token &Tok) { EnterCachingLexMode(); CachedTokens.insert(CachedTokens.begin()+CachedLexPos, Tok); } /// AnnotateCachedTokens - We notify the Preprocessor that if it is caching /// tokens (because backtrack is enabled) it should replace the most recent /// cached tokens with the given annotation token. This function has no effect /// if backtracking is not enabled. /// /// Note that the use of this function is just for optimization; so that the /// cached tokens doesn't get re-parsed and re-resolved after a backtrack is /// invoked. void AnnotateCachedTokens(const Token &Tok) { assert(Tok.isAnnotation() && "Expected annotation token"); if (CachedLexPos != 0 && isBacktrackEnabled()) AnnotatePreviousCachedTokens(Tok); } /// \brief Replace the last token with an annotation token. /// /// Like AnnotateCachedTokens(), this routine replaces an /// already-parsed (and resolved) token with an annotation /// token. However, this routine only replaces the last token with /// the annotation token; it does not affect any other cached /// tokens. This function has no effect if backtracking is not /// enabled. void ReplaceLastTokenWithAnnotation(const Token &Tok) { assert(Tok.isAnnotation() && "Expected annotation token"); if (CachedLexPos != 0 && isBacktrackEnabled()) CachedTokens[CachedLexPos-1] = Tok; } /// \brief Specify the point at which code-completion will be performed. /// /// \param File the file in which code completion should occur. If /// this file is included multiple times, code-completion will /// perform completion the first time it is included. If NULL, this /// function clears out the code-completion point. /// /// \param Line the line at which code completion should occur /// (1-based). /// /// \param Column the column at which code completion should occur /// (1-based). /// /// \returns true if an error occurred, false otherwise. bool SetCodeCompletionPoint(const FileEntry *File, unsigned Line, unsigned Column); /// \brief Determine if this source location refers into the file /// for which we are performing code completion. bool isCodeCompletionFile(SourceLocation FileLoc) const; /// Diag - Forwarding function for diagnostics. This emits a diagnostic at /// the specified Token's location, translating the token's start /// position in the current buffer into a SourcePosition object for rendering. DiagnosticBuilder Diag(SourceLocation Loc, unsigned DiagID) { return Diags->Report(FullSourceLoc(Loc, getSourceManager()), DiagID); } DiagnosticBuilder Diag(const Token &Tok, unsigned DiagID) { return Diags->Report(FullSourceLoc(Tok.getLocation(), getSourceManager()), DiagID); } /// getSpelling() - Return the 'spelling' of the Tok token. The spelling of a /// token is the characters used to represent the token in the source file /// after trigraph expansion and escaped-newline folding. In particular, this /// wants to get the true, uncanonicalized, spelling of things like digraphs /// UCNs, etc. /// /// \param Invalid If non-NULL, will be set \c true if an error occurs. std::string getSpelling(const Token &Tok, bool *Invalid = 0) const; /// getSpelling() - Return the 'spelling' of the Tok token. The spelling of a /// token is the characters used to represent the token in the source file /// after trigraph expansion and escaped-newline folding. In particular, this /// wants to get the true, uncanonicalized, spelling of things like digraphs /// UCNs, etc. static std::string getSpelling(const Token &Tok, const SourceManager &SourceMgr, const LangOptions &Features, bool *Invalid = 0); /// getSpelling - This method is used to get the spelling of a token into a /// preallocated buffer, instead of as an std::string. The caller is required /// to allocate enough space for the token, which is guaranteed to be at least /// Tok.getLength() bytes long. The length of the actual result is returned. /// /// Note that this method may do two possible things: it may either fill in /// the buffer specified with characters, or it may *change the input pointer* /// to point to a constant buffer with the data already in it (avoiding a /// copy). The caller is not allowed to modify the returned buffer pointer /// if an internal buffer is returned. unsigned getSpelling(const Token &Tok, const char *&Buffer, bool *Invalid = 0) const; /// getSpelling - This method is used to get the spelling of a token into a /// SmallVector. Note that the returned StringRef may not point to the /// supplied buffer if a copy can be avoided. llvm::StringRef getSpelling(const Token &Tok, llvm::SmallVectorImpl &Buffer, bool *Invalid = 0) const; /// getSpellingOfSingleCharacterNumericConstant - Tok is a numeric constant /// with length 1, return the character. char getSpellingOfSingleCharacterNumericConstant(const Token &Tok, bool *Invalid = 0) const { assert(Tok.is(tok::numeric_constant) && Tok.getLength() == 1 && "Called on unsupported token"); assert(!Tok.needsCleaning() && "Token can't need cleaning with length 1"); // If the token is carrying a literal data pointer, just use it. if (const char *D = Tok.getLiteralData()) return *D; // Otherwise, fall back on getCharacterData, which is slower, but always // works. return *SourceMgr.getCharacterData(Tok.getLocation(), Invalid); } /// CreateString - Plop the specified string into a scratch buffer and set the /// specified token's location and length to it. If specified, the source /// location provides a location of the instantiation point of the token. void CreateString(const char *Buf, unsigned Len, Token &Tok, SourceLocation SourceLoc = SourceLocation()); /// \brief Computes the source location just past the end of the /// token at this source location. /// /// This routine can be used to produce a source location that /// points just past the end of the token referenced by \p Loc, and /// is generally used when a diagnostic needs to point just after a /// token where it expected something different that it received. If /// the returned source location would not be meaningful (e.g., if /// it points into a macro), this routine returns an invalid /// source location. /// /// \param Offset an offset from the end of the token, where the source /// location should refer to. The default offset (0) produces a source /// location pointing just past the end of the token; an offset of 1 produces /// a source location pointing to the last character in the token, etc. SourceLocation getLocForEndOfToken(SourceLocation Loc, unsigned Offset = 0); /// DumpToken - Print the token to stderr, used for debugging. /// void DumpToken(const Token &Tok, bool DumpFlags = false) const; void DumpLocation(SourceLocation Loc) const; void DumpMacro(const MacroInfo &MI) const; /// AdvanceToTokenCharacter - Given a location that specifies the start of a /// token, return a new location that specifies a character within the token. SourceLocation AdvanceToTokenCharacter(SourceLocation TokStart,unsigned Char); /// IncrementPasteCounter - Increment the counters for the number of token /// paste operations performed. If fast was specified, this is a 'fast paste' /// case we handled. /// void IncrementPasteCounter(bool isFast) { if (isFast) ++NumFastTokenPaste; else ++NumTokenPaste; } void PrintStats(); /// HandleMicrosoftCommentPaste - When the macro expander pastes together a /// comment (/##/) in microsoft mode, this method handles updating the current /// state, returning the token on the next source line. void HandleMicrosoftCommentPaste(Token &Tok); //===--------------------------------------------------------------------===// // Preprocessor callback methods. These are invoked by a lexer as various // directives and events are found. /// LookUpIdentifierInfo - Given a tok::identifier token, look up the /// identifier information for the token and install it into the token. IdentifierInfo *LookUpIdentifierInfo(Token &Identifier, const char *BufPtr = 0) const; /// HandleIdentifier - This callback is invoked when the lexer reads an /// identifier and has filled in the tokens IdentifierInfo member. This /// callback potentially macro expands it or turns it into a named token (like /// 'for'). void HandleIdentifier(Token &Identifier); /// HandleEndOfFile - This callback is invoked when the lexer hits the end of /// the current file. This either returns the EOF token and returns true, or /// pops a level off the include stack and returns false, at which point the /// client should call lex again. bool HandleEndOfFile(Token &Result, bool isEndOfMacro = false); /// HandleEndOfTokenLexer - This callback is invoked when the current /// TokenLexer hits the end of its token stream. bool HandleEndOfTokenLexer(Token &Result); /// HandleDirective - This callback is invoked when the lexer sees a # token /// at the start of a line. This consumes the directive, modifies the /// lexer/preprocessor state, and advances the lexer(s) so that the next token /// read is the correct one. void HandleDirective(Token &Result); /// CheckEndOfDirective - Ensure that the next token is a tok::eom token. If /// not, emit a diagnostic and consume up until the eom. If EnableMacros is /// true, then we consider macros that expand to zero tokens as being ok. void CheckEndOfDirective(const char *Directive, bool EnableMacros = false); /// DiscardUntilEndOfDirective - Read and discard all tokens remaining on the /// current line until the tok::eom token is found. void DiscardUntilEndOfDirective(); /// SawDateOrTime - This returns true if the preprocessor has seen a use of /// __DATE__ or __TIME__ in the file so far. bool SawDateOrTime() const { return DATELoc != SourceLocation() || TIMELoc != SourceLocation(); } unsigned getCounterValue() const { return CounterValue; } void setCounterValue(unsigned V) { CounterValue = V; } /// AllocateMacroInfo - Allocate a new MacroInfo object with the provide /// SourceLocation. MacroInfo* AllocateMacroInfo(SourceLocation L); /// GetIncludeFilenameSpelling - Turn the specified lexer token into a fully /// checked and spelled filename, e.g. as an operand of #include. This returns /// true if the input filename was in <>'s or false if it were in ""'s. The /// caller is expected to provide a buffer that is large enough to hold the /// spelling of the filename, but is also expected to handle the case when /// this method decides to use a different buffer. bool GetIncludeFilenameSpelling(SourceLocation Loc,llvm::StringRef &Filename); /// LookupFile - Given a "foo" or reference, look up the indicated file, /// return null on failure. isAngled indicates whether the file reference is /// for system #include's or not (i.e. using <> instead of ""). const FileEntry *LookupFile(llvm::StringRef Filename, bool isAngled, const DirectoryLookup *FromDir, const DirectoryLookup *&CurDir); /// GetCurLookup - The DirectoryLookup structure used to find the current /// FileEntry, if CurLexer is non-null and if applicable. This allows us to /// implement #include_next and find directory-specific properties. const DirectoryLookup *GetCurDirLookup() { return CurDirLookup; } /// isInPrimaryFile - Return true if we're in the top-level file, not in a /// #include. bool isInPrimaryFile() const; /// ConcatenateIncludeName - Handle cases where the #include name is expanded /// from a macro as multiple tokens, which need to be glued together. This /// occurs for code like: /// #define FOO /// #include FOO /// because in this case, "" is returned as 7 tokens, not one. /// /// This code concatenates and consumes tokens up to the '>' token. It /// returns false if the > was found, otherwise it returns true if it finds /// and consumes the EOM marker. bool ConcatenateIncludeName(llvm::SmallString<128> &FilenameBuffer); private: void PushIncludeMacroStack() { IncludeMacroStack.push_back(IncludeStackInfo(CurLexer.take(), CurPTHLexer.take(), CurPPLexer, CurTokenLexer.take(), CurDirLookup)); CurPPLexer = 0; } void PopIncludeMacroStack() { CurLexer.reset(IncludeMacroStack.back().TheLexer); CurPTHLexer.reset(IncludeMacroStack.back().ThePTHLexer); CurPPLexer = IncludeMacroStack.back().ThePPLexer; CurTokenLexer.reset(IncludeMacroStack.back().TheTokenLexer); CurDirLookup = IncludeMacroStack.back().TheDirLookup; IncludeMacroStack.pop_back(); } /// ReleaseMacroInfo - Release the specified MacroInfo. This memory will /// be reused for allocating new MacroInfo objects. void ReleaseMacroInfo(MacroInfo* MI); /// ReadMacroName - Lex and validate a macro name, which occurs after a /// #define or #undef. This emits a diagnostic, sets the token kind to eom, /// and discards the rest of the macro line if the macro name is invalid. void ReadMacroName(Token &MacroNameTok, char isDefineUndef = 0); /// ReadMacroDefinitionArgList - The ( starting an argument list of a macro /// definition has just been read. Lex the rest of the arguments and the /// closing ), updating MI with what we learn. Return true if an error occurs /// parsing the arg list. bool ReadMacroDefinitionArgList(MacroInfo *MI); /// SkipExcludedConditionalBlock - We just read a #if or related directive and /// decided that the subsequent tokens are in the #if'd out portion of the /// file. Lex the rest of the file, until we see an #endif. If /// FoundNonSkipPortion is true, then we have already emitted code for part of /// this #if directive, so #else/#elif blocks should never be entered. If /// FoundElse is false, then #else directives are ok, if not, then we have /// already seen one so a #else directive is a duplicate. When this returns, /// the caller can lex the first valid token. void SkipExcludedConditionalBlock(SourceLocation IfTokenLoc, bool FoundNonSkipPortion, bool FoundElse); /// PTHSkipExcludedConditionalBlock - A fast PTH version of /// SkipExcludedConditionalBlock. void PTHSkipExcludedConditionalBlock(); /// EvaluateDirectiveExpression - Evaluate an integer constant expression that /// may occur after a #if or #elif directive and return it as a bool. If the /// expression is equivalent to "!defined(X)" return X in IfNDefMacro. bool EvaluateDirectiveExpression(IdentifierInfo *&IfNDefMacro); /// RegisterBuiltinPragmas - Install the standard preprocessor pragmas: /// #pragma GCC poison/system_header/dependency and #pragma once. void RegisterBuiltinPragmas(); /// RegisterBuiltinMacros - Register builtin macros, such as __LINE__ with the /// identifier table. void RegisterBuiltinMacros(); /// HandleMacroExpandedIdentifier - If an identifier token is read that is to /// be expanded as a macro, handle it and return the next token as 'Tok'. If /// the macro should not be expanded return true, otherwise return false. bool HandleMacroExpandedIdentifier(Token &Tok, MacroInfo *MI); /// isNextPPTokenLParen - Determine whether the next preprocessor token to be /// lexed is a '('. If so, consume the token and return true, if not, this /// method should have no observable side-effect on the lexed tokens. bool isNextPPTokenLParen(); /// ReadFunctionLikeMacroArgs - After reading "MACRO(", this method is /// invoked to read all of the formal arguments specified for the macro /// invocation. This returns null on error. MacroArgs *ReadFunctionLikeMacroArgs(Token &MacroName, MacroInfo *MI, SourceLocation &InstantiationEnd); /// ExpandBuiltinMacro - If an identifier token is read that is to be expanded /// as a builtin macro, handle it and return the next token as 'Tok'. void ExpandBuiltinMacro(Token &Tok); /// Handle_Pragma - Read a _Pragma directive, slice it up, process it, then /// return the first token after the directive. The _Pragma token has just /// been read into 'Tok'. void Handle_Pragma(Token &Tok); /// EnterSourceFileWithLexer - Add a lexer to the top of the include stack and /// start lexing tokens from it instead of the current buffer. void EnterSourceFileWithLexer(Lexer *TheLexer, const DirectoryLookup *Dir); /// EnterSourceFileWithPTH - Add a lexer to the top of the include stack and /// start getting tokens from it using the PTH cache. void EnterSourceFileWithPTH(PTHLexer *PL, const DirectoryLookup *Dir); /// IsFileLexer - Returns true if we are lexing from a file and not a /// pragma or a macro. static bool IsFileLexer(const Lexer* L, const PreprocessorLexer* P) { return L ? !L->isPragmaLexer() : P != 0; } static bool IsFileLexer(const IncludeStackInfo& I) { return IsFileLexer(I.TheLexer, I.ThePPLexer); } bool IsFileLexer() const { return IsFileLexer(CurLexer.get(), CurPPLexer); } //===--------------------------------------------------------------------===// // Caching stuff. void CachingLex(Token &Result); bool InCachingLexMode() const { return CurPPLexer == 0 && CurTokenLexer == 0;} void EnterCachingLexMode(); void ExitCachingLexMode() { if (InCachingLexMode()) RemoveTopOfLexerStack(); } const Token &PeekAhead(unsigned N); void AnnotatePreviousCachedTokens(const Token &Tok); //===--------------------------------------------------------------------===// /// Handle*Directive - implement the various preprocessor directives. These /// should side-effect the current preprocessor object so that the next call /// to Lex() will return the appropriate token next. void HandleLineDirective(Token &Tok); void HandleDigitDirective(Token &Tok); void HandleUserDiagnosticDirective(Token &Tok, bool isWarning); void HandleIdentSCCSDirective(Token &Tok); // File inclusion. void HandleIncludeDirective(Token &Tok, const DirectoryLookup *LookupFrom = 0, bool isImport = false); void HandleIncludeNextDirective(Token &Tok); void HandleIncludeMacrosDirective(Token &Tok); void HandleImportDirective(Token &Tok); // Macro handling. void HandleDefineDirective(Token &Tok); void HandleUndefDirective(Token &Tok); // Conditional Inclusion. void HandleIfdefDirective(Token &Tok, bool isIfndef, bool ReadAnyTokensBeforeDirective); void HandleIfDirective(Token &Tok, bool ReadAnyTokensBeforeDirective); void HandleEndifDirective(Token &Tok); void HandleElseDirective(Token &Tok); void HandleElifDirective(Token &Tok); // Pragmas. void HandlePragmaDirective(); public: void HandlePragmaOnce(Token &OnceTok); void HandlePragmaMark(); void HandlePragmaPoison(Token &PoisonTok); void HandlePragmaSystemHeader(Token &SysHeaderTok); void HandlePragmaDependency(Token &DependencyTok); void HandlePragmaComment(Token &CommentTok); // Return true and store the first token only if any CommentHandler // has inserted some tokens and getCommentRetentionState() is false. bool HandleComment(Token &Token, SourceRange Comment); }; /// \brief Abstract base class that describes a handler that will receive /// source ranges for each of the comments encountered in the source file. class CommentHandler { public: virtual ~CommentHandler(); // The handler shall return true if it has pushed any tokens // to be read using e.g. EnterToken or EnterTokenStream. virtual bool HandleComment(Preprocessor &PP, SourceRange Comment) = 0; }; } // end namespace clang #endif