//===--- PrintPreprocessedOutput.cpp - Implement the -E mode --------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This code simply runs the preprocessor on the input file and prints out the // result. This is the traditional behavior of the -E option. // //===----------------------------------------------------------------------===// #include "clang/Frontend/Utils.h" #include "clang/Basic/CharInfo.h" #include "clang/Basic/Diagnostic.h" #include "clang/Basic/SourceManager.h" #include "clang/Frontend/PreprocessorOutputOptions.h" #include "clang/Lex/MacroInfo.h" #include "clang/Lex/PPCallbacks.h" #include "clang/Lex/Pragma.h" #include "clang/Lex/Preprocessor.h" #include "clang/Lex/TokenConcatenation.h" #include "llvm/ADT/STLExtras.h" #include "llvm/ADT/SmallString.h" #include "llvm/ADT/StringRef.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/raw_ostream.h" #include using namespace clang; /// PrintMacroDefinition - Print a macro definition in a form that will be /// properly accepted back as a definition. static void PrintMacroDefinition(const IdentifierInfo &II, const MacroInfo &MI, Preprocessor &PP, raw_ostream *OS) { *OS << "#define " << II.getName(); if (MI.isFunctionLike()) { *OS << '('; if (!MI.param_empty()) { MacroInfo::param_iterator AI = MI.param_begin(), E = MI.param_end(); for (; AI+1 != E; ++AI) { *OS << (*AI)->getName(); *OS << ','; } // Last argument. if ((*AI)->getName() == "__VA_ARGS__") *OS << "..."; else *OS << (*AI)->getName(); } if (MI.isGNUVarargs()) *OS << "..."; // #define foo(x...) *OS << ')'; } // GCC always emits a space, even if the macro body is empty. However, do not // want to emit two spaces if the first token has a leading space. if (MI.tokens_empty() || !MI.tokens_begin()->hasLeadingSpace()) *OS << ' '; SmallString<128> SpellingBuffer; for (const auto &T : MI.tokens()) { if (T.hasLeadingSpace()) *OS << ' '; *OS << PP.getSpelling(T, SpellingBuffer); } } //===----------------------------------------------------------------------===// // Preprocessed token printer //===----------------------------------------------------------------------===// namespace { class PrintPPOutputPPCallbacks : public PPCallbacks { Preprocessor &PP; SourceManager &SM; TokenConcatenation ConcatInfo; public: raw_ostream *OS; private: unsigned CurLine; bool EmittedTokensOnThisLine; bool EmittedDirectiveOnThisLine; SrcMgr::CharacteristicKind FileType; SmallString<512> CurFilename; bool Initialized; bool DisableLineMarkers; bool DumpDefines; bool DumpIncludeDirectives; bool UseLineDirectives; bool IsFirstFileEntered; bool MinimizeWhitespace; bool DirectivesOnly; bool KeepSystemIncludes; raw_ostream *OrigOS; std::unique_ptr NullOS; Token PrevTok; Token PrevPrevTok; public: PrintPPOutputPPCallbacks(Preprocessor &pp, raw_ostream *os, bool lineMarkers, bool defines, bool DumpIncludeDirectives, bool UseLineDirectives, bool MinimizeWhitespace, bool DirectivesOnly, bool KeepSystemIncludes) : PP(pp), SM(PP.getSourceManager()), ConcatInfo(PP), OS(os), DisableLineMarkers(lineMarkers), DumpDefines(defines), DumpIncludeDirectives(DumpIncludeDirectives), UseLineDirectives(UseLineDirectives), MinimizeWhitespace(MinimizeWhitespace), DirectivesOnly(DirectivesOnly), KeepSystemIncludes(KeepSystemIncludes), OrigOS(os) { CurLine = 0; CurFilename += ""; EmittedTokensOnThisLine = false; EmittedDirectiveOnThisLine = false; FileType = SrcMgr::C_User; Initialized = false; IsFirstFileEntered = false; if (KeepSystemIncludes) NullOS = std::make_unique(); PrevTok.startToken(); PrevPrevTok.startToken(); } bool isMinimizeWhitespace() const { return MinimizeWhitespace; } void setEmittedTokensOnThisLine() { EmittedTokensOnThisLine = true; } bool hasEmittedTokensOnThisLine() const { return EmittedTokensOnThisLine; } void setEmittedDirectiveOnThisLine() { EmittedDirectiveOnThisLine = true; } bool hasEmittedDirectiveOnThisLine() const { return EmittedDirectiveOnThisLine; } /// Ensure that the output stream position is at the beginning of a new line /// and inserts one if it does not. It is intended to ensure that directives /// inserted by the directives not from the input source (such as #line) are /// in the first column. To insert newlines that represent the input, use /// MoveToLine(/*...*/, /*RequireStartOfLine=*/true). void startNewLineIfNeeded(); void FileChanged(SourceLocation Loc, FileChangeReason Reason, SrcMgr::CharacteristicKind FileType, FileID PrevFID) override; void InclusionDirective(SourceLocation HashLoc, const Token &IncludeTok, StringRef FileName, bool IsAngled, CharSourceRange FilenameRange, OptionalFileEntryRef File, StringRef SearchPath, StringRef RelativePath, const Module *Imported, SrcMgr::CharacteristicKind FileType) override; void Ident(SourceLocation Loc, StringRef str) override; void PragmaMessage(SourceLocation Loc, StringRef Namespace, PragmaMessageKind Kind, StringRef Str) override; void PragmaDebug(SourceLocation Loc, StringRef DebugType) override; void PragmaDiagnosticPush(SourceLocation Loc, StringRef Namespace) override; void PragmaDiagnosticPop(SourceLocation Loc, StringRef Namespace) override; void PragmaDiagnostic(SourceLocation Loc, StringRef Namespace, diag::Severity Map, StringRef Str) override; void PragmaWarning(SourceLocation Loc, PragmaWarningSpecifier WarningSpec, ArrayRef Ids) override; void PragmaWarningPush(SourceLocation Loc, int Level) override; void PragmaWarningPop(SourceLocation Loc) override; void PragmaExecCharsetPush(SourceLocation Loc, StringRef Str) override; void PragmaExecCharsetPop(SourceLocation Loc) override; void PragmaAssumeNonNullBegin(SourceLocation Loc) override; void PragmaAssumeNonNullEnd(SourceLocation Loc) override; /// Insert whitespace before emitting the next token. /// /// @param Tok Next token to be emitted. /// @param RequireSpace Ensure at least one whitespace is emitted. Useful /// if non-tokens have been emitted to the stream. /// @param RequireSameLine Never emit newlines. Useful when semantics depend /// on being on the same line, such as directives. void HandleWhitespaceBeforeTok(const Token &Tok, bool RequireSpace, bool RequireSameLine); /// Move to the line of the provided source location. This will /// return true if a newline was inserted or if /// the requested location is the first token on the first line. /// In these cases the next output will be the first column on the line and /// make it possible to insert indention. The newline was inserted /// implicitly when at the beginning of the file. /// /// @param Tok Token where to move to. /// @param RequireStartOfLine Whether the next line depends on being in the /// first column, such as a directive. /// /// @return Whether column adjustments are necessary. bool MoveToLine(const Token &Tok, bool RequireStartOfLine) { PresumedLoc PLoc = SM.getPresumedLoc(Tok.getLocation()); unsigned TargetLine = PLoc.isValid() ? PLoc.getLine() : CurLine; bool IsFirstInFile = Tok.isAtStartOfLine() && PLoc.isValid() && PLoc.getLine() == 1; return MoveToLine(TargetLine, RequireStartOfLine) || IsFirstInFile; } /// Move to the line of the provided source location. Returns true if a new /// line was inserted. bool MoveToLine(SourceLocation Loc, bool RequireStartOfLine) { PresumedLoc PLoc = SM.getPresumedLoc(Loc); unsigned TargetLine = PLoc.isValid() ? PLoc.getLine() : CurLine; return MoveToLine(TargetLine, RequireStartOfLine); } bool MoveToLine(unsigned LineNo, bool RequireStartOfLine); bool AvoidConcat(const Token &PrevPrevTok, const Token &PrevTok, const Token &Tok) { return ConcatInfo.AvoidConcat(PrevPrevTok, PrevTok, Tok); } void WriteLineInfo(unsigned LineNo, const char *Extra=nullptr, unsigned ExtraLen=0); bool LineMarkersAreDisabled() const { return DisableLineMarkers; } void HandleNewlinesInToken(const char *TokStr, unsigned Len); /// MacroDefined - This hook is called whenever a macro definition is seen. void MacroDefined(const Token &MacroNameTok, const MacroDirective *MD) override; /// MacroUndefined - This hook is called whenever a macro #undef is seen. void MacroUndefined(const Token &MacroNameTok, const MacroDefinition &MD, const MacroDirective *Undef) override; void BeginModule(const Module *M); void EndModule(const Module *M); }; } // end anonymous namespace void PrintPPOutputPPCallbacks::WriteLineInfo(unsigned LineNo, const char *Extra, unsigned ExtraLen) { startNewLineIfNeeded(); // Emit #line directives or GNU line markers depending on what mode we're in. if (UseLineDirectives) { *OS << "#line" << ' ' << LineNo << ' ' << '"'; OS->write_escaped(CurFilename); *OS << '"'; } else { *OS << '#' << ' ' << LineNo << ' ' << '"'; OS->write_escaped(CurFilename); *OS << '"'; if (ExtraLen) OS->write(Extra, ExtraLen); if (FileType == SrcMgr::C_System) OS->write(" 3", 2); else if (FileType == SrcMgr::C_ExternCSystem) OS->write(" 3 4", 4); } *OS << '\n'; } /// MoveToLine - Move the output to the source line specified by the location /// object. We can do this by emitting some number of \n's, or be emitting a /// #line directive. This returns false if already at the specified line, true /// if some newlines were emitted. bool PrintPPOutputPPCallbacks::MoveToLine(unsigned LineNo, bool RequireStartOfLine) { // If it is required to start a new line or finish the current, insert // vertical whitespace now and take it into account when moving to the // expected line. bool StartedNewLine = false; if ((RequireStartOfLine && EmittedTokensOnThisLine) || EmittedDirectiveOnThisLine) { *OS << '\n'; StartedNewLine = true; CurLine += 1; EmittedTokensOnThisLine = false; EmittedDirectiveOnThisLine = false; } // If this line is "close enough" to the original line, just print newlines, // otherwise print a #line directive. if (CurLine == LineNo) { // Nothing to do if we are already on the correct line. } else if (MinimizeWhitespace && DisableLineMarkers) { // With -E -P -fminimize-whitespace, don't emit anything if not necessary. } else if (!StartedNewLine && LineNo - CurLine == 1) { // Printing a single line has priority over printing a #line directive, even // when minimizing whitespace which otherwise would print #line directives // for every single line. *OS << '\n'; StartedNewLine = true; } else if (!DisableLineMarkers) { if (LineNo - CurLine <= 8) { const char *NewLines = "\n\n\n\n\n\n\n\n"; OS->write(NewLines, LineNo - CurLine); } else { // Emit a #line or line marker. WriteLineInfo(LineNo, nullptr, 0); } StartedNewLine = true; } else if (EmittedTokensOnThisLine) { // If we are not on the correct line and don't need to be line-correct, // at least ensure we start on a new line. *OS << '\n'; StartedNewLine = true; } if (StartedNewLine) { EmittedTokensOnThisLine = false; EmittedDirectiveOnThisLine = false; } CurLine = LineNo; return StartedNewLine; } void PrintPPOutputPPCallbacks::startNewLineIfNeeded() { if (EmittedTokensOnThisLine || EmittedDirectiveOnThisLine) { *OS << '\n'; EmittedTokensOnThisLine = false; EmittedDirectiveOnThisLine = false; } } /// FileChanged - Whenever the preprocessor enters or exits a #include file /// it invokes this handler. Update our conception of the current source /// position. void PrintPPOutputPPCallbacks::FileChanged(SourceLocation Loc, FileChangeReason Reason, SrcMgr::CharacteristicKind NewFileType, FileID PrevFID) { // Unless we are exiting a #include, make sure to skip ahead to the line the // #include directive was at. SourceManager &SourceMgr = SM; PresumedLoc UserLoc = SourceMgr.getPresumedLoc(Loc); if (UserLoc.isInvalid()) return; unsigned NewLine = UserLoc.getLine(); if (Reason == PPCallbacks::EnterFile) { SourceLocation IncludeLoc = UserLoc.getIncludeLoc(); if (IncludeLoc.isValid()) MoveToLine(IncludeLoc, /*RequireStartOfLine=*/false); } else if (Reason == PPCallbacks::SystemHeaderPragma) { // GCC emits the # directive for this directive on the line AFTER the // directive and emits a bunch of spaces that aren't needed. This is because // otherwise we will emit a line marker for THIS line, which requires an // extra blank line after the directive to avoid making all following lines // off by one. We can do better by simply incrementing NewLine here. NewLine += 1; } CurLine = NewLine; // In KeepSystemIncludes mode, redirect OS as needed. if (KeepSystemIncludes && (isSystem(FileType) != isSystem(NewFileType))) OS = isSystem(FileType) ? OrigOS : NullOS.get(); CurFilename.clear(); CurFilename += UserLoc.getFilename(); FileType = NewFileType; if (DisableLineMarkers) { if (!MinimizeWhitespace) startNewLineIfNeeded(); return; } if (!Initialized) { WriteLineInfo(CurLine); Initialized = true; } // Do not emit an enter marker for the main file (which we expect is the first // entered file). This matches gcc, and improves compatibility with some tools // which track the # line markers as a way to determine when the preprocessed // output is in the context of the main file. if (Reason == PPCallbacks::EnterFile && !IsFirstFileEntered) { IsFirstFileEntered = true; return; } switch (Reason) { case PPCallbacks::EnterFile: WriteLineInfo(CurLine, " 1", 2); break; case PPCallbacks::ExitFile: WriteLineInfo(CurLine, " 2", 2); break; case PPCallbacks::SystemHeaderPragma: case PPCallbacks::RenameFile: WriteLineInfo(CurLine); break; } } void PrintPPOutputPPCallbacks::InclusionDirective( SourceLocation HashLoc, const Token &IncludeTok, StringRef FileName, bool IsAngled, CharSourceRange FilenameRange, OptionalFileEntryRef File, StringRef SearchPath, StringRef RelativePath, const Module *Imported, SrcMgr::CharacteristicKind FileType) { // In -dI mode, dump #include directives prior to dumping their content or // interpretation. Similar for -fkeep-system-includes. if (DumpIncludeDirectives || (KeepSystemIncludes && isSystem(FileType))) { MoveToLine(HashLoc, /*RequireStartOfLine=*/true); const std::string TokenText = PP.getSpelling(IncludeTok); assert(!TokenText.empty()); *OS << "#" << TokenText << " " << (IsAngled ? '<' : '"') << FileName << (IsAngled ? '>' : '"') << " /* clang -E " << (DumpIncludeDirectives ? "-dI" : "-fkeep-system-includes") << " */"; setEmittedDirectiveOnThisLine(); } // When preprocessing, turn implicit imports into module import pragmas. if (Imported) { switch (IncludeTok.getIdentifierInfo()->getPPKeywordID()) { case tok::pp_include: case tok::pp_import: case tok::pp_include_next: MoveToLine(HashLoc, /*RequireStartOfLine=*/true); *OS << "#pragma clang module import " << Imported->getFullModuleName(true) << " /* clang -E: implicit import for " << "#" << PP.getSpelling(IncludeTok) << " " << (IsAngled ? '<' : '"') << FileName << (IsAngled ? '>' : '"') << " */"; setEmittedDirectiveOnThisLine(); break; case tok::pp___include_macros: // #__include_macros has no effect on a user of a preprocessed source // file; the only effect is on preprocessing. // // FIXME: That's not *quite* true: it causes the module in question to // be loaded, which can affect downstream diagnostics. break; default: llvm_unreachable("unknown include directive kind"); break; } } } /// Handle entering the scope of a module during a module compilation. void PrintPPOutputPPCallbacks::BeginModule(const Module *M) { startNewLineIfNeeded(); *OS << "#pragma clang module begin " << M->getFullModuleName(true); setEmittedDirectiveOnThisLine(); } /// Handle leaving the scope of a module during a module compilation. void PrintPPOutputPPCallbacks::EndModule(const Module *M) { startNewLineIfNeeded(); *OS << "#pragma clang module end /*" << M->getFullModuleName(true) << "*/"; setEmittedDirectiveOnThisLine(); } /// Ident - Handle #ident directives when read by the preprocessor. /// void PrintPPOutputPPCallbacks::Ident(SourceLocation Loc, StringRef S) { MoveToLine(Loc, /*RequireStartOfLine=*/true); OS->write("#ident ", strlen("#ident ")); OS->write(S.begin(), S.size()); setEmittedTokensOnThisLine(); } /// MacroDefined - This hook is called whenever a macro definition is seen. void PrintPPOutputPPCallbacks::MacroDefined(const Token &MacroNameTok, const MacroDirective *MD) { const MacroInfo *MI = MD->getMacroInfo(); // Print out macro definitions in -dD mode and when we have -fdirectives-only // for C++20 header units. if ((!DumpDefines && !DirectivesOnly) || // Ignore __FILE__ etc. MI->isBuiltinMacro()) return; SourceLocation DefLoc = MI->getDefinitionLoc(); if (DirectivesOnly && !MI->isUsed()) { SourceManager &SM = PP.getSourceManager(); if (SM.isWrittenInBuiltinFile(DefLoc) || SM.isWrittenInCommandLineFile(DefLoc)) return; } MoveToLine(DefLoc, /*RequireStartOfLine=*/true); PrintMacroDefinition(*MacroNameTok.getIdentifierInfo(), *MI, PP, OS); setEmittedDirectiveOnThisLine(); } void PrintPPOutputPPCallbacks::MacroUndefined(const Token &MacroNameTok, const MacroDefinition &MD, const MacroDirective *Undef) { // Print out macro definitions in -dD mode and when we have -fdirectives-only // for C++20 header units. if (!DumpDefines && !DirectivesOnly) return; MoveToLine(MacroNameTok.getLocation(), /*RequireStartOfLine=*/true); *OS << "#undef " << MacroNameTok.getIdentifierInfo()->getName(); setEmittedDirectiveOnThisLine(); } static void outputPrintable(raw_ostream *OS, StringRef Str) { for (unsigned char Char : Str) { if (isPrintable(Char) && Char != '\\' && Char != '"') *OS << (char)Char; else // Output anything hard as an octal escape. *OS << '\\' << (char)('0' + ((Char >> 6) & 7)) << (char)('0' + ((Char >> 3) & 7)) << (char)('0' + ((Char >> 0) & 7)); } } void PrintPPOutputPPCallbacks::PragmaMessage(SourceLocation Loc, StringRef Namespace, PragmaMessageKind Kind, StringRef Str) { MoveToLine(Loc, /*RequireStartOfLine=*/true); *OS << "#pragma "; if (!Namespace.empty()) *OS << Namespace << ' '; switch (Kind) { case PMK_Message: *OS << "message(\""; break; case PMK_Warning: *OS << "warning \""; break; case PMK_Error: *OS << "error \""; break; } outputPrintable(OS, Str); *OS << '"'; if (Kind == PMK_Message) *OS << ')'; setEmittedDirectiveOnThisLine(); } void PrintPPOutputPPCallbacks::PragmaDebug(SourceLocation Loc, StringRef DebugType) { MoveToLine(Loc, /*RequireStartOfLine=*/true); *OS << "#pragma clang __debug "; *OS << DebugType; setEmittedDirectiveOnThisLine(); } void PrintPPOutputPPCallbacks:: PragmaDiagnosticPush(SourceLocation Loc, StringRef Namespace) { MoveToLine(Loc, /*RequireStartOfLine=*/true); *OS << "#pragma " << Namespace << " diagnostic push"; setEmittedDirectiveOnThisLine(); } void PrintPPOutputPPCallbacks:: PragmaDiagnosticPop(SourceLocation Loc, StringRef Namespace) { MoveToLine(Loc, /*RequireStartOfLine=*/true); *OS << "#pragma " << Namespace << " diagnostic pop"; setEmittedDirectiveOnThisLine(); } void PrintPPOutputPPCallbacks::PragmaDiagnostic(SourceLocation Loc, StringRef Namespace, diag::Severity Map, StringRef Str) { MoveToLine(Loc, /*RequireStartOfLine=*/true); *OS << "#pragma " << Namespace << " diagnostic "; switch (Map) { case diag::Severity::Remark: *OS << "remark"; break; case diag::Severity::Warning: *OS << "warning"; break; case diag::Severity::Error: *OS << "error"; break; case diag::Severity::Ignored: *OS << "ignored"; break; case diag::Severity::Fatal: *OS << "fatal"; break; } *OS << " \"" << Str << '"'; setEmittedDirectiveOnThisLine(); } void PrintPPOutputPPCallbacks::PragmaWarning(SourceLocation Loc, PragmaWarningSpecifier WarningSpec, ArrayRef Ids) { MoveToLine(Loc, /*RequireStartOfLine=*/true); *OS << "#pragma warning("; switch(WarningSpec) { case PWS_Default: *OS << "default"; break; case PWS_Disable: *OS << "disable"; break; case PWS_Error: *OS << "error"; break; case PWS_Once: *OS << "once"; break; case PWS_Suppress: *OS << "suppress"; break; case PWS_Level1: *OS << '1'; break; case PWS_Level2: *OS << '2'; break; case PWS_Level3: *OS << '3'; break; case PWS_Level4: *OS << '4'; break; } *OS << ':'; for (ArrayRef::iterator I = Ids.begin(), E = Ids.end(); I != E; ++I) *OS << ' ' << *I; *OS << ')'; setEmittedDirectiveOnThisLine(); } void PrintPPOutputPPCallbacks::PragmaWarningPush(SourceLocation Loc, int Level) { MoveToLine(Loc, /*RequireStartOfLine=*/true); *OS << "#pragma warning(push"; if (Level >= 0) *OS << ", " << Level; *OS << ')'; setEmittedDirectiveOnThisLine(); } void PrintPPOutputPPCallbacks::PragmaWarningPop(SourceLocation Loc) { MoveToLine(Loc, /*RequireStartOfLine=*/true); *OS << "#pragma warning(pop)"; setEmittedDirectiveOnThisLine(); } void PrintPPOutputPPCallbacks::PragmaExecCharsetPush(SourceLocation Loc, StringRef Str) { MoveToLine(Loc, /*RequireStartOfLine=*/true); *OS << "#pragma character_execution_set(push"; if (!Str.empty()) *OS << ", " << Str; *OS << ')'; setEmittedDirectiveOnThisLine(); } void PrintPPOutputPPCallbacks::PragmaExecCharsetPop(SourceLocation Loc) { MoveToLine(Loc, /*RequireStartOfLine=*/true); *OS << "#pragma character_execution_set(pop)"; setEmittedDirectiveOnThisLine(); } void PrintPPOutputPPCallbacks:: PragmaAssumeNonNullBegin(SourceLocation Loc) { MoveToLine(Loc, /*RequireStartOfLine=*/true); *OS << "#pragma clang assume_nonnull begin"; setEmittedDirectiveOnThisLine(); } void PrintPPOutputPPCallbacks:: PragmaAssumeNonNullEnd(SourceLocation Loc) { MoveToLine(Loc, /*RequireStartOfLine=*/true); *OS << "#pragma clang assume_nonnull end"; setEmittedDirectiveOnThisLine(); } void PrintPPOutputPPCallbacks::HandleWhitespaceBeforeTok(const Token &Tok, bool RequireSpace, bool RequireSameLine) { // These tokens are not expanded to anything and don't need whitespace before // them. if (Tok.is(tok::eof) || (Tok.isAnnotation() && !Tok.is(tok::annot_header_unit) && !Tok.is(tok::annot_module_begin) && !Tok.is(tok::annot_module_end) && !Tok.is(tok::annot_repl_input_end))) return; // EmittedDirectiveOnThisLine takes priority over RequireSameLine. if ((!RequireSameLine || EmittedDirectiveOnThisLine) && MoveToLine(Tok, /*RequireStartOfLine=*/EmittedDirectiveOnThisLine)) { if (MinimizeWhitespace) { // Avoid interpreting hash as a directive under -fpreprocessed. if (Tok.is(tok::hash)) *OS << ' '; } else { // Print out space characters so that the first token on a line is // indented for easy reading. unsigned ColNo = SM.getExpansionColumnNumber(Tok.getLocation()); // The first token on a line can have a column number of 1, yet still // expect leading white space, if a macro expansion in column 1 starts // with an empty macro argument, or an empty nested macro expansion. In // this case, move the token to column 2. if (ColNo == 1 && Tok.hasLeadingSpace()) ColNo = 2; // This hack prevents stuff like: // #define HASH # // HASH define foo bar // From having the # character end up at column 1, which makes it so it // is not handled as a #define next time through the preprocessor if in // -fpreprocessed mode. if (ColNo <= 1 && Tok.is(tok::hash)) *OS << ' '; // Otherwise, indent the appropriate number of spaces. for (; ColNo > 1; --ColNo) *OS << ' '; } } else { // Insert whitespace between the previous and next token if either // - The caller requires it // - The input had whitespace between them and we are not in // whitespace-minimization mode // - The whitespace is necessary to keep the tokens apart and there is not // already a newline between them if (RequireSpace || (!MinimizeWhitespace && Tok.hasLeadingSpace()) || ((EmittedTokensOnThisLine || EmittedDirectiveOnThisLine) && AvoidConcat(PrevPrevTok, PrevTok, Tok))) *OS << ' '; } PrevPrevTok = PrevTok; PrevTok = Tok; } void PrintPPOutputPPCallbacks::HandleNewlinesInToken(const char *TokStr, unsigned Len) { unsigned NumNewlines = 0; for (; Len; --Len, ++TokStr) { if (*TokStr != '\n' && *TokStr != '\r') continue; ++NumNewlines; // If we have \n\r or \r\n, skip both and count as one line. if (Len != 1 && (TokStr[1] == '\n' || TokStr[1] == '\r') && TokStr[0] != TokStr[1]) { ++TokStr; --Len; } } if (NumNewlines == 0) return; CurLine += NumNewlines; } namespace { struct UnknownPragmaHandler : public PragmaHandler { const char *Prefix; PrintPPOutputPPCallbacks *Callbacks; // Set to true if tokens should be expanded bool ShouldExpandTokens; UnknownPragmaHandler(const char *prefix, PrintPPOutputPPCallbacks *callbacks, bool RequireTokenExpansion) : Prefix(prefix), Callbacks(callbacks), ShouldExpandTokens(RequireTokenExpansion) {} void HandlePragma(Preprocessor &PP, PragmaIntroducer Introducer, Token &PragmaTok) override { // Figure out what line we went to and insert the appropriate number of // newline characters. Callbacks->MoveToLine(PragmaTok.getLocation(), /*RequireStartOfLine=*/true); Callbacks->OS->write(Prefix, strlen(Prefix)); Callbacks->setEmittedTokensOnThisLine(); if (ShouldExpandTokens) { // The first token does not have expanded macros. Expand them, if // required. auto Toks = std::make_unique(1); Toks[0] = PragmaTok; PP.EnterTokenStream(std::move(Toks), /*NumToks=*/1, /*DisableMacroExpansion=*/false, /*IsReinject=*/false); PP.Lex(PragmaTok); } // Read and print all of the pragma tokens. bool IsFirst = true; while (PragmaTok.isNot(tok::eod)) { Callbacks->HandleWhitespaceBeforeTok(PragmaTok, /*RequireSpace=*/IsFirst, /*RequireSameLine=*/true); IsFirst = false; std::string TokSpell = PP.getSpelling(PragmaTok); Callbacks->OS->write(&TokSpell[0], TokSpell.size()); Callbacks->setEmittedTokensOnThisLine(); if (ShouldExpandTokens) PP.Lex(PragmaTok); else PP.LexUnexpandedToken(PragmaTok); } Callbacks->setEmittedDirectiveOnThisLine(); } }; } // end anonymous namespace static void PrintPreprocessedTokens(Preprocessor &PP, Token &Tok, PrintPPOutputPPCallbacks *Callbacks) { bool DropComments = PP.getLangOpts().TraditionalCPP && !PP.getCommentRetentionState(); bool IsStartOfLine = false; char Buffer[256]; while (true) { // Two lines joined with line continuation ('\' as last character on the // line) must be emitted as one line even though Tok.getLine() returns two // different values. In this situation Tok.isAtStartOfLine() is false even // though it may be the first token on the lexical line. When // dropping/skipping a token that is at the start of a line, propagate the // start-of-line-ness to the next token to not append it to the previous // line. IsStartOfLine = IsStartOfLine || Tok.isAtStartOfLine(); Callbacks->HandleWhitespaceBeforeTok(Tok, /*RequireSpace=*/false, /*RequireSameLine=*/!IsStartOfLine); if (DropComments && Tok.is(tok::comment)) { // Skip comments. Normally the preprocessor does not generate // tok::comment nodes at all when not keeping comments, but under // -traditional-cpp the lexer keeps /all/ whitespace, including comments. PP.Lex(Tok); continue; } else if (Tok.is(tok::annot_repl_input_end)) { PP.Lex(Tok); continue; } else if (Tok.is(tok::eod)) { // Don't print end of directive tokens, since they are typically newlines // that mess up our line tracking. These come from unknown pre-processor // directives or hash-prefixed comments in standalone assembly files. PP.Lex(Tok); // FIXME: The token on the next line after #include should have // Tok.isAtStartOfLine() set. IsStartOfLine = true; continue; } else if (Tok.is(tok::annot_module_include)) { // PrintPPOutputPPCallbacks::InclusionDirective handles producing // appropriate output here. Ignore this token entirely. PP.Lex(Tok); IsStartOfLine = true; continue; } else if (Tok.is(tok::annot_module_begin)) { // FIXME: We retrieve this token after the FileChanged callback, and // retrieve the module_end token before the FileChanged callback, so // we render this within the file and render the module end outside the // file, but this is backwards from the token locations: the module_begin // token is at the include location (outside the file) and the module_end // token is at the EOF location (within the file). Callbacks->BeginModule( reinterpret_cast(Tok.getAnnotationValue())); PP.Lex(Tok); IsStartOfLine = true; continue; } else if (Tok.is(tok::annot_module_end)) { Callbacks->EndModule( reinterpret_cast(Tok.getAnnotationValue())); PP.Lex(Tok); IsStartOfLine = true; continue; } else if (Tok.is(tok::annot_header_unit)) { // This is a header-name that has been (effectively) converted into a // module-name. // FIXME: The module name could contain non-identifier module name // components. We don't have a good way to round-trip those. Module *M = reinterpret_cast(Tok.getAnnotationValue()); std::string Name = M->getFullModuleName(); Callbacks->OS->write(Name.data(), Name.size()); Callbacks->HandleNewlinesInToken(Name.data(), Name.size()); } else if (Tok.isAnnotation()) { // Ignore annotation tokens created by pragmas - the pragmas themselves // will be reproduced in the preprocessed output. PP.Lex(Tok); continue; } else if (IdentifierInfo *II = Tok.getIdentifierInfo()) { *Callbacks->OS << II->getName(); } else if (Tok.isLiteral() && !Tok.needsCleaning() && Tok.getLiteralData()) { Callbacks->OS->write(Tok.getLiteralData(), Tok.getLength()); } else if (Tok.getLength() < std::size(Buffer)) { const char *TokPtr = Buffer; unsigned Len = PP.getSpelling(Tok, TokPtr); Callbacks->OS->write(TokPtr, Len); // Tokens that can contain embedded newlines need to adjust our current // line number. // FIXME: The token may end with a newline in which case // setEmittedDirectiveOnThisLine/setEmittedTokensOnThisLine afterwards is // wrong. if (Tok.getKind() == tok::comment || Tok.getKind() == tok::unknown) Callbacks->HandleNewlinesInToken(TokPtr, Len); if (Tok.is(tok::comment) && Len >= 2 && TokPtr[0] == '/' && TokPtr[1] == '/') { // It's a line comment; // Ensure that we don't concatenate anything behind it. Callbacks->setEmittedDirectiveOnThisLine(); } } else { std::string S = PP.getSpelling(Tok); Callbacks->OS->write(S.data(), S.size()); // Tokens that can contain embedded newlines need to adjust our current // line number. if (Tok.getKind() == tok::comment || Tok.getKind() == tok::unknown) Callbacks->HandleNewlinesInToken(S.data(), S.size()); if (Tok.is(tok::comment) && S.size() >= 2 && S[0] == '/' && S[1] == '/') { // It's a line comment; // Ensure that we don't concatenate anything behind it. Callbacks->setEmittedDirectiveOnThisLine(); } } Callbacks->setEmittedTokensOnThisLine(); IsStartOfLine = false; if (Tok.is(tok::eof)) break; PP.Lex(Tok); } } typedef std::pair id_macro_pair; static int MacroIDCompare(const id_macro_pair *LHS, const id_macro_pair *RHS) { return LHS->first->getName().compare(RHS->first->getName()); } static void DoPrintMacros(Preprocessor &PP, raw_ostream *OS) { // Ignore unknown pragmas. PP.IgnorePragmas(); // -dM mode just scans and ignores all tokens in the files, then dumps out // the macro table at the end. PP.EnterMainSourceFile(); Token Tok; do PP.Lex(Tok); while (Tok.isNot(tok::eof)); SmallVector MacrosByID; for (Preprocessor::macro_iterator I = PP.macro_begin(), E = PP.macro_end(); I != E; ++I) { auto *MD = I->second.getLatest(); if (MD && MD->isDefined()) MacrosByID.push_back(id_macro_pair(I->first, MD->getMacroInfo())); } llvm::array_pod_sort(MacrosByID.begin(), MacrosByID.end(), MacroIDCompare); for (unsigned i = 0, e = MacrosByID.size(); i != e; ++i) { MacroInfo &MI = *MacrosByID[i].second; // Ignore computed macros like __LINE__ and friends. if (MI.isBuiltinMacro()) continue; PrintMacroDefinition(*MacrosByID[i].first, MI, PP, OS); *OS << '\n'; } } /// DoPrintPreprocessedInput - This implements -E mode. /// void clang::DoPrintPreprocessedInput(Preprocessor &PP, raw_ostream *OS, const PreprocessorOutputOptions &Opts) { // Show macros with no output is handled specially. if (!Opts.ShowCPP) { assert(Opts.ShowMacros && "Not yet implemented!"); DoPrintMacros(PP, OS); return; } // Inform the preprocessor whether we want it to retain comments or not, due // to -C or -CC. PP.SetCommentRetentionState(Opts.ShowComments, Opts.ShowMacroComments); PrintPPOutputPPCallbacks *Callbacks = new PrintPPOutputPPCallbacks( PP, OS, !Opts.ShowLineMarkers, Opts.ShowMacros, Opts.ShowIncludeDirectives, Opts.UseLineDirectives, Opts.MinimizeWhitespace, Opts.DirectivesOnly, Opts.KeepSystemIncludes); // Expand macros in pragmas with -fms-extensions. The assumption is that // the majority of pragmas in such a file will be Microsoft pragmas. // Remember the handlers we will add so that we can remove them later. std::unique_ptr MicrosoftExtHandler( new UnknownPragmaHandler( "#pragma", Callbacks, /*RequireTokenExpansion=*/PP.getLangOpts().MicrosoftExt)); std::unique_ptr GCCHandler(new UnknownPragmaHandler( "#pragma GCC", Callbacks, /*RequireTokenExpansion=*/PP.getLangOpts().MicrosoftExt)); std::unique_ptr ClangHandler(new UnknownPragmaHandler( "#pragma clang", Callbacks, /*RequireTokenExpansion=*/PP.getLangOpts().MicrosoftExt)); PP.AddPragmaHandler(MicrosoftExtHandler.get()); PP.AddPragmaHandler("GCC", GCCHandler.get()); PP.AddPragmaHandler("clang", ClangHandler.get()); // The tokens after pragma omp need to be expanded. // // OpenMP [2.1, Directive format] // Preprocessing tokens following the #pragma omp are subject to macro // replacement. std::unique_ptr OpenMPHandler( new UnknownPragmaHandler("#pragma omp", Callbacks, /*RequireTokenExpansion=*/true)); PP.AddPragmaHandler("omp", OpenMPHandler.get()); PP.addPPCallbacks(std::unique_ptr(Callbacks)); // After we have configured the preprocessor, enter the main file. PP.EnterMainSourceFile(); if (Opts.DirectivesOnly) PP.SetMacroExpansionOnlyInDirectives(); // Consume all of the tokens that come from the predefines buffer. Those // should not be emitted into the output and are guaranteed to be at the // start. const SourceManager &SourceMgr = PP.getSourceManager(); Token Tok; do { PP.Lex(Tok); if (Tok.is(tok::eof) || !Tok.getLocation().isFileID()) break; PresumedLoc PLoc = SourceMgr.getPresumedLoc(Tok.getLocation()); if (PLoc.isInvalid()) break; if (strcmp(PLoc.getFilename(), "")) break; } while (true); // Read all the preprocessed tokens, printing them out to the stream. PrintPreprocessedTokens(PP, Tok, Callbacks); *OS << '\n'; // Remove the handlers we just added to leave the preprocessor in a sane state // so that it can be reused (for example by a clang::Parser instance). PP.RemovePragmaHandler(MicrosoftExtHandler.get()); PP.RemovePragmaHandler("GCC", GCCHandler.get()); PP.RemovePragmaHandler("clang", ClangHandler.get()); PP.RemovePragmaHandler("omp", OpenMPHandler.get()); }