//===- TGLexer.cpp - Lexer for TableGen -----------------------------------===// // // 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 // //===----------------------------------------------------------------------===// // // Implement the Lexer for TableGen. // //===----------------------------------------------------------------------===// #include "TGLexer.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/StringSwitch.h" #include "llvm/ADT/Twine.h" #include "llvm/Config/config.h" // for strtoull()/strtoll() define #include "llvm/Support/Compiler.h" #include "llvm/Support/MemoryBuffer.h" #include "llvm/Support/SourceMgr.h" #include "llvm/TableGen/Error.h" #include #include #include #include #include #include #include using namespace llvm; namespace { // A list of supported preprocessing directives with their // internal token kinds and names. struct { tgtok::TokKind Kind; const char *Word; } PreprocessorDirs[] = { { tgtok::Ifdef, "ifdef" }, { tgtok::Ifndef, "ifndef" }, { tgtok::Else, "else" }, { tgtok::Endif, "endif" }, { tgtok::Define, "define" } }; } // end anonymous namespace TGLexer::TGLexer(SourceMgr &SM, ArrayRef Macros) : SrcMgr(SM) { CurBuffer = SrcMgr.getMainFileID(); CurBuf = SrcMgr.getMemoryBuffer(CurBuffer)->getBuffer(); CurPtr = CurBuf.begin(); TokStart = nullptr; // Pretend that we enter the "top-level" include file. PrepIncludeStack.push_back( std::make_unique>()); // Put all macros defined in the command line into the DefinedMacros set. for (const std::string &MacroName : Macros) DefinedMacros.insert(MacroName); } SMLoc TGLexer::getLoc() const { return SMLoc::getFromPointer(TokStart); } SMRange TGLexer::getLocRange() const { return {getLoc(), SMLoc::getFromPointer(CurPtr)}; } /// ReturnError - Set the error to the specified string at the specified /// location. This is defined to always return tgtok::Error. tgtok::TokKind TGLexer::ReturnError(SMLoc Loc, const Twine &Msg) { PrintError(Loc, Msg); return tgtok::Error; } tgtok::TokKind TGLexer::ReturnError(const char *Loc, const Twine &Msg) { return ReturnError(SMLoc::getFromPointer(Loc), Msg); } bool TGLexer::processEOF() { SMLoc ParentIncludeLoc = SrcMgr.getParentIncludeLoc(CurBuffer); if (ParentIncludeLoc != SMLoc()) { // If prepExitInclude() detects a problem with the preprocessing // control stack, it will return false. Pretend that we reached // the final EOF and stop lexing more tokens by returning false // to LexToken(). if (!prepExitInclude(false)) return false; CurBuffer = SrcMgr.FindBufferContainingLoc(ParentIncludeLoc); CurBuf = SrcMgr.getMemoryBuffer(CurBuffer)->getBuffer(); CurPtr = ParentIncludeLoc.getPointer(); // Make sure TokStart points into the parent file's buffer. // LexToken() assigns to it before calling getNextChar(), // so it is pointing into the included file now. TokStart = CurPtr; return true; } // Pretend that we exit the "top-level" include file. // Note that in case of an error (e.g. control stack imbalance) // the routine will issue a fatal error. prepExitInclude(true); return false; } int TGLexer::getNextChar() { char CurChar = *CurPtr++; switch (CurChar) { default: return (unsigned char)CurChar; case 0: { // A NUL character in the stream is either the end of the current buffer or // a spurious NUL in the file. Disambiguate that here. if (CurPtr - 1 == CurBuf.end()) { --CurPtr; // Arrange for another call to return EOF again. return EOF; } PrintError(getLoc(), "NUL character is invalid in source; treated as space"); return ' '; } case '\n': case '\r': // Handle the newline character by ignoring it and incrementing the line // count. However, be careful about 'dos style' files with \n\r in them. // Only treat a \n\r or \r\n as a single line. if ((*CurPtr == '\n' || (*CurPtr == '\r')) && *CurPtr != CurChar) ++CurPtr; // Eat the two char newline sequence. return '\n'; } } int TGLexer::peekNextChar(int Index) const { return *(CurPtr + Index); } tgtok::TokKind TGLexer::LexToken(bool FileOrLineStart) { TokStart = CurPtr; // This always consumes at least one character. int CurChar = getNextChar(); switch (CurChar) { default: // Handle letters: [a-zA-Z_] if (isalpha(CurChar) || CurChar == '_') return LexIdentifier(); // Unknown character, emit an error. return ReturnError(TokStart, "Unexpected character"); case EOF: // Lex next token, if we just left an include file. // Note that leaving an include file means that the next // symbol is located at the end of the 'include "..."' // construct, so LexToken() is called with default // false parameter. if (processEOF()) return LexToken(); // Return EOF denoting the end of lexing. return tgtok::Eof; case ':': return tgtok::colon; case ';': return tgtok::semi; case ',': return tgtok::comma; case '<': return tgtok::less; case '>': return tgtok::greater; case ']': return tgtok::r_square; case '{': return tgtok::l_brace; case '}': return tgtok::r_brace; case '(': return tgtok::l_paren; case ')': return tgtok::r_paren; case '=': return tgtok::equal; case '?': return tgtok::question; case '#': if (FileOrLineStart) { tgtok::TokKind Kind = prepIsDirective(); if (Kind != tgtok::Error) return lexPreprocessor(Kind); } return tgtok::paste; // The period is a separate case so we can recognize the "..." // range punctuator. case '.': if (peekNextChar(0) == '.') { ++CurPtr; // Eat second dot. if (peekNextChar(0) == '.') { ++CurPtr; // Eat third dot. return tgtok::dotdotdot; } return ReturnError(TokStart, "Invalid '..' punctuation"); } return tgtok::dot; case '\r': PrintFatalError("getNextChar() must never return '\r'"); return tgtok::Error; case ' ': case '\t': // Ignore whitespace. return LexToken(FileOrLineStart); case '\n': // Ignore whitespace, and identify the new line. return LexToken(true); case '/': // If this is the start of a // comment, skip until the end of the line or // the end of the buffer. if (*CurPtr == '/') SkipBCPLComment(); else if (*CurPtr == '*') { if (SkipCComment()) return tgtok::Error; } else // Otherwise, this is an error. return ReturnError(TokStart, "Unexpected character"); return LexToken(FileOrLineStart); case '-': case '+': case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9': { int NextChar = 0; if (isdigit(CurChar)) { // Allow identifiers to start with a number if it is followed by // an identifier. This can happen with paste operations like // foo#8i. int i = 0; do { NextChar = peekNextChar(i++); } while (isdigit(NextChar)); if (NextChar == 'x' || NextChar == 'b') { // If this is [0-9]b[01] or [0-9]x[0-9A-fa-f] this is most // likely a number. int NextNextChar = peekNextChar(i); switch (NextNextChar) { default: break; case '0': case '1': if (NextChar == 'b') return LexNumber(); [[fallthrough]]; case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9': case 'a': case 'b': case 'c': case 'd': case 'e': case 'f': case 'A': case 'B': case 'C': case 'D': case 'E': case 'F': if (NextChar == 'x') return LexNumber(); break; } } } if (isalpha(NextChar) || NextChar == '_') return LexIdentifier(); return LexNumber(); } case '"': return LexString(); case '$': return LexVarName(); case '[': return LexBracket(); case '!': return LexExclaim(); } } /// LexString - Lex "[^"]*" tgtok::TokKind TGLexer::LexString() { const char *StrStart = CurPtr; CurStrVal = ""; while (*CurPtr != '"') { // If we hit the end of the buffer, report an error. if (*CurPtr == 0 && CurPtr == CurBuf.end()) return ReturnError(StrStart, "End of file in string literal"); if (*CurPtr == '\n' || *CurPtr == '\r') return ReturnError(StrStart, "End of line in string literal"); if (*CurPtr != '\\') { CurStrVal += *CurPtr++; continue; } ++CurPtr; switch (*CurPtr) { case '\\': case '\'': case '"': // These turn into their literal character. CurStrVal += *CurPtr++; break; case 't': CurStrVal += '\t'; ++CurPtr; break; case 'n': CurStrVal += '\n'; ++CurPtr; break; case '\n': case '\r': return ReturnError(CurPtr, "escaped newlines not supported in tblgen"); // If we hit the end of the buffer, report an error. case '\0': if (CurPtr == CurBuf.end()) return ReturnError(StrStart, "End of file in string literal"); [[fallthrough]]; default: return ReturnError(CurPtr, "invalid escape in string literal"); } } ++CurPtr; return tgtok::StrVal; } tgtok::TokKind TGLexer::LexVarName() { if (!isalpha(CurPtr[0]) && CurPtr[0] != '_') return ReturnError(TokStart, "Invalid variable name"); // Otherwise, we're ok, consume the rest of the characters. const char *VarNameStart = CurPtr++; while (isalpha(*CurPtr) || isdigit(*CurPtr) || *CurPtr == '_') ++CurPtr; CurStrVal.assign(VarNameStart, CurPtr); return tgtok::VarName; } tgtok::TokKind TGLexer::LexIdentifier() { // The first letter is [a-zA-Z_]. const char *IdentStart = TokStart; // Match the rest of the identifier regex: [0-9a-zA-Z_]* while (isalpha(*CurPtr) || isdigit(*CurPtr) || *CurPtr == '_') ++CurPtr; // Check to see if this identifier is a reserved keyword. StringRef Str(IdentStart, CurPtr-IdentStart); tgtok::TokKind Kind = StringSwitch(Str) .Case("int", tgtok::Int) .Case("bit", tgtok::Bit) .Case("bits", tgtok::Bits) .Case("string", tgtok::String) .Case("list", tgtok::List) .Case("code", tgtok::Code) .Case("dag", tgtok::Dag) .Case("class", tgtok::Class) .Case("def", tgtok::Def) .Case("true", tgtok::TrueVal) .Case("false", tgtok::FalseVal) .Case("foreach", tgtok::Foreach) .Case("defm", tgtok::Defm) .Case("defset", tgtok::Defset) .Case("multiclass", tgtok::MultiClass) .Case("field", tgtok::Field) .Case("let", tgtok::Let) .Case("in", tgtok::In) .Case("defvar", tgtok::Defvar) .Case("include", tgtok::Include) .Case("if", tgtok::If) .Case("then", tgtok::Then) .Case("else", tgtok::ElseKW) .Case("assert", tgtok::Assert) .Default(tgtok::Id); // A couple of tokens require special processing. switch (Kind) { case tgtok::Include: if (LexInclude()) return tgtok::Error; return Lex(); case tgtok::Id: CurStrVal.assign(Str.begin(), Str.end()); break; default: break; } return Kind; } /// LexInclude - We just read the "include" token. Get the string token that /// comes next and enter the include. bool TGLexer::LexInclude() { // The token after the include must be a string. tgtok::TokKind Tok = LexToken(); if (Tok == tgtok::Error) return true; if (Tok != tgtok::StrVal) { PrintError(getLoc(), "Expected filename after include"); return true; } // Get the string. std::string Filename = CurStrVal; std::string IncludedFile; CurBuffer = SrcMgr.AddIncludeFile(Filename, SMLoc::getFromPointer(CurPtr), IncludedFile); if (!CurBuffer) { PrintError(getLoc(), "Could not find include file '" + Filename + "'"); return true; } Dependencies.insert(IncludedFile); // Save the line number and lex buffer of the includer. CurBuf = SrcMgr.getMemoryBuffer(CurBuffer)->getBuffer(); CurPtr = CurBuf.begin(); PrepIncludeStack.push_back( std::make_unique>()); return false; } /// SkipBCPLComment - Skip over the comment by finding the next CR or LF. /// Or we may end up at the end of the buffer. void TGLexer::SkipBCPLComment() { ++CurPtr; // skip the second slash. auto EOLPos = CurBuf.find_first_of("\r\n", CurPtr - CurBuf.data()); CurPtr = (EOLPos == StringRef::npos) ? CurBuf.end() : CurBuf.data() + EOLPos; } /// SkipCComment - This skips C-style /**/ comments. The only difference from C /// is that we allow nesting. bool TGLexer::SkipCComment() { ++CurPtr; // skip the star. unsigned CommentDepth = 1; while (true) { int CurChar = getNextChar(); switch (CurChar) { case EOF: PrintError(TokStart, "Unterminated comment!"); return true; case '*': // End of the comment? if (CurPtr[0] != '/') break; ++CurPtr; // End the */. if (--CommentDepth == 0) return false; break; case '/': // Start of a nested comment? if (CurPtr[0] != '*') break; ++CurPtr; ++CommentDepth; break; } } } /// LexNumber - Lex: /// [-+]?[0-9]+ /// 0x[0-9a-fA-F]+ /// 0b[01]+ tgtok::TokKind TGLexer::LexNumber() { if (CurPtr[-1] == '0') { if (CurPtr[0] == 'x') { ++CurPtr; const char *NumStart = CurPtr; while (isxdigit(CurPtr[0])) ++CurPtr; // Requires at least one hex digit. if (CurPtr == NumStart) return ReturnError(TokStart, "Invalid hexadecimal number"); errno = 0; CurIntVal = strtoll(NumStart, nullptr, 16); if (errno == EINVAL) return ReturnError(TokStart, "Invalid hexadecimal number"); if (errno == ERANGE) { errno = 0; CurIntVal = (int64_t)strtoull(NumStart, nullptr, 16); if (errno == EINVAL) return ReturnError(TokStart, "Invalid hexadecimal number"); if (errno == ERANGE) return ReturnError(TokStart, "Hexadecimal number out of range"); } return tgtok::IntVal; } else if (CurPtr[0] == 'b') { ++CurPtr; const char *NumStart = CurPtr; while (CurPtr[0] == '0' || CurPtr[0] == '1') ++CurPtr; // Requires at least one binary digit. if (CurPtr == NumStart) return ReturnError(CurPtr-2, "Invalid binary number"); CurIntVal = strtoll(NumStart, nullptr, 2); return tgtok::BinaryIntVal; } } // Check for a sign without a digit. if (!isdigit(CurPtr[0])) { if (CurPtr[-1] == '-') return tgtok::minus; else if (CurPtr[-1] == '+') return tgtok::plus; } while (isdigit(CurPtr[0])) ++CurPtr; CurIntVal = strtoll(TokStart, nullptr, 10); return tgtok::IntVal; } /// LexBracket - We just read '['. If this is a code block, return it, /// otherwise return the bracket. Match: '[' and '[{ ( [^}]+ | }[^]] )* }]' tgtok::TokKind TGLexer::LexBracket() { if (CurPtr[0] != '{') return tgtok::l_square; ++CurPtr; const char *CodeStart = CurPtr; while (true) { int Char = getNextChar(); if (Char == EOF) break; if (Char != '}') continue; Char = getNextChar(); if (Char == EOF) break; if (Char == ']') { CurStrVal.assign(CodeStart, CurPtr-2); return tgtok::CodeFragment; } } return ReturnError(CodeStart - 2, "Unterminated code block"); } /// LexExclaim - Lex '!' and '![a-zA-Z]+'. tgtok::TokKind TGLexer::LexExclaim() { if (!isalpha(*CurPtr)) return ReturnError(CurPtr - 1, "Invalid \"!operator\""); const char *Start = CurPtr++; while (isalpha(*CurPtr)) ++CurPtr; // Check to see which operator this is. tgtok::TokKind Kind = StringSwitch(StringRef(Start, CurPtr - Start)) .Case("eq", tgtok::XEq) .Case("ne", tgtok::XNe) .Case("le", tgtok::XLe) .Case("lt", tgtok::XLt) .Case("ge", tgtok::XGe) .Case("gt", tgtok::XGt) .Case("if", tgtok::XIf) .Case("cond", tgtok::XCond) .Case("isa", tgtok::XIsA) .Case("head", tgtok::XHead) .Case("tail", tgtok::XTail) .Case("size", tgtok::XSize) .Case("con", tgtok::XConcat) .Case("dag", tgtok::XDag) .Case("add", tgtok::XADD) .Case("sub", tgtok::XSUB) .Case("mul", tgtok::XMUL) .Case("div", tgtok::XDIV) .Case("not", tgtok::XNOT) .Case("logtwo", tgtok::XLOG2) .Case("and", tgtok::XAND) .Case("or", tgtok::XOR) .Case("xor", tgtok::XXOR) .Case("shl", tgtok::XSHL) .Case("sra", tgtok::XSRA) .Case("srl", tgtok::XSRL) .Case("cast", tgtok::XCast) .Case("empty", tgtok::XEmpty) .Case("subst", tgtok::XSubst) .Case("foldl", tgtok::XFoldl) .Case("foreach", tgtok::XForEach) .Case("filter", tgtok::XFilter) .Case("listconcat", tgtok::XListConcat) .Case("listsplat", tgtok::XListSplat) .Case("listremove", tgtok::XListRemove) .Case("strconcat", tgtok::XStrConcat) .Case("interleave", tgtok::XInterleave) .Case("substr", tgtok::XSubstr) .Case("find", tgtok::XFind) .Cases("setdagop", "setop", tgtok::XSetDagOp) // !setop is deprecated. .Cases("getdagop", "getop", tgtok::XGetDagOp) // !getop is deprecated. .Case("exists", tgtok::XExists) .Default(tgtok::Error); return Kind != tgtok::Error ? Kind : ReturnError(Start-1, "Unknown operator"); } bool TGLexer::prepExitInclude(bool IncludeStackMustBeEmpty) { // Report an error, if preprocessor control stack for the current // file is not empty. if (!PrepIncludeStack.back()->empty()) { prepReportPreprocessorStackError(); return false; } // Pop the preprocessing controls from the include stack. if (PrepIncludeStack.empty()) { PrintFatalError("Preprocessor include stack is empty"); } PrepIncludeStack.pop_back(); if (IncludeStackMustBeEmpty) { if (!PrepIncludeStack.empty()) PrintFatalError("Preprocessor include stack is not empty"); } else { if (PrepIncludeStack.empty()) PrintFatalError("Preprocessor include stack is empty"); } return true; } tgtok::TokKind TGLexer::prepIsDirective() const { for (const auto &PD : PreprocessorDirs) { int NextChar = *CurPtr; bool Match = true; unsigned I = 0; for (; I < strlen(PD.Word); ++I) { if (NextChar != PD.Word[I]) { Match = false; break; } NextChar = peekNextChar(I + 1); } // Check for whitespace after the directive. If there is no whitespace, // then we do not recognize it as a preprocessing directive. if (Match) { tgtok::TokKind Kind = PD.Kind; // New line and EOF may follow only #else/#endif. It will be reported // as an error for #ifdef/#define after the call to prepLexMacroName(). if (NextChar == ' ' || NextChar == '\t' || NextChar == EOF || NextChar == '\n' || // It looks like TableGen does not support '\r' as the actual // carriage return, e.g. getNextChar() treats a single '\r' // as '\n'. So we do the same here. NextChar == '\r') return Kind; // Allow comments after some directives, e.g.: // #else// OR #else/**/ // #endif// OR #endif/**/ // // Note that we do allow comments after #ifdef/#define here, e.g. // #ifdef/**/ AND #ifdef// // #define/**/ AND #define// // // These cases will be reported as incorrect after calling // prepLexMacroName(). We could have supported C-style comments // after #ifdef/#define, but this would complicate the code // for little benefit. if (NextChar == '/') { NextChar = peekNextChar(I + 1); if (NextChar == '*' || NextChar == '/') return Kind; // Pretend that we do not recognize the directive. } } } return tgtok::Error; } bool TGLexer::prepEatPreprocessorDirective(tgtok::TokKind Kind) { TokStart = CurPtr; for (const auto &PD : PreprocessorDirs) if (PD.Kind == Kind) { // Advance CurPtr to the end of the preprocessing word. CurPtr += strlen(PD.Word); return true; } PrintFatalError("Unsupported preprocessing token in " "prepEatPreprocessorDirective()"); return false; } tgtok::TokKind TGLexer::lexPreprocessor( tgtok::TokKind Kind, bool ReturnNextLiveToken) { // We must be looking at a preprocessing directive. Eat it! if (!prepEatPreprocessorDirective(Kind)) PrintFatalError("lexPreprocessor() called for unknown " "preprocessor directive"); if (Kind == tgtok::Ifdef || Kind == tgtok::Ifndef) { StringRef MacroName = prepLexMacroName(); StringRef IfTokName = Kind == tgtok::Ifdef ? "#ifdef" : "#ifndef"; if (MacroName.empty()) return ReturnError(TokStart, "Expected macro name after " + IfTokName); bool MacroIsDefined = DefinedMacros.count(MacroName) != 0; // Canonicalize ifndef to ifdef equivalent if (Kind == tgtok::Ifndef) { MacroIsDefined = !MacroIsDefined; Kind = tgtok::Ifdef; } // Regardless of whether we are processing tokens or not, // we put the #ifdef control on stack. PrepIncludeStack.back()->push_back( {Kind, MacroIsDefined, SMLoc::getFromPointer(TokStart)}); if (!prepSkipDirectiveEnd()) return ReturnError(CurPtr, "Only comments are supported after " + IfTokName + " NAME"); // If we were not processing tokens before this #ifdef, // then just return back to the lines skipping code. if (!ReturnNextLiveToken) return Kind; // If we were processing tokens before this #ifdef, // and the macro is defined, then just return the next token. if (MacroIsDefined) return LexToken(); // We were processing tokens before this #ifdef, and the macro // is not defined, so we have to start skipping the lines. // If the skipping is successful, it will return the token following // either #else or #endif corresponding to this #ifdef. if (prepSkipRegion(ReturnNextLiveToken)) return LexToken(); return tgtok::Error; } else if (Kind == tgtok::Else) { // Check if this #else is correct before calling prepSkipDirectiveEnd(), // which will move CurPtr away from the beginning of #else. if (PrepIncludeStack.back()->empty()) return ReturnError(TokStart, "#else without #ifdef or #ifndef"); PreprocessorControlDesc IfdefEntry = PrepIncludeStack.back()->back(); if (IfdefEntry.Kind != tgtok::Ifdef) { PrintError(TokStart, "double #else"); return ReturnError(IfdefEntry.SrcPos, "Previous #else is here"); } // Replace the corresponding #ifdef's control with its negation // on the control stack. PrepIncludeStack.back()->pop_back(); PrepIncludeStack.back()->push_back( {Kind, !IfdefEntry.IsDefined, SMLoc::getFromPointer(TokStart)}); if (!prepSkipDirectiveEnd()) return ReturnError(CurPtr, "Only comments are supported after #else"); // If we were processing tokens before this #else, // we have to start skipping lines until the matching #endif. if (ReturnNextLiveToken) { if (prepSkipRegion(ReturnNextLiveToken)) return LexToken(); return tgtok::Error; } // Return to the lines skipping code. return Kind; } else if (Kind == tgtok::Endif) { // Check if this #endif is correct before calling prepSkipDirectiveEnd(), // which will move CurPtr away from the beginning of #endif. if (PrepIncludeStack.back()->empty()) return ReturnError(TokStart, "#endif without #ifdef"); auto &IfdefOrElseEntry = PrepIncludeStack.back()->back(); if (IfdefOrElseEntry.Kind != tgtok::Ifdef && IfdefOrElseEntry.Kind != tgtok::Else) { PrintFatalError("Invalid preprocessor control on the stack"); return tgtok::Error; } if (!prepSkipDirectiveEnd()) return ReturnError(CurPtr, "Only comments are supported after #endif"); PrepIncludeStack.back()->pop_back(); // If we were processing tokens before this #endif, then // we should continue it. if (ReturnNextLiveToken) { return LexToken(); } // Return to the lines skipping code. return Kind; } else if (Kind == tgtok::Define) { StringRef MacroName = prepLexMacroName(); if (MacroName.empty()) return ReturnError(TokStart, "Expected macro name after #define"); if (!DefinedMacros.insert(MacroName).second) PrintWarning(getLoc(), "Duplicate definition of macro: " + Twine(MacroName)); if (!prepSkipDirectiveEnd()) return ReturnError(CurPtr, "Only comments are supported after #define NAME"); if (!ReturnNextLiveToken) { PrintFatalError("#define must be ignored during the lines skipping"); return tgtok::Error; } return LexToken(); } PrintFatalError("Preprocessing directive is not supported"); return tgtok::Error; } bool TGLexer::prepSkipRegion(bool MustNeverBeFalse) { if (!MustNeverBeFalse) PrintFatalError("Invalid recursion."); do { // Skip all symbols to the line end. prepSkipToLineEnd(); // Find the first non-whitespace symbol in the next line(s). if (!prepSkipLineBegin()) return false; // If the first non-blank/comment symbol on the line is '#', // it may be a start of preprocessing directive. // // If it is not '#' just go to the next line. if (*CurPtr == '#') ++CurPtr; else continue; tgtok::TokKind Kind = prepIsDirective(); // If we did not find a preprocessing directive or it is #define, // then just skip to the next line. We do not have to do anything // for #define in the line-skipping mode. if (Kind == tgtok::Error || Kind == tgtok::Define) continue; tgtok::TokKind ProcessedKind = lexPreprocessor(Kind, false); // If lexPreprocessor() encountered an error during lexing this // preprocessor idiom, then return false to the calling lexPreprocessor(). // This will force tgtok::Error to be returned to the tokens processing. if (ProcessedKind == tgtok::Error) return false; if (Kind != ProcessedKind) PrintFatalError("prepIsDirective() and lexPreprocessor() " "returned different token kinds"); // If this preprocessing directive enables tokens processing, // then return to the lexPreprocessor() and get to the next token. // We can move from line-skipping mode to processing tokens only // due to #else or #endif. if (prepIsProcessingEnabled()) { if (Kind != tgtok::Else && Kind != tgtok::Endif) { PrintFatalError("Tokens processing was enabled by an unexpected " "preprocessing directive"); return false; } return true; } } while (CurPtr != CurBuf.end()); // We have reached the end of the file, but never left the lines-skipping // mode. This means there is no matching #endif. prepReportPreprocessorStackError(); return false; } StringRef TGLexer::prepLexMacroName() { // Skip whitespaces between the preprocessing directive and the macro name. while (*CurPtr == ' ' || *CurPtr == '\t') ++CurPtr; TokStart = CurPtr; // Macro names start with [a-zA-Z_]. if (*CurPtr != '_' && !isalpha(*CurPtr)) return ""; // Match the rest of the identifier regex: [0-9a-zA-Z_]* while (isalpha(*CurPtr) || isdigit(*CurPtr) || *CurPtr == '_') ++CurPtr; return StringRef(TokStart, CurPtr - TokStart); } bool TGLexer::prepSkipLineBegin() { while (CurPtr != CurBuf.end()) { switch (*CurPtr) { case ' ': case '\t': case '\n': case '\r': break; case '/': { int NextChar = peekNextChar(1); if (NextChar == '*') { // Skip C-style comment. // Note that we do not care about skipping the C++-style comments. // If the line contains "//", it may not contain any processable // preprocessing directive. Just return CurPtr pointing to // the first '/' in this case. We also do not care about // incorrect symbols after the first '/' - we are in lines-skipping // mode, so incorrect code is allowed to some extent. // Set TokStart to the beginning of the comment to enable proper // diagnostic printing in case of error in SkipCComment(). TokStart = CurPtr; // CurPtr must point to '*' before call to SkipCComment(). ++CurPtr; if (SkipCComment()) return false; } else { // CurPtr points to the non-whitespace '/'. return true; } // We must not increment CurPtr after the comment was lexed. continue; } default: return true; } ++CurPtr; } // We have reached the end of the file. Return to the lines skipping // code, and allow it to handle the EOF as needed. return true; } bool TGLexer::prepSkipDirectiveEnd() { while (CurPtr != CurBuf.end()) { switch (*CurPtr) { case ' ': case '\t': break; case '\n': case '\r': return true; case '/': { int NextChar = peekNextChar(1); if (NextChar == '/') { // Skip C++-style comment. // We may just return true now, but let's skip to the line/buffer end // to simplify the method specification. ++CurPtr; SkipBCPLComment(); } else if (NextChar == '*') { // When we are skipping C-style comment at the end of a preprocessing // directive, we can skip several lines. If any meaningful TD token // follows the end of the C-style comment on the same line, it will // be considered as an invalid usage of TD token. // For example, we want to forbid usages like this one: // #define MACRO class Class {} // But with C-style comments we also disallow the following: // #define MACRO /* This macro is used // to ... */ class Class {} // One can argue that this should be allowed, but it does not seem // to be worth of the complication. Moreover, this matches // the C preprocessor behavior. // Set TokStart to the beginning of the comment to enable proper // diagnostic printer in case of error in SkipCComment(). TokStart = CurPtr; ++CurPtr; if (SkipCComment()) return false; } else { TokStart = CurPtr; PrintError(CurPtr, "Unexpected character"); return false; } // We must not increment CurPtr after the comment was lexed. continue; } default: // Do not allow any non-whitespaces after the directive. TokStart = CurPtr; return false; } ++CurPtr; } return true; } void TGLexer::prepSkipToLineEnd() { while (*CurPtr != '\n' && *CurPtr != '\r' && CurPtr != CurBuf.end()) ++CurPtr; } bool TGLexer::prepIsProcessingEnabled() { for (const PreprocessorControlDesc &I : llvm::reverse(*PrepIncludeStack.back())) if (!I.IsDefined) return false; return true; } void TGLexer::prepReportPreprocessorStackError() { if (PrepIncludeStack.back()->empty()) PrintFatalError("prepReportPreprocessorStackError() called with " "empty control stack"); auto &PrepControl = PrepIncludeStack.back()->back(); PrintError(CurBuf.end(), "Reached EOF without matching #endif"); PrintError(PrepControl.SrcPos, "The latest preprocessor control is here"); TokStart = CurPtr; }