//===--- FormatTokenLexer.cpp - Lex FormatTokens -------------*- C++ ----*-===// // // 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 // //===----------------------------------------------------------------------===// /// /// \file /// This file implements FormatTokenLexer, which tokenizes a source file /// into a FormatToken stream suitable for ClangFormat. /// //===----------------------------------------------------------------------===// #include "FormatTokenLexer.h" #include "FormatToken.h" #include "clang/Basic/SourceLocation.h" #include "clang/Basic/SourceManager.h" #include "clang/Format/Format.h" #include "llvm/Support/Regex.h" namespace clang { namespace format { FormatTokenLexer::FormatTokenLexer( const SourceManager &SourceMgr, FileID ID, unsigned Column, const FormatStyle &Style, encoding::Encoding Encoding, llvm::SpecificBumpPtrAllocator &Allocator, IdentifierTable &IdentTable) : FormatTok(nullptr), IsFirstToken(true), StateStack({LexerState::NORMAL}), Column(Column), TrailingWhitespace(0), LangOpts(getFormattingLangOpts(Style)), SourceMgr(SourceMgr), ID(ID), Style(Style), IdentTable(IdentTable), Keywords(IdentTable), Encoding(Encoding), Allocator(Allocator), FirstInLineIndex(0), FormattingDisabled(false), MacroBlockBeginRegex(Style.MacroBlockBegin), MacroBlockEndRegex(Style.MacroBlockEnd) { Lex.reset(new Lexer(ID, SourceMgr.getBufferOrFake(ID), SourceMgr, LangOpts)); Lex->SetKeepWhitespaceMode(true); for (const std::string &ForEachMacro : Style.ForEachMacros) { auto Identifier = &IdentTable.get(ForEachMacro); Macros.insert({Identifier, TT_ForEachMacro}); } for (const std::string &IfMacro : Style.IfMacros) { auto Identifier = &IdentTable.get(IfMacro); Macros.insert({Identifier, TT_IfMacro}); } for (const std::string &AttributeMacro : Style.AttributeMacros) { auto Identifier = &IdentTable.get(AttributeMacro); Macros.insert({Identifier, TT_AttributeMacro}); } for (const std::string &StatementMacro : Style.StatementMacros) { auto Identifier = &IdentTable.get(StatementMacro); Macros.insert({Identifier, TT_StatementMacro}); } for (const std::string &TypenameMacro : Style.TypenameMacros) { auto Identifier = &IdentTable.get(TypenameMacro); Macros.insert({Identifier, TT_TypenameMacro}); } for (const std::string &NamespaceMacro : Style.NamespaceMacros) { auto Identifier = &IdentTable.get(NamespaceMacro); Macros.insert({Identifier, TT_NamespaceMacro}); } for (const std::string &WhitespaceSensitiveMacro : Style.WhitespaceSensitiveMacros) { auto Identifier = &IdentTable.get(WhitespaceSensitiveMacro); Macros.insert({Identifier, TT_UntouchableMacroFunc}); } for (const std::string &StatementAttributeLikeMacro : Style.StatementAttributeLikeMacros) { auto Identifier = &IdentTable.get(StatementAttributeLikeMacro); Macros.insert({Identifier, TT_StatementAttributeLikeMacro}); } for (const auto &TypeName : Style.TypeNames) TypeNames.insert(&IdentTable.get(TypeName)); } ArrayRef FormatTokenLexer::lex() { assert(Tokens.empty()); assert(FirstInLineIndex == 0); do { Tokens.push_back(getNextToken()); if (Style.isJavaScript()) { tryParseJSRegexLiteral(); handleTemplateStrings(); } if (Style.Language == FormatStyle::LK_TextProto) tryParsePythonComment(); tryMergePreviousTokens(); if (Style.isCSharp()) { // This needs to come after tokens have been merged so that C# // string literals are correctly identified. handleCSharpVerbatimAndInterpolatedStrings(); } if (Style.isTableGen()) { handleTableGenMultilineString(); handleTableGenNumericLikeIdentifier(); } if (Tokens.back()->NewlinesBefore > 0 || Tokens.back()->IsMultiline) FirstInLineIndex = Tokens.size() - 1; } while (Tokens.back()->isNot(tok::eof)); return Tokens; } void FormatTokenLexer::tryMergePreviousTokens() { if (tryMerge_TMacro()) return; if (tryMergeConflictMarkers()) return; if (tryMergeLessLess()) return; if (tryMergeGreaterGreater()) return; if (tryMergeForEach()) return; if (Style.isCpp() && tryTransformTryUsageForC()) return; if (Style.isJavaScript() || Style.isCSharp()) { static const tok::TokenKind NullishCoalescingOperator[] = {tok::question, tok::question}; static const tok::TokenKind NullPropagatingOperator[] = {tok::question, tok::period}; static const tok::TokenKind FatArrow[] = {tok::equal, tok::greater}; if (tryMergeTokens(FatArrow, TT_FatArrow)) return; if (tryMergeTokens(NullishCoalescingOperator, TT_NullCoalescingOperator)) { // Treat like the "||" operator (as opposed to the ternary ?). Tokens.back()->Tok.setKind(tok::pipepipe); return; } if (tryMergeTokens(NullPropagatingOperator, TT_NullPropagatingOperator)) { // Treat like a regular "." access. Tokens.back()->Tok.setKind(tok::period); return; } if (tryMergeNullishCoalescingEqual()) return; } if (Style.isCSharp()) { static const tok::TokenKind CSharpNullConditionalLSquare[] = { tok::question, tok::l_square}; if (tryMergeCSharpKeywordVariables()) return; if (tryMergeCSharpStringLiteral()) return; if (tryTransformCSharpForEach()) return; if (tryMergeTokens(CSharpNullConditionalLSquare, TT_CSharpNullConditionalLSquare)) { // Treat like a regular "[" operator. Tokens.back()->Tok.setKind(tok::l_square); return; } } if (tryMergeNSStringLiteral()) return; if (Style.isJavaScript()) { static const tok::TokenKind JSIdentity[] = {tok::equalequal, tok::equal}; static const tok::TokenKind JSNotIdentity[] = {tok::exclaimequal, tok::equal}; static const tok::TokenKind JSShiftEqual[] = {tok::greater, tok::greater, tok::greaterequal}; static const tok::TokenKind JSExponentiation[] = {tok::star, tok::star}; static const tok::TokenKind JSExponentiationEqual[] = {tok::star, tok::starequal}; static const tok::TokenKind JSPipePipeEqual[] = {tok::pipepipe, tok::equal}; static const tok::TokenKind JSAndAndEqual[] = {tok::ampamp, tok::equal}; // FIXME: Investigate what token type gives the correct operator priority. if (tryMergeTokens(JSIdentity, TT_BinaryOperator)) return; if (tryMergeTokens(JSNotIdentity, TT_BinaryOperator)) return; if (tryMergeTokens(JSShiftEqual, TT_BinaryOperator)) return; if (tryMergeTokens(JSExponentiation, TT_JsExponentiation)) return; if (tryMergeTokens(JSExponentiationEqual, TT_JsExponentiationEqual)) { Tokens.back()->Tok.setKind(tok::starequal); return; } if (tryMergeTokens(JSAndAndEqual, TT_JsAndAndEqual) || tryMergeTokens(JSPipePipeEqual, TT_JsPipePipeEqual)) { // Treat like the "=" assignment operator. Tokens.back()->Tok.setKind(tok::equal); return; } if (tryMergeJSPrivateIdentifier()) return; } if (Style.Language == FormatStyle::LK_Java) { static const tok::TokenKind JavaRightLogicalShiftAssign[] = { tok::greater, tok::greater, tok::greaterequal}; if (tryMergeTokens(JavaRightLogicalShiftAssign, TT_BinaryOperator)) return; } if (Style.isVerilog()) { // Merge the number following a base like `'h?a0`. if (Tokens.size() >= 3 && Tokens.end()[-3]->is(TT_VerilogNumberBase) && Tokens.end()[-2]->is(tok::numeric_constant) && Tokens.back()->isOneOf(tok::numeric_constant, tok::identifier, tok::question) && tryMergeTokens(2, TT_Unknown)) { return; } // Part select. if (tryMergeTokensAny({{tok::minus, tok::colon}, {tok::plus, tok::colon}}, TT_BitFieldColon)) { return; } // Xnor. The combined token is treated as a caret which can also be either a // unary or binary operator. The actual type is determined in // TokenAnnotator. We also check the token length so we know it is not // already a merged token. if (Tokens.back()->TokenText.size() == 1 && tryMergeTokensAny({{tok::caret, tok::tilde}, {tok::tilde, tok::caret}}, TT_BinaryOperator)) { Tokens.back()->Tok.setKind(tok::caret); return; } // Signed shift and distribution weight. if (tryMergeTokens({tok::less, tok::less}, TT_BinaryOperator)) { Tokens.back()->Tok.setKind(tok::lessless); return; } if (tryMergeTokens({tok::greater, tok::greater}, TT_BinaryOperator)) { Tokens.back()->Tok.setKind(tok::greatergreater); return; } if (tryMergeTokensAny({{tok::lessless, tok::equal}, {tok::lessless, tok::lessequal}, {tok::greatergreater, tok::equal}, {tok::greatergreater, tok::greaterequal}, {tok::colon, tok::equal}, {tok::colon, tok::slash}}, TT_BinaryOperator)) { Tokens.back()->ForcedPrecedence = prec::Assignment; return; } // Exponentiation, signed shift, case equality, and wildcard equality. if (tryMergeTokensAny({{tok::star, tok::star}, {tok::lessless, tok::less}, {tok::greatergreater, tok::greater}, {tok::exclaimequal, tok::equal}, {tok::exclaimequal, tok::question}, {tok::equalequal, tok::equal}, {tok::equalequal, tok::question}}, TT_BinaryOperator)) { return; } // Module paths in specify blocks and the implication and boolean equality // operators. if (tryMergeTokensAny({{tok::plusequal, tok::greater}, {tok::plus, tok::star, tok::greater}, {tok::minusequal, tok::greater}, {tok::minus, tok::star, tok::greater}, {tok::less, tok::arrow}, {tok::equal, tok::greater}, {tok::star, tok::greater}, {tok::pipeequal, tok::greater}, {tok::pipe, tok::arrow}, {tok::hash, tok::minus, tok::hash}, {tok::hash, tok::equal, tok::hash}}, TT_BinaryOperator) || Tokens.back()->is(tok::arrow)) { Tokens.back()->ForcedPrecedence = prec::Comma; return; } } // TableGen's Multi line string starts with [{ if (Style.isTableGen() && tryMergeTokens({tok::l_square, tok::l_brace}, TT_TableGenMultiLineString)) { // Set again with finalizing. This must never be annotated as other types. Tokens.back()->setFinalizedType(TT_TableGenMultiLineString); Tokens.back()->Tok.setKind(tok::string_literal); return; } } bool FormatTokenLexer::tryMergeNSStringLiteral() { if (Tokens.size() < 2) return false; auto &At = *(Tokens.end() - 2); auto &String = *(Tokens.end() - 1); if (At->isNot(tok::at) || String->isNot(tok::string_literal)) return false; At->Tok.setKind(tok::string_literal); At->TokenText = StringRef(At->TokenText.begin(), String->TokenText.end() - At->TokenText.begin()); At->ColumnWidth += String->ColumnWidth; At->setType(TT_ObjCStringLiteral); Tokens.erase(Tokens.end() - 1); return true; } bool FormatTokenLexer::tryMergeJSPrivateIdentifier() { // Merges #idenfier into a single identifier with the text #identifier // but the token tok::identifier. if (Tokens.size() < 2) return false; auto &Hash = *(Tokens.end() - 2); auto &Identifier = *(Tokens.end() - 1); if (Hash->isNot(tok::hash) || Identifier->isNot(tok::identifier)) return false; Hash->Tok.setKind(tok::identifier); Hash->TokenText = StringRef(Hash->TokenText.begin(), Identifier->TokenText.end() - Hash->TokenText.begin()); Hash->ColumnWidth += Identifier->ColumnWidth; Hash->setType(TT_JsPrivateIdentifier); Tokens.erase(Tokens.end() - 1); return true; } // Search for verbatim or interpolated string literals @"ABC" or // $"aaaaa{abc}aaaaa" i and mark the token as TT_CSharpStringLiteral, and to // prevent splitting of @, $ and ". // Merging of multiline verbatim strings with embedded '"' is handled in // handleCSharpVerbatimAndInterpolatedStrings with lower-level lexing. bool FormatTokenLexer::tryMergeCSharpStringLiteral() { if (Tokens.size() < 2) return false; // Look for @"aaaaaa" or $"aaaaaa". const auto String = *(Tokens.end() - 1); if (String->isNot(tok::string_literal)) return false; auto Prefix = *(Tokens.end() - 2); if (Prefix->isNot(tok::at) && Prefix->TokenText != "$") return false; if (Tokens.size() > 2) { const auto Tok = *(Tokens.end() - 3); if ((Tok->TokenText == "$" && Prefix->is(tok::at)) || (Tok->is(tok::at) && Prefix->TokenText == "$")) { // This looks like $@"aaa" or @$"aaa" so we need to combine all 3 tokens. Tok->ColumnWidth += Prefix->ColumnWidth; Tokens.erase(Tokens.end() - 2); Prefix = Tok; } } // Convert back into just a string_literal. Prefix->Tok.setKind(tok::string_literal); Prefix->TokenText = StringRef(Prefix->TokenText.begin(), String->TokenText.end() - Prefix->TokenText.begin()); Prefix->ColumnWidth += String->ColumnWidth; Prefix->setType(TT_CSharpStringLiteral); Tokens.erase(Tokens.end() - 1); return true; } // Valid C# attribute targets: // https://docs.microsoft.com/en-us/dotnet/csharp/programming-guide/concepts/attributes/#attribute-targets const llvm::StringSet<> FormatTokenLexer::CSharpAttributeTargets = { "assembly", "module", "field", "event", "method", "param", "property", "return", "type", }; bool FormatTokenLexer::tryMergeNullishCoalescingEqual() { if (Tokens.size() < 2) return false; auto &NullishCoalescing = *(Tokens.end() - 2); auto &Equal = *(Tokens.end() - 1); if (NullishCoalescing->getType() != TT_NullCoalescingOperator || Equal->isNot(tok::equal)) { return false; } NullishCoalescing->Tok.setKind(tok::equal); // no '??=' in clang tokens. NullishCoalescing->TokenText = StringRef(NullishCoalescing->TokenText.begin(), Equal->TokenText.end() - NullishCoalescing->TokenText.begin()); NullishCoalescing->ColumnWidth += Equal->ColumnWidth; NullishCoalescing->setType(TT_NullCoalescingEqual); Tokens.erase(Tokens.end() - 1); return true; } bool FormatTokenLexer::tryMergeCSharpKeywordVariables() { if (Tokens.size() < 2) return false; const auto At = *(Tokens.end() - 2); if (At->isNot(tok::at)) return false; const auto Keyword = *(Tokens.end() - 1); if (Keyword->TokenText == "$") return false; if (!Keywords.isCSharpKeyword(*Keyword)) return false; At->Tok.setKind(tok::identifier); At->TokenText = StringRef(At->TokenText.begin(), Keyword->TokenText.end() - At->TokenText.begin()); At->ColumnWidth += Keyword->ColumnWidth; At->setType(Keyword->getType()); Tokens.erase(Tokens.end() - 1); return true; } // In C# transform identifier foreach into kw_foreach bool FormatTokenLexer::tryTransformCSharpForEach() { if (Tokens.size() < 1) return false; auto &Identifier = *(Tokens.end() - 1); if (Identifier->isNot(tok::identifier)) return false; if (Identifier->TokenText != "foreach") return false; Identifier->setType(TT_ForEachMacro); Identifier->Tok.setKind(tok::kw_for); return true; } bool FormatTokenLexer::tryMergeForEach() { if (Tokens.size() < 2) return false; auto &For = *(Tokens.end() - 2); auto &Each = *(Tokens.end() - 1); if (For->isNot(tok::kw_for)) return false; if (Each->isNot(tok::identifier)) return false; if (Each->TokenText != "each") return false; For->setType(TT_ForEachMacro); For->Tok.setKind(tok::kw_for); For->TokenText = StringRef(For->TokenText.begin(), Each->TokenText.end() - For->TokenText.begin()); For->ColumnWidth += Each->ColumnWidth; Tokens.erase(Tokens.end() - 1); return true; } bool FormatTokenLexer::tryTransformTryUsageForC() { if (Tokens.size() < 2) return false; auto &Try = *(Tokens.end() - 2); if (Try->isNot(tok::kw_try)) return false; auto &Next = *(Tokens.end() - 1); if (Next->isOneOf(tok::l_brace, tok::colon, tok::hash, tok::comment)) return false; if (Tokens.size() > 2) { auto &At = *(Tokens.end() - 3); if (At->is(tok::at)) return false; } Try->Tok.setKind(tok::identifier); return true; } bool FormatTokenLexer::tryMergeLessLess() { // Merge X,less,less,Y into X,lessless,Y unless X or Y is less. if (Tokens.size() < 3) return false; auto First = Tokens.end() - 3; if (First[0]->isNot(tok::less) || First[1]->isNot(tok::less)) return false; // Only merge if there currently is no whitespace between the two "<". if (First[1]->hasWhitespaceBefore()) return false; auto X = Tokens.size() > 3 ? First[-1] : nullptr; if (X && X->is(tok::less)) return false; auto Y = First[2]; if ((!X || X->isNot(tok::kw_operator)) && Y->is(tok::less)) return false; First[0]->Tok.setKind(tok::lessless); First[0]->TokenText = "<<"; First[0]->ColumnWidth += 1; Tokens.erase(Tokens.end() - 2); return true; } bool FormatTokenLexer::tryMergeGreaterGreater() { // Merge kw_operator,greater,greater into kw_operator,greatergreater. if (Tokens.size() < 2) return false; auto First = Tokens.end() - 2; if (First[0]->isNot(tok::greater) || First[1]->isNot(tok::greater)) return false; // Only merge if there currently is no whitespace between the first two ">". if (First[1]->hasWhitespaceBefore()) return false; auto Tok = Tokens.size() > 2 ? First[-1] : nullptr; if (Tok && Tok->isNot(tok::kw_operator)) return false; First[0]->Tok.setKind(tok::greatergreater); First[0]->TokenText = ">>"; First[0]->ColumnWidth += 1; Tokens.erase(Tokens.end() - 1); return true; } bool FormatTokenLexer::tryMergeTokens(ArrayRef Kinds, TokenType NewType) { if (Tokens.size() < Kinds.size()) return false; SmallVectorImpl::const_iterator First = Tokens.end() - Kinds.size(); for (unsigned i = 0; i < Kinds.size(); ++i) if (First[i]->isNot(Kinds[i])) return false; return tryMergeTokens(Kinds.size(), NewType); } bool FormatTokenLexer::tryMergeTokens(size_t Count, TokenType NewType) { if (Tokens.size() < Count) return false; SmallVectorImpl::const_iterator First = Tokens.end() - Count; unsigned AddLength = 0; for (size_t i = 1; i < Count; ++i) { // If there is whitespace separating the token and the previous one, // they should not be merged. if (First[i]->hasWhitespaceBefore()) return false; AddLength += First[i]->TokenText.size(); } Tokens.resize(Tokens.size() - Count + 1); First[0]->TokenText = StringRef(First[0]->TokenText.data(), First[0]->TokenText.size() + AddLength); First[0]->ColumnWidth += AddLength; First[0]->setType(NewType); return true; } bool FormatTokenLexer::tryMergeTokensAny( ArrayRef> Kinds, TokenType NewType) { return llvm::any_of(Kinds, [this, NewType](ArrayRef Kinds) { return tryMergeTokens(Kinds, NewType); }); } // Returns \c true if \p Tok can only be followed by an operand in JavaScript. bool FormatTokenLexer::precedesOperand(FormatToken *Tok) { // NB: This is not entirely correct, as an r_paren can introduce an operand // location in e.g. `if (foo) /bar/.exec(...);`. That is a rare enough // corner case to not matter in practice, though. return Tok->isOneOf(tok::period, tok::l_paren, tok::comma, tok::l_brace, tok::r_brace, tok::l_square, tok::semi, tok::exclaim, tok::colon, tok::question, tok::tilde) || Tok->isOneOf(tok::kw_return, tok::kw_do, tok::kw_case, tok::kw_throw, tok::kw_else, tok::kw_new, tok::kw_delete, tok::kw_void, tok::kw_typeof, Keywords.kw_instanceof, Keywords.kw_in) || Tok->isBinaryOperator(); } bool FormatTokenLexer::canPrecedeRegexLiteral(FormatToken *Prev) { if (!Prev) return true; // Regex literals can only follow after prefix unary operators, not after // postfix unary operators. If the '++' is followed by a non-operand // introducing token, the slash here is the operand and not the start of a // regex. // `!` is an unary prefix operator, but also a post-fix operator that casts // away nullability, so the same check applies. if (Prev->isOneOf(tok::plusplus, tok::minusminus, tok::exclaim)) return Tokens.size() < 3 || precedesOperand(Tokens[Tokens.size() - 3]); // The previous token must introduce an operand location where regex // literals can occur. if (!precedesOperand(Prev)) return false; return true; } // Tries to parse a JavaScript Regex literal starting at the current token, // if that begins with a slash and is in a location where JavaScript allows // regex literals. Changes the current token to a regex literal and updates // its text if successful. void FormatTokenLexer::tryParseJSRegexLiteral() { FormatToken *RegexToken = Tokens.back(); if (!RegexToken->isOneOf(tok::slash, tok::slashequal)) return; FormatToken *Prev = nullptr; for (FormatToken *FT : llvm::drop_begin(llvm::reverse(Tokens))) { // NB: Because previous pointers are not initialized yet, this cannot use // Token.getPreviousNonComment. if (FT->isNot(tok::comment)) { Prev = FT; break; } } if (!canPrecedeRegexLiteral(Prev)) return; // 'Manually' lex ahead in the current file buffer. const char *Offset = Lex->getBufferLocation(); const char *RegexBegin = Offset - RegexToken->TokenText.size(); StringRef Buffer = Lex->getBuffer(); bool InCharacterClass = false; bool HaveClosingSlash = false; for (; !HaveClosingSlash && Offset != Buffer.end(); ++Offset) { // Regular expressions are terminated with a '/', which can only be // escaped using '\' or a character class between '[' and ']'. // See http://www.ecma-international.org/ecma-262/5.1/#sec-7.8.5. switch (*Offset) { case '\\': // Skip the escaped character. ++Offset; break; case '[': InCharacterClass = true; break; case ']': InCharacterClass = false; break; case '/': if (!InCharacterClass) HaveClosingSlash = true; break; } } RegexToken->setType(TT_RegexLiteral); // Treat regex literals like other string_literals. RegexToken->Tok.setKind(tok::string_literal); RegexToken->TokenText = StringRef(RegexBegin, Offset - RegexBegin); RegexToken->ColumnWidth = RegexToken->TokenText.size(); resetLexer(SourceMgr.getFileOffset(Lex->getSourceLocation(Offset))); } static auto lexCSharpString(const char *Begin, const char *End, bool Verbatim, bool Interpolated) { auto Repeated = [&Begin, End]() { return Begin + 1 < End && Begin[1] == Begin[0]; }; // Look for a terminating '"' in the current file buffer. // Make no effort to format code within an interpolated or verbatim string. // // Interpolated strings could contain { } with " characters inside. // $"{x ?? "null"}" // should not be split into $"{x ?? ", null, "}" but should be treated as a // single string-literal. // // We opt not to try and format expressions inside {} within a C# // interpolated string. Formatting expressions within an interpolated string // would require similar work as that done for JavaScript template strings // in `handleTemplateStrings()`. for (int UnmatchedOpeningBraceCount = 0; Begin < End; ++Begin) { switch (*Begin) { case '\\': if (!Verbatim) ++Begin; break; case '{': if (Interpolated) { // {{ inside an interpolated string is escaped, so skip it. if (Repeated()) ++Begin; else ++UnmatchedOpeningBraceCount; } break; case '}': if (Interpolated) { // }} inside an interpolated string is escaped, so skip it. if (Repeated()) ++Begin; else if (UnmatchedOpeningBraceCount > 0) --UnmatchedOpeningBraceCount; else return End; } break; case '"': if (UnmatchedOpeningBraceCount > 0) break; // "" within a verbatim string is an escaped double quote: skip it. if (Verbatim && Repeated()) { ++Begin; break; } return Begin; } } return End; } void FormatTokenLexer::handleCSharpVerbatimAndInterpolatedStrings() { FormatToken *CSharpStringLiteral = Tokens.back(); if (CSharpStringLiteral->isNot(TT_CSharpStringLiteral)) return; auto &TokenText = CSharpStringLiteral->TokenText; bool Verbatim = false; bool Interpolated = false; if (TokenText.starts_with(R"($@")") || TokenText.starts_with(R"(@$")")) { Verbatim = true; Interpolated = true; } else if (TokenText.starts_with(R"(@")")) { Verbatim = true; } else if (TokenText.starts_with(R"($")")) { Interpolated = true; } // Deal with multiline strings. if (!Verbatim && !Interpolated) return; const char *StrBegin = Lex->getBufferLocation() - TokenText.size(); const char *Offset = StrBegin; if (Verbatim && Interpolated) Offset += 3; else Offset += 2; const auto End = Lex->getBuffer().end(); Offset = lexCSharpString(Offset, End, Verbatim, Interpolated); // Make no attempt to format code properly if a verbatim string is // unterminated. if (Offset >= End) return; StringRef LiteralText(StrBegin, Offset - StrBegin + 1); TokenText = LiteralText; // Adjust width for potentially multiline string literals. size_t FirstBreak = LiteralText.find('\n'); StringRef FirstLineText = FirstBreak == StringRef::npos ? LiteralText : LiteralText.substr(0, FirstBreak); CSharpStringLiteral->ColumnWidth = encoding::columnWidthWithTabs( FirstLineText, CSharpStringLiteral->OriginalColumn, Style.TabWidth, Encoding); size_t LastBreak = LiteralText.rfind('\n'); if (LastBreak != StringRef::npos) { CSharpStringLiteral->IsMultiline = true; unsigned StartColumn = 0; CSharpStringLiteral->LastLineColumnWidth = encoding::columnWidthWithTabs(LiteralText.substr(LastBreak + 1), StartColumn, Style.TabWidth, Encoding); } assert(Offset < End); resetLexer(SourceMgr.getFileOffset(Lex->getSourceLocation(Offset + 1))); } void FormatTokenLexer::handleTableGenMultilineString() { FormatToken *MultiLineString = Tokens.back(); if (MultiLineString->isNot(TT_TableGenMultiLineString)) return; auto OpenOffset = Lex->getCurrentBufferOffset() - 2 /* "[{" */; // "}]" is the end of multi line string. auto CloseOffset = Lex->getBuffer().find("}]", OpenOffset); if (CloseOffset == StringRef::npos) return; auto Text = Lex->getBuffer().substr(OpenOffset, CloseOffset + 2); MultiLineString->TokenText = Text; resetLexer(SourceMgr.getFileOffset( Lex->getSourceLocation(Lex->getBufferLocation() - 2 + Text.size()))); auto FirstLineText = Text; auto FirstBreak = Text.find('\n'); // Set ColumnWidth and LastLineColumnWidth when it has multiple lines. if (FirstBreak != StringRef::npos) { MultiLineString->IsMultiline = true; FirstLineText = Text.substr(0, FirstBreak + 1); // LastLineColumnWidth holds the width of the last line. auto LastBreak = Text.rfind('\n'); MultiLineString->LastLineColumnWidth = encoding::columnWidthWithTabs( Text.substr(LastBreak + 1), MultiLineString->OriginalColumn, Style.TabWidth, Encoding); } // ColumnWidth holds only the width of the first line. MultiLineString->ColumnWidth = encoding::columnWidthWithTabs( FirstLineText, MultiLineString->OriginalColumn, Style.TabWidth, Encoding); } void FormatTokenLexer::handleTableGenNumericLikeIdentifier() { FormatToken *Tok = Tokens.back(); // TableGen identifiers can begin with digits. Such tokens are lexed as // numeric_constant now. if (Tok->isNot(tok::numeric_constant)) return; StringRef Text = Tok->TokenText; // The following check is based on llvm::TGLexer::LexToken. // That lexes the token as a number if any of the following holds: // 1. It starts with '+', '-'. // 2. All the characters are digits. // 3. The first non-digit character is 'b', and the next is '0' or '1'. // 4. The first non-digit character is 'x', and the next is a hex digit. // Note that in the case 3 and 4, if the next character does not exists in // this token, the token is an identifier. if (Text.size() < 1 || Text[0] == '+' || Text[0] == '-') return; const auto NonDigitPos = Text.find_if([](char C) { return !isdigit(C); }); // All the characters are digits if (NonDigitPos == StringRef::npos) return; char FirstNonDigit = Text[NonDigitPos]; if (NonDigitPos < Text.size() - 1) { char TheNext = Text[NonDigitPos + 1]; // Regarded as a binary number. if (FirstNonDigit == 'b' && (TheNext == '0' || TheNext == '1')) return; // Regarded as hex number. if (FirstNonDigit == 'x' && isxdigit(TheNext)) return; } if (isalpha(FirstNonDigit) || FirstNonDigit == '_') { // This is actually an identifier in TableGen. Tok->Tok.setKind(tok::identifier); Tok->Tok.setIdentifierInfo(nullptr); } } void FormatTokenLexer::handleTemplateStrings() { FormatToken *BacktickToken = Tokens.back(); if (BacktickToken->is(tok::l_brace)) { StateStack.push(LexerState::NORMAL); return; } if (BacktickToken->is(tok::r_brace)) { if (StateStack.size() == 1) return; StateStack.pop(); if (StateStack.top() != LexerState::TEMPLATE_STRING) return; // If back in TEMPLATE_STRING, fallthrough and continue parsing the } else if (BacktickToken->is(tok::unknown) && BacktickToken->TokenText == "`") { StateStack.push(LexerState::TEMPLATE_STRING); } else { return; // Not actually a template } // 'Manually' lex ahead in the current file buffer. const char *Offset = Lex->getBufferLocation(); const char *TmplBegin = Offset - BacktickToken->TokenText.size(); // at "`" for (; Offset != Lex->getBuffer().end(); ++Offset) { if (Offset[0] == '`') { StateStack.pop(); ++Offset; break; } if (Offset[0] == '\\') { ++Offset; // Skip the escaped character. } else if (Offset + 1 < Lex->getBuffer().end() && Offset[0] == '$' && Offset[1] == '{') { // '${' introduces an expression interpolation in the template string. StateStack.push(LexerState::NORMAL); Offset += 2; break; } } StringRef LiteralText(TmplBegin, Offset - TmplBegin); BacktickToken->setType(TT_TemplateString); BacktickToken->Tok.setKind(tok::string_literal); BacktickToken->TokenText = LiteralText; // Adjust width for potentially multiline string literals. size_t FirstBreak = LiteralText.find('\n'); StringRef FirstLineText = FirstBreak == StringRef::npos ? LiteralText : LiteralText.substr(0, FirstBreak); BacktickToken->ColumnWidth = encoding::columnWidthWithTabs( FirstLineText, BacktickToken->OriginalColumn, Style.TabWidth, Encoding); size_t LastBreak = LiteralText.rfind('\n'); if (LastBreak != StringRef::npos) { BacktickToken->IsMultiline = true; unsigned StartColumn = 0; // The template tail spans the entire line. BacktickToken->LastLineColumnWidth = encoding::columnWidthWithTabs(LiteralText.substr(LastBreak + 1), StartColumn, Style.TabWidth, Encoding); } SourceLocation loc = Lex->getSourceLocation(Offset); resetLexer(SourceMgr.getFileOffset(loc)); } void FormatTokenLexer::tryParsePythonComment() { FormatToken *HashToken = Tokens.back(); if (!HashToken->isOneOf(tok::hash, tok::hashhash)) return; // Turn the remainder of this line into a comment. const char *CommentBegin = Lex->getBufferLocation() - HashToken->TokenText.size(); // at "#" size_t From = CommentBegin - Lex->getBuffer().begin(); size_t To = Lex->getBuffer().find_first_of('\n', From); if (To == StringRef::npos) To = Lex->getBuffer().size(); size_t Len = To - From; HashToken->setType(TT_LineComment); HashToken->Tok.setKind(tok::comment); HashToken->TokenText = Lex->getBuffer().substr(From, Len); SourceLocation Loc = To < Lex->getBuffer().size() ? Lex->getSourceLocation(CommentBegin + Len) : SourceMgr.getLocForEndOfFile(ID); resetLexer(SourceMgr.getFileOffset(Loc)); } bool FormatTokenLexer::tryMerge_TMacro() { if (Tokens.size() < 4) return false; FormatToken *Last = Tokens.back(); if (Last->isNot(tok::r_paren)) return false; FormatToken *String = Tokens[Tokens.size() - 2]; if (String->isNot(tok::string_literal) || String->IsMultiline) return false; if (Tokens[Tokens.size() - 3]->isNot(tok::l_paren)) return false; FormatToken *Macro = Tokens[Tokens.size() - 4]; if (Macro->TokenText != "_T") return false; const char *Start = Macro->TokenText.data(); const char *End = Last->TokenText.data() + Last->TokenText.size(); String->TokenText = StringRef(Start, End - Start); String->IsFirst = Macro->IsFirst; String->LastNewlineOffset = Macro->LastNewlineOffset; String->WhitespaceRange = Macro->WhitespaceRange; String->OriginalColumn = Macro->OriginalColumn; String->ColumnWidth = encoding::columnWidthWithTabs( String->TokenText, String->OriginalColumn, Style.TabWidth, Encoding); String->NewlinesBefore = Macro->NewlinesBefore; String->HasUnescapedNewline = Macro->HasUnescapedNewline; Tokens.pop_back(); Tokens.pop_back(); Tokens.pop_back(); Tokens.back() = String; if (FirstInLineIndex >= Tokens.size()) FirstInLineIndex = Tokens.size() - 1; return true; } bool FormatTokenLexer::tryMergeConflictMarkers() { if (Tokens.back()->NewlinesBefore == 0 && Tokens.back()->isNot(tok::eof)) return false; // Conflict lines look like: // // For example: // >>>>>>> /file/in/file/system at revision 1234 // // We merge all tokens in a line that starts with a conflict marker // into a single token with a special token type that the unwrapped line // parser will use to correctly rebuild the underlying code. FileID ID; // Get the position of the first token in the line. unsigned FirstInLineOffset; std::tie(ID, FirstInLineOffset) = SourceMgr.getDecomposedLoc( Tokens[FirstInLineIndex]->getStartOfNonWhitespace()); StringRef Buffer = SourceMgr.getBufferOrFake(ID).getBuffer(); // Calculate the offset of the start of the current line. auto LineOffset = Buffer.rfind('\n', FirstInLineOffset); if (LineOffset == StringRef::npos) LineOffset = 0; else ++LineOffset; auto FirstSpace = Buffer.find_first_of(" \n", LineOffset); StringRef LineStart; if (FirstSpace == StringRef::npos) LineStart = Buffer.substr(LineOffset); else LineStart = Buffer.substr(LineOffset, FirstSpace - LineOffset); TokenType Type = TT_Unknown; if (LineStart == "<<<<<<<" || LineStart == ">>>>") { Type = TT_ConflictStart; } else if (LineStart == "|||||||" || LineStart == "=======" || LineStart == "====") { Type = TT_ConflictAlternative; } else if (LineStart == ">>>>>>>" || LineStart == "<<<<") { Type = TT_ConflictEnd; } if (Type != TT_Unknown) { FormatToken *Next = Tokens.back(); Tokens.resize(FirstInLineIndex + 1); // We do not need to build a complete token here, as we will skip it // during parsing anyway (as we must not touch whitespace around conflict // markers). Tokens.back()->setType(Type); Tokens.back()->Tok.setKind(tok::kw___unknown_anytype); Tokens.push_back(Next); return true; } return false; } FormatToken *FormatTokenLexer::getStashedToken() { // Create a synthesized second '>' or '<' token. Token Tok = FormatTok->Tok; StringRef TokenText = FormatTok->TokenText; unsigned OriginalColumn = FormatTok->OriginalColumn; FormatTok = new (Allocator.Allocate()) FormatToken; FormatTok->Tok = Tok; SourceLocation TokLocation = FormatTok->Tok.getLocation().getLocWithOffset(Tok.getLength() - 1); FormatTok->Tok.setLocation(TokLocation); FormatTok->WhitespaceRange = SourceRange(TokLocation, TokLocation); FormatTok->TokenText = TokenText; FormatTok->ColumnWidth = 1; FormatTok->OriginalColumn = OriginalColumn + 1; return FormatTok; } /// Truncate the current token to the new length and make the lexer continue /// from the end of the truncated token. Used for other languages that have /// different token boundaries, like JavaScript in which a comment ends at a /// line break regardless of whether the line break follows a backslash. Also /// used to set the lexer to the end of whitespace if the lexer regards /// whitespace and an unrecognized symbol as one token. void FormatTokenLexer::truncateToken(size_t NewLen) { assert(NewLen <= FormatTok->TokenText.size()); resetLexer(SourceMgr.getFileOffset(Lex->getSourceLocation( Lex->getBufferLocation() - FormatTok->TokenText.size() + NewLen))); FormatTok->TokenText = FormatTok->TokenText.substr(0, NewLen); FormatTok->ColumnWidth = encoding::columnWidthWithTabs( FormatTok->TokenText, FormatTok->OriginalColumn, Style.TabWidth, Encoding); FormatTok->Tok.setLength(NewLen); } /// Count the length of leading whitespace in a token. static size_t countLeadingWhitespace(StringRef Text) { // Basically counting the length matched by this regex. // "^([\n\r\f\v \t]|(\\\\|\\?\\?/)[\n\r])+" // Directly using the regex turned out to be slow. With the regex // version formatting all files in this directory took about 1.25 // seconds. This version took about 0.5 seconds. const unsigned char *const Begin = Text.bytes_begin(); const unsigned char *const End = Text.bytes_end(); const unsigned char *Cur = Begin; while (Cur < End) { if (isspace(Cur[0])) { ++Cur; } else if (Cur[0] == '\\' && (Cur[1] == '\n' || Cur[1] == '\r')) { // A '\' followed by a newline always escapes the newline, regardless // of whether there is another '\' before it. // The source has a null byte at the end. So the end of the entire input // isn't reached yet. Also the lexer doesn't break apart an escaped // newline. assert(End - Cur >= 2); Cur += 2; } else if (Cur[0] == '?' && Cur[1] == '?' && Cur[2] == '/' && (Cur[3] == '\n' || Cur[3] == '\r')) { // Newlines can also be escaped by a '?' '?' '/' trigraph. By the way, the // characters are quoted individually in this comment because if we write // them together some compilers warn that we have a trigraph in the code. assert(End - Cur >= 4); Cur += 4; } else { break; } } return Cur - Begin; } FormatToken *FormatTokenLexer::getNextToken() { if (StateStack.top() == LexerState::TOKEN_STASHED) { StateStack.pop(); return getStashedToken(); } FormatTok = new (Allocator.Allocate()) FormatToken; readRawToken(*FormatTok); SourceLocation WhitespaceStart = FormatTok->Tok.getLocation().getLocWithOffset(-TrailingWhitespace); FormatTok->IsFirst = IsFirstToken; IsFirstToken = false; // Consume and record whitespace until we find a significant token. // Some tok::unknown tokens are not just whitespace, e.g. whitespace // followed by a symbol such as backtick. Those symbols may be // significant in other languages. unsigned WhitespaceLength = TrailingWhitespace; while (FormatTok->isNot(tok::eof)) { auto LeadingWhitespace = countLeadingWhitespace(FormatTok->TokenText); if (LeadingWhitespace == 0) break; if (LeadingWhitespace < FormatTok->TokenText.size()) truncateToken(LeadingWhitespace); StringRef Text = FormatTok->TokenText; bool InEscape = false; for (int i = 0, e = Text.size(); i != e; ++i) { switch (Text[i]) { case '\r': // If this is a CRLF sequence, break here and the LF will be handled on // the next loop iteration. Otherwise, this is a single Mac CR, treat it // the same as a single LF. if (i + 1 < e && Text[i + 1] == '\n') break; [[fallthrough]]; case '\n': ++FormatTok->NewlinesBefore; if (!InEscape) FormatTok->HasUnescapedNewline = true; else InEscape = false; FormatTok->LastNewlineOffset = WhitespaceLength + i + 1; Column = 0; break; case '\f': case '\v': Column = 0; break; case ' ': ++Column; break; case '\t': Column += Style.TabWidth - (Style.TabWidth ? Column % Style.TabWidth : 0); break; case '\\': case '?': case '/': // The text was entirely whitespace when this loop was entered. Thus // this has to be an escape sequence. assert(Text.substr(i, 2) == "\\\r" || Text.substr(i, 2) == "\\\n" || Text.substr(i, 4) == "\?\?/\r" || Text.substr(i, 4) == "\?\?/\n" || (i >= 1 && (Text.substr(i - 1, 4) == "\?\?/\r" || Text.substr(i - 1, 4) == "\?\?/\n")) || (i >= 2 && (Text.substr(i - 2, 4) == "\?\?/\r" || Text.substr(i - 2, 4) == "\?\?/\n"))); InEscape = true; break; default: // This shouldn't happen. assert(false); break; } } WhitespaceLength += Text.size(); readRawToken(*FormatTok); } if (FormatTok->is(tok::unknown)) FormatTok->setType(TT_ImplicitStringLiteral); // JavaScript and Java do not allow to escape the end of the line with a // backslash. Backslashes are syntax errors in plain source, but can occur in // comments. When a single line comment ends with a \, it'll cause the next // line of code to be lexed as a comment, breaking formatting. The code below // finds comments that contain a backslash followed by a line break, truncates // the comment token at the backslash, and resets the lexer to restart behind // the backslash. if ((Style.isJavaScript() || Style.Language == FormatStyle::LK_Java) && FormatTok->is(tok::comment) && FormatTok->TokenText.starts_with("//")) { size_t BackslashPos = FormatTok->TokenText.find('\\'); while (BackslashPos != StringRef::npos) { if (BackslashPos + 1 < FormatTok->TokenText.size() && FormatTok->TokenText[BackslashPos + 1] == '\n') { truncateToken(BackslashPos + 1); break; } BackslashPos = FormatTok->TokenText.find('\\', BackslashPos + 1); } } if (Style.isVerilog()) { static const llvm::Regex NumberBase("^s?[bdho]", llvm::Regex::IgnoreCase); SmallVector Matches; // Verilog uses the backtick instead of the hash for preprocessor stuff. // And it uses the hash for delays and parameter lists. In order to continue // using `tok::hash` in other places, the backtick gets marked as the hash // here. And in order to tell the backtick and hash apart for // Verilog-specific stuff, the hash becomes an identifier. if (FormatTok->is(tok::numeric_constant)) { // In Verilog the quote is not part of a number. auto Quote = FormatTok->TokenText.find('\''); if (Quote != StringRef::npos) truncateToken(Quote); } else if (FormatTok->isOneOf(tok::hash, tok::hashhash)) { FormatTok->Tok.setKind(tok::raw_identifier); } else if (FormatTok->is(tok::raw_identifier)) { if (FormatTok->TokenText == "`") { FormatTok->Tok.setIdentifierInfo(nullptr); FormatTok->Tok.setKind(tok::hash); } else if (FormatTok->TokenText == "``") { FormatTok->Tok.setIdentifierInfo(nullptr); FormatTok->Tok.setKind(tok::hashhash); } else if (Tokens.size() > 0 && Tokens.back()->is(Keywords.kw_apostrophe) && NumberBase.match(FormatTok->TokenText, &Matches)) { // In Verilog in a based number literal like `'b10`, there may be // whitespace between `'b` and `10`. Therefore we handle the base and // the rest of the number literal as two tokens. But if there is no // space in the input code, we need to manually separate the two parts. truncateToken(Matches[0].size()); FormatTok->setFinalizedType(TT_VerilogNumberBase); } } } FormatTok->WhitespaceRange = SourceRange( WhitespaceStart, WhitespaceStart.getLocWithOffset(WhitespaceLength)); FormatTok->OriginalColumn = Column; TrailingWhitespace = 0; if (FormatTok->is(tok::comment)) { // FIXME: Add the trimmed whitespace to Column. StringRef UntrimmedText = FormatTok->TokenText; FormatTok->TokenText = FormatTok->TokenText.rtrim(" \t\v\f"); TrailingWhitespace = UntrimmedText.size() - FormatTok->TokenText.size(); } else if (FormatTok->is(tok::raw_identifier)) { IdentifierInfo &Info = IdentTable.get(FormatTok->TokenText); FormatTok->Tok.setIdentifierInfo(&Info); FormatTok->Tok.setKind(Info.getTokenID()); if (Style.Language == FormatStyle::LK_Java && FormatTok->isOneOf(tok::kw_struct, tok::kw_union, tok::kw_delete, tok::kw_operator)) { FormatTok->Tok.setKind(tok::identifier); FormatTok->Tok.setIdentifierInfo(nullptr); } else if (Style.isJavaScript() && FormatTok->isOneOf(tok::kw_struct, tok::kw_union, tok::kw_operator)) { FormatTok->Tok.setKind(tok::identifier); FormatTok->Tok.setIdentifierInfo(nullptr); } else if (Style.isTableGen() && !Keywords.isTableGenKeyword(*FormatTok)) { FormatTok->Tok.setKind(tok::identifier); FormatTok->Tok.setIdentifierInfo(nullptr); } } else if (FormatTok->is(tok::greatergreater)) { FormatTok->Tok.setKind(tok::greater); FormatTok->TokenText = FormatTok->TokenText.substr(0, 1); ++Column; StateStack.push(LexerState::TOKEN_STASHED); } else if (FormatTok->is(tok::lessless)) { FormatTok->Tok.setKind(tok::less); FormatTok->TokenText = FormatTok->TokenText.substr(0, 1); ++Column; StateStack.push(LexerState::TOKEN_STASHED); } if (Style.isVerilog() && Tokens.size() > 0 && Tokens.back()->is(TT_VerilogNumberBase) && FormatTok->Tok.isOneOf(tok::identifier, tok::question)) { // Mark the number following a base like `'h?a0` as a number. FormatTok->Tok.setKind(tok::numeric_constant); } // Now FormatTok is the next non-whitespace token. StringRef Text = FormatTok->TokenText; size_t FirstNewlinePos = Text.find('\n'); if (FirstNewlinePos == StringRef::npos) { // FIXME: ColumnWidth actually depends on the start column, we need to // take this into account when the token is moved. FormatTok->ColumnWidth = encoding::columnWidthWithTabs(Text, Column, Style.TabWidth, Encoding); Column += FormatTok->ColumnWidth; } else { FormatTok->IsMultiline = true; // FIXME: ColumnWidth actually depends on the start column, we need to // take this into account when the token is moved. FormatTok->ColumnWidth = encoding::columnWidthWithTabs( Text.substr(0, FirstNewlinePos), Column, Style.TabWidth, Encoding); // The last line of the token always starts in column 0. // Thus, the length can be precomputed even in the presence of tabs. FormatTok->LastLineColumnWidth = encoding::columnWidthWithTabs( Text.substr(Text.find_last_of('\n') + 1), 0, Style.TabWidth, Encoding); Column = FormatTok->LastLineColumnWidth; } if (Style.isCpp()) { auto *Identifier = FormatTok->Tok.getIdentifierInfo(); auto it = Macros.find(Identifier); if (!(Tokens.size() > 0 && Tokens.back()->Tok.getIdentifierInfo() && Tokens.back()->Tok.getIdentifierInfo()->getPPKeywordID() == tok::pp_define) && it != Macros.end()) { FormatTok->setType(it->second); if (it->second == TT_IfMacro) { // The lexer token currently has type tok::kw_unknown. However, for this // substitution to be treated correctly in the TokenAnnotator, faking // the tok value seems to be needed. Not sure if there's a more elegant // way. FormatTok->Tok.setKind(tok::kw_if); } } else if (FormatTok->is(tok::identifier)) { if (MacroBlockBeginRegex.match(Text)) FormatTok->setType(TT_MacroBlockBegin); else if (MacroBlockEndRegex.match(Text)) FormatTok->setType(TT_MacroBlockEnd); else if (TypeNames.contains(Identifier)) FormatTok->setFinalizedType(TT_TypeName); } } return FormatTok; } bool FormatTokenLexer::readRawTokenVerilogSpecific(Token &Tok) { // In Verilog the quote is not a character literal. // // Make the backtick and double backtick identifiers to match against them // more easily. // // In Verilog an escaped identifier starts with backslash and ends with // whitespace. Unless that whitespace is an escaped newline. A backslash can // also begin an escaped newline outside of an escaped identifier. We check // for that outside of the Regex since we can't use negative lookhead // assertions. Simply changing the '*' to '+' breaks stuff as the escaped // identifier may have a length of 0 according to Section A.9.3. // FIXME: If there is an escaped newline in the middle of an escaped // identifier, allow for pasting the two lines together, But escaped // identifiers usually occur only in generated code anyway. static const llvm::Regex VerilogToken(R"re(^('|``?|\\(\\)re" "(\r?\n|\r)|[^[:space:]])*)"); SmallVector Matches; const char *Start = Lex->getBufferLocation(); if (!VerilogToken.match(StringRef(Start, Lex->getBuffer().end() - Start), &Matches)) { return false; } // There is a null byte at the end of the buffer, so we don't have to check // Start[1] is within the buffer. if (Start[0] == '\\' && (Start[1] == '\r' || Start[1] == '\n')) return false; size_t Len = Matches[0].size(); // The kind has to be an identifier so we can match it against those defined // in Keywords. The kind has to be set before the length because the setLength // function checks that the kind is not an annotation. Tok.setKind(tok::raw_identifier); Tok.setLength(Len); Tok.setLocation(Lex->getSourceLocation(Start, Len)); Tok.setRawIdentifierData(Start); Lex->seek(Lex->getCurrentBufferOffset() + Len, /*IsAtStartofline=*/false); return true; } void FormatTokenLexer::readRawToken(FormatToken &Tok) { // For Verilog, first see if there is a special token, and fall back to the // normal lexer if there isn't one. if (!Style.isVerilog() || !readRawTokenVerilogSpecific(Tok.Tok)) Lex->LexFromRawLexer(Tok.Tok); Tok.TokenText = StringRef(SourceMgr.getCharacterData(Tok.Tok.getLocation()), Tok.Tok.getLength()); // For formatting, treat unterminated string literals like normal string // literals. if (Tok.is(tok::unknown)) { if (!Tok.TokenText.empty() && Tok.TokenText[0] == '"') { Tok.Tok.setKind(tok::string_literal); Tok.IsUnterminatedLiteral = true; } else if (Style.isJavaScript() && Tok.TokenText == "''") { Tok.Tok.setKind(tok::string_literal); } } if ((Style.isJavaScript() || Style.isProto()) && Tok.is(tok::char_constant)) Tok.Tok.setKind(tok::string_literal); if (Tok.is(tok::comment) && isClangFormatOn(Tok.TokenText)) FormattingDisabled = false; Tok.Finalized = FormattingDisabled; if (Tok.is(tok::comment) && isClangFormatOff(Tok.TokenText)) FormattingDisabled = true; } void FormatTokenLexer::resetLexer(unsigned Offset) { StringRef Buffer = SourceMgr.getBufferData(ID); LangOpts = getFormattingLangOpts(Style); Lex.reset(new Lexer(SourceMgr.getLocForStartOfFile(ID), LangOpts, Buffer.begin(), Buffer.begin() + Offset, Buffer.end())); Lex->SetKeepWhitespaceMode(true); TrailingWhitespace = 0; } } // namespace format } // namespace clang