//===--- Format.cpp - Format C++ code -------------------------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// /// /// \file /// \brief This file implements functions declared in Format.h. This will be /// split into separate files as we go. /// //===----------------------------------------------------------------------===// #include "ContinuationIndenter.h" #include "TokenAnnotator.h" #include "UnwrappedLineParser.h" #include "WhitespaceManager.h" #include "clang/Basic/Diagnostic.h" #include "clang/Basic/DiagnosticOptions.h" #include "clang/Basic/SourceManager.h" #include "clang/Format/Format.h" #include "clang/Lex/Lexer.h" #include "llvm/ADT/STLExtras.h" #include "llvm/Support/Allocator.h" #include "llvm/Support/Debug.h" #include "llvm/Support/Path.h" #include "llvm/Support/YAMLTraits.h" #include #include #define DEBUG_TYPE "format-formatter" using clang::format::FormatStyle; LLVM_YAML_IS_FLOW_SEQUENCE_VECTOR(std::string) namespace llvm { namespace yaml { template <> struct ScalarEnumerationTraits { static void enumeration(IO &IO, FormatStyle::LanguageKind &Value) { IO.enumCase(Value, "Cpp", FormatStyle::LK_Cpp); IO.enumCase(Value, "JavaScript", FormatStyle::LK_JavaScript); IO.enumCase(Value, "Proto", FormatStyle::LK_Proto); } }; template <> struct ScalarEnumerationTraits { static void enumeration(IO &IO, FormatStyle::LanguageStandard &Value) { IO.enumCase(Value, "Cpp03", FormatStyle::LS_Cpp03); IO.enumCase(Value, "C++03", FormatStyle::LS_Cpp03); IO.enumCase(Value, "Cpp11", FormatStyle::LS_Cpp11); IO.enumCase(Value, "C++11", FormatStyle::LS_Cpp11); IO.enumCase(Value, "Auto", FormatStyle::LS_Auto); } }; template <> struct ScalarEnumerationTraits { static void enumeration(IO &IO, FormatStyle::UseTabStyle &Value) { IO.enumCase(Value, "Never", FormatStyle::UT_Never); IO.enumCase(Value, "false", FormatStyle::UT_Never); IO.enumCase(Value, "Always", FormatStyle::UT_Always); IO.enumCase(Value, "true", FormatStyle::UT_Always); IO.enumCase(Value, "ForIndentation", FormatStyle::UT_ForIndentation); } }; template <> struct ScalarEnumerationTraits { static void enumeration(IO &IO, FormatStyle::ShortFunctionStyle &Value) { IO.enumCase(Value, "None", FormatStyle::SFS_None); IO.enumCase(Value, "false", FormatStyle::SFS_None); IO.enumCase(Value, "All", FormatStyle::SFS_All); IO.enumCase(Value, "true", FormatStyle::SFS_All); IO.enumCase(Value, "Inline", FormatStyle::SFS_Inline); } }; template <> struct ScalarEnumerationTraits { static void enumeration(IO &IO, FormatStyle::BraceBreakingStyle &Value) { IO.enumCase(Value, "Attach", FormatStyle::BS_Attach); IO.enumCase(Value, "Linux", FormatStyle::BS_Linux); IO.enumCase(Value, "Stroustrup", FormatStyle::BS_Stroustrup); IO.enumCase(Value, "Allman", FormatStyle::BS_Allman); IO.enumCase(Value, "GNU", FormatStyle::BS_GNU); } }; template <> struct ScalarEnumerationTraits { static void enumeration(IO &IO, FormatStyle::NamespaceIndentationKind &Value) { IO.enumCase(Value, "None", FormatStyle::NI_None); IO.enumCase(Value, "Inner", FormatStyle::NI_Inner); IO.enumCase(Value, "All", FormatStyle::NI_All); } }; template <> struct ScalarEnumerationTraits { static void enumeration(IO &IO, FormatStyle::PointerAlignmentStyle &Value) { IO.enumCase(Value, "Middle", FormatStyle::PAS_Middle); IO.enumCase(Value, "Left", FormatStyle::PAS_Left); IO.enumCase(Value, "Right", FormatStyle::PAS_Right); // For backward compability. IO.enumCase(Value, "true", FormatStyle::PAS_Left); IO.enumCase(Value, "false", FormatStyle::PAS_Right); } }; template <> struct ScalarEnumerationTraits { static void enumeration(IO &IO, FormatStyle::SpaceBeforeParensOptions &Value) { IO.enumCase(Value, "Never", FormatStyle::SBPO_Never); IO.enumCase(Value, "ControlStatements", FormatStyle::SBPO_ControlStatements); IO.enumCase(Value, "Always", FormatStyle::SBPO_Always); // For backward compatibility. IO.enumCase(Value, "false", FormatStyle::SBPO_Never); IO.enumCase(Value, "true", FormatStyle::SBPO_ControlStatements); } }; template <> struct MappingTraits { static void mapping(IO &IO, FormatStyle &Style) { // When reading, read the language first, we need it for getPredefinedStyle. IO.mapOptional("Language", Style.Language); if (IO.outputting()) { StringRef StylesArray[] = { "LLVM", "Google", "Chromium", "Mozilla", "WebKit", "GNU" }; ArrayRef Styles(StylesArray); for (size_t i = 0, e = Styles.size(); i < e; ++i) { StringRef StyleName(Styles[i]); FormatStyle PredefinedStyle; if (getPredefinedStyle(StyleName, Style.Language, &PredefinedStyle) && Style == PredefinedStyle) { IO.mapOptional("# BasedOnStyle", StyleName); break; } } } else { StringRef BasedOnStyle; IO.mapOptional("BasedOnStyle", BasedOnStyle); if (!BasedOnStyle.empty()) { FormatStyle::LanguageKind OldLanguage = Style.Language; FormatStyle::LanguageKind Language = ((FormatStyle *)IO.getContext())->Language; if (!getPredefinedStyle(BasedOnStyle, Language, &Style)) { IO.setError(Twine("Unknown value for BasedOnStyle: ", BasedOnStyle)); return; } Style.Language = OldLanguage; } } IO.mapOptional("AccessModifierOffset", Style.AccessModifierOffset); IO.mapOptional("ConstructorInitializerIndentWidth", Style.ConstructorInitializerIndentWidth); IO.mapOptional("AlignEscapedNewlinesLeft", Style.AlignEscapedNewlinesLeft); IO.mapOptional("AlignTrailingComments", Style.AlignTrailingComments); IO.mapOptional("AllowAllParametersOfDeclarationOnNextLine", Style.AllowAllParametersOfDeclarationOnNextLine); IO.mapOptional("AllowShortBlocksOnASingleLine", Style.AllowShortBlocksOnASingleLine); IO.mapOptional("AllowShortIfStatementsOnASingleLine", Style.AllowShortIfStatementsOnASingleLine); IO.mapOptional("AllowShortLoopsOnASingleLine", Style.AllowShortLoopsOnASingleLine); IO.mapOptional("AllowShortFunctionsOnASingleLine", Style.AllowShortFunctionsOnASingleLine); IO.mapOptional("AlwaysBreakTemplateDeclarations", Style.AlwaysBreakTemplateDeclarations); IO.mapOptional("AlwaysBreakBeforeMultilineStrings", Style.AlwaysBreakBeforeMultilineStrings); IO.mapOptional("BreakBeforeBinaryOperators", Style.BreakBeforeBinaryOperators); IO.mapOptional("BreakBeforeTernaryOperators", Style.BreakBeforeTernaryOperators); IO.mapOptional("BreakConstructorInitializersBeforeComma", Style.BreakConstructorInitializersBeforeComma); IO.mapOptional("BinPackParameters", Style.BinPackParameters); IO.mapOptional("ColumnLimit", Style.ColumnLimit); IO.mapOptional("ConstructorInitializerAllOnOneLineOrOnePerLine", Style.ConstructorInitializerAllOnOneLineOrOnePerLine); IO.mapOptional("DerivePointerAlignment", Style.DerivePointerAlignment); IO.mapOptional("ExperimentalAutoDetectBinPacking", Style.ExperimentalAutoDetectBinPacking); IO.mapOptional("IndentCaseLabels", Style.IndentCaseLabels); IO.mapOptional("IndentWrappedFunctionNames", Style.IndentWrappedFunctionNames); IO.mapOptional("IndentFunctionDeclarationAfterType", Style.IndentWrappedFunctionNames); IO.mapOptional("MaxEmptyLinesToKeep", Style.MaxEmptyLinesToKeep); IO.mapOptional("KeepEmptyLinesAtTheStartOfBlocks", Style.KeepEmptyLinesAtTheStartOfBlocks); IO.mapOptional("NamespaceIndentation", Style.NamespaceIndentation); IO.mapOptional("ObjCSpaceAfterProperty", Style.ObjCSpaceAfterProperty); IO.mapOptional("ObjCSpaceBeforeProtocolList", Style.ObjCSpaceBeforeProtocolList); IO.mapOptional("PenaltyBreakBeforeFirstCallParameter", Style.PenaltyBreakBeforeFirstCallParameter); IO.mapOptional("PenaltyBreakComment", Style.PenaltyBreakComment); IO.mapOptional("PenaltyBreakString", Style.PenaltyBreakString); IO.mapOptional("PenaltyBreakFirstLessLess", Style.PenaltyBreakFirstLessLess); IO.mapOptional("PenaltyExcessCharacter", Style.PenaltyExcessCharacter); IO.mapOptional("PenaltyReturnTypeOnItsOwnLine", Style.PenaltyReturnTypeOnItsOwnLine); IO.mapOptional("PointerAlignment", Style.PointerAlignment); IO.mapOptional("SpacesBeforeTrailingComments", Style.SpacesBeforeTrailingComments); IO.mapOptional("Cpp11BracedListStyle", Style.Cpp11BracedListStyle); IO.mapOptional("Standard", Style.Standard); IO.mapOptional("IndentWidth", Style.IndentWidth); IO.mapOptional("TabWidth", Style.TabWidth); IO.mapOptional("UseTab", Style.UseTab); IO.mapOptional("BreakBeforeBraces", Style.BreakBeforeBraces); IO.mapOptional("SpacesInParentheses", Style.SpacesInParentheses); IO.mapOptional("SpacesInAngles", Style.SpacesInAngles); IO.mapOptional("SpaceInEmptyParentheses", Style.SpaceInEmptyParentheses); IO.mapOptional("SpacesInCStyleCastParentheses", Style.SpacesInCStyleCastParentheses); IO.mapOptional("SpacesInContainerLiterals", Style.SpacesInContainerLiterals); IO.mapOptional("SpaceBeforeAssignmentOperators", Style.SpaceBeforeAssignmentOperators); IO.mapOptional("ContinuationIndentWidth", Style.ContinuationIndentWidth); IO.mapOptional("CommentPragmas", Style.CommentPragmas); IO.mapOptional("ForEachMacros", Style.ForEachMacros); // For backward compatibility. if (!IO.outputting()) { IO.mapOptional("SpaceAfterControlStatementKeyword", Style.SpaceBeforeParens); IO.mapOptional("PointerBindsToType", Style.PointerAlignment); IO.mapOptional("DerivePointerBinding", Style.DerivePointerAlignment); } IO.mapOptional("SpaceBeforeParens", Style.SpaceBeforeParens); IO.mapOptional("DisableFormat", Style.DisableFormat); } }; // Allows to read vector while keeping default values. // IO.getContext() should contain a pointer to the FormatStyle structure, that // will be used to get default values for missing keys. // If the first element has no Language specified, it will be treated as the // default one for the following elements. template <> struct DocumentListTraits > { static size_t size(IO &IO, std::vector &Seq) { return Seq.size(); } static FormatStyle &element(IO &IO, std::vector &Seq, size_t Index) { if (Index >= Seq.size()) { assert(Index == Seq.size()); FormatStyle Template; if (Seq.size() > 0 && Seq[0].Language == FormatStyle::LK_None) { Template = Seq[0]; } else { Template = *((const FormatStyle *)IO.getContext()); Template.Language = FormatStyle::LK_None; } Seq.resize(Index + 1, Template); } return Seq[Index]; } }; } } namespace clang { namespace format { const std::error_category &getParseCategory() { static ParseErrorCategory C; return C; } std::error_code make_error_code(ParseError e) { return std::error_code(static_cast(e), getParseCategory()); } const char *ParseErrorCategory::name() const LLVM_NOEXCEPT { return "clang-format.parse_error"; } std::string ParseErrorCategory::message(int EV) const { switch (static_cast(EV)) { case ParseError::Success: return "Success"; case ParseError::Error: return "Invalid argument"; case ParseError::Unsuitable: return "Unsuitable"; } llvm_unreachable("unexpected parse error"); } FormatStyle getLLVMStyle() { FormatStyle LLVMStyle; LLVMStyle.Language = FormatStyle::LK_Cpp; LLVMStyle.AccessModifierOffset = -2; LLVMStyle.AlignEscapedNewlinesLeft = false; LLVMStyle.AlignTrailingComments = true; LLVMStyle.AllowAllParametersOfDeclarationOnNextLine = true; LLVMStyle.AllowShortFunctionsOnASingleLine = FormatStyle::SFS_All; LLVMStyle.AllowShortBlocksOnASingleLine = false; LLVMStyle.AllowShortIfStatementsOnASingleLine = false; LLVMStyle.AllowShortLoopsOnASingleLine = false; LLVMStyle.AlwaysBreakBeforeMultilineStrings = false; LLVMStyle.AlwaysBreakTemplateDeclarations = false; LLVMStyle.BinPackParameters = true; LLVMStyle.BreakBeforeBinaryOperators = false; LLVMStyle.BreakBeforeTernaryOperators = true; LLVMStyle.BreakBeforeBraces = FormatStyle::BS_Attach; LLVMStyle.BreakConstructorInitializersBeforeComma = false; LLVMStyle.ColumnLimit = 80; LLVMStyle.CommentPragmas = "^ IWYU pragma:"; LLVMStyle.ConstructorInitializerAllOnOneLineOrOnePerLine = false; LLVMStyle.ConstructorInitializerIndentWidth = 4; LLVMStyle.ContinuationIndentWidth = 4; LLVMStyle.Cpp11BracedListStyle = true; LLVMStyle.DerivePointerAlignment = false; LLVMStyle.ExperimentalAutoDetectBinPacking = false; LLVMStyle.ForEachMacros.push_back("foreach"); LLVMStyle.ForEachMacros.push_back("Q_FOREACH"); LLVMStyle.ForEachMacros.push_back("BOOST_FOREACH"); LLVMStyle.IndentCaseLabels = false; LLVMStyle.IndentWrappedFunctionNames = false; LLVMStyle.IndentWidth = 2; LLVMStyle.TabWidth = 8; LLVMStyle.MaxEmptyLinesToKeep = 1; LLVMStyle.KeepEmptyLinesAtTheStartOfBlocks = true; LLVMStyle.NamespaceIndentation = FormatStyle::NI_None; LLVMStyle.ObjCSpaceAfterProperty = false; LLVMStyle.ObjCSpaceBeforeProtocolList = true; LLVMStyle.PointerAlignment = FormatStyle::PAS_Right; LLVMStyle.SpacesBeforeTrailingComments = 1; LLVMStyle.Standard = FormatStyle::LS_Cpp11; LLVMStyle.UseTab = FormatStyle::UT_Never; LLVMStyle.SpacesInParentheses = false; LLVMStyle.SpaceInEmptyParentheses = false; LLVMStyle.SpacesInContainerLiterals = true; LLVMStyle.SpacesInCStyleCastParentheses = false; LLVMStyle.SpaceBeforeParens = FormatStyle::SBPO_ControlStatements; LLVMStyle.SpaceBeforeAssignmentOperators = true; LLVMStyle.SpacesInAngles = false; LLVMStyle.PenaltyBreakComment = 300; LLVMStyle.PenaltyBreakFirstLessLess = 120; LLVMStyle.PenaltyBreakString = 1000; LLVMStyle.PenaltyExcessCharacter = 1000000; LLVMStyle.PenaltyReturnTypeOnItsOwnLine = 60; LLVMStyle.PenaltyBreakBeforeFirstCallParameter = 19; LLVMStyle.DisableFormat = false; return LLVMStyle; } FormatStyle getGoogleStyle(FormatStyle::LanguageKind Language) { FormatStyle GoogleStyle = getLLVMStyle(); GoogleStyle.Language = Language; GoogleStyle.AccessModifierOffset = -1; GoogleStyle.AlignEscapedNewlinesLeft = true; GoogleStyle.AllowShortIfStatementsOnASingleLine = true; GoogleStyle.AllowShortLoopsOnASingleLine = true; GoogleStyle.AlwaysBreakBeforeMultilineStrings = true; GoogleStyle.AlwaysBreakTemplateDeclarations = true; GoogleStyle.ConstructorInitializerAllOnOneLineOrOnePerLine = true; GoogleStyle.DerivePointerAlignment = true; GoogleStyle.IndentCaseLabels = true; GoogleStyle.KeepEmptyLinesAtTheStartOfBlocks = false; GoogleStyle.ObjCSpaceAfterProperty = false; GoogleStyle.ObjCSpaceBeforeProtocolList = false; GoogleStyle.PointerAlignment = FormatStyle::PAS_Left; GoogleStyle.SpacesBeforeTrailingComments = 2; GoogleStyle.Standard = FormatStyle::LS_Auto; GoogleStyle.PenaltyReturnTypeOnItsOwnLine = 200; GoogleStyle.PenaltyBreakBeforeFirstCallParameter = 1; if (Language == FormatStyle::LK_JavaScript) { GoogleStyle.BreakBeforeTernaryOperators = false; GoogleStyle.MaxEmptyLinesToKeep = 3; GoogleStyle.SpacesInContainerLiterals = false; } else if (Language == FormatStyle::LK_Proto) { GoogleStyle.AllowShortFunctionsOnASingleLine = FormatStyle::SFS_None; GoogleStyle.SpacesInContainerLiterals = false; } return GoogleStyle; } FormatStyle getChromiumStyle(FormatStyle::LanguageKind Language) { FormatStyle ChromiumStyle = getGoogleStyle(Language); ChromiumStyle.AllowAllParametersOfDeclarationOnNextLine = false; ChromiumStyle.AllowShortFunctionsOnASingleLine = FormatStyle::SFS_Inline; ChromiumStyle.AllowShortIfStatementsOnASingleLine = false; ChromiumStyle.AllowShortLoopsOnASingleLine = false; ChromiumStyle.BinPackParameters = false; ChromiumStyle.DerivePointerAlignment = false; ChromiumStyle.Standard = FormatStyle::LS_Cpp03; return ChromiumStyle; } FormatStyle getMozillaStyle() { FormatStyle MozillaStyle = getLLVMStyle(); MozillaStyle.AllowAllParametersOfDeclarationOnNextLine = false; MozillaStyle.Cpp11BracedListStyle = false; MozillaStyle.ConstructorInitializerAllOnOneLineOrOnePerLine = true; MozillaStyle.DerivePointerAlignment = true; MozillaStyle.IndentCaseLabels = true; MozillaStyle.ObjCSpaceAfterProperty = true; MozillaStyle.ObjCSpaceBeforeProtocolList = false; MozillaStyle.PenaltyReturnTypeOnItsOwnLine = 200; MozillaStyle.PointerAlignment = FormatStyle::PAS_Left; MozillaStyle.Standard = FormatStyle::LS_Cpp03; return MozillaStyle; } FormatStyle getWebKitStyle() { FormatStyle Style = getLLVMStyle(); Style.AccessModifierOffset = -4; Style.AlignTrailingComments = false; Style.BreakBeforeBinaryOperators = true; Style.BreakBeforeBraces = FormatStyle::BS_Stroustrup; Style.BreakConstructorInitializersBeforeComma = true; Style.Cpp11BracedListStyle = false; Style.ColumnLimit = 0; Style.IndentWidth = 4; Style.NamespaceIndentation = FormatStyle::NI_Inner; Style.ObjCSpaceAfterProperty = true; Style.PointerAlignment = FormatStyle::PAS_Left; Style.Standard = FormatStyle::LS_Cpp03; return Style; } FormatStyle getGNUStyle() { FormatStyle Style = getLLVMStyle(); Style.BreakBeforeBinaryOperators = true; Style.BreakBeforeBraces = FormatStyle::BS_GNU; Style.BreakBeforeTernaryOperators = true; Style.Cpp11BracedListStyle = false; Style.ColumnLimit = 79; Style.SpaceBeforeParens = FormatStyle::SBPO_Always; Style.Standard = FormatStyle::LS_Cpp03; return Style; } FormatStyle getNoStyle() { FormatStyle NoStyle = getLLVMStyle(); NoStyle.DisableFormat = true; return NoStyle; } bool getPredefinedStyle(StringRef Name, FormatStyle::LanguageKind Language, FormatStyle *Style) { if (Name.equals_lower("llvm")) { *Style = getLLVMStyle(); } else if (Name.equals_lower("chromium")) { *Style = getChromiumStyle(Language); } else if (Name.equals_lower("mozilla")) { *Style = getMozillaStyle(); } else if (Name.equals_lower("google")) { *Style = getGoogleStyle(Language); } else if (Name.equals_lower("webkit")) { *Style = getWebKitStyle(); } else if (Name.equals_lower("gnu")) { *Style = getGNUStyle(); } else if (Name.equals_lower("none")) { *Style = getNoStyle(); } else { return false; } Style->Language = Language; return true; } std::error_code parseConfiguration(StringRef Text, FormatStyle *Style) { assert(Style); FormatStyle::LanguageKind Language = Style->Language; assert(Language != FormatStyle::LK_None); if (Text.trim().empty()) return make_error_code(ParseError::Error); std::vector Styles; llvm::yaml::Input Input(Text); // DocumentListTraits> uses the context to get default // values for the fields, keys for which are missing from the configuration. // Mapping also uses the context to get the language to find the correct // base style. Input.setContext(Style); Input >> Styles; if (Input.error()) return Input.error(); for (unsigned i = 0; i < Styles.size(); ++i) { // Ensures that only the first configuration can skip the Language option. if (Styles[i].Language == FormatStyle::LK_None && i != 0) return make_error_code(ParseError::Error); // Ensure that each language is configured at most once. for (unsigned j = 0; j < i; ++j) { if (Styles[i].Language == Styles[j].Language) { DEBUG(llvm::dbgs() << "Duplicate languages in the config file on positions " << j << " and " << i << "\n"); return make_error_code(ParseError::Error); } } } // Look for a suitable configuration starting from the end, so we can // find the configuration for the specific language first, and the default // configuration (which can only be at slot 0) after it. for (int i = Styles.size() - 1; i >= 0; --i) { if (Styles[i].Language == Language || Styles[i].Language == FormatStyle::LK_None) { *Style = Styles[i]; Style->Language = Language; return make_error_code(ParseError::Success); } } return make_error_code(ParseError::Unsuitable); } std::string configurationAsText(const FormatStyle &Style) { std::string Text; llvm::raw_string_ostream Stream(Text); llvm::yaml::Output Output(Stream); // We use the same mapping method for input and output, so we need a non-const // reference here. FormatStyle NonConstStyle = Style; Output << NonConstStyle; return Stream.str(); } namespace { class NoColumnLimitFormatter { public: NoColumnLimitFormatter(ContinuationIndenter *Indenter) : Indenter(Indenter) {} /// \brief Formats the line starting at \p State, simply keeping all of the /// input's line breaking decisions. void format(unsigned FirstIndent, const AnnotatedLine *Line) { LineState State = Indenter->getInitialState(FirstIndent, Line, /*DryRun=*/false); while (State.NextToken) { bool Newline = Indenter->mustBreak(State) || (Indenter->canBreak(State) && State.NextToken->NewlinesBefore > 0); Indenter->addTokenToState(State, Newline, /*DryRun=*/false); } } private: ContinuationIndenter *Indenter; }; class LineJoiner { public: LineJoiner(const FormatStyle &Style) : Style(Style) {} /// \brief Calculates how many lines can be merged into 1 starting at \p I. unsigned tryFitMultipleLinesInOne(unsigned Indent, SmallVectorImpl::const_iterator I, SmallVectorImpl::const_iterator E) { // We can never merge stuff if there are trailing line comments. const AnnotatedLine *TheLine = *I; if (TheLine->Last->Type == TT_LineComment) return 0; if (Style.ColumnLimit > 0 && Indent > Style.ColumnLimit) return 0; unsigned Limit = Style.ColumnLimit == 0 ? UINT_MAX : Style.ColumnLimit - Indent; // If we already exceed the column limit, we set 'Limit' to 0. The different // tryMerge..() functions can then decide whether to still do merging. Limit = TheLine->Last->TotalLength > Limit ? 0 : Limit - TheLine->Last->TotalLength; if (I + 1 == E || I[1]->Type == LT_Invalid || I[1]->First->MustBreakBefore) return 0; // FIXME: TheLine->Level != 0 might or might not be the right check to do. // If necessary, change to something smarter. bool MergeShortFunctions = Style.AllowShortFunctionsOnASingleLine == FormatStyle::SFS_All || (Style.AllowShortFunctionsOnASingleLine == FormatStyle::SFS_Inline && TheLine->Level != 0); if (TheLine->Last->Type == TT_FunctionLBrace && TheLine->First != TheLine->Last) { return MergeShortFunctions ? tryMergeSimpleBlock(I, E, Limit) : 0; } if (TheLine->Last->is(tok::l_brace)) { return Style.BreakBeforeBraces == FormatStyle::BS_Attach ? tryMergeSimpleBlock(I, E, Limit) : 0; } if (I[1]->First->Type == TT_FunctionLBrace && Style.BreakBeforeBraces != FormatStyle::BS_Attach) { // Check for Limit <= 2 to account for the " {". if (Limit <= 2 || (Style.ColumnLimit == 0 && containsMustBreak(TheLine))) return 0; Limit -= 2; unsigned MergedLines = 0; if (MergeShortFunctions) { MergedLines = tryMergeSimpleBlock(I + 1, E, Limit); // If we managed to merge the block, count the function header, which is // on a separate line. if (MergedLines > 0) ++MergedLines; } return MergedLines; } if (TheLine->First->is(tok::kw_if)) { return Style.AllowShortIfStatementsOnASingleLine ? tryMergeSimpleControlStatement(I, E, Limit) : 0; } if (TheLine->First->isOneOf(tok::kw_for, tok::kw_while)) { return Style.AllowShortLoopsOnASingleLine ? tryMergeSimpleControlStatement(I, E, Limit) : 0; } if (TheLine->InPPDirective && (TheLine->First->HasUnescapedNewline || TheLine->First->IsFirst)) { return tryMergeSimplePPDirective(I, E, Limit); } return 0; } private: unsigned tryMergeSimplePPDirective(SmallVectorImpl::const_iterator I, SmallVectorImpl::const_iterator E, unsigned Limit) { if (Limit == 0) return 0; if (!I[1]->InPPDirective || I[1]->First->HasUnescapedNewline) return 0; if (I + 2 != E && I[2]->InPPDirective && !I[2]->First->HasUnescapedNewline) return 0; if (1 + I[1]->Last->TotalLength > Limit) return 0; return 1; } unsigned tryMergeSimpleControlStatement( SmallVectorImpl::const_iterator I, SmallVectorImpl::const_iterator E, unsigned Limit) { if (Limit == 0) return 0; if ((Style.BreakBeforeBraces == FormatStyle::BS_Allman || Style.BreakBeforeBraces == FormatStyle::BS_GNU) && (I[1]->First->is(tok::l_brace) && !Style.AllowShortBlocksOnASingleLine)) return 0; if (I[1]->InPPDirective != (*I)->InPPDirective || (I[1]->InPPDirective && I[1]->First->HasUnescapedNewline)) return 0; Limit = limitConsideringMacros(I + 1, E, Limit); AnnotatedLine &Line = **I; if (Line.Last->isNot(tok::r_paren)) return 0; if (1 + I[1]->Last->TotalLength > Limit) return 0; if (I[1]->First->isOneOf(tok::semi, tok::kw_if, tok::kw_for, tok::kw_while) || I[1]->First->Type == TT_LineComment) return 0; // Only inline simple if's (no nested if or else). if (I + 2 != E && Line.First->is(tok::kw_if) && I[2]->First->is(tok::kw_else)) return 0; return 1; } unsigned tryMergeSimpleBlock(SmallVectorImpl::const_iterator I, SmallVectorImpl::const_iterator E, unsigned Limit) { AnnotatedLine &Line = **I; // Don't merge ObjC @ keywords and methods. if (Line.First->isOneOf(tok::at, tok::minus, tok::plus)) return 0; // Check that the current line allows merging. This depends on whether we // are in a control flow statements as well as several style flags. if (Line.First->isOneOf(tok::kw_else, tok::kw_case)) return 0; if (Line.First->isOneOf(tok::kw_if, tok::kw_while, tok::kw_do, tok::kw_try, tok::kw_catch, tok::kw_for, tok::r_brace)) { if (!Style.AllowShortBlocksOnASingleLine) return 0; if (!Style.AllowShortIfStatementsOnASingleLine && Line.First->is(tok::kw_if)) return 0; if (!Style.AllowShortLoopsOnASingleLine && Line.First->isOneOf(tok::kw_while, tok::kw_do, tok::kw_for)) return 0; // FIXME: Consider an option to allow short exception handling clauses on // a single line. if (Line.First->isOneOf(tok::kw_try, tok::kw_catch)) return 0; } FormatToken *Tok = I[1]->First; if (Tok->is(tok::r_brace) && !Tok->MustBreakBefore && (Tok->getNextNonComment() == nullptr || Tok->getNextNonComment()->is(tok::semi))) { // We merge empty blocks even if the line exceeds the column limit. Tok->SpacesRequiredBefore = 0; Tok->CanBreakBefore = true; return 1; } else if (Limit != 0 && Line.First->isNot(tok::kw_namespace)) { // We don't merge short records. if (Line.First->isOneOf(tok::kw_class, tok::kw_union, tok::kw_struct)) return 0; // Check that we still have three lines and they fit into the limit. if (I + 2 == E || I[2]->Type == LT_Invalid) return 0; Limit = limitConsideringMacros(I + 2, E, Limit); if (!nextTwoLinesFitInto(I, Limit)) return 0; // Second, check that the next line does not contain any braces - if it // does, readability declines when putting it into a single line. if (I[1]->Last->Type == TT_LineComment) return 0; do { if (Tok->is(tok::l_brace) && Tok->BlockKind != BK_BracedInit) return 0; Tok = Tok->Next; } while (Tok); // Last, check that the third line starts with a closing brace. Tok = I[2]->First; if (Tok->isNot(tok::r_brace)) return 0; return 2; } return 0; } /// Returns the modified column limit for \p I if it is inside a macro and /// needs a trailing '\'. unsigned limitConsideringMacros(SmallVectorImpl::const_iterator I, SmallVectorImpl::const_iterator E, unsigned Limit) { if (I[0]->InPPDirective && I + 1 != E && !I[1]->First->HasUnescapedNewline && !I[1]->First->is(tok::eof)) { return Limit < 2 ? 0 : Limit - 2; } return Limit; } bool nextTwoLinesFitInto(SmallVectorImpl::const_iterator I, unsigned Limit) { if (I[1]->First->MustBreakBefore || I[2]->First->MustBreakBefore) return false; return 1 + I[1]->Last->TotalLength + 1 + I[2]->Last->TotalLength <= Limit; } bool containsMustBreak(const AnnotatedLine *Line) { for (const FormatToken *Tok = Line->First; Tok; Tok = Tok->Next) { if (Tok->MustBreakBefore) return true; } return false; } const FormatStyle &Style; }; class UnwrappedLineFormatter { public: UnwrappedLineFormatter(ContinuationIndenter *Indenter, WhitespaceManager *Whitespaces, const FormatStyle &Style) : Indenter(Indenter), Whitespaces(Whitespaces), Style(Style), Joiner(Style) {} unsigned format(const SmallVectorImpl &Lines, bool DryRun, int AdditionalIndent = 0, bool FixBadIndentation = false) { // Try to look up already computed penalty in DryRun-mode. std::pair *, unsigned> CacheKey( &Lines, AdditionalIndent); auto CacheIt = PenaltyCache.find(CacheKey); if (DryRun && CacheIt != PenaltyCache.end()) return CacheIt->second; assert(!Lines.empty()); unsigned Penalty = 0; std::vector IndentForLevel; for (unsigned i = 0, e = Lines[0]->Level; i != e; ++i) IndentForLevel.push_back(Style.IndentWidth * i + AdditionalIndent); const AnnotatedLine *PreviousLine = nullptr; for (SmallVectorImpl::const_iterator I = Lines.begin(), E = Lines.end(); I != E; ++I) { const AnnotatedLine &TheLine = **I; const FormatToken *FirstTok = TheLine.First; int Offset = getIndentOffset(*FirstTok); // Determine indent and try to merge multiple unwrapped lines. unsigned Indent; if (TheLine.InPPDirective) { Indent = TheLine.Level * Style.IndentWidth; } else { while (IndentForLevel.size() <= TheLine.Level) IndentForLevel.push_back(-1); IndentForLevel.resize(TheLine.Level + 1); Indent = getIndent(IndentForLevel, TheLine.Level); } unsigned LevelIndent = Indent; if (static_cast(Indent) + Offset >= 0) Indent += Offset; // Merge multiple lines if possible. unsigned MergedLines = Joiner.tryFitMultipleLinesInOne(Indent, I, E); if (MergedLines > 0 && Style.ColumnLimit == 0) { // Disallow line merging if there is a break at the start of one of the // input lines. for (unsigned i = 0; i < MergedLines; ++i) { if (I[i + 1]->First->NewlinesBefore > 0) MergedLines = 0; } } if (!DryRun) { for (unsigned i = 0; i < MergedLines; ++i) { join(*I[i], *I[i + 1]); } } I += MergedLines; bool FixIndentation = FixBadIndentation && (LevelIndent != FirstTok->OriginalColumn); if (TheLine.First->is(tok::eof)) { if (PreviousLine && PreviousLine->Affected && !DryRun) { // Remove the file's trailing whitespace. unsigned Newlines = std::min(FirstTok->NewlinesBefore, 1u); Whitespaces->replaceWhitespace(*TheLine.First, Newlines, /*IndentLevel=*/0, /*Spaces=*/0, /*TargetColumn=*/0); } } else if (TheLine.Type != LT_Invalid && (TheLine.Affected || FixIndentation)) { if (FirstTok->WhitespaceRange.isValid()) { if (!DryRun) formatFirstToken(*TheLine.First, PreviousLine, TheLine.Level, Indent, TheLine.InPPDirective); } else { Indent = LevelIndent = FirstTok->OriginalColumn; } // If everything fits on a single line, just put it there. unsigned ColumnLimit = Style.ColumnLimit; if (I + 1 != E) { AnnotatedLine *NextLine = I[1]; if (NextLine->InPPDirective && !NextLine->First->HasUnescapedNewline) ColumnLimit = getColumnLimit(TheLine.InPPDirective); } if (TheLine.Last->TotalLength + Indent <= ColumnLimit) { LineState State = Indenter->getInitialState(Indent, &TheLine, DryRun); while (State.NextToken) { formatChildren(State, /*Newline=*/false, /*DryRun=*/false, Penalty); Indenter->addTokenToState(State, /*Newline=*/false, DryRun); } } else if (Style.ColumnLimit == 0) { // FIXME: Implement nested blocks for ColumnLimit = 0. NoColumnLimitFormatter Formatter(Indenter); if (!DryRun) Formatter.format(Indent, &TheLine); } else { Penalty += format(TheLine, Indent, DryRun); } if (!TheLine.InPPDirective) IndentForLevel[TheLine.Level] = LevelIndent; } else if (TheLine.ChildrenAffected) { format(TheLine.Children, DryRun); } else { // Format the first token if necessary, and notify the WhitespaceManager // about the unchanged whitespace. for (FormatToken *Tok = TheLine.First; Tok; Tok = Tok->Next) { if (Tok == TheLine.First && (Tok->NewlinesBefore > 0 || Tok->IsFirst)) { unsigned LevelIndent = Tok->OriginalColumn; if (!DryRun) { // Remove trailing whitespace of the previous line. if ((PreviousLine && PreviousLine->Affected) || TheLine.LeadingEmptyLinesAffected) { formatFirstToken(*Tok, PreviousLine, TheLine.Level, LevelIndent, TheLine.InPPDirective); } else { Whitespaces->addUntouchableToken(*Tok, TheLine.InPPDirective); } } if (static_cast(LevelIndent) - Offset >= 0) LevelIndent -= Offset; if (Tok->isNot(tok::comment) && !TheLine.InPPDirective) IndentForLevel[TheLine.Level] = LevelIndent; } else if (!DryRun) { Whitespaces->addUntouchableToken(*Tok, TheLine.InPPDirective); } } } if (!DryRun) { for (FormatToken *Tok = TheLine.First; Tok; Tok = Tok->Next) { Tok->Finalized = true; } } PreviousLine = *I; } PenaltyCache[CacheKey] = Penalty; return Penalty; } private: /// \brief Formats an \c AnnotatedLine and returns the penalty. /// /// If \p DryRun is \c false, directly applies the changes. unsigned format(const AnnotatedLine &Line, unsigned FirstIndent, bool DryRun) { LineState State = Indenter->getInitialState(FirstIndent, &Line, DryRun); // If the ObjC method declaration does not fit on a line, we should format // it with one arg per line. if (State.Line->Type == LT_ObjCMethodDecl) State.Stack.back().BreakBeforeParameter = true; // Find best solution in solution space. return analyzeSolutionSpace(State, DryRun); } /// \brief An edge in the solution space from \c Previous->State to \c State, /// inserting a newline dependent on the \c NewLine. struct StateNode { StateNode(const LineState &State, bool NewLine, StateNode *Previous) : State(State), NewLine(NewLine), Previous(Previous) {} LineState State; bool NewLine; StateNode *Previous; }; /// \brief A pair of that is used to prioritize the BFS on. /// /// In case of equal penalties, we want to prefer states that were inserted /// first. During state generation we make sure that we insert states first /// that break the line as late as possible. typedef std::pair OrderedPenalty; /// \brief An item in the prioritized BFS search queue. The \c StateNode's /// \c State has the given \c OrderedPenalty. typedef std::pair QueueItem; /// \brief The BFS queue type. typedef std::priority_queue, std::greater > QueueType; /// \brief Get the offset of the line relatively to the level. /// /// For example, 'public:' labels in classes are offset by 1 or 2 /// characters to the left from their level. int getIndentOffset(const FormatToken &RootToken) { if (RootToken.isAccessSpecifier(false) || RootToken.isObjCAccessSpecifier()) return Style.AccessModifierOffset; return 0; } /// \brief Add a new line and the required indent before the first Token /// of the \c UnwrappedLine if there was no structural parsing error. void formatFirstToken(FormatToken &RootToken, const AnnotatedLine *PreviousLine, unsigned IndentLevel, unsigned Indent, bool InPPDirective) { unsigned Newlines = std::min(RootToken.NewlinesBefore, Style.MaxEmptyLinesToKeep + 1); // Remove empty lines before "}" where applicable. if (RootToken.is(tok::r_brace) && (!RootToken.Next || (RootToken.Next->is(tok::semi) && !RootToken.Next->Next))) Newlines = std::min(Newlines, 1u); if (Newlines == 0 && !RootToken.IsFirst) Newlines = 1; if (RootToken.IsFirst && !RootToken.HasUnescapedNewline) Newlines = 0; // Remove empty lines after "{". if (!Style.KeepEmptyLinesAtTheStartOfBlocks && PreviousLine && PreviousLine->Last->is(tok::l_brace) && PreviousLine->First->isNot(tok::kw_namespace)) Newlines = 1; // Insert extra new line before access specifiers. if (PreviousLine && PreviousLine->Last->isOneOf(tok::semi, tok::r_brace) && RootToken.isAccessSpecifier() && RootToken.NewlinesBefore == 1) ++Newlines; // Remove empty lines after access specifiers. if (PreviousLine && PreviousLine->First->isAccessSpecifier()) Newlines = std::min(1u, Newlines); Whitespaces->replaceWhitespace(RootToken, Newlines, IndentLevel, Indent, Indent, InPPDirective && !RootToken.HasUnescapedNewline); } /// \brief Get the indent of \p Level from \p IndentForLevel. /// /// \p IndentForLevel must contain the indent for the level \c l /// at \p IndentForLevel[l], or a value < 0 if the indent for /// that level is unknown. unsigned getIndent(const std::vector IndentForLevel, unsigned Level) { if (IndentForLevel[Level] != -1) return IndentForLevel[Level]; if (Level == 0) return 0; return getIndent(IndentForLevel, Level - 1) + Style.IndentWidth; } void join(AnnotatedLine &A, const AnnotatedLine &B) { assert(!A.Last->Next); assert(!B.First->Previous); if (B.Affected) A.Affected = true; A.Last->Next = B.First; B.First->Previous = A.Last; B.First->CanBreakBefore = true; unsigned LengthA = A.Last->TotalLength + B.First->SpacesRequiredBefore; for (FormatToken *Tok = B.First; Tok; Tok = Tok->Next) { Tok->TotalLength += LengthA; A.Last = Tok; } } unsigned getColumnLimit(bool InPPDirective) const { // In preprocessor directives reserve two chars for trailing " \" return Style.ColumnLimit - (InPPDirective ? 2 : 0); } struct CompareLineStatePointers { bool operator()(LineState *obj1, LineState *obj2) const { return *obj1 < *obj2; } }; /// \brief Analyze the entire solution space starting from \p InitialState. /// /// This implements a variant of Dijkstra's algorithm on the graph that spans /// the solution space (\c LineStates are the nodes). The algorithm tries to /// find the shortest path (the one with lowest penalty) from \p InitialState /// to a state where all tokens are placed. Returns the penalty. /// /// If \p DryRun is \c false, directly applies the changes. unsigned analyzeSolutionSpace(LineState &InitialState, bool DryRun = false) { std::set Seen; // Increasing count of \c StateNode items we have created. This is used to // create a deterministic order independent of the container. unsigned Count = 0; QueueType Queue; // Insert start element into queue. StateNode *Node = new (Allocator.Allocate()) StateNode(InitialState, false, nullptr); Queue.push(QueueItem(OrderedPenalty(0, Count), Node)); ++Count; unsigned Penalty = 0; // While not empty, take first element and follow edges. while (!Queue.empty()) { Penalty = Queue.top().first.first; StateNode *Node = Queue.top().second; if (!Node->State.NextToken) { DEBUG(llvm::dbgs() << "\n---\nPenalty for line: " << Penalty << "\n"); break; } Queue.pop(); // Cut off the analysis of certain solutions if the analysis gets too // complex. See description of IgnoreStackForComparison. if (Count > 10000) Node->State.IgnoreStackForComparison = true; if (!Seen.insert(&Node->State).second) // State already examined with lower penalty. continue; FormatDecision LastFormat = Node->State.NextToken->Decision; if (LastFormat == FD_Unformatted || LastFormat == FD_Continue) addNextStateToQueue(Penalty, Node, /*NewLine=*/false, &Count, &Queue); if (LastFormat == FD_Unformatted || LastFormat == FD_Break) addNextStateToQueue(Penalty, Node, /*NewLine=*/true, &Count, &Queue); } if (Queue.empty()) { // We were unable to find a solution, do nothing. // FIXME: Add diagnostic? DEBUG(llvm::dbgs() << "Could not find a solution.\n"); return 0; } // Reconstruct the solution. if (!DryRun) reconstructPath(InitialState, Queue.top().second); DEBUG(llvm::dbgs() << "Total number of analyzed states: " << Count << "\n"); DEBUG(llvm::dbgs() << "---\n"); return Penalty; } void reconstructPath(LineState &State, StateNode *Current) { std::deque Path; // We do not need a break before the initial token. while (Current->Previous) { Path.push_front(Current); Current = Current->Previous; } for (std::deque::iterator I = Path.begin(), E = Path.end(); I != E; ++I) { unsigned Penalty = 0; formatChildren(State, (*I)->NewLine, /*DryRun=*/false, Penalty); Penalty += Indenter->addTokenToState(State, (*I)->NewLine, false); DEBUG({ if ((*I)->NewLine) { llvm::dbgs() << "Penalty for placing " << (*I)->Previous->State.NextToken->Tok.getName() << ": " << Penalty << "\n"; } }); } } /// \brief Add the following state to the analysis queue \c Queue. /// /// Assume the current state is \p PreviousNode and has been reached with a /// penalty of \p Penalty. Insert a line break if \p NewLine is \c true. void addNextStateToQueue(unsigned Penalty, StateNode *PreviousNode, bool NewLine, unsigned *Count, QueueType *Queue) { if (NewLine && !Indenter->canBreak(PreviousNode->State)) return; if (!NewLine && Indenter->mustBreak(PreviousNode->State)) return; StateNode *Node = new (Allocator.Allocate()) StateNode(PreviousNode->State, NewLine, PreviousNode); if (!formatChildren(Node->State, NewLine, /*DryRun=*/true, Penalty)) return; Penalty += Indenter->addTokenToState(Node->State, NewLine, true); Queue->push(QueueItem(OrderedPenalty(Penalty, *Count), Node)); ++(*Count); } /// \brief If the \p State's next token is an r_brace closing a nested block, /// format the nested block before it. /// /// Returns \c true if all children could be placed successfully and adapts /// \p Penalty as well as \p State. If \p DryRun is false, also directly /// creates changes using \c Whitespaces. /// /// The crucial idea here is that children always get formatted upon /// encountering the closing brace right after the nested block. Now, if we /// are currently trying to keep the "}" on the same line (i.e. \p NewLine is /// \c false), the entire block has to be kept on the same line (which is only /// possible if it fits on the line, only contains a single statement, etc. /// /// If \p NewLine is true, we format the nested block on separate lines, i.e. /// break after the "{", format all lines with correct indentation and the put /// the closing "}" on yet another new line. /// /// This enables us to keep the simple structure of the /// \c UnwrappedLineFormatter, where we only have two options for each token: /// break or don't break. bool formatChildren(LineState &State, bool NewLine, bool DryRun, unsigned &Penalty) { FormatToken &Previous = *State.NextToken->Previous; const FormatToken *LBrace = State.NextToken->getPreviousNonComment(); if (!LBrace || LBrace->isNot(tok::l_brace) || LBrace->BlockKind != BK_Block || Previous.Children.size() == 0) // The previous token does not open a block. Nothing to do. We don't // assert so that we can simply call this function for all tokens. return true; if (NewLine) { int AdditionalIndent = State.FirstIndent - State.Line->Level * Style.IndentWidth; if (State.Stack.size() < 2 || !State.Stack[State.Stack.size() - 2].JSFunctionInlined) { AdditionalIndent = State.Stack.back().Indent - Previous.Children[0]->Level * Style.IndentWidth; } Penalty += format(Previous.Children, DryRun, AdditionalIndent, /*FixBadIndentation=*/true); return true; } // Cannot merge multiple statements into a single line. if (Previous.Children.size() > 1) return false; // Cannot merge into one line if this line ends on a comment. if (Previous.is(tok::comment)) return false; // We can't put the closing "}" on a line with a trailing comment. if (Previous.Children[0]->Last->isTrailingComment()) return false; // If the child line exceeds the column limit, we wouldn't want to merge it. // We add +2 for the trailing " }". if (Style.ColumnLimit > 0 && Previous.Children[0]->Last->TotalLength + State.Column + 2 > Style.ColumnLimit) return false; if (!DryRun) { Whitespaces->replaceWhitespace( *Previous.Children[0]->First, /*Newlines=*/0, /*IndentLevel=*/0, /*Spaces=*/1, /*StartOfTokenColumn=*/State.Column, State.Line->InPPDirective); } Penalty += format(*Previous.Children[0], State.Column + 1, DryRun); State.Column += 1 + Previous.Children[0]->Last->TotalLength; return true; } ContinuationIndenter *Indenter; WhitespaceManager *Whitespaces; FormatStyle Style; LineJoiner Joiner; llvm::SpecificBumpPtrAllocator Allocator; // Cache to store the penalty of formatting a vector of AnnotatedLines // starting from a specific additional offset. Improves performance if there // are many nested blocks. std::map *, unsigned>, unsigned> PenaltyCache; }; class FormatTokenLexer { public: FormatTokenLexer(Lexer &Lex, SourceManager &SourceMgr, FormatStyle &Style, encoding::Encoding Encoding) : FormatTok(nullptr), IsFirstToken(true), GreaterStashed(false), Column(0), TrailingWhitespace(0), Lex(Lex), SourceMgr(SourceMgr), Style(Style), IdentTable(getFormattingLangOpts()), Encoding(Encoding), FirstInLineIndex(0) { Lex.SetKeepWhitespaceMode(true); for (const std::string &ForEachMacro : Style.ForEachMacros) ForEachMacros.push_back(&IdentTable.get(ForEachMacro)); std::sort(ForEachMacros.begin(), ForEachMacros.end()); } ArrayRef lex() { assert(Tokens.empty()); assert(FirstInLineIndex == 0); do { Tokens.push_back(getNextToken()); tryMergePreviousTokens(); if (Tokens.back()->NewlinesBefore > 0) FirstInLineIndex = Tokens.size() - 1; } while (Tokens.back()->Tok.isNot(tok::eof)); return Tokens; } IdentifierTable &getIdentTable() { return IdentTable; } private: void tryMergePreviousTokens() { if (tryMerge_TMacro()) return; if (tryMergeConflictMarkers()) return; if (Style.Language == FormatStyle::LK_JavaScript) { if (tryMergeEscapeSequence()) return; if (tryMergeJSRegexLiteral()) return; static tok::TokenKind JSIdentity[] = { tok::equalequal, tok::equal }; static tok::TokenKind JSNotIdentity[] = { tok::exclaimequal, tok::equal }; static tok::TokenKind JSShiftEqual[] = { tok::greater, tok::greater, tok::greaterequal }; static tok::TokenKind JSRightArrow[] = { tok::equal, tok::greater }; // FIXME: We probably need to change token type to mimic operator with the // correct priority. if (tryMergeTokens(JSIdentity)) return; if (tryMergeTokens(JSNotIdentity)) return; if (tryMergeTokens(JSShiftEqual)) return; if (tryMergeTokens(JSRightArrow)) return; } } bool tryMergeTokens(ArrayRef Kinds) { if (Tokens.size() < Kinds.size()) return false; SmallVectorImpl::const_iterator First = Tokens.end() - Kinds.size(); if (!First[0]->is(Kinds[0])) return false; unsigned AddLength = 0; for (unsigned i = 1; i < Kinds.size(); ++i) { if (!First[i]->is(Kinds[i]) || First[i]->WhitespaceRange.getBegin() != First[i]->WhitespaceRange.getEnd()) return false; AddLength += First[i]->TokenText.size(); } Tokens.resize(Tokens.size() - Kinds.size() + 1); First[0]->TokenText = StringRef(First[0]->TokenText.data(), First[0]->TokenText.size() + AddLength); First[0]->ColumnWidth += AddLength; return true; } // Tries to merge an escape sequence, i.e. a "\\" and the following // character. Use e.g. inside JavaScript regex literals. bool tryMergeEscapeSequence() { if (Tokens.size() < 2) return false; FormatToken *Previous = Tokens[Tokens.size() - 2]; if (Previous->isNot(tok::unknown) || Previous->TokenText != "\\" || Tokens.back()->NewlinesBefore != 0) return false; Previous->ColumnWidth += Tokens.back()->ColumnWidth; StringRef Text = Previous->TokenText; Previous->TokenText = StringRef(Text.data(), Text.size() + Tokens.back()->TokenText.size()); Tokens.resize(Tokens.size() - 1); return true; } // Try to determine whether the current token ends a JavaScript regex literal. // We heuristically assume that this is a regex literal if we find two // unescaped slashes on a line and the token before the first slash is one of // "(;,{}![:?", a binary operator or 'return', as those cannot be followed by // a division. bool tryMergeJSRegexLiteral() { if (Tokens.size() < 2 || Tokens.back()->isNot(tok::slash) || (Tokens[Tokens.size() - 2]->is(tok::unknown) && Tokens[Tokens.size() - 2]->TokenText == "\\")) return false; unsigned TokenCount = 0; unsigned LastColumn = Tokens.back()->OriginalColumn; for (auto I = Tokens.rbegin() + 1, E = Tokens.rend(); I != E; ++I) { ++TokenCount; if (I[0]->is(tok::slash) && I + 1 != E && (I[1]->isOneOf(tok::l_paren, tok::semi, tok::l_brace, tok::r_brace, tok::exclaim, tok::l_square, tok::colon, tok::comma, tok::question, tok::kw_return) || I[1]->isBinaryOperator())) { Tokens.resize(Tokens.size() - TokenCount); Tokens.back()->Tok.setKind(tok::unknown); Tokens.back()->Type = TT_RegexLiteral; Tokens.back()->ColumnWidth += LastColumn - I[0]->OriginalColumn; return true; } // There can't be a newline inside a regex literal. if (I[0]->NewlinesBefore > 0) return false; } return false; } bool tryMerge_TMacro() { if (Tokens.size() < 4) return false; FormatToken *Last = Tokens.back(); if (!Last->is(tok::r_paren)) return false; FormatToken *String = Tokens[Tokens.size() - 2]; if (!String->is(tok::string_literal) || String->IsMultiline) return false; if (!Tokens[Tokens.size() - 3]->is(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); Tokens.pop_back(); Tokens.pop_back(); Tokens.pop_back(); Tokens.back() = String; return true; } bool 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.getBuffer(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()->Type = Type; Tokens.back()->Tok.setKind(tok::kw___unknown_anytype); Tokens.push_back(Next); return true; } return false; } FormatToken *getNextToken() { if (GreaterStashed) { // Create a synthesized second '>' token. // FIXME: Increment Column and set OriginalColumn. Token Greater = FormatTok->Tok; FormatTok = new (Allocator.Allocate()) FormatToken; FormatTok->Tok = Greater; SourceLocation GreaterLocation = FormatTok->Tok.getLocation().getLocWithOffset(1); FormatTok->WhitespaceRange = SourceRange(GreaterLocation, GreaterLocation); FormatTok->TokenText = ">"; FormatTok->ColumnWidth = 1; GreaterStashed = false; return FormatTok; } 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. unsigned WhitespaceLength = TrailingWhitespace; while (FormatTok->Tok.is(tok::unknown)) { for (int i = 0, e = FormatTok->TokenText.size(); i != e; ++i) { switch (FormatTok->TokenText[i]) { case '\n': ++FormatTok->NewlinesBefore; // FIXME: This is technically incorrect, as it could also // be a literal backslash at the end of the line. if (i == 0 || (FormatTok->TokenText[i - 1] != '\\' && (FormatTok->TokenText[i - 1] != '\r' || i == 1 || FormatTok->TokenText[i - 2] != '\\'))) FormatTok->HasUnescapedNewline = true; FormatTok->LastNewlineOffset = WhitespaceLength + i + 1; Column = 0; break; case '\r': case '\f': case '\v': Column = 0; break; case ' ': ++Column; break; case '\t': Column += Style.TabWidth - Column % Style.TabWidth; break; case '\\': ++Column; if (i + 1 == e || (FormatTok->TokenText[i + 1] != '\r' && FormatTok->TokenText[i + 1] != '\n')) FormatTok->Type = TT_ImplicitStringLiteral; break; default: FormatTok->Type = TT_ImplicitStringLiteral; ++Column; break; } } if (FormatTok->Type == TT_ImplicitStringLiteral) break; WhitespaceLength += FormatTok->Tok.getLength(); readRawToken(*FormatTok); } // In case the token starts with escaped newlines, we want to // take them into account as whitespace - this pattern is quite frequent // in macro definitions. // FIXME: Add a more explicit test. while (FormatTok->TokenText.size() > 1 && FormatTok->TokenText[0] == '\\' && FormatTok->TokenText[1] == '\n') { ++FormatTok->NewlinesBefore; WhitespaceLength += 2; Column = 0; FormatTok->TokenText = FormatTok->TokenText.substr(2); } FormatTok->WhitespaceRange = SourceRange( WhitespaceStart, WhitespaceStart.getLocWithOffset(WhitespaceLength)); FormatTok->OriginalColumn = Column; TrailingWhitespace = 0; if (FormatTok->Tok.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->Tok.is(tok::raw_identifier)) { IdentifierInfo &Info = IdentTable.get(FormatTok->TokenText); FormatTok->Tok.setIdentifierInfo(&Info); FormatTok->Tok.setKind(Info.getTokenID()); } else if (FormatTok->Tok.is(tok::greatergreater)) { FormatTok->Tok.setKind(tok::greater); FormatTok->TokenText = FormatTok->TokenText.substr(0, 1); GreaterStashed = true; } // 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; } FormatTok->IsForEachMacro = std::binary_search(ForEachMacros.begin(), ForEachMacros.end(), FormatTok->Tok.getIdentifierInfo()); return FormatTok; } FormatToken *FormatTok; bool IsFirstToken; bool GreaterStashed; unsigned Column; unsigned TrailingWhitespace; Lexer &Lex; SourceManager &SourceMgr; FormatStyle &Style; IdentifierTable IdentTable; encoding::Encoding Encoding; llvm::SpecificBumpPtrAllocator Allocator; // Index (in 'Tokens') of the last token that starts a new line. unsigned FirstInLineIndex; SmallVector Tokens; SmallVector ForEachMacros; void readRawToken(FormatToken &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.Language == FormatStyle::LK_JavaScript && Tok.TokenText == "''") { Tok.Tok.setKind(tok::char_constant); } } } }; static StringRef getLanguageName(FormatStyle::LanguageKind Language) { switch (Language) { case FormatStyle::LK_Cpp: return "C++"; case FormatStyle::LK_JavaScript: return "JavaScript"; case FormatStyle::LK_Proto: return "Proto"; default: return "Unknown"; } } class Formatter : public UnwrappedLineConsumer { public: Formatter(const FormatStyle &Style, Lexer &Lex, SourceManager &SourceMgr, const std::vector &Ranges) : Style(Style), Lex(Lex), SourceMgr(SourceMgr), Whitespaces(SourceMgr, Style, inputUsesCRLF(Lex.getBuffer())), Ranges(Ranges.begin(), Ranges.end()), UnwrappedLines(1), Encoding(encoding::detectEncoding(Lex.getBuffer())) { DEBUG(llvm::dbgs() << "File encoding: " << (Encoding == encoding::Encoding_UTF8 ? "UTF8" : "unknown") << "\n"); DEBUG(llvm::dbgs() << "Language: " << getLanguageName(Style.Language) << "\n"); } tooling::Replacements format() { tooling::Replacements Result; FormatTokenLexer Tokens(Lex, SourceMgr, Style, Encoding); UnwrappedLineParser Parser(Style, Tokens.lex(), *this); bool StructuralError = Parser.parse(); assert(UnwrappedLines.rbegin()->empty()); for (unsigned Run = 0, RunE = UnwrappedLines.size(); Run + 1 != RunE; ++Run) { DEBUG(llvm::dbgs() << "Run " << Run << "...\n"); SmallVector AnnotatedLines; for (unsigned i = 0, e = UnwrappedLines[Run].size(); i != e; ++i) { AnnotatedLines.push_back(new AnnotatedLine(UnwrappedLines[Run][i])); } tooling::Replacements RunResult = format(AnnotatedLines, StructuralError, Tokens); DEBUG({ llvm::dbgs() << "Replacements for run " << Run << ":\n"; for (tooling::Replacements::iterator I = RunResult.begin(), E = RunResult.end(); I != E; ++I) { llvm::dbgs() << I->toString() << "\n"; } }); for (unsigned i = 0, e = AnnotatedLines.size(); i != e; ++i) { delete AnnotatedLines[i]; } Result.insert(RunResult.begin(), RunResult.end()); Whitespaces.reset(); } return Result; } tooling::Replacements format(SmallVectorImpl &AnnotatedLines, bool StructuralError, FormatTokenLexer &Tokens) { TokenAnnotator Annotator(Style, Tokens.getIdentTable().get("in")); for (unsigned i = 0, e = AnnotatedLines.size(); i != e; ++i) { Annotator.annotate(*AnnotatedLines[i]); } deriveLocalStyle(AnnotatedLines); for (unsigned i = 0, e = AnnotatedLines.size(); i != e; ++i) { Annotator.calculateFormattingInformation(*AnnotatedLines[i]); } computeAffectedLines(AnnotatedLines.begin(), AnnotatedLines.end()); Annotator.setCommentLineLevels(AnnotatedLines); ContinuationIndenter Indenter(Style, SourceMgr, Whitespaces, Encoding, BinPackInconclusiveFunctions); UnwrappedLineFormatter Formatter(&Indenter, &Whitespaces, Style); Formatter.format(AnnotatedLines, /*DryRun=*/false); return Whitespaces.generateReplacements(); } private: // Determines which lines are affected by the SourceRanges given as input. // Returns \c true if at least one line between I and E or one of their // children is affected. bool computeAffectedLines(SmallVectorImpl::iterator I, SmallVectorImpl::iterator E) { bool SomeLineAffected = false; const AnnotatedLine *PreviousLine = nullptr; while (I != E) { AnnotatedLine *Line = *I; Line->LeadingEmptyLinesAffected = affectsLeadingEmptyLines(*Line->First); // If a line is part of a preprocessor directive, it needs to be formatted // if any token within the directive is affected. if (Line->InPPDirective) { FormatToken *Last = Line->Last; SmallVectorImpl::iterator PPEnd = I + 1; while (PPEnd != E && !(*PPEnd)->First->HasUnescapedNewline) { Last = (*PPEnd)->Last; ++PPEnd; } if (affectsTokenRange(*Line->First, *Last, /*IncludeLeadingNewlines=*/false)) { SomeLineAffected = true; markAllAsAffected(I, PPEnd); } I = PPEnd; continue; } if (nonPPLineAffected(Line, PreviousLine)) SomeLineAffected = true; PreviousLine = Line; ++I; } return SomeLineAffected; } // Determines whether 'Line' is affected by the SourceRanges given as input. // Returns \c true if line or one if its children is affected. bool nonPPLineAffected(AnnotatedLine *Line, const AnnotatedLine *PreviousLine) { bool SomeLineAffected = false; Line->ChildrenAffected = computeAffectedLines(Line->Children.begin(), Line->Children.end()); if (Line->ChildrenAffected) SomeLineAffected = true; // Stores whether one of the line's tokens is directly affected. bool SomeTokenAffected = false; // Stores whether we need to look at the leading newlines of the next token // in order to determine whether it was affected. bool IncludeLeadingNewlines = false; // Stores whether the first child line of any of this line's tokens is // affected. bool SomeFirstChildAffected = false; for (FormatToken *Tok = Line->First; Tok; Tok = Tok->Next) { // Determine whether 'Tok' was affected. if (affectsTokenRange(*Tok, *Tok, IncludeLeadingNewlines)) SomeTokenAffected = true; // Determine whether the first child of 'Tok' was affected. if (!Tok->Children.empty() && Tok->Children.front()->Affected) SomeFirstChildAffected = true; IncludeLeadingNewlines = Tok->Children.empty(); } // Was this line moved, i.e. has it previously been on the same line as an // affected line? bool LineMoved = PreviousLine && PreviousLine->Affected && Line->First->NewlinesBefore == 0; bool IsContinuedComment = Line->First->is(tok::comment) && Line->First->Next == nullptr && Line->First->NewlinesBefore < 2 && PreviousLine && PreviousLine->Affected && PreviousLine->Last->is(tok::comment); if (SomeTokenAffected || SomeFirstChildAffected || LineMoved || IsContinuedComment) { Line->Affected = true; SomeLineAffected = true; } return SomeLineAffected; } // Marks all lines between I and E as well as all their children as affected. void markAllAsAffected(SmallVectorImpl::iterator I, SmallVectorImpl::iterator E) { while (I != E) { (*I)->Affected = true; markAllAsAffected((*I)->Children.begin(), (*I)->Children.end()); ++I; } } // Returns true if the range from 'First' to 'Last' intersects with one of the // input ranges. bool affectsTokenRange(const FormatToken &First, const FormatToken &Last, bool IncludeLeadingNewlines) { SourceLocation Start = First.WhitespaceRange.getBegin(); if (!IncludeLeadingNewlines) Start = Start.getLocWithOffset(First.LastNewlineOffset); SourceLocation End = Last.getStartOfNonWhitespace(); if (Last.TokenText.size() > 0) End = End.getLocWithOffset(Last.TokenText.size() - 1); CharSourceRange Range = CharSourceRange::getCharRange(Start, End); return affectsCharSourceRange(Range); } // Returns true if one of the input ranges intersect the leading empty lines // before 'Tok'. bool affectsLeadingEmptyLines(const FormatToken &Tok) { CharSourceRange EmptyLineRange = CharSourceRange::getCharRange( Tok.WhitespaceRange.getBegin(), Tok.WhitespaceRange.getBegin().getLocWithOffset(Tok.LastNewlineOffset)); return affectsCharSourceRange(EmptyLineRange); } // Returns true if 'Range' intersects with one of the input ranges. bool affectsCharSourceRange(const CharSourceRange &Range) { for (SmallVectorImpl::const_iterator I = Ranges.begin(), E = Ranges.end(); I != E; ++I) { if (!SourceMgr.isBeforeInTranslationUnit(Range.getEnd(), I->getBegin()) && !SourceMgr.isBeforeInTranslationUnit(I->getEnd(), Range.getBegin())) return true; } return false; } static bool inputUsesCRLF(StringRef Text) { return Text.count('\r') * 2 > Text.count('\n'); } void deriveLocalStyle(const SmallVectorImpl &AnnotatedLines) { unsigned CountBoundToVariable = 0; unsigned CountBoundToType = 0; bool HasCpp03IncompatibleFormat = false; bool HasBinPackedFunction = false; bool HasOnePerLineFunction = false; for (unsigned i = 0, e = AnnotatedLines.size(); i != e; ++i) { if (!AnnotatedLines[i]->First->Next) continue; FormatToken *Tok = AnnotatedLines[i]->First->Next; while (Tok->Next) { if (Tok->Type == TT_PointerOrReference) { bool SpacesBefore = Tok->WhitespaceRange.getBegin() != Tok->WhitespaceRange.getEnd(); bool SpacesAfter = Tok->Next->WhitespaceRange.getBegin() != Tok->Next->WhitespaceRange.getEnd(); if (SpacesBefore && !SpacesAfter) ++CountBoundToVariable; else if (!SpacesBefore && SpacesAfter) ++CountBoundToType; } if (Tok->WhitespaceRange.getBegin() == Tok->WhitespaceRange.getEnd()) { if (Tok->is(tok::coloncolon) && Tok->Previous->Type == TT_TemplateOpener) HasCpp03IncompatibleFormat = true; if (Tok->Type == TT_TemplateCloser && Tok->Previous->Type == TT_TemplateCloser) HasCpp03IncompatibleFormat = true; } if (Tok->PackingKind == PPK_BinPacked) HasBinPackedFunction = true; if (Tok->PackingKind == PPK_OnePerLine) HasOnePerLineFunction = true; Tok = Tok->Next; } } if (Style.DerivePointerAlignment) { if (CountBoundToType > CountBoundToVariable) Style.PointerAlignment = FormatStyle::PAS_Left; else if (CountBoundToType < CountBoundToVariable) Style.PointerAlignment = FormatStyle::PAS_Right; } if (Style.Standard == FormatStyle::LS_Auto) { Style.Standard = HasCpp03IncompatibleFormat ? FormatStyle::LS_Cpp11 : FormatStyle::LS_Cpp03; } BinPackInconclusiveFunctions = HasBinPackedFunction || !HasOnePerLineFunction; } void consumeUnwrappedLine(const UnwrappedLine &TheLine) override { assert(!UnwrappedLines.empty()); UnwrappedLines.back().push_back(TheLine); } void finishRun() override { UnwrappedLines.push_back(SmallVector()); } FormatStyle Style; Lexer &Lex; SourceManager &SourceMgr; WhitespaceManager Whitespaces; SmallVector Ranges; SmallVector, 2> UnwrappedLines; encoding::Encoding Encoding; bool BinPackInconclusiveFunctions; }; } // end anonymous namespace tooling::Replacements reformat(const FormatStyle &Style, Lexer &Lex, SourceManager &SourceMgr, std::vector Ranges) { if (Style.DisableFormat) { tooling::Replacements EmptyResult; return EmptyResult; } Formatter formatter(Style, Lex, SourceMgr, Ranges); return formatter.format(); } tooling::Replacements reformat(const FormatStyle &Style, StringRef Code, std::vector Ranges, StringRef FileName) { FileManager Files((FileSystemOptions())); DiagnosticsEngine Diagnostics( IntrusiveRefCntPtr(new DiagnosticIDs), new DiagnosticOptions); SourceManager SourceMgr(Diagnostics, Files); llvm::MemoryBuffer *Buf = llvm::MemoryBuffer::getMemBuffer(Code, FileName); const clang::FileEntry *Entry = Files.getVirtualFile(FileName, Buf->getBufferSize(), 0); SourceMgr.overrideFileContents(Entry, Buf); FileID ID = SourceMgr.createFileID(Entry, SourceLocation(), clang::SrcMgr::C_User); Lexer Lex(ID, SourceMgr.getBuffer(ID), SourceMgr, getFormattingLangOpts(Style.Standard)); SourceLocation StartOfFile = SourceMgr.getLocForStartOfFile(ID); std::vector CharRanges; for (unsigned i = 0, e = Ranges.size(); i != e; ++i) { SourceLocation Start = StartOfFile.getLocWithOffset(Ranges[i].getOffset()); SourceLocation End = Start.getLocWithOffset(Ranges[i].getLength()); CharRanges.push_back(CharSourceRange::getCharRange(Start, End)); } return reformat(Style, Lex, SourceMgr, CharRanges); } LangOptions getFormattingLangOpts(FormatStyle::LanguageStandard Standard) { LangOptions LangOpts; LangOpts.CPlusPlus = 1; LangOpts.CPlusPlus11 = Standard == FormatStyle::LS_Cpp03 ? 0 : 1; LangOpts.CPlusPlus1y = Standard == FormatStyle::LS_Cpp03 ? 0 : 1; LangOpts.LineComment = 1; LangOpts.CXXOperatorNames = 1; LangOpts.Bool = 1; LangOpts.ObjC1 = 1; LangOpts.ObjC2 = 1; return LangOpts; } const char *StyleOptionHelpDescription = "Coding style, currently supports:\n" " LLVM, Google, Chromium, Mozilla, WebKit.\n" "Use -style=file to load style configuration from\n" ".clang-format file located in one of the parent\n" "directories of the source file (or current\n" "directory for stdin).\n" "Use -style=\"{key: value, ...}\" to set specific\n" "parameters, e.g.:\n" " -style=\"{BasedOnStyle: llvm, IndentWidth: 8}\""; static FormatStyle::LanguageKind getLanguageByFileName(StringRef FileName) { if (FileName.endswith_lower(".js")) { return FormatStyle::LK_JavaScript; } else if (FileName.endswith_lower(".proto") || FileName.endswith_lower(".protodevel")) { return FormatStyle::LK_Proto; } return FormatStyle::LK_Cpp; } FormatStyle getStyle(StringRef StyleName, StringRef FileName, StringRef FallbackStyle) { FormatStyle Style = getLLVMStyle(); Style.Language = getLanguageByFileName(FileName); if (!getPredefinedStyle(FallbackStyle, Style.Language, &Style)) { llvm::errs() << "Invalid fallback style \"" << FallbackStyle << "\" using LLVM style\n"; return Style; } if (StyleName.startswith("{")) { // Parse YAML/JSON style from the command line. if (std::error_code ec = parseConfiguration(StyleName, &Style)) { llvm::errs() << "Error parsing -style: " << ec.message() << ", using " << FallbackStyle << " style\n"; } return Style; } if (!StyleName.equals_lower("file")) { if (!getPredefinedStyle(StyleName, Style.Language, &Style)) llvm::errs() << "Invalid value for -style, using " << FallbackStyle << " style\n"; return Style; } // Look for .clang-format/_clang-format file in the file's parent directories. SmallString<128> UnsuitableConfigFiles; SmallString<128> Path(FileName); llvm::sys::fs::make_absolute(Path); for (StringRef Directory = Path; !Directory.empty(); Directory = llvm::sys::path::parent_path(Directory)) { if (!llvm::sys::fs::is_directory(Directory)) continue; SmallString<128> ConfigFile(Directory); llvm::sys::path::append(ConfigFile, ".clang-format"); DEBUG(llvm::dbgs() << "Trying " << ConfigFile << "...\n"); bool IsFile = false; // Ignore errors from is_regular_file: we only need to know if we can read // the file or not. llvm::sys::fs::is_regular_file(Twine(ConfigFile), IsFile); if (!IsFile) { // Try _clang-format too, since dotfiles are not commonly used on Windows. ConfigFile = Directory; llvm::sys::path::append(ConfigFile, "_clang-format"); DEBUG(llvm::dbgs() << "Trying " << ConfigFile << "...\n"); llvm::sys::fs::is_regular_file(Twine(ConfigFile), IsFile); } if (IsFile) { llvm::ErrorOr> Text = llvm::MemoryBuffer::getFile(ConfigFile.c_str()); if (std::error_code EC = Text.getError()) { llvm::errs() << EC.message() << "\n"; break; } if (std::error_code ec = parseConfiguration(Text.get()->getBuffer(), &Style)) { if (ec == ParseError::Unsuitable) { if (!UnsuitableConfigFiles.empty()) UnsuitableConfigFiles.append(", "); UnsuitableConfigFiles.append(ConfigFile); continue; } llvm::errs() << "Error reading " << ConfigFile << ": " << ec.message() << "\n"; break; } DEBUG(llvm::dbgs() << "Using configuration file " << ConfigFile << "\n"); return Style; } } llvm::errs() << "Can't find usable .clang-format, using " << FallbackStyle << " style\n"; if (!UnsuitableConfigFiles.empty()) { llvm::errs() << "Configuration file(s) do(es) not support " << getLanguageName(Style.Language) << ": " << UnsuitableConfigFiles << "\n"; } return Style; } } // namespace format } // namespace clang