//===- CodeCompleteConsumer.cpp - Code Completion Interface ---------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This file implements the CodeCompleteConsumer class. // //===----------------------------------------------------------------------===// #include "clang/Sema/CodeCompleteConsumer.h" #include "clang-c/Index.h" #include "clang/AST/Decl.h" #include "clang/AST/DeclBase.h" #include "clang/AST/DeclObjC.h" #include "clang/AST/DeclTemplate.h" #include "clang/AST/DeclarationName.h" #include "clang/AST/Type.h" #include "clang/Basic/IdentifierTable.h" #include "clang/Lex/Preprocessor.h" #include "clang/Sema/Sema.h" #include "llvm/ADT/SmallString.h" #include "llvm/ADT/SmallVector.h" #include "llvm/ADT/StringExtras.h" #include "llvm/ADT/StringRef.h" #include "llvm/ADT/Twine.h" #include "llvm/Support/Casting.h" #include "llvm/Support/Compiler.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/FormatVariadic.h" #include "llvm/Support/raw_ostream.h" #include #include #include #include using namespace clang; //===----------------------------------------------------------------------===// // Code completion context implementation //===----------------------------------------------------------------------===// bool CodeCompletionContext::wantConstructorResults() const { switch (CCKind) { case CCC_Recovery: case CCC_Statement: case CCC_Expression: case CCC_ObjCMessageReceiver: case CCC_ParenthesizedExpression: case CCC_Symbol: case CCC_SymbolOrNewName: case CCC_TopLevelOrExpression: return true; case CCC_TopLevel: case CCC_ObjCInterface: case CCC_ObjCImplementation: case CCC_ObjCIvarList: case CCC_ClassStructUnion: case CCC_DotMemberAccess: case CCC_ArrowMemberAccess: case CCC_ObjCPropertyAccess: case CCC_EnumTag: case CCC_UnionTag: case CCC_ClassOrStructTag: case CCC_ObjCProtocolName: case CCC_Namespace: case CCC_Type: case CCC_NewName: case CCC_MacroName: case CCC_MacroNameUse: case CCC_PreprocessorExpression: case CCC_PreprocessorDirective: case CCC_NaturalLanguage: case CCC_SelectorName: case CCC_TypeQualifiers: case CCC_Other: case CCC_OtherWithMacros: case CCC_ObjCInstanceMessage: case CCC_ObjCClassMessage: case CCC_ObjCInterfaceName: case CCC_ObjCCategoryName: case CCC_IncludedFile: case CCC_Attribute: case CCC_ObjCClassForwardDecl: return false; } llvm_unreachable("Invalid CodeCompletionContext::Kind!"); } StringRef clang::getCompletionKindString(CodeCompletionContext::Kind Kind) { using CCKind = CodeCompletionContext::Kind; switch (Kind) { case CCKind::CCC_Other: return "Other"; case CCKind::CCC_OtherWithMacros: return "OtherWithMacros"; case CCKind::CCC_TopLevel: return "TopLevel"; case CCKind::CCC_ObjCInterface: return "ObjCInterface"; case CCKind::CCC_ObjCImplementation: return "ObjCImplementation"; case CCKind::CCC_ObjCIvarList: return "ObjCIvarList"; case CCKind::CCC_ClassStructUnion: return "ClassStructUnion"; case CCKind::CCC_Statement: return "Statement"; case CCKind::CCC_Expression: return "Expression"; case CCKind::CCC_ObjCMessageReceiver: return "ObjCMessageReceiver"; case CCKind::CCC_DotMemberAccess: return "DotMemberAccess"; case CCKind::CCC_ArrowMemberAccess: return "ArrowMemberAccess"; case CCKind::CCC_ObjCPropertyAccess: return "ObjCPropertyAccess"; case CCKind::CCC_EnumTag: return "EnumTag"; case CCKind::CCC_UnionTag: return "UnionTag"; case CCKind::CCC_ClassOrStructTag: return "ClassOrStructTag"; case CCKind::CCC_ObjCProtocolName: return "ObjCProtocolName"; case CCKind::CCC_Namespace: return "Namespace"; case CCKind::CCC_Type: return "Type"; case CCKind::CCC_NewName: return "NewName"; case CCKind::CCC_Symbol: return "Symbol"; case CCKind::CCC_SymbolOrNewName: return "SymbolOrNewName"; case CCKind::CCC_MacroName: return "MacroName"; case CCKind::CCC_MacroNameUse: return "MacroNameUse"; case CCKind::CCC_PreprocessorExpression: return "PreprocessorExpression"; case CCKind::CCC_PreprocessorDirective: return "PreprocessorDirective"; case CCKind::CCC_NaturalLanguage: return "NaturalLanguage"; case CCKind::CCC_SelectorName: return "SelectorName"; case CCKind::CCC_TypeQualifiers: return "TypeQualifiers"; case CCKind::CCC_ParenthesizedExpression: return "ParenthesizedExpression"; case CCKind::CCC_ObjCInstanceMessage: return "ObjCInstanceMessage"; case CCKind::CCC_ObjCClassMessage: return "ObjCClassMessage"; case CCKind::CCC_ObjCInterfaceName: return "ObjCInterfaceName"; case CCKind::CCC_ObjCCategoryName: return "ObjCCategoryName"; case CCKind::CCC_IncludedFile: return "IncludedFile"; case CCKind::CCC_Attribute: return "Attribute"; case CCKind::CCC_Recovery: return "Recovery"; case CCKind::CCC_ObjCClassForwardDecl: return "ObjCClassForwardDecl"; case CCKind::CCC_TopLevelOrExpression: return "ReplTopLevel"; } llvm_unreachable("Invalid CodeCompletionContext::Kind!"); } //===----------------------------------------------------------------------===// // Code completion string implementation //===----------------------------------------------------------------------===// CodeCompletionString::Chunk::Chunk(ChunkKind Kind, const char *Text) : Kind(Kind), Text("") { switch (Kind) { case CK_TypedText: case CK_Text: case CK_Placeholder: case CK_Informative: case CK_ResultType: case CK_CurrentParameter: this->Text = Text; break; case CK_Optional: llvm_unreachable("Optional strings cannot be created from text"); case CK_LeftParen: this->Text = "("; break; case CK_RightParen: this->Text = ")"; break; case CK_LeftBracket: this->Text = "["; break; case CK_RightBracket: this->Text = "]"; break; case CK_LeftBrace: this->Text = "{"; break; case CK_RightBrace: this->Text = "}"; break; case CK_LeftAngle: this->Text = "<"; break; case CK_RightAngle: this->Text = ">"; break; case CK_Comma: this->Text = ", "; break; case CK_Colon: this->Text = ":"; break; case CK_SemiColon: this->Text = ";"; break; case CK_Equal: this->Text = " = "; break; case CK_HorizontalSpace: this->Text = " "; break; case CK_VerticalSpace: this->Text = "\n"; break; } } CodeCompletionString::Chunk CodeCompletionString::Chunk::CreateText(const char *Text) { return Chunk(CK_Text, Text); } CodeCompletionString::Chunk CodeCompletionString::Chunk::CreateOptional(CodeCompletionString *Optional) { Chunk Result; Result.Kind = CK_Optional; Result.Optional = Optional; return Result; } CodeCompletionString::Chunk CodeCompletionString::Chunk::CreatePlaceholder(const char *Placeholder) { return Chunk(CK_Placeholder, Placeholder); } CodeCompletionString::Chunk CodeCompletionString::Chunk::CreateInformative(const char *Informative) { return Chunk(CK_Informative, Informative); } CodeCompletionString::Chunk CodeCompletionString::Chunk::CreateResultType(const char *ResultType) { return Chunk(CK_ResultType, ResultType); } CodeCompletionString::Chunk CodeCompletionString::Chunk::CreateCurrentParameter( const char *CurrentParameter) { return Chunk(CK_CurrentParameter, CurrentParameter); } CodeCompletionString::CodeCompletionString( const Chunk *Chunks, unsigned NumChunks, unsigned Priority, CXAvailabilityKind Availability, const char **Annotations, unsigned NumAnnotations, StringRef ParentName, const char *BriefComment) : NumChunks(NumChunks), NumAnnotations(NumAnnotations), Priority(Priority), Availability(Availability), ParentName(ParentName), BriefComment(BriefComment) { assert(NumChunks <= 0xffff); assert(NumAnnotations <= 0xffff); Chunk *StoredChunks = reinterpret_cast(this + 1); for (unsigned I = 0; I != NumChunks; ++I) StoredChunks[I] = Chunks[I]; const char **StoredAnnotations = reinterpret_cast(StoredChunks + NumChunks); for (unsigned I = 0; I != NumAnnotations; ++I) StoredAnnotations[I] = Annotations[I]; } unsigned CodeCompletionString::getAnnotationCount() const { return NumAnnotations; } const char *CodeCompletionString::getAnnotation(unsigned AnnotationNr) const { if (AnnotationNr < NumAnnotations) return reinterpret_cast(end())[AnnotationNr]; else return nullptr; } std::string CodeCompletionString::getAsString() const { std::string Result; llvm::raw_string_ostream OS(Result); for (const Chunk &C : *this) { switch (C.Kind) { case CK_Optional: OS << "{#" << C.Optional->getAsString() << "#}"; break; case CK_Placeholder: OS << "<#" << C.Text << "#>"; break; case CK_Informative: case CK_ResultType: OS << "[#" << C.Text << "#]"; break; case CK_CurrentParameter: OS << "<#" << C.Text << "#>"; break; default: OS << C.Text; break; } } return Result; } const char *CodeCompletionString::getTypedText() const { for (const Chunk &C : *this) if (C.Kind == CK_TypedText) return C.Text; return nullptr; } std::string CodeCompletionString::getAllTypedText() const { std::string Res; for (const Chunk &C : *this) if (C.Kind == CK_TypedText) Res += C.Text; return Res; } const char *CodeCompletionAllocator::CopyString(const Twine &String) { SmallString<128> Data; StringRef Ref = String.toStringRef(Data); // FIXME: It would be more efficient to teach Twine to tell us its size and // then add a routine there to fill in an allocated char* with the contents // of the string. char *Mem = (char *)Allocate(Ref.size() + 1, 1); std::copy(Ref.begin(), Ref.end(), Mem); Mem[Ref.size()] = 0; return Mem; } StringRef CodeCompletionTUInfo::getParentName(const DeclContext *DC) { if (!isa(DC)) return {}; // Check whether we've already cached the parent name. StringRef &CachedParentName = ParentNames[DC]; if (!CachedParentName.empty()) return CachedParentName; // If we already processed this DeclContext and assigned empty to it, the // data pointer will be non-null. if (CachedParentName.data() != nullptr) return {}; // Find the interesting names. SmallVector Contexts; while (DC && !DC->isFunctionOrMethod()) { if (const auto *ND = dyn_cast(DC)) { if (ND->getIdentifier()) Contexts.push_back(DC); } DC = DC->getParent(); } { SmallString<128> S; llvm::raw_svector_ostream OS(S); bool First = true; for (const DeclContext *CurDC : llvm::reverse(Contexts)) { if (First) First = false; else { OS << "::"; } if (const auto *CatImpl = dyn_cast(CurDC)) CurDC = CatImpl->getCategoryDecl(); if (const auto *Cat = dyn_cast(CurDC)) { const ObjCInterfaceDecl *Interface = Cat->getClassInterface(); if (!Interface) { // Assign an empty StringRef but with non-null data to distinguish // between empty because we didn't process the DeclContext yet. CachedParentName = StringRef((const char *)(uintptr_t)~0U, 0); return {}; } OS << Interface->getName() << '(' << Cat->getName() << ')'; } else { OS << cast(CurDC)->getName(); } } CachedParentName = AllocatorRef->CopyString(OS.str()); } return CachedParentName; } CodeCompletionString *CodeCompletionBuilder::TakeString() { void *Mem = getAllocator().Allocate( sizeof(CodeCompletionString) + sizeof(Chunk) * Chunks.size() + sizeof(const char *) * Annotations.size(), alignof(CodeCompletionString)); CodeCompletionString *Result = new (Mem) CodeCompletionString( Chunks.data(), Chunks.size(), Priority, Availability, Annotations.data(), Annotations.size(), ParentName, BriefComment); Chunks.clear(); return Result; } void CodeCompletionBuilder::AddTypedTextChunk(const char *Text) { Chunks.push_back(Chunk(CodeCompletionString::CK_TypedText, Text)); } void CodeCompletionBuilder::AddTextChunk(const char *Text) { Chunks.push_back(Chunk::CreateText(Text)); } void CodeCompletionBuilder::AddOptionalChunk(CodeCompletionString *Optional) { Chunks.push_back(Chunk::CreateOptional(Optional)); } void CodeCompletionBuilder::AddPlaceholderChunk(const char *Placeholder) { Chunks.push_back(Chunk::CreatePlaceholder(Placeholder)); } void CodeCompletionBuilder::AddInformativeChunk(const char *Text) { Chunks.push_back(Chunk::CreateInformative(Text)); } void CodeCompletionBuilder::AddResultTypeChunk(const char *ResultType) { Chunks.push_back(Chunk::CreateResultType(ResultType)); } void CodeCompletionBuilder::AddCurrentParameterChunk( const char *CurrentParameter) { Chunks.push_back(Chunk::CreateCurrentParameter(CurrentParameter)); } void CodeCompletionBuilder::AddChunk(CodeCompletionString::ChunkKind CK, const char *Text) { Chunks.push_back(Chunk(CK, Text)); } void CodeCompletionBuilder::addParentContext(const DeclContext *DC) { if (DC->isTranslationUnit()) return; if (DC->isFunctionOrMethod()) return; if (!isa(DC)) return; ParentName = getCodeCompletionTUInfo().getParentName(DC); } void CodeCompletionBuilder::addBriefComment(StringRef Comment) { BriefComment = Allocator.CopyString(Comment); } //===----------------------------------------------------------------------===// // Code completion overload candidate implementation //===----------------------------------------------------------------------===// FunctionDecl *CodeCompleteConsumer::OverloadCandidate::getFunction() const { if (getKind() == CK_Function) return Function; else if (getKind() == CK_FunctionTemplate) return FunctionTemplate->getTemplatedDecl(); else return nullptr; } const FunctionType * CodeCompleteConsumer::OverloadCandidate::getFunctionType() const { switch (Kind) { case CK_Function: return Function->getType()->getAs(); case CK_FunctionTemplate: return FunctionTemplate->getTemplatedDecl() ->getType() ->getAs(); case CK_FunctionType: return Type; case CK_FunctionProtoTypeLoc: return ProtoTypeLoc.getTypePtr(); case CK_Template: case CK_Aggregate: return nullptr; } llvm_unreachable("Invalid CandidateKind!"); } const FunctionProtoTypeLoc CodeCompleteConsumer::OverloadCandidate::getFunctionProtoTypeLoc() const { if (Kind == CK_FunctionProtoTypeLoc) return ProtoTypeLoc; return FunctionProtoTypeLoc(); } unsigned CodeCompleteConsumer::OverloadCandidate::getNumParams() const { if (Kind == CK_Template) return Template->getTemplateParameters()->size(); if (Kind == CK_Aggregate) { unsigned Count = std::distance(AggregateType->field_begin(), AggregateType->field_end()); if (const auto *CRD = dyn_cast(AggregateType)) Count += CRD->getNumBases(); return Count; } if (const auto *FT = getFunctionType()) if (const auto *FPT = dyn_cast(FT)) return FPT->getNumParams(); return 0; } QualType CodeCompleteConsumer::OverloadCandidate::getParamType(unsigned N) const { if (Kind == CK_Aggregate) { if (const auto *CRD = dyn_cast(AggregateType)) { if (N < CRD->getNumBases()) return std::next(CRD->bases_begin(), N)->getType(); N -= CRD->getNumBases(); } for (const auto *Field : AggregateType->fields()) if (N-- == 0) return Field->getType(); return QualType(); } if (Kind == CK_Template) { TemplateParameterList *TPL = getTemplate()->getTemplateParameters(); if (N < TPL->size()) if (const auto *D = dyn_cast(TPL->getParam(N))) return D->getType(); return QualType(); } if (const auto *FT = getFunctionType()) if (const auto *FPT = dyn_cast(FT)) if (N < FPT->getNumParams()) return FPT->getParamType(N); return QualType(); } const NamedDecl * CodeCompleteConsumer::OverloadCandidate::getParamDecl(unsigned N) const { if (Kind == CK_Aggregate) { if (const auto *CRD = dyn_cast(AggregateType)) { if (N < CRD->getNumBases()) return std::next(CRD->bases_begin(), N)->getType()->getAsTagDecl(); N -= CRD->getNumBases(); } for (const auto *Field : AggregateType->fields()) if (N-- == 0) return Field; return nullptr; } if (Kind == CK_Template) { TemplateParameterList *TPL = getTemplate()->getTemplateParameters(); if (N < TPL->size()) return TPL->getParam(N); return nullptr; } // Note that if we only have a FunctionProtoType, we don't have param decls. if (const auto *FD = getFunction()) { if (N < FD->param_size()) return FD->getParamDecl(N); } else if (Kind == CK_FunctionProtoTypeLoc) { if (N < ProtoTypeLoc.getNumParams()) { return ProtoTypeLoc.getParam(N); } } return nullptr; } //===----------------------------------------------------------------------===// // Code completion consumer implementation //===----------------------------------------------------------------------===// CodeCompleteConsumer::~CodeCompleteConsumer() = default; bool PrintingCodeCompleteConsumer::isResultFilteredOut( StringRef Filter, CodeCompletionResult Result) { switch (Result.Kind) { case CodeCompletionResult::RK_Declaration: return !( Result.Declaration->getIdentifier() && Result.Declaration->getIdentifier()->getName().starts_with(Filter)); case CodeCompletionResult::RK_Keyword: return !StringRef(Result.Keyword).starts_with(Filter); case CodeCompletionResult::RK_Macro: return !Result.Macro->getName().starts_with(Filter); case CodeCompletionResult::RK_Pattern: return !(Result.Pattern->getTypedText() && StringRef(Result.Pattern->getTypedText()).starts_with(Filter)); } llvm_unreachable("Unknown code completion result Kind."); } void PrintingCodeCompleteConsumer::ProcessCodeCompleteResults( Sema &SemaRef, CodeCompletionContext Context, CodeCompletionResult *Results, unsigned NumResults) { std::stable_sort(Results, Results + NumResults); if (!Context.getPreferredType().isNull()) OS << "PREFERRED-TYPE: " << Context.getPreferredType() << '\n'; StringRef Filter = SemaRef.getPreprocessor().getCodeCompletionFilter(); // Print the completions. for (unsigned I = 0; I != NumResults; ++I) { if (!Filter.empty() && isResultFilteredOut(Filter, Results[I])) continue; OS << "COMPLETION: "; switch (Results[I].Kind) { case CodeCompletionResult::RK_Declaration: OS << *Results[I].Declaration; { std::vector Tags; if (Results[I].Hidden) Tags.push_back("Hidden"); if (Results[I].InBaseClass) Tags.push_back("InBase"); if (Results[I].Availability == CXAvailabilityKind::CXAvailability_NotAccessible) Tags.push_back("Inaccessible"); if (!Tags.empty()) OS << " (" << llvm::join(Tags, ",") << ")"; } if (CodeCompletionString *CCS = Results[I].CreateCodeCompletionString( SemaRef, Context, getAllocator(), CCTUInfo, includeBriefComments())) { OS << " : " << CCS->getAsString(); if (const char *BriefComment = CCS->getBriefComment()) OS << " : " << BriefComment; } break; case CodeCompletionResult::RK_Keyword: OS << Results[I].Keyword; break; case CodeCompletionResult::RK_Macro: OS << Results[I].Macro->getName(); if (CodeCompletionString *CCS = Results[I].CreateCodeCompletionString( SemaRef, Context, getAllocator(), CCTUInfo, includeBriefComments())) { OS << " : " << CCS->getAsString(); } break; case CodeCompletionResult::RK_Pattern: OS << "Pattern : " << Results[I].Pattern->getAsString(); break; } for (const FixItHint &FixIt : Results[I].FixIts) { const SourceLocation BLoc = FixIt.RemoveRange.getBegin(); const SourceLocation ELoc = FixIt.RemoveRange.getEnd(); SourceManager &SM = SemaRef.SourceMgr; std::pair BInfo = SM.getDecomposedLoc(BLoc); std::pair EInfo = SM.getDecomposedLoc(ELoc); // Adjust for token ranges. if (FixIt.RemoveRange.isTokenRange()) EInfo.second += Lexer::MeasureTokenLength(ELoc, SM, SemaRef.LangOpts); OS << " (requires fix-it:" << " {" << SM.getLineNumber(BInfo.first, BInfo.second) << ':' << SM.getColumnNumber(BInfo.first, BInfo.second) << '-' << SM.getLineNumber(EInfo.first, EInfo.second) << ':' << SM.getColumnNumber(EInfo.first, EInfo.second) << "}" << " to \"" << FixIt.CodeToInsert << "\")"; } OS << '\n'; } } // This function is used solely to preserve the former presentation of overloads // by "clang -cc1 -code-completion-at", since CodeCompletionString::getAsString // needs to be improved for printing the newer and more detailed overload // chunks. static std::string getOverloadAsString(const CodeCompletionString &CCS) { std::string Result; llvm::raw_string_ostream OS(Result); for (auto &C : CCS) { switch (C.Kind) { case CodeCompletionString::CK_Informative: case CodeCompletionString::CK_ResultType: OS << "[#" << C.Text << "#]"; break; case CodeCompletionString::CK_CurrentParameter: OS << "<#" << C.Text << "#>"; break; // FIXME: We can also print optional parameters of an overload. case CodeCompletionString::CK_Optional: break; default: OS << C.Text; break; } } return Result; } void PrintingCodeCompleteConsumer::ProcessOverloadCandidates( Sema &SemaRef, unsigned CurrentArg, OverloadCandidate *Candidates, unsigned NumCandidates, SourceLocation OpenParLoc, bool Braced) { OS << "OPENING_PAREN_LOC: "; OpenParLoc.print(OS, SemaRef.getSourceManager()); OS << "\n"; for (unsigned I = 0; I != NumCandidates; ++I) { if (CodeCompletionString *CCS = Candidates[I].CreateSignatureString( CurrentArg, SemaRef, getAllocator(), CCTUInfo, includeBriefComments(), Braced)) { OS << "OVERLOAD: " << getOverloadAsString(*CCS) << "\n"; } } } /// Retrieve the effective availability of the given declaration. static AvailabilityResult getDeclAvailability(const Decl *D) { AvailabilityResult AR = D->getAvailability(); if (isa(D)) AR = std::max(AR, cast(D->getDeclContext())->getAvailability()); return AR; } void CodeCompletionResult::computeCursorKindAndAvailability(bool Accessible) { switch (Kind) { case RK_Pattern: if (!Declaration) { // Do nothing: Patterns can come with cursor kinds! break; } [[fallthrough]]; case RK_Declaration: { // Set the availability based on attributes. switch (getDeclAvailability(Declaration)) { case AR_Available: case AR_NotYetIntroduced: Availability = CXAvailability_Available; break; case AR_Deprecated: Availability = CXAvailability_Deprecated; break; case AR_Unavailable: Availability = CXAvailability_NotAvailable; break; } if (const auto *Function = dyn_cast(Declaration)) if (Function->isDeleted()) Availability = CXAvailability_NotAvailable; CursorKind = getCursorKindForDecl(Declaration); if (CursorKind == CXCursor_UnexposedDecl) { // FIXME: Forward declarations of Objective-C classes and protocols // are not directly exposed, but we want code completion to treat them // like a definition. if (isa(Declaration)) CursorKind = CXCursor_ObjCInterfaceDecl; else if (isa(Declaration)) CursorKind = CXCursor_ObjCProtocolDecl; else CursorKind = CXCursor_NotImplemented; } break; } case RK_Macro: case RK_Keyword: llvm_unreachable("Macro and keyword kinds are handled by the constructors"); } if (!Accessible) Availability = CXAvailability_NotAccessible; } /// Retrieve the name that should be used to order a result. /// /// If the name needs to be constructed as a string, that string will be /// saved into Saved and the returned StringRef will refer to it. StringRef CodeCompletionResult::getOrderedName(std::string &Saved) const { switch (Kind) { case RK_Keyword: return Keyword; case RK_Pattern: return Pattern->getTypedText(); case RK_Macro: return Macro->getName(); case RK_Declaration: // Handle declarations below. break; } DeclarationName Name = Declaration->getDeclName(); // If the name is a simple identifier (by far the common case), or a // zero-argument selector, just return a reference to that identifier. if (IdentifierInfo *Id = Name.getAsIdentifierInfo()) return Id->getName(); if (Name.isObjCZeroArgSelector()) if (const IdentifierInfo *Id = Name.getObjCSelector().getIdentifierInfoForSlot(0)) return Id->getName(); Saved = Name.getAsString(); return Saved; } bool clang::operator<(const CodeCompletionResult &X, const CodeCompletionResult &Y) { std::string XSaved, YSaved; StringRef XStr = X.getOrderedName(XSaved); StringRef YStr = Y.getOrderedName(YSaved); int cmp = XStr.compare_insensitive(YStr); if (cmp) return cmp < 0; // If case-insensitive comparison fails, try case-sensitive comparison. return XStr.compare(YStr) < 0; }