Mercurial > hg > CbC > CbC_llvm
view clang-tools-extra/clang-doc/Serialize.cpp @ 173:0572611fdcc8 llvm10 llvm12
reorgnization done
| author | Shinji KONO <kono@ie.u-ryukyu.ac.jp> |
|---|---|
| date | Mon, 25 May 2020 11:55:54 +0900 |
| parents | 1d019706d866 |
| children | c4bab56944e8 |
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//===-- Serialize.cpp - ClangDoc Serializer ---------------------*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #include "Serialize.h" #include "BitcodeWriter.h" #include "clang/AST/Comment.h" #include "clang/Index/USRGeneration.h" #include "llvm/ADT/Hashing.h" #include "llvm/ADT/StringExtras.h" #include "llvm/Support/SHA1.h" using clang::comments::FullComment; namespace clang { namespace doc { namespace serialize { SymbolID hashUSR(llvm::StringRef USR) { return llvm::SHA1::hash(arrayRefFromStringRef(USR)); } template <typename T> static void populateParentNamespaces(llvm::SmallVector<Reference, 4> &Namespaces, const T *D, bool &IsAnonymousNamespace); // A function to extract the appropriate relative path for a given info's // documentation. The path returned is a composite of the parent namespaces. // // Example: Given the below, the directory path for class C info will be // <root>/A/B // // namespace A { // namespace B { // // class C {}; // // } // } llvm::SmallString<128> getInfoRelativePath(const llvm::SmallVectorImpl<doc::Reference> &Namespaces) { llvm::SmallString<128> Path; for (auto R = Namespaces.rbegin(), E = Namespaces.rend(); R != E; ++R) llvm::sys::path::append(Path, R->Name); return Path; } llvm::SmallString<128> getInfoRelativePath(const Decl *D) { llvm::SmallVector<Reference, 4> Namespaces; // The third arg in populateParentNamespaces is a boolean passed by reference, // its value is not relevant in here so it's not used anywhere besides the // function call bool B = true; populateParentNamespaces(Namespaces, D, B); return getInfoRelativePath(Namespaces); } class ClangDocCommentVisitor : public ConstCommentVisitor<ClangDocCommentVisitor> { public: ClangDocCommentVisitor(CommentInfo &CI) : CurrentCI(CI) {} void parseComment(const comments::Comment *C); void visitTextComment(const TextComment *C); void visitInlineCommandComment(const InlineCommandComment *C); void visitHTMLStartTagComment(const HTMLStartTagComment *C); void visitHTMLEndTagComment(const HTMLEndTagComment *C); void visitBlockCommandComment(const BlockCommandComment *C); void visitParamCommandComment(const ParamCommandComment *C); void visitTParamCommandComment(const TParamCommandComment *C); void visitVerbatimBlockComment(const VerbatimBlockComment *C); void visitVerbatimBlockLineComment(const VerbatimBlockLineComment *C); void visitVerbatimLineComment(const VerbatimLineComment *C); private: std::string getCommandName(unsigned CommandID) const; bool isWhitespaceOnly(StringRef S) const; CommentInfo &CurrentCI; }; void ClangDocCommentVisitor::parseComment(const comments::Comment *C) { CurrentCI.Kind = C->getCommentKindName(); ConstCommentVisitor<ClangDocCommentVisitor>::visit(C); for (comments::Comment *Child : llvm::make_range(C->child_begin(), C->child_end())) { CurrentCI.Children.emplace_back(std::make_unique<CommentInfo>()); ClangDocCommentVisitor Visitor(*CurrentCI.Children.back()); Visitor.parseComment(Child); } } void ClangDocCommentVisitor::visitTextComment(const TextComment *C) { if (!isWhitespaceOnly(C->getText())) CurrentCI.Text = C->getText(); } void ClangDocCommentVisitor::visitInlineCommandComment( const InlineCommandComment *C) { CurrentCI.Name = getCommandName(C->getCommandID()); for (unsigned I = 0, E = C->getNumArgs(); I != E; ++I) CurrentCI.Args.push_back(C->getArgText(I)); } void ClangDocCommentVisitor::visitHTMLStartTagComment( const HTMLStartTagComment *C) { CurrentCI.Name = C->getTagName(); CurrentCI.SelfClosing = C->isSelfClosing(); for (unsigned I = 0, E = C->getNumAttrs(); I < E; ++I) { const HTMLStartTagComment::Attribute &Attr = C->getAttr(I); CurrentCI.AttrKeys.push_back(Attr.Name); CurrentCI.AttrValues.push_back(Attr.Value); } } void ClangDocCommentVisitor::visitHTMLEndTagComment( const HTMLEndTagComment *C) { CurrentCI.Name = C->getTagName(); CurrentCI.SelfClosing = true; } void ClangDocCommentVisitor::visitBlockCommandComment( const BlockCommandComment *C) { CurrentCI.Name = getCommandName(C->getCommandID()); for (unsigned I = 0, E = C->getNumArgs(); I < E; ++I) CurrentCI.Args.push_back(C->getArgText(I)); } void ClangDocCommentVisitor::visitParamCommandComment( const ParamCommandComment *C) { CurrentCI.Direction = ParamCommandComment::getDirectionAsString(C->getDirection()); CurrentCI.Explicit = C->isDirectionExplicit(); if (C->hasParamName()) CurrentCI.ParamName = C->getParamNameAsWritten(); } void ClangDocCommentVisitor::visitTParamCommandComment( const TParamCommandComment *C) { if (C->hasParamName()) CurrentCI.ParamName = C->getParamNameAsWritten(); } void ClangDocCommentVisitor::visitVerbatimBlockComment( const VerbatimBlockComment *C) { CurrentCI.Name = getCommandName(C->getCommandID()); CurrentCI.CloseName = C->getCloseName(); } void ClangDocCommentVisitor::visitVerbatimBlockLineComment( const VerbatimBlockLineComment *C) { if (!isWhitespaceOnly(C->getText())) CurrentCI.Text = C->getText(); } void ClangDocCommentVisitor::visitVerbatimLineComment( const VerbatimLineComment *C) { if (!isWhitespaceOnly(C->getText())) CurrentCI.Text = C->getText(); } bool ClangDocCommentVisitor::isWhitespaceOnly(llvm::StringRef S) const { return std::all_of(S.begin(), S.end(), isspace); } std::string ClangDocCommentVisitor::getCommandName(unsigned CommandID) const { const CommandInfo *Info = CommandTraits::getBuiltinCommandInfo(CommandID); if (Info) return Info->Name; // TODO: Add parsing for \file command. return "<not a builtin command>"; } // Serializing functions. template <typename T> static std::string serialize(T &I) { SmallString<2048> Buffer; llvm::BitstreamWriter Stream(Buffer); ClangDocBitcodeWriter Writer(Stream); Writer.emitBlock(I); return Buffer.str().str(); } std::string serialize(std::unique_ptr<Info> &I) { switch (I->IT) { case InfoType::IT_namespace: return serialize(*static_cast<NamespaceInfo *>(I.get())); case InfoType::IT_record: return serialize(*static_cast<RecordInfo *>(I.get())); case InfoType::IT_enum: return serialize(*static_cast<EnumInfo *>(I.get())); case InfoType::IT_function: return serialize(*static_cast<FunctionInfo *>(I.get())); default: return ""; } } static void parseFullComment(const FullComment *C, CommentInfo &CI) { ClangDocCommentVisitor Visitor(CI); Visitor.parseComment(C); } static SymbolID getUSRForDecl(const Decl *D) { llvm::SmallString<128> USR; if (index::generateUSRForDecl(D, USR)) return SymbolID(); return hashUSR(USR); } static RecordDecl *getDeclForType(const QualType &T) { if (const RecordDecl *D = T->getAsRecordDecl()) return D->getDefinition(); return nullptr; } static bool isPublic(const clang::AccessSpecifier AS, const clang::Linkage Link) { if (AS == clang::AccessSpecifier::AS_private) return false; else if ((Link == clang::Linkage::ModuleLinkage) || (Link == clang::Linkage::ExternalLinkage)) return true; return false; // otherwise, linkage is some form of internal linkage } static bool shouldSerializeInfo(bool PublicOnly, bool IsInAnonymousNamespace, const NamedDecl *D) { bool IsAnonymousNamespace = false; if (const auto *N = dyn_cast<NamespaceDecl>(D)) IsAnonymousNamespace = N->isAnonymousNamespace(); return !PublicOnly || (!IsInAnonymousNamespace && !IsAnonymousNamespace && isPublic(D->getAccessUnsafe(), D->getLinkageInternal())); } // There are two uses for this function. // 1) Getting the resulting mode of inheritance of a record. // Example: class A {}; class B : private A {}; class C : public B {}; // It's explicit that C is publicly inherited from C and B is privately // inherited from A. It's not explicit but C is also privately inherited from // A. This is the AS that this function calculates. FirstAS is the // inheritance mode of `class C : B` and SecondAS is the inheritance mode of // `class B : A`. // 2) Getting the inheritance mode of an inherited attribute / method. // Example : class A { public: int M; }; class B : private A {}; // Class B is inherited from class A, which has a public attribute. This // attribute is now part of the derived class B but it's not public. This // will be private because the inheritance is private. This is the AS that // this function calculates. FirstAS is the inheritance mode and SecondAS is // the AS of the attribute / method. static AccessSpecifier getFinalAccessSpecifier(AccessSpecifier FirstAS, AccessSpecifier SecondAS) { if (FirstAS == AccessSpecifier::AS_none || SecondAS == AccessSpecifier::AS_none) return AccessSpecifier::AS_none; if (FirstAS == AccessSpecifier::AS_private || SecondAS == AccessSpecifier::AS_private) return AccessSpecifier::AS_private; if (FirstAS == AccessSpecifier::AS_protected || SecondAS == AccessSpecifier::AS_protected) return AccessSpecifier::AS_protected; return AccessSpecifier::AS_public; } // The Access parameter is only provided when parsing the field of an inherited // record, the access specification of the field depends on the inheritance mode static void parseFields(RecordInfo &I, const RecordDecl *D, bool PublicOnly, AccessSpecifier Access = AccessSpecifier::AS_public) { for (const FieldDecl *F : D->fields()) { if (!shouldSerializeInfo(PublicOnly, /*IsInAnonymousNamespace=*/false, F)) continue; if (const auto *T = getDeclForType(F->getTypeSourceInfo()->getType())) { // Use getAccessUnsafe so that we just get the default AS_none if it's not // valid, as opposed to an assert. if (const auto *N = dyn_cast<EnumDecl>(T)) { I.Members.emplace_back( getUSRForDecl(T), N->getNameAsString(), InfoType::IT_enum, getInfoRelativePath(N), F->getNameAsString(), getFinalAccessSpecifier(Access, N->getAccessUnsafe())); continue; } else if (const auto *N = dyn_cast<RecordDecl>(T)) { I.Members.emplace_back( getUSRForDecl(T), N->getNameAsString(), InfoType::IT_record, getInfoRelativePath(N), F->getNameAsString(), getFinalAccessSpecifier(Access, N->getAccessUnsafe())); continue; } } I.Members.emplace_back( F->getTypeSourceInfo()->getType().getAsString(), F->getNameAsString(), getFinalAccessSpecifier(Access, F->getAccessUnsafe())); } } static void parseEnumerators(EnumInfo &I, const EnumDecl *D) { for (const EnumConstantDecl *E : D->enumerators()) I.Members.emplace_back(E->getNameAsString()); } static void parseParameters(FunctionInfo &I, const FunctionDecl *D) { for (const ParmVarDecl *P : D->parameters()) { if (const auto *T = getDeclForType(P->getOriginalType())) { if (const auto *N = dyn_cast<EnumDecl>(T)) { I.Params.emplace_back(getUSRForDecl(N), N->getNameAsString(), InfoType::IT_enum, getInfoRelativePath(N), P->getNameAsString()); continue; } else if (const auto *N = dyn_cast<RecordDecl>(T)) { I.Params.emplace_back(getUSRForDecl(N), N->getNameAsString(), InfoType::IT_record, getInfoRelativePath(N), P->getNameAsString()); continue; } } I.Params.emplace_back(P->getOriginalType().getAsString(), P->getNameAsString()); } } // TODO: Remove the serialization of Parents and VirtualParents, this // information is also extracted in the other definition of parseBases. static void parseBases(RecordInfo &I, const CXXRecordDecl *D) { // Don't parse bases if this isn't a definition. if (!D->isThisDeclarationADefinition()) return; for (const CXXBaseSpecifier &B : D->bases()) { if (B.isVirtual()) continue; if (const auto *Ty = B.getType()->getAs<TemplateSpecializationType>()) { const TemplateDecl *D = Ty->getTemplateName().getAsTemplateDecl(); I.Parents.emplace_back(getUSRForDecl(D), B.getType().getAsString(), InfoType::IT_record); } else if (const RecordDecl *P = getDeclForType(B.getType())) I.Parents.emplace_back(getUSRForDecl(P), P->getNameAsString(), InfoType::IT_record, getInfoRelativePath(P)); else I.Parents.emplace_back(B.getType().getAsString()); } for (const CXXBaseSpecifier &B : D->vbases()) { if (const auto *P = getDeclForType(B.getType())) I.VirtualParents.emplace_back(getUSRForDecl(P), P->getNameAsString(), InfoType::IT_record, getInfoRelativePath(P)); else I.VirtualParents.emplace_back(B.getType().getAsString()); } } template <typename T> static void populateParentNamespaces(llvm::SmallVector<Reference, 4> &Namespaces, const T *D, bool &IsInAnonymousNamespace) { const auto *DC = dyn_cast<DeclContext>(D); while ((DC = DC->getParent())) { if (const auto *N = dyn_cast<NamespaceDecl>(DC)) { std::string Namespace; if (N->isAnonymousNamespace()) { Namespace = "@nonymous_namespace"; IsInAnonymousNamespace = true; } else Namespace = N->getNameAsString(); Namespaces.emplace_back(getUSRForDecl(N), Namespace, InfoType::IT_namespace); } else if (const auto *N = dyn_cast<RecordDecl>(DC)) Namespaces.emplace_back(getUSRForDecl(N), N->getNameAsString(), InfoType::IT_record); else if (const auto *N = dyn_cast<FunctionDecl>(DC)) Namespaces.emplace_back(getUSRForDecl(N), N->getNameAsString(), InfoType::IT_function); else if (const auto *N = dyn_cast<EnumDecl>(DC)) Namespaces.emplace_back(getUSRForDecl(N), N->getNameAsString(), InfoType::IT_enum); } // The global namespace should be added to the list of namespaces if the decl // corresponds to a Record and if it doesn't have any namespace (because this // means it's in the global namespace). Also if its outermost namespace is a // record because that record matches the previous condition mentioned. if ((Namespaces.empty() && dyn_cast<RecordDecl>(D)) || (!Namespaces.empty() && Namespaces.back().RefType == InfoType::IT_record)) Namespaces.emplace_back(SymbolID(), "GlobalNamespace", InfoType::IT_namespace); } template <typename T> static void populateInfo(Info &I, const T *D, const FullComment *C, bool &IsInAnonymousNamespace) { I.USR = getUSRForDecl(D); I.Name = D->getNameAsString(); populateParentNamespaces(I.Namespace, D, IsInAnonymousNamespace); if (C) { I.Description.emplace_back(); parseFullComment(C, I.Description.back()); } } template <typename T> static void populateSymbolInfo(SymbolInfo &I, const T *D, const FullComment *C, int LineNumber, StringRef Filename, bool IsFileInRootDir, bool &IsInAnonymousNamespace) { populateInfo(I, D, C, IsInAnonymousNamespace); if (D->isThisDeclarationADefinition()) I.DefLoc.emplace(LineNumber, Filename, IsFileInRootDir); else I.Loc.emplace_back(LineNumber, Filename, IsFileInRootDir); } static void populateFunctionInfo(FunctionInfo &I, const FunctionDecl *D, const FullComment *FC, int LineNumber, StringRef Filename, bool IsFileInRootDir, bool &IsInAnonymousNamespace) { populateSymbolInfo(I, D, FC, LineNumber, Filename, IsFileInRootDir, IsInAnonymousNamespace); if (const auto *T = getDeclForType(D->getReturnType())) { if (dyn_cast<EnumDecl>(T)) I.ReturnType = TypeInfo(getUSRForDecl(T), T->getNameAsString(), InfoType::IT_enum, getInfoRelativePath(T)); else if (dyn_cast<RecordDecl>(T)) I.ReturnType = TypeInfo(getUSRForDecl(T), T->getNameAsString(), InfoType::IT_record, getInfoRelativePath(T)); } else { I.ReturnType = TypeInfo(D->getReturnType().getAsString()); } parseParameters(I, D); } static void parseBases(RecordInfo &I, const CXXRecordDecl *D, bool IsFileInRootDir, bool PublicOnly, bool IsParent, AccessSpecifier ParentAccess = AccessSpecifier::AS_public) { // Don't parse bases if this isn't a definition. if (!D->isThisDeclarationADefinition()) return; for (const CXXBaseSpecifier &B : D->bases()) { if (const RecordType *Ty = B.getType()->getAs<RecordType>()) { if (const CXXRecordDecl *Base = cast_or_null<CXXRecordDecl>(Ty->getDecl()->getDefinition())) { // Initialized without USR and name, this will be set in the following // if-else stmt. BaseRecordInfo BI( {}, "", getInfoRelativePath(Base), B.isVirtual(), getFinalAccessSpecifier(ParentAccess, B.getAccessSpecifier()), IsParent); if (const auto *Ty = B.getType()->getAs<TemplateSpecializationType>()) { const TemplateDecl *D = Ty->getTemplateName().getAsTemplateDecl(); BI.USR = getUSRForDecl(D); BI.Name = B.getType().getAsString(); } else { BI.USR = getUSRForDecl(Base); BI.Name = Base->getNameAsString(); } parseFields(BI, Base, PublicOnly, BI.Access); for (const auto &Decl : Base->decls()) if (const auto *MD = dyn_cast<CXXMethodDecl>(Decl)) { // Don't serialize private methods if (MD->getAccessUnsafe() == AccessSpecifier::AS_private || !MD->isUserProvided()) continue; FunctionInfo FI; FI.IsMethod = true; // The seventh arg in populateFunctionInfo is a boolean passed by // reference, its value is not relevant in here so it's not used // anywhere besides the function call. bool IsInAnonymousNamespace; populateFunctionInfo(FI, MD, /*FullComment=*/{}, /*LineNumber=*/{}, /*FileName=*/{}, IsFileInRootDir, IsInAnonymousNamespace); FI.Access = getFinalAccessSpecifier(BI.Access, MD->getAccessUnsafe()); BI.ChildFunctions.emplace_back(std::move(FI)); } I.Bases.emplace_back(std::move(BI)); // Call this function recursively to get the inherited classes of // this base; these new bases will also get stored in the original // RecordInfo: I. parseBases(I, Base, IsFileInRootDir, PublicOnly, false, I.Bases.back().Access); } } } } std::pair<std::unique_ptr<Info>, std::unique_ptr<Info>> emitInfo(const NamespaceDecl *D, const FullComment *FC, int LineNumber, llvm::StringRef File, bool IsFileInRootDir, bool PublicOnly) { auto I = std::make_unique<NamespaceInfo>(); bool IsInAnonymousNamespace = false; populateInfo(*I, D, FC, IsInAnonymousNamespace); if (!shouldSerializeInfo(PublicOnly, IsInAnonymousNamespace, D)) return {}; I->Name = D->isAnonymousNamespace() ? llvm::SmallString<16>("@nonymous_namespace") : I->Name; I->Path = getInfoRelativePath(I->Namespace); if (I->Namespace.empty() && I->USR == SymbolID()) return {std::unique_ptr<Info>{std::move(I)}, nullptr}; auto ParentI = std::make_unique<NamespaceInfo>(); ParentI->USR = I->Namespace.empty() ? SymbolID() : I->Namespace[0].USR; ParentI->ChildNamespaces.emplace_back(I->USR, I->Name, InfoType::IT_namespace, getInfoRelativePath(I->Namespace)); if (I->Namespace.empty()) ParentI->Path = getInfoRelativePath(ParentI->Namespace); return {std::unique_ptr<Info>{std::move(I)}, std::unique_ptr<Info>{std::move(ParentI)}}; } std::pair<std::unique_ptr<Info>, std::unique_ptr<Info>> emitInfo(const RecordDecl *D, const FullComment *FC, int LineNumber, llvm::StringRef File, bool IsFileInRootDir, bool PublicOnly) { auto I = std::make_unique<RecordInfo>(); bool IsInAnonymousNamespace = false; populateSymbolInfo(*I, D, FC, LineNumber, File, IsFileInRootDir, IsInAnonymousNamespace); if (!shouldSerializeInfo(PublicOnly, IsInAnonymousNamespace, D)) return {}; I->TagType = D->getTagKind(); parseFields(*I, D, PublicOnly); if (const auto *C = dyn_cast<CXXRecordDecl>(D)) { if (const TypedefNameDecl *TD = C->getTypedefNameForAnonDecl()) { I->Name = TD->getNameAsString(); I->IsTypeDef = true; } // TODO: remove first call to parseBases, that function should be deleted parseBases(*I, C); parseBases(*I, C, IsFileInRootDir, PublicOnly, true); } I->Path = getInfoRelativePath(I->Namespace); switch (I->Namespace[0].RefType) { case InfoType::IT_namespace: { auto ParentI = std::make_unique<NamespaceInfo>(); ParentI->USR = I->Namespace[0].USR; ParentI->ChildRecords.emplace_back(I->USR, I->Name, InfoType::IT_record, getInfoRelativePath(I->Namespace)); return {std::unique_ptr<Info>{std::move(I)}, std::unique_ptr<Info>{std::move(ParentI)}}; } case InfoType::IT_record: { auto ParentI = std::make_unique<RecordInfo>(); ParentI->USR = I->Namespace[0].USR; ParentI->ChildRecords.emplace_back(I->USR, I->Name, InfoType::IT_record, getInfoRelativePath(I->Namespace)); return {std::unique_ptr<Info>{std::move(I)}, std::unique_ptr<Info>{std::move(ParentI)}}; } default: llvm_unreachable("Invalid reference type for parent namespace"); } } std::pair<std::unique_ptr<Info>, std::unique_ptr<Info>> emitInfo(const FunctionDecl *D, const FullComment *FC, int LineNumber, llvm::StringRef File, bool IsFileInRootDir, bool PublicOnly) { FunctionInfo Func; bool IsInAnonymousNamespace = false; populateFunctionInfo(Func, D, FC, LineNumber, File, IsFileInRootDir, IsInAnonymousNamespace); Func.Access = clang::AccessSpecifier::AS_none; if (!shouldSerializeInfo(PublicOnly, IsInAnonymousNamespace, D)) return {}; // Wrap in enclosing scope auto ParentI = std::make_unique<NamespaceInfo>(); if (!Func.Namespace.empty()) ParentI->USR = Func.Namespace[0].USR; else ParentI->USR = SymbolID(); if (Func.Namespace.empty()) ParentI->Path = getInfoRelativePath(ParentI->Namespace); ParentI->ChildFunctions.emplace_back(std::move(Func)); // Info is wrapped in its parent scope so it's returned in the second position return {nullptr, std::unique_ptr<Info>{std::move(ParentI)}}; } std::pair<std::unique_ptr<Info>, std::unique_ptr<Info>> emitInfo(const CXXMethodDecl *D, const FullComment *FC, int LineNumber, llvm::StringRef File, bool IsFileInRootDir, bool PublicOnly) { FunctionInfo Func; bool IsInAnonymousNamespace = false; populateFunctionInfo(Func, D, FC, LineNumber, File, IsFileInRootDir, IsInAnonymousNamespace); if (!shouldSerializeInfo(PublicOnly, IsInAnonymousNamespace, D)) return {}; Func.IsMethod = true; const NamedDecl *Parent = nullptr; if (const auto *SD = dyn_cast<ClassTemplateSpecializationDecl>(D->getParent())) Parent = SD->getSpecializedTemplate(); else Parent = D->getParent(); SymbolID ParentUSR = getUSRForDecl(Parent); Func.Parent = Reference{ParentUSR, Parent->getNameAsString(), InfoType::IT_record}; Func.Access = D->getAccess(); // Wrap in enclosing scope auto ParentI = std::make_unique<RecordInfo>(); ParentI->USR = ParentUSR; ParentI->ChildFunctions.emplace_back(std::move(Func)); // Info is wrapped in its parent scope so it's returned in the second position return {nullptr, std::unique_ptr<Info>{std::move(ParentI)}}; } std::pair<std::unique_ptr<Info>, std::unique_ptr<Info>> emitInfo(const EnumDecl *D, const FullComment *FC, int LineNumber, llvm::StringRef File, bool IsFileInRootDir, bool PublicOnly) { EnumInfo Enum; bool IsInAnonymousNamespace = false; populateSymbolInfo(Enum, D, FC, LineNumber, File, IsFileInRootDir, IsInAnonymousNamespace); if (!shouldSerializeInfo(PublicOnly, IsInAnonymousNamespace, D)) return {}; Enum.Scoped = D->isScoped(); parseEnumerators(Enum, D); // Put in global namespace if (Enum.Namespace.empty()) { auto ParentI = std::make_unique<NamespaceInfo>(); ParentI->USR = SymbolID(); ParentI->ChildEnums.emplace_back(std::move(Enum)); ParentI->Path = getInfoRelativePath(ParentI->Namespace); // Info is wrapped in its parent scope so it's returned in the second // position return {nullptr, std::unique_ptr<Info>{std::move(ParentI)}}; } // Wrap in enclosing scope switch (Enum.Namespace[0].RefType) { case InfoType::IT_namespace: { auto ParentI = std::make_unique<NamespaceInfo>(); ParentI->USR = Enum.Namespace[0].USR; ParentI->ChildEnums.emplace_back(std::move(Enum)); // Info is wrapped in its parent scope so it's returned in the second // position return {nullptr, std::unique_ptr<Info>{std::move(ParentI)}}; } case InfoType::IT_record: { auto ParentI = std::make_unique<RecordInfo>(); ParentI->USR = Enum.Namespace[0].USR; ParentI->ChildEnums.emplace_back(std::move(Enum)); // Info is wrapped in its parent scope so it's returned in the second // position return {nullptr, std::unique_ptr<Info>{std::move(ParentI)}}; } default: llvm_unreachable("Invalid reference type for parent namespace"); } } } // namespace serialize } // namespace doc } // namespace clang