clangd/index/YAMLSerialization.cpp - clang-tools-extra - Git at Google

 //===-- YAMLSerialization.cpp ------------------------------------*- 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
 //
 //===----------------------------------------------------------------------===//
 //
 // A YAML index file is a sequence of tagged entries.
 // Each entry either encodes a Symbol or the list of references to a symbol
 // (a "ref bundle").
 //
 //===----------------------------------------------------------------------===//

 #include "Index.h"
 #include "Relation.h"
 #include "Serialization.h"
 #include "SymbolLocation.h"
 #include "SymbolOrigin.h"
 #include "Trace.h"
 #include "dex/Dex.h"
 #include "llvm/ADT/Optional.h"
 #include "llvm/ADT/SmallVector.h"
 #include "llvm/ADT/StringRef.h"
 #include "llvm/Support/Allocator.h"
 #include "llvm/Support/Errc.h"
 #include "llvm/Support/MemoryBuffer.h"
 #include "llvm/Support/StringSaver.h"
 #include "llvm/Support/YAMLTraits.h"
 #include "llvm/Support/raw_ostream.h"
 #include <cstdint>

 LLVM_YAML_IS_SEQUENCE_VECTOR(clang::clangd::Symbol::IncludeHeaderWithReferences)
 LLVM_YAML_IS_SEQUENCE_VECTOR(clang::clangd::Ref)

 namespace {
 using RefBundle =
     std::pair<clang::clangd::SymbolID, std::vector<clang::clangd::Ref>>;
 // This is a pale imitation of std::variant<Symbol, RefBundle, Relation>
 struct VariantEntry {
   llvm::Optional<clang::clangd::Symbol> Symbol;
   llvm::Optional<RefBundle> Refs;
   llvm::Optional<clang::clangd::Relation> Relation;
 };
 // A class helps YAML to serialize the 32-bit encoded position (Line&Column),
 // as YAMLIO can't directly map bitfields.
 struct YPosition {
   uint32_t Line;
   uint32_t Column;
 };

 } // namespace
 namespace llvm {
 namespace yaml {

 using clang::clangd::Ref;
 using clang::clangd::RefKind;
 using clang::clangd::Relation;
 using clang::clangd::RelationKind;
 using clang::clangd::Symbol;
 using clang::clangd::SymbolID;
 using clang::clangd::SymbolLocation;
 using clang::clangd::SymbolOrigin;
 using clang::index::SymbolInfo;
 using clang::index::SymbolKind;
 using clang::index::SymbolLanguage;
 using clang::index::SymbolRole;

 // Helper to (de)serialize the SymbolID. We serialize it as a hex string.
 struct NormalizedSymbolID {
   NormalizedSymbolID(IO &) {}
   NormalizedSymbolID(IO &, const SymbolID &ID) {
     llvm::raw_string_ostream OS(HexString);
     OS << ID;
   }

   SymbolID denormalize(IO &I) {
     auto ID = SymbolID::fromStr(HexString);
     if (!ID) {
       I.setError(llvm::toString(ID.takeError()));
       return SymbolID();
     }
     return *ID;
   }

   std::string HexString;
 };

 struct NormalizedSymbolFlag {
   NormalizedSymbolFlag(IO &) {}
   NormalizedSymbolFlag(IO &, Symbol::SymbolFlag F) {
     Flag = static_cast<uint8_t>(F);
   }

   Symbol::SymbolFlag denormalize(IO &) {
     return static_cast<Symbol::SymbolFlag>(Flag);
   }

   uint8_t Flag = 0;
 };

 struct NormalizedSymbolOrigin {
   NormalizedSymbolOrigin(IO &) {}
   NormalizedSymbolOrigin(IO &, SymbolOrigin O) {
     Origin = static_cast<uint8_t>(O);
   }

   SymbolOrigin denormalize(IO &) { return static_cast<SymbolOrigin>(Origin); }

   uint8_t Origin = 0;
 };

 template <> struct MappingTraits<YPosition> {
   static void mapping(IO &IO, YPosition &Value) {
     IO.mapRequired("Line", Value.Line);
     IO.mapRequired("Column", Value.Column);
   }
 };

 struct NormalizedPosition {
   using Position = clang::clangd::SymbolLocation::Position;
   NormalizedPosition(IO &) {}
   NormalizedPosition(IO &, const Position &Pos) {
     P.Line = Pos.line();
     P.Column = Pos.column();
   }

   Position denormalize(IO &) {
     Position Pos;
     Pos.setLine(P.Line);
     Pos.setColumn(P.Column);
     return Pos;
   }
   YPosition P;
 };

 struct NormalizedFileURI {
   NormalizedFileURI(IO &) {}
   NormalizedFileURI(IO &, const char *FileURI) { URI = FileURI; }

   const char *denormalize(IO &IO) {
     assert(IO.getContext() &&
            "Expecting an UniqueStringSaver to allocate data");
     return static_cast<llvm::UniqueStringSaver *>(IO.getContext())
         ->save(URI)
         .data();
   }

   std::string URI;
 };

 template <> struct MappingTraits<SymbolLocation> {
   static void mapping(IO &IO, SymbolLocation &Value) {
     MappingNormalization<NormalizedFileURI, const char *> NFile(IO,
                                                                 Value.FileURI);
     IO.mapRequired("FileURI", NFile->URI);
     MappingNormalization<NormalizedPosition, SymbolLocation::Position> NStart(
         IO, Value.Start);
     IO.mapRequired("Start", NStart->P);
     MappingNormalization<NormalizedPosition, SymbolLocation::Position> NEnd(
         IO, Value.End);
     IO.mapRequired("End", NEnd->P);
   }
 };

 template <> struct MappingTraits<SymbolInfo> {
   static void mapping(IO &io, SymbolInfo &SymInfo) {
     // FIXME: expose other fields?
     io.mapRequired("Kind", SymInfo.Kind);
     io.mapRequired("Lang", SymInfo.Lang);
   }
 };

 template <>
 struct MappingTraits<clang::clangd::Symbol::IncludeHeaderWithReferences> {
   static void mapping(IO &io,
                       clang::clangd::Symbol::IncludeHeaderWithReferences &Inc) {
     io.mapRequired("Header", Inc.IncludeHeader);
     io.mapRequired("References", Inc.References);
   }
 };

 template <> struct MappingTraits<Symbol> {
   static void mapping(IO &IO, Symbol &Sym) {
     MappingNormalization<NormalizedSymbolID, SymbolID> NSymbolID(IO, Sym.ID);
     MappingNormalization<NormalizedSymbolFlag, Symbol::SymbolFlag> NSymbolFlag(
         IO, Sym.Flags);
     MappingNormalization<NormalizedSymbolOrigin, SymbolOrigin> NSymbolOrigin(
         IO, Sym.Origin);
     IO.mapRequired("ID", NSymbolID->HexString);
     IO.mapRequired("Name", Sym.Name);
     IO.mapRequired("Scope", Sym.Scope);
     IO.mapRequired("SymInfo", Sym.SymInfo);
     IO.mapOptional("CanonicalDeclaration", Sym.CanonicalDeclaration,
                    SymbolLocation());
     IO.mapOptional("Definition", Sym.Definition, SymbolLocation());
     IO.mapOptional("References", Sym.References, 0u);
     IO.mapOptional("Origin", NSymbolOrigin->Origin);
     IO.mapOptional("Flags", NSymbolFlag->Flag);
     IO.mapOptional("Signature", Sym.Signature);
     IO.mapOptional("TemplateSpecializationArgs",
                    Sym.TemplateSpecializationArgs);
     IO.mapOptional("CompletionSnippetSuffix", Sym.CompletionSnippetSuffix);
     IO.mapOptional("Documentation", Sym.Documentation);
     IO.mapOptional("ReturnType", Sym.ReturnType);
     IO.mapOptional("Type", Sym.Type);
     IO.mapOptional("IncludeHeaders", Sym.IncludeHeaders);
   }
 };

 template <> struct ScalarEnumerationTraits<SymbolLanguage> {
   static void enumeration(IO &IO, SymbolLanguage &Value) {
     IO.enumCase(Value, "C", SymbolLanguage::C);
     IO.enumCase(Value, "Cpp", SymbolLanguage::CXX);
     IO.enumCase(Value, "ObjC", SymbolLanguage::ObjC);
     IO.enumCase(Value, "Swift", SymbolLanguage::Swift);
   }
 };

 template <> struct ScalarEnumerationTraits<SymbolKind> {
   static void enumeration(IO &IO, SymbolKind &Value) {
 #define DEFINE_ENUM(name) IO.enumCase(Value, #name, SymbolKind::name)

     DEFINE_ENUM(Unknown);
     DEFINE_ENUM(Function);
     DEFINE_ENUM(Module);
     DEFINE_ENUM(Namespace);
     DEFINE_ENUM(NamespaceAlias);
     DEFINE_ENUM(Macro);
     DEFINE_ENUM(Enum);
     DEFINE_ENUM(Struct);
     DEFINE_ENUM(Class);
     DEFINE_ENUM(Protocol);
     DEFINE_ENUM(Extension);
     DEFINE_ENUM(Union);
     DEFINE_ENUM(TypeAlias);
     DEFINE_ENUM(Function);
     DEFINE_ENUM(Variable);
     DEFINE_ENUM(Field);
     DEFINE_ENUM(EnumConstant);
     DEFINE_ENUM(InstanceMethod);
     DEFINE_ENUM(ClassMethod);
     DEFINE_ENUM(StaticMethod);
     DEFINE_ENUM(InstanceProperty);
     DEFINE_ENUM(ClassProperty);
     DEFINE_ENUM(StaticProperty);
     DEFINE_ENUM(Constructor);
     DEFINE_ENUM(Destructor);
     DEFINE_ENUM(ConversionFunction);
     DEFINE_ENUM(Parameter);
     DEFINE_ENUM(Using);

 #undef DEFINE_ENUM
   }
 };

 template <> struct MappingTraits<RefBundle> {
   static void mapping(IO &IO, RefBundle &Refs) {
     MappingNormalization<NormalizedSymbolID, SymbolID> NSymbolID(IO,
                                                                  Refs.first);
     IO.mapRequired("ID", NSymbolID->HexString);
     IO.mapRequired("References", Refs.second);
   }
 };

 struct NormalizedRefKind {
   NormalizedRefKind(IO &) {}
   NormalizedRefKind(IO &, RefKind O) { Kind = static_cast<uint8_t>(O); }

   RefKind denormalize(IO &) { return static_cast<RefKind>(Kind); }

   uint8_t Kind = 0;
 };

 template <> struct MappingTraits<Ref> {
   static void mapping(IO &IO, Ref &R) {
     MappingNormalization<NormalizedRefKind, RefKind> NKind(IO, R.Kind);
     IO.mapRequired("Kind", NKind->Kind);
     IO.mapRequired("Location", R.Location);
   }
 };

 struct NormalizedSymbolRole {
   NormalizedSymbolRole(IO &) {}
   NormalizedSymbolRole(IO &IO, SymbolRole R) {
     Kind = static_cast<uint8_t>(clang::clangd::symbolRoleToRelationKind(R));
   }

   SymbolRole denormalize(IO &IO) {
     return clang::clangd::relationKindToSymbolRole(
         static_cast<RelationKind>(Kind));
   }

   uint8_t Kind = 0;
 };

 template <> struct MappingTraits<SymbolID> {
   static void mapping(IO &IO, SymbolID &ID) {
     MappingNormalization<NormalizedSymbolID, SymbolID> NSymbolID(IO, ID);
     IO.mapRequired("ID", NSymbolID->HexString);
   }
 };

 template <> struct MappingTraits<Relation> {
   static void mapping(IO &IO, Relation &Relation) {
     MappingNormalization<NormalizedSymbolRole, SymbolRole> NRole(
         IO, Relation.Predicate);
     IO.mapRequired("Subject", Relation.Subject);
     IO.mapRequired("Predicate", NRole->Kind);
     IO.mapRequired("Object", Relation.Object);
   }
 };

 template <> struct MappingTraits<VariantEntry> {
   static void mapping(IO &IO, VariantEntry &Variant) {
     if (IO.mapTag("!Symbol", Variant.Symbol.hasValue())) {
       if (!IO.outputting())
         Variant.Symbol.emplace();
       MappingTraits<Symbol>::mapping(IO, *Variant.Symbol);
     } else if (IO.mapTag("!Refs", Variant.Refs.hasValue())) {
       if (!IO.outputting())
         Variant.Refs.emplace();
       MappingTraits<RefBundle>::mapping(IO, *Variant.Refs);
     } else if (IO.mapTag("!Relations", Variant.Relation.hasValue())) {
       if (!IO.outputting())
         Variant.Relation.emplace();
       MappingTraits<Relation>::mapping(IO, *Variant.Relation);
     }
   }
 };

 } // namespace yaml
 } // namespace llvm

 namespace clang {
 namespace clangd {

 void writeYAML(const IndexFileOut &O, llvm::raw_ostream &OS) {
   llvm::yaml::Output Yout(OS);
   for (const auto &Sym : *O.Symbols) {
     VariantEntry Entry;
     Entry.Symbol = Sym;
     Yout << Entry;
   }
   if (O.Refs)
     for (auto &Sym : *O.Refs) {
       VariantEntry Entry;
       Entry.Refs = Sym;
       Yout << Entry;
     }
   if (O.Relations)
     for (auto &R : *O.Relations) {
       VariantEntry Entry;
       Entry.Relation = R;
       Yout << Entry;
     }
 }

 llvm::Expected<IndexFileIn> readYAML(llvm::StringRef Data) {
   SymbolSlab::Builder Symbols;
   RefSlab::Builder Refs;
   RelationSlab::Builder Relations;
   llvm::BumpPtrAllocator
       Arena; // store the underlying data of Position::FileURI.
   llvm::UniqueStringSaver Strings(Arena);
   llvm::yaml::Input Yin(Data, &Strings);
   while (Yin.setCurrentDocument()) {
     llvm::yaml::EmptyContext Ctx;
     VariantEntry Variant;
     yamlize(Yin, Variant, true, Ctx);
     if (Yin.error())
       return llvm::errorCodeToError(Yin.error());

     if (Variant.Symbol)
       Symbols.insert(*Variant.Symbol);
     if (Variant.Refs)
       for (const auto &Ref : Variant.Refs->second)
         Refs.insert(Variant.Refs->first, Ref);
     if (Variant.Relation)
       Relations.insert(*Variant.Relation);
     Yin.nextDocument();
   }

   IndexFileIn Result;
   Result.Symbols.emplace(std::move(Symbols).build());
   Result.Refs.emplace(std::move(Refs).build());
   Result.Relations.emplace(std::move(Relations).build());
   return std::move(Result);
 }

 std::string toYAML(const Symbol &S) {
   std::string Buf;
   {
     llvm::raw_string_ostream OS(Buf);
     llvm::yaml::Output Yout(OS);
     Symbol Sym = S; // copy: Yout<< requires mutability.
     Yout << Sym;
   }
   return Buf;
 }

 std::string toYAML(const std::pair<SymbolID, llvm::ArrayRef<Ref>> &Data) {
   RefBundle Refs = {Data.first, Data.second};
   std::string Buf;
   {
     llvm::raw_string_ostream OS(Buf);
     llvm::yaml::Output Yout(OS);
     Yout << Refs;
   }
   return Buf;
 }

 std::string toYAML(const Relation &R) {
   std::string Buf;
   {
     llvm::raw_string_ostream OS(Buf);
     llvm::yaml::Output Yout(OS);
     Relation Rel = R; // copy: Yout<< requires mutability.
     Yout << Rel;
   }
   return Buf;
 }

 } // namespace clangd
 } // namespace clang
	//===-- YAMLSerialization.cpp ------------------------------------- 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
	//
	//===----------------------------------------------------------------------===//
	//
	// A YAML index file is a sequence of tagged entries.
	// Each entry either encodes a Symbol or the list of references to a symbol
	// (a "ref bundle").
	//
	//===----------------------------------------------------------------------===//

	#include "Index.h"
	#include "Relation.h"
	#include "Serialization.h"
	#include "SymbolLocation.h"
	#include "SymbolOrigin.h"
	#include "Trace.h"
	#include "dex/Dex.h"
	#include "llvm/ADT/Optional.h"
	#include "llvm/ADT/SmallVector.h"
	#include "llvm/ADT/StringRef.h"
	#include "llvm/Support/Allocator.h"
	#include "llvm/Support/Errc.h"
	#include "llvm/Support/MemoryBuffer.h"
	#include "llvm/Support/StringSaver.h"
	#include "llvm/Support/YAMLTraits.h"
	#include "llvm/Support/raw_ostream.h"
	#include <cstdint>

	LLVM_YAML_IS_SEQUENCE_VECTOR(clang::clangd::Symbol::IncludeHeaderWithReferences)
	LLVM_YAML_IS_SEQUENCE_VECTOR(clang::clangd::Ref)

	namespace {
	using RefBundle =
	std::pair<clang::clangd::SymbolID, std::vector<clang::clangd::Ref>>;
	// This is a pale imitation of std::variant<Symbol, RefBundle, Relation>
	struct VariantEntry {
	llvm::Optional<clang::clangd::Symbol> Symbol;
	llvm::Optional<RefBundle> Refs;
	llvm::Optional<clang::clangd::Relation> Relation;
	};
	// A class helps YAML to serialize the 32-bit encoded position (Line&Column),
	// as YAMLIO can't directly map bitfields.
	struct YPosition {
	uint32_t Line;
	uint32_t Column;
	};

	} // namespace
	namespace llvm {
	namespace yaml {

	using clang::clangd::Ref;
	using clang::clangd::RefKind;
	using clang::clangd::Relation;
	using clang::clangd::RelationKind;
	using clang::clangd::Symbol;
	using clang::clangd::SymbolID;
	using clang::clangd::SymbolLocation;
	using clang::clangd::SymbolOrigin;
	using clang::index::SymbolInfo;
	using clang::index::SymbolKind;
	using clang::index::SymbolLanguage;
	using clang::index::SymbolRole;

	// Helper to (de)serialize the SymbolID. We serialize it as a hex string.
	struct NormalizedSymbolID {
	NormalizedSymbolID(IO &) {}
	NormalizedSymbolID(IO &, const SymbolID &ID) {
	llvm::raw_string_ostream OS(HexString);
	OS << ID;
	}

	SymbolID denormalize(IO &I) {
	auto ID = SymbolID::fromStr(HexString);
	if (!ID) {
	I.setError(llvm::toString(ID.takeError()));
	return SymbolID();
	}
	return *ID;
	}

	std::string HexString;
	};

	struct NormalizedSymbolFlag {
	NormalizedSymbolFlag(IO &) {}
	NormalizedSymbolFlag(IO &, Symbol::SymbolFlag F) {
	Flag = static_cast<uint8_t>(F);
	}

	Symbol::SymbolFlag denormalize(IO &) {
	return static_cast<Symbol::SymbolFlag>(Flag);
	}

	uint8_t Flag = 0;
	};

	struct NormalizedSymbolOrigin {
	NormalizedSymbolOrigin(IO &) {}
	NormalizedSymbolOrigin(IO &, SymbolOrigin O) {
	Origin = static_cast<uint8_t>(O);
	}

	SymbolOrigin denormalize(IO &) { return static_cast<SymbolOrigin>(Origin); }

	uint8_t Origin = 0;
	};

	template <> struct MappingTraits<YPosition> {
	static void mapping(IO &IO, YPosition &Value) {
	IO.mapRequired("Line", Value.Line);
	IO.mapRequired("Column", Value.Column);
	}
	};

	struct NormalizedPosition {
	using Position = clang::clangd::SymbolLocation::Position;
	NormalizedPosition(IO &) {}
	NormalizedPosition(IO &, const Position &Pos) {
	P.Line = Pos.line();
	P.Column = Pos.column();
	}

	Position denormalize(IO &) {
	Position Pos;
	Pos.setLine(P.Line);
	Pos.setColumn(P.Column);
	return Pos;
	}
	YPosition P;
	};

	struct NormalizedFileURI {
	NormalizedFileURI(IO &) {}
	NormalizedFileURI(IO &, const char *FileURI) { URI = FileURI; }

	const char *denormalize(IO &IO) {
	assert(IO.getContext() &&
	"Expecting an UniqueStringSaver to allocate data");
	return static_cast<llvm::UniqueStringSaver *>(IO.getContext())
	->save(URI)
	.data();
	}

	std::string URI;
	};

	template <> struct MappingTraits<SymbolLocation> {
	static void mapping(IO &IO, SymbolLocation &Value) {
	MappingNormalization<NormalizedFileURI, const char *> NFile(IO,
	Value.FileURI);
	IO.mapRequired("FileURI", NFile->URI);
	MappingNormalization<NormalizedPosition, SymbolLocation::Position> NStart(
	IO, Value.Start);
	IO.mapRequired("Start", NStart->P);
	MappingNormalization<NormalizedPosition, SymbolLocation::Position> NEnd(
	IO, Value.End);
	IO.mapRequired("End", NEnd->P);
	}
	};

	template <> struct MappingTraits<SymbolInfo> {
	static void mapping(IO &io, SymbolInfo &SymInfo) {
	// FIXME: expose other fields?
	io.mapRequired("Kind", SymInfo.Kind);
	io.mapRequired("Lang", SymInfo.Lang);
	}
	};

	template <>
	struct MappingTraits<clang::clangd::Symbol::IncludeHeaderWithReferences> {
	static void mapping(IO &io,
	clang::clangd::Symbol::IncludeHeaderWithReferences &Inc) {
	io.mapRequired("Header", Inc.IncludeHeader);
	io.mapRequired("References", Inc.References);
	}
	};

	template <> struct MappingTraits<Symbol> {
	static void mapping(IO &IO, Symbol &Sym) {
	MappingNormalization<NormalizedSymbolID, SymbolID> NSymbolID(IO, Sym.ID);
	MappingNormalization<NormalizedSymbolFlag, Symbol::SymbolFlag> NSymbolFlag(
	IO, Sym.Flags);
	MappingNormalization<NormalizedSymbolOrigin, SymbolOrigin> NSymbolOrigin(
	IO, Sym.Origin);
	IO.mapRequired("ID", NSymbolID->HexString);
	IO.mapRequired("Name", Sym.Name);
	IO.mapRequired("Scope", Sym.Scope);
	IO.mapRequired("SymInfo", Sym.SymInfo);
	IO.mapOptional("CanonicalDeclaration", Sym.CanonicalDeclaration,
	SymbolLocation());
	IO.mapOptional("Definition", Sym.Definition, SymbolLocation());
	IO.mapOptional("References", Sym.References, 0u);
	IO.mapOptional("Origin", NSymbolOrigin->Origin);
	IO.mapOptional("Flags", NSymbolFlag->Flag);
	IO.mapOptional("Signature", Sym.Signature);
	IO.mapOptional("TemplateSpecializationArgs",
	Sym.TemplateSpecializationArgs);
	IO.mapOptional("CompletionSnippetSuffix", Sym.CompletionSnippetSuffix);
	IO.mapOptional("Documentation", Sym.Documentation);
	IO.mapOptional("ReturnType", Sym.ReturnType);
	IO.mapOptional("Type", Sym.Type);
	IO.mapOptional("IncludeHeaders", Sym.IncludeHeaders);
	}
	};

	template <> struct ScalarEnumerationTraits<SymbolLanguage> {
	static void enumeration(IO &IO, SymbolLanguage &Value) {
	IO.enumCase(Value, "C", SymbolLanguage::C);
	IO.enumCase(Value, "Cpp", SymbolLanguage::CXX);
	IO.enumCase(Value, "ObjC", SymbolLanguage::ObjC);
	IO.enumCase(Value, "Swift", SymbolLanguage::Swift);
	}
	};

	template <> struct ScalarEnumerationTraits<SymbolKind> {
	static void enumeration(IO &IO, SymbolKind &Value) {
	#define DEFINE_ENUM(name) IO.enumCase(Value, #name, SymbolKind::name)

	DEFINE_ENUM(Unknown);
	DEFINE_ENUM(Function);
	DEFINE_ENUM(Module);
	DEFINE_ENUM(Namespace);
	DEFINE_ENUM(NamespaceAlias);
	DEFINE_ENUM(Macro);
	DEFINE_ENUM(Enum);
	DEFINE_ENUM(Struct);
	DEFINE_ENUM(Class);
	DEFINE_ENUM(Protocol);
	DEFINE_ENUM(Extension);
	DEFINE_ENUM(Union);
	DEFINE_ENUM(TypeAlias);
	DEFINE_ENUM(Function);
	DEFINE_ENUM(Variable);
	DEFINE_ENUM(Field);
	DEFINE_ENUM(EnumConstant);
	DEFINE_ENUM(InstanceMethod);
	DEFINE_ENUM(ClassMethod);
	DEFINE_ENUM(StaticMethod);
	DEFINE_ENUM(InstanceProperty);
	DEFINE_ENUM(ClassProperty);
	DEFINE_ENUM(StaticProperty);
	DEFINE_ENUM(Constructor);
	DEFINE_ENUM(Destructor);
	DEFINE_ENUM(ConversionFunction);
	DEFINE_ENUM(Parameter);
	DEFINE_ENUM(Using);

	#undef DEFINE_ENUM
	}
	};

	template <> struct MappingTraits<RefBundle> {
	static void mapping(IO &IO, RefBundle &Refs) {
	MappingNormalization<NormalizedSymbolID, SymbolID> NSymbolID(IO,
	Refs.first);
	IO.mapRequired("ID", NSymbolID->HexString);
	IO.mapRequired("References", Refs.second);
	}
	};

	struct NormalizedRefKind {
	NormalizedRefKind(IO &) {}
	NormalizedRefKind(IO &, RefKind O) { Kind = static_cast<uint8_t>(O); }

	RefKind denormalize(IO &) { return static_cast<RefKind>(Kind); }

	uint8_t Kind = 0;
	};

	template <> struct MappingTraits<Ref> {
	static void mapping(IO &IO, Ref &R) {
	MappingNormalization<NormalizedRefKind, RefKind> NKind(IO, R.Kind);
	IO.mapRequired("Kind", NKind->Kind);
	IO.mapRequired("Location", R.Location);
	}
	};

	struct NormalizedSymbolRole {
	NormalizedSymbolRole(IO &) {}
	NormalizedSymbolRole(IO &IO, SymbolRole R) {
	Kind = static_cast<uint8_t>(clang::clangd::symbolRoleToRelationKind(R));
	}

	SymbolRole denormalize(IO &IO) {
	return clang::clangd::relationKindToSymbolRole(
	static_cast<RelationKind>(Kind));
	}

	uint8_t Kind = 0;
	};

	template <> struct MappingTraits<SymbolID> {
	static void mapping(IO &IO, SymbolID &ID) {
	MappingNormalization<NormalizedSymbolID, SymbolID> NSymbolID(IO, ID);
	IO.mapRequired("ID", NSymbolID->HexString);
	}
	};

	template <> struct MappingTraits<Relation> {
	static void mapping(IO &IO, Relation &Relation) {
	MappingNormalization<NormalizedSymbolRole, SymbolRole> NRole(
	IO, Relation.Predicate);
	IO.mapRequired("Subject", Relation.Subject);
	IO.mapRequired("Predicate", NRole->Kind);
	IO.mapRequired("Object", Relation.Object);
	}
	};

	template <> struct MappingTraits<VariantEntry> {
	static void mapping(IO &IO, VariantEntry &Variant) {
	if (IO.mapTag("!Symbol", Variant.Symbol.hasValue())) {
	if (!IO.outputting())
	Variant.Symbol.emplace();
	MappingTraits<Symbol>::mapping(IO, *Variant.Symbol);
	} else if (IO.mapTag("!Refs", Variant.Refs.hasValue())) {
	if (!IO.outputting())
	Variant.Refs.emplace();
	MappingTraits<RefBundle>::mapping(IO, *Variant.Refs);
	} else if (IO.mapTag("!Relations", Variant.Relation.hasValue())) {
	if (!IO.outputting())
	Variant.Relation.emplace();
	MappingTraits<Relation>::mapping(IO, *Variant.Relation);
	}
	}
	};

	} // namespace yaml
	} // namespace llvm

	namespace clang {
	namespace clangd {

	void writeYAML(const IndexFileOut &O, llvm::raw_ostream &OS) {
	llvm::yaml::Output Yout(OS);
	for (const auto &Sym : *O.Symbols) {
	VariantEntry Entry;
	Entry.Symbol = Sym;
	Yout << Entry;
	}
	if (O.Refs)
	for (auto &Sym : *O.Refs) {
	VariantEntry Entry;
	Entry.Refs = Sym;
	Yout << Entry;
	}
	if (O.Relations)
	for (auto &R : *O.Relations) {
	VariantEntry Entry;
	Entry.Relation = R;
	Yout << Entry;
	}
	}

	llvm::Expected<IndexFileIn> readYAML(llvm::StringRef Data) {
	SymbolSlab::Builder Symbols;
	RefSlab::Builder Refs;
	RelationSlab::Builder Relations;
	llvm::BumpPtrAllocator
	Arena; // store the underlying data of Position::FileURI.
	llvm::UniqueStringSaver Strings(Arena);
	llvm::yaml::Input Yin(Data, &Strings);
	while (Yin.setCurrentDocument()) {
	llvm::yaml::EmptyContext Ctx;
	VariantEntry Variant;
	yamlize(Yin, Variant, true, Ctx);
	if (Yin.error())
	return llvm::errorCodeToError(Yin.error());

	if (Variant.Symbol)
	Symbols.insert(*Variant.Symbol);
	if (Variant.Refs)
	for (const auto &Ref : Variant.Refs->second)
	Refs.insert(Variant.Refs->first, Ref);
	if (Variant.Relation)
	Relations.insert(*Variant.Relation);
	Yin.nextDocument();
	}

	IndexFileIn Result;
	Result.Symbols.emplace(std::move(Symbols).build());
	Result.Refs.emplace(std::move(Refs).build());
	Result.Relations.emplace(std::move(Relations).build());
	return std::move(Result);
	}

	std::string toYAML(const Symbol &S) {
	std::string Buf;
	{
	llvm::raw_string_ostream OS(Buf);
	llvm::yaml::Output Yout(OS);
	Symbol Sym = S; // copy: Yout<< requires mutability.
	Yout << Sym;
	}
	return Buf;
	}

	std::string toYAML(const std::pair<SymbolID, llvm::ArrayRef<Ref>> &Data) {
	RefBundle Refs = {Data.first, Data.second};
	std::string Buf;
	{
	llvm::raw_string_ostream OS(Buf);
	llvm::yaml::Output Yout(OS);
	Yout << Refs;
	}
	return Buf;
	}

	std::string toYAML(const Relation &R) {
	std::string Buf;
	{
	llvm::raw_string_ostream OS(Buf);
	llvm::yaml::Output Yout(OS);
	Relation Rel = R; // copy: Yout<< requires mutability.
	Yout << Rel;
	}
	return Buf;
	}

	} // namespace clangd
	} // namespace clang