clang-r428724/include/llvm/BinaryFormat/MsgPackDocument.h - platform/prebuilts/clang/host/windows-x86 - Git at Google

 //===-- MsgPackDocument.h - MsgPack Document --------------------*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 /// \file
 /// This file declares a class that exposes a simple in-memory representation
 /// of a document of MsgPack objects, that can be read from MsgPack, written to
 /// MsgPack, and inspected and modified in memory. This is intended to be a
 /// lighter-weight (in terms of memory allocations) replacement for
 /// MsgPackTypes.
 ///
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_BINARYFORMAT_MSGPACKDOCUMENT_H
 #define LLVM_BINARYFORMAT_MSGPACKDOCUMENT_H

 #include "llvm/BinaryFormat/MsgPackReader.h"
 #include <map>

 namespace llvm {
 namespace msgpack {

 class ArrayDocNode;
 class Document;
 class MapDocNode;

 /// The kind of a DocNode and its owning Document.
 struct KindAndDocument {
   Document *Doc;
   Type Kind;
 };

 /// A node in a MsgPack Document. This is a simple copyable and
 /// passable-by-value type that does not own any memory.
 class DocNode {
   friend Document;

 public:
   typedef std::map<DocNode, DocNode> MapTy;
   typedef std::vector<DocNode> ArrayTy;

 private:
   // Using KindAndDocument allows us to squeeze Kind and a pointer to the
   // owning Document into the same word. Having a pointer to the owning
   // Document makes the API of DocNode more convenient, and allows its use in
   // YAMLIO.
   const KindAndDocument *KindAndDoc;

 protected:
   // The union of different values.
   union {
     int64_t Int;
     uint64_t UInt;
     bool Bool;
     double Float;
     StringRef Raw;
     ArrayTy *Array;
     MapTy *Map;
   };

 public:
   // Default constructor gives an empty node with no associated Document. All
   // you can do with it is "isEmpty()".
   DocNode() : KindAndDoc(nullptr) {}

   // Type methods
   bool isMap() const { return getKind() == Type::Map; }
   bool isArray() const { return getKind() == Type::Array; }
   bool isScalar() const { return !isMap() && !isArray(); }
   bool isString() const { return getKind() == Type::String; }

   // Accessors. isEmpty() returns true for both a default-constructed DocNode
   // that has no associated Document, and the result of getEmptyNode(), which
   // does have an associated document.
   bool isEmpty() const { return !KindAndDoc || getKind() == Type::Empty; }
   Type getKind() const { return KindAndDoc->Kind; }
   Document *getDocument() const { return KindAndDoc->Doc; }

   int64_t &getInt() {
     assert(getKind() == Type::Int);
     return Int;
   }

   uint64_t &getUInt() {
     assert(getKind() == Type::UInt);
     return UInt;
   }

   bool &getBool() {
     assert(getKind() == Type::Boolean);
     return Bool;
   }

   double &getFloat() {
     assert(getKind() == Type::Float);
     return Float;
   }

   int64_t getInt() const {
     assert(getKind() == Type::Int);
     return Int;
   }

   uint64_t getUInt() const {
     assert(getKind() == Type::UInt);
     return UInt;
   }

   bool getBool() const {
     assert(getKind() == Type::Boolean);
     return Bool;
   }

   double getFloat() const {
     assert(getKind() == Type::Float);
     return Float;
   }

   StringRef getString() const {
     assert(getKind() == Type::String);
     return Raw;
   }

   /// Get an ArrayDocNode for an array node. If Convert, convert the node to an
   /// array node if necessary.
   ArrayDocNode &getArray(bool Convert = false) {
     if (getKind() != Type::Array) {
       assert(Convert);
       convertToArray();
     }
     // This could be a static_cast, except ArrayDocNode is a forward reference.
     return *reinterpret_cast<ArrayDocNode *>(this);
   }

   /// Get a MapDocNode for a map node. If Convert, convert the node to a map
   /// node if necessary.
   MapDocNode &getMap(bool Convert = false) {
     if (getKind() != Type::Map) {
       assert(Convert);
       convertToMap();
     }
     // This could be a static_cast, except MapDocNode is a forward reference.
     return *reinterpret_cast<MapDocNode *>(this);
   }

   /// Comparison operator, used for map keys.
   friend bool operator<(const DocNode &Lhs, const DocNode &Rhs) {
     // This has to cope with one or both of the nodes being default-constructed,
     // such that KindAndDoc is not set.
     if (Rhs.isEmpty())
       return false;
     if (Lhs.KindAndDoc != Rhs.KindAndDoc) {
       if (Lhs.isEmpty())
         return true;
       return (unsigned)Lhs.getKind() < (unsigned)Rhs.getKind();
     }
     switch (Lhs.getKind()) {
     case Type::Int:
       return Lhs.Int < Rhs.Int;
     case Type::UInt:
       return Lhs.UInt < Rhs.UInt;
     case Type::Nil:
       return false;
     case Type::Boolean:
       return Lhs.Bool < Rhs.Bool;
     case Type::Float:
       return Lhs.Float < Rhs.Float;
     case Type::String:
     case Type::Binary:
       return Lhs.Raw < Rhs.Raw;
     default:
       llvm_unreachable("bad map key type");
     }
   }

   /// Equality operator
   friend bool operator==(const DocNode &Lhs, const DocNode &Rhs) {
     return !(Lhs < Rhs) && !(Rhs < Lhs);
   }

   /// Inequality operator
   friend bool operator!=(const DocNode &Lhs, const DocNode &Rhs) {
     return !(Lhs == Rhs);
   }

   /// Convert this node to a string, assuming it is scalar.
   std::string toString() const;

   /// Convert the StringRef and use it to set this DocNode (assuming scalar). If
   /// it is a string, copy the string into the Document's strings list so we do
   /// not rely on S having a lifetime beyond this call. Tag is "" or a YAML tag.
   StringRef fromString(StringRef S, StringRef Tag = "");

   /// Convenience assignment operators. This only works if the destination
   /// DocNode has an associated Document, i.e. it was not constructed using the
   /// default constructor. The string one does not copy, so the string must
   /// remain valid for the lifetime of the Document. Use fromString to avoid
   /// that restriction.
   DocNode &operator=(const char *Val) { return *this = StringRef(Val); }
   DocNode &operator=(StringRef Val);
   DocNode &operator=(bool Val);
   DocNode &operator=(int Val);
   DocNode &operator=(unsigned Val);
   DocNode &operator=(int64_t Val);
   DocNode &operator=(uint64_t Val);

 private:
   // Private constructor setting KindAndDoc, used by methods in Document.
   DocNode(const KindAndDocument *KindAndDoc) : KindAndDoc(KindAndDoc) {}

   void convertToArray();
   void convertToMap();
 };

 /// A DocNode that is a map.
 class MapDocNode : public DocNode {
 public:
   MapDocNode() {}
   MapDocNode(DocNode &N) : DocNode(N) { assert(getKind() == Type::Map); }

   // Map access methods.
   size_t size() const { return Map->size(); }
   bool empty() const { return !size(); }
   MapTy::iterator begin() { return Map->begin(); }
   MapTy::iterator end() { return Map->end(); }
   MapTy::iterator find(DocNode Key) { return Map->find(Key); }
   MapTy::iterator find(StringRef Key);
   MapTy::iterator erase(MapTy::const_iterator I) { return Map->erase(I); }
   size_t erase(DocNode Key) { return Map->erase(Key); }
   MapTy::iterator erase(MapTy::const_iterator First,
                         MapTy::const_iterator Second) {
     return Map->erase(First, Second);
   }
   /// Member access. The string data must remain valid for the lifetime of the
   /// Document.
   DocNode &operator[](StringRef S);
   /// Member access, with convenience versions for an integer key.
   DocNode &operator[](DocNode Key);
   DocNode &operator[](int Key);
   DocNode &operator[](unsigned Key);
   DocNode &operator[](int64_t Key);
   DocNode &operator[](uint64_t Key);
 };

 /// A DocNode that is an array.
 class ArrayDocNode : public DocNode {
 public:
   ArrayDocNode() {}
   ArrayDocNode(DocNode &N) : DocNode(N) { assert(getKind() == Type::Array); }

   // Array access methods.
   size_t size() const { return Array->size(); }
   bool empty() const { return !size(); }
   DocNode &back() const { return Array->back(); }
   ArrayTy::iterator begin() { return Array->begin(); }
   ArrayTy::iterator end() { return Array->end(); }
   void push_back(DocNode N) {
     assert(N.isEmpty() || N.getDocument() == getDocument());
     Array->push_back(N);
   }

   /// Element access. This extends the array if necessary, with empty nodes.
   DocNode &operator[](size_t Index);
 };

 /// Simple in-memory representation of a document of msgpack objects with
 /// ability to find and create array and map elements.  Does not currently cope
 /// with any extension types.
 class Document {
   // Maps, arrays and strings used by nodes in the document. No attempt is made
   // to free unused ones.
   std::vector<std::unique_ptr<DocNode::MapTy>> Maps;
   std::vector<std::unique_ptr<DocNode::ArrayTy>> Arrays;
   std::vector<std::unique_ptr<char[]>> Strings;

   // The root node of the document.
   DocNode Root;

   // The KindAndDocument structs pointed to by nodes in the document.
   KindAndDocument KindAndDocs[size_t(Type::Empty) + 1];

   // Whether YAML output uses hex for UInt.
   bool HexMode = false;

 public:
   Document() {
     clear();
     for (unsigned T = 0; T != unsigned(Type::Empty) + 1; ++T)
       KindAndDocs[T] = {this, Type(T)};
   }

   /// Get ref to the document's root element.
   DocNode &getRoot() { return Root; }

   /// Restore the Document to an empty state.
   void clear() { getRoot() = getEmptyNode(); }

   /// Create an empty node associated with this Document.
   DocNode getEmptyNode() {
     auto N = DocNode(&KindAndDocs[size_t(Type::Empty)]);
     return N;
   }

   /// Create a nil node associated with this Document.
   DocNode getNode() {
     auto N = DocNode(&KindAndDocs[size_t(Type::Nil)]);
     return N;
   }

   /// Create an Int node associated with this Document.
   DocNode getNode(int64_t V) {
     auto N = DocNode(&KindAndDocs[size_t(Type::Int)]);
     N.Int = V;
     return N;
   }

   /// Create an Int node associated with this Document.
   DocNode getNode(int V) {
     auto N = DocNode(&KindAndDocs[size_t(Type::Int)]);
     N.Int = V;
     return N;
   }

   /// Create a UInt node associated with this Document.
   DocNode getNode(uint64_t V) {
     auto N = DocNode(&KindAndDocs[size_t(Type::UInt)]);
     N.UInt = V;
     return N;
   }

   /// Create a UInt node associated with this Document.
   DocNode getNode(unsigned V) {
     auto N = DocNode(&KindAndDocs[size_t(Type::UInt)]);
     N.UInt = V;
     return N;
   }

   /// Create a Boolean node associated with this Document.
   DocNode getNode(bool V) {
     auto N = DocNode(&KindAndDocs[size_t(Type::Boolean)]);
     N.Bool = V;
     return N;
   }

   /// Create a Float node associated with this Document.
   DocNode getNode(double V) {
     auto N = DocNode(&KindAndDocs[size_t(Type::Float)]);
     N.Float = V;
     return N;
   }

   /// Create a String node associated with this Document. If !Copy, the passed
   /// string must remain valid for the lifetime of the Document.
   DocNode getNode(StringRef V, bool Copy = false) {
     if (Copy)
       V = addString(V);
     auto N = DocNode(&KindAndDocs[size_t(Type::String)]);
     N.Raw = V;
     return N;
   }

   /// Create a String node associated with this Document. If !Copy, the passed
   /// string must remain valid for the lifetime of the Document.
   DocNode getNode(const char *V, bool Copy = false) {
     return getNode(StringRef(V), Copy);
   }

   /// Create an empty Map node associated with this Document.
   MapDocNode getMapNode() {
     auto N = DocNode(&KindAndDocs[size_t(Type::Map)]);
     Maps.push_back(std::unique_ptr<DocNode::MapTy>(new DocNode::MapTy));
     N.Map = Maps.back().get();
     return N.getMap();
   }

   /// Create an empty Array node associated with this Document.
   ArrayDocNode getArrayNode() {
     auto N = DocNode(&KindAndDocs[size_t(Type::Array)]);
     Arrays.push_back(std::unique_ptr<DocNode::ArrayTy>(new DocNode::ArrayTy));
     N.Array = Arrays.back().get();
     return N.getArray();
   }

   /// Read a document from a binary msgpack blob, merging into anything already
   /// in the Document. The blob data must remain valid for the lifetime of this
   /// Document (because a string object in the document contains a StringRef
   /// into the original blob). If Multi, then this sets root to an array and
   /// adds top-level objects to it. If !Multi, then it only reads a single
   /// top-level object, even if there are more, and sets root to that. Returns
   /// false if failed due to illegal format or merge error.
   ///
   /// The Merger arg is a callback function that is called when the merge has a
   /// conflict, that is, it is trying to set an item that is already set. If the
   /// conflict cannot be resolved, the callback function returns -1. If the
   /// conflict can be resolved, the callback returns a non-negative number and
   /// sets *DestNode to the resolved node. The returned non-negative number is
   /// significant only for an array node; it is then the array index to start
   /// populating at. That allows Merger to choose whether to merge array
   /// elements (returns 0) or append new elements (returns existing size).
   ///
   /// If SrcNode is an array or map, the resolution must be that *DestNode is an
   /// array or map respectively, although it could be the array or map
   /// (respectively) that was already there. MapKey is the key if *DestNode is a
   /// map entry, a nil node otherwise.
   ///
   /// The default for Merger is to disallow any conflict.
   bool readFromBlob(
       StringRef Blob, bool Multi,
       function_ref<int(DocNode *DestNode, DocNode SrcNode, DocNode MapKey)>
           Merger = [](DocNode *DestNode, DocNode SrcNode, DocNode MapKey) {
             return -1;
           });

   /// Write a MsgPack document to a binary MsgPack blob.
   void writeToBlob(std::string &Blob);

   /// Copy a string into the Document's strings list, and return the copy that
   /// is owned by the Document.
   StringRef addString(StringRef S) {
     Strings.push_back(std::unique_ptr<char[]>(new char[S.size()]));
     memcpy(&Strings.back()[0], S.data(), S.size());
     return StringRef(&Strings.back()[0], S.size());
   }

   /// Set whether YAML output uses hex for UInt. Default off.
   void setHexMode(bool Val = true) { HexMode = Val; }

   /// Get Hexmode flag.
   bool getHexMode() const { return HexMode; }

   /// Convert MsgPack Document to YAML text.
   void toYAML(raw_ostream &OS);

   /// Read YAML text into the MsgPack document. Returns false on failure.
   bool fromYAML(StringRef S);
 };

 } // namespace msgpack
 } // namespace llvm

 #endif // LLVM_BINARYFORMAT_MSGPACKDOCUMENT_H
	//===-- MsgPackDocument.h - MsgPack Document --------------------- C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	/// \file
	/// This file declares a class that exposes a simple in-memory representation
	/// of a document of MsgPack objects, that can be read from MsgPack, written to
	/// MsgPack, and inspected and modified in memory. This is intended to be a
	/// lighter-weight (in terms of memory allocations) replacement for
	/// MsgPackTypes.
	///
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_BINARYFORMAT_MSGPACKDOCUMENT_H
	#define LLVM_BINARYFORMAT_MSGPACKDOCUMENT_H

	#include "llvm/BinaryFormat/MsgPackReader.h"
	#include <map>

	namespace llvm {
	namespace msgpack {

	class ArrayDocNode;
	class Document;
	class MapDocNode;

	/// The kind of a DocNode and its owning Document.
	struct KindAndDocument {
	Document *Doc;
	Type Kind;
	};

	/// A node in a MsgPack Document. This is a simple copyable and
	/// passable-by-value type that does not own any memory.
	class DocNode {
	friend Document;

	public:
	typedef std::map<DocNode, DocNode> MapTy;
	typedef std::vector<DocNode> ArrayTy;

	private:
	// Using KindAndDocument allows us to squeeze Kind and a pointer to the
	// owning Document into the same word. Having a pointer to the owning
	// Document makes the API of DocNode more convenient, and allows its use in
	// YAMLIO.
	const KindAndDocument *KindAndDoc;

	protected:
	// The union of different values.
	union {
	int64_t Int;
	uint64_t UInt;
	bool Bool;
	double Float;
	StringRef Raw;
	ArrayTy *Array;
	MapTy *Map;
	};

	public:
	// Default constructor gives an empty node with no associated Document. All
	// you can do with it is "isEmpty()".
	DocNode() : KindAndDoc(nullptr) {}

	// Type methods
	bool isMap() const { return getKind() == Type::Map; }
	bool isArray() const { return getKind() == Type::Array; }
	bool isScalar() const { return !isMap() && !isArray(); }
	bool isString() const { return getKind() == Type::String; }

	// Accessors. isEmpty() returns true for both a default-constructed DocNode
	// that has no associated Document, and the result of getEmptyNode(), which
	// does have an associated document.
	bool isEmpty() const { return !KindAndDoc \|\| getKind() == Type::Empty; }
	Type getKind() const { return KindAndDoc->Kind; }
	Document *getDocument() const { return KindAndDoc->Doc; }

	int64_t &getInt() {
	assert(getKind() == Type::Int);
	return Int;
	}

	uint64_t &getUInt() {
	assert(getKind() == Type::UInt);
	return UInt;
	}

	bool &getBool() {
	assert(getKind() == Type::Boolean);
	return Bool;
	}

	double &getFloat() {
	assert(getKind() == Type::Float);
	return Float;
	}

	int64_t getInt() const {
	assert(getKind() == Type::Int);
	return Int;
	}

	uint64_t getUInt() const {
	assert(getKind() == Type::UInt);
	return UInt;
	}

	bool getBool() const {
	assert(getKind() == Type::Boolean);
	return Bool;
	}

	double getFloat() const {
	assert(getKind() == Type::Float);
	return Float;
	}

	StringRef getString() const {
	assert(getKind() == Type::String);
	return Raw;
	}

	/// Get an ArrayDocNode for an array node. If Convert, convert the node to an
	/// array node if necessary.
	ArrayDocNode &getArray(bool Convert = false) {
	if (getKind() != Type::Array) {
	assert(Convert);
	convertToArray();
	}
	// This could be a static_cast, except ArrayDocNode is a forward reference.
	return reinterpret_cast<ArrayDocNode >(this);
	}

	/// Get a MapDocNode for a map node. If Convert, convert the node to a map
	/// node if necessary.
	MapDocNode &getMap(bool Convert = false) {
	if (getKind() != Type::Map) {
	assert(Convert);
	convertToMap();
	}
	// This could be a static_cast, except MapDocNode is a forward reference.
	return reinterpret_cast<MapDocNode >(this);
	}

	/// Comparison operator, used for map keys.
	friend bool operator<(const DocNode &Lhs, const DocNode &Rhs) {
	// This has to cope with one or both of the nodes being default-constructed,
	// such that KindAndDoc is not set.
	if (Rhs.isEmpty())
	return false;
	if (Lhs.KindAndDoc != Rhs.KindAndDoc) {
	if (Lhs.isEmpty())
	return true;
	return (unsigned)Lhs.getKind() < (unsigned)Rhs.getKind();
	}
	switch (Lhs.getKind()) {
	case Type::Int:
	return Lhs.Int < Rhs.Int;
	case Type::UInt:
	return Lhs.UInt < Rhs.UInt;
	case Type::Nil:
	return false;
	case Type::Boolean:
	return Lhs.Bool < Rhs.Bool;
	case Type::Float:
	return Lhs.Float < Rhs.Float;
	case Type::String:
	case Type::Binary:
	return Lhs.Raw < Rhs.Raw;
	default:
	llvm_unreachable("bad map key type");
	}
	}

	/// Equality operator
	friend bool operator==(const DocNode &Lhs, const DocNode &Rhs) {
	return !(Lhs < Rhs) && !(Rhs < Lhs);
	}

	/// Inequality operator
	friend bool operator!=(const DocNode &Lhs, const DocNode &Rhs) {
	return !(Lhs == Rhs);
	}

	/// Convert this node to a string, assuming it is scalar.
	std::string toString() const;

	/// Convert the StringRef and use it to set this DocNode (assuming scalar). If
	/// it is a string, copy the string into the Document's strings list so we do
	/// not rely on S having a lifetime beyond this call. Tag is "" or a YAML tag.
	StringRef fromString(StringRef S, StringRef Tag = "");

	/// Convenience assignment operators. This only works if the destination
	/// DocNode has an associated Document, i.e. it was not constructed using the
	/// default constructor. The string one does not copy, so the string must
	/// remain valid for the lifetime of the Document. Use fromString to avoid
	/// that restriction.
	DocNode &operator=(const char Val) { return this = StringRef(Val); }
	DocNode &operator=(StringRef Val);
	DocNode &operator=(bool Val);
	DocNode &operator=(int Val);
	DocNode &operator=(unsigned Val);
	DocNode &operator=(int64_t Val);
	DocNode &operator=(uint64_t Val);

	private:
	// Private constructor setting KindAndDoc, used by methods in Document.
	DocNode(const KindAndDocument *KindAndDoc) : KindAndDoc(KindAndDoc) {}

	void convertToArray();
	void convertToMap();
	};

	/// A DocNode that is a map.
	class MapDocNode : public DocNode {
	public:
	MapDocNode() {}
	MapDocNode(DocNode &N) : DocNode(N) { assert(getKind() == Type::Map); }

	// Map access methods.
	size_t size() const { return Map->size(); }
	bool empty() const { return !size(); }
	MapTy::iterator begin() { return Map->begin(); }
	MapTy::iterator end() { return Map->end(); }
	MapTy::iterator find(DocNode Key) { return Map->find(Key); }
	MapTy::iterator find(StringRef Key);
	MapTy::iterator erase(MapTy::const_iterator I) { return Map->erase(I); }
	size_t erase(DocNode Key) { return Map->erase(Key); }
	MapTy::iterator erase(MapTy::const_iterator First,
	MapTy::const_iterator Second) {
	return Map->erase(First, Second);
	}
	/// Member access. The string data must remain valid for the lifetime of the
	/// Document.
	DocNode &operator[](StringRef S);
	/// Member access, with convenience versions for an integer key.
	DocNode &operator[](DocNode Key);
	DocNode &operator[](int Key);
	DocNode &operator[](unsigned Key);
	DocNode &operator[](int64_t Key);
	DocNode &operator[](uint64_t Key);
	};

	/// A DocNode that is an array.
	class ArrayDocNode : public DocNode {
	public:
	ArrayDocNode() {}
	ArrayDocNode(DocNode &N) : DocNode(N) { assert(getKind() == Type::Array); }

	// Array access methods.
	size_t size() const { return Array->size(); }
	bool empty() const { return !size(); }
	DocNode &back() const { return Array->back(); }
	ArrayTy::iterator begin() { return Array->begin(); }
	ArrayTy::iterator end() { return Array->end(); }
	void push_back(DocNode N) {
	assert(N.isEmpty() \|\| N.getDocument() == getDocument());
	Array->push_back(N);
	}

	/// Element access. This extends the array if necessary, with empty nodes.
	DocNode &operator[](size_t Index);
	};

	/// Simple in-memory representation of a document of msgpack objects with
	/// ability to find and create array and map elements. Does not currently cope
	/// with any extension types.
	class Document {
	// Maps, arrays and strings used by nodes in the document. No attempt is made
	// to free unused ones.
	std::vector<std::unique_ptr<DocNode::MapTy>> Maps;
	std::vector<std::unique_ptr<DocNode::ArrayTy>> Arrays;
	std::vector<std::unique_ptr<char[]>> Strings;

	// The root node of the document.
	DocNode Root;

	// The KindAndDocument structs pointed to by nodes in the document.
	KindAndDocument KindAndDocs[size_t(Type::Empty) + 1];

	// Whether YAML output uses hex for UInt.
	bool HexMode = false;

	public:
	Document() {
	clear();
	for (unsigned T = 0; T != unsigned(Type::Empty) + 1; ++T)
	KindAndDocs[T] = {this, Type(T)};
	}

	/// Get ref to the document's root element.
	DocNode &getRoot() { return Root; }

	/// Restore the Document to an empty state.
	void clear() { getRoot() = getEmptyNode(); }

	/// Create an empty node associated with this Document.
	DocNode getEmptyNode() {
	auto N = DocNode(&KindAndDocs[size_t(Type::Empty)]);
	return N;
	}

	/// Create a nil node associated with this Document.
	DocNode getNode() {
	auto N = DocNode(&KindAndDocs[size_t(Type::Nil)]);
	return N;
	}

	/// Create an Int node associated with this Document.
	DocNode getNode(int64_t V) {
	auto N = DocNode(&KindAndDocs[size_t(Type::Int)]);
	N.Int = V;
	return N;
	}

	/// Create an Int node associated with this Document.
	DocNode getNode(int V) {
	auto N = DocNode(&KindAndDocs[size_t(Type::Int)]);
	N.Int = V;
	return N;
	}

	/// Create a UInt node associated with this Document.
	DocNode getNode(uint64_t V) {
	auto N = DocNode(&KindAndDocs[size_t(Type::UInt)]);
	N.UInt = V;
	return N;
	}

	/// Create a UInt node associated with this Document.
	DocNode getNode(unsigned V) {
	auto N = DocNode(&KindAndDocs[size_t(Type::UInt)]);
	N.UInt = V;
	return N;
	}

	/// Create a Boolean node associated with this Document.
	DocNode getNode(bool V) {
	auto N = DocNode(&KindAndDocs[size_t(Type::Boolean)]);
	N.Bool = V;
	return N;
	}

	/// Create a Float node associated with this Document.
	DocNode getNode(double V) {
	auto N = DocNode(&KindAndDocs[size_t(Type::Float)]);
	N.Float = V;
	return N;
	}

	/// Create a String node associated with this Document. If !Copy, the passed
	/// string must remain valid for the lifetime of the Document.
	DocNode getNode(StringRef V, bool Copy = false) {
	if (Copy)
	V = addString(V);
	auto N = DocNode(&KindAndDocs[size_t(Type::String)]);
	N.Raw = V;
	return N;
	}

	/// Create a String node associated with this Document. If !Copy, the passed
	/// string must remain valid for the lifetime of the Document.
	DocNode getNode(const char *V, bool Copy = false) {
	return getNode(StringRef(V), Copy);
	}

	/// Create an empty Map node associated with this Document.
	MapDocNode getMapNode() {
	auto N = DocNode(&KindAndDocs[size_t(Type::Map)]);
	Maps.push_back(std::unique_ptr<DocNode::MapTy>(new DocNode::MapTy));
	N.Map = Maps.back().get();
	return N.getMap();
	}

	/// Create an empty Array node associated with this Document.
	ArrayDocNode getArrayNode() {
	auto N = DocNode(&KindAndDocs[size_t(Type::Array)]);
	Arrays.push_back(std::unique_ptr<DocNode::ArrayTy>(new DocNode::ArrayTy));
	N.Array = Arrays.back().get();
	return N.getArray();
	}

	/// Read a document from a binary msgpack blob, merging into anything already
	/// in the Document. The blob data must remain valid for the lifetime of this
	/// Document (because a string object in the document contains a StringRef
	/// into the original blob). If Multi, then this sets root to an array and
	/// adds top-level objects to it. If !Multi, then it only reads a single
	/// top-level object, even if there are more, and sets root to that. Returns
	/// false if failed due to illegal format or merge error.
	///
	/// The Merger arg is a callback function that is called when the merge has a
	/// conflict, that is, it is trying to set an item that is already set. If the
	/// conflict cannot be resolved, the callback function returns -1. If the
	/// conflict can be resolved, the callback returns a non-negative number and
	/// sets *DestNode to the resolved node. The returned non-negative number is
	/// significant only for an array node; it is then the array index to start
	/// populating at. That allows Merger to choose whether to merge array
	/// elements (returns 0) or append new elements (returns existing size).
	///
	/// If SrcNode is an array or map, the resolution must be that *DestNode is an
	/// array or map respectively, although it could be the array or map
	/// (respectively) that was already there. MapKey is the key if *DestNode is a
	/// map entry, a nil node otherwise.
	///
	/// The default for Merger is to disallow any conflict.
	bool readFromBlob(
	StringRef Blob, bool Multi,
	function_ref<int(DocNode *DestNode, DocNode SrcNode, DocNode MapKey)>
	Merger = [](DocNode *DestNode, DocNode SrcNode, DocNode MapKey) {
	return -1;
	});

	/// Write a MsgPack document to a binary MsgPack blob.
	void writeToBlob(std::string &Blob);

	/// Copy a string into the Document's strings list, and return the copy that
	/// is owned by the Document.
	StringRef addString(StringRef S) {
	Strings.push_back(std::unique_ptr<char[]>(new char[S.size()]));
	memcpy(&Strings.back()[0], S.data(), S.size());
	return StringRef(&Strings.back()[0], S.size());
	}

	/// Set whether YAML output uses hex for UInt. Default off.
	void setHexMode(bool Val = true) { HexMode = Val; }

	/// Get Hexmode flag.
	bool getHexMode() const { return HexMode; }

	/// Convert MsgPack Document to YAML text.
	void toYAML(raw_ostream &OS);

	/// Read YAML text into the MsgPack document. Returns false on failure.
	bool fromYAML(StringRef S);
	};

	} // namespace msgpack
	} // namespace llvm

	#endif // LLVM_BINARYFORMAT_MSGPACKDOCUMENT_H