third_party/protobuf/3.6.1/src/google/protobuf/message_lite.h - bazel - Git at Google

 // Protocol Buffers - Google's data interchange format
 // Copyright 2008 Google Inc.  All rights reserved.
 // https://developers.google.com/protocol-buffers/
 //
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are
 // met:
 //
 //     * Redistributions of source code must retain the above copyright
 // notice, this list of conditions and the following disclaimer.
 //     * Redistributions in binary form must reproduce the above
 // copyright notice, this list of conditions and the following disclaimer
 // in the documentation and/or other materials provided with the
 // distribution.
 //     * Neither the name of Google Inc. nor the names of its
 // contributors may be used to endorse or promote products derived from
 // this software without specific prior written permission.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
 // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
 // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
 // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
 // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
 // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
 // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

 // Authors: wink@google.com (Wink Saville),
 //          kenton@google.com (Kenton Varda)
 //  Based on original Protocol Buffers design by
 //  Sanjay Ghemawat, Jeff Dean, and others.
 //
 // Defines MessageLite, the abstract interface implemented by all (lite
 // and non-lite) protocol message objects.

 #ifndef GOOGLE_PROTOBUF_MESSAGE_LITE_H__
 #define GOOGLE_PROTOBUF_MESSAGE_LITE_H__

 #include <climits>
 #include <google/protobuf/stubs/common.h>
 #include <google/protobuf/stubs/logging.h>
 #include <google/protobuf/stubs/once.h>
 #include <google/protobuf/arena.h>
 #include <google/protobuf/stubs/port.h>

 namespace google {
 namespace protobuf {
 template <typename T>
 class RepeatedPtrField;
 namespace io {
 class CodedInputStream;
 class CodedOutputStream;
 class ZeroCopyInputStream;
 class ZeroCopyOutputStream;
 }
 namespace internal {

 class RepeatedPtrFieldBase;
 class WireFormatLite;
 class WeakFieldMap;

 #ifndef SWIG
 // We compute sizes as size_t but cache them as int.  This function converts a
 // computed size to a cached size.  Since we don't proceed with serialization
 // if the total size was > INT_MAX, it is not important what this function
 // returns for inputs > INT_MAX.  However this case should not error or
 // GOOGLE_CHECK-fail, because the full size_t resolution is still returned from
 // ByteSizeLong() and checked against INT_MAX; we can catch the overflow
 // there.
 inline int ToCachedSize(size_t size) { return static_cast<int>(size); }

 // We mainly calculate sizes in terms of size_t, but some functions that
 // compute sizes return "int".  These int sizes are expected to always be
 // positive. This function is more efficient than casting an int to size_t
 // directly on 64-bit platforms because it avoids making the compiler emit a
 // sign extending instruction, which we don't want and don't want to pay for.
 inline size_t FromIntSize(int size) {
   // Convert to unsigned before widening so sign extension is not necessary.
   return static_cast<unsigned int>(size);
 }

 // For cases where a legacy function returns an integer size.  We GOOGLE_DCHECK()
 // that the conversion will fit within an integer; if this is false then we
 // are losing information.
 inline int ToIntSize(size_t size) {
   GOOGLE_DCHECK_LE(size, static_cast<size_t>(INT_MAX));
   return static_cast<int>(size);
 }

 // This type wraps a variable whose constructor and destructor are explicitly
 // called. It is particularly useful for a global variable, without its
 // constructor and destructor run on start and end of the program lifetime.
 // This circumvents the initial construction order fiasco, while keeping
 // the address of the empty string a compile time constant.
 //
 // Pay special attention to the initialization state of the object.
 // 1. The object is "uninitialized" to begin with.
 // 2. Call DefaultConstruct() only if the object is uninitialized.
 //    After the call, the object becomes "initialized".
 // 3. Call get() and get_mutable() only if the object is initialized.
 // 4. Call Destruct() only if the object is initialized.
 //    After the call, the object becomes uninitialized.
 template <typename T>
 class ExplicitlyConstructed {
  public:
   void DefaultConstruct() {
     new (&union_) T();
   }

   void Destruct() {
     get_mutable()->~T();
   }

   constexpr const T& get() const { return reinterpret_cast<const T&>(union_); }
   T* get_mutable() { return reinterpret_cast<T*>(&union_); }

  private:
   // Prefer c++14 aligned_storage, but for compatibility this will do.
   union AlignedUnion {
     char space[sizeof(T)];
     int64 align_to_int64;
     void* align_to_ptr;
   } union_;
 };

 // Default empty string object. Don't use this directly. Instead, call
 // GetEmptyString() to get the reference.
 LIBPROTOBUF_EXPORT extern ExplicitlyConstructed<::std::string> fixed_address_empty_string;

 LIBPROTOBUF_EXPORT inline const ::std::string& GetEmptyStringAlreadyInited() {
   return fixed_address_empty_string.get();
 }

 LIBPROTOBUF_EXPORT size_t StringSpaceUsedExcludingSelfLong(const string& str);
 #endif  // SWIG
 }  // namespace internal

 // Interface to light weight protocol messages.
 //
 // This interface is implemented by all protocol message objects.  Non-lite
 // messages additionally implement the Message interface, which is a
 // subclass of MessageLite.  Use MessageLite instead when you only need
 // the subset of features which it supports -- namely, nothing that uses
 // descriptors or reflection.  You can instruct the protocol compiler
 // to generate classes which implement only MessageLite, not the full
 // Message interface, by adding the following line to the .proto file:
 //
 //   option optimize_for = LITE_RUNTIME;
 //
 // This is particularly useful on resource-constrained systems where
 // the full protocol buffers runtime library is too big.
 //
 // Note that on non-constrained systems (e.g. servers) when you need
 // to link in lots of protocol definitions, a better way to reduce
 // total code footprint is to use optimize_for = CODE_SIZE.  This
 // will make the generated code smaller while still supporting all the
 // same features (at the expense of speed).  optimize_for = LITE_RUNTIME
 // is best when you only have a small number of message types linked
 // into your binary, in which case the size of the protocol buffers
 // runtime itself is the biggest problem.
 class LIBPROTOBUF_EXPORT MessageLite {
  public:
   inline MessageLite() {}
   virtual ~MessageLite() {}

   // Basic Operations ------------------------------------------------

   // Get the name of this message type, e.g. "foo.bar.BazProto".
   virtual string GetTypeName() const = 0;

   // Construct a new instance of the same type.  Ownership is passed to the
   // caller.
   virtual MessageLite* New() const = 0;

   // Construct a new instance on the arena. Ownership is passed to the caller
   // if arena is a NULL. Default implementation for backwards compatibility.
   virtual MessageLite* New(::google::protobuf::Arena* arena) const;

   // Get the arena, if any, associated with this message. Virtual method
   // required for generic operations but most arena-related operations should
   // use the GetArenaNoVirtual() generated-code method. Default implementation
   // to reduce code size by avoiding the need for per-type implementations
   // when types do not implement arena support.
   virtual ::google::protobuf::Arena* GetArena() const { return NULL; }

   // Get a pointer that may be equal to this message's arena, or may not be.
   // If the value returned by this method is equal to some arena pointer, then
   // this message is on that arena; however, if this message is on some arena,
   // this method may or may not return that arena's pointer. As a tradeoff,
   // this method may be more efficient than GetArena(). The intent is to allow
   // underlying representations that use e.g. tagged pointers to sometimes
   // store the arena pointer directly, and sometimes in a more indirect way,
   // and allow a fastpath comparison against the arena pointer when it's easy
   // to obtain.
   virtual void* GetMaybeArenaPointer() const { return GetArena(); }

   // Clear all fields of the message and set them to their default values.
   // Clear() avoids freeing memory, assuming that any memory allocated
   // to hold parts of the message will be needed again to hold the next
   // message.  If you actually want to free the memory used by a Message,
   // you must delete it.
   virtual void Clear() = 0;

   // Quickly check if all required fields have values set.
   virtual bool IsInitialized() const = 0;

   // This is not implemented for Lite messages -- it just returns "(cannot
   // determine missing fields for lite message)".  However, it is implemented
   // for full messages.  See message.h.
   virtual string InitializationErrorString() const;

   // If |other| is the exact same class as this, calls MergeFrom(). Otherwise,
   // results are undefined (probably crash).
   virtual void CheckTypeAndMergeFrom(const MessageLite& other) = 0;

   // Parsing ---------------------------------------------------------
   // Methods for parsing in protocol buffer format.  Most of these are
   // just simple wrappers around MergeFromCodedStream().  Clear() will be
   // called before merging the input.

   // Fill the message with a protocol buffer parsed from the given input
   // stream. Returns false on a read error or if the input is in the wrong
   // format.  A successful return does not indicate the entire input is
   // consumed, ensure you call ConsumedEntireMessage() to check that if
   // applicable.
   bool ParseFromCodedStream(io::CodedInputStream* input);
   // Like ParseFromCodedStream(), but accepts messages that are missing
   // required fields.
   bool ParsePartialFromCodedStream(io::CodedInputStream* input);
   // Read a protocol buffer from the given zero-copy input stream.  If
   // successful, the entire input will be consumed.
   bool ParseFromZeroCopyStream(io::ZeroCopyInputStream* input);
   // Like ParseFromZeroCopyStream(), but accepts messages that are missing
   // required fields.
   bool ParsePartialFromZeroCopyStream(io::ZeroCopyInputStream* input);
   // Read a protocol buffer from the given zero-copy input stream, expecting
   // the message to be exactly "size" bytes long.  If successful, exactly
   // this many bytes will have been consumed from the input.
   bool ParseFromBoundedZeroCopyStream(io::ZeroCopyInputStream* input, int size);
   // Like ParseFromBoundedZeroCopyStream(), but accepts messages that are
   // missing required fields.
   bool ParsePartialFromBoundedZeroCopyStream(io::ZeroCopyInputStream* input,
                                              int size);
   // Parses a protocol buffer contained in a string. Returns true on success.
   // This function takes a string in the (non-human-readable) binary wire
   // format, matching the encoding output by MessageLite::SerializeToString().
   // If you'd like to convert a human-readable string into a protocol buffer
   // object, see google::protobuf::TextFormat::ParseFromString().
   bool ParseFromString(const string& data);
   // Like ParseFromString(), but accepts messages that are missing
   // required fields.
   bool ParsePartialFromString(const string& data);
   // Parse a protocol buffer contained in an array of bytes.
   bool ParseFromArray(const void* data, int size);
   // Like ParseFromArray(), but accepts messages that are missing
   // required fields.
   bool ParsePartialFromArray(const void* data, int size);


   // Reads a protocol buffer from the stream and merges it into this
   // Message.  Singular fields read from the what is
   // already in the Message and repeated fields are appended to those
   // already present.
   //
   // It is the responsibility of the caller to call input->LastTagWas()
   // (for groups) or input->ConsumedEntireMessage() (for non-groups) after
   // this returns to verify that the message's end was delimited correctly.
   //
   // ParsefromCodedStream() is implemented as Clear() followed by
   // MergeFromCodedStream().
   bool MergeFromCodedStream(io::CodedInputStream* input);

   // Like MergeFromCodedStream(), but succeeds even if required fields are
   // missing in the input.
   //
   // MergeFromCodedStream() is just implemented as MergePartialFromCodedStream()
   // followed by IsInitialized().
   virtual bool MergePartialFromCodedStream(io::CodedInputStream* input) = 0;


   // Serialization ---------------------------------------------------
   // Methods for serializing in protocol buffer format.  Most of these
   // are just simple wrappers around ByteSize() and SerializeWithCachedSizes().

   // Write a protocol buffer of this message to the given output.  Returns
   // false on a write error.  If the message is missing required fields,
   // this may GOOGLE_CHECK-fail.
   bool SerializeToCodedStream(io::CodedOutputStream* output) const;
   // Like SerializeToCodedStream(), but allows missing required fields.
   bool SerializePartialToCodedStream(io::CodedOutputStream* output) const;
   // Write the message to the given zero-copy output stream.  All required
   // fields must be set.
   bool SerializeToZeroCopyStream(io::ZeroCopyOutputStream* output) const;
   // Like SerializeToZeroCopyStream(), but allows missing required fields.
   bool SerializePartialToZeroCopyStream(io::ZeroCopyOutputStream* output) const;
   // Serialize the message and store it in the given string.  All required
   // fields must be set.
   bool SerializeToString(string* output) const;
   // Like SerializeToString(), but allows missing required fields.
   bool SerializePartialToString(string* output) const;
   // Serialize the message and store it in the given byte array.  All required
   // fields must be set.
   bool SerializeToArray(void* data, int size) const;
   // Like SerializeToArray(), but allows missing required fields.
   bool SerializePartialToArray(void* data, int size) const;

   // Make a string encoding the message. Is equivalent to calling
   // SerializeToString() on a string and using that.  Returns the empty
   // string if SerializeToString() would have returned an error.
   // Note: If you intend to generate many such strings, you may
   // reduce heap fragmentation by instead re-using the same string
   // object with calls to SerializeToString().
   string SerializeAsString() const;
   // Like SerializeAsString(), but allows missing required fields.
   string SerializePartialAsString() const;

   // Like SerializeToString(), but appends to the data to the string's existing
   // contents.  All required fields must be set.
   bool AppendToString(string* output) const;
   // Like AppendToString(), but allows missing required fields.
   bool AppendPartialToString(string* output) const;

   // Computes the serialized size of the message.  This recursively calls
   // ByteSizeLong() on all embedded messages.
   //
   // ByteSizeLong() is generally linear in the number of fields defined for the
   // proto.
   virtual size_t ByteSizeLong() const = 0;

   // Legacy ByteSize() API.
   PROTOBUF_RUNTIME_DEPRECATED("Please use ByteSizeLong() instead")
   int ByteSize() const {
     return internal::ToIntSize(ByteSizeLong());
   }

   // Serializes the message without recomputing the size.  The message must not
   // have changed since the last call to ByteSize(), and the value returned by
   // ByteSize must be non-negative.  Otherwise the results are undefined.
   virtual void SerializeWithCachedSizes(
       io::CodedOutputStream* output) const;

   // Functions below here are not part of the public interface.  It isn't
   // enforced, but they should be treated as private, and will be private
   // at some future time.  Unfortunately the implementation of the "friend"
   // keyword in GCC is broken at the moment, but we expect it will be fixed.

   // Like SerializeWithCachedSizes, but writes directly to *target, returning
   // a pointer to the byte immediately after the last byte written.  "target"
   // must point at a byte array of at least ByteSize() bytes.  Whether to use
   // deterministic serialization, e.g., maps in sorted order, is determined by
   // CodedOutputStream::IsDefaultSerializationDeterministic().
   virtual uint8* SerializeWithCachedSizesToArray(uint8* target) const;

   // Returns the result of the last call to ByteSize().  An embedded message's
   // size is needed both to serialize it (because embedded messages are
   // length-delimited) and to compute the outer message's size.  Caching
   // the size avoids computing it multiple times.
   //
   // ByteSize() does not automatically use the cached size when available
   // because this would require invalidating it every time the message was
   // modified, which would be too hard and expensive.  (E.g. if a deeply-nested
   // sub-message is changed, all of its parents' cached sizes would need to be
   // invalidated, which is too much work for an otherwise inlined setter
   // method.)
   virtual int GetCachedSize() const = 0;

   virtual uint8* InternalSerializeWithCachedSizesToArray(bool deterministic,
                                                          uint8* target) const;

  protected:
   // CastToBase allows generated code to cast a RepeatedPtrField<T> to
   // RepeatedPtrFieldBase. We try to restrict access to RepeatedPtrFieldBase
   // because it is an implementation detail that user code should not access
   // directly.
   template <typename T>
   static ::google::protobuf::internal::RepeatedPtrFieldBase* CastToBase(
       ::google::protobuf::RepeatedPtrField<T>* repeated) {
     return repeated;
   }
   template <typename T>
   static const ::google::protobuf::internal::RepeatedPtrFieldBase& CastToBase(
       const ::google::protobuf::RepeatedPtrField<T>& repeated) {
     return repeated;
   }

   template <typename T>
   static T* CreateMaybeMessage(Arena* arena) {
     return Arena::CreateMaybeMessage<T>(arena);
   }

  private:
   // TODO(gerbens) make this a pure abstract function
   virtual const void* InternalGetTable() const { return NULL; }

   friend class internal::WireFormatLite;
   friend class Message;
   friend class internal::WeakFieldMap;

   GOOGLE_DISALLOW_EVIL_CONSTRUCTORS(MessageLite);
 };

 namespace internal {

 extern bool LIBPROTOBUF_EXPORT proto3_preserve_unknown_;

 // DO NOT USE: For migration only. Will be removed when Proto3 defaults to
 // preserve unknowns.
 inline bool GetProto3PreserveUnknownsDefault() {
   return proto3_preserve_unknown_;
 }

 // DO NOT USE: For migration only. Will be removed when Proto3 defaults to
 // preserve unknowns.
 void LIBPROTOBUF_EXPORT SetProto3PreserveUnknownsDefault(bool preserve);
 }  // namespace internal


 }  // namespace protobuf

 }  // namespace google
 #endif  // GOOGLE_PROTOBUF_MESSAGE_LITE_H__
	// Protocol Buffers - Google's data interchange format
	// Copyright 2008 Google Inc. All rights reserved.
	// https://developers.google.com/protocol-buffers/
	//
	// Redistribution and use in source and binary forms, with or without
	// modification, are permitted provided that the following conditions are
	// met:
	//
	// * Redistributions of source code must retain the above copyright
	// notice, this list of conditions and the following disclaimer.
	// * Redistributions in binary form must reproduce the above
	// copyright notice, this list of conditions and the following disclaimer
	// in the documentation and/or other materials provided with the
	// distribution.
	// * Neither the name of Google Inc. nor the names of its
	// contributors may be used to endorse or promote products derived from
	// this software without specific prior written permission.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

	// Authors: wink@google.com (Wink Saville),
	// kenton@google.com (Kenton Varda)
	// Based on original Protocol Buffers design by
	// Sanjay Ghemawat, Jeff Dean, and others.
	//
	// Defines MessageLite, the abstract interface implemented by all (lite
	// and non-lite) protocol message objects.

	#ifndef GOOGLE_PROTOBUF_MESSAGE_LITE_H__
	#define GOOGLE_PROTOBUF_MESSAGE_LITE_H__

	#include <climits>
	#include <google/protobuf/stubs/common.h>
	#include <google/protobuf/stubs/logging.h>
	#include <google/protobuf/stubs/once.h>
	#include <google/protobuf/arena.h>
	#include <google/protobuf/stubs/port.h>

	namespace google {
	namespace protobuf {
	template <typename T>
	class RepeatedPtrField;
	namespace io {
	class CodedInputStream;
	class CodedOutputStream;
	class ZeroCopyInputStream;
	class ZeroCopyOutputStream;
	}
	namespace internal {

	class RepeatedPtrFieldBase;
	class WireFormatLite;
	class WeakFieldMap;

	#ifndef SWIG
	// We compute sizes as size_t but cache them as int. This function converts a
	// computed size to a cached size. Since we don't proceed with serialization
	// if the total size was > INT_MAX, it is not important what this function
	// returns for inputs > INT_MAX. However this case should not error or
	// GOOGLE_CHECK-fail, because the full size_t resolution is still returned from
	// ByteSizeLong() and checked against INT_MAX; we can catch the overflow
	// there.
	inline int ToCachedSize(size_t size) { return static_cast<int>(size); }

	// We mainly calculate sizes in terms of size_t, but some functions that
	// compute sizes return "int". These int sizes are expected to always be
	// positive. This function is more efficient than casting an int to size_t
	// directly on 64-bit platforms because it avoids making the compiler emit a
	// sign extending instruction, which we don't want and don't want to pay for.
	inline size_t FromIntSize(int size) {
	// Convert to unsigned before widening so sign extension is not necessary.
	return static_cast<unsigned int>(size);
	}

	// For cases where a legacy function returns an integer size. We GOOGLE_DCHECK()
	// that the conversion will fit within an integer; if this is false then we
	// are losing information.
	inline int ToIntSize(size_t size) {
	GOOGLE_DCHECK_LE(size, static_cast<size_t>(INT_MAX));
	return static_cast<int>(size);
	}

	// This type wraps a variable whose constructor and destructor are explicitly
	// called. It is particularly useful for a global variable, without its
	// constructor and destructor run on start and end of the program lifetime.
	// This circumvents the initial construction order fiasco, while keeping
	// the address of the empty string a compile time constant.
	//
	// Pay special attention to the initialization state of the object.
	// 1. The object is "uninitialized" to begin with.
	// 2. Call DefaultConstruct() only if the object is uninitialized.
	// After the call, the object becomes "initialized".
	// 3. Call get() and get_mutable() only if the object is initialized.
	// 4. Call Destruct() only if the object is initialized.
	// After the call, the object becomes uninitialized.
	template <typename T>
	class ExplicitlyConstructed {
	public:
	void DefaultConstruct() {
	new (&union_) T();
	}

	void Destruct() {
	get_mutable()->~T();
	}

	constexpr const T& get() const { return reinterpret_cast<const T&>(union_); }
	T* get_mutable() { return reinterpret_cast<T*>(&union_); }

	private:
	// Prefer c++14 aligned_storage, but for compatibility this will do.
	union AlignedUnion {
	char space[sizeof(T)];
	int64 align_to_int64;
	void* align_to_ptr;
	} union_;
	};

	// Default empty string object. Don't use this directly. Instead, call
	// GetEmptyString() to get the reference.
	LIBPROTOBUF_EXPORT extern ExplicitlyConstructed<::std::string> fixed_address_empty_string;

	LIBPROTOBUF_EXPORT inline const ::std::string& GetEmptyStringAlreadyInited() {
	return fixed_address_empty_string.get();
	}

	LIBPROTOBUF_EXPORT size_t StringSpaceUsedExcludingSelfLong(const string& str);
	#endif // SWIG
	} // namespace internal

	// Interface to light weight protocol messages.
	//
	// This interface is implemented by all protocol message objects. Non-lite
	// messages additionally implement the Message interface, which is a
	// subclass of MessageLite. Use MessageLite instead when you only need
	// the subset of features which it supports -- namely, nothing that uses
	// descriptors or reflection. You can instruct the protocol compiler
	// to generate classes which implement only MessageLite, not the full
	// Message interface, by adding the following line to the .proto file:
	//
	// option optimize_for = LITE_RUNTIME;
	//
	// This is particularly useful on resource-constrained systems where
	// the full protocol buffers runtime library is too big.
	//
	// Note that on non-constrained systems (e.g. servers) when you need
	// to link in lots of protocol definitions, a better way to reduce
	// total code footprint is to use optimize_for = CODE_SIZE. This
	// will make the generated code smaller while still supporting all the
	// same features (at the expense of speed). optimize_for = LITE_RUNTIME
	// is best when you only have a small number of message types linked
	// into your binary, in which case the size of the protocol buffers
	// runtime itself is the biggest problem.
	class LIBPROTOBUF_EXPORT MessageLite {
	public:
	inline MessageLite() {}
	virtual ~MessageLite() {}

	// Basic Operations ------------------------------------------------

	// Get the name of this message type, e.g. "foo.bar.BazProto".
	virtual string GetTypeName() const = 0;

	// Construct a new instance of the same type. Ownership is passed to the
	// caller.
	virtual MessageLite* New() const = 0;

	// Construct a new instance on the arena. Ownership is passed to the caller
	// if arena is a NULL. Default implementation for backwards compatibility.
	virtual MessageLite* New(::google::protobuf::Arena* arena) const;

	// Get the arena, if any, associated with this message. Virtual method
	// required for generic operations but most arena-related operations should
	// use the GetArenaNoVirtual() generated-code method. Default implementation
	// to reduce code size by avoiding the need for per-type implementations
	// when types do not implement arena support.
	virtual ::google::protobuf::Arena* GetArena() const { return NULL; }

	// Get a pointer that may be equal to this message's arena, or may not be.
	// If the value returned by this method is equal to some arena pointer, then
	// this message is on that arena; however, if this message is on some arena,
	// this method may or may not return that arena's pointer. As a tradeoff,
	// this method may be more efficient than GetArena(). The intent is to allow
	// underlying representations that use e.g. tagged pointers to sometimes
	// store the arena pointer directly, and sometimes in a more indirect way,
	// and allow a fastpath comparison against the arena pointer when it's easy
	// to obtain.
	virtual void* GetMaybeArenaPointer() const { return GetArena(); }

	// Clear all fields of the message and set them to their default values.
	// Clear() avoids freeing memory, assuming that any memory allocated
	// to hold parts of the message will be needed again to hold the next
	// message. If you actually want to free the memory used by a Message,
	// you must delete it.
	virtual void Clear() = 0;

	// Quickly check if all required fields have values set.
	virtual bool IsInitialized() const = 0;

	// This is not implemented for Lite messages -- it just returns "(cannot
	// determine missing fields for lite message)". However, it is implemented
	// for full messages. See message.h.
	virtual string InitializationErrorString() const;

	// If \|other\| is the exact same class as this, calls MergeFrom(). Otherwise,
	// results are undefined (probably crash).
	virtual void CheckTypeAndMergeFrom(const MessageLite& other) = 0;

	// Parsing ---------------------------------------------------------
	// Methods for parsing in protocol buffer format. Most of these are
	// just simple wrappers around MergeFromCodedStream(). Clear() will be
	// called before merging the input.

	// Fill the message with a protocol buffer parsed from the given input
	// stream. Returns false on a read error or if the input is in the wrong
	// format. A successful return does not indicate the entire input is
	// consumed, ensure you call ConsumedEntireMessage() to check that if
	// applicable.
	bool ParseFromCodedStream(io::CodedInputStream* input);
	// Like ParseFromCodedStream(), but accepts messages that are missing
	// required fields.
	bool ParsePartialFromCodedStream(io::CodedInputStream* input);
	// Read a protocol buffer from the given zero-copy input stream. If
	// successful, the entire input will be consumed.
	bool ParseFromZeroCopyStream(io::ZeroCopyInputStream* input);
	// Like ParseFromZeroCopyStream(), but accepts messages that are missing
	// required fields.
	bool ParsePartialFromZeroCopyStream(io::ZeroCopyInputStream* input);
	// Read a protocol buffer from the given zero-copy input stream, expecting
	// the message to be exactly "size" bytes long. If successful, exactly
	// this many bytes will have been consumed from the input.
	bool ParseFromBoundedZeroCopyStream(io::ZeroCopyInputStream* input, int size);
	// Like ParseFromBoundedZeroCopyStream(), but accepts messages that are
	// missing required fields.
	bool ParsePartialFromBoundedZeroCopyStream(io::ZeroCopyInputStream* input,
	int size);
	// Parses a protocol buffer contained in a string. Returns true on success.
	// This function takes a string in the (non-human-readable) binary wire
	// format, matching the encoding output by MessageLite::SerializeToString().
	// If you'd like to convert a human-readable string into a protocol buffer
	// object, see google::protobuf::TextFormat::ParseFromString().
	bool ParseFromString(const string& data);
	// Like ParseFromString(), but accepts messages that are missing
	// required fields.
	bool ParsePartialFromString(const string& data);
	// Parse a protocol buffer contained in an array of bytes.
	bool ParseFromArray(const void* data, int size);
	// Like ParseFromArray(), but accepts messages that are missing
	// required fields.
	bool ParsePartialFromArray(const void* data, int size);


	// Reads a protocol buffer from the stream and merges it into this
	// Message. Singular fields read from the what is
	// already in the Message and repeated fields are appended to those
	// already present.
	//
	// It is the responsibility of the caller to call input->LastTagWas()
	// (for groups) or input->ConsumedEntireMessage() (for non-groups) after
	// this returns to verify that the message's end was delimited correctly.
	//
	// ParsefromCodedStream() is implemented as Clear() followed by
	// MergeFromCodedStream().
	bool MergeFromCodedStream(io::CodedInputStream* input);

	// Like MergeFromCodedStream(), but succeeds even if required fields are
	// missing in the input.
	//
	// MergeFromCodedStream() is just implemented as MergePartialFromCodedStream()
	// followed by IsInitialized().
	virtual bool MergePartialFromCodedStream(io::CodedInputStream* input) = 0;


	// Serialization ---------------------------------------------------
	// Methods for serializing in protocol buffer format. Most of these
	// are just simple wrappers around ByteSize() and SerializeWithCachedSizes().

	// Write a protocol buffer of this message to the given output. Returns
	// false on a write error. If the message is missing required fields,
	// this may GOOGLE_CHECK-fail.
	bool SerializeToCodedStream(io::CodedOutputStream* output) const;
	// Like SerializeToCodedStream(), but allows missing required fields.
	bool SerializePartialToCodedStream(io::CodedOutputStream* output) const;
	// Write the message to the given zero-copy output stream. All required
	// fields must be set.
	bool SerializeToZeroCopyStream(io::ZeroCopyOutputStream* output) const;
	// Like SerializeToZeroCopyStream(), but allows missing required fields.
	bool SerializePartialToZeroCopyStream(io::ZeroCopyOutputStream* output) const;
	// Serialize the message and store it in the given string. All required
	// fields must be set.
	bool SerializeToString(string* output) const;
	// Like SerializeToString(), but allows missing required fields.
	bool SerializePartialToString(string* output) const;
	// Serialize the message and store it in the given byte array. All required
	// fields must be set.
	bool SerializeToArray(void* data, int size) const;
	// Like SerializeToArray(), but allows missing required fields.
	bool SerializePartialToArray(void* data, int size) const;

	// Make a string encoding the message. Is equivalent to calling
	// SerializeToString() on a string and using that. Returns the empty
	// string if SerializeToString() would have returned an error.
	// Note: If you intend to generate many such strings, you may
	// reduce heap fragmentation by instead re-using the same string
	// object with calls to SerializeToString().
	string SerializeAsString() const;
	// Like SerializeAsString(), but allows missing required fields.
	string SerializePartialAsString() const;

	// Like SerializeToString(), but appends to the data to the string's existing
	// contents. All required fields must be set.
	bool AppendToString(string* output) const;
	// Like AppendToString(), but allows missing required fields.
	bool AppendPartialToString(string* output) const;

	// Computes the serialized size of the message. This recursively calls
	// ByteSizeLong() on all embedded messages.
	//
	// ByteSizeLong() is generally linear in the number of fields defined for the
	// proto.
	virtual size_t ByteSizeLong() const = 0;

	// Legacy ByteSize() API.
	PROTOBUF_RUNTIME_DEPRECATED("Please use ByteSizeLong() instead")
	int ByteSize() const {
	return internal::ToIntSize(ByteSizeLong());
	}

	// Serializes the message without recomputing the size. The message must not
	// have changed since the last call to ByteSize(), and the value returned by
	// ByteSize must be non-negative. Otherwise the results are undefined.
	virtual void SerializeWithCachedSizes(
	io::CodedOutputStream* output) const;

	// Functions below here are not part of the public interface. It isn't
	// enforced, but they should be treated as private, and will be private
	// at some future time. Unfortunately the implementation of the "friend"
	// keyword in GCC is broken at the moment, but we expect it will be fixed.

	// Like SerializeWithCachedSizes, but writes directly to *target, returning
	// a pointer to the byte immediately after the last byte written. "target"
	// must point at a byte array of at least ByteSize() bytes. Whether to use
	// deterministic serialization, e.g., maps in sorted order, is determined by
	// CodedOutputStream::IsDefaultSerializationDeterministic().
	virtual uint8* SerializeWithCachedSizesToArray(uint8* target) const;

	// Returns the result of the last call to ByteSize(). An embedded message's
	// size is needed both to serialize it (because embedded messages are
	// length-delimited) and to compute the outer message's size. Caching
	// the size avoids computing it multiple times.
	//
	// ByteSize() does not automatically use the cached size when available
	// because this would require invalidating it every time the message was
	// modified, which would be too hard and expensive. (E.g. if a deeply-nested
	// sub-message is changed, all of its parents' cached sizes would need to be
	// invalidated, which is too much work for an otherwise inlined setter
	// method.)
	virtual int GetCachedSize() const = 0;

	virtual uint8* InternalSerializeWithCachedSizesToArray(bool deterministic,
	uint8* target) const;

	protected:
	// CastToBase allows generated code to cast a RepeatedPtrField<T> to
	// RepeatedPtrFieldBase. We try to restrict access to RepeatedPtrFieldBase
	// because it is an implementation detail that user code should not access
	// directly.
	template <typename T>
	static ::google::protobuf::internal::RepeatedPtrFieldBase* CastToBase(
	::google::protobuf::RepeatedPtrField<T>* repeated) {
	return repeated;
	}
	template <typename T>
	static const ::google::protobuf::internal::RepeatedPtrFieldBase& CastToBase(
	const ::google::protobuf::RepeatedPtrField<T>& repeated) {
	return repeated;
	}

	template <typename T>
	static T* CreateMaybeMessage(Arena* arena) {
	return Arena::CreateMaybeMessage<T>(arena);
	}

	private:
	// TODO(gerbens) make this a pure abstract function
	virtual const void* InternalGetTable() const { return NULL; }

	friend class internal::WireFormatLite;
	friend class Message;
	friend class internal::WeakFieldMap;

	GOOGLE_DISALLOW_EVIL_CONSTRUCTORS(MessageLite);
	};

	namespace internal {

	extern bool LIBPROTOBUF_EXPORT proto3_preserve_unknown_;

	// DO NOT USE: For migration only. Will be removed when Proto3 defaults to
	// preserve unknowns.
	inline bool GetProto3PreserveUnknownsDefault() {
	return proto3_preserve_unknown_;
	}

	// DO NOT USE: For migration only. Will be removed when Proto3 defaults to
	// preserve unknowns.
	void LIBPROTOBUF_EXPORT SetProto3PreserveUnknownsDefault(bool preserve);
	} // namespace internal


	} // namespace protobuf

	} // namespace google
	#endif // GOOGLE_PROTOBUF_MESSAGE_LITE_H__