src/ProtocolBuffers/IMessageLite.cs - platform/external/protobuf-javalite - Gitiles

 #region Copyright notice and license
 // Protocol Buffers - Google's data interchange format
 // Copyright 2008 Google Inc.  All rights reserved.
 // http://github.com/jskeet/dotnet-protobufs/
 // Original C++/Java/Python code:
 // http://code.google.com/p/protobuf/
 //
 // 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.
 #endregion

 using System;
 using System.Collections.Generic;
 using System.IO;
 using Google.ProtocolBuffers.Descriptors;

 namespace Google.ProtocolBuffers {

   /// <summary>
   /// Non-generic interface used for all parts of the API which don't require
   /// any type knowledge.
   /// </summary>
   public interface IMessage {
     /// <summary>
     /// Returns the message's type's descriptor. This differs from the
     /// Descriptor property of each generated message class in that this
     /// method is an abstract method of IMessage whereas Descriptor is
     /// a static property of a specific class. They return the same thing.
     /// </summary>
     MessageDescriptor DescriptorForType { get; }
     /// <summary>
     /// Returns a collection of all the fields in this message which are set
     /// and their corresponding values.  A singular ("required" or "optional")
     /// field is set iff HasField() returns true for that field.  A "repeated"
     /// field is set iff GetRepeatedFieldSize() is greater than zero.  The
     /// values are exactly what would be returned by calling
     /// GetField(FieldDescriptor) for each field.  The map
     /// is guaranteed to be a sorted map, so iterating over it will return fields
     /// in order by field number.
     /// </summary>
     IDictionary<FieldDescriptor, object> AllFields { get; }

     /// <summary>
     /// Returns true if the given field is set. This is exactly equivalent
     /// to calling the generated "Has" property corresponding to the field.
     /// </summary>
     /// <exception cref="ArgumentException">the field is a repeated field,
     /// or it's not a field of this type</exception>
     bool HasField(FieldDescriptor field);

     /// <summary>
     /// Obtains the value of the given field, or the default value if
     /// it isn't set. For value type fields, the boxed value is returned.
     /// For enum fields, the EnumValueDescriptor for the enum is returned.
     /// For embedded message fields, the sub-message
     /// is returned. For repeated fields, an IList&lt;T&gt; is returned.
     /// </summary>
     object this[FieldDescriptor field] { get; }

     /// <summary>
     /// Returns the number of elements of a repeated field. This is
     /// exactly equivalent to calling the generated "Count" property
     /// corresponding to the field.
     /// </summary>
     /// <exception cref="ArgumentException">the field is not a repeated field,
     /// or it's not a field of this type</exception>
     int GetRepeatedFieldCount(FieldDescriptor field);

     /// <summary>
     /// Gets an element of a repeated field. For value type fields
     /// excluding enums, the boxed value is returned. For embedded
     /// message fields, the sub-message is returned. For enums, the
     /// relevant EnumValueDescriptor is returned.
     /// </summary>
     /// <exception cref="ArgumentException">the field is not a repeated field,
     /// or it's not a field of this type</exception>
     /// <exception cref="ArgumentOutOfRangeException">the index is out of
     /// range for the repeated field's value</exception>
     object this[FieldDescriptor field, int index] { get; }

     /// <summary>
     /// Returns the unknown fields for this message.
     /// </summary>
     UnknownFieldSet UnknownFields { get; }

     /// <summary>
     /// Returns true iff all required fields in the message and all embedded
     /// messages are set.
     /// </summary>
     bool IsInitialized { get; }

     /// <summary>
     /// Serializes the message and writes it to the given output stream.
     /// This does not flush or close the stream.
     /// </summary>
     /// <remarks>
     /// Protocol Buffers are not self-delimiting. Therefore, if you write
     /// any more data to the stream after the message, you must somehow ensure
     /// that the parser on the receiving end does not interpret this as being
     /// part of the protocol message. One way of doing this is by writing the size
     /// of the message before the data, then making sure you limit the input to
     /// that size when receiving the data. Alternatively, use WriteDelimitedTo(Stream).
     /// </remarks>
     void WriteTo(CodedOutputStream output);

     /// <summary>
     /// Like WriteTo(Stream) but writes the size of the message as a varint before
     /// writing the data. This allows more data to be written to the stream after the
     /// message without the need to delimit the message data yourself. Use
     /// IBuilder.MergeDelimitedFrom(Stream) or the static method
     /// YourMessageType.ParseDelimitedFrom(Stream) to parse messages written by this method.
     /// </summary>
     /// <param name="output"></param>
     void WriteDelimitedTo(Stream output);

     /// <summary>
     /// Returns the number of bytes required to encode this message.
     /// The result is only computed on the first call and memoized after that.
     /// </summary>
     int SerializedSize { get; }

     #region Comparison and hashing
     /// <summary>
     /// Compares the specified object with this message for equality.
     /// Returns true iff the given object is a message of the same type
     /// (as defined by DescriptorForType) and has identical values
     /// for all its fields.
     /// </summary>
     bool Equals(object other);

     /// <summary>
     /// Returns the hash code value for this message.
     /// TODO(jonskeet): Specify the hash algorithm, but better than the Java one!
     /// </summary>
     int GetHashCode();
     #endregion

     #region Convenience methods
     /// <summary>
     /// Converts the message to a string in protocol buffer text format.
     /// This is just a trivial wrapper around TextFormat.PrintToString.
     /// </summary>
     string ToString();

     /// <summary>
     /// Serializes the message to a ByteString. This is a trivial wrapper
     /// around WriteTo(CodedOutputStream).
     /// </summary>
     ByteString ToByteString();

     /// <summary>
     /// Serializes the message to a byte array. This is a trivial wrapper
     /// around WriteTo(CodedOutputStream).
     /// </summary>
     byte[] ToByteArray();

     /// <summary>
     /// Serializes the message and writes it to the given stream.
     /// This is just a wrapper around WriteTo(CodedOutputStream). This
     /// does not flush or close the stream.
     /// </summary>
     /// <param name="output"></param>
     void WriteTo(Stream output);
     #endregion

     /// <summary>
     /// Creates a builder for the type, but in a weakly typed manner. This
     /// is typically implemented by strongly typed messages by just returning
     /// the result of CreateBuilderForType.
     /// </summary>
     IBuilder WeakCreateBuilderForType();

     /// <summary>
     /// Creates a builder with the same contents as this message. This
     /// is typically implemented by strongly typed messages by just returning
     /// the result of ToBuilder.
     /// </summary>
     IBuilder WeakToBuilder();

     IMessage WeakDefaultInstanceForType { get; }
   }

   public interface IMessage<TMessage> : IMessage {
     /// <summary>
     /// Returns an instance of this message type with all fields set to
     /// their default values. This may or may not be a singleton. This differs
     /// from the DefaultInstance property of each generated message class in that this
     /// method is an abstract method of IMessage whereas DefaultInstance is
     /// a static property of a specific class. They return the same thing.
     /// </summary>
     TMessage DefaultInstanceForType { get; }
   }

   /// <summary>
   /// Type-safe interface for all generated messages to implement.
   /// </summary>
   public interface IMessage<TMessage, TBuilder> : IMessage<TMessage>
       where TMessage : IMessage<TMessage, TBuilder>
       where TBuilder : IBuilder<TMessage, TBuilder> {
     #region Builders
     /// <summary>
     /// Constructs a new builder for a message of the same type as this message.
     /// </summary>
     TBuilder CreateBuilderForType();
     /// <summary>
     /// Creates a builder with the same contents as this current instance.
     /// This is typically implemented by strongly typed messages by just
     /// returning the result of ToBuilder().
     /// </summary>
     TBuilder ToBuilder();
     #endregion
   }
 }
	#region Copyright notice and license
	// Protocol Buffers - Google's data interchange format
	// Copyright 2008 Google Inc. All rights reserved.
	// http://github.com/jskeet/dotnet-protobufs/
	// Original C++/Java/Python code:
	// http://code.google.com/p/protobuf/
	//
	// 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.
	#endregion

	using System;
	using System.Collections.Generic;
	using System.IO;
	using Google.ProtocolBuffers.Descriptors;

	namespace Google.ProtocolBuffers {

	/// <summary>
	/// Non-generic interface used for all parts of the API which don't require
	/// any type knowledge.
	/// </summary>
	public interface IMessage {
	/// <summary>
	/// Returns the message's type's descriptor. This differs from the
	/// Descriptor property of each generated message class in that this
	/// method is an abstract method of IMessage whereas Descriptor is
	/// a static property of a specific class. They return the same thing.
	/// </summary>
	MessageDescriptor DescriptorForType { get; }
	/// <summary>
	/// Returns a collection of all the fields in this message which are set
	/// and their corresponding values. A singular ("required" or "optional")
	/// field is set iff HasField() returns true for that field. A "repeated"
	/// field is set iff GetRepeatedFieldSize() is greater than zero. The
	/// values are exactly what would be returned by calling
	/// GetField(FieldDescriptor) for each field. The map
	/// is guaranteed to be a sorted map, so iterating over it will return fields
	/// in order by field number.
	/// </summary>
	IDictionary<FieldDescriptor, object> AllFields { get; }

	/// <summary>
	/// Returns true if the given field is set. This is exactly equivalent
	/// to calling the generated "Has" property corresponding to the field.
	/// </summary>
	/// <exception cref="ArgumentException">the field is a repeated field,
	/// or it's not a field of this type</exception>
	bool HasField(FieldDescriptor field);

	/// <summary>
	/// Obtains the value of the given field, or the default value if
	/// it isn't set. For value type fields, the boxed value is returned.
	/// For enum fields, the EnumValueDescriptor for the enum is returned.
	/// For embedded message fields, the sub-message
	/// is returned. For repeated fields, an IList<T> is returned.
	/// </summary>
	object this[FieldDescriptor field] { get; }

	/// <summary>
	/// Returns the number of elements of a repeated field. This is
	/// exactly equivalent to calling the generated "Count" property
	/// corresponding to the field.
	/// </summary>
	/// <exception cref="ArgumentException">the field is not a repeated field,
	/// or it's not a field of this type</exception>
	int GetRepeatedFieldCount(FieldDescriptor field);

	/// <summary>
	/// Gets an element of a repeated field. For value type fields
	/// excluding enums, the boxed value is returned. For embedded
	/// message fields, the sub-message is returned. For enums, the
	/// relevant EnumValueDescriptor is returned.
	/// </summary>
	/// <exception cref="ArgumentException">the field is not a repeated field,
	/// or it's not a field of this type</exception>
	/// <exception cref="ArgumentOutOfRangeException">the index is out of
	/// range for the repeated field's value</exception>
	object this[FieldDescriptor field, int index] { get; }

	/// <summary>
	/// Returns the unknown fields for this message.
	/// </summary>
	UnknownFieldSet UnknownFields { get; }

	/// <summary>
	/// Returns true iff all required fields in the message and all embedded
	/// messages are set.
	/// </summary>
	bool IsInitialized { get; }

	/// <summary>
	/// Serializes the message and writes it to the given output stream.
	/// This does not flush or close the stream.
	/// </summary>
	/// <remarks>
	/// Protocol Buffers are not self-delimiting. Therefore, if you write
	/// any more data to the stream after the message, you must somehow ensure
	/// that the parser on the receiving end does not interpret this as being
	/// part of the protocol message. One way of doing this is by writing the size
	/// of the message before the data, then making sure you limit the input to
	/// that size when receiving the data. Alternatively, use WriteDelimitedTo(Stream).
	/// </remarks>
	void WriteTo(CodedOutputStream output);

	/// <summary>
	/// Like WriteTo(Stream) but writes the size of the message as a varint before
	/// writing the data. This allows more data to be written to the stream after the
	/// message without the need to delimit the message data yourself. Use
	/// IBuilder.MergeDelimitedFrom(Stream) or the static method
	/// YourMessageType.ParseDelimitedFrom(Stream) to parse messages written by this method.
	/// </summary>
	/// <param name="output"></param>
	void WriteDelimitedTo(Stream output);

	/// <summary>
	/// Returns the number of bytes required to encode this message.
	/// The result is only computed on the first call and memoized after that.
	/// </summary>
	int SerializedSize { get; }

	#region Comparison and hashing
	/// <summary>
	/// Compares the specified object with this message for equality.
	/// Returns true iff the given object is a message of the same type
	/// (as defined by DescriptorForType) and has identical values
	/// for all its fields.
	/// </summary>
	bool Equals(object other);

	/// <summary>
	/// Returns the hash code value for this message.
	/// TODO(jonskeet): Specify the hash algorithm, but better than the Java one!
	/// </summary>
	int GetHashCode();
	#endregion

	#region Convenience methods
	/// <summary>
	/// Converts the message to a string in protocol buffer text format.
	/// This is just a trivial wrapper around TextFormat.PrintToString.
	/// </summary>
	string ToString();

	/// <summary>
	/// Serializes the message to a ByteString. This is a trivial wrapper
	/// around WriteTo(CodedOutputStream).
	/// </summary>
	ByteString ToByteString();

	/// <summary>
	/// Serializes the message to a byte array. This is a trivial wrapper
	/// around WriteTo(CodedOutputStream).
	/// </summary>
	byte[] ToByteArray();

	/// <summary>
	/// Serializes the message and writes it to the given stream.
	/// This is just a wrapper around WriteTo(CodedOutputStream). This
	/// does not flush or close the stream.
	/// </summary>
	/// <param name="output"></param>
	void WriteTo(Stream output);
	#endregion

	/// <summary>
	/// Creates a builder for the type, but in a weakly typed manner. This
	/// is typically implemented by strongly typed messages by just returning
	/// the result of CreateBuilderForType.
	/// </summary>
	IBuilder WeakCreateBuilderForType();

	/// <summary>
	/// Creates a builder with the same contents as this message. This
	/// is typically implemented by strongly typed messages by just returning
	/// the result of ToBuilder.
	/// </summary>
	IBuilder WeakToBuilder();

	IMessage WeakDefaultInstanceForType { get; }
	}

	public interface IMessage<TMessage> : IMessage {
	/// <summary>
	/// Returns an instance of this message type with all fields set to
	/// their default values. This may or may not be a singleton. This differs
	/// from the DefaultInstance property of each generated message class in that this
	/// method is an abstract method of IMessage whereas DefaultInstance is
	/// a static property of a specific class. They return the same thing.
	/// </summary>
	TMessage DefaultInstanceForType { get; }
	}

	/// <summary>
	/// Type-safe interface for all generated messages to implement.
	/// </summary>
	public interface IMessage<TMessage, TBuilder> : IMessage<TMessage>
	where TMessage : IMessage<TMessage, TBuilder>
	where TBuilder : IBuilder<TMessage, TBuilder> {
	#region Builders
	/// <summary>
	/// Constructs a new builder for a message of the same type as this message.
	/// </summary>
	TBuilder CreateBuilderForType();
	/// <summary>
	/// Creates a builder with the same contents as this current instance.
	/// This is typically implemented by strongly typed messages by just
	/// returning the result of ToBuilder().
	/// </summary>
	TBuilder ToBuilder();
	#endregion
	}
	}