// <auto-generated>

// Generated by the protocol buffer compiler. DO NOT EDIT!

// source: tensorflow/core/framework/node_def.proto

// </auto-generated>

#pragma warning disable 1591, 0612, 3021

#region Designer generated code

using pb = global::Google.Protobuf;

using pbc = global::Google.Protobuf.Collections;

using pbr = global::Google.Protobuf.Reflection;

using scg = global::System.Collections.Generic;

namespace Tensorflow {

/// <summary>Holder for reflection information generated from tensorflow/core/framework/node_def.proto</summary>

public static partial class NodeDefReflection {

#region Descriptor

/// <summary>File descriptor for tensorflow/core/framework/node_def.proto</summary>

public static pbr::FileDescriptor Descriptor {

get { return descriptor; }

}

private static pbr::FileDescriptor descriptor;

static NodeDefReflection() {

byte[] descriptorData = global::System.Convert.FromBase64String(

string.Concat(

"Cih0ZW5zb3JmbG93L2NvcmUvZnJhbWV3b3JrL25vZGVfZGVmLnByb3RvEgp0",

"ZW5zb3JmbG93Gip0ZW5zb3JmbG93L2NvcmUvZnJhbWV3b3JrL2F0dHJfdmFs",

"dWUucHJvdG8i0gIKB05vZGVEZWYSDAoEbmFtZRgBIAEoCRIKCgJvcBgCIAEo",

"CRINCgVpbnB1dBgDIAMoCRIOCgZkZXZpY2UYBCABKAkSKwoEYXR0chgFIAMo",

"CzIdLnRlbnNvcmZsb3cuTm9kZURlZi5BdHRyRW50cnkSSgoXZXhwZXJpbWVu",

"dGFsX2RlYnVnX2luZm8YBiABKAsyKS50ZW5zb3JmbG93Lk5vZGVEZWYuRXhw",

"ZXJpbWVudGFsRGVidWdJbmZvGkIKCUF0dHJFbnRyeRILCgNrZXkYASABKAkS",

"JAoFdmFsdWUYAiABKAsyFS50ZW5zb3JmbG93LkF0dHJWYWx1ZToCOAEaUQoV",

"RXhwZXJpbWVudGFsRGVidWdJbmZvEhsKE29yaWdpbmFsX25vZGVfbmFtZXMY",

"ASADKAkSGwoTb3JpZ2luYWxfZnVuY19uYW1lcxgCIAMoCUJ7ChhvcmcudGVu",

"c29yZmxvdy5mcmFtZXdvcmtCCU5vZGVQcm90b1ABWk9naXRodWIuY29tL3Rl",

"bnNvcmZsb3cvdGVuc29yZmxvdy90ZW5zb3JmbG93L2dvL2NvcmUvZnJhbWV3",

"b3JrL25vZGVfZGVmX2dvX3Byb3Rv+AEBYgZwcm90bzM="));

descriptor = pbr::FileDescriptor.FromGeneratedCode(descriptorData,

new pbr::FileDescriptor[] { global::Tensorflow.AttrValueReflection.Descriptor, },

new pbr::GeneratedClrTypeInfo(null, null, new pbr::GeneratedClrTypeInfo[] {

new pbr::GeneratedClrTypeInfo(typeof(global::Tensorflow.NodeDef), global::Tensorflow.NodeDef.Parser, new[]{ "Name", "Op", "Input", "Device", "Attr", "ExperimentalDebugInfo" }, null, null, null, new pbr::GeneratedClrTypeInfo[] { null, new pbr::GeneratedClrTypeInfo(typeof(global::Tensorflow.NodeDef.Types.ExperimentalDebugInfo), global::Tensorflow.NodeDef.Types.ExperimentalDebugInfo.Parser, new[]{ "OriginalNodeNames", "OriginalFuncNames" }, null, null, null, null)})

}));

}

#endregion

}

#region Messages

public sealed partial class NodeDef : pb::IMessage<NodeDef> {

private static readonly pb::MessageParser<NodeDef> _parser = new pb::MessageParser<NodeDef>(() => new NodeDef());

private pb::UnknownFieldSet _unknownFields;

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public static pb::MessageParser<NodeDef> Parser { get { return _parser; } }

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public static pbr::MessageDescriptor Descriptor {

get { return global::Tensorflow.NodeDefReflection.Descriptor.MessageTypes[0]; }

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

pbr::MessageDescriptor pb::IMessage.Descriptor {

get { return Descriptor; }

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public NodeDef() {

OnConstruction();

}

partial void OnConstruction();

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public NodeDef(NodeDef other) : this() {

name_ = other.name_;

op_ = other.op_;

input_ = other.input_.Clone();

device_ = other.device_;

attr_ = other.attr_.Clone();

experimentalDebugInfo_ = other.experimentalDebugInfo_ != null ? other.experimentalDebugInfo_.Clone() : null;

_unknownFields = pb::UnknownFieldSet.Clone(other._unknownFields);

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public NodeDef Clone() {

return new NodeDef(this);

}

/// <summary>Field number for the "name" field.</summary>

public const int NameFieldNumber = 1;

private string name_ = "";

/// <summary>

/// The name given to this operator. Used for naming inputs,

/// logging, visualization, etc. Unique within a single GraphDef.

/// Must match the regexp "[A-Za-z0-9.][A-Za-z0-9_>./]*".

/// </summary>

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public string Name {

get { return name_; }

set {

name_ = pb::ProtoPreconditions.CheckNotNull(value, "value");

}

}

/// <summary>Field number for the "op" field.</summary>

public const int OpFieldNumber = 2;

private string op_ = "";

/// <summary>

/// The operation name. There may be custom parameters in attrs.

/// Op names starting with an underscore are reserved for internal use.

/// </summary>

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public string Op {

get { return op_; }

set {

op_ = pb::ProtoPreconditions.CheckNotNull(value, "value");

}

}

/// <summary>Field number for the "input" field.</summary>

public const int InputFieldNumber = 3;

private static readonly pb::FieldCodec<string> _repeated_input_codec

= pb::FieldCodec.ForString(26);

private readonly pbc::RepeatedField<string> input_ = new pbc::RepeatedField<string>();

/// <summary>

/// Each input is "node:src_output" with "node" being a string name and

/// "src_output" indicating which output tensor to use from "node". If

/// "src_output" is 0 the ":0" suffix can be omitted. Regular inputs

/// may optionally be followed by control inputs that have the format

/// "^node".

/// </summary>

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public pbc::RepeatedField<string> Input {

get { return input_; }

}

/// <summary>Field number for the "device" field.</summary>

public const int DeviceFieldNumber = 4;

private string device_ = "";

/// <summary>

/// A (possibly partial) specification for the device on which this

/// node should be placed.

/// The expected syntax for this string is as follows:

///

/// DEVICE_SPEC ::= PARTIAL_SPEC

///

/// PARTIAL_SPEC ::= ("/" CONSTRAINT) *

/// CONSTRAINT ::= ("job:" JOB_NAME)

/// | ("replica:" [1-9][0-9]*)

/// | ("task:" [1-9][0-9]*)

/// | ("device:" [A-Za-z]* ":" ([1-9][0-9]* | "*") )

///

/// Valid values for this string include:

/// * "/job:worker/replica:0/task:1/device:GPU:3" (full specification)

/// * "/job:worker/device:GPU:3" (partial specification)

/// * "" (no specification)

///

/// If the constraints do not resolve to a single device (or if this

/// field is empty or not present), the runtime will attempt to

/// choose a device automatically.

/// </summary>

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public string Device {

get { return device_; }

set {

device_ = pb::ProtoPreconditions.CheckNotNull(value, "value");

}

}

/// <summary>Field number for the "attr" field.</summary>

public const int AttrFieldNumber = 5;

private static readonly pbc::MapField<string, global::Tensorflow.AttrValue>.Codec _map_attr_codec

= new pbc::MapField<string, global::Tensorflow.AttrValue>.Codec(pb::FieldCodec.ForString(10, ""), pb::FieldCodec.ForMessage(18, global::Tensorflow.AttrValue.Parser), 42);

private readonly pbc::MapField<string, global::Tensorflow.AttrValue> attr_ = new pbc::MapField<string, global::Tensorflow.AttrValue>();

/// <summary>

/// Operation-specific graph-construction-time configuration.

/// Note that this should include all attrs defined in the

/// corresponding OpDef, including those with a value matching

/// the default -- this allows the default to change and makes

/// NodeDefs easier to interpret on their own. However, if

/// an attr with a default is not specified in this list, the

/// default will be used.

/// The "names" (keys) must match the regexp "[a-z][a-z0-9_]+" (and

/// one of the names from the corresponding OpDef's attr field).

/// The values must have a type matching the corresponding OpDef

/// attr's type field.

/// TODO(josh11b): Add some examples here showing best practices.

/// </summary>

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public pbc::MapField<string, global::Tensorflow.AttrValue> Attr {

get { return attr_; }

}

/// <summary>Field number for the "experimental_debug_info" field.</summary>

public const int ExperimentalDebugInfoFieldNumber = 6;

private global::Tensorflow.NodeDef.Types.ExperimentalDebugInfo experimentalDebugInfo_;

/// <summary>

/// This stores debug information associated with the node.

/// </summary>

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public global::Tensorflow.NodeDef.Types.ExperimentalDebugInfo ExperimentalDebugInfo {

get { return experimentalDebugInfo_; }

set {

experimentalDebugInfo_ = value;

}

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public override bool Equals(object other) {

return Equals(other as NodeDef);

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public bool Equals(NodeDef other) {

if (ReferenceEquals(other, null)) {

return false;

}

if (ReferenceEquals(other, this)) {

return true;

}

if (Name != other.Name) return false;

if (Op != other.Op) return false;

if(!input_.Equals(other.input_)) return false;

if (Device != other.Device) return false;

if (!Attr.Equals(other.Attr)) return false;

if (!object.Equals(ExperimentalDebugInfo, other.ExperimentalDebugInfo)) return false;

return Equals(_unknownFields, other._unknownFields);

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public override int GetHashCode() {

int hash = 1;

if (Name.Length != 0) hash ^= Name.GetHashCode();

if (Op.Length != 0) hash ^= Op.GetHashCode();

hash ^= input_.GetHashCode();

if (Device.Length != 0) hash ^= Device.GetHashCode();

hash ^= Attr.GetHashCode();

if (experimentalDebugInfo_ != null) hash ^= ExperimentalDebugInfo.GetHashCode();

if (_unknownFields != null) {

hash ^= _unknownFields.GetHashCode();

}

return hash;

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public override string ToString() {

return pb::JsonFormatter.ToDiagnosticString(this);

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public void WriteTo(pb::CodedOutputStream output) {

if (Name.Length != 0) {

output.WriteRawTag(10);

output.WriteString(Name);

}

if (Op.Length != 0) {

output.WriteRawTag(18);

output.WriteString(Op);

}

input_.WriteTo(output, _repeated_input_codec);

if (Device.Length != 0) {

output.WriteRawTag(34);

output.WriteString(Device);

}

attr_.WriteTo(output, _map_attr_codec);

if (experimentalDebugInfo_ != null) {

output.WriteRawTag(50);

output.WriteMessage(ExperimentalDebugInfo);

}

if (_unknownFields != null) {

_unknownFields.WriteTo(output);

}

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public int CalculateSize() {

int size = 0;

if (Name.Length != 0) {

size += 1 + pb::CodedOutputStream.ComputeStringSize(Name);

}

if (Op.Length != 0) {

size += 1 + pb::CodedOutputStream.ComputeStringSize(Op);

}

size += input_.CalculateSize(_repeated_input_codec);

if (Device.Length != 0) {

size += 1 + pb::CodedOutputStream.ComputeStringSize(Device);

}

size += attr_.CalculateSize(_map_attr_codec);

if (experimentalDebugInfo_ != null) {

size += 1 + pb::CodedOutputStream.ComputeMessageSize(ExperimentalDebugInfo);

}

if (_unknownFields != null) {

size += _unknownFields.CalculateSize();

}

return size;

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public void MergeFrom(NodeDef other) {

if (other == null) {

return;

}

if (other.Name.Length != 0) {

Name = other.Name;

}

if (other.Op.Length != 0) {

Op = other.Op;

}

input_.Add(other.input_);

if (other.Device.Length != 0) {

Device = other.Device;

}

attr_.Add(other.attr_);

if (other.experimentalDebugInfo_ != null) {

if (experimentalDebugInfo_ == null) {

ExperimentalDebugInfo = new global::Tensorflow.NodeDef.Types.ExperimentalDebugInfo();

}

ExperimentalDebugInfo.MergeFrom(other.ExperimentalDebugInfo);

}

_unknownFields = pb::UnknownFieldSet.MergeFrom(_unknownFields, other._unknownFields);

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public void MergeFrom(pb::CodedInputStream input) {

uint tag;

while ((tag = input.ReadTag()) != 0) {

switch(tag) {

default:

_unknownFields = pb::UnknownFieldSet.MergeFieldFrom(_unknownFields, input);

break;

case 10: {

Name = input.ReadString();

break;

}

case 18: {

Op = input.ReadString();

break;

}

case 26: {

input_.AddEntriesFrom(input, _repeated_input_codec);

break;

}

case 34: {

Device = input.ReadString();

break;

}

case 42: {

attr_.AddEntriesFrom(input, _map_attr_codec);

break;

}

case 50: {

if (experimentalDebugInfo_ == null) {

ExperimentalDebugInfo = new global::Tensorflow.NodeDef.Types.ExperimentalDebugInfo();

}

input.ReadMessage(ExperimentalDebugInfo);

break;

}

}

}

}

#region Nested types

/// <summary>Container for nested types declared in the NodeDef message type.</summary>

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public static partial class Types {

public sealed partial class ExperimentalDebugInfo : pb::IMessage<ExperimentalDebugInfo> {

private static readonly pb::MessageParser<ExperimentalDebugInfo> _parser = new pb::MessageParser<ExperimentalDebugInfo>(() => new ExperimentalDebugInfo());

private pb::UnknownFieldSet _unknownFields;

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public static pb::MessageParser<ExperimentalDebugInfo> Parser { get { return _parser; } }

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public static pbr::MessageDescriptor Descriptor {

get { return global::Tensorflow.NodeDef.Descriptor.NestedTypes[1]; }

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

pbr::MessageDescriptor pb::IMessage.Descriptor {

get { return Descriptor; }

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public ExperimentalDebugInfo() {

OnConstruction();

}

partial void OnConstruction();

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public ExperimentalDebugInfo(ExperimentalDebugInfo other) : this() {

originalNodeNames_ = other.originalNodeNames_.Clone();

originalFuncNames_ = other.originalFuncNames_.Clone();

_unknownFields = pb::UnknownFieldSet.Clone(other._unknownFields);

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public ExperimentalDebugInfo Clone() {

return new ExperimentalDebugInfo(this);

}

/// <summary>Field number for the "original_node_names" field.</summary>

public const int OriginalNodeNamesFieldNumber = 1;

private static readonly pb::FieldCodec<string> _repeated_originalNodeNames_codec

= pb::FieldCodec.ForString(10);

private readonly pbc::RepeatedField<string> originalNodeNames_ = new pbc::RepeatedField<string>();

/// <summary>

/// Opaque string inserted into error messages created by the runtime.

///

/// This is intended to store the list of names of the nodes from the

/// original graph that this node was derived. For example if this node, say

/// C, was result of a fusion of 2 nodes A and B, then 'original_node' would

/// be {A, B}. This information can be used to map errors originating at the

/// current node to some top level source code.

/// </summary>

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public pbc::RepeatedField<string> OriginalNodeNames {

get { return originalNodeNames_; }

}

/// <summary>Field number for the "original_func_names" field.</summary>

public const int OriginalFuncNamesFieldNumber = 2;

private static readonly pb::FieldCodec<string> _repeated_originalFuncNames_codec

= pb::FieldCodec.ForString(18);

private readonly pbc::RepeatedField<string> originalFuncNames_ = new pbc::RepeatedField<string>();

/// <summary>

/// This is intended to store the list of names of the functions from the

/// original graph that this node was derived. For example if this node, say

/// C, was result of a fusion of node A in function FA and node B in function

/// FB, then `original_funcs` would be {FA, FB}. If the node is in the top

/// level graph, the `original_func` is empty. This information, with the

/// `original_node_names` can be used to map errors originating at the

/// current ndoe to some top level source code.

/// </summary>

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public pbc::RepeatedField<string> OriginalFuncNames {

get { return originalFuncNames_; }

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public override bool Equals(object other) {

return Equals(other as ExperimentalDebugInfo);

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public bool Equals(ExperimentalDebugInfo other) {

if (ReferenceEquals(other, null)) {

return false;

}

if (ReferenceEquals(other, this)) {

return true;

}

if(!originalNodeNames_.Equals(other.originalNodeNames_)) return false;

if(!originalFuncNames_.Equals(other.originalFuncNames_)) return false;

return Equals(_unknownFields, other._unknownFields);

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public override int GetHashCode() {

int hash = 1;

hash ^= originalNodeNames_.GetHashCode();

hash ^= originalFuncNames_.GetHashCode();

if (_unknownFields != null) {

hash ^= _unknownFields.GetHashCode();

}

return hash;

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public override string ToString() {

return pb::JsonFormatter.ToDiagnosticString(this);

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public void WriteTo(pb::CodedOutputStream output) {

originalNodeNames_.WriteTo(output, _repeated_originalNodeNames_codec);

originalFuncNames_.WriteTo(output, _repeated_originalFuncNames_codec);

if (_unknownFields != null) {

_unknownFields.WriteTo(output);

}

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public int CalculateSize() {

int size = 0;

size += originalNodeNames_.CalculateSize(_repeated_originalNodeNames_codec);

size += originalFuncNames_.CalculateSize(_repeated_originalFuncNames_codec);

if (_unknownFields != null) {

size += _unknownFields.CalculateSize();

}

return size;

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public void MergeFrom(ExperimentalDebugInfo other) {

if (other == null) {

return;

}

originalNodeNames_.Add(other.originalNodeNames_);

originalFuncNames_.Add(other.originalFuncNames_);

_unknownFields = pb::UnknownFieldSet.MergeFrom(_unknownFields, other._unknownFields);

}

[global::System.Diagnostics.DebuggerNonUserCodeAttribute]

public void MergeFrom(pb::CodedInputStream input) {

uint tag;

while ((tag = input.ReadTag()) != 0) {

switch(tag) {

default:

_unknownFields = pb::UnknownFieldSet.MergeFieldFrom(_unknownFields, input);

break;

case 10: {

originalNodeNames_.AddEntriesFrom(input, _repeated_originalNodeNames_codec);

break;

}

case 18: {

originalFuncNames_.AddEntriesFrom(input, _repeated_originalFuncNames_codec);

break;

}

}

}

}

}

}

#endregion

}

#endregion

}

#endregion Designer generated code