public void Read(TProtocol iprot) { TField field; iprot.ReadStructBegin(); while (true) { field = iprot.ReadFieldBegin(); if (field.Type == TType.Stop) { break; } switch (field.ID) { case 1: if (field.Type == TType.Struct) { Ann = new CFastCyclicNetwork(); Ann.Read(iprot); } else { TProtocolUtil.Skip(iprot, field.Type); } break; default: TProtocolUtil.Skip(iprot, field.Type); break; } iprot.ReadFieldEnd(); } iprot.ReadStructEnd(); }
public CFitnessInfo calculateXorPhenotypeFitness(CFastCyclicNetwork ann) { #if !SILVERLIGHT send_calculateXorPhenotypeFitness(ann); return(recv_calculateXorPhenotypeFitness()); #else var asyncResult = Begin_calculateXorPhenotypeFitness(null, null, ann); return(End_calculateXorPhenotypeFitness(asyncResult)); #endif }
public void Read(TProtocol iprot) { TField field; iprot.ReadStructBegin(); while (true) { field = iprot.ReadFieldBegin(); if (field.Type == TType.Stop) { break; } switch (field.ID) { case 5: if (field.Type == TType.I32) { Generation = iprot.ReadI32(); } else { TProtocolUtil.Skip(iprot, field.Type); } break; case 10: if (field.Type == TType.List) { { Phenomes = new List <CFastCyclicNetwork>(); TList _list20 = iprot.ReadListBegin(); for (int _i21 = 0; _i21 < _list20.Count; ++_i21) { CFastCyclicNetwork _elem22 = new CFastCyclicNetwork(); _elem22 = new CFastCyclicNetwork(); _elem22.Read(iprot); Phenomes.Add(_elem22); } iprot.ReadListEnd(); } } else { TProtocolUtil.Skip(iprot, field.Type); } break; default: TProtocolUtil.Skip(iprot, field.Type); break; } iprot.ReadFieldEnd(); } iprot.ReadStructEnd(); }
public void send_calculateXorPhenotypeFitness(CFastCyclicNetwork ann) #endif { oprot_.WriteMessageBegin(new TMessage("calculateXorPhenotypeFitness", TMessageType.Call, seqid_)); calculateXorPhenotypeFitness_args args = new calculateXorPhenotypeFitness_args(); args.Ann = ann; args.Write(oprot_); oprot_.WriteMessageEnd(); #if SILVERLIGHT return(oprot_.Transport.BeginFlush(callback, state)); #else oprot_.Transport.Flush(); #endif }
public static CFastCyclicNetwork Convert(FastCyclicNetwork fcn) { var cfcn = new CFastCyclicNetwork(); var numberOfNeurons = fcn._neuronActivationFnArray.Length; // Copy connections cfcn.Connections = new List<CConnection>(fcn._connectionArray.Length); foreach (var c in fcn._connectionArray) { var cc = new CConnection { ToNeuronId = c._tgtNeuronIdx, FromNeuronId = c._srcNeuronIdx, Weight = c._weight }; cfcn.Connections.Add(cc); } // Copy activation functions cfcn.ActivationFunctions = new List<string>(numberOfNeurons); foreach (var s in fcn._neuronActivationFnArray) { if (s == null) cfcn.ActivationFunctions.Add(""); else cfcn.ActivationFunctions.Add(s.FunctionId); } // Copy auxiliary arguments cfcn.NeuronAuxArgs = new List<List<double>>(numberOfNeurons); foreach (var aux in fcn._neuronAuxArgsArray) { if (aux == null) cfcn.NeuronAuxArgs.Add(new List<double>()); else cfcn.NeuronAuxArgs.Add(new List<double>(aux)); } cfcn.NeuronCount = fcn._neuronCount; cfcn.InputNeuronCount = fcn._inputNeuronCount; cfcn.OutputNeuronCount = fcn._outputNeuronCount; cfcn.TimestepsPerActivation = fcn._timestepsPerActivation; return cfcn; }
public void Read (TProtocol iprot) { TField field; iprot.ReadStructBegin(); while (true) { field = iprot.ReadFieldBegin(); if (field.Type == TType.Stop) { break; } switch (field.ID) { case 10: if (field.Type == TType.List) { { Phenomes = new List<CFastCyclicNetwork>(); TList _list20 = iprot.ReadListBegin(); for( int _i21 = 0; _i21 < _list20.Count; ++_i21) { CFastCyclicNetwork _elem22 = new CFastCyclicNetwork(); _elem22 = new CFastCyclicNetwork(); _elem22.Read(iprot); Phenomes.Add(_elem22); } iprot.ReadListEnd(); } } else { TProtocolUtil.Skip(iprot, field.Type); } break; default: TProtocolUtil.Skip(iprot, field.Type); break; } iprot.ReadFieldEnd(); } iprot.ReadStructEnd(); }
public IAsyncResult send_calculateXorPhenotypeFitness(AsyncCallback callback, object state, CFastCyclicNetwork ann)
public IAsyncResult Begin_calculateXorPhenotypeFitness(AsyncCallback callback, object state, CFastCyclicNetwork ann) { return(send_calculateXorPhenotypeFitness(callback, state, ann)); }
public void Read (TProtocol iprot) { TField field; iprot.ReadStructBegin(); while (true) { field = iprot.ReadFieldBegin(); if (field.Type == TType.Stop) { break; } switch (field.ID) { case 1: if (field.Type == TType.Struct) { Ann = new CFastCyclicNetwork(); Ann.Read(iprot); } else { TProtocolUtil.Skip(iprot, field.Type); } break; default: TProtocolUtil.Skip(iprot, field.Type); break; } iprot.ReadFieldEnd(); } iprot.ReadStructEnd(); }
public void send_calculateXorPhenotypeFitness(CFastCyclicNetwork ann) #endif { oprot_.WriteMessageBegin(new TMessage("calculateXorPhenotypeFitness", TMessageType.Call, seqid_)); calculateXorPhenotypeFitness_args args = new calculateXorPhenotypeFitness_args(); args.Ann = ann; args.Write(oprot_); oprot_.WriteMessageEnd(); #if SILVERLIGHT return oprot_.Transport.BeginFlush(callback, state); #else oprot_.Transport.Flush(); #endif }
public CFitnessInfo calculateXorPhenotypeFitness(CFastCyclicNetwork ann) { #if !SILVERLIGHT send_calculateXorPhenotypeFitness(ann); return recv_calculateXorPhenotypeFitness(); #else var asyncResult = Begin_calculateXorPhenotypeFitness(null, null, ann); return End_calculateXorPhenotypeFitness(asyncResult); #endif }
public IAsyncResult Begin_calculateXorPhenotypeFitness(AsyncCallback callback, object state, CFastCyclicNetwork ann) { return send_calculateXorPhenotypeFitness(callback, state, ann); }