/// <summary>
/// Returns the related feature for a corresponding relationship number
/// <returns></returns>
/// <summary>
private IGTKeyObjects GetRelatedFeatures()
{
try
{
IGTKeyObjects configuredKeyObjects = GTClassFactory.Create <IGTKeyObjects>();
using (IGTRelationshipService relService = GTClassFactory.Create <IGTRelationshipService>())
{
relService.DataContext = DataContext;
relService.ActiveFeature = ActiveFeature;
IGTKeyObjects relatedFeatures = relService.GetRelatedFeatures(RNO);
if (ProcessingMode.Equals(GTRelationshipGeometryProcessingModeConstants.gtrgiValidation))
{
foreach (IGTKeyObject item in relatedFeatures)
{
if (IsFeatureConfiguredInRelationshipGeomtery(item.FNO))
{
if ((ActiveFeature.FNO == 16 && (item.FNO == 17 || item.FNO == 18)) || ((ActiveFeature.FNO == 17 || ActiveFeature.FNO == 18) && item.FNO == 16))
{
continue;
}
else
{
configuredKeyObjects.Add(item);
}
}
}
}
else
{
configuredKeyObjects = relatedFeatures;
}
return(configuredKeyObjects);
}
}
catch
{
throw;
}
}
/// <summary>
/// Sets voltage attributes when establishing connectivity,based on the voltage attributes corresponding to the connected nodes.
/// <summary>
/// <param name="p_errorPriority">Error Priority</param>
private void SetAffectedRelatedNodeVoltages(string p_errorPriority = null)
{
Recordset activeConnectivityRS = null;
Recordset relatedConnectivityRS = null;
short connectivityCNO = 11;
try
{
activeConnectivityRS = ActiveFeature.Components.GetComponent(connectivityCNO).Recordset;
foreach (IGTKeyObject relatedFeature in GetRelatedFeatures())
{
relatedConnectivityRS = relatedFeature.Components.GetComponent(connectivityCNO).Recordset;
if (activeConnectivityRS != null && relatedConnectivityRS != null)
{
if (!(activeConnectivityRS.EOF && activeConnectivityRS.BOF) && !(relatedConnectivityRS.EOF && relatedConnectivityRS.BOF))
{
activeConnectivityRS.MoveFirst();
relatedConnectivityRS.MoveFirst();
if (activeConnectivityRS.Fields["NODE_1_ID"].Value != DBNull.Value && (activeConnectivityRS.Fields["NODE_1_ID"].Value.Equals(relatedConnectivityRS.Fields["NODE_1_ID"].Value)))
{
SetAffectedRelatedValues(Convert.ToString(activeConnectivityRS.Fields["VOLT_1_Q"].Value), Convert.ToString(relatedConnectivityRS.Fields["VOLT_1_Q"].Value), Convert.ToString(activeConnectivityRS.Fields["PP_VOLT_1_Q"].Value), Convert.ToString(relatedConnectivityRS.Fields["PP_VOLT_1_Q"].Value), "VOLT_2_Q", "PP_VOLT_2_Q");
if (!ProcessingMode.Equals(GTRelationshipGeometryProcessingModeConstants.gtrgiValidation))
{
if (!String.IsNullOrEmpty(m_sActualRelatedVoltage))
{
activeConnectivityRS.Fields["VOLT_1_Q"].Value = m_sActualRelatedVoltage;
}
if (!String.IsNullOrEmpty(m_sProposedRelatedVoltage))
{
activeConnectivityRS.Fields["PP_VOLT_1_Q"].Value = m_sProposedRelatedVoltage;
}
}
}
else if (activeConnectivityRS.Fields["NODE_2_ID"].Value != DBNull.Value && (activeConnectivityRS.Fields["NODE_2_ID"].Value.Equals(relatedConnectivityRS.Fields["NODE_2_ID"].Value)))
{
SetAffectedRelatedValues(Convert.ToString(activeConnectivityRS.Fields["VOLT_2_Q"].Value), Convert.ToString(relatedConnectivityRS.Fields["VOLT_2_Q"].Value), Convert.ToString(activeConnectivityRS.Fields["PP_VOLT_2_Q"].Value), Convert.ToString(relatedConnectivityRS.Fields["PP_VOLT_2_Q"].Value), "VOLT_1_Q", "PP_VOLT_1_Q");
if (!ProcessingMode.Equals(GTRelationshipGeometryProcessingModeConstants.gtrgiValidation))
{
if (!String.IsNullOrEmpty(m_sActualRelatedVoltage))
{
activeConnectivityRS.Fields["VOLT_2_Q"].Value = m_sActualRelatedVoltage;
}
if (!String.IsNullOrEmpty(m_sProposedRelatedVoltage))
{
activeConnectivityRS.Fields["PP_VOLT_2_Q"].Value = m_sProposedRelatedVoltage;
}
}
}
else if (activeConnectivityRS.Fields["NODE_1_ID"].Value != DBNull.Value && (activeConnectivityRS.Fields["NODE_1_ID"].Value.Equals(relatedConnectivityRS.Fields["NODE_2_ID"].Value)))
{
SetAffectedRelatedValues(Convert.ToString(activeConnectivityRS.Fields["VOLT_1_Q"].Value), Convert.ToString(relatedConnectivityRS.Fields["VOLT_2_Q"].Value), Convert.ToString(activeConnectivityRS.Fields["PP_VOLT_1_Q"].Value), Convert.ToString(relatedConnectivityRS.Fields["PP_VOLT_2_Q"].Value), "VOLT_2_Q", "PP_VOLT_2_Q");
if (!ProcessingMode.Equals(GTRelationshipGeometryProcessingModeConstants.gtrgiValidation))
{
if (!String.IsNullOrEmpty(m_sActualRelatedVoltage))
{
activeConnectivityRS.Fields["VOLT_1_Q"].Value = m_sActualRelatedVoltage;
}
if (!String.IsNullOrEmpty(m_sProposedRelatedVoltage))
{
activeConnectivityRS.Fields["PP_VOLT_1_Q"].Value = m_sProposedRelatedVoltage;
}
}
}
else if (activeConnectivityRS.Fields["NODE_2_ID"].Value != DBNull.Value && (activeConnectivityRS.Fields["NODE_2_ID"].Value.Equals(relatedConnectivityRS.Fields["NODE_1_ID"].Value)))
{
SetAffectedRelatedValues(Convert.ToString(activeConnectivityRS.Fields["VOLT_2_Q"].Value), Convert.ToString(relatedConnectivityRS.Fields["VOLT_1_Q"].Value), Convert.ToString(activeConnectivityRS.Fields["PP_VOLT_2_Q"].Value), Convert.ToString(relatedConnectivityRS.Fields["PP_VOLT_1_Q"].Value), "VOLT_1_Q", "PP_VOLT_1_Q");
if (!ProcessingMode.Equals(GTRelationshipGeometryProcessingModeConstants.gtrgiValidation))
{
if (!String.IsNullOrEmpty(m_sActualRelatedVoltage))
{
activeConnectivityRS.Fields["VOLT_2_Q"].Value = m_sActualRelatedVoltage;
}
if (!String.IsNullOrEmpty(m_sProposedRelatedVoltage))
{
activeConnectivityRS.Fields["PP_VOLT_2_Q"].Value = m_sProposedRelatedVoltage;
}
}
}
}
}
if (ProcessingMode.Equals(GTRelationshipGeometryProcessingModeConstants.gtrgiValidation))
{
ValidateVoltages(p_errorPriority);
}
else
{
CopyAffectedRelatedNodeVoltages();
}
}
}
catch
{
throw;
}
}