'DeclarationPublic Function Match( _ ByVal other As UANodeDescriptor _ ) As Boolean
'UsageDim instance As UANodeDescriptor Dim other As UANodeDescriptor Dim value As Boolean value = instance.Match(other)
public bool Match( UANodeDescriptor other )
public: bool Match( UANodeDescriptor^ other )
| Exception | Description |
|---|---|
| System.ArgumentNullException |
A This is a usage error, i.e. it will never occur (the exception will not be thrown) in a correctly written program. Your code should not catch this exception. |
// Shows how to write complex data with OPC UA Complex Data plug-in. using System; using OpcLabs.BaseLib.DataTypeModel; using OpcLabs.EasyOpc.UA; using OpcLabs.EasyOpc.UA.ComplexData; using OpcLabs.EasyOpc.UA.OperationModel; namespace UADocExamples.ComplexData._EasyUAClient { class WriteValue { public static void Main1() { // Define which server and node we will work with. UAEndpointDescriptor endpointDescriptor = "opc.tcp://opcua.demo-this.com:51210/UA/SampleServer"; // or "http://opcua.demo-this.com:51211/UA/SampleServer" (currently not supported) // or "https://opcua.demo-this.com:51212/UA/SampleServer/" UANodeDescriptor nodeDescriptor = "nsu=http://test.org/UA/Data/ ;i=10239"; // [ObjectsFolder]/Data.Static.Scalar.StructureValue // Instantiate the client object. var client = new EasyUAClient(); // Read a node which returns complex data. // We know that this node returns complex data, so we can type cast to UAGenericObject. Console.WriteLine("Reading..."); UAGenericObject genericObject; try { genericObject = (UAGenericObject)client.ReadValue(endpointDescriptor, nodeDescriptor); } catch (UAException uaException) { Console.WriteLine("*** Failure: {0}", uaException.GetBaseException().Message); return; } // Modify the data read. // This node returns one of the two data types, randomly (this is not common, usually the type is fixed). The // data types are sub-types of one common type which the data type of the node. We therefore use the data type // ID in the returned UAGenericObject to detect which data type has been returned. // For processing the internals of the data, refer to examples for GenericData and DataType classes. // We know how the data is structured, and have hard-coded a logic that modifies certain values inside. It is // also possible to discover the structure of the data type in the program, and write generic clients that can // cope with any kind of complex data. // // Note that the code below is not fully robust - it will throw an exception if the data is not as expected. Console.WriteLine("Modifying..."); Console.WriteLine(genericObject.DataTypeId); if (genericObject.DataTypeId.NodeDescriptor.Match("nsu=http://test.org/UA/Data/ ;i=9440")) // ScalarValueDataType { // Negate the byte in the "ByteValue" field. var structuredData = (StructuredData)genericObject.GenericData; var byteValue = (PrimitiveData)structuredData.FieldData["ByteValue"]; byteValue.Value = (Byte)~((Byte)byteValue.Value); Console.WriteLine(byteValue.Value); } else if (genericObject.DataTypeId.NodeDescriptor.Match("nsu=http://test.org/UA/Data/ ;i=9669")) // ArrayValueDataType { // Negate bytes at indexes 0 and 1 of the array in the "ByteValue" field. var structuredData = (StructuredData)genericObject.GenericData; var byteValue = (SequenceData)structuredData.FieldData["ByteValue"]; var element0 = (PrimitiveData)byteValue.Elements[0]; var element1 = (PrimitiveData)byteValue.Elements[1]; element0.Value = (Byte)~((Byte)element0.Value); element1.Value = (Byte)~((Byte)element1.Value); Console.WriteLine(element0.Value); Console.WriteLine(element1.Value); } // Write the modified complex data back to the node. // The data type ID in the UAGenericObject is borrowed without change from what we have read, so that the server // knows which data type we are writing. The data type ID not necessary if writing precisely the same data type // as the node has (not a subtype). Console.WriteLine("Writing..."); try { client.WriteValue(endpointDescriptor, nodeDescriptor, genericObject); } catch (UAException uaException) { Console.WriteLine("*** Failure: {0}", uaException.GetBaseException().Message); } } } }
# Shows how to write complex data with OPC UA Complex Data plug-in. # The QuickOPC package is needed. Install it using "pip install opclabs_quickopc". import opclabs_quickopc # Import .NET namespaces. from System import * from OpcLabs.BaseLib.DataTypeModel import * from OpcLabs.EasyOpc.UA import * from OpcLabs.EasyOpc.UA.OperationModel import * endpointDescriptor = UAEndpointDescriptor('opc.tcp://opcua.demo-this.com:51210/UA/SampleServer') # or 'http://opcua.demo-this.com:51211/UA/SampleServer' (currently not supported) # or 'https://opcua.demo-this.com:51212/UA/SampleServer/' # [ObjectsFolder]/Data.Static.Scalar.StructureValue nodeDescriptor = UANodeDescriptor('nsu=http://test.org/UA/Data/ ;i=10239') # Instantiate the client object. client = EasyUAClient() # Read a node which returns complex data. # We know that this node returns complex data, so we can type cast to UAGenericObject. try: print('Reading...') genericObject = IEasyUAClientExtension.ReadValue(client, endpointDescriptor, nodeDescriptor) except UAException as uaException: print('*** Failure: ' + uaException.GetBaseException().Message) exit() # Modify the data read. # This node returns one of the two data types, randomly (this is not common, usually the type is fixed). The # data types are sub-types of one common type which the data type of the node. We therefore use the data type # ID in the returned UAGenericObject to detect which data type has been returned. # # For processing the internals of the data, refer to examples for GenericData and DataType classes. # We know how the data is structured, and have hard-coded a logic that modifies certain values inside. It is # also possible to discover the structure of the data type in the program, and write generic clients that can # cope with any kind of complex data. # # Note that the code below is not fully robust - it will throw an exception if the data is not as expected. print ('Modifying...') print(genericObject.DataTypeId) if genericObject.DataTypeId.NodeDescriptor.Match(UANodeDescriptor('nsu=http://test.org/UA/Data/ ;i=9440')): # ScalarValueDataType # Negate the byte in the "ByteValue" field. structuredData = genericObject.GenericData byteValue = structuredData.FieldData.get_Item('ByteValue') # PrimitiveData byteValue.Value = (~byteValue.Value) & 0xFF print(byteValue.Value) elif genericObject.DataTypeId.NodeDescriptor.Match(UANodeDescriptor('nsu=http://test.org/UA/Data/ ;i=9669')): # ArrayValueDataType # Negate bytes at indexes 0 and 1 of the array in the "ByteValue" field. structuredData = genericObject.GenericData byteValue = structuredData.FieldData.get_Item('ByteValue') # SequenceData element0 = byteValue.Elements.get_Item(0) # PrimitiveData element1 = byteValue.Elements.get_Item(1) # PrimitiveData element0.Value = (~element0.Value) & 0xFF element1.Value = (~element1.Value) & 0xFF print(element0.Value) print(element1.Value) # Write the modified complex data back to the node. # The data type ID in the UAGenericObject is borrowed without change from what we have read, so that the server # knows which data type we are writing. The data type ID not necessary if writing precisely the same data type # as the node has (not a subtype). try: print('Writing...') IEasyUAClientExtension.WriteValue(client, endpointDescriptor, nodeDescriptor, genericObject) except UAException as uaException: print('*** Failure: ' + uaException.GetBaseException().Message) print() print('Finished.')
' Shows how to write complex data with OPC UA Complex Data plug-in. Imports System Imports OpcLabs.BaseLib.DataTypeModel Imports OpcLabs.EasyOpc.UA Imports OpcLabs.EasyOpc.UA.ComplexData Imports OpcLabs.EasyOpc.UA.OperationModel Namespace ComplexData._EasyUAClient Friend Class WriteValue Public Shared Sub Main1() ' Define which server we will work with. Dim endpointDescriptor As UAEndpointDescriptor = "opc.tcp://opcua.demo-this.com:51210/UA/SampleServer" ' or "http://opcua.demo-this.com:51211/UA/SampleServer" (currently not supported) ' or "https://opcua.demo-this.com:51212/UA/SampleServer/" ' Define which node we will work with. Dim nodeDescriptor As UANodeDescriptor = _ "nsu=http://test.org/UA/Data/ ;i=10239" ' [ObjectsFolder]/Data.Static.Scalar.StructureValue ' Instantiate the client object. Dim client = New EasyUAClient ' Read a node which returns complex data. ' We know that this node returns complex data, so we can type cast to UAGenericObject. Console.WriteLine("Reading...") Dim genericObject As UAGenericObject Try genericObject = CType(client.ReadValue(endpointDescriptor, nodeDescriptor), UAGenericObject) Catch uaException As UAException Console.WriteLine("*** Failure: {0}", uaException.GetBaseException.Message) Exit Sub End Try ' Modify the data read. ' This node returns one of the two data types, randomly (this is not common, usually the type is fixed). The ' data types are sub-types of one common type which the data type of the node. We therefore use the data type ' ID in the returned UAGenericObject to detect which data type has been returned. ' For processing the internals of the data, refer to examples for GenericData and DataType classes. ' We know how the data is structured, and have hard-coded a logic that modifies certain values inside. It is ' also possible to discover the structure of the data type in the program, and write generic clients that can ' cope with any kind of complex data. ' ' Note that the code below is not fully robust - it will throw an exception if the data is not as expected. Console.WriteLine("Modifying...") Console.WriteLine(genericObject.DataTypeId) If genericObject.DataTypeId.NodeDescriptor.Match("nsu=http://test.org/UA/Data/ ;i=9440") Then ' ScalarValueDataType ' Negate the byte in the "ByteValue" field. Dim structuredData = CType(genericObject.GenericData, StructuredData) Dim byteValue = CType(structuredData.FieldData("ByteValue"), PrimitiveData) byteValue.Value = CType(Not CType(byteValue.Value, Byte), Byte) Console.WriteLine(byteValue.Value) ElseIf genericObject.DataTypeId.NodeDescriptor.Match("nsu=http://test.org/UA/Data/ ;i=9669") Then ' ArrayValueDataType ' Negate bytes at indexes 0 and 1 of the array in the "ByteValue" field. Dim structuredData = CType(genericObject.GenericData, StructuredData) Dim byteValue = CType(structuredData.FieldData("ByteValue"), SequenceData) Dim element0 = CType(byteValue.Elements(0), PrimitiveData) Dim element1 = CType(byteValue.Elements(1), PrimitiveData) element0.Value = CType(Not CType(element0.Value, Byte), Byte) element1.Value = CType(Not CType(element1.Value, Byte), Byte) Console.WriteLine(element0.Value) Console.WriteLine(element1.Value) End If ' Write the modified complex data back to the node. ' The data type ID in the UAGenericObject is borrowed without change from what we have read, so that the server ' knows which data type we are writing. The data type ID not necessary if writing precisely the same data type ' as the node has (not a subtype). Console.WriteLine("Writing...") Try client.WriteValue(endpointDescriptor, nodeDescriptor, genericObject) Catch uaException As UAException Console.WriteLine("*** Failure: {0}", uaException.GetBaseException.Message) Exit Sub End Try End Sub End Class End Namespace
// Shows how to write complex data with OPC UA Complex Data plug-in. class procedure WriteValue.Main; var ArrayValueDataType: _UANodeDescriptor; ByteValue: _PrimitiveData; ByteValue2: _SequenceData; Client: _EasyUAClient; Element0, Element1: _PrimitiveData; EndpointDescriptor: string; GenericObject: _UAGenericObject; NodeDescriptor: string; ScalarValueDataType: _UANodeDescriptor; StructuredData: _StructuredData; begin // Define which server and node we will work with. EndpointDescriptor := //'http://opcua.demo-this.com:51211/UA/SampleServer'; //'https://opcua.demo-this.com:51212/UA/SampleServer/'; 'opc.tcp://opcua.demo-this.com:51210/UA/SampleServer'; NodeDescriptor := 'nsu=http://test.org/UA/Data/ ;i=10239'; // [ObjectsFolder]/Data.Static.Scalar.StructureValue // Instantiate the client object Client := CoEasyUAClient.Create; // Read a node which returns complex data. // We know that this node returns complex data, so we can type cast to UAGenericObject. WriteLn('Reading...'); try GenericObject := _UAGenericObject(IUnknown(Client.ReadValue(EndpointDescriptor, NodeDescriptor))); except on E: EOleException do begin WriteLn(Format('*** Failure: %s', [E.GetBaseException.Message])); Exit; end; end; // Modify the data read. // This node returns one of the two data types, randomly (this is not common, usually the type is fixed). The // data types are sub-types of one common type which the data type of the node. We therefore use the data type // ID in the returned UAGenericObject to detect which data type has been returned. // For processing the internals of the data, refer to examples for GenericData and DataType classes. // We know how the data is structured, and have hard-coded a logic that modifies certain values inside. It is // also possible to discover the structure of the data type in the program, and write generic clients that can // cope with any kind of complex data. // // Note that the code below is not fully robust - it will throw an exception if the data is not as expected. WriteLn('Modifying...'); WriteLn(GenericObject.DataTypeId.ToString); ScalarValueDataType := CoUANodeDescriptor.Create; ScalarValueDataType.NodeId.ExpandedText := 'nsu=http://test.org/UA/Data/ ;i=9440'; // ScalarValueDataType if GenericObject.DataTypeId.NodeDescriptor.Match(ScalarValueDataType) then begin // Negate the byte in the "ByteValue" field. StructuredData := IUnknown(GenericObject.GenericData) as _StructuredData; ByteValue := IUnknown(StructuredData.FieldData['ByteValue']) as _PrimitiveData; ByteValue.Value := Byte(not (Byte(byteValue.Value))); WriteLn(ByteValue.Value); end else begin ArrayValueDataType := CoUANodeDescriptor.Create; ArrayValueDataType.NodeId.ExpandedText := 'nsu=http://test.org/UA/Data/ ;i=9669'; // ArrayValueDataType if GenericObject.DataTypeId.Nodedescriptor.Match(ArrayValueDataType) then begin // Negate bytes at indexes 0 and 1 of the array in the "ByteValue" field. StructuredData := IUnknown(GenericObject.GenericData) as _StructuredData; ByteValue2 := IUnknown(StructuredData.FieldData['ByteValue']) as _SequenceData; Element0 := IUnknown(ByteValue2.Elements[0]) as _PrimitiveData; Element1 := IUnknown(ByteValue2.Elements[1]) as _PrimitiveData; Element0.Value := Byte(not (Byte(element0.Value))); Element1.Value := Byte(not (Byte(element1.Value))); WriteLn(Element0.Value); WriteLn(Element1.Value); end; end; // Write the modified complex data back to the node. // The data type ID in the UAGenericObject is borrowed without change from what we have read, so that the server // knows which data type we are writing. The data type ID not necessary if writing precisely the same data type // as the node has (not a subtype). WriteLn('Writing...'); try Client.WriteValue(EndpointDescriptor, NodeDescriptor, GenericObject); except on E: EOleException do begin WriteLn(Format('*** Failure: %s', [E.GetBaseException.Message])); Exit; end; end; end;
// Shows how to write complex data with OPC UA Complex Data plug-in. // Define which server and node we will work with. $EndpointDescriptor = //"http://opcua.demo-this.com:51211/UA/SampleServer"; //"https://opcua.demo-this.com:51212/UA/SampleServer/"; "opc.tcp://opcua.demo-this.com:51210/UA/SampleServer"; $NodeDescriptor = "nsu=http://test.org/UA/Data/ ;i=10239"; // [ObjectsFolder]/Data.Static.Scalar.StructureValue // Instantiate the client object $Client = new COM("OpcLabs.EasyOpc.UA.EasyUAClient"); // Read a node which returns complex data. // We know that this node returns complex data, so we can type cast to UAGenericObject. printf("Reading...\n"); try { $GenericObject = $Client->ReadValue($EndpointDescriptor, $NodeDescriptor); } catch (com_exception $e) { printf("*** Failure: %s\n", $e->getMessage()); Exit(); } // Modify the data read. // This node returns one of the two data types, randomly (this is not common, usually the type is fixed). The // data types are sub-types of one common type which the data type of the node. We therefore use the data type // ID in the returned UAGenericObject to detect which data type has been returned. // For processing the internals of the data, refer to examples for GenericData and DataType classes. // We know how the data is structured, and have hard-coded a logic that modifies certain values inside. It is // also possible to discover the structure of the data type in the program, and write generic clients that can // cope with any kind of complex data. // // Note that the code below is not fully robust - it will throw an exception if the data is not as expected. printf("Modifying...\n"); printf("%s\n", $GenericObject->DataTypeId); $ScalarValueDataType = new COM("OpcLabs.EasyOpc.UA.UANodeDescriptor"); $ScalarValueDataType->NodeId->ExpandedText = "nsu=http://test.org/UA/Data/ ;i=9440"; // ScalarValueDataType if ($GenericObject->DataTypeId->NodeDescriptor->Match($ScalarValueDataType)) { // Negate the byte in the "ByteValue" field. $StructuredData = $GenericObject->GenericData->AsStructuredData(); $ByteValue = $StructuredData->FieldData["ByteValue"]->AsPrimitiveData(); $ByteValue->Value = ~($ByteValue->Value) & 255; printf("%s\n", $ByteValue->Value); } else { $ArrayValueDataType = new COM("OpcLabs.EasyOpc.UA.UANodeDescriptor"); $ArrayValueDataType->NodeId->ExpandedText = "nsu=http://test.org/UA/Data/ ;i=9669"; // ArrayValueDataType if ($GenericObject->DataTypeId->Nodedescriptor->Match($ArrayValueDataType)) { // Negate bytes at indexes 0 and 1 of the array in the "ByteValue" field. $StructuredData = $GenericObject->GenericData->AsStructuredData(); $ByteValue2 = $StructuredData->FieldData["ByteValue"]->AsSequenceData(); $Element0 = $ByteValue2->Elements[0]->AsPrimitiveData(); $Element1 = $ByteValue2->Elements[1]->AsPrimitiveData(); $Element0->Value = ~($Element0->Value) & 255; $Element1->Value = ~($Element1->Value) & 255; printf("%s\n", $Element0->Value); printf("%s\n", $Element1->Value); } } // Write the modified complex data back to the node. // The data type ID in the UAGenericObject is borrowed without change from what we have read, so that the server // knows which data type we are writing. The data type ID not necessary if writing precisely the same data type // as the node has (not a subtype). printf("Writing...\n"); try { $Client->WriteValue($EndpointDescriptor, $NodeDescriptor, $GenericObject); } catch (com_exception $e) { printf("Failure: %s\n", $e->getMessage()); Exit(); }