Initialize() public method

Initialize the run-time log.

Initialization performs initial run-time log read, establishes new start time and enables automatic write log timer.

Last logged stop time will be validated against last logged running time. If the last logged running time is later than the last logged stop time, the stop time will be set to the running time with the assumption that the log file was not properly shut down (e.g., due to abnormal host termination).

It is important to separate initialization from construction such that consumer can attach to events before class is initialized in case initialization causes events to be raised.

public Initialize ( ) : void
return void
コード例 #1
0
ファイル: DataSubscriber.cs プロジェクト: rmc00/gsf
        private void ProcessServerResponse(byte[] buffer, int length)
        {
            // Currently this work is done on the async socket completion thread, make sure work to be done is timely and if the response processing
            // is coming in via the command channel and needs to send a command back to the server, it should be done on a separate thread...
            if (buffer != null && length > 0)
            {
                try
                {
                    Dictionary<Guid, DeviceStatisticsHelper<SubscribedDevice>> subscribedDevicesLookup;
                    DeviceStatisticsHelper<SubscribedDevice> statisticsHelper;

                    ServerResponse responseCode = (ServerResponse)buffer[0];
                    ServerCommand commandCode = (ServerCommand)buffer[1];
                    int responseLength = BigEndian.ToInt32(buffer, 2);
                    int responseIndex = DataPublisher.ClientResponseHeaderSize;
                    bool solicited = false;
                    byte[][][] keyIVs;

                    // See if this was a solicited response to a requested server command
                    if (responseCode.IsSolicited())
                    {
                        lock (m_requests)
                        {
                            int index = m_requests.BinarySearch(commandCode);

                            if (index >= 0)
                            {
                                solicited = true;
                                m_requests.RemoveAt(index);
                            }
                        }

                        // Disconnect any established UDP data channel upon successful unsubscribe
                        if (solicited && commandCode == ServerCommand.Unsubscribe && responseCode == ServerResponse.Succeeded)
                            DataChannel = null;
                    }

                    OnReceivedServerResponse(responseCode, commandCode);

                    switch (responseCode)
                    {
                        case ServerResponse.Succeeded:
                            if (solicited)
                            {
                                switch (commandCode)
                                {
                                    case ServerCommand.Authenticate:
                                        OnStatusMessage("Success code received in response to server command \"{0}\": {1}", commandCode, InterpretResponseMessage(buffer, responseIndex, responseLength));
                                        m_authenticated = true;
                                        OnConnectionAuthenticated();
                                        break;
                                    case ServerCommand.Subscribe:
                                        OnStatusMessage("Success code received in response to server command \"{0}\": {1}", commandCode, InterpretResponseMessage(buffer, responseIndex, responseLength));
                                        m_subscribed = true;
                                        break;
                                    case ServerCommand.Unsubscribe:
                                        OnStatusMessage("Success code received in response to server command \"{0}\": {1}", commandCode, InterpretResponseMessage(buffer, responseIndex, responseLength));
                                        m_subscribed = false;
                                        if ((object)m_dataStreamMonitor != null)
                                            m_dataStreamMonitor.Enabled = false;
                                        break;
                                    case ServerCommand.RotateCipherKeys:
                                        OnStatusMessage("Success code received in response to server command \"{0}\": {1}", commandCode, InterpretResponseMessage(buffer, responseIndex, responseLength));
                                        break;
                                    case ServerCommand.MetaDataRefresh:
                                        OnStatusMessage("Success code received in response to server command \"{0}\": latest meta-data received.", commandCode);
                                        OnMetaDataReceived(DeserializeMetadata(buffer.BlockCopy(responseIndex, responseLength)));
                                        m_metadataRefreshPending = false;
                                        break;
                                }
                            }
                            else
                            {
                                switch (commandCode)
                                {
                                    case ServerCommand.MetaDataRefresh:
                                        // Meta-data refresh may be unsolicited
                                        OnStatusMessage("Received server confirmation for unsolicited request to \"{0}\" command: latest meta-data received.", commandCode);
                                        OnMetaDataReceived(DeserializeMetadata(buffer.BlockCopy(responseIndex, responseLength)));
                                        m_metadataRefreshPending = false;
                                        break;
                                    case ServerCommand.RotateCipherKeys:
                                        // Key rotation may be unsolicited
                                        OnStatusMessage("Received server confirmation for unsolicited request to \"{0}\" command: {1}", commandCode, InterpretResponseMessage(buffer, responseIndex, responseLength));
                                        break;
                                    case ServerCommand.Subscribe:
                                        OnStatusMessage("Received unsolicited response to \"{0}\" command: {1}", commandCode, InterpretResponseMessage(buffer, responseIndex, responseLength));
                                        break;
                                    default:
                                        OnProcessException(new InvalidOperationException("Publisher sent a success code for an unsolicited server command: " + commandCode));
                                        break;
                                }
                            }
                            break;
                        case ServerResponse.Failed:
                            if (solicited)
                                OnStatusMessage("Failure code received in response to server command \"{0}\": {1}", commandCode, InterpretResponseMessage(buffer, responseIndex, responseLength));
                            else
                                OnProcessException(new InvalidOperationException("Publisher sent a failed code for an unsolicited server command: " + commandCode));

                            if (commandCode == ServerCommand.MetaDataRefresh)
                                m_metadataRefreshPending = false;
                            break;
                        case ServerResponse.DataPacket:
                            long now = DateTime.UtcNow.Ticks;

                            // Deserialize data packet
                            List<IMeasurement> measurements = new List<IMeasurement>();
                            DataPacketFlags flags;
                            Ticks timestamp = 0;
                            int count;

                            if (m_totalBytesReceived == 0)
                            {
                                // At the point when data is being received, data monitor should be enabled
                                if ((object)m_dataStreamMonitor != null && !m_dataStreamMonitor.Enabled)
                                    m_dataStreamMonitor.Enabled = true;

                                // Establish run-time log for subscriber
                                if (m_autoConnect || m_dataGapRecoveryEnabled)
                                {
                                    if ((object)m_runTimeLog == null)
                                    {
                                        m_runTimeLog = new RunTimeLog();
                                        m_runTimeLog.FileName = GetLoggingPath(Name + "_RunTimeLog.txt");
                                        m_runTimeLog.ProcessException += m_runTimeLog_ProcessException;
                                        m_runTimeLog.Initialize();
                                    }
                                    else
                                    {
                                        // Mark the start of any data transmissions
                                        m_runTimeLog.StartTime = DateTime.UtcNow;
                                        m_runTimeLog.Enabled = true;
                                    }
                                }

                                // The duration between last disconnection and start of data transmissions
                                // represents a gap in data - if data gap recovery is enabled, we log
                                // this as a gap for recovery:
                                if (m_dataGapRecoveryEnabled && (object)m_dataGapRecoverer != null)
                                    m_dataGapRecoverer.LogDataGap(m_runTimeLog.StopTime, DateTime.UtcNow);
                            }

                            // Track total data packet bytes received from any channel
                            m_totalBytesReceived += m_lastBytesReceived;
                            m_monitoredBytesReceived += m_lastBytesReceived;

                            // Get data packet flags
                            flags = (DataPacketFlags)buffer[responseIndex];
                            responseIndex++;

                            bool synchronizedMeasurements = ((byte)(flags & DataPacketFlags.Synchronized) > 0);
                            bool compactMeasurementFormat = ((byte)(flags & DataPacketFlags.Compact) > 0);
                            bool compressedPayload = ((byte)(flags & DataPacketFlags.Compressed) > 0);
                            int cipherIndex = (flags & DataPacketFlags.CipherIndex) > 0 ? 1 : 0;

                            // Decrypt data packet payload if keys are available
                            if ((object)m_keyIVs != null)
                            {
                                // Get a local copy of volatile keyIVs reference since this can change at any time
                                keyIVs = m_keyIVs;

                                // Decrypt payload portion of data packet
                                buffer = Common.SymmetricAlgorithm.Decrypt(buffer, responseIndex, responseLength - 1, keyIVs[cipherIndex][0], keyIVs[cipherIndex][1]);
                                responseIndex = 0;
                                responseLength = buffer.Length;
                            }

                            // Synchronized packets contain a frame level timestamp
                            if (synchronizedMeasurements)
                            {
                                timestamp = BigEndian.ToInt64(buffer, responseIndex);
                                responseIndex += 8;
                            }

                            // Deserialize number of measurements that follow
                            count = BigEndian.ToInt32(buffer, responseIndex);
                            responseIndex += 4;

                            if (compressedPayload)
                            {
                                if ((object)m_signalIndexCache == null && m_lastMissingCacheWarning + MissingCacheWarningInterval < now)
                                {
                                    if (m_lastMissingCacheWarning != 0L)
                                    {
                                        // Warning message for missing signal index cache
                                        OnStatusMessage("WARNING: Signal index cache has not arrived. No compact measurements can be parsed.");
                                    }

                                    m_lastMissingCacheWarning = now;
                                }
                                else
                                {
                                    try
                                    {
                                        if (CompressionModes.HasFlag(CompressionModes.TSSC))
                                        {
                                            // Use TSSC compression to decompress measurements                                            
                                            if ((object)m_decompressionBlock == null)
                                                m_decompressionBlock = new MeasurementDecompressionBlock();

                                            MemoryStream bufferStream = new MemoryStream(buffer, responseIndex, responseLength - responseIndex + DataPublisher.ClientResponseHeaderSize);
                                            bool eos = false;

                                            while (!eos)
                                            {
                                                Measurement measurement;
                                                Tuple<Guid, string, uint> tuple;
                                                ushort id;
                                                long time;
                                                uint quality;
                                                float value;
                                                byte command;

                                                switch (m_decompressionBlock.GetMeasurement(out id, out time, out quality, out value, out command))
                                                {
                                                    case DecompressionExitCode.EndOfStreamOccured:
                                                        if (bufferStream.Position != bufferStream.Length)
                                                            m_decompressionBlock.Fill(bufferStream);
                                                        else
                                                            eos = true;
                                                        break;
                                                    case DecompressionExitCode.CommandRead:
                                                        break;
                                                    case DecompressionExitCode.MeasurementRead:                                                        
                                                        // Attempt to restore signal identification
                                                        if (m_signalIndexCache.Reference.TryGetValue(id, out tuple))
                                                        {
                                                            measurement = new Measurement();
                                                            measurement.Key = MeasurementKey.LookUpOrCreate(tuple.Item1, tuple.Item2, tuple.Item3);
                                                            measurement.Timestamp = time;
                                                            measurement.StateFlags = (MeasurementStateFlags)quality;
                                                            measurement.Value = value;
                                                            measurements.Add(measurement);
                                                        }
                                                        break;
                                                }
                                            }
                                        }
                                        else
                                        {
                                            // Decompress compact measurements from payload
                                            measurements.AddRange(buffer.DecompressPayload(m_signalIndexCache, responseIndex, responseLength - responseIndex + DataPublisher.ClientResponseHeaderSize, count, m_includeTime, flags));
                                        }
                                    }
                                    catch (Exception ex)
                                    {
                                        OnProcessException(new InvalidOperationException("WARNING: Decompression failure: " + ex.Message, ex));
                                    }
                                }
                            }
                            else
                            {
                                // Deserialize measurements
                                for (int i = 0; i < count; i++)
                                {
                                    if (!compactMeasurementFormat)
                                    {
                                        // Deserialize full measurement format
                                        SerializableMeasurement measurement = new SerializableMeasurement(m_encoding);
                                        responseIndex += measurement.ParseBinaryImage(buffer, responseIndex, responseLength - responseIndex);
                                        measurements.Add(measurement);
                                    }
                                    else if ((object)m_signalIndexCache != null)
                                    {
                                        // Deserialize compact measurement format
                                        CompactMeasurement measurement = new CompactMeasurement(m_signalIndexCache, m_includeTime, m_baseTimeOffsets, m_timeIndex, m_useMillisecondResolution);
                                        responseIndex += measurement.ParseBinaryImage(buffer, responseIndex, responseLength - responseIndex);

                                        // Apply timestamp from frame if not included in transmission
                                        if (!measurement.IncludeTime)
                                            measurement.Timestamp = timestamp;

                                        measurements.Add(measurement);
                                    }
                                    else if (m_lastMissingCacheWarning + MissingCacheWarningInterval < now)
                                    {
                                        if (m_lastMissingCacheWarning != 0L)
                                        {
                                            // Warning message for missing signal index cache
                                            OnStatusMessage("WARNING: Signal index cache has not arrived. No compact measurements can be parsed.");
                                        }

                                        m_lastMissingCacheWarning = now;
                                    }
                                }
                            }

                            // Calculate statistics
                            subscribedDevicesLookup = m_subscribedDevicesLookup;
                            statisticsHelper = null;

                            if ((object)subscribedDevicesLookup != null)
                            {
                                IEnumerable<IGrouping<DeviceStatisticsHelper<SubscribedDevice>, IMeasurement>> deviceGroups = measurements
                                    .Where(measurement => subscribedDevicesLookup.TryGetValue(measurement.ID, out statisticsHelper))
                                    .Select(measurement => Tuple.Create(statisticsHelper, measurement))
                                    .ToList()
                                    .GroupBy(tuple => tuple.Item1, tuple => tuple.Item2);

                                foreach (IGrouping<DeviceStatisticsHelper<SubscribedDevice>, IMeasurement> deviceGroup in deviceGroups)
                                {
                                    statisticsHelper = deviceGroup.Key;

                                    foreach (IGrouping<Ticks, IMeasurement> frame in deviceGroup.GroupBy(measurement => measurement.Timestamp))
                                    {
                                        // Determine the number of measurements received with valid values
                                        int measurementsReceived = frame.Count(measurement => !double.IsNaN(measurement.Value));

                                        IMeasurement statusFlags = null;
                                        IMeasurement frequency = null;
                                        IMeasurement deltaFrequency = null;

                                        // Attempt to update real-time
                                        if (!m_useLocalClockAsRealTime && frame.Key > m_realTime)
                                            m_realTime = frame.Key;

                                        // Search the frame for status flags, frequency, and delta frequency
                                        foreach (IMeasurement measurement in frame)
                                        {
                                            if (measurement.ID == statisticsHelper.Device.StatusFlagsID)
                                                statusFlags = measurement;
                                            else if (measurement.ID == statisticsHelper.Device.FrequencyID)
                                                frequency = measurement;
                                            else if (measurement.ID == statisticsHelper.Device.DeltaFrequencyID)
                                                deltaFrequency = measurement;
                                        }

                                        // If we are receiving status flags for this device,
                                        // count the data quality, time quality, and device errors
                                        if ((object)statusFlags != null)
                                        {
                                            uint commonStatusFlags = (uint)statusFlags.Value;

                                            if ((commonStatusFlags & (uint)Bits.Bit19) > 0)
                                                statisticsHelper.Device.DataQualityErrors++;

                                            if ((commonStatusFlags & (uint)Bits.Bit18) > 0)
                                                statisticsHelper.Device.TimeQualityErrors++;

                                            if ((commonStatusFlags & (uint)Bits.Bit16) > 0)
                                                statisticsHelper.Device.DeviceErrors++;

                                            measurementsReceived--;
                                        }

                                        // Zero is not a valid value for frequency.
                                        // If frequency is zero, invalidate both frequency and delta frequency
                                        if ((object)frequency != null && frequency.Value == 0.0D)
                                        {
                                            if ((object)deltaFrequency != null)
                                                measurementsReceived -= 2;
                                            else
                                                measurementsReceived--;
                                        }

                                        // Track the number of measurements received
                                        statisticsHelper.AddToMeasurementsReceived(measurementsReceived);
                                    }
                                }
                            }

                            // Provide new measurements to local concentrator, if defined, otherwise directly expose them to the consumer
                            if ((object)m_localConcentrator != null)
                                m_localConcentrator.SortMeasurements(measurements);
                            else
                                OnNewMeasurements(measurements);

                            // Gather statistics on received data
                            DateTime timeReceived = RealTime;

                            if (!m_useLocalClockAsRealTime && timeReceived.Ticks - m_lastStatisticsHelperUpdate > Ticks.PerSecond)
                            {
                                UpdateStatisticsHelpers();
                                m_lastStatisticsHelperUpdate = m_realTime;
                            }

                            m_lifetimeMeasurements += measurements.Count;
                            UpdateMeasurementsPerSecond(timeReceived, measurements.Count);

                            for (int x = 0; x < measurements.Count; x++)
                            {
                                long latency = timeReceived.Ticks - (long)measurements[x].Timestamp;

                                // Throw out latencies that exceed one hour as invalid
                                if (Math.Abs(latency) > Time.SecondsPerHour * Ticks.PerSecond)
                                    continue;

                                if (m_lifetimeMinimumLatency > latency || m_lifetimeMinimumLatency == 0)
                                    m_lifetimeMinimumLatency = latency;

                                if (m_lifetimeMaximumLatency < latency || m_lifetimeMaximumLatency == 0)
                                    m_lifetimeMaximumLatency = latency;

                                m_lifetimeTotalLatency += latency;
                                m_lifetimeLatencyMeasurements++;
                            }
                            break;
                        case ServerResponse.BufferBlock:
                            // Buffer block received - wrap as a buffer block measurement and expose back to consumer
                            uint sequenceNumber = BigEndian.ToUInt32(buffer, responseIndex);
                            int cacheIndex = (int)(sequenceNumber - m_expectedBufferBlockSequenceNumber);
                            BufferBlockMeasurement bufferBlockMeasurement;
                            Tuple<Guid, string, uint> measurementKey;
                            ushort signalIndex;

                            // Check if this buffer block has already been processed (e.g., mistaken retransmission due to timeout)
                            if (cacheIndex >= 0 && (cacheIndex >= m_bufferBlockCache.Count || (object)m_bufferBlockCache[cacheIndex] == null))
                            {
                                // Send confirmation that buffer block is received
                                SendServerCommand(ServerCommand.ConfirmBufferBlock, buffer.BlockCopy(responseIndex, 4));

                                // Get measurement key from signal index cache
                                signalIndex = BigEndian.ToUInt16(buffer, responseIndex + 4);

                                if (!m_signalIndexCache.Reference.TryGetValue(signalIndex, out measurementKey))
                                    throw new InvalidOperationException("Failed to find associated signal identification for runtime ID " + signalIndex);

                                // Skip the sequence number and signal index when creating the buffer block measurement
                                bufferBlockMeasurement = new BufferBlockMeasurement(buffer, responseIndex + 6, responseLength - 6)
                                {
                                    Key = MeasurementKey.LookUpOrCreate(measurementKey.Item1, measurementKey.Item2, measurementKey.Item3)
                                };

                                // Determine if this is the next buffer block in the sequence
                                if (sequenceNumber == m_expectedBufferBlockSequenceNumber)
                                {
                                    List<IMeasurement> bufferBlockMeasurements = new List<IMeasurement>();
                                    int i;

                                    // Add the buffer block measurement to the list of measurements to be published
                                    bufferBlockMeasurements.Add(bufferBlockMeasurement);
                                    m_expectedBufferBlockSequenceNumber++;

                                    // Add cached buffer block measurements to the list of measurements to be published
                                    for (i = 1; i < m_bufferBlockCache.Count; i++)
                                    {
                                        if ((object)m_bufferBlockCache[i] == null)
                                            break;

                                        bufferBlockMeasurements.Add(m_bufferBlockCache[i]);
                                        m_expectedBufferBlockSequenceNumber++;
                                    }

                                    // Remove published measurements from the buffer block queue
                                    if (m_bufferBlockCache.Count > 0)
                                        m_bufferBlockCache.RemoveRange(0, i);

                                    // Publish measurements
                                    OnNewMeasurements(bufferBlockMeasurements);
                                }
                                else
                                {
                                    // Ensure that the list has at least as many
                                    // elements as it needs to cache this measurement
                                    for (int i = m_bufferBlockCache.Count; i <= cacheIndex; i++)
                                        m_bufferBlockCache.Add(null);

                                    // Insert this buffer block into the proper location in the list
                                    m_bufferBlockCache[cacheIndex] = bufferBlockMeasurement;
                                }
                            }

                            m_lifetimeMeasurements += 1;
                            UpdateMeasurementsPerSecond(DateTime.UtcNow, 1);
                            break;
                        case ServerResponse.DataStartTime:
                            // Raise data start time event
                            OnDataStartTime(BigEndian.ToInt64(buffer, responseIndex));
                            break;
                        case ServerResponse.ProcessingComplete:
                            // Raise input processing completed event
                            OnProcessingComplete(InterpretResponseMessage(buffer, responseIndex, responseLength));
                            break;
                        case ServerResponse.UpdateSignalIndexCache:
                            // Deserialize new signal index cache
                            m_remoteSignalIndexCache = DeserializeSignalIndexCache(buffer.BlockCopy(responseIndex, responseLength));
                            m_signalIndexCache = new SignalIndexCache(DataSource, m_remoteSignalIndexCache);
                            FixExpectedMeasurementCounts();
                            break;
                        case ServerResponse.UpdateBaseTimes:
                            // Get active time index
                            m_timeIndex = BigEndian.ToInt32(buffer, responseIndex);
                            responseIndex += 4;

                            // Deserialize new base time offsets
                            m_baseTimeOffsets = new[] { BigEndian.ToInt64(buffer, responseIndex), BigEndian.ToInt64(buffer, responseIndex + 8) };
                            break;
                        case ServerResponse.UpdateCipherKeys:
                            // Move past active cipher index (not currently used anywhere else)
                            responseIndex++;

                            // Extract remaining response
                            byte[] bytes = buffer.BlockCopy(responseIndex, responseLength - 1);

                            // Decrypt response payload if subscription is authenticated
                            if (m_authenticated)
                                bytes = bytes.Decrypt(m_sharedSecret, CipherStrength.Aes256);

                            // Deserialize new cipher keys
                            keyIVs = new byte[2][][];
                            keyIVs[EvenKey] = new byte[2][];
                            keyIVs[OddKey] = new byte[2][];

                            int index = 0;
                            int bufferLen;

                            // Read even key size
                            bufferLen = BigEndian.ToInt32(bytes, index);
                            index += 4;

                            // Read even key
                            keyIVs[EvenKey][KeyIndex] = new byte[bufferLen];
                            Buffer.BlockCopy(bytes, index, keyIVs[EvenKey][KeyIndex], 0, bufferLen);
                            index += bufferLen;

                            // Read even initialization vector size
                            bufferLen = BigEndian.ToInt32(bytes, index);
                            index += 4;

                            // Read even initialization vector
                            keyIVs[EvenKey][IVIndex] = new byte[bufferLen];
                            Buffer.BlockCopy(bytes, index, keyIVs[EvenKey][IVIndex], 0, bufferLen);
                            index += bufferLen;

                            // Read odd key size
                            bufferLen = BigEndian.ToInt32(bytes, index);
                            index += 4;

                            // Read odd key
                            keyIVs[OddKey][KeyIndex] = new byte[bufferLen];
                            Buffer.BlockCopy(bytes, index, keyIVs[OddKey][KeyIndex], 0, bufferLen);
                            index += bufferLen;

                            // Read odd initialization vector size
                            bufferLen = BigEndian.ToInt32(bytes, index);
                            index += 4;

                            // Read odd initialization vector
                            keyIVs[OddKey][IVIndex] = new byte[bufferLen];
                            Buffer.BlockCopy(bytes, index, keyIVs[OddKey][IVIndex], 0, bufferLen);
                            //index += bufferLen;

                            // Exchange keys
                            m_keyIVs = keyIVs;

                            OnStatusMessage("Successfully established new cipher keys for data packet transmissions.");
                            break;
                        case ServerResponse.Notify:
                            // Skip the 4-byte hash
                            string message = m_encoding.GetString(buffer, responseIndex + 4, responseLength - 4);

                            // Display notification
                            OnStatusMessage("NOTIFICATION: {0}", message);
                            OnNotificationReceived(message);

                            // Send confirmation of receipt of the notification
                            SendServerCommand(ServerCommand.ConfirmNotification, buffer.BlockCopy(responseIndex, 4));
                            break;
                        case ServerResponse.ConfigurationChanged:
                            OnStatusMessage("Received notification from publisher that configuration has changed.");
                            OnServerConfigurationChanged();

                            // Initiate meta-data refresh when publisher configuration has changed - we only do this
                            // for automatic connections since API style connections have to manually initiate a
                            // meta-data refresh. API style connection should attach to server configuration changed
                            // event and request meta-data refresh to complete automated cycle.
                            if (m_autoConnect && m_autoSynchronizeMetadata)
                                SendServerCommand(ServerCommand.MetaDataRefresh, m_metadataFilters);
                            break;
                    }
                }
                catch (Exception ex)
                {
                    OnProcessException(new InvalidOperationException("Failed to process publisher response packet due to exception: " + ex.Message, ex));
                }
            }
        }
コード例 #2
0
        /// <summary>
        /// Event handler for service starting operations.
        /// </summary>
        /// <param name="sender">Event source.</param>
        /// <param name="e">Event arguments containing command line arguments passed into service at startup.</param>
        /// <remarks>
        /// Time-series framework uses this handler to load settings from configuration file as service is starting.
        /// </remarks>
        protected virtual void ServiceStartingHandler(object sender, EventArgs<string[]> e)
        {
            ShutdownHandler.Initialize();

            // Define a run-time log
            m_runTimeLog = new RunTimeLog();
            m_runTimeLog.FileName = "RunTimeLog.txt";
            m_runTimeLog.ProcessException += ProcessExceptionHandler;
            m_runTimeLog.Initialize();

            // Initialize Iaon session
            m_iaonSession = new IaonSession();
            m_iaonSession.StatusMessage += StatusMessageHandler;
            m_iaonSession.ProcessException += ProcessExceptionHandler;
            m_iaonSession.ConfigurationChanged += ConfigurationChangedHandler;

            // Create a handler for unobserved task exceptions
            TaskScheduler.UnobservedTaskException += TaskScheduler_UnobservedTaskException;

            // Make sure default service settings exist
            ConfigurationFile configFile = ConfigurationFile.Current;

            string servicePath = FilePath.GetAbsolutePath("");
            string cachePath = string.Format("{0}{1}ConfigurationCache{1}", servicePath, Path.DirectorySeparatorChar);
            string defaultLogPath = string.Format("{0}{1}Logs{1}", servicePath, Path.DirectorySeparatorChar);

            // System settings
            CategorizedSettingsElementCollection systemSettings = configFile.Settings["systemSettings"];
            systemSettings.Add("ConfigurationType", "Database", "Specifies type of configuration: Database, WebService, BinaryFile or XmlFile");
            systemSettings.Add("ConnectionString", "Provider=Microsoft.Jet.OLEDB.4.0;Data Source=IaonHost.mdb", "Configuration database connection string");
            systemSettings.Add("DataProviderString", "AssemblyName={System.Data, Version=2.0.0.0, Culture=neutral, PublicKeyToken=b77a5c561934e089};ConnectionType=System.Data.OleDb.OleDbConnection;AdapterType=System.Data.OleDb.OleDbDataAdapter", "Configuration database ADO.NET data provider assembly type creation string");
            systemSettings.Add("ConfigurationCachePath", cachePath, "Defines the path used to cache serialized configurations");
            systemSettings.Add("LogPath", defaultLogPath, "Defines the path used to archive log files");
            systemSettings.Add("MaxLogFiles", DefaultMaxLogFiles, "Defines the maximum number of log files to keep");
            systemSettings.Add("CachedConfigurationFile", "SystemConfiguration.xml", "File name for last known good system configuration (only cached for a Database or WebService connection)");
            systemSettings.Add("UniqueAdaptersIDs", "True", "Set to true if all runtime adapter ID's will be unique to allow for easier adapter specification");
            systemSettings.Add("ProcessPriority", "High", "Sets desired process priority: Normal, AboveNormal, High, RealTime");
            systemSettings.Add("AllowRemoteRestart", "True", "Controls ability to remotely restart the host service.");
            systemSettings.Add("MinThreadPoolWorkerThreads", DefaultMinThreadPoolSize, "Defines the minimum number of allowed thread pool worker threads.");
            systemSettings.Add("MaxThreadPoolWorkerThreads", DefaultMaxThreadPoolSize, "Defines the maximum number of allowed thread pool worker threads.");
            systemSettings.Add("MinThreadPoolIOPortThreads", DefaultMinThreadPoolSize, "Defines the minimum number of allowed thread pool I/O completion port threads (used by socket layer).");
            systemSettings.Add("MaxThreadPoolIOPortThreads", DefaultMaxThreadPoolSize, "Defines the maximum number of allowed thread pool I/O completion port threads (used by socket layer).");
            systemSettings.Add("ConfigurationBackups", DefaultConfigurationBackups, "Defines the total number of older backup configurations to maintain.");
            systemSettings.Add("PreferCachedConfiguration", "False", "Set to true to try the cached configuration first, before loading database configuration - typically used when cache is updated by external process.");
            systemSettings.Add("LocalCertificate", $"{ServiceName}.cer", "Path to the local certificate used by this server for authentication.");
            systemSettings.Add("RemoteCertificatesPath", @"Certs\Remotes", "Path to the directory where remote certificates are stored.");
            systemSettings.Add("DefaultCulture", "en-US", "Default culture to use for language, country/region and calendar formats.");

            // Example connection settings
            CategorizedSettingsElementCollection exampleSettings = configFile.Settings["exampleConnectionSettings"];
            exampleSettings.Add("SqlServer.ConnectionString", "Data Source=serverName; Initial Catalog=databaseName; User ID=userName; Password=password", "Example SQL Server database connection string");
            exampleSettings.Add("SqlServer.DataProviderString", "AssemblyName={System.Data, Version=4.0.0.0, Culture=neutral, PublicKeyToken=b77a5c561934e089}; ConnectionType=System.Data.SqlClient.SqlConnection; AdapterType=System.Data.SqlClient.SqlDataAdapter", "Example SQL Server database .NET provider string");
            exampleSettings.Add("MySQL.ConnectionString", "Server=serverName;Database=databaseName; Uid=root; Pwd=password; allow user variables = true;", "Example MySQL database connection string");
            exampleSettings.Add("MySQL.DataProviderString", "AssemblyName={MySql.Data, Version=6.3.6.0, Culture=neutral, PublicKeyToken=c5687fc88969c44d}; ConnectionType=MySql.Data.MySqlClient.MySqlConnection; AdapterType=MySql.Data.MySqlClient.MySqlDataAdapter", "Example MySQL database .NET provider string");
            exampleSettings.Add("Oracle.ConnectionString", "Data Source=tnsName; User ID=schemaUserName; Password=schemaPassword", "Example Oracle database connection string");
            exampleSettings.Add("Oracle.DataProviderString", "AssemblyName={Oracle.DataAccess, Version=2.112.2.0, Culture=neutral, PublicKeyToken=89b483f429c47342}; ConnectionType=Oracle.DataAccess.Client.OracleConnection; AdapterType=Oracle.DataAccess.Client.OracleDataAdapter", "Example Oracle database .NET provider string");
            exampleSettings.Add("SQLite.ConnectionString", "Data Source=databaseName.db; Version=3; Foreign Keys=True; FailIfMissing=True", "Example SQLite database connection string");
            exampleSettings.Add("SQLite.DataProviderString", "AssemblyName={System.Data.SQLite, Version=1.0.99.0, Culture=neutral, PublicKeyToken=db937bc2d44ff139}; ConnectionType=System.Data.SQLite.SQLiteConnection; AdapterType=System.Data.SQLite.SQLiteDataAdapter", "Example SQLite database .NET provider string");
            exampleSettings.Add("OleDB.ConnectionString", "Provider=Microsoft.Jet.OLEDB.4.0; Data Source=databaseName.mdb", "Example Microsoft Access (via OleDb) database connection string");
            exampleSettings.Add("OleDB.DataProviderString", "AssemblyName={System.Data, Version=4.0.0.0, Culture=neutral, PublicKeyToken=b77a5c561934e089}; ConnectionType=System.Data.OleDb.OleDbConnection; AdapterType=System.Data.OleDb.OleDbDataAdapter", "Example OleDb database .NET provider string");
            exampleSettings.Add("Odbc.ConnectionString", "Driver={SQL Server Native Client 10.0}; Server=serverName; Database=databaseName; Uid=userName; Pwd=password;", "Example ODBC database connection string");
            exampleSettings.Add("Odbc.DataProviderString", "AssemblyName={System.Data, Version=4.0.0.0, Culture=neutral, PublicKeyToken=b77a5c561934e089}; ConnectionType=System.Data.Odbc.OdbcConnection; AdapterType=System.Data.Odbc.OdbcDataAdapter", "Example ODBC database .NET provider string");
            exampleSettings.Add("WebService.ConnectionString", "http://localhost/ConfigSource/SystemConfiguration.xml", "Example web service connection string");
            exampleSettings.Add("XmlFile.ConnectionString", "SystemConfiguration.xml", "Example XML configuration file connection string");

            // Attempt to set default culture
            try
            {
                string defaultCulture = systemSettings["DefaultCulture"].ValueAs("en-US");
                CultureInfo.DefaultThreadCurrentCulture = CultureInfo.CreateSpecificCulture(defaultCulture);     // Defaults for date formatting, etc.
                CultureInfo.DefaultThreadCurrentUICulture = CultureInfo.CreateSpecificCulture(defaultCulture);   // Culture for resource strings, etc.
            }
            catch (Exception ex)
            {
                DisplayStatusMessage("Failed to set default culture due to exception, defaulting to \"{1}\": {0}", UpdateType.Alarm, ex.Message, CultureInfo.CurrentCulture.Name.ToNonNullNorEmptyString("Undetermined"));
                LogException(ex);
            }

            // Retrieve application log path as defined in the config file
            string logPath = FilePath.GetAbsolutePath(systemSettings["LogPath"].Value);

            // Make sure log directory exists
            try
            {
                if (!Directory.Exists(logPath))
                    Directory.CreateDirectory(logPath);
            }
            catch (Exception ex)
            {
                // Attempt to default back to common log file path
                if (!Directory.Exists(defaultLogPath))
                {
                    try
                    {
                        Directory.CreateDirectory(defaultLogPath);
                    }
                    catch
                    {
                        defaultLogPath = servicePath;
                    }
                }

                DisplayStatusMessage("Failed to create logging directory \"{0}\" due to exception, defaulting to \"{1}\": {2}", UpdateType.Alarm, logPath, defaultLogPath, ex.Message);
                LogException(ex);
                logPath = defaultLogPath;
            }

            int maxLogFiles = systemSettings["MaxLogFiles"].ValueAs(DefaultMaxLogFiles);

            try
            {
                Logger.FileWriter.SetPath(logPath);
                Logger.FileWriter.SetLoggingFileCount(maxLogFiles);
            }
            catch (Exception ex)
            {
                DisplayStatusMessage("Failed to set logging path \"{0}\" or max file count \"{1}\" due to exception: {2}", UpdateType.Alarm, logPath, maxLogFiles, ex.Message);
                LogException(ex);
            }

            // Retrieve configuration cache directory as defined in the config file
            cachePath = FilePath.GetAbsolutePath(systemSettings["ConfigurationCachePath"].Value);

            // Make sure configuration cache directory exists
            try
            {
                if (!Directory.Exists(cachePath))
                    Directory.CreateDirectory(cachePath);
            }
            catch (Exception ex)
            {
                DisplayStatusMessage("Failed to create configuration cache directory \"{0}\" due to exception: {1}", UpdateType.Alarm, cachePath, ex.Message);
                LogException(ex);
            }

            try
            {
                Directory.SetCurrentDirectory(servicePath);
            }
            catch (Exception ex)
            {
                DisplayStatusMessage("Failed to set current directory to execution path \"{0}\" due to exception: {1}", UpdateType.Alarm, servicePath, ex.Message);
                LogException(ex);
            }

            // Initialize system settings
            m_configurationType = systemSettings["ConfigurationType"].ValueAs<ConfigurationType>();
            m_cachedXmlConfigurationFile = FilePath.AddPathSuffix(cachePath) + systemSettings["CachedConfigurationFile"].Value;
            m_cachedBinaryConfigurationFile = FilePath.AddPathSuffix(cachePath) + FilePath.GetFileNameWithoutExtension(m_cachedXmlConfigurationFile) + ".bin";
            m_configurationBackups = systemSettings["ConfigurationBackups"].ValueAs(DefaultConfigurationBackups);
            m_uniqueAdapterIDs = systemSettings["UniqueAdaptersIDs"].ValueAsBoolean(true);
            m_allowRemoteRestart = systemSettings["AllowRemoteRestart"].ValueAsBoolean(true);
            m_preferCachedConfiguration = systemSettings["PreferCachedConfiguration"].ValueAsBoolean(false);

            m_reloadConfigQueue = ProcessQueue<Tuple<string, Action<bool>>>.CreateSynchronousQueue(ExecuteReloadConfig, 500.0D, Timeout.Infinite, false, false);
            m_reloadConfigQueue.ProcessException += m_iaonSession.ProcessExceptionHandler;

            m_configurationCacheOperation = new LongSynchronizedOperation(ExecuteConfigurationCache)
            {
                IsBackground = true
            };

            // Setup default thread pool size
            try
            {
                ThreadPool.SetMinThreads(systemSettings["MinThreadPoolWorkerThreads"].ValueAs(DefaultMinThreadPoolSize), systemSettings["MinThreadPoolIOPortThreads"].ValueAs(DefaultMinThreadPoolSize));
                ThreadPool.SetMaxThreads(systemSettings["MaxThreadPoolWorkerThreads"].ValueAs(DefaultMaxThreadPoolSize), systemSettings["MaxThreadPoolIOPortThreads"].ValueAs(DefaultMaxThreadPoolSize));
            }
            catch (Exception ex)
            {
                DisplayStatusMessage("Failed to set desired thread pool size due to exception: {0}", UpdateType.Alarm, ex.Message);
                LogException(ex);
            }

            // Define guid with query string delimiters according to database needs
            if (string.IsNullOrWhiteSpace(m_nodeIDQueryString))
                m_nodeIDQueryString = "'" + m_iaonSession.NodeID + "'";

            // Set up the configuration loader
            switch (m_configurationType)
            {
                case ConfigurationType.Database:
                    m_configurationLoader = new DatabaseConfigurationLoader
                    {
                        ConnectionString = systemSettings["ConnectionString"].Value,
                        DataProviderString = systemSettings["DataProviderString"].Value,
                        NodeIDQueryString = m_nodeIDQueryString
                    };

                    break;

                case ConfigurationType.WebService:
                    m_configurationLoader = new WebServiceConfigurationLoader
                    {
                        URI = systemSettings["ConnectionString"].Value
                    };

                    break;

                case ConfigurationType.BinaryFile:
                    m_configurationLoader = new BinaryFileConfigurationLoader
                    {
                        FilePath = systemSettings["ConnectionString"].Value
                    };

                    break;

                case ConfigurationType.XmlFile:
                    m_configurationLoader = new XMLConfigurationLoader
                    {
                        FilePath = systemSettings["ConnectionString"].Value
                    };

                    break;
            }

            m_binaryCacheConfigurationLoader = new BinaryFileConfigurationLoader
            {
                FilePath = m_cachedBinaryConfigurationFile
            };

            m_xmlCacheConfigurationLoader = new XMLConfigurationLoader
            {
                FilePath = m_cachedXmlConfigurationFile
            };

            m_configurationLoader.StatusMessage += (o, args) => DisplayStatusMessage(args.Argument, UpdateType.Information);
            m_binaryCacheConfigurationLoader.StatusMessage += (o, args) => DisplayStatusMessage(args.Argument, UpdateType.Information);
            m_xmlCacheConfigurationLoader.StatusMessage += (o, args) => DisplayStatusMessage(args.Argument, UpdateType.Information);

            m_configurationLoader.ProcessException += ConfigurationLoader_ProcessException;
            m_binaryCacheConfigurationLoader.ProcessException += ConfigurationLoader_ProcessException;
            m_xmlCacheConfigurationLoader.ProcessException += ConfigurationLoader_ProcessException;

            m_reloadConfigQueue.Start();

#if !MONO
            try
            {
                // Attempt to assign desired process priority. Note that process will require SeIncreaseBasePriorityPrivilege or 
                // Administrative privileges to make this change
                Process.GetCurrentProcess().PriorityClass = systemSettings["ProcessPriority"].ValueAs<ProcessPriorityClass>();
            }
            catch (Exception ex)
            {
                LogException(ex);
            }
#endif
        }