/******************************************************** * CLASS METHODS *********************************************************/ /// <summary> /// Launch the algorithm manager to run this strategy /// </summary> /// <param name="job">Algorithm job</param> /// <param name="algorithm">Algorithm instance</param> /// <param name="feed">Datafeed object</param> /// <param name="transactions">Transaction manager object</param> /// <param name="results">Result handler object</param> /// <param name="setup">Setup handler object</param> /// <param name="realtime">Realtime processing object</param> /// <remarks>Modify with caution</remarks> public static void Run(AlgorithmNodePacket job, IAlgorithm algorithm, IDataFeed feed, ITransactionHandler transactions, IResultHandler results, ISetupHandler setup, IRealTimeHandler realtime) { //Initialize: _dataPointCount = 0; var startingPortfolioValue = setup.StartingPortfolioValue; var backtestMode = (job.Type == PacketType.BacktestNode); var methodInvokers = new Dictionary <Type, MethodInvoker>(); var marginCallFrequency = TimeSpan.FromMinutes(5); var nextMarginCallTime = DateTime.MinValue; //Initialize Properties: _algorithmId = job.AlgorithmId; _algorithmState = AlgorithmStatus.Running; _previousTime = setup.StartingDate.Date; //Create the method accessors to push generic types into algorithm: Find all OnData events: // Algorithm 1.0 data accessors var hasOnTradeBar = AddMethodInvoker <Dictionary <string, TradeBar> >(algorithm, methodInvokers, "OnTradeBar"); var hasOnTick = AddMethodInvoker <Dictionary <string, List <Tick> > >(algorithm, methodInvokers, "OnTick"); // Algorithm 2.0 data accessors var hasOnDataTradeBars = AddMethodInvoker <TradeBars>(algorithm, methodInvokers); var hasOnDataTicks = AddMethodInvoker <Ticks>(algorithm, methodInvokers); // determine what mode we're in var backwardsCompatibilityMode = !hasOnDataTradeBars && !hasOnDataTicks; // dividend and split events var hasOnDataDividends = AddMethodInvoker <Dividends>(algorithm, methodInvokers); var hasOnDataSplits = AddMethodInvoker <Splits>(algorithm, methodInvokers); //Go through the subscription types and create invokers to trigger the event handlers for each custom type: foreach (var config in feed.Subscriptions) { //If type is a tradebar, combine tradebars and ticks into unified array: if (config.Type.Name != "TradeBar" && config.Type.Name != "Tick") { //Get the matching method for this event handler - e.g. public void OnData(Quandl data) { .. } var genericMethod = (algorithm.GetType()).GetMethod("OnData", new[] { config.Type }); //If we already have this Type-handler then don't add it to invokers again. if (methodInvokers.ContainsKey(config.Type)) { continue; } //If we couldnt find the event handler, let the user know we can't fire that event. if (genericMethod == null) { algorithm.RunTimeError = new Exception("Data event handler not found, please create a function matching this template: public void OnData(" + config.Type.Name + " data) { }"); _algorithmState = AlgorithmStatus.RuntimeError; return; } methodInvokers.Add(config.Type, genericMethod.DelegateForCallMethod()); } } //Loop over the queues: get a data collection, then pass them all into relevent methods in the algorithm. Log.Debug("AlgorithmManager.Run(): Algorithm initialized, launching time loop."); foreach (var newData in DataStream.GetData(feed, setup.StartingDate)) { //Check this backtest is still running: if (_algorithmState != AlgorithmStatus.Running) { break; } //Execute with TimeLimit Monitor: if (Isolator.IsCancellationRequested) { return; } var time = DataStream.AlorithmTime; //If we're in backtest mode we need to capture the daily performance. We do this here directly //before updating the algorithm state with the new data from this time step, otherwise we'll //produce incorrect samples (they'll take into account this time step's new price values) if (backtestMode) { //Refresh the realtime event monitor: //in backtest mode use the algorithms clock as realtime. realtime.SetTime(time); //On day-change sample equity and daily performance for statistics calculations if (_previousTime.Date != time.Date) { //Sample the portfolio value over time for chart. results.SampleEquity(_previousTime, Math.Round(algorithm.Portfolio.TotalPortfolioValue, 4)); //Check for divide by zero if (startingPortfolioValue == 0m) { results.SamplePerformance(_previousTime.Date, 0); } else { results.SamplePerformance(_previousTime.Date, Math.Round((algorithm.Portfolio.TotalPortfolioValue - startingPortfolioValue) * 100 / startingPortfolioValue, 10)); } startingPortfolioValue = algorithm.Portfolio.TotalPortfolioValue; } } //Update algorithm state after capturing performance from previous day //On each time step push the real time prices to the cashbook so we can have updated conversion rates algorithm.Portfolio.CashBook.Update(newData); //Update the securities properties: first before calling user code to avoid issues with data algorithm.Securities.Update(time, newData); // perform margin calls, in live mode we can also use realtime to emit these if (time >= nextMarginCallTime || (Engine.LiveMode && nextMarginCallTime > DateTime.Now)) { // determine if there are possible margin call orders to be executed var marginCallOrders = algorithm.Portfolio.ScanForMarginCall(); if (marginCallOrders.Count != 0) { // execute the margin call orders var executedOrders = algorithm.Portfolio.MarginCallModel.ExecuteMarginCall(marginCallOrders); foreach (var order in executedOrders) { algorithm.Error(string.Format("Executed MarginCallOrder: {0} - Quantity: {1} @ {2}", order.Symbol, order.Quantity, order.Price)); } } nextMarginCallTime = time + marginCallFrequency; } //Check if the user's signalled Quit: loop over data until day changes. if (algorithm.GetQuit()) { _algorithmState = AlgorithmStatus.Quit; break; } if (algorithm.RunTimeError != null) { _algorithmState = AlgorithmStatus.RuntimeError; break; } //Pass in the new time first: algorithm.SetDateTime(time); //Trigger the data events: Invoke the types we have data for: var oldBars = new Dictionary <string, TradeBar>(); var oldTicks = new Dictionary <string, List <Tick> >(); var newBars = new TradeBars(time); var newTicks = new Ticks(time); var newDividends = new Dividends(time); var newSplits = new Splits(time); //Invoke all non-tradebars, non-ticks methods and build up the TradeBars and Ticks dictionaries // --> i == Subscription Configuration Index, so we don't need to compare types. foreach (var i in newData.Keys) { //Data point and config of this point: var dataPoints = newData[i]; var config = feed.Subscriptions[i]; //Keep track of how many data points we've processed _dataPointCount += dataPoints.Count; //We don't want to pump data that we added just for currency conversions if (config.IsInternalFeed) { continue; } //Create TradeBars Unified Data --> OR --> invoke generic data event. One loop. // Aggregate Dividends and Splits -- invoke portfolio application methods foreach (var dataPoint in dataPoints) { var dividend = dataPoint as Dividend; if (dividend != null) { Log.Trace("AlgorithmManager.Run(): Applying Dividend for " + dividend.Symbol); // if this is a dividend apply to portfolio algorithm.Portfolio.ApplyDividend(dividend); if (hasOnDataDividends) { // and add to our data dictionary to pump into OnData(Dividends data) newDividends.Add(dividend); } continue; } var split = dataPoint as Split; if (split != null) { Log.Trace("AlgorithmManager.Run(): Applying Split for " + split.Symbol); // if this is a split apply to portfolio algorithm.Portfolio.ApplySplit(split); if (hasOnDataSplits) { // and add to our data dictionary to pump into OnData(Splits data) newSplits.Add(split); } continue; } //Update registered consolidators for this symbol index try { for (var j = 0; j < config.Consolidators.Count; j++) { config.Consolidators[j].Update(dataPoint); } } catch (Exception err) { algorithm.RunTimeError = err; _algorithmState = AlgorithmStatus.RuntimeError; Log.Error("AlgorithmManager.Run(): RuntimeError: Consolidators update: " + err.Message); return; } // TRADEBAR -- add to our dictionary var bar = dataPoint as TradeBar; if (bar != null) { try { if (backwardsCompatibilityMode) { oldBars[bar.Symbol] = bar; } else { newBars[bar.Symbol] = bar; } } catch (Exception err) { Log.Error(time.ToLongTimeString() + " >> " + bar.Time.ToLongTimeString() + " >> " + bar.Symbol + " >> " + bar.Value.ToString("C")); Log.Error("AlgorithmManager.Run(): Failed to add TradeBar (" + bar.Symbol + ") Time: (" + time.ToLongTimeString() + ") Count:(" + newBars.Count + ") " + err.Message); } continue; } // TICK -- add to our dictionary var tick = dataPoint as Tick; if (tick != null) { if (backwardsCompatibilityMode) { List <Tick> ticks; if (!oldTicks.TryGetValue(tick.Symbol, out ticks)) { ticks = new List <Tick>(3); oldTicks.Add(tick.Symbol, ticks); } ticks.Add(tick); } else { List <Tick> ticks; if (!newTicks.TryGetValue(tick.Symbol, out ticks)) { ticks = new List <Tick>(3); newTicks.Add(tick.Symbol, ticks); } ticks.Add(tick); } continue; } // if it was nothing else then it must be custom data // CUSTOM DATA -- invoke on data method //Send data into the generic algorithm event handlers try { methodInvokers[config.Type](algorithm, dataPoint); } catch (Exception err) { algorithm.RunTimeError = err; _algorithmState = AlgorithmStatus.RuntimeError; Log.Debug("AlgorithmManager.Run(): RuntimeError: Custom Data: " + err.Message + " STACK >>> " + err.StackTrace); return; } } } try { // fire off the dividend and split events before pricing events if (hasOnDataDividends && newDividends.Count != 0) { methodInvokers[typeof(Dividends)](algorithm, newDividends); } if (hasOnDataSplits && newSplits.Count != 0) { methodInvokers[typeof(Splits)](algorithm, newSplits); } } catch (Exception err) { algorithm.RunTimeError = err; _algorithmState = AlgorithmStatus.RuntimeError; Log.Debug("AlgorithmManager.Run(): RuntimeError: Dividends/Splits: " + err.Message + " STACK >>> " + err.StackTrace); return; } //After we've fired all other events in this second, fire the pricing events: if (backwardsCompatibilityMode) { //Log.Debug("AlgorithmManager.Run(): Invoking v1.0 Event Handlers..."); try { if (hasOnTradeBar && oldBars.Count > 0) { methodInvokers[typeof(Dictionary <string, TradeBar>)](algorithm, oldBars); } if (hasOnTick && oldTicks.Count > 0) { methodInvokers[typeof(Dictionary <string, List <Tick> >)](algorithm, oldTicks); } } catch (Exception err) { algorithm.RunTimeError = err; _algorithmState = AlgorithmStatus.RuntimeError; Log.Debug("AlgorithmManager.Run(): RuntimeError: Backwards Compatibility Mode: " + err.Message + " STACK >>> " + err.StackTrace); return; } } else { //Log.Debug("AlgorithmManager.Run(): Invoking v2.0 Event Handlers..."); try { if (hasOnDataTradeBars && newBars.Count > 0) { methodInvokers[typeof(TradeBars)](algorithm, newBars); } if (hasOnDataTicks && newTicks.Count > 0) { methodInvokers[typeof(Ticks)](algorithm, newTicks); } } catch (Exception err) { algorithm.RunTimeError = err; _algorithmState = AlgorithmStatus.RuntimeError; Log.Debug("AlgorithmManager.Run(): RuntimeError: New Style Mode: " + err.Message + " STACK >>> " + err.StackTrace); return; } } //If its the historical/paper trading models, wait until market orders have been "filled" // Manually trigger the event handler to prevent thread switch. transactions.ProcessSynchronousEvents(); //Save the previous time for the sample calculations _previousTime = time; // Process any required events of the results handler such as sampling assets, equity, or stock prices. results.ProcessSynchronousEvents(); } // End of ForEach DataStream //Stream over:: Send the final packet and fire final events: Log.Trace("AlgorithmManager.Run(): Firing On End Of Algorithm..."); try { algorithm.OnEndOfAlgorithm(); } catch (Exception err) { _algorithmState = AlgorithmStatus.RuntimeError; algorithm.RunTimeError = new Exception("Error running OnEndOfAlgorithm(): " + err.Message, err.InnerException); Log.Debug("AlgorithmManager.OnEndOfAlgorithm(): " + err.Message + " STACK >>> " + err.StackTrace); return; } // Process any required events of the results handler such as sampling assets, equity, or stock prices. results.ProcessSynchronousEvents(forceProcess: true); //Liquidate Holdings for Calculations: if (_algorithmState == AlgorithmStatus.Liquidated || !Engine.LiveMode) { // without this we can't liquidate equities since the exchange is 'technically' closed var hackedFrontier = algorithm.Time.AddMilliseconds(-1); algorithm.SetDateTime(hackedFrontier); foreach (var security in algorithm.Securities) { security.Value.SetMarketPrice(hackedFrontier, null); } Log.Trace("AlgorithmManager.Run(): Liquidating algorithm holdings..."); algorithm.Liquidate(); results.LogMessage("Algorithm Liquidated"); results.SendStatusUpdate(job.AlgorithmId, AlgorithmStatus.Liquidated); } //Manually stopped the algorithm if (_algorithmState == AlgorithmStatus.Stopped) { Log.Trace("AlgorithmManager.Run(): Stopping algorithm..."); results.LogMessage("Algorithm Stopped"); results.SendStatusUpdate(job.AlgorithmId, AlgorithmStatus.Stopped); } //Backtest deleted. if (_algorithmState == AlgorithmStatus.Deleted) { Log.Trace("AlgorithmManager.Run(): Deleting algorithm..."); results.DebugMessage("Algorithm Id:(" + job.AlgorithmId + ") Deleted by request."); results.SendStatusUpdate(job.AlgorithmId, AlgorithmStatus.Deleted); } //Algorithm finished, send regardless of commands: results.SendStatusUpdate(job.AlgorithmId, AlgorithmStatus.Completed); //Take final samples: results.SampleRange(algorithm.GetChartUpdates()); results.SampleEquity(DataStream.AlorithmTime, Math.Round(algorithm.Portfolio.TotalPortfolioValue, 4)); results.SamplePerformance(DataStream.AlorithmTime, Math.Round((algorithm.Portfolio.TotalPortfolioValue - startingPortfolioValue) * 100 / startingPortfolioValue, 10)); } // End of Run();
/******************************************************** * CLASS METHODS *********************************************************/ /// <summary> /// Launch the algorithm manager to run this strategy /// </summary> /// <param name="job">Algorithm job</param> /// <param name="algorithm">Algorithm instance</param> /// <param name="feed">Datafeed object</param> /// <param name="transactions">Transaction manager object</param> /// <param name="results">Result handler object</param> /// <param name="setup">Setup handler object</param> /// <param name="realtime">Realtime processing object</param> /// <remarks>Modify with caution</remarks> public static void Run(AlgorithmNodePacket job, IAlgorithm algorithm, IDataFeed feed, ITransactionHandler transactions, IResultHandler results, ISetupHandler setup, IRealTimeHandler realtime) { //Initialize: var backwardsCompatibilityMode = false; var tradebarsType = typeof(TradeBars); var ticksType = typeof(Ticks); var startingPortfolioValue = setup.StartingCapital; var backtestMode = (job.Type == PacketType.BacktestNode); var methodInvokers = new Dictionary <Type, MethodInvoker>(); //Initialize Properties: _frontier = setup.StartingDate; _runtimeError = null; _algorithmId = job.AlgorithmId; _algorithmState = AlgorithmStatus.Running; _previousTime = setup.StartingDate.Date; //Create the method accessors to push generic types into algorithm: Find all OnData events: //Algorithm 1.0 Data Accessors. //If the users defined these methods, add them in manually. This allows keeping backwards compatibility to algorithm 1.0. var oldTradeBarsMethodInfo = (algorithm.GetType()).GetMethod("OnTradeBar", new[] { typeof(Dictionary <string, TradeBar>) }); var oldTicksMethodInfo = (algorithm.GetType()).GetMethod("OnTick", new[] { typeof(Dictionary <string, List <Tick> >) }); //Algorithm 2.0 Data Generics Accessors. //New hidden access to tradebars with custom type. var newTradeBarsMethodInfo = (algorithm.GetType()).GetMethod("OnData", new[] { tradebarsType }); var newTicksMethodInfo = (algorithm.GetType()).GetMethod("OnData", new[] { ticksType }); if (newTradeBarsMethodInfo == null && newTicksMethodInfo == null) { backwardsCompatibilityMode = true; if (oldTradeBarsMethodInfo != null) { methodInvokers.Add(tradebarsType, oldTradeBarsMethodInfo.DelegateForCallMethod()); } if (oldTradeBarsMethodInfo != null) { methodInvokers.Add(ticksType, oldTicksMethodInfo.DelegateForCallMethod()); } } else { backwardsCompatibilityMode = false; if (newTradeBarsMethodInfo != null) { methodInvokers.Add(tradebarsType, newTradeBarsMethodInfo.DelegateForCallMethod()); } if (newTicksMethodInfo != null) { methodInvokers.Add(ticksType, newTicksMethodInfo.DelegateForCallMethod()); } } //Go through the subscription types and create invokers to trigger the event handlers for each custom type: foreach (var config in feed.Subscriptions) { //If type is a tradebar, combine tradebars and ticks into unified array: if (config.Type.Name != "TradeBar" && config.Type.Name != "Tick") { //Get the matching method for this event handler - e.g. public void OnData(Quandl data) { .. } var genericMethod = (algorithm.GetType()).GetMethod("OnData", new[] { config.Type }); //Is we already have this Type-handler then don't add it to invokers again. if (methodInvokers.ContainsKey(config.Type)) { continue; } //If we couldnt find the event handler, let the user know we can't fire that event. if (genericMethod == null) { _runtimeError = new Exception("Data event handler not found, please create a function matching this template: public void OnData(" + config.Type.Name + " data) { }"); _algorithmState = AlgorithmStatus.RuntimeError; return; } methodInvokers.Add(config.Type, genericMethod.DelegateForCallMethod()); } } //Loop over the queues: get a data collection, then pass them all into relevent methods in the algorithm. Log.Debug("AlgorithmManager.Run(): Algorithm initialized, launching time loop."); foreach (var newData in DataStream.GetData(feed, setup.StartingDate)) { //Check this backtest is still running: if (_algorithmState != AlgorithmStatus.Running) { break; } //Go over each time stamp we've collected, pass it into the algorithm in order: foreach (var time in newData.Keys) { //Set the time frontier: _frontier = time; //Execute with TimeLimit Monitor: if (Isolator.IsCancellationRequested) { return; } //Fire EOD if the time packet we just processed is greater if (backtestMode) { //Refresh the realtime event monitor: //in backtest mode use the algorithms clock as realtime. realtime.SetTime(time); //On day-change sample equity and daily performance for statistics calculations if (_previousTime.Date != time.Date) { //Sample the portfolio value over time for chart. results.SampleEquity(_previousTime, Math.Round(algorithm.Portfolio.TotalPortfolioValue, 4)); if (startingPortfolioValue == 0) { results.SamplePerformance(_previousTime.Date, 0); } else { results.SamplePerformance(_previousTime.Date, Math.Round((algorithm.Portfolio.TotalPortfolioValue - startingPortfolioValue) * 100 / startingPortfolioValue, 10)); } startingPortfolioValue = algorithm.Portfolio.TotalPortfolioValue; } } //Check if the user's signalled Quit: loop over data until day changes. if (algorithm.GetQuit()) { _algorithmState = AlgorithmStatus.Quit; break; } //Pass in the new time first: algorithm.SetDateTime(time); //Trigger the data events: Invoke the types we have data for: var oldBars = new Dictionary <string, TradeBar>(); var oldTicks = new Dictionary <string, List <Tick> >(); var newBars = new TradeBars(time); var newTicks = new Ticks(time); //Invoke all non-tradebars, non-ticks methods: // --> i == Subscription Configuration Index, so we don't need to compare types. foreach (var i in newData[time].Keys) { //Data point and config of this point: var dataPoints = newData[time][i]; var config = feed.Subscriptions[i]; //Create TradeBars Unified Data --> OR --> invoke generic data event. One loop. foreach (var dataPoint in dataPoints) { //Update the securities properties: first before calling user code to avoid issues with data algorithm.Securities.Update(time, dataPoint); //Update registered consolidators for this symbol index for (var j = 0; j < config.Consolidators.Count; j++) { config.Consolidators[j].Update(dataPoint); } switch (config.Type.Name) { case "TradeBar": var bar = dataPoint as TradeBar; try { if (bar != null) { if (backwardsCompatibilityMode) { if (!oldBars.ContainsKey(bar.Symbol)) { oldBars.Add(bar.Symbol, bar); } } else { if (!newBars.ContainsKey(bar.Symbol)) { newBars.Add(bar.Symbol, bar); } } } } catch (Exception err) { Log.Error(time.ToLongTimeString() + " >> " + bar.Time.ToLongTimeString() + " >> " + bar.Symbol + " >> " + bar.Value.ToString("C")); Log.Error("AlgorithmManager.Run(): Failed to add TradeBar (" + bar.Symbol + ") Time: (" + time.ToLongTimeString() + ") Count:(" + newBars.Count + ") " + err.Message); } break; case "Tick": var tick = dataPoint as Tick; if (tick != null) { if (backwardsCompatibilityMode) { if (!oldTicks.ContainsKey(tick.Symbol)) { oldTicks.Add(tick.Symbol, new List <Tick>()); } oldTicks[tick.Symbol].Add(tick); } else { if (!newTicks.ContainsKey(tick.Symbol)) { newTicks.Add(tick.Symbol, new List <Tick>()); } newTicks[tick.Symbol].Add(tick); } } break; default: //Send data into the generic algorithm event handlers try { methodInvokers[config.Type](algorithm, dataPoint); } catch (Exception err) { _runtimeError = err; _algorithmState = AlgorithmStatus.RuntimeError; Log.Debug("AlgorithmManager.Run(): RuntimeError: Custom Data: " + err.Message + " STACK >>> " + err.StackTrace); return; } break; } } } //After we've fired all other events in this second, fire the pricing events: if (backwardsCompatibilityMode) { //Log.Debug("AlgorithmManager.Run(): Invoking v1.0 Event Handlers..."); try { if (oldTradeBarsMethodInfo != null && oldBars.Count > 0) { methodInvokers[tradebarsType](algorithm, oldBars); } if (oldTicksMethodInfo != null && oldTicks.Count > 0) { methodInvokers[ticksType](algorithm, oldTicks); } } catch (Exception err) { _runtimeError = err; _algorithmState = AlgorithmStatus.RuntimeError; Log.Debug("AlgorithmManager.Run(): RuntimeError: Backwards Compatibility Mode: " + err.Message + " STACK >>> " + err.StackTrace); return; } } else { //Log.Debug("AlgorithmManager.Run(): Invoking v2.0 Event Handlers..."); try { if (newTradeBarsMethodInfo != null && newBars.Count > 0) { methodInvokers[tradebarsType](algorithm, newBars); } if (newTicksMethodInfo != null && newTicks.Count > 0) { methodInvokers[ticksType](algorithm, newTicks); } } catch (Exception err) { _runtimeError = err; _algorithmState = AlgorithmStatus.RuntimeError; Log.Debug("AlgorithmManager.Run(): RuntimeError: New Style Mode: " + err.Message + " STACK >>> " + err.StackTrace); return; } } //If its the historical/paper trading models, wait until market orders have been "filled" // Manually trigger the event handler to prevent thread switch. transactions.ProcessSynchronousEvents(); //Save the previous time for the sample calculations _previousTime = time; } // End of Time Loop // Process any required events of the results handler such as sampling assets, equity, or stock prices. results.ProcessSynchronousEvents(); } // End of ForEach DataStream //Stream over:: Send the final packet and fire final events: Log.Trace("AlgorithmManager.Run(): Firing On End Of Algorithm..."); try { algorithm.OnEndOfAlgorithm(); } catch (Exception err) { _algorithmState = AlgorithmStatus.RuntimeError; _runtimeError = new Exception("Error running OnEndOfAlgorithm(): " + err.Message, err.InnerException); Log.Debug("AlgorithmManager.OnEndOfAlgorithm(): " + err.Message + " STACK >>> " + err.StackTrace); return; } // Process any required events of the results handler such as sampling assets, equity, or stock prices. results.ProcessSynchronousEvents(forceProcess: true); //Liquidate Holdings for Calculations: if (_algorithmState == AlgorithmStatus.Liquidated || !Engine.LiveMode) { Log.Trace("AlgorithmManager.Run(): Liquidating algorithm holdings..."); algorithm.Liquidate(); results.LogMessage("Algorithm Liquidated"); results.SendStatusUpdate(job.AlgorithmId, AlgorithmStatus.Liquidated); } //Manually stopped the algorithm if (_algorithmState == AlgorithmStatus.Stopped) { Log.Trace("AlgorithmManager.Run(): Stopping algorithm..."); results.LogMessage("Algorithm Stopped"); results.SendStatusUpdate(job.AlgorithmId, AlgorithmStatus.Stopped); } //Backtest deleted. if (_algorithmState == AlgorithmStatus.Deleted) { Log.Trace("AlgorithmManager.Run(): Deleting algorithm..."); results.DebugMessage("Algorithm Id:(" + job.AlgorithmId + ") Deleted by request."); results.SendStatusUpdate(job.AlgorithmId, AlgorithmStatus.Deleted); } //Algorithm finished, send regardless of commands: results.SendStatusUpdate(job.AlgorithmId, AlgorithmStatus.Completed); //Take final samples: results.SampleRange(algorithm.GetChartUpdates()); results.SampleEquity(_frontier, Math.Round(algorithm.Portfolio.TotalPortfolioValue, 4)); results.SamplePerformance(_frontier, Math.Round((algorithm.Portfolio.TotalPortfolioValue - startingPortfolioValue) * 100 / startingPortfolioValue, 10)); } // End of Run();