public QuickPulseDataSample(QuickPulseDataAccumulator accumulator, IDictionary <string, Tuple <PerformanceCounterData, double> > perfData)
{
if (accumulator == null)
{
throw new ArgumentNullException(nameof(accumulator));
}
if (perfData == null)
{
throw new ArgumentNullException(nameof(perfData));
}
if (accumulator.StartTimestamp == null)
{
throw new ArgumentNullException(nameof(accumulator.StartTimestamp));
}
if (accumulator.EndTimestamp == null)
{
throw new ArgumentNullException(nameof(accumulator.EndTimestamp));
}
this.StartTimestamp = accumulator.StartTimestamp.Value;
this.EndTimestamp = accumulator.EndTimestamp.Value;
if ((this.EndTimestamp - this.StartTimestamp) < TimeSpan.Zero)
{
throw new InvalidOperationException("StartTimestamp must be less than EndTimestamp.");
}
TimeSpan sampleDuration = this.EndTimestamp - this.StartTimestamp;
Tuple <long, long> requestCountAndDuration = QuickPulseDataAccumulator.DecodeCountAndDuration(accumulator.AIRequestCountAndDurationInTicks);
long requestCount = requestCountAndDuration.Item1;
long requestDurationInTicks = requestCountAndDuration.Item2;
this.AIRequests = (int)requestCount;
this.AIRequestsPerSecond = sampleDuration.TotalSeconds > 0 ? requestCount / sampleDuration.TotalSeconds : 0;
this.AIRequestDurationAveInMs = requestCount > 0 ? (double)requestDurationInTicks / TimeSpan.TicksPerMillisecond / requestCount : 0;
this.AIRequestsFailedPerSecond = sampleDuration.TotalSeconds > 0 ? accumulator.AIRequestFailureCount / sampleDuration.TotalSeconds : 0;
this.AIRequestsSucceededPerSecond = sampleDuration.TotalSeconds > 0 ? accumulator.AIRequestSuccessCount / sampleDuration.TotalSeconds : 0;
Tuple <long, long> dependencyCountAndDuration = QuickPulseDataAccumulator.DecodeCountAndDuration(accumulator.AIDependencyCallCountAndDurationInTicks);
long dependencyCount = dependencyCountAndDuration.Item1;
long dependencyDurationInTicks = dependencyCountAndDuration.Item2;
this.AIDependencyCalls = (int)dependencyCount;
this.AIDependencyCallsPerSecond = sampleDuration.TotalSeconds > 0 ? dependencyCount / sampleDuration.TotalSeconds : 0;
this.AIDependencyCallDurationAveInMs = dependencyCount > 0 ? (double)dependencyDurationInTicks / TimeSpan.TicksPerMillisecond / dependencyCount : 0;
this.AIDependencyCallsFailedPerSecond = sampleDuration.TotalSeconds > 0 ? accumulator.AIDependencyCallFailureCount / sampleDuration.TotalSeconds : 0;
this.AIDependencyCallsSucceededPerSecond = sampleDuration.TotalSeconds > 0 ? accumulator.AIDependencyCallSuccessCount / sampleDuration.TotalSeconds : 0;
this.AIExceptionsPerSecond = sampleDuration.TotalSeconds > 0 ? accumulator.AIExceptionCount / sampleDuration.TotalSeconds : 0;
this.PerfCountersLookup = perfData.ToDictionary(
p => (QuickPulseDefaults.CounterOriginalStringMapping.ContainsKey(p.Value.Item1.OriginalString) ? QuickPulseDefaults.CounterOriginalStringMapping[p.Value.Item1.OriginalString] : p.Value.Item1.OriginalString),
p => p.Value.Item2);
this.TelemetryDocuments = accumulator.TelemetryDocuments.ToArray();
}
public QuickPulseDataAccumulatorManager(CollectionConfiguration collectionConfiguration)
{
if (collectionConfiguration == null)
{
throw new ArgumentNullException(nameof(collectionConfiguration));
}
this.currentDataAccumulator = new QuickPulseDataAccumulator(collectionConfiguration);
}
public void QuickPulseDataSampleCalculatesAIDependencyCallsFailedPerSecondCorrectly()
{
// ARRANGE
var accumulator = new QuickPulseDataAccumulator
{
StartTimestamp = DateTimeOffset.UtcNow,
EndTimestamp = DateTimeOffset.UtcNow.AddSeconds(2),
AIDependencyCallFailureCount = 10
};
// ACT
var dataSample = new QuickPulseDataSample(accumulator, this.dummyDictionary);
// ASSERT
Assert.AreEqual(10.0 / 2, dataSample.AIDependencyCallsFailedPerSecond);
}
public void QuickPulseDataSampleCalculatesAIDependencyCallDurationAveWhenDependencyCallCountIsZeroCorrectly()
{
// ARRANGE
var accumulator = new QuickPulseDataAccumulator
{
StartTimestamp = DateTimeOffset.UtcNow,
EndTimestamp = DateTimeOffset.UtcNow.AddSeconds(2),
AIDependencyCallCountAndDurationInTicks =
QuickPulseDataAccumulator.EncodeCountAndDuration(0, TimeSpan.FromSeconds(5).Ticks)
};
// ACT
var dataSample = new QuickPulseDataSample(accumulator, this.dummyDictionary);
// ASSERT
Assert.AreEqual(0.0, dataSample.AIDependencyCallDurationAveInMs);
}
public void QuickPulseDataAccumulatorCollectsTelemetryItemsInThreadSafeManner()
{
// ARRANGE
var accumulator = new QuickPulseDataAccumulator();
// ACT
var iterationCount = 1000;
var concurrency = 12;
Action addItemTask =
() =>
Enumerable.Range(0, iterationCount)
.ToList()
.ForEach(
i => accumulator.TelemetryDocuments.Push(new RequestTelemetryDocument()
{
Name = i.ToString(CultureInfo.InvariantCulture)
}));
var tasks = new List<Action>();
for (int i = 0; i < concurrency; i++)
{
tasks.Add(addItemTask);
}
Parallel.Invoke(new ParallelOptions() { MaxDegreeOfParallelism = concurrency }, tasks.ToArray());
// ASSERT
var dict = new Dictionary<int, int>();
foreach (var item in accumulator.TelemetryDocuments)
{
int requestNumber = int.Parse(((RequestTelemetryDocument)item).Name, CultureInfo.InvariantCulture);
if (dict.ContainsKey(requestNumber))
{
dict[requestNumber]++;
}
else
{
dict[requestNumber] = 1;
}
}
Assert.AreEqual(iterationCount, dict.Count);
Assert.IsTrue(dict.All(pair => pair.Value == concurrency));
}
public QuickPulseDataAccumulator CompleteCurrentDataAccumulator()
{
/*
Here we need to
- promote currentDataAccumulator to completedDataAccumulator
- reset (zero out) the new currentDataAccumulator
Certain telemetry items will be "sprayed" between two neighboring accumulators due to the fact that the snap might occure in the middle of a reader executing its Interlocked's.
*/
this.completedDataAccumulator = Interlocked.Exchange(ref this.currentDataAccumulator, new QuickPulseDataAccumulator());
var timestamp = DateTimeOffset.UtcNow;
this.completedDataAccumulator.EndTimestamp = timestamp;
this.currentDataAccumulator.StartTimestamp = timestamp;
return this.completedDataAccumulator;
}
public QuickPulseDataAccumulator CompleteCurrentDataAccumulator()
{
/*
* Here we need to
* - promote currentDataAccumulator to completedDataAccumulator
* - reset (zero out) the new currentDataAccumulator
*
* Certain telemetry items will be "sprayed" between two neighboring accumulators due to the fact that the snap might occure in the middle of a reader executing its Interlocked's.
*/
this.completedDataAccumulator = Interlocked.Exchange(ref this.currentDataAccumulator, new QuickPulseDataAccumulator());
var timestamp = DateTimeOffset.UtcNow;
this.completedDataAccumulator.EndTimestamp = timestamp;
this.currentDataAccumulator.StartTimestamp = timestamp;
return(this.completedDataAccumulator);
}
public QuickPulseDataSample(QuickPulseDataAccumulator accumulator, IDictionary <string, Tuple <PerformanceCounterData, double> > perfData, IEnumerable <Tuple <string, int> > topCpuData, bool topCpuDataAccessDenied)
{
// NOTE: it is crucial not to keep any heap references on input parameters, new objects with separate roots must be created!
// CollectionConfiguration is an exception to this rule as it may be still processed, and the sender will check the reference count before sending it out
if (accumulator == null)
{
throw new ArgumentNullException(nameof(accumulator));
}
if (perfData == null)
{
throw new ArgumentNullException(nameof(perfData));
}
if (accumulator.StartTimestamp == null)
{
throw new ArgumentNullException(nameof(accumulator.StartTimestamp));
}
if (accumulator.EndTimestamp == null)
{
throw new ArgumentNullException(nameof(accumulator.EndTimestamp));
}
this.StartTimestamp = accumulator.StartTimestamp.Value;
this.EndTimestamp = accumulator.EndTimestamp.Value;
if ((this.EndTimestamp - this.StartTimestamp) < TimeSpan.Zero)
{
throw new InvalidOperationException("StartTimestamp must be less than EndTimestamp.");
}
TimeSpan sampleDuration = this.EndTimestamp - this.StartTimestamp;
Tuple <long, long> requestCountAndDuration = QuickPulseDataAccumulator.DecodeCountAndDuration(accumulator.AIRequestCountAndDurationInTicks);
long requestCount = requestCountAndDuration.Item1;
long requestDurationInTicks = requestCountAndDuration.Item2;
this.AIRequests = (int)requestCount;
this.AIRequestsPerSecond = sampleDuration.TotalSeconds > 0 ? requestCount / sampleDuration.TotalSeconds : 0;
this.AIRequestDurationAveInMs = requestCount > 0 ? (double)requestDurationInTicks / TimeSpan.TicksPerMillisecond / requestCount : 0;
this.AIRequestsFailedPerSecond = sampleDuration.TotalSeconds > 0 ? accumulator.AIRequestFailureCount / sampleDuration.TotalSeconds : 0;
this.AIRequestsSucceededPerSecond = sampleDuration.TotalSeconds > 0 ? accumulator.AIRequestSuccessCount / sampleDuration.TotalSeconds : 0;
Tuple <long, long> dependencyCountAndDuration = QuickPulseDataAccumulator.DecodeCountAndDuration(accumulator.AIDependencyCallCountAndDurationInTicks);
long dependencyCount = dependencyCountAndDuration.Item1;
long dependencyDurationInTicks = dependencyCountAndDuration.Item2;
this.AIDependencyCalls = (int)dependencyCount;
this.AIDependencyCallsPerSecond = sampleDuration.TotalSeconds > 0 ? dependencyCount / sampleDuration.TotalSeconds : 0;
this.AIDependencyCallDurationAveInMs = dependencyCount > 0 ? (double)dependencyDurationInTicks / TimeSpan.TicksPerMillisecond / dependencyCount : 0;
this.AIDependencyCallsFailedPerSecond = sampleDuration.TotalSeconds > 0 ? accumulator.AIDependencyCallFailureCount / sampleDuration.TotalSeconds : 0;
this.AIDependencyCallsSucceededPerSecond = sampleDuration.TotalSeconds > 0 ? accumulator.AIDependencyCallSuccessCount / sampleDuration.TotalSeconds : 0;
this.AIExceptionsPerSecond = sampleDuration.TotalSeconds > 0 ? accumulator.AIExceptionCount / sampleDuration.TotalSeconds : 0;
this.GlobalDocumentQuotaReached = accumulator.GlobalDocumentQuotaReached;
try
{
this.PerfCountersLookup =
perfData.ToDictionary(
p =>
(QuickPulseDefaults.DefaultCounterOriginalStringMapping.ContainsKey(p.Value.Item1.ReportAs)
? QuickPulseDefaults.DefaultCounterOriginalStringMapping[p.Value.Item1.ReportAs]
: p.Value.Item1.ReportAs),
p => p.Value.Item2);
}
catch (Exception e)
{
// something went wrong with counter names, log an error
QuickPulseEventSource.Log.UnknownErrorEvent(e.ToString());
}
this.TopCpuData = topCpuData.ToArray();
this.TelemetryDocuments = accumulator.TelemetryDocuments.ToArray();
this.TopCpuDataAccessDenied = topCpuDataAccessDenied;
this.CollectionConfigurationAccumulator = accumulator.CollectionConfigurationAccumulator;
}
public QuickPulseDataSample(QuickPulseDataAccumulator accumulator, IDictionary<string, Tuple<PerformanceCounterData, float>> perfData)
{
if (accumulator == null)
{
throw new ArgumentNullException(nameof(accumulator));
}
if (perfData == null)
{
throw new ArgumentNullException(nameof(perfData));
}
if (accumulator.StartTimestamp == null)
{
throw new ArgumentNullException(nameof(accumulator.StartTimestamp));
}
if (accumulator.EndTimestamp == null)
{
throw new ArgumentNullException(nameof(accumulator.EndTimestamp));
}
this.StartTimestamp = accumulator.StartTimestamp.Value;
this.EndTimestamp = accumulator.EndTimestamp.Value;
if ((this.EndTimestamp - this.StartTimestamp) < TimeSpan.Zero)
{
throw new InvalidOperationException("StartTimestamp must be lesser than EndTimestamp.");
}
TimeSpan sampleDuration = this.EndTimestamp - this.StartTimestamp;
Tuple<long, long> requestCountAndDuration = QuickPulseDataAccumulator.DecodeCountAndDuration(accumulator.AIRequestCountAndDurationInTicks);
long requestCount = requestCountAndDuration.Item1;
long requestDurationInTicks = requestCountAndDuration.Item2;
this.AIRequests = (int)requestCount;
this.AIRequestsPerSecond = sampleDuration.TotalSeconds > 0 ? requestCount / sampleDuration.TotalSeconds : 0;
this.AIRequestDurationAveInMs = requestCount > 0 ? (double)requestDurationInTicks / TimeSpan.TicksPerMillisecond / requestCount : 0;
this.AIRequestsFailedPerSecond = sampleDuration.TotalSeconds > 0 ? accumulator.AIRequestFailureCount / sampleDuration.TotalSeconds : 0;
this.AIRequestsSucceededPerSecond = sampleDuration.TotalSeconds > 0 ? accumulator.AIRequestSuccessCount / sampleDuration.TotalSeconds : 0;
Tuple<long, long> dependencyCountAndDuration = QuickPulseDataAccumulator.DecodeCountAndDuration(accumulator.AIDependencyCallCountAndDurationInTicks);
long dependencyCount = dependencyCountAndDuration.Item1;
long dependencyDurationInTicks = dependencyCountAndDuration.Item2;
this.AIDependencyCalls = (int)dependencyCount;
this.AIDependencyCallsPerSecond = sampleDuration.TotalSeconds > 0 ? dependencyCount / sampleDuration.TotalSeconds : 0;
this.AIDependencyCallDurationAveInMs = dependencyCount > 0 ? (double)dependencyDurationInTicks / TimeSpan.TicksPerMillisecond / dependencyCount : 0;
this.AIDependencyCallsFailedPerSecond = sampleDuration.TotalSeconds > 0 ? accumulator.AIDependencyCallFailureCount / sampleDuration.TotalSeconds : 0;
this.AIDependencyCallsSucceededPerSecond = sampleDuration.TotalSeconds > 0 ? accumulator.AIDependencyCallSuccessCount / sampleDuration.TotalSeconds : 0;
this.AIExceptionsPerSecond = sampleDuration.TotalSeconds > 0 ? accumulator.AIExceptionCount / sampleDuration.TotalSeconds : 0;
// avoiding reflection (Enum.GetNames()) to speed things up
Tuple<PerformanceCounterData, float> value;
if (perfData.TryGetValue(QuickPulsePerfCounters.PerfIisQueueSize.ToString(), out value))
{
this.PerfIisQueueSize = value.Item2;
}
if (perfData.TryGetValue(QuickPulsePerfCounters.PerfCpuUtilization.ToString(), out value))
{
this.PerfCpuUtilization = value.Item2;
}
if (perfData.TryGetValue(QuickPulsePerfCounters.PerfMemoryInBytes.ToString(), out value))
{
this.PerfMemoryInBytes = value.Item2;
}
this.PerfCountersLookup = perfData.ToDictionary(p => p.Value.Item1.OriginalString, p => p.Value.Item2);
}
public void QuickPulseDataSampleTimestampsItselfCorrectly()
{
// ARRANGE
var timestampStart = DateTimeOffset.UtcNow;
var timestampEnd = DateTimeOffset.UtcNow.AddSeconds(3);
var accumulator = new QuickPulseDataAccumulator { StartTimestamp = timestampStart, EndTimestamp = timestampEnd };
// ACT
var dataSample = new QuickPulseDataSample(accumulator, this.dummyDictionary);
// ASSERT
Assert.AreEqual(timestampStart, dataSample.StartTimestamp);
Assert.AreEqual(timestampEnd, dataSample.EndTimestamp);
}
public void QuickPulseDataSampleHandlesAbsentCounterInPerfData()
{
// ARRANGE
var accumulator = new QuickPulseDataAccumulator
{
StartTimestamp = DateTimeOffset.UtcNow,
EndTimestamp = DateTimeOffset.UtcNow.AddSeconds(2)
};
// ACT
var dataSample = new QuickPulseDataSample(accumulator, this.dummyDictionary);
// ASSERT
Assert.IsFalse(dataSample.PerfCountersLookup.Any());
}
public void QuickPulseDataSampleCalculatesAIRpsCorrectly()
{
// ARRANGE
var accumulator = new QuickPulseDataAccumulator
{
StartTimestamp = DateTimeOffset.UtcNow,
EndTimestamp = DateTimeOffset.UtcNow.AddSeconds(2),
AIRequestCountAndDurationInTicks = QuickPulseDataAccumulator.EncodeCountAndDuration(10, 0)
};
// ACT
var dataSample = new QuickPulseDataSample(accumulator, this.dummyDictionary);
// ASSERT
Assert.AreEqual(10.0 / 2, dataSample.AIRequestsPerSecond);
}
public void QuickPulseDataSampleCalculatesAIRequestDurationAveCorrectly()
{
// ARRANGE
var accumulator = new QuickPulseDataAccumulator
{
StartTimestamp = DateTimeOffset.UtcNow,
EndTimestamp = DateTimeOffset.UtcNow.AddSeconds(2),
AIRequestCountAndDurationInTicks =
QuickPulseDataAccumulator.EncodeCountAndDuration(10, TimeSpan.FromSeconds(5).Ticks)
};
// ACT
var dataSample = new QuickPulseDataSample(accumulator, this.dummyDictionary);
// ASSERT
Assert.AreEqual(TimeSpan.FromSeconds(5).TotalMilliseconds / 10.0, dataSample.AIRequestDurationAveInMs);
}
public void QuickPulseDataSampleCalculatesAIExceptionsPerSecondCorrectly()
{
// ARRANGE
var accumulator = new QuickPulseDataAccumulator
{
StartTimestamp = DateTimeOffset.UtcNow,
EndTimestamp = DateTimeOffset.UtcNow.AddSeconds(2),
AIExceptionCount = 3
};
// ACT
var dataSample = new QuickPulseDataSample(accumulator, this.dummyDictionary);
// ASSERT
Assert.AreEqual(3.0 / 2, dataSample.AIExceptionsPerSecond);
}
private QuickPulseDataSample CreateDataSample(
QuickPulseDataAccumulator accumulator,
IEnumerable<Tuple<PerformanceCounterData, double>> perfData)
{
return new QuickPulseDataSample(accumulator, perfData.ToDictionary(tuple => tuple.Item1.ReportAs, tuple => tuple));
}
public QuickPulseDataSample(QuickPulseDataAccumulator accumulator, IDictionary <string, Tuple <PerformanceCounterData, float> > perfData)
{
if (accumulator == null)
{
throw new ArgumentNullException(nameof(accumulator));
}
if (perfData == null)
{
throw new ArgumentNullException(nameof(perfData));
}
if (accumulator.StartTimestamp == null)
{
throw new ArgumentNullException(nameof(accumulator.StartTimestamp));
}
if (accumulator.EndTimestamp == null)
{
throw new ArgumentNullException(nameof(accumulator.EndTimestamp));
}
this.StartTimestamp = accumulator.StartTimestamp.Value;
this.EndTimestamp = accumulator.EndTimestamp.Value;
if ((this.EndTimestamp - this.StartTimestamp) < TimeSpan.Zero)
{
throw new InvalidOperationException("StartTimestamp must be lesser than EndTimestamp.");
}
TimeSpan sampleDuration = this.EndTimestamp - this.StartTimestamp;
Tuple <long, long> requestCountAndDuration = QuickPulseDataAccumulator.DecodeCountAndDuration(accumulator.AIRequestCountAndDurationInTicks);
long requestCount = requestCountAndDuration.Item1;
long requestDurationInTicks = requestCountAndDuration.Item2;
this.AIRequests = (int)requestCount;
this.AIRequestsPerSecond = sampleDuration.TotalSeconds > 0 ? requestCount / sampleDuration.TotalSeconds : 0;
this.AIRequestDurationAveInMs = requestCount > 0 ? (double)requestDurationInTicks / TimeSpan.TicksPerMillisecond / requestCount : 0;
this.AIRequestsFailedPerSecond = sampleDuration.TotalSeconds > 0 ? accumulator.AIRequestFailureCount / sampleDuration.TotalSeconds : 0;
this.AIRequestsSucceededPerSecond = sampleDuration.TotalSeconds > 0 ? accumulator.AIRequestSuccessCount / sampleDuration.TotalSeconds : 0;
Tuple <long, long> dependencyCountAndDuration = QuickPulseDataAccumulator.DecodeCountAndDuration(accumulator.AIDependencyCallCountAndDurationInTicks);
long dependencyCount = dependencyCountAndDuration.Item1;
long dependencyDurationInTicks = dependencyCountAndDuration.Item2;
this.AIDependencyCalls = (int)dependencyCount;
this.AIDependencyCallsPerSecond = sampleDuration.TotalSeconds > 0 ? dependencyCount / sampleDuration.TotalSeconds : 0;
this.AIDependencyCallDurationAveInMs = dependencyCount > 0 ? (double)dependencyDurationInTicks / TimeSpan.TicksPerMillisecond / dependencyCount : 0;
this.AIDependencyCallsFailedPerSecond = sampleDuration.TotalSeconds > 0 ? accumulator.AIDependencyCallFailureCount / sampleDuration.TotalSeconds : 0;
this.AIDependencyCallsSucceededPerSecond = sampleDuration.TotalSeconds > 0 ? accumulator.AIDependencyCallSuccessCount / sampleDuration.TotalSeconds : 0;
this.AIExceptionsPerSecond = sampleDuration.TotalSeconds > 0 ? accumulator.AIExceptionCount / sampleDuration.TotalSeconds : 0;
// avoiding reflection (Enum.GetNames()) to speed things up
Tuple <PerformanceCounterData, float> value;
if (perfData.TryGetValue(QuickPulsePerfCounters.PerfIisQueueSize.ToString(), out value))
{
this.PerfIisQueueSize = value.Item2;
}
if (perfData.TryGetValue(QuickPulsePerfCounters.PerfCpuUtilization.ToString(), out value))
{
this.PerfCpuUtilization = value.Item2;
}
if (perfData.TryGetValue(QuickPulsePerfCounters.PerfMemoryInBytes.ToString(), out value))
{
this.PerfMemoryInBytes = value.Item2;
}
this.PerfCountersLookup = perfData.ToDictionary(p => p.Value.Item1.OriginalString, p => p.Value.Item2);
}
