Enumerazione System.Diagnostics.PerformanceCounterType
Questo articolo fornisce osservazioni supplementari alla documentazione di riferimento per questa API.
L'enumerazione PerformanceCounterType specifica i tipi di contatori delle prestazioni che eseguono il mapping direttamente ai tipi nativi.
Alcuni tipi di contatore rappresentano dati non elaborati, mentre altri rappresentano valori calcolati basati su uno o più campioni di contatori. Le categorie seguenti classificano i tipi di contatori disponibili.
- Media: misura un valore nel tempo e visualizza la media delle ultime due misurazioni. Un contatore di base che tiene traccia del numero di campioni coinvolti è associato a ogni contatore medio.
- Differenza: sottrae l'ultima misura rispetto a quella precedente e, se la differenza è positiva, la visualizza; se negativo, visualizza uno zero.
- Istantaneo: visualizza la misura più recente.
- Percentuale: visualizza i valori calcolati come percentuale.
- Frequenza: campione un numero crescente di eventi nel tempo e divide la modifica dei valori del conteggio in base alla modifica nel tempo per visualizzare una frequenza di attività.
Quando si esegue il campionamento dei dati del contatore delle prestazioni, l'uso di un tipo di contatore che rappresenta una media può rendere significativi i valori di dati non elaborati per l'uso. Ad esempio, il contatore NumberOfItems64 dati non elaborato può esporre dati abbastanza casuali dal campione all'esempio. La formula per un calcolo medio dei valori restituiti dal contatore sarà (X 0 +X 1 +...+X n)/n, dove ogni X i è un campione di contatore non elaborato.
I contatori di frequenza sono simili ai contatori medi, ma più utili per le situazioni in cui la frequenza aumenta quando viene usata una risorsa. Una formula che calcola rapidamente la media è ((X n -X 0)/(T n -T 0)) / frequenza, dove ogni X i è un campione di contatore e ogni T i è il momento in cui è stato acquisito il campione corrispondente. Il risultato è l'utilizzo medio al secondo.
I contatori multitimer raccolgono dati da più di un'istanza di un componente, ad esempio un processore o un disco.
I contatori inversa misurano il tempo in cui un componente non è attivo e derivano l'ora attiva da tale misura.
Nota
Se non diversamente indicato, la base temporale è di secondi.
Durante la strumentazione delle applicazioni (creazione e scrittura di contatori delle prestazioni personalizzati), è possibile utilizzare tipi di contatori delle prestazioni che si basano su un contatore di base associato usato nei calcoli. Il contatore di base deve essere immediatamente dopo il CounterCreationDataCollection contatore associato nella raccolta usata dall'applicazione. Nella tabella seguente sono elencati i tipi di contatore di base con i tipi di contatore delle prestazioni corrispondenti.
| Tipo di contatore di base | Tipi di contatori delle prestazioni |
|---|---|
AverageBase |
AverageTimer32AverageCount64 |
RawBase |
RawFraction |
CounterMultiBase |
CounterMultiTimerCounterMultiTimerInverseCounterMultiTimer100NsCounterMultiTimer100NsInverse |
SampleBase |
SampleFraction |
Di seguito sono riportate le formule usate da alcuni dei contatori che rappresentano valori calcolati:
AverageCount64: (N1 - N0)/(B1 - B0), dove N 1 e N 0 sono letture dei contatori delle prestazioni e B1 e B0 sono i valori corrispondentiAverageBase. Pertanto, il numeratore rappresenta il numero di elementi elaborati durante l'intervallo di campionamento e il denominatore rappresenta il numero di operazioni completate durante l'intervallo di campionamento.AverageTimer32: ((N1 - N0)/F)/(B1 - B0), dove N1 e N0 sono letture dei contatori delle prestazioni, B1 e B0 sono i valori corrispondentiAverageBasee F è il numero di tick al secondo. Il valore di F viene inserito nell'equazione in modo che il risultato possa essere visualizzato in secondi. Pertanto, il numeratore rappresenta i numeri di tick conteggiati durante l'ultimo intervallo di campionamento, F rappresenta la frequenza dei tick e il denominatore rappresenta il numero di operazioni completate durante l'ultimo intervallo di campionamento.CounterDelta32: N1 - N0, dove N1 e N0 sono letture dei contatori delle prestazioni.CounterDelta64: N1 - N0, dove N1 e N0 sono letture dei contatori delle prestazioni.CounterMultiTimer: ((N1 - N0) / (D1 - D0)) x 100 / B, dove N1 e N0 sono letture dei contatori delle prestazioni, D1 e D0 sono le letture temporali corrispondenti nei tick del timer delle prestazioni di sistema e la variabile B indica il conteggio di base per i componenti monitorati (usando un contatore di base di tipoCounterMultiBase). Pertanto, il numeratore rappresenta le parti dell'intervallo di campionamento durante il quale i componenti monitorati erano attivi e il denominatore rappresenta il tempo totale trascorso dell'intervallo di campionamento.CounterMultiTimer100Ns: ((N1 - N0) / (D1 - D0)) x 100 / B, dove N1 e N0 sono letture dei contatori delle prestazioni, D1 e D0 sono le letture temporali corrispondenti in unità da 100 nanosecondi e la variabile B indica il conteggio di base per i componenti monitorati (usando un contatore di base di tipoCounterMultiBase). Pertanto, il numeratore rappresenta le parti dell'intervallo di campionamento durante il quale i componenti monitorati erano attivi e il denominatore rappresenta il tempo totale trascorso dell'intervallo di campionamento.CounterMultiTimer100NsInverse: (B - ((N1 - N0) / (D1 - D0))) x 100, dove il denominatore rappresenta il tempo trascorso totale dell'intervallo di campionamento, il numeratore rappresenta il tempo durante l'intervallo in cui i componenti monitorati sono inattivi e B rappresenta il numero di componenti monitorati, usando un contatore di base di tipoCounterMultiBase.CounterMultiTimerInverse: (B- ((N1 - N0) / (D1 - D0))) x 100, dove il denominatore rappresenta il tempo trascorso totale dell'intervallo di campionamento, il numeratore rappresenta il tempo durante l'intervallo in cui i componenti monitorati sono inattivi e B rappresenta il numero di componenti monitorati, usando un contatore di base di tipoCounterMultiBase.CounterTimer: (N1 - N0) / (D1 - D0), dove N1 e N0 sono letture dei contatori delle prestazioni e D1 e D0 sono le letture temporali corrispondenti. Pertanto, il numeratore rappresenta le parti dell'intervallo di campionamento durante il quale i componenti monitorati erano attivi e il denominatore rappresenta il tempo totale trascorso dell'intervallo di campionamento.CounterTimerInverse: (1- ((N1 - N0) / (D1 - D0))) x 100, dove il numeratore rappresenta il tempo durante l'intervallo in cui i componenti monitorati erano inattivi e il denominatore rappresenta il tempo totale trascorso dell'intervallo di campionamento.CountPerTimeInterval32: (N1 - N0) / (D1 - D0), dove il numeratore rappresenta il numero di elementi nella coda e il denominatore rappresenta il tempo trascorso durante l'ultimo intervallo di campionamento.CountPerTimeInterval64: (N1 - N0) / (D1 - D0), dove il numeratore rappresenta il numero di elementi in una coda e il denominatore rappresenta il tempo trascorso durante l'intervallo di campionamento.ElapsedTime: (D0 - N0) / F, dove D0 rappresenta l'ora corrente, N0 rappresenta l'ora di avvio dell'oggetto e F rappresenta il numero di unità di tempo trascorse in un secondo. Il valore di F viene inserito nell'equazione in modo che il risultato possa essere visualizzato in secondi.NumberOfItems32:Nessuno. Non visualizza una media, ma mostra i dati non elaborati durante la raccolta.NumberOfItems64:Nessuno. Non visualizza una media, ma mostra i dati non elaborati durante la raccolta.NumberOfItemsHEX32:Nessuno. Non visualizza una media, ma mostra i dati non elaborati durante la raccolta.NumberOfItemsHEX64:Nessuno. Non visualizza una media, ma mostra i dati non elaborati durante la raccoltaRateOfCountsPerSecond32: (N1 - N0) / ((D1 - D0) / F), dove N1 e N0 sono letture dei contatori delle prestazioni, D1 e D0 sono le letture temporali corrispondenti e F rappresenta il numero di tick al secondo. Pertanto, il numeratore rappresenta il numero di operazioni eseguite durante l'ultimo intervallo di campionamento, il denominatore rappresenta il numero di tick trascorsi durante l'ultimo intervallo di campionamento e F è la frequenza dei tick. Il valore di F viene inserito nell'equazione in modo che il risultato possa essere visualizzato in secondi.RateOfCountsPerSecond64: (N1 - N0) / ((D1 - D0) / F), dove N1 e N0 sono letture dei contatori delle prestazioni, D1 e D0 sono le letture temporali corrispondenti e F rappresenta il numero di tick al secondo. Pertanto, il numeratore rappresenta il numero di operazioni eseguite durante l'ultimo intervallo di campionamento, il denominatore rappresenta il numero di tick trascorsi durante l'ultimo intervallo di campionamento e F è la frequenza dei tick. Il valore di F viene inserito nell'equazione in modo che il risultato possa essere visualizzato in secondi.RawFraction: (N0/D0) x 100, dove D0 rappresenta un attributo misurato (usando un contatore di base di tipoRawBase) e N0 rappresenta un componente di tale attributo.SampleCounter: (N1 - N0) / ((D1 - D0) / F), dove il numeratore (N) rappresenta il numero di operazioni completate, il denominatore (D) rappresenta il tempo trascorso in unità di tick del timer delle prestazioni del sistema e F rappresenta il numero di tick trascorsi in un secondo. F viene inserito nell'equazione in modo che il risultato possa essere visualizzato in secondi.SampleFraction: ((N1 - N0) / (D1 - D0)) x 100, dove il numeratore rappresenta il numero di operazioni riuscite durante l'ultimo intervallo di campionamento e il denominatore rappresenta la modifica nel numero di tutte le operazioni (del tipo misurato) completate durante l'intervallo di campionamento, utilizzando contatori di tipoSampleBase.Timer100Ns: (N1 - N0) / (D1 - D0) x 100, dove il numeratore rappresenta le parti dell'intervallo di campionamento durante il quale i componenti monitorati erano attivi e il denominatore rappresenta il tempo totale trascorso dell'intervallo di campionamento.Timer100NsInverse: (1- ((N1 - N0) / (D1 - D0))) x 100, dove il numeratore rappresenta il tempo durante l'intervallo in cui i componenti monitorati erano inattivi e il denominatore rappresenta il tempo totale trascorso dell'intervallo di campionamento.
Esempi
Negli esempi seguenti vengono illustrati diversi tipi di contatore nell'enumerazione PerformanceCounterType .
AverageCount64
using System;
using System.Collections;
using System.Diagnostics;
using System.Runtime.Versioning;
[SupportedOSPlatform("Windows")]
public class App
{
private static PerformanceCounter avgCounter64Sample;
private static PerformanceCounter avgCounter64SampleBase;
public static void Main()
{
ArrayList samplesList = new ArrayList();
// If the category does not exist, create the category and exit.
// Performance counters should not be created and immediately used.
// There is a latency time to enable the counters, they should be created
// prior to executing the application that uses the counters.
// Execute this sample a second time to use the category.
if (SetupCategory())
return;
CreateCounters();
CollectSamples(samplesList);
CalculateResults(samplesList);
}
private static bool SetupCategory()
{
if (!PerformanceCounterCategory.Exists("AverageCounter64SampleCategory"))
{
CounterCreationDataCollection counterDataCollection = new CounterCreationDataCollection();
// Add the counter.
CounterCreationData averageCount64 = new CounterCreationData();
averageCount64.CounterType = PerformanceCounterType.AverageCount64;
averageCount64.CounterName = "AverageCounter64Sample";
counterDataCollection.Add(averageCount64);
// Add the base counter.
CounterCreationData averageCount64Base = new CounterCreationData();
averageCount64Base.CounterType = PerformanceCounterType.AverageBase;
averageCount64Base.CounterName = "AverageCounter64SampleBase";
counterDataCollection.Add(averageCount64Base);
// Create the category.
PerformanceCounterCategory.Create("AverageCounter64SampleCategory",
"Demonstrates usage of the AverageCounter64 performance counter type.",
PerformanceCounterCategoryType.SingleInstance, counterDataCollection);
return (true);
}
else
{
Console.WriteLine("Category exists - AverageCounter64SampleCategory");
return (false);
}
}
private static void CreateCounters()
{
// Create the counters.
avgCounter64Sample = new PerformanceCounter("AverageCounter64SampleCategory",
"AverageCounter64Sample",
false);
avgCounter64SampleBase = new PerformanceCounter("AverageCounter64SampleCategory",
"AverageCounter64SampleBase",
false);
avgCounter64Sample.RawValue = 0;
avgCounter64SampleBase.RawValue = 0;
}
private static void CollectSamples(ArrayList samplesList)
{
Random r = new Random(DateTime.Now.Millisecond);
// Loop for the samples.
for (int j = 0; j < 100; j++)
{
int value = r.Next(1, 10);
Console.Write(j + " = " + value);
avgCounter64Sample.IncrementBy(value);
avgCounter64SampleBase.Increment();
if ((j % 10) == 9)
{
OutputSample(avgCounter64Sample.NextSample());
samplesList.Add(avgCounter64Sample.NextSample());
}
else
{
Console.WriteLine();
}
System.Threading.Thread.Sleep(50);
}
}
private static void CalculateResults(ArrayList samplesList)
{
for (int i = 0; i < (samplesList.Count - 1); i++)
{
// Output the sample.
OutputSample((CounterSample)samplesList[i]);
OutputSample((CounterSample)samplesList[i + 1]);
// Use .NET to calculate the counter value.
Console.WriteLine(".NET computed counter value = " +
CounterSampleCalculator.ComputeCounterValue((CounterSample)samplesList[i],
(CounterSample)samplesList[i + 1]));
// Calculate the counter value manually.
Console.WriteLine("My computed counter value = " +
MyComputeCounterValue((CounterSample)samplesList[i],
(CounterSample)samplesList[i + 1]));
}
}
//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
// Description - This counter type shows how many items are processed, on average,
// during an operation. Counters of this type display a ratio of the items
// processed (such as bytes sent) to the number of operations completed. The
// ratio is calculated by comparing the number of items processed during the
// last interval to the number of operations completed during the last interval.
// Generic type - Average
// Formula - (N1 - N0) / (D1 - D0), where the numerator (N) represents the number
// of items processed during the last sample interval and the denominator (D)
// represents the number of operations completed during the last two sample
// intervals.
// Average (Nx - N0) / (Dx - D0)
// Example PhysicalDisk\ Avg. Disk Bytes/Transfer
//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
private static Single MyComputeCounterValue(CounterSample s0, CounterSample s1)
{
Single numerator = (Single)s1.RawValue - (Single)s0.RawValue;
Single denomenator = (Single)s1.BaseValue - (Single)s0.BaseValue;
Single counterValue = numerator / denomenator;
return (counterValue);
}
// Output information about the counter sample.
private static void OutputSample(CounterSample s)
{
Console.WriteLine("\r\n+++++++++++");
Console.WriteLine("Sample values - \r\n");
Console.WriteLine(" BaseValue = " + s.BaseValue);
Console.WriteLine(" CounterFrequency = " + s.CounterFrequency);
Console.WriteLine(" CounterTimeStamp = " + s.CounterTimeStamp);
Console.WriteLine(" CounterType = " + s.CounterType);
Console.WriteLine(" RawValue = " + s.RawValue);
Console.WriteLine(" SystemFrequency = " + s.SystemFrequency);
Console.WriteLine(" TimeStamp = " + s.TimeStamp);
Console.WriteLine(" TimeStamp100nSec = " + s.TimeStamp100nSec);
Console.WriteLine("++++++++++++++++++++++");
}
}
Imports System.Collections
Imports System.Collections.Specialized
Imports System.Diagnostics
Imports System.Runtime.Versioning
<SupportedOSPlatform("Windows")>
Public Class App1
Private Shared avgCounter64Sample As PerformanceCounter
Private Shared avgCounter64SampleBase As PerformanceCounter
Public Shared Sub Main()
Dim samplesList As New ArrayList()
'If the category does not exist, create the category and exit.
'Performance counters should not be created and immediately used.
'There is a latency time to enable the counters, they should be created
'prior to executing the App1lication that uses the counters.
'Execute this sample a second time to use the counters.
If Not (SetupCategory()) Then
CreateCounters()
CollectSamples(samplesList)
CalculateResults(samplesList)
End If
End Sub
Private Shared Function SetupCategory() As Boolean
If Not PerformanceCounterCategory.Exists("AverageCounter64SampleCategory") Then
Dim counterDataCollection As New CounterCreationDataCollection()
' Add the counter.
Dim averageCount64 As New CounterCreationData()
averageCount64.CounterType = PerformanceCounterType.AverageCount64
averageCount64.CounterName = "AverageCounter64Sample"
counterDataCollection.Add(averageCount64)
' Add the base counter.
Dim averageCount64Base As New CounterCreationData()
averageCount64Base.CounterType = PerformanceCounterType.AverageBase
averageCount64Base.CounterName = "AverageCounter64SampleBase"
counterDataCollection.Add(averageCount64Base)
' Create the category.
PerformanceCounterCategory.Create("AverageCounter64SampleCategory",
"Demonstrates usage of the AverageCounter64 performance counter type.",
PerformanceCounterCategoryType.SingleInstance, counterDataCollection)
Return True
Else
Console.WriteLine("Category exists - AverageCounter64SampleCategory")
Return False
End If
End Function 'SetupCategory
Private Shared Sub CreateCounters()
' Create the counters.
avgCounter64Sample = New PerformanceCounter("AverageCounter64SampleCategory", "AverageCounter64Sample", False)
avgCounter64SampleBase = New PerformanceCounter("AverageCounter64SampleCategory", "AverageCounter64SampleBase", False)
avgCounter64Sample.RawValue = 0
avgCounter64SampleBase.RawValue = 0
End Sub
Private Shared Sub CollectSamples(ByVal samplesList As ArrayList)
Dim r As New Random(DateTime.Now.Millisecond)
' Loop for the samples.
Dim j As Integer
For j = 0 To 99
Dim value As Integer = r.Next(1, 10)
Console.Write(j.ToString() + " = " + value.ToString())
avgCounter64Sample.IncrementBy(value)
avgCounter64SampleBase.Increment()
If j Mod 10 = 9 Then
OutputSample(avgCounter64Sample.NextSample())
samplesList.Add(avgCounter64Sample.NextSample())
Else
Console.WriteLine()
End If
System.Threading.Thread.Sleep(50)
Next j
End Sub
Private Shared Sub CalculateResults(ByVal samplesList As ArrayList)
Dim i As Integer
For i = 0 To (samplesList.Count - 1) - 1
' Output the sample.
OutputSample(CType(samplesList(i), CounterSample))
OutputSample(CType(samplesList((i + 1)), CounterSample))
' Use .NET to calculate the counter value.
Console.WriteLine(".NET computed counter value = " + CounterSampleCalculator.ComputeCounterValue(CType(samplesList(i), CounterSample), CType(samplesList((i + 1)), CounterSample)).ToString())
' Calculate the counter value manually.
Console.WriteLine("My computed counter value = " + MyComputeCounterValue(CType(samplesList(i), CounterSample), CType(samplesList((i + 1)), CounterSample)).ToString())
Next i
End Sub
'++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
' Description - This counter type shows how many items are processed, on average,
' during an operation. Counters of this type display a ratio of the items
' processed (such as bytes sent) to the number of operations completed. The
' ratio is calculated by comparing the number of items processed during the
' last interval to the number of operations completed during the last interval.
' Generic type - Average
' Formula - (N1 - N0) / (D1 - D0), where the numerator (N) represents the number
' of items processed during the last sample interval and the denominator (D)
' represents the number of operations completed during the last two sample
' intervals.
' Average (Nx - N0) / (Dx - D0)
' Example PhysicalDisk\ Avg. Disk Bytes/Transfer
'++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
Private Shared Function MyComputeCounterValue(ByVal s0 As CounterSample, ByVal s1 As CounterSample) As [Single]
Dim numerator As [Single] = CType(s1.RawValue, [Single]) - CType(s0.RawValue, [Single])
Dim denomenator As [Single] = CType(s1.BaseValue, [Single]) - CType(s0.BaseValue, [Single])
Dim counterValue As [Single] = numerator / denomenator
Return counterValue
End Function 'MyComputeCounterValue
' Output information about the counter sample.
Private Shared Sub OutputSample(ByVal s As CounterSample)
Console.WriteLine(ControlChars.Lf + ControlChars.Cr + "+++++++++++")
Console.WriteLine("Sample values - " + ControlChars.Lf + ControlChars.Cr)
Console.WriteLine((" BaseValue = " + s.BaseValue.ToString()))
Console.WriteLine((" CounterFrequency = " + s.CounterFrequency.ToString()))
Console.WriteLine((" CounterTimeStamp = " + s.CounterTimeStamp.ToString()))
Console.WriteLine((" CounterType = " + s.CounterType.ToString()))
Console.WriteLine((" RawValue = " + s.RawValue.ToString()))
Console.WriteLine((" SystemFrequency = " + s.SystemFrequency.ToString()))
Console.WriteLine((" TimeStamp = " + s.TimeStamp.ToString()))
Console.WriteLine((" TimeStamp100nSec = " + s.TimeStamp100nSec.ToString()))
Console.WriteLine("++++++++++++++++++++++")
End Sub
End Class
AverageTimer32
using System;
using System.Collections;
using System.Diagnostics;
using System.Runtime.Versioning;
[SupportedOSPlatform("Windows")]
public class App2
{
private static PerformanceCounter PC;
private static PerformanceCounter BPC;
private const String categoryName = "AverageTimer32SampleCategory";
private const String counterName = "AverageTimer32Sample";
private const String baseCounterName = "AverageTimer32SampleBase";
public static void Main()
{
ArrayList samplesList = new ArrayList();
// If the category does not exist, create the category and exit.
// Performance counters should not be created and immediately used.
// There is a latency time to enable the counters, they should be created
// prior to executing the application that uses the counters.
// Execute this sample a second time to use the category.
if (SetupCategory())
return;
CreateCounters();
CollectSamples(samplesList);
CalculateResults(samplesList);
}
private static bool SetupCategory()
{
if (!PerformanceCounterCategory.Exists(categoryName))
{
CounterCreationDataCollection CCDC = new CounterCreationDataCollection();
// Add the counter.
CounterCreationData averageTimer32 = new CounterCreationData();
averageTimer32.CounterType = PerformanceCounterType.AverageTimer32;
averageTimer32.CounterName = counterName;
CCDC.Add(averageTimer32);
// Add the base counter.
CounterCreationData averageTimer32Base = new CounterCreationData();
averageTimer32Base.CounterType = PerformanceCounterType.AverageBase;
averageTimer32Base.CounterName = baseCounterName;
CCDC.Add(averageTimer32Base);
// Create the category.
PerformanceCounterCategory.Create(categoryName,
"Demonstrates usage of the AverageTimer32 performance counter type",
PerformanceCounterCategoryType.SingleInstance, CCDC);
Console.WriteLine("Category created - " + categoryName);
return (true);
}
else
{
Console.WriteLine("Category exists - " + categoryName);
return (false);
}
}
private static void CreateCounters()
{
// Create the counters.
PC = new PerformanceCounter(categoryName,
counterName,
false);
BPC = new PerformanceCounter(categoryName,
baseCounterName,
false);
PC.RawValue = 0;
BPC.RawValue = 0;
}
private static void CollectSamples(ArrayList samplesList)
{
Random r = new Random(DateTime.Now.Millisecond);
// Loop for the samples.
for (int i = 0; i < 10; i++)
{
PC.RawValue = Stopwatch.GetTimestamp();
BPC.IncrementBy(10);
System.Threading.Thread.Sleep(1000);
Console.WriteLine("Next value = " + PC.NextValue().ToString());
samplesList.Add(PC.NextSample());
}
}
private static void CalculateResults(ArrayList samplesList)
{
for (int i = 0; i < (samplesList.Count - 1); i++)
{
// Output the sample.
OutputSample((CounterSample)samplesList[i]);
OutputSample((CounterSample)samplesList[i + 1]);
// Use .NET to calculate the counter value.
Console.WriteLine(".NET computed counter value = " +
CounterSample.Calculate((CounterSample)samplesList[i],
(CounterSample)samplesList[i + 1]));
// Calculate the counter value manually.
Console.WriteLine("My computed counter value = " +
MyComputeCounterValue((CounterSample)samplesList[i],
(CounterSample)samplesList[i + 1]));
}
}
//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//+++++++
// PERF_AVERAGE_TIMER
// Description - This counter type measures the time it takes, on
// average, to complete a process or operation. Counters of this
// type display a ratio of the total elapsed time of the sample
// interval to the number of processes or operations completed
// during that time. This counter type measures time in ticks
// of the system clock. The F variable represents the number of
// ticks per second. The value of F is factored into the equation
// so that the result can be displayed in seconds.
//
// Generic type - Average
//
// Formula - ((N1 - N0) / F) / (D1 - D0), where the numerator (N)
// represents the number of ticks counted during the last
// sample interval, F represents the frequency of the ticks,
// and the denominator (D) represents the number of operations
// completed during the last sample interval.
//
// Average - ((Nx - N0) / F) / (Dx - D0)
//
// Example - PhysicalDisk\ Avg. Disk sec/Transfer
//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//+++++++
private static Single MyComputeCounterValue(CounterSample s0, CounterSample s1)
{
Int64 n1 = s1.RawValue;
Int64 n0 = s0.RawValue;
ulong f = (ulong)s1.SystemFrequency;
Int64 d1 = s1.BaseValue;
Int64 d0 = s0.BaseValue;
double numerator = (double)(n1 - n0);
double denominator = (double)(d1 - d0);
Single counterValue = (Single)((numerator / f) / denominator);
return (counterValue);
}
// Output information about the counter sample.
private static void OutputSample(CounterSample s)
{
Console.WriteLine("+++++++++++");
Console.WriteLine("Sample values - \r\n");
Console.WriteLine(" CounterType = " + s.CounterType);
Console.WriteLine(" RawValue = " + s.RawValue);
Console.WriteLine(" BaseValue = " + s.BaseValue);
Console.WriteLine(" CounterFrequency = " + s.CounterFrequency);
Console.WriteLine(" CounterTimeStamp = " + s.CounterTimeStamp);
Console.WriteLine(" SystemFrequency = " + s.SystemFrequency);
Console.WriteLine(" TimeStamp = " + s.TimeStamp);
Console.WriteLine(" TimeStamp100nSec = " + s.TimeStamp100nSec);
Console.WriteLine("++++++++++++++++++++++");
}
}
Imports System.Collections
Imports System.Collections.Specialized
Imports System.Diagnostics
Imports System.Runtime.InteropServices
Imports System.Runtime.Versioning
<SupportedOSPlatform("Windows")>
Public Class App
Private Const categoryName As String = "AverageTimer32SampleCategory"
Private Const counterName As String = "AverageTimer32Sample"
Private Const baseCounterName As String = "AverageTimer32SampleBase"
Private Shared PC As PerformanceCounter
Private Shared BPC As PerformanceCounter
Public Shared Sub Main()
Dim samplesList As New ArrayList()
SetupCategory()
CreateCounters()
CollectSamples(samplesList)
CalculateResults(samplesList)
End Sub
Private Shared Function SetupCategory() As Boolean
If Not PerformanceCounterCategory.Exists(categoryName) Then
Dim CCDC As New CounterCreationDataCollection()
' Add the counter.
Dim averageTimer32 As New CounterCreationData()
averageTimer32.CounterType = PerformanceCounterType.AverageTimer32
averageTimer32.CounterName = counterName
CCDC.Add(averageTimer32)
' Add the base counter.
Dim averageTimer32Base As New CounterCreationData()
averageTimer32Base.CounterType = PerformanceCounterType.AverageBase
averageTimer32Base.CounterName = baseCounterName
CCDC.Add(averageTimer32Base)
' Create the category.
PerformanceCounterCategory.Create( _
categoryName, _
"Demonstrates usage of the AverageTimer32 performance counter type", _
PerformanceCounterCategoryType.SingleInstance, CCDC)
Console.WriteLine("Category created - " + categoryName)
Return True
Else
Console.WriteLine(("Category exists - " + _
categoryName))
Return False
End If
End Function
Private Shared Sub CreateCounters()
' Create the counters.
PC = New PerformanceCounter(categoryName, _
counterName, False)
BPC = New PerformanceCounter(categoryName, _
baseCounterName, False)
PC.RawValue = 0
BPC.RawValue = 0
End Sub
Private Shared Sub CollectSamples(ByVal samplesList As ArrayList)
Dim r As New Random(DateTime.Now.Millisecond)
' Loop for the samples.
Dim i As Integer
For i = 0 To 9
PC.RawValue = Stopwatch.GetTimeStamp()
BPC.IncrementBy(10)
System.Threading.Thread.Sleep(1000)
Console.WriteLine(("Next value = " + PC.NextValue().ToString()))
samplesList.Add(PC.NextSample())
Next i
End Sub
Private Shared Sub CalculateResults(ByVal samplesList As ArrayList)
Dim i As Integer
Dim sample1 As CounterSample
Dim sample2 As CounterSample
For i = 0 To (samplesList.Count - 1) - 1
' Output the sample.
sample1 = CType(samplesList(i), CounterSample)
sample2 = CType(samplesList(i + 1), CounterSample)
OutputSample(sample1)
OutputSample(sample2)
' Use .NET to calculate the counter value.
Console.WriteLine((".NET computed counter value = " _
+ CounterSample.Calculate(sample1, sample2).ToString()))
' Calculate the counter value manually.
Console.WriteLine(("My computed counter value = " _
+ MyComputeCounterValue(sample1, sample2).ToString()))
Next i
End Sub
'++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//+++++++
' PERF_AVERAGE_TIMER
' Description - This counter type measures the time it takes, on
' average, to complete a process or operation. Counters of this
' type display a ratio of the total elapsed time of the sample
' interval to the number of processes or operations completed
' during that time. This counter type measures time in ticks
' of the system clock. The F variable represents the number of
' ticks per second. The value of F is factored into the equation
' so that the result can be displayed in seconds.
'
' Generic type - Average
'
' Formula - ((N1 - N0) / F) / (D1 - D0), where the numerator (N)
' represents the number of ticks counted during the last
' sample interval, F represents the frequency of the ticks,
' and the denominator (D) represents the number of operations
' completed during the last sample interval.
'
' Average - ((Nx - N0) / F) / (Dx - D0)
'
' Example - PhysicalDisk\ Avg. Disk sec/Transfer
'++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//+++++++
Private Shared Function MyComputeCounterValue( _
ByVal s0 As CounterSample, _
ByVal s1 As CounterSample) As Single
Dim n1 As Int64 = s1.RawValue
Dim n0 As Int64 = s0.RawValue
Dim f As Decimal = CType(s1.SystemFrequency, Decimal)
Dim d1 As Int64 = s1.BaseValue
Dim d0 As Int64 = s0.BaseValue
Dim numerator As Double = System.Convert.ToDouble(n1 - n0)
Dim denominator As Double = System.Convert.ToDouble(d1 - d0)
Dim counterValue As Single = CType(numerator, Single)
counterValue = counterValue / CType(f, Single)
counterValue = counterValue / CType(denominator, Single)
Return counterValue
End Function
' Output information about the counter sample.
Private Shared Sub OutputSample(ByVal s As CounterSample)
Console.WriteLine("+++++++++++")
Console.WriteLine("Sample values - " + ControlChars.Cr _
+ ControlChars.Lf)
Console.WriteLine((" CounterType = " + _
s.CounterType.ToString()))
Console.WriteLine((" RawValue = " + _
s.RawValue.ToString()))
Console.WriteLine((" BaseValue = " _
+ s.BaseValue.ToString()))
Console.WriteLine((" CounterFrequency = " + _
s.CounterFrequency.ToString()))
Console.WriteLine((" CounterTimeStamp = " + _
s.CounterTimeStamp.ToString()))
Console.WriteLine((" SystemFrequency = " + _
s.SystemFrequency.ToString()))
Console.WriteLine((" TimeStamp = " + _
s.TimeStamp.ToString()))
Console.WriteLine((" TimeStamp100nSec = " + _
s.TimeStamp100nSec.ToString()))
Console.WriteLine("++++++++++++++++++++++")
End Sub
End Class
ElapsedTime
using System;
using System.Diagnostics;
using System.Runtime.Versioning;
[SupportedOSPlatform("Windows")]
public class App
{
public static void Main()
{
CollectSamples();
}
public static void CollectSamples()
{
const String categoryName = "ElapsedTimeSampleCategory";
const String counterName = "ElapsedTimeSample";
// If the category does not exist, create the category and exit.
// Performance counters should not be created and immediately used.
// There is a latency time to enable the counters, they should be created
// prior to executing the application that uses the counters.
// Execute this sample a second time to use the category.
if ( !PerformanceCounterCategory.Exists(categoryName) )
{
CounterCreationDataCollection CCDC = new CounterCreationDataCollection();
// Add the counter.
CounterCreationData ETimeData = new CounterCreationData();
ETimeData.CounterType = PerformanceCounterType.ElapsedTime;
ETimeData.CounterName = counterName;
CCDC.Add(ETimeData);
// Create the category.
PerformanceCounterCategory.Create(categoryName,
"Demonstrates ElapsedTime performance counter usage.",
PerformanceCounterCategoryType.SingleInstance, CCDC);
// Return, rerun the application to make use of the new counters.
return;
}
else
{
Console.WriteLine("Category exists - {0}", categoryName);
}
// Create the performance counter.
PerformanceCounter PC = new PerformanceCounter(categoryName,
counterName,
false);
// Initialize the counter.
PC.RawValue = Stopwatch.GetTimestamp();
DateTime Start = DateTime.Now;
// Loop for the samples.
for (int j = 0; j < 100; j++)
{
// Output the values.
if ((j % 10) == 9)
{
Console.WriteLine("NextValue() = " + PC.NextValue().ToString());
Console.WriteLine("Actual elapsed time = " + DateTime.Now.Subtract(Start).ToString());
OutputSample(PC.NextSample());
}
// Reset the counter on every 20th iteration.
if (j % 20 == 0)
{
PC.RawValue = Stopwatch.GetTimestamp();
Start = DateTime.Now;
}
System.Threading.Thread.Sleep(50);
}
Console.WriteLine("Elapsed time = " + DateTime.Now.Subtract(Start).ToString());
}
private static void OutputSample(CounterSample s)
{
Console.WriteLine("\r\n+++++++++++");
Console.WriteLine("Sample values - \r\n");
Console.WriteLine(" BaseValue = " + s.BaseValue);
Console.WriteLine(" CounterFrequency = " + s.CounterFrequency);
Console.WriteLine(" CounterTimeStamp = " + s.CounterTimeStamp);
Console.WriteLine(" CounterType = " + s.CounterType);
Console.WriteLine(" RawValue = " + s.RawValue);
Console.WriteLine(" SystemFrequency = " + s.SystemFrequency);
Console.WriteLine(" TimeStamp = " + s.TimeStamp);
Console.WriteLine(" TimeStamp100nSec = " + s.TimeStamp100nSec);
Console.WriteLine("++++++++++++++++++++++");
}
}
Imports System.Collections
Imports System.Collections.Specialized
Imports System.Diagnostics
Imports System.Runtime.InteropServices
Imports System.Runtime.Versioning
<SupportedOSPlatform("Windows")>
Public Class App2
Public Shared Sub Main()
CollectSamples()
End Sub
Private Shared Sub CollectSamples()
Dim categoryName As String = "ElapsedTimeSampleCategory"
Dim counterName As String = "ElapsedTimeSample"
If Not PerformanceCounterCategory.Exists(categoryName) Then
Dim CCDC As New CounterCreationDataCollection()
' Add the counter.
Dim ETimeData As New CounterCreationData()
ETimeData.CounterType = PerformanceCounterType.ElapsedTime
ETimeData.CounterName = counterName
CCDC.Add(ETimeData)
' Create the category.
PerformanceCounterCategory.Create(categoryName,
"Demonstrates ElapsedTime performance counter usage.",
PerformanceCounterCategoryType.SingleInstance, CCDC)
Else
Console.WriteLine("Category exists - {0}", categoryName)
End If
' Create the counter.
Dim PC As PerformanceCounter
PC = New PerformanceCounter(categoryName, counterName, False)
' Initialize the counter.
PC.RawValue = Stopwatch.GetTimestamp()
Dim Start As DateTime = DateTime.Now
' Loop for the samples.
Dim j As Integer
For j = 0 To 99
' Output the values.
If j Mod 10 = 9 Then
Console.WriteLine(("NextValue() = " _
+ PC.NextValue().ToString()))
Console.WriteLine(("Actual elapsed time = " _
+ DateTime.Now.Subtract(Start).ToString()))
OutputSample(PC.NextSample())
End If
' Reset the counter every 20th iteration.
If j Mod 20 = 0 Then
PC.RawValue = Stopwatch.GetTimestamp()
Start = DateTime.Now
End If
System.Threading.Thread.Sleep(50)
Next j
Console.WriteLine(("Elapsed time = " +
DateTime.Now.Subtract(Start).ToString()))
End Sub
Private Shared Sub OutputSample(ByVal s As CounterSample)
Console.WriteLine(ControlChars.Lf + ControlChars.Cr + "+++++++")
Console.WriteLine("Sample values - " + ControlChars.Cr _
+ ControlChars.Lf)
Console.WriteLine((" BaseValue = " _
+ s.BaseValue.ToString()))
Console.WriteLine((" CounterFrequency = " +
s.CounterFrequency.ToString()))
Console.WriteLine((" CounterTimeStamp = " +
s.CounterTimeStamp.ToString()))
Console.WriteLine((" CounterType = " +
s.CounterType.ToString()))
Console.WriteLine((" RawValue = " +
s.RawValue.ToString()))
Console.WriteLine((" SystemFrequency = " +
s.SystemFrequency.ToString()))
Console.WriteLine((" TimeStamp = " +
s.TimeStamp.ToString()))
Console.WriteLine((" TimeStamp100nSec = " +
s.TimeStamp100nSec.ToString()))
Console.WriteLine("+++++++")
End Sub
End Class
NumberOfItems32
using System;
using System.Collections;
using System.Collections.Specialized;
using System.Diagnostics;
public class NumberOfItems64
{
private static PerformanceCounter PC;
public static void Main()
{
ArrayList samplesList = new ArrayList();
// If the category does not exist, create the category and exit.
// Performance counters should not be created and immediately used.
// There is a latency time to enable the counters, they should be created
// prior to executing the application that uses the counters.
// Execute this sample a second time to use the category.
if (SetupCategory())
return;
CreateCounters();
CollectSamples(samplesList);
CalculateResults(samplesList);
}
private static bool SetupCategory()
{
if ( !PerformanceCounterCategory.Exists("NumberOfItems32SampleCategory") )
{
CounterCreationDataCollection CCDC = new CounterCreationDataCollection();
// Add the counter.
CounterCreationData NOI64 = new CounterCreationData();
NOI64.CounterType = PerformanceCounterType.NumberOfItems64;
NOI64.CounterName = "NumberOfItems32Sample";
CCDC.Add(NOI64);
// Create the category.
PerformanceCounterCategory.Create("NumberOfItems32SampleCategory",
"Demonstrates usage of the NumberOfItems32 performance counter type.",
PerformanceCounterCategoryType.SingleInstance, CCDC);
return(true);
}
else
{
Console.WriteLine("Category exists - NumberOfItems32SampleCategory");
return(false);
}
}
private static void CreateCounters()
{
// Create the counter.
PC = new PerformanceCounter("NumberOfItems32SampleCategory",
"NumberOfItems32Sample",
false);
PC.RawValue=0;
}
private static void CollectSamples(ArrayList samplesList)
{
Random r = new Random( DateTime.Now.Millisecond );
// Loop for the samples.
for (int j = 0; j < 100; j++)
{
int value = r.Next(1, 10);
Console.Write(j + " = " + value);
PC.IncrementBy(value);
if ((j % 10) == 9)
{
OutputSample(PC.NextSample());
samplesList.Add( PC.NextSample() );
}
else
{
Console.WriteLine();
}
System.Threading.Thread.Sleep(50);
}
}
private static void CalculateResults(ArrayList samplesList)
{
for(int i = 0; i < (samplesList.Count - 1); i++)
{
// Output the sample.
OutputSample( (CounterSample)samplesList[i] );
OutputSample( (CounterSample)samplesList[i+1] );
// Use .NET to calculate the counter value.
Console.WriteLine(".NET computed counter value = " +
CounterSampleCalculator.ComputeCounterValue((CounterSample)samplesList[i],
(CounterSample)samplesList[i+1]) );
// Calculate the counter value manually.
Console.WriteLine("My computed counter value = " +
MyComputeCounterValue((CounterSample)samplesList[i],
(CounterSample)samplesList[i+1]) );
}
}
//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
private static Single MyComputeCounterValue(CounterSample s0, CounterSample s1)
{
Single counterValue = s1.RawValue;
return(counterValue);
}
// Output information about the counter sample.
private static void OutputSample(CounterSample s)
{
Console.WriteLine("\r\n+++++++++++");
Console.WriteLine("Sample values - \r\n");
Console.WriteLine(" BaseValue = " + s.BaseValue);
Console.WriteLine(" CounterFrequency = " + s.CounterFrequency);
Console.WriteLine(" CounterTimeStamp = " + s.CounterTimeStamp);
Console.WriteLine(" CounterType = " + s.CounterType);
Console.WriteLine(" RawValue = " + s.RawValue);
Console.WriteLine(" SystemFrequency = " + s.SystemFrequency);
Console.WriteLine(" TimeStamp = " + s.TimeStamp);
Console.WriteLine(" TimeStamp100nSec = " + s.TimeStamp100nSec);
Console.WriteLine("++++++++++++++++++++++");
}
}
Imports System.Collections
Imports System.Collections.Specialized
Imports System.Diagnostics
Imports System.Runtime.Versioning
<SupportedOSPlatform("Windows")>
Public Class NumberOfItems64
Private Shared PC As PerformanceCounter
Public Shared Sub Main()
Dim samplesList As New ArrayList()
'If the category does not exist, create the category and exit.
'Performance counters should not be created and immediately used.
'There is a latency time to enable the counters, they should be created
'prior to executing the application that uses the counters.
'Execute this sample a second time to use the counters.
If Not (SetupCategory()) Then
CreateCounters()
CollectSamples(samplesList)
CalculateResults(samplesList)
End If
End Sub
Private Shared Function SetupCategory() As Boolean
If Not PerformanceCounterCategory.Exists("NumberOfItems32SampleCategory") Then
Dim CCDC As New CounterCreationDataCollection()
' Add the counter.
Dim NOI64 As New CounterCreationData()
NOI64.CounterType = PerformanceCounterType.NumberOfItems64
NOI64.CounterName = "NumberOfItems32Sample"
CCDC.Add(NOI64)
' Create the category.
PerformanceCounterCategory.Create("NumberOfItems32SampleCategory", _
"Demonstrates usage of the NumberOfItems32 performance counter type.", _
PerformanceCounterCategoryType.SingleInstance, CCDC)
Return True
Else
Console.WriteLine("Category exists - NumberOfItems32SampleCategory")
Return False
End If
End Function 'SetupCategory
Private Shared Sub CreateCounters()
' Create the counter.
PC = New PerformanceCounter("NumberOfItems32SampleCategory", "NumberOfItems32Sample", False)
PC.RawValue = 0
End Sub
Private Shared Sub CollectSamples(ByVal samplesList As ArrayList)
Dim r As New Random(DateTime.Now.Millisecond)
' Loop for the samples.
Dim j As Integer
For j = 0 To 99
Dim value As Integer = r.Next(1, 10)
Console.Write(j.ToString() + " = " + value.ToString())
PC.IncrementBy(value)
If j Mod 10 = 9 Then
OutputSample(PC.NextSample())
samplesList.Add(PC.NextSample())
Else
Console.WriteLine()
End If
System.Threading.Thread.Sleep(50)
Next j
End Sub
Private Shared Sub CalculateResults(ByVal samplesList As ArrayList)
Dim i As Integer
For i = 0 To (samplesList.Count - 1) - 1
' Output the sample.
OutputSample(CType(samplesList(i), CounterSample))
OutputSample(CType(samplesList((i + 1)), CounterSample))
' Use .NET to calculate the counter value.
Console.WriteLine(".NET computed counter value = " + CounterSampleCalculator.ComputeCounterValue(CType(samplesList(i), CounterSample), CType(samplesList((i + 1)), CounterSample)).ToString())
' Calculate the counter value manually.
Console.WriteLine("My computed counter value = " + MyComputeCounterValue(CType(samplesList(i), CounterSample), CType(samplesList((i + 1)), CounterSample)).ToString())
Next i
End Sub
'++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
'++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
Private Shared Function MyComputeCounterValue(ByVal s0 As CounterSample, ByVal s1 As CounterSample) As [Single]
Dim counterValue As [Single] = s1.RawValue
Return counterValue
End Function 'MyComputeCounterValue
' Output information about the counter sample.
Private Shared Sub OutputSample(ByVal s As CounterSample)
Console.WriteLine(ControlChars.Lf + ControlChars.Cr + "+++++++++++")
Console.WriteLine("Sample values - " + ControlChars.Lf + ControlChars.Cr)
Console.WriteLine(" BaseValue = " + s.BaseValue.ToString())
Console.WriteLine(" CounterFrequency = " + s.CounterFrequency.ToString())
Console.WriteLine(" CounterTimeStamp = " + s.CounterTimeStamp.ToString())
Console.WriteLine(" CounterType = " + s.CounterType.ToString())
Console.WriteLine(" RawValue = " + s.RawValue.ToString())
Console.WriteLine(" SystemFrequency = " + s.SystemFrequency.ToString())
Console.WriteLine(" TimeStamp = " + s.TimeStamp.ToString())
Console.WriteLine(" TimeStamp100nSec = " + s.TimeStamp100nSec.ToString())
Console.WriteLine("++++++++++++++++++++++")
End Sub
End Class
NumberOfItems64
using System;
using System.Collections;
using System.Diagnostics;
using System.Runtime.Versioning;
[SupportedOSPlatform("Windows")]
public class NumberOfItems64_1
{
private static PerformanceCounter PC;
public static void Main()
{
ArrayList samplesList = new ArrayList();
// If the category does not exist, create the category and exit.
// Perfomance counters should not be created and immediately used.
// There is a latency time to enable the counters, they should be created
// prior to executing the application that uses the counters.
// Execute this sample a second time to use the category.
if (SetupCategory())
return;
CreateCounters();
CollectSamples(samplesList);
CalculateResults(samplesList);
}
private static bool SetupCategory()
{
if (!PerformanceCounterCategory.Exists("NumberOfItems64SampleCategory"))
{
CounterCreationDataCollection CCDC = new CounterCreationDataCollection();
// Add the counter.
CounterCreationData NOI64 = new CounterCreationData();
NOI64.CounterType = PerformanceCounterType.NumberOfItems64;
NOI64.CounterName = "NumberOfItems64Sample";
CCDC.Add(NOI64);
// Create the category.
PerformanceCounterCategory.Create("NumberOfItems64SampleCategory",
"Demonstrates usage of the NumberOfItems64 performance counter type.",
PerformanceCounterCategoryType.SingleInstance, CCDC);
return (true);
}
else
{
Console.WriteLine("Category exists - NumberOfItems64SampleCategory");
return (false);
}
}
private static void CreateCounters()
{
// Create the counters.
PC = new PerformanceCounter("NumberOfItems64SampleCategory",
"NumberOfItems64Sample",
false);
PC.RawValue = 0;
}
private static void CollectSamples(ArrayList samplesList)
{
Random r = new Random(DateTime.Now.Millisecond);
// Loop for the samples.
for (int j = 0; j < 100; j++)
{
int value = r.Next(1, 10);
Console.Write(j + " = " + value);
PC.IncrementBy(value);
if ((j % 10) == 9)
{
OutputSample(PC.NextSample());
samplesList.Add(PC.NextSample());
}
else
{
Console.WriteLine();
}
System.Threading.Thread.Sleep(50);
}
}
private static void CalculateResults(ArrayList samplesList)
{
for (int i = 0; i < (samplesList.Count - 1); i++)
{
// Output the sample.
OutputSample((CounterSample)samplesList[i]);
OutputSample((CounterSample)samplesList[i + 1]);
// Use .NET to calculate the counter value.
Console.WriteLine(".NET computed counter value = " +
CounterSampleCalculator.ComputeCounterValue((CounterSample)samplesList[i],
(CounterSample)samplesList[i + 1]));
// Calculate the counter value manually.
Console.WriteLine("My computed counter value = " +
MyComputeCounterValue((CounterSample)samplesList[i],
(CounterSample)samplesList[i + 1]));
}
}
//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
private static Single MyComputeCounterValue(CounterSample s0, CounterSample s1)
{
Single counterValue = s1.RawValue;
return (counterValue);
}
// Output information about the counter sample.
private static void OutputSample(CounterSample s)
{
Console.WriteLine("\r\n+++++++++++");
Console.WriteLine("Sample values - \r\n");
Console.WriteLine(" BaseValue = " + s.BaseValue);
Console.WriteLine(" CounterFrequency = " + s.CounterFrequency);
Console.WriteLine(" CounterTimeStamp = " + s.CounterTimeStamp);
Console.WriteLine(" CounterType = " + s.CounterType);
Console.WriteLine(" RawValue = " + s.RawValue);
Console.WriteLine(" SystemFrequency = " + s.SystemFrequency);
Console.WriteLine(" TimeStamp = " + s.TimeStamp);
Console.WriteLine(" TimeStamp100nSec = " + s.TimeStamp100nSec);
Console.WriteLine("++++++++++++++++++++++");
}
}
Imports System.Collections
Imports System.Collections.Specialized
Imports System.Diagnostics
Imports System.Runtime.Versioning
<SupportedOSPlatform("Windows")>
Public Class NumberOfItems64_1
Private Shared PC As PerformanceCounter
Public Shared Sub Main()
Dim samplesList As New ArrayList()
'If the category does not exist, create the category and exit.
'Performance counters should not be created and immediately used.
'There is a latency time to enable the counters, they should be created
'prior to executing the application that uses the counters.
'Execute this sample a second time to use the counters.
If Not (SetupCategory()) Then
CreateCounters()
CollectSamples(samplesList)
CalculateResults(samplesList)
End If
End Sub
Private Shared Function SetupCategory() As Boolean
If Not PerformanceCounterCategory.Exists("NumberOfItems64SampleCategory") Then
Dim CCDC As New CounterCreationDataCollection()
' Add the counter.
Dim NOI64 As New CounterCreationData()
NOI64.CounterType = PerformanceCounterType.NumberOfItems64
NOI64.CounterName = "NumberOfItems64Sample"
CCDC.Add(NOI64)
' Create the category.
PerformanceCounterCategory.Create("NumberOfItems64SampleCategory",
"Demonstrates usage of the NumberOfItems64_1 performance counter type.",
PerformanceCounterCategoryType.SingleInstance, CCDC)
Return True
Else
Console.WriteLine("Category exists - NumberOfItems64SampleCategory")
Return False
End If
End Function 'SetupCategory
Private Shared Sub CreateCounters()
' Create the counters.
PC = New PerformanceCounter("NumberOfItems64SampleCategory", "NumberOfItems64Sample", False)
PC.RawValue = 0
End Sub
Private Shared Sub CollectSamples(ByVal samplesList As ArrayList)
Dim r As New Random(DateTime.Now.Millisecond)
' Loop for the samples.
Dim j As Integer
For j = 0 To 99
Dim value As Integer = r.Next(1, 10)
Console.Write((j.ToString() + " = " + value.ToString()))
PC.IncrementBy(value)
If j Mod 10 = 9 Then
OutputSample(PC.NextSample())
samplesList.Add(PC.NextSample())
Else
Console.WriteLine()
End If
System.Threading.Thread.Sleep(50)
Next j
End Sub
Private Shared Sub CalculateResults(ByVal samplesList As ArrayList)
Dim i As Integer
For i = 0 To (samplesList.Count - 1) - 1
' Output the sample.
OutputSample(CType(samplesList(i), CounterSample))
OutputSample(CType(samplesList((i + 1)), CounterSample))
' Use .NET to calculate the counter value.
Console.WriteLine(".NET computed counter value = " + CounterSampleCalculator.ComputeCounterValue(CType(samplesList(i), CounterSample), CType(samplesList((i + 1)), CounterSample)).ToString())
' Calculate the counter value manually.
Console.WriteLine("My computed counter value = " + MyComputeCounterValue(CType(samplesList(i), CounterSample), CType(samplesList((i + 1)), CounterSample)).ToString())
Next i
End Sub
'++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
'++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
Private Shared Function MyComputeCounterValue(ByVal s0 As CounterSample, ByVal s1 As CounterSample) As [Single]
Dim counterValue As [Single] = s1.RawValue
Return counterValue
End Function 'MyComputeCounterValue
' Output information about the counter sample.
Private Shared Sub OutputSample(ByVal s As CounterSample)
Console.WriteLine(ControlChars.Lf + ControlChars.Cr + "+++++++++++")
Console.WriteLine("Sample values - " + ControlChars.Lf + ControlChars.Cr)
Console.WriteLine((" BaseValue = " + s.BaseValue.ToString()))
Console.WriteLine((" CounterFrequency = " + s.CounterFrequency.ToString()))
Console.WriteLine((" CounterTimeStamp = " + s.CounterTimeStamp.ToString()))
Console.WriteLine((" CounterType = " + s.CounterType.ToString()))
Console.WriteLine((" RawValue = " + s.RawValue.ToString()))
Console.WriteLine((" SystemFrequency = " + s.SystemFrequency.ToString()))
Console.WriteLine((" TimeStamp = " + s.TimeStamp.ToString()))
Console.WriteLine((" TimeStamp100nSec = " + s.TimeStamp100nSec.ToString()))
Console.WriteLine("++++++++++++++++++++++")
End Sub
End Class
SampleFraction
using System;
using System.Collections;
using System.Collections.Specialized;
using System.Diagnostics;
// Provides a SampleFraction counter to measure the percentage of the user processor
// time for this process to total processor time for the process.
public class App
{
private static PerformanceCounter perfCounter;
private static PerformanceCounter basePerfCounter;
private static Process thisProcess = Process.GetCurrentProcess();
public static void Main()
{
ArrayList samplesList = new ArrayList();
// If the category does not exist, create the category and exit.
// Performance counters should not be created and immediately used.
// There is a latency time to enable the counters, they should be created
// prior to executing the application that uses the counters.
// Execute this sample a second time to use the category.
if (SetupCategory())
return;
CreateCounters();
CollectSamples(samplesList);
CalculateResults(samplesList);
}
private static bool SetupCategory()
{
if (!PerformanceCounterCategory.Exists("SampleFractionCategory"))
{
CounterCreationDataCollection CCDC = new CounterCreationDataCollection();
// Add the counter.
CounterCreationData sampleFraction = new CounterCreationData();
sampleFraction.CounterType = PerformanceCounterType.SampleFraction;
sampleFraction.CounterName = "SampleFractionSample";
CCDC.Add(sampleFraction);
// Add the base counter.
CounterCreationData sampleFractionBase = new CounterCreationData();
sampleFractionBase.CounterType = PerformanceCounterType.SampleBase;
sampleFractionBase.CounterName = "SampleFractionSampleBase";
CCDC.Add(sampleFractionBase);
// Create the category.
PerformanceCounterCategory.Create("SampleFractionCategory",
"Demonstrates usage of the SampleFraction performance counter type.",
PerformanceCounterCategoryType.SingleInstance, CCDC);
return (true);
}
else
{
Console.WriteLine("Category exists - SampleFractionCategory");
return (false);
}
}
private static void CreateCounters()
{
// Create the counters.
perfCounter = new PerformanceCounter("SampleFractionCategory",
"SampleFractionSample",
false);
basePerfCounter = new PerformanceCounter("SampleFractionCategory",
"SampleFractionSampleBase",
false);
perfCounter.RawValue = thisProcess.UserProcessorTime.Ticks;
basePerfCounter.RawValue = thisProcess.TotalProcessorTime.Ticks;
}
private static void CollectSamples(ArrayList samplesList)
{
// Loop for the samples.
for (int j = 0; j < 100; j++)
{
perfCounter.IncrementBy(thisProcess.UserProcessorTime.Ticks);
basePerfCounter.IncrementBy(thisProcess.TotalProcessorTime.Ticks);
if ((j % 10) == 9)
{
OutputSample(perfCounter.NextSample());
samplesList.Add(perfCounter.NextSample());
}
else
{
Console.WriteLine();
}
System.Threading.Thread.Sleep(50);
}
}
private static void CalculateResults(ArrayList samplesList)
{
for (int i = 0; i < (samplesList.Count - 1); i++)
{
// Output the sample.
OutputSample((CounterSample)samplesList[i]);
OutputSample((CounterSample)samplesList[i + 1]);
// Use .NET to calculate the counter value.
Console.WriteLine(".NET computed counter value = " +
CounterSampleCalculator.ComputeCounterValue((CounterSample)samplesList[i],
(CounterSample)samplesList[i + 1]));
// Calculate the counter value manually.
Console.WriteLine("My computed counter value = " +
MyComputeCounterValue((CounterSample)samplesList[i],
(CounterSample)samplesList[i + 1]));
}
}
//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
// Description - This counter type provides A percentage counter that shows the
// average ratio of user proccessor time to total processor time during the last
// two sample intervals.
//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
private static Single MyComputeCounterValue(CounterSample s0, CounterSample s1)
{
Single numerator = (Single)s1.RawValue - (Single)s0.RawValue;
Single denomenator = (Single)s1.BaseValue - (Single)s0.BaseValue;
Single counterValue = 100 * (numerator / denomenator);
return (counterValue);
}
// Output information about the counter sample.
private static void OutputSample(CounterSample s)
{
Console.WriteLine("\r\n+++++++++++");
Console.WriteLine("Sample values - \r\n");
Console.WriteLine(" BaseValue = " + s.BaseValue);
Console.WriteLine(" CounterFrequency = " + s.CounterFrequency);
Console.WriteLine(" CounterTimeStamp = " + s.CounterTimeStamp);
Console.WriteLine(" CounterType = " + s.CounterType);
Console.WriteLine(" RawValue = " + s.RawValue);
Console.WriteLine(" SystemFrequency = " + s.SystemFrequency);
Console.WriteLine(" TimeStamp = " + s.TimeStamp);
Console.WriteLine(" TimeStamp100nSec = " + s.TimeStamp100nSec);
Console.WriteLine("++++++++++++++++++++++");
}
}
Imports System.Collections
Imports System.Collections.Specialized
Imports System.Diagnostics
Imports System.Runtime.Versioning
' Provides a SampleFraction counter to measure the percentage of the user processor
' time for this process to total processor time for the process.
<SupportedOSPlatform("Windows")>
Public Class App3
Private Shared perfCounter As PerformanceCounter
Private Shared basePerfCounter As PerformanceCounter
Private Shared thisProcess As Process = Process.GetCurrentProcess()
Public Shared Sub Main()
Dim samplesList As New ArrayList()
' If the category does not exist, create the category and exit.
' Performance counters should not be created and immediately used.
' There is a latency time to enable the counters, they should be created
' prior to executing the application that uses the counters.
' Execute this sample a second time to use the category.
If SetupCategory() Then
Return
End If
CreateCounters()
CollectSamples(samplesList)
CalculateResults(samplesList)
End Sub
Private Shared Function SetupCategory() As Boolean
If Not PerformanceCounterCategory.Exists("SampleFractionCategory") Then
Dim CCDC As New CounterCreationDataCollection()
' Add the counter.
Dim sampleFraction As New CounterCreationData()
sampleFraction.CounterType = PerformanceCounterType.SampleFraction
sampleFraction.CounterName = "SampleFractionSample"
CCDC.Add(sampleFraction)
' Add the base counter.
Dim sampleFractionBase As New CounterCreationData()
sampleFractionBase.CounterType = PerformanceCounterType.SampleBase
sampleFractionBase.CounterName = "SampleFractionSampleBase"
CCDC.Add(sampleFractionBase)
' Create the category.
PerformanceCounterCategory.Create("SampleFractionCategory", "Demonstrates usage of the SampleFraction performance counter type.", PerformanceCounterCategoryType.SingleInstance, CCDC)
Return True
Else
Console.WriteLine("Category exists - SampleFractionCategory")
Return False
End If
End Function 'SetupCategory
Private Shared Sub CreateCounters()
' Create the counters.
perfCounter = New PerformanceCounter("SampleFractionCategory", "SampleFractionSample", False)
basePerfCounter = New PerformanceCounter("SampleFractionCategory", "SampleFractionSampleBase", False)
perfCounter.RawValue = thisProcess.UserProcessorTime.Ticks
basePerfCounter.RawValue = thisProcess.TotalProcessorTime.Ticks
End Sub
Private Shared Sub CollectSamples(ByVal samplesList As ArrayList)
' Loop for the samples.
Dim j As Integer
For j = 0 To 99
perfCounter.IncrementBy(thisProcess.UserProcessorTime.Ticks)
basePerfCounter.IncrementBy(thisProcess.TotalProcessorTime.Ticks)
If j Mod 10 = 9 Then
OutputSample(perfCounter.NextSample())
samplesList.Add(perfCounter.NextSample())
Else
Console.WriteLine()
End If
System.Threading.Thread.Sleep(50)
Next j
End Sub
Private Shared Sub CalculateResults(ByVal samplesList As ArrayList)
Dim i As Integer
For i = 0 To (samplesList.Count - 1)
' Output the sample.
OutputSample(CType(samplesList(i), CounterSample))
OutputSample(CType(samplesList((i + 1)), CounterSample))
' Use .NET to calculate the counter value.
Console.WriteLine(".NET computed counter value = " + CounterSampleCalculator.ComputeCounterValue(CType(samplesList(i), CounterSample), CType(samplesList((i + 1)), CounterSample)))
' Calculate the counter value manually.
Console.WriteLine("My computed counter value = " + MyComputeCounterValue(CType(samplesList(i), CounterSample), CType(samplesList((i + 1)), CounterSample)))
Next i
End Sub
'++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
' Description - This counter type provides A percentage counter that shows the
' average ratio of user proccessor time to total processor time during the last
' two sample intervals.
'++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
Private Shared Function MyComputeCounterValue(ByVal s0 As CounterSample, ByVal s1 As CounterSample) As [Single]
Dim numerator As [Single] = CType(s1.RawValue, [Single]) - CType(s0.RawValue, [Single])
Dim denomenator As [Single] = CType(s1.BaseValue, [Single]) - CType(s0.BaseValue, [Single])
Dim counterValue As [Single] = 100 * (numerator / denomenator)
Return counterValue
End Function 'MyComputeCounterValue
' Output information about the counter sample.
Private Shared Sub OutputSample(ByVal s As CounterSample)
Console.WriteLine(vbCr + vbLf + "+++++++++++")
Console.WriteLine("Sample values - " + vbCr + vbLf)
Console.WriteLine(" BaseValue = " + s.BaseValue)
Console.WriteLine(" CounterFrequency = " + s.CounterFrequency)
Console.WriteLine(" CounterTimeStamp = " + s.CounterTimeStamp)
Console.WriteLine(" CounterType = " + s.CounterType)
Console.WriteLine(" RawValue = " + s.RawValue)
Console.WriteLine(" SystemFrequency = " + s.SystemFrequency)
Console.WriteLine(" TimeStamp = " + s.TimeStamp)
Console.WriteLine(" TimeStamp100nSec = " + s.TimeStamp100nSec)
Console.WriteLine("++++++++++++++++++++++")
End Sub
End Class
RateOfCountsPerSecond32
using System;
using System.Collections;
using System.Diagnostics;
using System.Runtime.Versioning;
[SupportedOSPlatform("Windows")]
public class App3
{
private static PerformanceCounter PC;
public static void Main()
{
ArrayList samplesList = new ArrayList();
// If the category does not exist, create the category and exit.
// Perfomance counters should not be created and immediately used.
// There is a latency time to enable the counters, they should be created
// prior to executing the application that uses the counters.
// Execute this sample a second time to use the category.
if (SetupCategory())
return;
CreateCounters();
CollectSamples(samplesList);
CalculateResults(samplesList);
}
private static bool SetupCategory()
{
if (!PerformanceCounterCategory.Exists("RateOfCountsPerSecond32SampleCategory"))
{
CounterCreationDataCollection CCDC = new CounterCreationDataCollection();
// Add the counter.
CounterCreationData rateOfCounts32 = new CounterCreationData();
rateOfCounts32.CounterType = PerformanceCounterType.RateOfCountsPerSecond32;
rateOfCounts32.CounterName = "RateOfCountsPerSecond32Sample";
CCDC.Add(rateOfCounts32);
// Create the category.
PerformanceCounterCategory.Create("RateOfCountsPerSecond32SampleCategory",
"Demonstrates usage of the RateOfCountsPerSecond32 performance counter type.",
PerformanceCounterCategoryType.SingleInstance, CCDC);
return (true);
}
else
{
Console.WriteLine("Category exists - RateOfCountsPerSecond32SampleCategory");
return (false);
}
}
private static void CreateCounters()
{
// Create the counter.
PC = new PerformanceCounter("RateOfCountsPerSecond32SampleCategory",
"RateOfCountsPerSecond32Sample",
false);
PC.RawValue = 0;
}
private static void CollectSamples(ArrayList samplesList)
{
Random r = new Random(DateTime.Now.Millisecond);
// Initialize the performance counter.
PC.NextSample();
// Loop for the samples.
for (int j = 0; j < 100; j++)
{
int value = r.Next(1, 10);
PC.IncrementBy(value);
Console.Write(j + " = " + value);
if ((j % 10) == 9)
{
Console.WriteLine("; NextValue() = " + PC.NextValue().ToString());
OutputSample(PC.NextSample());
samplesList.Add(PC.NextSample());
}
else
{
Console.WriteLine();
}
System.Threading.Thread.Sleep(50);
}
}
private static void CalculateResults(ArrayList samplesList)
{
for (int i = 0; i < (samplesList.Count - 1); i++)
{
// Output the sample.
OutputSample((CounterSample)samplesList[i]);
OutputSample((CounterSample)samplesList[i + 1]);
// Use .NET to calculate the counter value.
Console.WriteLine(".NET computed counter value = " +
CounterSampleCalculator.ComputeCounterValue((CounterSample)samplesList[i],
(CounterSample)samplesList[i + 1]));
// Calculate the counter value manually.
Console.WriteLine("My computed counter value = " +
MyComputeCounterValue((CounterSample)samplesList[i],
(CounterSample)samplesList[i + 1]));
}
}
//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
// PERF_COUNTER_COUNTER
// Description - This counter type shows the average number of operations completed
// during each second of the sample interval. Counters of this type
// measure time in ticks of the system clock. The F variable represents
// the number of ticks per second. The value of F is factored into the
// equation so that the result can be displayed in seconds.
//
// Generic type - Difference
//
// Formula - (N1 - N0) / ( (D1 - D0) / F), where the numerator (N) represents the number
// of operations performed during the last sample interval, the denominator
// (D) represents the number of ticks elapsed during the last sample
// interval, and F is the frequency of the ticks.
//
// Average - (Nx - N0) / ((Dx - D0) / F)
//
// Example - System\ File Read Operations/sec
//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
private static Single MyComputeCounterValue(CounterSample s0, CounterSample s1)
{
Single numerator = (Single)(s1.RawValue - s0.RawValue);
Single denomenator = (Single)(s1.TimeStamp - s0.TimeStamp) / (Single)s1.SystemFrequency;
Single counterValue = numerator / denomenator;
return (counterValue);
}
// Output information about the counter sample.
private static void OutputSample(CounterSample s)
{
Console.WriteLine("\r\n+++++++++++");
Console.WriteLine("Sample values - \r\n");
Console.WriteLine(" BaseValue = " + s.BaseValue);
Console.WriteLine(" CounterFrequency = " + s.CounterFrequency);
Console.WriteLine(" CounterTimeStamp = " + s.CounterTimeStamp);
Console.WriteLine(" CounterType = " + s.CounterType);
Console.WriteLine(" RawValue = " + s.RawValue);
Console.WriteLine(" SystemFrequency = " + s.SystemFrequency);
Console.WriteLine(" TimeStamp = " + s.TimeStamp);
Console.WriteLine(" TimeStamp100nSec = " + s.TimeStamp100nSec);
Console.WriteLine("++++++++++++++++++++++");
}
}
Imports System.Collections
Imports System.Collections.Specialized
Imports System.Diagnostics
Imports System.Runtime.Versioning
<SupportedOSPlatform("Windows")>
Public Class App4
Private Shared PC As PerformanceCounter
Public Shared Sub Main()
Dim samplesList As New ArrayList()
'If the category does not exist, create the category and exit.
'Performance counters should not be created and immediately used.
'There is a latency time to enable the counters, they should be created
'prior to executing the App4lication that uses the counters.
'Execute this sample a second time to use the counters.
If Not (SetupCategory()) Then
CreateCounters()
CollectSamples(samplesList)
CalculateResults(samplesList)
End If
End Sub
Private Shared Function SetupCategory() As Boolean
If Not PerformanceCounterCategory.Exists("RateOfCountsPerSecond32SampleCategory") Then
Dim CCDC As New CounterCreationDataCollection()
' Add the counter.
Dim rateOfCounts32 As New CounterCreationData()
rateOfCounts32.CounterType = PerformanceCounterType.RateOfCountsPerSecond32
rateOfCounts32.CounterName = "RateOfCountsPerSecond32Sample"
CCDC.Add(rateOfCounts32)
' Create the category.
PerformanceCounterCategory.Create("RateOfCountsPerSecond32SampleCategory", _
"Demonstrates usage of the RateOfCountsPerSecond32 performance counter type.", _
PerformanceCounterCategoryType.SingleInstance, CCDC)
Return True
Else
Console.WriteLine("Category exists - RateOfCountsPerSecond32SampleCategory")
Return False
End If
End Function 'SetupCategory
Private Shared Sub CreateCounters()
' Create the counter.
PC = New PerformanceCounter("RateOfCountsPerSecond32SampleCategory", "RateOfCountsPerSecond32Sample", False)
PC.RawValue = 0
End Sub
Private Shared Sub CollectSamples(ByVal samplesList As ArrayList)
Dim r As New Random(DateTime.Now.Millisecond)
' Initialize the performance counter.
PC.NextSample()
' Loop for the samples.
Dim j As Integer
For j = 0 To 99
Dim value As Integer = r.Next(1, 10)
PC.IncrementBy(value)
Console.Write((j.ToString() + " = " + value.ToString()))
If j Mod 10 = 9 Then
Console.WriteLine(("; NextValue() = " + PC.NextValue().ToString()))
OutputSample(PC.NextSample())
samplesList.Add(PC.NextSample())
Else
Console.WriteLine()
End If
System.Threading.Thread.Sleep(50)
Next j
End Sub
Private Shared Sub CalculateResults(ByVal samplesList As ArrayList)
Dim i As Integer
For i = 0 To (samplesList.Count - 1) - 1
' Output the sample.
OutputSample(CType(samplesList(i), CounterSample))
OutputSample(CType(samplesList((i + 1)), CounterSample))
' Use .NET to calculate the counter value.
Console.WriteLine(".NET computed counter value = " + CounterSampleCalculator.ComputeCounterValue(CType(samplesList(i), CounterSample), CType(samplesList((i + 1)), CounterSample)).ToString())
' Calculate the counter value manually.
Console.WriteLine("My computed counter value = " + MyComputeCounterValue(CType(samplesList(i), CounterSample), CType(samplesList((i + 1)), CounterSample)).ToString())
Next i
End Sub
'++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
' PERF_COUNTER_COUNTER
' Description - This counter type shows the average number of operations completed
' during each second of the sample interval. Counters of this type
' measure time in ticks of the system clock. The F variable represents
' the number of ticks per second. The value of F is factored into the
' equation so that the result can be displayed in seconds.
'
' Generic type - Difference
'
' Formula - (N1 - N0) / ( (D1 - D0) / F), where the numerator (N) represents the number
' of operations performed during the last sample interval, the denominator
' (D) represents the number of ticks elapsed during the last sample
' interval, and F is the frequency of the ticks.
'
' Average - (Nx - N0) / ((Dx - D0) / F)
'
' Example - System\ File Read Operations/sec
'++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
Private Shared Function MyComputeCounterValue(ByVal s0 As CounterSample, ByVal s1 As CounterSample) As [Single]
Dim numerator As [Single] = CType(s1.RawValue - s0.RawValue, [Single])
Dim denomenator As [Single] = CType(s1.TimeStamp - s0.TimeStamp, [Single]) / CType(s1.SystemFrequency, [Single])
Dim counterValue As [Single] = numerator / denomenator
Return counterValue
End Function 'MyComputeCounterValue
' Output information about the counter sample.
Private Shared Sub OutputSample(ByVal s As CounterSample)
Console.WriteLine(ControlChars.Lf + ControlChars.Cr + "+++++++++++")
Console.WriteLine("Sample values - " + ControlChars.Lf + ControlChars.Cr)
Console.WriteLine((" BaseValue = " + s.BaseValue.ToString()))
Console.WriteLine((" CounterFrequency = " + s.CounterFrequency.ToString()))
Console.WriteLine((" CounterTimeStamp = " + s.CounterTimeStamp.ToString()))
Console.WriteLine((" CounterType = " + s.CounterType.ToString()))
Console.WriteLine((" RawValue = " + s.RawValue.ToString()))
Console.WriteLine((" SystemFrequency = " + s.SystemFrequency.ToString()))
Console.WriteLine((" TimeStamp = " + s.TimeStamp.ToString()))
Console.WriteLine((" TimeStamp100nSec = " + s.TimeStamp100nSec.ToString()))
Console.WriteLine("++++++++++++++++++++++")
End Sub
End Class
RateOfCountsPerSecond64
using System;
using System.Collections;
using System.Diagnostics;
using System.Runtime.Versioning;
[SupportedOSPlatform("Windows")]
public class App4
{
private static PerformanceCounter PC;
public static void Main()
{
ArrayList samplesList = new ArrayList();
// If the category does not exist, create the category and exit.
// Perfomance counters should not be created and immediately used.
// There is a latency time to enable the counters, they should be created
// prior to executing the application that uses the counters.
// Execute this sample a second time to use the category.
if (SetupCategory())
return;
CreateCounters();
CollectSamples(samplesList);
CalculateResults(samplesList);
}
private static bool SetupCategory()
{
if (!PerformanceCounterCategory.Exists("RateOfCountsPerSecond64SampleCategory"))
{
CounterCreationDataCollection CCDC = new CounterCreationDataCollection();
// Add the counter.
CounterCreationData rateOfCounts64 = new CounterCreationData();
rateOfCounts64.CounterType = PerformanceCounterType.RateOfCountsPerSecond64;
rateOfCounts64.CounterName = "RateOfCountsPerSecond64Sample";
CCDC.Add(rateOfCounts64);
// Create the category.
PerformanceCounterCategory.Create("RateOfCountsPerSecond64SampleCategory",
"Demonstrates usage of the RateOfCountsPerSecond64 performance counter type.",
PerformanceCounterCategoryType.SingleInstance, CCDC);
return (true);
}
else
{
Console.WriteLine("Category exists - RateOfCountsPerSecond64SampleCategory");
return (false);
}
}
private static void CreateCounters()
{
// Create the counter.
PC = new PerformanceCounter("RateOfCountsPerSecond64SampleCategory",
"RateOfCountsPerSecond64Sample",
false);
PC.RawValue = 0;
}
private static void CollectSamples(ArrayList samplesList)
{
Random r = new Random(DateTime.Now.Millisecond);
// Initialize the performance counter.
PC.NextSample();
// Loop for the samples.
for (int j = 0; j < 100; j++)
{
int value = r.Next(1, 10);
PC.IncrementBy(value);
Console.Write(j + " = " + value);
if ((j % 10) == 9)
{
Console.WriteLine("; NextValue() = " + PC.NextValue().ToString());
OutputSample(PC.NextSample());
samplesList.Add(PC.NextSample());
}
else
{
Console.WriteLine();
}
System.Threading.Thread.Sleep(50);
}
}
private static void CalculateResults(ArrayList samplesList)
{
for (int i = 0; i < (samplesList.Count - 1); i++)
{
// Output the sample.
OutputSample((CounterSample)samplesList[i]);
OutputSample((CounterSample)samplesList[i + 1]);
// Use .NET to calculate the counter value.
Console.WriteLine(".NET computed counter value = " +
CounterSampleCalculator.ComputeCounterValue((CounterSample)samplesList[i],
(CounterSample)samplesList[i + 1]));
// Calculate the counter value manually.
Console.WriteLine("My computed counter value = " +
MyComputeCounterValue((CounterSample)samplesList[i],
(CounterSample)samplesList[i + 1]));
}
}
//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
// PERF_COUNTER_COUNTER
// Description - This counter type shows the average number of operations completed
// during each second of the sample interval. Counters of this type
// measure time in ticks of the system clock. The F variable represents
// the number of ticks per second. The value of F is factored into the
// equation so that the result can be displayed in seconds.
//
// Generic type - Difference
//
// Formula - (N1 - N0) / ( (D1 - D0) / F), where the numerator (N) represents the number
// of operations performed during the last sample interval, the denominator
// (D) represents the number of ticks elapsed during the last sample
// interval, and F is the frequency of the ticks.
//
// Average - (Nx - N0) / ((Dx - D0) / F)
//
// Example - System\ File Read Operations/sec
//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
private static Single MyComputeCounterValue(CounterSample s0, CounterSample s1)
{
Single numerator = (Single)(s1.RawValue - s0.RawValue);
Single denomenator = (Single)(s1.TimeStamp - s0.TimeStamp) / (Single)s1.SystemFrequency;
Single counterValue = numerator / denomenator;
return (counterValue);
}
private static void OutputSample(CounterSample s)
{
Console.WriteLine("\r\n+++++++++++");
Console.WriteLine("Sample values - \r\n");
Console.WriteLine(" BaseValue = " + s.BaseValue);
Console.WriteLine(" CounterFrequency = " + s.CounterFrequency);
Console.WriteLine(" CounterTimeStamp = " + s.CounterTimeStamp);
Console.WriteLine(" CounterType = " + s.CounterType);
Console.WriteLine(" RawValue = " + s.RawValue);
Console.WriteLine(" SystemFrequency = " + s.SystemFrequency);
Console.WriteLine(" TimeStamp = " + s.TimeStamp);
Console.WriteLine(" TimeStamp100nSec = " + s.TimeStamp100nSec);
Console.WriteLine("++++++++++++++++++++++");
}
}
Imports System.Collections
Imports System.Collections.Specialized
Imports System.Diagnostics
Imports System.Runtime.Versioning
<SupportedOSPlatform("Windows")>
Public Class App5
Private Shared PC As PerformanceCounter
Public Shared Sub Main()
Dim samplesList As New ArrayList()
'If the category does not exist, create the category and exit.
'Performance counters should not be created and immediately used.
'There is a latency time to enable the counters, they should be created
'prior to executing the App5lication that uses the counters.
'Execute this sample a second time to use the counters.
If Not (SetupCategory()) Then
CreateCounters()
CollectSamples(samplesList)
CalculateResults(samplesList)
End If
End Sub
Private Shared Function SetupCategory() As Boolean
If Not PerformanceCounterCategory.Exists("RateOfCountsPerSecond64SampleCategory") Then
Dim CCDC As New CounterCreationDataCollection()
' Add the counter.
Dim rateOfCounts64 As New CounterCreationData()
rateOfCounts64.CounterType = PerformanceCounterType.RateOfCountsPerSecond64
rateOfCounts64.CounterName = "RateOfCountsPerSecond64Sample"
CCDC.Add(rateOfCounts64)
' Create the category.
PerformanceCounterCategory.Create("RateOfCountsPerSecond64SampleCategory", _
"Demonstrates usage of the RateOfCountsPerSecond64 performance counter type.", _
PerformanceCounterCategoryType.SingleInstance, CCDC)
Return True
Else
Console.WriteLine("Category exists - RateOfCountsPerSecond64SampleCategory")
Return False
End If
End Function 'SetupCategory
Private Shared Sub CreateCounters()
' Create the counter.
PC = New PerformanceCounter("RateOfCountsPerSecond64SampleCategory", "RateOfCountsPerSecond64Sample", False)
PC.RawValue = 0
End Sub
Private Shared Sub CollectSamples(ByVal samplesList As ArrayList)
Dim r As New Random(DateTime.Now.Millisecond)
' Initialize the performance counter.
PC.NextSample()
' Loop for the samples.
Dim j As Integer
For j = 0 To 99
Dim value As Integer = r.Next(1, 10)
PC.IncrementBy(value)
Console.Write((j.ToString() + " = " + value.ToString()))
If j Mod 10 = 9 Then
Console.WriteLine(("; NextValue() = " + PC.NextValue().ToString()))
OutputSample(PC.NextSample())
samplesList.Add(PC.NextSample())
Else
Console.WriteLine()
End If
System.Threading.Thread.Sleep(50)
Next j
End Sub
Private Shared Sub CalculateResults(ByVal samplesList As ArrayList)
Dim i As Integer
For i = 0 To (samplesList.Count - 1) - 1
' Output the sample.
OutputSample(CType(samplesList(i), CounterSample))
OutputSample(CType(samplesList((i + 1)), CounterSample))
' Use .NET to calculate the counter value.
Console.WriteLine(".NET computed counter value = " + _
CounterSampleCalculator.ComputeCounterValue(CType(samplesList(i), CounterSample), CType(samplesList((i + 1)), CounterSample)).ToString())
' Calculate the counter value manually.
Console.WriteLine("My computed counter value = " + _
MyComputeCounterValue(CType(samplesList(i), CounterSample), CType(samplesList((i + 1)), CounterSample)).ToString())
Next i
End Sub
'++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
' PERF_COUNTER_COUNTER
' Description - This counter type shows the average number of operations completed
' during each second of the sample interval. Counters of this type
' measure time in ticks of the system clock. The F variable represents
' the number of ticks per second. The value of F is factored into the
' equation so that the result can be displayed in seconds.
'
' Generic type - Difference
'
' Formula - (N1 - N0) / ( (D1 - D0) / F), where the numerator (N) represents the number
' of operations performed during the last sample interval, the denominator
' (D) represents the number of ticks elapsed during the last sample
' interval, and F is the frequency of the ticks.
'
' Average - (Nx - N0) / ((Dx - D0) / F)
'
' Example - System\ File Read Operations/sec
'++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
Private Shared Function MyComputeCounterValue(ByVal s0 As CounterSample, ByVal s1 As CounterSample) As [Single]
Dim numerator As [Single] = CType(s1.RawValue - s0.RawValue, [Single])
Dim denomenator As [Single] = CType(s1.TimeStamp - s0.TimeStamp, [Single]) / CType(s1.SystemFrequency, [Single])
Dim counterValue As [Single] = numerator / denomenator
Return counterValue
End Function 'MyComputeCounterValue
Private Shared Sub OutputSample(ByVal s As CounterSample)
Console.WriteLine(ControlChars.Lf + ControlChars.Cr + "+++++++++++")
Console.WriteLine("Sample values - " + ControlChars.Lf + ControlChars.Cr)
Console.WriteLine((" BaseValue = " + s.BaseValue.ToString()))
Console.WriteLine((" CounterFrequency = " + s.CounterFrequency.ToString()))
Console.WriteLine((" CounterTimeStamp = " + s.CounterTimeStamp.ToString()))
Console.WriteLine((" CounterType = " + s.CounterType.ToString()))
Console.WriteLine((" RawValue = " + s.RawValue.ToString()))
Console.WriteLine((" SystemFrequency = " + s.SystemFrequency.ToString()))
Console.WriteLine((" TimeStamp = " + s.TimeStamp.ToString()))
Console.WriteLine((" TimeStamp100nSec = " + s.TimeStamp100nSec.ToString()))
Console.WriteLine("++++++++++++++++++++++")
End Sub
End Class
RawFraction
using System;
using System.Collections;
using System.Diagnostics;
using System.Runtime.Versioning;
[SupportedOSPlatform("Windows")]
public class App5
{
private static PerformanceCounter PC;
private static PerformanceCounter BPC;
public static void Main()
{
ArrayList samplesList = new ArrayList();
// If the category does not exist, create the category and exit.
// Performance counters should not be created and immediately used.
// There is a latency time to enable the counters, they should be created
// prior to executing the application that uses the counters.
// Execute this sample a second time to use the counters.
if (SetupCategory())
return;
CreateCounters();
CollectSamples(samplesList);
CalculateResults(samplesList);
}
private static bool SetupCategory()
{
if (!PerformanceCounterCategory.Exists("RawFractionSampleCategory"))
{
CounterCreationDataCollection CCDC = new CounterCreationDataCollection();
// Add the counter.
CounterCreationData rf = new CounterCreationData();
rf.CounterType = PerformanceCounterType.RawFraction;
rf.CounterName = "RawFractionSample";
CCDC.Add(rf);
// Add the base counter.
CounterCreationData rfBase = new CounterCreationData();
rfBase.CounterType = PerformanceCounterType.RawBase;
rfBase.CounterName = "RawFractionSampleBase";
CCDC.Add(rfBase);
// Create the category.
PerformanceCounterCategory.Create("RawFractionSampleCategory",
"Demonstrates usage of the RawFraction performance counter type.",
PerformanceCounterCategoryType.SingleInstance, CCDC);
return (true);
}
else
{
Console.WriteLine("Category exists - RawFractionSampleCategory");
return (false);
}
}
private static void CreateCounters()
{
// Create the counters.
PC = new PerformanceCounter("RawFractionSampleCategory",
"RawFractionSample",
false);
BPC = new PerformanceCounter("RawFractionSampleCategory",
"RawFractionSampleBase",
false);
PC.RawValue = 0;
BPC.RawValue = 0;
}
private static void CollectSamples(ArrayList samplesList)
{
Random r = new Random(DateTime.Now.Millisecond);
// Initialize the performance counter.
PC.NextSample();
// Loop for the samples.
for (int j = 0; j < 100; j++)
{
int value = r.Next(1, 10);
Console.Write(j + " = " + value);
// Increment the base every time, because the counter measures the number
// of high hits (raw fraction value) against all the hits (base value).
BPC.Increment();
// Get the % of samples that are 9 or 10 out of all the samples taken.
if (value >= 9)
PC.Increment();
// Copy out the next value every ten times around the loop.
if ((j % 10) == 9)
{
Console.WriteLine("; NextValue() = " + PC.NextValue().ToString());
OutputSample(PC.NextSample());
samplesList.Add(PC.NextSample());
}
else
{
Console.WriteLine();
}
System.Threading.Thread.Sleep(50);
}
}
private static void CalculateResults(ArrayList samplesList)
{
for (int i = 0; i < samplesList.Count; i++)
{
// Output the sample.
OutputSample((CounterSample)samplesList[i]);
// Use .NET to calculate the counter value.
Console.WriteLine(".NET computed counter value = " +
CounterSampleCalculator.ComputeCounterValue((CounterSample)samplesList[i]));
// Calculate the counter value manually.
Console.WriteLine("My computed counter value = " +
MyComputeCounterValue((CounterSample)samplesList[i]));
}
}
//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
// Formula from MSDN -
// Description - This counter type shows the ratio of a subset to its set as a percentage.
// For example, it compares the number of bytes in use on a disk to the
// total number of bytes on the disk. Counters of this type display the
// current percentage only, not an average over time.
//
// Generic type - Instantaneous, Percentage
// Formula - (N0 / D0), where D represents a measured attribute and N represents one
// component of that attribute.
//
// Average - SUM (N / D) /x
// Example - Paging File\% Usage Peak
//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
private static Single MyComputeCounterValue(CounterSample rfSample)
{
Single numerator = (Single)rfSample.RawValue;
Single denomenator = (Single)rfSample.BaseValue;
Single counterValue = (numerator / denomenator) * 100;
return (counterValue);
}
// Output information about the counter sample.
private static void OutputSample(CounterSample s)
{
Console.WriteLine("+++++++++++");
Console.WriteLine("Sample values - \r\n");
Console.WriteLine(" BaseValue = " + s.BaseValue);
Console.WriteLine(" CounterFrequency = " + s.CounterFrequency);
Console.WriteLine(" CounterTimeStamp = " + s.CounterTimeStamp);
Console.WriteLine(" CounterType = " + s.CounterType);
Console.WriteLine(" RawValue = " + s.RawValue);
Console.WriteLine(" SystemFrequency = " + s.SystemFrequency);
Console.WriteLine(" TimeStamp = " + s.TimeStamp);
Console.WriteLine(" TimeStamp100nSec = " + s.TimeStamp100nSec);
Console.WriteLine("++++++++++++++++++++++");
}
}
Imports System.Collections
Imports System.Collections.Specialized
Imports System.Diagnostics
Imports System.Runtime.Versioning
<SupportedOSPlatform("Windows")>
Public Class App6
Private Shared PC As PerformanceCounter
Private Shared BPC As PerformanceCounter
Public Shared Sub Main()
Dim samplesList As New ArrayList()
'If the category does not exist, create the category and exit.
'Performance counters should not be created and immediately used.
'There is a latency time to enable the counters, they should be created
'prior to executing the App6lication that uses the counters.
'Execute this sample a second time to use the counters.
If Not (SetupCategory()) Then
CreateCounters()
CollectSamples(samplesList)
CalculateResults(samplesList)
End If
End Sub
Private Shared Function SetupCategory() As Boolean
If Not PerformanceCounterCategory.Exists("RawFractionSampleCategory") Then
Dim CCDC As New CounterCreationDataCollection()
' Add the counter.
Dim rf As New CounterCreationData()
rf.CounterType = PerformanceCounterType.RawFraction
rf.CounterName = "RawFractionSample"
CCDC.Add(rf)
' Add the base counter.
Dim rfBase As New CounterCreationData()
rfBase.CounterType = PerformanceCounterType.RawBase
rfBase.CounterName = "RawFractionSampleBase"
CCDC.Add(rfBase)
' Create the category.
PerformanceCounterCategory.Create("RawFractionSampleCategory",
"Demonstrates usage of the RawFraction performance counter type.",
PerformanceCounterCategoryType.SingleInstance, CCDC)
Return True
Else
Console.WriteLine("Category exists - RawFractionSampleCategory")
Return False
End If
End Function 'SetupCategory
Private Shared Sub CreateCounters()
' Create the counters.
PC = New PerformanceCounter("RawFractionSampleCategory", "RawFractionSample", False)
BPC = New PerformanceCounter("RawFractionSampleCategory", "RawFractionSampleBase", False)
PC.RawValue = 0
BPC.RawValue = 0
End Sub
Private Shared Sub CollectSamples(ByVal samplesList As ArrayList)
Dim r As New Random(DateTime.Now.Millisecond)
' Initialize the performance counter.
PC.NextSample()
' Loop for the samples.
Dim j As Integer
For j = 0 To 99
Dim value As Integer = r.Next(1, 10)
Console.Write((j.ToString() + " = " + value.ToString()))
' Increment the base every time, because the counter measures the number
' of high hits (raw fraction value) against all the hits (base value).
BPC.Increment()
' Get the % of samples that are 9 or 10 out of all the samples taken.
If value >= 9 Then
PC.Increment()
End If
' Copy out the next value every ten times around the loop.
If j Mod 10 = 9 Then
Console.WriteLine(("; NextValue() = " + PC.NextValue().ToString()))
OutputSample(PC.NextSample())
samplesList.Add(PC.NextSample())
Else
Console.WriteLine()
End If
System.Threading.Thread.Sleep(50)
Next j
End Sub
Private Shared Sub CalculateResults(ByVal samplesList As ArrayList)
Dim i As Integer
For i = 0 To samplesList.Count - 1
' Output the sample.
OutputSample(CType(samplesList(i), CounterSample))
' Use .NET to calculate the counter value.
Console.WriteLine(".NET computed counter value = " + CounterSampleCalculator.ComputeCounterValue(CType(samplesList(i), CounterSample)).ToString())
' Calculate the counter value manually.
Console.WriteLine("My computed counter value = " + MyComputeCounterValue(CType(samplesList(i), CounterSample)).ToString())
Next i
End Sub
'++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
' Formula from MSDN -
' Description - This counter type shows the ratio of a subset to its set as a percentage.
' For example, it compares the number of bytes in use on a disk to the
' total number of bytes on the disk. Counters of this type display the
' current percentage only, not an average over time.
'
' Generic type - Instantaneous, Percentage
' Formula - (N0 / D0), where D represents a measured attribute and N represents one
' component of that attribute.
'
' Average - SUM (N / D) /x
' Example - Paging File\% Usage Peak
'++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
Private Shared Function MyComputeCounterValue(ByVal rfSample As CounterSample) As [Single]
Dim numerator As [Single] = CType(rfSample.RawValue, [Single])
Dim denomenator As [Single] = CType(rfSample.BaseValue, [Single])
Dim counterValue As [Single] = numerator / denomenator * 100
Return counterValue
End Function 'MyComputeCounterValue
' Output information about the counter sample.
Private Shared Sub OutputSample(ByVal s As CounterSample)
Console.WriteLine("+++++++++++")
Console.WriteLine("Sample values - " + ControlChars.Lf + ControlChars.Cr)
Console.WriteLine((" BaseValue = " + s.BaseValue.ToString()))
Console.WriteLine((" CounterFrequency = " + s.CounterFrequency.ToString()))
Console.WriteLine((" CounterTimeStamp = " + s.CounterTimeStamp.ToString()))
Console.WriteLine((" CounterType = " + s.CounterType.ToString()))
Console.WriteLine((" RawValue = " + s.RawValue.ToString()))
Console.WriteLine((" SystemFrequency = " + s.SystemFrequency.ToString()))
Console.WriteLine((" TimeStamp = " + s.TimeStamp.ToString()))
Console.WriteLine((" TimeStamp100nSec = " + s.TimeStamp100nSec.ToString()))
Console.WriteLine("++++++++++++++++++++++")
End Sub
End Class
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