PerformanceCounterType PerformanceCounterType PerformanceCounterType PerformanceCounterType Enum

Определение

Задает формулу для вычисления метода NextValue() для экземпляра PerformanceCounter.Specifies the formula used to calculate the NextValue() method for a PerformanceCounter instance.

public enum class PerformanceCounterType
[System.ComponentModel.TypeConverter(typeof(System.Diagnostics.AlphabeticalEnumConverter))]
public enum PerformanceCounterType
type PerformanceCounterType = 
Public Enum PerformanceCounterType
Наследование
PerformanceCounterTypePerformanceCounterTypePerformanceCounterTypePerformanceCounterType
Атрибуты

Поля

AverageBase AverageBase AverageBase AverageBase 1073939458

Базовый счетчик, используемый в расчете времени или количества средних значений, например AverageTimer32 и AverageCount64.A base counter that is used in the calculation of time or count averages, such as AverageTimer32 and AverageCount64. Хранит знаменатель для подсчета значения счетчика для представления времени, необходимого для совершения операции или количества за операцию.Stores the denominator for calculating a counter to present "time per operation" or "count per operation".

AverageCount64 AverageCount64 AverageCount64 AverageCount64 1073874176

Счетчик средних значений, показывающий, сколько элементов обработано в среднем за операцию.An average counter that shows how many items are processed, on average, during an operation. Счетчики этого типа отображают отношение обработанных элементов к числу завершенных операций.Counters of this type display a ratio of the items processed to the number of operations completed. Отношение вычисляется соотношением числа обработанных элементов в течение последнего интервала времени к числу завершенных операций за этот же интервал.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. Счетчики этого типа включают "Физический диск\ Средний размер одного обмена с диском (байт)".Counters of this type include PhysicalDisk\ Avg. Disk Bytes/Transfer.

AverageTimer32 AverageTimer32 AverageTimer32 AverageTimer32 805438464

Счетчик среднего значения, измеряющий время, которое он в среднем займет для завершения процесса или операции.An average counter that measures the time it takes, on average, to complete a process or operation. Счетчики этого типа отображают отношение всего прошедшего интервала измерения к числу процессов или операций, завершенных за это время.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. Этот тип счетчика измеряет время в тактах системных часов.This counter type measures time in ticks of the system clock. Счетчики этого типа включают "Физический диск\ Средний время обращения к диску".Counters of this type include PhysicalDisk\ Avg. Disk sec/Transfer.

CounterDelta32 CounterDelta32 CounterDelta32 CounterDelta32 4195328

Счетчик разницы, показывающий изменение в измеряемом атрибуте между двумя последними интервалами измерения.A difference counter that shows the change in the measured attribute between the two most recent sample intervals.

CounterDelta64 CounterDelta64 CounterDelta64 CounterDelta64 4195584

Счетчик разницы, показывающий изменение в измеряемом атрибуте между двумя последними интервалами измерения.A difference counter that shows the change in the measured attribute between the two most recent sample intervals. Он аналогичен типу счетчика CounterDelta32, за исключением того, что используются большие поля для размещения больших значений.It is the same as the CounterDelta32 counter type except that is uses larger fields to accommodate larger values.

CounterMultiBase CounterMultiBase CounterMultiBase CounterMultiBase 1107494144

Базовый счетчик, показывающий число измеренных элементов.A base counter that indicates the number of items sampled. Используется как знаменатель в вычислениях для получения среднего значения среди измеренных элементов при измерении времени нескольких, но однотипных элементов.It is used as the denominator in the calculations to get an average among the items sampled when taking timings of multiple, but similar items. Используется со счетчиками CounterMultiTimer, CounterMultiTimerInverse, CounterMultiTimer100Ns и CounterMultiTimer100NsInverse.Used with CounterMultiTimer, CounterMultiTimerInverse, CounterMultiTimer100Ns, and CounterMultiTimer100NsInverse.

CounterMultiTimer CounterMultiTimer CounterMultiTimer CounterMultiTimer 574686464

Счетчик процентов, отображающий процент отношения активности одного или более компонентов ко всему интервалу измерения.A percentage counter that displays the active time of one or more components as a percentage of the total time of the sample interval. Поскольку числитель записывает время активности работающих компонентов одновременно, результат может превышать 100%.Because the numerator records the active time of components operating simultaneously, the resulting percentage can exceed 100 percent. Этот тип счетчика отличается от CounterMultiTimer100Ns, в нем вычисляется время в тактах системного таймера производительности, а не в единицах измерения, равных 100 нс.This counter type differs from CounterMultiTimer100Ns in that it measures time in units of ticks of the system performance timer, rather than in 100 nanosecond units. Этот тип счетчика представляет собой мультитаймер.This counter type is a multitimer.

CounterMultiTimer100Ns CounterMultiTimer100Ns CounterMultiTimer100Ns CounterMultiTimer100Ns 575735040

Счетчик процентов, показывающий процент активного времени одного или более компонентов за весь интервал измерения.A percentage counter that shows the active time of one or more components as a percentage of the total time of the sample interval. Вычисляет время в единицах времени, равных 100 нс.It measures time in 100 nanosecond (ns) units. Этот тип счетчика представляет собой мультитаймер.This counter type is a multitimer.

CounterMultiTimer100NsInverse CounterMultiTimer100NsInverse CounterMultiTimer100NsInverse CounterMultiTimer100NsInverse 592512256

Счетчик процентов, показывающий процент активного времени одного или более компонентов за весь интервал измерения.A percentage counter that shows the active time of one or more components as a percentage of the total time of the sample interval. Счетчики этого типа вычисляют время в единицах времени, равных 100 нс.Counters of this type measure time in 100 nanosecond (ns) units. Они получают активное время путем измерения времени, в котором компоненты не были активны, и вычитая результат из 100 процентов, умноженных на число исследуемых объектов.They derive the active time by measuring the time that the components were not active and subtracting the result from multiplying 100 percent by the number of objects monitored. Этот тип счетчика представляет собой обратный мультитаймер.This counter type is an inverse multitimer.

CounterMultiTimerInverse CounterMultiTimerInverse CounterMultiTimerInverse CounterMultiTimerInverse 591463680

Счетчик процентов, показывающий процент активного времени одного или более компонентов за весь интервал измерения.A percentage counter that shows the active time of one or more components as a percentage of the total time of the sample interval. Он получает активное время путем измерения времени, в котором компоненты не были активны, и вычитая результат из 100 процентов, умноженных на число исследуемых объектов.It derives the active time by measuring the time that the components were not active and subtracting the result from 100 percent by the number of objects monitored. Этот тип счетчика представляет собой обратный мультитаймер.This counter type is an inverse multitimer. Он отличается от CounterMultiTimer100NsInverse тем, что в нем вычисляется время в тактах системного таймера производительности, а не в единицах измерения, равных 100 нс.It differs from CounterMultiTimer100NsInverse in that it measures time in units of ticks of the system performance timer, rather than in 100 nanosecond units.

CounterTimer CounterTimer CounterTimer CounterTimer 541132032

Счетчик процентов, показывающий среднее время как процент отношения времени активности компонента к полному времени измерения.A percentage counter that shows the average time that a component is active as a percentage of the total sample time.

CounterTimerInverse CounterTimerInverse CounterTimerInverse CounterTimerInverse 557909248

Счетчик процентов, который отображает средний процент наблюдавшегося активного времени за интервал измерения.A percentage counter that displays the average percentage of active time observed during sample interval. Значение этих счетчиков вычисляется за счет измерения процента времени, в течение которого служба была неактивна, и затем вычитанием этого значения из 100%.The value of these counters is calculated by monitoring the percentage of time that the service was inactive and then subtracting that value from 100 percent. Это обратный тип счетчика.This is an inverse counter type. Он отличается от CounterTimer100NsInv только тем, что в нем вычисляется время в тактах системного таймера производительности, а не в единицах измерения, равных 100 нс.It is the same as CounterTimer100NsInv, except that it measures time in units of ticks of the system performance timer rather than in 100 nanosecond units.

CountPerTimeInterval32 CountPerTimeInterval32 CountPerTimeInterval32 CountPerTimeInterval32 4523008

Счетчик среднего значения предназначен для исследования средней длины очереди к ресурсу за все время наблюдения.An average counter designed to monitor the average length of a queue to a resource over time. Он показывает разницу между длинами очередей, наблюдаемых в течение двух последних интервалов измерения, деленную на продолжительность интервала.It shows the difference between the queue lengths observed during the last two sample intervals divided by the duration of the interval. Этот тип счетчика обычно используется для хранения числа элементов, ожидающих очереди.This type of counter is typically used to track the number of items that are queued or waiting.

CountPerTimeInterval64 CountPerTimeInterval64 CountPerTimeInterval64 CountPerTimeInterval64 4523264

Счетчик среднего значения, наблюдающий среднюю длину очереди к ресурсу за все время наблюдения.An average counter that monitors the average length of a queue to a resource over time. Счетчики этого типа отображают разницу между длинами очередей, наблюдаемых в течение двух последних интервалов измерения, деленную на продолжительность интервала.Counters of this type display the difference between the queue lengths observed during the last two sample intervals, divided by the duration of the interval. Этот тип счетчика такой же, что и CountPerTimeInterval32, за тем исключением, что используются большие поля для размещения больших значений.This counter type is the same as CountPerTimeInterval32 except that it uses larger fields to accommodate larger values. Этот тип счетчика обычно используется для хранения очень большого числа элементов, ожидающих очереди.This type of counter is typically used to track a high-volume or very large number of items that are queued or waiting.

ElapsedTime ElapsedTime ElapsedTime ElapsedTime 807666944

Таймер разницы, который показывает полное время между началом работы компонента или процесса и вычислением значения.A difference timer that shows the total time between when the component or process started and the time when this value is calculated. Счетчики этого типа включают "Система\ Время работы системы".Counters of this type include System\ System Up Time.

NumberOfItems32 NumberOfItems32 NumberOfItems32 NumberOfItems32 65536

Счетчик мгновенного значения, показывающий последнее наблюдавшееся значение.An instantaneous counter that shows the most recently observed value. Используется, например, для хранения числа элементов или операций.Used, for example, to maintain a simple count of items or operations. Счетчики этого типа включают "Память\Доступно байт".Counters of this type include Memory\Available Bytes.

NumberOfItems64 NumberOfItems64 NumberOfItems64 NumberOfItems64 65792

Счетчик мгновенного значения, показывающий последнее наблюдавшееся значение.An instantaneous counter that shows the most recently observed value. Используется, например, для хранения очень большого числа элементов или операций.Used, for example, to maintain a simple count of a very large number of items or operations. Такой же, что и тип NumberOfItems32, за тем исключением, что используются большие поля для размещения больших значений.It is the same as NumberOfItems32 except that it uses larger fields to accommodate larger values.

NumberOfItemsHEX32 NumberOfItemsHEX32 NumberOfItemsHEX32 NumberOfItemsHEX32 0

Счетчик мгновенного значения, показывающий последнее наблюдавшееся значение в шестнадцатеричном формате.An instantaneous counter that shows the most recently observed value in hexadecimal format. Используется, например, для хранения числа элементов или операций.Used, for example, to maintain a simple count of items or operations.

NumberOfItemsHEX64 NumberOfItemsHEX64 NumberOfItemsHEX64 NumberOfItemsHEX64 256

Счетчик мгновенного значения, показывающий последнее наблюдавшееся значение.An instantaneous counter that shows the most recently observed value. Используется, например, для хранения очень большого числа элементов или операций.Used, for example, to maintain a simple count of a very large number of items or operations. Такой же, что и тип NumberOfItemsHEX32, за тем исключением, что используются большие поля для размещения больших значений.It is the same as NumberOfItemsHEX32 except that it uses larger fields to accommodate larger values.

RateOfCountsPerSecond32 RateOfCountsPerSecond32 RateOfCountsPerSecond32 RateOfCountsPerSecond32 272696320

Счетчик разницы, показывающий среднее число операций, завершенных в течение каждой секунды интервала измерения.A difference counter that shows the average number of operations completed during each second of the sample interval. Счетчики этого типа измеряют время в тактах системных часов.Counters of this type measure time in ticks of the system clock. Счетчики этого типа включают "Система\ Операций чтения файлов/с".Counters of this type include System\ File Read Operations/sec.

RateOfCountsPerSecond64 RateOfCountsPerSecond64 RateOfCountsPerSecond64 RateOfCountsPerSecond64 272696576

Счетчик разницы, показывающий среднее число операций, завершенных в течение каждой секунды интервала измерения.A difference counter that shows the average number of operations completed during each second of the sample interval. Счетчики этого типа измеряют время в тактах системных часов.Counters of this type measure time in ticks of the system clock. Этот тип счетчика такой же, что и тип RateOfCountsPerSecond32, но использует большие поля для размещения больших значений для хранения очень большого числа элементов или операций в секунду, например частоты передачи байтов.This counter type is the same as the RateOfCountsPerSecond32 type, but it uses larger fields to accommodate larger values to track a high-volume number of items or operations per second, such as a byte-transmission rate. Счетчики этого типа включают "Система\ Байт чтения файлов/с".Counters of this type include System\ File Read Bytes/sec.

RawBase RawBase RawBase RawBase 1073939459

Базовый счетчик, который хранит знаменатель счетчика, представляющего обычную арифметическую дробь.A base counter that stores the denominator of a counter that presents a general arithmetic fraction. Следует проверить, что это значение больше нуля до использования его в качестве знаменателя при расчете значения RawFraction.Check that this value is greater than zero before using it as the denominator in a RawFraction value calculation.

RawFraction RawFraction RawFraction RawFraction 537003008

Счетчик мгновенного значения в процентах, показывающий отношение подмножества к множеству в процентах.An instantaneous percentage counter that shows the ratio of a subset to its set as a percentage. Например, он позволяет сравнить число байтов, используемых на диске, и общее число байтов на этом диске.For example, it compares the number of bytes in use on a disk to the total number of bytes on the disk. Счетчики этого типа отображают только текущий процент, а не среднее значение за все время.Counters of this type display the current percentage only, not an average over time. Счетчики этого типа включают "Файл подкачки\% использования (пик)".Counters of this type include Paging File\% Usage Peak.

SampleBase SampleBase SampleBase SampleBase 1073939457

Базовый счетчик, который хранит число взятых выборочных прерываний и используется в качестве знаменателя дроби.A base counter that stores the number of sampling interrupts taken and is used as a denominator in the sampling fraction. Выборочная доля представляет собой число измерений, равных 1 (или true), для выборочного прерывания.The sampling fraction is the number of samples that were 1 (or true) for a sample interrupt. Следует проверить, что это значение больше нуля до использования его в качестве знаменателя при расчете значения SampleFraction.Check that this value is greater than zero before using it as the denominator in a calculation of SampleFraction.

SampleCounter SampleCounter SampleCounter SampleCounter 4260864

Счетчик среднего значения, который показывает среднее число операций, завершенных за одну секунду.An average counter that shows the average number of operations completed in one second. Когда счетчик этого типа измеряет данные, каждое выборочное прерывание возвращает единицу или ноль.When a counter of this type samples the data, each sampling interrupt returns one or zero. Данными счетчика является число измеренных единиц.The counter data is the number of ones that were sampled. Он измеряет время в тактах системного таймера производительности.It measures time in units of ticks of the system performance timer.

SampleFraction SampleFraction SampleFraction SampleFraction 549585920

Счетчик процентов, показывающий среднее отношение обращений ко всем операциям за последние два интервала измерения.A percentage counter that shows the average ratio of hits to all operations during the last two sample intervals. Счетчики этого типа включают "Кэш\ % попаданий фиксации при чтении".Counters of this type include Cache\Pin Read Hits %.

Timer100Ns Timer100Ns Timer100Ns Timer100Ns 542180608

Счетчик процентов, показывающий процент активного времени компонента за все прошедшее время интервала измерения.A percentage counter that shows the active time of a component as a percentage of the total elapsed time of the sample interval. Вычисляет время в единицах времени, равных 100 нс.It measures time in units of 100 nanoseconds (ns). Счетчики этого типа предназначены для измерения активности компонента в течение какого-либо времени.Counters of this type are designed to measure the activity of one component at a time. Счетчики этого типа включают "Процессор\ % работы в пользовательском режиме".Counters of this type include Processor\ % User Time.

Timer100NsInverse Timer100NsInverse Timer100NsInverse Timer100NsInverse 558957824

Счетчик процентов, который показывает средний процент наблюдавшегося активного времени за интервал измерения.A percentage counter that shows the average percentage of active time observed during the sample interval. Это обратный счетчик.This is an inverse counter. Счетчики этого типа включают "Процессор\ % загруженности процессора".Counters of this type include Processor\ % Processor Time.

Примеры

В следующих примерах демонстрируется несколько типов счетчиков в PerformanceCounterType перечислении.The following examples demonstrate several of the counter types in the PerformanceCounterType enumeration.

AverageCount64

#using <System.dll>

using namespace System;
using namespace System::Collections;
using namespace System::Collections::Specialized;
using namespace System::Diagnostics;

// Output information about the counter sample.
void OutputSample( CounterSample s )
{
   Console::WriteLine( "\r\n+++++++++++" );
   Console::WriteLine( "Sample values - \r\n" );
   Console::WriteLine( "   BaseValue        = {0}", s.BaseValue );
   Console::WriteLine( "   CounterFrequency = {0}", s.CounterFrequency );
   Console::WriteLine( "   CounterTimeStamp = {0}", s.CounterTimeStamp );
   Console::WriteLine( "   CounterType      = {0}", s.CounterType );
   Console::WriteLine( "   RawValue         = {0}", s.RawValue );
   Console::WriteLine( "   SystemFrequency  = {0}", s.SystemFrequency );
   Console::WriteLine( "   TimeStamp        = {0}", s.TimeStamp );
   Console::WriteLine( "   TimeStamp100nSec = {0}", s.TimeStamp100nSec );
   Console::WriteLine( "++++++++++++++++++++++" );
}

//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
//    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 
//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
float MyComputeCounterValue( CounterSample s0, CounterSample s1 )
{
   float numerator = (float)s1.RawValue - (float)s0.RawValue;
   float denomenator = (float)s1.BaseValue - (float)s0.BaseValue;
   float counterValue = numerator / denomenator;
   return counterValue;
}

bool SetupCategory()
{
   if (  !PerformanceCounterCategory::Exists( "AverageCounter64SampleCategory" ) )
   {
      CounterCreationDataCollection^ CCDC = gcnew CounterCreationDataCollection;
      
      // Add the counter.
      CounterCreationData^ averageCount64 = gcnew CounterCreationData;
      averageCount64->CounterType = PerformanceCounterType::AverageCount64;
      averageCount64->CounterName = "AverageCounter64Sample";
      CCDC->Add( averageCount64 );
      
      // Add the base counter.
      CounterCreationData^ averageCount64Base = gcnew CounterCreationData;
      averageCount64Base->CounterType = PerformanceCounterType::AverageBase;
      averageCount64Base->CounterName = "AverageCounter64SampleBase";
      CCDC->Add( averageCount64Base );
      
      // Create the category.
      PerformanceCounterCategory::Create( "AverageCounter64SampleCategory", "Demonstrates usage of the AverageCounter64 performance counter type.", CCDC );
      return (true);
   }
   else
   {
      Console::WriteLine( "Category exists - AverageCounter64SampleCategory" );
      return (false);
   }
}

void CreateCounters( PerformanceCounter^% PC, PerformanceCounter^% BPC )
{
   
   // Create the counters.
   PC = gcnew PerformanceCounter( "AverageCounter64SampleCategory","AverageCounter64Sample",false );

   BPC = gcnew PerformanceCounter( "AverageCounter64SampleCategory","AverageCounter64SampleBase",false );
   PC->RawValue = 0;
   BPC->RawValue = 0;
}
void CollectSamples( ArrayList^ samplesList, PerformanceCounter^ PC, PerformanceCounter^ BPC )
{
   Random^ r = gcnew Random( DateTime::Now.Millisecond );

   // Loop for the samples.
   for ( int j = 0; j < 100; j++ )
   {
      int value = r->Next( 1, 10 );
      Console::Write( "{0} = {1}", j, value );
      PC->IncrementBy( value );
      BPC->Increment();
      if ( (j % 10) == 9 )
      {
         OutputSample( PC->NextSample() );
         samplesList->Add( PC->NextSample() );
      }
      else
            Console::WriteLine();
      System::Threading::Thread::Sleep( 50 );
   }
}

void CalculateResults( ArrayList^ samplesList )
{
   for ( int i = 0; i < (samplesList->Count - 1); i++ )
   {
      // Output the sample.
      OutputSample(  *safe_cast<CounterSample^>(samplesList[ i ]) );
      OutputSample(  *safe_cast<CounterSample^>(samplesList[ i + 1 ]) );
      
      // Use .NET to calculate the counter value.
      Console::WriteLine( ".NET computed counter value = {0}", CounterSampleCalculator::ComputeCounterValue(  *safe_cast<CounterSample^>(samplesList[ i ]),  *safe_cast<CounterSample^>(samplesList[ i + 1 ]) ) );
      
      // Calculate the counter value manually.
      Console::WriteLine( "My computed counter value = {0}", MyComputeCounterValue(  *safe_cast<CounterSample^>(samplesList[ i ]),  *safe_cast<CounterSample^>(samplesList[ i + 1 ]) ) );
   }
}

int main()
{
   ArrayList^ samplesList = gcnew ArrayList;
   PerformanceCounter^ PC;
   PerformanceCounter^ BPC;
   SetupCategory();
   CreateCounters( PC, BPC );
   CollectSamples( samplesList, PC, BPC );
   CalculateResults( samplesList );
}

using System;
using System.Collections;
using System.Collections.Specialized;
using System.Diagnostics;

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

 _

Public Class App

    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 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("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.dll>

using namespace System;
using namespace System::Collections;
using namespace System::Collections::Specialized;
using namespace System::Diagnostics;
using namespace System::Runtime::InteropServices;

//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//+++++++
// 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 
//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//+++++++
float MyComputeCounterValue( CounterSample s0, CounterSample s1 )
{
    __int64 n1 = s1.RawValue;
    __int64 n0 = s0.RawValue;
    unsigned __int64 f = s1.SystemFrequency;
    __int64 d1 = s1.BaseValue;
    __int64 d0 = s0.BaseValue;
    double numerator = (double)(n1 - n0);
    double denominator = (double)(d1 - d0);
    float counterValue = (float)((numerator / f) / denominator);
    return counterValue;
}

// Output information about the counter sample.
void OutputSample( CounterSample s )
{
    Console::WriteLine( "+++++++++++" );
    Console::WriteLine( "Sample values - \r\n" );
    Console::WriteLine( "   CounterType      = {0}", s.CounterType );
    Console::WriteLine( "   RawValue         = {0}", s.RawValue.ToString() );
    Console::WriteLine( "   BaseValue        = {0}", s.BaseValue.ToString() );
    Console::WriteLine( "   CounterFrequency = {0}", s.CounterFrequency.ToString() );
    Console::WriteLine( "   CounterTimeStamp = {0}", s.CounterTimeStamp.ToString() );
    Console::WriteLine( "   SystemFrequency  = {0}", s.SystemFrequency.ToString() );
    Console::WriteLine( "   TimeStamp        = {0}", s.TimeStamp.ToString() );
    Console::WriteLine( "   TimeStamp100nSec = {0}", s.TimeStamp100nSec.ToString() );
    Console::WriteLine( "++++++++++++++++++++++" );
}

bool SetupCategory()
{
    if (  !PerformanceCounterCategory::Exists( "AverageTimer32SampleCategory") )
       {
        CounterCreationDataCollection^ CCDC = gcnew CounterCreationDataCollection;

        // Add the counter.
        CounterCreationData^ averageTimer32 = gcnew CounterCreationData;
        averageTimer32->CounterType = PerformanceCounterType::AverageTimer32;
        averageTimer32->CounterName = "AverageTimer32Sample";
        CCDC->Add( averageTimer32 );

        // Add the base counter.
        CounterCreationData^ averageTimer32Base = gcnew CounterCreationData;
        averageTimer32Base->CounterType = PerformanceCounterType::AverageBase;
        averageTimer32Base->CounterName = "AverageTimer32SampleBase";
        CCDC->Add( averageTimer32Base );

        // Create the category.
        PerformanceCounterCategory::Create( "AverageTimer32SampleCategory", 
            "Demonstrates usage of the AverageTimer32 performance counter type", 
            PerformanceCounterCategoryType::SingleInstance, CCDC );
        Console::WriteLine( "Category created - AverageTimer32SampleCategory" );
        return (true);
        }

    Console::WriteLine( "Category exists - AverageTimer32SampleCategory" );
    return (false);
}

void CreateCounters( PerformanceCounter^% PC, PerformanceCounter^% BPC )
{
    // Create the counters.
    PC = gcnew PerformanceCounter( "AverageTimer32SampleCategory","AverageTimer32Sample",false );
    BPC = gcnew PerformanceCounter( "AverageTimer32SampleCategory","AverageTimer32SampleBase",false );
    PC->RawValue = 0;
    BPC->RawValue = 0;
}

void CollectSamples( ArrayList^ samplesList, PerformanceCounter^ PC, 
PerformanceCounter^ BPC )
{
    __int64 perfTime = 0;
    Random^ r = gcnew 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 = {0}", PC->NextValue().ToString() );
        samplesList->Add( PC->NextSample() );
        }
}

void CalculateResults( ArrayList^ samplesList )
{
    for ( int i = 0; i < (samplesList->Count - 1); i++ )
        {
        // Output the sample.
        OutputSample(  *safe_cast<CounterSample^>(samplesList[ i ]) );
        OutputSample(  *safe_cast<CounterSample^>(samplesList[ i + 1 ]) );

        // Use .NET to calculate the counter value.
        Console::WriteLine( ".NET computed counter value = {0}",
           CounterSample::Calculate(  *safe_cast<CounterSample^>(samplesList[ i ]),
           *safe_cast<CounterSample^>(samplesList[ i + 1 ]) ) );

        // Calculate the counter value manually.
        Console::WriteLine( "My computed counter value = {0}", 
            MyComputeCounterValue(  *safe_cast<CounterSample^>(samplesList[ i ]),
           *safe_cast<CounterSample^>(samplesList[ i + 1 ]) ) );
        }
}

int main()
{
    ArrayList^ samplesList = gcnew ArrayList;
    PerformanceCounter^ PC;
    PerformanceCounter^ BPC;
    SetupCategory();
    CreateCounters( PC, BPC );
    CollectSamples( samplesList, PC, BPC );
    CalculateResults( samplesList );

    Console::WriteLine("\n\nHit ENTER to return");
    Console::ReadLine();
}

using System;
using System.Collections;
using System.Collections.Specialized;
using System.Diagnostics;
using System.Runtime.InteropServices;

public class App
{

    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
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.dll>

using namespace System;
using namespace System::Collections;
using namespace System::Collections::Specialized;
using namespace System::Diagnostics;
using namespace System::Runtime::InteropServices;

void OutputSample( CounterSample s )
{
   Console::WriteLine( "\r\n+++++++++++" );
   Console::WriteLine( "Sample values - \r\n" );
   Console::WriteLine( "   BaseValue        = {0}", s.BaseValue );
   Console::WriteLine( "   CounterFrequency = {0}", s.CounterFrequency );
   Console::WriteLine( "   CounterTimeStamp = {0}", s.CounterTimeStamp );
   Console::WriteLine( "   CounterType      = {0}", s.CounterType );
   Console::WriteLine( "   RawValue         = {0}", s.RawValue );
   Console::WriteLine( "   SystemFrequency  = {0}", s.SystemFrequency );
   Console::WriteLine( "   TimeStamp        = {0}", s.TimeStamp );
   Console::WriteLine( "   TimeStamp100nSec = {0}", s.TimeStamp100nSec );
   Console::WriteLine( "++++++++++++++++++++++" );
}

void CollectSamples()
{
   String^ categoryName = "ElapsedTimeSampleCategory";
   String^ counterName = "ElapsedTimeSample";
   
   // Create the performance counter category.
   if (  !PerformanceCounterCategory::Exists( categoryName ) )
   {
      CounterCreationDataCollection^ CCDC = gcnew CounterCreationDataCollection;
      
      // Add the counter.
      CounterCreationData^ ETimeData = gcnew CounterCreationData;
      ETimeData->CounterType = PerformanceCounterType::ElapsedTime;
      ETimeData->CounterName = counterName;
      CCDC->Add( ETimeData );
      
      // Create the category.
      PerformanceCounterCategory::Create( categoryName,
         "Demonstrates ElapsedTime performance counter usage.",
         CCDC );
   }
   else
   {
      Console::WriteLine( "Category exists - {0}", categoryName );
   }

   
   // Create the performance counter.
   PerformanceCounter^ PC = gcnew 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() = {0}", PC->NextValue() );
         Console::WriteLine( "Actual elapsed time = {0}", DateTime::Now.Subtract( Start ) );
         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 = {0}", DateTime::Now.Subtract( Start ) );
}

int main()
{
   CollectSamples();
}

using System;
using System.Collections;
using System.Collections.Specialized;
using System.Diagnostics;
using System.Runtime.InteropServices;

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

Public Class App

    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.dll>

using namespace System;
using namespace System::Collections;
using namespace System::Collections::Specialized;
using namespace System::Diagnostics;
float MyComputeCounterValue( CounterSample s0, CounterSample s1 )
{
   float counterValue = (float)s1.RawValue;
   return counterValue;
}

// Output information about the counter sample.
void OutputSample( CounterSample s )
{
   Console::WriteLine( "\r\n+++++++++++" );
   Console::WriteLine( "Sample values - \r\n" );
   Console::WriteLine( "   BaseValue        = {0}", s.BaseValue );
   Console::WriteLine( "   CounterFrequency = {0}", s.CounterFrequency );
   Console::WriteLine( "   CounterTimeStamp = {0}", s.CounterTimeStamp );
   Console::WriteLine( "   CounterType      = {0}", s.CounterType );
   Console::WriteLine( "   RawValue         = {0}", s.RawValue );
   Console::WriteLine( "   SystemFrequency  = {0}", s.SystemFrequency );
   Console::WriteLine( "   TimeStamp        = {0}", s.TimeStamp );
   Console::WriteLine( "   TimeStamp100nSec = {0}", s.TimeStamp100nSec );
   Console::WriteLine( "++++++++++++++++++++++" );
}

bool SetupCategory()
{
   if (  !PerformanceCounterCategory::Exists( "NumberOfItems32SampleCategory" ) )
   {
      CounterCreationDataCollection^ CCDC = gcnew CounterCreationDataCollection;

      // Add the counter.
      CounterCreationData^ NOI64 = gcnew 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.", CCDC );
      return true;
   }
   else
   {
      Console::WriteLine( "Category exists - NumberOfItems32SampleCategory" );
      return false;
   }
}

void CreateCounters( PerformanceCounter^% PC )
{
   // Create the counter.
   PC = gcnew PerformanceCounter( "NumberOfItems32SampleCategory","NumberOfItems32Sample",false );
   PC->RawValue = 0;
}

void CollectSamples( ArrayList^ samplesList, PerformanceCounter^ PC )
{
   Random^ r = gcnew Random( DateTime::Now.Millisecond );

   // Loop for the samples.
   for ( int j = 0; j < 100; j++ )
   {
      int value = r->Next( 1, 10 );
      Console::Write( "{0} = {1}", j, value );
      PC->IncrementBy( value );
      if ( (j % 10) == 9 )
      {
         OutputSample( PC->NextSample() );
         samplesList->Add( PC->NextSample() );
      }
      else
            Console::WriteLine();
      System::Threading::Thread::Sleep( 50 );

   }
}

void CalculateResults( ArrayList^ samplesList )
{
   for ( int i = 0; i < (samplesList->Count - 1); i++ )
   {
      // Output the sample.
      OutputSample(  *safe_cast<CounterSample^>(samplesList[ i ]) );
      OutputSample(  *safe_cast<CounterSample^>(samplesList[ i + 1 ]) );

      // Use .NET to calculate the counter value.
      Console::WriteLine( ".NET computed counter value = {0}", CounterSampleCalculator::ComputeCounterValue(  *safe_cast<CounterSample^>(samplesList[ i ]),  *safe_cast<CounterSample^>(samplesList[ i + 1 ]) ) );

      // Calculate the counter value manually.
      Console::WriteLine( "My computed counter value = {0}", MyComputeCounterValue(  *safe_cast<CounterSample^>(samplesList[ i ]),  *safe_cast<CounterSample^>(samplesList[ i + 1 ]) ) );
   }
}

void main()
{
   ArrayList^ samplesList = gcnew ArrayList;
   PerformanceCounter^ PC;
   SetupCategory();
   CreateCounters( PC );
   CollectSamples( samplesList, PC );
   CalculateResults( samplesList );
}
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

 _

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.dll>

using namespace System;
using namespace System::Collections;
using namespace System::Collections::Specialized;
using namespace System::Diagnostics;
float MyComputeCounterValue( CounterSample s0, CounterSample s1 )
{
   float counterValue = (float)s1.RawValue;
   return counterValue;
}


// Output information about the counter sample.
void OutputSample( CounterSample s )
{
   Console::WriteLine( "\r\n+++++++++++" );
   Console::WriteLine( "Sample values - \r\n" );
   Console::WriteLine( "   BaseValue        = {0}", s.BaseValue );
   Console::WriteLine( "   CounterFrequency = {0}", s.CounterFrequency );
   Console::WriteLine( "   CounterTimeStamp = {0}", s.CounterTimeStamp );
   Console::WriteLine( "   CounterType      = {0}", s.CounterType );
   Console::WriteLine( "   RawValue         = {0}", s.RawValue );
   Console::WriteLine( "   SystemFrequency  = {0}", s.SystemFrequency );
   Console::WriteLine( "   TimeStamp        = {0}", s.TimeStamp );
   Console::WriteLine( "   TimeStamp100nSec = {0}", s.TimeStamp100nSec );
   Console::WriteLine( "++++++++++++++++++++++" );
}

bool SetupCategory()
{
   if (  !PerformanceCounterCategory::Exists( "NumberOfItems64SampleCategory" ) )
   {
      CounterCreationDataCollection^ CCDC = gcnew CounterCreationDataCollection;

      // Add the counter.
      CounterCreationData^ NOI64 = gcnew 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.", CCDC );
      return true;
   }
   else
   {
      Console::WriteLine( "Category exists - NumberOfItems64SampleCategory" );
      return false;
   }
}

void CreateCounters( PerformanceCounter^% PC )
{
   // Create the counters.
   PC = gcnew PerformanceCounter( "NumberOfItems64SampleCategory","NumberOfItems64Sample",false );
   PC->RawValue = 0;
}

void CollectSamples( ArrayList^ samplesList, PerformanceCounter^ PC )
{
   Random^ r = gcnew Random( DateTime::Now.Millisecond );

   // Loop for the samples.
   for ( int j = 0; j < 100; j++ )
   {
      int value = r->Next( 1, 10 );
      Console::Write( "{0} = {1}", j, value );
      PC->IncrementBy( value );
      if ( (j % 10) == 9 )
      {
         OutputSample( PC->NextSample() );
         samplesList->Add( PC->NextSample() );
      }
      else
            Console::WriteLine();
      System::Threading::Thread::Sleep( 50 );
   }
}

void CalculateResults( ArrayList^ samplesList )
{
   for ( int i = 0; i < (samplesList->Count - 1); i++ )
   {
      // Output the sample.
      OutputSample(  *safe_cast<CounterSample^>(samplesList[ i ]) );
      OutputSample(  *safe_cast<CounterSample^>(samplesList[ i + 1 ]) );

      // Use .NET to calculate the counter value.
      Console::WriteLine( ".NET computed counter value = {0}", CounterSampleCalculator::ComputeCounterValue(  *safe_cast<CounterSample^>(samplesList[ i ]),  *safe_cast<CounterSample^>(samplesList[ i + 1 ]) ) );

      // Calculate the counter value manually.
      Console::WriteLine( "My computed counter value = {0}", MyComputeCounterValue(  *safe_cast<CounterSample^>(samplesList[ i ]),  *safe_cast<CounterSample^>(samplesList[ i + 1 ]) ) );
   }
}

int main()
{
   ArrayList^ samplesList = gcnew ArrayList;
   PerformanceCounter^ PC;
   SetupCategory();
   CreateCounters( PC );
   CollectSamples( samplesList, PC );
   CalculateResults( samplesList );
}
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.
        // 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

 _

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("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 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


' 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 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.dll>

using namespace System;
using namespace System::Collections;
using namespace System::Collections::Specialized;
using namespace System::Diagnostics;

//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
//    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 
//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
float MyComputeCounterValue( CounterSample s0, CounterSample s1 )
{
   float numerator = (float)(s1.RawValue - s0.RawValue);
   float denomenator = (float)(s1.TimeStamp - s0.TimeStamp) / (float)s1.SystemFrequency;
   float counterValue = numerator / denomenator;
   return counterValue;
}


// Output information about the counter sample.
void OutputSample( CounterSample s )
{
   Console::WriteLine( "\r\n+++++++++++" );
   Console::WriteLine( "Sample values - \r\n" );
   Console::WriteLine( "   BaseValue        = {0}", s.BaseValue );
   Console::WriteLine( "   CounterFrequency = {0}", s.CounterFrequency );
   Console::WriteLine( "   CounterTimeStamp = {0}", s.CounterTimeStamp );
   Console::WriteLine( "   CounterType      = {0}", s.CounterType );
   Console::WriteLine( "   RawValue         = {0}", s.RawValue );
   Console::WriteLine( "   SystemFrequency  = {0}", s.SystemFrequency );
   Console::WriteLine( "   TimeStamp        = {0}", s.TimeStamp );
   Console::WriteLine( "   TimeStamp100nSec = {0}", s.TimeStamp100nSec );
   Console::WriteLine( "++++++++++++++++++++++" );
}

bool SetupCategory()
{
   if (  !PerformanceCounterCategory::Exists( "RateOfCountsPerSecond32SampleCategory" ) )
   {
      CounterCreationDataCollection^ CCDC = gcnew CounterCreationDataCollection;

      // Add the counter.
      CounterCreationData^ rateOfCounts32 = gcnew 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.", CCDC );
      return true;
   }
   else
   {
      Console::WriteLine( "Category exists - RateOfCountsPerSecond32SampleCategory" );
      return false;
   }
}

void CreateCounters( PerformanceCounter^% PC )
{
   // Create the counter.
   PC = gcnew PerformanceCounter( "RateOfCountsPerSecond32SampleCategory","RateOfCountsPerSecond32Sample",false );
   PC->RawValue = 0;
}

void CollectSamples( ArrayList^ samplesList, PerformanceCounter^ PC )
{
   Random^ r = gcnew 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( "{0} = {1}", j, value );
      if ( (j % 10) == 9 )
      {
         Console::WriteLine( ";       NextValue() = {0}", PC->NextValue() );
         OutputSample( PC->NextSample() );
         samplesList->Add( PC->NextSample() );
      }
      else
            Console::WriteLine();
      System::Threading::Thread::Sleep( 50 );
   }
}

void CalculateResults( ArrayList^ samplesList )
{
   for ( int i = 0; i < (samplesList->Count - 1); i++ )
   {
      // Output the sample.
      OutputSample(  *safe_cast<CounterSample^>(samplesList[ i ]) );
      OutputSample(  *safe_cast<CounterSample^>(samplesList[ i + 1 ]) );

      // Use .NET to calculate the counter value.
      Console::WriteLine( ".NET computed counter value = {0}", CounterSampleCalculator::ComputeCounterValue(  *safe_cast<CounterSample^>(samplesList[ i ]),  *safe_cast<CounterSample^>(samplesList[ i + 1 ]) ) );

      // Calculate the counter value manually.
      Console::WriteLine( "My computed counter value = {0}", MyComputeCounterValue(  *safe_cast<CounterSample^>(samplesList[ i ]),  *safe_cast<CounterSample^>(samplesList[ i + 1 ]) ) );
   }
}

int main()
{
   ArrayList^ samplesList = gcnew ArrayList;
   PerformanceCounter^ PC;
   SetupCategory();
   CreateCounters( PC );
   CollectSamples( samplesList, PC );
   CalculateResults( samplesList );
}
using System;
using System.Collections;
using System.Collections.Specialized;
using System.Diagnostics;

public class App 
{
    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

 _

Public Class App
    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("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.dll>

using namespace System;
using namespace System::Collections;
using namespace System::Collections::Specialized;
using namespace System::Diagnostics;

//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
//    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 
//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
float MyComputeCounterValue( CounterSample s0, CounterSample s1 )
{
   float numerator = (float)(s1.RawValue - s0.RawValue);
   float denomenator = (float)(s1.TimeStamp - s0.TimeStamp) / (float)s1.SystemFrequency;
   float counterValue = numerator / denomenator;
   return counterValue;
}

void OutputSample( CounterSample s )
{
   Console::WriteLine( "\r\n+++++++++++" );
   Console::WriteLine( "Sample values - \r\n" );
   Console::WriteLine( "   BaseValue        = {0}", s.BaseValue );
   Console::WriteLine( "   CounterFrequency = {0}", s.CounterFrequency );
   Console::WriteLine( "   CounterTimeStamp = {0}", s.CounterTimeStamp );
   Console::WriteLine( "   CounterType      = {0}", s.CounterType );
   Console::WriteLine( "   RawValue         = {0}", s.RawValue );
   Console::WriteLine( "   SystemFrequency  = {0}", s.SystemFrequency );
   Console::WriteLine( "   TimeStamp        = {0}", s.TimeStamp );
   Console::WriteLine( "   TimeStamp100nSec = {0}", s.TimeStamp100nSec );
   Console::WriteLine( "++++++++++++++++++++++" );
}

bool SetupCategory()
{
   if (  !PerformanceCounterCategory::Exists( "RateOfCountsPerSecond64SampleCategory" ) )
   {
      CounterCreationDataCollection^ CCDC = gcnew CounterCreationDataCollection;

      // Add the counter.
      CounterCreationData^ rateOfCounts64 = gcnew 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.", CCDC );
      return true;
   }
   else
   {
      Console::WriteLine( "Category exists - RateOfCountsPerSecond64SampleCategory" );
      return false;
   }
}

void CreateCounters( PerformanceCounter^% PC )
{
   // Create the counter.
   PC = gcnew PerformanceCounter( "RateOfCountsPerSecond64SampleCategory","RateOfCountsPerSecond64Sample",false );
   PC->RawValue = 0;
}

void CollectSamples( ArrayList^ samplesList, PerformanceCounter^ PC )
{
   Random^ r = gcnew 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( "{0} = {1}", j, value );
      if ( (j % 10) == 9 )
      {
         Console::WriteLine( ";       NextValue() = {0}", PC->NextValue() );
         OutputSample( PC->NextSample() );
         samplesList->Add( PC->NextSample() );
      }
      else
            Console::WriteLine();
      System::Threading::Thread::Sleep( 50 );
   }
}

void CalculateResults( ArrayList^ samplesList )
{
   for ( int i = 0; i < (samplesList->Count - 1); i++ )
   {
      // Output the sample.
      OutputSample(  *safe_cast<CounterSample^>(samplesList[ i ]) );
      OutputSample(  *safe_cast<CounterSample^>(samplesList[ i + 1 ]) );

      // Use .NET to calculate the counter value.
      Console::WriteLine( ".NET computed counter value = {0}", CounterSampleCalculator::ComputeCounterValue(  *safe_cast<CounterSample^>(samplesList[ i ]),  *safe_cast<CounterSample^>(samplesList[ i + 1 ]) ) );

      // Calculate the counter value manually.
      Console::WriteLine( "My computed counter value = {0}", MyComputeCounterValue(  *safe_cast<CounterSample^>(samplesList[ i ]),  *safe_cast<CounterSample^>(samplesList[ i + 1 ]) ) );
   }
}

int main()
{
   ArrayList^ samplesList = gcnew ArrayList;
   PerformanceCounter^ PC;
   SetupCategory();
   CreateCounters( PC );
   CollectSamples( samplesList, PC );
   CalculateResults( samplesList );
}
using System;
using System.Collections;
using System.Collections.Specialized;
using System.Diagnostics;

public class App
{
    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

 _

Public Class App
    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("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.dll>

using namespace System;
using namespace System::Collections;
using namespace System::Collections::Specialized;
using namespace System::Diagnostics;

//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
// 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
//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++//++++++++
float MyComputeCounterValue( CounterSample rfSample )
{
   float numerator = (float)rfSample.RawValue;
   float denomenator = (float)rfSample.BaseValue;
   float counterValue = (numerator / denomenator) * 100;
   return counterValue;
}


// Output information about the counter sample.
void OutputSample( CounterSample s )
{
   Console::WriteLine( "+++++++++++" );
   Console::WriteLine( "Sample values - \r\n" );
   Console::WriteLine( "   BaseValue        = {0}", s.BaseValue );
   Console::WriteLine( "   CounterFrequency = {0}", s.CounterFrequency );
   Console::WriteLine( "   CounterTimeStamp = {0}", s.CounterTimeStamp );
   Console::WriteLine( "   CounterType      = {0}", s.CounterType );
   Console::WriteLine( "   RawValue         = {0}", s.RawValue );
   Console::WriteLine( "   SystemFrequency  = {0}", s.SystemFrequency );
   Console::WriteLine( "   TimeStamp        = {0}", s.TimeStamp );
   Console::WriteLine( "   TimeStamp100nSec = {0}", s.TimeStamp100nSec );
   Console::WriteLine( "++++++++++++++++++++++" );
}

bool SetupCategory()
{
   if (  !PerformanceCounterCategory::Exists( "RawFractionSampleCategory" ) )
   {
      CounterCreationDataCollection^ CCDC = gcnew CounterCreationDataCollection;
      
      // Add the counter.
      CounterCreationData^ rf = gcnew CounterCreationData;
      rf->CounterType = PerformanceCounterType::RawFraction;
      rf->CounterName = "RawFractionSample";
      CCDC->Add( rf );
      
      // Add the base counter.
      CounterCreationData^ rfBase = gcnew 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.", CCDC );
      return true;
   }
   else
   {
      Console::WriteLine( "Category exists - RawFractionSampleCategory" );
      return false;
   }
}

void CreateCounters( PerformanceCounter^% PC, PerformanceCounter^% BPC )
{
   
   // Create the counters.
   PC = gcnew PerformanceCounter( "RawFractionSampleCategory","RawFractionSample",false );
   BPC = gcnew PerformanceCounter( "RawFractionSampleCategory","RawFractionSampleBase",false );
   PC->RawValue = 0;
   BPC->RawValue = 0;
}

void CollectSamples( ArrayList^ samplesList, PerformanceCounter^ PC, PerformanceCounter^ BPC )
{
   Random^ r = gcnew 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( "{0} = {1}", 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() = {0}", PC->NextValue() );
         OutputSample( PC->NextSample() );
         samplesList->Add( PC->NextSample() );
      }
      else
            Console::WriteLine();
      System::Threading::Thread::Sleep( 50 );

   }
}

void CalculateResults( ArrayList^ samplesList )
{
   for ( int i = 0; i < samplesList->Count; i++ )
   {
      
      // Output the sample.
      OutputSample(  *safe_cast<CounterSample^>(samplesList[ i ]) );
      
      // Use .NET to calculate the counter value.
      Console::WriteLine( ".NET computed counter value = {0}", CounterSampleCalculator::ComputeCounterValue(  *safe_cast<CounterSample^>(samplesList[ i ]) ) );
      
      // Calculate the counter value manually.
      Console::WriteLine( "My computed counter value = {0}", MyComputeCounterValue(  *safe_cast<CounterSample^>(samplesList[ i ]) ) );

   }
}

int main()
{
   ArrayList^ samplesList = gcnew ArrayList;
   PerformanceCounter^ PC;
   PerformanceCounter^ BPC;
   SetupCategory();
   CreateCounters( PC, BPC );
   CollectSamples( samplesList, PC, BPC );
   CalculateResults( samplesList );
}

using System;
using System.Collections;
using System.Collections.Specialized;
using System.Diagnostics;


public class App
{
    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

 _


Public Class App
    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 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("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



Комментарии

Некоторые типы счетчиков представляют необработанные данные, а другие представляют вычисляемые значения, основанные на одном или нескольких примерах счетчиков.Some counter types represent raw data, while others represent calculated values that are based on one or more counter samples. Следующие категории классифицируют доступные типы счетчиков.The following categories classify the types of counters available.

  • Среднее значение: Измеряет значение с течением времени и отображает среднее для двух последних измерений.Average: Measures a value over time and displays the average of the last two measurements. Счетчик, связанный с каждым средним, является базовым счетчиком, отслеживающим количество участвующих выборок.Associated with each average counter is a base counter that tracks the number of samples involved.

  • Разница: Вычитает Последнее измерение из предыдущего и отображает разницу, если она положительна; Если отрицательное значение, отображается ноль.Difference: Subtracts the last measurement from the previous one and displays the difference, if it is positive; if negative, it displays a zero.

  • Мгновенно: Отображает самое последнее измерение.Instantaneous: Displays the most recent measurement.

  • Процент: Отображает вычисленные значения в процентах.Percentage: Displays calculated values as a percentage.

  • Ставка: Выборка с увеличением числа событий за период времени и деление изменения количества значений на изменение времени для показа интенсивности действий.Rate: Samples an increasing count of events over time and divides the change in count values by the change in time to display a rate of activity.

При выборке данных счетчика производительности использование типа счетчика, представляющего среднее значение, может сделать необработанные значения данных пригодными для использования.When sampling performance counter data, using a counter type that represents an average can make raw data values meaningful for your use. Например, счетчик NumberOfItems64 необработанных данных может представлять данные, которые довольно случайные от выборки к примеру.For example, the raw data counter NumberOfItems64 can expose data that is fairly random from sample to sample. Формула для среднего вычисления значений, возвращаемых счетчиком, будет иметь значение (X 0 + X 1 +... + X n)/n, где каждый X я является необработанным примером счетчика.The formula for an average calculation of the values that the counter returns would be (X 0 +X 1 +…+X n)/n, where each X i is a raw counter sample.

Счетчики частоты похожи на средние счетчики, но более полезны для ситуаций, в которых скорость увеличивается по мере использования ресурса.Rate counters are similar to average counters, but more useful for situations in which the rate increases as a resource is used. Формула, которая быстро вычисляет среднее, — ((X n-X 0)/(T n-T 0))/Frequency, где каждый X i является образцом счетчика, а каждый T — время, когда был получен соответствующий пример.A formula that quickly calculates the average is ((X n -X 0)/(T n -T 0)) / frequency, where each X i is a counter sample and each T i is the time that the corresponding sample was taken. Результатом является среднее использование в секунду.The result is the average usage per second.

Счетчики с несколькими временными интервалами собираются данные из более чем одного экземпляра компонента, например процессора или диска.Multitimer counters collect data from more than one instance of a component, such as a processor or disk.

Обратные счетчики измеряют время, в течение которого компонент не является активным, и извлекает активное время из этого измерения.Inverse counters measure the time that a component is not active and derive the active time from that measurement.

Примечание

Если не указано иное, базовое время — секунды.Unless otherwise indicated, the time base is seconds.

При инструментировании приложений (создание и запись пользовательских счетчиков производительности) вы можете работать с типами счетчиков производительности, которые используют сопутствующий базовый счетчик, используемый в вычислениях.When instrumenting applications (creating and writing custom performance counters), you might be working with performance counter types that rely on an accompanying base counter that is used in the calculations. Базовый счетчик должен быть сразу после связанного счетчика в коллекции, CounterCreationDataCollection используемой приложением.The base counter must be immediately after its associated counter in the CounterCreationDataCollection collection your application uses. В следующей таблице перечислены базовые типы счетчиков с соответствующими типами счетчиков производительности.The following table lists the base counter types with their corresponding performance counter types.

Базовый тип счетчикаBase counter type Типы счетчиков производительностиPerformance counter types
AverageBase AverageTimer32

AverageCount64
CounterMultiBase CounterMultiTimer

CounterMultiTimerInverse

CounterMultiTimer100Ns

CounterMultiTimer100NsInverse
RawBase RawFraction
SampleBase SampleFraction

Ниже приведены формулы, используемые некоторыми счетчиками, которые представляют собой вычисляемые значения:The following are the formulas used by some of the counters that represent calculated values:

  • AverageCount64: (N1-N0)/(B1-B0), где n 1 и n 0 — чтение счетчиков производительности, а B1 и B0 — соответствующие AverageBase значения.AverageCount64: (N1 - N0)/(B1 - B0), where N 1 and N 0 are performance counter readings, and B1 and B0 are their corresponding AverageBase values. Таким же числитель представляет количество элементов, обработанных в течение интервала выборки, а знаменатель представляет число операций, выполненных в течение интервала выборки.Thus, the numerator represents the numbers of items processed during the sample interval, and the denominator represents the number of operations completed during the sample interval.

  • AverageTimer32: ((N1-N0)/f)/(B1-B0), где N1 и N0 — чтение счетчиков производительности, B1 и B0 — это соответствующие AverageBase значения, а F — число тактов в секунду.AverageTimer32: ((N1 - N0)/F)/(B1 - B0), where N1 and N0 are performance counter readings, B1 and B0 are their corresponding AverageBase values, and F is the number of ticks per second. Значение F разбивается на уравнение, чтобы результат можно было отобразить в секундах.The value of F is factored into the equation so that the result can be displayed in seconds. Таким же числителем представляется число тактов, подсчитанных в течение последнего интервала выборки, F представляет частоту тактов, а знаменатель представляет количество операций, выполненных в течение последнего интервала выборки.Thus, the numerator represents the numbers of ticks counted during the last sample interval, F represents the frequency of the ticks, and the denominator represents the number of operations completed during the last sample interval.

  • CounterDelta32: N1 — N0, где N1 и N0 — показания счетчиков производительности.CounterDelta32: N1 - N0, where N1 and N0 are performance counter readings.

  • CounterDelta64: N1 — N0, где N1 и N0 — показания счетчиков производительности.CounterDelta64: N1 - N0, where N1 and N0 are performance counter readings.

  • CounterMultiTimer: ((N1-N0)/(D1-D0)) x 100/B, где N1 и N0 — считывания счетчиков производительности, D1 и D0 — их соответствующие временные показания в тактах системного таймера производительности, а переменная B обозначает базовое количество отслеживаемых компонентов (с использованием базового счетчика Ty PE CounterMultiBase).CounterMultiTimer: ((N1 - N0) / (D1 - D0)) x 100 / B, where N1 and N0 are performance counter readings, D1 and D0 are their corresponding time readings in ticks of the system performance timer, and the variable B denotes the base count for the monitored components (using a base counter of type CounterMultiBase). Таким же числитель представляет части интервала выборки, в течение которых наблюдаемые компоненты были активны, а знаменатель представляет общее время, затраченное на интервал выборки.Thus, the numerator represents the portions of the sample interval during which the monitored components were active, and the denominator represents the total elapsed time of the sample interval.

  • CounterMultiTimer100Ns: ((N1-N0)/(D1-D0)) x 100/B, где N1 и N0 — считывания счетчиков производительности, D1 и D0 — это их соответствующее время чтения в единицах 100-наносекундных. переменная B обозначает базовое количество отслеживаемых компонентов (с использованием базового счетчика типа CounterMultiBase).CounterMultiTimer100Ns: ((N1 - N0) / (D1 - D0)) x 100 / B, where N1 and N0 are performance counter readings, D1 and D0 are their corresponding time readings in 100-nanosecond units, and the variable B denotes the base count for the monitored components (using a base counter of type CounterMultiBase). Таким же числитель представляет части интервала выборки, в течение которых наблюдаемые компоненты были активны, а знаменатель представляет общее время, затраченное на интервал выборки.Thus, the numerator represents the portions of the sample interval during which the monitored components were active, and the denominator represents the total elapsed time of the sample interval.

  • CounterMultiTimer100NsInverse: (B-((N1-N0)/(D1-D0)) x 100, где знаменатель представляет общее время, затраченное на интервал выборки, числитель представляет время в течение интервала, когда наблюдаемые компоненты были неактивны, а B — число отслеживаемых компонентов. , используя базовый счетчик типа CounterMultiBase.CounterMultiTimer100NsInverse: (B - ((N1 - N0) / (D1 - D0))) x 100, where the denominator represents the total elapsed time of the sample interval, the numerator represents the time during the interval when monitored components were inactive, and B represents the number of components being monitored, using a base counter of type CounterMultiBase.

  • CounterMultiTimerInverse: (B-((N1-N0)/(D1-D0)) x 100, где знаменатель представляет общее время, затраченное на интервал выборки, числитель представляет время в течение интервала, когда наблюдаемые компоненты были неактивны, а B — число отслеживаемых компонентов. , используя базовый счетчик типа CounterMultiBase.CounterMultiTimerInverse: (B- ((N1 - N0) / (D1 - D0))) x 100, where the denominator represents the total elapsed time of the sample interval, the numerator represents the time during the interval when monitored components were inactive, and B represents the number of components being monitored, using a base counter of type CounterMultiBase.

  • CounterTimer: (N1-N0)/(D1-D0), где N1 и N0 — чтение счетчиков производительности, а D1 и D0 — их соответствующие показания времени.CounterTimer: (N1 - N0) / (D1 - D0), where N1 and N0 are performance counter readings, and D1 and D0 are their corresponding time readings. Таким же числитель представляет части интервала выборки, в течение которых наблюдаемые компоненты были активны, а знаменатель представляет общее время, затраченное на интервал выборки.Thus, the numerator represents the portions of the sample interval during which the monitored components were active, and the denominator represents the total elapsed time of the sample interval.

  • CounterTimerInverse: (1-((N1-N0)/(D1-D0)) x 100, где числитель представляет время в течение интервала, когда отслеживаемые компоненты были неактивны, а знаменатель представляет общее время, затраченное на интервал выборки.CounterTimerInverse: (1- ((N1 - N0) / (D1 - D0))) x 100, where the numerator represents the time during the interval when the monitored components were inactive, and the denominator represents the total elapsed time of the sample interval.

  • CountPerTimeInterval32: (N1-N0)/(D1-D0), где числитель представляет количество элементов в очереди, а знаменатель представляет время, прошедшее в течение последнего интервала выборки.CountPerTimeInterval32: (N1 - N0) / (D1 - D0), where the numerator represents the number of items in the queue, and the denominator represents the time elapsed during the last sample interval.

  • CountPerTimeInterval64: (N1-N0)/(D1-D0), где числитель представляет количество элементов в очереди, а знаменатель представляет время, прошедшее в течение интервала выборки.CountPerTimeInterval64: (N1 - N0) / (D1 - D0), where the numerator represents the number of items in a queue and the denominator represents the time elapsed during the sample interval.

  • ElapsedTime: (D0-N0)/F, где D0 представляет текущее время, N0 представляет время запуска объекта, а F — количество единиц времени, прошедших через одну секунду.ElapsedTime: (D0 - N0) / F, where D0 represents the current time, N0 represents the time the object was started, and F represents the number of time units that elapse in one second. Значение F разбивается на уравнение, чтобы результат можно было отобразить в секундах.The value of F is factored into the equation so that the result can be displayed in seconds.

  • NumberOfItems32: Нет.NumberOfItems32: None. Не отображает среднее значение, но отображает необработанные данные по мере их сбора.Does not display an average, but shows the raw data as it is collected.

  • NumberOfItems64: Нет.NumberOfItems64: None. Не отображает среднее значение, но отображает необработанные данные по мере их сбора.Does not display an average, but shows the raw data as it is collected.

  • NumberOfItemsHEX32: Нет.NumberOfItemsHEX32: None. Не отображает среднее значение, но отображает необработанные данные по мере их сбора.Does not display an average, but shows the raw data as it is collected.

  • NumberOfItemsHEX64: Нет.NumberOfItemsHEX64: None. Не отображает среднее значение, но отображает необработанные данные по мере их сбораDoes not display an average, but shows the raw data as it is collected

  • RateOfCountsPerSecond32: (N1-N0)/((D1-D0)/F), где N1 и N0 — считывание счетчиков производительности, D1 и D0 — их соответствующие показания времени, а F — число тактов в секунду.RateOfCountsPerSecond32: (N1 - N0) / ((D1 - D0) / F), where N1 and N0 are performance counter readings, D1 and D0 are their corresponding time readings, and F represents the number of ticks per second. Таким же числителем представляется количество операций, выполненных в течение последнего интервала выборки, знаменатель представляет число тактов, прошедших за последний интервал выборки, а F — частоту тактов.Thus, the numerator represents the number of operations performed during the last sample interval, the denominator represents the number of ticks elapsed during the last sample interval, and F is the frequency of the ticks. Значение F разбивается на уравнение, чтобы результат можно было отобразить в секундах.The value of F is factored into the equation so that the result can be displayed in seconds.

  • RateOfCountsPerSecond64: (N1-N0)/((D1-D0)/F), где N1 и N0 — считывание счетчиков производительности, D1 и D0 — их соответствующие показания времени, а F — число тактов в секунду.RateOfCountsPerSecond64: (N1 - N0) / ((D1 - D0) / F), where N1 and N0 are performance counter readings, D1 and D0 are their corresponding time readings, and F represents the number of ticks per second. Таким же числителем представляется количество операций, выполненных в течение последнего интервала выборки, знаменатель представляет число тактов, прошедших за последний интервал выборки, а F — частоту тактов.Thus, the numerator represents the number of operations performed during the last sample interval, the denominator represents the number of ticks elapsed during the last sample interval, and F is the frequency of the ticks. Значение F разбивается на уравнение, чтобы результат можно было отобразить в секундах.The value of F is factored into the equation so that the result can be displayed in seconds.

  • RawFraction: (N0/D0) x 100, где D0 представляет измеряемый атрибут (с использованием базового счетчика типа RawBase), а N0 представляет один компонент этого атрибута.RawFraction: (N0 / D0) x 100, where D0 represents a measured attribute (using a base counter of type RawBase) and N0 represents one component of that attribute.

  • SampleCounter: (N1-N0)/((D1-D0)/F), где числитель (N) представляет количество выполненных операций, знаменатель (D) представляет прошедшее время в тактах таймера производительности системы, а F — число тактов, прошедших через одну секунду.SampleCounter: (N1 - N0) / ((D1 - D0) / F), where the numerator (N) represents the number of operations completed, the denominator (D) represents elapsed time in units of ticks of the system performance timer, and F represents the number of ticks that elapse in one second. F в уравнение разбивается, чтобы результат отображался в секундах.F is factored into the equation so that the result can be displayed in seconds.

  • SampleFraction: ((N1-N0)/(D1-D0)) x 100, где числитель представляет количество успешных операций в течение последнего интервала выборки, а знаменатель представляет изменение количества всех операций (измеряемого типа), выполненных в течение интервала выборки. Использование счетчиков типа SampleBase.SampleFraction: ((N1 - N0) / (D1 - D0)) x 100, where the numerator represents the number of successful operations during the last sample interval, and the denominator represents the change in the number of all operations (of the type measured) completed during the sample interval, using counters of type SampleBase.

  • Timer100Ns: (N1-N0)/(D1-D0) x 100, где числитель представляет части интервала выборки, в течение которых наблюдаемые компоненты были активны, а знаменатель представляет общее время, затраченное на интервал выборки.Timer100Ns: (N1 - N0) / (D1 - D0) x 100, where the numerator represents the portions of the sample interval during which the monitored components were active, and the denominator represents the total elapsed time of the sample interval.

  • Timer100NsInverse: (1-((N1-N0)/(D1-D0)) x 100, где числитель представляет время в течение интервала, когда отслеживаемые компоненты были неактивны, а знаменатель представляет общее время, затраченное на интервал выборки.Timer100NsInverse: (1- ((N1 - N0) / (D1 - D0))) x 100, where the numerator represents the time during the interval when the monitored components were inactive, and the denominator represents the total elapsed time of the sample interval.

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