Windows Performance Counter Types

There are several types of performance counters in Windows. However, I had a hard time of understanding all these types just from their documentation. So I decided to compile some examples for each counter type.

I also wrote some C# code to demonstrate how to use performance counters. You’ll find it at the end of this article.

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.NET Serializers Comparison Chart

There are many object serializers in C#/.NET but their details are often not so obvious, for example:

  • Does my class need a parameterless constructor?
  • Can I serialize private fields?
  • Can I serialize readonly fields?

So, I’ve compiled a comparison chart in this article that will compare the various serializers and their capabilities.

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High Resolution Clock in C#

Clocks in computers have (among others) the following three properties: accuracy, precision, and resolution.

People generally agree on what’s the difference between accuracy and precision/resolution but there seem to be lots of opinions on what’s the difference between precision and resolution and which is which. So I’m going to shamelessly copy a definition I found on Stack Overflow that I’m agreeing with.

  • Precision: the amount of information, i.e. the number of significant digits you report. (E.g. I’m 2m, 1.8m, 1.83m, 1.8322m tall. All those measurements are accurate, but increasingly precise.)
  • Accuracy: the relation between the reported information and the truth. (E.g. “I’m 1.70m tall” is more precise than “1.8m”, but not actually accurate.)
  • Resolution (or Granularity): the smallest time interval that a clock can measure. For example, if you have 1 ms resolution, there’s little point reporting the result with nanosecond precision, since the clock cannot possibly be accurate to that level of precision.

This article will be mainly about resolution (and precision and accuracy to some extend).

DateTime

C# provides the DateTime type (MSDN) that allows to:

  • store a certain point in time
  • get the current date and time (via Now or UtcNow)

First, lets take a look at precision: The DateTime type is basically just a 64 bit integer that counts “ticks”. One tick is 100 nanoseconds (or 0.0001 milliseconds) long (MSDN). So DateTime‘s precision can be up to 0.0001 milliseconds.

Next, resolution. Basically, we’re asking: “How long does it take for value of DateTime.UtcNow to change?” Lets find out.

The following C# code measures the resolution of DateTime.UtcNow:

Console.WriteLine("Running for 5 seconds...");

var distinctValues = new HashSet<DateTime>();
var sw = Stopwatch.StartNew();

while (sw.Elapsed.TotalSeconds < 5)
{
    distinctValues.Add(DateTime.UtcNow);
}

sw.Stop();

Console.WriteLine("Precision: {0:0.000000} ms ({1} samples)",
                  sw.Elapsed.TotalMilliseconds / distinctValues.Count,
                  distinctValues.Count);

This program records all the different values DateTime.UtcNow returns over the course of 5 seconds. This way, we know how often this value changes per second (or millisecond in this example) and that’s the resolution.

According to MSDN the resolution depends on the operating system but in my tests I found out that the resolution also seems to depend on the hardware (unless newer OS versions have a worse resolution).

Machine OS Resolution
Dev Box Windows 7 x64 1 ms
Laptop Windows 8 x64 16 ms

High Resolution Clock

On Windows 8 (or Windows Server 2012) or higher there’s a new API that returns the current time with a much higher resolution:

GetSystemTimePreciseAsFileTime()

Here’s how to use it in C#:

using System;
using System.Runtime.InteropServices;

public static class HighResolutionDateTime
{
    public static bool IsAvailable { get; private set; }

    [DllImport("Kernel32.dll", CallingConvention = CallingConvention.Winapi)]
    private static extern void GetSystemTimePreciseAsFileTime(out long filetime);

    public static DateTime UtcNow
    {
        get
        {
            if (!IsAvailable)
            {
                throw new InvalidOperationException(
                    "High resolution clock isn't available.");
            }

            long filetime;
            GetSystemTimePreciseAsFileTime(out filetime);

            return DateTime.FromFileTimeUtc(filetime);
        }
    }

    static HighResolutionDateTime()
    {
        try
        {
            long filetime;
            GetSystemTimePreciseAsFileTime(out filetime);
            IsAvailable = true;
        }
        catch (EntryPointNotFoundException)
        {
            // Not running Windows 8 or higher.
            IsAvailable = false;
        }
    }
}

Using the same test code as above but using HighResolutionDateTime.UtcNow as input (instead of DateTime.UtcNow) leads to:

Machine OS Resolution
Dev Box Windows 7 x64 n/a
Laptop Windows 8 x64 0.0004 ms

So, on my laptop the resolution increased by a factor of 40000.

Note: The resolution can never be better/smaller than 0.0001 ms because this is the highest precision supported by DateTime (see above).

Accuracy

To complete this article, lets also talk about accuracy.

DateTime.UtcNow and HighResolutionDateTime.UtcNow are both very accurate. The first one has lower resolution, the second one has higher resolution.

There’s also Stopwatch in C#. Stopwatch has a high resolution. Using Stopwatch.ElapsedTicks as input for resolution measure code from above, I got these results:

Machine OS Resolution
Dev Box Windows 7 x64 0.0004 ms
Laptop Windows 8 x64 0.0004 ms

However, Stopwatch is not very accurate. On my laptop it drifts by 0.2 ms per second, i.e. it gets less accurate over time.

Here’s how to measure the drift/accuracy loss:

var start = HighResolutionDateTime.UtcNow;
var sw = Stopwatch.StartNew();

while (sw.Elapsed.TotalSeconds < 10)
{
    DateTime nowBasedOnStopwatch = start + sw.Elapsed;
    TimeSpan diff = HighResolutionDateTime.UtcNow - nowBasedOnStopwatch;

    Console.WriteLine("Diff: {0:0.000} ms", diff.TotalMilliseconds);

    Thread.Sleep(1000);
}

This gives me an output like this:

Diff: 0,075 ms
Diff: 0,414 ms
Diff: 0,754 ms
Diff: 0,924 ms
Diff: 1,084 ms
Diff: 1,247 ms
Diff: 1,409 ms
Diff: 1,571 ms
Diff: 1,734 ms
Diff: 1,898 ms

As you can see, the difference increases over time. Thus, Stopwatch becomes less accurate over time.

Spaß mit C

Was macht diese Codezeile (sz ist ein TCHAR*)?

_tcsrchr(sz, '\\')[1] = '\0';

C ist einfach toll

Dann begannen Dennis und Brian an einer wirklich verzerrten Version von Pascal zu arbeiten, genannt ‘A’. Als wir merkten, daß andere tatsächlich vorhatten, Programme mit ‘A’ zu entwerfen, fügten wir rasch zusätzliche kryptische Eigenschaften hinzu, und entwickelten daraufhin B, BCPL und schließlich C. Wir hörten auf, als es uns gelang, den Ausdruck

for(;P("\\n"),R--;P("|"))for(e=C;e--;P("_"+(*u++/8)%2))P("| "+(*u/4)%2);

fehlerfrei zu kompilieren.

Quelle

LINQ to SQL – bits and pieces

In a project I’m currently working on we’re using LINQ to SQL. While most of it is straight forward, there are some quirks that are not that obvious (at least to me).

This article is mostly a FAQ but I will explain some of the not-so-obvious features in more detail.

Note: I’m not going to explain how to setup the connection to the database in this article. I’m assuming that this already works.

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