public void BenchmarkICaptureDevice()
{
int packetsRead = 0;
var startTime = DateTime.Now;
while (packetsRead < packetsToRead)
{
using var captureDevice = new CaptureFileReaderDevice(TestHelper.GetFile("10k_packets.pcap"));
captureDevice.Open();
RawCapture rawCapture = null;
do
{
rawCapture = captureDevice.GetNextPacket();
// Parse the packet using PacketDotNet
if (rawCapture != null)
{
Packet.ParsePacket(rawCapture.LinkLayerType, rawCapture.Data);
}
packetsRead++;
}while (rawCapture != null);
}
var endTime = DateTime.Now;
var rate = new Rate(startTime, endTime, packetsRead, "packets parsed");
Console.WriteLine("{0}", rate.ToString());
}
public void BenchmarkICaptureDevice()
{
int packetsRead = 0;
var startTime = DateTime.Now;
while(packetsRead < packetsToRead)
{
ICaptureDevice captureDevice = new SharpPcap.LibPcap.CaptureFileReaderDevice("../../capture_files/10k_packets.pcap");
captureDevice.Open();
RawCapture rawCapture = null;
do
{
rawCapture = captureDevice.GetNextPacket();
packetsRead++;
}
while(rawCapture != null);
captureDevice.Close();
}
var endTime = DateTime.Now;
var rate = new Rate(startTime, endTime, packetsRead, "packets captured");
Console.WriteLine("{0}", rate.ToString());
}
public unsafe void BenchmarkICaptureDeviceUnsafe()
{
int packetsRead = 0;
var startTime = DateTime.Now;
while (packetsRead < packetsToRead)
{
ICaptureDevice captureDevice = new SharpPcap.LibPcap.CaptureFileReaderDevice(TestHelper.GetFile("10k_packets.pcap"));
captureDevice.Open();
RawCapture rawCapture = null;
do
{
rawCapture = captureDevice.GetNextPacket();
packetsRead++;
}while(rawCapture != null);
captureDevice.Close();
}
var endTime = DateTime.Now;
var rate = new Rate(startTime, endTime, packetsRead, "packets captured");
Console.WriteLine("{0}", rate.ToString());
}
public void Benchmark()
{
int packetsRead = 0;
var startTime = DateTime.Now;
while(packetsRead < packetsToRead)
{
var captureDevice = new SharpPcap.LibPcap.CaptureFileReaderDevice("../../capture_files/10k_packets.pcap");
captureDevice.Open();
RawCapture rawCapture = null;
do
{
rawCapture = captureDevice.GetNextPacket();
// Parse the packet using PacketDotNet
if(rawCapture != null)
Packet.ParsePacket(rawCapture.LinkLayerType, rawCapture.Data);
packetsRead++;
}
while(rawCapture != null);
captureDevice.Close();
}
var endTime = DateTime.Now;
var rate = new Rate(startTime, endTime, packetsRead, "packets parsed");
Console.WriteLine("{0}", rate.ToString());
}
public void ArrayCopyPerformance()
{
// create a realistic packet for testing
var ethernetPacket = EthernetPacket.RandomPacket();
// create the array to store the copy result
byte[] hwAddress = new byte[EthernetFields.MacAddressLength];
// store the logging value
var oldThreshold = LoggingConfiguration.GlobalLoggingLevel;
// disable logging to improve performance
LoggingConfiguration.GlobalLoggingLevel = log4net.Core.Level.Off;
// Store the time before the processing starts
var startTime = DateTime.Now;
// run the test
for (int i = 0; i < testRuns; i++)
{
Array.Copy(ethernetPacket.Bytes, EthernetFields.SourceMacPosition,
hwAddress, 0, EthernetFields.MacAddressLength);
}
// store the time after the processing is finished
var endTime = DateTime.Now;
// restore logging
LoggingConfiguration.GlobalLoggingLevel = oldThreshold;
// calculate the statistics
var rate = new Rate(startTime, endTime, testRuns, "Test runs");
// output the statistics to the console
Console.WriteLine(rate.ToString());
}
public unsafe void BenchmarkICaptureDeviceUnsafe()
{
int packetsRead = 0;
var startTime = DateTime.Now;
while (packetsRead < packetsToRead)
{
ICaptureDevice captureDevice = new SharpPcap.LibPcap.CaptureFileReaderDevice("../../capture_files/10k_packets.pcap");
captureDevice.Open();
RawCapture rawCapture = null;
do
{
rawCapture = captureDevice.GetNextPacket();
// Parse the packet using PacketDotNet
if (rawCapture != null)
{
Packet.ParsePacket(rawCapture.LinkLayerType, rawCapture.Data);
}
packetsRead++;
}while(rawCapture != null);
captureDevice.Close();
}
var endTime = DateTime.Now;
var rate = new Rate(startTime, endTime, packetsRead, "packets parsed");
Console.WriteLine("{0}", rate.ToString());
}
public void TestOptimalByteRetrieval()
{
var ethernetPacket = BuildNonContiguousEthernetPacket();
// now extract a contiguous series of bytes
var contiguousBytes = ethernetPacket.Bytes;
// and re-parse the packet
var contiguousEthernetPacket = new EthernetPacket(new PacketDotNet.Utils.ByteArraySegment(contiguousBytes));
// used to make sure we get the same byte[] reference returned each time
// because thats what we expect
Byte[] theByteArray = null;
// store the logging value
var oldThreshold = LoggingConfiguration.GlobalLoggingLevel;
// disable logging to improve performance
LoggingConfiguration.GlobalLoggingLevel = log4net.Core.Level.Off;
// now benchmark retrieving the byte[] for several seconds
var startTime = DateTime.Now;
var endTime = startTime.Add(new TimeSpan(0, 0, 2));
Int32 testRuns = 0;
while (DateTime.Now < endTime)
{
var theBytes = contiguousEthernetPacket.Bytes;
// make sure that we always get back the same reference
// for the byte[]
if (theByteArray == null)
{
theByteArray = theBytes;
}
else
{
Assert.AreSame(theByteArray, theBytes);
}
testRuns++;
}
// update the actual end of the loop
endTime = DateTime.Now;
// restore logging
LoggingConfiguration.GlobalLoggingLevel = oldThreshold;
var rate = new Rate(startTime, endTime, testRuns, "Test runs");
Console.WriteLine(rate.ToString());
}
public void EndianReaderWriterPerformance()
{
// store the logging value
var oldThreshold = LoggingConfiguration.GlobalLoggingLevel;
// disable logging to improve performance
LoggingConfiguration.GlobalLoggingLevel = log4net.Core.Level.Off;
Byte[] bytes;
Int32 testRuns;
Int32 startIndex;
Int32 expectedValue;
ByteSetupMethods.Setup(out bytes, out testRuns, out startIndex,
out expectedValue);
var memStream = new MemoryStream(bytes);
var endianReader = new EndianBinaryReader(EndianBitConverter.Big, memStream);
var startTime = DateTime.Now;
for (Int32 i = 0; i < testRuns; i++)
{
endianReader.Seek(startIndex, SeekOrigin.Begin);
var actualValue = endianReader.ReadInt32();
// NOTE: Assert.AreEqual() significantly slows, by a factor of ~6x
// the execution of this loop, so we perform ourself and
// then call Assert.AreEqual() if the comparison fails.
// This doesn't reduce performance by a noticable amount
if (actualValue != expectedValue)
{
Assert.AreEqual(expectedValue, actualValue);
}
}
var endTime = DateTime.Now;
// restore logging
LoggingConfiguration.GlobalLoggingLevel = oldThreshold;
var rate = new Rate(startTime, endTime, testRuns, "Test runs");
Console.WriteLine(rate.ToString());
}
public void TestSubOptimalByteRetrieval()
{
var ethernetPacket = BuildNonContiguousEthernetPacket();
Byte[] lastByteArray = null;
// store the logging value
var oldThreshold = LoggingConfiguration.GlobalLoggingLevel;
// disable logging to improve performance
LoggingConfiguration.GlobalLoggingLevel = log4net.Core.Level.Off;
// now benchmark retrieving the byte[] for several seconds
var startTime = DateTime.Now;
var endTime = startTime.Add(new TimeSpan(0, 0, 2));
Int32 testRuns = 0;
while (DateTime.Now < endTime)
{
var theBytes = ethernetPacket.Bytes;
// make sure we don't get back the same reference
if (lastByteArray == null)
{
lastByteArray = theBytes;
}
else
{
Assert.AreNotSame(lastByteArray, theBytes);
lastByteArray = theBytes;
}
testRuns++;
}
// update the actual end of the loop
endTime = DateTime.Now;
// restore logging
LoggingConfiguration.GlobalLoggingLevel = oldThreshold;
var rate = new Rate(startTime, endTime, testRuns, "Test runs");
Console.WriteLine(rate.ToString());
}
public void ArrayCopyBitConverterIpAddressPerformance()
{
// store the logging value
var oldThreshold = LoggingConfiguration.GlobalLoggingLevel;
// disable logging to improve performance
LoggingConfiguration.GlobalLoggingLevel = log4net.Core.Level.Off;
Byte[] bytes;
Int32 testRuns;
Int32 startIndex;
Int32 expectedValue;
ByteSetupMethods.Setup(out bytes, out testRuns, out startIndex,
out expectedValue);
var startTime = DateTime.Now;
for (Int32 i = 0; i < testRuns; i++)
{
var actualValue = IPAddress.NetworkToHostOrder(BitConverter.ToInt32(bytes, startIndex));
// NOTE: Assert.AreEqual() significantly slows, by a factor of ~6x
// the execution of this loop, so we perform ourself and
// then call Assert.AreEqual() if the comparison fails.
// This doesn't reduce performance by a noticable amount
if (actualValue != expectedValue)
{
Assert.AreEqual(expectedValue, actualValue);
}
}
var endTime = DateTime.Now;
// restore logging
LoggingConfiguration.GlobalLoggingLevel = oldThreshold;
var rate = new Rate(startTime, endTime, testRuns, "Test runs");
Console.WriteLine(rate.ToString());
}
public void ArrayCopyBitConverterIpAddressPerformance()
{
// store the logging value
var oldThreshold = LoggingConfiguration.GlobalLoggingLevel;
// disable logging to improve performance
LoggingConfiguration.GlobalLoggingLevel = log4net.Core.Level.Off;
byte[] bytes;
int testRuns;
int startIndex;
int expectedValue;
ByteSetupMethods.Setup(out bytes, out testRuns, out startIndex,
out expectedValue);
var startTime = DateTime.Now;
for(int i = 0; i < testRuns; i++)
{
var actualValue = IPAddress.NetworkToHostOrder(BitConverter.ToInt32(bytes, startIndex));
// NOTE: Assert.AreEqual() significantly slows, by a factor of ~6x
// the execution of this loop, so we perform ourself and
// then call Assert.AreEqual() if the comparison fails.
// This doesn't reduce performance by a noticable amount
if(actualValue != expectedValue)
{
Assert.AreEqual(expectedValue, actualValue);
}
}
var endTime = DateTime.Now;
// restore logging
LoggingConfiguration.GlobalLoggingLevel = oldThreshold;
var rate = new Rate(startTime, endTime, testRuns, "Test runs");
Console.WriteLine(rate.ToString());
}
public void TestGetEncapsulated()
{
var ethernetPacket = BuildTCPPacket();
// store the logging value
var oldThreshold = LoggingConfiguration.GlobalLoggingLevel;
// disable logging to improve performance
LoggingConfiguration.GlobalLoggingLevel = log4net.Core.Level.Off;
var startTime = DateTime.Now;
var endTime = startTime.Add(new TimeSpan(0, 0, 15));
int testRuns = 0;
while (DateTime.Now < endTime)
{
// Disable CS0618 (use of obsolete method), because we are testing the now obsolete
// methods for performance
#pragma warning disable 0618
var tcpPacket = TcpPacket.GetEncapsulated(ethernetPacket);
#pragma warning restore 0618
Assert.IsNotNull(tcpPacket);
Assert.AreEqual(tcpPacket.SourcePort, tcpSourcePort);
Assert.AreEqual(tcpPacket.DestinationPort, tcpDestinationPort);
testRuns++;
}
// update the actual end of the loop
endTime = DateTime.Now;
// restore logging
LoggingConfiguration.GlobalLoggingLevel = oldThreshold;
var rate = new Rate(startTime, endTime, testRuns, "Test runs");
Console.WriteLine(rate.ToString());
}
public void BufferCopyPerformance()
{
// create a realistic packet for testing
var ethernetPacket = EthernetPacket.RandomPacket();
// create the array to store the copy result
var hwAddress = new byte[EthernetFields.MacAddressLength];
// store the logging value
var oldThreshold = LoggingConfiguration.GlobalLoggingLevel;
// disable logging to improve performance
LoggingConfiguration.GlobalLoggingLevel = Level.Off;
// Store the time before the processing starts
var startTime = DateTime.Now;
// run the test
for (var i = 0; i < testRuns; i++)
{
Buffer.BlockCopy(ethernetPacket.Bytes,
EthernetFields.SourceMacPosition,
hwAddress,
0,
EthernetFields.MacAddressLength);
}
// store the time after the processing is finished
var endTime = DateTime.Now;
// restore logging
LoggingConfiguration.GlobalLoggingLevel = oldThreshold;
// calculate the statistics
var rate = new Rate(startTime, endTime, testRuns, "Test runs");
// output the statistics to the console
Console.WriteLine(rate.ToString());
}
public void TestOptimalByteRetrieval()
{
var ethernetPacket = BuildNonContiguousEthernetPacket();
// now extract a contiguous series of bytes
var contiguousBytes = ethernetPacket.Bytes;
// and re-parse the packet
var contiguousEthernetPacket = new EthernetPacket(new PacketDotNet.Utils.ByteArraySegment(contiguousBytes));
// used to make sure we get the same byte[] reference returned each time
// because thats what we expect
byte[] theByteArray = null;
// store the logging value
var oldThreshold = LoggingConfiguration.GlobalLoggingLevel;
// disable logging to improve performance
LoggingConfiguration.GlobalLoggingLevel = log4net.Core.Level.Off;
// now benchmark retrieving the byte[] for several seconds
var startTime = DateTime.Now;
var endTime = startTime.Add(new TimeSpan(0, 0, 2));
int testRuns = 0;
while(DateTime.Now < endTime)
{
var theBytes = contiguousEthernetPacket.Bytes;
// make sure that we always get back the same reference
// for the byte[]
if(theByteArray == null)
{
theByteArray = theBytes;
} else
{
Assert.AreSame(theByteArray, theBytes);
}
testRuns++;
}
// update the actual end of the loop
endTime = DateTime.Now;
// restore logging
LoggingConfiguration.GlobalLoggingLevel = oldThreshold;
var rate = new Rate(startTime, endTime, testRuns, "Test runs");
Console.WriteLine(rate.ToString());
}
public void TestSubOptimalByteRetrieval()
{
var ethernetPacket = BuildNonContiguousEthernetPacket();
byte[] lastByteArray = null;
// store the logging value
var oldThreshold = LoggingConfiguration.GlobalLoggingLevel;
// disable logging to improve performance
LoggingConfiguration.GlobalLoggingLevel = log4net.Core.Level.Off;
// now benchmark retrieving the byte[] for several seconds
var startTime = DateTime.Now;
var endTime = startTime.Add(new TimeSpan(0, 0, 2));
int testRuns = 0;
while(DateTime.Now < endTime)
{
var theBytes = ethernetPacket.Bytes;
// make sure we don't get back the same reference
if(lastByteArray == null)
{
lastByteArray = theBytes;
} else
{
Assert.AreNotSame(lastByteArray, theBytes);
lastByteArray = theBytes;
}
testRuns++;
}
// update the actual end of the loop
endTime = DateTime.Now;
// restore logging
LoggingConfiguration.GlobalLoggingLevel = oldThreshold;
var rate = new Rate(startTime, endTime, testRuns, "Test runs");
Console.WriteLine(rate.ToString());
}
public void TestGetEncapsulated()
{
var ethernetPacket = BuildTCPPacket();
// store the logging value
var oldThreshold = LoggingConfiguration.GlobalLoggingLevel;
// disable logging to improve performance
LoggingConfiguration.GlobalLoggingLevel = log4net.Core.Level.Off;
var startTime = DateTime.Now;
var endTime = startTime.Add(new TimeSpan(0, 0, 15));
int testRuns = 0;
while(DateTime.Now < endTime)
{
// Disable CS0618 (use of obsolete method), because we are testing the now obsolete
// methods for performance
#pragma warning disable 0618
var tcpPacket = TcpPacket.GetEncapsulated(ethernetPacket);
#pragma warning restore 0618
Assert.IsNotNull(tcpPacket);
Assert.AreEqual(tcpPacket.SourcePort, tcpSourcePort);
Assert.AreEqual(tcpPacket.DestinationPort, tcpDestinationPort);
testRuns++;
}
// update the actual end of the loop
endTime = DateTime.Now;
// restore logging
LoggingConfiguration.GlobalLoggingLevel = oldThreshold;
var rate = new Rate(startTime, endTime, testRuns, "Test runs");
Console.WriteLine(rate.ToString());
}
public void TestPacketExtract()
{
var ethernetPacket = BuildTCPPacket();
// store the logging value
var oldThreshold = LoggingConfiguration.GlobalLoggingLevel;
// disable logging to improve performance
LoggingConfiguration.GlobalLoggingLevel = log4net.Core.Level.Off;
var startTime = DateTime.Now;
var endTime = startTime.Add(new TimeSpan(0, 0, 15));
int testRuns = 0;
while(DateTime.Now < endTime)
{
var tcpPacket = (TcpPacket)ethernetPacket.Extract(typeof(TcpPacket));
Assert.IsNotNull(tcpPacket);
Assert.AreEqual(tcpPacket.SourcePort, tcpSourcePort);
Assert.AreEqual(tcpPacket.DestinationPort, tcpDestinationPort);
testRuns++;
}
// update the actual end of the loop
endTime = DateTime.Now;
// restore logging
LoggingConfiguration.GlobalLoggingLevel = oldThreshold;
var rate = new Rate(startTime, endTime, testRuns, "Test runs");
Console.WriteLine(rate.ToString());
}
public void EndianReaderWriterPerformance()
{
// store the logging value
var oldThreshold = LoggingConfiguration.GlobalLoggingLevel;
// disable logging to improve performance
LoggingConfiguration.GlobalLoggingLevel = log4net.Core.Level.Off;
byte[] bytes;
int testRuns;
int startIndex;
int expectedValue;
ByteSetupMethods.Setup(out bytes, out testRuns, out startIndex,
out expectedValue);
var memStream = new MemoryStream(bytes);
var endianReader = new EndianBinaryReader(EndianBitConverter.Big, memStream);
var startTime = DateTime.Now;
for(int i = 0; i < testRuns; i++)
{
endianReader.Seek(startIndex, SeekOrigin.Begin);
var actualValue = endianReader.ReadInt32();
// NOTE: Assert.AreEqual() significantly slows, by a factor of ~6x
// the execution of this loop, so we perform ourself and
// then call Assert.AreEqual() if the comparison fails.
// This doesn't reduce performance by a noticable amount
if(actualValue != expectedValue)
{
Assert.AreEqual(expectedValue, actualValue);
}
}
var endTime = DateTime.Now;
// restore logging
LoggingConfiguration.GlobalLoggingLevel = oldThreshold;
var rate = new Rate(startTime, endTime, testRuns, "Test runs");
Console.WriteLine(rate.ToString());
}