/// <summary>
/// Initializes a new instance of the IpPacket class using the specified
/// values.
/// </summary>
/// <param name="destination">The IPv4 address of the destination
/// host.</param>
/// <param name="source">The IPv4 address of the sending host.</param>
/// <param name="type">The type of the transport protocol encapsulated in
/// the IP packet's data section.</param>
/// <param name="fragmentOffset">The fragment offset of the packet.</param>
/// <param name="data">The transport data to transfer as part of the IP
/// packet.</param>
/// <param name="ihl">The Internet Header Length.</param>
/// <param name="dscp">The Differentiated Services Code Point.</param>
/// <param name="ttl">The time-to-live of the IP packet.</param>
/// <param name="identification">The idenfication used for uniquely identifying
/// fragments of a fragmented IP packet.</param>
/// <param name="flags">The flags set on the IP packet.</param>
/// <exception cref="ArgumentNullException">Thrown if any of the arguments
/// is null.</exception>
public IpPacket(IpAddress destination, IpAddress source,
IpProtocol type, byte ihl, byte dscp, byte ttl, ushort identification,
IpFlag flags, ushort fragmentOffset, byte[] data)
{
destination.ThrowIfNull("destination");
source.ThrowIfNull("source");
data.ThrowIfNull("data");
if (ihl > 0x0F)
{
throw new ArgumentException("The Internet Header Length field must " +
"be in the range from 0 to 15.", nameof(ihl));
}
if (fragmentOffset > 0x1FFF)
{
throw new ArgumentException("The Fragment Offset field must be in " +
"the range from 0 to 8191.", nameof(fragmentOffset));
}
Version = IpVersion.Ipv4;
Ihl = ihl;
Dscp = dscp;
Identification = identification;
Flags = flags;
FragmentOffset = fragmentOffset;
TimeToLive = ttl;
Protocol = type;
Source = source;
Destination = destination;
Data = data;
TotalLength = (ushort)(20 + Data.Length);
Checksum = ComputeChecksum(this);
}
/// <summary>
/// Private constructor used for deserialization.
/// </summary>
private IpPacket(IpVersion version, byte ihl, byte dscp, ushort totalLength,
ushort identification, IpFlag flags, ushort fragmentOffset,
byte ttl, IpProtocol protocol, ushort checksum, IpAddress source,
IpAddress destination)
{
destination.ThrowIfNull("destination");
source.ThrowIfNull("source");
if (ihl > 0x0F)
{
throw new ArgumentException("The Internet Header Length field must " +
"be in the range from 0 to 15.", nameof(ihl));
}
if (fragmentOffset > 0x1FFF)
{
throw new ArgumentException("The Fragment Offset field must be in " +
"the range from 0 to 8191.", nameof(fragmentOffset));
}
Version = version;
Ihl = ihl;
Dscp = dscp;
TotalLength = totalLength;
Identification = identification;
Flags = flags;
FragmentOffset = fragmentOffset;
TimeToLive = ttl;
Protocol = protocol;
Checksum = checksum;
Source = source;
Destination = destination;
Data = new byte[0];
}
private void PacketArrival(object sender, EthernetPacket eth)
{
var myInterface = (Interface)sender;
var arp = eth.Extract <ArpPacket>();
if (arp != null)
{
var protocol = new ArpProtocol(this, CurrentApp.Logging);
protocol.Process(myInterface, arp);
RouterChange?.Invoke(this, null);
return;
}
if (!eth.DestinationHardwareAddress.Equals(myInterface.MacAddress) && !eth.DestinationHardwareAddress.Equals(PhysicalAddress.Parse("01-00-5E-00-00-09")))
{
return;
}
var ip = eth.Extract <IPPacket>();
if (ip != null)
{
var protocol = new IpProtocol(this, CurrentApp.Logging);
protocol.Process(myInterface, ip);
}
}
public override async Task <Mapping> GetSpecificMappingAsync(IpProtocol protocol, int publicPort)
{
var message = new GetSpecificPortMappingEntryMessage(protocol, publicPort, this);
var response = await SendMessageAsync(message).ConfigureAwait(false);
if (!(response is GetSpecificPortMappingEntryResponseMessage msg))
{
throw new MappingException(ErrorCode.Unknown, "Invalid response received when getting the specific mapping", null);
}
return(new Mapping(protocol, msg.InternalPort, publicPort, msg.LeaseDuration, msg.PortMappingDescription));
}
/// <summary>
/// Hands up the data part of the specified IP packet to the transport
/// layer.
/// </summary>
/// <param name="data">The data to hand up.</param>
/// <param name="protocol">The protocol of the data.</param>
static void HandUp(byte[] data, IpProtocol protocol)
{
// ICMP is a special case since it's not a tranport protocol
// but is implemented as part of the network layer.
if (protocol == IpProtocol.Icmp)
{
WriteLine("Handling ICMP message");
}
else
{
WriteLine("Handing up IP data to Transport Layer: " + data.Length);
}
}
/// <summary>
/// Initializes a new instance of the IpPacket class using the specified
/// values.
/// </summary>
/// <param name="destination">The IPv4 address of the destination
/// host.</param>
/// <param name="source">The IPv4 address of the sending host.</param>
/// <param name="type">The type of the transport protocol encapsulated in
/// the IP packet's data section.</param>
/// <param name="data">The transport data to transfer as part of the IP
/// packet.</param>
/// <exception cref="ArgumentNullException">Thrown if any of the arguments
/// is null.</exception>
public IpPacket(IpAddress destination, IpAddress source,
IpProtocol type, byte[] data)
{
destination.ThrowIfNull("destination");
source.ThrowIfNull("source");
data.ThrowIfNull("data");
Destination = destination;
Source = source;
Protocol = type;
Data = data;
TimeToLive = 64;
Ihl = 5;
TotalLength = (ushort)(20 + Data.Length);
Version = IpVersion.Ipv4;
Checksum = ComputeChecksum(this);
}
public Task <GenericService> Locate(string serviceName, IpProtocol protocol)
{
if (string.IsNullOrWhiteSpace(serviceName))
{
throw new ArgumentNullException(nameof(serviceName));
}
// get name of service to resolve
string sProtocol = protocol.ToString().ToLowerInvariant();
ServiceDnsName name = new ServiceDnsName
{
Domain = ServiceDomain,
ServiceName = serviceName,
Protocol = sProtocol,
DnsName = string.IsNullOrEmpty(ServiceDomain)
? serviceName.ToLowerInvariant()
: $"{serviceName.ToLowerInvariant()}._{sProtocol}.{ServiceDomain}"
};
return(Locate(name, _ => ServiceLookup.SrvTxt(name, MyServiceFactory)));
}
/// <summary>
/// Create a port mapping so traffic sent to the <paramref name="publicPort"/> on the WAN device is sent to the <paramref name="privatePort"/> on the LAN device.
/// </summary>
/// <param name="protocol">The protocol used by the port mapping.</param>
/// <param name="privatePort">The internal/LAN port which will receive traffic sent to the <paramref name="publicPort"/> on the WAN device.</param>
/// <param name="publicPort">Traffic sent to this public/WAN port is forwarded to the <paramref name="privatePort"/> on the LAN device.</param>
/// <param name="lifetime">The lifetime of the port mapping in seconds. If a lifetime of '0' is specified then the protocol default lifetime is used. uPnP defaults to 'indefinite' whereas NAT-PMP defaults to 7,200 seconds.</param>
/// <param name="description">The text description for the port mapping.</param>
public Mapping(IpProtocol protocol, int privatePort, int publicPort, int lifetime, string description)
{
Protocol = protocol;
PrivatePort = privatePort;
PublicPort = publicPort;
Lifetime = lifetime;
Description = description;
if (lifetime == int.MaxValue)
{
Expiration = DateTime.MaxValue;
}
else if (lifetime == 0)
{
Expiration = DateTime.Now;
}
else
{
Expiration = DateTime.Now.AddSeconds(lifetime);
}
}
public static ResponseMessage Decode(byte [] data)
{
if (data.Length < 16)
{
throw new MappingException(ErrorCode.Unknown, $"The received message was too short, only {data.Length} bytes", null);
}
if (data [0] != PmpConstants.Version)
{
throw new MappingException(ErrorCode.Unknown, $"The received message was unsupported version {data[0]}", null);
}
byte opCode = (byte)(data [1] & (byte)127);
IpProtocol protocol = IpProtocol.Tcp;
if (opCode == PmpConstants.OperationCodeUdp)
{
protocol = IpProtocol.Udp;
}
var resultCode = (ErrorCode)IPAddress.NetworkToHostOrder(BitConverter.ToInt16(data, 2));
uint epoch = (uint)IPAddress.NetworkToHostOrder(BitConverter.ToInt32(data, 4));
int privatePort = IPAddress.NetworkToHostOrder(BitConverter.ToInt16(data, 8));
int publicPort = IPAddress.NetworkToHostOrder(BitConverter.ToInt16(data, 10));
uint lifetime = (uint)IPAddress.NetworkToHostOrder(BitConverter.ToInt32(data, 12));
if (publicPort < 0 || privatePort < 0 || resultCode != ErrorCode.Success)
{
throw new MappingException((ErrorCode)resultCode, "Could not modify the port map", null);
}
var mapping = new Mapping(protocol, privatePort, publicPort, (int)lifetime, null);
return(new MappingResponseMessage(mapping));
}
/// <summary>
/// Wraps the specified higher-level data into IP packets and
/// transmits them to the specified destination.
/// </summary>
/// <param name="ifc">The interface through which to output the data.</param>
/// <param name="destination">The logical address of the destination
/// host.</param>
/// <param name="data">The higher-level data to transmit.</param>
/// <param name="type">The type of the higher-level data.</param>
/// <exception cref="ArgumentNullException">Thrown if any of the arguments
/// is null.</exception>
/// <remarks>This API is exposed to the next higher-up layer.</remarks>
public void Output(Interface ifc, IpAddress destination, byte[] data,
IpProtocol type)
{
ifc.ThrowIfNull("ifc");
destination.ThrowIfNull("destination");
data.ThrowIfNull("data");
// Construct IP packets of the size of the MTU of the data-link.
var maxDataSize = ifc.MaximumTransmissionUnit - 20;
var numPackets = (int)Math.Ceiling(data.Length / (double)maxDataSize);
var sameSubnet = (destination & ifc.Netmask) == (ifc.IpAddress & ifc.Netmask);
for (int i = 0, index = 0; i < numPackets; i++)
{
var numBytes = Math.Min(maxDataSize, data.Length - index);
var packetData = new byte[numBytes];
Array.Copy(data, index, packetData, 0, numBytes);
index = index + numBytes;
// Construct the packet.
var packet = new IpPacket(destination, ifc.IpAddress, type, packetData);
// If source and destination are in the same subnet, we can deliver the
// packet directly. Otherwise send it to the configured default gateway.
Output(ifc, sameSubnet ? destination : ifc.Gateway, packet);
}
}
/// <summary>
/// Private constructor used for deserialization.
/// </summary>
private IpPacket(IpVersion version, byte ihl, byte dscp, ushort totalLength,
ushort identification, IpFlag flags, ushort fragmentOffset,
byte ttl, IpProtocol protocol, ushort checksum, IpAddress source,
IpAddress destination) {
destination.ThrowIfNull("destination");
source.ThrowIfNull("source");
if (ihl > 0x0F)
throw new ArgumentException("The Internet Header Length field must " +
"be in the range from 0 to 15.", nameof(ihl));
if (fragmentOffset > 0x1FFF)
throw new ArgumentException("The Fragment Offset field must be in " +
"the range from 0 to 8191.", nameof(fragmentOffset));
Version = version;
Ihl = ihl;
Dscp = dscp;
TotalLength = totalLength;
Identification = identification;
Flags = flags;
FragmentOffset = fragmentOffset;
TimeToLive = ttl;
Protocol = protocol;
Checksum = checksum;
Source = source;
Destination = destination;
Data = new byte[0];
}
/// <summary>
/// Initializes a new instance of the IpPacket class using the specified
/// values.
/// </summary>
/// <param name="destination">The IPv4 address of the destination
/// host.</param>
/// <param name="source">The IPv4 address of the sending host.</param>
/// <param name="type">The type of the transport protocol encapsulated in
/// the IP packet's data section.</param>
/// <param name="fragmentOffset">The fragment offset of the packet.</param>
/// <param name="data">The transport data to transfer as part of the IP
/// packet.</param>
/// <param name="ihl">The Internet Header Length.</param>
/// <param name="dscp">The Differentiated Services Code Point.</param>
/// <param name="ttl">The time-to-live of the IP packet.</param>
/// <param name="identification">The idenfication used for uniquely identifying
/// fragments of a fragmented IP packet.</param>
/// <param name="flags">The flags set on the IP packet.</param>
/// <exception cref="ArgumentNullException">Thrown if any of the arguments
/// is null.</exception>
public IpPacket(IpAddress destination, IpAddress source,
IpProtocol type, byte ihl, byte dscp, byte ttl, ushort identification,
IpFlag flags, ushort fragmentOffset, byte[] data) {
destination.ThrowIfNull("destination");
source.ThrowIfNull("source");
data.ThrowIfNull("data");
if (ihl > 0x0F)
throw new ArgumentException("The Internet Header Length field must " +
"be in the range from 0 to 15.", nameof(ihl));
if (fragmentOffset > 0x1FFF)
throw new ArgumentException("The Fragment Offset field must be in " +
"the range from 0 to 8191.", nameof(fragmentOffset));
Version = IpVersion.Ipv4;
Ihl = ihl;
Dscp = dscp;
Identification = identification;
Flags = flags;
FragmentOffset = fragmentOffset;
TimeToLive = ttl;
Protocol = type;
Source = source;
Destination = destination;
Data = data;
TotalLength = (ushort) (20 + Data.Length);
Checksum = ComputeChecksum(this);
}
/// <summary>
/// Initializes a new instance of the IpPacket class using the specified
/// values.
/// </summary>
/// <param name="destination">The IPv4 address of the destination
/// host.</param>
/// <param name="source">The IPv4 address of the sending host.</param>
/// <param name="type">The type of the transport protocol encapsulated in
/// the IP packet's data section.</param>
/// <param name="data">The transport data to transfer as part of the IP
/// packet.</param>
/// <exception cref="ArgumentNullException">Thrown if any of the arguments
/// is null.</exception>
public IpPacket(IpAddress destination, IpAddress source,
IpProtocol type, byte[] data) {
destination.ThrowIfNull("destination");
source.ThrowIfNull("source");
data.ThrowIfNull("data");
Destination = destination;
Source = source;
Protocol = type;
Data = data;
TimeToLive = 64;
Ihl = 5;
TotalLength = (ushort) (20 + Data.Length);
Version = IpVersion.Ipv4;
Checksum = ComputeChecksum(this);
}
protected static void WriteFullElement(XmlWriter writer, string element, IpProtocol value) => WriteFullElement(writer, element, value == IpProtocol.Tcp ? "TCP" : "UDP");
public PacketFilter(IpProtocol? protocol = null, PacketDirection? direction = null, string host = null)
{
this.Protocol = protocol;
this.Direction = direction;
this.Host = host;
}
public XsSocket(IpProtocol protocol, NetworkLayerProtocol ipVersion) : this(xsensdeviceapiPINVOKE.new_XsSocket__SWIG_0((int)protocol, (int)ipVersion), true)
{
}
public GetSpecificPortMappingEntryMessage(IpProtocol protocol, int externalPort, UpnpNatRouterDevice device)
: base(device, "GetSpecificPortMappingEntry")
{
Protocol = protocol;
ExternalPort = externalPort;
}
public XsSocket(IpProtocol protocol) : this(xsensdeviceapiPINVOKE.new_XsSocket__SWIG_1((int)protocol), true)
{
}
public override Task <Mapping> GetSpecificMappingAsync(IpProtocol protocol, int publicPort)
=> throw new NotImplementedException("The NAT-PMP protocol does not support retrieving a specific mappings");
/// <summary>
/// Create a port mapping so traffic sent to the <paramref name="publicPort"/> on the WAN device is sent to the <paramref name="privatePort"/> on the LAN device.
/// </summary>
/// <param name="protocol">The protocol used by the port mapping.</param>
/// <param name="privatePort">The internal/LAN port which will receive traffic sent to the <paramref name="publicPort"/> on the WAN device.</param>
/// <param name="publicPort">Traffic sent to this external/WAN port is forwarded to the <paramref name="privatePort"/> on the LAN device.</param>
public Mapping(IpProtocol protocol, int privatePort, int publicPort)
: this(protocol, privatePort, publicPort, 0, null)
{
}
/// <summary> /// Retrieves the mapping associated with this combination of public port and protocol. Throws a MappingException /// if there is no mapping matching the criteria. /// </summary> public abstract Task <Mapping> GetSpecificMappingAsync(IpProtocol protocol, int publicPort);
