df/da2/fragmentation-ipv6-_p_m_t_u_8cc_source.html

 /*

  * Copyright (c) 2008-2009 Strasbourg University

  * Copyright (c) 2013 Universita' di Firenze

  * Copyright (c) 2022 Jadavpur University

  *

  * This program is free software; you can redistribute it and/or modify

  * it under the terms of the GNU General Public License version 2 as

  * published by the Free Software Foundation;

  *

  * This program is distributed in the hope that it will be useful,

  * but WITHOUT ANY WARRANTY; without even the implied warranty of

  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the

  * GNU General Public License for more details.

  *

  * You should have received a copy of the GNU General Public License

  * along with this program; if not, write to the Free Software

  * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA

  *

  * Author: David Gross <gdavid.devel@gmail.com>

  *         Sebastien Vincent <vincent@clarinet.u-strasbg.fr>

  * Modified by Akash Mondal <a98mondal@gmail.com>

  */


 // Network topology

 // //

 // //      Src  n0        r1     n1      r2        n2

 // //           |         _      |       _         |

 // //           =========|_|============|_|=========

 // //      MTU   5000           2000          1500

 // //

 // // - Tracing of queues and packet receptions to file "fragmentation-ipv6-PMTU.tr"


 #include "ns3/applications-module.h"

 #include "ns3/core-module.h"

 #include "ns3/csma-module.h"

 #include "ns3/internet-module.h"

 #include "ns3/ipv6-routing-table-entry.h"

 #include "ns3/ipv6-static-routing-helper.h"

 #include "ns3/network-module.h"

 #include "ns3/point-to-point-module.h"


 #include <fstream>


 using namespace ns3;


 NS_LOG_COMPONENT_DEFINE("FragmentationIpv6PmtuExample");


 int

 main(int argc, char** argv)

 {

     bool verbose = false;


     CommandLine cmd(__FILE__);

     cmd.AddValue("verbose", "turn on log components", verbose);

     cmd.Parse(argc, argv);


     if (verbose)

     {

         LogComponentEnable("Ipv6L3Protocol", LOG_LEVEL_ALL);

         LogComponentEnable("Icmpv6L4Protocol", LOG_LEVEL_ALL);

         LogComponentEnable("Ipv6StaticRouting", LOG_LEVEL_ALL);

         LogComponentEnable("Ipv6Interface", LOG_LEVEL_ALL);

         LogComponentEnable("UdpEchoClientApplication", LOG_LEVEL_ALL);

         LogComponentEnable("UdpEchoServerApplication", LOG_LEVEL_ALL);

     }

     LogComponentEnable("UdpEchoClientApplication", LOG_LEVEL_INFO);


     NS_LOG_INFO("Create nodes.");

     Ptr<Node> n0 = CreateObject<Node>();

     Ptr<Node> r1 = CreateObject<Node>();

     Ptr<Node> n1 = CreateObject<Node>();

     Ptr<Node> r2 = CreateObject<Node>();

     Ptr<Node> n2 = CreateObject<Node>();


     NodeContainer net1(n0, r1);

     NodeContainer net2(r1, n1, r2);

     NodeContainer net3(r2, n2);

     NodeContainer all(n0, r1, n1, r2, n2);


     NS_LOG_INFO("Create IPv6 Internet Stack");

     InternetStackHelper internetv6;

     internetv6.Install(all);


     NS_LOG_INFO("Create channels.");

     CsmaHelper csma;

     csma.SetChannelAttribute("DataRate", DataRateValue(5000000));

     csma.SetChannelAttribute("Delay", TimeValue(MilliSeconds(2)));

     csma.SetDeviceAttribute("Mtu", UintegerValue(2000));

     NetDeviceContainer d2 = csma.Install(net2); // CSMA Network with MTU 2000


     csma.SetDeviceAttribute("Mtu", UintegerValue(5000));

     NetDeviceContainer d1 = csma.Install(net1); // CSMA Network with MTU 5000


     PointToPointHelper pointToPoint;

     pointToPoint.SetDeviceAttribute("DataRate", DataRateValue(5000000));

     pointToPoint.SetChannelAttribute("Delay", StringValue("2ms"));

     pointToPoint.SetDeviceAttribute("Mtu", UintegerValue(1500));

     NetDeviceContainer d3 = pointToPoint.Install(net3); // P2P Network with MTU 1500


     NS_LOG_INFO("Create networks and assign IPv6 Addresses.");

     Ipv6AddressHelper ipv6;


     ipv6.SetBase(Ipv6Address("2001:1::"), Ipv6Prefix(64));

     Ipv6InterfaceContainer i1 = ipv6.Assign(d1);

     i1.SetForwarding(1, true);

     i1.SetDefaultRouteInAllNodes(1);


     ipv6.SetBase(Ipv6Address("2001:2::"), Ipv6Prefix(64));

     Ipv6InterfaceContainer i2 = ipv6.Assign(d2);

     i2.SetForwarding(0, true);

     i2.SetDefaultRouteInAllNodes(0);

     i2.SetForwarding(1, true);

     i2.SetDefaultRouteInAllNodes(0);

     i2.SetForwarding(2, true);

     i2.SetDefaultRouteInAllNodes(2);


     ipv6.SetBase(Ipv6Address("2001:3::"), Ipv6Prefix(64));

     Ipv6InterfaceContainer i3 = ipv6.Assign(d3);

     i3.SetForwarding(0, true);

     i3.SetDefaultRouteInAllNodes(0);


     Ptr<OutputStreamWrapper> routingStream = Create<OutputStreamWrapper>(&std::cout);

     Ipv6RoutingHelper::PrintRoutingTableAt(Seconds(0), r1, routingStream);


     // Create an UDP Echo server on n2

     UdpEchoServerHelper echoServer(42);

     ApplicationContainer serverApps = echoServer.Install(n2);

     serverApps.Start(Seconds(0.0));

     serverApps.Stop(Seconds(30.0));


     uint32_t maxPacketCount = 5;


     // Create an UDP Echo client on n1 to send UDP packets to n2 via r1

     uint32_t packetSizeN1 = 1600; // Packet should fragment as intermediate link MTU is 1500

     UdpEchoClientHelper echoClient(i3.GetAddress(1, 1), 42);

     echoClient.SetAttribute("PacketSize", UintegerValue(packetSizeN1));

     echoClient.SetAttribute("MaxPackets", UintegerValue(maxPacketCount));

     ApplicationContainer clientAppsN1 = echoClient.Install(n1);

     clientAppsN1.Start(Seconds(2.0));

     clientAppsN1.Stop(Seconds(10.0));


     // Create an UDP Echo client on n0 to send UDP packets to n2 via r0 and r1

     uint32_t packetSizeN2 = 4000; // Packet should fragment as intermediate link MTU is 1500

     echoClient.SetAttribute("PacketSize", UintegerValue(packetSizeN2));

     echoClient.SetAttribute("MaxPackets", UintegerValue(maxPacketCount));

     ApplicationContainer clientAppsN2 = echoClient.Install(n1);

     clientAppsN2.Start(Seconds(11.0));

     clientAppsN2.Stop(Seconds(20.0));


     AsciiTraceHelper ascii;

     csma.EnableAsciiAll(ascii.CreateFileStream("fragmentation-ipv6-PMTU.tr"));

     csma.EnablePcapAll(std::string("fragmentation-ipv6-PMTU"), true);

     pointToPoint.EnablePcapAll(std::string("fragmentation-ipv6-PMTU"), true);


     NS_LOG_INFO("Run Simulation.");

     Simulator::Run();

     Simulator::Destroy();

     NS_LOG_INFO("Done.");


     return 0;

 }

ns3::ApplicationContainer
holds a vector of ns3::Application pointers.
Definition: application-container.h:44

ns3::ApplicationContainer::Start
void Start(Time start) const
Start all of the Applications in this container at the start time given as a parameter.
Definition: application-container.cc:92

ns3::ApplicationContainer::Stop
void Stop(Time stop) const
Arrange for all of the Applications in this container to Stop() at the Time given as a parameter.
Definition: application-container.cc:114

ns3::AsciiTraceHelper
Manage ASCII trace files for device models.
Definition: trace-helper.h:174

ns3::AsciiTraceHelper::CreateFileStream
Ptr< OutputStreamWrapper > CreateFileStream(std::string filename, std::ios::openmode filemode=std::ios::out)
Create and initialize an output stream object we'll use to write the traced bits.
Definition: trace-helper.cc:193

ns3::CommandLine
Parse command-line arguments.
Definition: command-line.h:232

ns3::CsmaHelper
build a set of CsmaNetDevice objects
Definition: csma-helper.h:48

ns3::InternetStackHelper
aggregate IP/TCP/UDP functionality to existing Nodes.
Definition: internet-stack-helper.h:92

ns3::InternetStackHelper::Install
void Install(std::string nodeName) const
Aggregate implementations of the ns3::Ipv4, ns3::Ipv6, ns3::Udp, and ns3::Tcp classes onto the provid...
Definition: internet-stack-helper.cc:370

ns3::Ipv6AddressHelper
Helper class to auto-assign global IPv6 unicast addresses.
Definition: ipv6-address-helper.h:84

ns3::Ipv6AddressHelper::SetBase
void SetBase(Ipv6Address network, Ipv6Prefix prefix, Ipv6Address base=Ipv6Address("::1"))
Set the base network number, network prefix, and base interface ID.
Definition: ipv6-address-helper.cc:70

ns3::Ipv6AddressHelper::Assign
Ipv6InterfaceContainer Assign(const NetDeviceContainer &c)
Allocate an Ipv6InterfaceContainer with auto-assigned addresses.
Definition: ipv6-address-helper.cc:220

ns3::Ipv6Address
Describes an IPv6 address.
Definition: ipv6-address.h:49

ns3::Ipv6InterfaceContainer
Keep track of a set of IPv6 interfaces.
Definition: ipv6-interface-container.h:40

ns3::Ipv6InterfaceContainer::SetForwarding
void SetForwarding(uint32_t i, bool state)
Set the state of the stack (act as a router or as an host) for the specified index.
Definition: ipv6-interface-container.cc:97

ns3::Ipv6InterfaceContainer::SetDefaultRouteInAllNodes
void SetDefaultRouteInAllNodes(uint32_t router)
Set the default route for all the devices (except the router itself).
Definition: ipv6-interface-container.cc:104

ns3::Ipv6InterfaceContainer::GetAddress
Ipv6Address GetAddress(uint32_t i, uint32_t j) const
Get the address for the specified index.
Definition: ipv6-interface-container.cc:61

ns3::Ipv6Prefix
Describes an IPv6 prefix.
Definition: ipv6-address.h:455

ns3::Ipv6RoutingHelper::PrintRoutingTableAt
static void PrintRoutingTableAt(Time printTime, Ptr< Node > node, Ptr< OutputStreamWrapper > stream, Time::Unit unit=Time::S)
prints the routing tables of a node at a particular time.
Definition: ipv6-routing-helper.cc:69

ns3::NetDeviceContainer
holds a vector of ns3::NetDevice pointers
Definition: net-device-container.h:43

ns3::NodeContainer
keep track of a set of node pointers.
Definition: node-container.h:40

ns3::PointToPointHelper
Build a set of PointToPointNetDevice objects.
Definition: point-to-point-helper.h:44

ns3::Ptr< Node >

ns3::Simulator::Destroy
static void Destroy()
Execute the events scheduled with ScheduleDestroy().
Definition: simulator.cc:142

ns3::Simulator::Run
static void Run()
Run the simulation.
Definition: simulator.cc:178

ns3::StringValue
Hold variables of type string.
Definition: string.h:56

ns3::TimeValue
Definition: nstime.h:1413

ns3::UdpEchoClientHelper
Create an application which sends a UDP packet and waits for an echo of this packet.
Definition: udp-echo-helper.h:108

ns3::UdpEchoServerHelper
Create a server application which waits for input UDP packets and sends them back to the original sen...
Definition: udp-echo-helper.h:39

ns3::UintegerValue
Hold an unsigned integer type.
Definition: uinteger.h:45

NS_LOG_COMPONENT_DEFINE
#define NS_LOG_COMPONENT_DEFINE(name)
Define a Log component with a specific name.
Definition: log.h:202

NS_LOG_INFO
#define NS_LOG_INFO(msg)
Use NS_LOG to output a message of level LOG_INFO.
Definition: log.h:275

ns3::Seconds
Time Seconds(double value)
Construct a Time in the indicated unit.
Definition: nstime.h:1326

ns3::MilliSeconds
Time MilliSeconds(uint64_t value)
Construct a Time in the indicated unit.
Definition: nstime.h:1338

first.echoClient
echoClient
Definition: first.py:59

first.serverApps
serverApps
Definition: first.py:54

first.pointToPoint
pointToPoint
Definition: first.py:38

first.echoServer
echoServer
Definition: first.py:52

ns3
Every class exported by the ns3 library is enclosed in the ns3 namespace.

ns3::LogComponentEnable
void LogComponentEnable(const std::string &name, LogLevel level)
Enable the logging output associated with that log component.
Definition: log.cc:302

ns3::LOG_LEVEL_ALL
@ LOG_LEVEL_ALL
Print everything.
Definition: log.h:116

ns3::LOG_LEVEL_INFO
@ LOG_LEVEL_INFO
LOG_INFO and above.
Definition: log.h:104

second.csma
csma
Definition: second.py:63

second.cmd
cmd
Definition: second.py:40

verbose
bool verbose
Definition: openflow-switch.cc:53