void FlameRegressionTest::CreateDevices () { int64_t streamsUsed = 0; // 1. setup WiFi YansWifiPhyHelper wifiPhy = YansWifiPhyHelper::Default (); // This test suite output was originally based on YansErrorRateModel wifiPhy.SetErrorRateModel ("ns3::YansErrorRateModel"); YansWifiChannelHelper wifiChannel = YansWifiChannelHelper::Default (); Ptr<YansWifiChannel> chan = wifiChannel.Create (); wifiPhy.SetChannel (chan); // 2. setup mesh MeshHelper mesh = MeshHelper::Default (); mesh.SetStackInstaller ("ns3::FlameStack"); mesh.SetMacType ("RandomStart", TimeValue (Seconds (0.1))); mesh.SetNumberOfInterfaces (1); NetDeviceContainer meshDevices = mesh.Install (wifiPhy, *m_nodes); // Three devices, two streams per device streamsUsed += mesh.AssignStreams (meshDevices, streamsUsed); NS_TEST_ASSERT_MSG_EQ (streamsUsed, (meshDevices.GetN () * 2), "Stream assignment unexpected value"); streamsUsed += wifiChannel.AssignStreams (chan, streamsUsed); NS_TEST_ASSERT_MSG_EQ (streamsUsed, (meshDevices.GetN () * 2), "Stream assignment unexpected value"); // 3. setup TCP/IP InternetStackHelper internetStack; internetStack.Install (*m_nodes); Ipv4AddressHelper address; address.SetBase ("10.1.1.0", "255.255.255.0"); m_interfaces = address.Assign (meshDevices); // 4. write PCAP if needed wifiPhy.EnablePcapAll (CreateTempDirFilename (PREFIX)); }
int main (int argc, char *argv[]) { NodeContainer nodes; nodes.Create (2); PointToPointHelper pointToPoint; NetDeviceContainer devices; devices = pointToPoint.Install (nodes); InternetStackHelper stack; stack.Install (nodes); Ipv4AddressHelper address; address.SetBase ("10.1.1.0", "255.255.255.252"); Ipv4InterfaceContainer interfaces = address.Assign (devices); uint16_t sinkPort = 8080; Address sinkAddress (InetSocketAddress (interfaces.GetAddress (1), sinkPort)); Ptr<PacketSink> receiverApplication = CreateObject<PacketSink> (); receiverApplication->SetAttribute ("Local", AddressValue (InetSocketAddress (Ipv4Address::GetAny(), 8080))); receiverApplication->SetAttribute ("Protocol", TypeIdValue(TcpSocketFactory::GetTypeId())); receiverApplication->TraceConnectWithoutContext ("Rx", MakeCallback (&CountRx)); nodes.Get(1)->AddApplication(receiverApplication); Ptr<MyApp> app = CreateObject<MyApp> (nodes.Get (0), sinkAddress); nodes.Get (0)->AddApplication (app); Simulator::Stop (); Simulator::Run (); Simulator::Destroy (); return 0; }
// // Network topology // (sender) (receiver) // n0 n1 n2 n3 // | | | | // ===================== // // Node n0 sends data to node n3 over a raw IP socket. The protocol // number used is 2. // void CsmaRawIpSocketTestCase::DoRun (void) { // Here, we will explicitly create four nodes. NodeContainer c; c.Create (4); // connect all our nodes to a shared channel. CsmaHelper csma; csma.SetChannelAttribute ("DataRate", DataRateValue (DataRate (5000000))); csma.SetChannelAttribute ("Delay", TimeValue (MilliSeconds (2))); csma.SetDeviceAttribute ("EncapsulationMode", StringValue ("Llc")); NetDeviceContainer devs = csma.Install (c); // add an ip stack to all nodes. InternetStackHelper ipStack; ipStack.Install (c); // assign ip addresses Ipv4AddressHelper ip; ip.SetBase ("192.168.1.0", "255.255.255.0"); Ipv4InterfaceContainer addresses = ip.Assign (devs); // IP protocol configuration // // Make packets be sent about every DefaultPacketSize / DataRate = // 4096 bits / (5000 bits/second) = 0.82 second. Config::SetDefault ("ns3::Ipv4RawSocketImpl::Protocol", StringValue ("2")); InetSocketAddress dst = InetSocketAddress (addresses.GetAddress (3)); OnOffHelper onoff = OnOffHelper ("ns3::Ipv4RawSocketFactory", dst); onoff.SetConstantRate (DataRate (5000)); ApplicationContainer apps = onoff.Install (c.Get (0)); apps.Start (Seconds (1.0)); apps.Stop (Seconds (10.0)); PacketSinkHelper sink = PacketSinkHelper ("ns3::Ipv4RawSocketFactory", dst); apps = sink.Install (c.Get (3)); apps.Start (Seconds (0.0)); apps.Stop (Seconds (12.0)); // Trace receptions Config::ConnectWithoutContext ("/NodeList/3/ApplicationList/0/$ns3::PacketSink/Rx", MakeCallback (&CsmaRawIpSocketTestCase::SinkRx, this)); Simulator::Run (); Simulator::Destroy (); // We should have sent and received 10 packets NS_TEST_ASSERT_MSG_EQ (m_count, 10, "Node 3 should have received 10 packets"); }
void AodvExample::InstallInternetStack () { AodvHelper aodv; // you can configure AODV attributes here using aodv.Set(name, value) InternetStackHelper stack; stack.SetRoutingHelper (aodv); // has effect on the next Install () stack.Install (nodes); Ipv4AddressHelper address; address.SetBase ("10.0.0.0", "255.0.0.0"); interfaces = address.Assign (devices); if (printRoutes) { Ptr<OutputStreamWrapper> routingStream = Create<OutputStreamWrapper> ("aodv.routes", std::ios::out); aodv.PrintRoutingTableAllAt (Seconds (8), routingStream); } }
int main (int argc, char *argv[]) { Time::SetResolution (Time::NS); LogComponentEnable ("UdpEchoClientApplication", LOG_LEVEL_INFO); LogComponentEnable ("UdpEchoServerApplication", LOG_LEVEL_INFO); NodeContainer nodes; nodes.Create (2); PointToPointHelper pointToPoint; pointToPoint.SetDeviceAttribute ("DataRate", StringValue ("5Mbps")); pointToPoint.SetChannelAttribute ("Delay", StringValue ("2ms")); NetDeviceContainer devices; devices = pointToPoint.Install (nodes); InternetStackHelper stack; stack.Install (nodes); Ipv4AddressHelper address; address.SetBase ("10.1.1.0", "255.255.255.0"); Ipv4InterfaceContainer interfaces = address.Assign (devices); UdpEchoServerHelper echoServer (9); ApplicationContainer serverApps = echoServer.Install (nodes.Get (1)); serverApps.Start (Seconds (1.0)); serverApps.Stop (Seconds (10.0)); UdpEchoClientHelper echoClient (interfaces.GetAddress (1), 9); echoClient.SetAttribute ("MaxPackets", UintegerValue (1)); echoClient.SetAttribute ("Interval", TimeValue (Seconds (1.0))); echoClient.SetAttribute ("PacketSize", UintegerValue (1024)); ApplicationContainer clientApps = echoClient.Install (nodes.Get (0)); clientApps.Start (Seconds (2.0)); clientApps.Stop (Seconds (10.0)); Simulator::Run (); Simulator::Destroy (); return 0; }
int main (int argc, char *argv[]) { GlobalValue::Bind ("ChecksumEnabled", BooleanValue (true)); uint16_t sinkPort = 8000; uint32_t packetSize = 10000; // bytes std::string dataRate("10Mb/s"); NS_LOG_INFO ("Create Node"); NodeContainer nodes; nodes.Create (2); NS_LOG_INFO ("Create Device"); FdNetDeviceHelper fd; NetDeviceContainer devices = fd.Install (nodes); int sv[2]; if (socketpair (AF_UNIX, SOCK_DGRAM, 0, sv) < 0) { NS_FATAL_ERROR ("Error creating pipe=" << strerror (errno)); } Ptr<NetDevice> d1 = devices.Get (0); Ptr<FdNetDevice> clientDevice = d1->GetObject<FdNetDevice> (); clientDevice->SetFileDescriptor (sv[0]); Ptr<NetDevice> d2 = devices.Get (1); Ptr<FdNetDevice> serverDevice = d2->GetObject<FdNetDevice> (); serverDevice->SetFileDescriptor (sv[1]); NS_LOG_INFO ("Add Internet Stack"); InternetStackHelper internetStackHelper; internetStackHelper.SetIpv4StackInstall(true); internetStackHelper.Install (nodes); NS_LOG_INFO ("Create IPv4 Interface"); Ipv4AddressHelper addresses; addresses.SetBase ("10.0.0.0", "255.255.255.0"); Ipv4InterfaceContainer interfaces = addresses.Assign (devices); Ptr<Node> clientNode = nodes.Get (0); Ipv4Address serverIp = interfaces.GetAddress (1); Ptr<Node> serverNode = nodes.Get (1); // server Address sinkLocalAddress (InetSocketAddress (serverIp, sinkPort)); PacketSinkHelper sinkHelper ("ns3::TcpSocketFactory", sinkLocalAddress); ApplicationContainer sinkApp = sinkHelper.Install (serverNode); sinkApp.Start (Seconds (0.0)); sinkApp.Stop (Seconds (30.0)); fd.EnablePcap ("fd2fd-onoff-server", serverDevice); // client AddressValue serverAddress (InetSocketAddress (serverIp, sinkPort)); OnOffHelper onoff ("ns3::TcpSocketFactory", Address ()); onoff.SetAttribute ("Remote", serverAddress); onoff.SetAttribute ("OnTime", StringValue ("ns3::ConstantRandomVariable[Constant=1]")); onoff.SetAttribute ("OffTime", StringValue ("ns3::ConstantRandomVariable[Constant=0]")); onoff.SetAttribute ("DataRate", DataRateValue (dataRate)); onoff.SetAttribute ("PacketSize", UintegerValue (packetSize)); ApplicationContainer clientApps = onoff.Install (clientNode); clientApps.Start (Seconds (2.0)); clientApps.Stop (Seconds (29.0)); fd.EnablePcap ("fd2fd-onoff-client", clientDevice); Simulator::Stop (Seconds (30.0)); Simulator::Run (); Simulator::Destroy (); }
void Ns3TcpNoDelayTestCase::DoRun (void) { uint16_t sinkPort = 50000; double sinkStopTime = 8; // sec; will trigger Socket::Close double writerStopTime = 5; // sec; will trigger Socket::Close double simStopTime = 10; // sec Time sinkStopTimeObj = Seconds (sinkStopTime); Time writerStopTimeObj = Seconds (writerStopTime); Time simStopTimeObj= Seconds (simStopTime); Ptr<Node> n0 = CreateObject<Node> (); Ptr<Node> n1 = CreateObject<Node> (); PointToPointHelper pointToPoint; pointToPoint.SetDeviceAttribute ("DataRate", StringValue ("5Mbps")); pointToPoint.SetChannelAttribute ("Delay", StringValue ("2ms")); NetDeviceContainer devices; devices = pointToPoint.Install (n0, n1); InternetStackHelper internet; internet.InstallAll (); Ipv4AddressHelper address; address.SetBase ("10.1.1.0", "255.255.255.252"); Ipv4InterfaceContainer ifContainer = address.Assign (devices); Ptr<SocketWriter> socketWriter = CreateObject<SocketWriter> (); Address sinkAddress (InetSocketAddress (ifContainer.GetAddress (1), sinkPort)); socketWriter->Setup (n0, sinkAddress); n0->AddApplication (socketWriter); socketWriter->SetStartTime (Seconds (0.)); socketWriter->SetStopTime (writerStopTimeObj); PacketSinkHelper sink ("ns3::TcpSocketFactory", InetSocketAddress (Ipv4Address::GetAny (), sinkPort)); ApplicationContainer apps = sink.Install (n1); // Start the sink application at time zero, and stop it at sinkStopTime apps.Start (Seconds (0.0)); apps.Stop (sinkStopTimeObj); Config::Connect ("/NodeList/*/ApplicationList/*/$ns3::PacketSink/Rx", MakeCallback (&Ns3TcpNoDelayTestCase::SinkRx, this)); // Enable or disable TCP no delay option Config::SetDefault ("ns3::TcpSocket::TcpNoDelay", BooleanValue (m_noDelay)); // Connect the socket writer Simulator::Schedule (Seconds (1), &SocketWriter::Connect, socketWriter); // Write 5 packets to get some bytes in flight and some acks going Simulator::Schedule (Seconds (2), &SocketWriter::Write, socketWriter, 2680); m_inputs.Add (536); m_inputs.Add (536); m_inputs.Add (536); m_inputs.Add (536); m_inputs.Add (536); // Write one byte after 10 ms to ensure that some data is outstanding // and the window is big enough Simulator::Schedule (Seconds (2.010), &SocketWriter::Write, socketWriter, 1); // If Nagle is not enabled, i.e. no delay is on, add an input for a 1-byte // packet to be received if (m_noDelay) { m_inputs.Add (1); } // One ms later, write 535 bytes, i.e. one segment size - 1 Simulator::Schedule (Seconds (2.012), &SocketWriter::Write, socketWriter, 535); // If Nagle is not enabled, add an input for a 535 byte packet, // otherwise, we should get a single "full" packet of 536 bytes if (m_noDelay) { m_inputs.Add (535); } else { m_inputs.Add (536); } // Close down the socket Simulator::Schedule (writerStopTimeObj, &SocketWriter::Close, socketWriter); if (m_writeResults) { std::ostringstream oss; if (m_noDelay) { oss << "tcp-no-delay-on-test-case"; pointToPoint.EnablePcapAll (oss.str ()); } else { oss << "tcp-no-delay-off-test-case"; pointToPoint.EnablePcapAll (oss.str ()); } } Simulator::Stop (simStopTimeObj); Simulator::Run (); Simulator::Destroy (); // Compare inputs and outputs NS_TEST_ASSERT_MSG_EQ (m_inputs.GetN (), m_responses.GetN (), "Incorrect number of expected receive events"); for (uint32_t i = 0; i < m_responses.GetN (); i++) { uint32_t in = m_inputs.Get (i); uint32_t out = m_responses.Get (i); NS_TEST_ASSERT_MSG_EQ (in, out, "Mismatch: expected " << in << " bytes, got " << out << " bytes"); } }
// Network topology (default) // // n2 + + n3 . // | ... |\ /| ... | . // ======= \ / ======= . // CSMA \ / CSMA . // \ / . // n1 +--- n0 ---+ n4 . // | ... | / \ | ... | . // ======= / \ ======= . // CSMA / \ CSMA . // / \ . // n6 + + n5 . // | ... | | ... | . // ======= ======= . // CSMA CSMA . // void CsmaStarTestCase::DoRun (void) { // // Default number of nodes in the star. // uint32_t nSpokes = 7; CsmaHelper csma; csma.SetChannelAttribute ("DataRate", StringValue ("100Mbps")); csma.SetChannelAttribute ("Delay", StringValue ("1ms")); CsmaStarHelper star (nSpokes, csma); NodeContainer fillNodes; // // Just to be nasy, hang some more nodes off of the CSMA channel for each // spoke, so that there are a total of 16 nodes on each channel. Stash // all of these new devices into a container. // NetDeviceContainer fillDevices; uint32_t nFill = 14; for (uint32_t i = 0; i < star.GetSpokeDevices ().GetN (); ++i) { Ptr<Channel> channel = star.GetSpokeDevices ().Get (i)->GetChannel (); Ptr<CsmaChannel> csmaChannel = channel->GetObject<CsmaChannel> (); NodeContainer newNodes; newNodes.Create (nFill); fillNodes.Add (newNodes); fillDevices.Add (csma.Install (newNodes, csmaChannel)); } InternetStackHelper internet; star.InstallStack (internet); internet.Install (fillNodes); star.AssignIpv4Addresses (Ipv4AddressHelper ("10.1.0.0", "255.255.255.0")); // // We assigned addresses to the logical hub and the first "drop" of the // CSMA network that acts as the spoke, but we also have a number of fill // devices (nFill) also hanging off the CSMA network. We have got to // assign addresses to them as well. We put all of the fill devices into // a single device container, so the first nFill devices are associated // with the channel connected to spokeDevices.Get (0), the second nFill // devices afe associated with the channel connected to spokeDevices.Get (1) // etc. // Ipv4AddressHelper address; for(uint32_t i = 0; i < star.SpokeCount (); ++i) { std::ostringstream subnet; subnet << "10.1." << i << ".0"; address.SetBase (subnet.str ().c_str (), "255.255.255.0", "0.0.0.3"); for (uint32_t j = 0; j < nFill; ++j) { address.Assign (fillDevices.Get (i * nFill + j)); } } // // Create a packet sink on the star "hub" to receive packets. // uint16_t port = 50000; Address hubLocalAddress (InetSocketAddress (Ipv4Address::GetAny (), port)); PacketSinkHelper packetSinkHelper ("ns3::TcpSocketFactory", hubLocalAddress); ApplicationContainer hubApp = packetSinkHelper.Install (star.GetHub ()); hubApp.Start (Seconds (1.0)); hubApp.Stop (Seconds (10.0)); // // Create OnOff applications to send TCP to the hub, one on each spoke node. // // Make packets be sent about every DefaultPacketSize / DataRate = // 4096 bits / (5000 bits/second) = 0.82 second. OnOffHelper onOffHelper ("ns3::TcpSocketFactory", Address ()); onOffHelper.SetConstantRate (DataRate (5000)); ApplicationContainer spokeApps; for (uint32_t i = 0; i < star.SpokeCount (); ++i) { AddressValue remoteAddress (InetSocketAddress (star.GetHubIpv4Address (i), port)); onOffHelper.SetAttribute ("Remote", remoteAddress); spokeApps.Add (onOffHelper.Install (star.GetSpokeNode (i))); } spokeApps.Start (Seconds (1.0)); spokeApps.Stop (Seconds (10.0)); // // Because we are evil, we also add OnOff applications to send TCP to the hub // from the fill devices on each CSMA link. The first nFill nodes in the // fillNodes container are on the CSMA network talking to the zeroth device // on the hub node. The next nFill nodes are on the CSMA network talking to // the first device on the hub node, etc. So the ith fillNode is associated // with the hub address found on the (i / nFill)th device on the hub node. // ApplicationContainer fillApps; for (uint32_t i = 0; i < fillNodes.GetN (); ++i) { AddressValue remoteAddress (InetSocketAddress (star.GetHubIpv4Address (i / nFill), port)); onOffHelper.SetAttribute ("Remote", remoteAddress); fillApps.Add (onOffHelper.Install (fillNodes.Get (i))); } fillApps.Start (Seconds (1.0)); fillApps.Stop (Seconds (10.0)); // // Turn on global static routing so we can actually be routed across the star. // Ipv4GlobalRoutingHelper::PopulateRoutingTables (); // Trace receptions Config::ConnectWithoutContext ("/NodeList/0/ApplicationList/*/$ns3::PacketSink/Rx", MakeCallback (&CsmaStarTestCase::SinkRx, this)); Simulator::Run (); Simulator::Destroy (); // The hub node should have received 10 packets from the nFill + 1 // nodes on each spoke. NS_TEST_ASSERT_MSG_EQ (m_count, 10 * ( nSpokes * (nFill + 1)), "Hub node did not receive the proper number of packets"); }
void part2() { cout << "Seting up Part B with C" << endl; string rateHR = "100Mbps"; //data rate b/w hosts and routers string latencyHR = "20ms"; //latency b/w hosts and routers string rateRR = "10Mbps"; //data rate b/w routers string latencyRR = "50ms"; //latenc b/w routers uint32_t packetSize = 1.2*1024; //1.2KB uint32_t queueSizeHR = (100000*20)/packetSize; //100Mbps uint32_t queueSizeRR = (10000*50)/packetSize; //10Mbps uint32_t numSender = 3; double errorP = 0.000001; Config::SetDefault("ns3::DropTailQueue::Mode", StringValue("QUEUE_MODE_PACKETS")); //Creating channel without IP address PointToPointHelper p2pHR, p2pRR; p2pHR.SetDeviceAttribute("DataRate", StringValue(rateHR)); p2pHR.SetChannelAttribute("Delay", StringValue(latencyHR)); p2pHR.SetQueue("ns3::DropTailQueue", "MaxPackets", UintegerValue(queueSizeHR)); p2pRR.SetDeviceAttribute("DataRate", StringValue(rateRR)); p2pRR.SetChannelAttribute("Delay", StringValue(latencyRR)); p2pRR.SetQueue("ns3::DropTailQueue", "MaxPackets", UintegerValue(queueSizeRR)); //Adding some errorrate Ptr<RateErrorModel> em = CreateObjectWithAttributes<RateErrorModel> ("ErrorRate", DoubleValue (errorP)); //create nodes(routers, senders and recievers) NodeContainer routers, senders, recievers; routers.Create(2); senders.Create(numSender); recievers.Create(numSender); NetDeviceContainer routerDevices = p2pRR.Install(routers); NetDeviceContainer leftRouterDevices, rightRouterDevices, senderDevices, recieverDevices; //Adding links for(uint32_t i = 0; i < numSender; ++i) { NetDeviceContainer cleft = p2pHR.Install(routers.Get(0), senders.Get(i)); leftRouterDevices.Add(cleft.Get(0)); senderDevices.Add(cleft.Get(1)); cleft.Get(0)->SetAttribute("ReceiveErrorModel", PointerValue(em)); NetDeviceContainer cright = p2pHR.Install(routers.Get(1), recievers.Get(i)); rightRouterDevices.Add(cright.Get(0)); recieverDevices.Add(cright.Get(1)); cright.Get(0)->SetAttribute("ReceiveErrorModel", PointerValue(em)); } //Install Internet Stack InternetStackHelper stack; stack.Install(routers); stack.Install(senders); stack.Install(recievers); //Adding IP addresses Ipv4AddressHelper routerIP = Ipv4AddressHelper("10.3.0.0", "255.255.255.0"); Ipv4AddressHelper senderIP = Ipv4AddressHelper("10.1.0.0", "255.255.255.0"); Ipv4AddressHelper recieverIP = Ipv4AddressHelper("10.2.0.0", "255.255.255.0"); Ipv4InterfaceContainer routerIFC, senderIFCs, recieverIFCs, leftRouterIFCs, rightRouterIFCs; routerIFC = routerIP.Assign(routerDevices); for(uint32_t i = 0; i < numSender; ++i) { NetDeviceContainer senderDevice; senderDevice.Add(senderDevices.Get(i)); senderDevice.Add(leftRouterDevices.Get(i)); Ipv4InterfaceContainer senderIFC = senderIP.Assign(senderDevice); senderIFCs.Add(senderIFC.Get(0)); leftRouterIFCs.Add(senderIFC.Get(1)); senderIP.NewNetwork(); NetDeviceContainer recieverDevice; recieverDevice.Add(recieverDevices.Get(i)); recieverDevice.Add(rightRouterDevices.Get(i)); Ipv4InterfaceContainer recieverIFC = recieverIP.Assign(recieverDevice); recieverIFCs.Add(recieverIFC.Get(0)); rightRouterIFCs.Add(recieverIFC.Get(1)); recieverIP.NewNetwork(); } /******************************************************************** PART (2) start 2 other flows while one is progress -> measure throughput and CWND of each flow at steady state -> Also find the max throuhput per flow ********************************************************************/ cout << "Part B Starting" << endl; double durationGap = 100; double oneFlowStart = 0; double otherFlowStart = 20; uint32_t port = 9000; uint32_t numPackets = 10000000; string transferSpeed = "400Mbps"; //TCP Reno from H1 to H4 cout << "Flow from H1 -> H4 : TcpReno" << endl; cout << "Writing to app6_h1_h4_b.cwnd (congestion window) and app6_h1_h4_b.tp (throughput)" << endl; AsciiTraceHelper asciiTraceHelper; Ptr<OutputStreamWrapper> stream1CWND = asciiTraceHelper.CreateFileStream("app6_h1_h4_b.cwnd"); Ptr<OutputStreamWrapper> stream1PD = asciiTraceHelper.CreateFileStream("app6_h1_h4_b.congestion_loss"); Ptr<OutputStreamWrapper> stream1TP = asciiTraceHelper.CreateFileStream("app6_h1_h4_b.tp"); Ptr<OutputStreamWrapper> stream1GP = asciiTraceHelper.CreateFileStream("app6_h1_h4_b.gp"); Ptr<Socket> ns3TcpSocket1 = uniFlow(InetSocketAddress(recieverIFCs.GetAddress(0), port), port, "TcpReno", senders.Get(0), recievers.Get(0), oneFlowStart, oneFlowStart+durationGap, packetSize, numPackets, transferSpeed, oneFlowStart, oneFlowStart+durationGap); ns3TcpSocket1->TraceConnectWithoutContext("CongestionWindow", MakeBoundCallback (&CwndChange, stream1CWND, 0)); ns3TcpSocket1->TraceConnectWithoutContext("Drop", MakeBoundCallback (&packetDrop, stream1PD, 0, 1)); std::string sink_ = "/NodeList/5/ApplicationList/0/$ns3::PacketSink/Rx"; Config::Connect(sink_, MakeBoundCallback(&ReceivedPacket, stream1TP, oneFlowStart)); std::string sink = "/NodeList/5/ApplicationList/0/$ns3::PacketSink/Rx"; Config::Connect(sink, MakeBoundCallback(&ReceivedPacket, stream1GP, 0)); //TCP Tahoe from H2 to H5 cout << "Flow from H2 -> H5 : TcpTahoe" << endl; cout << "Writing to app6_h2_h5_b.cwnd (congestion window) and app6_h2_h5_b.tp (throughput)" << endl; Ptr<OutputStreamWrapper> stream2CWND = asciiTraceHelper.CreateFileStream("app6_h2_h5_b.cwnd"); Ptr<OutputStreamWrapper> stream2PD = asciiTraceHelper.CreateFileStream("app6_h2_h5_b.congestion_loss"); Ptr<OutputStreamWrapper> stream2TP = asciiTraceHelper.CreateFileStream("app6_h2_h5_b.tp"); Ptr<OutputStreamWrapper> stream2GP = asciiTraceHelper.CreateFileStream("app6_h2_h5_b.gp"); Ptr<Socket> ns3TcpSocket2 = uniFlow(InetSocketAddress(recieverIFCs.GetAddress(1), port), port, "TcpTahoe", senders.Get(1), recievers.Get(1), otherFlowStart, otherFlowStart+durationGap, packetSize, numPackets, transferSpeed, otherFlowStart, otherFlowStart+durationGap); ns3TcpSocket2->TraceConnectWithoutContext("CongestionWindow", MakeBoundCallback (&CwndChange, stream2CWND, 0)); ns3TcpSocket2->TraceConnectWithoutContext("Drop", MakeBoundCallback (&packetDrop, stream2PD, 0, 2)); sink_ = "/NodeList/6/ApplicationList/0/$ns3::PacketSink/Rx"; Config::Connect(sink_, MakeBoundCallback(&ReceivedPacket, stream2TP, otherFlowStart)); sink = "/NodeList/6/ApplicationList/0/$ns3::PacketSink/Rx"; Config::Connect(sink, MakeBoundCallback(&ReceivedPacket, stream2GP, 0)); //TCP WestWood from H3 to H6 cout << "Flow from H3 -> H6 : TcpWestwood" << endl; cout << "Writing to app6_h3_h6_b.cwnd (congestion window) and app6_h3_h6_b.tp (throughput)" << endl; Ptr<OutputStreamWrapper> stream3CWND = asciiTraceHelper.CreateFileStream("app6_h3_h6_b.cwnd"); Ptr<OutputStreamWrapper> stream3PD = asciiTraceHelper.CreateFileStream("app6_h3_h6_b.congestion_loss"); Ptr<OutputStreamWrapper> stream3TP = asciiTraceHelper.CreateFileStream("app6_h3_h6_b.tp"); Ptr<OutputStreamWrapper> stream3GP = asciiTraceHelper.CreateFileStream("app6_h3_h6_b.gp"); Ptr<Socket> ns3TcpSocket3 = uniFlow(InetSocketAddress(recieverIFCs.GetAddress(2), port), port, "TcpWestwood", senders.Get(2), recievers.Get(2), otherFlowStart, otherFlowStart+durationGap, packetSize, numPackets, transferSpeed, otherFlowStart, otherFlowStart+durationGap); ns3TcpSocket3->TraceConnectWithoutContext("CongestionWindow", MakeBoundCallback (&CwndChange, stream3CWND, 0)); ns3TcpSocket3->TraceConnectWithoutContext("Drop", MakeBoundCallback (&packetDrop, stream3PD, 0, 3)); sink = "/NodeList/7/ApplicationList/0/$ns3::PacketSink/Rx"; Config::Connect(sink, MakeBoundCallback(&ReceivedPacket, stream3GP, 0)); sink_ = "/NodeList/7/ApplicationList/0/$ns3::PacketSink/Rx"; Config::Connect(sink_, MakeBoundCallback(&ReceivedPacket, stream3TP, otherFlowStart)); //Turning on Static Global Routing Ipv4GlobalRoutingHelper::PopulateRoutingTables(); Ptr<FlowMonitor> flowmon; FlowMonitorHelper flowmonHelper; flowmon = flowmonHelper.InstallAll(); Simulator::Stop(Seconds(durationGap+otherFlowStart)); //animation("anim4.xml", routers, senders, recievers); //animation Simulator::Run(); flowmon->CheckForLostPackets(); cout << "Part b throughput into app6_b.tp" << endl; //Ptr<OutputStreamWrapper> streamTP = asciiTraceHelper.CreateFileStream("app6_b.tp"); Ptr<Ipv4FlowClassifier> classifier = DynamicCast<Ipv4FlowClassifier>(flowmonHelper.GetClassifier()); std::map<FlowId, FlowMonitor::FlowStats> stats = flowmon->GetFlowStats(); for (std::map<FlowId, FlowMonitor::FlowStats>::const_iterator i = stats.begin(); i != stats.end(); ++i) { Ipv4FlowClassifier::FiveTuple t = classifier->FindFlow (i->first); if(t.sourceAddress == "10.1.0.1") { if(mapDrop.find(1)==mapDrop.end()) mapDrop[1] = 0; *stream1PD->GetStream() << "TcpReno Flow " << i->first << " (" << t.sourceAddress << " -> " << t.destinationAddress << ")\n"; *stream1PD->GetStream() << "Net Packet Lost: " << i->second.lostPackets << "\n"; *stream1PD->GetStream() << "Packet Lost due to buffer overflow: " << mapDrop[1] << "\n"; *stream1PD->GetStream() << "Packet Lost due to Congestion: " << i->second.lostPackets - mapDrop[1] << "\n"; *stream1PD->GetStream() << "Max throughput: " << mapMaxThroughput["/NodeList/5/$ns3::Ipv4L3Protocol/Rx"] << std::endl; } else if(t.sourceAddress == "10.1.1.1") { if(mapDrop.find(2)==mapDrop.end()) mapDrop[2] = 0; *stream2PD->GetStream() << "TcpTahoe Flow " << i->first << " (" << t.sourceAddress << " -> " << t.destinationAddress << ")\n"; *stream2PD->GetStream() << "Net Packet Lost: " << i->second.lostPackets << "\n"; *stream2PD->GetStream() << "Packet Lost due to buffer overflow: " << mapDrop[2] << "\n"; *stream2PD->GetStream() << "Packet Lost due to Congestion: " << i->second.lostPackets - mapDrop[2] << "\n"; *stream2PD->GetStream() << "Max throughput: " << mapMaxThroughput["/NodeList/6/$ns3::Ipv4L3Protocol/Rx"] << std::endl; } else if(t.sourceAddress == "10.1.2.1") { if(mapDrop.find(3)==mapDrop.end()) mapDrop[3] = 0; *stream3PD->GetStream() << "TcpWestWood Flow " << i->first << " (" << t.sourceAddress << " -> " << t.destinationAddress << ")\n"; *stream3PD->GetStream() << "Net Packet Lost: " << i->second.lostPackets << "\n"; *stream3PD->GetStream() << "Packet Lost due to buffer overflow: " << mapDrop[3] << "\n"; *stream3PD->GetStream() << "Packet Lost due to Congestion: " << i->second.lostPackets - mapDrop[3] << "\n"; *stream3PD->GetStream() << "Max throughput: " << mapMaxThroughput["/NodeList/7/$ns3::Ipv4L3Protocol/Rx"] << std::endl; } } //flowmon->SerializeToXmlFile("app6_b.flowmon", true, true); Simulator::Destroy(); }
int main (int argc, char *argv[]) { CommandLine cmd; cmd.Parse (argc, argv); // Here, we will explicitly create four nodes. NS_LOG_INFO ("Create nodes."); NodeContainer c; c.Create (4); // connect all our nodes to a shared channel. NS_LOG_INFO ("Build Topology."); CsmaHelper csma; csma.SetChannelAttribute ("DataRate", DataRateValue (DataRate (5000000))); csma.SetChannelAttribute ("Delay", TimeValue (MilliSeconds (2))); csma.SetDeviceAttribute ("EncapsulationMode", StringValue ("Llc")); NetDeviceContainer devs = csma.Install (c); // add an ip stack to all nodes. NS_LOG_INFO ("Add ip stack."); InternetStackHelper ipStack; ipStack.Install (c); // assign ip addresses NS_LOG_INFO ("Assign ip addresses."); Ipv4AddressHelper ip; ip.SetBase ("192.168.1.0", "255.255.255.0"); Ipv4InterfaceContainer addresses = ip.Assign (devs); NS_LOG_INFO ("Create Source"); Config::SetDefault ("ns3::Ipv4RawSocketImpl::Protocol", StringValue ("2")); InetSocketAddress dst = InetSocketAddress (addresses.GetAddress (3)); OnOffHelper onoff = OnOffHelper ("ns3::Ipv4RawSocketFactory", dst); onoff.SetConstantRate (DataRate (15000)); onoff.SetAttribute ("PacketSize", UintegerValue (1200)); ApplicationContainer apps = onoff.Install (c.Get (0)); apps.Start (Seconds (1.0)); apps.Stop (Seconds (10.0)); NS_LOG_INFO ("Create Sink."); PacketSinkHelper sink = PacketSinkHelper ("ns3::Ipv4RawSocketFactory", dst); apps = sink.Install (c.Get (3)); apps.Start (Seconds (0.0)); apps.Stop (Seconds (11.0)); NS_LOG_INFO ("Create pinger"); V4PingHelper ping = V4PingHelper (addresses.GetAddress (2)); NodeContainer pingers; pingers.Add (c.Get (0)); pingers.Add (c.Get (1)); pingers.Add (c.Get (3)); apps = ping.Install (pingers); apps.Start (Seconds (2.0)); apps.Stop (Seconds (5.0)); NS_LOG_INFO ("Configure Tracing."); // first, pcap tracing in non-promiscuous mode csma.EnablePcapAll ("csma-ping", false); // then, print what the packet sink receives. Config::ConnectWithoutContext ("/NodeList/3/ApplicationList/0/$ns3::PacketSink/Rx", MakeCallback (&SinkRx)); // finally, print the ping rtts. Config::Connect ("/NodeList/*/ApplicationList/*/$ns3::V4Ping/Rtt", MakeCallback (&PingRtt)); Packet::EnablePrinting (); NS_LOG_INFO ("Run Simulation."); Simulator::Run (); Simulator::Destroy (); NS_LOG_INFO ("Done."); }
int main (int argc, char *argv[]) { uint32_t nWifis = 2; uint32_t nStas = 2; bool sendIp = true; bool writeMobility = false; CommandLine cmd; cmd.AddValue ("nWifis", "Number of wifi networks", nWifis); cmd.AddValue ("nStas", "Number of stations per wifi network", nStas); cmd.AddValue ("SendIp", "Send Ipv4 or raw packets", sendIp); cmd.AddValue ("writeMobility", "Write mobility trace", writeMobility); cmd.Parse (argc, argv); NodeContainer backboneNodes; NetDeviceContainer backboneDevices; Ipv4InterfaceContainer backboneInterfaces; std::vector<NodeContainer> staNodes; std::vector<NetDeviceContainer> staDevices; std::vector<NetDeviceContainer> apDevices; std::vector<Ipv4InterfaceContainer> staInterfaces; std::vector<Ipv4InterfaceContainer> apInterfaces; InternetStackHelper stack; CsmaHelper csma; Ipv4AddressHelper ip; ip.SetBase ("192.168.0.0", "255.255.255.0"); backboneNodes.Create (nWifis); stack.Install (backboneNodes); backboneDevices = csma.Install (backboneNodes); double wifiX = 0.0; YansWifiPhyHelper wifiPhy = YansWifiPhyHelper::Default (); wifiPhy.SetPcapDataLinkType (YansWifiPhyHelper::DLT_IEEE802_11_RADIO); for (uint32_t i = 0; i < nWifis; ++i) { // calculate ssid for wifi subnetwork std::ostringstream oss; oss << "wifi-default-" << i; Ssid ssid = Ssid (oss.str ()); NodeContainer sta; NetDeviceContainer staDev; NetDeviceContainer apDev; Ipv4InterfaceContainer staInterface; Ipv4InterfaceContainer apInterface; MobilityHelper mobility; BridgeHelper bridge; WifiHelper wifi = WifiHelper::Default (); NqosWifiMacHelper wifiMac = NqosWifiMacHelper::Default (); YansWifiChannelHelper wifiChannel = YansWifiChannelHelper::Default (); wifiPhy.SetChannel (wifiChannel.Create ()); sta.Create (nStas); mobility.SetPositionAllocator ("ns3::GridPositionAllocator", "MinX", DoubleValue (wifiX), "MinY", DoubleValue (0.0), "DeltaX", DoubleValue (5.0), "DeltaY", DoubleValue (5.0), "GridWidth", UintegerValue (1), "LayoutType", StringValue ("RowFirst")); // setup the AP. mobility.SetMobilityModel ("ns3::ConstantPositionMobilityModel"); mobility.Install (backboneNodes.Get (i)); wifiMac.SetType ("ns3::ApWifiMac", "Ssid", SsidValue (ssid)); apDev = wifi.Install (wifiPhy, wifiMac, backboneNodes.Get (i)); NetDeviceContainer bridgeDev; bridgeDev = bridge.Install (backboneNodes.Get (i), NetDeviceContainer (apDev, backboneDevices.Get (i))); // assign AP IP address to bridge, not wifi apInterface = ip.Assign (bridgeDev); // setup the STAs stack.Install (sta); mobility.SetMobilityModel ("ns3::RandomWalk2dMobilityModel", "Mode", StringValue ("Time"), "Time", StringValue ("2s"), "Speed", StringValue ("ns3::ConstantRandomVariable[Constant=1.0]"), "Bounds", RectangleValue (Rectangle (wifiX, wifiX+5.0,0.0, (nStas+1)*5.0))); mobility.Install (sta); wifiMac.SetType ("ns3::StaWifiMac", "Ssid", SsidValue (ssid), "ActiveProbing", BooleanValue (false)); staDev = wifi.Install (wifiPhy, wifiMac, sta); staInterface = ip.Assign (staDev); // save everything in containers. staNodes.push_back (sta); apDevices.push_back (apDev); apInterfaces.push_back (apInterface); staDevices.push_back (staDev); staInterfaces.push_back (staInterface); wifiX += 20.0; } Address dest; std::string protocol; if (sendIp) { dest = InetSocketAddress (staInterfaces[1].GetAddress (1), 1025); protocol = "ns3::UdpSocketFactory"; } else { PacketSocketAddress tmp; tmp.SetSingleDevice (staDevices[0].Get (0)->GetIfIndex ()); tmp.SetPhysicalAddress (staDevices[1].Get (0)->GetAddress ()); tmp.SetProtocol (0x807); dest = tmp; protocol = "ns3::PacketSocketFactory"; } OnOffHelper onoff = OnOffHelper (protocol, dest); onoff.SetConstantRate (DataRate ("500kb/s")); ApplicationContainer apps = onoff.Install (staNodes[0].Get (0)); apps.Start (Seconds (0.5)); apps.Stop (Seconds (3.0)); wifiPhy.EnablePcap ("wifi-wired-bridging", apDevices[0]); wifiPhy.EnablePcap ("wifi-wired-bridging", apDevices[1]); if (writeMobility) { AsciiTraceHelper ascii; MobilityHelper::EnableAsciiAll (ascii.CreateFileStream ("wifi-wired-bridging.mob")); } Simulator::Stop (Seconds (5.0)); Simulator::Run (); Simulator::Destroy (); }
int main (int argc, char *argv[]) { #ifdef NS3_MPI // Distributed simulation setup MpiInterface::Enable (&argc, &argv); GlobalValue::Bind ("SimulatorImplementationType", StringValue ("ns3::DistributedSimulatorImpl")); LogComponentEnable ("BriteMPITest", LOG_LEVEL_ALL); LogComponentEnable ("TcpSocketBase", LOG_LEVEL_INFO); uint32_t systemId = MpiInterface::GetSystemId (); uint32_t systemCount = MpiInterface::GetSize (); // Check for valid distributed parameters. // For just this particular example, must have 2 and only 2 Logical Processors (LPs) NS_ASSERT_MSG (systemCount == 2, "This demonstration requires 2 and only 2 logical processors."); // BRITE needs a configuration file to build its graph. By default, this // example will use the TD_ASBarabasi_RTWaxman.conf file. There are many others // which can be found in the BRITE/conf_files directory std::string confFile = "src/brite/examples/conf_files/TD_ASBarabasi_RTWaxman.conf"; bool tracing = false; bool nix = false; CommandLine cmd; cmd.AddValue ("confFile", "BRITE conf file", confFile); cmd.AddValue ("tracing", "Enable or disable ascii tracing", tracing); cmd.AddValue ("nix", "Enable or disable nix-vector routing", nix); cmd.Parse (argc,argv); // Invoke the BriteTopologyHelper and pass in a BRITE // configuration file and a seed file. This will use // BRITE to build a graph from which we can build the ns-3 topology BriteTopologyHelper bth (confFile); PointToPointHelper p2p; Ipv4StaticRoutingHelper staticRouting; Ipv4GlobalRoutingHelper globalRouting; Ipv4ListRoutingHelper listRouting; Ipv4NixVectorHelper nixRouting; InternetStackHelper stack; if (nix) { listRouting.Add (staticRouting, 0); listRouting.Add (nixRouting, 10); } else { listRouting.Add (staticRouting, 0); listRouting.Add (globalRouting, 10); } stack.SetRoutingHelper (listRouting); Ipv4AddressHelper address; address.SetBase ("10.0.0.0", "255.255.255.252"); //build topology as normal but also pass systemCount bth.BuildBriteTopology (stack, systemCount); bth.AssignIpv4Addresses (address); NS_LOG_LOGIC ("Number of AS created " << bth.GetNAs ()); uint16_t port = 5001; NodeContainer client; NodeContainer server; //For this example will use AS 0 and AS 1 which will be on seperate systems //due to the mod divide used to assign AS to system. //GetSystemNumberForAs (uint32_t) can be used to determine which system an //AS is assigned to NS_LOG_LOGIC ("AS 0 has been assigned to system " << bth.GetSystemNumberForAs (0)); NS_LOG_LOGIC ("As 1 has been assigned to system " << bth.GetSystemNumberForAs (1)); //install client node on last leaf node of AS 0 client.Add (CreateObject<Node> (0)); stack.Install (client); int numLeafNodesInAsZero = bth.GetNLeafNodesForAs (0); client.Add (bth.GetLeafNodeForAs (0, numLeafNodesInAsZero - 1)); //install server node on last leaf node on AS 1 server.Add (CreateObject<Node> (1)); stack.Install (server); int numLeafNodesInAsOne = bth.GetNLeafNodesForAs (1); server.Add (bth.GetLeafNodeForAs (1, numLeafNodesInAsOne - 1)); p2p.SetDeviceAttribute ("DataRate", StringValue ("5Mbps")); p2p.SetChannelAttribute ("Delay", StringValue ("2ms")); NetDeviceContainer p2pClientDevices; NetDeviceContainer p2pServerDevices; p2pClientDevices = p2p.Install (client); p2pServerDevices = p2p.Install (server); address.SetBase ("10.1.0.0", "255.255.0.0"); Ipv4InterfaceContainer clientInterfaces; clientInterfaces = address.Assign (p2pClientDevices); address.SetBase ("10.2.0.0", "255.255.0.0"); Ipv4InterfaceContainer serverInterfaces; serverInterfaces = address.Assign (p2pServerDevices); if (!nix) { Ipv4GlobalRoutingHelper::PopulateRoutingTables (); } //only has two systems in this example. Install applications only on nodes in my system //Moved here to get totalRX at end ApplicationContainer sinkApps; if (systemId == 1) { Address sinkLocalAddress (InetSocketAddress (Ipv4Address::GetAny (), port)); PacketSinkHelper packetSinkHelper ("ns3::TcpSocketFactory", sinkLocalAddress); sinkApps.Add (packetSinkHelper.Install (server.Get (0))); sinkApps.Start (Seconds (0.0)); sinkApps.Stop (Seconds (10.0)); } if (systemId == 0) { OnOffHelper clientHelper ("ns3::TcpSocketFactory", Address ()); clientHelper.SetAttribute ("OnTime", StringValue ("ns3::ConstantRandomVariable[Constant=1]")); clientHelper.SetAttribute ("OffTime", StringValue ("ns3::ConstantRandomVariable[Constant=0]")); ApplicationContainer clientApps; AddressValue remoteAddress (InetSocketAddress (serverInterfaces.GetAddress (0), port)); clientHelper.SetAttribute ("Remote", remoteAddress); clientApps.Add (clientHelper.Install (client.Get (0))); clientApps.Start (Seconds (1.0)); // Start 1 second after sink clientApps.Stop (Seconds (9.0)); // Stop before the sink } if (!nix) { Ipv4GlobalRoutingHelper::PopulateRoutingTables (); } if (tracing) { AsciiTraceHelper ascii; p2p.EnableAsciiAll (ascii.CreateFileStream ("briteLeaves.tr")); } // Run the simulator Simulator::Stop (Seconds (200.0)); Simulator::Run (); Simulator::Destroy (); if (systemId == 1) { Ptr<PacketSink> sink1 = DynamicCast<PacketSink> (sinkApps.Get (0)); NS_LOG_DEBUG ("Total Bytes Received: " << sink1->GetTotalRx ()); } MpiInterface::Disable (); return 0; #else NS_FATAL_ERROR ("Can't use distributed simulator without MPI compiled in"); #endif }