lte-test-deactivate-bearer.cc

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/*
 * Copyright (c) 2011, 2012 Centre Tecnologic de Telecomunicacions de Catalunya (CTTC)
 *
 * SPDX-License-Identifier: GPL-2.0-only
 *
 * Author:Gaurav Sathe <gaurav.sathe@tcs.com>
 */
 
#include "lte-test-deactivate-bearer.h"
 
#include "ns3/boolean.h"
#include "ns3/constant-position-mobility-model.h"
#include "ns3/double.h"
#include "ns3/enum.h"
#include "ns3/eps-bearer.h"
#include "ns3/internet-module.h"
#include "ns3/ipv4-global-routing-helper.h"
#include "ns3/log.h"
#include "ns3/lte-enb-net-device.h"
#include "ns3/lte-enb-phy.h"
#include "ns3/lte-helper.h"
#include "ns3/lte-ue-net-device.h"
#include "ns3/lte-ue-phy.h"
#include "ns3/lte-ue-rrc.h"
#include "ns3/mobility-helper.h"
#include "ns3/net-device-container.h"
#include "ns3/network-module.h"
#include "ns3/node-container.h"
#include "ns3/object.h"
#include "ns3/packet-sink-helper.h"
#include "ns3/packet.h"
#include "ns3/point-to-point-epc-helper.h"
#include "ns3/point-to-point-helper.h"
#include "ns3/ptr.h"
#include "ns3/radio-bearer-stats-calculator.h"
#include "ns3/rng-seed-manager.h"
#include "ns3/simulator.h"
#include "ns3/spectrum-error-model.h"
#include "ns3/spectrum-interference.h"
#include "ns3/string.h"
#include "ns3/test.h"
#include "ns3/udp-client-server-helper.h"
 
#include <iostream>
#include <sstream>
#include <string>
 
NS_LOG_COMPONENT_DEFINE("LenaTestDeactivateBearer");
 
namespace ns3
{
 
LenaTestBearerDeactivateSuite::LenaTestBearerDeactivateSuite()
    : TestSuite("lte-test-deactivate-bearer", Type::SYSTEM)
{
    NS_LOG_INFO("creating LenaTestPssFfMacSchedulerSuite");
 
    bool errorModel = false;
 
    // Test Case: homogeneous flow test in PSS (different distance)
    // Traffic1 info
    //   UDP traffic: payload size = 100 bytes, interval = 1 ms
    //   UDP rate in scheduler: (payload + RLC header + PDCP header + IP header + UDP header) * 1000
    //   byte/sec -> 132000 byte/rate
    // Maximum throughput = 3 / ( 1/2196000 + 1/1191000 + 1/1383000) = 1486569 byte/s
    // 132000 * 3 = 396000 < 1209046 -> estimated throughput in downlink = 132000 byte/sec
    std::vector<uint16_t> dist_1;
 
    dist_1.push_back(0); // User 0 distance --> MCS 28
    dist_1.push_back(0); // User 1 distance --> MCS 22
    dist_1.push_back(0); // User 2 distance --> MCS 20
 
    std::vector<uint16_t> packetSize_1;
 
    packetSize_1.push_back(100); // 1
    packetSize_1.push_back(100); // 2
    packetSize_1.push_back(100); // 3
 
    std::vector<uint32_t> estThrPssDl_1;
 
    estThrPssDl_1.push_back(132000); // User 0 estimated TTI throughput from PSS
    estThrPssDl_1.push_back(132000); // User 1 estimated TTI throughput from PSS
    estThrPssDl_1.push_back(132000); // User 2 estimated TTI throughput from PSS
 
    AddTestCase(
        new LenaDeactivateBearerTestCase(dist_1, estThrPssDl_1, packetSize_1, 1, errorModel, true),
        TestCase::Duration::QUICK);
}
 
/**
 * @ingroup lte-test
 * Static variable for test initialization
 */
static LenaTestBearerDeactivateSuite lenaTestBearerDeactivateSuite;
 
std::string
LenaDeactivateBearerTestCase::BuildNameString(uint16_t nUser, std::vector<uint16_t> dist)
{
    std::ostringstream oss;
    oss << "distances (m) = [ ";
    for (auto it = dist.begin(); it != dist.end(); ++it)
    {
        oss << *it << " ";
    }
    oss << "]";
    return oss.str();
}
 
LenaDeactivateBearerTestCase::LenaDeactivateBearerTestCase(std::vector<uint16_t> dist,
                                                           std::vector<uint32_t> estThrPssDl,
                                                           std::vector<uint16_t> packetSize,
                                                           uint16_t interval,
                                                           bool errorModelEnabled,
                                                           bool useIdealRrc)
    : TestCase(BuildNameString(dist.size(), dist)),
      m_nUser(dist.size()),
      m_dist(dist),
      m_packetSize(packetSize),
      m_interval(interval),
      m_estThrPssDl(estThrPssDl),
      m_errorModelEnabled(errorModelEnabled)
{
}
 
LenaDeactivateBearerTestCase::~LenaDeactivateBearerTestCase()
{
}
 
void
LenaDeactivateBearerTestCase::DoRun()
{
    SetDataDir(NS_TEST_SOURCEDIR);
    uint32_t originalSeed = RngSeedManager::GetSeed();
    uint32_t originalRun = RngSeedManager::GetRun();
    RngSeedManager::SetSeed(1);
    RngSeedManager::SetRun(1);
 
    if (!m_errorModelEnabled)
    {
        Config::SetDefault("ns3::LteSpectrumPhy::CtrlErrorModelEnabled", BooleanValue(false));
        Config::SetDefault("ns3::LteSpectrumPhy::DataErrorModelEnabled", BooleanValue(false));
    }
 
    Config::SetDefault("ns3::LteHelper::UseIdealRrc", BooleanValue(true));
    Config::SetDefault("ns3::RadioBearerStatsCalculator::DlRlcOutputFilename",
                       StringValue(CreateTempDirFilename("DlRlcStats.txt")));
    Config::SetDefault("ns3::RadioBearerStatsCalculator::UlRlcOutputFilename",
                       StringValue(CreateTempDirFilename("UlRlcStats.txt")));
 
    Ptr<LteHelper> lteHelper = CreateObject<LteHelper>();
    Ptr<PointToPointEpcHelper> epcHelper = CreateObject<PointToPointEpcHelper>();
    lteHelper->SetEpcHelper(epcHelper);
 
    Ptr<Node> pgw = epcHelper->GetPgwNode();
 
    // Create a single RemoteHost
    NodeContainer remoteHostContainer;
    remoteHostContainer.Create(1);
    Ptr<Node> remoteHost = remoteHostContainer.Get(0);
    InternetStackHelper internet;
    internet.Install(remoteHostContainer);
 
    // Create the Internet
    PointToPointHelper p2ph;
    p2ph.SetDeviceAttribute("DataRate", DataRateValue(DataRate("100Gb/s")));
    p2ph.SetDeviceAttribute("Mtu", UintegerValue(1500));
    p2ph.SetChannelAttribute("Delay", TimeValue(Seconds(0.001)));
    NetDeviceContainer internetDevices = p2ph.Install(pgw, remoteHost);
    Ipv4AddressHelper ipv4h;
    ipv4h.SetBase("1.0.0.0", "255.0.0.0");
    Ipv4InterfaceContainer internetIpIfaces = ipv4h.Assign(internetDevices);
    // interface 0 is localhost, 1 is the p2p device
    Ipv4Address remoteHostAddr = internetIpIfaces.GetAddress(1);
 
    Ipv4StaticRoutingHelper ipv4RoutingHelper;
    Ptr<Ipv4StaticRouting> remoteHostStaticRouting =
        ipv4RoutingHelper.GetStaticRouting(remoteHost->GetObject<Ipv4>());
    remoteHostStaticRouting->AddNetworkRouteTo(Ipv4Address("7.0.0.0"), Ipv4Mask("255.0.0.0"), 1);
 
    // LogLevel logLevel = (LogLevel)(LOG_PREFIX_FUNC | LOG_PREFIX_TIME | LOG_LEVEL_ALL);
 
    // LogComponentEnable ("LenaTestDeactivateBearer", LOG_LEVEL_ALL);
    // LogComponentEnable ("LteHelper", logLevel);
    // LogComponentEnable ("EpcHelper", logLevel);
    // LogComponentEnable ("EpcEnbApplication", logLevel);
    // LogComponentEnable ("EpcMmeApplication", logLevel);
    // LogComponentEnable ("EpcPgwApplication", logLevel);
    // LogComponentEnable ("EpcSgwApplication", logLevel);
    // LogComponentEnable ("LteEnbRrc", logLevel);
 
    lteHelper->SetAttribute("PathlossModel", StringValue("ns3::FriisSpectrumPropagationLossModel"));
 
    // Create Nodes: eNodeB and UE
    NodeContainer enbNodes;
    NodeContainer ueNodes;
    enbNodes.Create(1);
    ueNodes.Create(m_nUser);
 
    // Install Mobility Model
    MobilityHelper mobility;
    mobility.SetMobilityModel("ns3::ConstantPositionMobilityModel");
    mobility.Install(enbNodes);
    mobility.SetMobilityModel("ns3::ConstantPositionMobilityModel");
    mobility.Install(ueNodes);
 
    // Create Devices and install them in the Nodes (eNB and UE)
    NetDeviceContainer enbDevs;
    NetDeviceContainer ueDevs;
    int64_t stream = 1;
 
    lteHelper->SetSchedulerType("ns3::PssFfMacScheduler");
    enbDevs = lteHelper->InstallEnbDevice(enbNodes);
    stream += lteHelper->AssignStreams(enbDevs, stream);
 
    ueDevs = lteHelper->InstallUeDevice(ueNodes);
    stream += lteHelper->AssignStreams(ueDevs, stream);
 
    Ptr<LteEnbNetDevice> lteEnbDev = enbDevs.Get(0)->GetObject<LteEnbNetDevice>();
    Ptr<LteEnbPhy> enbPhy = lteEnbDev->GetPhy();
    enbPhy->SetAttribute("TxPower", DoubleValue(30.0));
    enbPhy->SetAttribute("NoiseFigure", DoubleValue(5.0));
 
    // Set UEs' position and power
    for (int i = 0; i < m_nUser; i++)
    {
        Ptr<ConstantPositionMobilityModel> mm =
            ueNodes.Get(i)->GetObject<ConstantPositionMobilityModel>();
        mm->SetPosition(Vector(m_dist.at(i), 0.0, 0.0));
        Ptr<LteUeNetDevice> lteUeDev = ueDevs.Get(i)->GetObject<LteUeNetDevice>();
        Ptr<LteUePhy> uePhy = lteUeDev->GetPhy();
        uePhy->SetAttribute("TxPower", DoubleValue(23.0));
        uePhy->SetAttribute("NoiseFigure", DoubleValue(9.0));
    }
 
    // Install the IP stack on the UEs
    internet.Install(ueNodes);
    Ipv4InterfaceContainer ueIpIface;
    ueIpIface = epcHelper->AssignUeIpv4Address(NetDeviceContainer(ueDevs));
 
    // Assign IP address to UEs
    for (uint32_t u = 0; u < ueNodes.GetN(); ++u)
    {
        Ptr<Node> ueNode = ueNodes.Get(u);
        // Set the default gateway for the UE
        Ptr<Ipv4StaticRouting> ueStaticRouting =
            ipv4RoutingHelper.GetStaticRouting(ueNode->GetObject<Ipv4>());
        ueStaticRouting->SetDefaultRoute(epcHelper->GetUeDefaultGatewayAddress(), 1);
    }
 
    // Attach a UE to a eNB
    lteHelper->Attach(ueDevs, enbDevs.Get(0));
 
    // Activate an EPS bearer on all UEs
 
    for (uint32_t u = 0; u < ueNodes.GetN(); ++u)
    {
        Ptr<NetDevice> ueDevice = ueDevs.Get(u);
        GbrQosInformation qos;
        qos.gbrDl = (m_packetSize.at(u) + 32) * (1000 / m_interval) *
                    8; // bit/s, considering IP, UDP, RLC, PDCP header size
        qos.gbrUl = (m_packetSize.at(u) + 32) * (1000 / m_interval) * 8;
        qos.mbrDl = qos.gbrDl;
        qos.mbrUl = qos.gbrUl;
 
        EpsBearer::Qci q = EpsBearer::GBR_CONV_VOICE;
        EpsBearer bearer(q, qos);
        bearer.arp.priorityLevel = 15 - (u + 1);
        bearer.arp.preemptionCapability = true;
        bearer.arp.preemptionVulnerability = true;
        lteHelper->ActivateDedicatedEpsBearer(ueDevice, bearer, EpcTft::Default());
    }
 
    // Install downlink and uplink applications
    uint16_t dlPort = 1234;
    uint16_t ulPort = 2000;
    PacketSinkHelper dlPacketSinkHelper("ns3::UdpSocketFactory",
                                        InetSocketAddress(Ipv4Address::GetAny(), dlPort));
    ApplicationContainer clientApps;
    ApplicationContainer serverApps;
 
    for (uint32_t u = 0; u < ueNodes.GetN(); ++u)
    {
        ++ulPort;
        serverApps.Add(
            dlPacketSinkHelper.Install(ueNodes.Get(u))); // receive packets from remotehost
        PacketSinkHelper ulPacketSinkHelper("ns3::UdpSocketFactory",
                                            InetSocketAddress(Ipv4Address::GetAny(), ulPort));
        serverApps.Add(ulPacketSinkHelper.Install(remoteHost)); // receive packets from UEs
 
        UdpClientHelper dlClient(ueIpIface.GetAddress(u), dlPort); // uplink packets generator
        dlClient.SetAttribute("Interval", TimeValue(MilliSeconds(m_interval)));
        dlClient.SetAttribute("MaxPackets", UintegerValue(1000000));
        dlClient.SetAttribute("PacketSize", UintegerValue(m_packetSize.at(u)));
 
        UdpClientHelper ulClient(remoteHostAddr, ulPort); // downlink packets generator
        ulClient.SetAttribute("Interval", TimeValue(MilliSeconds(m_interval)));
        ulClient.SetAttribute("MaxPackets", UintegerValue(1000000));
        ulClient.SetAttribute("PacketSize", UintegerValue(m_packetSize.at(u)));
 
        clientApps.Add(dlClient.Install(remoteHost));
        clientApps.Add(ulClient.Install(ueNodes.Get(u)));
    }
 
    serverApps.Start(Seconds(0.030));
    clientApps.Start(Seconds(0.030));
 
    double statsStartTime = 0.04; // need to allow for RRC connection establishment + SRS
    double statsDuration = 1.0;
    double tolerance = 0.1;
 
    lteHelper->EnableRlcTraces();
    Ptr<RadioBearerStatsCalculator> rlcStats = lteHelper->GetRlcStats();
    rlcStats->SetAttribute("StartTime", TimeValue(Seconds(statsStartTime)));
    rlcStats->SetAttribute("EpochDuration", TimeValue(Seconds(statsDuration)));
 
    // get ue device pointer for UE-ID 0 IMSI 1 and enb device pointer
    Ptr<NetDevice> ueDevice = ueDevs.Get(0);
    Ptr<NetDevice> enbDevice = enbDevs.Get(0);
 
    /*
     *   Instantiate De-activation using Simulator::Schedule() method which will initiate bearer
     * de-activation after deActivateTime Instantiate De-activation in sequence (Time const &time,
     * MEM mem_ptr, OBJ obj, T1 a1, T2 a2, T3 a3)
     */
    Time deActivateTime(Seconds(1.5));
    Simulator::Schedule(deActivateTime,
                        &LteHelper::DeActivateDedicatedEpsBearer,
                        lteHelper,
                        ueDevice,
                        enbDevice,
                        2);
 
    // stop simulation after 3 seconds
    Simulator::Stop(Seconds(3));
 
    Simulator::Run();
 
    NS_LOG_INFO("DL - Test with " << m_nUser << " user(s)");
    std::vector<uint64_t> dlDataRxed;
    std::vector<uint64_t> dlDataTxed;
    for (int i = 0; i < m_nUser; i++)
    {
        // get the imsi
        uint64_t imsi = ueDevs.Get(i)->GetObject<LteUeNetDevice>()->GetImsi();
        // get the lcId
        // lcId is hard-coded, since only one dedicated bearer is added
        uint8_t lcId = 4;
        dlDataRxed.push_back(rlcStats->GetDlRxData(imsi, lcId));
        dlDataTxed.push_back(rlcStats->GetDlTxData(imsi, lcId));
        NS_LOG_INFO("\tUser " << i << " dist " << m_dist.at(i) << " imsi " << imsi << " bytes rxed "
                              << (double)dlDataRxed.at(i) << "  thr "
                              << (double)dlDataRxed.at(i) / statsDuration << " ref "
                              << m_estThrPssDl.at(i));
        NS_LOG_INFO("\tUser " << i << " imsi " << imsi << " bytes txed " << (double)dlDataTxed.at(i)
                              << "  thr " << (double)dlDataTxed.at(i) / statsDuration);
    }
 
    for (int i = 0; i < m_nUser; i++)
    {
        uint64_t imsi = ueDevs.Get(i)->GetObject<LteUeNetDevice>()->GetImsi();
 
        /*
         * For UE ID-0 IMSI 1, LCID=4 is deactivated hence If traffic seen on it, test case should
         * fail Else For other UE's, test case should validate throughput
         */
        if (imsi == 1)
        {
            NS_TEST_ASSERT_MSG_EQ((double)dlDataTxed.at(i), 0, "Invalid LCID in Statistics ");
        }
        else
        {
            NS_TEST_ASSERT_MSG_EQ_TOL((double)dlDataTxed.at(i) / statsDuration,
                                      m_estThrPssDl.at(i),
                                      m_estThrPssDl.at(i) * tolerance,
                                      " Unfair Throughput!");
        }
    }
 
    Simulator::Destroy();
 
    RngSeedManager::SetSeed(originalSeed);
    RngSeedManager::SetRun(originalRun);
}
} // namespace ns3