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Debug+Do Simulations

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Loic Guegan 2019-04-26 11:13:36 +02:00
parent 79ef212a8c
commit 89d815f81e
70 changed files with 190288 additions and 312708 deletions
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12
ns3-simulations/simulator/modules/callbacks.cc Normal file
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#include "modules.hpp"
void PktReceived(std::string nodeName,Ptr< const Packet > packet, const Address &address){
NS_LOG_UNCOND("Node " << nodeName << " receive a packet" << " at time " << Simulator::Now ().GetSeconds () << "s");
}
void EnergyUpdated(std::string nodeName,double oldValue, double newValue){
double currentTime=Simulator::Now ().GetSeconds ();
double energyConsumes=newValue-oldValue;
NS_LOG_UNCOND("Node " << nodeName << " consumes " << energyConsumes << "J" << " at time " << currentTime << "s");
}

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ns3-simulations/simulator/modules/energy.cc Normal file
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#include "modules.hpp"
void setupCellEnergy(Cell cell){
NodeContainer nodes(cell.first.first,cell.first.second);
NetDeviceContainer nodesNetDev(cell.second.first,cell.second.second);
// Install energy source
BasicEnergySourceHelper edgeBasicSourceHelper;
edgeBasicSourceHelper.Set ("BasicEnergySourceInitialEnergyJ", DoubleValue (BASICENERGYSOURCEINITIALENERGYJ));
edgeBasicSourceHelper.Set ("BasicEnergySupplyVoltageV", DoubleValue (BASICENERGYSUPPLYVOLTAGEV));
EnergySourceContainer apEdgeNodesSources = edgeBasicSourceHelper.Install (cell.first.first);
EnergySourceContainer wifiEdgeNodesSources = edgeBasicSourceHelper.Install (cell.first.second);
// Install device energy model
WifiRadioEnergyModelHelper radioEnergyHelper;
radioEnergyHelper.Set ("TxCurrentA", DoubleValue (TXCURRENTA));
radioEnergyHelper.Set ("RxCurrentA", DoubleValue (RXCURRENTA));
radioEnergyHelper.Set ("IdleCurrentA", DoubleValue (IDLECURRENTA));
DeviceEnergyModelContainer edgeApDeviceModels = radioEnergyHelper.Install (cell.second.first, apEdgeNodesSources);
DeviceEnergyModelContainer edgeDeviceModels = radioEnergyHelper.Install (cell.second.second, wifiEdgeNodesSources);
// Trace
DeviceEnergyModelContainer::Iterator it=edgeDeviceModels.Begin();
int i=1; // Node 0 will be AP, other node will have negative id (cf following while)
// This is usefull in logs, in fact ECOFEN nodes will have positive ID and WIFI energy nodes negative id
// AP will have id 0 in ECOFEN and WIFI (in order to combine their energy value when parsing logs
while(it!=edgeDeviceModels.End()){
(*it)->TraceConnect ("TotalEnergyConsumption", std::to_string(0-i),MakeCallback (&EnergyUpdated));
it++;
i++;
}
// AP will have id 0
(*edgeApDeviceModels.Begin())->TraceConnect ("TotalEnergyConsumption", std::to_string(0),MakeCallback (&EnergyUpdated));
// Ptr<BasicEnergySource> basicSourcePtr0 = DynamicCast<BasicEnergySource> (wifiEdgeNodesSources.Get (0));
// //basicSourcePtr0->TraceConnectWithoutContext ("RemainingEnergy", MakeCallback (&RemainingEnergy));
// //device energy model
// Ptr<DeviceEnergyModel> basicRadioModelPtr0 =
// basicSourcePtr0->FindDeviceEnergyModels ("ns3::WifiRadioEnergyModel").Get (0);
// NS_ASSERT (basicRadioModelPtr0 != NULL);
// basicRadioModelPtr0->TraceConnectWithoutContext ("TotalEnergyConsumption", MakeCallback (&TotalEnergy));
}
void setupCloudEnergy(CloudInfos cloudInfos){
NodeContainer cloudNodes=cloudInfos.first;
// Install basic energy
ns3::BasicNodeEnergyHelper basicNodeEnergy;
basicNodeEnergy.Set("OnConso", ns3::DoubleValue (ONCONSO));
basicNodeEnergy.Set("OffConso", ns3::DoubleValue (OFFCONSO));
basicNodeEnergy.Install (cloudNodes);
ns3::CompleteNetdeviceEnergyHelper completeNetdeviceEnergy;
completeNetdeviceEnergy.Set ("OffConso", ns3::DoubleValue (OFFCONSO));
completeNetdeviceEnergy.Set ("IdleConso", ns3::DoubleValue (IDLECONSO));
completeNetdeviceEnergy.Set ("RecvByteEnergy", ns3::DoubleValue (RECVBYTEENERGY));
completeNetdeviceEnergy.Set ("SentByteEnergy", ns3::DoubleValue (SENTBYTEENERGY));
completeNetdeviceEnergy.Set ("RecvPktEnergy", ns3::DoubleValue (RECVPKTENERGY));
completeNetdeviceEnergy.Set ("SentPktEnergy", ns3::DoubleValue (SENTPKTENERGY));
completeNetdeviceEnergy.Install(cloudNodes);
ns3::ConsumptionLogger conso;
conso.NodeConso(ns3::Seconds (ECOFEN_LOG_EVERY), ns3::Seconds(ECOFEN_LOG_UNTIL), cloudNodes);
}

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ns3-simulations/simulator/modules/modules.hpp Normal file
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#ifndef MODULES_HPP
#define MODULES_HPP
#include "ns3/command-line.h"
#include "ns3/config.h"
#include "ns3/string.h"
#include "ns3/log.h"
#include "ns3/yans-wifi-helper.h"
#include "ns3/ssid.h"
#include "ns3/mobility-helper.h"
#include "ns3/on-off-helper.h"
#include "ns3/yans-wifi-channel.h"
#include "ns3/mobility-model.h"
#include "ns3/packet-sink.h"
#include "ns3/packet-sink-helper.h"
#include "ns3/udp-echo-helper.h"
#include "ns3/tcp-westwood.h"
#include "ns3/internet-stack-helper.h"
#include "ns3/ipv4-address-helper.h"
#include "ns3/ipv4-global-routing-helper.h"
#include "ns3/constant-position-mobility-model.h"
#include "ns3/energy-module.h"
#include "ns3/wifi-radio-energy-model-helper.h"
#include "ns3/point-to-point-helper.h"
#include "ns3/ecofen-module.h"
#include "ns3/node-list.h"
#include "ns3/flow-monitor-module.h"
// C++ library
#include <iostream> // Why not ?
#include <utility> // To use std::pair
#include <iomanip> // To use std::setw
// ECOFEN
#define ECOFEN_LOG_UNTIL 100
#define ECOFEN_LOG_EVERY 0.1
// WIFI Energy Values
#define BASICENERGYSOURCEINITIALENERGYJ 10
#define BASICENERGYSUPPLYVOLTAGEV 3.3
#define TXCURRENTA 0.38
#define RXCURRENTA 0.313
#define IDLECURRENTA 0.273
// Cloud Energy Values
#define ONCONSO 0
#define OFFCONSO 0
#define IDLECONSO 1
#define RECVBYTEENERGY 3.4
#define SENTBYTEENERGY 3.4
#define RECVPKTENERGY 192.2
#define SENTPKTENERGY 192.2
using namespace ns3;
// ---------- Data types ----------
typedef std::pair<NodeContainer,NodeContainer> CellNodes; // Format (APNode, SensorsNodes)
typedef std::pair<NetDeviceContainer,NetDeviceContainer> CellNetDevices; // Format (APNetDev, SensorsNetDev)
typedef std::pair<CellNodes,CellNetDevices> Cell;
typedef std::pair<Ipv4Address,int> EndPoint; // Format (IP,Port)
typedef std::pair<NodeContainer,EndPoint> CloudInfos; // Format (CloudHops,CloudEndPoint), here data sent to CloudEndPoint
// ---------- platform.cc ----------
/**
* Create a WIFI cell paltform composed of nbSensors sensors and ap as an access point
*/
Cell createCell(uint32_t nbSensors, Ptr<ns3::Node> ap);
/**
* Build P2P network composed of nbHop hops (to simulate edge->cloud communications)
* Note: Cloud Servers are not considered here and completely ignored !
*/
CloudInfos createCloud(int nbHop, uint32_t bandwidth, uint32_t latency);
/**
* Setup simulation scenario on the platforms. Sensors in cell will send packets of sensorsPktSize size every
* sensorsSensInterval second to the cloud using cloudInfos.
*/
void setupScenario(Cell cell, CloudInfos cloudInfos, int sensorsPktSize, int sensorsSendInterval);
// ---------- energy.cc ----------
/*
* Configure WIFI energy module for cell
*/
void setupCellEnergy(Cell cell);
/*
* Configure link/port energy using ecofen
*/
void setupCloudEnergy(CloudInfos cloudInfos);
// ---------- callbacks.cc ----------
void PktReceived(std::string nodeName,Ptr< const Packet > packet, const Address &address);
void EnergyUpdated(std::string nodeName,double oldValue, double newValue);
#endif

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#include "modules.hpp"
/**
* Create a sensors cell base on
* nbSensors Number of temperature sensors in the cell
* ap the Access Point (usually linked to the cloud)
*/
Cell createCell(uint32_t nbSensors, Ptr<ns3::Node> ap){
// Create sensors
NodeContainer sensors;
sensors.Create(nbSensors);
// Place nodes somehow, this is required by every wireless simulation
for (uint32_t i = 0; i < nbSensors; i++)
{
sensors.Get (i)->AggregateObject (CreateObject<ConstantPositionMobilityModel> ());
}
ap->AggregateObject (CreateObject<ConstantPositionMobilityModel> ());
// To apply XXWifiPhy and WifiMac on sensors
WifiHelper wifiHelper;
wifiHelper.SetStandard (WIFI_PHY_STANDARD_80211n_5GHZ);
/* Set up Legacy Channel */
YansWifiChannelHelper wifiChannel;
wifiChannel.SetPropagationDelay ("ns3::ConstantSpeedPropagationDelayModel");
wifiChannel.AddPropagationLoss ("ns3::FriisPropagationLossModel", "Frequency", DoubleValue (5e9));
/* Setup Physical Layer */
YansWifiPhyHelper wifiPhy = YansWifiPhyHelper::Default ();
wifiPhy.SetChannel (wifiChannel.Create ());
wifiPhy.Set ("TxPowerStart", DoubleValue (10.0));
wifiPhy.Set ("TxPowerEnd", DoubleValue (10.0));
wifiPhy.Set ("TxPowerLevels", UintegerValue (1));
wifiPhy.Set ("TxGain", DoubleValue (0));
wifiPhy.Set ("RxGain", DoubleValue (0));
wifiPhy.Set ("RxNoiseFigure", DoubleValue (10));
wifiPhy.Set ("CcaMode1Threshold", DoubleValue (-79));
wifiPhy.Set ("EnergyDetectionThreshold", DoubleValue (-79 + 3));
// wifiPhy.SetErrorRateModel ("ns3::YansErrorRateModel");
wifiHelper.SetRemoteStationManager ("ns3::ConstantRateWifiManager",
"DataMode", StringValue ("HtMcs7"),
"ControlMode", StringValue ("HtMcs0"));
/* Configure AP */
Ssid ssid = Ssid ("network");
WifiMacHelper wifiMac;
wifiMac.SetType ("ns3::ApWifiMac", "Ssid", SsidValue (ssid));
NetDeviceContainer apNetDevice;
apNetDevice = wifiHelper.Install (wifiPhy, wifiMac, ap);
/* Configure STA */
wifiMac.SetType ("ns3::StaWifiMac", "Ssid", SsidValue (ssid));
NetDeviceContainer sensorsNetDevices;
sensorsNetDevices = wifiHelper.Install (wifiPhy, wifiMac, sensors);
return(std::make_pair(std::make_pair(ap,sensors),std::make_pair(apNetDevice,sensorsNetDevices)));
}
/**
* Install network stack and applications
*/
void setupScenario(Cell cell, CloudInfos cloudInfos, int sensorsPktSize, int sensorsSendInterval){
NodeContainer ap=cell.first.first;
NodeContainer sensors=cell.first.second;
NetDeviceContainer apNetDev= cell.second.first;
NetDeviceContainer sensorsNetDev= cell.second.second;
// 6. Install TCP/IP stack & assign IP addresses
InternetStackHelper internet;
// internet.Install (ap);
internet.Install (sensors);
Ipv4AddressHelper ipv4;
ipv4.SetBase ("10.0.0.0", "255.255.0.0");
Ipv4InterfaceContainer apInt,sensorsInt;
apInt=ipv4.Assign(apNetDev);
sensorsInt=ipv4.Assign(sensorsNetDev);
UdpEchoClientHelper echoClientHelper (InetSocketAddress (cloudInfos.second.first, cloudInfos.second.second));
// echoClientHelper.SetAttribute ("MaxPackets", UintegerValue (10));
echoClientHelper.SetAttribute ("Interval", TimeValue (Seconds (sensorsSendInterval)));
echoClientHelper.SetAttribute ("PacketSize", UintegerValue (sensorsPktSize));
ApplicationContainer pingApps;
// again using different start times to workaround Bug 388 and Bug 912
echoClientHelper.SetAttribute ("StartTime", TimeValue (Seconds (1))); // Start at 1 (WIFI seems to not work when t<1)
echoClientHelper.Install (sensors);
}
CloudInfos createCloud(int nbHop, uint32_t bandwidth, uint32_t latency){
NodeContainer HopNodes;
HopNodes.Create(nbHop);
InternetStackHelper stack;
stack.Install(HopNodes);
Ipv4Address cloudIP; // Will be fill in the following for loop
int cloudPort=80;
for(int i=0;i<nbHop-1;i++){
NodeContainer curNodes(HopNodes.Get(i),HopNodes.Get(i+1));
PointToPointHelper pointToPoint;
pointToPoint.SetDeviceAttribute ("DataRate", StringValue ((std::to_string(bandwidth)+"Mbps").c_str()));
pointToPoint.SetChannelAttribute ("Delay", StringValue ((std::to_string(latency)+"ms").c_str()));
NetDeviceContainer p2pDevices;
p2pDevices = pointToPoint.Install (curNodes);
Ipv4AddressHelper address;
address.SetBase (("10."+std::to_string(i+1)+".0.0").c_str(), "255.255.0.0"); // Remember: 10.0.0.0 is used by WIFI
Ipv4InterfaceContainer p2pInterfaces;
p2pInterfaces = address.Assign (p2pDevices);
if(i==nbHop-2){ // If we are on the last for loop (before last node)
cloudIP=p2pInterfaces.GetAddress (1); // Get Last node interface
PacketSinkHelper apSink("ns3::UdpSocketFactory",InetSocketAddress (Ipv4Address::GetAny (), cloudPort));
ApplicationContainer sinkApp=apSink.Install(curNodes.Get(1)); // Instal sink on last node
sinkApp.Get(0)->TraceConnect("Rx","CloudSwitch",MakeCallback(&PktReceived));
sinkApp.Start (Seconds (0));
}
}
return(std::make_pair(HopNodes,std::make_pair(cloudIP,cloudPort)));
}