Exemplo n.º 1
0
// Reads in the deterlab-config and drops out if there is an error
func deterFromConfig(name ...string) *platform.Deterlab {
	d := &platform.Deterlab{}
	configName := "deter.toml"
	if len(name) > 0 {
		configName = name[0]
	}
	err := sda.ReadTomlConfig(d, configName)
	_, caller, line, _ := runtime.Caller(1)
	who := caller + ":" + strconv.Itoa(line)
	if err != nil {
		log.Fatal("Couldn't read config in", who, ":", err)
	}
	log.SetDebugVisible(d.Debug)
	return d
}
Exemplo n.º 2
0
// Main starts the host and will setup the protocol.
func main() {
	flag.Parse()
	log.SetDebugVisible(debugVisible)
	log.Lvl3("Flags are:", hostAddress, simul, log.DebugVisible, monitorAddress)

	scs, err := sda.LoadSimulationConfig(".", hostAddress)
	measures := make([]*monitor.CounterIOMeasure, len(scs))
	if err != nil {
		// We probably are not needed
		log.Lvl2(err, hostAddress)
		return
	}
	if monitorAddress != "" {
		if err := monitor.ConnectSink(monitorAddress); err != nil {
			log.Error("Couldn't connect monitor to sink:", err)
		}
	}
	sims := make([]sda.Simulation, len(scs))
	var rootSC *sda.SimulationConfig
	var rootSim sda.Simulation
	for i, sc := range scs {
		// Starting all hosts for that server
		host := sc.Host
		measures[i] = monitor.NewCounterIOMeasure("bandwidth", host)
		log.Lvl3(hostAddress, "Starting host", host.ServerIdentity.Addresses)
		host.Listen()
		host.StartProcessMessages()
		sim, err := sda.NewSimulation(simul, sc.Config)
		if err != nil {
			log.Fatal(err)
		}
		err = sim.Node(sc)
		if err != nil {
			log.Fatal(err)
		}
		sims[i] = sim
		if host.ServerIdentity.ID == sc.Tree.Root.ServerIdentity.ID {
			log.Lvl2(hostAddress, "is root-node, will start protocol")
			rootSim = sim
			rootSC = sc
		}
	}
	if rootSim != nil {
		// If this cothority has the root-host, it will start the simulation
		log.Lvl2("Starting protocol", simul, "on host", rootSC.Host.ServerIdentity.Addresses)
		//log.Lvl5("Tree is", rootSC.Tree.Dump())

		// First count the number of available children
		childrenWait := monitor.NewTimeMeasure("ChildrenWait")
		wait := true
		// The timeout starts with 1 second, which is the time of response between
		// each level of the tree.
		timeout := 1000
		for wait {
			p, err := rootSC.Overlay.CreateProtocolSDA(rootSC.Tree, "Count")
			if err != nil {
				log.Fatal(err)
			}
			proto := p.(*manage.ProtocolCount)
			proto.SetTimeout(timeout)
			proto.Start()
			log.Lvl1("Started counting children with timeout of", timeout)
			select {
			case count := <-proto.Count:
				if count == rootSC.Tree.Size() {
					log.Lvl1("Found all", count, "children")
					wait = false
				} else {
					log.Lvl1("Found only", count, "children, counting again")
				}
			}
			// Double the timeout and try again if not successful.
			timeout *= 2
		}
		childrenWait.Record()
		log.Lvl1("Starting new node", simul)
		measureNet := monitor.NewCounterIOMeasure("bandwidth_root", rootSC.Host)
		err := rootSim.Run(rootSC)
		if err != nil {
			log.Fatal(err)
		}
		measureNet.Record()

		// Test if all ServerIdentities are used in the tree, else we'll run into
		// troubles with CloseAll
		if !rootSC.Tree.UsesList() {
			log.Error("The tree doesn't use all ServerIdentities from the list!\n" +
				"This means that the CloseAll will fail and the experiment never ends!")
		}
		closeTree := rootSC.Tree
		if rootSC.GetSingleHost() {
			// In case of "SingleHost" we need a new tree that contains every
			// entity only once, whereas rootSC.Tree will have the same
			// entity at different TreeNodes, which makes it difficult to
			// correctly close everything.
			log.Lvl2("Making new root-tree for SingleHost config")
			closeTree = rootSC.Roster.GenerateBinaryTree()
			rootSC.Overlay.RegisterTree(closeTree)
		}
		pi, err := rootSC.Overlay.CreateProtocolSDA(closeTree, "CloseAll")
		pi.Start()
		if err != nil {
			log.Fatal(err)
		}
	}

	// Wait for all hosts to be closed
	allClosed := make(chan bool)
	go func() {
		for i, sc := range scs {
			sc.Host.WaitForClose()
			// record the bandwidth
			measures[i].Record()
			log.Lvl3(hostAddress, "Simulation closed host", sc.Host.ServerIdentity.Addresses, "closed")
		}
		allClosed <- true
	}()
	log.Lvl3(hostAddress, scs[0].Host.ServerIdentity.First(), "is waiting for all hosts to close")
	<-allClosed
	log.Lvl2(hostAddress, "has all hosts closed")
	monitor.EndAndCleanup()
}