= Exercise 2: Measuring Performance of a !MobilityFirst Router = [[TOC(Tutorials/oMF*, depth=2)]] == !Design/Setup == === Objective === In this exercise, we will try to drive synthetic traffic through the router and measure key performance characteristics such as throughput and forwarding latency. Since !MobilityFirst presents a hop-by-hop block data transport, we can vary the unit size of the data block and observe it's impact on the performance. We will also try to visualize the performance results using OMF's result service by installing an OML-enabled monitor on the routers. === Pre-requisites === * Experimenters are expected to have basic networking knowledge and familiarity with Linux OS and some of its tools (command line tools, ssh, etc.). * An ORBIT user account. * Some familiarity with the !MobilityFirst terminology. === Deploy the Network === This tutorial assumes that a 4 nodes topology has been already established in one of the Orbit sandboxes or the grid: [[Image(Tutorials/oMF:MFTurorialNetwork.png)]] If not coming from [wiki:Tutorials/oMF/tut1 exercise 1] follow these instructions on how to setup the topology. Running exercise 1 before moving to exercise 2 is advised to understand the steps and software components involved. [[CollapsibleStart(4 nodes topology setup)]] First of all, log in into the grid console using SSH: {{{ #!sh ssh username@console.grid.orbit-lab.org }}} For simplicity, open 3 different consoles on your laptop and access the grid's console with all of them; you will need them in the continuation of the exercise. From the console we will start loading the !Mobilityfirst image into the four nodes that have been assigned to you: {{{ #!sh omf load -i 'mf-release-latest.ndz' -t system:topo:mf-groupX }}} ''system:topo:mf-groupX'' represents the topology of 4 nodes that has been assigned to you're group and ''mf-groupX'' has to be replaced by the group id assigned to you. For example, ''mf-group1'' will load the image on nodes 'node20-20,node20-19,node19-19,node19-20' If at the end of the execution, the final output of your console looks similar to: {{{ #!sh INFO exp: ----------------------------- INFO exp: Imaging Process Done INFO exp: 4 nodes successfully imaged - Topology saved in '/tmp/pxe_slice-2014-10-15t02.10.16.594-04.00-topo-success.rb' INFO exp: ----------------------------- INFO EXPERIMENT_DONE: Event triggered. Starting the associated tasks. INFO NodeHandler: INFO NodeHandler: Shutting down experiment, please wait... INFO NodeHandler: INFO NodeHandler: Shutdown flag is set - Turning Off the resources INFO run: Experiment pxe_slice-2014-10-15t02.10.16.594-04.00 finished after 1:50 }}} your nodes have been imaged correctly. === Deploy Network === Software and experiment control in the ORBIT testbed can be automated greatly using the OMF framework. An OMF control script is written in Ruby and allows the experimenter to specify the set of nodes, their network configuration, to specify software components and arguments, and to control their execution on one or more nodes. We will use an OMF script to bring up 4 ORBIT nodes to host our topology, with the corresponding software components. We will first introduce the main details of the scripts that will be run and then we will step to the execution process itself. ==== Software Component Specification ==== The following snippet shows the specification of the !MobilityFirst components along with the required arguments. A typical application will have at least a brief description, a path for the associated binary to execute and a list of properties that correspond to the parameters that will be passed once starting the executable. {{{ #!ruby #Application definition of a MobilityFirst access router defApplication('MF-Router', 'router') {|app| app.shortDescription = "Click-based MobilityFirst Access Router" app.path = "/usr/local/src/mobilityfirst/eval/orbit/tutorial/scripts/ARWrapper.sh" # click options app.defProperty('num_threads', 'number of threads', "-t",{:type => :integer, :mandatory => true, :default => 4, :order => 1}) app.defProperty('ctrl_port', 'port for Click control socket', "-c",{:type => :integer, :order => 2}) # click config file app.defProperty('config_file', 'Click configuration file', "-C",{:type => :string,:mandatory=> true}) # keyword parameters used in click config file app.defProperty('my_GUID', 'router GUID', "-m",{:type => :string, :mandatory => true}) app.defProperty('topo_file', 'path to topology file', "-f",{:type => :string, :mandatory => true}) app.defProperty('core_dev', 'core network interface', "-d",{:type => :string,:mandatory => true}) app.defProperty('GNRS_server_ip', 'IP of local GNRS server', "-s",{:type => :string,:mandatory => true}) app.defProperty('GNRS_server_port', 'Port of GNRS server', "-p",{:type => :string,:mandatory => true}) app.defProperty('GNRS_listen_ip', 'IP to listen for GNRS response', "-i",{:type => :string,:default => "0.0.0.0"}) app.defProperty('GNRS_listen_port', 'port to listen for GNRS response', "-P",{:type => :string,:default => "10001"}) app.defProperty('edge_dev', 'edge network interface', "-D",{:type => :string,:mandatory => true}) app.defProperty('edge_dev_ip', 'IP assigned to edge interface', "-I",{:type => :string,:mandatory => true}) } #Application definition of a GNRS server defApplication('MF-GNRS', 'gnrs') {|app| app.shortDescription = "GNRS Server" app.path = "/usr/local/src/mobilityfirst/eval/orbit/tutorial/scripts/GNRSWrapper.sh" app.defProperty('log4j_config_file', 'log 4j configuration file', "-d",{:type => :string, :order => 1}) app.defProperty('jar_file', 'server jar file with all dependencies', "-j" ,{:type => :string, :mandatory=> true, :default => "/usr/local/src/mobilityfirst/gnrs/jserver/target/gnrs-server-1.0.0-SNAPSHOT-jar-with-dependencies.jar", :order => 2}) app.defProperty('config_file', 'server configuration file', "-c",{:type => :string, :mandatory=> true, :order => 3}) } #Application definition of the client network protocol stack defApplication('MF-HostStack', 'hoststack') {|app| app.shortDescription = "MF host network stack" app.path = "/usr/local/bin/mfstack" app.defProperty('log_level', 'log level', nil,{:type => :string, :mandatory => true, :order => 1, :default => "-e"}) # default is 'error' app.defProperty('config_file', 'stack configuration file', nil,{:type => :string, :mandatory => true, :order => 2}) } }}} A few considerations on the defined applications: * As seen above, the router is configured with both 'core' (''core_dev'') and 'edge' (''edge_dev'') interfaces. Different router configurations are available depending on the required functionality. In this case we use what we call a !MobilityFirst Access Router, which has the particularity of having the core interfaces connected towards the core of the network, while the edge interface enables hosts to connect and access the !MobilityFirst network. * For this basic setup, the GNRS has been configured to be running as a single server instance, but in a larger experiment, it is designed to be a distributed system deployed at different locations. * Most of the client settings are located in a configuration file pre-loaded on the ORBIT image in the folder ''/usr/local/src/mobilityfirst/eval/orbit/conf/''. ==== Setting up the Software Node Groups ==== The following snippet shows how the node groups for the routers are setup in the OMF control scripts. Node groups allow experimenters to use single statements to set configuration (e.g. network interfaces) and execute commands across all nodes belonging to the group. {{{ #!ruby #Create router groups for i in 1..num_routers #Create a topology with a single router in it defTopology("topo:router_#{i}") { |t| aNode = routersTopo.getNodeByIndex(i-1) t.addNode(aNode) info aNode, " assigned role of router with GUID: #{i}" } #Through the group definition we set up the applications to run defGroup("router_#{i}", "topo:router_#{i}") {|node| node.addApplication('MF-Router') {|app| app.setProperty('num_threads', router_threads) app.setProperty('config_file', click_conf) app.setProperty('my_GUID', router_guid[i-1]) app.setProperty('topo_file', rtr_topo_file) app.setProperty('core_dev', core_dev) app.setProperty('GNRS_server_ip', GNRS_server_ip) app.setProperty('GNRS_server_port', GNRS_server_port) app.setProperty('GNRS_listen_ip', "192.168.100.#{i}") app.setProperty('GNRS_listen_port', GNRS_listen_port) app.setProperty('edge_dev', edge_dev) app.setProperty('edge_dev_ip', router_ether_if_ip[i-1]) } #If it is the first router add the GNRS if i == 1 aNode = routersTopo.getNodeByIndex(i-1) info aNode, " will also host the GNRS server" node.addApplication('MF-GNRS') {|app| app.setProperty('log4j_config_file', GNRS_log_file) app.setProperty('jar_file', GNRS_jar_file) app.setProperty('config_file', GNRS_conf_file) } end #Setup the node interfaces #The first ethernet interface is used as the core interface node.net.e0.ip = "192.168.100.#{i}" node.net.e0.netmask = '255.255.255.0' #The first wireless interface is used to give access to clients node.net.w0.mode = "adhoc" node.net.w0.type = 'g' node.net.w0.channel = "11" node.net.w0.essid = "SSID_group_#{i}" node.net.w0.ip = "192.168.#{i}.1" } end #Create host groups for i in 1..num_hosts #Create a topology with a single router in it defTopology("topo:host_#{i}") { |t| aNode = hostsTopo.getNodeByIndex(i-1) t.addNode(aNode) info aNode, " assigned role of client with GUID: #{100 + i}" } #Through the group definition we set up the applications to run defGroup("host_#{i}", "topo:host_#{i}") {|node| node.addApplication('MF-HostStack') {|app| app.setProperty('config_file', hoststack_conf_file[i-1]) app.setProperty('log_level', log_level) } #The first wifi interface is used to connect to the Access Router node.net.w0.mode = "adhoc" node.net.w0.type = 'g' node.net.w0.channel = "11" node.net.w0.essid = "SSID_group_#{i}" node.net.w0.ip = "192.168.#{i}.2" } end }}} As it can be seen above, once defining applications that each group will execute, the application properties are set accordingly. While we do not want to enter the details of each parameter, it is important to notice how by simple use of counters, the different nodes can be assigned different values. Moreover, resources such node interfaces and their corresponding IP addresses have to be set up in this phase of the experiment. As we discussed earlier the router is configured with both edge and core interfaces. An ethernet interface is used to connect to 2 core routers, while a wireless interface is used to provide access for the clients. [[CollapsibleEnd]] ==== Setting up the 'OML enabled Monitor on Routers Application' ==== At this point, the network topology described and initialized in Exercise 1 is up and functional. In order to produce synthetic traffic, we will use mfping to send packets between the hosts. In order to perform more advanced network measurements, other applications are also available, such as a modified version of the commonly used application ''iperf''. In addition to the deployment specified in exercise 1, we install OML-enabled statistics monitor for !MobilityFirst routers. The entire script is available as part of the tutorial package as orbit/tutorial/scripts/exercise2.rb The key extensions over previous script are briefly discussed below. The following snippet from the script shows the code added to set up the OML enabled Monitor on Routers Application and its arguments: {{{ #!ruby defApplication("mf_click_monitor", "mf_click_monitor") do |app| app.shortDescription = "OML enabld statistics monitor for MobilityFirst Routers" app.path = "/usr/local/bin/mf_click_mon" app.defProperty('ctrl_port', 'Port for Click control socket', nil,{:type => :string, :mandatory => true, :order => 1}) app.defProperty('self-id', 'OML ID', nil,{:type => :string, :mandatory => true, :order => 2}) app.defProperty('oml-config-file', 'OML configuration file', "--oml-config",{:type => :string,:mandatory=> true}) app.defProperty('oml-domain', 'OML domain name', "--oml-domain",{:type => :string,:mandatory=> true}) end self_id = "MonitorID" oml_config_file = "/usr/local/src/mobilityfirst/eval/orbit/tutorial/conf/click-oml-config.xml" oml_domain = "#{Experiment.ID}" defGroup("router_monitors", "router_universe") {|node| node.addApplication('mf_click_monitor') {|app| app.setProperty('ctrl_port', router_control_port) app.setProperty('self-id', self_id) app.setProperty('oml-config-file', oml_config_file) app.setProperty('oml-domain', oml_domain) } } }}} As seen above, the OML enabled monitor will work with the !MobilityFirst router that will enable us to track and visualize the forwarding performance of MFRs. In order report statistics to the OML server, the monitor periodically queries the monitor through the control port (''ctrl_port'' in our script) == Execute == ==== Running the Benchmark Application ==== To generate the traffic that will be reported by the routers, we will use the same ''mfping'' application as in the previous exercise. First of all, you will need to start the experiment via the OMF script. Download the script to the orbit console: {{{ #!sh wget www.winlab.rutgers.edu/~bronzino/downloads/orbit/exercise2.rb }}} Once the file has been downloaded, execute it with the following command: {{{ #!sh omf exec exercise2.rb }}} The following snippet shows how the exercise runs. As indicated above first we will run mfping between the hosts as described in exercise 1: [[CollapsibleStart(If not coming from the previous exercise follow these instructions to run mfping)]] Once the host and router components are up, you can log in to the sender (host identified by GUID 101) and receiver (host identified by GUID 102) host nodes (two separate terminals) and run the 'mfping' application. Run the mfping 'server' specifying the application GUID: {{{ #!sh mfping -s -m 102 -o 101 }}} where "-s" specifies that the host is running as server, "-m" specifies the source guid and "-o" the destination one To run the mfping 'client' {{{ #!sh mfping -c -m 101 -o 102 -n 10 }}} Where "-c" specifies the client is running and "-n" specifies the number of pings between the two nodes. If successfully executed, the client will display some information similar to the following snippet {{{ #!sh root@node1-1:~# mfping -c -m 101 -o 102 -n 10 64 bytes received: seq_n=0, time=25.1470 msec 64 bytes received: seq_n=1, time=23.7070 msec 64 bytes received: seq_n=2, time=20.0559 msec 64 bytes received: seq_n=3, time=24.0371 msec 64 bytes received: seq_n=4, time=23.1831 msec 64 bytes received: seq_n=5, time=20.3069 msec 64 bytes received: seq_n=6, time=24.1379 msec 64 bytes received: seq_n=7, time=19.6230 msec 64 bytes received: seq_n=8, time=20.3931 msec 64 bytes received: seq_n=9, time=20.2239 msec }}} [[CollapsibleEnd]] ==== Visualizing the Performance Data ==== '''Method 1:''' OMF framework supports a result service that allows experimenters to query data stored using the OML measurement framework. The query is performed over the web and requires that you know the hostname and port where the result service runs, and the ''experiment ID'' associated with this experiment - this is obtained from the output following the execution of the control script. It should look something like this : {{{ #!sh Experiment ID: default_slice-2014-10-15t02.12.19.869-04.00 }}} The result service supports either dumping of the entire database or a SQL-like querying option to selectively retrieve required measurement data. The below HTTP request shows an example query to retrieve the reported statistics from the OML enabled monitor for !MobilityFirst Routers. In order to see the results the following web page should be retrieved using any browser. The following URL should be typed in the browser: {{{ #!sh http://oml.orbit-lab.org:5054/result/dumpDatabase?expID=default_slice-2014-10-15t02.12.19.869-04.00 }}} In this case the hostname is "oml.orbit-lab.org" and the port number is "5054". Note that the URL used in wget, in particular the arguments, may require to be encoded to unambiguously represent special characters when using the HTTP protocol. This data can also be downloaded using "wget" command and easily visualized using a tool such as gnuplot. You can find a helper script in the tutorial package that plots they key performance data downloaded. '''Method 2:''' Alternatively, the performance data may be visualized using ''omf-web'', OMF's web-based visualization service. It also works in concert with the result service referenced in Method 1, and makes available a variety of graph widgets to visualize live-experiment data logged using OML. Detailed documentation on the installation and usage of omf-web can be found on the [https://github.com/mytestbed/omf_web omf-web github site]. Since this is installed on all ORBIT domains, we only need to concern ourselves with defining the widget configuration required to bring up the live graphs for the performance data we are logging. In order to bring up the visualization, we only need to start the basic omf-web service with the configuration file arguments. == Finish == Once the application has successfully completed its task, follow these steps to complete the experiments: * Kill the ''mfping'' server using Ctrl-C on the corresponding node. * On the grid's console running the experiment script, interrupt the experiment using the Ctrl-C key combination. This will stop all the applications and will conclude the experiment.