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--- qos_project [2017/11/29 08:54] – [5. [CO1] Connecting the Platform] samer
+++ qos_project [2017/11/30 18:55] – [6. [CO2] Implementing the Applications and Tools] samer
@@ Line 81: / Line 81: @@
 <code bash>
-.0.0.0/24 dev eth0  proto kernel  scope link  src 10.0.0.1 # Loopback address
+.0.0.0/24 dev eth0  proto kernel  scope link  src 10.0.0.1 # loopback address
-.168.8.0/24 dev wlan0  proto kernel  scope link  src 192.168.8.1 # Connection to the wifi interface
+.168.8.0/24 dev wlan0  proto kernel  scope link  src 192.168.8.1 # connection to the wifi interface
-.168.100.0/24 dev eth1  proto kernel  scope link  src 192.168.100.1 # Connection to the LAN 192.168.100.0/24
+.168.100.0/24 dev eth1  proto kernel  scope link  src 192.168.100.1 # connection to the LAN 192.168.100.0/24
-.168.200.0/24 via 10.0.0.2 dev eth0  proto static # Static route to the 192.168.200.0/24 network via the interface
+.168.200.0/24 via 10.0.0.2 dev eth0  proto static # static route to the 192.168.200.0/24 network via the interface
 .0.0.2 of the TP-LINK router
 </code>
@@ Line 97: / Line 97: @@
 </code>
-<code bash>
+We note on the two routers that static routes are used in order to give access to the two LANs. Particularly, the configuration of the routers is given in the ''/etc/config/network'' files as on a typical OpenWrt system.
-#Configurations on TP-LINK router
-#Configuration of LAN interface :
+As given below, the configuration of the TP-Link router shows the static addressing of the interface ''eth0'' (LAN interface) and the interface ''eth1'' (WAN interface). We also note the section ''route'' that configures a static routers towards the LAN connected to the TP-LINK router.
+<file bash /etc/config/network>
+#Configuration of LAN interface:
 config interface 'lan'
         option type 'bridge'
@@ Line 111: / Line 111: @@
         option ip6assign '60'
-#Configuration of WAN interface :
+#Configuration of WAN interface:
 config interface 'wan'
         option ifname 'eth1'
@@ Line 127: / Line 126: @@
         option netmask '255.255.255.0'
         option gateway '10.0.0.1'
+</file>
+Similarly, the configuration of the GL-iNET router below shows the following:
+  * The WiFi interface is configured with a static IP address 192.168.8.1/24
+  * The WAN interface is configured with a static IP address 10.0.0.1/24
+  * A static route enables GL-iNET to reach the network 192.168.200.0/24 via 10.0.0.2 of the other router.
+<file bash /etc/config/network>
+config interface 'lan'
+        option force_link '1'
+        option proto 'static'
+        option ipaddr '192.168.8.1'
+        option netmask '255.255.255.0'
+        option ip6assign '60'
+        option _orig_ifname 'eth1'
+        option _orig_bridge 'false'
+config interface 'wan'
+        option ifname 'eth0'
+        option hostname 'GL-iNet-b2d'
+        option proto 'static'
+        option ipaddr '10.0.0.1'
+        option netmask '255.255.255.0'
+config route
+        option interface 'wan'
+        option target '192.168.200.0'
+        option netmask '255.255.255.0'
+        option gateway '10.0.0.2'
+</file>
+The two routers allocate IP addresses using DHCP. In order to facilitate the usage of the platform, fixed allocations are configured for the end hosts. This is configured in ''/etc/config/dhcp'' on each router as in the following.
+<file /etc/config/dhcp>
+config dhcp 'lan'
+        option interface 'lan'
+        option start '100'
+        option limit '150'
+        option leasetime '12h'
+        option dhcpv6 'server'
+        option ra 'server'
+config host
+        option name 'pi2'
+        option mac 'b8:27:eb:0f:f8:95'
+        option ip '192.168.200.192'
+config host
+        option name 'pi3'
+        option mac 'b8:27:eb:20:aa:54'
+        option ip '192.168.200.193'
+</file>
+Finally, we verify the routing and addressing on the Raspberry Pi devices using ''ifconfig'' (or ''ip addr show'') and ''ip route'' commands.
+<code bash>
+pi@raspberrypi:~ $ ifconfig
+eth0      Link encap:Ethernet  HWaddr b8:27:eb:0f:f8:95
+          inet addr:192.168.200.192  Bcast:192.168.200.255  Mask:255.255.255.0
+          inet6 addr: fdd5:bc83:a776:0:2377:1496:eb81:1433/64 Scope:Global
+          inet6 addr: fe80::20ae:134e:ae88:4bc5/64 Scope:Link
+          inet6 addr: fdd5:bc83:a776::192/128 Scope:Global
+          UP BROADCAST RUNNING MULTICAST  MTU:1500  Metric:1
+          RX packets:1216 errors:0 dropped:3 overruns:0 frame:0
+          TX packets:983 errors:0 dropped:0 overruns:0 carrier:0
+          collisions:0 txqueuelen:1000
+          RX bytes:229130 (223.7 KiB)  TX bytes:121127 (118.2 KiB)
 </code>
-===== Extracts =====
+<code bash>
+pi@raspberrypi:~ $ ip route
+default via 192.168.200.1 dev eth0  metric 202
+.168.200.0/24 dev eth0  proto kernel  scope link  src 192.168.200.192  metric                                                                                                                                                              202
+</code>
+===== -. [CO2] Implementing the Applications and Tools =====
+In order to describe and analyze the basic steps for installing and using the tools and client/server applications, we need to look carefully to these four applications: iperf, flent, VLC, HTTP.
+Let us start with the application iperf. In the following, we present a short tutorial on the main functions of the perf tool.
+- To activate iperf3:
+  * On the server side: ''iperf3 -s''
+  * On the client side: ''iperf3 -c 192.168.200.192'', where 192.168.200.192is the IP address of the server.
+- To visualize UDP trafic with a specific bandwidth:
+  * On the client side: iperf3 -c 192.168.200.192 -u -b 2M
+Here we set the bandwidth with UDP to 2Mbit/s.
+Note that by default ,UDP sets the bandwidth to 1Mbit/s
+- To extend the transmission time(second) as well as the number packets sent:
+	    * On the Client side: iperf3 -c 192.168.200.192 -t 15
+Note that  by default, iperf3 sets the time to 10 seconds
+- To reverse mode(server sends, client receives):
+	    * On the Client side: iper3 -c 192.168.200.192 -R
+- To end multiple flows:
+	    * On the Client side: iper3 -c 192.168.200.192 -P 2 -t 60
+Here we are sending 2 flows in 1 min(60 seconds)
+Note that we need to extend more the tx time in order to have similar throughput for the 2 flows so that we don't consider it as a fairness issue.
+Let's analyze flent application:
+            * On the Server side: netserver &
+-To visualize one TCP stream:
+            * On the Client side:  flent tcp_upload -p totals -l 60 -H 192.168.200.192 -t title2 -o test2.png
+-To visualize 12 TCP streams:
+            * On the Client side:  flent tcp_12up -p totals -l 60 -H 192.168.200.192 -t title3 -o test3.png