[[Include(WikiToC)]] == Setting an Optical Network on COSMOS Test-bed == This wiki page contains the tutorial of setting up an optical network on the COSMOS Test-bed. Authors: Zehao Wang, Duke University \\ Tingjun Chen, Duke University ---- = Description = Cosmos test-bed provides a possibility to create and use optical networks of various topologies. An example of how an optical network could be configured and used is provided. A simple experiment on switching of optical paths is described. ---- = Compute Nodes and ToR switch interfaces used = * Interfaces on sw-da-co1: {{{ Eth 1/1/1:1 (vlan 1066) srv1-co1 data1 Eth 1/1/66 (vlan 1066) 10g dwdm tunable (Calient 5.7.3) }}} * Interfaces on sw-da-lg1: {{{ Eth 1/1/1:1 (vlan 1033) srv1-lg1 data1 Eth 1/1/1:2 (vlan 1034) srv2-lg1 data1 Eth 1/1/33 (vlan 1033) 10g dwdm tunable (Calient 5.7.5) Eth 1/1/34 (vlan 1034) 10g dwdm tunable (Calient 5.7.6) }}} ---- = Experiment_1 Context = || [[Image(Experiment_1.png, width=500px)]] || Fig.1 Logical Topology of Experiment_1 Experiment consists in changing the light path from ToR1<-->ToR2 to ToR1<-->ToR3, representing changing of the light path in C-RAN when “Client” wants to move its base-band processing from “Edge Cloud” to “Central Cloud”. Experiment includes 3 servers: {{{ srv1-lg1.bed.cosmos-lab.org srv2-lg1.bed.cosmos-lab.org srv3-lg1.bed.cosmos-lab.org }}} Experiment includes 4 ROADMs: {{{ roadm1-co1.cosmos-lab.org (10.104.1.1) roadm2-co1.cosmos-lab.org (10.104.1.2) roadm3-co1.cosmos-lab.org (10.104.1.3) roadm4-co1.cosmos-lab.org (10.104.1.4) }}} 3 interfaces are connected to these servers from data1 pool of ToR interfaces: {{{ twentyFiveGigE 1/1/1 <--> srv1-lg1.bed.cosmos-lab.org twentyFiveGigE 1/1/2 <--> srv2-lg1.bed.cosmos-lab.org twentyFiveGigE 1/1/3<--> srv3-lg1.bed.cosmos-lab.org }}} 3 interfaces and 3 transceivers are associated with them in vlans: {{{ vlan 121: twentyFiveGigE 1/1/1 ; tengigabitethernet 1/32/1; vlan 122: twentyFiveGigE 1/1/2; tengigabitethernet 1/29/1; vlan 123: twentyFiveGigE 1/1/2; tengigabitethernet 1/31/1; }}} We are assigning next wavelengths to tengigabitethernet: {{{ 1553,30 nm 193,00 with bandwidth ~[192.95;193.05] Thz }}} ---- = Setting Up Optical Topology = Setting up an optical topology consists in connecting ROADMs accordingly to the needs of experiment. ROADMs need to be connected correctly to each other and to ToR switch. All interconnections are realized by Calient S320 Switch. [[Include(Architecture/optical#prog_topo)]] Fig.2 Physical Optical Interconnections. Calient Switch S320 has ports physically connected to ROADMs, ToR, Prof. Zussman’s lab and 3 loopback connections. All ports are designated in the Fig.2 Physical Optical Interconnections. In order to support the Experiment_1 logical connections and to realize emulate real distance between Edge Cloud an Central Cloud, one could choose to pass the optical signal through the loop of 22 km passing by 32 Avenue of the Americas, NYC; and organize Client port Connections as Next: * For the comb source: || ID |||| Ports Connection |||| Devices Connection |||| Comment || || 1 |||| 5.8.5->1.1.1||||comb_source_1 to ROADM1-CO1.port_1 |||| Forming background traffic into ROADM1-CO1 add port 2 || || 2 |||| 5.8.8->1.4.1||||comb_source_2 to ROADM2-CO1.port_1 |||| Forming background traffic into ROADM2-CO1 add port 2 || || 4 |||| 5.7.3<->1.1.1||||transceiver_3 with ROADM1-CO1.port_2 |||| Connecting transceiver3 with ROADM1-CO1 add/drop port 1 || || 5 |||| 1.1.8->5.5.1||||ROADM1-CO1.line_port to 10km fiber spool |||| Connecting ROADM1-CO1 line out to the 10 km fiber spool || || 6 |||| 5.5.2->1.1.8||||10km fiber spool to ROADM1-CO1.line_port |||| Connecting the 10 km fiber spool to ROADM1-CO1 line in || || 7 |||| 5.5.1->1.4.8||||10km fiber spool to ROADM1-LG1.line_port |||| Connecting the 10 km fiber spool to ROADM1-LG1 line in || || 8 |||| 1.4.8->5.5.2||||ROADM1-LG1.line_port to 10km fiber spool |||| Connecting ROADM1-LG1 line out to the 10 km fiber spool || || 9 |||| 2.1.8->4.6.1||||ROADM2-LG1.line_port to dark_fiber_1 |||| Connecting ROADM2-LG1 line out to the 34 km dark fiber || || 10 |||| 4.6.2->2.1.8||||dark_fiber_1 to ROADM2-LG1.line_port |||| Connecting the 34 km dark fiber to ROADM2-LG1 line in || || 11 |||| 4.6.1->2.4.8||||dark_fiber_2 to ROADM2-CO1.line_port |||| Connecting the 34 km dark fiber to ROADM2-CO1 line in || || 12 |||| 2.4.8->4.6.2||||ROADM2-CO1.line_port to dark_fiber_2 |||| Connecting ROADM2-CO1 line out to the 34 km dark fiber || * For the short route: || ID |||| Ports Connection |||| Devices Connection |||| Comment || || 1 |||| 2.4.1<->5.7.5 |||| ROADM1-LG1.port_2 with transceiver_5 |||| Connecting ROADM1-LG1 add/drop port 2 to transceiver5 to emulate the connection to the edge cloud || * For the long route: || ID |||| Ports Connection |||| Devices Connection |||| Comment || || 1 |||| 2.4.1<->5.7.6 |||| ROADM2-CO1.port_2 with transceiver_6 |||| Connecting ROADM2-CO1 add/drop port 2 to transceiver6 to emulate the connection to the center cloud || ---- = ROADMs Configuration = All of these configurations can be performed by Python scripts developed to work with the COSMOS test-bed. The Python commands send NETCONF commands to the ROADM. == Setting “Snake” Connection == Correct ROADM operation requires Line In port of a ROADM to always receive a light. That is why there is a dedicated transceiver (tengigabitethernet 1/33 on ToR) that sends light through all ROADMs by passing through loop-back connection on Calient S320 (port 5.5.1) and redirecting back, so the light is received on the same transceiver. This kind of connection is called “Snake”. In order maintain this “Snake” for “Experiment_1” next connections form Table 1 must be in place: 1,3,5,6,8,9. === tengigabitethernet 1/33/1 on ToR configuration === Snake Interface (to passe through all ROADMs in loop): 60 (DWDM Channel C60) 1529,55 nm 196,00 Thz with frequency range [195.95,196.05] Thz === MUX/DEMUX configuration === * ROADM 4: DEMUX IN/OUT port: 5101/5204 MUX IN/OUT port: 4104/4201 * ROADM 1: DEMUX IN/OUT port: 5101/5201 MUX IN/OUT port: 4101/4201 * ROADM 2: DEMUX IN/OUT port: 5101/5201 MUX IN/OUT port: 4101/4201 * ROADM 3: DEMUX IN/OUT port: 5101/5204 MUX IN/OUT port: 4104/4201 === ALS Disable Sequence (for 60 seconds) === 1. ROADM 4 booster, 2. ROADM 2 booster, 3. ROADM 3 booster, 4. ROADM 1 booster, == Setting “Experiment_1” Connections == === Configuring ToR1<->ToR2 Connection 1 === * ROADM 4: 1. Enable MUX port 4102 “From ToR 1” 2. Add Connection “Exp1-FromTor1” with Input/ Output Port 4102/4201 with bandwidth [192.95;193.05] (python add_connection.py 10.104.1.4 1 10 in-service false 4102 4201 192950 193050 5 Exp1-FromTor1) 3. Enable DEMUX port 5202 “Towards ToR 1” 4. Add Connection “Exp1-TorwardTor1” with I/O Port 5101/5202 (python add_connection.py 10.104.1.4 2 10 in-service false 5101 5202 192950 193050 5 Exp1-TorwardTor1) * ROADM 1: 5. Enable MUX port 4102 “From ToR 2” 6. Add Connection “From ToR 2” with I/O Port 4102/4201 with bandwidth [192.95;193.05] 7. Enable DEMUX port 5202 “Towards ToR 2” 8. Add Connection “Towards ToR 2” with I/O Port 5101/5202 === Configuting ToR1<->ToR3 Connection 2 === * ROADM 4 (Same As For Connection 1): 1. Enable MUX port 4102 “From ToR 1” 2. Add Connection “From ToR 1” with I/O Port 4102/4201 with bandwidth [192.95;193.05] 3. Enable DEMUX port 5202 “Towards ToR 1” 4. Add Connection “Towards ToR 1” with I/O Port 5101/5202 with bandwidth [192.95;193.05] * ROADM 1 : 5. Enable MUX port 4101 “Through Port” (enabled for Snake) 6. Add Connection “Through In” with I/O Port 4101/4201 with bandwidth [192.95;193.05] 7. Enable DEMUX port 5201 “Through Port” (enabled for Snake) 8. Add Connection “Through Out” with I/O Port 5101/5201 with bandwidth [192.95;193.05] * ROADM 2 (Same As For ROADM1): 9. Enable MUX port 4101 “Through Port” (enabled for Snake) 10. Add Connection “Through In” with I/O Port 4101/4201 with bandwidth [192.95;193.05] 11. Enable DEMUX port 5201 “Through Port” (enabled for Snake) 12. Add Connection “Through Out” with I/O Port 5101/5201 with bandwidth [192.95;193.05] * ROADM 3 (Same As For ROADM4): 13. Enable MUX port 4102 “From ToR 3” 14. Add Connection “From ToR 3” with I/O Port 4102/4201 with bandwidth [192.95;193.05] 15. Enable DEMUX port 5202 “Towards ToR 3” 16. Add Connection “Towards ToR 3” with I/O Port 5101/5202 with bandwidth [192.95;193.05] ---- = Network Interfaces Configuration for Experiment_1 = == Setting Up ToR switch with 3 logical ToR switches == 1. Preparing the interfaces to be set as VLAN switch ports: {{{ sw-tor-lg1#configure sw-tor-lg1(conf)#interface twentyFiveGigE 1/1/1 sw-tor-lg1(conf-if-tf-1/1/1)#switchport sw-tor-lg1(conf-if-tf-1/1/1)#no shutdown sw-tor-lg1(conf-if-tf-1/1/1)#exit sw-tor-lg1(conf)#interface twentyFiveGigE 1/1/2 sw-tor-lg1(conf-if-tf-1/1/2)#switchport sw-tor-lg1(conf-if-tf-1/1/2)#no shutdown sw-tor-lg1(conf-if-tf-1/1/2)#exit sw-tor-lg1(conf)#interface twentyFiveGigE 1/1/3 sw-tor-lg1(conf-if-tf-1/1/3)#switchport sw-tor-lg1(conf-if-tf-1/1/3)#no shutdown sw-tor-lg1(conf-if-tf-1/1/3)#exit sw-tor-lg1(conf)#interface tengigabitethernet 1/31/1 sw-tor-lg1(conf-if-te-1/31/1)#switchport sw-tor-lg1(conf-if-te-1/31/1)#no shutdown sw-tor-lg1(conf-if-te-1/31/1)#exit sw-tor-lg1(conf)#interface tengigabitethernet 1/29/1 sw-tor-lg1(conf-if-te-1/29/1)#switchport sw-tor-lg1(conf-if-te-1/29/1)#no shutdown sw-tor-lg1(conf-if-te-1/29/1)#exit sw-tor-lg1(conf)#interface tengigabitethernet 1/32/1 sw-tor-lg1(conf-if-te-1/32/1)#switchport sw-tor-lg1(conf-if-te-1/32/1)#no shutdown sw-tor-lg1(conf-if-te-1/32/1)#exit }}} 2. Assigning interfaces to VLANs {{{ sw-tor-lg1#configure sw-tor-lg1(conf)#interface vlan 121 sw-tor-lg1(conf-if-vl-121)#untagged twentyFiveGigE 1/1/1 sw-tor-lg1(conf-if-vl-121)#untagged tengigabitethernet 1/32/1 sw-tor-lg1(conf-if-vl-121)#exit sw-tor-lg1(conf)#interface vlan 122 sw-tor-lg1(conf-if-vl-122)#untagged twentyFiveGigE 1/1/2 sw-tor-lg1(conf-if-vl-122)#untagged tengigabitethernet 1/29/1 sw-tor-lg1(conf-if-vl-122)#exit sw-tor-lg1(conf)#interface vlan 123 sw-tor-lg1(conf-if-vl-123)#untagged twentyFiveGigE 1/1/3 sw-tor-lg1(conf-if-vl-123)#untagged tengigabitethernet 1/31/1 sw-tor-lg1(conf-if-vl-123)#exit sw-tor-lg1(conf)#exit }}} 3. Assigning a wavelength to transceivers: {{{ sw-tor-lg1#configure sw-tor-lg1(conf)#interface tengigabitethernet 1/32/1 sw-tor-lg1(conf-if-te-1/32/1)#wavelength 1553.3 sw-tor-lg1(conf-if-te-1/32/1)#exit sw-tor-lg1(conf)#interface tengigabitethernet 1/29/1 sw-tor-lg1(conf-if-te-1/29/1)#wavelength 1553.3 sw-tor-lg1(conf-if-te-1/29/1)#exit sw-tor-lg1(conf)#interface tengigabitethernet 1/32/1 sw-tor-lg1(conf-if-te-1/32/1)#wavelength 1553.3 sw-tor-lg1(conf-if-te-1/32/1)#exit sw-tor-lg1(conf)#exit }}} 4. Verify VLANs: {{{ sw-tor-lg1#show vlan Codes: * - Default VLAN, G - GVRP VLANs, R - Remote Port Mirroring VLANs, P - Primary, C - Community, I - Isolated O - Openflow, Vx - Vxlan Q: U - Untagged, T - Tagged x - Dot1x untagged, X - Dot1x tagged o - OpenFlow untagged, O - OpenFlow tagged G - GVRP tagged, M - Vlan-stack i - Internal untagged, I - Internal tagged, v - VLT untagged, V - VLT tagged NUM Status Description Q Ports 121 Active U Te 1/32/1 U Tf 1/1/1 122 Active U Te 1/29/1 U Tf 1/1/2 123 Active U Te 1/31/1 U Tf 1/1/3 }}} == Configuring Compute Nodes (Servers srv1..3-lg1) == 1. Install net-tools: {{{#!shell-session sudo apt install net-tools }}} 2. Configure interfaces eo1 and assign IP addresses: {{{#!shell-session native@srv1-lg1:~$ sudo ifconfig eno1 192.168.1.1 netmask 255.255.255.0 native@srv2-lg1:~$ sudo ifconfig eno1 192.168.1.2 netmask 255.255.255.0 native@srv3-lg1:~$ sudo ifconfig eno1 192.168.1.3 netmask 255.255.255.0 }}} ---- = Perform Experiment_1 = 1. Establish Connection ToR1<->ToR2. 2. Try Ping from Srv1 to Srv2: {{{#!shell-session native@srv1-lg1:~$ ping 192.168.1.3 PING 192.168.1.3 (192.168.1.3) 56(84) bytes of data. 64 bytes from 192.168.1.3: icmp_seq=1 ttl=64 time=0.460 ms 64 bytes from 192.168.1.3: icmp_seq=2 ttl=64 time=0.423 ms }}} 3. Establish Connection ToR1<->ToR2. 4. Try Ping from Srv1 to Srv3.