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<img src="https://jenkins.onosproject.org/view/QA/job/postjob-VM/lastSuccessfulBuild/artifact/HAbackupRecover_onos-2.2_20-builds_graph.jpg", alt="HAbackupRecover", style="width:525px;height:350px;border:0">

commit e80c15bc3580db128129cc170f152f1e8a09d8f2 (HEAD, origin/onos-2.2, onos-2.2)
Author: ONOS Jenkins User [jenkins@onlab.us]
AuthorDate: Mon Sep 28 17:26:11 2020 +0000
Commit: ONOS Jenkins User [jenkins@onlab.us]
CommitDate: Mon Sep 28 17:26:11 2020 +0000

Starting snapshot 2.2.6-SNAPSHOT

Case 1: Starting up 5 node(s) ONOS cluster - PASS

Set up ONOS with 5 node(s) ONOS cluster

• 1.1 Constructing test variables - PASS
• 1.2 Apply cell to environment - PASS
• 1.3 Uninstalling Atomix - PASS
• 1.4 Uninstalling ONOS package - PASS
• 1.5 Starting Mininet - PASS
• 1.6 Creating ONOS package - PASS
• 1.7 Installing Atomix - PASS
• 1.8 Installing ONOS package - PASS
• 1.9 Set up ONOS secure SSH - PASS
• 1.10 Checking ONOS service - PASS
• 1.11 Starting ONOS CLI sessions - PASS
• 1.12 Checking ONOS nodes - PASS
• 1.13 Checking ONOS applications - PASS
• 1.14 Checking ONOS nodes - PASS
• 1.15 Activate apps defined in the params file - No Result
• 1.16 Set ONOS configurations - PASS
• 1.17 Check app ids - PASS
• 1.18 Set logging levels - PASS

Case 2: Assigning devices to controllers - PASS

Assign switches to ONOS using 'ovs-vsctl' and check that an ONOS node becomes the master of the device.

• 2.1 Assign switches to controllers - PASS

Case 8: Compare ONOS Topology view to Mininet topology - PASS

Compare topology objects between Mininet and ONOS

• 8.1 Comparing ONOS topology to MN topology - PASS
• 8.2 Hosts view is consistent across all ONOS nodes - PASS
• 8.3 Hosts information is correct - PASS
• 8.4 Host attachment points to the network - PASS
• 8.5 Clusters view is consistent across all ONOS nodes - PASS
• 8.6 There is only one SCC - PASS
• 8.7 Device information is correct - PASS
• 8.8 Links are correct - PASS
• 8.9 Hosts are correct - PASS
• 8.10 Checking ONOS nodes - PASS

Case 21: Assigning Controller roles for switches - PASS

Check that ONOS is connected to each device. Then manually assign mastership to specific ONOS nodes using 'device-role'

• 21.1 Assign mastership of switches to specific controllers - PASS
• 21.2 Check mastership was correctly assigned - PASS

Case 3: Adding host Intents - PASS

Discover hosts by using pingall then assign predetermined host-to-host intents. After installation, check that the intent is distributed to all nodes and the state is INSTALLED

• 3.1 Install reactive forwarding app - PASS
• 3.2 Check app ids - PASS
• 3.3 Discovering Hosts( Via pingall for now ) - PASS
• 3.4 Uninstall reactive forwarding app - PASS
• 3.5 Check app ids - PASS
• 3.6 Add host intents via cli - PASS
• 3.7 Intent Anti-Entropy dispersion - PASS

Case 8: Compare ONOS Topology view to Mininet topology - PASS

Compare topology objects between Mininet and ONOS

• 8.1 Comparing ONOS topology to MN topology - PASS
• 8.2 Hosts view is consistent across all ONOS nodes - PASS
• 8.3 Hosts information is correct - PASS
• 8.4 Host attachment points to the network - PASS
• 8.5 Clusters view is consistent across all ONOS nodes - PASS
• 8.6 There is only one SCC - PASS
• 8.7 Device information is correct - PASS
• 8.8 Links are correct - PASS
• 8.9 Hosts are correct - PASS
• 8.10 Checking ONOS nodes - PASS

Case 4: Verify connectivity by sending traffic across Intents - PASS

Ping across added host intents to check functionality and check the state of the intent

• 4.1 Check Intent state - PASS
• 4.2 Ping across added host intents - PASS
• 4.3 Check leadership of topics - PASS
• 4.4 Wait a minute then ping again - PASS

Case 5: Setting up and gathering data for current state - PASS

• 5.1 Check that each switch has a master - PASS
• 5.2 Get the Mastership of each switch from each controller - No Result
• 5.3 Read device roles from ONOS - PASS
• 5.4 Check for consistency in roles from each controller - PASS
• 5.5 Get the intents from each controller - PASS
• 5.6 Check for consistency in Intents from each controller - PASS
• 5.7 Get the flows from each controller - PASS
• 5.8 Check for consistency in Flows from each controller - PASS
• 5.9 Get the OF Table entries - No Result
• 5.10 Start continuous pings - No Result
• 5.11 Collecting topology information from ONOS - No Result
• 5.12 Host view is consistent across ONOS nodes - PASS
• 5.13 Each host has an IP address - PASS
• 5.14 Cluster view is consistent across ONOS nodes - PASS
• 5.15 Cluster view correct across ONOS nodes - PASS
• 5.16 Comparing ONOS topology to MN - PASS
• 5.17 Device information is correct - PASS
• 5.18 Links are correct - PASS
• 5.19 Hosts are correct - PASS

Case 14: Start Leadership Election app - PASS

• 14.1 Install leadership election app - PASS
• 14.2 Run for election on each node - PASS
• 14.3 Active node was elected leader? - PASS

Case 15: Check that Leadership Election is still functional - PASS

• 15.1 Run for election on each node - PASS
• 15.2 Check that each node shows the same leader and candidates - PASS
• 15.3 Find current leader and withdraw - PASS
• 15.4 Check that a new node was elected leader - PASS
• 15.5 Check that that new leader was the candidate of old leader - PASS
• 15.6 Run for election on old leader( just so everyone is in the hat ) - PASS
• 15.7 Check that oldLeader is a candidate, and leader if only 1 node - No Result

Case 16: Install Primitives app - PASS

• 16.1 Install Primitives app - PASS

Case 17: Check for basic functionality with distributed primitives - FAIL

Test the methods of the distributed primitives (counters and sets) throught the cli

• 17.1 Increment then get a default counter on each node - PASS
• 17.2 Get then Increment a default counter on each node - PASS
• 17.3 Counters we added have the correct values - PASS
• 17.4 Add -8 to then get a default counter on each node - PASS
• 17.5 Add 5 to then get a default counter on each node - PASS
• 17.6 Get then add 5 to a default counter on each node - PASS
• 17.7 Counters we added have the correct values - PASS
• 17.8 Distributed Set get - PASS
• 17.9 Distributed Set size - PASS
• 17.10 Distributed Set add() - PASS
• 17.11 Distributed Set addAll() - PASS
• 17.12 Distributed Set contains() - PASS
• 17.13 Distributed Set containsAll() - PASS
• 17.14 Distributed Set remove() - PASS
• 17.15 Distributed Set removeAll() - PASS
• 17.16 Distributed Set addAll() - PASS
• 17.17 Distributed Set clear() - PASS
• 17.18 Distributed Set addAll() - PASS
• 17.19 Distributed Set retain() - FAIL
• Set retain was incorrect
• 17.20 Partitioned Transactional maps put - PASS
• 17.21 Partitioned Transactional maps get - PASS
• 17.22 Get the value of a new value - PASS
• 17.23 Atomic Value set() - PASS
• 17.24 Get the value after set() - PASS
• 17.25 Atomic Value compareAndSet() - PASS
• 17.26 Get the value after compareAndSet() - PASS
• 17.27 Atomic Value getAndSet() - PASS
• 17.28 Get the value after getAndSet() - PASS
• 17.29 Atomic Value destory() - PASS
• 17.30 Get the value after destroy() - PASS
• 17.31 Work Queue add() - PASS
• 17.32 Check the work queue stats - PASS
• 17.33 Work Queue addMultiple() - PASS
• 17.34 Check the work queue stats - PASS
• 17.35 Work Queue takeAndComplete() 1 - PASS
• 17.36 Check the work queue stats - PASS
• 17.37 Work Queue takeAndComplete() 2 - PASS
• 17.38 Check the work queue stats - PASS
• 17.39 Work Queue destroy() - PASS
• 17.40 Check the work queue stats - PASS

Case 6: Restart entire ONOS cluster with backed up state - PASS

• 6.1 Backup ONOS data - PASS
• 6.2 Checking ONOS Logs for errors - No Result
• 6.3 Uninstalling ONOS package - PASS
• 6.4 Installing ONOS package - PASS
• 6.5 Restore ONOS data - PASS
• 6.6 Restart ONOS nodes - No Result
• 6.7 Set up ONOS secure SSH - PASS
• 6.8 Checking ONOS service - PASS
• 6.9 Starting ONOS CLI sessions - PASS

Case 8: Compare ONOS Topology view to Mininet topology - PASS

Compare topology objects between Mininet and ONOS

• 8.1 Comparing ONOS topology to MN topology - PASS
• 8.2 Hosts view is consistent across all ONOS nodes - PASS
• 8.3 Hosts information is correct - PASS
• 8.4 Host attachment points to the network - PASS
• 8.5 Clusters view is consistent across all ONOS nodes - PASS
• 8.6 There is only one SCC - PASS
• 8.7 Device information is correct - PASS
• 8.8 Links are correct - PASS
• 8.9 Hosts are correct - PASS
• 8.10 Checking ONOS nodes - PASS

Case 3: Adding host Intents - PASS

Discover hosts by using pingall then assign predetermined host-to-host intents. After installation, check that the intent is distributed to all nodes and the state is INSTALLED

• 3.1 Install reactive forwarding app - PASS
• 3.2 Check app ids - PASS
• 3.3 Discovering Hosts( Via pingall for now ) - PASS
• 3.4 Uninstall reactive forwarding app - PASS
• 3.5 Check app ids - PASS
• 3.6 Add host intents via cli - PASS
• 3.7 Intent Anti-Entropy dispersion - PASS

Case 7: Running ONOS Constant State Tests - PASS

• 7.1 Check that each switch has a master - PASS
• 7.2 Read device roles from ONOS - PASS
• 7.3 Check for consistency in roles from each controller - PASS
• 7.4 Get the intents from each controller - PASS
• 7.5 Check for consistency in Intents from each controller - PASS
• 7.6 Leadership Election is still functional - PASS

Case 4: Verify connectivity by sending traffic across Intents - PASS

Ping across added host intents to check functionality and check the state of the intent

• 4.1 Check Intent state - PASS
• 4.2 Ping across added host intents - PASS
• 4.3 Check leadership of topics - PASS
• 4.4 Wait a minute then ping again - PASS

Case 15: Check that Leadership Election is still functional - PASS

• 15.1 Run for election on each node - PASS
• 15.2 Check that each node shows the same leader and candidates - PASS
• 15.3 Find current leader and withdraw - PASS
• 15.4 Check that a new node was elected leader - PASS
• 15.5 Check that that new leader was the candidate of old leader - PASS
• 15.6 Run for election on old leader( just so everyone is in the hat ) - PASS
• 15.7 Check that oldLeader is a candidate, and leader if only 1 node - No Result

Case 17: Check for basic functionality with distributed primitives - FAIL

Test the methods of the distributed primitives (counters and sets) throught the cli

• 17.1 Increment then get a default counter on each node - PASS
• 17.2 Get then Increment a default counter on each node - PASS
• 17.3 Counters we added have the correct values - PASS
• 17.4 Add -8 to then get a default counter on each node - PASS
• 17.5 Add 5 to then get a default counter on each node - PASS
• 17.6 Get then add 5 to a default counter on each node - PASS
• 17.7 Counters we added have the correct values - PASS
• 17.8 Distributed Set get - FAIL
• Set elements are incorrect
• 17.9 Distributed Set size - FAIL
• Set sizes are incorrect
• 17.10 Distributed Set add() - PASS
• 17.11 Distributed Set addAll() - PASS
• 17.12 Distributed Set contains() - PASS
• 17.13 Distributed Set containsAll() - PASS
• 17.14 Distributed Set remove() - PASS
• 17.15 Distributed Set removeAll() - PASS
• 17.16 Distributed Set addAll() - PASS
• 17.17 Distributed Set clear() - PASS
• 17.18 Distributed Set addAll() - PASS
• 17.19 Distributed Set retain() - FAIL
• Set retain was incorrect
• 17.20 Partitioned Transactional maps put - PASS
• 17.21 Partitioned Transactional maps get - PASS
• 17.22 Get the value of a new value - PASS
• 17.23 Atomic Value set() - PASS
• 17.24 Get the value after set() - PASS
• 17.25 Atomic Value compareAndSet() - PASS
• 17.26 Get the value after compareAndSet() - PASS
• 17.27 Atomic Value getAndSet() - PASS
• 17.28 Get the value after getAndSet() - PASS
• 17.29 Atomic Value destory() - PASS
• 17.30 Get the value after destroy() - PASS
• 17.31 Work Queue add() - PASS
• 17.32 Check the work queue stats - PASS
• 17.33 Work Queue addMultiple() - PASS
• 17.34 Check the work queue stats - PASS
• 17.35 Work Queue takeAndComplete() 1 - PASS
• 17.36 Check the work queue stats - PASS
• 17.37 Work Queue takeAndComplete() 2 - PASS
• 17.38 Check the work queue stats - PASS
• 17.39 Work Queue destroy() - PASS
• 17.40 Check the work queue stats - PASS

Case 9: Turn off a link to ensure that Link Discovery is working properly - PASS

• 9.1 Kill Link between s28 and s3 - PASS

Case 8: Compare ONOS Topology view to Mininet topology - PASS

Compare topology objects between Mininet and ONOS

• 8.1 Comparing ONOS topology to MN topology - PASS
• 8.2 Hosts view is consistent across all ONOS nodes - PASS
• 8.3 Hosts information is correct - PASS
• 8.4 Host attachment points to the network - PASS
• 8.5 Clusters view is consistent across all ONOS nodes - PASS
• 8.6 There is only one SCC - PASS
• 8.7 Device information is correct - PASS
• 8.8 Links are correct - PASS
• 8.9 Hosts are correct - PASS
• 8.10 Checking ONOS nodes - PASS

Case 4: Verify connectivity by sending traffic across Intents - PASS

Ping across added host intents to check functionality and check the state of the intent

• 4.1 Check Intent state - PASS
• 4.2 Ping across added host intents - PASS
• 4.3 Check leadership of topics - PASS
• 4.4 Wait a minute then ping again - PASS

Case 10: Restore a link to ensure that Link Discovery is working properly - PASS

• 10.1 Bring link between s28 and s3 back up - PASS

Case 8: Compare ONOS Topology view to Mininet topology - PASS

Compare topology objects between Mininet and ONOS

• 8.1 Comparing ONOS topology to MN topology - PASS
• 8.2 Hosts view is consistent across all ONOS nodes - PASS
• 8.3 Hosts information is correct - PASS
• 8.4 Host attachment points to the network - PASS
• 8.5 Clusters view is consistent across all ONOS nodes - PASS
• 8.6 There is only one SCC - PASS
• 8.7 Device information is correct - PASS
• 8.8 Links are correct - PASS
• 8.9 Hosts are correct - PASS
• 8.10 Checking ONOS nodes - PASS

Case 4: Verify connectivity by sending traffic across Intents - PASS

Ping across added host intents to check functionality and check the state of the intent

• 4.1 Check Intent state - PASS
• 4.2 Ping across added host intents - PASS
• 4.3 Check leadership of topics - PASS
• 4.4 Wait a minute then ping again - PASS

Case 11: Killing a switch to ensure it is discovered correctly - PASS

• 11.1 Kill s5 - PASS

Case 8: Compare ONOS Topology view to Mininet topology - PASS

Compare topology objects between Mininet and ONOS

• 8.1 Comparing ONOS topology to MN topology - PASS
• 8.2 Hosts view is consistent across all ONOS nodes - PASS
• 8.3 Hosts information is correct - PASS
• 8.4 Host attachment points to the network - PASS
• 8.5 Clusters view is consistent across all ONOS nodes - PASS
• 8.6 There is only one SCC - PASS
• 8.7 Device information is correct - PASS
• 8.8 Links are correct - PASS
• 8.9 Hosts are correct - PASS
• 8.10 Checking ONOS nodes - PASS

Case 4: Verify connectivity by sending traffic across Intents - PASS

Ping across added host intents to check functionality and check the state of the intent

• 4.1 Check Intent state - PASS
• 4.2 Ping across added host intents - PASS
• 4.3 Check leadership of topics - PASS
• 4.4 Wait a minute then ping again - PASS

Case 12: Adding a switch to ensure it is discovered correctly - PASS

• 12.1 Add back s5 - PASS

Case 8: Compare ONOS Topology view to Mininet topology - PASS

Compare topology objects between Mininet and ONOS

• 8.1 Comparing ONOS topology to MN topology - PASS
• 8.2 Hosts view is consistent across all ONOS nodes - PASS
• 8.3 Hosts information is correct - PASS
• 8.4 Host attachment points to the network - PASS
• 8.5 Clusters view is consistent across all ONOS nodes - PASS
• 8.6 There is only one SCC - PASS
• 8.7 Device information is correct - PASS
• 8.8 Links are correct - PASS
• 8.9 Hosts are correct - PASS
• 8.10 Checking ONOS nodes - PASS

Case 4: Verify connectivity by sending traffic across Intents - PASS

Ping across added host intents to check functionality and check the state of the intent

• 4.1 Check Intent state - PASS
• 4.2 Ping across added host intents - PASS
• 4.3 Check leadership of topics - PASS
• 4.4 Wait a minute then ping again - PASS

Case 13: Test Cleanup - PASS

• 13.1 Checking raft log size - PASS
• 13.2 Killing tcpdumps - No Result
• 13.3 Checking ONOS Logs for errors - No Result
• 13.4 Stopping Mininet - PASS