Migration Strategy

This document details an in-place migration strategy from ML2/OVS to ML2/OVN in either ovs-firewall or ovs-hybrid mode for a TripleO OpenStack deployment.

For non TripleO deployments, please refer to the file migration/README.rst and the ansible playbook migration/migrate-to-ovn.yml.

Overview

The migration process is orchestrated through the shell script ovn_migration.sh, which is provided with networking-ovn.

The administrator uses ovn_migration.sh to perform readiness steps and migration from the undercloud node. The readiness steps, such as host inventory production, DHCP and MTU adjustments, prepare the environment for the procedure.

Subsequent steps start the migration via Ansible.

Plan for a 24-hour wait after the setup-mtu-t1 step to allow VMs to catch up with the new MTU size. The default neutron ML2/OVS configuration has a dhcp_lease_duration of 86400 seconds (24h).

Also, if there are instances using static IP assignment, the administrator should be ready to update the MTU of those instances to the new value of 8 bytes less than the ML2/OVS (VXLAN) MTU value. For example, the typical 1500 MTU network value that makes VXLAN tenant networks use 1450 bytes of MTU will need to change to 1442 under Geneve. Or under the same overlay network, a GRE encapsulated tenant network would use a 1458 MTU, but again a 1442 MTU for Geneve.

If there are instances which use DHCP but don’t support lease update during the T1 period the administrator will need to reboot them to ensure that MTU is updated inside those instances.

Steps for migration

Perform the following steps in the overcloud/undercloud

  1. Ensure that you have updated to the latest openstack/neutron version.

Perform the following steps in the undercloud

  1. Install python-networking-ovn-migration-tool.

yum install python-networking-ovn-migration-tool
  1. Create a working directory on the undercloud, and copy the ansible playbooks

mkdir ~/ovn_migration
cd ~/ovn_migration
cp -rfp /usr/share/ansible/networking-ovn-migration/playbooks .

3. Create ~/overcloud-deploy-ovn.sh script in your $HOME. This script must source your stackrc file, and then execute an openstack overcloud deploy with your original deployment parameters, plus the following environment files, added to the end of the command in the following order:

When your network topology is DVR and your compute nodes have connectivity to the external network:

-e /usr/share/openstack-tripleo-heat-templates/environments/services/neutron-ovn-dvr-ha.yaml \
-e $HOME/ovn-extras.yaml

When your compute nodes don’t have external connectivity and you don’t use DVR:

-e /usr/share/openstack-tripleo-heat-templates/environments/services/neutron-ovn-ha.yaml \
-e $HOME/ovn-extras.yaml

Make sure that all users have execution privileges on the script, because it will be called by ovn_migration.sh/ansible during the migration process.

$ chmod a+x ~/overcloud-deploy-ovn.sh

4. To configure the parameters of your migration you can set the environment variables that will be used by ovn_migration.sh. You can skip setting any values matching the defaults.

  • STACKRC_FILE - must point to your stackrc file in your undercloud. Default: ~/stackrc

  • OVERCLOUDRC_FILE - must point to your overcloudrc file in your undercloud. Default: ~/overcloudrc

  • OVERCLOUD_OVN_DEPLOY_SCRIPT - must point to the script described in step 1.. Default: ~/overcloud-deploy-ovn.sh

  • UNDERCLOUD_NODE_USER - user used on the undercloud nodes Default: heat-admin

  • STACK_NAME - Name or ID of the heat stack Default: ‘overcloud’ If the stack that is migrated differs from the default, please set this environment variable to the stack name or ID.

  • PUBLIC_NETWORK_NAME - Name of your public network. Default: ‘public’. To support migration validation, this network must have available floating IPs, and those floating IPs must be pingable from the undercloud. If that’s not possible please configure VALIDATE_MIGRATION to False.

  • IMAGE_NAME - Name/ID of the glance image to us for booting a test server. Default:’cirros’. If the image does not exist it will automatically download and use cirros during the pre-validation / post-validation process.

  • VALIDATE_MIGRATION - Create migration resources to validate the migration. The migration script, before starting the migration, boot a server and validates that the server is reachable after the migration. Default: True.

  • SERVER_USER_NAME - User name to use for logging into the migration instances. Default: ‘cirros’.

  • DHCP_RENEWAL_TIME - DHCP renewal time in seconds to configure in DHCP agent configuration file. This renewal time is used only temporarily during migration to ensure a synchronized MTU switch across the networks. Default: 30

Warning

Please note that VALIDATE_MIGRATION requires enough quota (2 available floating ips, 2 networks, 2 subnets, 2 instances, and 2 routers as admin).

For example:

$ export PUBLIC_NETWORK_NAME=my-public-network
$ ovn_migration.sh .........
  1. Run ovn_migration.sh generate-inventory to generate the inventory file - hosts_for_migration and ansible.cfg. Please review hosts_for_migration for correctness.

    $ ovn_migration.sh generate-inventory


At this step the script will inspect the TripleO ansible inventory
and generate an inventory of hosts, specifically tagged to work
with the migration playbooks.
  1. Run ovn_migration.sh setup-mtu-t1

    $ ovn_migration.sh setup-mtu-t1


This lowers the T1 parameter
of the internal neutron DHCP servers configuring the ``dhcp_renewal_time``
in /var/lib/config-data/puppet-generated/neutron/etc/neutron/dhcp_agent.ini
in all the nodes where DHCP agent is running.

We lower the T1 parameter to make sure that the instances start refreshing
the DHCP lease quicker (every 30 seconds by default) during the migration
proccess. The reason why we force this is to make sure that the MTU update
happens quickly across the network during step 8, this is very important
because during those 30 seconds there will be connectivity issues with
bigger packets (MTU missmatchess across the network), this is also why
step 7 is very important, even though we reduce T1, the previous T1 value
the instances leased from the DHCP server will be much higher
(24h by default) and we need to wait those 24h to make sure they have
updated T1. After migration the DHCP T1 parameter returns to normal values.

7. If you are using VXLAN or GRE tenant networking, wait at least 24 hours before continuing. This will allow VMs to catch up with the new MTU size of the next step.

Warning

If you are using VXLAN or GRE networks, this 24-hour wait step is critical. If you are using VLAN tenant networks you can proceed to the next step without delay.

Warning

If you have any instance with static IP assignment on VXLAN or GRE tenant networks, you must manually modify the configuration of those instances. If your instances don’t honor the T1 parameter of DHCP they will need to be rebooted. to configure the new geneve MTU, which is the current VXLAN MTU minus 8 bytes. For instance, if the VXLAN-based MTU was 1450, change it to 1442.

Note

24 hours is the time based on default configuration. It actually depends on /var/lib/config-data/puppet-generated/neutron/etc/neutron/dhcp_agent.ini dhcp_renewal_time and /var/lib/config-data/puppet-generated/neutron/etc/neutron/neutron.conf dhcp_lease_duration parameters. (defaults to 86400 seconds)

Note

Please note that migrating a deployment which uses VLAN for tenant/project networks is not recommended at this time because of a bug in core ovn, full support is being worked out here: https://mail.openvswitch.org/pipermail/ovs-dev/2018-May/347594.html

One way to verify that the T1 parameter has propagated to existing VMs is to connect to one of the compute nodes, and run tcpdump over one of the VM taps attached to a tenant network. If T1 propegation was a success, you should see that requests happen on an interval of approximately 30 seconds.

[heat-admin@overcloud-novacompute-0 ~]$ sudo tcpdump -i tap52e872c2-e6 port 67 or port 68 -n
tcpdump: verbose output suppressed, use -v or -vv for full protocol decode
listening on tap52e872c2-e6, link-type EN10MB (Ethernet), capture size 262144 bytes
13:17:28.954675 IP 192.168.99.5.bootpc > 192.168.99.3.bootps: BOOTP/DHCP, Request from fa:16:3e:6b:41:3d, length 300
13:17:28.961321 IP 192.168.99.3.bootps > 192.168.99.5.bootpc: BOOTP/DHCP, Reply, length 355
13:17:56.241156 IP 192.168.99.5.bootpc > 192.168.99.3.bootps: BOOTP/DHCP, Request from fa:16:3e:6b:41:3d, length 300
13:17:56.249899 IP 192.168.99.3.bootps > 192.168.99.5.bootpc: BOOTP/DHCP, Reply, length 355

Note

This verification is not possible with cirros VMs. The cirros udhcpc implementation does not obey DHCP option 58 (T1). Please try this verification on a port that belongs to a full linux VM. We recommend you to check all the different types of workloads your system runs (Windows, different flavors of linux, etc..).

  1. Run ovn_migration.sh reduce-mtu.

    This lowers the MTU of the pre migration VXLAN and GRE networks. The tool will ignore non-VXLAN/GRE networks, so if you use VLAN for tenant networks it will be fine if you find this step not doing anything.

    $ ovn_migration.sh reduce-mtu
    

    This step will go network by network reducing the MTU, and tagging with adapted_mtu the networks which have been already handled.

    Every time a network is updated all the existing L3/DHCP agents connected to such network will update their internal leg MTU, instances will start fetching the new MTU as the DHCP T1 timer expires. As explained before, instances not obeying the DHCP T1 parameter will need to be restarted, and instances with static IP assignment will need to be manually updated.

  2. Make TripleO prepare the new container images for OVN.

    If your deployment didn’t have a containers-prepare-parameter.yaml, you can create one with:

    $ test -f $HOME/containers-prepare-parameter.yaml || \
          openstack tripleo container image prepare default \
                --output-env-file $HOME/containers-prepare-parameter.yaml
    

    If you had to create the file, please make sure it’s included at the end of your $HOME/overcloud-deploy-ovn.sh and $HOME/overcloud-deploy.sh

    Change the neutron_driver in the containers-prepare-parameter.yaml file to ovn:

    $ sed -i -E 's/neutron_driver:([ ]\w+)/neutron_driver: ovn/' $HOME/containers-prepare-parameter.yaml
    

    You can verify with:

    $ grep neutron_driver $HOME/containers-prepare-parameter.yaml
    neutron_driver: ovn
    

    Then update the images:

    $ openstack tripleo container image prepare \
         --environment-file $HOME/containers-prepare-parameter.yaml
    

    Note

    It’s important to provide the full path to your containers-prepare-parameter.yaml otherwise the command will finish very quickly and won’t work (current version doesn’t seem to output any error).

    During this step TripleO will build a list of containers, pull them from the remote registry and push them to your deployment local registry.

  3. Run ovn_migration.sh start-migration to kick start the migration process.

$ ovn_migration.sh start-migration

During this step, this is what will happen:

  • Create pre-migration resources (network and VM) to validate existing deployment and final migration.

  • Update the overcloud stack to deploy OVN alongside reference implementation services using a temporary bridge “br-migration” instead of br-int.

  • Start the migration process:

    1. generate the OVN north db by running neutron-ovn-db-sync util

    2. clone the existing resources from br-int to br-migration, to ovn find the same resources UUIDS over br-migration

    3. re-assign ovn-controller to br-int instead of br-migration

    4. cleanup network namespaces (fip, snat, qrouter, qdhcp),

    5. remove any unnecessary patch ports on br-int

    6. remove br-tun and br-migration ovs bridges

    7. delete qr-, ha- and qg-* ports from br-int (via neutron netns cleanup)

  • Delete neutron agents and neutron HA internal networks from the database via API.

  • Validate connectivity on pre-migration resources.

  • Delete pre-migration resources.

  • Create post-migration resources.

  • Validate connectivity on post-migration resources.

  • Cleanup post-migration resources.

  • Re-run deployment tool to update OVN on br-int, this step ensures that the TripleO database is updated with the final integration bridge.

  • Run an extra validation round to ensure the final state of the system is fully operational.

Migration is complete !!!