Nova aims to provide upgrades with minimal downtime.
Firstly, the data plane. There should be no VM downtime when you upgrade Nova. Nova has had this since the early days.
Secondly, we want no downtime during upgrades of the Nova control plane. This document is trying to describe how we can achieve that.
Once we have introduced the key concepts relating to upgrade, we will introduce the process needed for a no downtime upgrade of nova.
Minimal Downtime Upgrade Process¶
Plan your upgrade¶
Read and ensure you understand the release notes for the next release.
You should ensure all required steps from the previous upgrade have been completed, such as data migrations.
Make a backup of your database. Nova does not support downgrading of the database. Hence, in case of upgrade failure, restoring database from backup is the only choice.
During upgrade be aware that there will be additional load on nova-conductor. You may find you need to add extra nova-conductor workers to deal with the additional upgrade related load.
Rolling upgrade process¶
To reduce downtime, the compute services can be upgraded in a rolling fashion. It means upgrading a few services at a time. This results in a condition where both old (N) and new (N+1) nova-compute services co-exist for a certain time period. Note that, there is no upgrade of the hypervisor here, this is just upgrading the nova services. If reduced downtime is not a concern (or lower complexity is desired), all services may be taken down and restarted at the same time.
Nova does not currently support the coexistence of N and N+2 or greater
nova-compute or nova-conductor services in the same
deployment. The nova-conductor` service will fail to start when a
nova-compute service that is older than the previous release (N-2 or
greater) is detected. Similarly, in a deployment with multiple cells, neither the super conductor service nor any
per-cell conductor service will start if any other conductor service in the
deployment is older than the previous release.
Before maintenance window:
Start the process with the controller node. Install the code for the next version of Nova, either in a venv or a separate control plane node, including all the python dependencies.
Using the newly installed nova code, run the DB sync. First run
nova-manage api_db sync, then
nova-manage db sync.
nova-manage db syncshould be run for all cell databases, including
cell0. If necessary, the
--config-fileargument can be used to point to the correct
nova.conffile for the given cell.
These schema change operations should have minimal or no effect on performance, and should not cause any operations to fail.
At this point, new columns and tables may exist in the database. These DB schema changes are done in a way that both the N and N+1 release can perform operations against the same schema.
During maintenance window:
Several nova services rely on the external placement service being at the latest level. Therefore, you must upgrade placement before any nova services. See the placement upgrade notes for more details on upgrading the placement service.
For maximum safety (no failed API operations), gracefully shutdown all the services (i.e. SIG_TERM) except nova-compute.
Before restarting services with new code, perform the release-specific readiness check with
nova-status upgrade check. See the nova-status upgrade check for more details on status check.
Start all services on the new code, with
[upgrade_levels]compute=autoin nova.conf. It is safest to start nova-conductor first and nova-api last. Note that you may use a static alias name instead of
auto, such as
[upgrade_levels]compute=<release_name>. Also note that this step is only required if compute services are not upgraded in lock-step with the control services.
If desired, gracefully shutdown nova-compute (i.e. SIG_TERM) services in small batches, then start the new version of the code with:
[upgrade_levels]compute=auto. If this batch-based approach is used, only a few compute nodes will have any delayed API actions, and to ensure there is enough capacity online to service any boot requests that happen during this time.
After maintenance window:
Once all services are running the new code, double check in the DB that there are no old orphaned service records using nova service-list.
Now that all services are upgraded, we need to send the SIG_HUP signal, so all the services clear any cached service version data. When a new service starts, it automatically detects which version of the compute RPC protocol to use, and it can decide if it is safe to do any online data migrations. Note, if you used a static value for the upgrade_level, such as
[upgrade_levels]compute=<release_name>, you must update nova.conf to remove that configuration value and do a full service restart.
Now all the services are upgraded and signaled, the system is able to use the latest version of the RPC protocol and can access all of the features in the new release.
Once all the services are running the latest version of the code, and all the services are aware they all have been upgraded, it is safe to transform the data in the database into its new format. While some of this work happens on demand when the system reads a database row that needs updating, we must get all the data transformed into the current version before the next upgrade. Additionally, some data may not be transformed automatically so performing the data migration is necessary to avoid performance degradation due to compatibility routines.
This process can put significant extra write load on the database. Complete all online data migrations using:
nova-manage db online_data_migrations --max-count <number>. Note that you can use the
--max-countargument to reduce the load this operation will place on the database, which allows you to run a small chunk of the migrations until all of the work is done. The chunk size you should use depends on your infrastructure and how much additional load you can impose on the database. To reduce load, perform smaller batches with delays between chunks. To reduce time to completion, run larger batches. Each time it is run, the command will show a summary of completed and remaining records. If using the
--max-countoption, the command should be rerun while it returns exit status 1 (which indicates that some migrations took effect, and more work may remain to be done), even if some migrations produce errors. If all possible migrations have completed and some are still producing errors, exit status 2 will be returned. In this case, the cause of the errors should be investigated and resolved. Migrations should be considered successfully completed only when the command returns exit status 0.
At this point, you must also ensure you update the configuration, to stop using any deprecated features or options, and perform any required work to transition to alternative features. All deprecated options are supported for at least one cycle, but should be removed before your next upgrade is performed.
Current Database Upgrade Types¶
Currently Nova has two types of database upgrades that are in use.
Nova does not support database downgrades.
Schema migrations are defined in
nova/db/api/migrations/versions. They are the routines that transform our
database structure, which should be additive and able to be applied to a
running system before service code has been upgraded.
For information on developing your own schema migrations as part of a feature or bugfix, refer to Database migrations.
The API database migrations should be assumed to run before the migrations for the main/cell databases. This is because the former contains information about how to find and connect to the latter. Some management commands that operate on multiple cells will attempt to list and iterate over cell mapping records, which require a functioning API database schema.
Online data migrations occur in two places:
Inline migrations that occur as part of normal run-time activity as data is read in the old format and written in the new format
Background online migrations that are performed using
nova-manageto complete transformations that will not occur incidentally due to normal runtime activity.
An example of online data migrations are the flavor migrations done as part of Nova object version 1.18. This included a transient migration of flavor storage from one database location to another.
For information on developing your own schema migrations as part of a feature or bugfix, refer to Database migrations.
The following guidelines for schema and data migrations are followed in order to ease upgrades:
Additive schema migrations - In general, almost all schema migrations should be additive. Put simply, they should only create elements like columns, indices, and tables.
Subtractive schema migrations - To remove an element like a column or table during the N release cycle:
The element must be deprecated and retained for backward compatibility. (This allows for graceful upgrade from N to N+1.)
Data migration, by the objects layer, must completely migrate data from the old version of the schema to the new version.
The column can then be removed with a migration at the start of N+2.
All schema migrations should be idempotent. For example, a migration should check if an element exists in the schema before attempting to add it. This logic comes for free in the autogenerated workflow of the online migrations.
Constraints - When adding a foreign or unique key constraint, the schema migration code needs to handle possible problems with data before applying the constraint. (Example: A unique constraint must clean up duplicate records before applying said constraint.)
Data migrations - As mentioned above, data migrations will be done in an online fashion by custom code in the object layer that handles moving data between the old and new portions of the schema. In addition, for each type of data migration performed, there should exist a nova-manage option for an operator to manually request that rows be migrated.
Here are the key concepts you need to know before reading the section on the upgrade process:
- RPC version pinning
Through careful RPC versioning, newer nodes are able to talk to older nova-compute nodes. When upgrading control plane nodes, we can pin them at an older version of the compute RPC API, until all the compute nodes are able to be upgraded. https://wiki.openstack.org/wiki/RpcMajorVersionUpdates
The procedure for rolling upgrades with multiple cells v2 cells is not yet determined.
- Online Configuration Reload
During the upgrade, we pin new serves at the older RPC version. When all services are updated to use newer code, we need to unpin them so we are able to use any new functionality. To avoid having to restart the service, using the current SIGHUP signal handling, or otherwise, ideally we need a way to update the currently running process to use the latest configuration.
- Graceful service shutdown
Many nova services are python processes listening for messages on a AMQP queue, including nova-compute. When sending the process the SIGTERM the process stops getting new work from its queue, completes any outstanding work, then terminates. During this process, messages can be left on the queue for when the python process starts back up. This gives us a way to shutdown a service using older code, and start up a service using newer code with minimal impact. If its a service that can have multiple workers, like nova-conductor, you can usually add the new workers before the graceful shutdown of the old workers. In the case of singleton services, like nova-compute, some actions could be delayed during the restart, but ideally no actions should fail due to the restart.
While this is true for the RabbitMQ RPC backend, we need to confirm what happens for other RPC backends.
- API load balancer draining
When upgrading API nodes, you can make your load balancer only send new connections to the newer API nodes, allowing for a seamless update of your API nodes.
- Expand/Contract DB Migrations
Modern databases are able to make many schema changes while you are still writing to the database. Taking this a step further, we can make all DB changes by first adding the new structures, expanding. Then you can slowly move all the data into a new location and format. Once that is complete, you can drop bits of the scheme that are no long needed, i.e. contract. This happens multiple cycles after we have stopped using a particular piece of schema, and can happen in a schema migration without affecting runtime code.
- Online Data Migrations using objects
Since Kilo, we have moved all data migration into the DB objects code. When trying to migrate data in the database from the old format to the new format, this is done in the object code when reading or saving things that are in the old format. For records that are not updated, you need to run a background process to convert those records into the newer format. This process must be completed before you contract the database schema.
- DB prune deleted rows
Currently resources are soft deleted in the main database, so users are able to track instances in the DB that are created and destroyed in production. However, most people have a data retention policy, of say 30 days or 90 days after which they will want to delete those entries. Not deleting those entries affects DB performance as indices grow very large and data migrations take longer as there is more data to migrate.
- nova-conductor object backports
RPC pinning ensures new services can talk to the older service’s method signatures. But many of the parameters are objects that may well be too new for the old service to understand, so you are able to send the object back to the nova-conductor to be downgraded to a version the older service can understand.
We use the “grenade” jobs to test upgrades. The current tests only cover the existing upgrade process where old computes can run with new control plane but control plane is turned off for DB migrations.