525 lines
20 KiB
Markdown
525 lines
20 KiB
Markdown
---
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type: reference, dev
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stage: none
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group: Development
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info: "See the Technical Writers assigned to Development Guidelines: https://about.gitlab.com/handbook/engineering/ux/technical-writing/#assignments-to-development-guidelines"
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---
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# Background migrations
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Background migrations should be used to perform data migrations whenever a
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migration exceeds [the time limits in our guidelines](migration_style_guide.md#how-long-a-migration-should-take). For example, you can use background
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migrations to migrate data that's stored in a single JSON column
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to a separate table instead.
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If the database cluster is considered to be in an unhealthy state, background
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migrations automatically reschedule themselves for a later point in time.
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## When To Use Background Migrations
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You should use a background migration when you migrate _data_ in tables that have
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so many rows that the process would exceed [the time limits in our guidelines](migration_style_guide.md#how-long-a-migration-should-take) if performed using a regular Rails migration.
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- Background migrations should be used when migrating data in [high-traffic tables](migration_style_guide.md#high-traffic-tables).
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- Background migrations may also be used when executing numerous single-row queries
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for every item on a large dataset. Typically, for single-record patterns, runtime is
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largely dependent on the size of the dataset, hence it should be split accordingly
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and put into background migrations.
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- Background migrations should not be used to perform schema migrations.
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Some examples where background migrations can be useful:
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- Migrating events from one table to multiple separate tables.
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- Populating one column based on JSON stored in another column.
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- Migrating data that depends on the output of external services (for example, an API).
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NOTE:
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If the background migration is part of an important upgrade, make sure it's announced
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in the release post. Discuss with your Project Manager if you're not sure the migration falls
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into this category.
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## Isolation
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Background migrations must be isolated and can not use application code (for example,
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models defined in `app/models`). Since these migrations can take a long time to
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run it's possible for new versions to be deployed while they are still running.
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It's also possible for different migrations to be executed at the same time.
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This means that different background migrations should not migrate data in a
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way that would cause conflicts.
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## Idempotence
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Background migrations are executed in a context of a Sidekiq process.
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Usual Sidekiq rules apply, especially the rule that jobs should be small
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and idempotent.
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See [Sidekiq best practices guidelines](https://github.com/mperham/sidekiq/wiki/Best-Practices)
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for more details.
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Make sure that in case that your migration job is going to be retried data
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integrity is guaranteed.
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## Background migrations for EE-only features
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All the background migration classes for EE-only features should be present in GitLab CE.
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For this purpose, an empty class can be created for GitLab CE, and it can be extended for GitLab EE
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as explained in the [guidelines for implementing Enterprise Edition features](ee_features.md#code-in-libgitlabbackground_migration).
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## How It Works
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Background migrations are simple classes that define a `perform` method. A
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Sidekiq worker will then execute such a class, passing any arguments to it. All
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migration classes must be defined in the namespace
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`Gitlab::BackgroundMigration`, the files should be placed in the directory
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`lib/gitlab/background_migration/`.
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## Scheduling
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Scheduling a background migration should be done in a post-deployment
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migration that includes `Gitlab::Database::MigrationHelpers`
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To do so, simply use the following code while
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replacing the class name and arguments with whatever values are necessary for
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your migration:
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```ruby
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migrate_async('BackgroundMigrationClassName', [arg1, arg2, ...])
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```
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Usually it's better to enqueue jobs in bulk, for this you can use
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`bulk_migrate_async`:
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```ruby
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bulk_migrate_async(
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[['BackgroundMigrationClassName', [1]],
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['BackgroundMigrationClassName', [2]]]
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)
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```
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Note that this will queue a Sidekiq job immediately: if you have a large number
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of records, this may not be what you want. You can use the function
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`queue_background_migration_jobs_by_range_at_intervals` to split the job into
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batches:
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```ruby
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queue_background_migration_jobs_by_range_at_intervals(
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ClassName,
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BackgroundMigrationClassName,
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2.minutes,
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batch_size: 10_000
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)
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```
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You'll also need to make sure that newly created data is either migrated, or
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saved in both the old and new version upon creation. For complex and time
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consuming migrations it's best to schedule a background job using an
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`after_create` hook so this doesn't affect response timings. The same applies to
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updates. Removals in turn can be handled by simply defining foreign keys with
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cascading deletes.
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If you would like to schedule jobs in bulk with a delay, you can use
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`BackgroundMigrationWorker.bulk_perform_in`:
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```ruby
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jobs = [['BackgroundMigrationClassName', [1]],
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['BackgroundMigrationClassName', [2]]]
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bulk_migrate_in(5.minutes, jobs)
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```
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### Rescheduling background migrations
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If one of the background migrations contains a bug that is fixed in a patch
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release, the background migration needs to be rescheduled so the migration would
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be repeated on systems that already performed the initial migration.
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When you reschedule the background migration, make sure to turn the original
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scheduling into a no-op by clearing up the `#up` and `#down` methods of the
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migration performing the scheduling. Otherwise the background migration would be
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scheduled multiple times on systems that are upgrading multiple patch releases at
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once.
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When you start the second post-deployment migration, you should delete any
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previously queued jobs from the initial migration with the provided
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helper:
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```ruby
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delete_queued_jobs('BackgroundMigrationClassName')
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```
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## Cleaning Up
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NOTE:
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Cleaning up any remaining background migrations _must_ be done in either a major
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or minor release, you _must not_ do this in a patch release.
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Because background migrations can take a long time you can't immediately clean
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things up after scheduling them. For example, you can't drop a column that's
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used in the migration process as this would cause jobs to fail. This means that
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you'll need to add a separate _post deployment_ migration in a future release
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that finishes any remaining jobs before cleaning things up (for example, removing a
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column).
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As an example, say you want to migrate the data from column `foo` (containing a
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big JSON blob) to column `bar` (containing a string). The process for this would
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roughly be as follows:
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1. Release A:
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1. Create a migration class that performs the migration for a row with a given ID.
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You can use [background jobs tracking](#background-jobs-tracking) to simplify cleaning up.
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1. Deploy the code for this release, this should include some code that will
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schedule jobs for newly created data (for example, using an `after_create` hook).
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1. Schedule jobs for all existing rows in a post-deployment migration. It's
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possible some newly created rows may be scheduled twice so your migration
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should take care of this.
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1. Release B:
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1. Deploy code so that the application starts using the new column and stops
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scheduling jobs for newly created data.
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1. In a post-deployment migration, finalize all jobs that have not succeeded by now.
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If you used [background jobs tracking](#background-jobs-tracking) in release A,
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you can use `finalize_background_migration` from `BackgroundMigrationHelpers` to ensure no jobs remain.
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This helper will:
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1. Use `Gitlab::BackgroundMigration.steal` to process any remaining
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jobs in Sidekiq.
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1. Reschedule the migration to be run directly (that is, not through Sidekiq)
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on any rows that weren't migrated by Sidekiq. This can happen if, for
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instance, Sidekiq received a SIGKILL, or if a particular batch failed
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enough times to be marked as dead.
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1. Remove `Gitlab::Database::BackgroundMigrationJob` rows where
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`status = succeeded`. To retain diagnostic information that may
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help with future bug tracking you can skip this step by specifying
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the `delete_tracking_jobs: false` parameter.
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1. Remove the old column.
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This may also require a bump to the [import/export version](../user/project/settings/import_export.md), if
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importing a project from a prior version of GitLab requires the data to be in
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the new format.
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## Example
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To explain all this, let's use the following example: the table `services` has a
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field called `properties` which is stored in JSON. For all rows you want to
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extract the `url` key from this JSON object and store it in the `services.url`
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column. There are millions of services and parsing JSON is slow, thus you can't
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do this in a regular migration.
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To do this using a background migration we'll start with defining our migration
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class:
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```ruby
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class Gitlab::BackgroundMigration::ExtractServicesUrl
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class Service < ActiveRecord::Base
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self.table_name = 'services'
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end
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def perform(service_id)
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# A row may be removed between scheduling and starting of a job, thus we
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# need to make sure the data is still present before doing any work.
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service = Service.select(:properties).find_by(id: service_id)
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return unless service
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begin
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json = JSON.load(service.properties)
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rescue JSON::ParserError
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# If the JSON is invalid we don't want to keep the job around forever,
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# instead we'll just leave the "url" field to whatever the default value
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# is.
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return
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end
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service.update(url: json['url']) if json['url']
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end
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end
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```
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Next we'll need to adjust our code so we schedule the above migration for newly
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created and updated services. We can do this using something along the lines of
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the following:
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```ruby
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class Service < ActiveRecord::Base
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after_commit :schedule_service_migration, on: :update
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after_commit :schedule_service_migration, on: :create
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def schedule_service_migration
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BackgroundMigrationWorker.perform_async('ExtractServicesUrl', [id])
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end
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end
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```
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We're using `after_commit` here to ensure the Sidekiq job is not scheduled
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before the transaction completes as doing so can lead to race conditions where
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the changes are not yet visible to the worker.
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Next we'll need a post-deployment migration that schedules the migration for
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existing data. Since we're dealing with a lot of rows we'll schedule jobs in
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batches instead of doing this one by one:
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```ruby
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class ScheduleExtractServicesUrl < Gitlab::Database::Migration[1.0]
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disable_ddl_transaction!
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def up
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define_batchable_model('services').select(:id).in_batches do |relation|
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jobs = relation.pluck(:id).map do |id|
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['ExtractServicesUrl', [id]]
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end
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BackgroundMigrationWorker.bulk_perform_async(jobs)
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end
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end
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def down
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end
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end
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```
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Once deployed our application will continue using the data as before but at the
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same time will ensure that both existing and new data is migrated.
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In the next release we can remove the `after_commit` hooks and related code. We
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will also need to add a post-deployment migration that consumes any remaining
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jobs and manually run on any un-migrated rows. Such a migration would look like
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this:
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```ruby
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class ConsumeRemainingExtractServicesUrlJobs < Gitlab::Database::Migration[1.0]
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disable_ddl_transaction!
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def up
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# This must be included
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Gitlab::BackgroundMigration.steal('ExtractServicesUrl')
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# This should be included, but can be skipped - see below
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define_batchable_model('services').where(url: nil).each_batch(of: 50) do |batch|
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range = batch.pluck('MIN(id)', 'MAX(id)').first
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Gitlab::BackgroundMigration::ExtractServicesUrl.new.perform(*range)
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end
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end
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def down
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end
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end
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```
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The final step runs for any un-migrated rows after all of the jobs have been
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processed. This is in case a Sidekiq process running the background migrations
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received SIGKILL, leading to the jobs being lost. (See
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[more reliable Sidekiq queue](https://gitlab.com/gitlab-org/gitlab-foss/-/issues/36791) for more information.)
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If the application does not depend on the data being 100% migrated (for
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instance, the data is advisory, and not mission-critical), then this final step
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can be skipped.
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This migration will then process any jobs for the ExtractServicesUrl migration
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and continue once all jobs have been processed. Once done you can safely remove
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the `services.properties` column.
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## Testing
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It is required to write tests for:
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- The background migrations' scheduling migration.
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- The background migration itself.
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- A cleanup migration.
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The `:migration` and `schema: :latest` RSpec tags are automatically set for
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background migration specs.
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See the
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[Testing Rails migrations](testing_guide/testing_migrations_guide.md#testing-a-non-activerecordmigration-class)
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style guide.
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Keep in mind that `before` and `after` RSpec hooks are going
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to migrate you database down and up, which can result in other background
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migrations being called. That means that using `spy` test doubles with
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`have_received` is encouraged, instead of using regular test doubles, because
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your expectations defined in a `it` block can conflict with what is being
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called in RSpec hooks. See [issue #35351](https://gitlab.com/gitlab-org/gitlab/-/issues/18839)
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for more details.
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## Best practices
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1. Make sure to know how much data you're dealing with.
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1. Make sure that background migration jobs are idempotent.
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1. Make sure that tests you write are not false positives.
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1. Make sure that if the data being migrated is critical and cannot be lost, the
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clean-up migration also checks the final state of the data before completing.
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1. When migrating many columns, make sure it won't generate too many
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dead tuples in the process (you may need to directly query the number of dead tuples
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and adjust the scheduling according to this piece of data).
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1. Make sure to discuss the numbers with a database specialist, the migration may add
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more pressure on DB than you expect (measure on staging,
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or ask someone to measure on production).
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1. Make sure to know how much time it'll take to run all scheduled migrations.
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1. Provide an estimation section in the description, estimating both the total migration
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run time and the query times for each background migration job. Explain plans for each query
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should also be provided.
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For example, assuming a migration that deletes data, include information similar to
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the following section:
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```plaintext
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Background Migration Details:
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47600 items to delete
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batch size = 1000
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47600 / 1000 = 48 batches
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Estimated times per batch:
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- 820ms for select statement with 1000 items (see linked explain plan)
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- 900ms for delete statement with 1000 items (see linked explain plan)
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Total: ~2 sec per batch
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2 mins delay per batch (safe for the given total time per batch)
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48 batches * 2 min per batch = 96 mins to run all the scheduled jobs
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```
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The execution time per batch (2 sec in this example) is not included in the calculation
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for total migration time. The jobs are scheduled 2 minutes apart without knowledge of
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the execution time.
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## Additional tips and strategies
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### Nested batching
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A strategy to make the migration run faster is to schedule larger batches, and then use `EachBatch`
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within the background migration to perform multiple statements.
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The background migration helpers that queue multiple jobs such as
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`queue_background_migration_jobs_by_range_at_intervals` use [`EachBatch`](iterating_tables_in_batches.md).
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The example above has batches of 1000, where each queued job takes two seconds. If the query has been optimized
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to make the time for the delete statement within the [query performance guidelines](query_performance.md),
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1000 may be the largest number of records that can be deleted in a reasonable amount of time.
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The minimum and most common interval for delaying jobs is two minutes. This results in two seconds
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of work for each two minute job. There's nothing that prevents you from executing multiple delete
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statements in each background migration job.
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Looking at the example above, you could alternatively do:
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```plaintext
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Background Migration Details:
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47600 items to delete
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batch size = 10_000
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47600 / 10_000 = 5 batches
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Estimated times per batch:
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- Records are updated in sub-batches of 1000 => 10_000 / 1000 = 10 total updates
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- 820ms for select statement with 1000 items (see linked explain plan)
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- 900ms for delete statement with 1000 items (see linked explain plan)
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Sub-batch total: ~2 sec per sub-batch,
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Total batch time: 2 * 10 = 20 sec per batch
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2 mins delay per batch
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5 batches * 2 min per batch = 10 mins to run all the scheduled jobs
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```
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The batch time of 20 seconds still fits comfortably within the two minute delay, yet the total run
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time is cut by a tenth from around 100 minutes to 10 minutes! When dealing with large background
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migrations, this can cut the total migration time by days.
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When batching in this way, it is important to look at query times on the higher end
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of the table or relation being updated. `EachBatch` may generate some queries that become much
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slower when dealing with higher ID ranges.
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### Delay time
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When looking at the batch execution time versus the delay time, the execution time
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should fit comfortably within the delay time for a few reasons:
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- To allow for a variance in query times.
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- To allow autovacuum to catch up after periods of high churn.
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Never try to optimize by fully filling the delay window even if you are confident
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the queries themselves have no timing variance.
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### Background jobs tracking
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`queue_background_migration_jobs_by_range_at_intervals` can create records for each job that is scheduled to run.
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You can enable this behavior by passing `track_jobs: true`. Each record starts with a `pending` status. Make sure that your worker updates the job status to `succeeded` by calling `Gitlab::Database::BackgroundMigrationJob.mark_all_as_succeeded` in the `perform` method of your background migration.
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```ruby
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# Background migration code
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def perform(start_id, end_id)
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# do work here
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mark_job_as_succeeded(start_id, end_id)
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end
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private
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# Make sure that the arguments passed here match those passed to the background
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# migration
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def mark_job_as_succeeded(*arguments)
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Gitlab::Database::BackgroundMigrationJob.mark_all_as_succeeded(
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self.class.name.demodulize,
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arguments
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)
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end
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```
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```ruby
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# Post deployment migration
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MIGRATION = 'YourBackgroundMigrationName'
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DELAY_INTERVAL = 2.minutes.to_i # can be different
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BATCH_SIZE = 10_000 # can be different
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disable_ddl_transaction!
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def up
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queue_background_migration_jobs_by_range_at_intervals(
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define_batchable_model('name_of_the_table_backing_the_model'),
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MIGRATION,
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DELAY_INTERVAL,
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batch_size: BATCH_SIZE,
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track_jobs: true
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)
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end
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def down
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# no-op
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end
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```
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See [`lib/gitlab/background_migration/drop_invalid_vulnerabilities.rb`](https://gitlab.com/gitlab-org/gitlab/blob/master/lib/gitlab/background_migration/drop_invalid_vulnerabilities.rb) for a full example.
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#### Rescheduling pending jobs
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You can reschedule pending migrations from the `background_migration_jobs` table by creating a post-deployment migration and calling `requeue_background_migration_jobs_by_range_at_intervals` with the migration name and delay interval.
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```ruby
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# Post deployment migration
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MIGRATION = 'YourBackgroundMigrationName'
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DELAY_INTERVAL = 2.minutes
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|
|
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disable_ddl_transaction!
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|
|
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def up
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requeue_background_migration_jobs_by_range_at_intervals(MIGRATION, DELAY_INTERVAL)
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end
|
|
|
|
def down
|
|
# no-op
|
|
end
|
|
```
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|
|
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See [`db/post_migrate/20210604070207_retry_backfill_traversal_ids.rb`](https://gitlab.com/gitlab-org/gitlab/blob/master/db/post_migrate/20210604070207_retry_backfill_traversal_ids.rb) for a full example.
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### Viewing failure error logs
|
|
|
|
After running a background migration, if any jobs have failed, you can view the logs in [Kibana](https://log.gprd.gitlab.net/goto/5f06a57f768c6025e1c65aefb4075694).
|
|
View the production Sidekiq log and filter for:
|
|
|
|
- `json.class: BackgroundMigrationWorker`
|
|
- `json.job_status: fail`
|
|
- `json.meta.caller_id: <MyBackgroundMigrationClassName>`
|
|
|
|
Looking at the `json.error_class`, `json.error_message` and `json.error_backtrace` values may be helpful in understanding why the jobs failed.
|
|
|
|
Depending on when and how the failure occurred, you may find other helpful information by filtering with `json.class: <MyBackgroundMigrationClassName>`.
|