--- stage: Data Stores group: Sharding info: To determine the technical writer assigned to the Stage/Group associated with this page, see https://about.gitlab.com/handbook/engineering/ux/technical-writing/#assignments --- # Multiple Databases To allow GitLab to scale further we [decomposed the GitLab application database into multiple databases](https://gitlab.com/groups/gitlab-org/-/epics/6168). The two databases are `main` and `ci`. GitLab supports being run with either one database or two databases. On GitLab.com we are using two separate databases. ## GitLab Schema For properly discovering allowed patterns between different databases the GitLab application implements the `lib/gitlab/database/gitlab_schemas.yml` YAML file. This file provides a virtual classification of tables into a `gitlab_schema` which conceptually is similar to [PostgreSQL Schema](https://www.postgresql.org/docs/current/ddl-schemas.html). We decided as part of [using database schemas to better isolated CI decomposed features](https://gitlab.com/gitlab-org/gitlab/-/issues/333415) that we cannot use PostgreSQL schema due to complex migration procedures. Instead we implemented the concept of application-level classification. Each table of GitLab needs to have a `gitlab_schema` assigned: - `gitlab_main`: describes all tables that are being stored in the `main:` database (for example, like `projects`, `users`). - `gitlab_ci`: describes all CI tables that are being stored in the `ci:` database (for example, `ci_pipelines`, `ci_builds`). - `gitlab_geo`: describes all Geo tables that are being stored in the `geo:` database (for example, like `project_registry`, `secondary_usage_data`). - `gitlab_shared`: describe all application tables that contain data across all decomposed databases (for example, `loose_foreign_keys_deleted_records`) for models that inherit from `Gitlab::Database::SharedModel`. - `gitlab_internal`: describe all internal tables of Rails and PostgreSQL (for example, `ar_internal_metadata`, `schema_migrations`, `pg_*`). - `...`: more schemas to be introduced with additional decomposed databases The usage of schema enforces the base class to be used: - `ApplicationRecord` for `gitlab_main` - `Ci::ApplicationRecord` for `gitlab_ci` - `Geo::TrackingBase` for `gitlab_geo` - `Gitlab::Database::SharedModel` for `gitlab_shared` ### The impact of `gitlab_schema` The usage of `gitlab_schema` has a significant impact on the application. The `gitlab_schema` primary purpose is to introduce a barrier between different data access patterns. This is used as a primary source of classification for: - [Discovering cross-joins across tables from different schemas](#removing-joins-between-ci-and-non-ci-tables) - [Discovering cross-database transactions across tables from different schemas](#removing-cross-database-transactions) ### The special purpose of `gitlab_shared` `gitlab_shared` is a special case that describes tables or views that, by design, contain data across all decomposed databases. This classification describes application-defined tables (like `loose_foreign_keys_deleted_records`). **Be careful** to use `gitlab_shared` as it requires special handling while accessing data. Since `gitlab_shared` shares not only structure but also data, the application needs to be written in a way that traverses all data from all databases in sequential manner. ```ruby Gitlab::Database::EachDatabase.each_model_connection([MySharedModel]) do |connection, connection_name| MySharedModel.select_all_data... end ``` As such, migrations modifying data of `gitlab_shared` tables are expected to run across all decomposed databases. ### The special purpose of `gitlab_internal` `gitlab_internal` describes Rails-defined tables (like `schema_migrations` or `ar_internal_metadata`), as well as internal PostgreSQL tables (for example, `pg_attribute`). Its primary purpose is to [support other databases](https://gitlab.com/gitlab-org/gitlab/-/merge_requests/85842#note_943453682), like Geo, that might be missing some of those application-defined `gitlab_shared` tables (like `loose_foreign_keys_deleted_records`), but are valid Rails databases. ## Migrations Read [Migrations for Multiple Databases](migrations_for_multiple_databases.md). ## CI/CD Database ### Configure single database By default, GDK is configured to run with multiple databases. WARNING: Switching back-and-forth between single and multiple databases in the same development instance is discouraged. Any data in the `ci` database will not be accessible in single database mode. For single database, you should use a separate development instance. To configure GDK to use a single database: 1. On the GDK root directory, run: ```shell gdk config set gitlab.rails.databases.ci.enabled false ``` 1. Reconfigure GDK: ```shell gdk reconfigure ``` To switch back to using multiple databases, set `gitlab.rails.databases.ci.enabled` to `true` and run `gdk reconfigure`. ### Removing joins between `ci` and non `ci` tables Queries that join across databases raise an error. [Introduced](https://gitlab.com/gitlab-org/gitlab/-/merge_requests/68620) in GitLab 14.3, for new queries only. Pre-existing queries do not raise an error. Because GitLab can be run with multiple separate databases, referencing `ci` tables with non `ci` tables in a single query is not possible. Therefore, using any kind of `JOIN` in SQL queries will not work. #### Suggestions for removing cross-database joins The following sections are some real examples that were identified as joining across databases, along with possible suggestions on how to fix them. ##### Remove the code The simplest solution we've seen several times now has been an existing scope that is unused. This is the easiest example to fix. So the first step is to investigate if the code is unused and then remove it. These are some real examples: - - - There may be more examples where the code is used, but we can evaluate if we need it or if the feature should behave this way. Before complicating things by adding new columns and tables, consider if you can simplify the solution and still meet the requirements. One case being evaluated involves changing how certain `UsageData` is calculated to remove a join query in . This is a good candidate to evaluate, because `UsageData` is not critical to users and it may be possible to get a similarly useful metric with a simpler approach. Alternatively we may find that nobody is using these metrics, so we can remove them. ##### Use `preload` instead of `includes` The `includes` and `preload` methods in Rails are both ways to avoid an N+1 query. The `includes` method in Rails uses a heuristic approach to determine if it needs to join to the table, or if it can load all of the records in a separate query. This method assumes it needs to join if it thinks you need to query the columns from the other table, but sometimes this method gets it wrong and executes a join even when not needed. In this case using `preload` to explicitly load the data in a separate query allows you to avoid the join, while still avoiding the N+1 query. You can see a real example of this solution being used in . ##### De-normalize some foreign key to the table De-normalization refers to adding redundant precomputed (duplicated) data to a table to simplify certain queries or to improve performance. In this case, it can be useful when you are doing a join that involves three tables, where you are joining through some intermediate table. Generally when modeling a database schema, a "normalized" structure is preferred because of the following reasons: - Duplicate data uses extra storage. - Duplicate data needs to be kept in sync. Sometimes normalized data is less performant so de-normalization has been a common technique GitLab has used to improve the performance of database queries for a while. The above problems are mitigated when the following conditions are met: 1. There isn't much data (for example, it's just an integer column). 1. The data does not update often (for example, the `project_id` column is almost never updated for most tables). One example we found was the `security_scans` table. This table has a foreign key `security_scans.build_id` which allows you to join to the build. Therefore you could join to the project like so: ```sql select projects.* from security_scans inner join ci_builds on security_scans.build_id = ci_builds.id inner join projects on ci_builds.project_id = projects.id ``` The problem with this query is that `ci_builds` is in a different database from the other two tables. The solution in this case is to add the `project_id` column to `security_scans`. This doesn't use much extra storage, and due to the way these features work, it's never updated (a build never moves projects). This simplified the query to: ```sql select projects.* from security_scans inner join projects on security_scans.project_id = projects.id ``` This also improves performance because you don't need to join through an extra table. You can see this approach implemented in . This MR also de-normalizes `pipeline_id` to fix a similar query. ##### De-normalize into an extra table Sometimes the previous de-normalization (adding an extra column) doesn't work for your specific case. This may be due to the fact that your data is not 1:1, or because the table you're adding to is already too wide (for example, the `projects` table shouldn't have more columns added). In this case you may decide to just store the extra data in a separate table. One example where this approach is being used was to implement the `Project.with_code_coverage` scope. This scope was essentially used to narrow down a list of projects to only those that have at one point in time used code coverage features. This query (simplified) was: ```sql select projects.* from projects inner join ci_daily_build_group_report_results on ci_daily_build_group_report_results.project_id = projects.id where ((data->'coverage') is not null) and ci_daily_build_group_report_results.default_branch = true group by projects.id ``` This work is still in progress but the current plan is to introduce a new table called `projects_with_ci_feature_usage` which has 2 columns `project_id` and `ci_feature`. This table would be written to the first time a project creates a `ci_daily_build_group_report_results` for code coverage. Therefore the new query would be: ```sql select projects.* from projects inner join projects_with_ci_feature_usage on projects_with_ci_feature_usage.project_id = projects.id where projects_with_ci_feature_usage.ci_feature = 'code_coverage' ``` The above example uses as a text column for simplicity but we should probably use an [enum](../creating_enums.md) to save space. The downside of this new design is that this may need to be updated (removed if the `ci_daily_build_group_report_results` is deleted). Depending on your domain, however, this may not be necessary because deletes are edge cases or impossible, or because the user impact of seeing the project on the list page may not be problematic. It's also possible to implement the logic to delete these rows if or whenever necessary in your domain. Finally, this de-normalization and new query also improves performance because it does less joins and needs less filtering. ##### Remove a redundant join Sometimes there are cases where a query is doing excess (or redundant) joins. A common example occurs where a query is joining from `A` to `C`, via some table with both foreign keys, `B`. When you only care about counting how many rows there are in `C` and if there are foreign keys and `NOT NULL` constraints on the foreign keys in `B`, then it might be enough to count those rows. For example, in [MR 71811](https://gitlab.com/gitlab-org/gitlab/-/merge_requests/71811), it was previously doing `project.runners.count`, which would produce a query like: ```sql select count(*) from projects inner join ci_runner_projects on ci_runner_projects.project_id = projects.id where ci_runner_projects.runner_id IN (1, 2, 3) ``` This was changed to avoid the cross-join by changing the code to `project.runner_projects.count`. It produces the same response with the following query: ```sql select count(*) from ci_runner_projects where ci_runner_projects.runner_id IN (1, 2, 3) ``` Another common redundant join is joining all the way to another table, then filtering by primary key when you could have instead filtered on a foreign key. See an example in [MR 71614](https://gitlab.com/gitlab-org/gitlab/-/merge_requests/71614). The previous code was `joins(scan: :build).where(ci_builds: { id: build_ids })`, which generated a query like: ```sql select ... inner join security_scans inner join ci_builds on security_scans.build_id = ci_builds.id where ci_builds.id IN (1, 2, 3) ``` However, as `security_scans` already has a foreign key `build_id`, the code can be changed to `joins(:scan).where(security_scans: { build_id: build_ids })`, which produces the same response with the following query: ```sql select ... inner join security_scans where security_scans.build_id IN (1, 2, 3) ``` Both of these examples of removing redundant joins remove the cross-joins, but they have the added benefit of producing simpler and faster queries. ##### Use `disable_joins` for `has_one` or `has_many` `through:` relations Sometimes a join query is caused by using `has_one ... through:` or `has_many ... through:` across tables that span the different databases. These joins sometimes can be solved by adding [`disable_joins:true`](https://edgeguides.rubyonrails.org/active_record_multiple_databases.html#handling-associations-with-joins-across-databases). This is a Rails feature which we [backported](https://gitlab.com/gitlab-org/gitlab/-/merge_requests/66400). We also extended the feature to allow a lambda syntax for enabling `disable_joins` with a feature flag. If you use this feature we encourage using a feature flag as it mitigates risk if there is some serious performance regression. You can see an example where this was used in . With any change to DB queries it is important to analyze and compare the SQL before and after the change. `disable_joins` can introduce very poorly performing code depending on the actual logic of the `has_many` or `has_one` relationship. The key thing to look for is whether any of the intermediate result sets used to construct the final result set have an unbounded amount of data loaded. The best way to tell is by looking at the SQL generated and confirming that each one is limited in some way. You can tell by either a `LIMIT 1` clause or by `WHERE` clause that is limiting based on a unique column. Any unbounded intermediate dataset could lead to loading too many IDs into memory. An example where you may see very poor performance is the following hypothetical code: ```ruby class Project has_many :pipelines has_many :builds, through: :pipelines end class Pipeline has_many :builds end class Build belongs_to :pipeline end def some_action @builds = Project.find(5).builds.order(created_at: :desc).limit(10) end ``` In the above case `some_action` will generate a query like: ```sql select * from builds inner join pipelines on builds.pipeline_id = pipelines.id where pipelines.project_id = 5 order by builds.created_at desc limit 10 ``` However, if you changed the relation to be: ```ruby class Project has_many :pipelines has_many :builds, through: :pipelines, disable_joins: true end ``` Then you would get the following 2 queries: ```sql select id from pipelines where project_id = 5; select * from builds where pipeline_id in (...) order by created_at desc limit 10; ``` Because the first query does not limit by any unique column or have a `LIMIT` clause, it can load an unlimited number of pipeline IDs into memory, which are then sent in the following query. This can lead to very poor performance in the Rails application and the database. In cases like this, you might need to re-write the query or look at other patterns described above for removing cross-joins. #### How to validate you have correctly removed a cross-join RSpec is configured to automatically validate all SQL queries do not join across databases. If this validation is disabled in `spec/support/database/cross-join-allowlist.yml` then you can still validate an isolated code block using `with_cross_joins_prevented`. You can use this method like so: ```ruby it 'does not join across databases' do with_cross_joins_prevented do ::Ci::Build.joins(:project).to_a end end ``` This will raise an exception if the query joins across the two databases. The previous example is fixed by removing the join, like so: ```ruby it 'does not join across databases' do with_cross_joins_prevented do ::Ci::Build.preload(:project).to_a end end ``` You can see a real example of using this method for fixing a cross-join in . #### Allowlist for existing cross-joins A cross-join across databases can be explicitly allowed by wrapping the code in the `::Gitlab::Database.allow_cross_joins_across_databases` helper method. Alternative way is to mark a given relation as `relation.allow_cross_joins_across_databases`. This method should only be used: - For existing code. - If the code is required to help migrate away from a cross-join. For example, in a migration that backfills data for future use to remove a cross-join. The `allow_cross_joins_across_databases` helper method can be used as follows: ```ruby # Scope the block executing a object from database ::Gitlab::Database.allow_cross_joins_across_databases(url: 'https://gitlab.com/gitlab-org/gitlab/-/issues/336590') do subject.perform(1, 4) end ``` ```ruby # Mark a relation as allowed to cross-join databases def find_actual_head_pipeline all_pipelines .allow_cross_joins_across_databases(url: 'https://gitlab.com/gitlab-org/gitlab/-/issues/336891') .for_sha_or_source_sha(diff_head_sha) .first end ``` The `url` parameter should point to an issue with a milestone for when we intend to fix the cross-join. If the cross-join is being used in a migration, we do not need to fix the code. See for more details. ### Removing cross-database transactions When dealing with multiple databases, it's important to pay close attention to data modification that affects more than one database. [Introduced](https://gitlab.com/gitlab-org/gitlab/-/issues/339811) GitLab 14.4, an automated check prevents cross-database modifications. When at least two different databases are modified during a transaction initiated on any database server, the application triggers a cross-database modification error (only in test environment). Example: ```ruby # Open transaction on Main DB ApplicationRecord.transaction do ci_build.update!(updated_at: Time.current) # UPDATE on CI DB ci_build.project.update!(updated_at: Time.current) # UPDATE on Main DB end # raises error: Cross-database data modification of 'main, ci' were detected within # a transaction modifying the 'ci_build, projects' tables ``` The code example above updates the timestamp for two records within a transaction. With the ongoing work on the CI database decomposition, we cannot ensure the schematics of a database transaction. If the second update query fails, the first update query will not be rolled back because the `ci_build` record is located on a different database server. For more information, look at the [transaction guidelines](transaction_guidelines.md#dangerous-example-third-party-api-calls) page. #### Fixing cross-database errors ##### Removing the transaction block Without an open transaction, the cross-database modification check cannot raise an error. By making this change, we sacrifice consistency. In case of an application failure after the first `UPDATE` query, the second `UPDATE` query will never execute. The same code without the `transaction` block: ```ruby ci_build.update!(updated_at: Time.current) # CI DB ci_build.project.update!(updated_at: Time.current) # Main DB ``` ##### Asynchronous processing If we need more guarantee that an operation finishes the work consistently we can execute it within a background job. A background job is scheduled asynchronously and retried several times in case of an error. There is still a very small chance of introducing inconsistency. Example: ```ruby current_time = Time.current MyAsyncConsistencyJob.perform_async(cu_build.id) ci_build.update!(updated_at: current_time) ci_build.project.update!(updated_at: current_time) ``` The `MyAsyncConsistencyJob` would also attempt to update the timestamp if they differ. ##### Aiming for perfect consistency At this point, we don't have the tooling (we might not even need it) to ensure similar consistency characteristics as we had with one database. If you think that the code you're working on requires these properties, then you can disable the cross-database modification check in your tests by wrapping the offending test code with a block and create a follow-up issue. ```ruby allow_cross_database_modification_within_transaction(url: 'gitlab issue URL') do ApplicationRecord.transaction do ci_build.update!(updated_at: Time.current) # UPDATE on CI DB ci_build.project.update!(updated_at: Time.current) # UPDATE on Main DB end end ``` Don't hesitate to reach out to the [pods group](https://about.gitlab.com/handbook/engineering/development/enablement/data_stores/pods/) for advice. ##### Avoid `dependent: :nullify` and `dependent: :destroy` across databases There may be cases where we want to use `dependent: :nullify` or `dependent: :destroy` across databases. This is technically possible, but it's problematic because these hooks run in the context of an outer transaction from the call to `#destroy`, which creates a cross-database transaction and we are trying to avoid that. Cross-database transactions caused this way could lead to confusing outcomes when we switch to decomposed, because now you have some queries happening outside the transaction and they may be partially applied while the outer transaction fails, which could lead to surprising bugs. For non-trivial objects that need to clean up data outside the database (for example, object storage), we recommend the setting [`dependent: :restrict_with_error`](https://guides.rubyonrails.org/association_basics.html#options-for-has-one-dependent). Such objects should be removed explicitly ahead of time. Using `dependent: :restrict_with_error` ensures that we forbid destroying the parent object if something is not cleaned up. If all you need to do is clean up the child records themselves from PostgreSQL, consider using [loose foreign keys](loose_foreign_keys.md). ## Foreign keys that cross databases There are many places where we use foreign keys that reference across the two databases. This is not possible to do with two separate PostgreSQL databases, so we need to replicate the behavior we get from PostgreSQL in a performant way. We can't, and shouldn't, try to replicate the data guarantees given by PostgreSQL which prevent creating invalid references, but we still need a way to replace cascading deletes so we don't end up with orphaned data or records that point to nowhere, which might lead to bugs. As such we created ["loose foreign keys"](loose_foreign_keys.md) which is an asynchronous process of cleaning up orphaned records. ## Locking writes on the tables that don't belong to the database schemas When the CI database is promoted and the two databases are fully split, as an extra safeguard against creating a split brain situation, run the Rake task `gitlab:db:lock_writes`. This command locks writes on: - The `gitlab_main` tables on the CI Database. - The `gitlab_ci` tables on the Main Database. This Rake task adds triggers to all the tables, to prevent any `INSERT`, `UPDATE`, `DELETE`, or `TRUNCATE` statements from running against the tables that need to be locked. If this task was run against a GitLab setup that uses only a single database for both `gitlab_main` and `gitlab_ci` tables, then no tables will be locked. To undo the operation, run the opposite Rake task: `gitlab:db:unlock_writes`.