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Aggregated Value Stream Analytics

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This page provides a high-level overview of the aggregated backend for Value Stream Analytics (VSA).

Current Status

The aggregated backend is used by default since GitLab 15.0 on the group-level.

Motivation

The aggregated backend aims to solve the performance limitations of the VSA feature and set it up for long-term growth.

Our main database is not prepared for analytical workloads. Executing long-running queries can affect the reliability of the application. For large groups, the current implementation (old backend) is slow and, in some cases, doesn't even load due to the configured statement timeout (15 s).

The database queries in the old backend use the core domain models directly through IssuableFinders classes: (MergeRequestsFinder and IssuesFinder). With the requested change of the date range filters, this approach was no longer viable from the performance point of view.

Benefits of the aggregated VSA backend:

  • Simpler database queries (fewer JOINs).
  • Faster aggregations, only a single table is accessed.
  • Possibility to introduce further aggregations for improving the first page load time.
  • Better performance for large groups (with many subgroups, projects, issues and, merge requests).
  • Ready for database decomposition. The VSA related database tables could live in a separate database with a minimal development effort.
  • Ready for keyset pagination which can be useful for exporting the data.
  • Possibility to implement more complex event definitions.
    • For example, the start event can be two timestamp columns where the earliest value would be used by the system.
    • Example: MIN(issues.created_at, issues.updated_at)

Example configuration

VSA object hierarchy example

In this example, two independent value streams are set up for two teams that are using different development workflows within the Test Group (top-level namespace).

The first value stream uses standard timestamp-based events for defining the stages. The second value stream uses label events.

Each value stream and stage item from the example is persisted in the database. Notice that the Deployment stage is identical for both value streams; that means that the underlying stage_event_hash_id is the same for both stages. The stage_event_hash_id reduces the amount of data the backend collects and plays a vital role in database partitioning.

We expect value streams and stages to be rarely changed. When stages (start and end events) are changed, the aggregated data gets stale. This is fixed by the periodical aggregation occurring every day.

Feature availability

The aggregated VSA feature is available on the group and project level however, the aggregated backend is only available for Premium and Ultimate customers due to data storage and data computation costs. Storing de-normalized, aggregated data requires significant disk space.

Aggregated value stream analytics architecture

The main idea behind the aggregated VSA backend is separation: VSA database tables and queries do not use the core domain models directly (Issue, MergeRequest). This allows us to scale and optimize VSA independently from the other parts of the application.

The architecture consists of two main mechanisms:

  • Periodical data collection and loading (happens in the background).
  • Querying the collected data (invoked by the user).

Data loading

The aggregated nature of VSA comes from the periodical data loading. The system queries the core domain models to collect the stage and timestamp data. This data is periodically inserted into the VSA database tables.

High-level overview for each top-level namespace with Premium or Ultimate license:

  1. Load all stages in the group.
  2. Iterate over the issues and merge requests records.
  3. Based on the stage configurations (start and end event identifiers) collect the timestamp data.
  4. INSERT or UPDATE the data into the VSA database tables.

The data loading is implemented within the Analytics::CycleAnalytics::DataLoaderService class. Some groups contain a lot of data, so to avoid overloading the primary database, the service performs operations in batches and enforces strict application limits:

  • Load records in batches.
  • Insert records in batches.
  • Stop processing when a limit is reached, schedule a background job to continue the processing later.
  • Continue processing data from a specific point.

The data loading is done manually. Once the feature is ready, the service is invoked periodically by the system via a cron job (this part is not implemented yet).

Record iteration

The batched iteration is implemented with the efficient IN operator. The background job scans all issues and merge request records in the group hierarchy ordered by the updated_at and the id columns. For already aggregated groups, the DataLoaderService continues the aggregation from a specific point which saves time.

Collecting the timestamp data happens on every iteration. The DataLoaderService determines which stage events are configured within the group hierarchy and builds a query that selects the required timestamps. The stage record knows which events are configured and the events know how to select the timestamp columns.

Example for collected stage events: merge request merged, merge request created, merge request closed

Generated SQL query for loading the timestamps:

SELECT
  -- the list of columns depends on the configured stages
  "merge_request_metrics"."merged_at",
  "merge_requests"."created_at",
  "merge_request_metrics"."latest_closed_at"
  FROM "merge_requests"
  LEFT OUTER JOIN "merge_request_metrics" ON "merge_request_metrics"."merge_request_id" = "merge_requests"."id"
  WHERE "merge_requests"."id" IN (1, 2, 3, 4) -- ids are coming from the batching query

The merged_at column is located in a separate table (merge_request_metrics). The Gitlab::Analytics::CycleAnalytics::StagEvents::MergeRequestMerged class adds itself to a scope for loading the timestamp data without affecting the number of rows (uses LEFT JOIN). This behavior is implemented for each StageEvent class with the include_in method.

The data collection query works on the event level. It extracts the event timestamps from the stages and ensures that we don't collect the same data multiple times. The events mentioned above could come from the following stage configuration:

  • merge request created - merge request merged
  • merge request created - merge request closed

Other combinations might be also possible, but we prevent the ones that make no sense, for example:

  • merge request merged - merge request created

Creation time always happens first, so this stage always reports negative duration.

Data scope

The data collection scans and processes all issues and merge requests records in the group hierarchy, starting from the top-level group. This means that if a group only has one value stream in a subgroup, we nevertheless collect data of all issues and merge requests in the hierarchy of this group. This aims to simplify the data collection mechanism. Moreover, data research shows that most group hierarchies have their stages configured on the top level.

During the data collection process, the collected timestamp data is transformed into rows. For each configured stage, if the start event timestamp is present, the system inserts or updates one event record. This allows us to determine the upper limit of the inserted rows per group by counting all issues and merge requests and multiplying the sum by the stage count.

Data consistency concerns

Due to the async nature of the data collection, data consistency issues are bound to happen. This is a trade-off that makes the query performance significantly faster. We think that for analytical workload a slight lag in the data is acceptable.

Before the rollout we plan to implement some indicators on the VSA page that shows the most recent backend activities. For example, indicators that show the last data collection timestamp and the last consistency check timestamp.

Database structure

VSA collects data for the following domain models: Issue and MergeRequest. To keep the aggregated data separated, we use two additional database tables:

  • analytics_cycle_analytics_issue_stage_events
  • analytics_cycle_analytics_merge_request_stage_events

Both tables are hash partitioned by the stage_event_hash_id. Each table uses 32 partitions. It's an arbitrary number and it could be changed. Important is to keep the partitions under 100 GB in size (which gives the feature a lot of headroom).

Column Description
stage_event_hash_id partitioning key
merge_request_id or issue_id reference to the domain record (Issuable)
group_id reference to the group (de-normalization)
project_id reference to the project
milestone_id duplicated data from the domain record table
author_id duplicated data from the domain record table
state_id duplicated data from the domain record table
start_event_timestamp timestamp derived from the stage configuration
end_event_timestamp timestamp derived from the stage configuration

With accordance to the data separation requirements, the table doesn't have any foreign keys. The consistency is ensured by a background job (eventually consistent).

Data querying

The base query always includes the following filters:

  • stage_event_hash_id - partition key
  • project_id or group_id - depending if it's a project or group level query
  • end_event_timestamp - date range filter (last 30 days)

Example: Selecting review stage duration for the GitLab project

SELECT end_event_timestamp - start_event_timestamp
FROM analytics_cycle_analytics_merge_request_stage_events
WHERE
stage_event_hash_id = 16 AND -- hits a specific partition
project_id = 278964 AND
end_event_timestamp > '2022-01-01' AND end_event_timestamp < '2022-01-30'

Query generation

The query backend is hidden behind the same interface that the old backend implementation uses. Thanks to this, we can easily switch between the old and new query backends.

  • DataCollector: entrypoint for querying VSA data
    • BaseQueryBuilder: provides the base ActiveRecord scope (filters are applied here).
    • average: average aggregation.
    • median: median aggregation.
    • count: row counting.
    • records: list of issue or merge request records.

Filters

VSA supports various filters on the base query. Most of the filters require no additional JOINs:

Filter name Description
milestone_title The backend translates it to milestone_id filter
author_username The backend translates it to author_id filter
project_ids Only used on the group-level

Exceptions: these filters are applied on other tables which means we JOIN them.

Filter name Description
label_name Array filter, using the label_links table
assignee_username Array filter, using the *_assignees table

To fully decompose the database, the required ID values would need to be replicated in the VSA database tables. This change could be implemented using array columns.

Endpoints

The feature uses private JSON APIs for delivering the data to the frontend. On the first page load , the following requests are invoked:

  • Initial HTML page load which is mostly empty. Some configuration data is exposed via data attributes.
  • value_streams - Load the available value streams for the given group.
  • stages - Load the stages for the currently selected value stream.
  • median - For each stage, request the median duration.
  • count - For each stage, request the number of items in the stage (this is a limit count, maximum 1000 rows).
  • average_duration_chart - Data for the duration chart.
  • summary, time_summary - Top-level aggregations, most of the metrics are using different APIs/ finders and not invoking the aggregated backend.

When selecting a specific stage, the records endpoint is invoked, which returns the related records (paginated) for the chosen stage in a specific order.

Database decomposition

By separating the query logic from the main application code, the feature is ready for database decomposition. If we decide that VSA requires a separate database instance, then moving the aggregated tables can be accomplished with little effort.

A different database technology could also be used to further improve the performance of the feature, for example Timescale DB.