347 lines
13 KiB
Markdown
347 lines
13 KiB
Markdown
---
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stage: Manage
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group: Integrations
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info: To determine the technical writer assigned to the Stage/Group associated with this page, see https://about.gitlab.com/handbook/product/ux/technical-writing/#assignments
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---
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# GraphQL pagination
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## Types of pagination
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GitLab uses two primary types of pagination: **offset** and **keyset**
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(sometimes called cursor-based) pagination.
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The GraphQL API mainly uses keyset pagination, falling back to offset pagination when needed.
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### Performance considerations
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See the [general pagination guidelines section](../database/pagination_guidelines.md) for more information.
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### Offset pagination
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This is the traditional, page-by-page pagination, that is most common,
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and used across much of GitLab. You can recognize it by
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a list of page numbers near the bottom of a page, which, when selected,
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take you to that page of results.
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For example, when you select **Page 100**, we send `100` to the
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backend. For example, if each page has say 20 items, the
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backend calculates `20 * 100 = 2000`,
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and it queries the database by offsetting (skipping) the first 2000
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records and pulls the next 20.
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```plaintext
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page number * page size = where to find my records
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```
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There are a couple of problems with this:
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- Performance. When we query for page 100 (which gives an offset of
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2000), then the database has to scan through the table to that
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specific offset, and then pick up the next 20 records. As the offset
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increases, the performance degrades quickly.
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Read more in
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[The SQL I Love <3. Efficient pagination of a table with 100M records](http://allyouneedisbackend.com/blog/2017/09/24/the-sql-i-love-part-1-scanning-large-table/).
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- Data stability. When you get the 20 items for page 100 (at
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offset 2000), GitLab shows those 20 items. If someone then
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deletes or adds records in page 99 or before, the items at
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offset 2000 become a different set of items. You can even get into a
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situation where, when paginating, you could skip over items,
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because the list keeps changing.
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Read more in
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[Pagination: You're (Probably) Doing It Wrong](https://coderwall.com/p/lkcaag/pagination-you-re-probably-doing-it-wrong).
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### Keyset pagination
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Given any specific record, if you know how to calculate what comes
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after it, you can query the database for those specific records.
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For example, suppose you have a list of issues sorted by creation date.
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If you know the first item on a page has a specific date (say Jan 1), you can ask
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for all records that were created after that date and take the first 20.
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It no longer matters if many are deleted or added, as you always ask for
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the ones after that date, and so get the correct items.
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Unfortunately, there is no easy way to know if the issue created
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on Jan 1 is on page 20 or page 100.
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Some of the benefits and tradeoffs of keyset pagination are
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- Performance is much better.
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- More data stability for end-users since records are not missing from lists due to
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deletions or insertions.
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- It's the best way to do infinite scrolling.
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- It's more difficult to program and maintain. Easy for `updated_at` and
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`sort_order`, complicated (or impossible) for [complex sorting scenarios](#limitations-of-query-complexity).
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## Implementation
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When pagination is supported for a query, GitLab defaults to using
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keyset pagination. You can see where this is configured in
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[`pagination/connections.rb`](https://gitlab.com/gitlab-org/gitlab/-/blob/master/lib/gitlab/graphql/pagination/connections.rb).
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If a query returns `ActiveRecord::Relation`, keyset pagination is automatically used.
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This was a conscious decision to support performance and data stability.
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However, there are some cases where we have to use the offset
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pagination connection, `OffsetActiveRecordRelationConnection`, such as when
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sorting by label priority in issues, due to the complexity of the sort.
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If you return a relation from a resolver that is not suitable for keyset
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pagination (due to the sort order for example), then you can use the
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`BaseResolver#offset_pagination` method to wrap the relation in the correct
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connection type. For example:
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```ruby
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def resolve(**args)
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result = Finder.new(object, current_user, args).execute
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result = offset_pagination(result) if needs_offset?(args[:sort])
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result
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end
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```
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### Keyset pagination
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The keyset pagination implementation is a subclass of `GraphQL::Pagination::ActiveRecordRelationConnection`,
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which is a part of the `graphql` gem. This is installed as the default for all `ActiveRecord::Relation`.
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However, instead of using a cursor based on an offset (which is the default), GitLab uses a more specialized cursor.
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The cursor is created by encoding a JSON object which contains the relevant ordering fields. For example:
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```ruby
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ordering = {"id"=>"72410125", "created_at"=>"2020-10-08 18:05:21.953398000 UTC"}
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json = ordering.to_json
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cursor = Base64Bp.urlsafe_encode64(json, padding: false)
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"eyJpZCI6IjcyNDEwMTI1IiwiY3JlYXRlZF9hdCI6IjIwMjAtMTAtMDggMTg6MDU6MjEuOTUzMzk4MDAwIFVUQyJ9"
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json = Base64Bp.urlsafe_decode64(cursor)
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Gitlab::Json.parse(json)
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{"id"=>"72410125", "created_at"=>"2020-10-08 18:05:21.953398000 UTC"}
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```
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The benefits of storing the order attribute values in the cursor:
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- If only the ID of the object were stored, the object and its attributes could be queried.
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That would require an additional query, and if the object is no longer there, then the needed
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attributes are not available.
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- If an attribute is `NULL`, then one SQL query can be used. If it's not `NULL`, then a
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different SQL query can be used.
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Based on whether the main attribute field being sorted on is `NULL` in the cursor, the proper query
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condition is built. The last ordering field is considered to be unique (a primary key), meaning the
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column never contains `NULL` values.
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#### Limitations of query complexity
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We only support two ordering fields, and one of those fields needs to be the primary key.
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Here are two examples of pseudocode for the query:
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- **Two-condition query.** `X` represents the values from the cursor. `C` represents
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the columns in the database, sorted in ascending order, using an `:after` cursor, and with `NULL`
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values sorted last.
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```plaintext
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X1 IS NOT NULL
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AND
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(C1 > X1)
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OR
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(C1 IS NULL)
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OR
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(C1 = X1
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AND
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C2 > X2)
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X1 IS NULL
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AND
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(C1 IS NULL
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AND
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C2 > X2)
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```
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Below is an example based on the relation `Issue.order(relative_position: :asc).order(id: :asc)`
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with an after cursor of `relative_position: 1500, id: 500`:
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```plaintext
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when cursor[relative_position] is not NULL
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("issues"."relative_position" > 1500)
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OR (
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"issues"."relative_position" = 1500
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AND
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"issues"."id" > 500
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)
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OR ("issues"."relative_position" IS NULL)
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when cursor[relative_position] is NULL
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"issues"."relative_position" IS NULL
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AND
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"issues"."id" > 500
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```
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- **Three-condition query.** The example below is not complete, but shows the
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complexity of adding one more condition. `X` represents the values from the cursor. `C` represents
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the columns in the database, sorted in ascending order, using an `:after` cursor, and with `NULL`
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values sorted last.
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```plaintext
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X1 IS NOT NULL
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AND
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(C1 > X1)
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OR
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(C1 IS NULL)
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OR
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(C1 = X1 AND C2 > X2)
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OR
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(C1 = X1
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AND
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X2 IS NOT NULL
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AND
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((C2 > X2)
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OR
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(C2 IS NULL)
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OR
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(C2 = X2 AND C3 > X3)
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OR
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X2 IS NULL.....
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```
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By using
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[`Gitlab::Graphql::Pagination::Keyset::QueryBuilder`](https://gitlab.com/gitlab-org/gitlab/-/blob/master/lib/gitlab/graphql/pagination/keyset/query_builder.rb),
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we're able to build the necessary SQL conditions and apply them to the Active Record relation.
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Complex queries can be difficult or impossible to use. For example,
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in [`issuable.rb`](https://gitlab.com/gitlab-org/gitlab/-/blob/master/app/models/concerns/issuable.rb),
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the `order_due_date_and_labels_priority` method creates a very complex query.
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These types of queries are not supported. In these instances, you can use offset pagination.
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#### Gotchas
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Do not define a collection's order using the string syntax:
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```ruby
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# Bad
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items.order('created_at DESC')
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```
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Instead, use the hash syntax:
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```ruby
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# Good
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items.order(created_at: :desc)
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```
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The first example won't correctly embed the sort information (`created_at`, in
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the example above) into the pagination cursors, which will result in an
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incorrect sort order.
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### Offset pagination
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There are times when the [complexity of sorting](#limitations-of-query-complexity)
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is more than our keyset pagination can handle.
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For example, in [`ProjectIssuesResolver`](https://gitlab.com/gitlab-org/gitlab/-/blob/master/app/graphql/resolvers/project_issues_resolver.rb),
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when sorting by `priority_asc`, we can't use keyset pagination as the ordering is much
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too complex. For more information, read [`issuable.rb`](https://gitlab.com/gitlab-org/gitlab/-/blob/master/app/models/concerns/issuable.rb).
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In cases like this, we can fall back to regular offset pagination by returning a
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[`Gitlab::Graphql::Pagination::OffsetActiveRecordRelationConnection`](https://gitlab.com/gitlab-org/gitlab/-/blob/master/lib/gitlab/graphql/pagination/offset_active_record_relation_connection.rb)
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instead of an `ActiveRecord::Relation`:
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```ruby
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def resolve(parent, finder, **args)
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issues = apply_lookahead(Gitlab::Graphql::Loaders::IssuableLoader.new(parent, finder).batching_find_all)
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if non_stable_cursor_sort?(args[:sort])
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# Certain complex sorts are not supported by the stable cursor pagination yet.
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# In these cases, we use offset pagination, so we return the correct connection.
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offset_pagination(issues)
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else
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issues
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end
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end
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```
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<!-- ### External pagination -->
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### External pagination
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There may be times where you need to return data through the GitLab API that is stored in
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another system. In these cases you may have to paginate a third-party's API.
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An example of this is with our [Error Tracking](../../operations/error_tracking.md) implementation,
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where we proxy [Sentry errors](../../operations/error_tracking.md#sentry-error-tracking) through
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the GitLab API. We do this by calling the Sentry API which enforces its own pagination rules.
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This means we cannot access the collection within GitLab to perform our own custom pagination.
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For consistency, we manually set the pagination cursors based on values returned by the external API, using `Gitlab::Graphql::ExternallyPaginatedArray.new(previous_cursor, next_cursor, *items)`.
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You can see an example implementation in the following files:
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- [`types/error__tracking/sentry_error_collection_type.rb`](https://gitlab.com/gitlab-org/gitlab/-/blob/master/app/graphql/types/error_tracking/sentry_error_collection_type.rb) which adds an extension to `field :errors`.
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- [`resolvers/error_tracking/sentry_errors_resolver.rb`](https://gitlab.com/gitlab-org/gitlab/-/blob/master/app/graphql/resolvers/error_tracking/sentry_errors_resolver.rb) which returns the data from the resolver.
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## Testing
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Any GraphQL field that supports pagination and sorting should be tested
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using the sorted paginated query shared example found in
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[`graphql/sorted_paginated_query_shared_examples.rb`](https://gitlab.com/gitlab-org/gitlab/-/blob/master/spec/support/shared_examples/graphql/sorted_paginated_query_shared_examples.rb).
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It helps verify that your sort keys are compatible and that cursors
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work properly.
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This is particularly important when using keyset pagination, as some sort keys might not be supported.
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Add a section to your request specs like this:
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```ruby
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describe 'sorting and pagination' do
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...
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end
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```
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You can then use
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[`issues_spec.rb`](https://gitlab.com/gitlab-org/gitlab/-/blob/master/spec/requests/api/graphql/project/issues_spec.rb)
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as an example to construct your tests.
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[`graphql/sorted_paginated_query_shared_examples.rb`](https://gitlab.com/gitlab-org/gitlab/-/blob/master/spec/support/shared_examples/graphql/sorted_paginated_query_shared_examples.rb)
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also contains some documentation on how to use the shared examples.
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The shared example requires certain `let` variables and methods to be set up:
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```ruby
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describe 'sorting and pagination' do
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let_it_be(:sort_project) { create(:project, :public) }
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let(:data_path) { [:project, :issues] }
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def pagination_query(params)
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graphql_query_for( :project, { full_path: sort_project.full_path },
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query_nodes(:issues, :id, include_pagination_info: true, args: params))
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)
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end
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def pagination_results_data(nodes)
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nodes.map { |issue| issue['iid'].to_i }
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end
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context 'when sorting by weight' do
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let_it_be(:issues) { make_some_issues_with_weights }
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context 'when ascending' do
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let(:ordered_issues) { issues.sort_by(&:weight) }
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it_behaves_like 'sorted paginated query' do
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let(:sort_param) { :WEIGHT_ASC }
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let(:first_param) { 2 }
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let(:all_records) { ordered_issues.map(&:iid) }
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end
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end
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end
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```
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