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---
stage: Enablement
group: Database
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
---
# Efficient `IN` operator queries
This document describes a technique for building efficient ordered database queries with the `IN`
SQL operator and the usage of a GitLab utility module to help apply the technique.
NOTE:
The described technique makes heavy use of
[keyset pagination ](pagination_guidelines.md#keyset-pagination ).
It's advised to get familiar with the topic first.
## Motivation
In GitLab, many domain objects like `Issue` live under nested hierarchies of projects and groups.
To fetch nested database records for domain objects at the group-level,
we often perform queries with the `IN` SQL operator.
We are usually interested in ordering the records by some attributes
and limiting the number of records using `ORDER BY` and `LIMIT` clauses for performance.
Pagination may be used to fetch subsequent records.
Example tasks requiring querying nested domain objects from the group level:
- Show first 20 issues by creation date or due date from the group `gitlab-org` .
- Show first 20 merge_requests by merged at date from the group `gitlab-com` .
Unfortunately, ordered group-level queries typically perform badly
as their executions require heavy I/O, memory, and computations.
Let's do an in-depth examination of executing one such query.
### Performance problems with `IN` queries
Consider the task of fetching the twenty oldest created issues
from the group `gitlab-org` with the following query:
```sql
SELECT "issues".*
FROM "issues"
WHERE "issues"."project_id" IN
(SELECT "projects"."id"
FROM "projects"
WHERE "projects"."namespace_id" IN
(SELECT traversal_ids[array_length(traversal_ids, 1)] AS id
FROM "namespaces"
WHERE (traversal_ids @> ('{9970}'))))
ORDER BY "issues"."created_at" ASC,
"issues"."id" ASC
LIMIT 20
```
NOTE:
For pagination, ordering by the `created_at` column is not enough,
we must add the `id` column as a
[tie-breaker ](pagination_performance_guidelines.md#tie-breaker-column ).
The execution of the query can be largely broken down into three steps:
1. The database accesses both `namespaces` and `projects` tables
to find all projects from all groups in the group hierarchy.
1. The database retrieves `issues` records for each project causing heavy disk I/O.
Ideally, an appropriate index configuration should optimize this process.
1. The database sorts the `issues` rows in memory by `created_at` and returns `LIMIT 20` rows to
the end-user. For large groups, this final step requires both large memory and CPU resources.
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Execution plan for this DB query:
```sql
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Limit (cost=90170.07..90170.12 rows=20 width=1329) (actual time=967.597..967.607 rows=20 loops=1)
Buffers: shared hit=239127 read=3060
I/O Timings: read=336.879
-> Sort (cost=90170.07..90224.02 rows=21578 width=1329) (actual time=967.596..967.603 rows=20 loops=1)
Sort Key: issues.created_at, issues.id
Sort Method: top-N heapsort Memory: 74kB
Buffers: shared hit=239127 read=3060
I/O Timings: read=336.879
-> Nested Loop (cost=1305.66..89595.89 rows=21578 width=1329) (actual time=4.709..797.659 rows=241534 loops=1)
Buffers: shared hit=239121 read=3060
I/O Timings: read=336.879
-> HashAggregate (cost=1305.10..1360.22 rows=5512 width=4) (actual time=4.657..5.370 rows=1528 loops=1)
Group Key: projects.id
Buffers: shared hit=2597
-> Nested Loop (cost=576.76..1291.32 rows=5512 width=4) (actual time=2.427..4.244 rows=1528 loops=1)
Buffers: shared hit=2597
-> HashAggregate (cost=576.32..579.06 rows=274 width=25) (actual time=2.406..2.447 rows=265 loops=1)
Group Key: namespaces.traversal_ids[array_length(namespaces.traversal_ids, 1)]
Buffers: shared hit=334
-> Bitmap Heap Scan on namespaces (cost=141.62..575.63 rows=274 width=25) (actual time=1.933..2.330 rows=265 loops=1)
Recheck Cond: (traversal_ids @> '{9970}'::integer[])
Heap Blocks: exact=243
Buffers: shared hit=334
-> Bitmap Index Scan on index_namespaces_on_traversal_ids (cost=0.00..141.55 rows=274 width=0) (actual time=1.897..1.898 rows=265 loops=1)
Index Cond: (traversal_ids @> '{9970}'::integer[])
Buffers: shared hit=91
-> Index Only Scan using index_projects_on_namespace_id_and_id on projects (cost=0.44..2.40 rows=20 width=8) (actual time=0.004..0.006 rows=6 loops=265)
Index Cond: (namespace_id = (namespaces.traversal_ids)[array_length(namespaces.traversal_ids, 1)])
Heap Fetches: 51
Buffers: shared hit=2263
-> Index Scan using index_issues_on_project_id_and_iid on issues (cost=0.57..10.57 rows=544 width=1329) (actual time=0.114..0.484 rows=158 loops=1528)
Index Cond: (project_id = projects.id)
Buffers: shared hit=236524 read=3060
I/O Timings: read=336.879
Planning Time: 7.750 ms
Execution Time: 967.973 ms
(36 rows)
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```
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The performance of the query depends on the number of rows in the database.
On average, we can say the following:
- Number of groups in the group-hierarchy: less than 1 000
- Number of projects: less than 5 000
- Number of issues: less than 100 000
From the list, it's apparent that the number of `issues` records has
the largest impact on the performance.
As per normal usage, we can say that the number of issue records grows
at a faster rate than the `namespaces` and the `projects` records.
This problem affects most of our group-level features where records are listed
in a specific order, such as group-level issues, merge requests pages, and APIs.
For very large groups the database queries can easily time out, causing HTTP 500 errors.
## Optimizing ordered `IN` queries
In the talk
["How to teach an elephant to dance rock'n'roll" ](https://www.youtube.com/watch?v=Ha38lcjVyhQ ),
Maxim Boguk demonstrated a technique to optimize a special class of ordered `IN` queries,
such as our ordered group-level queries.
A typical ordered `IN` query may look like this:
```sql
SELECT t.* FROM t
WHERE t.fkey IN (value_set)
ORDER BY t.pkey
LIMIT N;
```
Here's the key insight used in the technique: we need at most `|value_set| + N` record lookups,
rather than retrieving all records satisfying the condition `t.fkey IN value_set` (`|value_set|`
is the number of values in `value_set` ).
We adopted and generalized the technique for use in GitLab by implementing utilities in the
`Gitlab::Pagination::Keyset::InOperatorOptimization` class to facilitate building efficient `IN`
queries.
### Requirements
The technique is not a drop-in replacement for the existing group-level queries using `IN` operator.
The technique can only optimize `IN` queries that satisfy the following requirements:
- `LIMIT` is present, which usually means that the query is paginated
(offset or keyset pagination).
- The column used with the `IN` query and the columns in the `ORDER BY`
clause are covered with a database index. The columns in the index must be
in the following order: `column_for_the_in_query` , `order by column 1` , and
`order by column 2` .
- The columns in the `ORDER BY` clause are distinct
(the combination of the columns uniquely identifies one particular column in the table).
WARNING:
This technique will not improve the performance of the `COUNT(*)` queries.
## The `InOperatorOptimization` module
> [Introduced](https://gitlab.com/gitlab-org/gitlab/-/merge_requests/67352) in GitLab 14.3.
The `Gitlab::Pagination::Keyset::InOperatorOptimization` module implements utilities for applying a generalized version of
the efficient `IN` query technique described in the previous section.
To build optimized, ordered `IN` queries that meet [the requirements ](#requirements ),
use the utility class `QueryBuilder` from the module.
NOTE:
The generic keyset pagination module introduced in the merge request
[51481 ](https://gitlab.com/gitlab-org/gitlab/-/merge_requests/51481 )
plays a fundamental role in the generalized implementation of the technique
in `Gitlab::Pagination::Keyset::InOperatorOptimization` .
### Basic usage of `QueryBuilder`
To illustrate a basic usage, we will build a query that
fetches 20 issues with the oldest `created_at` from the group `gitlab-org` .
The following ActiveRecord query would produce a query similar to
[the unoptimized query ](#performance-problems-with-in-queries ) that we examined earlier:
```ruby
scope = Issue
.where(project_id: Group.find(9970).all_projects.select(:id)) # `gitlab-org` group and its subgroups
.order(:created_at, :id)
.limit(20)
```
Instead, use the query builder `InOperatorOptimization::QueryBuilder` to produce an optimized
version:
```ruby
scope = Issue.order(:created_at, :id)
array_scope = Group.find(9970).all_projects.select(:id)
array_mapping_scope = -> (id_expression) { Issue.where(Issue.arel_table[:project_id].eq(id_expression)) }
finder_query = -> (created_at_expression, id_expression) { Issue.where(Issue.arel_table[:id].eq(id_expression)) }
Gitlab::Pagination::Keyset::InOperatorOptimization::QueryBuilder.new(
scope: scope,
array_scope: array_scope,
array_mapping_scope: array_mapping_scope,
finder_query: finder_query
).execute.limit(20)
```
- `scope` represents the original `ActiveRecord::Relation` object without the `IN` query. The
relation should define an order which must be supported by the
[keyset pagination library ](keyset_pagination.md#usage ).
- `array_scope` contains the `ActiveRecord::Relation` object, which represents the original
`IN (subquery)` . The select values must contain the columns by which the subquery is "connected"
to the main query: the `id` of the project record.
- `array_mapping_scope` defines a lambda returning an `ActiveRecord::Relation` object. The lambda
matches (`=`) single select values from the `array_scope` . The lambda yields as many
arguments as the select values defined in the `array_scope` . The arguments are Arel SQL expressions.
- `finder_query` loads the actual record row from the database. It must also be a lambda, where
the order by column expressions is available for locating the record. In this example, the
yielded values are `created_at` and `id` SQL expressions. Finding a record is very fast via the
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primary key, so we don't use the `created_at` value. Providing the `finder_query` lambda is optional.
If it's not given, the IN operator optimization will only make the ORDER BY columns available to
the end-user and not the full database row.
If it's not given, the IN operator optimization will only make the ORDER BY columns available to
the end-user and not the full database row.
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The following database index on the `issues` table must be present
to make the query execute efficiently:
```sql
"idx_issues_on_project_id_and_created_at_and_id" btree (project_id, created_at, id)
```
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The SQL query:
```sql
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SELECT "issues".*
FROM
(WITH RECURSIVE "array_cte" AS MATERIALIZED
(SELECT "projects"."id"
FROM "projects"
WHERE "projects"."namespace_id" IN
(SELECT traversal_ids[array_length(traversal_ids, 1)] AS id
FROM "namespaces"
WHERE (traversal_ids @> ('{9970}')))),
"recursive_keyset_cte" AS ( -- initializer row start
(SELECT NULL::issues AS records,
array_cte_id_array,
issues_created_at_array,
issues_id_array,
0::bigint AS COUNT
FROM
(SELECT ARRAY_AGG("array_cte"."id") AS array_cte_id_array,
ARRAY_AGG("issues"."created_at") AS issues_created_at_array,
ARRAY_AGG("issues"."id") AS issues_id_array
FROM
(SELECT "array_cte"."id"
FROM array_cte) array_cte
LEFT JOIN LATERAL
(SELECT "issues"."created_at",
"issues"."id"
FROM "issues"
WHERE "issues"."project_id" = "array_cte"."id"
ORDER BY "issues"."created_at" ASC, "issues"."id" ASC
LIMIT 1) issues ON TRUE
WHERE "issues"."created_at" IS NOT NULL
AND "issues"."id" IS NOT NULL) array_scope_lateral_query
LIMIT 1)
-- initializer row finished
UNION ALL
(SELECT
-- result row start
(SELECT issues -- record finder query as the first column
FROM "issues"
WHERE "issues"."id" = recursive_keyset_cte.issues_id_array[position]
LIMIT 1),
array_cte_id_array,
recursive_keyset_cte.issues_created_at_array[:position_query.position-1]||next_cursor_values.created_at||recursive_keyset_cte.issues_created_at_array[position_query.position+1:],
recursive_keyset_cte.issues_id_array[:position_query.position-1]||next_cursor_values.id||recursive_keyset_cte.issues_id_array[position_query.position+1:],
recursive_keyset_cte.count + 1
-- result row finished
FROM recursive_keyset_cte,
LATERAL
-- finding the cursor values of the next record start
(SELECT created_at,
id,
position
FROM UNNEST(issues_created_at_array, issues_id_array) WITH
ORDINALITY AS u(created_at, id, position)
WHERE created_at IS NOT NULL
AND id IS NOT NULL
ORDER BY "created_at" ASC, "id" ASC
LIMIT 1) AS position_query,
-- finding the cursor values of the next record end
-- finding the next cursor values (next_cursor_values_query) start
LATERAL
(SELECT "record"."created_at",
"record"."id"
FROM (
VALUES (NULL,
NULL)) AS nulls
LEFT JOIN
(SELECT "issues"."created_at",
"issues"."id"
FROM (
(SELECT "issues"."created_at",
"issues"."id"
FROM "issues"
WHERE "issues"."project_id" = recursive_keyset_cte.array_cte_id_array[position]
AND recursive_keyset_cte.issues_created_at_array[position] IS NULL
AND "issues"."created_at" IS NULL
AND "issues"."id" > recursive_keyset_cte.issues_id_array[position]
ORDER BY "issues"."created_at" ASC, "issues"."id" ASC)
UNION ALL
(SELECT "issues"."created_at",
"issues"."id"
FROM "issues"
WHERE "issues"."project_id" = recursive_keyset_cte.array_cte_id_array[position]
AND recursive_keyset_cte.issues_created_at_array[position] IS NOT NULL
AND "issues"."created_at" IS NULL
ORDER BY "issues"."created_at" ASC, "issues"."id" ASC)
UNION ALL
(SELECT "issues"."created_at",
"issues"."id"
FROM "issues"
WHERE "issues"."project_id" = recursive_keyset_cte.array_cte_id_array[position]
AND recursive_keyset_cte.issues_created_at_array[position] IS NOT NULL
AND "issues"."created_at" > recursive_keyset_cte.issues_created_at_array[position]
ORDER BY "issues"."created_at" ASC, "issues"."id" ASC)
UNION ALL
(SELECT "issues"."created_at",
"issues"."id"
FROM "issues"
WHERE "issues"."project_id" = recursive_keyset_cte.array_cte_id_array[position]
AND recursive_keyset_cte.issues_created_at_array[position] IS NOT NULL
AND "issues"."created_at" = recursive_keyset_cte.issues_created_at_array[position]
AND "issues"."id" > recursive_keyset_cte.issues_id_array[position]
ORDER BY "issues"."created_at" ASC, "issues"."id" ASC)) issues
ORDER BY "issues"."created_at" ASC, "issues"."id" ASC
LIMIT 1) record ON TRUE
LIMIT 1) AS next_cursor_values))
-- finding the next cursor values (next_cursor_values_query) END
SELECT (records).*
FROM "recursive_keyset_cte" AS "issues"
WHERE (COUNT < > 0)) issues -- filtering out the initializer row
LIMIT 20
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```
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### Using the `IN` query optimization
#### Adding more filters
In this example, let's add an extra filter by `milestone_id` .
Be careful when adding extra filters to the query. If the column is not covered by the same index,
then the query might perform worse than the non-optimized query. The `milestone_id` column in the
`issues` table is currently covered by a different index:
```sql
"index_issues_on_milestone_id" btree (milestone_id)
```
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Adding the `milestone_id = X` filter to the `scope` argument or to the optimized scope causes bad performance.
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Example (bad):
```ruby
Gitlab::Pagination::Keyset::InOperatorOptimization::QueryBuilder.new(
scope: scope,
array_scope: array_scope,
array_mapping_scope: array_mapping_scope,
finder_query: finder_query
).execute
.where(milestone_id: 5)
.limit(20)
```
To address this concern, we could define another index:
```sql
"idx_issues_on_project_id_and_milestone_id_and_created_at_and_id" btree (project_id, milestone_id, created_at, id)
```
Adding more indexes to the `issues` table could significantly affect the performance of
the `UPDATE` queries. In this case, it's better to rely on the original query. It means that if we
want to use the optimization for the unfiltered page we need to add extra logic in the application code:
```ruby
if optimization_possible? # no extra params or params covered with the same index as the ORDER BY clause
run_optimized_query
else
run_normal_in_query
end
```
#### Multiple `IN` queries
Let's assume that we want to extend the group-level queries to include only incident and test case
issue types.
The original ActiveRecord query would look like this:
```ruby
scope = Issue
.where(project_id: Group.find(9970).all_projects.select(:id)) # `gitlab-org` group and its subgroups
.where(issue_type: [:incident, :test_case]) # 1, 2
.order(:created_at, :id)
.limit(20)
```
To construct the array scope, we'll need to take the Cartesian product of the `project_id IN` and
the `issue_type IN` queries. `issue_type` is an ActiveRecord enum, so we need to
construct the following table:
| `project_id` | `issue_type_value` |
| ------------ | ------------------ |
| 2 | 1 |
| 2 | 2 |
| 5 | 1 |
| 5 | 2 |
| 10 | 1 |
| 10 | 2 |
| 9 | 1 |
| 9 | 2 |
For the `issue_types` query we can construct a value list without querying a table:
```ruby
value_list = Arel::Nodes::ValuesList.new([[Issue.issue_types[:incident]],[Issue.issue_types[:test_case]]])
issue_type_values = Arel::Nodes::Grouping.new(value_list).as('issue_type_values (value)').to_sql
array_scope = Group
.find(9970)
.all_projects
.from("#{Project.table_name}, #{issue_type_values}")
.select(:id, :value)
```
Building the `array_mapping_scope` query requires two arguments: `id` and `issue_type_value` :
```ruby
array_mapping_scope = -> (id_expression, issue_type_value_expression) { Issue.where(Issue.arel_table[:project_id].eq(id_expression)).where(Issue.arel_table[:issue_type].eq(issue_type_value_expression)) }
```
The `scope` and the `finder` queries don't change:
```ruby
scope = Issue.order(:created_at, :id)
finder_query = -> (created_at_expression, id_expression) { Issue.where(Issue.arel_table[:id].eq(id_expression)) }
Gitlab::Pagination::Keyset::InOperatorOptimization::QueryBuilder.new(
scope: scope,
array_scope: array_scope,
array_mapping_scope: array_mapping_scope,
finder_query: finder_query
).execute.limit(20)
```
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The SQL query:
```sql
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SELECT "issues".*
FROM
(WITH RECURSIVE "array_cte" AS MATERIALIZED
(SELECT "projects"."id", "value"
FROM projects, (
VALUES (1), (2)) AS issue_type_values (value)
WHERE "projects"."namespace_id" IN
(WITH RECURSIVE "base_and_descendants" AS (
(SELECT "namespaces".*
FROM "namespaces"
WHERE "namespaces"."type" = 'Group'
AND "namespaces"."id" = 9970)
UNION
(SELECT "namespaces".*
FROM "namespaces", "base_and_descendants"
WHERE "namespaces"."type" = 'Group'
AND "namespaces"."parent_id" = "base_and_descendants"."id")) SELECT "id"
FROM "base_and_descendants" AS "namespaces")),
"recursive_keyset_cte" AS (
(SELECT NULL::issues AS records,
array_cte_id_array,
array_cte_value_array,
issues_created_at_array,
issues_id_array,
0::bigint AS COUNT
FROM
(SELECT ARRAY_AGG("array_cte"."id") AS array_cte_id_array,
ARRAY_AGG("array_cte"."value") AS array_cte_value_array,
ARRAY_AGG("issues"."created_at") AS issues_created_at_array,
ARRAY_AGG("issues"."id") AS issues_id_array
FROM
(SELECT "array_cte"."id",
"array_cte"."value"
FROM array_cte) array_cte
LEFT JOIN LATERAL
(SELECT "issues"."created_at",
"issues"."id"
FROM "issues"
WHERE "issues"."project_id" = "array_cte"."id"
AND "issues"."issue_type" = "array_cte"."value"
ORDER BY "issues"."created_at" ASC, "issues"."id" ASC
LIMIT 1) issues ON TRUE
WHERE "issues"."created_at" IS NOT NULL
AND "issues"."id" IS NOT NULL) array_scope_lateral_query
LIMIT 1)
UNION ALL
(SELECT
(SELECT issues
FROM "issues"
WHERE "issues"."id" = recursive_keyset_cte.issues_id_array[POSITION]
LIMIT 1), array_cte_id_array,
array_cte_value_array,
recursive_keyset_cte.issues_created_at_array[:position_query.position-1]||next_cursor_values.created_at||recursive_keyset_cte.issues_created_at_array[position_query.position+1:], recursive_keyset_cte.issues_id_array[:position_query.position-1]||next_cursor_values.id||recursive_keyset_cte.issues_id_array[position_query.position+1:], recursive_keyset_cte.count + 1
FROM recursive_keyset_cte,
LATERAL
(SELECT created_at,
id,
POSITION
FROM UNNEST(issues_created_at_array, issues_id_array) WITH
ORDINALITY AS u(created_at, id, POSITION)
WHERE created_at IS NOT NULL
AND id IS NOT NULL
ORDER BY "created_at" ASC, "id" ASC
LIMIT 1) AS position_query,
LATERAL
(SELECT "record"."created_at",
"record"."id"
FROM (
VALUES (NULL,
NULL)) AS nulls
LEFT JOIN
(SELECT "issues"."created_at",
"issues"."id"
FROM (
(SELECT "issues"."created_at",
"issues"."id"
FROM "issues"
WHERE "issues"."project_id" = recursive_keyset_cte.array_cte_id_array[POSITION]
AND "issues"."issue_type" = recursive_keyset_cte.array_cte_value_array[POSITION]
AND recursive_keyset_cte.issues_created_at_array[POSITION] IS NULL
AND "issues"."created_at" IS NULL
AND "issues"."id" > recursive_keyset_cte.issues_id_array[POSITION]
ORDER BY "issues"."created_at" ASC, "issues"."id" ASC)
UNION ALL
(SELECT "issues"."created_at",
"issues"."id"
FROM "issues"
WHERE "issues"."project_id" = recursive_keyset_cte.array_cte_id_array[POSITION]
AND "issues"."issue_type" = recursive_keyset_cte.array_cte_value_array[POSITION]
AND recursive_keyset_cte.issues_created_at_array[POSITION] IS NOT NULL
AND "issues"."created_at" IS NULL
ORDER BY "issues"."created_at" ASC, "issues"."id" ASC)
UNION ALL
(SELECT "issues"."created_at",
"issues"."id"
FROM "issues"
WHERE "issues"."project_id" = recursive_keyset_cte.array_cte_id_array[POSITION]
AND "issues"."issue_type" = recursive_keyset_cte.array_cte_value_array[POSITION]
AND recursive_keyset_cte.issues_created_at_array[POSITION] IS NOT NULL
AND "issues"."created_at" > recursive_keyset_cte.issues_created_at_array[POSITION]
ORDER BY "issues"."created_at" ASC, "issues"."id" ASC)
UNION ALL
(SELECT "issues"."created_at",
"issues"."id"
FROM "issues"
WHERE "issues"."project_id" = recursive_keyset_cte.array_cte_id_array[POSITION]
AND "issues"."issue_type" = recursive_keyset_cte.array_cte_value_array[POSITION]
AND recursive_keyset_cte.issues_created_at_array[POSITION] IS NOT NULL
AND "issues"."created_at" = recursive_keyset_cte.issues_created_at_array[POSITION]
AND "issues"."id" > recursive_keyset_cte.issues_id_array[POSITION]
ORDER BY "issues"."created_at" ASC, "issues"."id" ASC)) issues
ORDER BY "issues"."created_at" ASC, "issues"."id" ASC
LIMIT 1) record ON TRUE
LIMIT 1) AS next_cursor_values)) SELECT (records).*
FROM "recursive_keyset_cte" AS "issues"
WHERE (COUNT < > 0)) issues
LIMIT 20
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```
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NOTE:
To make the query efficient, the following columns need to be covered with an index: `project_id` , `issue_type` , `created_at` , and `id` .
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#### Using calculated ORDER BY expression
The following example orders epic records by the duration between the creation time and closed
time. It is calculated with the following formula:
```sql
SELECT EXTRACT('epoch' FROM epics.closed_at - epics.created_at) FROM epics
```
The query above returns the duration in seconds (`double precision`) between the two timestamp
columns in seconds. To order the records by this expression, you must reference it
in the `ORDER BY` clause:
```sql
SELECT EXTRACT('epoch' FROM epics.closed_at - epics.created_at)
FROM epics
ORDER BY EXTRACT('epoch' FROM epics.closed_at - epics.created_at) DESC
```
To make this ordering efficient on the group-level with the in-operator optimization, use a
custom `ORDER BY` configuration. Since the duration is not a distinct value (no unique index
present), you must add a tie-breaker column (`id`).
The following example shows the final `ORDER BY` clause:
```sql
ORDER BY extract('epoch' FROM epics.closed_at - epics.created_at) DESC, epics.id DESC
```
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Snippet for loading records ordered by the calculated duration:
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```ruby
arel_table = Epic.arel_table
order = Gitlab::Pagination::Keyset::Order.build([
Gitlab::Pagination::Keyset::ColumnOrderDefinition.new(
attribute_name: 'duration_in_seconds',
order_expression: Arel.sql('EXTRACT(EPOCH FROM epics.closed_at - epics.created_at)').desc,
distinct: false,
sql_type: 'double precision' # important for calculated SQL expressions
),
Gitlab::Pagination::Keyset::ColumnOrderDefinition.new(
attribute_name: 'id',
order_expression: arel_table[:id].desc
)
])
records = Gitlab::Pagination::Keyset::InOperatorOptimization::QueryBuilder.new(
scope: Epic.where.not(closed_at: nil).reorder(order), # filter out NULL values
array_scope: Group.find(9970).self_and_descendants.select(:id),
array_mapping_scope: -> (id_expression) { Epic.where(Epic.arel_table[:group_id].eq(id_expression)) }
).execute.limit(20)
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puts records.pluck(:duration_in_seconds, :id) # other columns are not available
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```
Building the query requires quite a bit of configuration. For the order configuration you
can find more information within the
[complex order configuration ](keyset_pagination.md#complex-order-configuration )
section for keyset paginated database queries.
The query requires a specialized database index:
```sql
CREATE INDEX index_epics_on_duration ON epics USING btree (group_id, EXTRACT(EPOCH FROM epics.closed_at - epics.created_at) DESC, id DESC) WHERE (closed_at IS NOT NULL);
```
Notice that the `finder_query` parameter is not used. The query only returns the `ORDER BY` columns
which are the `duration_in_seconds` (calculated column) and the `id` columns. This is a limitation
of the feature, defining the `finder_query` with calculated `ORDER BY` expressions is not supported.
To get the complete database records, an extra query can be invoked by the returned `id` column:
```ruby
records_by_id = records.index_by(& :id)
complete_records = Epic.where(id: records_by_id.keys).index_by(& :id)
# Printing the complete records according to the `ORDER BY` clause
records_by_id.each do |id, _|
puts complete_records[id].attributes
end
```
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#### Batch iteration
Batch iteration over the records is possible via the keyset `Iterator` class.
```ruby
scope = Issue.order(:created_at, :id)
array_scope = Group.find(9970).all_projects.select(:id)
array_mapping_scope = -> (id_expression) { Issue.where(Issue.arel_table[:project_id].eq(id_expression)) }
finder_query = -> (created_at_expression, id_expression) { Issue.where(Issue.arel_table[:id].eq(id_expression)) }
opts = {
in_operator_optimization_options: {
array_scope: array_scope,
array_mapping_scope: array_mapping_scope,
finder_query: finder_query
}
}
Gitlab::Pagination::Keyset::Iterator.new(scope: scope, **opts).each_batch(of: 100) do |records|
puts records.select(:id).map { |r| [r.id] }
end
```
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NOTE:
The query loads complete database rows from the disk. This may cause increased I/O and slower
database queries. Depending on the use case, the primary key is often only
needed for the batch query to invoke additional statements. For example, `UPDATE` or `DELETE` . The
`id` column is included in the `ORDER BY` columns (`created_at` and `id` ) and is already
loaded. In this case, you can omit the `finder_query` parameter.
Example for loading the `ORDER BY` columns only:
```ruby
scope = Issue.order(:created_at, :id)
array_scope = Group.find(9970).all_projects.select(:id)
array_mapping_scope = -> (id_expression) { Issue.where(Issue.arel_table[:project_id].eq(id_expression)) }
opts = {
in_operator_optimization_options: {
array_scope: array_scope,
array_mapping_scope: array_mapping_scope
}
}
Gitlab::Pagination::Keyset::Iterator.new(scope: scope, **opts).each_batch(of: 100) do |records|
puts records.select(:id).map { |r| [r.id] } # only id and created_at are available
end
```
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#### Keyset pagination
The optimization works out of the box with GraphQL and the `keyset_paginate` helper method.
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Read more about [keyset pagination ](keyset_pagination.md ).
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```ruby
array_scope = Group.find(9970).all_projects.select(:id)
array_mapping_scope = -> (id_expression) { Issue.where(Issue.arel_table[:project_id].eq(id_expression)) }
finder_query = -> (created_at_expression, id_expression) { Issue.where(Issue.arel_table[:id].eq(id_expression)) }
opts = {
in_operator_optimization_options: {
array_scope: array_scope,
array_mapping_scope: array_mapping_scope,
finder_query: finder_query
}
}
issues = Issue
.order(:created_at, :id)
.keyset_paginate(per_page: 20, keyset_order_options: opts)
.records
```
#### Offset pagination with Kaminari
The `ActiveRecord` scope produced by the `InOperatorOptimization` class can be used in
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[offset-paginated ](pagination_guidelines.md#offset-pagination )
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queries.
```ruby
Gitlab::Pagination::Keyset::InOperatorOptimization::QueryBuilder
.new(...)
.execute
.page(1)
.per(20)
.without_count
```
## Generalized `IN` optimization technique
Let's dive into how `QueryBuilder` builds the optimized query
to fetch the twenty oldest created issues from the group `gitlab-org`
using the generalized `IN` optimization technique.
### Array CTE
As the first step, we use a common table expression (CTE) for collecting the `projects.id` values.
This is done by wrapping the incoming `array_scope` ActiveRecord relation parameter with a CTE.
```sql
WITH array_cte AS MATERIALIZED (
SELECT "projects"."id"
FROM "projects"
WHERE "projects"."namespace_id" IN
(SELECT traversal_ids[array_length(traversal_ids, 1)] AS id
FROM "namespaces"
WHERE (traversal_ids @> ('{9970}')))
)
```
This query produces the following result set with only one column (`projects.id`):
| ID |
| --- |
| 9 |
| 2 |
| 5 |
| 10 |
### Array mapping
For each project (that is, each record storing a project ID in `array_cte` ),
we will fetch the cursor value identifying the first issue respecting the `ORDER BY` clause.
As an example, let's pick the first record `ID=9` from `array_cte` .
The following query should fetch the cursor value `(created_at, id)` identifying
the first issue record respecting the `ORDER BY` clause for the project with `ID=9` :
```sql
SELECT "issues"."created_at", "issues"."id"
FROM "issues"."project_id"=9
ORDER BY "issues"."created_at" ASC, "issues"."id" ASC
LIMIT 1;
```
We will use `LATERAL JOIN` to loop over the records in the `array_cte` and find the
cursor value for each project. The query would be built using the `array_mapping_scope` lambda
function.
```sql
SELECT ARRAY_AGG("array_cte"."id") AS array_cte_id_array,
ARRAY_AGG("issues"."created_at") AS issues_created_at_array,
ARRAY_AGG("issues"."id") AS issues_id_array
FROM (
SELECT "array_cte"."id" FROM array_cte
) array_cte
LEFT JOIN LATERAL
(
SELECT "issues"."created_at", "issues"."id"
FROM "issues"
WHERE "issues"."project_id" = "array_cte"."id"
ORDER BY "issues"."created_at" ASC, "issues"."id" ASC
LIMIT 1
) issues ON TRUE
```
Since we have an index on `project_id` , `created_at` , and `id` ,
index-only scans should quickly locate all the cursor values.
This is how the query could be translated to Ruby:
```ruby
created_at_values = []
id_values = []
project_ids.map do |project_id|
created_at, id = Issue.select(:created_at, :id).where(project_id: project_id).order(:created_at, :id).limit(1).first # N+1 but it's fast
created_at_values < < created_at
id_values < < id
end
```
This is what the result set would look like:
| `project_ids` | `created_at_values` | `id_values` |
| ------------- | ------------------- | ----------- |
| 2 | 2020-01-10 | 5 |
| 5 | 2020-01-05 | 4 |
| 10 | 2020-01-15 | 7 |
| 9 | 2020-01-05 | 3 |
The table shows the cursor values (`created_at, id`) of the first record for each project
respecting the `ORDER BY` clause.
At this point, we have the initial data. To start collecting the actual records from the database,
we'll use a recursive CTE query where each recursion locates one row until
the `LIMIT` is reached or no more data can be found.
Here's an outline of the steps we will take in the recursive CTE query
(expressing the steps in SQL is non-trivial but will be explained next):
1. Sort the initial resultset according to the `ORDER BY` clause.
1. Pick the top cursor to fetch the record, this is our first record. In the example,
this cursor would be (`2020-01-05`, `3` ) for `project_id=9` .
1. We can use (`2020-01-05`, `3` ) to fetch the next issue respecting the `ORDER BY` clause
`project_id=9` filter. This produces an updated resultset.
| `project_ids` | `created_at_values` | `id_values` |
| ------------- | ------------------- | ----------- |
| 2 | 2020-01-10 | 5 |
| 5 | 2020-01-05 | 4 |
| 10 | 2020-01-15 | 7 |
| **9** | **2020-01-06** | **6** |
1. Repeat 1 to 3 with the updated resultset until we have fetched `N=20` records.
### Initializing the recursive CTE query
For the initial recursive query, we'll need to produce exactly one row, we call this the
initializer query (`initializer_query`).
Use `ARRAY_AGG` function to compact the initial result set into a single row
and use the row as the initial value for the recursive CTE query:
Example initializer row:
| `records` | `project_ids` | `created_at_values` | `id_values` | `Count` | `Position` |
| -------------- | --------------- | ------------------- | ----------- | ------- | ---------- |
| `NULL::issues` | `[9, 2, 5, 10]` | `[...]` | `[...]` | `0` | `NULL` |
- The `records` column contains our sorted database records, and the initializer query sets the
first value to `NULL` , which is filtered out later.
- The `count` column tracks the number of records found. We use this column to filter out the
initializer row from the result set.
### Recursive portion of the CTE query
The result row is produced with the following steps:
1. [Order the keyset arrays. ](#order-the-keyset-arrays )
1. [Find the next cursor. ](#find-the-next-cursor )
1. [Produce a new row. ](#produce-a-new-row )
#### Order the keyset arrays
Order the keyset arrays according to the original `ORDER BY` clause with `LIMIT 1` using the
`UNNEST [] WITH ORDINALITY` table function. The function locates the "lowest" keyset cursor
values and gives us the array position. These cursor values are used to locate the record.
NOTE:
At this point, we haven't read anything from the database tables, because we relied on
fast index-only scans.
| `project_ids` | `created_at_values` | `id_values` |
| ------------- | ------------------- | ----------- |
| 2 | 2020-01-10 | 5 |
| 5 | 2020-01-05 | 4 |
| 10 | 2020-01-15 | 7 |
| 9 | 2020-01-05 | 3 |
The first row is the 4th one (`position = 4`), because it has the lowest `created_at` and
`id` values. The `UNNEST` function also exposes the position using an extra column (note:
PostgreSQL uses 1-based index).
Demonstration of the `UNNEST [] WITH ORDINALITY` table function:
```sql
SELECT position FROM unnest('{2020-01-10, 2020-01-05, 2020-01-15, 2020-01-05}'::timestamp[], '{5, 4, 7, 3}'::int[])
WITH ORDINALITY AS t(created_at, id, position) ORDER BY created_at ASC, id ASC LIMIT 1;
```
Result:
```sql
position
----------
4
(1 row)
```
#### Find the next cursor
Now, let's find the next cursor values (`next_cursor_values_query`) for the project with `id = 9` .
To do that, we build a keyset pagination SQL query. Find the next row after
`created_at = 2020-01-05` and `id = 3` . Because we order by two database columns, there can be two
cases:
- There are rows with `created_at = 2020-01-05` and `id > 3` .
- There are rows with `created_at > 2020-01-05` .
Generating this query is done by the generic keyset pagination library. After the query is done,
we have a temporary table with the next cursor values:
| `created_at` | ID |
| ------------ | --- |
| 2020-01-06 | 6 |
#### Produce a new row
As the final step, we need to produce a new row by manipulating the initializer row
(`data_collector_query` method). Two things happen here:
- Read the full row from the DB and return it in the `records` columns. (`result_collector_columns`
method)
- Replace the cursor values at the current position with the results from the keyset query.
Reading the full row from the database is only one index scan by the primary key. We use the
ActiveRecord query passed as the `finder_query` :
```sql
(SELECT "issues".* FROM issues WHERE id = id_values[position] LIMIT 1)
```
By adding parentheses, the result row can be put into the `records` column.
Replacing the cursor values at `position` can be done via standard PostgreSQL array operators:
```sql
-- created_at_values column value
created_at_values[:position-1]||next_cursor_values.created_at||created_at_values[position+1:]
-- id_values column value
id_values[:position-1]||next_cursor_values.id||id_values[position+1:]
```
The Ruby equivalent would be the following:
```ruby
id_values[0..(position - 1)] + [next_cursor_values.id] + id_values[(position + 1)..-1]
```
After this, the recursion starts again by finding the next lowest cursor value.
### Finalizing the query
For producing the final `issues` rows, we're going to wrap the query with another `SELECT` statement:
```sql
SELECT "issues".*
FROM (
SELECT (records).* -- similar to ruby splat operator
FROM recursive_keyset_cte
WHERE recursive_keyset_cte.count < > 0 -- filter out the initializer row
) AS issues
```
### Performance comparison
Assuming that we have the correct database index in place, we can compare the query performance by
looking at the number of database rows accessed by the query.
- Number of groups: 100
- Number of projects: 500
- Number of issues (in the group hierarchy): 50 000
Standard `IN` query:
| Query | Entries read from index | Rows read from the table | Rows sorted in memory |
| ------------------------ | ----------------------- | ------------------------ | --------------------- |
| group hierarchy subquery | 100 | 0 | 0 |
| project lookup query | 500 | 0 | 0 |
| issue lookup query | 50 000 | 20 | 50 000 |
Optimized `IN` query:
| Query | Entries read from index | Rows read from the table | Rows sorted in memory |
| ------------------------ | ----------------------- | ------------------------ | --------------------- |
| group hierarchy subquery | 100 | 0 | 0 |
| project lookup query | 500 | 0 | 0 |
| issue lookup query | 519 | 20 | 10 000 |
The group and project queries are not using sorting, the necessary columns are read from database
indexes. These values are accessed frequently so it's very likely that most of the data will be
in the PostgreSQL's buffer cache.
The optimized `IN` query will read maximum 519 entries (cursor values) from the index:
- 500 index-only scans for populating the arrays for each project. The cursor values of the first
record will be here.
- Maximum 19 additional index-only scans for the consecutive records.
The optimized `IN` query will sort the array (cursor values per project array) 20 times, which
means we'll sort 20 x 500 rows. However, this might be a less memory-intensive task than
sorting 10 000 rows at once.
Performance comparison for the `gitlab-org` group:
| Query | Number of 8K Buffers involved | Uncached execution time | Cached execution time |
| -------------------- | ----------------------------- | ----------------------- | --------------------- |
| `IN` query | 240833 | 1.2s | 660ms |
| Optimized `IN` query | 9783 | 450ms | 22ms |
NOTE:
Before taking measurements, the group lookup query was executed separately in order to make
the group data available in the buffer cache. Since it's a frequently called query, it's going to
hit many shared buffers during the query execution in the production environment.
