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author | Robert Speicher <robert@gitlab.com> | 2018-08-17 21:06:05 +0000 |
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committer | Robert Speicher <robert@gitlab.com> | 2018-08-17 21:06:05 +0000 |
commit | 1198337344b4ef78136f11055b15e09a0917d855 (patch) | |
tree | 236249036fa48e30f1a79abd4e68fbda6c3949c5 /doc | |
parent | 120ce02e5e7e72654cb42edddc25ff3b057ec136 (diff) | |
parent | 3d46f3155ae07d566dfbc72776e0b4a3207a91fc (diff) | |
download | gitlab-ce-1198337344b4ef78136f11055b15e09a0917d855.tar.gz |
Merge branch 'docs/document-query-plans' into 'master'29398-support-kubernetes-rbac-for-gitlab-managed-apps-2
Add documentation about reading query plans
See merge request gitlab-org/gitlab-ce!21199
Diffstat (limited to 'doc')
-rw-r--r-- | doc/development/README.md | 8 | ||||
-rw-r--r-- | doc/development/understanding_explain_plans.md | 676 |
2 files changed, 683 insertions, 1 deletions
diff --git a/doc/development/README.md b/doc/development/README.md index fed3903c771..ee9a9852205 100644 --- a/doc/development/README.md +++ b/doc/development/README.md @@ -55,7 +55,13 @@ description: 'Learn how to contribute to GitLab.' - [Merge request performance guidelines](merge_request_performance_guidelines.md) for ensuring merge requests do not negatively impact GitLab performance -## Databases guides +## Database guides + +### Tooling + +- [Understanding EXPLAIN plans](understanding_explain_plans.md) +- [explain.depesz.com](https://explain.depesz.com/) for visualising the output + of `EXPLAIN` ### Migrations diff --git a/doc/development/understanding_explain_plans.md b/doc/development/understanding_explain_plans.md new file mode 100644 index 00000000000..adf8795a5e3 --- /dev/null +++ b/doc/development/understanding_explain_plans.md @@ -0,0 +1,676 @@ +# Understanding EXPLAIN plans + +PostgreSQL allows you to obtain query plans using the `EXPLAIN` command. This +command can be invaluable when trying to determine how a query will perform. +You can use this command directly in your SQL query, as long as the query starts +with it: + +```sql +EXPLAIN +SELECT COUNT(*) +FROM projects +WHERE visibility_level IN (0, 20); +``` + +When running this on GitLab.com, we are presented with the following output: + +``` +Aggregate (cost=922411.76..922411.77 rows=1 width=8) + -> Seq Scan on projects (cost=0.00..908044.47 rows=5746914 width=0) + Filter: (visibility_level = ANY ('{0,20}'::integer[])) +``` + +When using _just_ `EXPLAIN`, PostgreSQL won't actually execute our query, +instead it produces an _estimated_ execution plan based on the available +statistics. This means the actual plan can differ quite a bit. Fortunately, +PostgreSQL provides us with the option to execute the query as well. To do so, +we need to use `EXPLAIN ANALYZE` instead of just `EXPLAIN`: + +```sql +EXPLAIN ANALYZE +SELECT COUNT(*) +FROM projects +WHERE visibility_level IN (0, 20); +``` + +This will produce: + +``` +Aggregate (cost=922420.60..922420.61 rows=1 width=8) (actual time=3428.535..3428.535 rows=1 loops=1) + -> Seq Scan on projects (cost=0.00..908053.18 rows=5746969 width=0) (actual time=0.041..2987.606 rows=5746940 loops=1) + Filter: (visibility_level = ANY ('{0,20}'::integer[])) + Rows Removed by Filter: 65677 +Planning time: 2.861 ms +Execution time: 3428.596 ms +``` + +As we can see this plan is quite different, and includes a lot more data. Let's +discuss this step by step. + +Because `EXPLAIN ANALYZE` executes the query, care should be taken when using a +query that will write data or might time out. If the query modifies data, +consider wrapping it in a transaction that rolls back automatically like so: + +```sql +BEGIN; +EXPLAIN ANALYZE +DELETE FROM users WHERE id = 1; +ROLLBACK; +``` + +The `EXPLAIN` command also takes additional options, such as `BUFFERS`: + +```sql +EXPLAIN (ANALYZE, BUFFERS) +SELECT COUNT(*) +FROM projects +WHERE visibility_level IN (0, 20); +``` + +This will then produce: + +``` +Aggregate (cost=922420.60..922420.61 rows=1 width=8) (actual time=3428.535..3428.535 rows=1 loops=1) + Buffers: shared hit=208846 + -> Seq Scan on projects (cost=0.00..908053.18 rows=5746969 width=0) (actual time=0.041..2987.606 rows=5746940 loops=1) + Filter: (visibility_level = ANY ('{0,20}'::integer[])) + Rows Removed by Filter: 65677 + Buffers: shared hit=208846 +Planning time: 2.861 ms +Execution time: 3428.596 ms +``` + +For more information, refer to the official [EXPLAIN +documentation](https://www.postgresql.org/docs/current/static/sql-explain.html). + +## Nodes + +Every query plan consists of nodes. Nodes can be nested, and are executed from +the inside out. This means that the innermost node is executed before an outer +node. This can be best thought of as nested function calls, returning their +results as they unwind. For example, a plan starting with an `Aggregate` +followed by a `Nested Loop`, followed by an `Index Only scan` can be thought of +as the following Ruby code: + +```ruby +aggregate( + nested_loop( + index_only_scan() + index_only_scan() + ) +) +``` + +Nodes are indicated using a `->` followed by the type of node taken. For +example: + +``` +Aggregate (cost=922411.76..922411.77 rows=1 width=8) + -> Seq Scan on projects (cost=0.00..908044.47 rows=5746914 width=0) + Filter: (visibility_level = ANY ('{0,20}'::integer[])) +``` + +Here the first node executed is `Seq scan on projects`. The `Filter:` is an +additional filter applied to the results of the node. A filter is very similar +to Ruby's `Array#select`: it takes the input rows, applies the filter, and +produces a new list of rows. Once the node is done, we perform the `Aggregate` +above it. + +Nested nodes will look like this: + +``` +Aggregate (cost=176.97..176.98 rows=1 width=8) (actual time=0.252..0.252 rows=1 loops=1) + Buffers: shared hit=155 + -> Nested Loop (cost=0.86..176.75 rows=87 width=0) (actual time=0.035..0.249 rows=36 loops=1) + Buffers: shared hit=155 + -> Index Only Scan using users_pkey on users users_1 (cost=0.43..4.95 rows=87 width=4) (actual time=0.029..0.123 rows=36 loops=1) + Index Cond: (id < 100) + Heap Fetches: 0 + -> Index Only Scan using users_pkey on users (cost=0.43..1.96 rows=1 width=4) (actual time=0.003..0.003 rows=1 loops=36) + Index Cond: (id = users_1.id) + Heap Fetches: 0 +Planning time: 2.585 ms +Execution time: 0.310 ms +``` + +Here we first perform two separate "Index Only" scans, followed by performing a +"Nested Loop" on the result of these two scans. + +## Node statistics + +Each node in a plan has a set of associated statistics, such as the cost, the +number of rows produced, the number of loops performed, and more. For example: + +``` +Seq Scan on projects (cost=0.00..908044.47 rows=5746914 width=0) +``` + +Here we can see that our cost ranges from `0.00..908044.47` (we'll cover this in +a moment), and we estimate (since we're using `EXPLAIN` and not `EXPLAIN +ANALYZE`) a total of 5,746,914 rows to be produced by this node. The `width` +statistics describes the estimated width of each row, in bytes. + +The `costs` field specifies how expensive a node was. The cost is measured in +arbitrary units determined by the query planner's cost parameters. What +influences the costs depends on a variety of settings, such as `seq_page_cost`, +`cpu_tuple_cost`, and various others. +The format of the costs field is as follows: + +``` +STARTUP COST..TOTAL COST +``` + +The startup cost states how expensive it was to start the node, with the total +cost describing how expensive the entire node was. In general: the greater the +values, the more expensive the node. + +When using `EXPLAIN ANALYZE`, these statistics will also include the actual time +(in milliseconds) spent, and other runtime statistics (e.g. the actual number of +produced rows): + +``` +Seq Scan on projects (cost=0.00..908053.18 rows=5746969 width=0) (actual time=0.041..2987.606 rows=5746940 loops=1) +``` + +Here we can see we estimated 5,746,969 rows to be returned, but in reality we +returned 5,746,940 rows. We can also see that _just_ this sequential scan took +2.98 seconds to run. + +Using `EXPLAIN (ANALYZE, BUFFERS)` will also give us information about the +number of rows removed by a filter, the number of buffers used, and more. For +example: + +``` +Seq Scan on projects (cost=0.00..908053.18 rows=5746969 width=0) (actual time=0.041..2987.606 rows=5746940 loops=1) + Filter: (visibility_level = ANY ('{0,20}'::integer[])) + Rows Removed by Filter: 65677 + Buffers: shared hit=208846 +``` + +Here we can see that our filter has to remove 65,677 rows, and that we use +208,846 buffers. Each buffer in PostgreSQL is 8 KB (8192 bytes), meaning our +above node uses *1.6 GB of buffers*. That's a lot! + +## Node types + +There are quite a few different types of nodes, so we only cover some of the +more common ones here. + +A full list of all the available nodes and their descriptions can be found in +the [PostgreSQL source file +"plannodes.h"](https://github.com/postgres/postgres/blob/master/src/include/nodes/plannodes.h) + +### Seq Scan + +A sequential scan over (a chunk of) a database table. This is like using +`Array#each`, but on a database table. Sequential scans can be quite slow when +retrieving lots of rows, so it's best to avoid these for large tables. + +### Index Only Scan + +A scan on an index that did not require fetching anything from the table. In +certain cases an index only scan may still fetch data from the table, in this +case the node will include a `Heap Fetches:` statistic. + +### Index Scan + +A scan on an index that required retrieving some data from the table. + +### Bitmap Index Scan and Bitmap Heap scan + +Bitmap scans fall between sequential scans and index scans. These are typically +used when we would read too much data from an index scan, but too little to +perform a sequential scan. A bitmap scan uses what is known as a [bitmap +index](https://en.wikipedia.org/wiki/Bitmap_index) to perform its work. + +The [source code of PostgreSQL](https://github.com/postgres/postgres/blob/1c2cb2744bf3d8ad751cd5cf3b347f10f48492b3/src/include/nodes/plannodes.h#L446-L457) +states the following on bitmap scans: + +> Bitmap Index Scan delivers a bitmap of potential tuple locations; it does not +> access the heap itself. The bitmap is used by an ancestor Bitmap Heap Scan +> node, possibly after passing through intermediate Bitmap And and/or Bitmap Or +> nodes to combine it with the results of other Bitmap Index Scans. + +### Limit + +Applies a `LIMIT` on the input rows. + +### Sort + +Sorts the input rows as specified using an `ORDER BY` statement. + +### Nested Loop + +A nested loop will execute its child nodes for every row produced by a node that +precedes it. For example: + +``` +-> Nested Loop (cost=0.86..176.75 rows=87 width=0) (actual time=0.035..0.249 rows=36 loops=1) + Buffers: shared hit=155 + -> Index Only Scan using users_pkey on users users_1 (cost=0.43..4.95 rows=87 width=4) (actual time=0.029..0.123 rows=36 loops=1) + Index Cond: (id < 100) + Heap Fetches: 0 + -> Index Only Scan using users_pkey on users (cost=0.43..1.96 rows=1 width=4) (actual time=0.003..0.003 rows=1 loops=36) + Index Cond: (id = users_1.id) + Heap Fetches: 0 +``` + +Here the first child node (`Index Only Scan using users_pkey on users users_1`) +produces 36 rows, and is executed once (`rows=36 loops=1`). The next node +produces 1 row (`rows=1`), but is repeated 36 times (`loops=36`). This is +because the previous node produced 36 rows. + +This means that nested loops can quickly slow the query down if the various +child nodes keep producing many rows. + +## Optimising queries + +With that out of the way, let's see how we can optimise a query. Let's use the +following query as an example: + +```sql +SELECT COUNT(*) +FROM users +WHERE twitter != ''; +``` + +This query simply counts the number of users that have a Twitter profile set. +Let's run this using `EXPLAIN (ANALYZE, BUFFERS)`: + +```sql +EXPLAIN (ANALYZE, BUFFERS) +SELECT COUNT(*) +FROM users +WHERE twitter != ''; +``` + +This will produce the following plan: + +``` +Aggregate (cost=845110.21..845110.22 rows=1 width=8) (actual time=1271.157..1271.158 rows=1 loops=1) + Buffers: shared hit=202662 + -> Seq Scan on users (cost=0.00..844969.99 rows=56087 width=0) (actual time=0.019..1265.883 rows=51833 loops=1) + Filter: ((twitter)::text <> ''::text) + Rows Removed by Filter: 2487813 + Buffers: shared hit=202662 +Planning time: 0.390 ms +Execution time: 1271.180 ms +``` + +From this query plan we can see the following: + +1. We need to perform a sequential scan on the `users` table. +1. This sequential scan filters out 2,487,813 rows using a `Filter`. +1. We use 202,622 buffers, which equals 1.58 GB of memory. +1. It takes us 1.2 seconds to do all of this. + +Considering we are just counting users, that's quite expensive! + +Before we start making any changes, let's see if there are any existing indexes +on the `users` table that we might be able to use. We can obtain this +information by running `\d users` in a `psql` console, then scrolling down to +the `Indexes:` section: + +``` +Indexes: + "users_pkey" PRIMARY KEY, btree (id) + "users_confirmation_token_key" UNIQUE CONSTRAINT, btree (confirmation_token) + "users_email_key" UNIQUE CONSTRAINT, btree (email) + "users_reset_password_token_key" UNIQUE CONSTRAINT, btree (reset_password_token) + "index_on_users_lower_email" btree (lower(email::text)) + "index_on_users_lower_username" btree (lower(username::text)) + "index_on_users_name_lower" btree (lower(name::text)) + "index_users_on_admin" btree (admin) + "index_users_on_created_at" btree (created_at) + "index_users_on_email_trigram" gin (email gin_trgm_ops) + "index_users_on_feed_token" btree (feed_token) + "index_users_on_ghost" btree (ghost) + "index_users_on_incoming_email_token" btree (incoming_email_token) + "index_users_on_name" btree (name) + "index_users_on_name_trigram" gin (name gin_trgm_ops) + "index_users_on_state" btree (state) + "index_users_on_state_and_internal_attrs" btree (state) WHERE ghost <> true AND support_bot <> true + "index_users_on_support_bot" btree (support_bot) + "index_users_on_username" btree (username) + "index_users_on_username_trigram" gin (username gin_trgm_ops) +``` + +Here we can see there is no index on the `twitter` column, which means +PostgreSQL has to perform a sequential scan in this case. Let's try to fix this +by adding the following index: + +```sql +CREATE INDEX CONCURRENTLY twitter_test ON users (twitter); +``` + +If we now re-run our query using `EXPLAIN (ANALYZE, BUFFERS)` we get the +following plan: + +``` +Aggregate (cost=61002.82..61002.83 rows=1 width=8) (actual time=297.311..297.312 rows=1 loops=1) + Buffers: shared hit=51854 dirtied=19 + -> Index Only Scan using twitter_test on users (cost=0.43..60873.13 rows=51877 width=0) (actual time=279.184..293.532 rows=51833 loops=1) + Filter: ((twitter)::text <> ''::text) + Rows Removed by Filter: 2487830 + Heap Fetches: 26037 + Buffers: shared hit=51854 dirtied=19 +Planning time: 0.191 ms +Execution time: 297.334 ms +``` + +Now it takes just under 300 milliseconds to get our data, instead of 1.2 +seconds. However, we still use 51,854 buffers, which is about 400 MB of memory. +300 milliseconds is also quite slow for such a simple query. To understand why +this query is still expensive, let's take a look at the following: + +``` +Index Only Scan using twitter_test on users (cost=0.43..60873.13 rows=51877 width=0) (actual time=279.184..293.532 rows=51833 loops=1) + Filter: ((twitter)::text <> ''::text) + Rows Removed by Filter: 2487830 +``` + +We start with an index only scan on our index, but we somehow still apply a +`Filter` that filters out 2,487,830 rows. Why is that? Well, let's look at how +we created the index: + +```sql +CREATE INDEX CONCURRENTLY twitter_test ON users (twitter); +``` + +We simply told PostgreSQL to index all possible values of the `twitter` column, +even empty strings. Our query in turn uses `WHERE twitter != ''`. This means +that the index does improve things, as we don't need to do a sequential scan, +but we may still encounter empty strings. This means PostgreSQL _has_ to apply a +Filter on the index results to get rid of those values. + +Fortunately, we can improve this even further using "partial indexes". Partial +indexes are indexes with a `WHERE` condition that is applied when indexing data. +For example: + +```sql +CREATE INDEX CONCURRENTLY some_index ON users (email) WHERE id < 100 +``` + +This index would only index the `email` value of rows that match `WHERE id < +100`. We can use partial indexes to change our Twitter index to the following: + +```sql +CREATE INDEX CONCURRENTLY twitter_test ON users (twitter) WHERE twitter != ''; +``` + +Once created, if we run our query again we will be given the following plan: + +``` +Aggregate (cost=1608.26..1608.27 rows=1 width=8) (actual time=19.821..19.821 rows=1 loops=1) + Buffers: shared hit=44036 + -> Index Only Scan using twitter_test on users (cost=0.41..1479.71 rows=51420 width=0) (actual time=0.023..15.514 rows=51833 loops=1) + Heap Fetches: 1208 + Buffers: shared hit=44036 +Planning time: 0.123 ms +Execution time: 19.848 ms +``` + +That's _a lot_ better! Now it only takes 20 milliseconds to get the data, and we +only use about 344 MB of buffers (instead of the original 1.58 GB). The reason +this works is that now PostgreSQL no longer needs to apply a `Filter`, as the +index only contains `twitter` values that are not empty. + +Keep in mind that you shouldn't just add partial indexes every time you want to +optimise a query. Every index has to be updated for every write, and they may +require quite a bit of space, depending on the amount of indexed data. As a +result, first check if there are any existing indexes you may be able to reuse. +If there aren't any, check if you can perhaps slightly change an existing one to +fit both the existing and new queries. Only add a new index if none of the +existing indexes can be used in any way. + +## Queries that can't be optimised + +Now that we have seen how to optimise a query, let's look at another query that +we might not be able to optimise: + +```sql +EXPLAIN (ANALYZE, BUFFERS) +SELECT COUNT(*) +FROM projects +WHERE visibility_level IN (0, 20); +``` + +The output of `EXPLAIN (ANALYZE, BUFFERS)` is as follows: + +``` +Aggregate (cost=922420.60..922420.61 rows=1 width=8) (actual time=3428.535..3428.535 rows=1 loops=1) + Buffers: shared hit=208846 + -> Seq Scan on projects (cost=0.00..908053.18 rows=5746969 width=0) (actual time=0.041..2987.606 rows=5746940 loops=1) + Filter: (visibility_level = ANY ('{0,20}'::integer[])) + Rows Removed by Filter: 65677 + Buffers: shared hit=208846 +Planning time: 2.861 ms +Execution time: 3428.596 ms +``` + +Looking at the output we see the following Filter: + +``` +Filter: (visibility_level = ANY ('{0,20}'::integer[])) +Rows Removed by Filter: 65677 +``` + +Looking at the number of rows removed by the filter, we may be tempted to add an +index on `projects.visibility_level` to somehow turn this Sequential scan + +filter into an index-only scan. + +Unfortunately, doing so is unlikely to improve anything. Contrary to what some +might believe, an index being present _does not guarantee_ that PostgreSQL will +actually use it. For example, when doing a `SELECT * FROM projects` it is much +cheaper to just scan the entire table, instead of using an index and then +fetching data from the table. In such cases PostgreSQL may decide to not use an +index. + +Second, let's think for a moment what our query does: it gets all projects with +visibility level 0 or 20. In the above plan we can see this produces quite a lot +of rows (5,745,940), but how much is that relative to the total? Let's find out +by running the following query: + +```sql +SELECT visibility_level, count(*) AS amount +FROM projects +GROUP BY visibility_level +ORDER BY visibility_level ASC; +``` + +For GitLab.com this produces: + +``` + visibility_level | amount +------------------+--------- + 0 | 5071325 + 10 | 65678 + 20 | 674801 +``` + +Here the total number of projects is 5,811,804, and 5,746,126 of those are of +level 0 or 20. That's 98% of the entire table! + +So no matter what we do, this query will retrieve 98% of the entire table. Since +most time is spent doing exactly that, there isn't really much we can do to +improve this query, other than _not_ running it at all. + +What is important here is that while some may recommend to straight up add an +index the moment you see a sequential scan, it is _much more important_ to first +understand what your query does, how much data it retrieves, and so on. After +all, you can not optimise something you do not understand. + +### Cardinality and selectivity + +Earlier we saw that our query had to retrieve 98% of the rows in the table. +There are two terms commonly used for databases: cardinality, and selectivity. +Cardinality refers to the number of unique values in a particular column in a +table. + +Selectivity is the number of unique values produced by an operation (e.g. an +index scan or filter), relative to the total number of rows. The higher the +selectivity, the more likely PostgreSQL is able to use an index. + +In the above example, there are only 3 unique values: 0, 10, and 20. This means +the cardinality is 3. The selectivity in turn is also very low: 0.0000003% (2 / +5,811,804), because our `Filter` only filters using two values (`0` and `20`). +With such a low selectivity value it's not surprising that PostgreSQL decides +using an index is not worth it, because it would produce almost no unique rows. + +## Rewriting queries + +So the above query can't really be optimised as-is, or at least not much. But +what if we slightly change the purpose of it? What if instead of retrieving all +projects with `visibility_level` 0 or 20, we retrieve those that a user +interacted with somehow? + +Fortunately, GitLab has an answer for this, and it's a table called +`user_interacted_projects`. This table has the following schema: + +``` +Table "public.user_interacted_projects" + Column | Type | Modifiers +------------+---------+----------- + user_id | integer | not null + project_id | integer | not null +Indexes: + "index_user_interacted_projects_on_project_id_and_user_id" UNIQUE, btree (project_id, user_id) + "index_user_interacted_projects_on_user_id" btree (user_id) +Foreign-key constraints: + "fk_rails_0894651f08" FOREIGN KEY (user_id) REFERENCES users(id) ON DELETE CASCADE + "fk_rails_722ceba4f7" FOREIGN KEY (project_id) REFERENCES projects(id) ON DELETE CASCADE +``` + +Let's rewrite our query to JOIN this table onto our projects, and get the +projects for a specific user: + +```sql +EXPLAIN ANALYZE +SELECT COUNT(*) +FROM projects +INNER JOIN user_interacted_projects ON user_interacted_projects.project_id = projects.id +WHERE projects.visibility_level IN (0, 20) +AND user_interacted_projects.user_id = 1; +``` + +What we do here is the following: + +1. Get our projects. +1. INNER JOIN `user_interacted_projects`, meaning we're only left with rows in + `projects` that have a corresponding row in `user_interacted_projects`. +1. Limit this to the projects with `visibility_level` of 0 or 20, and to + projects that the user with ID 1 interacted with. + +If we run this query we get the following plan: + +``` + Aggregate (cost=871.03..871.04 rows=1 width=8) (actual time=9.763..9.763 rows=1 loops=1) + -> Nested Loop (cost=0.86..870.52 rows=203 width=0) (actual time=1.072..9.748 rows=143 loops=1) + -> Index Scan using index_user_interacted_projects_on_user_id on user_interacted_projects (cost=0.43..160.71 rows=205 width=4) (actual time=0.939..2.508 rows=145 loops=1) + Index Cond: (user_id = 1) + -> Index Scan using projects_pkey on projects (cost=0.43..3.45 rows=1 width=4) (actual time=0.049..0.050 rows=1 loops=145) + Index Cond: (id = user_interacted_projects.project_id) + Filter: (visibility_level = ANY ('{0,20}'::integer[])) + Rows Removed by Filter: 0 + Planning time: 2.614 ms + Execution time: 9.809 ms +``` + +Here it only took us just under 10 milliseconds to get the data. We can also see +we're retrieving far fewer projects: + +``` +Index Scan using projects_pkey on projects (cost=0.43..3.45 rows=1 width=4) (actual time=0.049..0.050 rows=1 loops=145) + Index Cond: (id = user_interacted_projects.project_id) + Filter: (visibility_level = ANY ('{0,20}'::integer[])) + Rows Removed by Filter: 0 +``` + +Here we see we perform 145 loops (`loops=145`), with every loop producing 1 row +(`rows=1`). This is much less than before, and our query performs much better! + +If we look at the plan we also see our costs are very low: + +``` +Index Scan using projects_pkey on projects (cost=0.43..3.45 rows=1 width=4) (actual time=0.049..0.050 rows=1 loops=145) +``` + +Here our cost is only 3.45, and it only takes us 0.050 milliseconds to do so. +The next index scan is a bit more expensive: + +``` +Index Scan using index_user_interacted_projects_on_user_id on user_interacted_projects (cost=0.43..160.71 rows=205 width=4) (actual time=0.939..2.508 rows=145 loops=1) +``` + +Here the cost is 160.71 (`cost=0.43..160.71`), taking about 2.5 milliseconds +(based on the output of `actual time=....`). + +The most expensive part here is the "Nested Loop" that acts upon the result of +these two index scans: + +``` +Nested Loop (cost=0.86..870.52 rows=203 width=0) (actual time=1.072..9.748 rows=143 loops=1) +``` + +Here we had to perform 870.52 disk page fetches for 203 rows, 9.748 +milliseconds, producing 143 rows in a single loop. + +The key takeaway here is that sometimes you have to rewrite (parts of) a query +to make it better. Sometimes that means having to slightly change your feature +to accommodate for better performance. + +## What makes a bad plan + +This is a bit of a difficult question to answer, because the definition of "bad" +is relative to the problem you are trying to solve. However, some patterns are +best avoided in most cases, such as: + +* Sequential scans on large tables +* Filters that remove a lot of rows +* Performing a certain step (e.g. an index scan) that requires _a lot_ of + buffers (e.g. more than 512 MB for GitLab.com). + +As a general guideline, aim for a query that: + +1. Takes no more than 10 milliseconds. Our target time spent in SQL per request + is around 100 milliseconds, so every query should be as fast as possible. +1. Does not use an excessive number of buffers, relative to the workload. For + example, retrieving ten rows shouldn't require 1 GB of buffers. +1. Does not spend a long amount of time performing disk IO operations. The + setting `track_io_timing` must be enabled for this data to be included in the + output of `EXPLAIN ANALYZE`. +1. Applies a `LIMIT` when retrieving rows without aggregating them, such as + `SELECT * FROM users`. +1. Doesn't use a `Filter` to filter out too many rows, especially if the query + does not use a `LIMIT` to limit the number of returned rows. Filters can + usually be removed by adding a (partial) index. + +These are _guidelines_ and not hard requirements, as different needs may require +different queries. The only _rule_ is that you _must always measure_ your query +(preferably using a production-like database) using `EXPLAIN (ANALYZE, BUFFERS)` +and related tools such as: + +* <https://explain.depesz.com/> +* <http://tatiyants.com/postgres-query-plan-visualization/> + +GitLab employees can also use our chatops solution, available in Slack using the +`/chatops` slash command. You can use chatops to get a query plan by running the +following: + +``` +/chatops run explain SELECT COUNT(*) FROM projects WHERE visibility_level IN (0, 20) +``` + +Visualising the plan using <https://explain.depesz.com/> is also supported: + +``` +/chatops run explain --visual SELECT COUNT(*) FROM projects WHERE visibility_level IN (0, 20) +``` + +Quoting the query is not necessary. + +For more information about the available options, run: + +``` +/chatops run explain --help +``` |