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239 lines
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ReStructuredText
239 lines
7.7 KiB
ReStructuredText
.. meta::
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:description: Performance of Hasura GraphQL queries
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:keywords: hasura, docs, schema, queries, performance
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.. _query_performance:
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Query performance
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=================
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.. contents:: Table of contents
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:backlinks: none
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:depth: 2
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:local:
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Introduction
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------------
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Sometimes queries can become slow due to large data volumes or levels of nesting.
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This page explains how to identify the query performance, how the query plan caching in Hasura works, and how queries can be optimized.
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.. _analysing_query_performance:
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Analysing query performance
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---------------------------
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Let's say we want to analyse the following query:
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.. code-block:: graphql
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query {
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authors(where: {name: {_eq: "Mario"}}) {
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rating
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}
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}
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In order to analyse the performance of a query, you can click on the ``Analyze`` button on the Hasura console:
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.. thumbnail:: ../../../img/graphql/manual/queries/analyze-query.png
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:class: no-shadow
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:width: 75%
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:alt: Query analyze button on Hasura console
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The following query execution plan is generated:
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.. thumbnail:: ../../../img/graphql/manual/queries/query-analysis-before-index.png
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:class: no-shadow
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:width: 75%
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:alt: Execution plan for Hasura GraphQL query
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We can see that a sequential scan is conducted on the ``authors`` table. This means that Postgres goes through every row of the ``authors`` table in order to check if the author's name equals "Mario".
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The ``cost`` of a query is an arbitrary number generated by Postgres and is to be interpreted as a measure of comparison rather than an absolute measure of something.
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Read more about query performance analysis in the `Postgres explain statement docs <https://www.postgresql.org/docs/current/sql-explain.html>`__.
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.. _query_plan_caching:
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Query plan caching
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------------------
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How it works
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^^^^^^^^^^^^
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Hasura executes GraphQL queries as follows:
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1. The incoming GraphQL query is parsed into an `abstract syntax tree <https://en.wikipedia.org/wiki/Abstract_syntax_tree>`__ (AST) which is how GraphQL is represented.
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2. The GraphQL AST is validated against the schema to generate an internal representation.
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3. The internal representation is converted into an SQL statement (a `prepared statement <https://www.postgresql.org/docs/current/sql-prepare.html>`__ whenever possible).
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4. The (prepared) statement is executed on Postgres to retrieve the result of the query.
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For most use cases, Hasura constructs a "plan" for a query, so that a new instance of the same query can be executed without the overhead of steps 1 to 3.
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For example, let's consider the following query:
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.. code-block:: graphql
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query getAuthor($id: Int!) {
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authors(where: {id: {_eq: $id}}) {
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name
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rating
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}
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}
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With the following variable:
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.. code-block:: graphql
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{
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"id": 1
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}
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Hasura now tries to map a GraphQL query to a prepared statement where the parameters have a one-to-one correspondence to the variables defined in the GraphQL query.
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The first time a query comes in, Hasura generates a plan for the query which consists of two things:
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1. The prepared statement
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2. Information necessary to convert variables into the prepared statement's arguments
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For the above query, Hasura generates the following prepared statement (simplified):
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.. code-block:: plpgsql
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select name, rating from author where id = $1
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With the following prepared variables:
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.. code-block:: plpgsql
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$1 = 1
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This plan is then saved in a data structure called ``Query Plan Cache``. The next time the same query is executed,
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Hasura uses the plan to convert the provided variables into the prepared statement's arguments and then executes the statement.
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This will significantly cut down the execution time for a GraphQL query resulting in lower latencies and higher throughput.
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Caveats
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^^^^^^^
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The above optimization is not possible for all types of queries. For example, consider this query:
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.. code-block:: graphql
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query getAuthorWithCondition($condition: author_bool_exp!) {
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author(where: $condition)
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name
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rating
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}
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}
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The statement generated for ``getAuthorWithCondition`` is now dependent on the variables.
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With the following variables:
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.. code-block:: json
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{
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"condition": {"id": {"_eq": 1}}
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}
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the generated statement will be:
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.. code-block:: plpgsql
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select name, rating from author where id = $1
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However, with the following variables:
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.. code-block:: json
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{
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"condition": {"name": {"_eq": "John"}}
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}
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the generated statement will be:
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.. code-block:: plpgsql
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select name, rating from author where name = 'John'
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A plan cannot be generated for such queries because the variables defined in the GraphQL query don't have a one-to-one correspondence to the parameters in the prepared statement.
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Query optimization
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------------------
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Using GraphQL variables
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^^^^^^^^^^^^^^^^^^^^^^^
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In order to leverage Hasura's query plan caching (as explained in the :ref:`previous section <query_plan_caching>`) to the full extent, GraphQL queries should be defined with
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variables whose types are **non-nullable scalars** whenever possible.
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To make variables non-nullable, add a ``!`` at the end of the type, like here:
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.. code-block:: graphql
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:emphasize-lines: 1
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query getAuthor($id: Int!) {
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authors(where: {id: {_eq: $id}}) {
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name
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rating
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}
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}
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If the ``!`` is not added and the variable is nullable, the generated query will be different depending if an ``id`` is passed or if the variables is ``null``
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(for the latter, there is no ``where`` statement present). Therefore, it's not possible for Hasura to create a reusable plan for a query in this case.
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.. note::
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Hasura is fast even for queries which cannot have a reusable plan.
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This should concern you only if you face a high volume of traffic (thousands of requests per second).
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Using PG indexes
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^^^^^^^^^^^^^^^^
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`Postgres indexes <https://www.tutorialspoint.com/postgresql/postgresql_indexes.htm>`__ are special lookup tables that Postgres can use to speed up data lookup.
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An index acts as a pointer to data in a table, and it works very similar to an index in the back of a book.
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If you look in the index first, you'll find the data much quicker than searching the whole book (or - in this case - database).
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Let's say we know that ``authors`` table is frequently queried by ``name``:
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.. code-block:: graphql
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query {
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authors(where: {name: {_eq: "Mario"}}) {
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rating
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}
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}
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We've seen in the :ref:`above example <analysing_query_performance>` that by default Postgres conducts a sequential scan i.e. going through all the rows.
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Whenever there is a sequential scan, it can be optimized by adding an index.
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.. rst-class:: api_tabs
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.. tabs::
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.. tab:: Console
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An index can be added in the ``SQL -> Data`` tab in the Hasura console:
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.. tab:: API
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An index can be added via the :ref:`run_sql <run_sql>` metadata API.
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The following statement sets an index on ``name`` in the ``authors`` table.
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.. code-block:: plpgsql
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CREATE INDEX ON authors (name);
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Let's compare the performance analysis to :ref:`the one before adding the index <analysing_query_performance>`.
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What was a ``sequential scan`` in the example earlier is now an ``index scan``. ``Index scans`` are usually more performant than ``sequential scans``.
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We can also see that the ``cost`` of the query is now lower than the one before we added the index.
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.. thumbnail:: ../../../img/graphql/manual/queries/query-analysis-after-index.png
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:class: no-shadow
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:width: 75%
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:alt: Execution plan for Hasura GraphQL query
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.. note::
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In some cases sequential scans can still be faster than index scans, e.g. if the result returns a high percentage of the rows in the table.
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Postgres comes up with multiple query plans and takes the call on what kind of scan would be faster.
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