mirror of https://github.com/apache/druid.git
837 lines
27 KiB
Markdown
837 lines
27 KiB
Markdown
---
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id: sql-translation
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title: "SQL query translation"
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sidebar_label: "SQL query translation"
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---
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<!--
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~ Licensed to the Apache Software Foundation (ASF) under one
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~ or more contributor license agreements. See the NOTICE file
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~ regarding copyright ownership. The ASF licenses this file
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~ with the License. You may obtain a copy of the License at
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~ http://www.apache.org/licenses/LICENSE-2.0
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~ Unless required by applicable law or agreed to in writing,
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~ software distributed under the License is distributed on an
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~ "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
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~ KIND, either express or implied. See the License for the
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~ specific language governing permissions and limitations
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~ under the License.
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> Apache Druid supports two query languages: Druid SQL and [native queries](querying.md).
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> This document describes the Druid SQL language.
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Druid uses [Apache Calcite](https://calcite.apache.org/) to parse and plan SQL queries.
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Druid translates SQL statements into its [native JSON-based query language](querying.md).
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In general, the slight overhead of translating SQL on the Broker is the only minor performance penalty to using Druid SQL compared to native queries.
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This topic includes best practices and tools to help you achieve good performance and minimize the impact of translation.
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## Best practices
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Consider the following non-exhaustive list of best practices when looking into performance implications of
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translating Druid SQL queries to native queries.
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1. If you wrote a filter on the primary time column `__time`, make sure it is being correctly translated to an
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`"intervals"` filter, as described in the [Time filters](#time-filters) section below. If not, you may need to change
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the way you write the filter.
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2. Try to avoid subqueries underneath joins: they affect both performance and scalability. This includes implicit
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subqueries generated by conditions on mismatched types, and implicit subqueries generated by conditions that use
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expressions to refer to the right-hand side.
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3. Currently, Druid does not support pushing down predicates (condition and filter) past a Join (i.e. into
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Join's children). Druid only supports pushing predicates into the join if they originated from
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above the join. Hence, the location of predicates and filters in your Druid SQL is very important.
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Also, as a result of this, comma joins should be avoided.
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4. Read through the [Query execution](query-execution.md) page to understand how various types of native queries
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will be executed.
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5. Be careful when interpreting EXPLAIN PLAN output, and use request logging if in doubt. Request logs will show the
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exact native query that was run. See the [next section](#interpreting-explain-plan-output) for more details.
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6. If you encounter a query that could be planned better, feel free to
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[raise an issue on GitHub](https://github.com/apache/druid/issues/new/choose). A reproducible test case is always
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appreciated.
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## Interpreting EXPLAIN PLAN output
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The [EXPLAIN PLAN](sql.md#explain-plan) functionality can help you understand how a given SQL query will
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be translated to native.
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EXPLAIN PLAN statements return:
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- a `PLAN` column that contains a JSON array of native queries that Druid will run
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- a `RESOURCES` column that describes the resources used in the query
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- an `ATTRIBUTES` column that describes the attributes of the query, including:
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- `statementType`: the SQL statement type
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- `targetDataSource`: the target datasource in an INSERT or REPLACE statement
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- `partitionedBy`: the time-based partitioning granularity in an INSERT or REPLACE statement
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- `clusteredBy`: the clustering columns in an INSERT or REPLACE statement
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- `replaceTimeChunks`: the time chunks in a REPLACE statement
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Example 1: EXPLAIN PLAN for a `SELECT` query on the `wikipedia` datasource:
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<details><summary>Show the query</summary>
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```sql
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EXPLAIN PLAN FOR
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SELECT
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channel,
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COUNT(*)
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FROM wikipedia
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WHERE channel IN (SELECT page FROM wikipedia GROUP BY page ORDER BY COUNT(*) DESC LIMIT 10)
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GROUP BY channel
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```
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</details>
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The above EXPLAIN PLAN query returns the following result:
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<details><summary>Show the result</summary>
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```json
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[
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[
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{
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"query": {
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"queryType": "topN",
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"dataSource": {
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"type": "join",
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"left": {
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"type": "table",
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"name": "wikipedia"
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},
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"right": {
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"type": "query",
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"query": {
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"queryType": "groupBy",
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"dataSource": {
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"type": "table",
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"name": "wikipedia"
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},
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"intervals": {
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"type": "intervals",
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"intervals": [
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"-146136543-09-08T08:23:32.096Z/146140482-04-24T15:36:27.903Z"
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]
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},
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"granularity": {
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"type": "all"
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},
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"dimensions": [
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{
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"type": "default",
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"dimension": "page",
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"outputName": "d0",
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"outputType": "STRING"
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}
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],
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"aggregations": [
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{
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"type": "count",
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"name": "a0"
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}
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],
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"limitSpec": {
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"type": "default",
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"columns": [
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{
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"dimension": "a0",
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"direction": "descending",
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"dimensionOrder": {
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"type": "numeric"
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}
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}
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],
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"limit": 10
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},
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"context": {
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"sqlOuterLimit": 101,
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"sqlQueryId": "ee616a36-c30c-4eae-af00-245127956e42",
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"useApproximateCountDistinct": false,
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"useApproximateTopN": false
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}
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}
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},
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"rightPrefix": "j0.",
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"condition": "(\"channel\" == \"j0.d0\")",
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"joinType": "INNER"
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},
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"dimension": {
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"type": "default",
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"dimension": "channel",
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"outputName": "d0",
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"outputType": "STRING"
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},
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"metric": {
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"type": "dimension",
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"ordering": {
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"type": "lexicographic"
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}
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},
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"threshold": 101,
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"intervals": {
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"type": "intervals",
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"intervals": [
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"-146136543-09-08T08:23:32.096Z/146140482-04-24T15:36:27.903Z"
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]
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},
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"granularity": {
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"type": "all"
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},
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"aggregations": [
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{
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"type": "count",
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"name": "a0"
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}
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],
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"context": {
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"sqlOuterLimit": 101,
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"sqlQueryId": "ee616a36-c30c-4eae-af00-245127956e42",
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"useApproximateCountDistinct": false,
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"useApproximateTopN": false
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}
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},
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"signature": [
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{
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"name": "d0",
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"type": "STRING"
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},
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{
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"name": "a0",
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"type": "LONG"
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}
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],
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"columnMappings": [
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{
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"queryColumn": "d0",
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"outputColumn": "channel"
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},
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{
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"queryColumn": "a0",
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"outputColumn": "EXPR$1"
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}
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]
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}
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],
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[
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{
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"name": "wikipedia",
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"type": "DATASOURCE"
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}
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],
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{
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"statementType": "SELECT"
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}
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]
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```
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</details>
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Example 2: EXPLAIN PLAN for an `INSERT` query that inserts data into the `wikipedia` datasource:
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<details><summary>Show the query</summary>
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```sql
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EXPLAIN PLAN FOR
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INSERT INTO wikipedia2
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SELECT
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TIME_PARSE("timestamp") AS __time,
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namespace,
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cityName,
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countryName,
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regionIsoCode,
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metroCode,
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countryIsoCode,
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regionName
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FROM TABLE(
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EXTERN(
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'{"type":"http","uris":["https://druid.apache.org/data/wikipedia.json.gz"]}',
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'{"type":"json"}',
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'[{"name":"timestamp","type":"string"},{"name":"namespace","type":"string"},{"name":"cityName","type":"string"},{"name":"countryName","type":"string"},{"name":"regionIsoCode","type":"string"},{"name":"metroCode","type":"long"},{"name":"countryIsoCode","type":"string"},{"name":"regionName","type":"string"}]'
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)
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)
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PARTITIONED BY ALL
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```
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</details>
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The above EXPLAIN PLAN returns the following result:
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<details><summary>Show the result</summary>
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```json
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[
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[
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{
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"query": {
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"queryType": "scan",
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"dataSource": {
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"type": "external",
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"inputSource": {
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"type": "http",
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"uris": [
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"https://druid.apache.org/data/wikipedia.json.gz"
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]
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},
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"inputFormat": {
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"type": "json",
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"keepNullColumns": false,
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"assumeNewlineDelimited": false,
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"useJsonNodeReader": false
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},
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"signature": [
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{
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"name": "timestamp",
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"type": "STRING"
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},
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{
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"name": "namespace",
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"type": "STRING"
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},
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{
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"name": "cityName",
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"type": "STRING"
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},
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{
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"name": "countryName",
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"type": "STRING"
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},
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{
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"name": "regionIsoCode",
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"type": "STRING"
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},
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{
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"name": "metroCode",
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"type": "LONG"
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},
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{
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"name": "countryIsoCode",
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"type": "STRING"
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},
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{
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"name": "regionName",
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"type": "STRING"
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}
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]
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},
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"intervals": {
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"type": "intervals",
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"intervals": [
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"-146136543-09-08T08:23:32.096Z/146140482-04-24T15:36:27.903Z"
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]
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},
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"virtualColumns": [
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{
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"type": "expression",
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"name": "v0",
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"expression": "timestamp_parse(\"timestamp\",null,'UTC')",
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"outputType": "LONG"
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}
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],
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"resultFormat": "compactedList",
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"columns": [
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"cityName",
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"countryIsoCode",
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"countryName",
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"metroCode",
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"namespace",
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"regionIsoCode",
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"regionName",
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"v0"
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],
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"legacy": false,
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"context": {
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"finalizeAggregations": false,
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"forceExpressionVirtualColumns": true,
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"groupByEnableMultiValueUnnesting": false,
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"maxNumTasks": 5,
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"multiStageQuery": true,
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"queryId": "42e3de2b-daaf-40f9-a0e7-2c6184529ea3",
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"scanSignature": "[{\"name\":\"cityName\",\"type\":\"STRING\"},{\"name\":\"countryIsoCode\",\"type\":\"STRING\"},{\"name\":\"countryName\",\"type\":\"STRING\"},{\"name\":\"metroCode\",\"type\":\"LONG\"},{\"name\":\"namespace\",\"type\":\"STRING\"},{\"name\":\"regionIsoCode\",\"type\":\"STRING\"},{\"name\":\"regionName\",\"type\":\"STRING\"},{\"name\":\"v0\",\"type\":\"LONG\"}]",
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"sqlInsertSegmentGranularity": "{\"type\":\"all\"}",
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"sqlQueryId": "42e3de2b-daaf-40f9-a0e7-2c6184529ea3",
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"useNativeQueryExplain": true
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},
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"granularity": {
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"type": "all"
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}
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},
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"signature": [
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{
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"name": "v0",
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"type": "LONG"
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},
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{
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"name": "namespace",
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"type": "STRING"
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},
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{
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"name": "cityName",
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"type": "STRING"
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},
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{
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"name": "countryName",
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"type": "STRING"
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},
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{
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"name": "regionIsoCode",
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"type": "STRING"
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},
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{
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"name": "metroCode",
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"type": "LONG"
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},
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{
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"name": "countryIsoCode",
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"type": "STRING"
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},
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{
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"name": "regionName",
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"type": "STRING"
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}
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],
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"columnMappings": [
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{
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"queryColumn": "v0",
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"outputColumn": "__time"
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},
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{
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"queryColumn": "namespace",
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"outputColumn": "namespace"
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},
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{
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"queryColumn": "cityName",
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"outputColumn": "cityName"
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},
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{
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"queryColumn": "countryName",
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"outputColumn": "countryName"
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},
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{
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"queryColumn": "regionIsoCode",
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"outputColumn": "regionIsoCode"
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},
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{
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"queryColumn": "metroCode",
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"outputColumn": "metroCode"
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},
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{
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"queryColumn": "countryIsoCode",
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"outputColumn": "countryIsoCode"
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},
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{
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"queryColumn": "regionName",
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"outputColumn": "regionName"
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}
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]
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}
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],
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[
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{
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"name": "EXTERNAL",
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"type": "EXTERNAL"
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},
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{
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"name": "wikipedia",
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"type": "DATASOURCE"
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}
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],
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{
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"statementType": "INSERT",
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"targetDataSource": "wikipedia",
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"partitionedBy": {
|
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"type": "all"
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}
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}
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]
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```
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</details>
|
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|
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Example 3: EXPLAIN PLAN for a `REPLACE` query that replaces all the data in the `wikipedia` datasource with a `DAY`
|
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time partitioning, and `cityName` and `countryName` as the clustering columns:
|
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|
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<details><summary>Show the query</summary>
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|
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```sql
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EXPLAIN PLAN FOR
|
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REPLACE INTO wikipedia
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OVERWRITE ALL
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SELECT
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TIME_PARSE("timestamp") AS __time,
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namespace,
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cityName,
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countryName,
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regionIsoCode,
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metroCode,
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countryIsoCode,
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regionName
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FROM TABLE(
|
|
EXTERN(
|
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'{"type":"http","uris":["https://druid.apache.org/data/wikipedia.json.gz"]}',
|
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'{"type":"json"}',
|
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'[{"name":"timestamp","type":"string"},{"name":"namespace","type":"string"},{"name":"cityName","type":"string"},{"name":"countryName","type":"string"},{"name":"regionIsoCode","type":"string"},{"name":"metroCode","type":"long"},{"name":"countryIsoCode","type":"string"},{"name":"regionName","type":"string"}]'
|
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)
|
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)
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PARTITIONED BY DAY
|
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CLUSTERED BY cityName, countryName
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```
|
|
</details>
|
|
|
|
|
|
The above EXPLAIN PLAN query returns the following result:
|
|
|
|
<details><summary>Show the result</summary>
|
|
|
|
```json
|
|
[
|
|
[
|
|
{
|
|
"query": {
|
|
"queryType": "scan",
|
|
"dataSource": {
|
|
"type": "external",
|
|
"inputSource": {
|
|
"type": "http",
|
|
"uris": [
|
|
"https://druid.apache.org/data/wikipedia.json.gz"
|
|
]
|
|
},
|
|
"inputFormat": {
|
|
"type": "json",
|
|
"keepNullColumns": false,
|
|
"assumeNewlineDelimited": false,
|
|
"useJsonNodeReader": false
|
|
},
|
|
"signature": [
|
|
{
|
|
"name": "timestamp",
|
|
"type": "STRING"
|
|
},
|
|
{
|
|
"name": "namespace",
|
|
"type": "STRING"
|
|
},
|
|
{
|
|
"name": "cityName",
|
|
"type": "STRING"
|
|
},
|
|
{
|
|
"name": "countryName",
|
|
"type": "STRING"
|
|
},
|
|
{
|
|
"name": "regionIsoCode",
|
|
"type": "STRING"
|
|
},
|
|
{
|
|
"name": "metroCode",
|
|
"type": "LONG"
|
|
},
|
|
{
|
|
"name": "countryIsoCode",
|
|
"type": "STRING"
|
|
},
|
|
{
|
|
"name": "regionName",
|
|
"type": "STRING"
|
|
}
|
|
]
|
|
},
|
|
"intervals": {
|
|
"type": "intervals",
|
|
"intervals": [
|
|
"-146136543-09-08T08:23:32.096Z/146140482-04-24T15:36:27.903Z"
|
|
]
|
|
},
|
|
"virtualColumns": [
|
|
{
|
|
"type": "expression",
|
|
"name": "v0",
|
|
"expression": "timestamp_parse(\"timestamp\",null,'UTC')",
|
|
"outputType": "LONG"
|
|
}
|
|
],
|
|
"resultFormat": "compactedList",
|
|
"columns": [
|
|
"cityName",
|
|
"countryIsoCode",
|
|
"countryName",
|
|
"metroCode",
|
|
"namespace",
|
|
"regionIsoCode",
|
|
"regionName",
|
|
"v0"
|
|
],
|
|
"legacy": false,
|
|
"context": {
|
|
"finalizeAggregations": false,
|
|
"groupByEnableMultiValueUnnesting": false,
|
|
"maxNumTasks": 5,
|
|
"queryId": "d88e0823-76d4-40d9-a1a7-695c8577b79f",
|
|
"scanSignature": "[{\"name\":\"cityName\",\"type\":\"STRING\"},{\"name\":\"countryIsoCode\",\"type\":\"STRING\"},{\"name\":\"countryName\",\"type\":\"STRING\"},{\"name\":\"metroCode\",\"type\":\"LONG\"},{\"name\":\"namespace\",\"type\":\"STRING\"},{\"name\":\"regionIsoCode\",\"type\":\"STRING\"},{\"name\":\"regionName\",\"type\":\"STRING\"},{\"name\":\"v0\",\"type\":\"LONG\"}]",
|
|
"sqlInsertSegmentGranularity": "\"DAY\"",
|
|
"sqlQueryId": "d88e0823-76d4-40d9-a1a7-695c8577b79f",
|
|
"sqlReplaceTimeChunks": "all"
|
|
},
|
|
"granularity": {
|
|
"type": "all"
|
|
}
|
|
},
|
|
"signature": [
|
|
{
|
|
"name": "v0",
|
|
"type": "LONG"
|
|
},
|
|
{
|
|
"name": "namespace",
|
|
"type": "STRING"
|
|
},
|
|
{
|
|
"name": "cityName",
|
|
"type": "STRING"
|
|
},
|
|
{
|
|
"name": "countryName",
|
|
"type": "STRING"
|
|
},
|
|
{
|
|
"name": "regionIsoCode",
|
|
"type": "STRING"
|
|
},
|
|
{
|
|
"name": "metroCode",
|
|
"type": "LONG"
|
|
},
|
|
{
|
|
"name": "countryIsoCode",
|
|
"type": "STRING"
|
|
},
|
|
{
|
|
"name": "regionName",
|
|
"type": "STRING"
|
|
}
|
|
],
|
|
"columnMappings": [
|
|
{
|
|
"queryColumn": "v0",
|
|
"outputColumn": "__time"
|
|
},
|
|
{
|
|
"queryColumn": "namespace",
|
|
"outputColumn": "namespace"
|
|
},
|
|
{
|
|
"queryColumn": "cityName",
|
|
"outputColumn": "cityName"
|
|
},
|
|
{
|
|
"queryColumn": "countryName",
|
|
"outputColumn": "countryName"
|
|
},
|
|
{
|
|
"queryColumn": "regionIsoCode",
|
|
"outputColumn": "regionIsoCode"
|
|
},
|
|
{
|
|
"queryColumn": "metroCode",
|
|
"outputColumn": "metroCode"
|
|
},
|
|
{
|
|
"queryColumn": "countryIsoCode",
|
|
"outputColumn": "countryIsoCode"
|
|
},
|
|
{
|
|
"queryColumn": "regionName",
|
|
"outputColumn": "regionName"
|
|
}
|
|
]
|
|
}
|
|
],
|
|
[
|
|
{
|
|
"name": "EXTERNAL",
|
|
"type": "EXTERNAL"
|
|
},
|
|
{
|
|
"name": "wikipedia",
|
|
"type": "DATASOURCE"
|
|
}
|
|
],
|
|
{
|
|
"statementType": "REPLACE",
|
|
"targetDataSource": "wikipedia",
|
|
"partitionedBy": "DAY",
|
|
"clusteredBy": ["cityName","countryName"],
|
|
"replaceTimeChunks": "all"
|
|
}
|
|
]
|
|
```
|
|
|
|
</details>
|
|
|
|
|
|
In this case the JOIN operator gets translated to a `join` datasource. See the [Join translation](#joins) section
|
|
for more details about how this works.
|
|
|
|
We can see this for ourselves using Druid's [request logging](../configuration/index.md#request-logging) feature. After
|
|
enabling logging and running this query, we can see that it actually runs as the following native query.
|
|
|
|
```json
|
|
{
|
|
"queryType": "groupBy",
|
|
"dataSource": {
|
|
"type": "join",
|
|
"left": "wikipedia",
|
|
"right": {
|
|
"type": "query",
|
|
"query": {
|
|
"queryType": "topN",
|
|
"dataSource": "wikipedia",
|
|
"dimension": {"type": "default", "dimension": "page", "outputName": "d0"},
|
|
"metric": {"type": "numeric", "metric": "a0"},
|
|
"threshold": 10,
|
|
"intervals": "-146136543-09-08T08:23:32.096Z/146140482-04-24T15:36:27.903Z",
|
|
"granularity": "all",
|
|
"aggregations": [
|
|
{ "type": "count", "name": "a0"}
|
|
]
|
|
}
|
|
},
|
|
"rightPrefix": "j0.",
|
|
"condition": "(\"page\" == \"j0.d0\")",
|
|
"joinType": "INNER"
|
|
},
|
|
"intervals": "-146136543-09-08T08:23:32.096Z/146140482-04-24T15:36:27.903Z",
|
|
"granularity": "all",
|
|
"dimensions": [
|
|
{"type": "default", "dimension": "channel", "outputName": "d0"}
|
|
],
|
|
"aggregations": [
|
|
{ "type": "count", "name": "a0"}
|
|
]
|
|
}
|
|
```
|
|
|
|
## Query types
|
|
|
|
Druid SQL uses four different native query types.
|
|
|
|
- [Scan](scan-query.md) is used for queries that do not aggregate—no GROUP BY, no DISTINCT.
|
|
|
|
- [Timeseries](timeseriesquery.md) is used for queries that GROUP BY `FLOOR(__time TO unit)` or `TIME_FLOOR(__time, period)`, have no other grouping expressions, no HAVING clause, no nesting, and either no ORDER BY, or an
|
|
ORDER BY that orders by same expression as present in GROUP BY. It also uses Timeseries for "grand total" queries that
|
|
have aggregation functions but no GROUP BY. This query type takes advantage of the fact that Druid segments are sorted
|
|
by time.
|
|
|
|
- [TopN](topnquery.md) is used by default for queries that group by a single expression, do have ORDER BY and LIMIT
|
|
clauses, do not have HAVING clauses, and are not nested. However, the TopN query type will deliver approximate ranking
|
|
and results in some cases; if you want to avoid this, set "useApproximateTopN" to "false". TopN results are always
|
|
computed in memory. See the TopN documentation for more details.
|
|
|
|
- [GroupBy](groupbyquery.md) is used for all other aggregations, including any nested aggregation queries. Druid's
|
|
GroupBy is a traditional aggregation engine: it delivers exact results and rankings and supports a wide variety of
|
|
features. GroupBy aggregates in memory if it can, but it may spill to disk if it doesn't have enough memory to complete
|
|
your query. Results are streamed back from data processes through the Broker if you ORDER BY the same expressions in your
|
|
GROUP BY clause, or if you don't have an ORDER BY at all. If your query has an ORDER BY referencing expressions that
|
|
don't appear in the GROUP BY clause (like aggregation functions) then the Broker will materialize a list of results in
|
|
memory, up to a max of your LIMIT, if any. See the GroupBy documentation for details about tuning performance and memory
|
|
use.
|
|
|
|
## Time filters
|
|
|
|
For all native query types, filters on the `__time` column will be translated into top-level query "intervals" whenever
|
|
possible, which allows Druid to use its global time index to quickly prune the set of data that must be scanned.
|
|
Consider this (non-exhaustive) list of time filters that will be recognized and translated to "intervals":
|
|
|
|
- `__time >= TIMESTAMP '2000-01-01 00:00:00'` (comparison to absolute time)
|
|
- `__time >= CURRENT_TIMESTAMP - INTERVAL '8' HOUR` (comparison to relative time)
|
|
- `FLOOR(__time TO DAY) = TIMESTAMP '2000-01-01 00:00:00'` (specific day)
|
|
|
|
Refer to the [Interpreting EXPLAIN PLAN output](#interpreting-explain-plan-output) section for details on confirming
|
|
that time filters are being translated as you expect.
|
|
|
|
## Joins
|
|
|
|
SQL join operators are translated to native join datasources as follows:
|
|
|
|
1. Joins that the native layer can handle directly are translated literally, to a [join datasource](datasource.md#join)
|
|
whose `left`, `right`, and `condition` are faithful translations of the original SQL. This includes any SQL join where
|
|
the right-hand side is a lookup or subquery, and where the condition is an equality where one side is an expression based
|
|
on the left-hand table, the other side is a simple column reference to the right-hand table, and both sides of the
|
|
equality are the same data type.
|
|
|
|
2. If a join cannot be handled directly by a native [join datasource](datasource.md#join) as written, Druid SQL
|
|
will insert subqueries to make it runnable. For example, `foo INNER JOIN bar ON foo.abc = LOWER(bar.def)` cannot be
|
|
directly translated, because there is an expression on the right-hand side instead of a simple column access. A subquery
|
|
will be inserted that effectively transforms this clause to
|
|
`foo INNER JOIN (SELECT LOWER(def) AS def FROM bar) t ON foo.abc = t.def`.
|
|
|
|
3. Druid SQL does not currently reorder joins to optimize queries.
|
|
|
|
Refer to the [Interpreting EXPLAIN PLAN output](#interpreting-explain-plan-output) section for details on confirming
|
|
that joins are being translated as you expect.
|
|
|
|
Refer to the [Query execution](query-execution.md#join) page for information about how joins are executed.
|
|
|
|
## Subqueries
|
|
|
|
Subqueries in SQL are generally translated to native query datasources. Refer to the
|
|
[Query execution](query-execution.md#query) page for information about how subqueries are executed.
|
|
|
|
> Note: Subqueries in the WHERE clause, like `WHERE col1 IN (SELECT foo FROM ...)` are translated to inner joins.
|
|
|
|
## Approximations
|
|
|
|
Druid SQL will use approximate algorithms in some situations:
|
|
|
|
- The `COUNT(DISTINCT col)` aggregation functions by default uses a variant of
|
|
[HyperLogLog](http://algo.inria.fr/flajolet/Publications/FlFuGaMe07.pdf), a fast approximate distinct counting
|
|
algorithm. Druid SQL will switch to exact distinct counts if you set "useApproximateCountDistinct" to "false", either
|
|
through query context or through Broker configuration.
|
|
|
|
- GROUP BY queries over a single column with ORDER BY and LIMIT may be executed using the TopN engine, which uses an
|
|
approximate algorithm. Druid SQL will switch to an exact grouping algorithm if you set "useApproximateTopN" to "false",
|
|
either through query context or through Broker configuration.
|
|
|
|
- Aggregation functions that are labeled as using sketches or approximations, such as APPROX_COUNT_DISTINCT, are always
|
|
approximate, regardless of configuration.
|
|
|
|
**A known issue with approximate functions based on data sketches**
|
|
|
|
The `APPROX_QUANTILE_DS` and `DS_QUANTILES_SKETCH` functions can fail with an `IllegalStateException` if one of the sketches for
|
|
the query hits `maxStreamLength`: the maximum number of items to store in each sketch.
|
|
See [GitHub issue 11544](https://github.com/apache/druid/issues/11544) for more details.
|
|
To workaround the issue, increase value of the maximum string length with the `approxQuantileDsMaxStreamLength` parameter
|
|
in the query context. Since it is set to 1,000,000,000 by default, you don't need to override it in most cases.
|
|
See [accuracy information](https://datasketches.apache.org/docs/Quantiles/OrigQuantilesSketch) in the DataSketches documentation for how many bytes are required per stream length.
|
|
This query context parameter is a temporary solution to avoid the known issue. It may be removed in a future release after the bug is fixed.
|
|
|
|
## Unsupported features
|
|
|
|
Druid does not support all SQL features. In particular, the following features are not supported.
|
|
|
|
- JOIN between native datasources (table, lookup, subquery) and [system tables](sql-metadata-tables.md).
|
|
- JOIN conditions that are not an equality between expressions from the left- and right-hand sides.
|
|
- JOIN conditions containing a constant value inside the condition.
|
|
- JOIN conditions on a column which contains a multi-value dimension.
|
|
- OVER clauses, and analytic functions such as `LAG` and `LEAD`.
|
|
- ORDER BY for a non-aggregating query, except for `ORDER BY __time` or `ORDER BY __time DESC`, which are supported.
|
|
This restriction only applies to non-aggregating queries; you can ORDER BY any column in an aggregating query.
|
|
- DDL and DML.
|
|
- Using Druid-specific functions like `TIME_PARSE` and `APPROX_QUANTILE_DS` on [system tables](sql-metadata-tables.md).
|
|
|
|
Additionally, some Druid native query features are not supported by the SQL language. Some unsupported Druid features
|
|
include:
|
|
|
|
- [Inline datasources](datasource.md#inline).
|
|
- [Spatial filters](geo.md).
|
|
- [Multi-value dimensions](sql-data-types.md#multi-value-strings) are only partially implemented in Druid SQL. There are known
|
|
inconsistencies between their behavior in SQL queries and in native queries due to how they are currently treated by
|
|
the SQL planner.
|
|
|
|
|