Muokkaa

Jaa


Best practices for Kusto Query Language queries

Applies to: ✅ Microsoft FabricAzure Data ExplorerAzure MonitorMicrosoft Sentinel

Here are several best practices to follow to make your query run faster.

In short

Action Use Don't use Notes
Reduce the amount of data being queried Use mechanisms such as the where operator to reduce the amount of data being processed. For more information on efficient ways to reduce the amount of data being processed, see Reduce the amount of data being processed.
Avoid using redundant qualified references When referencing local entities, use the unqualified name. For more information, see Avoid using redundant qualified references.
datetime columns Use the datetime data type. Don't use the long data type. In queries, don't use Unix time conversion functions, such as unixtime_milliseconds_todatetime(). Instead, use update policies to convert Unix time to the datetime data type during ingestion.
String operators Use the has operator. Don't use contains When looking for full tokens, has works better, since it doesn't look for substrings.
Case-sensitive operators Use ==. Don't use =~. Use case-sensitive operators when possible.
Use in. Don't use in~.
Use contains_cs. Don't use contains. Using has/has_cs is preferred to contains/contains_cs.
Searching text Look in a specific column. Don't use *. * does a full text search across all columns.
Extract fields from dynamic objects across millions of rows Materialize your column at ingestion time if most of your queries extract fields from dynamic objects across millions of rows. With this method you only pay once for column extraction.
Lookup for rare keys/values in dynamic objects Use MyTable | where DynamicColumn has "Rare value" | where DynamicColumn.SomeKey == "Rare value". Don't use MyTable | where DynamicColumn.SomeKey == "Rare value". With this method you filter out most records and only do JSON parsing on the remainder.
let statement with a value that you use more than once Use the materialize() function. For more information on how to use materialize(), see materialize(). For more information, see Optimize queries that use named expressions.
Apply type conversions on more than one billion records Reshape your query to reduce the amount of data fed into the conversion. Don't convert large amounts of data if it can be avoided.
New queries Use limit [small number] or count at the end. Running unbound queries over unknown datasets can yield a return of gigabytes of results, resulting in a slow response and a busy environment.
Case-insensitive comparisons Use Col =~ "lowercasestring". Don't use tolower(Col) == "lowercasestring".
Compare data already in lowercase (or uppercase) Col == "lowercasestring" (or Col == "UPPERCASESTRING"). Avoid using case insensitive comparisons.
Filtering on columns Filter on a table column. Don't filter on a calculated column.
Use T | where predicate(*Expression*) Don't use T | extend _value = *Expression* | where predicate(_value)
summarize operator Use the hint.shufflekey=<key> when the group by keys of the summarize operator have high cardinality. High cardinality is ideally more than one million.
join operator Select the table with the fewest rows as the first one (left-most in query).
Use in instead of left semi join for filtering by a single column.
Join across clusters Run the query on the "right" side of the join across remote environments, such as clusters or Eventhouses, where most of the data is located.
Join when left side is small and right side is large Use hint.strategy=broadcast. Small refers to up to 100 megabytes (MB) of data.
Join when right side is small and left side is large Use the lookup operator instead of the join operator If the right side of the lookup is larger than several tens of MB, the query fails.
Join when both sides are too large Use hint.shufflekey=<key>. Use when the join key has high cardinality.
Extract values on column with strings sharing the same format or pattern Use the parse operator. Don't use several extract() statements. For example, values like "Time = <time>, ResourceId = <resourceId>, Duration = <duration>, ....".
extract() function Use when parsed strings don't all follow the same format or pattern. Extract the required values by using a REGEX.
materialize() function Push all possible operators that reduce the materialized dataset and still keep the semantics of the query. For example, filters, or project only required columns. For more information, see Optimize queries that use named expressions.
Use materialized views Use materialized views for storing commonly used aggregations. Prefer using the materialized_view() function to query materialized part only. materialized_view('MV')

Reduce the amount of data being processed

A query's performance depends directly on the amount of data it needs to process. The less data is processed, the quicker the query (and the fewer resources it consumes). Therefore, the most important best-practice is to structure the query in such a way that reduces the amount of data being processed.

Note

In the following discussion, it is important to have in mind the concept of filter selectivity. Selectivity is what percentage of the records get filtered-out when filtering by some predicate. A highly-selective predicate means that only a handful of records remain after applying the predicate, reducing the amount of data that needs to then be processed effectively.

In order of importance:

  • Only reference tables whose data is needed by the query. For example, when using the union operator with wildcard table references, it's better from a performance point-of-view to only reference a handful of tables, instead of using a wildcard (*) to reference all tables and then filter data out using a predicate on the source table name.

  • Take advantage of a table's data scope if the query is relevant only for a specific scope. The table() function provides an efficient way to eliminate data by scoping it according to the caching policy (the DataScope parameter).

  • Apply the where query operator immediately following table references.

  • When using the where query operator, the order in which you place the predicates, whether you use a single where operator, or multiple consecutive where operators, can have a significant effect on the query performance.

  • Apply whole-shard predicates first. This means that predicates that use the extent_id() function and extent_tags() function should be applied first. Also, when you have selective predicates that narrow the data down to specific partitions, they should be applied first.

  • Then apply predicates that act upon datetime table columns. Kusto includes an efficient index on such columns, often completely eliminating whole data shards without needing to access those shards.

  • Then apply predicates that act upon string and dynamic columns, especially such predicates that apply at the term-level. Order the predicates by the selectivity. For example, searching for a user ID when there are millions of users is highly selective and usually involves a term search, for which the index is very efficient.

  • Then apply predicates that are selective and are based on numeric columns.

  • Last, for queries that scan a table column's data (for example, for predicates such as contains "@!@!", that have no terms and don't benefit from indexing), order the predicates such that the ones that scan columns with less data are first. Doing so reduces the need to decompress and scan large columns.

Avoid using redundant qualified references

Reference entities such as tables and materialized views by name.

For example, the table T can be referenced as simply T (the unqualified name), or by using a database qualifier (for example, database("DB").T when the table is in a database called DB), or by using a fully qualified name (for example, cluster("<serviceURL>").database("DB").T).

For example, the table T can be referenced as simply T (the unqualified name), or by using a database qualifier (for example, database("DB").T when the table is in a database called DB), or by using a fully qualified name (for example, cluster("X.Y.kusto.windows.net").database("DB").T).

It's a best practice to avoid using name qualifications when they're redundant, for the following reasons:

  1. Unqualified names are easier to identify (for a human reader) as belonging to the database-in-scope.

  2. Referencing database-in-scope entities is always at least as fast, and in some cases much faster, then entities that belong to other databases.

This is especially true when those databases are in a different cluster.

This is especially true when those databases are in a different Eventhouse.

Avoiding qualified names helps the reader to do the right thing.

Note

This doesn't mean that qualified names are bad for performance. In fact, Kusto is able in most cases to identify when a fully qualified name references an entity that belongs to the database-in-scope and "short-circuit" the query so that it's not regarded as a cross-cluster query. However, we don't recommend relying on this when not necessary.

Note

This doesn't mean that qualified names are bad for performance. In fact, Kusto is able in most cases to identify when a fully qualified name references an entity belonging to the database-in-scope. However, we don't recommend relying on this when not necessary.