OpenSearch/docs/reference/query-dsl/percolate-query.asciidoc

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[[query-dsl-percolate-query]]
=== Percolate Query
The `percolate` query can be used to match queries
stored in an index. The `percolate` query itself
contains the document that will be used as query
to match with the stored queries.
[float]
=== Sample Usage
Create an index with two fields:
[source,js]
--------------------------------------------------
PUT /my-index
{
"mappings": {
"doc": {
"properties": {
"message": {
"type": "text"
},
"query": {
"type": "percolator"
}
}
}
}
}
--------------------------------------------------
// CONSOLE
The `message` field is the field used to preprocess the document defined in
the `percolator` query before it gets indexed into a temporary index.
The `query` field is used for indexing the query documents. It will hold a
json object that represents an actual Elasticsearch query. The `query` field
has been configured to use the <<percolator,percolator field type>>. This field
type understands the query dsl and stored the query in such a way that it can be
used later on to match documents defined on the `percolate` query.
Register a query in the percolator:
[source,js]
--------------------------------------------------
PUT /my-index/doc/1?refresh
{
"query" : {
"match" : {
"message" : "bonsai tree"
}
}
}
--------------------------------------------------
// CONSOLE
// TEST[continued]
Match a document to the registered percolator queries:
[source,js]
--------------------------------------------------
GET /my-index/_search
{
"query" : {
"percolate" : {
"field" : "query",
"document" : {
"message" : "A new bonsai tree in the office"
}
}
}
}
--------------------------------------------------
// CONSOLE
// TEST[continued]
The above request will yield the following response:
[source,js]
--------------------------------------------------
{
"took": 13,
"timed_out": false,
"_shards": {
"total": 5,
"successful": 5,
Add a shard filter search phase to pre-filter shards based on query rewriting (#25658) Today if we search across a large amount of shards we hit every shard. Yet, it's quite common to search across an index pattern for time based indices but filtering will exclude all results outside a certain time range ie. `now-3d`. While the search can potentially hit hundreds of shards the majority of the shards might yield 0 results since there is not document that is within this date range. Kibana for instance does this regularly but used `_field_stats` to optimize the indexes they need to query. Now with the deprecation of `_field_stats` and it's upcoming removal a single dashboard in kibana can potentially turn into searches hitting hundreds or thousands of shards and that can easily cause search rejections even though the most of the requests are very likely super cheap and only need a query rewriting to early terminate with 0 results. This change adds a pre-filter phase for searches that can, if the number of shards are higher than a the `pre_filter_shard_size` threshold (defaults to 128 shards), fan out to the shards and check if the query can potentially match any documents at all. While false positives are possible, a negative response means that no matches are possible. These requests are not subject to rejection and can greatly reduce the number of shards a request needs to hit. The approach here is preferable to the kibana approach with field stats since it correctly handles aliases and uses the correct threadpools to execute these requests. Further it's completely transparent to the user and improves scalability of elasticsearch in general on large clusters.
2017-07-12 16:19:20 -04:00
"skipped" : 0,
"failed": 0
},
"hits": {
"total": 1,
"max_score": 0.5753642,
"hits": [
{ <1>
"_index": "my-index",
"_type": "doc",
"_id": "1",
"_score": 0.5753642,
"_source": {
"query": {
"match": {
"message": "bonsai tree"
}
}
}
}
]
}
}
--------------------------------------------------
// TESTRESPONSE[s/"took": 13,/"took": "$body.took",/]
<1> The query with id `1` matches our document.
[float]
==== Parameters
The following parameters are required when percolating a document:
[horizontal]
`field`:: The field of type `percolator` that holds the indexed queries. This is a required parameter.
`document`:: The source of the document being percolated.
`document_type`:: The type / mapping of the document being percolated. This setting is deprecated and only required for indices created before 6.0
Instead of specifying the source of the document being percolated, the source can also be retrieved from an already
stored document. The `percolate` query will then internally execute a get request to fetch that document.
In that case the `document` parameter can be substituted with the following parameters:
[horizontal]
`index`:: The index the document resides in. This is a required parameter.
`type`:: The type of the document to fetch. This is a required parameter.
`id`:: The id of the document to fetch. This is a required parameter.
`routing`:: Optionally, routing to be used to fetch document to percolate.
`preference`:: Optionally, preference to be used to fetch document to percolate.
`version`:: Optionally, the expected version of the document to be fetched.
[float]
==== Percolating an Existing Document
In order to percolate a newly indexed document, the `percolate` query can be used. Based on the response
from an index request, the `_id` and other meta information can be used to immediately percolate the newly added
document.
[float]
===== Example
Based on the previous example.
Index the document we want to percolate:
[source,js]
--------------------------------------------------
PUT /my-index/doc/2
{
"message" : "A new bonsai tree in the office"
}
--------------------------------------------------
// CONSOLE
// TEST[continued]
Index response:
[source,js]
--------------------------------------------------
{
"_index": "my-index",
"_type": "doc",
"_id": "2",
"_version": 1,
"_shards": {
"total": 2,
"successful": 1,
"failed": 0
},
"result": "created",
"_seq_no" : 0,
"_primary_term" : 1
}
--------------------------------------------------
// TESTRESPONSE
Percolating an existing document, using the index response as basis to build to new search request:
[source,js]
--------------------------------------------------
GET /my-index/_search
{
"query" : {
"percolate" : {
"field": "query",
"index" : "my-index",
"type" : "doc",
"id" : "2",
"version" : 1 <1>
}
}
}
--------------------------------------------------
// CONSOLE
// TEST[continued]
<1> The version is optional, but useful in certain cases. We can ensure that we are trying to percolate
the document we just have indexed. A change may be made after we have indexed, and if that is the
case the then the search request would fail with a version conflict error.
The search response returned is identical as in the previous example.
[float]
==== Percolate query and highlighting
The `percolate` query is handled in a special way when it comes to highlighting. The queries hits are used
to highlight the document that is provided in the `percolate` query. Whereas with regular highlighting the query in
the search request is used to highlight the hits.
[float]
===== Example
This example is based on the mapping of the first example.
Save a query:
[source,js]
--------------------------------------------------
PUT /my-index/doc/3?refresh
{
"query" : {
"match" : {
"message" : "brown fox"
}
}
}
--------------------------------------------------
// CONSOLE
// TEST[continued]
Save another query:
[source,js]
--------------------------------------------------
PUT /my-index/doc/4?refresh
{
"query" : {
"match" : {
"message" : "lazy dog"
}
}
}
--------------------------------------------------
// CONSOLE
// TEST[continued]
Execute a search request with the `percolate` query and highlighting enabled:
[source,js]
--------------------------------------------------
GET /my-index/_search
{
"query" : {
"percolate" : {
"field": "query",
"document" : {
"message" : "The quick brown fox jumps over the lazy dog"
}
}
},
"highlight": {
"fields": {
"message": {}
}
}
}
--------------------------------------------------
// CONSOLE
// TEST[continued]
This will yield the following response.
[source,js]
--------------------------------------------------
{
"took": 7,
"timed_out": false,
"_shards": {
"total": 5,
"successful": 5,
Add a shard filter search phase to pre-filter shards based on query rewriting (#25658) Today if we search across a large amount of shards we hit every shard. Yet, it's quite common to search across an index pattern for time based indices but filtering will exclude all results outside a certain time range ie. `now-3d`. While the search can potentially hit hundreds of shards the majority of the shards might yield 0 results since there is not document that is within this date range. Kibana for instance does this regularly but used `_field_stats` to optimize the indexes they need to query. Now with the deprecation of `_field_stats` and it's upcoming removal a single dashboard in kibana can potentially turn into searches hitting hundreds or thousands of shards and that can easily cause search rejections even though the most of the requests are very likely super cheap and only need a query rewriting to early terminate with 0 results. This change adds a pre-filter phase for searches that can, if the number of shards are higher than a the `pre_filter_shard_size` threshold (defaults to 128 shards), fan out to the shards and check if the query can potentially match any documents at all. While false positives are possible, a negative response means that no matches are possible. These requests are not subject to rejection and can greatly reduce the number of shards a request needs to hit. The approach here is preferable to the kibana approach with field stats since it correctly handles aliases and uses the correct threadpools to execute these requests. Further it's completely transparent to the user and improves scalability of elasticsearch in general on large clusters.
2017-07-12 16:19:20 -04:00
"skipped" : 0,
"failed": 0
},
"hits": {
"total": 2,
"max_score": 0.5753642,
"hits": [
{
"_index": "my-index",
"_type": "doc",
"_id": "4",
"_score": 0.5753642,
"_source": {
"query": {
"match": {
"message": "lazy dog"
}
}
},
"highlight": {
"message": [
2016-04-19 08:11:23 -04:00
"The quick brown fox jumps over the <em>lazy</em> <em>dog</em>" <1>
]
}
},
{
"_index": "my-index",
"_type": "doc",
"_id": "3",
"_score": 0.5753642,
"_source": {
"query": {
"match": {
"message": "brown fox"
}
}
},
"highlight": {
"message": [
2016-04-19 08:11:23 -04:00
"The quick <em>brown</em> <em>fox</em> jumps over the lazy dog" <1>
]
}
}
]
}
}
--------------------------------------------------
// TESTRESPONSE[s/"took": 7,/"took": "$body.took",/]
<1> The terms from each query have been highlighted in the document.
Instead of the query in the search request highlighting the percolator hits, the percolator queries are highlighting
the document defined in the `percolate` query.
[float]
==== How it Works Under the Hood
When indexing a document into an index that has the <<percolator,percolator field type>> mapping configured, the query
part of the document gets parsed into a Lucene query and is stored into the Lucene index. A binary representation
of the query gets stored, but also the query's terms are analyzed and stored into an indexed field.
At search time, the document specified in the request gets parsed into a Lucene document and is stored in a in-memory
temporary Lucene index. This in-memory index can just hold this one document and it is optimized for that. After this
a special query is built based on the terms in the in-memory index that select candidate percolator queries based on
their indexed query terms. These queries are then evaluated by the in-memory index if they actually match.
The selecting of candidate percolator queries matches is an important performance optimization during the execution
2016-05-22 16:50:31 -04:00
of the `percolate` query as it can significantly reduce the number of candidate matches the in-memory index needs to
evaluate. The reason the `percolate` query can do this is because during indexing of the percolator queries the query
terms are being extracted and indexed with the percolator query. Unfortunately the percolator cannot extract terms from
all queries (for example the `wildcard` or `geo_shape` query) and as a result of that in certain cases the percolator
can't do the selecting optimization (for example if an unsupported query is defined in a required clause of a boolean query
or the unsupported query is the only query in the percolator document). These queries are marked by the percolator and
can be found by running the following search:
[source,js]
---------------------------------------------------
GET /_search
{
"query": {
"term" : {
"query.extraction_result" : "failed"
}
}
}
---------------------------------------------------
// CONSOLE
NOTE: The above example assumes that there is a `query` field of type
`percolator` in the mappings.