This plugin extends Elasticsearch with new search actions and a filter query parser that enables to perform a "Filter Join" between two set of documents (in the same index or in different indexes).
The Filter Join is basically a (left) semi-join between two set of documents based on a common attribute, where
the result only contains the attributes of one of the joined set of documents. This join is
used to filter one document set based on a second document set, hence its name. It is equivalent
to the EXISTS()
operator in SQL.
The following table shows the compatibility between releases of Elasticsearch and the SIREn Join plugin:
Elasticsearch | SIREn Join |
---|---|
2.3.5 | 2.3.5 |
2.3.4 | 2.3.4 |
2.3.3 | 2.3.3-1 |
2.2.0 | 2.2.0-1 |
2.1.2 | 2.1.2 |
2.1.1 | 2.1.1 |
1.7.x | 1.0 |
You can use the following command to download the plugin from the online repository:
$ bin/plugin install solutions.siren/siren-join/2.3.5
-
Get the ZIPball from maven.org
-
Install with the downloaded file
$ bin/plugin install file:/path/to/folder/with/siren-join-2.3.5.zip
Alternatively, you can assemble it via Maven (you must build it as a non-root user):
$ git clone [email protected]:sirensolutions/siren-join.git
$ cd siren-join
$ mvn package
This creates a single Zip file that can be installed using the Elasticsearch plugin command:
$ bin/plugin install file:/PATH-TO-SIRENJOIN-PROJECT/target/releases/siren-join-2.3.5.zip
You can now start Elasticsearch and see that our plugin gets loaded:
$ bin/elasticsearch
...
[2013-09-04 17:33:27,443][INFO ][node ] [Andrew Chord] initializing ...
[2013-09-04 17:33:27,455][INFO ][plugins ] [Andrew Chord] loaded [siren-join], sites []
...
To uninstall the plugin:
$ bin/plugin remove siren-join
This plugin introduces two new search actions, _coordinate_search
that replaces the _search
action,
and _coordinate_msearch
that replaces the _msearch
action. Both actions are wrappers around the original
elasticsearch actions and therefore supports the same API. One must use these actions with the filterjoin
filter,
as the filterjoin
filter is not supported by the original elaticsearch actions.
filterjoin
: the filter nameindices
: the index names to lookup the terms from (optional, default to all indices).types
: the index types to lookup the terms from (optional, default to all types).path
: the path within the document to lookup the terms from.query
: the query used to lookup terms with.orderBy
: the ordering to use to lookup the maximum number of terms: default, doc_score (optional, default to default ordering).maxTermsPerShard
: the maximum number of terms per shard to lookup (optional, default to all terms).termsEncoding
: the encoding to use when transferring terms across the network: long, integer, bloom, bytes (optional, default to long).
In this example, we will join all the documents from index1
with the documents of index2
.
The query first filters documents from index2
and of type type
with the query
{ "terms" : { "tag" : [ "aaa" ] } }
. It then retrieves the ids of the documents from the field id
specified by the parameter path
. The list of ids is then used as filter and applied on the field
foreign_key
of the documents from index1
.
{
"bool" : {
"filter" : {
"filterjoin" : {
"foreign_key" : {
"indices" : ["index2"],
"types" : ["type"],
"path" : "id",
"query" : {
"terms" : {
"tag" : [ "aaa" ]
}
}
}
}
}
}
}
The response returned by the coordinate search API is identical to the response
returned by Elasticsearch's search API, but augmented with additional information
about the execution of the relational query planning. This additional information
is stored within the field named coordinate_search
at the root of the response,
see example below. The object contains the following parameters:
actions
: a list of actions that has been executed - an action represents the execution of one single join.relations
: the definition of the relations of the join - it contains two nested objects,from
andto
, one for each relation.size
: the size of the filter used to compute the join, i.e., the number of terms across all shards used by the filterjoin.size_in_bytes
: the size in bytes of the filter used to compute the join.is_pruned
: a flag to indicate if the join computation has been pruned based on themaxTermsPerShard
limit.cache_hit
: a flag to indicate if the join was already computed and cached.terms_encoding
: the terms encoding used to transfer terms across the network.took
: the time it took to construct the filter.
{
"coordinate_search": {
"actions": [
{
"relations": {
"from": {
"indices": ["index2"],
"types": ["type"],
"field": "id"
},
"to": {
"indices": null,
"types": null,
"field": "foreign_key"
}
},
"size": 2,
"size_in_bytes": 20,
"is_pruned": false,
"cache_hit": false,
"terms_encoding" : "long",
"took": 313
}
]
},
...
}
- We recommend to activate caching for all queries via the setting
index.queries.cache.everything: true
. The new caching policy of Elasticsearch will not cache afilterjoin
query on small segments which can lead to a significant drop of performance. See issue 16529 for more information. - Joining numeric attributes is more efficient than joining string attributes.
- The bloom filter is the most efficient and the default encoding method for terms. It can encode 40M unique values in ~30MB. However, this trades precision for space, i.e., the bloom filter can lead to false-positive results. If precision is critical, then it is recommended to switch to the terms encoding to long.
- If the joined attributes of your documents contain incremental integers, switch the terms encoding to integer.
- The
filterjoin
includes a circuit breaker to prevent OOME when joining a field with a large number of unique values. As a rule of thumb, the maximum amount of unique values transferred across the shards should be around 50 to 100M when using bloom encoding, 5 to 10M when using long or integer encoding. It is recommended to configure amaxTermsPerShard
limit if the attribute defined by thepath
parameter contains a larger number of values. - The
bytes
terms encoding will likely provide better performance for highly selective queries over large indices, as it will perform the filtering based on a dictionary lookup instead of a doc value scan.
Part of this plugin is inspired and based on the pull request 3278 submitted by Matt Weber to the Elasticsearch project.
Copyright (c) 2016, SIREn Solutions. All Rights Reserved.