Elasticsearch DSL is a high-level library whose aim is to help with writing and running queries against Elasticsearch. It is built on top of the official low-level client (elasticsearch-py).
It provides a more convenient and idiomatic way to write and manipulate queries. It stays close to the Elasticsearch JSON DSL, mirroring its terminology and structure. It exposes the whole range of the DSL from Python either directly using defined classes or a queryset-like expressions.
It also provides an optional wrapper for working with documents as Python objects: defining mappings, retrieving and saving documents, wrapping the document data in user-defined classes.
To use the other Elasticsearch APIs (eg. cluster health) just use the underlying client.
pip install elasticsearch-dsl
The engineering team here at Elastic is looking for developers to participate in research and feedback sessions to learn more about how you use our Python client and what improvements we can make to their design and your workflow. If you're interested in sharing your insights into developer experience and language client design, please fill out this short form. Depending on the number of responses we get, we may either contact you for a 1:1 conversation or a focus group with other developers who use the same client. Thank you in advance - your feedback is crucial to improving the user experience for all Elasticsearch developers!
Please see the examples directory to see some complex examples using elasticsearch-dsl
.
The library is compatible with all Elasticsearch versions since 2.x
but you have to use a matching major version:
For Elasticsearch 8.0 and later, use the major version 8 (8.x.y
) of the library.
For Elasticsearch 7.0 and later, use the major version 7 (7.x.y
) of the library.
For Elasticsearch 6.0 and later, use the major version 6 (6.x.y
) of the library.
For Elasticsearch 5.0 and later, use the major version 5 (5.x.y
) of the library.
For Elasticsearch 2.0 and later, use the major version 2 (2.x.y
) of the library.
The recommended way to set your requirements in your setup.py or requirements.txt is:
# Elasticsearch 8.x
elasticsearch-dsl>=8.0.0,<9.0.0
# Elasticsearch 7.x
elasticsearch-dsl>=7.0.0,<8.0.0
# Elasticsearch 6.x
elasticsearch-dsl>=6.0.0,<7.0.0
# Elasticsearch 5.x
elasticsearch-dsl>=5.0.0,<6.0.0
# Elasticsearch 2.x
elasticsearch-dsl>=2.0.0,<3.0.0
The development is happening on main
, older branches only get bugfix releases
Let's have a typical search request written directly as a dict
:
from elasticsearch import Elasticsearch
client = Elasticsearch("https://localhost:9200")
response = client.search(
index="my-index",
body={
"query": {
"bool": {
"must": [{"match": {"title": "python"}}],
"must_not": [{"match": {"description": "beta"}}],
"filter": [{"term": {"category": "search"}}]
}
},
"aggs" : {
"per_tag": {
"terms": {"field": "tags"},
"aggs": {
"max_lines": {"max": {"field": "lines"}}
}
}
}
}
)
for hit in response['hits']['hits']:
print(hit['_score'], hit['_source']['title'])
for tag in response['aggregations']['per_tag']['buckets']:
print(tag['key'], tag['max_lines']['value'])
The problem with this approach is that it is very verbose, prone to syntax mistakes like incorrect nesting, hard to modify (eg. adding another filter) and definitely not fun to write.
Let's rewrite the example using the Python DSL:
from elasticsearch import Elasticsearch
from elasticsearch_dsl import Search
client = Elasticsearch("https://localhost:9200")
s = Search(using=client, index="my-index") \
.filter("term", category="search") \
.query("match", title="python") \
.exclude("match", description="beta")
s.aggs.bucket('per_tag', 'terms', field='tags') \
.metric('max_lines', 'max', field='lines')
response = s.execute()
for hit in response:
print(hit.meta.score, hit.title)
for tag in response.aggregations.per_tag.buckets:
print(tag.key, tag.max_lines.value)
As you see, the library took care of:
- creating appropriate
Query
objects by name (eq. "match") - composing queries into a compound
bool
query - putting the
term
query in a filter context of thebool
query - providing a convenient access to response data
- no curly or square brackets everywhere
Let's have a simple Python class representing an article in a blogging system:
from datetime import datetime
from elasticsearch_dsl import Document, Date, Integer, Keyword, Text, connections
# Define a default Elasticsearch client
connections.create_connection(hosts="https://localhost:9200")
class Article(Document):
title = Text(analyzer='snowball', fields={'raw': Keyword()})
body = Text(analyzer='snowball')
tags = Keyword()
published_from = Date()
lines = Integer()
class Index:
name = 'blog'
settings = {
"number_of_shards": 2,
}
def save(self, ** kwargs):
self.lines = len(self.body.split())
return super(Article, self).save(** kwargs)
def is_published(self):
return datetime.now() > self.published_from
# create the mappings in elasticsearch
Article.init()
# create and save and article
article = Article(meta={'id': 42}, title='Hello world!', tags=['test'])
article.body = ''' looong text '''
article.published_from = datetime.now()
article.save()
article = Article.get(id=42)
print(article.is_published())
# Display cluster health
print(connections.get_connection().cluster.health())
In this example you can see:
- providing a default connection
- defining fields with mapping configuration
- setting index name
- defining custom methods
- overriding the built-in
.save()
method to hook into the persistence life cycle - retrieving and saving the object into Elasticsearch
- accessing the underlying client for other APIs
You can see more in the persistence chapter of the documentation.
You don't have to port your entire application to get the benefits of the Python DSL, you can start gradually by creating a Search
object from your existing dict
, modifying it using the API and serializing it back to a dict
:
body = {...} # insert complicated query here
# Convert to Search object
s = Search.from_dict(body)
# Add some filters, aggregations, queries, ...
s.filter("term", tags="python")
# Convert back to dict to plug back into existing code
body = s.to_dict()
Activate Virtual Environment (virtualenvs):
$ virtualenv venv
$ source venv/bin/activate
To install all of the dependencies necessary for development, run:
$ pip install -e '.[develop]'
To run all of the tests for elasticsearch-dsl-py
, run:
$ python setup.py test
Alternatively, it is possible to use the run_tests.py
script in test_elasticsearch_dsl
, which wraps pytest, to run subsets of the test suite. Some examples can be seen below:
# Run all of the tests in `test_elasticsearch_dsl/test_analysis.py`
$ ./run_tests.py test_analysis.py
# Run only the `test_analyzer_serializes_as_name` test.
$ ./run_tests.py test_analysis.py::test_analyzer_serializes_as_name
pytest
will skip tests from test_elasticsearch_dsl/test_integration
unless there is an instance of Elasticsearch on which a connection can occur. By default, the test connection is attempted at localhost:9200
, based on the defaults specified in the elasticsearch-py
Connection <https://github.com/elastic/elasticsearch-py/blob/master/elasticsearch /connection/base.py#L29> class. Because running the integration tests will cause destructive changes to the Elasticsearch cluster, only run them when the associated cluster is empty. As such, if the Elasticsearch instance at localhost:9200
does not meet these requirements, it is possible to specify a different test Elasticsearch server through the TEST_ES_SERVER
environment variable.
$ TEST_ES_SERVER=my-test-server:9201 ./run_tests
Documentation is available at https://elasticsearch-dsl.readthedocs.io.
Want to hack on Elasticsearch DSL? Awesome! We have Contribution-Guide.
Copyright 2013 Elasticsearch
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