Tutorials
editTutorials
editSearch
editLet’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 DSL module:
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
Queryobjects by name (eq. "match") -
composing queries into a compound
boolquery -
putting the
termquery in a filter context of theboolquery - providing a convenient access to response data
- no curly or square brackets everywhere
Persistence
editLet’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.
Pre-built Faceted Search
editIf you have your `Document`s defined you can very easily create a faceted search class to simplify searching and filtering.
This feature is experimental and may be subject to change.
from elasticsearch.dsl import FacetedSearch, TermsFacet, DateHistogramFacet class BlogSearch(FacetedSearch): doc_types = [Article, ] # fields that should be searched fields = ['tags', 'title', 'body'] facets = { # use bucket aggregations to define facets 'tags': TermsFacet(field='tags'), 'publishing_frequency': DateHistogramFacet(field='published_from', interval='month') } # empty search bs = BlogSearch() response = bs.execute() for hit in response: print(hit.meta.score, hit.title) for (tag, count, selected) in response.facets.tags: print(tag, ' (SELECTED):' if selected else ':', count) for (month, count, selected) in response.facets.publishing_frequency: print(month.strftime('%B %Y'), ' (SELECTED):' if selected else ':', count)
You can find more details in the faceted_search chapter.
Update By Query
editLet’s resume the simple example of articles on a blog, and let’s assume
that each article has a number of likes. For this example, imagine we
want to increment the number of likes by 1 for all articles that match a
certain tag and do not match a certain description. Writing this as a
dict, we would have the following code:
from elasticsearch import Elasticsearch client = Elasticsearch() response = client.update_by_query( index="my-index", body={ "query": { "bool": { "must": [{"match": {"tag": "python"}}], "must_not": [{"match": {"description": "beta"}}] } }, "script"={ "source": "ctx._source.likes++", "lang": "painless" } }, )
Using the DSL, we can now express this query as such:
from elasticsearch import Elasticsearch from elasticsearch.dsl import Search, UpdateByQuery client = Elasticsearch() ubq = UpdateByQuery(using=client, index="my-index") \ .query("match", title="python") \ .exclude("match", description="beta") \ .script(source="ctx._source.likes++", lang="painless") response = ubq.execute()
As you can see, the Update By Query object provides many of the
savings offered by the Search object, and additionally allows one to
update the results of the search based on a script assigned in the same
manner.
Migration from the standard client
editYou don’t have to port your entire application to get the benefits of
the DSL module, 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()
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