The database functions in the django.contrib.postgres.search module ease
the use of PostgreSQL’s full text search engine.
For the examples in this document, we’ll use the models defined in Making queries.
See also
For a high-level overview of searching, see the topic documentation.
search lookup¶A common way to use full text search is to search a single term against a single column in the database. For example:
>>> Entry.objects.filter(body_text__search="Cheese")
[<Entry: Cheese on Toast recipes>, <Entry: Pizza Recipes>]
This creates a to_tsvector in the database from the body_text field
and a plainto_tsquery from the search term 'Cheese', both using the
default database search configuration. The results are obtained by matching the
query and the vector.
To use the search lookup, 'django.contrib.postgres' must be in your
INSTALLED_APPS.
SearchVector¶Searching against a single field is great but rather limiting. The Entry
instances we’re searching belong to a Blog, which has a tagline field.
To query against both fields, use a SearchVector:
>>> from django.contrib.postgres.search import SearchVector
>>> Entry.objects.annotate(
... search=SearchVector("body_text", "blog__tagline"),
... ).filter(search="Cheese")
[<Entry: Cheese on Toast recipes>, <Entry: Pizza Recipes>]
The arguments to SearchVector can be any
Expression or the name of a field. Multiple
arguments will be concatenated together using a space so that the search
document includes them all.
SearchVector objects can be combined together, allowing you to reuse them.
For example:
>>> Entry.objects.annotate(
... search=SearchVector("body_text") + SearchVector("blog__tagline"),
... ).filter(search="Cheese")
[<Entry: Cheese on Toast recipes>, <Entry: Pizza Recipes>]
See Changing the search configuration and
Weighting queries for an explanation of the config
and weight parameters.
SearchQuery¶SearchQuery translates the terms the user provides into a search query
object that the database compares to a search vector. By default, all the words
the user provides are passed through the stemming algorithms, and then it
looks for matches for all of the resulting terms.
If search_type is 'plain', which is the default, the terms are treated
as separate keywords. If search_type is 'phrase', the terms are treated
as a single phrase. If search_type is 'raw', then you can provide a
formatted search query with terms and operators. If search_type is
'websearch', then you can provide a formatted search query, similar to the
one used by web search engines. 'websearch' requires PostgreSQL ≥ 11. Read
PostgreSQL’s Full Text Search docs to learn about differences and syntax.
Examples:
>>> from django.contrib.postgres.search import SearchQuery
>>> SearchQuery("red tomato") # two keywords
>>> SearchQuery("tomato red") # same results as above
>>> SearchQuery("red tomato", search_type="phrase") # a phrase
>>> SearchQuery("tomato red", search_type="phrase") # a different phrase
>>> SearchQuery("'tomato' & ('red' | 'green')", search_type="raw") # boolean operators
>>> SearchQuery(
... "'tomato' ('red' OR 'green')", search_type="websearch"
... ) # websearch operators
SearchQuery terms can be combined logically to provide more flexibility:
>>> from django.contrib.postgres.search import SearchQuery
>>> SearchQuery("meat") & SearchQuery("cheese") # AND
>>> SearchQuery("meat") | SearchQuery("cheese") # OR
>>> ~SearchQuery("meat") # NOT
See Changing the search configuration for an explanation of the
config parameter.
SearchRank¶So far, we’ve returned the results for which any match between the vector and the query are possible. It’s likely you may wish to order the results by some sort of relevancy. PostgreSQL provides a ranking function which takes into account how often the query terms appear in the document, how close together the terms are in the document, and how important the part of the document is where they occur. The better the match, the higher the value of the rank. To order by relevancy:
>>> from django.contrib.postgres.search import SearchQuery, SearchRank, SearchVector
>>> vector = SearchVector("body_text")
>>> query = SearchQuery("cheese")
>>> Entry.objects.annotate(rank=SearchRank(vector, query)).order_by("-rank")
[<Entry: Cheese on Toast recipes>, <Entry: Pizza recipes>]
See Weighting queries for an explanation of the
weights parameter.
Set the cover_density parameter to True to enable the cover density
ranking, which means that the proximity of matching query terms is taken into
account.
Provide an integer to the normalization parameter to control rank
normalization. This integer is a bit mask, so you can combine multiple
behaviors:
>>> from django.db.models import Value
>>> Entry.objects.annotate(
... rank=SearchRank(
... vector,
... query,
... normalization=Value(2).bitor(Value(4)),
... )
... )
The PostgreSQL documentation has more details about different rank normalization options.
SearchHeadline¶Accepts a single text field or an expression, a query, a config, and a set of options. Returns highlighted search results.
Set the start_sel and stop_sel parameters to the string values to be
used to wrap highlighted query terms in the document. PostgreSQL’s defaults are
<b> and </b>.
Provide integer values to the max_words and min_words parameters to
determine the longest and shortest headlines. PostgreSQL’s defaults are 35 and
15.
Provide an integer value to the short_word parameter to discard words of
this length or less in each headline. PostgreSQL’s default is 3.
Set the highlight_all parameter to True to use the whole document in
place of a fragment and ignore max_words, min_words, and short_word
parameters. That’s disabled by default in PostgreSQL.
Provide a non-zero integer value to the max_fragments to set the maximum
number of fragments to display. That’s disabled by default in PostgreSQL.
Set the fragment_delimiter string parameter to configure the delimiter
between fragments. PostgreSQL’s default is " ... ".
The PostgreSQL documentation has more details on highlighting search results.
Usage example:
>>> from django.contrib.postgres.search import SearchHeadline, SearchQuery
>>> query = SearchQuery("red tomato")
>>> entry = Entry.objects.annotate(
... headline=SearchHeadline(
... "body_text",
... query,
... start_sel="<span>",
... stop_sel="</span>",
... ),
... ).get()
>>> print(entry.headline)
Sandwich with <span>tomato</span> and <span>red</span> cheese.
See Changing the search configuration for an explanation of the
config parameter.
You can specify the config attribute to a SearchVector and
SearchQuery to use a different search configuration. This allows using
different language parsers and dictionaries as defined by the database:
>>> from django.contrib.postgres.search import SearchQuery, SearchVector
>>> Entry.objects.annotate(
... search=SearchVector("body_text", config="french"),
... ).filter(search=SearchQuery("œuf", config="french"))
[<Entry: Pain perdu>]
The value of config could also be stored in another column:
>>> from django.db.models import F
>>> Entry.objects.annotate(
... search=SearchVector("body_text", config=F("blog__language")),
... ).filter(search=SearchQuery("œuf", config=F("blog__language")))
[<Entry: Pain perdu>]
Every field may not have the same relevance in a query, so you can set weights of various vectors before you combine them:
>>> from django.contrib.postgres.search import SearchQuery, SearchRank, SearchVector
>>> vector = SearchVector("body_text", weight="A") + SearchVector(
... "blog__tagline", weight="B"
... )
>>> query = SearchQuery("cheese")
>>> Entry.objects.annotate(rank=SearchRank(vector, query)).filter(rank__gte=0.3).order_by(
... "rank"
... )
The weight should be one of the following letters: D, C, B, A. By default,
these weights refer to the numbers 0.1, 0.2, 0.4, and 1.0,
respectively. If you wish to weight them differently, pass a list of four
floats to SearchRank as weights in the same order above:
>>> rank = SearchRank(vector, query, weights=[0.2, 0.4, 0.6, 0.8])
>>> Entry.objects.annotate(rank=rank).filter(rank__gte=0.3).order_by("-rank")
Special database configuration isn’t necessary to use any of these functions, however, if you’re searching more than a few hundred records, you’re likely to run into performance problems. Full text search is a more intensive process than comparing the size of an integer, for example.
In the event that all the fields you’re querying on are contained within one
particular model, you can create a functional
GIN or
GiST index which matches
the search vector you wish to use. For example:
GinIndex(
SearchVector("body_text", "headline", config="english"),
name="search_vector_idx",
)
The PostgreSQL documentation has details on creating indexes for full text search.
SearchVectorField¶If this approach becomes too slow, you can add a SearchVectorField to your
model. You’ll need to keep it populated with triggers, for example, as
described in the PostgreSQL documentation. You can then query the field as
if it were an annotated SearchVector:
>>> Entry.objects.update(search_vector=SearchVector("body_text"))
>>> Entry.objects.filter(search_vector="cheese")
[<Entry: Cheese on Toast recipes>, <Entry: Pizza recipes>]
Another approach to searching is trigram similarity. A trigram is a group of
three consecutive characters. In addition to the trigram_similar,
trigram_word_similar, and trigram_strict_word_similar
lookups, you can use a couple of other expressions.
To use them, you need to activate the pg_trgm extension on PostgreSQL. You can
install it using the
TrigramExtension migration
operation.
TrigramSimilarity¶Accepts a field name or expression, and a string or expression. Returns the trigram similarity between the two arguments.
Usage example:
>>> from django.contrib.postgres.search import TrigramSimilarity
>>> Author.objects.create(name="Katy Stevens")
>>> Author.objects.create(name="Stephen Keats")
>>> test = "Katie Stephens"
>>> Author.objects.annotate(
... similarity=TrigramSimilarity("name", test),
... ).filter(
... similarity__gt=0.3
... ).order_by("-similarity")
[<Author: Katy Stevens>, <Author: Stephen Keats>]
TrigramWordSimilarity¶Accepts a string or expression, and a field name or expression. Returns the trigram word similarity between the two arguments.
Usage example:
>>> from django.contrib.postgres.search import TrigramWordSimilarity
>>> Author.objects.create(name="Katy Stevens")
>>> Author.objects.create(name="Stephen Keats")
>>> test = "Kat"
>>> Author.objects.annotate(
... similarity=TrigramWordSimilarity(test, "name"),
... ).filter(
... similarity__gt=0.3
... ).order_by("-similarity")
[<Author: Katy Stevens>]
TrigramStrictWordSimilarity¶Accepts a string or expression, and a field name or expression. Returns the
trigram strict word similarity between the two arguments. Similar to
TrigramWordSimilarity(), except that it forces
extent boundaries to match word boundaries.
TrigramDistance¶Accepts a field name or expression, and a string or expression. Returns the trigram distance between the two arguments.
Usage example:
>>> from django.contrib.postgres.search import TrigramDistance
>>> Author.objects.create(name="Katy Stevens")
>>> Author.objects.create(name="Stephen Keats")
>>> test = "Katie Stephens"
>>> Author.objects.annotate(
... distance=TrigramDistance("name", test),
... ).filter(
... distance__lte=0.7
... ).order_by("distance")
[<Author: Katy Stevens>, <Author: Stephen Keats>]
TrigramWordDistance¶Accepts a string or expression, and a field name or expression. Returns the trigram word distance between the two arguments.
Usage example:
>>> from django.contrib.postgres.search import TrigramWordDistance
>>> Author.objects.create(name="Katy Stevens")
>>> Author.objects.create(name="Stephen Keats")
>>> test = "Kat"
>>> Author.objects.annotate(
... distance=TrigramWordDistance(test, "name"),
... ).filter(
... distance__lte=0.7
... ).order_by("distance")
[<Author: Katy Stevens>]
TrigramStrictWordDistance¶Accepts a string or expression, and a field name or expression. Returns the trigram strict word distance between the two arguments.
Dec 25, 2023