Once you’ve created your data models, Django automatically gives you a database-abstraction API that lets you create, retrieve, update and delete objects. This document explains how to use this API. Refer to the data model reference for full details of all the various model lookup options.
Throughout this guide (and in the reference), we’ll refer to the following models, which comprise a Weblog application:
from django.db import models
class Blog(models.Model):
name = models.CharField(max_length=100)
tagline = models.TextField()
def __str__(self):
return self.name
class Author(models.Model):
name = models.CharField(max_length=200)
email = models.EmailField()
def __str__(self):
return self.name
class Entry(models.Model):
blog = models.ForeignKey(Blog, on_delete=models.CASCADE)
headline = models.CharField(max_length=255)
body_text = models.TextField()
pub_date = models.DateField()
mod_date = models.DateField()
authors = models.ManyToManyField(Author)
number_of_comments = models.IntegerField()
number_of_pingbacks = models.IntegerField()
rating = models.IntegerField()
def __str__(self):
return self.headline
To represent database-table data in Python objects, Django uses an intuitive system: A model class represents a database table, and an instance of that class represents a particular record in the database table.
To create an object, instantiate it using keyword arguments to the model class,
then call save()
to save it to the database.
Assuming models live in a file mysite/blog/models.py
, here’s an example:
>>> from blog.models import Blog
>>> b = Blog(name='Beatles Blog', tagline='All the latest Beatles news.')
>>> b.save()
This performs an INSERT
SQL statement behind the scenes. Django doesn’t hit
the database until you explicitly call save()
.
The save()
method has no return value.
To save changes to an object that’s already in the database, use
save()
.
Given a Blog
instance b5
that has already been saved to the database,
this example changes its name and updates its record in the database:
>>> b5.name = 'New name'
>>> b5.save()
This performs an UPDATE
SQL statement behind the scenes. Django doesn’t hit
the database until you explicitly call save()
.
ForeignKey
and ManyToManyField
fields¶Updating a ForeignKey
field works exactly the same
way as saving a normal field – assign an object of the right type to the field
in question. This example updates the blog
attribute of an Entry
instance entry
, assuming appropriate instances of Entry
and Blog
are already saved to the database (so we can retrieve them below):
>>> from blog.models import Blog, Entry
>>> entry = Entry.objects.get(pk=1)
>>> cheese_blog = Blog.objects.get(name="Cheddar Talk")
>>> entry.blog = cheese_blog
>>> entry.save()
Updating a ManyToManyField
works a little
differently – use the
add()
method on the field
to add a record to the relation. This example adds the Author
instance
joe
to the entry
object:
>>> from blog.models import Author
>>> joe = Author.objects.create(name="Joe")
>>> entry.authors.add(joe)
To add multiple records to a ManyToManyField
in one
go, include multiple arguments in the call to
add()
, like this:
>>> john = Author.objects.create(name="John")
>>> paul = Author.objects.create(name="Paul")
>>> george = Author.objects.create(name="George")
>>> ringo = Author.objects.create(name="Ringo")
>>> entry.authors.add(john, paul, george, ringo)
Django will complain if you try to assign or add an object of the wrong type.
To retrieve objects from your database, construct a
QuerySet
via a
Manager
on your model class.
A QuerySet
represents a collection of objects
from your database. It can have zero, one or many filters. Filters narrow
down the query results based on the given parameters. In SQL terms, a
QuerySet
equates to a SELECT
statement,
and a filter is a limiting clause such as WHERE
or LIMIT
.
You get a QuerySet
by using your model’s
Manager
. Each model has at least one
Manager
, and it’s called
objects
by default. Access it directly via the
model class, like so:
>>> Blog.objects
<django.db.models.manager.Manager object at ...>
>>> b = Blog(name='Foo', tagline='Bar')
>>> b.objects
Traceback:
...
AttributeError: "Manager isn't accessible via Blog instances."
Note
Managers
are accessible only via model classes, rather than from model
instances, to enforce a separation between “table-level” operations and
“record-level” operations.
The Manager
is the main source of QuerySets
for
a model. For example, Blog.objects.all()
returns a
QuerySet
that contains all Blog
objects in
the database.
The simplest way to retrieve objects from a table is to get all of them. To do
this, use the all()
method on a
Manager
:
>>> all_entries = Entry.objects.all()
The all()
method returns a
QuerySet
of all the objects in the database.
The QuerySet
returned by
all()
describes all objects in the
database table. Usually, though, you’ll need to select only a subset of the
complete set of objects.
To create such a subset, you refine the initial
QuerySet
, adding filter conditions. The two
most common ways to refine a QuerySet
are:
filter(**kwargs)
Returns a new QuerySet
containing objects
that match the given lookup parameters.
exclude(**kwargs)
Returns a new QuerySet
containing objects
that do not match the given lookup parameters.
The lookup parameters (**kwargs
in the above function definitions) should
be in the format described in Field lookups below.
For example, to get a QuerySet
of blog entries
from the year 2006, use filter()
like
so:
Entry.objects.filter(pub_date__year=2006)
With the default manager class, it is the same as:
Entry.objects.all().filter(pub_date__year=2006)
The result of refining a QuerySet
is itself a
QuerySet
, so it’s possible to chain
refinements together. For example:
>>> Entry.objects.filter(
... headline__startswith='What'
... ).exclude(
... pub_date__gte=datetime.date.today()
... ).filter(
... pub_date__gte=datetime.date(2005, 1, 30)
... )
This takes the initial QuerySet
of all entries
in the database, adds a filter, then an exclusion, then another filter. The
final result is a QuerySet
containing all
entries with a headline that starts with “What”, that were published between
January 30, 2005, and the current day.
QuerySet
s are unique¶Each time you refine a QuerySet
, you get a
brand-new QuerySet
that is in no way bound to
the previous QuerySet
. Each refinement creates
a separate and distinct QuerySet
that can be
stored, used and reused.
Example:
>>> q1 = Entry.objects.filter(headline__startswith="What")
>>> q2 = q1.exclude(pub_date__gte=datetime.date.today())
>>> q3 = q1.filter(pub_date__gte=datetime.date.today())
These three QuerySets
are separate. The first is a base
QuerySet
containing all entries that contain a
headline starting with “What”. The second is a subset of the first, with an
additional criteria that excludes records whose pub_date
is today or in the
future. The third is a subset of the first, with an additional criteria that
selects only the records whose pub_date
is today or in the future. The
initial QuerySet
(q1
) is unaffected by the
refinement process.
QuerySet
s are lazy¶QuerySets
are lazy – the act of creating a
QuerySet
doesn’t involve any database
activity. You can stack filters together all day long, and Django won’t
actually run the query until the QuerySet
is
evaluated. Take a look at this example:
>>> q = Entry.objects.filter(headline__startswith="What")
>>> q = q.filter(pub_date__lte=datetime.date.today())
>>> q = q.exclude(body_text__icontains="food")
>>> print(q)
Though this looks like three database hits, in fact it hits the database only
once, at the last line (print(q)
). In general, the results of a
QuerySet
aren’t fetched from the database
until you “ask” for them. When you do, the
QuerySet
is evaluated by accessing the
database. For more details on exactly when evaluation takes place, see
When QuerySets are evaluated.
get()
¶filter()
will always give you a
QuerySet
, even if only a single object matches
the query - in this case, it will be a
QuerySet
containing a single element.
If you know there is only one object that matches your query, you can use the
get()
method on a
Manager
which returns the object directly:
>>> one_entry = Entry.objects.get(pk=1)
You can use any query expression with
get()
, just like with
filter()
- again, see Field lookups
below.
Note that there is a difference between using
get()
, and using
filter()
with a slice of [0]
. If
there are no results that match the query,
get()
will raise a DoesNotExist
exception. This exception is an attribute of the model class that the query is
being performed on - so in the code above, if there is no Entry
object with
a primary key of 1, Django will raise Entry.DoesNotExist
.
Similarly, Django will complain if more than one item matches the
get()
query. In this case, it will raise
MultipleObjectsReturned
, which again is an
attribute of the model class itself.
QuerySet
methods¶Most of the time you’ll use all()
,
get()
,
filter()
and
exclude()
when you need to look up
objects from the database. However, that’s far from all there is; see the
QuerySet API Reference for a complete list of all the
various QuerySet
methods.
QuerySet
s¶Use a subset of Python’s array-slicing syntax to limit your
QuerySet
to a certain number of results. This
is the equivalent of SQL’s LIMIT
and OFFSET
clauses.
For example, this returns the first 5 objects (LIMIT 5
):
>>> Entry.objects.all()[:5]
This returns the sixth through tenth objects (OFFSET 5 LIMIT 5
):
>>> Entry.objects.all()[5:10]
Negative indexing (i.e. Entry.objects.all()[-1]
) is not supported.
Generally, slicing a QuerySet
returns a new
QuerySet
– it doesn’t evaluate the query. An
exception is if you use the “step” parameter of Python slice syntax. For
example, this would actually execute the query in order to return a list of
every second object of the first 10:
>>> Entry.objects.all()[:10:2]
Further filtering or ordering of a sliced queryset is prohibited due to the ambiguous nature of how that might work.
To retrieve a single object rather than a list
(e.g. SELECT foo FROM bar LIMIT 1
), use an index instead of a slice. For
example, this returns the first Entry
in the database, after ordering
entries alphabetically by headline:
>>> Entry.objects.order_by('headline')[0]
This is roughly equivalent to:
>>> Entry.objects.order_by('headline')[0:1].get()
Note, however, that the first of these will raise IndexError
while the
second will raise DoesNotExist
if no objects match the given criteria. See
get()
for more details.
Field lookups are how you specify the meat of an SQL WHERE
clause. They’re
specified as keyword arguments to the QuerySet
methods filter()
,
exclude()
and
get()
.
Basic lookups keyword arguments take the form field__lookuptype=value
.
(That’s a double-underscore). For example:
>>> Entry.objects.filter(pub_date__lte='2006-01-01')
translates (roughly) into the following SQL:
SELECT * FROM blog_entry WHERE pub_date <= '2006-01-01';
How this is possible
Python has the ability to define functions that accept arbitrary name-value arguments whose names and values are evaluated at runtime. For more information, see Keyword Arguments in the official Python tutorial.
The field specified in a lookup has to be the name of a model field. There’s
one exception though, in case of a ForeignKey
you
can specify the field name suffixed with _id
. In this case, the value
parameter is expected to contain the raw value of the foreign model’s primary
key. For example:
>>> Entry.objects.filter(blog_id=4)
If you pass an invalid keyword argument, a lookup function will raise
TypeError
.
The database API supports about two dozen lookup types; a complete reference can be found in the field lookup reference. To give you a taste of what’s available, here’s some of the more common lookups you’ll probably use:
exact
An “exact” match. For example:
>>> Entry.objects.get(headline__exact="Cat bites dog")
Would generate SQL along these lines:
SELECT ... WHERE headline = 'Cat bites dog';
If you don’t provide a lookup type – that is, if your keyword argument
doesn’t contain a double underscore – the lookup type is assumed to be
exact
.
For example, the following two statements are equivalent:
>>> Blog.objects.get(id__exact=14) # Explicit form
>>> Blog.objects.get(id=14) # __exact is implied
This is for convenience, because exact
lookups are the common case.
iexact
A case-insensitive match. So, the query:
>>> Blog.objects.get(name__iexact="beatles blog")
Would match a Blog
titled "Beatles Blog"
, "beatles blog"
, or
even "BeAtlES blOG"
.
contains
Case-sensitive containment test. For example:
Entry.objects.get(headline__contains='Lennon')
Roughly translates to this SQL:
SELECT ... WHERE headline LIKE '%Lennon%';
Note this will match the headline 'Today Lennon honored'
but not
'today lennon honored'
.
There’s also a case-insensitive version, icontains
.
startswith
, endswith
Starts-with and ends-with search, respectively. There are also
case-insensitive versions called istartswith
and
iendswith
.
Again, this only scratches the surface. A complete reference can be found in the field lookup reference.
Django offers a powerful and intuitive way to “follow” relationships in
lookups, taking care of the SQL JOIN
s for you automatically, behind the
scenes. To span a relationship, use the field name of related fields
across models, separated by double underscores, until you get to the field you
want.
This example retrieves all Entry
objects with a Blog
whose name
is 'Beatles Blog'
:
>>> Entry.objects.filter(blog__name='Beatles Blog')
This spanning can be as deep as you’d like.
It works backwards, too. While it can be customized
, by default you refer to a “reverse”
relationship in a lookup using the lowercase name of the model.
This example retrieves all Blog
objects which have at least one Entry
whose headline
contains 'Lennon'
:
>>> Blog.objects.filter(entry__headline__contains='Lennon')
If you are filtering across multiple relationships and one of the intermediate
models doesn’t have a value that meets the filter condition, Django will treat
it as if there is an empty (all values are NULL
), but valid, object there.
All this means is that no error will be raised. For example, in this filter:
Blog.objects.filter(entry__authors__name='Lennon')
(if there was a related Author
model), if there was no author
associated with an entry, it would be treated as if there was also no name
attached, rather than raising an error because of the missing author
.
Usually this is exactly what you want to have happen. The only case where it
might be confusing is if you are using isnull
. Thus:
Blog.objects.filter(entry__authors__name__isnull=True)
will return Blog
objects that have an empty name
on the author
and
also those which have an empty author
on the entry
. If you don’t want
those latter objects, you could write:
Blog.objects.filter(entry__authors__isnull=False, entry__authors__name__isnull=True)
When you are filtering an object based on a
ManyToManyField
or a reverse
ForeignKey
, there are two different sorts of filter
you may be interested in. Consider the Blog
/Entry
relationship
(Blog
to Entry
is a one-to-many relation). We might be interested in
finding blogs that have an entry which has both “Lennon” in the headline and
was published in 2008. Or we might want to find blogs that have an entry with
“Lennon” in the headline as well as an entry that was published
in 2008. Since there are multiple entries associated with a single Blog
,
both of these queries are possible and make sense in some situations.
The same type of situation arises with a
ManyToManyField
. For example, if an Entry
has a
ManyToManyField
called tags
, we might want to
find entries linked to tags called “music” and “bands” or we might want an
entry that contains a tag with a name of “music” and a status of “public”.
To handle both of these situations, Django has a consistent way of processing
filter()
calls. Everything inside a
single filter()
call is applied
simultaneously to filter out items matching all those requirements. Successive
filter()
calls further restrict the set
of objects, but for multi-valued relations, they apply to any object linked to
the primary model, not necessarily those objects that were selected by an
earlier filter()
call.
That may sound a bit confusing, so hopefully an example will clarify. To select all blogs that contain entries with both “Lennon” in the headline and that were published in 2008 (the same entry satisfying both conditions), we would write:
Blog.objects.filter(entry__headline__contains='Lennon', entry__pub_date__year=2008)
To select all blogs that contain an entry with “Lennon” in the headline as well as an entry that was published in 2008, we would write:
Blog.objects.filter(entry__headline__contains='Lennon').filter(entry__pub_date__year=2008)
Suppose there is only one blog that had both entries containing “Lennon” and entries from 2008, but that none of the entries from 2008 contained “Lennon”. The first query would not return any blogs, but the second query would return that one blog.
In the second example, the first filter restricts the queryset to all those
blogs linked to entries with “Lennon” in the headline. The second filter
restricts the set of blogs further to those that are also linked to entries
that were published in 2008. The entries selected by the second filter may or
may not be the same as the entries in the first filter. We are filtering the
Blog
items with each filter statement, not the Entry
items.
Note
The behavior of filter()
for queries
that span multi-value relationships, as described above, is not implemented
equivalently for exclude()
. Instead,
the conditions in a single exclude()
call will not necessarily refer to the same item.
For example, the following query would exclude blogs that contain both entries with “Lennon” in the headline and entries published in 2008:
Blog.objects.exclude(
entry__headline__contains='Lennon',
entry__pub_date__year=2008,
)
However, unlike the behavior when using
filter()
, this will not limit blogs
based on entries that satisfy both conditions. In order to do that, i.e.
to select all blogs that do not contain entries published with “Lennon”
that were published in 2008, you need to make two queries:
Blog.objects.exclude(
entry__in=Entry.objects.filter(
headline__contains='Lennon',
pub_date__year=2008,
),
)
In the examples given so far, we have constructed filters that compare the value of a model field with a constant. But what if you want to compare the value of a model field with another field on the same model?
Django provides F expressions
to allow such
comparisons. Instances of F()
act as a reference to a model field within a
query. These references can then be used in query filters to compare the values
of two different fields on the same model instance.
For example, to find a list of all blog entries that have had more comments
than pingbacks, we construct an F()
object to reference the pingback count,
and use that F()
object in the query:
>>> from django.db.models import F
>>> Entry.objects.filter(number_of_comments__gt=F('number_of_pingbacks'))
Django supports the use of addition, subtraction, multiplication,
division, modulo, and power arithmetic with F()
objects, both with constants
and with other F()
objects. To find all the blog entries with more than
twice as many comments as pingbacks, we modify the query:
>>> Entry.objects.filter(number_of_comments__gt=F('number_of_pingbacks') * 2)
To find all the entries where the rating of the entry is less than the sum of the pingback count and comment count, we would issue the query:
>>> Entry.objects.filter(rating__lt=F('number_of_comments') + F('number_of_pingbacks'))
You can also use the double underscore notation to span relationships in
an F()
object. An F()
object with a double underscore will introduce
any joins needed to access the related object. For example, to retrieve all
the entries where the author’s name is the same as the blog name, we could
issue the query:
>>> Entry.objects.filter(authors__name=F('blog__name'))
For date and date/time fields, you can add or subtract a
timedelta
object. The following would return all entries
that were modified more than 3 days after they were published:
>>> from datetime import timedelta
>>> Entry.objects.filter(mod_date__gt=F('pub_date') + timedelta(days=3))
The F()
objects support bitwise operations by .bitand()
, .bitor()
,
.bitxor()
, .bitrightshift()
, and .bitleftshift()
. For example:
>>> F('somefield').bitand(16)
Oracle
Oracle doesn’t support bitwise XOR operation.
Support for .bitxor()
was added.
Django supports using transforms in expressions.
For example, to find all Entry
objects published in the same year as they
were last modified:
>>> Entry.objects.filter(pub_date__year=F('mod_date__year'))
To find the earliest year an entry was published, we can issue the query:
>>> Entry.objects.aggregate(first_published_year=Min('pub_date__year'))
This example finds the value of the highest rated entry and the total number of comments on all entries for each year:
>>> Entry.objects.values('pub_date__year').annotate(
... top_rating=Subquery(
... Entry.objects.filter(
... pub_date__year=OuterRef('pub_date__year'),
... ).order_by('-rating').values('rating')[:1]
... ),
... total_comments=Sum('number_of_comments'),
... )
pk
lookup shortcut¶For convenience, Django provides a pk
lookup shortcut, which stands for
“primary key”.
In the example Blog
model, the primary key is the id
field, so these
three statements are equivalent:
>>> Blog.objects.get(id__exact=14) # Explicit form
>>> Blog.objects.get(id=14) # __exact is implied
>>> Blog.objects.get(pk=14) # pk implies id__exact
The use of pk
isn’t limited to __exact
queries – any query term
can be combined with pk
to perform a query on the primary key of a model:
# Get blogs entries with id 1, 4 and 7
>>> Blog.objects.filter(pk__in=[1,4,7])
# Get all blog entries with id > 14
>>> Blog.objects.filter(pk__gt=14)
pk
lookups also work across joins. For example, these three statements are
equivalent:
>>> Entry.objects.filter(blog__id__exact=3) # Explicit form
>>> Entry.objects.filter(blog__id=3) # __exact is implied
>>> Entry.objects.filter(blog__pk=3) # __pk implies __id__exact
LIKE
statements¶The field lookups that equate to LIKE
SQL statements (iexact
,
contains
, icontains
, startswith
, istartswith
, endswith
and iendswith
) will automatically escape the two special characters used in
LIKE
statements – the percent sign and the underscore. (In a LIKE
statement, the percent sign signifies a multiple-character wildcard and the
underscore signifies a single-character wildcard.)
This means things should work intuitively, so the abstraction doesn’t leak. For example, to retrieve all the entries that contain a percent sign, use the percent sign as any other character:
>>> Entry.objects.filter(headline__contains='%')
Django takes care of the quoting for you; the resulting SQL will look something like this:
SELECT ... WHERE headline LIKE '%\%%';
Same goes for underscores. Both percentage signs and underscores are handled for you transparently.
QuerySet
s¶Each QuerySet
contains a cache to minimize
database access. Understanding how it works will allow you to write the most
efficient code.
In a newly created QuerySet
, the cache is
empty. The first time a QuerySet
is evaluated
– and, hence, a database query happens – Django saves the query results in
the QuerySet
’s cache and returns the results
that have been explicitly requested (e.g., the next element, if the
QuerySet
is being iterated over). Subsequent
evaluations of the QuerySet
reuse the cached
results.
Keep this caching behavior in mind, because it may bite you if you don’t use
your QuerySet
s correctly. For example, the
following will create two QuerySet
s, evaluate
them, and throw them away:
>>> print([e.headline for e in Entry.objects.all()])
>>> print([e.pub_date for e in Entry.objects.all()])
That means the same database query will be executed twice, effectively doubling
your database load. Also, there’s a possibility the two lists may not include
the same database records, because an Entry
may have been added or deleted
in the split second between the two requests.
To avoid this problem, save the QuerySet
and
reuse it:
>>> queryset = Entry.objects.all()
>>> print([p.headline for p in queryset]) # Evaluate the query set.
>>> print([p.pub_date for p in queryset]) # Re-use the cache from the evaluation.
QuerySet
s are not cached¶Querysets do not always cache their results. When evaluating only part of the queryset, the cache is checked, but if it is not populated then the items returned by the subsequent query are not cached. Specifically, this means that limiting the queryset using an array slice or an index will not populate the cache.
For example, repeatedly getting a certain index in a queryset object will query the database each time:
>>> queryset = Entry.objects.all()
>>> print(queryset[5]) # Queries the database
>>> print(queryset[5]) # Queries the database again
However, if the entire queryset has already been evaluated, the cache will be checked instead:
>>> queryset = Entry.objects.all()
>>> [entry for entry in queryset] # Queries the database
>>> print(queryset[5]) # Uses cache
>>> print(queryset[5]) # Uses cache
Here are some examples of other actions that will result in the entire queryset being evaluated and therefore populate the cache:
>>> [entry for entry in queryset]
>>> bool(queryset)
>>> entry in queryset
>>> list(queryset)
Note
Simply printing the queryset will not populate the cache. This is because
the call to __repr__()
only returns a slice of the entire queryset.
JSONField
¶Lookups implementation is different in JSONField
,
mainly due to the existence of key transformations. To demonstrate, we will use
the following example model:
from django.db import models
class Dog(models.Model):
name = models.CharField(max_length=200)
data = models.JSONField(null=True)
def __str__(self):
return self.name
None
¶As with other fields, storing None
as the field’s value will store it as
SQL NULL
. While not recommended, it is possible to store JSON scalar
null
instead of SQL NULL
by using Value('null')
.
Whichever of the values is stored, when retrieved from the database, the Python
representation of the JSON scalar null
is the same as SQL NULL
, i.e.
None
. Therefore, it can be hard to distinguish between them.
This only applies to None
as the top-level value of the field. If None
is inside a list
or dict
, it will always be interpreted
as JSON null
.
When querying, None
value will always be interpreted as JSON null
. To
query for SQL NULL
, use isnull
:
>>> Dog.objects.create(name='Max', data=None) # SQL NULL.
<Dog: Max>
>>> Dog.objects.create(name='Archie', data=Value('null')) # JSON null.
<Dog: Archie>
>>> Dog.objects.filter(data=None)
<QuerySet [<Dog: Archie>]>
>>> Dog.objects.filter(data=Value('null'))
<QuerySet [<Dog: Archie>]>
>>> Dog.objects.filter(data__isnull=True)
<QuerySet [<Dog: Max>]>
>>> Dog.objects.filter(data__isnull=False)
<QuerySet [<Dog: Archie>]>
Unless you are sure you wish to work with SQL NULL
values, consider setting
null=False
and providing a suitable default for empty values, such as
default=dict
.
Note
Storing JSON scalar null
does not violate null=False
.
To query based on a given dictionary key, use that key as the lookup name:
>>> Dog.objects.create(name='Rufus', data={
... 'breed': 'labrador',
... 'owner': {
... 'name': 'Bob',
... 'other_pets': [{
... 'name': 'Fishy',
... }],
... },
... })
<Dog: Rufus>
>>> Dog.objects.create(name='Meg', data={'breed': 'collie', 'owner': None})
<Dog: Meg>
>>> Dog.objects.filter(data__breed='collie')
<QuerySet [<Dog: Meg>]>
Multiple keys can be chained together to form a path lookup:
>>> Dog.objects.filter(data__owner__name='Bob')
<QuerySet [<Dog: Rufus>]>
If the key is an integer, it will be interpreted as an index transform in an array:
>>> Dog.objects.filter(data__owner__other_pets__0__name='Fishy')
<QuerySet [<Dog: Rufus>]>
If the key you wish to query by clashes with the name of another lookup, use
the contains
lookup instead.
To query for missing keys, use the isnull
lookup:
>>> Dog.objects.create(name='Shep', data={'breed': 'collie'})
<Dog: Shep>
>>> Dog.objects.filter(data__owner__isnull=True)
<QuerySet [<Dog: Shep>]>
Note
The lookup examples given above implicitly use the exact
lookup.
Key, index, and path transforms can also be chained with:
icontains
, endswith
, iendswith
,
iexact
, regex
, iregex
, startswith
,
istartswith
, lt
, lte
, gt
, and
gte
, as well as with Containment and key lookups.
Note
Due to the way in which key-path queries work,
exclude()
and
filter()
are not guaranteed to
produce exhaustive sets. If you want to include objects that do not have
the path, add the isnull
lookup.
Warning
Since any string could be a key in a JSON object, any lookup other than those listed below will be interpreted as a key lookup. No errors are raised. Be extra careful for typing mistakes, and always check your queries work as you intend.
MariaDB and Oracle users
Using order_by()
on key, index, or
path transforms will sort the objects using the string representation of
the values. This is because MariaDB and Oracle Database do not provide a
function that converts JSON values into their equivalent SQL values.
Oracle users
On Oracle Database, using None
as the lookup value in an
exclude()
query will return objects
that do not have null
as the value at the given path, including objects
that do not have the path. On other database backends, the query will
return objects that have the path and the value is not null
.
PostgreSQL users
On PostgreSQL, if only one key or index is used, the SQL operator ->
is
used. If multiple operators are used then the #>
operator is used.
contains
¶The contains
lookup is overridden on JSONField
. The returned
objects are those where the given dict
of key-value pairs are all
contained in the top-level of the field. For example:
>>> Dog.objects.create(name='Rufus', data={'breed': 'labrador', 'owner': 'Bob'})
<Dog: Rufus>
>>> Dog.objects.create(name='Meg', data={'breed': 'collie', 'owner': 'Bob'})
<Dog: Meg>
>>> Dog.objects.create(name='Fred', data={})
<Dog: Fred>
>>> Dog.objects.filter(data__contains={'owner': 'Bob'})
<QuerySet [<Dog: Rufus>, <Dog: Meg>]>
>>> Dog.objects.filter(data__contains={'breed': 'collie'})
<QuerySet [<Dog: Meg>]>
Oracle and SQLite
contains
is not supported on Oracle and SQLite.
contained_by
¶This is the inverse of the contains
lookup - the
objects returned will be those where the key-value pairs on the object are a
subset of those in the value passed. For example:
>>> Dog.objects.create(name='Rufus', data={'breed': 'labrador', 'owner': 'Bob'})
<Dog: Rufus>
>>> Dog.objects.create(name='Meg', data={'breed': 'collie', 'owner': 'Bob'})
<Dog: Meg>
>>> Dog.objects.create(name='Fred', data={})
<Dog: Fred>
>>> Dog.objects.filter(data__contained_by={'breed': 'collie', 'owner': 'Bob'})
<QuerySet [<Dog: Meg>, <Dog: Fred>]>
>>> Dog.objects.filter(data__contained_by={'breed': 'collie'})
<QuerySet [<Dog: Fred>]>
Oracle and SQLite
contained_by
is not supported on Oracle and SQLite.
has_key
¶Returns objects where the given key is in the top-level of the data. For example:
>>> Dog.objects.create(name='Rufus', data={'breed': 'labrador'})
<Dog: Rufus>
>>> Dog.objects.create(name='Meg', data={'breed': 'collie', 'owner': 'Bob'})
<Dog: Meg>
>>> Dog.objects.filter(data__has_key='owner')
<QuerySet [<Dog: Meg>]>
has_keys
¶Returns objects where all of the given keys are in the top-level of the data. For example:
>>> Dog.objects.create(name='Rufus', data={'breed': 'labrador'})
<Dog: Rufus>
>>> Dog.objects.create(name='Meg', data={'breed': 'collie', 'owner': 'Bob'})
<Dog: Meg>
>>> Dog.objects.filter(data__has_keys=['breed', 'owner'])
<QuerySet [<Dog: Meg>]>
has_any_keys
¶Returns objects where any of the given keys are in the top-level of the data. For example:
>>> Dog.objects.create(name='Rufus', data={'breed': 'labrador'})
<Dog: Rufus>
>>> Dog.objects.create(name='Meg', data={'owner': 'Bob'})
<Dog: Meg>
>>> Dog.objects.filter(data__has_any_keys=['owner', 'breed'])
<QuerySet [<Dog: Rufus>, <Dog: Meg>]>
Q
objects¶Keyword argument queries – in filter()
,
etc. – are “AND”ed together. If you need to execute more complex queries (for
example, queries with OR
statements), you can use Q objects
.
A Q object
(django.db.models.Q
) is an object
used to encapsulate a collection of keyword arguments. These keyword arguments
are specified as in “Field lookups” above.
For example, this Q
object encapsulates a single LIKE
query:
from django.db.models import Q
Q(question__startswith='What')
Q
objects can be combined using the &
and |
operators. When an
operator is used on two Q
objects, it yields a new Q
object.
For example, this statement yields a single Q
object that represents the
“OR” of two "question__startswith"
queries:
Q(question__startswith='Who') | Q(question__startswith='What')
This is equivalent to the following SQL WHERE
clause:
WHERE question LIKE 'Who%' OR question LIKE 'What%'
You can compose statements of arbitrary complexity by combining Q
objects
with the &
and |
operators and use parenthetical grouping. Also, Q
objects can be negated using the ~
operator, allowing for combined lookups
that combine both a normal query and a negated (NOT
) query:
Q(question__startswith='Who') | ~Q(pub_date__year=2005)
Each lookup function that takes keyword-arguments
(e.g. filter()
,
exclude()
,
get()
) can also be passed one or more
Q
objects as positional (not-named) arguments. If you provide multiple
Q
object arguments to a lookup function, the arguments will be “AND”ed
together. For example:
Poll.objects.get(
Q(question__startswith='Who'),
Q(pub_date=date(2005, 5, 2)) | Q(pub_date=date(2005, 5, 6))
)
… roughly translates into the SQL:
SELECT * from polls WHERE question LIKE 'Who%'
AND (pub_date = '2005-05-02' OR pub_date = '2005-05-06')
Lookup functions can mix the use of Q
objects and keyword arguments. All
arguments provided to a lookup function (be they keyword arguments or Q
objects) are “AND”ed together. However, if a Q
object is provided, it must
precede the definition of any keyword arguments. For example:
Poll.objects.get(
Q(pub_date=date(2005, 5, 2)) | Q(pub_date=date(2005, 5, 6)),
question__startswith='Who',
)
… would be a valid query, equivalent to the previous example; but:
# INVALID QUERY
Poll.objects.get(
question__startswith='Who',
Q(pub_date=date(2005, 5, 2)) | Q(pub_date=date(2005, 5, 6))
)
… would not be valid.
See also
The OR lookups examples in Django’s
unit tests show some possible uses of Q
.
To compare two model instances, use the standard Python comparison operator,
the double equals sign: ==
. Behind the scenes, that compares the primary
key values of two models.
Using the Entry
example above, the following two statements are equivalent:
>>> some_entry == other_entry
>>> some_entry.id == other_entry.id
If a model’s primary key isn’t called id
, no problem. Comparisons will
always use the primary key, whatever it’s called. For example, if a model’s
primary key field is called name
, these two statements are equivalent:
>>> some_obj == other_obj
>>> some_obj.name == other_obj.name
The delete method, conveniently, is named
delete()
. This method immediately deletes the
object and returns the number of objects deleted and a dictionary with
the number of deletions per object type. Example:
>>> e.delete()
(1, {'weblog.Entry': 1})
You can also delete objects in bulk. Every
QuerySet
has a
delete()
method, which deletes all
members of that QuerySet
.
For example, this deletes all Entry
objects with a pub_date
year of
2005:
>>> Entry.objects.filter(pub_date__year=2005).delete()
(5, {'webapp.Entry': 5})
Keep in mind that this will, whenever possible, be executed purely in SQL, and
so the delete()
methods of individual object instances will not necessarily
be called during the process. If you’ve provided a custom delete()
method
on a model class and want to ensure that it is called, you will need to
“manually” delete instances of that model (e.g., by iterating over a
QuerySet
and calling delete()
on each
object individually) rather than using the bulk
delete()
method of a
QuerySet
.
When Django deletes an object, by default it emulates the behavior of the SQL
constraint ON DELETE CASCADE
– in other words, any objects which had
foreign keys pointing at the object to be deleted will be deleted along with
it. For example:
b = Blog.objects.get(pk=1)
# This will delete the Blog and all of its Entry objects.
b.delete()
This cascade behavior is customizable via the
on_delete
argument to the
ForeignKey
.
Note that delete()
is the only
QuerySet
method that is not exposed on a
Manager
itself. This is a safety mechanism to
prevent you from accidentally requesting Entry.objects.delete()
, and
deleting all the entries. If you do want to delete all the objects, then
you have to explicitly request a complete query set:
Entry.objects.all().delete()
Although there is no built-in method for copying model instances, it is
possible to easily create new instance with all fields’ values copied. In the
simplest case, you can set pk
to None
and
_state.adding
to True
. Using our
blog example:
blog = Blog(name='My blog', tagline='Blogging is easy')
blog.save() # blog.pk == 1
blog.pk = None
blog._state.adding = True
blog.save() # blog.pk == 2
Things get more complicated if you use inheritance. Consider a subclass of
Blog
:
class ThemeBlog(Blog):
theme = models.CharField(max_length=200)
django_blog = ThemeBlog(name='Django', tagline='Django is easy', theme='python')
django_blog.save() # django_blog.pk == 3
Due to how inheritance works, you have to set both pk
and id
to
None
, and _state.adding
to True
:
django_blog.pk = None
django_blog.id = None
django_blog._state.adding = True
django_blog.save() # django_blog.pk == 4
This process doesn’t copy relations that aren’t part of the model’s database
table. For example, Entry
has a ManyToManyField
to Author
. After
duplicating an entry, you must set the many-to-many relations for the new
entry:
entry = Entry.objects.all()[0] # some previous entry
old_authors = entry.authors.all()
entry.pk = None
entry._state.adding = True
entry.save()
entry.authors.set(old_authors)
For a OneToOneField
, you must duplicate the related object and assign it
to the new object’s field to avoid violating the one-to-one unique constraint.
For example, assuming entry
is already duplicated as above:
detail = EntryDetail.objects.all()[0]
detail.pk = None
detail._state.adding = True
detail.entry = entry
detail.save()
Sometimes you want to set a field to a particular value for all the objects in
a QuerySet
. You can do this with the
update()
method. For example:
# Update all the headlines with pub_date in 2007.
Entry.objects.filter(pub_date__year=2007).update(headline='Everything is the same')
You can only set non-relation fields and ForeignKey
fields using this method. To update a non-relation field, provide the new value
as a constant. To update ForeignKey
fields, set the
new value to be the new model instance you want to point to. For example:
>>> b = Blog.objects.get(pk=1)
# Change every Entry so that it belongs to this Blog.
>>> Entry.objects.all().update(blog=b)
The update()
method is applied instantly and returns the number of rows
matched by the query (which may not be equal to the number of rows updated if
some rows already have the new value). The only restriction on the
QuerySet
being updated is that it can only
access one database table: the model’s main table. You can filter based on
related fields, but you can only update columns in the model’s main
table. Example:
>>> b = Blog.objects.get(pk=1)
# Update all the headlines belonging to this Blog.
>>> Entry.objects.filter(blog=b).update(headline='Everything is the same')
Be aware that the update()
method is converted directly to an SQL
statement. It is a bulk operation for direct updates. It doesn’t run any
save()
methods on your models, or emit the
pre_save
or post_save
signals (which are a consequence of calling
save()
), or honor the
auto_now
field option.
If you want to save every item in a QuerySet
and make sure that the save()
method is called on
each instance, you don’t need any special function to handle that. Loop over
them and call save()
:
for item in my_queryset:
item.save()
Calls to update can also use F expressions
to
update one field based on the value of another field in the model. This is
especially useful for incrementing counters based upon their current value. For
example, to increment the pingback count for every entry in the blog:
>>> Entry.objects.all().update(number_of_pingbacks=F('number_of_pingbacks') + 1)
However, unlike F()
objects in filter and exclude clauses, you can’t
introduce joins when you use F()
objects in an update – you can only
reference fields local to the model being updated. If you attempt to introduce
a join with an F()
object, a FieldError
will be raised:
# This will raise a FieldError
>>> Entry.objects.update(headline=F('blog__name'))
If you find yourself needing to write an SQL query that is too complex for Django’s database-mapper to handle, you can fall back on writing SQL by hand. Django has a couple of options for writing raw SQL queries; see Performing raw SQL queries.
Finally, it’s important to note that the Django database layer is merely an interface to your database. You can access your database via other tools, programming languages or database frameworks; there’s nothing Django-specific about your database.
Dec 25, 2023