Django includes a contenttypes
application that can track all of the models installed in your Django-powered project, providing a high-level, generic interface for working with your models.
At the heart of the contenttypes application is the ContentType
model, which lives at django.contrib.contenttypes.models.ContentType
. Instances of ContentType
represent and store information about the models installed in your project, and new instances of ContentType
are automatically created whenever new models are installed.
Instances of ContentType
have methods for returning the model classes they represent and for querying objects from those models. ContentType
also has a custom manager that adds methods for working with ContentType
and for obtaining instances of ContentType
for a particular model.
Relations between your models and ContentType
can also be used to enable “generic” relationships between an instance of one of your models and instances of any model you have installed.
The contenttypes framework is included in the default INSTALLED_APPS
list created by django-admin startproject
, but if you’ve removed it or if you manually set up your INSTALLED_APPS
list, you can enable it by adding 'django.contrib.contenttypes'
to your INSTALLED_APPS
setting.
It’s generally a good idea to have the contenttypes framework installed; several of Django’s other bundled applications require it:
authentication framework
uses it to tie user permissions to specific models.ContentType
modelclass ContentType
Each instance of ContentType
has two fields which, taken together, uniquely describe an installed model:
app_label
The name of the application the model is part of. This is taken from the app_label
attribute of the model, and includes only the last part of the application’s Python import path; django.contrib.contenttypes
, for example, becomes an app_label
of contenttypes
.
model
The name of the model class.
Additionally, the following property is available:
name
The human-readable name of the content type. This is taken from the verbose_name
attribute of the model.
Let’s look at an example to see how this works. If you already have the contenttypes
application installed, and then add the sites application
to your INSTALLED_APPS
setting and run manage.py migrate
to install it, the model django.contrib.sites.models.Site
will be installed into your database. Along with it a new instance of ContentType
will be created with the following values:
app_label
will be set to 'sites'
(the last part of the Python path django.contrib.sites
).model
will be set to 'site'
.ContentType
instancesEach ContentType
instance has methods that allow you to get from a ContentType
instance to the model it represents, or to retrieve objects from that model:
ContentType.get_object_for_this_type(**kwargs)
Takes a set of valid lookup arguments for the model the ContentType
represents, and does a get() lookup
on that model, returning the corresponding object.
ContentType.model_class()
Returns the model class represented by this ContentType
instance.
For example, we could look up the ContentType
for the User
model:
>>> from django.contrib.contenttypes.models import ContentType >>> user_type = ContentType.objects.get(app_label='auth', model='user') >>> user_type <ContentType: user>
And then use it to query for a particular User
, or to get access to the User
model class:
>>> user_type.model_class() <class 'django.contrib.auth.models.User'> >>> user_type.get_object_for_this_type(username='Guido') <User: Guido>
Together, get_object_for_this_type()
and model_class()
enable two extremely important use cases:
app_label
and model
into a ContentType
lookup at runtime, and then work with the model class or retrieve objects from it.ContentType
as a way of tying instances of it to particular model classes, and use these methods to get access to those model classes.Several of Django’s bundled applications make use of the latter technique. For example, the permissions system
in Django’s authentication framework uses a Permission
model with a foreign key to ContentType
; this lets Permission
represent concepts like “can add blog entry” or “can delete news story”.
ContentTypeManager
class ContentTypeManager
ContentType
also has a custom manager, ContentTypeManager
, which adds the following methods:
clear_cache()
Clears an internal cache used by ContentType
to keep track of models for which it has created ContentType
instances. You probably won’t ever need to call this method yourself; Django will call it automatically when it’s needed.
get_for_id(id)
Lookup a ContentType
by ID. Since this method uses the same shared cache as get_for_model()
, it’s preferred to use this method over the usual ContentType.objects.get(pk=id)
get_for_model(model, for_concrete_model=True)
Takes either a model class or an instance of a model, and returns the ContentType
instance representing that model. for_concrete_model=False
allows fetching the ContentType
of a proxy model.
get_for_models(*models, for_concrete_models=True)
Takes a variadic number of model classes, and returns a dictionary mapping the model classes to the ContentType
instances representing them. for_concrete_models=False
allows fetching the ContentType
of proxy models.
get_by_natural_key(app_label, model)
Returns the ContentType
instance uniquely identified by the given application label and model name. The primary purpose of this method is to allow ContentType
objects to be referenced via a natural key during deserialization.
The get_for_model()
method is especially useful when you know you need to work with a ContentType
but don’t want to go to the trouble of obtaining the model’s metadata to perform a manual lookup:
>>> from django.contrib.auth.models import User >>> ContentType.objects.get_for_model(User) <ContentType: user>
Adding a foreign key from one of your own models to ContentType
allows your model to effectively tie itself to another model class, as in the example of the Permission
model above. But it’s possible to go one step further and use ContentType
to enable truly generic (sometimes called “polymorphic”) relationships between models.
For example, it could be used for a tagging system like so:
from django.contrib.contenttypes.fields import GenericForeignKey from django.contrib.contenttypes.models import ContentType from django.db import models class TaggedItem(models.Model): tag = models.SlugField() content_type = models.ForeignKey(ContentType, on_delete=models.CASCADE) object_id = models.PositiveIntegerField() content_object = GenericForeignKey('content_type', 'object_id') def __str__(self): return self.tag
A normal ForeignKey
can only “point to” one other model, which means that if the TaggedItem
model used a ForeignKey
it would have to choose one and only one model to store tags for. The contenttypes application provides a special field type (GenericForeignKey
) which works around this and allows the relationship to be with any model:
class GenericForeignKey
There are three parts to setting up a GenericForeignKey
:
ForeignKey
to ContentType
. The usual name for this field is “content_type”.PositiveIntegerField
. The usual name for this field is “object_id”.GenericForeignKey
, and pass it the names of the two fields described above. If these fields are named “content_type” and “object_id”, you can omit this – those are the default field names GenericForeignKey
will look for.for_concrete_model
If False
, the field will be able to reference proxy models. Default is True
. This mirrors the for_concrete_model
argument to get_for_model()
.
Primary key type compatibility
The “object_id” field doesn’t have to be the same type as the primary key fields on the related models, but their primary key values must be coercible to the same type as the “object_id” field by its get_db_prep_value()
method.
For example, if you want to allow generic relations to models with either IntegerField
or CharField
primary key fields, you can use CharField
for the “object_id” field on your model since integers can be coerced to strings by get_db_prep_value()
.
For maximum flexibility you can use a TextField
which doesn’t have a maximum length defined, however this may incur significant performance penalties depending on your database backend.
There is no one-size-fits-all solution for which field type is best. You should evaluate the models you expect to be pointing to and determine which solution will be most effective for your use case.
Serializing references to ContentType
objects
If you’re serializing data (for example, when generating fixtures
) from a model that implements generic relations, you should probably be using a natural key to uniquely identify related ContentType
objects. See natural keys and dumpdata --natural-foreign
for more information.
This will enable an API similar to the one used for a normal ForeignKey
; each TaggedItem
will have a content_object
field that returns the object it’s related to, and you can also assign to that field or use it when creating a TaggedItem
:
>>> from django.contrib.auth.models import User >>> guido = User.objects.get(username='Guido') >>> t = TaggedItem(content_object=guido, tag='bdfl') >>> t.save() >>> t.content_object <User: Guido>
If the related object is deleted, the content_type
and object_id
fields remain set to their original values and the GenericForeignKey
returns None
:
>>> guido.delete() >>> t.content_object # returns None
Due to the way GenericForeignKey
is implemented, you cannot use such fields directly with filters (filter()
and exclude()
, for example) via the database API. Because a GenericForeignKey
isn’t a normal field object, these examples will not work:
# This will fail >>> TaggedItem.objects.filter(content_object=guido) # This will also fail >>> TaggedItem.objects.get(content_object=guido)
Likewise, GenericForeignKey
s does not appear in ModelForm
s.
class GenericRelation
The relation on the related object back to this object doesn’t exist by default. Setting related_query_name
creates a relation from the related object back to this one. This allows querying and filtering from the related object.
If you know which models you’ll be using most often, you can also add a “reverse” generic relationship to enable an additional API. For example:
from django.contrib.contenttypes.fields import GenericRelation from django.db import models class Bookmark(models.Model): url = models.URLField() tags = GenericRelation(TaggedItem)
Bookmark
instances will each have a tags
attribute, which can be used to retrieve their associated TaggedItems
:
>>> b = Bookmark(url='https://www.djangoproject.com/') >>> b.save() >>> t1 = TaggedItem(content_object=b, tag='django') >>> t1.save() >>> t2 = TaggedItem(content_object=b, tag='python') >>> t2.save() >>> b.tags.all() <QuerySet [<TaggedItem: django>, <TaggedItem: python>]>
You can also use add()
, create()
, or set()
to create relationships:
>>> t3 = TaggedItem(tag='Web development') >>> b.tags.add(t3, bulk=False) >>> b.tags.create(tag='Web framework') <TaggedItem: Web framework> >>> b.tags.all() <QuerySet [<TaggedItem: django>, <TaggedItem: python>, <TaggedItem: Web development>, <TaggedItem: Web framework>]> >>> b.tags.set([t1, t3]) >>> b.tags.all() <QuerySet [<TaggedItem: django>, <TaggedItem: Web development>]>
The remove()
call will bulk delete the specified model objects:
>>> b.tags.remove(t3) >>> b.tags.all() <QuerySet [<TaggedItem: django>]> >>> TaggedItem.objects.all() <QuerySet [<TaggedItem: django>]>
The clear()
method can be used to bulk delete all related objects for an instance:
>>> b.tags.clear() >>> b.tags.all() <QuerySet []> >>> TaggedItem.objects.all() <QuerySet []>
Defining GenericRelation
with related_query_name
set allows querying from the related object:
tags = GenericRelation(TaggedItem, related_query_name='bookmark')
This enables filtering, ordering, and other query operations on Bookmark
from TaggedItem
:
>>> # Get all tags belonging to bookmarks containing `django` in the url >>> TaggedItem.objects.filter(bookmark__url__contains='django') <QuerySet [<TaggedItem: django>, <TaggedItem: python>]>
If you don’t add the related_query_name
, you can do the same types of lookups manually:
>>> bookmarks = Bookmark.objects.filter(url__contains='django') >>> bookmark_type = ContentType.objects.get_for_model(Bookmark) >>> TaggedItem.objects.filter(content_type__pk=bookmark_type.id, object_id__in=bookmarks) <QuerySet [<TaggedItem: django>, <TaggedItem: python>]>
Just as GenericForeignKey
accepts the names of the content-type and object-ID fields as arguments, so too does GenericRelation
; if the model which has the generic foreign key is using non-default names for those fields, you must pass the names of the fields when setting up a GenericRelation
to it. For example, if the TaggedItem
model referred to above used fields named content_type_fk
and object_primary_key
to create its generic foreign key, then a GenericRelation
back to it would need to be defined like so:
tags = GenericRelation( TaggedItem, content_type_field='content_type_fk', object_id_field='object_primary_key', )
Note also, that if you delete an object that has a GenericRelation
, any objects which have a GenericForeignKey
pointing at it will be deleted as well. In the example above, this means that if a Bookmark
object were deleted, any TaggedItem
objects pointing at it would be deleted at the same time.
Unlike ForeignKey
, GenericForeignKey
does not accept an on_delete
argument to customize this behavior; if desired, you can avoid the cascade-deletion by not using GenericRelation
, and alternate behavior can be provided via the pre_delete
signal.
Django’s database aggregation API works with a GenericRelation
. For example, you can find out how many tags all the bookmarks have:
>>> Bookmark.objects.aggregate(Count('tags')) {'tags__count': 3}
The django.contrib.contenttypes.forms
module provides:
BaseGenericInlineFormSet
generic_inlineformset_factory()
, for use with GenericForeignKey
.class BaseGenericInlineFormSet
generic_inlineformset_factory(model, form=ModelForm, formset=BaseGenericInlineFormSet, ct_field="content_type", fk_field="object_id", fields=None, exclude=None, extra=3, can_order=False, can_delete=True, max_num=None, formfield_callback=None, validate_max=False, for_concrete_model=True, min_num=None, validate_min=False, absolute_max=None, can_delete_extra=True)
Returns a GenericInlineFormSet
using modelformset_factory()
.
You must provide ct_field
and fk_field
if they are different from the defaults, content_type
and object_id
respectively. Other parameters are similar to those documented in modelformset_factory()
and inlineformset_factory()
.
The for_concrete_model
argument corresponds to the for_concrete_model
argument on GenericForeignKey
.
The absolute_max
and can_delete_extra
arguments were added.
The django.contrib.contenttypes.admin
module provides GenericTabularInline
and GenericStackedInline
(subclasses of GenericInlineModelAdmin
)
These classes and functions enable the use of generic relations in forms and the admin. See the model formset and admin documentation for more information.
class GenericInlineModelAdmin
The GenericInlineModelAdmin
class inherits all properties from an InlineModelAdmin
class. However, it adds a couple of its own for working with the generic relation:
ct_field
The name of the ContentType
foreign key field on the model. Defaults to content_type
.
ct_fk_field
The name of the integer field that represents the ID of the related object. Defaults to object_id
.
class GenericTabularInline
class GenericStackedInline
Subclasses of GenericInlineModelAdmin
with stacked and tabular layouts, respectively.
© Django Software Foundation and individual contributors
Licensed under the BSD License.
https://docs.djangoproject.com/en/3.2/ref/contrib/contenttypes/