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ee5147cfd7
Co-authored-by: Emad Mokhtar <emad.mokhtar@veneficus.nl>
728 lines
26 KiB
Plaintext
728 lines
26 KiB
Plaintext
==========================
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Serializing Django objects
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==========================
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Django's serialization framework provides a mechanism for "translating" Django
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models into other formats. Usually these other formats will be text-based and
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used for sending Django data over a wire, but it's possible for a
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serializer to handle any format (text-based or not).
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.. seealso::
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If you just want to get some data from your tables into a serialized
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form, you could use the :djadmin:`dumpdata` management command.
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Serializing data
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================
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At the highest level, you can serialize data like this::
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from django.core import serializers
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data = serializers.serialize("xml", SomeModel.objects.all())
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The arguments to the ``serialize`` function are the format to serialize the data
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to (see `Serialization formats`_) and a
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:class:`~django.db.models.query.QuerySet` to serialize. (Actually, the second
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argument can be any iterator that yields Django model instances, but it'll
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almost always be a QuerySet).
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.. function:: django.core.serializers.get_serializer(format)
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You can also use a serializer object directly::
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XMLSerializer = serializers.get_serializer("xml")
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xml_serializer = XMLSerializer()
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xml_serializer.serialize(queryset)
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data = xml_serializer.getvalue()
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This is useful if you want to serialize data directly to a file-like object
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(which includes an :class:`~django.http.HttpResponse`)::
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with open("file.xml", "w") as out:
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xml_serializer.serialize(SomeModel.objects.all(), stream=out)
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.. note::
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Calling :func:`~django.core.serializers.get_serializer` with an unknown
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:ref:`format <serialization-formats>` will raise a
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``django.core.serializers.SerializerDoesNotExist`` exception.
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.. _subset-of-fields:
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Subset of fields
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----------------
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If you only want a subset of fields to be serialized, you can
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specify a ``fields`` argument to the serializer::
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from django.core import serializers
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data = serializers.serialize("xml", SomeModel.objects.all(), fields=["name", "size"])
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In this example, only the ``name`` and ``size`` attributes of each model will
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be serialized. The primary key is always serialized as the ``pk`` element in the
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resulting output; it never appears in the ``fields`` part.
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.. note::
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Depending on your model, you may find that it is not possible to
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deserialize a model that only serializes a subset of its fields. If a
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serialized object doesn't specify all the fields that are required by a
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model, the deserializer will not be able to save deserialized instances.
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Inherited models
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----------------
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If you have a model that is defined using an :ref:`abstract base class
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<abstract-base-classes>`, you don't have to do anything special to serialize
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that model. Call the serializer on the object (or objects) that you want to
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serialize, and the output will be a complete representation of the serialized
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object.
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However, if you have a model that uses :ref:`multi-table inheritance
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<multi-table-inheritance>`, you also need to serialize all of the base classes
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for the model. This is because only the fields that are locally defined on the
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model will be serialized. For example, consider the following models::
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class Place(models.Model):
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name = models.CharField(max_length=50)
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class Restaurant(Place):
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serves_hot_dogs = models.BooleanField(default=False)
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If you only serialize the Restaurant model::
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data = serializers.serialize("xml", Restaurant.objects.all())
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the fields on the serialized output will only contain the ``serves_hot_dogs``
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attribute. The ``name`` attribute of the base class will be ignored.
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In order to fully serialize your ``Restaurant`` instances, you will need to
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serialize the ``Place`` models as well::
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all_objects = [*Restaurant.objects.all(), *Place.objects.all()]
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data = serializers.serialize("xml", all_objects)
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Deserializing data
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==================
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Deserializing data is very similar to serializing it::
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for obj in serializers.deserialize("xml", data):
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do_something_with(obj)
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As you can see, the ``deserialize`` function takes the same format argument as
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``serialize``, a string or stream of data, and returns an iterator.
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However, here it gets slightly complicated. The objects returned by the
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``deserialize`` iterator *aren't* regular Django objects. Instead, they are
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special ``DeserializedObject`` instances that wrap a created -- but unsaved --
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object and any associated relationship data.
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Calling ``DeserializedObject.save()`` saves the object to the database.
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.. note::
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If the ``pk`` attribute in the serialized data doesn't exist or is
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null, a new instance will be saved to the database.
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This ensures that deserializing is a non-destructive operation even if the
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data in your serialized representation doesn't match what's currently in the
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database. Usually, working with these ``DeserializedObject`` instances looks
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something like::
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for deserialized_object in serializers.deserialize("xml", data):
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if object_should_be_saved(deserialized_object):
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deserialized_object.save()
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In other words, the usual use is to examine the deserialized objects to make
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sure that they are "appropriate" for saving before doing so. If you trust your
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data source you can instead save the object directly and move on.
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The Django object itself can be inspected as ``deserialized_object.object``.
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If fields in the serialized data do not exist on a model, a
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``DeserializationError`` will be raised unless the ``ignorenonexistent``
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argument is passed in as ``True``::
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serializers.deserialize("xml", data, ignorenonexistent=True)
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.. _serialization-formats:
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Serialization formats
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=====================
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Django supports a number of serialization formats, some of which require you
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to install third-party Python modules:
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========== ==============================================================
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Identifier Information
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========== ==============================================================
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``xml`` Serializes to and from a simple XML dialect.
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``json`` Serializes to and from JSON_.
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``jsonl`` Serializes to and from JSONL_.
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``yaml`` Serializes to YAML (YAML Ain't a Markup Language). This
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serializer is only available if PyYAML_ is installed.
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========== ==============================================================
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.. _json: https://json.org/
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.. _jsonl: https://jsonlines.org/
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.. _PyYAML: https://pyyaml.org/
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XML
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---
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The basic XML serialization format looks like this:
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.. code-block:: xml
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<?xml version="1.0" encoding="utf-8"?>
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<django-objects version="1.0">
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<object pk="123" model="sessions.session">
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<field type="DateTimeField" name="expire_date">2013-01-16T08:16:59.844560+00:00</field>
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<!-- ... -->
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</object>
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</django-objects>
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The whole collection of objects that is either serialized or deserialized is
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represented by a ``<django-objects>``-tag which contains multiple
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``<object>``-elements. Each such object has two attributes: "pk" and "model",
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the latter being represented by the name of the app ("sessions") and the
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lowercase name of the model ("session") separated by a dot.
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Each field of the object is serialized as a ``<field>``-element sporting the
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fields "type" and "name". The text content of the element represents the value
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that should be stored.
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Foreign keys and other relational fields are treated a little bit differently:
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.. code-block:: xml
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<object pk="27" model="auth.permission">
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<!-- ... -->
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<field to="contenttypes.contenttype" name="content_type" rel="ManyToOneRel">9</field>
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<!-- ... -->
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</object>
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In this example we specify that the ``auth.Permission`` object with the PK 27
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has a foreign key to the ``contenttypes.ContentType`` instance with the PK 9.
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ManyToMany-relations are exported for the model that binds them. For instance,
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the ``auth.User`` model has such a relation to the ``auth.Permission`` model:
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.. code-block:: xml
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<object pk="1" model="auth.user">
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<!-- ... -->
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<field to="auth.permission" name="user_permissions" rel="ManyToManyRel">
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<object pk="46"></object>
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<object pk="47"></object>
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</field>
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</object>
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This example links the given user with the permission models with PKs 46 and 47.
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.. admonition:: Control characters
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If the content to be serialized contains control characters that are not
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accepted in the XML 1.0 standard, the serialization will fail with a
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:exc:`ValueError` exception. Read also the W3C's explanation of `HTML,
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XHTML, XML and Control Codes
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<https://www.w3.org/International/questions/qa-controls>`_.
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.. _serialization-formats-json:
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JSON
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----
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When staying with the same example data as before it would be serialized as
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JSON in the following way::
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[
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{
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"pk": "4b678b301dfd8a4e0dad910de3ae245b",
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"model": "sessions.session",
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"fields": {
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"expire_date": "2013-01-16T08:16:59.844Z",
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# ...
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},
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}
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]
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The formatting here is a bit simpler than with XML. The whole collection
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is just represented as an array and the objects are represented by JSON objects
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with three properties: "pk", "model" and "fields". "fields" is again an object
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containing each field's name and value as property and property-value
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respectively.
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Foreign keys have the PK of the linked object as property value.
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ManyToMany-relations are serialized for the model that defines them and are
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represented as a list of PKs.
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Be aware that not all Django output can be passed unmodified to :mod:`json`.
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For example, if you have some custom type in an object to be serialized, you'll
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have to write a custom :mod:`json` encoder for it. Something like this will
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work::
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from django.core.serializers.json import DjangoJSONEncoder
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class LazyEncoder(DjangoJSONEncoder):
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def default(self, obj):
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if isinstance(obj, YourCustomType):
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return str(obj)
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return super().default(obj)
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You can then pass ``cls=LazyEncoder`` to the ``serializers.serialize()``
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function::
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from django.core.serializers import serialize
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serialize("json", SomeModel.objects.all(), cls=LazyEncoder)
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Also note that GeoDjango provides a :doc:`customized GeoJSON serializer
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</ref/contrib/gis/serializers>`.
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``DjangoJSONEncoder``
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~~~~~~~~~~~~~~~~~~~~~
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.. class:: django.core.serializers.json.DjangoJSONEncoder
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The JSON serializer uses ``DjangoJSONEncoder`` for encoding. A subclass of
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:class:`~json.JSONEncoder`, it handles these additional types:
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:class:`~datetime.datetime`
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A string of the form ``YYYY-MM-DDTHH:mm:ss.sssZ`` or
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``YYYY-MM-DDTHH:mm:ss.sss+HH:MM`` as defined in `ECMA-262`_.
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:class:`~datetime.date`
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A string of the form ``YYYY-MM-DD`` as defined in `ECMA-262`_.
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:class:`~datetime.time`
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A string of the form ``HH:MM:ss.sss`` as defined in `ECMA-262`_.
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:class:`~datetime.timedelta`
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A string representing a duration as defined in ISO-8601. For example,
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``timedelta(days=1, hours=2, seconds=3.4)`` is represented as
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``'P1DT02H00M03.400000S'``.
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:class:`~decimal.Decimal`, ``Promise`` (``django.utils.functional.lazy()`` objects), :class:`~uuid.UUID`
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A string representation of the object.
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.. _ecma-262: https://262.ecma-international.org/5.1/#sec-15.9.1.15
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.. _serialization-formats-jsonl:
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JSONL
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-----
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*JSONL* stands for *JSON Lines*. With this format, objects are separated by new
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lines, and each line contains a valid JSON object. JSONL serialized data looks
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like this::
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{"pk": "4b678b301dfd8a4e0dad910de3ae245b", "model": "sessions.session", "fields": {...}}
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{"pk": "88bea72c02274f3c9bf1cb2bb8cee4fc", "model": "sessions.session", "fields": {...}}
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{"pk": "9cf0e26691b64147a67e2a9f06ad7a53", "model": "sessions.session", "fields": {...}}
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JSONL can be useful for populating large databases, since the data can be
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processed line by line, rather than being loaded into memory all at once.
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YAML
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----
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YAML serialization looks quite similar to JSON. The object list is serialized
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as a sequence mappings with the keys "pk", "model" and "fields". Each field is
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again a mapping with the key being name of the field and the value the value:
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.. code-block:: yaml
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- model: sessions.session
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pk: 4b678b301dfd8a4e0dad910de3ae245b
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fields:
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expire_date: 2013-01-16 08:16:59.844560+00:00
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Referential fields are again represented by the PK or sequence of PKs.
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.. _custom-serialization-formats:
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Custom serialization formats
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----------------------------
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In addition to the default formats, you can create a custom serialization
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format.
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For example, let’s consider a csv serializer and deserializer. First, define a
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``Serializer`` and a ``Deserializer`` class. These can override existing
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serialization format classes:
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.. code-block:: python
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:caption: ``path/to/custom_csv_serializer.py``
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import csv
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from django.apps import apps
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from django.core import serializers
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from django.core.serializers.base import DeserializationError
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class Serializer(serializers.python.Serializer):
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def get_dump_object(self, obj):
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dumped_object = super().get_dump_object(obj)
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row = [dumped_object["model"], str(dumped_object["pk"])]
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row += [str(value) for value in dumped_object["fields"].values()]
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return ",".join(row), dumped_object["model"]
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def end_object(self, obj):
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dumped_object_str, model = self.get_dump_object(obj)
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if self.first:
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fields = [field.name for field in apps.get_model(model)._meta.fields]
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header = ",".join(fields)
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self.stream.write(f"model,{header}\n")
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self.stream.write(f"{dumped_object_str}\n")
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def getvalue(self):
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return super(serializers.python.Serializer, self).getvalue()
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class Deserializer(serializers.python.Deserializer):
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def __init__(self, stream_or_string, **options):
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if isinstance(stream_or_string, bytes):
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stream_or_string = stream_or_string.decode()
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if isinstance(stream_or_string, str):
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stream_or_string = stream_or_string.splitlines()
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try:
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objects = csv.DictReader(stream_or_string)
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except Exception as exc:
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raise DeserializationError() from exc
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super().__init__(objects, **options)
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def _handle_object(self, obj):
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try:
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model_fields = apps.get_model(obj["model"])._meta.fields
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obj["fields"] = {
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field.name: obj[field.name]
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for field in model_fields
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if field.name in obj
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}
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yield from super()._handle_object(obj)
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except (GeneratorExit, DeserializationError):
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raise
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except Exception as exc:
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raise DeserializationError(f"Error deserializing object: {exc}") from exc
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Then add the module containing the serializer definitions to your
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:setting:`SERIALIZATION_MODULES` setting::
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SERIALIZATION_MODULES = {
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"csv": "path.to.custom_csv_serializer",
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"json": "django.core.serializers.json",
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}
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.. versionchanged:: 5.2
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A ``Deserializer`` class definition was added to each of the provided
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serialization formats.
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.. _topics-serialization-natural-keys:
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Natural keys
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============
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The default serialization strategy for foreign keys and many-to-many relations
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is to serialize the value of the primary key(s) of the objects in the relation.
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This strategy works well for most objects, but it can cause difficulty in some
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circumstances.
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Consider the case of a list of objects that have a foreign key referencing
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:class:`~django.contrib.contenttypes.models.ContentType`. If you're going to
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serialize an object that refers to a content type, then you need to have a way
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to refer to that content type to begin with. Since ``ContentType`` objects are
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automatically created by Django during the database synchronization process,
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the primary key of a given content type isn't easy to predict; it will
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depend on how and when :djadmin:`migrate` was executed. This is true for all
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models which automatically generate objects, notably including
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:class:`~django.contrib.auth.models.Permission`,
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:class:`~django.contrib.auth.models.Group`, and
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:class:`~django.contrib.auth.models.User`.
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.. warning::
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You should never include automatically generated objects in a fixture or
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other serialized data. By chance, the primary keys in the fixture
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may match those in the database and loading the fixture will
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have no effect. In the more likely case that they don't match, the fixture
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loading will fail with an :class:`~django.db.IntegrityError`.
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There is also the matter of convenience. An integer id isn't always
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the most convenient way to refer to an object; sometimes, a
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more natural reference would be helpful.
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It is for these reasons that Django provides *natural keys*. A natural
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key is a tuple of values that can be used to uniquely identify an
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object instance without using the primary key value.
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Deserialization of natural keys
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-------------------------------
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Consider the following two models::
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from django.db import models
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class Person(models.Model):
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first_name = models.CharField(max_length=100)
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last_name = models.CharField(max_length=100)
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birthdate = models.DateField()
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class Meta:
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constraints = [
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models.UniqueConstraint(
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fields=["first_name", "last_name"],
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name="unique_first_last_name",
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),
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]
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class Book(models.Model):
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name = models.CharField(max_length=100)
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author = models.ForeignKey(Person, on_delete=models.CASCADE)
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Ordinarily, serialized data for ``Book`` would use an integer to refer to
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the author. For example, in JSON, a Book might be serialized as::
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...
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{"pk": 1, "model": "store.book", "fields": {"name": "Mostly Harmless", "author": 42}}
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...
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This isn't a particularly natural way to refer to an author. It
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requires that you know the primary key value for the author; it also
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requires that this primary key value is stable and predictable.
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However, if we add natural key handling to Person, the fixture becomes
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much more humane. To add natural key handling, you define a default
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Manager for Person with a ``get_by_natural_key()`` method. In the case
|
||
of a Person, a good natural key might be the pair of first and last
|
||
name::
|
||
|
||
from django.db import models
|
||
|
||
|
||
class PersonManager(models.Manager):
|
||
def get_by_natural_key(self, first_name, last_name):
|
||
return self.get(first_name=first_name, last_name=last_name)
|
||
|
||
|
||
class Person(models.Model):
|
||
first_name = models.CharField(max_length=100)
|
||
last_name = models.CharField(max_length=100)
|
||
birthdate = models.DateField()
|
||
|
||
objects = PersonManager()
|
||
|
||
class Meta:
|
||
constraints = [
|
||
models.UniqueConstraint(
|
||
fields=["first_name", "last_name"],
|
||
name="unique_first_last_name",
|
||
),
|
||
]
|
||
|
||
Now books can use that natural key to refer to ``Person`` objects::
|
||
|
||
...
|
||
{
|
||
"pk": 1,
|
||
"model": "store.book",
|
||
"fields": {"name": "Mostly Harmless", "author": ["Douglas", "Adams"]},
|
||
}
|
||
...
|
||
|
||
When you try to load this serialized data, Django will use the
|
||
``get_by_natural_key()`` method to resolve ``["Douglas", "Adams"]``
|
||
into the primary key of an actual ``Person`` object.
|
||
|
||
.. note::
|
||
|
||
Whatever fields you use for a natural key must be able to uniquely
|
||
identify an object. This will usually mean that your model will
|
||
have a uniqueness clause (either ``unique=True`` on a single field, or a
|
||
``UniqueConstraint`` or ``unique_together`` over multiple fields) for the
|
||
field or fields in your natural key. However, uniqueness doesn't need to be
|
||
enforced at the database level. If you are certain that a set of fields
|
||
will be effectively unique, you can still use those fields as a natural
|
||
key.
|
||
|
||
Deserialization of objects with no primary key will always check whether the
|
||
model's manager has a ``get_by_natural_key()`` method and if so, use it to
|
||
populate the deserialized object's primary key.
|
||
|
||
Serialization of natural keys
|
||
-----------------------------
|
||
|
||
So how do you get Django to emit a natural key when serializing an object?
|
||
Firstly, you need to add another method -- this time to the model itself::
|
||
|
||
class Person(models.Model):
|
||
first_name = models.CharField(max_length=100)
|
||
last_name = models.CharField(max_length=100)
|
||
birthdate = models.DateField()
|
||
|
||
objects = PersonManager()
|
||
|
||
class Meta:
|
||
constraints = [
|
||
models.UniqueConstraint(
|
||
fields=["first_name", "last_name"],
|
||
name="unique_first_last_name",
|
||
),
|
||
]
|
||
|
||
def natural_key(self):
|
||
return (self.first_name, self.last_name)
|
||
|
||
That method should always return a natural key tuple -- in this
|
||
example, ``(first name, last name)``. Then, when you call
|
||
``serializers.serialize()``, you provide ``use_natural_foreign_keys=True``
|
||
or ``use_natural_primary_keys=True`` arguments:
|
||
|
||
.. code-block:: pycon
|
||
|
||
>>> serializers.serialize(
|
||
... "json",
|
||
... [book1, book2],
|
||
... indent=2,
|
||
... use_natural_foreign_keys=True,
|
||
... use_natural_primary_keys=True,
|
||
... )
|
||
|
||
When ``use_natural_foreign_keys=True`` is specified, Django will use the
|
||
``natural_key()`` method to serialize any foreign key reference to objects
|
||
of the type that defines the method.
|
||
|
||
When ``use_natural_primary_keys=True`` is specified, Django will not provide the
|
||
primary key in the serialized data of this object since it can be calculated
|
||
during deserialization::
|
||
|
||
...
|
||
{
|
||
"model": "store.person",
|
||
"fields": {
|
||
"first_name": "Douglas",
|
||
"last_name": "Adams",
|
||
"birth_date": "1952-03-11",
|
||
},
|
||
}
|
||
...
|
||
|
||
This can be useful when you need to load serialized data into an existing
|
||
database and you cannot guarantee that the serialized primary key value is not
|
||
already in use, and do not need to ensure that deserialized objects retain the
|
||
same primary keys.
|
||
|
||
If you are using :djadmin:`dumpdata` to generate serialized data, use the
|
||
:option:`dumpdata --natural-foreign` and :option:`dumpdata --natural-primary`
|
||
command line flags to generate natural keys.
|
||
|
||
.. note::
|
||
|
||
You don't need to define both ``natural_key()`` and
|
||
``get_by_natural_key()``. If you don't want Django to output
|
||
natural keys during serialization, but you want to retain the
|
||
ability to load natural keys, then you can opt to not implement
|
||
the ``natural_key()`` method.
|
||
|
||
Conversely, if (for some strange reason) you want Django to output
|
||
natural keys during serialization, but *not* be able to load those
|
||
key values, just don't define the ``get_by_natural_key()`` method.
|
||
|
||
.. _natural-keys-and-forward-references:
|
||
|
||
Natural keys and forward references
|
||
-----------------------------------
|
||
|
||
Sometimes when you use :ref:`natural foreign keys
|
||
<topics-serialization-natural-keys>` you'll need to deserialize data where
|
||
an object has a foreign key referencing another object that hasn't yet been
|
||
deserialized. This is called a "forward reference".
|
||
|
||
For instance, suppose you have the following objects in your fixture::
|
||
|
||
...
|
||
{
|
||
"model": "store.book",
|
||
"fields": {"name": "Mostly Harmless", "author": ["Douglas", "Adams"]},
|
||
},
|
||
...
|
||
{"model": "store.person", "fields": {"first_name": "Douglas", "last_name": "Adams"}},
|
||
...
|
||
|
||
In order to handle this situation, you need to pass
|
||
``handle_forward_references=True`` to ``serializers.deserialize()``. This will
|
||
set the ``deferred_fields`` attribute on the ``DeserializedObject`` instances.
|
||
You'll need to keep track of ``DeserializedObject`` instances where this
|
||
attribute isn't ``None`` and later call ``save_deferred_fields()`` on them.
|
||
|
||
Typical usage looks like this::
|
||
|
||
objs_with_deferred_fields = []
|
||
|
||
for obj in serializers.deserialize("xml", data, handle_forward_references=True):
|
||
obj.save()
|
||
if obj.deferred_fields is not None:
|
||
objs_with_deferred_fields.append(obj)
|
||
|
||
for obj in objs_with_deferred_fields:
|
||
obj.save_deferred_fields()
|
||
|
||
For this to work, the ``ForeignKey`` on the referencing model must have
|
||
``null=True``.
|
||
|
||
Dependencies during serialization
|
||
---------------------------------
|
||
|
||
It's often possible to avoid explicitly having to handle forward references by
|
||
taking care with the ordering of objects within a fixture.
|
||
|
||
To help with this, calls to :djadmin:`dumpdata` that use the :option:`dumpdata
|
||
--natural-foreign` option will serialize any model with a ``natural_key()``
|
||
method before serializing standard primary key objects.
|
||
|
||
However, this may not always be enough. If your natural key refers to
|
||
another object (by using a foreign key or natural key to another object
|
||
as part of a natural key), then you need to be able to ensure that
|
||
the objects on which a natural key depends occur in the serialized data
|
||
before the natural key requires them.
|
||
|
||
To control this ordering, you can define dependencies on your
|
||
``natural_key()`` methods. You do this by setting a ``dependencies``
|
||
attribute on the ``natural_key()`` method itself.
|
||
|
||
For example, let's add a natural key to the ``Book`` model from the
|
||
example above::
|
||
|
||
class Book(models.Model):
|
||
name = models.CharField(max_length=100)
|
||
author = models.ForeignKey(Person, on_delete=models.CASCADE)
|
||
|
||
def natural_key(self):
|
||
return (self.name,) + self.author.natural_key()
|
||
|
||
The natural key for a ``Book`` is a combination of its name and its
|
||
author. This means that ``Person`` must be serialized before ``Book``.
|
||
To define this dependency, we add one extra line::
|
||
|
||
def natural_key(self):
|
||
return (self.name,) + self.author.natural_key()
|
||
|
||
|
||
natural_key.dependencies = ["example_app.person"]
|
||
|
||
This definition ensures that all ``Person`` objects are serialized before
|
||
any ``Book`` objects. In turn, any object referencing ``Book`` will be
|
||
serialized after both ``Person`` and ``Book`` have been serialized.
|