9.3 KiB
Validators
Validators can be useful for re-using validation logic between different types of fields.
Most of the time you're dealing with validation in REST framework you'll simply be relying on the default field validation, or writing explicit validation methods on serializer or field classes.
However, sometimes you'll want to place your validation logic into reusable components, so that it can easily be reused throughout your codebase. This can be achieved by using validator functions and validator classes.
## Validation in REST framework
Validation in Django REST framework serializers is handled a little differently to how validation works in Django's ModelForm
class.
With ModelForm
the validation is performed partially on the form, and partially on the model instance. With REST framework the validation is performed entirely on the serializer class. This is advantageous for the following reasons:
- It introduces a proper separation of concerns, making your code behavior more obvious.
- It is easy to switch between using shortcut
ModelSerializer
classes and using explicitSerializer
classes. Any validation behavior being used forModelSerializer
is simple to replicate. - Printing the
repr
of a serializer instance will show you exactly what validation rules it applies. There's no extra hidden validation behavior being called on the model instance.
When you're using ModelSerializer
all of this is handled automatically for you. If you want to drop down to using a Serializer
classes instead, then you need to define the validation rules explicitly.
Example
As an example of how REST framework uses explicit validation, we'll take a simple model class that has a field with a uniqueness constraint.
class CustomerReportRecord(models.Model):
time_raised = models.DateTimeField(default=timezone.now, editable=False)
reference = models.CharField(unique=True, max_length=20)
description = models.TextField()
Here's a basic ModelSerializer
that we can use for creating or updating instances of CustomerReportRecord
:
class CustomerReportSerializer(serializers.ModelSerializer):
class Meta:
model = CustomerReportRecord
If we open up the Django shell using manage.py shell
we can now
>>> from project.example.serializers import CustomerReportSerializer
>>> serializer = CustomerReportSerializer()
>>> print(repr(serializer))
CustomerReportSerializer():
id = IntegerField(label='ID', read_only=True)
time_raised = DateTimeField(read_only=True)
reference = CharField(max_length=20, validators=[<UniqueValidator(queryset=CustomerReportRecord.objects.all())>])
description = CharField(style={'type': 'textarea'})
The interesting bit here is the reference
field. We can see that the uniqueness constraint is being explicitly enforced by a validator on the serializer field.
Because of this more explicit style REST framework includes a few validator classes that are not available in core Django. These classes are detailed below.
UniqueValidator
This validator can be used to enforce the unique=True
constraint on model fields.
It takes a single required argument, and an optional messages
argument:
queryset
required - This is the queryset against which uniqueness should be enforced.message
- The error message that should be used when validation fails.
This validator should be applied to serializer fields, like so:
slug = SlugField(
max_length=100,
validators=[UniqueValidator(queryset=BlogPost.objects.all())]
)
## UniqueTogetherValidator
This validator can be used to enforce unique_together
constraints on model instances.
It has two required arguments, and a single optional messages
argument:
queryset
required - This is the queryset against which uniqueness should be enforced.fields
required - A list or tuple of field names which should make a unique set. These must exist as fields on the serializer class.message
- The error message that should be used when validation fails.
The validator should be applied to serializer classes, like so:
class ExampleSerializer(serializers.Serializer):
# ...
class Meta:
# ToDo items belong to a parent list, and have an ordering defined
# by the 'position' field. No two items in a given list may share
# the same position.
validators = [
UniqueTogetherValidator(
queryset=ToDoItem.objects.all(),
fields=('list', 'position')
)
]
Note: The UniqueTogetherValidation
class always imposes an implicit constraint that all the fields it applies to are always treated as required. Fields with default
values are an exception to this as they always supply a value even when omitted from user input.
UniqueForDateValidator
UniqueForMonthValidator
UniqueForYearValidator
These validators can be used to enforce the unique_for_date
, unique_for_month
and unique_for_year
constraints on model instances. They take the following arguments:
queryset
required - This is the queryset against which uniqueness should be enforced.field
required - A field name against which uniqueness in the given date range will be validated. This must exist as a field on the serializer class.date_field
required - A field name which will be used to determine date range for the uniqueness constrain. This must exist as a field on the serializer class.message
- The error message that should be used when validation fails.
The validator should be applied to serializer classes, like so:
class ExampleSerializer(serializers.Serializer):
# ...
class Meta:
# Blog posts should have a slug that is unique for the current year.
validators = [
UniqueForYearValidator(
queryset=BlogPostItem.objects.all(),
field='slug',
date_field='published'
)
]
The date field that is used for the validation is always required to be present on the serializer class. You can't simply rely on a model class default=...
, because the value being used for the default wouldn't be generated until after the validation has run.
There are a couple of styles you may want to use for this depending on how you want your API to behave. If you're using ModelSerializer
you'll probably simply rely on the defaults that REST framework generates for you, but if you are using Serializer
or simply want more explicit control, use on of the styles demonstrated below.
Using with a writable date field.
If you want the date field to be writable the only thing worth noting is that you should ensure that it is always available in the input data, either by setting a default
argument, or by setting required=True
.
published = serializers.DateTimeField(required=True)
Using with a read-only date field.
If you want the date field to be visible, but not editable by the user, then set read_only=True
and additionally set a default=...
argument.
published = serializers.DateTimeField(read_only=True, default=timezone.now)
The field will not be writable to the user, but the default value will still be passed through to the validated_data
.
Using with a hidden date field.
If you want the date field to be entirely hidden from the user, then use HiddenField
. This field type does not accept user input, but instead always returns it's default value to the validated_data
in the serializer.
published = serializers.HiddenField(default=timezone.now)
Note: The UniqueFor<Range>Validation
classes always imposes an implicit constraint that the fields they are applied to are always treated as required. Fields with default
values are an exception to this as they always supply a value even when omitted from user input.
Writing custom validators
You can use any of Django's existing validators, or write your own custom validators.
Function based
A validator may be any callable that raises a serializers.ValidationError
on failure.
def even_number(value):
if value % 2 != 0:
raise serializers.ValidationError('This field must be an even number.')
Class based
To write a class based validator, use the __call__
method. Class based validators are useful as they allow you to parameterize and reuse behavior.
class MultipleOf:
def __init__(self, base):
self.base = base
def __call__(self, value):
if value % self.base != 0
message = 'This field must be a multiple of %d.' % self.base
raise serializers.ValidationError(message)
Using set_context()
In some advanced cases you might want a validator to be passed the serializer field it is being used with as additional context. You can do so by declaring a set_context
method on a class based validator.
def set_context(self, serializer_field):
# Determine if this is an update or a create operation.
# In `__call__` we can then use that information to modify the validation behavior.
self.is_update = serializer_field.parent.instance is not None