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django1/django/db/models/fields/related.py

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from __future__ import unicode_literals
from operator import attrgetter
from django.apps import apps
from django.core import checks
from django.db import connection, connections, router, transaction
from django.db.backends import utils
from django.db.models import signals, Q
from django.db.models.deletion import SET_NULL, SET_DEFAULT, CASCADE
from django.db.models.fields import (AutoField, Field, IntegerField,
PositiveIntegerField, PositiveSmallIntegerField, FieldDoesNotExist)
from django.db.models.lookups import IsNull
from django.db.models.related import RelatedObject, PathInfo
from django.db.models.query import QuerySet
from django.db.models.sql.datastructures import Col
from django.utils.encoding import smart_text
from django.utils import six
from django.utils.translation import ugettext_lazy as _
from django.utils.functional import curry, cached_property
from django.core import exceptions
from django import forms
RECURSIVE_RELATIONSHIP_CONSTANT = 'self'
def add_lazy_relation(cls, field, relation, operation):
"""
Adds a lookup on ``cls`` when a related field is defined using a string,
i.e.::
class MyModel(Model):
fk = ForeignKey("AnotherModel")
This string can be:
* RECURSIVE_RELATIONSHIP_CONSTANT (i.e. "self") to indicate a recursive
relation.
* The name of a model (i.e "AnotherModel") to indicate another model in
the same app.
* An app-label and model name (i.e. "someapp.AnotherModel") to indicate
another model in a different app.
If the other model hasn't yet been loaded -- almost a given if you're using
lazy relationships -- then the relation won't be set up until the
class_prepared signal fires at the end of model initialization.
operation is the work that must be performed once the relation can be resolved.
"""
# Check for recursive relations
if relation == RECURSIVE_RELATIONSHIP_CONSTANT:
app_label = cls._meta.app_label
model_name = cls.__name__
else:
# Look for an "app.Model" relation
if isinstance(relation, six.string_types):
try:
app_label, model_name = relation.split(".")
except ValueError:
# If we can't split, assume a model in current app
app_label = cls._meta.app_label
model_name = relation
else:
# it's actually a model class
app_label = relation._meta.app_label
model_name = relation._meta.object_name
# Try to look up the related model, and if it's already loaded resolve the
# string right away. If get_model returns None, it means that the related
# model isn't loaded yet, so we need to pend the relation until the class
# is prepared.
try:
model = cls._meta.apps.get_registered_model(app_label, model_name)
except LookupError:
key = (app_label, model_name)
value = (cls, field, operation)
cls._meta.apps._pending_lookups.setdefault(key, []).append(value)
else:
operation(field, model, cls)
def do_pending_lookups(sender, **kwargs):
"""
Handle any pending relations to the sending model. Sent from class_prepared.
"""
key = (sender._meta.app_label, sender.__name__)
for cls, field, operation in sender._meta.apps._pending_lookups.pop(key, []):
operation(field, sender, cls)
signals.class_prepared.connect(do_pending_lookups)
class RelatedField(Field):
def check(self, **kwargs):
errors = super(RelatedField, self).check(**kwargs)
errors.extend(self._check_relation_model_exists())
errors.extend(self._check_referencing_to_swapped_model())
errors.extend(self._check_clashes())
return errors
def _check_relation_model_exists(self):
rel_is_missing = self.rel.to not in apps.get_models()
rel_is_string = isinstance(self.rel.to, six.string_types)
model_name = self.rel.to if rel_is_string else self.rel.to._meta.object_name
if rel_is_missing and (rel_is_string or not self.rel.to._meta.swapped):
return [
checks.Error(
("Field defines a relation with model '%s', which "
"is either not installed, or is abstract.") % model_name,
hint=None,
obj=self,
id='fields.E300',
)
]
return []
def _check_referencing_to_swapped_model(self):
if (self.rel.to not in apps.get_models() and
not isinstance(self.rel.to, six.string_types) and
self.rel.to._meta.swapped):
model = "%s.%s" % (
self.rel.to._meta.app_label,
self.rel.to._meta.object_name
)
return [
checks.Error(
("Field defines a relation with the model '%s', "
"which has been swapped out.") % model,
hint="Update the relation to point at 'settings.%s'." % self.rel.to._meta.swappable,
obj=self,
id='fields.E301',
)
]
return []
def _check_clashes(self):
""" Check accessor and reverse query name clashes. """
from django.db.models.base import ModelBase
errors = []
opts = self.model._meta
# `f.rel.to` may be a string instead of a model. Skip if model name is
# not resolved.
if not isinstance(self.rel.to, ModelBase):
return []
# If the field doesn't install backward relation on the target model (so
# `is_hidden` returns True), then there are no clashes to check and we
# can skip these fields.
if self.rel.is_hidden():
return []
try:
self.related
except AttributeError:
return []
# Consider that we are checking field `Model.foreign` and the models
# are:
#
# class Target(models.Model):
# model = models.IntegerField()
# model_set = models.IntegerField()
#
# class Model(models.Model):
# foreign = models.ForeignKey(Target)
# m2m = models.ManyToManyField(Target)
rel_opts = self.rel.to._meta
# rel_opts.object_name == "Target"
rel_name = self.related.get_accessor_name() # i. e. "model_set"
rel_query_name = self.related_query_name() # i. e. "model"
field_name = "%s.%s" % (opts.object_name,
self.name) # i. e. "Model.field"
# Check clashes between accessor or reverse query name of `field`
# and any other field name -- i. e. accessor for Model.foreign is
# model_set and it clashes with Target.model_set.
potential_clashes = rel_opts.fields + rel_opts.many_to_many
for clash_field in potential_clashes:
clash_name = "%s.%s" % (rel_opts.object_name,
clash_field.name) # i. e. "Target.model_set"
if clash_field.name == rel_name:
errors.append(
checks.Error(
"Reverse accessor for '%s' clashes with field name '%s'." % (field_name, clash_name),
hint=("Rename field '%s', or add/change a related_name "
"argument to the definition for field '%s'.") % (clash_name, field_name),
obj=self,
id='fields.E302',
)
)
if clash_field.name == rel_query_name:
errors.append(
checks.Error(
"Reverse query name for '%s' clashes with field name '%s'." % (field_name, clash_name),
hint=("Rename field '%s', or add/change a related_name "
"argument to the definition for field '%s'.") % (clash_name, field_name),
obj=self,
id='fields.E303',
)
)
# Check clashes between accessors/reverse query names of `field` and
# any other field accessor -- i. e. Model.foreign accessor clashes with
# Model.m2m accessor.
potential_clashes = rel_opts.get_all_related_many_to_many_objects()
potential_clashes += rel_opts.get_all_related_objects()
potential_clashes = (r for r in potential_clashes
if r.field is not self)
for clash_field in potential_clashes:
clash_name = "%s.%s" % ( # i. e. "Model.m2m"
clash_field.model._meta.object_name,
clash_field.field.name)
if clash_field.get_accessor_name() == rel_name:
errors.append(
checks.Error(
"Reverse accessor for '%s' clashes with reverse accessor for '%s'." % (field_name, clash_name),
hint=("Add or change a related_name argument "
"to the definition for '%s' or '%s'.") % (field_name, clash_name),
obj=self,
id='fields.E304',
)
)
if clash_field.get_accessor_name() == rel_query_name:
errors.append(
checks.Error(
"Reverse query name for '%s' clashes with reverse query name for '%s'." % (field_name, clash_name),
hint=("Add or change a related_name argument "
"to the definition for '%s' or '%s'.") % (field_name, clash_name),
obj=self,
id='fields.E305',
)
)
return errors
def db_type(self, connection):
'''By default related field will not have a column
as it relates columns to another table'''
return None
def contribute_to_class(self, cls, name, virtual_only=False):
sup = super(RelatedField, self)
# Store the opts for related_query_name()
self.opts = cls._meta
if hasattr(sup, 'contribute_to_class'):
sup.contribute_to_class(cls, name, virtual_only=virtual_only)
if not cls._meta.abstract and self.rel.related_name:
related_name = self.rel.related_name % {
'class': cls.__name__.lower(),
'app_label': cls._meta.app_label.lower()
}
self.rel.related_name = related_name
other = self.rel.to
if isinstance(other, six.string_types) or other._meta.pk is None:
def resolve_related_class(field, model, cls):
field.rel.to = model
field.do_related_class(model, cls)
add_lazy_relation(cls, self, other, resolve_related_class)
else:
self.do_related_class(other, cls)
@property
def swappable_setting(self):
"""
Gets the setting that this is powered from for swapping, or None
if it's not swapped in / marked with swappable=False.
"""
if self.swappable:
# Work out string form of "to"
if isinstance(self.rel.to, six.string_types):
to_string = self.rel.to
else:
to_string = "%s.%s" % (
self.rel.to._meta.app_label,
self.rel.to._meta.object_name,
)
# See if anything swapped/swappable matches
for model in apps.get_models(include_swapped=True):
if model._meta.swapped:
if model._meta.swapped == to_string:
return model._meta.swappable
if ("%s.%s" % (model._meta.app_label, model._meta.object_name)) == to_string and model._meta.swappable:
return model._meta.swappable
return None
def set_attributes_from_rel(self):
self.name = self.name or (self.rel.to._meta.model_name + '_' + self.rel.to._meta.pk.name)
if self.verbose_name is None:
self.verbose_name = self.rel.to._meta.verbose_name
self.rel.set_field_name()
def do_related_class(self, other, cls):
self.set_attributes_from_rel()
self.related = RelatedObject(other, cls, self)
if not cls._meta.abstract:
self.contribute_to_related_class(other, self.related)
def get_limit_choices_to(self):
"""Returns 'limit_choices_to' for this model field.
If it is a callable, it will be invoked and the result will be
returned.
"""
if callable(self.rel.limit_choices_to):
return self.rel.limit_choices_to()
return self.rel.limit_choices_to
def formfield(self, **kwargs):
"""Passes ``limit_choices_to`` to field being constructed.
Only passes it if there is a type that supports related fields.
This is a similar strategy used to pass the ``queryset`` to the field
being constructed.
"""
defaults = {}
if hasattr(self.rel, 'get_related_field'):
# If this is a callable, do not invoke it here. Just pass
# it in the defaults for when the form class will later be
# instantiated.
limit_choices_to = self.rel.limit_choices_to
defaults.update({
'limit_choices_to': limit_choices_to,
})
defaults.update(kwargs)
return super(RelatedField, self).formfield(**defaults)
def related_query_name(self):
# This method defines the name that can be used to identify this
# related object in a table-spanning query. It uses the lower-cased
# object_name by default, but this can be overridden with the
# "related_name" option.
return self.rel.related_query_name or self.rel.related_name or self.opts.model_name
class SingleRelatedObjectDescriptor(object):
# This class provides the functionality that makes the related-object
# managers available as attributes on a model class, for fields that have
# a single "remote" value, on the class pointed to by a related field.
# In the example "place.restaurant", the restaurant attribute is a
# SingleRelatedObjectDescriptor instance.
def __init__(self, related):
self.related = related
self.cache_name = related.get_cache_name()
@cached_property
def RelatedObjectDoesNotExist(self):
# The exception isn't created at initialization time for the sake of
# consistency with `ReverseSingleRelatedObjectDescriptor`.
return type(
str('RelatedObjectDoesNotExist'),
(self.related.model.DoesNotExist, AttributeError),
{}
)
def is_cached(self, instance):
return hasattr(instance, self.cache_name)
def get_queryset(self, **hints):
# Gotcha: we return a `Manager` instance (i.e. not a `QuerySet`)!
return self.related.model._base_manager.db_manager(hints=hints)
def get_prefetch_queryset(self, instances, queryset=None):
if queryset is None:
# Despite its name `get_queryset()` returns an instance of
# `Manager`, therefore we call `all()` to normalize to `QuerySet`.
queryset = self.get_queryset().all()
queryset._add_hints(instance=instances[0])
rel_obj_attr = attrgetter(self.related.field.attname)
instance_attr = lambda obj: obj._get_pk_val()
instances_dict = dict((instance_attr(inst), inst) for inst in instances)
query = {'%s__in' % self.related.field.name: instances}
queryset = queryset.filter(**query)
# Since we're going to assign directly in the cache,
# we must manage the reverse relation cache manually.
rel_obj_cache_name = self.related.field.get_cache_name()
for rel_obj in queryset:
instance = instances_dict[rel_obj_attr(rel_obj)]
setattr(rel_obj, rel_obj_cache_name, instance)
return queryset, rel_obj_attr, instance_attr, True, self.cache_name
def __get__(self, instance, instance_type=None):
if instance is None:
return self
try:
rel_obj = getattr(instance, self.cache_name)
except AttributeError:
related_pk = instance._get_pk_val()
if related_pk is None:
rel_obj = None
else:
params = {}
for lh_field, rh_field in self.related.field.related_fields:
params['%s__%s' % (self.related.field.name, rh_field.name)] = getattr(instance, rh_field.attname)
try:
rel_obj = self.get_queryset(instance=instance).get(**params)
except self.related.model.DoesNotExist:
rel_obj = None
else:
setattr(rel_obj, self.related.field.get_cache_name(), instance)
setattr(instance, self.cache_name, rel_obj)
if rel_obj is None:
raise self.RelatedObjectDoesNotExist(
"%s has no %s." % (
instance.__class__.__name__,
self.related.get_accessor_name()
)
)
else:
return rel_obj
def __set__(self, instance, value):
# The similarity of the code below to the code in
# ReverseSingleRelatedObjectDescriptor is annoying, but there's a bunch
# of small differences that would make a common base class convoluted.
# If null=True, we can assign null here, but otherwise the value needs
# to be an instance of the related class.
if value is None and self.related.field.null is False:
raise ValueError(
'Cannot assign None: "%s.%s" does not allow null values.' % (
instance._meta.object_name,
self.related.get_accessor_name(),
)
)
elif value is not None and not isinstance(value, self.related.model):
raise ValueError(
'Cannot assign "%r": "%s.%s" must be a "%s" instance.' % (
value,
instance._meta.object_name,
self.related.get_accessor_name(),
self.related.opts.object_name,
)
)
elif value is not None:
if instance._state.db is None:
instance._state.db = router.db_for_write(instance.__class__, instance=value)
elif value._state.db is None:
value._state.db = router.db_for_write(value.__class__, instance=instance)
elif value._state.db is not None and instance._state.db is not None:
if not router.allow_relation(value, instance):
raise ValueError('Cannot assign "%r": the current database router prevents this relation.' % value)
related_pk = tuple(getattr(instance, field.attname) for field in self.related.field.foreign_related_fields)
if None in related_pk:
raise ValueError(
'Cannot assign "%r": "%s" instance isn\'t saved in the database.' %
(value, instance._meta.object_name)
)
# Set the value of the related field to the value of the related object's related field
for index, field in enumerate(self.related.field.local_related_fields):
setattr(value, field.attname, related_pk[index])
# Since we already know what the related object is, seed the related
# object caches now, too. This avoids another db hit if you get the
# object you just set.
setattr(instance, self.cache_name, value)
setattr(value, self.related.field.get_cache_name(), instance)
class ReverseSingleRelatedObjectDescriptor(object):
# This class provides the functionality that makes the related-object
# managers available as attributes on a model class, for fields that have
# a single "remote" value, on the class that defines the related field.
# In the example "choice.poll", the poll attribute is a
# ReverseSingleRelatedObjectDescriptor instance.
def __init__(self, field_with_rel):
self.field = field_with_rel
self.cache_name = self.field.get_cache_name()
@cached_property
def RelatedObjectDoesNotExist(self):
# The exception can't be created at initialization time since the
# related model might not be resolved yet; `rel.to` might still be
# a string model reference.
return type(
str('RelatedObjectDoesNotExist'),
(self.field.rel.to.DoesNotExist, AttributeError),
{}
)
def is_cached(self, instance):
return hasattr(instance, self.cache_name)
def get_queryset(self, **hints):
rel_mgr = self.field.rel.to._default_manager.db_manager(hints=hints)
# If the related manager indicates that it should be used for
# related fields, respect that.
if getattr(rel_mgr, 'use_for_related_fields', False):
# Gotcha: we return a `Manager` instance (i.e. not a `QuerySet`)!
return rel_mgr
else:
return QuerySet(self.field.rel.to, hints=hints)
def get_prefetch_queryset(self, instances, queryset=None):
if queryset is None:
# Despite its name `get_queryset()` may return an instance of
# `Manager`, therefore we call `all()` to normalize to `QuerySet`.
queryset = self.get_queryset().all()
queryset._add_hints(instance=instances[0])
rel_obj_attr = self.field.get_foreign_related_value
instance_attr = self.field.get_local_related_value
instances_dict = dict((instance_attr(inst), inst) for inst in instances)
related_field = self.field.foreign_related_fields[0]
# FIXME: This will need to be revisited when we introduce support for
# composite fields. In the meantime we take this practical approach to
# solve a regression on 1.6 when the reverse manager in hidden
# (related_name ends with a '+'). Refs #21410.
# The check for len(...) == 1 is a special case that allows the query
# to be join-less and smaller. Refs #21760.
if self.field.rel.is_hidden() or len(self.field.foreign_related_fields) == 1:
query = {'%s__in' % related_field.name: set(instance_attr(inst)[0] for inst in instances)}
else:
query = {'%s__in' % self.field.related_query_name(): instances}
queryset = queryset.filter(**query)
# Since we're going to assign directly in the cache,
# we must manage the reverse relation cache manually.
if not self.field.rel.multiple:
rel_obj_cache_name = self.field.related.get_cache_name()
for rel_obj in queryset:
instance = instances_dict[rel_obj_attr(rel_obj)]
setattr(rel_obj, rel_obj_cache_name, instance)
return queryset, rel_obj_attr, instance_attr, True, self.cache_name
def __get__(self, instance, instance_type=None):
if instance is None:
return self
try:
rel_obj = getattr(instance, self.cache_name)
except AttributeError:
val = self.field.get_local_related_value(instance)
if None in val:
rel_obj = None
else:
params = dict(
(rh_field.attname, getattr(instance, lh_field.attname))
for lh_field, rh_field in self.field.related_fields)
qs = self.get_queryset(instance=instance)
extra_filter = self.field.get_extra_descriptor_filter(instance)
if isinstance(extra_filter, dict):
params.update(extra_filter)
qs = qs.filter(**params)
else:
qs = qs.filter(extra_filter, **params)
# Assuming the database enforces foreign keys, this won't fail.
rel_obj = qs.get()
if not self.field.rel.multiple:
setattr(rel_obj, self.field.related.get_cache_name(), instance)
setattr(instance, self.cache_name, rel_obj)
if rel_obj is None and not self.field.null:
raise self.RelatedObjectDoesNotExist(
"%s has no %s." % (self.field.model.__name__, self.field.name)
)
else:
return rel_obj
def __set__(self, instance, value):
# If null=True, we can assign null here, but otherwise the value needs
# to be an instance of the related class.
if value is None and self.field.null is False:
raise ValueError(
'Cannot assign None: "%s.%s" does not allow null values.' %
(instance._meta.object_name, self.field.name)
)
elif value is not None and not isinstance(value, self.field.rel.to):
raise ValueError(
'Cannot assign "%r": "%s.%s" must be a "%s" instance.' % (
value,
instance._meta.object_name,
self.field.name,
self.field.rel.to._meta.object_name,
)
)
elif value is not None:
if instance._state.db is None:
instance._state.db = router.db_for_write(instance.__class__, instance=value)
elif value._state.db is None:
value._state.db = router.db_for_write(value.__class__, instance=instance)
elif value._state.db is not None and instance._state.db is not None:
if not router.allow_relation(value, instance):
raise ValueError('Cannot assign "%r": the current database router prevents this relation.' % value)
# If we're setting the value of a OneToOneField to None, we need to clear
# out the cache on any old related object. Otherwise, deleting the
# previously-related object will also cause this object to be deleted,
# which is wrong.
if value is None:
# Look up the previously-related object, which may still be available
# since we've not yet cleared out the related field.
# Use the cache directly, instead of the accessor; if we haven't
# populated the cache, then we don't care - we're only accessing
# the object to invalidate the accessor cache, so there's no
# need to populate the cache just to expire it again.
related = getattr(instance, self.cache_name, None)
# If we've got an old related object, we need to clear out its
# cache. This cache also might not exist if the related object
# hasn't been accessed yet.
if related is not None:
setattr(related, self.field.related.get_cache_name(), None)
for lh_field, rh_field in self.field.related_fields:
setattr(instance, lh_field.attname, None)
# Set the values of the related field.
else:
for lh_field, rh_field in self.field.related_fields:
pk = value._get_pk_val()
if pk is None:
raise ValueError(
'Cannot assign "%r": "%s" instance isn\'t saved in the database.' %
(value, self.field.rel.to._meta.object_name)
)
setattr(instance, lh_field.attname, getattr(value, rh_field.attname))
# Since we already know what the related object is, seed the related
# object caches now, too. This avoids another db hit if you get the
# object you just set.
setattr(instance, self.cache_name, value)
if value is not None and not self.field.rel.multiple:
setattr(value, self.field.related.get_cache_name(), instance)
def create_foreign_related_manager(superclass, rel_field, rel_model):
class RelatedManager(superclass):
def __init__(self, instance):
super(RelatedManager, self).__init__()
self.instance = instance
self.core_filters = {'%s__exact' % rel_field.name: instance}
self.model = rel_model
def __call__(self, **kwargs):
# We use **kwargs rather than a kwarg argument to enforce the
# `manager='manager_name'` syntax.
manager = getattr(self.model, kwargs.pop('manager'))
manager_class = create_foreign_related_manager(manager.__class__, rel_field, rel_model)
return manager_class(self.instance)
do_not_call_in_templates = True
def get_queryset(self):
try:
return self.instance._prefetched_objects_cache[rel_field.related_query_name()]
except (AttributeError, KeyError):
db = self._db or router.db_for_read(self.model, instance=self.instance)
empty_strings_as_null = connections[db].features.interprets_empty_strings_as_nulls
qs = super(RelatedManager, self).get_queryset()
qs._add_hints(instance=self.instance)
if self._db:
qs = qs.using(self._db)
qs = qs.filter(**self.core_filters)
for field in rel_field.foreign_related_fields:
val = getattr(self.instance, field.attname)
if val is None or (val == '' and empty_strings_as_null):
return qs.none()
qs._known_related_objects = {rel_field: {self.instance.pk: self.instance}}
return qs
def get_prefetch_queryset(self, instances, queryset=None):
if queryset is None:
queryset = super(RelatedManager, self).get_queryset()
queryset._add_hints(instance=instances[0])
queryset = queryset.using(queryset._db or self._db)
rel_obj_attr = rel_field.get_local_related_value
instance_attr = rel_field.get_foreign_related_value
instances_dict = dict((instance_attr(inst), inst) for inst in instances)
query = {'%s__in' % rel_field.name: instances}
queryset = queryset.filter(**query)
# Since we just bypassed this class' get_queryset(), we must manage
# the reverse relation manually.
for rel_obj in queryset:
instance = instances_dict[rel_obj_attr(rel_obj)]
setattr(rel_obj, rel_field.name, instance)
cache_name = rel_field.related_query_name()
return queryset, rel_obj_attr, instance_attr, False, cache_name
def add(self, *objs):
objs = list(objs)
db = router.db_for_write(self.model, instance=self.instance)
with transaction.atomic(using=db, savepoint=False):
for obj in objs:
if not isinstance(obj, self.model):
raise TypeError("'%s' instance expected, got %r" %
(self.model._meta.object_name, obj))
setattr(obj, rel_field.name, self.instance)
obj.save()
add.alters_data = True
def create(self, **kwargs):
kwargs[rel_field.name] = self.instance
db = router.db_for_write(self.model, instance=self.instance)
return super(RelatedManager, self.db_manager(db)).create(**kwargs)
create.alters_data = True
def get_or_create(self, **kwargs):
# Update kwargs with the related object that this
# ForeignRelatedObjectsDescriptor knows about.
kwargs[rel_field.name] = self.instance
db = router.db_for_write(self.model, instance=self.instance)
return super(RelatedManager, self.db_manager(db)).get_or_create(**kwargs)
get_or_create.alters_data = True
# remove() and clear() are only provided if the ForeignKey can have a value of null.
if rel_field.null:
def remove(self, *objs, **kwargs):
if not objs:
return
bulk = kwargs.pop('bulk', True)
val = rel_field.get_foreign_related_value(self.instance)
old_ids = set()
for obj in objs:
# Is obj actually part of this descriptor set?
if rel_field.get_local_related_value(obj) == val:
old_ids.add(obj.pk)
else:
raise rel_field.rel.to.DoesNotExist("%r is not related to %r." % (obj, self.instance))
self._clear(self.filter(pk__in=old_ids), bulk)
remove.alters_data = True
def clear(self, **kwargs):
bulk = kwargs.pop('bulk', True)
self._clear(self, bulk)
clear.alters_data = True
def _clear(self, queryset, bulk):
db = router.db_for_write(self.model, instance=self.instance)
queryset = queryset.using(db)
if bulk:
# `QuerySet.update()` is intrinsically atomic.
queryset.update(**{rel_field.name: None})
else:
with transaction.atomic(using=db, savepoint=False):
for obj in queryset:
setattr(obj, rel_field.name, None)
obj.save(update_fields=[rel_field.name])
_clear.alters_data = True
return RelatedManager
class ForeignRelatedObjectsDescriptor(object):
# This class provides the functionality that makes the related-object
# managers available as attributes on a model class, for fields that have
# multiple "remote" values and have a ForeignKey pointed at them by
# some other model. In the example "poll.choice_set", the choice_set
# attribute is a ForeignRelatedObjectsDescriptor instance.
def __init__(self, related):
self.related = related # RelatedObject instance
def __get__(self, instance, instance_type=None):
if instance is None:
return self
return self.related_manager_cls(instance)
def __set__(self, instance, value):
# Force evaluation of `value` in case it's a queryset whose
# value could be affected by `manager.clear()`. Refs #19816.
value = tuple(value)
manager = self.__get__(instance)
db = router.db_for_write(manager.model, instance=manager.instance)
with transaction.atomic(using=db, savepoint=False):
# If the foreign key can support nulls, then completely clear the related set.
# Otherwise, just move the named objects into the set.
if self.related.field.null:
manager.clear()
manager.add(*value)
@cached_property
def related_manager_cls(self):
# Dynamically create a class that subclasses the related model's default
# manager.
return create_foreign_related_manager(
self.related.model._default_manager.__class__,
self.related.field,
self.related.model,
)
def create_many_related_manager(superclass, rel):
"""Creates a manager that subclasses 'superclass' (which is a Manager)
and adds behavior for many-to-many related objects."""
class ManyRelatedManager(superclass):
def __init__(self, model=None, query_field_name=None, instance=None, symmetrical=None,
source_field_name=None, target_field_name=None, reverse=False,
through=None, prefetch_cache_name=None):
super(ManyRelatedManager, self).__init__()
self.model = model
self.query_field_name = query_field_name
source_field = through._meta.get_field(source_field_name)
source_related_fields = source_field.related_fields
self.core_filters = {}
for lh_field, rh_field in source_related_fields:
self.core_filters['%s__%s' % (query_field_name, rh_field.name)] = getattr(instance, rh_field.attname)
self.instance = instance
self.symmetrical = symmetrical
self.source_field = source_field
self.target_field = through._meta.get_field(target_field_name)
self.source_field_name = source_field_name
self.target_field_name = target_field_name
self.reverse = reverse
self.through = through
self.prefetch_cache_name = prefetch_cache_name
self.related_val = source_field.get_foreign_related_value(instance)
if None in self.related_val:
raise ValueError('"%r" needs to have a value for field "%s" before '
'this many-to-many relationship can be used.' %
(instance, source_field_name))
# Even if this relation is not to pk, we require still pk value.
# The wish is that the instance has been already saved to DB,
# although having a pk value isn't a guarantee of that.
if instance.pk is None:
raise ValueError("%r instance needs to have a primary key value before "
"a many-to-many relationship can be used." %
instance.__class__.__name__)
def __call__(self, **kwargs):
# We use **kwargs rather than a kwarg argument to enforce the
# `manager='manager_name'` syntax.
manager = getattr(self.model, kwargs.pop('manager'))
manager_class = create_many_related_manager(manager.__class__, rel)
return manager_class(
model=self.model,
query_field_name=self.query_field_name,
instance=self.instance,
symmetrical=self.symmetrical,
source_field_name=self.source_field_name,
target_field_name=self.target_field_name,
reverse=self.reverse,
through=self.through,
prefetch_cache_name=self.prefetch_cache_name,
)
do_not_call_in_templates = True
def _build_remove_filters(self, removed_vals):
filters = Q(**{self.source_field_name: self.related_val})
# No need to add a subquery condition if removed_vals is a QuerySet without
# filters.
removed_vals_filters = (not isinstance(removed_vals, QuerySet) or
removed_vals._has_filters())
if removed_vals_filters:
filters &= Q(**{'%s__in' % self.target_field_name: removed_vals})
if self.symmetrical:
symmetrical_filters = Q(**{self.target_field_name: self.related_val})
if removed_vals_filters:
symmetrical_filters &= Q(
**{'%s__in' % self.source_field_name: removed_vals})
filters |= symmetrical_filters
return filters
def get_queryset(self):
try:
return self.instance._prefetched_objects_cache[self.prefetch_cache_name]
except (AttributeError, KeyError):
qs = super(ManyRelatedManager, self).get_queryset()
qs._add_hints(instance=self.instance)
if self._db:
qs = qs.using(self._db)
return qs._next_is_sticky().filter(**self.core_filters)
def get_prefetch_queryset(self, instances, queryset=None):
if queryset is None:
queryset = super(ManyRelatedManager, self).get_queryset()
queryset._add_hints(instance=instances[0])
queryset = queryset.using(queryset._db or self._db)
query = {'%s__in' % self.query_field_name: instances}
queryset = queryset._next_is_sticky().filter(**query)
# M2M: need to annotate the query in order to get the primary model
# that the secondary model was actually related to. We know that
# there will already be a join on the join table, so we can just add
# the select.
# For non-autocreated 'through' models, can't assume we are
# dealing with PK values.
fk = self.through._meta.get_field(self.source_field_name)
join_table = self.through._meta.db_table
connection = connections[queryset.db]
qn = connection.ops.quote_name
queryset = queryset.extra(select=dict(
('_prefetch_related_val_%s' % f.attname,
'%s.%s' % (qn(join_table), qn(f.column))) for f in fk.local_related_fields))
return (queryset,
lambda result: tuple(getattr(result, '_prefetch_related_val_%s' % f.attname) for f in fk.local_related_fields),
lambda inst: tuple(getattr(inst, f.attname) for f in fk.foreign_related_fields),
False,
self.prefetch_cache_name)
def add(self, *objs):
if not rel.through._meta.auto_created:
opts = self.through._meta
raise AttributeError(
"Cannot use add() on a ManyToManyField which specifies an intermediary model. Use %s.%s's Manager instead." %
(opts.app_label, opts.object_name)
)
db = router.db_for_write(self.through, instance=self.instance)
with transaction.atomic(using=db, savepoint=False):
self._add_items(self.source_field_name, self.target_field_name, *objs)
# If this is a symmetrical m2m relation to self, add the mirror entry in the m2m table
if self.symmetrical:
self._add_items(self.target_field_name, self.source_field_name, *objs)
add.alters_data = True
def remove(self, *objs):
if not rel.through._meta.auto_created:
opts = self.through._meta
raise AttributeError(
"Cannot use remove() on a ManyToManyField which specifies an intermediary model. Use %s.%s's Manager instead." %
(opts.app_label, opts.object_name)
)
self._remove_items(self.source_field_name, self.target_field_name, *objs)
remove.alters_data = True
def clear(self):
db = router.db_for_write(self.through, instance=self.instance)
with transaction.atomic(using=db, savepoint=False):
signals.m2m_changed.send(sender=self.through, action="pre_clear",
instance=self.instance, reverse=self.reverse,
model=self.model, pk_set=None, using=db)
filters = self._build_remove_filters(super(ManyRelatedManager, self).get_queryset().using(db))
self.through._default_manager.using(db).filter(filters).delete()
signals.m2m_changed.send(sender=self.through, action="post_clear",
instance=self.instance, reverse=self.reverse,
model=self.model, pk_set=None, using=db)
clear.alters_data = True
def create(self, **kwargs):
# This check needs to be done here, since we can't later remove this
# from the method lookup table, as we do with add and remove.
if not self.through._meta.auto_created:
opts = self.through._meta
raise AttributeError(
"Cannot use create() on a ManyToManyField which specifies an intermediary model. Use %s.%s's Manager instead." %
(opts.app_label, opts.object_name)
)
db = router.db_for_write(self.instance.__class__, instance=self.instance)
new_obj = super(ManyRelatedManager, self.db_manager(db)).create(**kwargs)
self.add(new_obj)
return new_obj
create.alters_data = True
def get_or_create(self, **kwargs):
db = router.db_for_write(self.instance.__class__, instance=self.instance)
obj, created = \
super(ManyRelatedManager, self.db_manager(db)).get_or_create(**kwargs)
# We only need to add() if created because if we got an object back
# from get() then the relationship already exists.
if created:
self.add(obj)
return obj, created
get_or_create.alters_data = True
def _add_items(self, source_field_name, target_field_name, *objs):
# source_field_name: the PK fieldname in join table for the source object
# target_field_name: the PK fieldname in join table for the target object
# *objs - objects to add. Either object instances, or primary keys of object instances.
# If there aren't any objects, there is nothing to do.
from django.db.models import Model
if objs:
new_ids = set()
for obj in objs:
if isinstance(obj, self.model):
if not router.allow_relation(obj, self.instance):
raise ValueError(
'Cannot add "%r": instance is on database "%s", value is on database "%s"' %
(obj, self.instance._state.db, obj._state.db)
)
fk_val = self.through._meta.get_field(
target_field_name).get_foreign_related_value(obj)[0]
if fk_val is None:
raise ValueError(
'Cannot add "%r": the value for field "%s" is None' %
(obj, target_field_name)
)
new_ids.add(fk_val)
elif isinstance(obj, Model):
raise TypeError(
"'%s' instance expected, got %r" %
(self.model._meta.object_name, obj)
)
else:
new_ids.add(obj)
db = router.db_for_write(self.through, instance=self.instance)
vals = (self.through._default_manager.using(db)
.values_list(target_field_name, flat=True)
.filter(**{
source_field_name: self.related_val[0],
'%s__in' % target_field_name: new_ids,
}))
new_ids = new_ids - set(vals)
with transaction.atomic(using=db, savepoint=False):
if self.reverse or source_field_name == self.source_field_name:
# Don't send the signal when we are inserting the
# duplicate data row for symmetrical reverse entries.
signals.m2m_changed.send(sender=self.through, action='pre_add',
instance=self.instance, reverse=self.reverse,
model=self.model, pk_set=new_ids, using=db)
# Add the ones that aren't there already
self.through._default_manager.using(db).bulk_create([
self.through(**{
'%s_id' % source_field_name: self.related_val[0],
'%s_id' % target_field_name: obj_id,
})
for obj_id in new_ids
])
if self.reverse or source_field_name == self.source_field_name:
# Don't send the signal when we are inserting the
# duplicate data row for symmetrical reverse entries.
signals.m2m_changed.send(sender=self.through, action='post_add',
instance=self.instance, reverse=self.reverse,
model=self.model, pk_set=new_ids, using=db)
def _remove_items(self, source_field_name, target_field_name, *objs):
# source_field_name: the PK colname in join table for the source object
# target_field_name: the PK colname in join table for the target object
# *objs - objects to remove
if not objs:
return
# Check that all the objects are of the right type
old_ids = set()
for obj in objs:
if isinstance(obj, self.model):
fk_val = self.target_field.get_foreign_related_value(obj)[0]
old_ids.add(fk_val)
else:
old_ids.add(obj)
db = router.db_for_write(self.through, instance=self.instance)
with transaction.atomic(using=db, savepoint=False):
# Send a signal to the other end if need be.
signals.m2m_changed.send(sender=self.through, action="pre_remove",
instance=self.instance, reverse=self.reverse,
model=self.model, pk_set=old_ids, using=db)
target_model_qs = super(ManyRelatedManager, self).get_queryset()
if target_model_qs._has_filters():
old_vals = target_model_qs.using(db).filter(**{
'%s__in' % self.target_field.related_field.attname: old_ids})
else:
old_vals = old_ids
filters = self._build_remove_filters(old_vals)
self.through._default_manager.using(db).filter(filters).delete()
signals.m2m_changed.send(sender=self.through, action="post_remove",
instance=self.instance, reverse=self.reverse,
model=self.model, pk_set=old_ids, using=db)
return ManyRelatedManager
class ManyRelatedObjectsDescriptor(object):
# This class provides the functionality that makes the related-object
# managers available as attributes on a model class, for fields that have
# multiple "remote" values and have a ManyToManyField pointed at them by
# some other model (rather than having a ManyToManyField themselves).
# In the example "publication.article_set", the article_set attribute is a
# ManyRelatedObjectsDescriptor instance.
def __init__(self, related):
self.related = related # RelatedObject instance
@cached_property
def related_manager_cls(self):
# Dynamically create a class that subclasses the related
# model's default manager.
return create_many_related_manager(
self.related.model._default_manager.__class__,
self.related.field.rel
)
def __get__(self, instance, instance_type=None):
if instance is None:
return self
rel_model = self.related.model
manager = self.related_manager_cls(
model=rel_model,
query_field_name=self.related.field.name,
prefetch_cache_name=self.related.field.related_query_name(),
instance=instance,
symmetrical=False,
source_field_name=self.related.field.m2m_reverse_field_name(),
target_field_name=self.related.field.m2m_field_name(),
reverse=True,
through=self.related.field.rel.through,
)
return manager
def __set__(self, instance, value):
if not self.related.field.rel.through._meta.auto_created:
opts = self.related.field.rel.through._meta
raise AttributeError("Cannot set values on a ManyToManyField which specifies an intermediary model. Use %s.%s's Manager instead." % (opts.app_label, opts.object_name))
# Force evaluation of `value` in case it's a queryset whose
# value could be affected by `manager.clear()`. Refs #19816.
value = tuple(value)
manager = self.__get__(instance)
db = router.db_for_write(manager.through, instance=manager.instance)
with transaction.atomic(using=db, savepoint=False):
manager.clear()
manager.add(*value)
class ReverseManyRelatedObjectsDescriptor(object):
# This class provides the functionality that makes the related-object
# managers available as attributes on a model class, for fields that have
# multiple "remote" values and have a ManyToManyField defined in their
# model (rather than having another model pointed *at* them).
# In the example "article.publications", the publications attribute is a
# ReverseManyRelatedObjectsDescriptor instance.
def __init__(self, m2m_field):
self.field = m2m_field
@property
def through(self):
# through is provided so that you have easy access to the through
# model (Book.authors.through) for inlines, etc. This is done as
# a property to ensure that the fully resolved value is returned.
return self.field.rel.through
@cached_property
def related_manager_cls(self):
# Dynamically create a class that subclasses the related model's
# default manager.
return create_many_related_manager(
self.field.rel.to._default_manager.__class__,
self.field.rel
)
def __get__(self, instance, instance_type=None):
if instance is None:
return self
manager = self.related_manager_cls(
model=self.field.rel.to,
query_field_name=self.field.related_query_name(),
prefetch_cache_name=self.field.name,
instance=instance,
symmetrical=self.field.rel.symmetrical,
source_field_name=self.field.m2m_field_name(),
target_field_name=self.field.m2m_reverse_field_name(),
reverse=False,
through=self.field.rel.through,
)
return manager
def __set__(self, instance, value):
if not self.field.rel.through._meta.auto_created:
opts = self.field.rel.through._meta
raise AttributeError("Cannot set values on a ManyToManyField which specifies an intermediary model. Use %s.%s's Manager instead." % (opts.app_label, opts.object_name))
# Force evaluation of `value` in case it's a queryset whose
# value could be affected by `manager.clear()`. Refs #19816.
value = tuple(value)
manager = self.__get__(instance)
db = router.db_for_write(manager.through, instance=manager.instance)
with transaction.atomic(using=db, savepoint=False):
manager.clear()
manager.add(*value)
class ForeignObjectRel(object):
def __init__(self, field, to, related_name=None, limit_choices_to=None,
parent_link=False, on_delete=None, related_query_name=None):
try:
to._meta
except AttributeError: # to._meta doesn't exist, so it must be RECURSIVE_RELATIONSHIP_CONSTANT
assert isinstance(to, six.string_types), "'to' must be either a model, a model name or the string %r" % RECURSIVE_RELATIONSHIP_CONSTANT
self.field = field
self.to = to
self.related_name = related_name
self.related_query_name = related_query_name
self.limit_choices_to = {} if limit_choices_to is None else limit_choices_to
self.multiple = True
self.parent_link = parent_link
self.on_delete = on_delete
def is_hidden(self):
"Should the related object be hidden?"
return self.related_name and self.related_name[-1] == '+'
def get_joining_columns(self):
return self.field.get_reverse_joining_columns()
def get_extra_restriction(self, where_class, alias, related_alias):
return self.field.get_extra_restriction(where_class, related_alias, alias)
def set_field_name(self):
"""
Sets the related field's name, this is not available until later stages
of app loading, so set_field_name is called from
set_attributes_from_rel()
"""
# By default foreign object doesn't relate to any remote field (for
# example custom multicolumn joins currently have no remote field).
self.field_name = None
def get_lookup_constraint(self, constraint_class, alias, targets, sources, lookup_type,
raw_value):
return self.field.get_lookup_constraint(constraint_class, alias, targets, sources,
lookup_type, raw_value)
class ManyToOneRel(ForeignObjectRel):
def __init__(self, field, to, field_name, related_name=None, limit_choices_to=None,
parent_link=False, on_delete=None, related_query_name=None):
super(ManyToOneRel, self).__init__(
field, to, related_name=related_name, limit_choices_to=limit_choices_to,
parent_link=parent_link, on_delete=on_delete, related_query_name=related_query_name)
self.field_name = field_name
def get_related_field(self):
"""
Returns the Field in the 'to' object to which this relationship is
tied.
"""
data = self.to._meta.get_field_by_name(self.field_name)
if not data[2]:
raise FieldDoesNotExist("No related field named '%s'" %
self.field_name)
return data[0]
def set_field_name(self):
self.field_name = self.field_name or self.to._meta.pk.name
class OneToOneRel(ManyToOneRel):
def __init__(self, field, to, field_name, related_name=None, limit_choices_to=None,
parent_link=False, on_delete=None, related_query_name=None):
super(OneToOneRel, self).__init__(field, to, field_name,
related_name=related_name, limit_choices_to=limit_choices_to,
parent_link=parent_link, on_delete=on_delete, related_query_name=related_query_name)
self.multiple = False
class ManyToManyRel(object):
def __init__(self, to, related_name=None, limit_choices_to=None,
symmetrical=True, through=None, through_fields=None,
db_constraint=True, related_query_name=None):
if through and not db_constraint:
raise ValueError("Can't supply a through model and db_constraint=False")
if through_fields and not through:
raise ValueError("Cannot specify through_fields without a through model")
self.to = to
self.related_name = related_name
self.related_query_name = related_query_name
if limit_choices_to is None:
limit_choices_to = {}
self.limit_choices_to = limit_choices_to
self.symmetrical = symmetrical
self.multiple = True
self.through = through
self.through_fields = through_fields
self.db_constraint = db_constraint
def is_hidden(self):
"Should the related object be hidden?"
return self.related_name and self.related_name[-1] == '+'
def get_related_field(self):
"""
Returns the field in the to' object to which this relationship is tied
(this is always the primary key on the target model). Provided for
symmetry with ManyToOneRel.
"""
return self.to._meta.pk
class ForeignObject(RelatedField):
requires_unique_target = True
generate_reverse_relation = True
related_accessor_class = ForeignRelatedObjectsDescriptor
def __init__(self, to, from_fields, to_fields, swappable=True, **kwargs):
self.from_fields = from_fields
self.to_fields = to_fields
self.swappable = swappable
if 'rel' not in kwargs:
kwargs['rel'] = ForeignObjectRel(
self, to,
related_name=kwargs.pop('related_name', None),
related_query_name=kwargs.pop('related_query_name', None),
limit_choices_to=kwargs.pop('limit_choices_to', None),
parent_link=kwargs.pop('parent_link', False),
on_delete=kwargs.pop('on_delete', CASCADE),
)
kwargs['verbose_name'] = kwargs.get('verbose_name', None)
super(ForeignObject, self).__init__(**kwargs)
def check(self, **kwargs):
errors = super(ForeignObject, self).check(**kwargs)
errors.extend(self._check_unique_target())
return errors
def _check_unique_target(self):
rel_is_string = isinstance(self.rel.to, six.string_types)
if rel_is_string or not self.requires_unique_target:
return []
# Skip if the
try:
self.foreign_related_fields
except FieldDoesNotExist:
return []
try:
self.related
except AttributeError:
return []
has_unique_field = any(rel_field.unique
for rel_field in self.foreign_related_fields)
if not has_unique_field and len(self.foreign_related_fields) > 1:
field_combination = ', '.join("'%s'" % rel_field.name
for rel_field in self.foreign_related_fields)
model_name = self.rel.to.__name__
return [
checks.Error(
"None of the fields %s on model '%s' have a unique=True constraint." % (field_combination, model_name),
hint=None,
obj=self,
id='fields.E310',
)
]
elif not has_unique_field:
field_name = self.foreign_related_fields[0].name
model_name = self.rel.to.__name__
return [
checks.Error(
("'%s.%s' must set unique=True "
"because it is referenced by a foreign key.") % (model_name, field_name),
hint=None,
obj=self,
id='fields.E311',
)
]
else:
return []
def deconstruct(self):
name, path, args, kwargs = super(ForeignObject, self).deconstruct()
kwargs['from_fields'] = self.from_fields
kwargs['to_fields'] = self.to_fields
if self.rel.related_name is not None:
kwargs['related_name'] = self.rel.related_name
if self.rel.related_query_name is not None:
kwargs['related_query_name'] = self.rel.related_query_name
if self.rel.on_delete != CASCADE:
kwargs['on_delete'] = self.rel.on_delete
if self.rel.parent_link:
kwargs['parent_link'] = self.rel.parent_link
# Work out string form of "to"
if isinstance(self.rel.to, six.string_types):
kwargs['to'] = self.rel.to
else:
kwargs['to'] = "%s.%s" % (self.rel.to._meta.app_label, self.rel.to._meta.object_name)
# If swappable is True, then see if we're actually pointing to the target
# of a swap.
swappable_setting = self.swappable_setting
if swappable_setting is not None:
# If it's already a settings reference, error
if hasattr(kwargs['to'], "setting_name"):
if kwargs['to'].setting_name != swappable_setting:
raise ValueError("Cannot deconstruct a ForeignKey pointing to a model that is swapped in place of more than one model (%s and %s)" % (kwargs['to'].setting_name, swappable_setting))
# Set it
from django.db.migrations.writer import SettingsReference
kwargs['to'] = SettingsReference(
kwargs['to'],
swappable_setting,
)
return name, path, args, kwargs
def resolve_related_fields(self):
if len(self.from_fields) < 1 or len(self.from_fields) != len(self.to_fields):
raise ValueError('Foreign Object from and to fields must be the same non-zero length')
if isinstance(self.rel.to, six.string_types):
raise ValueError('Related model %r cannot be resolved' % self.rel.to)
related_fields = []
for index in range(len(self.from_fields)):
from_field_name = self.from_fields[index]
to_field_name = self.to_fields[index]
from_field = (self if from_field_name == 'self'
else self.opts.get_field_by_name(from_field_name)[0])
to_field = (self.rel.to._meta.pk if to_field_name is None
else self.rel.to._meta.get_field_by_name(to_field_name)[0])
related_fields.append((from_field, to_field))
return related_fields
@property
def related_fields(self):
if not hasattr(self, '_related_fields'):
self._related_fields = self.resolve_related_fields()
return self._related_fields
@property
def reverse_related_fields(self):
return [(rhs_field, lhs_field) for lhs_field, rhs_field in self.related_fields]
@property
def local_related_fields(self):
return tuple(lhs_field for lhs_field, rhs_field in self.related_fields)
@property
def foreign_related_fields(self):
return tuple(rhs_field for lhs_field, rhs_field in self.related_fields)
def get_local_related_value(self, instance):
return self.get_instance_value_for_fields(instance, self.local_related_fields)
def get_foreign_related_value(self, instance):
return self.get_instance_value_for_fields(instance, self.foreign_related_fields)
@staticmethod
def get_instance_value_for_fields(instance, fields):
ret = []
opts = instance._meta
for field in fields:
# Gotcha: in some cases (like fixture loading) a model can have
# different values in parent_ptr_id and parent's id. So, use
# instance.pk (that is, parent_ptr_id) when asked for instance.id.
if field.primary_key:
possible_parent_link = opts.get_ancestor_link(field.model)
if (not possible_parent_link or
possible_parent_link.primary_key or
possible_parent_link.model._meta.abstract):
ret.append(instance.pk)
continue
ret.append(getattr(instance, field.attname))
return tuple(ret)
def get_attname_column(self):
attname, column = super(ForeignObject, self).get_attname_column()
return attname, None
def get_joining_columns(self, reverse_join=False):
source = self.reverse_related_fields if reverse_join else self.related_fields
return tuple((lhs_field.column, rhs_field.column) for lhs_field, rhs_field in source)
def get_reverse_joining_columns(self):
return self.get_joining_columns(reverse_join=True)
def get_extra_descriptor_filter(self, instance):
"""
Returns an extra filter condition for related object fetching when
user does 'instance.fieldname', that is the extra filter is used in
the descriptor of the field.
The filter should be either a dict usable in .filter(**kwargs) call or
a Q-object. The condition will be ANDed together with the relation's
joining columns.
A parallel method is get_extra_restriction() which is used in
JOIN and subquery conditions.
"""
return {}
def get_extra_restriction(self, where_class, alias, related_alias):
"""
Returns a pair condition used for joining and subquery pushdown. The
condition is something that responds to as_sql(qn, connection) method.
Note that currently referring both the 'alias' and 'related_alias'
will not work in some conditions, like subquery pushdown.
A parallel method is get_extra_descriptor_filter() which is used in
instance.fieldname related object fetching.
"""
return None
def get_path_info(self):
"""
Get path from this field to the related model.
"""
opts = self.rel.to._meta
from_opts = self.model._meta
return [PathInfo(from_opts, opts, self.foreign_related_fields, self, False, True)]
def get_reverse_path_info(self):
"""
Get path from the related model to this field's model.
"""
opts = self.model._meta
from_opts = self.rel.to._meta
pathinfos = [PathInfo(from_opts, opts, (opts.pk,), self.rel, not self.unique, False)]
return pathinfos
def get_lookup_constraint(self, constraint_class, alias, targets, sources, lookups,
raw_value):
from django.db.models.sql.where import SubqueryConstraint, AND, OR
root_constraint = constraint_class()
assert len(targets) == len(sources)
if len(lookups) > 1:
raise exceptions.FieldError('Relation fields do not support nested lookups')
lookup_type = lookups[0]
def get_normalized_value(value):
from django.db.models import Model
if isinstance(value, Model):
value_list = []
for source in sources:
# Account for one-to-one relations when sent a different model
while not isinstance(value, source.model) and source.rel:
source = source.rel.to._meta.get_field(source.rel.field_name)
value_list.append(getattr(value, source.attname))
return tuple(value_list)
elif not isinstance(value, tuple):
return (value,)
return value
is_multicolumn = len(self.related_fields) > 1
if (hasattr(raw_value, '_as_sql') or
hasattr(raw_value, 'get_compiler')):
root_constraint.add(SubqueryConstraint(alias, [target.column for target in targets],
[source.name for source in sources], raw_value),
AND)
elif lookup_type == 'isnull':
root_constraint.add(IsNull(Col(alias, targets[0], sources[0]), raw_value), AND)
elif (lookup_type == 'exact' or (lookup_type in ['gt', 'lt', 'gte', 'lte']
and not is_multicolumn)):
value = get_normalized_value(raw_value)
for target, source, val in zip(targets, sources, value):
lookup_class = target.get_lookup(lookup_type)
root_constraint.add(
lookup_class(Col(alias, target, source), val), AND)
elif lookup_type in ['range', 'in'] and not is_multicolumn:
values = [get_normalized_value(value) for value in raw_value]
value = [val[0] for val in values]
lookup_class = targets[0].get_lookup(lookup_type)
root_constraint.add(lookup_class(Col(alias, targets[0], sources[0]), value), AND)
elif lookup_type == 'in':
values = [get_normalized_value(value) for value in raw_value]
for value in values:
value_constraint = constraint_class()
for source, target, val in zip(sources, targets, value):
lookup_class = target.get_lookup('exact')
lookup = lookup_class(Col(alias, target, source), val)
value_constraint.add(lookup, AND)
root_constraint.add(value_constraint, OR)
else:
raise TypeError('Related Field got invalid lookup: %s' % lookup_type)
return root_constraint
@property
def attnames(self):
return tuple(field.attname for field in self.local_related_fields)
def get_defaults(self):
return tuple(field.get_default() for field in self.local_related_fields)
def contribute_to_class(self, cls, name, virtual_only=False):
super(ForeignObject, self).contribute_to_class(cls, name, virtual_only=virtual_only)
setattr(cls, self.name, ReverseSingleRelatedObjectDescriptor(self))
def contribute_to_related_class(self, cls, related):
# Internal FK's - i.e., those with a related name ending with '+' -
# and swapped models don't get a related descriptor.
if not self.rel.is_hidden() and not related.model._meta.swapped:
setattr(cls, related.get_accessor_name(), self.related_accessor_class(related))
# While 'limit_choices_to' might be a callable, simply pass
# it along for later - this is too early because it's still
# model load time.
if self.rel.limit_choices_to:
cls._meta.related_fkey_lookups.append(self.rel.limit_choices_to)
class ForeignKey(ForeignObject):
empty_strings_allowed = False
default_error_messages = {
'invalid': _('%(model)s instance with %(field)s %(value)r does not exist.')
}
description = _("Foreign Key (type determined by related field)")
def __init__(self, to, to_field=None, rel_class=ManyToOneRel,
db_constraint=True, **kwargs):
try:
to._meta.model_name
except AttributeError: # to._meta doesn't exist, so it must be RECURSIVE_RELATIONSHIP_CONSTANT
assert isinstance(to, six.string_types), "%s(%r) is invalid. First parameter to ForeignKey must be either a model, a model name, or the string %r" % (self.__class__.__name__, to, RECURSIVE_RELATIONSHIP_CONSTANT)
else:
# For backwards compatibility purposes, we need to *try* and set
# the to_field during FK construction. It won't be guaranteed to
# be correct until contribute_to_class is called. Refs #12190.
to_field = to_field or (to._meta.pk and to._meta.pk.name)
if 'db_index' not in kwargs:
kwargs['db_index'] = True
self.db_constraint = db_constraint
kwargs['rel'] = rel_class(
self, to, to_field,
related_name=kwargs.pop('related_name', None),
related_query_name=kwargs.pop('related_query_name', None),
limit_choices_to=kwargs.pop('limit_choices_to', None),
parent_link=kwargs.pop('parent_link', False),
on_delete=kwargs.pop('on_delete', CASCADE),
)
super(ForeignKey, self).__init__(to, ['self'], [to_field], **kwargs)
def check(self, **kwargs):
errors = super(ForeignKey, self).check(**kwargs)
errors.extend(self._check_on_delete())
return errors
def _check_on_delete(self):
on_delete = getattr(self.rel, 'on_delete', None)
if on_delete == SET_NULL and not self.null:
return [
checks.Error(
'Field specifies on_delete=SET_NULL, but cannot be null.',
hint='Set null=True argument on the field, or change the on_delete rule.',
obj=self,
id='fields.E320',
)
]
elif on_delete == SET_DEFAULT and not self.has_default():
return [
checks.Error(
'Field specifies on_delete=SET_DEFAULT, but has no default value.',
hint='Set a default value, or change the on_delete rule.',
obj=self,
id='fields.E321',
)
]
else:
return []
def deconstruct(self):
name, path, args, kwargs = super(ForeignKey, self).deconstruct()
del kwargs['to_fields']
del kwargs['from_fields']
# Handle the simpler arguments
if self.db_index:
del kwargs['db_index']
else:
kwargs['db_index'] = False
if self.db_constraint is not True:
kwargs['db_constraint'] = self.db_constraint
# Rel needs more work.
to_meta = getattr(self.rel.to, "_meta", None)
if self.rel.field_name and (not to_meta or (to_meta.pk and self.rel.field_name != to_meta.pk.name)):
kwargs['to_field'] = self.rel.field_name
return name, path, args, kwargs
@property
def related_field(self):
return self.foreign_related_fields[0]
def get_reverse_path_info(self):
"""
Get path from the related model to this field's model.
"""
opts = self.model._meta
from_opts = self.rel.to._meta
pathinfos = [PathInfo(from_opts, opts, (opts.pk,), self.rel, not self.unique, False)]
return pathinfos
def validate(self, value, model_instance):
if self.rel.parent_link:
return
super(ForeignKey, self).validate(value, model_instance)
if value is None:
return
using = router.db_for_read(model_instance.__class__, instance=model_instance)
qs = self.rel.to._default_manager.using(using).filter(
**{self.rel.field_name: value}
)
qs = qs.complex_filter(self.get_limit_choices_to())
if not qs.exists():
raise exceptions.ValidationError(
self.error_messages['invalid'],
code='invalid',
params={
'model': self.rel.to._meta.verbose_name, 'pk': value,
'field': self.rel.field_name, 'value': value,
}, # 'pk' is included for backwards compatibilty
)
def get_attname(self):
return '%s_id' % self.name
def get_attname_column(self):
attname = self.get_attname()
column = self.db_column or attname
return attname, column
def get_validator_unique_lookup_type(self):
return '%s__%s__exact' % (self.name, self.related_field.name)
def get_default(self):
"Here we check if the default value is an object and return the to_field if so."
field_default = super(ForeignKey, self).get_default()
if isinstance(field_default, self.rel.to):
return getattr(field_default, self.related_field.attname)
return field_default
def get_db_prep_save(self, value, connection):
if value is None or (value == '' and
(not self.related_field.empty_strings_allowed or
connection.features.interprets_empty_strings_as_nulls)):
return None
else:
return self.related_field.get_db_prep_save(value, connection=connection)
def value_to_string(self, obj):
if not obj:
# In required many-to-one fields with only one available choice,
# select that one available choice. Note: For SelectFields
# we have to check that the length of choices is *2*, not 1,
# because SelectFields always have an initial "blank" value.
if not self.blank and self.choices:
choice_list = self.get_choices_default()
if len(choice_list) == 2:
return smart_text(choice_list[1][0])
return super(ForeignKey, self).value_to_string(obj)
def contribute_to_related_class(self, cls, related):
super(ForeignKey, self).contribute_to_related_class(cls, related)
if self.rel.field_name is None:
self.rel.field_name = cls._meta.pk.name
def formfield(self, **kwargs):
db = kwargs.pop('using', None)
if isinstance(self.rel.to, six.string_types):
raise ValueError("Cannot create form field for %r yet, because "
"its related model %r has not been loaded yet" %
(self.name, self.rel.to))
defaults = {
'form_class': forms.ModelChoiceField,
'queryset': self.rel.to._default_manager.using(db),
'to_field_name': self.rel.field_name,
}
defaults.update(kwargs)
return super(ForeignKey, self).formfield(**defaults)
def db_type(self, connection):
# The database column type of a ForeignKey is the column type
# of the field to which it points. An exception is if the ForeignKey
# points to an AutoField/PositiveIntegerField/PositiveSmallIntegerField,
# in which case the column type is simply that of an IntegerField.
# If the database needs similar types for key fields however, the only
# thing we can do is making AutoField an IntegerField.
rel_field = self.related_field
if (isinstance(rel_field, AutoField) or
(not connection.features.related_fields_match_type and
isinstance(rel_field, (PositiveIntegerField,
PositiveSmallIntegerField)))):
return IntegerField().db_type(connection=connection)
return rel_field.db_type(connection=connection)
def db_parameters(self, connection):
return {"type": self.db_type(connection), "check": []}
class OneToOneField(ForeignKey):
"""
A OneToOneField is essentially the same as a ForeignKey, with the exception
that always carries a "unique" constraint with it and the reverse relation
always returns the object pointed to (since there will only ever be one),
rather than returning a list.
"""
related_accessor_class = SingleRelatedObjectDescriptor
description = _("One-to-one relationship")
def __init__(self, to, to_field=None, **kwargs):
kwargs['unique'] = True
super(OneToOneField, self).__init__(to, to_field, OneToOneRel, **kwargs)
def deconstruct(self):
name, path, args, kwargs = super(OneToOneField, self).deconstruct()
if "unique" in kwargs:
del kwargs['unique']
return name, path, args, kwargs
def formfield(self, **kwargs):
if self.rel.parent_link:
return None
return super(OneToOneField, self).formfield(**kwargs)
def save_form_data(self, instance, data):
if isinstance(data, self.rel.to):
setattr(instance, self.name, data)
else:
setattr(instance, self.attname, data)
def create_many_to_many_intermediary_model(field, klass):
from django.db import models
managed = True
if isinstance(field.rel.to, six.string_types) and field.rel.to != RECURSIVE_RELATIONSHIP_CONSTANT:
to_model = field.rel.to
to = to_model.split('.')[-1]
def set_managed(field, model, cls):
field.rel.through._meta.managed = model._meta.managed or cls._meta.managed
add_lazy_relation(klass, field, to_model, set_managed)
elif isinstance(field.rel.to, six.string_types):
to = klass._meta.object_name
to_model = klass
managed = klass._meta.managed
else:
to = field.rel.to._meta.object_name
to_model = field.rel.to
managed = klass._meta.managed or to_model._meta.managed
name = '%s_%s' % (klass._meta.object_name, field.name)
if field.rel.to == RECURSIVE_RELATIONSHIP_CONSTANT or to == klass._meta.object_name:
from_ = 'from_%s' % to.lower()
to = 'to_%s' % to.lower()
else:
from_ = klass._meta.model_name
to = to.lower()
meta = type(str('Meta'), (object,), {
'db_table': field._get_m2m_db_table(klass._meta),
'managed': managed,
'auto_created': klass,
'app_label': klass._meta.app_label,
'db_tablespace': klass._meta.db_tablespace,
'unique_together': (from_, to),
'verbose_name': '%(from)s-%(to)s relationship' % {'from': from_, 'to': to},
'verbose_name_plural': '%(from)s-%(to)s relationships' % {'from': from_, 'to': to},
'apps': field.model._meta.apps,
})
# Construct and return the new class.
return type(str(name), (models.Model,), {
'Meta': meta,
'__module__': klass.__module__,
from_: models.ForeignKey(klass, related_name='%s+' % name, db_tablespace=field.db_tablespace, db_constraint=field.rel.db_constraint),
to: models.ForeignKey(to_model, related_name='%s+' % name, db_tablespace=field.db_tablespace, db_constraint=field.rel.db_constraint)
})
class ManyToManyField(RelatedField):
description = _("Many-to-many relationship")
def __init__(self, to, db_constraint=True, swappable=True, **kwargs):
try:
to._meta
except AttributeError: # to._meta doesn't exist, so it must be RECURSIVE_RELATIONSHIP_CONSTANT
assert isinstance(to, six.string_types), "%s(%r) is invalid. First parameter to ManyToManyField must be either a model, a model name, or the string %r" % (self.__class__.__name__, to, RECURSIVE_RELATIONSHIP_CONSTANT)
# Class names must be ASCII in Python 2.x, so we forcibly coerce it here to break early if there's a problem.
to = str(to)
kwargs['verbose_name'] = kwargs.get('verbose_name', None)
kwargs['rel'] = ManyToManyRel(to,
related_name=kwargs.pop('related_name', None),
related_query_name=kwargs.pop('related_query_name', None),
limit_choices_to=kwargs.pop('limit_choices_to', None),
symmetrical=kwargs.pop('symmetrical', to == RECURSIVE_RELATIONSHIP_CONSTANT),
through=kwargs.pop('through', None),
through_fields=kwargs.pop('through_fields', None),
db_constraint=db_constraint,
)
self.swappable = swappable
self.db_table = kwargs.pop('db_table', None)
if kwargs['rel'].through is not None:
assert self.db_table is None, "Cannot specify a db_table if an intermediary model is used."
super(ManyToManyField, self).__init__(**kwargs)
def check(self, **kwargs):
errors = super(ManyToManyField, self).check(**kwargs)
errors.extend(self._check_unique(**kwargs))
errors.extend(self._check_relationship_model(**kwargs))
errors.extend(self._check_ignored_options(**kwargs))
return errors
def _check_unique(self, **kwargs):
if self.unique:
return [
checks.Error(
'ManyToManyFields cannot be unique.',
hint=None,
obj=self,
id='fields.E330',
)
]
return []
def _check_ignored_options(self, **kwargs):
warnings = []
if self.null:
warnings.append(
checks.Warning(
'null has no effect on ManyToManyField.',
hint=None,
obj=self,
id='fields.W340',
)
)
if len(self._validators) > 0:
warnings.append(
checks.Warning(
'ManyToManyField does not support validators.',
hint=None,
obj=self,
id='fields.W341',
)
)
return warnings
def _check_relationship_model(self, from_model=None, **kwargs):
if hasattr(self.rel.through, '_meta'):
qualified_model_name = "%s.%s" % (
self.rel.through._meta.app_label, self.rel.through.__name__)
else:
qualified_model_name = self.rel.through
errors = []
if self.rel.through not in apps.get_models(include_auto_created=True):
# The relationship model is not installed.
errors.append(
checks.Error(
("Field specifies a many-to-many relation through model "
"'%s', which has not been installed.") %
qualified_model_name,
hint=None,
obj=self,
id='fields.E331',
)
)
else:
assert from_model is not None, \
"ManyToManyField with intermediate " \
"tables cannot be checked if you don't pass the model " \
"where the field is attached to."
# Set some useful local variables
to_model = self.rel.to
from_model_name = from_model._meta.object_name
if isinstance(to_model, six.string_types):
to_model_name = to_model
else:
to_model_name = to_model._meta.object_name
relationship_model_name = self.rel.through._meta.object_name
self_referential = from_model == to_model
# Check symmetrical attribute.
if (self_referential and self.rel.symmetrical and
not self.rel.through._meta.auto_created):
errors.append(
checks.Error(
'Many-to-many fields with intermediate tables must not be symmetrical.',
hint=None,
obj=self,
id='fields.E332',
)
)
# Count foreign keys in intermediate model
if self_referential:
seen_self = sum(from_model == getattr(field.rel, 'to', None)
for field in self.rel.through._meta.fields)
if seen_self > 2 and not self.rel.through_fields:
errors.append(
checks.Error(
("The model is used as an intermediate model by "
"'%s', but it has more than two foreign keys "
"to '%s', which is ambiguous. You must specify "
"which two foreign keys Django should use via the "
"through_fields keyword argument.") % (self, from_model_name),
hint=("Use through_fields to specify which two "
"foreign keys Django should use."),
obj=self.rel.through,
id='fields.E333',
)
)
else:
# Count foreign keys in relationship model
seen_from = sum(from_model == getattr(field.rel, 'to', None)
for field in self.rel.through._meta.fields)
seen_to = sum(to_model == getattr(field.rel, 'to', None)
for field in self.rel.through._meta.fields)
if seen_from > 1 and not self.rel.through_fields:
errors.append(
checks.Error(
("The model is used as an intermediate model by "
"'%s', but it has more than one foreign key "
"from '%s', which is ambiguous. You must specify "
"which foreign key Django should use via the "
"through_fields keyword argument.") % (self, from_model_name),
hint=('If you want to create a recursive relationship, '
'use ForeignKey("self", symmetrical=False, '
'through="%s").') % relationship_model_name,
obj=self,
id='fields.E334',
)
)
if seen_to > 1 and not self.rel.through_fields:
errors.append(
checks.Error(
("The model is used as an intermediate model by "
"'%s', but it has more than one foreign key "
"to '%s', which is ambiguous. You must specify "
"which foreign key Django should use via the "
"through_fields keyword argument.") % (self, to_model_name),
hint=('If you want to create a recursive '
'relationship, use ForeignKey("self", '
'symmetrical=False, through="%s").') % relationship_model_name,
obj=self,
id='fields.E335',
)
)
if seen_from == 0 or seen_to == 0:
errors.append(
checks.Error(
("The model is used as an intermediate model by "
"'%s', but it does not have a foreign key to '%s' or '%s'.") % (
self, from_model_name, to_model_name
),
hint=None,
obj=self.rel.through,
id='fields.E336',
)
)
# Validate `through_fields`
if self.rel.through_fields is not None:
# Validate that we're given an iterable of at least two items
# and that none of them is "falsy"
if not (len(self.rel.through_fields) >= 2 and
self.rel.through_fields[0] and self.rel.through_fields[1]):
errors.append(
checks.Error(
("Field specifies 'through_fields' but does not "
"provide the names of the two link fields that should be "
"used for the relation through model "
"'%s'.") % qualified_model_name,
hint=("Make sure you specify 'through_fields' as "
"through_fields=('field1', 'field2')"),
obj=self,
id='fields.E337',
)
)
# Validate the given through fields -- they should be actual
# fields on the through model, and also be foreign keys to the
# expected models
else:
assert from_model is not None, \
"ManyToManyField with intermediate " \
"tables cannot be checked if you don't pass the model " \
"where the field is attached to."
source, through, target = from_model, self.rel.through, self.rel.to
source_field_name, target_field_name = self.rel.through_fields[:2]
for field_name, related_model in ((source_field_name, source),
(target_field_name, target)):
possible_field_names = []
for f in through._meta.fields:
if hasattr(f, 'rel') and getattr(f.rel, 'to', None) == related_model:
possible_field_names.append(f.name)
if possible_field_names:
hint = ("Did you mean one of the following foreign "
"keys to '%s': %s?") % (related_model._meta.object_name,
', '.join(possible_field_names))
else:
hint = None
try:
field = through._meta.get_field(field_name)
except FieldDoesNotExist:
errors.append(
checks.Error(
("The intermediary model '%s' has no field '%s'.") % (
qualified_model_name, field_name),
hint=hint,
obj=self,
id='fields.E338',
)
)
else:
if not (hasattr(field, 'rel') and
getattr(field.rel, 'to', None) == related_model):
errors.append(
checks.Error(
"'%s.%s' is not a foreign key to '%s'." % (
through._meta.object_name, field_name,
related_model._meta.object_name),
hint=hint,
obj=self,
id='fields.E339',
)
)
return errors
def deconstruct(self):
name, path, args, kwargs = super(ManyToManyField, self).deconstruct()
# Handle the simpler arguments
if self.db_table is not None:
kwargs['db_table'] = self.db_table
if self.rel.db_constraint is not True:
kwargs['db_constraint'] = self.rel.db_constraint
if self.rel.related_name is not None:
kwargs['related_name'] = self.rel.related_name
if self.rel.related_query_name is not None:
kwargs['related_query_name'] = self.rel.related_query_name
# Rel needs more work.
if isinstance(self.rel.to, six.string_types):
kwargs['to'] = self.rel.to
else:
kwargs['to'] = "%s.%s" % (self.rel.to._meta.app_label, self.rel.to._meta.object_name)
if getattr(self.rel, 'through', None) is not None:
if isinstance(self.rel.through, six.string_types):
kwargs['through'] = self.rel.through
elif not self.rel.through._meta.auto_created:
kwargs['through'] = "%s.%s" % (self.rel.through._meta.app_label, self.rel.through._meta.object_name)
# If swappable is True, then see if we're actually pointing to the target
# of a swap.
swappable_setting = self.swappable_setting
if swappable_setting is not None:
# If it's already a settings reference, error
if hasattr(kwargs['to'], "setting_name"):
if kwargs['to'].setting_name != swappable_setting:
raise ValueError("Cannot deconstruct a ManyToManyField pointing to a model that is swapped in place of more than one model (%s and %s)" % (kwargs['to'].setting_name, swappable_setting))
# Set it
from django.db.migrations.writer import SettingsReference
kwargs['to'] = SettingsReference(
kwargs['to'],
swappable_setting,
)
return name, path, args, kwargs
def _get_path_info(self, direct=False):
"""
Called by both direct and indirect m2m traversal.
"""
pathinfos = []
int_model = self.rel.through
linkfield1 = int_model._meta.get_field_by_name(self.m2m_field_name())[0]
linkfield2 = int_model._meta.get_field_by_name(self.m2m_reverse_field_name())[0]
if direct:
join1infos = linkfield1.get_reverse_path_info()
join2infos = linkfield2.get_path_info()
else:
join1infos = linkfield2.get_reverse_path_info()
join2infos = linkfield1.get_path_info()
pathinfos.extend(join1infos)
pathinfos.extend(join2infos)
return pathinfos
def get_path_info(self):
return self._get_path_info(direct=True)
def get_reverse_path_info(self):
return self._get_path_info(direct=False)
def get_choices_default(self):
return Field.get_choices(self, include_blank=False)
def _get_m2m_db_table(self, opts):
"Function that can be curried to provide the m2m table name for this relation"
if self.rel.through is not None:
return self.rel.through._meta.db_table
elif self.db_table:
return self.db_table
else:
return utils.truncate_name('%s_%s' % (opts.db_table, self.name),
connection.ops.max_name_length())
def _get_m2m_attr(self, related, attr):
"Function that can be curried to provide the source accessor or DB column name for the m2m table"
cache_attr = '_m2m_%s_cache' % attr
if hasattr(self, cache_attr):
return getattr(self, cache_attr)
if self.rel.through_fields is not None:
link_field_name = self.rel.through_fields[0]
else:
link_field_name = None
for f in self.rel.through._meta.fields:
if hasattr(f, 'rel') and f.rel and f.rel.to == related.model and \
(link_field_name is None or link_field_name == f.name):
setattr(self, cache_attr, getattr(f, attr))
return getattr(self, cache_attr)
def _get_m2m_reverse_attr(self, related, attr):
"Function that can be curried to provide the related accessor or DB column name for the m2m table"
cache_attr = '_m2m_reverse_%s_cache' % attr
if hasattr(self, cache_attr):
return getattr(self, cache_attr)
found = False
if self.rel.through_fields is not None:
link_field_name = self.rel.through_fields[1]
else:
link_field_name = None
for f in self.rel.through._meta.fields:
if hasattr(f, 'rel') and f.rel and f.rel.to == related.parent_model:
if link_field_name is None and related.model == related.parent_model:
# If this is an m2m-intermediate to self,
# the first foreign key you find will be
# the source column. Keep searching for
# the second foreign key.
if found:
setattr(self, cache_attr, getattr(f, attr))
break
else:
found = True
elif link_field_name is None or link_field_name == f.name:
setattr(self, cache_attr, getattr(f, attr))
break
return getattr(self, cache_attr)
def value_to_string(self, obj):
data = ''
if obj:
qs = getattr(obj, self.name).all()
data = [instance._get_pk_val() for instance in qs]
else:
# In required many-to-many fields with only one available choice,
# select that one available choice.
if not self.blank:
choices_list = self.get_choices_default()
if len(choices_list) == 1:
data = [choices_list[0][0]]
return smart_text(data)
def contribute_to_class(self, cls, name, **kwargs):
# To support multiple relations to self, it's useful to have a non-None
# related name on symmetrical relations for internal reasons. The
# concept doesn't make a lot of sense externally ("you want me to
# specify *what* on my non-reversible relation?!"), so we set it up
# automatically. The funky name reduces the chance of an accidental
# clash.
if self.rel.symmetrical and (self.rel.to == "self" or self.rel.to == cls._meta.object_name):
self.rel.related_name = "%s_rel_+" % name
super(ManyToManyField, self).contribute_to_class(cls, name, **kwargs)
# The intermediate m2m model is not auto created if:
# 1) There is a manually specified intermediate, or
# 2) The class owning the m2m field is abstract.
# 3) The class owning the m2m field has been swapped out.
if not self.rel.through and not cls._meta.abstract and not cls._meta.swapped:
self.rel.through = create_many_to_many_intermediary_model(self, cls)
# Add the descriptor for the m2m relation
setattr(cls, self.name, ReverseManyRelatedObjectsDescriptor(self))
# Set up the accessor for the m2m table name for the relation
self.m2m_db_table = curry(self._get_m2m_db_table, cls._meta)
# Populate some necessary rel arguments so that cross-app relations
# work correctly.
if isinstance(self.rel.through, six.string_types):
def resolve_through_model(field, model, cls):
field.rel.through = model
add_lazy_relation(cls, self, self.rel.through, resolve_through_model)
def contribute_to_related_class(self, cls, related):
# Internal M2Ms (i.e., those with a related name ending with '+')
# and swapped models don't get a related descriptor.
if not self.rel.is_hidden() and not related.model._meta.swapped:
setattr(cls, related.get_accessor_name(), ManyRelatedObjectsDescriptor(related))
# Set up the accessors for the column names on the m2m table
self.m2m_column_name = curry(self._get_m2m_attr, related, 'column')
self.m2m_reverse_name = curry(self._get_m2m_reverse_attr, related, 'column')
self.m2m_field_name = curry(self._get_m2m_attr, related, 'name')
self.m2m_reverse_field_name = curry(self._get_m2m_reverse_attr, related, 'name')
get_m2m_rel = curry(self._get_m2m_attr, related, 'rel')
self.m2m_target_field_name = lambda: get_m2m_rel().field_name
get_m2m_reverse_rel = curry(self._get_m2m_reverse_attr, related, 'rel')
self.m2m_reverse_target_field_name = lambda: get_m2m_reverse_rel().field_name
def set_attributes_from_rel(self):
pass
def value_from_object(self, obj):
"Returns the value of this field in the given model instance."
return getattr(obj, self.attname).all()
def save_form_data(self, instance, data):
setattr(instance, self.attname, data)
def formfield(self, **kwargs):
db = kwargs.pop('using', None)
defaults = {
'form_class': forms.ModelMultipleChoiceField,
'queryset': self.rel.to._default_manager.using(db),
}
defaults.update(kwargs)
# If initial is passed in, it's a list of related objects, but the
# MultipleChoiceField takes a list of IDs.
if defaults.get('initial') is not None:
initial = defaults['initial']
if callable(initial):
initial = initial()
defaults['initial'] = [i._get_pk_val() for i in initial]
return super(ManyToManyField, self).formfield(**defaults)
def db_type(self, connection):
# A ManyToManyField is not represented by a single column,
# so return None.
return None
def db_parameters(self, connection):
return {"type": None, "check": None}
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