Source code for django.db.models.query_utils
"""
Various data structures used in query construction.
Factored out from django.db.models.query to avoid making the main module very
large and/or so that they can be used by other modules without getting into
circular import difficulties.
"""
import functools
import inspect
import logging
from collections import namedtuple
from django.core.exceptions import FieldError
from django.db import DEFAULT_DB_ALIAS, DatabaseError, connections
from django.db.models.constants import LOOKUP_SEP
from django.utils import tree
from django.utils.functional import cached_property
from django.utils.hashable import make_hashable
logger = logging.getLogger("django.db.models")
# PathInfo is used when converting lookups (fk__somecol). The contents
# describe the relation in Model terms (model Options and Fields for both
# sides of the relation. The join_field is the field backing the relation.
PathInfo = namedtuple(
"PathInfo",
"from_opts to_opts target_fields join_field m2m direct filtered_relation",
)
def subclasses(cls):
yield cls
for subclass in cls.__subclasses__():
yield from subclasses(subclass)
[docs]
class Q(tree.Node):
"""
Encapsulate filters as objects that can then be combined logically (using
`&` and `|`).
"""
# Connection types
AND = "AND"
OR = "OR"
XOR = "XOR"
default = AND
conditional = True
def __init__(self, *args, _connector=None, _negated=False, **kwargs):
super().__init__(
children=[*args, *sorted(kwargs.items())],
connector=_connector,
negated=_negated,
)
def _combine(self, other, conn):
if getattr(other, "conditional", False) is False:
raise TypeError(other)
if not self:
return other.copy()
if not other and isinstance(other, Q):
return self.copy()
obj = self.create(connector=conn)
obj.add(self, conn)
obj.add(other, conn)
return obj
def __or__(self, other):
return self._combine(other, self.OR)
def __and__(self, other):
return self._combine(other, self.AND)
def __xor__(self, other):
return self._combine(other, self.XOR)
def __invert__(self):
obj = self.copy()
obj.negate()
return obj
def resolve_expression(
self, query=None, allow_joins=True, reuse=None, summarize=False, for_save=False
):
# We must promote any new joins to left outer joins so that when Q is
# used as an expression, rows aren't filtered due to joins.
clause, joins = query._add_q(
self,
reuse,
allow_joins=allow_joins,
split_subq=False,
check_filterable=False,
summarize=summarize,
)
query.promote_joins(joins)
return clause
def flatten(self):
"""
Recursively yield this Q object and all subexpressions, in depth-first
order.
"""
yield self
for child in self.children:
if isinstance(child, tuple):
# Use the lookup.
child = child[1]
if hasattr(child, "flatten"):
yield from child.flatten()
else:
yield child
def check(self, against, using=DEFAULT_DB_ALIAS):
"""
Do a database query to check if the expressions of the Q instance
matches against the expressions.
"""
# Avoid circular imports.
from django.db.models import BooleanField, Value
from django.db.models.functions import Coalesce
from django.db.models.sql import Query
from django.db.models.sql.constants import SINGLE
query = Query(None)
for name, value in against.items():
if not hasattr(value, "resolve_expression"):
value = Value(value)
query.add_annotation(value, name, select=False)
query.add_annotation(Value(1), "_check")
# This will raise a FieldError if a field is missing in "against".
if connections[using].features.supports_comparing_boolean_expr:
query.add_q(Q(Coalesce(self, True, output_field=BooleanField())))
else:
query.add_q(self)
compiler = query.get_compiler(using=using)
try:
return compiler.execute_sql(SINGLE) is not None
except DatabaseError as e:
logger.warning("Got a database error calling check() on %r: %s", self, e)
return True
def deconstruct(self):
path = "%s.%s" % (self.__class__.__module__, self.__class__.__name__)
if path.startswith("django.db.models.query_utils"):
path = path.replace("django.db.models.query_utils", "django.db.models")
args = tuple(self.children)
kwargs = {}
if self.connector != self.default:
kwargs["_connector"] = self.connector
if self.negated:
kwargs["_negated"] = True
return path, args, kwargs
@cached_property
def identity(self):
path, args, kwargs = self.deconstruct()
identity = [path, *kwargs.items()]
for child in args:
if isinstance(child, tuple):
arg, value = child
value = make_hashable(value)
identity.append((arg, value))
else:
identity.append(child)
return tuple(identity)
def __eq__(self, other):
if not isinstance(other, Q):
return NotImplemented
return other.identity == self.identity
def __hash__(self):
return hash(self.identity)
@cached_property
def referenced_base_fields(self):
"""
Retrieve all base fields referenced directly or through F expressions
excluding any fields referenced through joins.
"""
# Avoid circular imports.
from django.db.models.sql import query
return {
child.split(LOOKUP_SEP, 1)[0] for child in query.get_children_from_q(self)
}
class DeferredAttribute:
"""
A wrapper for a deferred-loading field. When the value is read from this
object the first time, the query is executed.
"""
def __init__(self, field):
self.field = field
def __get__(self, instance, cls=None):
"""
Retrieve and caches the value from the datastore on the first lookup.
Return the cached value.
"""
if instance is None:
return self
data = instance.__dict__
field_name = self.field.attname
if field_name not in data:
# Let's see if the field is part of the parent chain. If so we
# might be able to reuse the already loaded value. Refs #18343.
val = self._check_parent_chain(instance)
if val is None:
if instance.pk is None and self.field.generated:
raise AttributeError(
"Cannot read a generated field from an unsaved model."
)
instance.refresh_from_db(fields=[field_name])
else:
data[field_name] = val
return data[field_name]
def _check_parent_chain(self, instance):
"""
Check if the field value can be fetched from a parent field already
loaded in the instance. This can be done if the to-be fetched
field is a primary key field.
"""
opts = instance._meta
link_field = opts.get_ancestor_link(self.field.model)
if self.field.primary_key and self.field != link_field:
return getattr(instance, link_field.attname)
return None
class class_or_instance_method:
"""
Hook used in RegisterLookupMixin to return partial functions depending on
the caller type (instance or class of models.Field).
"""
def __init__(self, class_method, instance_method):
self.class_method = class_method
self.instance_method = instance_method
def __get__(self, instance, owner):
if instance is None:
return functools.partial(self.class_method, owner)
return functools.partial(self.instance_method, instance)
class RegisterLookupMixin:
def _get_lookup(self, lookup_name):
return self.get_lookups().get(lookup_name, None)
@functools.cache
def get_class_lookups(cls):
class_lookups = [
parent.__dict__.get("class_lookups", {}) for parent in inspect.getmro(cls)
]
return cls.merge_dicts(class_lookups)
def get_instance_lookups(self):
class_lookups = self.get_class_lookups()
if instance_lookups := getattr(self, "instance_lookups", None):
return {**class_lookups, **instance_lookups}
return class_lookups
get_lookups = class_or_instance_method(get_class_lookups, get_instance_lookups)
get_class_lookups = classmethod(get_class_lookups)
def get_lookup(self, lookup_name):
from django.db.models.lookups import Lookup
found = self._get_lookup(lookup_name)
if found is None and hasattr(self, "output_field"):
return self.output_field.get_lookup(lookup_name)
if found is not None and not issubclass(found, Lookup):
return None
return found
def get_transform(self, lookup_name):
from django.db.models.lookups import Transform
found = self._get_lookup(lookup_name)
if found is None and hasattr(self, "output_field"):
return self.output_field.get_transform(lookup_name)
if found is not None and not issubclass(found, Transform):
return None
return found
@staticmethod
def merge_dicts(dicts):
"""
Merge dicts in reverse to preference the order of the original list. e.g.,
merge_dicts([a, b]) will preference the keys in 'a' over those in 'b'.
"""
merged = {}
for d in reversed(dicts):
merged.update(d)
return merged
@classmethod
def _clear_cached_class_lookups(cls):
for subclass in subclasses(cls):
subclass.get_class_lookups.cache_clear()
def register_class_lookup(cls, lookup, lookup_name=None):
if lookup_name is None:
lookup_name = lookup.lookup_name
if "class_lookups" not in cls.__dict__:
cls.class_lookups = {}
cls.class_lookups[lookup_name] = lookup
cls._clear_cached_class_lookups()
return lookup
def register_instance_lookup(self, lookup, lookup_name=None):
if lookup_name is None:
lookup_name = lookup.lookup_name
if "instance_lookups" not in self.__dict__:
self.instance_lookups = {}
self.instance_lookups[lookup_name] = lookup
return lookup
register_lookup = class_or_instance_method(
register_class_lookup, register_instance_lookup
)
register_class_lookup = classmethod(register_class_lookup)
def _unregister_class_lookup(cls, lookup, lookup_name=None):
"""
Remove given lookup from cls lookups. For use in tests only as it's
not thread-safe.
"""
if lookup_name is None:
lookup_name = lookup.lookup_name
del cls.class_lookups[lookup_name]
cls._clear_cached_class_lookups()
def _unregister_instance_lookup(self, lookup, lookup_name=None):
"""
Remove given lookup from instance lookups. For use in tests only as
it's not thread-safe.
"""
if lookup_name is None:
lookup_name = lookup.lookup_name
del self.instance_lookups[lookup_name]
_unregister_lookup = class_or_instance_method(
_unregister_class_lookup, _unregister_instance_lookup
)
_unregister_class_lookup = classmethod(_unregister_class_lookup)
def select_related_descend(field, restricted, requested, select_mask, reverse=False):
"""
Return True if this field should be used to descend deeper for
select_related() purposes. Used by both the query construction code
(compiler.get_related_selections()) and the model instance creation code
(compiler.klass_info).
Arguments:
* field - the field to be checked
* restricted - a boolean field, indicating if the field list has been
manually restricted using a requested clause)
* requested - The select_related() dictionary.
* select_mask - the dictionary of selected fields.
* reverse - boolean, True if we are checking a reverse select related
"""
if not field.remote_field:
return False
if field.remote_field.parent_link and not reverse:
return False
if restricted:
if reverse and field.related_query_name() not in requested:
return False
if not reverse and field.name not in requested:
return False
if not restricted and field.null:
return False
if (
restricted
and select_mask
and field.name in requested
and field not in select_mask
):
raise FieldError(
f"Field {field.model._meta.object_name}.{field.name} cannot be both "
"deferred and traversed using select_related at the same time."
)
return True
def refs_expression(lookup_parts, annotations):
"""
Check if the lookup_parts contains references to the given annotations set.
Because the LOOKUP_SEP is contained in the default annotation names, check
each prefix of the lookup_parts for a match.
"""
for n in range(1, len(lookup_parts) + 1):
level_n_lookup = LOOKUP_SEP.join(lookup_parts[0:n])
if annotations.get(level_n_lookup):
return level_n_lookup, lookup_parts[n:]
return None, ()
def check_rel_lookup_compatibility(model, target_opts, field):
"""
Check that self.model is compatible with target_opts. Compatibility
is OK if:
1) model and opts match (where proxy inheritance is removed)
2) model is parent of opts' model or the other way around
"""
def check(opts):
return (
model._meta.concrete_model == opts.concrete_model
or opts.concrete_model in model._meta.get_parent_list()
or model in opts.get_parent_list()
)
# If the field is a primary key, then doing a query against the field's
# model is ok, too. Consider the case:
# class Restaurant(models.Model):
# place = OneToOneField(Place, primary_key=True):
# Restaurant.objects.filter(pk__in=Restaurant.objects.all()).
# If we didn't have the primary key check, then pk__in (== place__in) would
# give Place's opts as the target opts, but Restaurant isn't compatible
# with that. This logic applies only to primary keys, as when doing __in=qs,
# we are going to turn this into __in=qs.values('pk') later on.
return check(target_opts) or (
getattr(field, "primary_key", False) and check(field.model._meta)
)
[docs]
class FilteredRelation:
"""Specify custom filtering in the ON clause of SQL joins."""
def __init__(self, relation_name, *, condition=Q()):
if not relation_name:
raise ValueError("relation_name cannot be empty.")
self.relation_name = relation_name
self.alias = None
if not isinstance(condition, Q):
raise ValueError("condition argument must be a Q() instance.")
# .condition and .resolved_condition have to be stored independently
# as the former must remain unchanged for Join.__eq__ to remain stable
# and reusable even once their .filtered_relation are resolved.
self.condition = condition
self.resolved_condition = None
def __eq__(self, other):
if not isinstance(other, self.__class__):
return NotImplemented
return (
self.relation_name == other.relation_name
and self.alias == other.alias
and self.condition == other.condition
)
def clone(self):
clone = FilteredRelation(self.relation_name, condition=self.condition)
clone.alias = self.alias
if (resolved_condition := self.resolved_condition) is not None:
clone.resolved_condition = resolved_condition.clone()
return clone
def relabeled_clone(self, change_map):
clone = self.clone()
if resolved_condition := clone.resolved_condition:
clone.resolved_condition = resolved_condition.relabeled_clone(change_map)
return clone
def resolve_expression(self, query, reuse, *args, **kwargs):
clone = self.clone()
clone.resolved_condition = query.build_filter(
self.condition,
can_reuse=reuse,
allow_joins=True,
split_subq=False,
update_join_types=False,
)[0]
return clone
def as_sql(self, compiler, connection):
return compiler.compile(self.resolved_condition)