2132 lines
92 KiB
Python
2132 lines
92 KiB
Python
"""
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Create SQL statements for QuerySets.
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The code in here encapsulates all of the SQL construction so that QuerySets
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themselves do not have to (and could be backed by things other than SQL
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databases). The abstraction barrier only works one way: this module has to know
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all about the internals of models in order to get the information it needs.
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"""
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from collections import Mapping, OrderedDict
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import copy
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import warnings
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from django.core.exceptions import FieldError
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from django.db import connections, DEFAULT_DB_ALIAS
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from django.db.models.constants import LOOKUP_SEP
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from django.db.models.aggregates import refs_aggregate
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from django.db.models.expressions import ExpressionNode
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from django.db.models.fields import FieldDoesNotExist
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from django.db.models.query_utils import Q
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from django.db.models.related import PathInfo
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from django.db.models.sql import aggregates as base_aggregates_module
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from django.db.models.sql.constants import (QUERY_TERMS, ORDER_DIR, SINGLE,
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ORDER_PATTERN, JoinInfo, SelectInfo)
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from django.db.models.sql.datastructures import EmptyResultSet, Empty, MultiJoin, Col
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from django.db.models.sql.expressions import SQLEvaluator
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from django.db.models.sql.where import (WhereNode, Constraint, EverythingNode,
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ExtraWhere, AND, OR, EmptyWhere)
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from django.utils import six
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from django.utils.deprecation import RemovedInDjango19Warning
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from django.utils.encoding import force_text
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from django.utils.tree import Node
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__all__ = ['Query', 'RawQuery']
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class RawQuery(object):
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"""
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A single raw SQL query
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"""
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def __init__(self, sql, using, params=None):
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self.params = params or ()
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self.sql = sql
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self.using = using
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self.cursor = None
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# Mirror some properties of a normal query so that
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# the compiler can be used to process results.
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self.low_mark, self.high_mark = 0, None # Used for offset/limit
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self.extra_select = {}
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self.aggregate_select = {}
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def clone(self, using):
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return RawQuery(self.sql, using, params=self.params)
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def get_columns(self):
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if self.cursor is None:
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self._execute_query()
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converter = connections[self.using].introspection.column_name_converter
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return [converter(column_meta[0])
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for column_meta in self.cursor.description]
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def __iter__(self):
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# Always execute a new query for a new iterator.
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# This could be optimized with a cache at the expense of RAM.
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self._execute_query()
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if not connections[self.using].features.can_use_chunked_reads:
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# If the database can't use chunked reads we need to make sure we
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# evaluate the entire query up front.
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result = list(self.cursor)
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else:
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result = self.cursor
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return iter(result)
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def __repr__(self):
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return "<RawQuery: %s>" % self
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def __str__(self):
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_type = dict if isinstance(self.params, Mapping) else tuple
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return self.sql % _type(self.params)
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def _execute_query(self):
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self.cursor = connections[self.using].cursor()
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self.cursor.execute(self.sql, self.params)
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class Query(object):
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"""
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A single SQL query.
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"""
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# SQL join types. These are part of the class because their string forms
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# vary from database to database and can be customised by a subclass.
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INNER = 'INNER JOIN'
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LOUTER = 'LEFT OUTER JOIN'
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alias_prefix = 'T'
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subq_aliases = frozenset([alias_prefix])
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query_terms = QUERY_TERMS
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aggregates_module = base_aggregates_module
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compiler = 'SQLCompiler'
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def __init__(self, model, where=WhereNode):
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self.model = model
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self.alias_refcount = {}
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# alias_map is the most important data structure regarding joins.
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# It's used for recording which joins exist in the query and what
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# type they are. The key is the alias of the joined table (possibly
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# the table name) and the value is JoinInfo from constants.py.
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self.alias_map = {}
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self.table_map = {} # Maps table names to list of aliases.
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self.join_map = {}
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self.default_cols = True
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self.default_ordering = True
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self.standard_ordering = True
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self.used_aliases = set()
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self.filter_is_sticky = False
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self.included_inherited_models = {}
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# SQL-related attributes
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# Select and related select clauses as SelectInfo instances.
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# The select is used for cases where we want to set up the select
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# clause to contain other than default fields (values(), annotate(),
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# subqueries...)
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self.select = []
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# The related_select_cols is used for columns needed for
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# select_related - this is populated in the compile stage.
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self.related_select_cols = []
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self.tables = [] # Aliases in the order they are created.
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self.where = where()
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self.where_class = where
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self.group_by = None
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self.having = where()
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self.order_by = []
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self.low_mark, self.high_mark = 0, None # Used for offset/limit
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self.distinct = False
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self.distinct_fields = []
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self.select_for_update = False
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self.select_for_update_nowait = False
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self.select_related = False
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# SQL aggregate-related attributes
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# The _aggregates will be an OrderedDict when used. Due to the cost
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# of creating OrderedDict this attribute is created lazily (in
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# self.aggregates property).
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self._aggregates = None # Maps alias -> SQL aggregate function
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self.aggregate_select_mask = None
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self._aggregate_select_cache = None
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# Arbitrary maximum limit for select_related. Prevents infinite
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# recursion. Can be changed by the depth parameter to select_related().
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self.max_depth = 5
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# These are for extensions. The contents are more or less appended
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# verbatim to the appropriate clause.
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# The _extra attribute is an OrderedDict, lazily created similarly to
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# .aggregates
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self._extra = None # Maps col_alias -> (col_sql, params).
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self.extra_select_mask = None
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self._extra_select_cache = None
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self.extra_tables = ()
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self.extra_order_by = ()
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# A tuple that is a set of model field names and either True, if these
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# are the fields to defer, or False if these are the only fields to
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# load.
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self.deferred_loading = (set(), True)
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@property
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def extra(self):
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if self._extra is None:
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self._extra = OrderedDict()
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return self._extra
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@property
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def aggregates(self):
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if self._aggregates is None:
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self._aggregates = OrderedDict()
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return self._aggregates
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def __str__(self):
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"""
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Returns the query as a string of SQL with the parameter values
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substituted in (use sql_with_params() to see the unsubstituted string).
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Parameter values won't necessarily be quoted correctly, since that is
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done by the database interface at execution time.
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"""
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sql, params = self.sql_with_params()
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return sql % params
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def sql_with_params(self):
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"""
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Returns the query as an SQL string and the parameters that will be
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substituted into the query.
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"""
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return self.get_compiler(DEFAULT_DB_ALIAS).as_sql()
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def __deepcopy__(self, memo):
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result = self.clone(memo=memo)
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memo[id(self)] = result
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return result
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def prepare(self):
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return self
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def get_compiler(self, using=None, connection=None):
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if using is None and connection is None:
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raise ValueError("Need either using or connection")
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if using:
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connection = connections[using]
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# Check that the compiler will be able to execute the query
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for alias, aggregate in self.aggregate_select.items():
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connection.ops.check_aggregate_support(aggregate)
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return connection.ops.compiler(self.compiler)(self, connection, using)
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def get_meta(self):
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"""
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Returns the Options instance (the model._meta) from which to start
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processing. Normally, this is self.model._meta, but it can be changed
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by subclasses.
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"""
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return self.model._meta
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def clone(self, klass=None, memo=None, **kwargs):
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"""
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Creates a copy of the current instance. The 'kwargs' parameter can be
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used by clients to update attributes after copying has taken place.
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"""
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obj = Empty()
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obj.__class__ = klass or self.__class__
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obj.model = self.model
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obj.alias_refcount = self.alias_refcount.copy()
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obj.alias_map = self.alias_map.copy()
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obj.table_map = self.table_map.copy()
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obj.join_map = self.join_map.copy()
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obj.default_cols = self.default_cols
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obj.default_ordering = self.default_ordering
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obj.standard_ordering = self.standard_ordering
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obj.included_inherited_models = self.included_inherited_models.copy()
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obj.select = self.select[:]
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obj.related_select_cols = []
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obj.tables = self.tables[:]
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obj.where = self.where.clone()
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obj.where_class = self.where_class
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if self.group_by is None:
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obj.group_by = None
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else:
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obj.group_by = self.group_by[:]
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obj.having = self.having.clone()
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obj.order_by = self.order_by[:]
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obj.low_mark, obj.high_mark = self.low_mark, self.high_mark
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obj.distinct = self.distinct
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obj.distinct_fields = self.distinct_fields[:]
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obj.select_for_update = self.select_for_update
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obj.select_for_update_nowait = self.select_for_update_nowait
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obj.select_related = self.select_related
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obj.related_select_cols = []
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obj._aggregates = self._aggregates.copy() if self._aggregates is not None else None
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if self.aggregate_select_mask is None:
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obj.aggregate_select_mask = None
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else:
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obj.aggregate_select_mask = self.aggregate_select_mask.copy()
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# _aggregate_select_cache cannot be copied, as doing so breaks the
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# (necessary) state in which both aggregates and
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# _aggregate_select_cache point to the same underlying objects.
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# It will get re-populated in the cloned queryset the next time it's
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# used.
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obj._aggregate_select_cache = None
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obj.max_depth = self.max_depth
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obj._extra = self._extra.copy() if self._extra is not None else None
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if self.extra_select_mask is None:
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obj.extra_select_mask = None
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else:
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obj.extra_select_mask = self.extra_select_mask.copy()
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if self._extra_select_cache is None:
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obj._extra_select_cache = None
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else:
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obj._extra_select_cache = self._extra_select_cache.copy()
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obj.extra_tables = self.extra_tables
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obj.extra_order_by = self.extra_order_by
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obj.deferred_loading = copy.copy(self.deferred_loading[0]), self.deferred_loading[1]
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if self.filter_is_sticky and self.used_aliases:
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obj.used_aliases = self.used_aliases.copy()
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else:
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obj.used_aliases = set()
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obj.filter_is_sticky = False
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if 'alias_prefix' in self.__dict__:
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obj.alias_prefix = self.alias_prefix
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if 'subq_aliases' in self.__dict__:
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obj.subq_aliases = self.subq_aliases.copy()
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obj.__dict__.update(kwargs)
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if hasattr(obj, '_setup_query'):
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obj._setup_query()
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return obj
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def resolve_aggregate(self, value, aggregate, connection):
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"""Resolve the value of aggregates returned by the database to
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consistent (and reasonable) types.
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This is required because of the predisposition of certain backends
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to return Decimal and long types when they are not needed.
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"""
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if value is None:
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if aggregate.is_ordinal:
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return 0
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# Return None as-is
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return value
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elif aggregate.is_ordinal:
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# Any ordinal aggregate (e.g., count) returns an int
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return int(value)
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elif aggregate.is_computed:
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# Any computed aggregate (e.g., avg) returns a float
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return float(value)
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else:
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# Return value depends on the type of the field being processed.
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backend_converters = connection.ops.get_db_converters(aggregate.field.get_internal_type())
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field_converters = aggregate.field.get_db_converters(connection)
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for converter in backend_converters:
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value = converter(value, aggregate.field)
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for converter in field_converters:
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value = converter(value, connection)
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return value
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def get_aggregation(self, using, force_subq=False):
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"""
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Returns the dictionary with the values of the existing aggregations.
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"""
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if not self.aggregate_select:
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return {}
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# If there is a group by clause, aggregating does not add useful
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# information but retrieves only the first row. Aggregate
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# over the subquery instead.
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if self.group_by is not None or force_subq:
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from django.db.models.sql.subqueries import AggregateQuery
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query = AggregateQuery(self.model)
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obj = self.clone()
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if not force_subq:
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# In forced subq case the ordering and limits will likely
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# affect the results.
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obj.clear_ordering(True)
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obj.clear_limits()
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obj.select_for_update = False
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obj.select_related = False
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obj.related_select_cols = []
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relabels = dict((t, 'subquery') for t in self.tables)
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# Remove any aggregates marked for reduction from the subquery
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# and move them to the outer AggregateQuery.
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for alias, aggregate in self.aggregate_select.items():
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if aggregate.is_summary:
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query.aggregates[alias] = aggregate.relabeled_clone(relabels)
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del obj.aggregate_select[alias]
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try:
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query.add_subquery(obj, using)
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except EmptyResultSet:
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return dict(
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(alias, None)
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for alias in query.aggregate_select
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)
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else:
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query = self
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self.select = []
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self.default_cols = False
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self._extra = {}
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self.remove_inherited_models()
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query.clear_ordering(True)
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query.clear_limits()
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query.select_for_update = False
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query.select_related = False
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query.related_select_cols = []
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result = query.get_compiler(using).execute_sql(SINGLE)
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if result is None:
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result = [None for q in query.aggregate_select.items()]
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return dict(
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(alias, self.resolve_aggregate(val, aggregate, connection=connections[using]))
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for (alias, aggregate), val
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in zip(query.aggregate_select.items(), result)
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)
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def get_count(self, using):
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"""
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Performs a COUNT() query using the current filter constraints.
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"""
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obj = self.clone()
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if len(self.select) > 1 or self.aggregate_select or (self.distinct and self.distinct_fields):
|
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# If a select clause exists, then the query has already started to
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# specify the columns that are to be returned.
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# In this case, we need to use a subquery to evaluate the count.
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from django.db.models.sql.subqueries import AggregateQuery
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subquery = obj
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subquery.clear_ordering(True)
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subquery.clear_limits()
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obj = AggregateQuery(obj.model)
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try:
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obj.add_subquery(subquery, using=using)
|
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except EmptyResultSet:
|
|
# add_subquery evaluates the query, if it's an EmptyResultSet
|
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# then there are can be no results, and therefore there the
|
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# count is obviously 0
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return 0
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|
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obj.add_count_column()
|
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number = obj.get_aggregation(using=using)[None]
|
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|
|
# Apply offset and limit constraints manually, since using LIMIT/OFFSET
|
|
# in SQL (in variants that provide them) doesn't change the COUNT
|
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# output.
|
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number = max(0, number - self.low_mark)
|
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if self.high_mark is not None:
|
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number = min(number, self.high_mark - self.low_mark)
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return number
|
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|
|
def has_filters(self):
|
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return self.where or self.having
|
|
|
|
def has_results(self, using):
|
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q = self.clone()
|
|
if not q.distinct:
|
|
q.clear_select_clause()
|
|
q.clear_ordering(True)
|
|
q.set_limits(high=1)
|
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compiler = q.get_compiler(using=using)
|
|
return compiler.has_results()
|
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|
|
def combine(self, rhs, connector):
|
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"""
|
|
Merge the 'rhs' query into the current one (with any 'rhs' effects
|
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being applied *after* (that is, "to the right of") anything in the
|
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current query. 'rhs' is not modified during a call to this function.
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|
|
|
The 'connector' parameter describes how to connect filters from the
|
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'rhs' query.
|
|
"""
|
|
assert self.model == rhs.model, \
|
|
"Cannot combine queries on two different base models."
|
|
assert self.can_filter(), \
|
|
"Cannot combine queries once a slice has been taken."
|
|
assert self.distinct == rhs.distinct, \
|
|
"Cannot combine a unique query with a non-unique query."
|
|
assert self.distinct_fields == rhs.distinct_fields, \
|
|
"Cannot combine queries with different distinct fields."
|
|
|
|
self.remove_inherited_models()
|
|
# Work out how to relabel the rhs aliases, if necessary.
|
|
change_map = {}
|
|
conjunction = (connector == AND)
|
|
|
|
# Determine which existing joins can be reused. When combining the
|
|
# query with AND we must recreate all joins for m2m filters. When
|
|
# combining with OR we can reuse joins. The reason is that in AND
|
|
# case a single row can't fulfill a condition like:
|
|
# revrel__col=1 & revrel__col=2
|
|
# But, there might be two different related rows matching this
|
|
# condition. In OR case a single True is enough, so single row is
|
|
# enough, too.
|
|
#
|
|
# Note that we will be creating duplicate joins for non-m2m joins in
|
|
# the AND case. The results will be correct but this creates too many
|
|
# joins. This is something that could be fixed later on.
|
|
reuse = set() if conjunction else set(self.tables)
|
|
# Base table must be present in the query - this is the same
|
|
# table on both sides.
|
|
self.get_initial_alias()
|
|
joinpromoter = JoinPromoter(connector, 2, False)
|
|
joinpromoter.add_votes(
|
|
j for j in self.alias_map if self.alias_map[j].join_type == self.INNER)
|
|
rhs_votes = set()
|
|
# Now, add the joins from rhs query into the new query (skipping base
|
|
# table).
|
|
for alias in rhs.tables[1:]:
|
|
table, _, join_type, lhs, join_cols, nullable, join_field = rhs.alias_map[alias]
|
|
# If the left side of the join was already relabeled, use the
|
|
# updated alias.
|
|
lhs = change_map.get(lhs, lhs)
|
|
new_alias = self.join(
|
|
(lhs, table, join_cols), reuse=reuse,
|
|
nullable=nullable, join_field=join_field)
|
|
if join_type == self.INNER:
|
|
rhs_votes.add(new_alias)
|
|
# We can't reuse the same join again in the query. If we have two
|
|
# distinct joins for the same connection in rhs query, then the
|
|
# combined query must have two joins, too.
|
|
reuse.discard(new_alias)
|
|
change_map[alias] = new_alias
|
|
if not rhs.alias_refcount[alias]:
|
|
# The alias was unused in the rhs query. Unref it so that it
|
|
# will be unused in the new query, too. We have to add and
|
|
# unref the alias so that join promotion has information of
|
|
# the join type for the unused alias.
|
|
self.unref_alias(new_alias)
|
|
joinpromoter.add_votes(rhs_votes)
|
|
joinpromoter.update_join_types(self)
|
|
|
|
# Now relabel a copy of the rhs where-clause and add it to the current
|
|
# one.
|
|
if rhs.where:
|
|
w = rhs.where.clone()
|
|
w.relabel_aliases(change_map)
|
|
if not self.where:
|
|
# Since 'self' matches everything, add an explicit "include
|
|
# everything" where-constraint so that connections between the
|
|
# where clauses won't exclude valid results.
|
|
self.where.add(EverythingNode(), AND)
|
|
elif self.where:
|
|
# rhs has an empty where clause.
|
|
w = self.where_class()
|
|
w.add(EverythingNode(), AND)
|
|
else:
|
|
w = self.where_class()
|
|
self.where.add(w, connector)
|
|
|
|
# Selection columns and extra extensions are those provided by 'rhs'.
|
|
self.select = []
|
|
for col, field in rhs.select:
|
|
if isinstance(col, (list, tuple)):
|
|
new_col = change_map.get(col[0], col[0]), col[1]
|
|
self.select.append(SelectInfo(new_col, field))
|
|
else:
|
|
new_col = col.relabeled_clone(change_map)
|
|
self.select.append(SelectInfo(new_col, field))
|
|
|
|
if connector == OR:
|
|
# It would be nice to be able to handle this, but the queries don't
|
|
# really make sense (or return consistent value sets). Not worth
|
|
# the extra complexity when you can write a real query instead.
|
|
if self._extra and rhs._extra:
|
|
raise ValueError("When merging querysets using 'or', you "
|
|
"cannot have extra(select=...) on both sides.")
|
|
self.extra.update(rhs.extra)
|
|
extra_select_mask = set()
|
|
if self.extra_select_mask is not None:
|
|
extra_select_mask.update(self.extra_select_mask)
|
|
if rhs.extra_select_mask is not None:
|
|
extra_select_mask.update(rhs.extra_select_mask)
|
|
if extra_select_mask:
|
|
self.set_extra_mask(extra_select_mask)
|
|
self.extra_tables += rhs.extra_tables
|
|
|
|
# Ordering uses the 'rhs' ordering, unless it has none, in which case
|
|
# the current ordering is used.
|
|
self.order_by = rhs.order_by[:] if rhs.order_by else self.order_by
|
|
self.extra_order_by = rhs.extra_order_by or self.extra_order_by
|
|
|
|
def deferred_to_data(self, target, callback):
|
|
"""
|
|
Converts the self.deferred_loading data structure to an alternate data
|
|
structure, describing the field that *will* be loaded. This is used to
|
|
compute the columns to select from the database and also by the
|
|
QuerySet class to work out which fields are being initialized on each
|
|
model. Models that have all their fields included aren't mentioned in
|
|
the result, only those that have field restrictions in place.
|
|
|
|
The "target" parameter is the instance that is populated (in place).
|
|
The "callback" is a function that is called whenever a (model, field)
|
|
pair need to be added to "target". It accepts three parameters:
|
|
"target", and the model and list of fields being added for that model.
|
|
"""
|
|
field_names, defer = self.deferred_loading
|
|
if not field_names:
|
|
return
|
|
orig_opts = self.get_meta()
|
|
seen = {}
|
|
must_include = {orig_opts.concrete_model: set([orig_opts.pk])}
|
|
for field_name in field_names:
|
|
parts = field_name.split(LOOKUP_SEP)
|
|
cur_model = self.model._meta.concrete_model
|
|
opts = orig_opts
|
|
for name in parts[:-1]:
|
|
old_model = cur_model
|
|
source = opts.get_field_by_name(name)[0]
|
|
if is_reverse_o2o(source):
|
|
cur_model = source.model
|
|
else:
|
|
cur_model = source.rel.to
|
|
opts = cur_model._meta
|
|
# Even if we're "just passing through" this model, we must add
|
|
# both the current model's pk and the related reference field
|
|
# (if it's not a reverse relation) to the things we select.
|
|
if not is_reverse_o2o(source):
|
|
must_include[old_model].add(source)
|
|
add_to_dict(must_include, cur_model, opts.pk)
|
|
field, model, _, _ = opts.get_field_by_name(parts[-1])
|
|
if model is None:
|
|
model = cur_model
|
|
if not is_reverse_o2o(field):
|
|
add_to_dict(seen, model, field)
|
|
|
|
if defer:
|
|
# We need to load all fields for each model, except those that
|
|
# appear in "seen" (for all models that appear in "seen"). The only
|
|
# slight complexity here is handling fields that exist on parent
|
|
# models.
|
|
workset = {}
|
|
for model, values in six.iteritems(seen):
|
|
for field, m in model._meta.get_fields_with_model():
|
|
if field in values:
|
|
continue
|
|
add_to_dict(workset, m or model, field)
|
|
for model, values in six.iteritems(must_include):
|
|
# If we haven't included a model in workset, we don't add the
|
|
# corresponding must_include fields for that model, since an
|
|
# empty set means "include all fields". That's why there's no
|
|
# "else" branch here.
|
|
if model in workset:
|
|
workset[model].update(values)
|
|
for model, values in six.iteritems(workset):
|
|
callback(target, model, values)
|
|
else:
|
|
for model, values in six.iteritems(must_include):
|
|
if model in seen:
|
|
seen[model].update(values)
|
|
else:
|
|
# As we've passed through this model, but not explicitly
|
|
# included any fields, we have to make sure it's mentioned
|
|
# so that only the "must include" fields are pulled in.
|
|
seen[model] = values
|
|
# Now ensure that every model in the inheritance chain is mentioned
|
|
# in the parent list. Again, it must be mentioned to ensure that
|
|
# only "must include" fields are pulled in.
|
|
for model in orig_opts.get_parent_list():
|
|
if model not in seen:
|
|
seen[model] = set()
|
|
for model, values in six.iteritems(seen):
|
|
callback(target, model, values)
|
|
|
|
def deferred_to_columns_cb(self, target, model, fields):
|
|
"""
|
|
Callback used by deferred_to_columns(). The "target" parameter should
|
|
be a set instance.
|
|
"""
|
|
table = model._meta.db_table
|
|
if table not in target:
|
|
target[table] = set()
|
|
for field in fields:
|
|
target[table].add(field.column)
|
|
|
|
def table_alias(self, table_name, create=False):
|
|
"""
|
|
Returns a table alias for the given table_name and whether this is a
|
|
new alias or not.
|
|
|
|
If 'create' is true, a new alias is always created. Otherwise, the
|
|
most recently created alias for the table (if one exists) is reused.
|
|
"""
|
|
alias_list = self.table_map.get(table_name)
|
|
if not create and alias_list:
|
|
alias = alias_list[0]
|
|
self.alias_refcount[alias] += 1
|
|
return alias, False
|
|
|
|
# Create a new alias for this table.
|
|
if alias_list:
|
|
alias = '%s%d' % (self.alias_prefix, len(self.alias_map) + 1)
|
|
alias_list.append(alias)
|
|
else:
|
|
# The first occurrence of a table uses the table name directly.
|
|
alias = table_name
|
|
self.table_map[alias] = [alias]
|
|
self.alias_refcount[alias] = 1
|
|
self.tables.append(alias)
|
|
return alias, True
|
|
|
|
def ref_alias(self, alias):
|
|
""" Increases the reference count for this alias. """
|
|
self.alias_refcount[alias] += 1
|
|
|
|
def unref_alias(self, alias, amount=1):
|
|
""" Decreases the reference count for this alias. """
|
|
self.alias_refcount[alias] -= amount
|
|
|
|
def promote_joins(self, aliases):
|
|
"""
|
|
Promotes recursively the join type of given aliases and its children to
|
|
an outer join. If 'unconditional' is False, the join is only promoted if
|
|
it is nullable or the parent join is an outer join.
|
|
|
|
The children promotion is done to avoid join chains that contain a LOUTER
|
|
b INNER c. So, if we have currently a INNER b INNER c and a->b is promoted,
|
|
then we must also promote b->c automatically, or otherwise the promotion
|
|
of a->b doesn't actually change anything in the query results.
|
|
"""
|
|
aliases = list(aliases)
|
|
while aliases:
|
|
alias = aliases.pop(0)
|
|
if self.alias_map[alias].join_cols[0][1] is None:
|
|
# This is the base table (first FROM entry) - this table
|
|
# isn't really joined at all in the query, so we should not
|
|
# alter its join type.
|
|
continue
|
|
# Only the first alias (skipped above) should have None join_type
|
|
assert self.alias_map[alias].join_type is not None
|
|
parent_alias = self.alias_map[alias].lhs_alias
|
|
parent_louter = (
|
|
parent_alias
|
|
and self.alias_map[parent_alias].join_type == self.LOUTER)
|
|
already_louter = self.alias_map[alias].join_type == self.LOUTER
|
|
if ((self.alias_map[alias].nullable or parent_louter) and
|
|
not already_louter):
|
|
data = self.alias_map[alias]._replace(join_type=self.LOUTER)
|
|
self.alias_map[alias] = data
|
|
# Join type of 'alias' changed, so re-examine all aliases that
|
|
# refer to this one.
|
|
aliases.extend(
|
|
join for join in self.alias_map.keys()
|
|
if (self.alias_map[join].lhs_alias == alias
|
|
and join not in aliases))
|
|
|
|
def demote_joins(self, aliases):
|
|
"""
|
|
Change join type from LOUTER to INNER for all joins in aliases.
|
|
|
|
Similarly to promote_joins(), this method must ensure no join chains
|
|
containing first an outer, then an inner join are generated. If we
|
|
are demoting b->c join in chain a LOUTER b LOUTER c then we must
|
|
demote a->b automatically, or otherwise the demotion of b->c doesn't
|
|
actually change anything in the query results. .
|
|
"""
|
|
aliases = list(aliases)
|
|
while aliases:
|
|
alias = aliases.pop(0)
|
|
if self.alias_map[alias].join_type == self.LOUTER:
|
|
self.alias_map[alias] = self.alias_map[alias]._replace(join_type=self.INNER)
|
|
parent_alias = self.alias_map[alias].lhs_alias
|
|
if self.alias_map[parent_alias].join_type == self.INNER:
|
|
aliases.append(parent_alias)
|
|
|
|
def reset_refcounts(self, to_counts):
|
|
"""
|
|
This method will reset reference counts for aliases so that they match
|
|
the value passed in :param to_counts:.
|
|
"""
|
|
for alias, cur_refcount in self.alias_refcount.copy().items():
|
|
unref_amount = cur_refcount - to_counts.get(alias, 0)
|
|
self.unref_alias(alias, unref_amount)
|
|
|
|
def change_aliases(self, change_map):
|
|
"""
|
|
Changes the aliases in change_map (which maps old-alias -> new-alias),
|
|
relabelling any references to them in select columns and the where
|
|
clause.
|
|
"""
|
|
assert set(change_map.keys()).intersection(set(change_map.values())) == set()
|
|
|
|
def relabel_column(col):
|
|
if isinstance(col, (list, tuple)):
|
|
old_alias = col[0]
|
|
return (change_map.get(old_alias, old_alias), col[1])
|
|
else:
|
|
return col.relabeled_clone(change_map)
|
|
# 1. Update references in "select" (normal columns plus aliases),
|
|
# "group by", "where" and "having".
|
|
self.where.relabel_aliases(change_map)
|
|
self.having.relabel_aliases(change_map)
|
|
if self.group_by:
|
|
self.group_by = [relabel_column(col) for col in self.group_by]
|
|
self.select = [SelectInfo(relabel_column(s.col), s.field)
|
|
for s in self.select]
|
|
if self._aggregates:
|
|
self._aggregates = OrderedDict(
|
|
(key, relabel_column(col)) for key, col in self._aggregates.items())
|
|
|
|
# 2. Rename the alias in the internal table/alias datastructures.
|
|
for ident, aliases in self.join_map.items():
|
|
del self.join_map[ident]
|
|
aliases = tuple(change_map.get(a, a) for a in aliases)
|
|
ident = (change_map.get(ident[0], ident[0]),) + ident[1:]
|
|
self.join_map[ident] = aliases
|
|
for old_alias, new_alias in six.iteritems(change_map):
|
|
alias_data = self.alias_map[old_alias]
|
|
alias_data = alias_data._replace(rhs_alias=new_alias)
|
|
self.alias_refcount[new_alias] = self.alias_refcount[old_alias]
|
|
del self.alias_refcount[old_alias]
|
|
self.alias_map[new_alias] = alias_data
|
|
del self.alias_map[old_alias]
|
|
|
|
table_aliases = self.table_map[alias_data.table_name]
|
|
for pos, alias in enumerate(table_aliases):
|
|
if alias == old_alias:
|
|
table_aliases[pos] = new_alias
|
|
break
|
|
for pos, alias in enumerate(self.tables):
|
|
if alias == old_alias:
|
|
self.tables[pos] = new_alias
|
|
break
|
|
for key, alias in self.included_inherited_models.items():
|
|
if alias in change_map:
|
|
self.included_inherited_models[key] = change_map[alias]
|
|
|
|
# 3. Update any joins that refer to the old alias.
|
|
for alias, data in six.iteritems(self.alias_map):
|
|
lhs = data.lhs_alias
|
|
if lhs in change_map:
|
|
data = data._replace(lhs_alias=change_map[lhs])
|
|
self.alias_map[alias] = data
|
|
|
|
def bump_prefix(self, outer_query):
|
|
"""
|
|
Changes the alias prefix to the next letter in the alphabet in a way
|
|
that the outer query's aliases and this query's aliases will not
|
|
conflict. Even tables that previously had no alias will get an alias
|
|
after this call.
|
|
"""
|
|
if self.alias_prefix != outer_query.alias_prefix:
|
|
# No clashes between self and outer query should be possible.
|
|
return
|
|
self.alias_prefix = chr(ord(self.alias_prefix) + 1)
|
|
while self.alias_prefix in self.subq_aliases:
|
|
self.alias_prefix = chr(ord(self.alias_prefix) + 1)
|
|
assert self.alias_prefix < 'Z'
|
|
self.subq_aliases = self.subq_aliases.union([self.alias_prefix])
|
|
outer_query.subq_aliases = outer_query.subq_aliases.union(self.subq_aliases)
|
|
change_map = OrderedDict()
|
|
for pos, alias in enumerate(self.tables):
|
|
new_alias = '%s%d' % (self.alias_prefix, pos)
|
|
change_map[alias] = new_alias
|
|
self.tables[pos] = new_alias
|
|
self.change_aliases(change_map)
|
|
|
|
def get_initial_alias(self):
|
|
"""
|
|
Returns the first alias for this query, after increasing its reference
|
|
count.
|
|
"""
|
|
if self.tables:
|
|
alias = self.tables[0]
|
|
self.ref_alias(alias)
|
|
else:
|
|
alias = self.join((None, self.get_meta().db_table, None))
|
|
return alias
|
|
|
|
def count_active_tables(self):
|
|
"""
|
|
Returns the number of tables in this query with a non-zero reference
|
|
count. Note that after execution, the reference counts are zeroed, so
|
|
tables added in compiler will not be seen by this method.
|
|
"""
|
|
return len([1 for count in self.alias_refcount.values() if count])
|
|
|
|
def join(self, connection, reuse=None, nullable=False, join_field=None):
|
|
"""
|
|
Returns an alias for the join in 'connection', either reusing an
|
|
existing alias for that join or creating a new one. 'connection' is a
|
|
tuple (lhs, table, join_cols) where 'lhs' is either an existing
|
|
table alias or a table name. 'join_cols' is a tuple of tuples containing
|
|
columns to join on ((l_id1, r_id1), (l_id2, r_id2)). The join corresponds
|
|
to the SQL equivalent of::
|
|
|
|
lhs.l_id1 = table.r_id1 AND lhs.l_id2 = table.r_id2
|
|
|
|
The 'reuse' parameter can be either None which means all joins
|
|
(matching the connection) are reusable, or it can be a set containing
|
|
the aliases that can be reused.
|
|
|
|
A join is always created as LOUTER if the lhs alias is LOUTER to make
|
|
sure we do not generate chains like t1 LOUTER t2 INNER t3. All new
|
|
joins are created as LOUTER if nullable is True.
|
|
|
|
If 'nullable' is True, the join can potentially involve NULL values and
|
|
is a candidate for promotion (to "left outer") when combining querysets.
|
|
|
|
The 'join_field' is the field we are joining along (if any).
|
|
"""
|
|
lhs, table, join_cols = connection
|
|
assert lhs is None or join_field is not None
|
|
existing = self.join_map.get(connection, ())
|
|
if reuse is None:
|
|
reuse = existing
|
|
else:
|
|
reuse = [a for a in existing if a in reuse]
|
|
for alias in reuse:
|
|
if join_field and self.alias_map[alias].join_field != join_field:
|
|
# The join_map doesn't contain join_field (mainly because
|
|
# fields in Query structs are problematic in pickling), so
|
|
# check that the existing join is created using the same
|
|
# join_field used for the under work join.
|
|
continue
|
|
self.ref_alias(alias)
|
|
return alias
|
|
|
|
# No reuse is possible, so we need a new alias.
|
|
alias, _ = self.table_alias(table, create=True)
|
|
if not lhs:
|
|
# Not all tables need to be joined to anything. No join type
|
|
# means the later columns are ignored.
|
|
join_type = None
|
|
elif self.alias_map[lhs].join_type == self.LOUTER or nullable:
|
|
join_type = self.LOUTER
|
|
else:
|
|
join_type = self.INNER
|
|
join = JoinInfo(table, alias, join_type, lhs, join_cols or ((None, None),), nullable,
|
|
join_field)
|
|
self.alias_map[alias] = join
|
|
if connection in self.join_map:
|
|
self.join_map[connection] += (alias,)
|
|
else:
|
|
self.join_map[connection] = (alias,)
|
|
return alias
|
|
|
|
def setup_inherited_models(self):
|
|
"""
|
|
If the model that is the basis for this QuerySet inherits other models,
|
|
we need to ensure that those other models have their tables included in
|
|
the query.
|
|
|
|
We do this as a separate step so that subclasses know which
|
|
tables are going to be active in the query, without needing to compute
|
|
all the select columns (this method is called from pre_sql_setup(),
|
|
whereas column determination is a later part, and side-effect, of
|
|
as_sql()).
|
|
"""
|
|
opts = self.get_meta()
|
|
root_alias = self.tables[0]
|
|
seen = {None: root_alias}
|
|
|
|
for field, model in opts.get_fields_with_model():
|
|
if model not in seen:
|
|
self.join_parent_model(opts, model, root_alias, seen)
|
|
self.included_inherited_models = seen
|
|
|
|
def join_parent_model(self, opts, model, alias, seen):
|
|
"""
|
|
Makes sure the given 'model' is joined in the query. If 'model' isn't
|
|
a parent of 'opts' or if it is None this method is a no-op.
|
|
|
|
The 'alias' is the root alias for starting the join, 'seen' is a dict
|
|
of model -> alias of existing joins. It must also contain a mapping
|
|
of None -> some alias. This will be returned in the no-op case.
|
|
"""
|
|
if model in seen:
|
|
return seen[model]
|
|
chain = opts.get_base_chain(model)
|
|
if chain is None:
|
|
return alias
|
|
curr_opts = opts
|
|
for int_model in chain:
|
|
if int_model in seen:
|
|
return seen[int_model]
|
|
# Proxy model have elements in base chain
|
|
# with no parents, assign the new options
|
|
# object and skip to the next base in that
|
|
# case
|
|
if not curr_opts.parents[int_model]:
|
|
curr_opts = int_model._meta
|
|
continue
|
|
link_field = curr_opts.get_ancestor_link(int_model)
|
|
_, _, _, joins, _ = self.setup_joins(
|
|
[link_field.name], curr_opts, alias)
|
|
curr_opts = int_model._meta
|
|
alias = seen[int_model] = joins[-1]
|
|
return alias or seen[None]
|
|
|
|
def remove_inherited_models(self):
|
|
"""
|
|
Undoes the effects of setup_inherited_models(). Should be called
|
|
whenever select columns (self.select) are set explicitly.
|
|
"""
|
|
for key, alias in self.included_inherited_models.items():
|
|
if key:
|
|
self.unref_alias(alias)
|
|
self.included_inherited_models = {}
|
|
|
|
def add_aggregate(self, aggregate, model, alias, is_summary):
|
|
"""
|
|
Adds a single aggregate expression to the Query
|
|
"""
|
|
opts = model._meta
|
|
field_list = aggregate.lookup.split(LOOKUP_SEP)
|
|
if len(field_list) == 1 and self._aggregates and aggregate.lookup in self.aggregates:
|
|
# Aggregate is over an annotation
|
|
field_name = field_list[0]
|
|
col = field_name
|
|
source = self.aggregates[field_name]
|
|
if not is_summary:
|
|
raise FieldError("Cannot compute %s('%s'): '%s' is an aggregate" % (
|
|
aggregate.name, field_name, field_name))
|
|
elif ((len(field_list) > 1) or
|
|
(field_list[0] not in [i.name for i in opts.fields]) or
|
|
self.group_by is None or
|
|
not is_summary):
|
|
# If:
|
|
# - the field descriptor has more than one part (foo__bar), or
|
|
# - the field descriptor is referencing an m2m/m2o field, or
|
|
# - this is a reference to a model field (possibly inherited), or
|
|
# - this is an annotation over a model field
|
|
# then we need to explore the joins that are required.
|
|
|
|
# Join promotion note - we must not remove any rows here, so use
|
|
# outer join if there isn't any existing join.
|
|
_, sources, opts, join_list, path = self.setup_joins(
|
|
field_list, opts, self.get_initial_alias())
|
|
|
|
# Process the join chain to see if it can be trimmed
|
|
targets, _, join_list = self.trim_joins(sources, join_list, path)
|
|
|
|
col = targets[0].column
|
|
source = sources[0]
|
|
col = (join_list[-1], col)
|
|
else:
|
|
# The simplest cases. No joins required -
|
|
# just reference the provided column alias.
|
|
field_name = field_list[0]
|
|
source = opts.get_field(field_name)
|
|
col = field_name
|
|
# We want to have the alias in SELECT clause even if mask is set.
|
|
self.append_aggregate_mask([alias])
|
|
|
|
# Add the aggregate to the query
|
|
aggregate.add_to_query(self, alias, col=col, source=source, is_summary=is_summary)
|
|
|
|
def prepare_lookup_value(self, value, lookups, can_reuse):
|
|
# Default lookup if none given is exact.
|
|
if len(lookups) == 0:
|
|
lookups = ['exact']
|
|
# Interpret '__exact=None' as the sql 'is NULL'; otherwise, reject all
|
|
# uses of None as a query value.
|
|
if value is None:
|
|
if lookups[-1] not in ('exact', 'iexact'):
|
|
raise ValueError("Cannot use None as a query value")
|
|
lookups[-1] = 'isnull'
|
|
value = True
|
|
elif callable(value):
|
|
warnings.warn(
|
|
"Passing callable arguments to queryset is deprecated.",
|
|
RemovedInDjango19Warning, stacklevel=2)
|
|
value = value()
|
|
elif isinstance(value, ExpressionNode):
|
|
# If value is a query expression, evaluate it
|
|
value = SQLEvaluator(value, self, reuse=can_reuse)
|
|
if hasattr(value, 'query') and hasattr(value.query, 'bump_prefix'):
|
|
value = value._clone()
|
|
value.query.bump_prefix(self)
|
|
if hasattr(value, 'bump_prefix'):
|
|
value = value.clone()
|
|
value.bump_prefix(self)
|
|
# For Oracle '' is equivalent to null. The check needs to be done
|
|
# at this stage because join promotion can't be done at compiler
|
|
# stage. Using DEFAULT_DB_ALIAS isn't nice, but it is the best we
|
|
# can do here. Similar thing is done in is_nullable(), too.
|
|
if (connections[DEFAULT_DB_ALIAS].features.interprets_empty_strings_as_nulls and
|
|
lookups[-1] == 'exact' and value == ''):
|
|
value = True
|
|
lookups[-1] = 'isnull'
|
|
return value, lookups
|
|
|
|
def solve_lookup_type(self, lookup):
|
|
"""
|
|
Solve the lookup type from the lookup (eg: 'foobar__id__icontains')
|
|
"""
|
|
lookup_splitted = lookup.split(LOOKUP_SEP)
|
|
if self._aggregates:
|
|
aggregate, aggregate_lookups = refs_aggregate(lookup_splitted, self.aggregates)
|
|
if aggregate:
|
|
return aggregate_lookups, (), aggregate
|
|
_, field, _, lookup_parts = self.names_to_path(lookup_splitted, self.get_meta())
|
|
field_parts = lookup_splitted[0:len(lookup_splitted) - len(lookup_parts)]
|
|
if len(lookup_parts) == 0:
|
|
lookup_parts = ['exact']
|
|
elif len(lookup_parts) > 1:
|
|
if not field_parts:
|
|
raise FieldError(
|
|
'Invalid lookup "%s" for model %s".' %
|
|
(lookup, self.get_meta().model.__name__))
|
|
return lookup_parts, field_parts, False
|
|
|
|
def check_query_object_type(self, value, opts):
|
|
"""
|
|
Checks whether the object passed while querying is of the correct type.
|
|
If not, it raises a ValueError specifying the wrong object.
|
|
"""
|
|
if hasattr(value, '_meta'):
|
|
if not (value._meta.concrete_model == opts.concrete_model
|
|
or opts.concrete_model in value._meta.get_parent_list()
|
|
or value._meta.concrete_model in opts.get_parent_list()):
|
|
raise ValueError(
|
|
'Cannot query "%s": Must be "%s" instance.' %
|
|
(value, opts.object_name))
|
|
|
|
def check_related_objects(self, field, value, opts):
|
|
"""
|
|
Checks the type of object passed to query relations.
|
|
"""
|
|
if field.rel:
|
|
# testing for iterable of models
|
|
if hasattr(value, '__iter__'):
|
|
# Check if the iterable has a model attribute, if so
|
|
# it is likely something like a QuerySet.
|
|
if hasattr(value, 'model') and hasattr(value.model, '_meta'):
|
|
model = value.model
|
|
if not (model == opts.concrete_model
|
|
or opts.concrete_model in model._meta.get_parent_list()
|
|
or model in opts.get_parent_list()):
|
|
raise ValueError(
|
|
'Cannot use QuerySet for "%s": Use a QuerySet for "%s".' %
|
|
(model._meta.model_name, opts.object_name))
|
|
else:
|
|
for v in value:
|
|
self.check_query_object_type(v, opts)
|
|
else:
|
|
# expecting single model instance here
|
|
self.check_query_object_type(value, opts)
|
|
|
|
def build_lookup(self, lookups, lhs, rhs):
|
|
lookups = lookups[:]
|
|
while lookups:
|
|
lookup = lookups[0]
|
|
if len(lookups) == 1:
|
|
final_lookup = lhs.get_lookup(lookup)
|
|
if final_lookup:
|
|
return final_lookup(lhs, rhs)
|
|
# We didn't find a lookup, so we are going to try get_transform
|
|
# + get_lookup('exact').
|
|
lookups.append('exact')
|
|
next = lhs.get_transform(lookup)
|
|
if next:
|
|
lhs = next(lhs, lookups)
|
|
else:
|
|
raise FieldError(
|
|
"Unsupported lookup '%s' for %s or join on the field not "
|
|
"permitted." %
|
|
(lookup, lhs.output_field.__class__.__name__))
|
|
lookups = lookups[1:]
|
|
|
|
def build_filter(self, filter_expr, branch_negated=False, current_negated=False,
|
|
can_reuse=None, connector=AND):
|
|
"""
|
|
Builds a WhereNode for a single filter clause, but doesn't add it
|
|
to this Query. Query.add_q() will then add this filter to the where
|
|
or having Node.
|
|
|
|
The 'branch_negated' tells us if the current branch contains any
|
|
negations. This will be used to determine if subqueries are needed.
|
|
|
|
The 'current_negated' is used to determine if the current filter is
|
|
negated or not and this will be used to determine if IS NULL filtering
|
|
is needed.
|
|
|
|
The difference between current_netageted and branch_negated is that
|
|
branch_negated is set on first negation, but current_negated is
|
|
flipped for each negation.
|
|
|
|
Note that add_filter will not do any negating itself, that is done
|
|
upper in the code by add_q().
|
|
|
|
The 'can_reuse' is a set of reusable joins for multijoins.
|
|
|
|
The method will create a filter clause that can be added to the current
|
|
query. However, if the filter isn't added to the query then the caller
|
|
is responsible for unreffing the joins used.
|
|
"""
|
|
arg, value = filter_expr
|
|
if not arg:
|
|
raise FieldError("Cannot parse keyword query %r" % arg)
|
|
lookups, parts, reffed_aggregate = self.solve_lookup_type(arg)
|
|
|
|
# Work out the lookup type and remove it from the end of 'parts',
|
|
# if necessary.
|
|
value, lookups = self.prepare_lookup_value(value, lookups, can_reuse)
|
|
used_joins = getattr(value, '_used_joins', [])
|
|
|
|
clause = self.where_class()
|
|
if reffed_aggregate:
|
|
condition = self.build_lookup(lookups, reffed_aggregate, value)
|
|
if not condition:
|
|
# Backwards compat for custom lookups
|
|
assert len(lookups) == 1
|
|
condition = (reffed_aggregate, lookups[0], value)
|
|
clause.add(condition, AND)
|
|
return clause, []
|
|
|
|
opts = self.get_meta()
|
|
alias = self.get_initial_alias()
|
|
allow_many = not branch_negated
|
|
|
|
try:
|
|
field, sources, opts, join_list, path = self.setup_joins(
|
|
parts, opts, alias, can_reuse=can_reuse, allow_many=allow_many)
|
|
|
|
self.check_related_objects(field, value, opts)
|
|
|
|
# split_exclude() needs to know which joins were generated for the
|
|
# lookup parts
|
|
self._lookup_joins = join_list
|
|
except MultiJoin as e:
|
|
return self.split_exclude(filter_expr, LOOKUP_SEP.join(parts[:e.level]),
|
|
can_reuse, e.names_with_path)
|
|
|
|
if can_reuse is not None:
|
|
can_reuse.update(join_list)
|
|
used_joins = set(used_joins).union(set(join_list))
|
|
|
|
# Process the join list to see if we can remove any non-needed joins from
|
|
# the far end (fewer tables in a query is better).
|
|
targets, alias, join_list = self.trim_joins(sources, join_list, path)
|
|
|
|
if hasattr(field, 'get_lookup_constraint'):
|
|
# For now foreign keys get special treatment. This should be
|
|
# refactored when composite fields lands.
|
|
condition = field.get_lookup_constraint(self.where_class, alias, targets, sources,
|
|
lookups, value)
|
|
lookup_type = lookups[-1]
|
|
else:
|
|
assert(len(targets) == 1)
|
|
col = Col(alias, targets[0], field)
|
|
condition = self.build_lookup(lookups, col, value)
|
|
if not condition:
|
|
# Backwards compat for custom lookups
|
|
if lookups[0] not in self.query_terms:
|
|
raise FieldError(
|
|
"Join on field '%s' not permitted. Did you "
|
|
"misspell '%s' for the lookup type?" %
|
|
(col.output_field.name, lookups[0]))
|
|
if len(lookups) > 1:
|
|
raise FieldError("Nested lookup '%s' not supported." %
|
|
LOOKUP_SEP.join(lookups))
|
|
condition = (Constraint(alias, targets[0].column, field), lookups[0], value)
|
|
lookup_type = lookups[-1]
|
|
else:
|
|
lookup_type = condition.lookup_name
|
|
|
|
clause.add(condition, AND)
|
|
|
|
require_outer = lookup_type == 'isnull' and value is True and not current_negated
|
|
if current_negated and (lookup_type != 'isnull' or value is False):
|
|
require_outer = True
|
|
if (lookup_type != 'isnull' and (
|
|
self.is_nullable(targets[0]) or
|
|
self.alias_map[join_list[-1]].join_type == self.LOUTER)):
|
|
# The condition added here will be SQL like this:
|
|
# NOT (col IS NOT NULL), where the first NOT is added in
|
|
# upper layers of code. The reason for addition is that if col
|
|
# is null, then col != someval will result in SQL "unknown"
|
|
# which isn't the same as in Python. The Python None handling
|
|
# is wanted, and it can be gotten by
|
|
# (col IS NULL OR col != someval)
|
|
# <=>
|
|
# NOT (col IS NOT NULL AND col = someval).
|
|
lookup_class = targets[0].get_lookup('isnull')
|
|
clause.add(lookup_class(Col(alias, targets[0], sources[0]), False), AND)
|
|
return clause, used_joins if not require_outer else ()
|
|
|
|
def add_filter(self, filter_clause):
|
|
self.add_q(Q(**{filter_clause[0]: filter_clause[1]}))
|
|
|
|
def need_having(self, obj):
|
|
"""
|
|
Returns whether or not all elements of this q_object need to be put
|
|
together in the HAVING clause.
|
|
"""
|
|
if not self._aggregates:
|
|
return False
|
|
if not isinstance(obj, Node):
|
|
return (refs_aggregate(obj[0].split(LOOKUP_SEP), self.aggregates)[0]
|
|
or (hasattr(obj[1], 'contains_aggregate')
|
|
and obj[1].contains_aggregate(self.aggregates)))
|
|
return any(self.need_having(c) for c in obj.children)
|
|
|
|
def split_having_parts(self, q_object, negated=False):
|
|
"""
|
|
Returns a list of q_objects which need to go into the having clause
|
|
instead of the where clause. Removes the splitted out nodes from the
|
|
given q_object. Note that the q_object is altered, so cloning it is
|
|
needed.
|
|
"""
|
|
having_parts = []
|
|
for c in q_object.children[:]:
|
|
# When constructing the having nodes we need to take care to
|
|
# preserve the negation status from the upper parts of the tree
|
|
if isinstance(c, Node):
|
|
# For each negated child, flip the in_negated flag.
|
|
in_negated = c.negated ^ negated
|
|
if c.connector == OR and self.need_having(c):
|
|
# A subtree starting from OR clause must go into having in
|
|
# whole if any part of that tree references an aggregate.
|
|
q_object.children.remove(c)
|
|
having_parts.append(c)
|
|
c.negated = in_negated
|
|
else:
|
|
having_parts.extend(
|
|
self.split_having_parts(c, in_negated)[1])
|
|
elif self.need_having(c):
|
|
q_object.children.remove(c)
|
|
new_q = self.where_class(children=[c], negated=negated)
|
|
having_parts.append(new_q)
|
|
return q_object, having_parts
|
|
|
|
def add_q(self, q_object):
|
|
"""
|
|
A preprocessor for the internal _add_q(). Responsible for
|
|
splitting the given q_object into where and having parts and
|
|
setting up some internal variables.
|
|
"""
|
|
if not self.need_having(q_object):
|
|
where_part, having_parts = q_object, []
|
|
else:
|
|
where_part, having_parts = self.split_having_parts(
|
|
q_object.clone(), q_object.negated)
|
|
# For join promotion this case is doing an AND for the added q_object
|
|
# and existing conditions. So, any existing inner join forces the join
|
|
# type to remain inner. Existing outer joins can however be demoted.
|
|
# (Consider case where rel_a is LOUTER and rel_a__col=1 is added - if
|
|
# rel_a doesn't produce any rows, then the whole condition must fail.
|
|
# So, demotion is OK.
|
|
existing_inner = set(
|
|
(a for a in self.alias_map if self.alias_map[a].join_type == self.INNER))
|
|
clause, require_inner = self._add_q(where_part, self.used_aliases)
|
|
self.where.add(clause, AND)
|
|
for hp in having_parts:
|
|
clause, _ = self._add_q(hp, self.used_aliases)
|
|
self.having.add(clause, AND)
|
|
self.demote_joins(existing_inner)
|
|
|
|
def _add_q(self, q_object, used_aliases, branch_negated=False,
|
|
current_negated=False):
|
|
"""
|
|
Adds a Q-object to the current filter.
|
|
"""
|
|
connector = q_object.connector
|
|
current_negated = current_negated ^ q_object.negated
|
|
branch_negated = branch_negated or q_object.negated
|
|
target_clause = self.where_class(connector=connector,
|
|
negated=q_object.negated)
|
|
joinpromoter = JoinPromoter(q_object.connector, len(q_object.children), current_negated)
|
|
for child in q_object.children:
|
|
if isinstance(child, Node):
|
|
child_clause, needed_inner = self._add_q(
|
|
child, used_aliases, branch_negated,
|
|
current_negated)
|
|
joinpromoter.add_votes(needed_inner)
|
|
else:
|
|
child_clause, needed_inner = self.build_filter(
|
|
child, can_reuse=used_aliases, branch_negated=branch_negated,
|
|
current_negated=current_negated, connector=connector)
|
|
joinpromoter.add_votes(needed_inner)
|
|
target_clause.add(child_clause, connector)
|
|
needed_inner = joinpromoter.update_join_types(self)
|
|
return target_clause, needed_inner
|
|
|
|
def names_to_path(self, names, opts, allow_many=True, fail_on_missing=False):
|
|
"""
|
|
Walks the names path and turns them PathInfo tuples. Note that a
|
|
single name in 'names' can generate multiple PathInfos (m2m for
|
|
example).
|
|
|
|
'names' is the path of names to travel, 'opts' is the model Options we
|
|
start the name resolving from, 'allow_many' is as for setup_joins().
|
|
|
|
Returns a list of PathInfo tuples. In addition returns the final field
|
|
(the last used join field), and target (which is a field guaranteed to
|
|
contain the same value as the final field).
|
|
"""
|
|
path, names_with_path = [], []
|
|
for pos, name in enumerate(names):
|
|
cur_names_with_path = (name, [])
|
|
if name == 'pk':
|
|
name = opts.pk.name
|
|
try:
|
|
field, model, direct, m2m = opts.get_field_by_name(name)
|
|
except FieldDoesNotExist:
|
|
# We didn't found the current field, so move position back
|
|
# one step.
|
|
pos -= 1
|
|
break
|
|
# Check if we need any joins for concrete inheritance cases (the
|
|
# field lives in parent, but we are currently in one of its
|
|
# children)
|
|
if model:
|
|
# The field lives on a base class of the current model.
|
|
# Skip the chain of proxy to the concrete proxied model
|
|
proxied_model = opts.concrete_model
|
|
|
|
for int_model in opts.get_base_chain(model):
|
|
if int_model is proxied_model:
|
|
opts = int_model._meta
|
|
else:
|
|
final_field = opts.parents[int_model]
|
|
targets = (final_field.rel.get_related_field(),)
|
|
opts = int_model._meta
|
|
path.append(PathInfo(final_field.model._meta, opts, targets, final_field, False, True))
|
|
cur_names_with_path[1].append(
|
|
PathInfo(final_field.model._meta, opts, targets, final_field, False, True)
|
|
)
|
|
if hasattr(field, 'get_path_info'):
|
|
pathinfos = field.get_path_info()
|
|
if not allow_many:
|
|
for inner_pos, p in enumerate(pathinfos):
|
|
if p.m2m:
|
|
cur_names_with_path[1].extend(pathinfos[0:inner_pos + 1])
|
|
names_with_path.append(cur_names_with_path)
|
|
raise MultiJoin(pos + 1, names_with_path)
|
|
last = pathinfos[-1]
|
|
path.extend(pathinfos)
|
|
final_field = last.join_field
|
|
opts = last.to_opts
|
|
targets = last.target_fields
|
|
cur_names_with_path[1].extend(pathinfos)
|
|
names_with_path.append(cur_names_with_path)
|
|
else:
|
|
# Local non-relational field.
|
|
final_field = field
|
|
targets = (field,)
|
|
break
|
|
if pos == -1 or (fail_on_missing and pos + 1 != len(names)):
|
|
self.raise_field_error(opts, name)
|
|
return path, final_field, targets, names[pos + 1:]
|
|
|
|
def raise_field_error(self, opts, name):
|
|
available = opts.get_all_field_names() + list(self.aggregate_select)
|
|
raise FieldError("Cannot resolve keyword %r into field. "
|
|
"Choices are: %s" % (name, ", ".join(available)))
|
|
|
|
def setup_joins(self, names, opts, alias, can_reuse=None, allow_many=True):
|
|
"""
|
|
Compute the necessary table joins for the passage through the fields
|
|
given in 'names'. 'opts' is the Options class for the current model
|
|
(which gives the table we are starting from), 'alias' is the alias for
|
|
the table to start the joining from.
|
|
|
|
The 'can_reuse' defines the reverse foreign key joins we can reuse. It
|
|
can be None in which case all joins are reusable or a set of aliases
|
|
that can be reused. Note that non-reverse foreign keys are always
|
|
reusable when using setup_joins().
|
|
|
|
If 'allow_many' is False, then any reverse foreign key seen will
|
|
generate a MultiJoin exception.
|
|
|
|
Returns the final field involved in the joins, the target field (used
|
|
for any 'where' constraint), the final 'opts' value, the joins and the
|
|
field path travelled to generate the joins.
|
|
|
|
The target field is the field containing the concrete value. Final
|
|
field can be something different, for example foreign key pointing to
|
|
that value. Final field is needed for example in some value
|
|
conversions (convert 'obj' in fk__id=obj to pk val using the foreign
|
|
key field for example).
|
|
"""
|
|
joins = [alias]
|
|
# First, generate the path for the names
|
|
path, final_field, targets, rest = self.names_to_path(
|
|
names, opts, allow_many, fail_on_missing=True)
|
|
|
|
# Then, add the path to the query's joins. Note that we can't trim
|
|
# joins at this stage - we will need the information about join type
|
|
# of the trimmed joins.
|
|
for pos, join in enumerate(path):
|
|
opts = join.to_opts
|
|
if join.direct:
|
|
nullable = self.is_nullable(join.join_field)
|
|
else:
|
|
nullable = True
|
|
connection = alias, opts.db_table, join.join_field.get_joining_columns()
|
|
reuse = can_reuse if join.m2m else None
|
|
alias = self.join(
|
|
connection, reuse=reuse, nullable=nullable, join_field=join.join_field)
|
|
joins.append(alias)
|
|
if hasattr(final_field, 'field'):
|
|
final_field = final_field.field
|
|
return final_field, targets, opts, joins, path
|
|
|
|
def trim_joins(self, targets, joins, path):
|
|
"""
|
|
The 'target' parameter is the final field being joined to, 'joins'
|
|
is the full list of join aliases. The 'path' contain the PathInfos
|
|
used to create the joins.
|
|
|
|
Returns the final target field and table alias and the new active
|
|
joins.
|
|
|
|
We will always trim any direct join if we have the target column
|
|
available already in the previous table. Reverse joins can't be
|
|
trimmed as we don't know if there is anything on the other side of
|
|
the join.
|
|
"""
|
|
joins = joins[:]
|
|
for pos, info in enumerate(reversed(path)):
|
|
if len(joins) == 1 or not info.direct:
|
|
break
|
|
join_targets = set(t.column for t in info.join_field.foreign_related_fields)
|
|
cur_targets = set(t.column for t in targets)
|
|
if not cur_targets.issubset(join_targets):
|
|
break
|
|
targets = tuple(r[0] for r in info.join_field.related_fields if r[1].column in cur_targets)
|
|
self.unref_alias(joins.pop())
|
|
return targets, joins[-1], joins
|
|
|
|
def split_exclude(self, filter_expr, prefix, can_reuse, names_with_path):
|
|
"""
|
|
When doing an exclude against any kind of N-to-many relation, we need
|
|
to use a subquery. This method constructs the nested query, given the
|
|
original exclude filter (filter_expr) and the portion up to the first
|
|
N-to-many relation field.
|
|
|
|
As an example we could have original filter ~Q(child__name='foo').
|
|
We would get here with filter_expr = child__name, prefix = child and
|
|
can_reuse is a set of joins usable for filters in the original query.
|
|
|
|
We will turn this into equivalent of:
|
|
WHERE NOT (pk IN (SELECT parent_id FROM thetable
|
|
WHERE name = 'foo' AND parent_id IS NOT NULL))
|
|
|
|
It might be worth it to consider using WHERE NOT EXISTS as that has
|
|
saner null handling, and is easier for the backend's optimizer to
|
|
handle.
|
|
"""
|
|
# Generate the inner query.
|
|
query = Query(self.model)
|
|
query.add_filter(filter_expr)
|
|
query.clear_ordering(True)
|
|
# Try to have as simple as possible subquery -> trim leading joins from
|
|
# the subquery.
|
|
trimmed_prefix, contains_louter = query.trim_start(names_with_path)
|
|
query.remove_inherited_models()
|
|
|
|
# Add extra check to make sure the selected field will not be null
|
|
# since we are adding an IN <subquery> clause. This prevents the
|
|
# database from tripping over IN (...,NULL,...) selects and returning
|
|
# nothing
|
|
alias, col = query.select[0].col
|
|
if self.is_nullable(query.select[0].field):
|
|
lookup_class = query.select[0].field.get_lookup('isnull')
|
|
lookup = lookup_class(Col(alias, query.select[0].field, query.select[0].field), False)
|
|
query.where.add(lookup, AND)
|
|
if alias in can_reuse:
|
|
select_field = query.select[0].field
|
|
pk = select_field.model._meta.pk
|
|
# Need to add a restriction so that outer query's filters are in effect for
|
|
# the subquery, too.
|
|
query.bump_prefix(self)
|
|
lookup_class = select_field.get_lookup('exact')
|
|
lookup = lookup_class(Col(query.select[0].col[0], pk, pk),
|
|
Col(alias, pk, pk))
|
|
query.where.add(lookup, AND)
|
|
|
|
condition, needed_inner = self.build_filter(
|
|
('%s__in' % trimmed_prefix, query),
|
|
current_negated=True, branch_negated=True, can_reuse=can_reuse)
|
|
if contains_louter:
|
|
or_null_condition, _ = self.build_filter(
|
|
('%s__isnull' % trimmed_prefix, True),
|
|
current_negated=True, branch_negated=True, can_reuse=can_reuse)
|
|
condition.add(or_null_condition, OR)
|
|
# Note that the end result will be:
|
|
# (outercol NOT IN innerq AND outercol IS NOT NULL) OR outercol IS NULL.
|
|
# This might look crazy but due to how IN works, this seems to be
|
|
# correct. If the IS NOT NULL check is removed then outercol NOT
|
|
# IN will return UNKNOWN. If the IS NULL check is removed, then if
|
|
# outercol IS NULL we will not match the row.
|
|
return condition, needed_inner
|
|
|
|
def set_empty(self):
|
|
self.where = EmptyWhere()
|
|
self.having = EmptyWhere()
|
|
|
|
def is_empty(self):
|
|
return isinstance(self.where, EmptyWhere) or isinstance(self.having, EmptyWhere)
|
|
|
|
def set_limits(self, low=None, high=None):
|
|
"""
|
|
Adjusts the limits on the rows retrieved. We use low/high to set these,
|
|
as it makes it more Pythonic to read and write. When the SQL query is
|
|
created, they are converted to the appropriate offset and limit values.
|
|
|
|
Any limits passed in here are applied relative to the existing
|
|
constraints. So low is added to the current low value and both will be
|
|
clamped to any existing high value.
|
|
"""
|
|
if high is not None:
|
|
if self.high_mark is not None:
|
|
self.high_mark = min(self.high_mark, self.low_mark + high)
|
|
else:
|
|
self.high_mark = self.low_mark + high
|
|
if low is not None:
|
|
if self.high_mark is not None:
|
|
self.low_mark = min(self.high_mark, self.low_mark + low)
|
|
else:
|
|
self.low_mark = self.low_mark + low
|
|
|
|
def clear_limits(self):
|
|
"""
|
|
Clears any existing limits.
|
|
"""
|
|
self.low_mark, self.high_mark = 0, None
|
|
|
|
def can_filter(self):
|
|
"""
|
|
Returns True if adding filters to this instance is still possible.
|
|
|
|
Typically, this means no limits or offsets have been put on the results.
|
|
"""
|
|
return not self.low_mark and self.high_mark is None
|
|
|
|
def clear_select_clause(self):
|
|
"""
|
|
Removes all fields from SELECT clause.
|
|
"""
|
|
self.select = []
|
|
self.default_cols = False
|
|
self.select_related = False
|
|
self.set_extra_mask(())
|
|
self.set_aggregate_mask(())
|
|
|
|
def clear_select_fields(self):
|
|
"""
|
|
Clears the list of fields to select (but not extra_select columns).
|
|
Some queryset types completely replace any existing list of select
|
|
columns.
|
|
"""
|
|
self.select = []
|
|
|
|
def add_distinct_fields(self, *field_names):
|
|
"""
|
|
Adds and resolves the given fields to the query's "distinct on" clause.
|
|
"""
|
|
self.distinct_fields = field_names
|
|
self.distinct = True
|
|
|
|
def add_fields(self, field_names, allow_m2m=True):
|
|
"""
|
|
Adds the given (model) fields to the select set. The field names are
|
|
added in the order specified.
|
|
"""
|
|
alias = self.get_initial_alias()
|
|
opts = self.get_meta()
|
|
|
|
try:
|
|
for name in field_names:
|
|
# Join promotion note - we must not remove any rows here, so
|
|
# if there is no existing joins, use outer join.
|
|
_, targets, _, joins, path = self.setup_joins(
|
|
name.split(LOOKUP_SEP), opts, alias, allow_many=allow_m2m)
|
|
targets, final_alias, joins = self.trim_joins(targets, joins, path)
|
|
for target in targets:
|
|
self.select.append(SelectInfo((final_alias, target.column), target))
|
|
except MultiJoin:
|
|
raise FieldError("Invalid field name: '%s'" % name)
|
|
except FieldError:
|
|
if LOOKUP_SEP in name:
|
|
# For lookups spanning over relationships, show the error
|
|
# from the model on which the lookup failed.
|
|
raise
|
|
else:
|
|
names = sorted(opts.get_all_field_names() + list(self.extra)
|
|
+ list(self.aggregate_select))
|
|
raise FieldError("Cannot resolve keyword %r into field. "
|
|
"Choices are: %s" % (name, ", ".join(names)))
|
|
self.remove_inherited_models()
|
|
|
|
def add_ordering(self, *ordering):
|
|
"""
|
|
Adds items from the 'ordering' sequence to the query's "order by"
|
|
clause. These items are either field names (not column names) --
|
|
possibly with a direction prefix ('-' or '?') -- or ordinals,
|
|
corresponding to column positions in the 'select' list.
|
|
|
|
If 'ordering' is empty, all ordering is cleared from the query.
|
|
"""
|
|
errors = []
|
|
for item in ordering:
|
|
if not ORDER_PATTERN.match(item):
|
|
errors.append(item)
|
|
if errors:
|
|
raise FieldError('Invalid order_by arguments: %s' % errors)
|
|
if ordering:
|
|
self.order_by.extend(ordering)
|
|
else:
|
|
self.default_ordering = False
|
|
|
|
def clear_ordering(self, force_empty):
|
|
"""
|
|
Removes any ordering settings. If 'force_empty' is True, there will be
|
|
no ordering in the resulting query (not even the model's default).
|
|
"""
|
|
self.order_by = []
|
|
self.extra_order_by = ()
|
|
if force_empty:
|
|
self.default_ordering = False
|
|
|
|
def set_group_by(self):
|
|
"""
|
|
Expands the GROUP BY clause required by the query.
|
|
|
|
This will usually be the set of all non-aggregate fields in the
|
|
return data. If the database backend supports grouping by the
|
|
primary key, and the query would be equivalent, the optimization
|
|
will be made automatically.
|
|
"""
|
|
self.group_by = []
|
|
|
|
for col, _ in self.select:
|
|
self.group_by.append(col)
|
|
|
|
def add_count_column(self):
|
|
"""
|
|
Converts the query to do count(...) or count(distinct(pk)) in order to
|
|
get its size.
|
|
"""
|
|
if not self.distinct:
|
|
if not self.select:
|
|
count = self.aggregates_module.Count('*', is_summary=True)
|
|
else:
|
|
assert len(self.select) == 1, \
|
|
"Cannot add count col with multiple cols in 'select': %r" % self.select
|
|
count = self.aggregates_module.Count(self.select[0].col)
|
|
else:
|
|
opts = self.get_meta()
|
|
if not self.select:
|
|
count = self.aggregates_module.Count(
|
|
(self.join((None, opts.db_table, None)), opts.pk.column),
|
|
is_summary=True, distinct=True)
|
|
else:
|
|
# Because of SQL portability issues, multi-column, distinct
|
|
# counts need a sub-query -- see get_count() for details.
|
|
assert len(self.select) == 1, \
|
|
"Cannot add count col with multiple cols in 'select'."
|
|
|
|
count = self.aggregates_module.Count(self.select[0].col, distinct=True)
|
|
# Distinct handling is done in Count(), so don't do it at this
|
|
# level.
|
|
self.distinct = False
|
|
|
|
# Set only aggregate to be the count column.
|
|
# Clear out the select cache to reflect the new unmasked aggregates.
|
|
self._aggregates = {None: count}
|
|
self.set_aggregate_mask(None)
|
|
self.group_by = None
|
|
|
|
def add_select_related(self, fields):
|
|
"""
|
|
Sets up the select_related data structure so that we only select
|
|
certain related models (as opposed to all models, when
|
|
self.select_related=True).
|
|
"""
|
|
if isinstance(self.select_related, bool):
|
|
field_dict = {}
|
|
else:
|
|
field_dict = self.select_related
|
|
for field in fields:
|
|
d = field_dict
|
|
for part in field.split(LOOKUP_SEP):
|
|
d = d.setdefault(part, {})
|
|
self.select_related = field_dict
|
|
self.related_select_cols = []
|
|
|
|
def add_extra(self, select, select_params, where, params, tables, order_by):
|
|
"""
|
|
Adds data to the various extra_* attributes for user-created additions
|
|
to the query.
|
|
"""
|
|
if select:
|
|
# We need to pair any placeholder markers in the 'select'
|
|
# dictionary with their parameters in 'select_params' so that
|
|
# subsequent updates to the select dictionary also adjust the
|
|
# parameters appropriately.
|
|
select_pairs = OrderedDict()
|
|
if select_params:
|
|
param_iter = iter(select_params)
|
|
else:
|
|
param_iter = iter([])
|
|
for name, entry in select.items():
|
|
entry = force_text(entry)
|
|
entry_params = []
|
|
pos = entry.find("%s")
|
|
while pos != -1:
|
|
entry_params.append(next(param_iter))
|
|
pos = entry.find("%s", pos + 2)
|
|
select_pairs[name] = (entry, entry_params)
|
|
# This is order preserving, since self.extra_select is an OrderedDict.
|
|
self.extra.update(select_pairs)
|
|
if where or params:
|
|
self.where.add(ExtraWhere(where, params), AND)
|
|
if tables:
|
|
self.extra_tables += tuple(tables)
|
|
if order_by:
|
|
self.extra_order_by = order_by
|
|
|
|
def clear_deferred_loading(self):
|
|
"""
|
|
Remove any fields from the deferred loading set.
|
|
"""
|
|
self.deferred_loading = (set(), True)
|
|
|
|
def add_deferred_loading(self, field_names):
|
|
"""
|
|
Add the given list of model field names to the set of fields to
|
|
exclude from loading from the database when automatic column selection
|
|
is done. The new field names are added to any existing field names that
|
|
are deferred (or removed from any existing field names that are marked
|
|
as the only ones for immediate loading).
|
|
"""
|
|
# Fields on related models are stored in the literal double-underscore
|
|
# format, so that we can use a set datastructure. We do the foo__bar
|
|
# splitting and handling when computing the SQL column names (as part of
|
|
# get_columns()).
|
|
existing, defer = self.deferred_loading
|
|
if defer:
|
|
# Add to existing deferred names.
|
|
self.deferred_loading = existing.union(field_names), True
|
|
else:
|
|
# Remove names from the set of any existing "immediate load" names.
|
|
self.deferred_loading = existing.difference(field_names), False
|
|
|
|
def add_immediate_loading(self, field_names):
|
|
"""
|
|
Add the given list of model field names to the set of fields to
|
|
retrieve when the SQL is executed ("immediate loading" fields). The
|
|
field names replace any existing immediate loading field names. If
|
|
there are field names already specified for deferred loading, those
|
|
names are removed from the new field_names before storing the new names
|
|
for immediate loading. (That is, immediate loading overrides any
|
|
existing immediate values, but respects existing deferrals.)
|
|
"""
|
|
existing, defer = self.deferred_loading
|
|
field_names = set(field_names)
|
|
if 'pk' in field_names:
|
|
field_names.remove('pk')
|
|
field_names.add(self.get_meta().pk.name)
|
|
|
|
if defer:
|
|
# Remove any existing deferred names from the current set before
|
|
# setting the new names.
|
|
self.deferred_loading = field_names.difference(existing), False
|
|
else:
|
|
# Replace any existing "immediate load" field names.
|
|
self.deferred_loading = field_names, False
|
|
|
|
def get_loaded_field_names(self):
|
|
"""
|
|
If any fields are marked to be deferred, returns a dictionary mapping
|
|
models to a set of names in those fields that will be loaded. If a
|
|
model is not in the returned dictionary, none of its fields are
|
|
deferred.
|
|
|
|
If no fields are marked for deferral, returns an empty dictionary.
|
|
"""
|
|
# We cache this because we call this function multiple times
|
|
# (compiler.fill_related_selections, query.iterator)
|
|
try:
|
|
return self._loaded_field_names_cache
|
|
except AttributeError:
|
|
collection = {}
|
|
self.deferred_to_data(collection, self.get_loaded_field_names_cb)
|
|
self._loaded_field_names_cache = collection
|
|
return collection
|
|
|
|
def get_loaded_field_names_cb(self, target, model, fields):
|
|
"""
|
|
Callback used by get_deferred_field_names().
|
|
"""
|
|
target[model] = set(f.name for f in fields)
|
|
|
|
def set_aggregate_mask(self, names):
|
|
"Set the mask of aggregates that will actually be returned by the SELECT"
|
|
if names is None:
|
|
self.aggregate_select_mask = None
|
|
else:
|
|
self.aggregate_select_mask = set(names)
|
|
self._aggregate_select_cache = None
|
|
|
|
def append_aggregate_mask(self, names):
|
|
if self.aggregate_select_mask is not None:
|
|
self.set_aggregate_mask(set(names).union(self.aggregate_select_mask))
|
|
|
|
def set_extra_mask(self, names):
|
|
"""
|
|
Set the mask of extra select items that will be returned by SELECT,
|
|
we don't actually remove them from the Query since they might be used
|
|
later
|
|
"""
|
|
if names is None:
|
|
self.extra_select_mask = None
|
|
else:
|
|
self.extra_select_mask = set(names)
|
|
self._extra_select_cache = None
|
|
|
|
@property
|
|
def aggregate_select(self):
|
|
"""The OrderedDict of aggregate columns that are not masked, and should
|
|
be used in the SELECT clause.
|
|
|
|
This result is cached for optimization purposes.
|
|
"""
|
|
if self._aggregate_select_cache is not None:
|
|
return self._aggregate_select_cache
|
|
elif not self._aggregates:
|
|
return {}
|
|
elif self.aggregate_select_mask is not None:
|
|
self._aggregate_select_cache = OrderedDict(
|
|
(k, v) for k, v in self.aggregates.items()
|
|
if k in self.aggregate_select_mask
|
|
)
|
|
return self._aggregate_select_cache
|
|
else:
|
|
return self.aggregates
|
|
|
|
@property
|
|
def extra_select(self):
|
|
if self._extra_select_cache is not None:
|
|
return self._extra_select_cache
|
|
if not self._extra:
|
|
return {}
|
|
elif self.extra_select_mask is not None:
|
|
self._extra_select_cache = OrderedDict(
|
|
(k, v) for k, v in self.extra.items()
|
|
if k in self.extra_select_mask
|
|
)
|
|
return self._extra_select_cache
|
|
else:
|
|
return self.extra
|
|
|
|
def trim_start(self, names_with_path):
|
|
"""
|
|
Trims joins from the start of the join path. The candidates for trim
|
|
are the PathInfos in names_with_path structure that are m2m joins.
|
|
|
|
Also sets the select column so the start matches the join.
|
|
|
|
This method is meant to be used for generating the subquery joins &
|
|
cols in split_exclude().
|
|
|
|
Returns a lookup usable for doing outerq.filter(lookup=self). Returns
|
|
also if the joins in the prefix contain a LEFT OUTER join.
|
|
_"""
|
|
all_paths = []
|
|
for _, paths in names_with_path:
|
|
all_paths.extend(paths)
|
|
contains_louter = False
|
|
# Trim and operate only on tables that were generated for
|
|
# the lookup part of the query. That is, avoid trimming
|
|
# joins generated for F() expressions.
|
|
lookup_tables = [t for t in self.tables if t in self._lookup_joins or t == self.tables[0]]
|
|
for trimmed_paths, path in enumerate(all_paths):
|
|
if path.m2m:
|
|
break
|
|
if self.alias_map[lookup_tables[trimmed_paths + 1]].join_type == self.LOUTER:
|
|
contains_louter = True
|
|
self.unref_alias(lookup_tables[trimmed_paths])
|
|
# The path.join_field is a Rel, lets get the other side's field
|
|
join_field = path.join_field.field
|
|
# Build the filter prefix.
|
|
paths_in_prefix = trimmed_paths
|
|
trimmed_prefix = []
|
|
for name, path in names_with_path:
|
|
if paths_in_prefix - len(path) < 0:
|
|
break
|
|
trimmed_prefix.append(name)
|
|
paths_in_prefix -= len(path)
|
|
trimmed_prefix.append(
|
|
join_field.foreign_related_fields[0].name)
|
|
trimmed_prefix = LOOKUP_SEP.join(trimmed_prefix)
|
|
# Lets still see if we can trim the first join from the inner query
|
|
# (that is, self). We can't do this for LEFT JOINs because we would
|
|
# miss those rows that have nothing on the outer side.
|
|
if self.alias_map[lookup_tables[trimmed_paths + 1]].join_type != self.LOUTER:
|
|
select_fields = [r[0] for r in join_field.related_fields]
|
|
select_alias = lookup_tables[trimmed_paths + 1]
|
|
self.unref_alias(lookup_tables[trimmed_paths])
|
|
extra_restriction = join_field.get_extra_restriction(
|
|
self.where_class, None, lookup_tables[trimmed_paths + 1])
|
|
if extra_restriction:
|
|
self.where.add(extra_restriction, AND)
|
|
else:
|
|
# TODO: It might be possible to trim more joins from the start of the
|
|
# inner query if it happens to have a longer join chain containing the
|
|
# values in select_fields. Lets punt this one for now.
|
|
select_fields = [r[1] for r in join_field.related_fields]
|
|
select_alias = lookup_tables[trimmed_paths]
|
|
self.select = [SelectInfo((select_alias, f.column), f) for f in select_fields]
|
|
return trimmed_prefix, contains_louter
|
|
|
|
def is_nullable(self, field):
|
|
"""
|
|
A helper to check if the given field should be treated as nullable.
|
|
|
|
Some backends treat '' as null and Django treats such fields as
|
|
nullable for those backends. In such situations field.null can be
|
|
False even if we should treat the field as nullable.
|
|
"""
|
|
# We need to use DEFAULT_DB_ALIAS here, as QuerySet does not have
|
|
# (nor should it have) knowledge of which connection is going to be
|
|
# used. The proper fix would be to defer all decisions where
|
|
# is_nullable() is needed to the compiler stage, but that is not easy
|
|
# to do currently.
|
|
if ((connections[DEFAULT_DB_ALIAS].features.interprets_empty_strings_as_nulls)
|
|
and field.empty_strings_allowed):
|
|
return True
|
|
else:
|
|
return field.null
|
|
|
|
|
|
def get_order_dir(field, default='ASC'):
|
|
"""
|
|
Returns the field name and direction for an order specification. For
|
|
example, '-foo' is returned as ('foo', 'DESC').
|
|
|
|
The 'default' param is used to indicate which way no prefix (or a '+'
|
|
prefix) should sort. The '-' prefix always sorts the opposite way.
|
|
"""
|
|
dirn = ORDER_DIR[default]
|
|
if field[0] == '-':
|
|
return field[1:], dirn[1]
|
|
return field, dirn[0]
|
|
|
|
|
|
def add_to_dict(data, key, value):
|
|
"""
|
|
A helper function to add "value" to the set of values for "key", whether or
|
|
not "key" already exists.
|
|
"""
|
|
if key in data:
|
|
data[key].add(value)
|
|
else:
|
|
data[key] = set([value])
|
|
|
|
|
|
def is_reverse_o2o(field):
|
|
"""
|
|
A little helper to check if the given field is reverse-o2o. The field is
|
|
expected to be some sort of relation field or related object.
|
|
"""
|
|
return not hasattr(field, 'rel') and field.field.unique
|
|
|
|
|
|
def alias_diff(refcounts_before, refcounts_after):
|
|
"""
|
|
Given the before and after copies of refcounts works out which aliases
|
|
have been added to the after copy.
|
|
"""
|
|
# Use -1 as default value so that any join that is created, then trimmed
|
|
# is seen as added.
|
|
return set(t for t in refcounts_after
|
|
if refcounts_after[t] > refcounts_before.get(t, -1))
|
|
|
|
|
|
class JoinPromoter(object):
|
|
"""
|
|
A class to abstract away join promotion problems for complex filter
|
|
conditions.
|
|
"""
|
|
|
|
def __init__(self, connector, num_children, negated):
|
|
self.connector = connector
|
|
self.negated = negated
|
|
if self.negated:
|
|
if connector == AND:
|
|
self.effective_connector = OR
|
|
else:
|
|
self.effective_connector = AND
|
|
else:
|
|
self.effective_connector = self.connector
|
|
self.num_children = num_children
|
|
# Maps of table alias to how many times it is seen as required for
|
|
# inner and/or outer joins.
|
|
self.outer_votes = {}
|
|
self.inner_votes = {}
|
|
|
|
def add_votes(self, inner_votes):
|
|
"""
|
|
Add single vote per item to self.inner_votes. Parameter can be any
|
|
iterable.
|
|
"""
|
|
for voted in inner_votes:
|
|
self.inner_votes[voted] = self.inner_votes.get(voted, 0) + 1
|
|
|
|
def update_join_types(self, query):
|
|
"""
|
|
Change join types so that the generated query is as efficient as
|
|
possible, but still correct. So, change as many joins as possible
|
|
to INNER, but don't make OUTER joins INNER if that could remove
|
|
results from the query.
|
|
"""
|
|
to_promote = set()
|
|
to_demote = set()
|
|
# The effective_connector is used so that NOT (a AND b) is treated
|
|
# similarly to (a OR b) for join promotion.
|
|
for table, votes in self.inner_votes.items():
|
|
# We must use outer joins in OR case when the join isn't contained
|
|
# in all of the joins. Otherwise the INNER JOIN itself could remove
|
|
# valid results. Consider the case where a model with rel_a and
|
|
# rel_b relations is queried with rel_a__col=1 | rel_b__col=2. Now,
|
|
# if rel_a join doesn't produce any results is null (for example
|
|
# reverse foreign key or null value in direct foreign key), and
|
|
# there is a matching row in rel_b with col=2, then an INNER join
|
|
# to rel_a would remove a valid match from the query. So, we need
|
|
# to promote any existing INNER to LOUTER (it is possible this
|
|
# promotion in turn will be demoted later on).
|
|
if self.effective_connector == 'OR' and votes < self.num_children:
|
|
to_promote.add(table)
|
|
# If connector is AND and there is a filter that can match only
|
|
# when there is a joinable row, then use INNER. For example, in
|
|
# rel_a__col=1 & rel_b__col=2, if either of the rels produce NULL
|
|
# as join output, then the col=1 or col=2 can't match (as
|
|
# NULL=anything is always false).
|
|
# For the OR case, if all children voted for a join to be inner,
|
|
# then we can use INNER for the join. For example:
|
|
# (rel_a__col__icontains=Alex | rel_a__col__icontains=Russell)
|
|
# then if rel_a doesn't produce any rows, the whole condition
|
|
# can't match. Hence we can safely use INNER join.
|
|
if self.effective_connector == 'AND' or (
|
|
self.effective_connector == 'OR' and votes == self.num_children):
|
|
to_demote.add(table)
|
|
# Finally, what happens in cases where we have:
|
|
# (rel_a__col=1|rel_b__col=2) & rel_a__col__gte=0
|
|
# Now, we first generate the OR clause, and promote joins for it
|
|
# in the first if branch above. Both rel_a and rel_b are promoted
|
|
# to LOUTER joins. After that we do the AND case. The OR case
|
|
# voted no inner joins but the rel_a__col__gte=0 votes inner join
|
|
# for rel_a. We demote it back to INNER join (in AND case a single
|
|
# vote is enough). The demotion is OK, if rel_a doesn't produce
|
|
# rows, then the rel_a__col__gte=0 clause can't be true, and thus
|
|
# the whole clause must be false. So, it is safe to use INNER
|
|
# join.
|
|
# Note that in this example we could just as well have the __gte
|
|
# clause and the OR clause swapped. Or we could replace the __gte
|
|
# clause with an OR clause containing rel_a__col=1|rel_a__col=2,
|
|
# and again we could safely demote to INNER.
|
|
query.promote_joins(to_promote)
|
|
query.demote_joins(to_demote)
|
|
return to_demote
|