Add files using upload-large-folder tool

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	import copy
	from collections import defaultdict
	from contextlib import contextmanager
	from functools import partial

	from django.apps import AppConfig
	from django.apps.registry import Apps
	from django.apps.registry import apps as global_apps
	from django.conf import settings
	from django.core.exceptions import FieldDoesNotExist
	from django.db import models
	from django.db.migrations.utils import field_is_referenced, get_references
	from django.db.models import NOT_PROVIDED
	from django.db.models.fields.related import RECURSIVE_RELATIONSHIP_CONSTANT
	from django.db.models.options import DEFAULT_NAMES, normalize_together
	from django.db.models.utils import make_model_tuple
	from django.utils.functional import cached_property
	from django.utils.module_loading import import_string
	from django.utils.version import get_docs_version

	from .exceptions import InvalidBasesError
	from .utils import resolve_relation


	def _get_app_label_and_model_name(model, app_label=""):
	if isinstance(model, str):
	split = model.split(".", 1)
	return tuple(split) if len(split) == 2 else (app_label, split[0])
	else:
	return model._meta.app_label, model._meta.model_name


	def _get_related_models(m):
	"""Return all models that have a direct relationship to the given model."""
	related_models = [
	subclass
	for subclass in m.__subclasses__()
	if issubclass(subclass, models.Model)
	]
	related_fields_models = set()
	for f in m._meta.get_fields(include_parents=True, include_hidden=True):
	if (
	f.is_relation
	and f.related_model is not None
	and not isinstance(f.related_model, str)
	):
	related_fields_models.add(f.model)
	related_models.append(f.related_model)
	# Reverse accessors of foreign keys to proxy models are attached to their
	# concrete proxied model.
	opts = m._meta
	if opts.proxy and m in related_fields_models:
	related_models.append(opts.concrete_model)
	return related_models


	def get_related_models_tuples(model):
	"""
	Return a list of typical (app_label, model_name) tuples for all related
	models for the given model.
	"""
	return {
	(rel_mod._meta.app_label, rel_mod._meta.model_name)
	for rel_mod in _get_related_models(model)
	}


	def get_related_models_recursive(model):
	"""
	Return all models that have a direct or indirect relationship
	to the given model.

	Relationships are either defined by explicit relational fields, like
	ForeignKey, ManyToManyField or OneToOneField, or by inheriting from another
	model (a superclass is related to its subclasses, but not vice versa). Note,
	however, that a model inheriting from a concrete model is also related to
	its superclass through the implicit *_ptr OneToOneField on the subclass.
	"""
	seen = set()
	queue = _get_related_models(model)
	for rel_mod in queue:
	rel_app_label, rel_model_name = (
	rel_mod._meta.app_label,
	rel_mod._meta.model_name,
	)
	if (rel_app_label, rel_model_name) in seen:
	continue
	seen.add((rel_app_label, rel_model_name))
	queue.extend(_get_related_models(rel_mod))
	return seen - {(model._meta.app_label, model._meta.model_name)}


	class ProjectState:
	"""
	Represent the entire project's overall state. This is the item that is
	passed around - do it here rather than at the app level so that cross-app
	FKs/etc. resolve properly.
	"""

	def __init__(self, models=None, real_apps=None):
	self.models = models or {}
	# Apps to include from main registry, usually unmigrated ones
	if real_apps is None:
	real_apps = set()
	else:
	assert isinstance(real_apps, set)
	self.real_apps = real_apps
	self.is_delayed = False
	# {remote_model_key: {model_key: {field_name: field}}}
	self._relations = None

	@property
	def relations(self):
	if self._relations is None:
	self.resolve_fields_and_relations()
	return self._relations

	def add_model(self, model_state):
	model_key = model_state.app_label, model_state.name_lower
	self.models[model_key] = model_state
	if self._relations is not None:
	self.resolve_model_relations(model_key)
	if "apps" in self.__dict__: # hasattr would cache the property
	self.reload_model(*model_key)

	def remove_model(self, app_label, model_name):
	model_key = app_label, model_name
	del self.models[model_key]
	if self._relations is not None:
	self._relations.pop(model_key, None)
	# Call list() since _relations can change size during iteration.
	for related_model_key, model_relations in list(self._relations.items()):
	model_relations.pop(model_key, None)
	if not model_relations:
	del self._relations[related_model_key]
	if "apps" in self.__dict__: # hasattr would cache the property
	self.apps.unregister_model(*model_key)
	# Need to do this explicitly since unregister_model() doesn't clear
	# the cache automatically (#24513)
	self.apps.clear_cache()

	def rename_model(self, app_label, old_name, new_name):
	# Add a new model.
	old_name_lower = old_name.lower()
	new_name_lower = new_name.lower()
	renamed_model = self.models[app_label, old_name_lower].clone()
	renamed_model.name = new_name
	self.models[app_label, new_name_lower] = renamed_model
	# Repoint all fields pointing to the old model to the new one.
	old_model_tuple = (app_label, old_name_lower)
	new_remote_model = f"{app_label}.{new_name}"
	to_reload = set()
	for model_state, name, field, reference in get_references(
	self, old_model_tuple
	):
	changed_field = None
	if reference.to:
	changed_field = field.clone()
	changed_field.remote_field.model = new_remote_model
	if reference.through:
	if changed_field is None:
	changed_field = field.clone()
	changed_field.remote_field.through = new_remote_model
	if changed_field:
	model_state.fields[name] = changed_field
	to_reload.add((model_state.app_label, model_state.name_lower))
	if self._relations is not None:
	old_name_key = app_label, old_name_lower
	new_name_key = app_label, new_name_lower
	if old_name_key in self._relations:
	self._relations[new_name_key] = self._relations.pop(old_name_key)
	for model_relations in self._relations.values():
	if old_name_key in model_relations:
	model_relations[new_name_key] = model_relations.pop(old_name_key)
	# Reload models related to old model before removing the old model.
	self.reload_models(to_reload, delay=True)
	# Remove the old model.
	self.remove_model(app_label, old_name_lower)
	self.reload_model(app_label, new_name_lower, delay=True)

	def alter_model_options(self, app_label, model_name, options, option_keys=None):
	model_state = self.models[app_label, model_name]
	model_state.options = {model_state.options, options}
	if option_keys:
	for key in option_keys:
	if key not in options:
	model_state.options.pop(key, False)
	self.reload_model(app_label, model_name, delay=True)

	def remove_model_options(self, app_label, model_name, option_name, value_to_remove):
	model_state = self.models[app_label, model_name]
	if objs := model_state.options.get(option_name):
	model_state.options[option_name] = [
	obj for obj in objs if tuple(obj) != tuple(value_to_remove)
	]
	self.reload_model(app_label, model_name, delay=True)

	def alter_model_managers(self, app_label, model_name, managers):
	model_state = self.models[app_label, model_name]
	model_state.managers = list(managers)
	self.reload_model(app_label, model_name, delay=True)

	def _append_option(self, app_label, model_name, option_name, obj):
	model_state = self.models[app_label, model_name]
	model_state.options[option_name] = [*model_state.options[option_name], obj]
	self.reload_model(app_label, model_name, delay=True)

	def _remove_option(self, app_label, model_name, option_name, obj_name):
	model_state = self.models[app_label, model_name]
	objs = model_state.options[option_name]
	model_state.options[option_name] = [obj for obj in objs if obj.name != obj_name]
	self.reload_model(app_label, model_name, delay=True)

	def add_index(self, app_label, model_name, index):
	self._append_option(app_label, model_name, "indexes", index)

	def remove_index(self, app_label, model_name, index_name):
	self._remove_option(app_label, model_name, "indexes", index_name)

	def rename_index(self, app_label, model_name, old_index_name, new_index_name):
	model_state = self.models[app_label, model_name]
	objs = model_state.options["indexes"]

	new_indexes = []
	for obj in objs:
	if obj.name == old_index_name:
	obj = obj.clone()
	obj.name = new_index_name
	new_indexes.append(obj)

	model_state.options["indexes"] = new_indexes
	self.reload_model(app_label, model_name, delay=True)

	def add_constraint(self, app_label, model_name, constraint):
	self._append_option(app_label, model_name, "constraints", constraint)

	def remove_constraint(self, app_label, model_name, constraint_name):
	self._remove_option(app_label, model_name, "constraints", constraint_name)

	def add_field(self, app_label, model_name, name, field, preserve_default):
	# If preserve default is off, don't use the default for future state.
	if not preserve_default:
	field = field.clone()
	field.default = NOT_PROVIDED
	else:
	field = field
	model_key = app_label, model_name
	self.models[model_key].fields[name] = field
	if self._relations is not None:
	self.resolve_model_field_relations(model_key, name, field)
	# Delay rendering of relationships if it's not a relational field.
	delay = not field.is_relation
	self.reload_model(*model_key, delay=delay)

	def remove_field(self, app_label, model_name, name):
	model_key = app_label, model_name
	model_state = self.models[model_key]
	old_field = model_state.fields.pop(name)
	if self._relations is not None:
	self.resolve_model_field_relations(model_key, name, old_field)
	# Delay rendering of relationships if it's not a relational field.
	delay = not old_field.is_relation
	self.reload_model(*model_key, delay=delay)

	def alter_field(self, app_label, model_name, name, field, preserve_default):
	if not preserve_default:
	field = field.clone()
	field.default = NOT_PROVIDED
	else:
	field = field
	model_key = app_label, model_name
	fields = self.models[model_key].fields
	if self._relations is not None:
	old_field = fields.pop(name)
	if old_field.is_relation:
	self.resolve_model_field_relations(model_key, name, old_field)
	fields[name] = field
	if field.is_relation:
	self.resolve_model_field_relations(model_key, name, field)
	else:
	fields[name] = field
	# TODO: investigate if old relational fields must be reloaded or if
	# it's sufficient if the new field is (#27737).
	# Delay rendering of relationships if it's not a relational field and
	# not referenced by a foreign key.
	delay = not field.is_relation and not field_is_referenced(
	self, model_key, (name, field)
	)
	self.reload_model(*model_key, delay=delay)

	def rename_field(self, app_label, model_name, old_name, new_name):
	model_key = app_label, model_name
	model_state = self.models[model_key]
	# Rename the field.
	fields = model_state.fields
	try:
	found = fields.pop(old_name)
	except KeyError:
	raise FieldDoesNotExist(
	f"{app_label}.{model_name} has no field named '{old_name}'"
	)
	fields[new_name] = found
	for field in fields.values():
	# Fix from_fields to refer to the new field.
	from_fields = getattr(field, "from_fields", None)
	if from_fields:
	field.from_fields = tuple(
	[
	new_name if from_field_name == old_name else from_field_name
	for from_field_name in from_fields
	]
	)
	# Fix index/unique_together to refer to the new field.
	options = model_state.options
	for option in ("index_together", "unique_together"):
	if option in options:
	options[option] = [
	[new_name if n == old_name else n for n in together]
	for together in options[option]
	]
	# Fix to_fields to refer to the new field.
	delay = True
	references = get_references(self, model_key, (old_name, found))
	for *_, field, reference in references:
	delay = False
	if reference.to:
	remote_field, to_fields = reference.to
	if getattr(remote_field, "field_name", None) == old_name:
	remote_field.field_name = new_name
	if to_fields:
	field.to_fields = tuple(
	[
	new_name if to_field_name == old_name else to_field_name
	for to_field_name in to_fields
	]
	)
	if self._relations is not None:
	old_name_lower = old_name.lower()
	new_name_lower = new_name.lower()
	for to_model in self._relations.values():
	if old_name_lower in to_model[model_key]:
	field = to_model[model_key].pop(old_name_lower)
	field.name = new_name_lower
	to_model[model_key][new_name_lower] = field
	self.reload_model(*model_key, delay=delay)

	def _find_reload_model(self, app_label, model_name, delay=False):
	if delay:
	self.is_delayed = True

	related_models = set()

	try:
	old_model = self.apps.get_model(app_label, model_name)
	except LookupError:
	pass
	else:
	# Get all relations to and from the old model before reloading,
	# as _meta.apps may change
	if delay:
	related_models = get_related_models_tuples(old_model)
	else:
	related_models = get_related_models_recursive(old_model)

	# Get all outgoing references from the model to be rendered
	model_state = self.models[(app_label, model_name)]
	# Directly related models are the models pointed to by ForeignKeys,
	# OneToOneFields, and ManyToManyFields.
	direct_related_models = set()
	for field in model_state.fields.values():
	if field.is_relation:
	if field.remote_field.model == RECURSIVE_RELATIONSHIP_CONSTANT:
	continue
	rel_app_label, rel_model_name = _get_app_label_and_model_name(
	field.related_model, app_label
	)
	direct_related_models.add((rel_app_label, rel_model_name.lower()))

	# For all direct related models recursively get all related models.
	related_models.update(direct_related_models)
	for rel_app_label, rel_model_name in direct_related_models:
	try:
	rel_model = self.apps.get_model(rel_app_label, rel_model_name)
	except LookupError:
	pass
	else:
	if delay:
	related_models.update(get_related_models_tuples(rel_model))
	else:
	related_models.update(get_related_models_recursive(rel_model))

	# Include the model itself
	related_models.add((app_label, model_name))

	return related_models

	def reload_model(self, app_label, model_name, delay=False):
	if "apps" in self.__dict__: # hasattr would cache the property
	related_models = self._find_reload_model(app_label, model_name, delay)
	self._reload(related_models)

	def reload_models(self, models, delay=True):
	if "apps" in self.__dict__: # hasattr would cache the property
	related_models = set()
	for app_label, model_name in models:
	related_models.update(
	self._find_reload_model(app_label, model_name, delay)
	)
	self._reload(related_models)

	def _reload(self, related_models):
	# Unregister all related models
	with self.apps.bulk_update():
	for rel_app_label, rel_model_name in related_models:
	self.apps.unregister_model(rel_app_label, rel_model_name)

	states_to_be_rendered = []
	# Gather all models states of those models that will be rerendered.
	# This includes:
	# 1. All related models of unmigrated apps
	for model_state in self.apps.real_models:
	if (model_state.app_label, model_state.name_lower) in related_models:
	states_to_be_rendered.append(model_state)

	# 2. All related models of migrated apps
	for rel_app_label, rel_model_name in related_models:
	try:
	model_state = self.models[rel_app_label, rel_model_name]
	except KeyError:
	pass
	else:
	states_to_be_rendered.append(model_state)

	# Render all models
	self.apps.render_multiple(states_to_be_rendered)

	def update_model_field_relation(
	self,
	model,
	model_key,
	field_name,
	field,
	concretes,
	):
	remote_model_key = resolve_relation(model, *model_key)
	if remote_model_key[0] not in self.real_apps and remote_model_key in concretes:
	remote_model_key = concretes[remote_model_key]
	relations_to_remote_model = self._relations[remote_model_key]
	if field_name in self.models[model_key].fields:
	# The assert holds because it's a new relation, or an altered
	# relation, in which case references have been removed by
	# alter_field().
	assert field_name not in relations_to_remote_model[model_key]
	relations_to_remote_model[model_key][field_name] = field
	else:
	del relations_to_remote_model[model_key][field_name]
	if not relations_to_remote_model[model_key]:
	del relations_to_remote_model[model_key]

	def resolve_model_field_relations(
	self,
	model_key,
	field_name,
	field,
	concretes=None,
	):
	remote_field = field.remote_field
	if not remote_field:
	return
	if concretes is None:
	concretes, _ = self._get_concrete_models_mapping_and_proxy_models()

	self.update_model_field_relation(
	remote_field.model,
	model_key,
	field_name,
	field,
	concretes,
	)

	through = getattr(remote_field, "through", None)
	if not through:
	return
	self.update_model_field_relation(
	through, model_key, field_name, field, concretes
	)

	def resolve_model_relations(self, model_key, concretes=None):
	if concretes is None:
	concretes, _ = self._get_concrete_models_mapping_and_proxy_models()

	model_state = self.models[model_key]
	for field_name, field in model_state.fields.items():
	self.resolve_model_field_relations(model_key, field_name, field, concretes)

	def resolve_fields_and_relations(self):
	# Resolve fields.
	for model_state in self.models.values():
	for field_name, field in model_state.fields.items():
	field.name = field_name
	# Resolve relations.
	# {remote_model_key: {model_key: {field_name: field}}}
	self._relations = defaultdict(partial(defaultdict, dict))
	concretes, proxies = self._get_concrete_models_mapping_and_proxy_models()

	for model_key in concretes:
	self.resolve_model_relations(model_key, concretes)

	for model_key in proxies:
	self._relations[model_key] = self._relations[concretes[model_key]]

	def get_concrete_model_key(self, model):
	(
	concrete_models_mapping,
	_,
	) = self._get_concrete_models_mapping_and_proxy_models()
	model_key = make_model_tuple(model)
	return concrete_models_mapping[model_key]

	def _get_concrete_models_mapping_and_proxy_models(self):
	concrete_models_mapping = {}
	proxy_models = {}
	# Split models to proxy and concrete models.
	for model_key, model_state in self.models.items():
	if model_state.options.get("proxy"):
	proxy_models[model_key] = model_state
	# Find a concrete model for the proxy.
	concrete_models_mapping[
	model_key
	] = self._find_concrete_model_from_proxy(
	proxy_models,
	model_state,
	)
	else:
	concrete_models_mapping[model_key] = model_key
	return concrete_models_mapping, proxy_models

	def _find_concrete_model_from_proxy(self, proxy_models, model_state):
	for base in model_state.bases:
	if not (isinstance(base, str) or issubclass(base, models.Model)):
	continue
	base_key = make_model_tuple(base)
	base_state = proxy_models.get(base_key)
	if not base_state:
	# Concrete model found, stop looking at bases.
	return base_key
	return self._find_concrete_model_from_proxy(proxy_models, base_state)

	def clone(self):
	"""Return an exact copy of this ProjectState."""
	new_state = ProjectState(
	models={k: v.clone() for k, v in self.models.items()},
	real_apps=self.real_apps,
	)
	if "apps" in self.__dict__:
	new_state.apps = self.apps.clone()
	new_state.is_delayed = self.is_delayed
	return new_state

	def clear_delayed_apps_cache(self):
	if self.is_delayed and "apps" in self.__dict__:
	del self.__dict__["apps"]

	@cached_property
	def apps(self):
	return StateApps(self.real_apps, self.models)

	@classmethod
	def from_apps(cls, apps):
	"""Take an Apps and return a ProjectState matching it."""
	app_models = {}
	for model in apps.get_models(include_swapped=True):
	model_state = ModelState.from_model(model)
	app_models[(model_state.app_label, model_state.name_lower)] = model_state
	return cls(app_models)

	def __eq__(self, other):
	return self.models == other.models and self.real_apps == other.real_apps


	class AppConfigStub(AppConfig):
	"""Stub of an AppConfig. Only provides a label and a dict of models."""

	def __init__(self, label):
	self.apps = None
	self.models = {}
	# App-label and app-name are not the same thing, so technically passing
	# in the label here is wrong. In practice, migrations don't care about
	# the app name, but we need something unique, and the label works fine.
	self.label = label
	self.name = label

	def import_models(self):
	self.models = self.apps.all_models[self.label]


	class StateApps(Apps):
	"""
	Subclass of the global Apps registry class to better handle dynamic model
	additions and removals.
	"""

	def __init__(self, real_apps, models, ignore_swappable=False):
	# Any apps in self.real_apps should have all their models included
	# in the render. We don't use the original model instances as there
	# are some variables that refer to the Apps object.
	# FKs/M2Ms from real apps are also not included as they just
	# mess things up with partial states (due to lack of dependencies)
	self.real_models = []
	for app_label in real_apps:
	app = global_apps.get_app_config(app_label)
	for model in app.get_models():
	self.real_models.append(ModelState.from_model(model, exclude_rels=True))
	# Populate the app registry with a stub for each application.
	app_labels = {model_state.app_label for model_state in models.values()}
	app_configs = [
	AppConfigStub(label) for label in sorted([real_apps, app_labels])
	]
	super().__init__(app_configs)

	# These locks get in the way of copying as implemented in clone(),
	# which is called whenever Django duplicates a StateApps before
	# updating it.
	self._lock = None
	self.ready_event = None

	self.render_multiple([models.values(), self.real_models])

	# There shouldn't be any operations pending at this point.
	from django.core.checks.model_checks import _check_lazy_references

	ignore = (
	{make_model_tuple(settings.AUTH_USER_MODEL)} if ignore_swappable else set()
	)
	errors = _check_lazy_references(self, ignore=ignore)
	if errors:
	raise ValueError("\n".join(error.msg for error in errors))

	@contextmanager
	def bulk_update(self):
	# Avoid clearing each model's cache for each change. Instead, clear
	# all caches when we're finished updating the model instances.
	ready = self.ready
	self.ready = False
	try:
	yield
	finally:
	self.ready = ready
	self.clear_cache()

	def render_multiple(self, model_states):
	# We keep trying to render the models in a loop, ignoring invalid
	# base errors, until the size of the unrendered models doesn't
	# decrease by at least one, meaning there's a base dependency loop/
	# missing base.
	if not model_states:
	return
	# Prevent that all model caches are expired for each render.
	with self.bulk_update():
	unrendered_models = model_states
	while unrendered_models:
	new_unrendered_models = []
	for model in unrendered_models:
	try:
	model.render(self)
	except InvalidBasesError:
	new_unrendered_models.append(model)
	if len(new_unrendered_models) == len(unrendered_models):
	raise InvalidBasesError(
	"Cannot resolve bases for %r\nThis can happen if you are "
	"inheriting models from an app with migrations (e.g. "
	"contrib.auth)\n in an app with no migrations; see "
	"https://docs.djangoproject.com/en/%s/topics/migrations/"
	"#dependencies for more"
	% (new_unrendered_models, get_docs_version())
	)
	unrendered_models = new_unrendered_models

	def clone(self):
	"""Return a clone of this registry."""
	clone = StateApps([], {})
	clone.all_models = copy.deepcopy(self.all_models)

	for app_label in self.app_configs:
	app_config = AppConfigStub(app_label)
	app_config.apps = clone
	app_config.import_models()
	clone.app_configs[app_label] = app_config

	# No need to actually clone them, they'll never change
	clone.real_models = self.real_models
	return clone

	def register_model(self, app_label, model):
	self.all_models[app_label][model._meta.model_name] = model
	if app_label not in self.app_configs:
	self.app_configs[app_label] = AppConfigStub(app_label)
	self.app_configs[app_label].apps = self
	self.app_configs[app_label].models[model._meta.model_name] = model
	self.do_pending_operations(model)
	self.clear_cache()

	def unregister_model(self, app_label, model_name):
	try:
	del self.all_models[app_label][model_name]
	del self.app_configs[app_label].models[model_name]
	except KeyError:
	pass


	class ModelState:
	"""
	Represent a Django Model. Don't use the actual Model class as it's not
	designed to have its options changed - instead, mutate this one and then
	render it into a Model as required.

	Note that while you are allowed to mutate .fields, you are not allowed
	to mutate the Field instances inside there themselves - you must instead
	assign new ones, as these are not detached during a clone.
	"""

	def __init__(
	self, app_label, name, fields, options=None, bases=None, managers=None
	):
	self.app_label = app_label
	self.name = name
	self.fields = dict(fields)
	self.options = options or {}
	self.options.setdefault("indexes", [])
	self.options.setdefault("constraints", [])
	self.bases = bases or (models.Model,)
	self.managers = managers or []
	for name, field in self.fields.items():
	# Sanity-check that fields are NOT already bound to a model.
	if hasattr(field, "model"):
	raise ValueError(
	'ModelState.fields cannot be bound to a model - "%s" is.' % name
	)
	# Sanity-check that relation fields are NOT referring to a model class.
	if field.is_relation and hasattr(field.related_model, "_meta"):
	raise ValueError(
	'ModelState.fields cannot refer to a model class - "%s.to" does. '
	"Use a string reference instead." % name
	)
	if field.many_to_many and hasattr(field.remote_field.through, "_meta"):
	raise ValueError(
	'ModelState.fields cannot refer to a model class - "%s.through" '
	"does. Use a string reference instead." % name
	)
	# Sanity-check that indexes have their name set.
	for index in self.options["indexes"]:
	if not index.name:
	raise ValueError(
	"Indexes passed to ModelState require a name attribute. "
	"%r doesn't have one." % index
	)

	@cached_property
	def name_lower(self):
	return self.name.lower()

	def get_field(self, field_name):
	if field_name == "_order":
	field_name = self.options.get("order_with_respect_to", field_name)
	return self.fields[field_name]

	@classmethod
	def from_model(cls, model, exclude_rels=False):
	"""Given a model, return a ModelState representing it."""
	# Deconstruct the fields
	fields = []
	for field in model._meta.local_fields:
	if getattr(field, "remote_field", None) and exclude_rels:
	continue
	if isinstance(field, models.OrderWrt):
	continue
	name = field.name
	try:
	fields.append((name, field.clone()))
	except TypeError as e:
	raise TypeError(
	"Couldn't reconstruct field %s on %s: %s"
	% (
	name,
	model._meta.label,
	e,
	)
	)
	if not exclude_rels:
	for field in model._meta.local_many_to_many:
	name = field.name
	try:
	fields.append((name, field.clone()))
	except TypeError as e:
	raise TypeError(
	"Couldn't reconstruct m2m field %s on %s: %s"
	% (
	name,
	model._meta.object_name,
	e,
	)
	)
	# Extract the options
	options = {}
	for name in DEFAULT_NAMES:
	# Ignore some special options
	if name in ["apps", "app_label"]:
	continue
	elif name in model._meta.original_attrs:
	if name == "unique_together":
	ut = model._meta.original_attrs["unique_together"]
	options[name] = set(normalize_together(ut))
	elif name == "index_together":
	it = model._meta.original_attrs["index_together"]
	options[name] = set(normalize_together(it))
	elif name == "indexes":
	indexes = [idx.clone() for idx in model._meta.indexes]
	for index in indexes:
	if not index.name:
	index.set_name_with_model(model)
	options["indexes"] = indexes
	elif name == "constraints":
	options["constraints"] = [
	con.clone() for con in model._meta.constraints
	]
	else:
	options[name] = model._meta.original_attrs[name]
	# If we're ignoring relationships, remove all field-listing model
	# options (that option basically just means "make a stub model")
	if exclude_rels:
	for key in ["unique_together", "index_together", "order_with_respect_to"]:
	if key in options:
	del options[key]
	# Private fields are ignored, so remove options that refer to them.
	elif options.get("order_with_respect_to") in {
	field.name for field in model._meta.private_fields
	}:
	del options["order_with_respect_to"]

	def flatten_bases(model):
	bases = []
	for base in model.__bases__:
	if hasattr(base, "_meta") and base._meta.abstract:
	bases.extend(flatten_bases(base))
	else:
	bases.append(base)
	return bases

	# We can't rely on __mro__ directly because we only want to flatten
	# abstract models and not the whole tree. However by recursing on
	# __bases__ we may end up with duplicates and ordering issues, we
	# therefore discard any duplicates and reorder the bases according
	# to their index in the MRO.
	flattened_bases = sorted(
	set(flatten_bases(model)), key=lambda x: model.__mro__.index(x)
	)

	# Make our record
	bases = tuple(
	(base._meta.label_lower if hasattr(base, "_meta") else base)
	for base in flattened_bases
	)
	# Ensure at least one base inherits from models.Model
	if not any(
	(isinstance(base, str) or issubclass(base, models.Model)) for base in bases
	):
	bases = (models.Model,)

	managers = []
	manager_names = set()
	default_manager_shim = None
	for manager in model._meta.managers:
	if manager.name in manager_names:
	# Skip overridden managers.
	continue
	elif manager.use_in_migrations:
	# Copy managers usable in migrations.
	new_manager = copy.copy(manager)
	new_manager._set_creation_counter()
	elif manager is model._base_manager or manager is model._default_manager:
	# Shim custom managers used as default and base managers.
	new_manager = models.Manager()
	new_manager.model = manager.model
	new_manager.name = manager.name
	if manager is model._default_manager:
	default_manager_shim = new_manager
	else:
	continue
	manager_names.add(manager.name)
	managers.append((manager.name, new_manager))

	# Ignore a shimmed default manager called objects if it's the only one.
	if managers == [("objects", default_manager_shim)]:
	managers = []

	# Construct the new ModelState
	return cls(
	model._meta.app_label,
	model._meta.object_name,
	fields,
	options,
	bases,
	managers,
	)

	def construct_managers(self):
	"""Deep-clone the managers using deconstruction."""
	# Sort all managers by their creation counter
	sorted_managers = sorted(self.managers, key=lambda v: v[1].creation_counter)
	for mgr_name, manager in sorted_managers:
	as_manager, manager_path, qs_path, args, kwargs = manager.deconstruct()
	if as_manager:
	qs_class = import_string(qs_path)
	yield mgr_name, qs_class.as_manager()
	else:
	manager_class = import_string(manager_path)
	yield mgr_name, manager_class(args, *kwargs)

	def clone(self):
	"""Return an exact copy of this ModelState."""
	return self.__class__(
	app_label=self.app_label,
	name=self.name,
	fields=dict(self.fields),
	# Since options are shallow-copied here, operations such as
	# AddIndex must replace their option (e.g 'indexes') rather
	# than mutating it.
	options=dict(self.options),
	bases=self.bases,
	managers=list(self.managers),
	)

	def render(self, apps):
	"""Create a Model object from our current state into the given apps."""
	# First, make a Meta object
	meta_contents = {"app_label": self.app_label, "apps": apps, **self.options}
	meta = type("Meta", (), meta_contents)
	# Then, work out our bases
	try:
	bases = tuple(
	(apps.get_model(base) if isinstance(base, str) else base)
	for base in self.bases
	)
	except LookupError:
	raise InvalidBasesError(
	"Cannot resolve one or more bases from %r" % (self.bases,)
	)
	# Clone fields for the body, add other bits.
	body = {name: field.clone() for name, field in self.fields.items()}
	body["Meta"] = meta
	body["__module__"] = "__fake__"

	# Restore managers
	body.update(self.construct_managers())
	# Then, make a Model object (apps.register_model is called in __new__)
	return type(self.name, bases, body)

	def get_index_by_name(self, name):
	for index in self.options["indexes"]:
	if index.name == name:
	return index
	raise ValueError("No index named %s on model %s" % (name, self.name))

	def get_constraint_by_name(self, name):
	for constraint in self.options["constraints"]:
	if constraint.name == name:
	return constraint
	raise ValueError("No constraint named %s on model %s" % (name, self.name))

	def __repr__(self):
	return "<%s: '%s.%s'>" % (self.__class__.__name__, self.app_label, self.name)

	def __eq__(self, other):
	return (
	(self.app_label == other.app_label)
	and (self.name == other.name)
	and (len(self.fields) == len(other.fields))
	and all(
	k1 == k2 and f1.deconstruct()[1:] == f2.deconstruct()[1:]
	for (k1, f1), (k2, f2) in zip(
	sorted(self.fields.items()),
	sorted(other.fields.items()),
	)
	)
	and (self.options == other.options)
	and (self.bases == other.bases)
	and (self.managers == other.managers)
	)