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	# ### this file stubs are generated by tools/write_pyi.py - do not edit ###
	# ### imports are manually managed
	from __future__ import annotations

	from contextlib import contextmanager
	from typing import Any
	from typing import Awaitable
	from typing import Callable
	from typing import Dict
	from typing import Iterator
	from typing import List
	from typing import Literal
	from typing import Mapping
	from typing import Optional
	from typing import overload
	from typing import Sequence
	from typing import Tuple
	from typing import Type
	from typing import TYPE_CHECKING
	from typing import TypeVar
	from typing import Union

	if TYPE_CHECKING:
	from sqlalchemy.engine import Connection
	from sqlalchemy.sql import Executable
	from sqlalchemy.sql.elements import ColumnElement
	from sqlalchemy.sql.elements import conv
	from sqlalchemy.sql.elements import TextClause
	from sqlalchemy.sql.expression import TableClause
	from sqlalchemy.sql.functions import Function
	from sqlalchemy.sql.schema import Column
	from sqlalchemy.sql.schema import Computed
	from sqlalchemy.sql.schema import Identity
	from sqlalchemy.sql.schema import SchemaItem
	from sqlalchemy.sql.schema import Table
	from sqlalchemy.sql.type_api import TypeEngine
	from sqlalchemy.util import immutabledict

	from .operations.base import BatchOperations
	from .operations.ops import AddColumnOp
	from .operations.ops import AddConstraintOp
	from .operations.ops import AlterColumnOp
	from .operations.ops import AlterTableOp
	from .operations.ops import BulkInsertOp
	from .operations.ops import CreateIndexOp
	from .operations.ops import CreateTableCommentOp
	from .operations.ops import CreateTableOp
	from .operations.ops import DropColumnOp
	from .operations.ops import DropConstraintOp
	from .operations.ops import DropIndexOp
	from .operations.ops import DropTableCommentOp
	from .operations.ops import DropTableOp
	from .operations.ops import ExecuteSQLOp
	from .operations.ops import MigrateOperation
	from .runtime.migration import MigrationContext
	from .util.sqla_compat import _literal_bindparam

	_T = TypeVar("_T")
	_C = TypeVar("_C", bound=Callable[..., Any])

	### end imports ###

	def add_column(
	table_name: str, column: Column[Any], *, schema: Optional[str] = None
	) -> None:
	"""Issue an "add column" instruction using the current
	migration context.

	e.g.::

	from alembic import op
	from sqlalchemy import Column, String

	op.add_column("organization", Column("name", String()))

	The :meth:`.Operations.add_column` method typically corresponds
	to the SQL command "ALTER TABLE... ADD COLUMN". Within the scope
	of this command, the column's name, datatype, nullability,
	and optional server-generated defaults may be indicated.

	.. note::

	With the exception of NOT NULL constraints or single-column FOREIGN
	KEY constraints, other kinds of constraints such as PRIMARY KEY,
	UNIQUE or CHECK constraints cannot be generated using this
	method; for these constraints, refer to operations such as
	:meth:`.Operations.create_primary_key` and
	:meth:`.Operations.create_check_constraint`. In particular, the
	following :class:`~sqlalchemy.schema.Column` parameters are
	ignored:

	* :paramref:`~sqlalchemy.schema.Column.primary_key` - SQL databases
	typically do not support an ALTER operation that can add
	individual columns one at a time to an existing primary key
	constraint, therefore it's less ambiguous to use the
	:meth:`.Operations.create_primary_key` method, which assumes no
	existing primary key constraint is present.
	* :paramref:`~sqlalchemy.schema.Column.unique` - use the
	:meth:`.Operations.create_unique_constraint` method
	* :paramref:`~sqlalchemy.schema.Column.index` - use the
	:meth:`.Operations.create_index` method


	The provided :class:`~sqlalchemy.schema.Column` object may include a
	:class:`~sqlalchemy.schema.ForeignKey` constraint directive,
	referencing a remote table name. For this specific type of constraint,
	Alembic will automatically emit a second ALTER statement in order to
	add the single-column FOREIGN KEY constraint separately::

	from alembic import op
	from sqlalchemy import Column, INTEGER, ForeignKey

	op.add_column(
	"organization",
	Column("account_id", INTEGER, ForeignKey("accounts.id")),
	)

	The column argument passed to :meth:`.Operations.add_column` is a
	:class:`~sqlalchemy.schema.Column` construct, used in the same way it's
	used in SQLAlchemy. In particular, values or functions to be indicated
	as producing the column's default value on the database side are
	specified using the ``server_default`` parameter, and not ``default``
	which only specifies Python-side defaults::

	from alembic import op
	from sqlalchemy import Column, TIMESTAMP, func

	# specify "DEFAULT NOW" along with the column add
	op.add_column(
	"account",
	Column("timestamp", TIMESTAMP, server_default=func.now()),
	)

	:param table_name: String name of the parent table.
	:param column: a :class:`sqlalchemy.schema.Column` object
	representing the new column.
	:param schema: Optional schema name to operate within. To control
	quoting of the schema outside of the default behavior, use
	the SQLAlchemy construct
	:class:`~sqlalchemy.sql.elements.quoted_name`.

	"""

	def alter_column(
	table_name: str,
	column_name: str,
	*,
	nullable: Optional[bool] = None,
	comment: Union[str, Literal[False], None] = False,
	server_default: Any = False,
	new_column_name: Optional[str] = None,
	type_: Union[TypeEngine[Any], Type[TypeEngine[Any]], None] = None,
	existing_type: Union[TypeEngine[Any], Type[TypeEngine[Any]], None] = None,
	existing_server_default: Union[
	str, bool, Identity, Computed, None
	] = False,
	existing_nullable: Optional[bool] = None,
	existing_comment: Optional[str] = None,
	schema: Optional[str] = None,
	**kw: Any,
	) -> None:
	r"""Issue an "alter column" instruction using the
	current migration context.

	Generally, only that aspect of the column which
	is being changed, i.e. name, type, nullability,
	default, needs to be specified. Multiple changes
	can also be specified at once and the backend should
	"do the right thing", emitting each change either
	separately or together as the backend allows.

	MySQL has special requirements here, since MySQL
	cannot ALTER a column without a full specification.
	When producing MySQL-compatible migration files,
	it is recommended that the ``existing_type``,
	``existing_server_default``, and ``existing_nullable``
	parameters be present, if not being altered.

	Type changes which are against the SQLAlchemy
	"schema" types :class:`~sqlalchemy.types.Boolean`
	and :class:`~sqlalchemy.types.Enum` may also
	add or drop constraints which accompany those
	types on backends that don't support them natively.
	The ``existing_type`` argument is
	used in this case to identify and remove a previous
	constraint that was bound to the type object.

	:param table_name: string name of the target table.
	:param column_name: string name of the target column,
	as it exists before the operation begins.
	:param nullable: Optional; specify ``True`` or ``False``
	to alter the column's nullability.
	:param server_default: Optional; specify a string
	SQL expression, :func:`~sqlalchemy.sql.expression.text`,
	or :class:`~sqlalchemy.schema.DefaultClause` to indicate
	an alteration to the column's default value.
	Set to ``None`` to have the default removed.
	:param comment: optional string text of a new comment to add to the
	column.
	:param new_column_name: Optional; specify a string name here to
	indicate the new name within a column rename operation.
	:param type\_: Optional; a :class:`~sqlalchemy.types.TypeEngine`
	type object to specify a change to the column's type.
	For SQLAlchemy types that also indicate a constraint (i.e.
	:class:`~sqlalchemy.types.Boolean`, :class:`~sqlalchemy.types.Enum`),
	the constraint is also generated.
	:param autoincrement: set the ``AUTO_INCREMENT`` flag of the column;
	currently understood by the MySQL dialect.
	:param existing_type: Optional; a
	:class:`~sqlalchemy.types.TypeEngine`
	type object to specify the previous type. This
	is required for all MySQL column alter operations that
	don't otherwise specify a new type, as well as for
	when nullability is being changed on a SQL Server
	column. It is also used if the type is a so-called
	SQLAlchemy "schema" type which may define a constraint (i.e.
	:class:`~sqlalchemy.types.Boolean`,
	:class:`~sqlalchemy.types.Enum`),
	so that the constraint can be dropped.
	:param existing_server_default: Optional; The existing
	default value of the column. Required on MySQL if
	an existing default is not being changed; else MySQL
	removes the default.
	:param existing_nullable: Optional; the existing nullability
	of the column. Required on MySQL if the existing nullability
	is not being changed; else MySQL sets this to NULL.
	:param existing_autoincrement: Optional; the existing autoincrement
	of the column. Used for MySQL's system of altering a column
	that specifies ``AUTO_INCREMENT``.
	:param existing_comment: string text of the existing comment on the
	column to be maintained. Required on MySQL if the existing comment
	on the column is not being changed.
	:param schema: Optional schema name to operate within. To control
	quoting of the schema outside of the default behavior, use
	the SQLAlchemy construct
	:class:`~sqlalchemy.sql.elements.quoted_name`.
	:param postgresql_using: String argument which will indicate a
	SQL expression to render within the Postgresql-specific USING clause
	within ALTER COLUMN. This string is taken directly as raw SQL which
	must explicitly include any necessary quoting or escaping of tokens
	within the expression.

	"""

	@contextmanager
	def batch_alter_table(
	table_name: str,
	schema: Optional[str] = None,
	recreate: Literal["auto", "always", "never"] = "auto",
	partial_reordering: Optional[Tuple[Any, ...]] = None,
	copy_from: Optional[Table] = None,
	table_args: Tuple[Any, ...] = (),
	table_kwargs: Mapping[str, Any] = immutabledict({}),
	reflect_args: Tuple[Any, ...] = (),
	reflect_kwargs: Mapping[str, Any] = immutabledict({}),
	naming_convention: Optional[Dict[str, str]] = None,
	) -> Iterator[BatchOperations]:
	"""Invoke a series of per-table migrations in batch.

	Batch mode allows a series of operations specific to a table
	to be syntactically grouped together, and allows for alternate
	modes of table migration, in particular the "recreate" style of
	migration required by SQLite.

	"recreate" style is as follows:

	1. A new table is created with the new specification, based on the
	migration directives within the batch, using a temporary name.

	2. the data copied from the existing table to the new table.

	3. the existing table is dropped.

	4. the new table is renamed to the existing table name.

	The directive by default will only use "recreate" style on the
	SQLite backend, and only if directives are present which require
	this form, e.g. anything other than ``add_column()``. The batch
	operation on other backends will proceed using standard ALTER TABLE
	operations.

	The method is used as a context manager, which returns an instance
	of :class:`.BatchOperations`; this object is the same as
	:class:`.Operations` except that table names and schema names
	are omitted. E.g.::

	with op.batch_alter_table("some_table") as batch_op:
	batch_op.add_column(Column("foo", Integer))
	batch_op.drop_column("bar")

	The operations within the context manager are invoked at once
	when the context is ended. When run against SQLite, if the
	migrations include operations not supported by SQLite's ALTER TABLE,
	the entire table will be copied to a new one with the new
	specification, moving all data across as well.

	The copy operation by default uses reflection to retrieve the current
	structure of the table, and therefore :meth:`.batch_alter_table`
	in this mode requires that the migration is run in "online" mode.
	The ``copy_from`` parameter may be passed which refers to an existing
	:class:`.Table` object, which will bypass this reflection step.

	.. note:: The table copy operation will currently not copy
	CHECK constraints, and may not copy UNIQUE constraints that are
	unnamed, as is possible on SQLite. See the section
	:ref:`sqlite_batch_constraints` for workarounds.

	:param table_name: name of table
	:param schema: optional schema name.
	:param recreate: under what circumstances the table should be
	recreated. At its default of ``"auto"``, the SQLite dialect will
	recreate the table if any operations other than ``add_column()``,
	``create_index()``, or ``drop_index()`` are
	present. Other options include ``"always"`` and ``"never"``.
	:param copy_from: optional :class:`~sqlalchemy.schema.Table` object
	that will act as the structure of the table being copied. If omitted,
	table reflection is used to retrieve the structure of the table.

	.. seealso::

	:ref:`batch_offline_mode`

	:paramref:`~.Operations.batch_alter_table.reflect_args`

	:paramref:`~.Operations.batch_alter_table.reflect_kwargs`

	:param reflect_args: a sequence of additional positional arguments that
	will be applied to the table structure being reflected / copied;
	this may be used to pass column and constraint overrides to the
	table that will be reflected, in lieu of passing the whole
	:class:`~sqlalchemy.schema.Table` using
	:paramref:`~.Operations.batch_alter_table.copy_from`.
	:param reflect_kwargs: a dictionary of additional keyword arguments
	that will be applied to the table structure being copied; this may be
	used to pass additional table and reflection options to the table that
	will be reflected, in lieu of passing the whole
	:class:`~sqlalchemy.schema.Table` using
	:paramref:`~.Operations.batch_alter_table.copy_from`.
	:param table_args: a sequence of additional positional arguments that
	will be applied to the new :class:`~sqlalchemy.schema.Table` when
	created, in addition to those copied from the source table.
	This may be used to provide additional constraints such as CHECK
	constraints that may not be reflected.
	:param table_kwargs: a dictionary of additional keyword arguments
	that will be applied to the new :class:`~sqlalchemy.schema.Table`
	when created, in addition to those copied from the source table.
	This may be used to provide for additional table options that may
	not be reflected.
	:param naming_convention: a naming convention dictionary of the form
	described at :ref:`autogen_naming_conventions` which will be applied
	to the :class:`~sqlalchemy.schema.MetaData` during the reflection
	process. This is typically required if one wants to drop SQLite
	constraints, as these constraints will not have names when
	reflected on this backend. Requires SQLAlchemy 0.9.4 or greater.

	.. seealso::

	:ref:`dropping_sqlite_foreign_keys`

	:param partial_reordering: a list of tuples, each suggesting a desired
	ordering of two or more columns in the newly created table. Requires
	that :paramref:`.batch_alter_table.recreate` is set to ``"always"``.
	Examples, given a table with columns "a", "b", "c", and "d":

	Specify the order of all columns::

	with op.batch_alter_table(
	"some_table",
	recreate="always",
	partial_reordering=[("c", "d", "a", "b")],
	) as batch_op:
	pass

	Ensure "d" appears before "c", and "b", appears before "a"::

	with op.batch_alter_table(
	"some_table",
	recreate="always",
	partial_reordering=[("d", "c"), ("b", "a")],
	) as batch_op:
	pass

	The ordering of columns not included in the partial_reordering
	set is undefined. Therefore it is best to specify the complete
	ordering of all columns for best results.

	.. note:: batch mode requires SQLAlchemy 0.8 or above.

	.. seealso::

	:ref:`batch_migrations`

	"""

	def bulk_insert(
	table: Union[Table, TableClause],
	rows: List[Dict[str, Any]],
	*,
	multiinsert: bool = True,
	) -> None:
	"""Issue a "bulk insert" operation using the current
	migration context.

	This provides a means of representing an INSERT of multiple rows
	which works equally well in the context of executing on a live
	connection as well as that of generating a SQL script. In the
	case of a SQL script, the values are rendered inline into the
	statement.

	e.g.::

	from alembic import op
	from datetime import date
	from sqlalchemy.sql import table, column
	from sqlalchemy import String, Integer, Date

	# Create an ad-hoc table to use for the insert statement.
	accounts_table = table(
	"account",
	column("id", Integer),
	column("name", String),
	column("create_date", Date),
	)

	op.bulk_insert(
	accounts_table,
	[
	{
	"id": 1,
	"name": "John Smith",
	"create_date": date(2010, 10, 5),
	},
	{
	"id": 2,
	"name": "Ed Williams",
	"create_date": date(2007, 5, 27),
	},
	{
	"id": 3,
	"name": "Wendy Jones",
	"create_date": date(2008, 8, 15),
	},
	],
	)

	When using --sql mode, some datatypes may not render inline
	automatically, such as dates and other special types. When this
	issue is present, :meth:`.Operations.inline_literal` may be used::

	op.bulk_insert(
	accounts_table,
	[
	{
	"id": 1,
	"name": "John Smith",
	"create_date": op.inline_literal("2010-10-05"),
	},
	{
	"id": 2,
	"name": "Ed Williams",
	"create_date": op.inline_literal("2007-05-27"),
	},
	{
	"id": 3,
	"name": "Wendy Jones",
	"create_date": op.inline_literal("2008-08-15"),
	},
	],
	multiinsert=False,
	)

	When using :meth:`.Operations.inline_literal` in conjunction with
	:meth:`.Operations.bulk_insert`, in order for the statement to work
	in "online" (e.g. non --sql) mode, the
	:paramref:`~.Operations.bulk_insert.multiinsert`
	flag should be set to ``False``, which will have the effect of
	individual INSERT statements being emitted to the database, each
	with a distinct VALUES clause, so that the "inline" values can
	still be rendered, rather than attempting to pass the values
	as bound parameters.

	:param table: a table object which represents the target of the INSERT.

	:param rows: a list of dictionaries indicating rows.

	:param multiinsert: when at its default of True and --sql mode is not
	enabled, the INSERT statement will be executed using
	"executemany()" style, where all elements in the list of
	dictionaries are passed as bound parameters in a single
	list. Setting this to False results in individual INSERT
	statements being emitted per parameter set, and is needed
	in those cases where non-literal values are present in the
	parameter sets.

	"""

	def create_check_constraint(
	constraint_name: Optional[str],
	table_name: str,
	condition: Union[str, ColumnElement[bool], TextClause],
	*,
	schema: Optional[str] = None,
	**kw: Any,
	) -> None:
	"""Issue a "create check constraint" instruction using the
	current migration context.

	e.g.::

	from alembic import op
	from sqlalchemy.sql import column, func

	op.create_check_constraint(
	"ck_user_name_len",
	"user",
	func.len(column("name")) > 5,
	)

	CHECK constraints are usually against a SQL expression, so ad-hoc
	table metadata is usually needed. The function will convert the given
	arguments into a :class:`sqlalchemy.schema.CheckConstraint` bound
	to an anonymous table in order to emit the CREATE statement.

	:param name: Name of the check constraint. The name is necessary
	so that an ALTER statement can be emitted. For setups that
	use an automated naming scheme such as that described at
	:ref:`sqla:constraint_naming_conventions`,
	``name`` here can be ``None``, as the event listener will
	apply the name to the constraint object when it is associated
	with the table.
	:param table_name: String name of the source table.
	:param condition: SQL expression that's the condition of the
	constraint. Can be a string or SQLAlchemy expression language
	structure.
	:param deferrable: optional bool. If set, emit DEFERRABLE or
	NOT DEFERRABLE when issuing DDL for this constraint.
	:param initially: optional string. If set, emit INITIALLY <value>
	when issuing DDL for this constraint.
	:param schema: Optional schema name to operate within. To control
	quoting of the schema outside of the default behavior, use
	the SQLAlchemy construct
	:class:`~sqlalchemy.sql.elements.quoted_name`.

	"""

	def create_exclude_constraint(
	constraint_name: str, table_name: str, elements: Any, *kw: Any
	) -> Optional[Table]:
	"""Issue an alter to create an EXCLUDE constraint using the
	current migration context.

	.. note:: This method is Postgresql specific, and additionally
	requires at least SQLAlchemy 1.0.

	e.g.::

	from alembic import op

	op.create_exclude_constraint(
	"user_excl",
	"user",
	("period", "&&"),
	("group", "="),
	where=("group != 'some group'"),
	)

	Note that the expressions work the same way as that of
	the ``ExcludeConstraint`` object itself; if plain strings are
	passed, quoting rules must be applied manually.

	:param name: Name of the constraint.
	:param table_name: String name of the source table.
	:param elements: exclude conditions.
	:param where: SQL expression or SQL string with optional WHERE
	clause.
	:param deferrable: optional bool. If set, emit DEFERRABLE or
	NOT DEFERRABLE when issuing DDL for this constraint.
	:param initially: optional string. If set, emit INITIALLY <value>
	when issuing DDL for this constraint.
	:param schema: Optional schema name to operate within.

	"""

	def create_foreign_key(
	constraint_name: Optional[str],
	source_table: str,
	referent_table: str,
	local_cols: List[str],
	remote_cols: List[str],
	*,
	onupdate: Optional[str] = None,
	ondelete: Optional[str] = None,
	deferrable: Optional[bool] = None,
	initially: Optional[str] = None,
	match: Optional[str] = None,
	source_schema: Optional[str] = None,
	referent_schema: Optional[str] = None,
	**dialect_kw: Any,
	) -> None:
	"""Issue a "create foreign key" instruction using the
	current migration context.

	e.g.::

	from alembic import op

	op.create_foreign_key(
	"fk_user_address",
	"address",
	"user",
	["user_id"],
	["id"],
	)

	This internally generates a :class:`~sqlalchemy.schema.Table` object
	containing the necessary columns, then generates a new
	:class:`~sqlalchemy.schema.ForeignKeyConstraint`
	object which it then associates with the
	:class:`~sqlalchemy.schema.Table`.
	Any event listeners associated with this action will be fired
	off normally. The :class:`~sqlalchemy.schema.AddConstraint`
	construct is ultimately used to generate the ALTER statement.

	:param constraint_name: Name of the foreign key constraint. The name
	is necessary so that an ALTER statement can be emitted. For setups
	that use an automated naming scheme such as that described at
	:ref:`sqla:constraint_naming_conventions`,
	``name`` here can be ``None``, as the event listener will
	apply the name to the constraint object when it is associated
	with the table.
	:param source_table: String name of the source table.
	:param referent_table: String name of the destination table.
	:param local_cols: a list of string column names in the
	source table.
	:param remote_cols: a list of string column names in the
	remote table.
	:param onupdate: Optional string. If set, emit ON UPDATE <value> when
	issuing DDL for this constraint. Typical values include CASCADE,
	DELETE and RESTRICT.
	:param ondelete: Optional string. If set, emit ON DELETE <value> when
	issuing DDL for this constraint. Typical values include CASCADE,
	DELETE and RESTRICT.
	:param deferrable: optional bool. If set, emit DEFERRABLE or NOT
	DEFERRABLE when issuing DDL for this constraint.
	:param source_schema: Optional schema name of the source table.
	:param referent_schema: Optional schema name of the destination table.

	"""

	def create_index(
	index_name: Optional[str],
	table_name: str,
	columns: Sequence[Union[str, TextClause, Function[Any]]],
	*,
	schema: Optional[str] = None,
	unique: bool = False,
	if_not_exists: Optional[bool] = None,
	**kw: Any,
	) -> None:
	r"""Issue a "create index" instruction using the current
	migration context.

	e.g.::

	from alembic import op

	op.create_index("ik_test", "t1", ["foo", "bar"])

	Functional indexes can be produced by using the
	:func:`sqlalchemy.sql.expression.text` construct::

	from alembic import op
	from sqlalchemy import text

	op.create_index("ik_test", "t1", [text("lower(foo)")])

	:param index_name: name of the index.
	:param table_name: name of the owning table.
	:param columns: a list consisting of string column names and/or
	:func:`~sqlalchemy.sql.expression.text` constructs.
	:param schema: Optional schema name to operate within. To control
	quoting of the schema outside of the default behavior, use
	the SQLAlchemy construct
	:class:`~sqlalchemy.sql.elements.quoted_name`.
	:param unique: If True, create a unique index.

	:param quote: Force quoting of this column's name on or off,
	corresponding to ``True`` or ``False``. When left at its default
	of ``None``, the column identifier will be quoted according to
	whether the name is case sensitive (identifiers with at least one
	upper case character are treated as case sensitive), or if it's a
	reserved word. This flag is only needed to force quoting of a
	reserved word which is not known by the SQLAlchemy dialect.

	:param if_not_exists: If True, adds IF NOT EXISTS operator when
	creating the new index.

	.. versionadded:: 1.12.0

	:param \**kw: Additional keyword arguments not mentioned above are
	dialect specific, and passed in the form
	``<dialectname>_<argname>``.
	See the documentation regarding an individual dialect at
	:ref:`dialect_toplevel` for detail on documented arguments.

	"""

	def create_primary_key(
	constraint_name: Optional[str],
	table_name: str,
	columns: List[str],
	*,
	schema: Optional[str] = None,
	) -> None:
	"""Issue a "create primary key" instruction using the current
	migration context.

	e.g.::

	from alembic import op

	op.create_primary_key("pk_my_table", "my_table", ["id", "version"])

	This internally generates a :class:`~sqlalchemy.schema.Table` object
	containing the necessary columns, then generates a new
	:class:`~sqlalchemy.schema.PrimaryKeyConstraint`
	object which it then associates with the
	:class:`~sqlalchemy.schema.Table`.
	Any event listeners associated with this action will be fired
	off normally. The :class:`~sqlalchemy.schema.AddConstraint`
	construct is ultimately used to generate the ALTER statement.

	:param constraint_name: Name of the primary key constraint. The name
	is necessary so that an ALTER statement can be emitted. For setups
	that use an automated naming scheme such as that described at
	:ref:`sqla:constraint_naming_conventions`
	``name`` here can be ``None``, as the event listener will
	apply the name to the constraint object when it is associated
	with the table.
	:param table_name: String name of the target table.
	:param columns: a list of string column names to be applied to the
	primary key constraint.
	:param schema: Optional schema name to operate within. To control
	quoting of the schema outside of the default behavior, use
	the SQLAlchemy construct
	:class:`~sqlalchemy.sql.elements.quoted_name`.

	"""

	def create_table(table_name: str, columns: SchemaItem, *kw: Any) -> Table:
	r"""Issue a "create table" instruction using the current migration
	context.

	This directive receives an argument list similar to that of the
	traditional :class:`sqlalchemy.schema.Table` construct, but without the
	metadata::

	from sqlalchemy import INTEGER, VARCHAR, NVARCHAR, Column
	from alembic import op

	op.create_table(
	"account",
	Column("id", INTEGER, primary_key=True),
	Column("name", VARCHAR(50), nullable=False),
	Column("description", NVARCHAR(200)),
	Column("timestamp", TIMESTAMP, server_default=func.now()),
	)

	Note that :meth:`.create_table` accepts
	:class:`~sqlalchemy.schema.Column`
	constructs directly from the SQLAlchemy library. In particular,
	default values to be created on the database side are
	specified using the ``server_default`` parameter, and not
	``default`` which only specifies Python-side defaults::

	from alembic import op
	from sqlalchemy import Column, TIMESTAMP, func

	# specify "DEFAULT NOW" along with the "timestamp" column
	op.create_table(
	"account",
	Column("id", INTEGER, primary_key=True),
	Column("timestamp", TIMESTAMP, server_default=func.now()),
	)

	The function also returns a newly created
	:class:`~sqlalchemy.schema.Table` object, corresponding to the table
	specification given, which is suitable for
	immediate SQL operations, in particular
	:meth:`.Operations.bulk_insert`::

	from sqlalchemy import INTEGER, VARCHAR, NVARCHAR, Column
	from alembic import op

	account_table = op.create_table(
	"account",
	Column("id", INTEGER, primary_key=True),
	Column("name", VARCHAR(50), nullable=False),
	Column("description", NVARCHAR(200)),
	Column("timestamp", TIMESTAMP, server_default=func.now()),
	)

	op.bulk_insert(
	account_table,
	[
	{"name": "A1", "description": "account 1"},
	{"name": "A2", "description": "account 2"},
	],
	)

	:param table_name: Name of the table
	:param \*columns: collection of :class:`~sqlalchemy.schema.Column`
	objects within
	the table, as well as optional :class:`~sqlalchemy.schema.Constraint`
	objects
	and :class:`~.sqlalchemy.schema.Index` objects.
	:param schema: Optional schema name to operate within. To control
	quoting of the schema outside of the default behavior, use
	the SQLAlchemy construct
	:class:`~sqlalchemy.sql.elements.quoted_name`.
	:param \**kw: Other keyword arguments are passed to the underlying
	:class:`sqlalchemy.schema.Table` object created for the command.

	:return: the :class:`~sqlalchemy.schema.Table` object corresponding
	to the parameters given.

	"""

	def create_table_comment(
	table_name: str,
	comment: Optional[str],
	*,
	existing_comment: Optional[str] = None,
	schema: Optional[str] = None,
	) -> None:
	"""Emit a COMMENT ON operation to set the comment for a table.

	:param table_name: string name of the target table.
	:param comment: string value of the comment being registered against
	the specified table.
	:param existing_comment: String value of a comment
	already registered on the specified table, used within autogenerate
	so that the operation is reversible, but not required for direct
	use.

	.. seealso::

	:meth:`.Operations.drop_table_comment`

	:paramref:`.Operations.alter_column.comment`

	"""

	def create_unique_constraint(
	constraint_name: Optional[str],
	table_name: str,
	columns: Sequence[str],
	*,
	schema: Optional[str] = None,
	**kw: Any,
	) -> Any:
	"""Issue a "create unique constraint" instruction using the
	current migration context.

	e.g.::

	from alembic import op
	op.create_unique_constraint("uq_user_name", "user", ["name"])

	This internally generates a :class:`~sqlalchemy.schema.Table` object
	containing the necessary columns, then generates a new
	:class:`~sqlalchemy.schema.UniqueConstraint`
	object which it then associates with the
	:class:`~sqlalchemy.schema.Table`.
	Any event listeners associated with this action will be fired
	off normally. The :class:`~sqlalchemy.schema.AddConstraint`
	construct is ultimately used to generate the ALTER statement.

	:param name: Name of the unique constraint. The name is necessary
	so that an ALTER statement can be emitted. For setups that
	use an automated naming scheme such as that described at
	:ref:`sqla:constraint_naming_conventions`,
	``name`` here can be ``None``, as the event listener will
	apply the name to the constraint object when it is associated
	with the table.
	:param table_name: String name of the source table.
	:param columns: a list of string column names in the
	source table.
	:param deferrable: optional bool. If set, emit DEFERRABLE or
	NOT DEFERRABLE when issuing DDL for this constraint.
	:param initially: optional string. If set, emit INITIALLY <value>
	when issuing DDL for this constraint.
	:param schema: Optional schema name to operate within. To control
	quoting of the schema outside of the default behavior, use
	the SQLAlchemy construct
	:class:`~sqlalchemy.sql.elements.quoted_name`.

	"""

	def drop_column(
	table_name: str,
	column_name: str,
	*,
	schema: Optional[str] = None,
	**kw: Any,
	) -> None:
	"""Issue a "drop column" instruction using the current
	migration context.

	e.g.::

	drop_column("organization", "account_id")

	:param table_name: name of table
	:param column_name: name of column
	:param schema: Optional schema name to operate within. To control
	quoting of the schema outside of the default behavior, use
	the SQLAlchemy construct
	:class:`~sqlalchemy.sql.elements.quoted_name`.
	:param mssql_drop_check: Optional boolean. When ``True``, on
	Microsoft SQL Server only, first
	drop the CHECK constraint on the column using a
	SQL-script-compatible
	block that selects into a @variable from sys.check_constraints,
	then exec's a separate DROP CONSTRAINT for that constraint.
	:param mssql_drop_default: Optional boolean. When ``True``, on
	Microsoft SQL Server only, first
	drop the DEFAULT constraint on the column using a
	SQL-script-compatible
	block that selects into a @variable from sys.default_constraints,
	then exec's a separate DROP CONSTRAINT for that default.
	:param mssql_drop_foreign_key: Optional boolean. When ``True``, on
	Microsoft SQL Server only, first
	drop a single FOREIGN KEY constraint on the column using a
	SQL-script-compatible
	block that selects into a @variable from
	sys.foreign_keys/sys.foreign_key_columns,
	then exec's a separate DROP CONSTRAINT for that default. Only
	works if the column has exactly one FK constraint which refers to
	it, at the moment.

	"""

	def drop_constraint(
	constraint_name: str,
	table_name: str,
	type_: Optional[str] = None,
	*,
	schema: Optional[str] = None,
	) -> None:
	r"""Drop a constraint of the given name, typically via DROP CONSTRAINT.

	:param constraint_name: name of the constraint.
	:param table_name: table name.
	:param type\_: optional, required on MySQL. can be
	'foreignkey', 'primary', 'unique', or 'check'.
	:param schema: Optional schema name to operate within. To control
	quoting of the schema outside of the default behavior, use
	the SQLAlchemy construct
	:class:`~sqlalchemy.sql.elements.quoted_name`.

	"""

	def drop_index(
	index_name: str,
	table_name: Optional[str] = None,
	*,
	schema: Optional[str] = None,
	if_exists: Optional[bool] = None,
	**kw: Any,
	) -> None:
	r"""Issue a "drop index" instruction using the current
	migration context.

	e.g.::

	drop_index("accounts")

	:param index_name: name of the index.
	:param table_name: name of the owning table. Some
	backends such as Microsoft SQL Server require this.
	:param schema: Optional schema name to operate within. To control
	quoting of the schema outside of the default behavior, use
	the SQLAlchemy construct
	:class:`~sqlalchemy.sql.elements.quoted_name`.

	:param if_exists: If True, adds IF EXISTS operator when
	dropping the index.

	.. versionadded:: 1.12.0

	:param \**kw: Additional keyword arguments not mentioned above are
	dialect specific, and passed in the form
	``<dialectname>_<argname>``.
	See the documentation regarding an individual dialect at
	:ref:`dialect_toplevel` for detail on documented arguments.

	"""

	def drop_table(
	table_name: str, , schema: Optional[str] = None, *kw: Any
	) -> None:
	r"""Issue a "drop table" instruction using the current
	migration context.


	e.g.::

	drop_table("accounts")

	:param table_name: Name of the table
	:param schema: Optional schema name to operate within. To control
	quoting of the schema outside of the default behavior, use
	the SQLAlchemy construct
	:class:`~sqlalchemy.sql.elements.quoted_name`.
	:param \**kw: Other keyword arguments are passed to the underlying
	:class:`sqlalchemy.schema.Table` object created for the command.

	"""

	def drop_table_comment(
	table_name: str,
	*,
	existing_comment: Optional[str] = None,
	schema: Optional[str] = None,
	) -> None:
	"""Issue a "drop table comment" operation to
	remove an existing comment set on a table.

	:param table_name: string name of the target table.
	:param existing_comment: An optional string value of a comment already
	registered on the specified table.

	.. seealso::

	:meth:`.Operations.create_table_comment`

	:paramref:`.Operations.alter_column.comment`

	"""

	def execute(
	sqltext: Union[Executable, str],
	*,
	execution_options: Optional[dict[str, Any]] = None,
	) -> None:
	r"""Execute the given SQL using the current migration context.

	The given SQL can be a plain string, e.g.::

	op.execute("INSERT INTO table (foo) VALUES ('some value')")

	Or it can be any kind of Core SQL Expression construct, such as
	below where we use an update construct::

	from sqlalchemy.sql import table, column
	from sqlalchemy import String
	from alembic import op

	account = table("account", column("name", String))
	op.execute(
	account.update()
	.where(account.c.name == op.inline_literal("account 1"))
	.values({"name": op.inline_literal("account 2")})
	)

	Above, we made use of the SQLAlchemy
	:func:`sqlalchemy.sql.expression.table` and
	:func:`sqlalchemy.sql.expression.column` constructs to make a brief,
	ad-hoc table construct just for our UPDATE statement. A full
	:class:`~sqlalchemy.schema.Table` construct of course works perfectly
	fine as well, though note it's a recommended practice to at least
	ensure the definition of a table is self-contained within the migration
	script, rather than imported from a module that may break compatibility
	with older migrations.

	In a SQL script context, the statement is emitted directly to the
	output stream. There is no return result, however, as this
	function is oriented towards generating a change script
	that can run in "offline" mode. Additionally, parameterized
	statements are discouraged here, as they will not work in offline
	mode. Above, we use :meth:`.inline_literal` where parameters are
	to be used.

	For full interaction with a connected database where parameters can
	also be used normally, use the "bind" available from the context::

	from alembic import op

	connection = op.get_bind()

	connection.execute(
	account.update()
	.where(account.c.name == "account 1")
	.values({"name": "account 2"})
	)

	Additionally, when passing the statement as a plain string, it is first
	coerced into a :func:`sqlalchemy.sql.expression.text` construct
	before being passed along. In the less likely case that the
	literal SQL string contains a colon, it must be escaped with a
	backslash, as::

	op.execute(r"INSERT INTO table (foo) VALUES ('\:colon_value')")


	:param sqltext: Any legal SQLAlchemy expression, including:

	* a string
	* a :func:`sqlalchemy.sql.expression.text` construct.
	* a :func:`sqlalchemy.sql.expression.insert` construct.
	* a :func:`sqlalchemy.sql.expression.update` construct.
	* a :func:`sqlalchemy.sql.expression.delete` construct.
	* Any "executable" described in SQLAlchemy Core documentation,
	noting that no result set is returned.

	.. note:: when passing a plain string, the statement is coerced into
	a :func:`sqlalchemy.sql.expression.text` construct. This construct
	considers symbols with colons, e.g. ``:foo`` to be bound parameters.
	To avoid this, ensure that colon symbols are escaped, e.g.
	``\:foo``.

	:param execution_options: Optional dictionary of
	execution options, will be passed to
	:meth:`sqlalchemy.engine.Connection.execution_options`.
	"""

	def f(name: str) -> conv:
	"""Indicate a string name that has already had a naming convention
	applied to it.

	This feature combines with the SQLAlchemy ``naming_convention`` feature
	to disambiguate constraint names that have already had naming
	conventions applied to them, versus those that have not. This is
	necessary in the case that the ``"%(constraint_name)s"`` token
	is used within a naming convention, so that it can be identified
	that this particular name should remain fixed.

	If the :meth:`.Operations.f` is used on a constraint, the naming
	convention will not take effect::

	op.add_column("t", "x", Boolean(name=op.f("ck_bool_t_x")))

	Above, the CHECK constraint generated will have the name
	``ck_bool_t_x`` regardless of whether or not a naming convention is
	in use.

	Alternatively, if a naming convention is in use, and 'f' is not used,
	names will be converted along conventions. If the ``target_metadata``
	contains the naming convention
	``{"ck": "ck_bool_%(table_name)s_%(constraint_name)s"}``, then the
	output of the following:

	op.add_column("t", "x", Boolean(name="x"))

	will be::

	CONSTRAINT ck_bool_t_x CHECK (x in (1, 0)))

	The function is rendered in the output of autogenerate when
	a particular constraint name is already converted.

	"""

	def get_bind() -> Connection:
	"""Return the current 'bind'.

	Under normal circumstances, this is the
	:class:`~sqlalchemy.engine.Connection` currently being used
	to emit SQL to the database.

	In a SQL script context, this value is ``None``. [TODO: verify this]

	"""

	def get_context() -> MigrationContext:
	"""Return the :class:`.MigrationContext` object that's
	currently in use.

	"""

	def implementation_for(op_cls: Any) -> Callable[[_C], _C]:
	"""Register an implementation for a given :class:`.MigrateOperation`.

	This is part of the operation extensibility API.

	.. seealso::

	:ref:`operation_plugins` - example of use

	"""

	def inline_literal(
	value: Union[str, int], type_: Optional[TypeEngine[Any]] = None
	) -> _literal_bindparam:
	r"""Produce an 'inline literal' expression, suitable for
	using in an INSERT, UPDATE, or DELETE statement.

	When using Alembic in "offline" mode, CRUD operations
	aren't compatible with SQLAlchemy's default behavior surrounding
	literal values,
	which is that they are converted into bound values and passed
	separately into the ``execute()`` method of the DBAPI cursor.
	An offline SQL
	script needs to have these rendered inline. While it should
	always be noted that inline literal values are an enormous
	security hole in an application that handles untrusted input,
	a schema migration is not run in this context, so
	literals are safe to render inline, with the caveat that
	advanced types like dates may not be supported directly
	by SQLAlchemy.

	See :meth:`.Operations.execute` for an example usage of
	:meth:`.Operations.inline_literal`.

	The environment can also be configured to attempt to render
	"literal" values inline automatically, for those simple types
	that are supported by the dialect; see
	:paramref:`.EnvironmentContext.configure.literal_binds` for this
	more recently added feature.

	:param value: The value to render. Strings, integers, and simple
	numerics should be supported. Other types like boolean,
	dates, etc. may or may not be supported yet by various
	backends.
	:param type\_: optional - a :class:`sqlalchemy.types.TypeEngine`
	subclass stating the type of this value. In SQLAlchemy
	expressions, this is usually derived automatically
	from the Python type of the value itself, as well as
	based on the context in which the value is used.

	.. seealso::

	:paramref:`.EnvironmentContext.configure.literal_binds`

	"""

	@overload
	def invoke(operation: CreateTableOp) -> Table: ...
	@overload
	def invoke(
	operation: Union[
	AddConstraintOp,
	DropConstraintOp,
	CreateIndexOp,
	DropIndexOp,
	AddColumnOp,
	AlterColumnOp,
	AlterTableOp,
	CreateTableCommentOp,
	DropTableCommentOp,
	DropColumnOp,
	BulkInsertOp,
	DropTableOp,
	ExecuteSQLOp,
	]
	) -> None: ...
	@overload
	def invoke(operation: MigrateOperation) -> Any:
	"""Given a :class:`.MigrateOperation`, invoke it in terms of
	this :class:`.Operations` instance.

	"""

	def register_operation(
	name: str, sourcename: Optional[str] = None
	) -> Callable[[Type[_T]], Type[_T]]:
	"""Register a new operation for this class.

	This method is normally used to add new operations
	to the :class:`.Operations` class, and possibly the
	:class:`.BatchOperations` class as well. All Alembic migration
	operations are implemented via this system, however the system
	is also available as a public API to facilitate adding custom
	operations.

	.. seealso::

	:ref:`operation_plugins`


	"""

	def rename_table(
	old_table_name: str, new_table_name: str, *, schema: Optional[str] = None
	) -> None:
	"""Emit an ALTER TABLE to rename a table.

	:param old_table_name: old name.
	:param new_table_name: new name.
	:param schema: Optional schema name to operate within. To control
	quoting of the schema outside of the default behavior, use
	the SQLAlchemy construct
	:class:`~sqlalchemy.sql.elements.quoted_name`.

	"""

	def run_async(
	async_function: Callable[..., Awaitable[_T]], args: Any, *kw_args: Any
	) -> _T:
	"""Invoke the given asynchronous callable, passing an asynchronous
	:class:`~sqlalchemy.ext.asyncio.AsyncConnection` as the first
	argument.

	This method allows calling async functions from within the
	synchronous ``upgrade()`` or ``downgrade()`` alembic migration
	method.

	The async connection passed to the callable shares the same
	transaction as the connection running in the migration context.

	Any additional arg or kw_arg passed to this function are passed
	to the provided async function.

	.. versionadded: 1.11

	.. note::

	This method can be called only when alembic is called using
	an async dialect.
	"""