# sql/schema.py # Copyright (C) 2005-2023 the SQLAlchemy authors and contributors # # # This module is part of SQLAlchemy and is released under # the MIT License: https://www.opensource.org/licenses/mit-license.php """The schema module provides the building blocks for database metadata. Each element within this module describes a database entity which can be created and dropped, or is otherwise part of such an entity. Examples include tables, columns, sequences, and indexes. All entities are subclasses of :class:`~sqlalchemy.schema.SchemaItem`, and as defined in this module they are intended to be agnostic of any vendor-specific constructs. A collection of entities are grouped into a unit called :class:`~sqlalchemy.schema.MetaData`. MetaData serves as a logical grouping of schema elements, and can also be associated with an actual database connection such that operations involving the contained elements can contact the database as needed. Two of the elements here also build upon their "syntactic" counterparts, which are defined in :class:`~sqlalchemy.sql.expression.`, specifically :class:`~sqlalchemy.schema.Table` and :class:`~sqlalchemy.schema.Column`. Since these objects are part of the SQL expression language, they are usable as components in SQL expressions. """ from __future__ import annotations from abc import ABC import collections from enum import Enum import operator import typing from typing import Any from typing import Callable from typing import cast from typing import Collection from typing import Dict from typing import Iterable from typing import Iterator from typing import List from typing import NoReturn from typing import Optional from typing import overload from typing import Sequence as _typing_Sequence from typing import Set from typing import Tuple from typing import TYPE_CHECKING from typing import TypeVar from typing import Union from . import coercions from . import ddl from . import roles from . import type_api from . import visitors from .base import _NoneName from .base import DedupeColumnCollection from .base import DialectKWArgs from .base import Executable from .base import SchemaEventTarget as SchemaEventTarget from .coercions import _document_text_coercion from .elements import ClauseElement from .elements import ColumnClause from .elements import ColumnElement from .elements import quoted_name from .elements import TextClause from .selectable import TableClause from .type_api import to_instance from .visitors import ExternallyTraversible from .visitors import InternalTraversal from .. import event from .. import exc from .. import inspection from .. import util from ..util.typing import Final from ..util.typing import Literal from ..util.typing import Protocol from ..util.typing import Self from ..util.typing import TypeGuard if typing.TYPE_CHECKING: from ._typing import _AutoIncrementType from ._typing import _DDLColumnArgument from ._typing import _InfoType from ._typing import _TextCoercedExpressionArgument from ._typing import _TypeEngineArgument from .base import ReadOnlyColumnCollection from .compiler import DDLCompiler from .elements import BindParameter from .functions import Function from .type_api import TypeEngine from .visitors import _TraverseInternalsType from .visitors import anon_map from ..engine import Connection from ..engine import Engine from ..engine.interfaces import _CoreMultiExecuteParams from ..engine.interfaces import CoreExecuteOptionsParameter from ..engine.interfaces import ExecutionContext from ..engine.mock import MockConnection from ..engine.reflection import _ReflectionInfo from ..sql.selectable import FromClause _T = TypeVar("_T", bound="Any") _SI = TypeVar("_SI", bound="SchemaItem") _ServerDefaultType = Union["FetchedValue", str, TextClause, ColumnElement[Any]] _TAB = TypeVar("_TAB", bound="Table") _CreateDropBind = Union["Engine", "Connection", "MockConnection"] _ConstraintNameArgument = Optional[Union[str, _NoneName]] class SchemaConst(Enum): RETAIN_SCHEMA = 1 """Symbol indicating that a :class:`_schema.Table`, :class:`.Sequence` or in some cases a :class:`_schema.ForeignKey` object, in situations where the object is being copied for a :meth:`.Table.to_metadata` operation, should retain the schema name that it already has. """ BLANK_SCHEMA = 2 """Symbol indicating that a :class:`_schema.Table` or :class:`.Sequence` should have 'None' for its schema, even if the parent :class:`_schema.MetaData` has specified a schema. .. seealso:: :paramref:`_schema.MetaData.schema` :paramref:`_schema.Table.schema` :paramref:`.Sequence.schema` .. versionadded:: 1.0.14 """ NULL_UNSPECIFIED = 3 """Symbol indicating the "nullable" keyword was not passed to a Column. This is used to distinguish between the use case of passing ``nullable=None`` to a :class:`.Column`, which has special meaning on some backends such as SQL Server. """ RETAIN_SCHEMA: Final[ Literal[SchemaConst.RETAIN_SCHEMA] ] = SchemaConst.RETAIN_SCHEMA BLANK_SCHEMA: Final[ Literal[SchemaConst.BLANK_SCHEMA] ] = SchemaConst.BLANK_SCHEMA NULL_UNSPECIFIED: Final[ Literal[SchemaConst.NULL_UNSPECIFIED] ] = SchemaConst.NULL_UNSPECIFIED def _get_table_key(name: str, schema: Optional[str]) -> str: if schema is None: return name else: return schema + "." + name # this should really be in sql/util.py but we'd have to # break an import cycle def _copy_expression( expression: ColumnElement[Any], source_table: Optional[Table], target_table: Optional[Table], ) -> ColumnElement[Any]: if source_table is None or target_table is None: return expression fixed_source_table = source_table fixed_target_table = target_table def replace( element: ExternallyTraversible, **kw: Any ) -> Optional[ExternallyTraversible]: if ( isinstance(element, Column) and element.table is fixed_source_table and element.key in fixed_source_table.c ): return fixed_target_table.c[element.key] else: return None return cast( ColumnElement[Any], visitors.replacement_traverse(expression, {}, replace), ) @inspection._self_inspects class SchemaItem(SchemaEventTarget, visitors.Visitable): """Base class for items that define a database schema.""" __visit_name__ = "schema_item" create_drop_stringify_dialect = "default" def _init_items(self, *args: SchemaItem, **kw: Any) -> None: """Initialize the list of child items for this SchemaItem.""" for item in args: if item is not None: try: spwd = item._set_parent_with_dispatch except AttributeError as err: raise exc.ArgumentError( "'SchemaItem' object, such as a 'Column' or a " "'Constraint' expected, got %r" % item ) from err else: spwd(self, **kw) def __repr__(self) -> str: return util.generic_repr(self, omit_kwarg=["info"]) @util.memoized_property def info(self) -> _InfoType: """Info dictionary associated with the object, allowing user-defined data to be associated with this :class:`.SchemaItem`. The dictionary is automatically generated when first accessed. It can also be specified in the constructor of some objects, such as :class:`_schema.Table` and :class:`_schema.Column`. """ return {} def _schema_item_copy(self, schema_item: _SI) -> _SI: if "info" in self.__dict__: schema_item.info = self.info.copy() schema_item.dispatch._update(self.dispatch) return schema_item _use_schema_map = True class HasConditionalDDL: """define a class that includes the :meth:`.HasConditionalDDL.ddl_if` method, allowing for conditional rendering of DDL. Currently applies to constraints and indexes. .. versionadded:: 2.0 """ _ddl_if: Optional[ddl.DDLIf] = None def ddl_if( self, dialect: Optional[str] = None, callable_: Optional[ddl.DDLIfCallable] = None, state: Optional[Any] = None, ) -> Self: r"""apply a conditional DDL rule to this schema item. These rules work in a similar manner to the :meth:`.ExecutableDDLElement.execute_if` callable, with the added feature that the criteria may be checked within the DDL compilation phase for a construct such as :class:`.CreateTable`. :meth:`.HasConditionalDDL.ddl_if` currently applies towards the :class:`.Index` construct as well as all :class:`.Constraint` constructs. :param dialect: string name of a dialect, or a tuple of string names to indicate multiple dialect types. :param callable\_: a callable that is constructed using the same form as that described in :paramref:`.ExecutableDDLElement.execute_if.callable_`. :param state: any arbitrary object that will be passed to the callable, if present. .. versionadded:: 2.0 .. seealso:: :ref:`schema_ddl_ddl_if` - background and usage examples """ self._ddl_if = ddl.DDLIf(dialect, callable_, state) return self class HasSchemaAttr(SchemaItem): """schema item that includes a top-level schema name""" schema: Optional[str] class Table( DialectKWArgs, HasSchemaAttr, TableClause, inspection.Inspectable["Table"] ): r"""Represent a table in a database. e.g.:: mytable = Table( "mytable", metadata, Column('mytable_id', Integer, primary_key=True), Column('value', String(50)) ) The :class:`_schema.Table` object constructs a unique instance of itself based on its name and optional schema name within the given :class:`_schema.MetaData` object. Calling the :class:`_schema.Table` constructor with the same name and same :class:`_schema.MetaData` argument a second time will return the *same* :class:`_schema.Table` object - in this way the :class:`_schema.Table` constructor acts as a registry function. .. seealso:: :ref:`metadata_describing` - Introduction to database metadata """ __visit_name__ = "table" if TYPE_CHECKING: @util.ro_non_memoized_property def primary_key(self) -> PrimaryKeyConstraint: ... @util.ro_non_memoized_property def foreign_keys(self) -> Set[ForeignKey]: ... _columns: DedupeColumnCollection[Column[Any]] constraints: Set[Constraint] """A collection of all :class:`_schema.Constraint` objects associated with this :class:`_schema.Table`. Includes :class:`_schema.PrimaryKeyConstraint`, :class:`_schema.ForeignKeyConstraint`, :class:`_schema.UniqueConstraint`, :class:`_schema.CheckConstraint`. A separate collection :attr:`_schema.Table.foreign_key_constraints` refers to the collection of all :class:`_schema.ForeignKeyConstraint` objects, and the :attr:`_schema.Table.primary_key` attribute refers to the single :class:`_schema.PrimaryKeyConstraint` associated with the :class:`_schema.Table`. .. seealso:: :attr:`_schema.Table.constraints` :attr:`_schema.Table.primary_key` :attr:`_schema.Table.foreign_key_constraints` :attr:`_schema.Table.indexes` :class:`_reflection.Inspector` """ indexes: Set[Index] """A collection of all :class:`_schema.Index` objects associated with this :class:`_schema.Table`. .. seealso:: :meth:`_reflection.Inspector.get_indexes` """ _traverse_internals: _TraverseInternalsType = ( TableClause._traverse_internals + [("schema", InternalTraversal.dp_string)] ) if TYPE_CHECKING: @util.ro_non_memoized_property def columns(self) -> ReadOnlyColumnCollection[str, Column[Any]]: ... @util.ro_non_memoized_property def exported_columns( self, ) -> ReadOnlyColumnCollection[str, Column[Any]]: ... @util.ro_non_memoized_property def c(self) -> ReadOnlyColumnCollection[str, Column[Any]]: ... def _gen_cache_key( self, anon_map: anon_map, bindparams: List[BindParameter[Any]] ) -> Tuple[Any, ...]: if self._annotations: return (self,) + self._annotations_cache_key else: return (self,) if not typing.TYPE_CHECKING: # typing tools seem to be inconsistent in how they handle # __new__, so suggest this pattern for classes that use # __new__. apply typing to the __init__ method normally @util.deprecated_params( mustexist=( "1.4", "Deprecated alias of :paramref:`_schema.Table.must_exist`", ), ) def __new__(cls, *args: Any, **kw: Any) -> Any: return cls._new(*args, **kw) @classmethod def _new(cls, *args: Any, **kw: Any) -> Any: if not args and not kw: # python3k pickle seems to call this return object.__new__(cls) try: name, metadata, args = args[0], args[1], args[2:] except IndexError: raise TypeError( "Table() takes at least two positional-only " "arguments 'name' and 'metadata'" ) schema = kw.get("schema", None) if schema is None: schema = metadata.schema elif schema is BLANK_SCHEMA: schema = None keep_existing = kw.get("keep_existing", False) extend_existing = kw.get("extend_existing", False) if keep_existing and extend_existing: msg = "keep_existing and extend_existing are mutually exclusive." raise exc.ArgumentError(msg) must_exist = kw.pop("must_exist", kw.pop("mustexist", False)) key = _get_table_key(name, schema) if key in metadata.tables: if not keep_existing and not extend_existing and bool(args): raise exc.InvalidRequestError( "Table '%s' is already defined for this MetaData " "instance. Specify 'extend_existing=True' " "to redefine " "options and columns on an " "existing Table object." % key ) table = metadata.tables[key] if extend_existing: table._init_existing(*args, **kw) return table else: if must_exist: raise exc.InvalidRequestError("Table '%s' not defined" % (key)) table = object.__new__(cls) table.dispatch.before_parent_attach(table, metadata) metadata._add_table(name, schema, table) try: table.__init__(name, metadata, *args, _no_init=False, **kw) table.dispatch.after_parent_attach(table, metadata) return table except Exception: with util.safe_reraise(): metadata._remove_table(name, schema) def __init__( self, name: str, metadata: MetaData, *args: SchemaItem, schema: Optional[Union[str, Literal[SchemaConst.BLANK_SCHEMA]]] = None, quote: Optional[bool] = None, quote_schema: Optional[bool] = None, autoload_with: Optional[Union[Engine, Connection]] = None, autoload_replace: bool = True, keep_existing: bool = False, extend_existing: bool = False, resolve_fks: bool = True, include_columns: Optional[Collection[str]] = None, implicit_returning: bool = True, comment: Optional[str] = None, info: Optional[Dict[Any, Any]] = None, listeners: Optional[ _typing_Sequence[Tuple[str, Callable[..., Any]]] ] = None, prefixes: Optional[_typing_Sequence[str]] = None, # used internally in the metadata.reflect() process _extend_on: Optional[Set[Table]] = None, # used by __new__ to bypass __init__ _no_init: bool = True, # dialect-specific keyword args **kw: Any, ) -> None: r"""Constructor for :class:`_schema.Table`. :param name: The name of this table as represented in the database. The table name, along with the value of the ``schema`` parameter, forms a key which uniquely identifies this :class:`_schema.Table` within the owning :class:`_schema.MetaData` collection. Additional calls to :class:`_schema.Table` with the same name, metadata, and schema name will return the same :class:`_schema.Table` object. Names which contain no upper case characters will be treated as case insensitive names, and will not be quoted unless they are a reserved word or contain special characters. A name with any number of upper case characters is considered to be case sensitive, and will be sent as quoted. To enable unconditional quoting for the table name, specify the flag ``quote=True`` to the constructor, or use the :class:`.quoted_name` construct to specify the name. :param metadata: a :class:`_schema.MetaData` object which will contain this table. The metadata is used as a point of association of this table with other tables which are referenced via foreign key. It also may be used to associate this table with a particular :class:`.Connection` or :class:`.Engine`. :param \*args: Additional positional arguments are used primarily to add the list of :class:`_schema.Column` objects contained within this table. Similar to the style of a CREATE TABLE statement, other :class:`.SchemaItem` constructs may be added here, including :class:`.PrimaryKeyConstraint`, and :class:`_schema.ForeignKeyConstraint`. :param autoload_replace: Defaults to ``True``; when using :paramref:`_schema.Table.autoload_with` in conjunction with :paramref:`_schema.Table.extend_existing`, indicates that :class:`_schema.Column` objects present in the already-existing :class:`_schema.Table` object should be replaced with columns of the same name retrieved from the autoload process. When ``False``, columns already present under existing names will be omitted from the reflection process. Note that this setting does not impact :class:`_schema.Column` objects specified programmatically within the call to :class:`_schema.Table` that also is autoloading; those :class:`_schema.Column` objects will always replace existing columns of the same name when :paramref:`_schema.Table.extend_existing` is ``True``. .. seealso:: :paramref:`_schema.Table.autoload_with` :paramref:`_schema.Table.extend_existing` :param autoload_with: An :class:`_engine.Engine` or :class:`_engine.Connection` object, or a :class:`_reflection.Inspector` object as returned by :func:`_sa.inspect` against one, with which this :class:`_schema.Table` object will be reflected. When set to a non-None value, the autoload process will take place for this table against the given engine or connection. :param extend_existing: When ``True``, indicates that if this :class:`_schema.Table` is already present in the given :class:`_schema.MetaData`, apply further arguments within the constructor to the existing :class:`_schema.Table`. If :paramref:`_schema.Table.extend_existing` or :paramref:`_schema.Table.keep_existing` are not set, and the given name of the new :class:`_schema.Table` refers to a :class:`_schema.Table` that is already present in the target :class:`_schema.MetaData` collection, and this :class:`_schema.Table` specifies additional columns or other constructs or flags that modify the table's state, an error is raised. The purpose of these two mutually-exclusive flags is to specify what action should be taken when a :class:`_schema.Table` is specified that matches an existing :class:`_schema.Table`, yet specifies additional constructs. :paramref:`_schema.Table.extend_existing` will also work in conjunction with :paramref:`_schema.Table.autoload_with` to run a new reflection operation against the database, even if a :class:`_schema.Table` of the same name is already present in the target :class:`_schema.MetaData`; newly reflected :class:`_schema.Column` objects and other options will be added into the state of the :class:`_schema.Table`, potentially overwriting existing columns and options of the same name. As is always the case with :paramref:`_schema.Table.autoload_with`, :class:`_schema.Column` objects can be specified in the same :class:`_schema.Table` constructor, which will take precedence. Below, the existing table ``mytable`` will be augmented with :class:`_schema.Column` objects both reflected from the database, as well as the given :class:`_schema.Column` named "y":: Table("mytable", metadata, Column('y', Integer), extend_existing=True, autoload_with=engine ) .. seealso:: :paramref:`_schema.Table.autoload_with` :paramref:`_schema.Table.autoload_replace` :paramref:`_schema.Table.keep_existing` :param implicit_returning: True by default - indicates that RETURNING can be used, typically by the ORM, in order to fetch server-generated values such as primary key values and server side defaults, on those backends which support RETURNING. In modern SQLAlchemy there is generally no reason to alter this setting, except for some backend specific cases (see :ref:`mssql_triggers` in the SQL Server dialect documentation for one such example). :param include_columns: A list of strings indicating a subset of columns to be loaded via the ``autoload`` operation; table columns who aren't present in this list will not be represented on the resulting ``Table`` object. Defaults to ``None`` which indicates all columns should be reflected. :param resolve_fks: Whether or not to reflect :class:`_schema.Table` objects related to this one via :class:`_schema.ForeignKey` objects, when :paramref:`_schema.Table.autoload_with` is specified. Defaults to True. Set to False to disable reflection of related tables as :class:`_schema.ForeignKey` objects are encountered; may be used either to save on SQL calls or to avoid issues with related tables that can't be accessed. Note that if a related table is already present in the :class:`_schema.MetaData` collection, or becomes present later, a :class:`_schema.ForeignKey` object associated with this :class:`_schema.Table` will resolve to that table normally. .. versionadded:: 1.3 .. seealso:: :paramref:`.MetaData.reflect.resolve_fks` :param info: Optional data dictionary which will be populated into the :attr:`.SchemaItem.info` attribute of this object. :param keep_existing: When ``True``, indicates that if this Table is already present in the given :class:`_schema.MetaData`, ignore further arguments within the constructor to the existing :class:`_schema.Table`, and return the :class:`_schema.Table` object as originally created. This is to allow a function that wishes to define a new :class:`_schema.Table` on first call, but on subsequent calls will return the same :class:`_schema.Table`, without any of the declarations (particularly constraints) being applied a second time. If :paramref:`_schema.Table.extend_existing` or :paramref:`_schema.Table.keep_existing` are not set, and the given name of the new :class:`_schema.Table` refers to a :class:`_schema.Table` that is already present in the target :class:`_schema.MetaData` collection, and this :class:`_schema.Table` specifies additional columns or other constructs or flags that modify the table's state, an error is raised. The purpose of these two mutually-exclusive flags is to specify what action should be taken when a :class:`_schema.Table` is specified that matches an existing :class:`_schema.Table`, yet specifies additional constructs. .. seealso:: :paramref:`_schema.Table.extend_existing` :param listeners: A list of tuples of the form ``(, )`` which will be passed to :func:`.event.listen` upon construction. This alternate hook to :func:`.event.listen` allows the establishment of a listener function specific to this :class:`_schema.Table` before the "autoload" process begins. Historically this has been intended for use with the :meth:`.DDLEvents.column_reflect` event, however note that this event hook may now be associated with the :class:`_schema.MetaData` object directly:: def listen_for_reflect(table, column_info): "handle the column reflection event" # ... t = Table( 'sometable', autoload_with=engine, listeners=[ ('column_reflect', listen_for_reflect) ]) .. seealso:: :meth:`_events.DDLEvents.column_reflect` :param must_exist: When ``True``, indicates that this Table must already be present in the given :class:`_schema.MetaData` collection, else an exception is raised. :param prefixes: A list of strings to insert after CREATE in the CREATE TABLE statement. They will be separated by spaces. :param quote: Force quoting of this table'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. .. note:: setting this flag to ``False`` will not provide case-insensitive behavior for table reflection; table reflection will always search for a mixed-case name in a case sensitive fashion. Case insensitive names are specified in SQLAlchemy only by stating the name with all lower case characters. :param quote_schema: same as 'quote' but applies to the schema identifier. :param schema: The schema name for this table, which is required if the table resides in a schema other than the default selected schema for the engine's database connection. Defaults to ``None``. If the owning :class:`_schema.MetaData` of this :class:`_schema.Table` specifies its own :paramref:`_schema.MetaData.schema` parameter, then that schema name will be applied to this :class:`_schema.Table` if the schema parameter here is set to ``None``. To set a blank schema name on a :class:`_schema.Table` that would otherwise use the schema set on the owning :class:`_schema.MetaData`, specify the special symbol :attr:`.BLANK_SCHEMA`. .. versionadded:: 1.0.14 Added the :attr:`.BLANK_SCHEMA` symbol to allow a :class:`_schema.Table` to have a blank schema name even when the parent :class:`_schema.MetaData` specifies :paramref:`_schema.MetaData.schema`. The quoting rules for the schema name are the same as those for the ``name`` parameter, in that quoting is applied for reserved words or case-sensitive names; to enable unconditional quoting for the schema name, specify the flag ``quote_schema=True`` to the constructor, or use the :class:`.quoted_name` construct to specify the name. :param comment: Optional string that will render an SQL comment on table creation. .. versionadded:: 1.2 Added the :paramref:`_schema.Table.comment` parameter to :class:`_schema.Table`. :param \**kw: Additional keyword arguments not mentioned above are dialect specific, and passed in the form ``_``. See the documentation regarding an individual dialect at :ref:`dialect_toplevel` for detail on documented arguments. """ # noqa: E501 if _no_init: # don't run __init__ from __new__ by default; # __new__ has a specific place that __init__ is called return super().__init__(quoted_name(name, quote)) self.metadata = metadata if schema is None: self.schema = metadata.schema elif schema is BLANK_SCHEMA: self.schema = None else: quote_schema = quote_schema assert isinstance(schema, str) self.schema = quoted_name(schema, quote_schema) self.indexes = set() self.constraints = set() PrimaryKeyConstraint( _implicit_generated=True )._set_parent_with_dispatch(self) self.foreign_keys = set() # type: ignore self._extra_dependencies: Set[Table] = set() if self.schema is not None: self.fullname = "%s.%s" % (self.schema, self.name) else: self.fullname = self.name self.implicit_returning = implicit_returning _reflect_info = kw.pop("_reflect_info", None) self.comment = comment if info is not None: self.info = info if listeners is not None: for evt, fn in listeners: event.listen(self, evt, fn) self._prefixes = prefixes if prefixes else [] self._extra_kwargs(**kw) # load column definitions from the database if 'autoload' is defined # we do it after the table is in the singleton dictionary to support # circular foreign keys if autoload_with is not None: self._autoload( metadata, autoload_with, include_columns, _extend_on=_extend_on, _reflect_info=_reflect_info, resolve_fks=resolve_fks, ) # initialize all the column, etc. objects. done after reflection to # allow user-overrides self._init_items( *args, allow_replacements=extend_existing or keep_existing or autoload_with, all_names={}, ) def _autoload( self, metadata: MetaData, autoload_with: Union[Engine, Connection], include_columns: Optional[Collection[str]], exclude_columns: Collection[str] = (), resolve_fks: bool = True, _extend_on: Optional[Set[Table]] = None, _reflect_info: _ReflectionInfo | None = None, ) -> None: insp = inspection.inspect(autoload_with) with insp._inspection_context() as conn_insp: conn_insp.reflect_table( self, include_columns, exclude_columns, resolve_fks, _extend_on=_extend_on, _reflect_info=_reflect_info, ) @property def _sorted_constraints(self) -> List[Constraint]: """Return the set of constraints as a list, sorted by creation order. """ return sorted(self.constraints, key=lambda c: c._creation_order) @property def foreign_key_constraints(self) -> Set[ForeignKeyConstraint]: """:class:`_schema.ForeignKeyConstraint` objects referred to by this :class:`_schema.Table`. This list is produced from the collection of :class:`_schema.ForeignKey` objects currently associated. .. seealso:: :attr:`_schema.Table.constraints` :attr:`_schema.Table.foreign_keys` :attr:`_schema.Table.indexes` """ return { fkc.constraint for fkc in self.foreign_keys if fkc.constraint is not None } def _init_existing(self, *args: Any, **kwargs: Any) -> None: autoload_with = kwargs.pop("autoload_with", None) autoload = kwargs.pop("autoload", autoload_with is not None) autoload_replace = kwargs.pop("autoload_replace", True) schema = kwargs.pop("schema", None) _extend_on = kwargs.pop("_extend_on", None) _reflect_info = kwargs.pop("_reflect_info", None) # these arguments are only used with _init() extend_existing = kwargs.pop("extend_existing", False) keep_existing = kwargs.pop("keep_existing", False) assert extend_existing assert not keep_existing if schema and schema != self.schema: raise exc.ArgumentError( "Can't change schema of existing table from '%s' to '%s'", (self.schema, schema), ) include_columns = kwargs.pop("include_columns", None) if include_columns is not None: for c in self.c: if c.name not in include_columns: self._columns.remove(c) resolve_fks = kwargs.pop("resolve_fks", True) for key in ("quote", "quote_schema"): if key in kwargs: raise exc.ArgumentError( "Can't redefine 'quote' or 'quote_schema' arguments" ) # update `self` with these kwargs, if provided self.comment = kwargs.pop("comment", self.comment) self.implicit_returning = kwargs.pop( "implicit_returning", self.implicit_returning ) self.info = kwargs.pop("info", self.info) exclude_columns: _typing_Sequence[str] if autoload: if not autoload_replace: # don't replace columns already present. # we'd like to do this for constraints also however we don't # have simple de-duping for unnamed constraints. exclude_columns = [c.name for c in self.c] else: exclude_columns = () self._autoload( self.metadata, autoload_with, include_columns, exclude_columns, resolve_fks, _extend_on=_extend_on, _reflect_info=_reflect_info, ) all_names = {c.name: c for c in self.c} self._extra_kwargs(**kwargs) self._init_items(*args, allow_replacements=True, all_names=all_names) def _extra_kwargs(self, **kwargs: Any) -> None: self._validate_dialect_kwargs(kwargs) def _init_collections(self) -> None: pass def _reset_exported(self) -> None: pass @util.ro_non_memoized_property def _autoincrement_column(self) -> Optional[Column[int]]: return self.primary_key._autoincrement_column @property def autoincrement_column(self) -> Optional[Column[int]]: """Returns the :class:`.Column` object which currently represents the "auto increment" column, if any, else returns None. This is based on the rules for :class:`.Column` as defined by the :paramref:`.Column.autoincrement` parameter, which generally means the column within a single integer column primary key constraint that is not constrained by a foreign key. If the table does not have such a primary key constraint, then there's no "autoincrement" column. A :class:`.Table` may have only one column defined as the "autoincrement" column. .. versionadded:: 2.0.4 .. seealso:: :paramref:`.Column.autoincrement` """ return self._autoincrement_column @property def key(self) -> str: """Return the 'key' for this :class:`_schema.Table`. This value is used as the dictionary key within the :attr:`_schema.MetaData.tables` collection. It is typically the same as that of :attr:`_schema.Table.name` for a table with no :attr:`_schema.Table.schema` set; otherwise it is typically of the form ``schemaname.tablename``. """ return _get_table_key(self.name, self.schema) def __repr__(self) -> str: return "Table(%s)" % ", ".join( [repr(self.name)] + [repr(self.metadata)] + [repr(x) for x in self.columns] + ["%s=%s" % (k, repr(getattr(self, k))) for k in ["schema"]] ) def __str__(self) -> str: return _get_table_key(self.description, self.schema) def add_is_dependent_on(self, table: Table) -> None: """Add a 'dependency' for this Table. This is another Table object which must be created first before this one can, or dropped after this one. Usually, dependencies between tables are determined via ForeignKey objects. However, for other situations that create dependencies outside of foreign keys (rules, inheriting), this method can manually establish such a link. """ self._extra_dependencies.add(table) def append_column( self, column: ColumnClause[Any], replace_existing: bool = False ) -> None: """Append a :class:`_schema.Column` to this :class:`_schema.Table`. The "key" of the newly added :class:`_schema.Column`, i.e. the value of its ``.key`` attribute, will then be available in the ``.c`` collection of this :class:`_schema.Table`, and the column definition will be included in any CREATE TABLE, SELECT, UPDATE, etc. statements generated from this :class:`_schema.Table` construct. Note that this does **not** change the definition of the table as it exists within any underlying database, assuming that table has already been created in the database. Relational databases support the addition of columns to existing tables using the SQL ALTER command, which would need to be emitted for an already-existing table that doesn't contain the newly added column. :param replace_existing: When ``True``, allows replacing existing columns. When ``False``, the default, an warning will be raised if a column with the same ``.key`` already exists. A future version of sqlalchemy will instead rise a warning. .. versionadded:: 1.4.0 """ try: column._set_parent_with_dispatch( self, allow_replacements=replace_existing, all_names={c.name: c for c in self.c}, ) except exc.DuplicateColumnError as de: raise exc.DuplicateColumnError( f"{de.args[0]} Specify replace_existing=True to " "Table.append_column() to replace an " "existing column." ) from de def append_constraint(self, constraint: Union[Index, Constraint]) -> None: """Append a :class:`_schema.Constraint` to this :class:`_schema.Table`. This has the effect of the constraint being included in any future CREATE TABLE statement, assuming specific DDL creation events have not been associated with the given :class:`_schema.Constraint` object. Note that this does **not** produce the constraint within the relational database automatically, for a table that already exists in the database. To add a constraint to an existing relational database table, the SQL ALTER command must be used. SQLAlchemy also provides the :class:`.AddConstraint` construct which can produce this SQL when invoked as an executable clause. """ constraint._set_parent_with_dispatch(self) def _set_parent(self, parent: SchemaEventTarget, **kw: Any) -> None: metadata = parent assert isinstance(metadata, MetaData) metadata._add_table(self.name, self.schema, self) self.metadata = metadata def create(self, bind: _CreateDropBind, checkfirst: bool = False) -> None: """Issue a ``CREATE`` statement for this :class:`_schema.Table`, using the given :class:`.Connection` or :class:`.Engine` for connectivity. .. seealso:: :meth:`_schema.MetaData.create_all`. """ bind._run_ddl_visitor(ddl.SchemaGenerator, self, checkfirst=checkfirst) def drop(self, bind: _CreateDropBind, checkfirst: bool = False) -> None: """Issue a ``DROP`` statement for this :class:`_schema.Table`, using the given :class:`.Connection` or :class:`.Engine` for connectivity. .. seealso:: :meth:`_schema.MetaData.drop_all`. """ bind._run_ddl_visitor(ddl.SchemaDropper, self, checkfirst=checkfirst) @util.deprecated( "1.4", ":meth:`_schema.Table.tometadata` is renamed to " ":meth:`_schema.Table.to_metadata`", ) def tometadata( self, metadata: MetaData, schema: Union[str, Literal[SchemaConst.RETAIN_SCHEMA]] = RETAIN_SCHEMA, referred_schema_fn: Optional[ Callable[ [Table, Optional[str], ForeignKeyConstraint, Optional[str]], Optional[str], ] ] = None, name: Optional[str] = None, ) -> Table: """Return a copy of this :class:`_schema.Table` associated with a different :class:`_schema.MetaData`. See :meth:`_schema.Table.to_metadata` for a full description. """ return self.to_metadata( metadata, schema=schema, referred_schema_fn=referred_schema_fn, name=name, ) def to_metadata( self, metadata: MetaData, schema: Union[str, Literal[SchemaConst.RETAIN_SCHEMA]] = RETAIN_SCHEMA, referred_schema_fn: Optional[ Callable[ [Table, Optional[str], ForeignKeyConstraint, Optional[str]], Optional[str], ] ] = None, name: Optional[str] = None, ) -> Table: """Return a copy of this :class:`_schema.Table` associated with a different :class:`_schema.MetaData`. E.g.:: m1 = MetaData() user = Table('user', m1, Column('id', Integer, primary_key=True)) m2 = MetaData() user_copy = user.to_metadata(m2) .. versionchanged:: 1.4 The :meth:`_schema.Table.to_metadata` function was renamed from :meth:`_schema.Table.tometadata`. :param metadata: Target :class:`_schema.MetaData` object, into which the new :class:`_schema.Table` object will be created. :param schema: optional string name indicating the target schema. Defaults to the special symbol :attr:`.RETAIN_SCHEMA` which indicates that no change to the schema name should be made in the new :class:`_schema.Table`. If set to a string name, the new :class:`_schema.Table` will have this new name as the ``.schema``. If set to ``None``, the schema will be set to that of the schema set on the target :class:`_schema.MetaData`, which is typically ``None`` as well, unless set explicitly:: m2 = MetaData(schema='newschema') # user_copy_one will have "newschema" as the schema name user_copy_one = user.to_metadata(m2, schema=None) m3 = MetaData() # schema defaults to None # user_copy_two will have None as the schema name user_copy_two = user.to_metadata(m3, schema=None) :param referred_schema_fn: optional callable which can be supplied in order to provide for the schema name that should be assigned to the referenced table of a :class:`_schema.ForeignKeyConstraint`. The callable accepts this parent :class:`_schema.Table`, the target schema that we are changing to, the :class:`_schema.ForeignKeyConstraint` object, and the existing "target schema" of that constraint. The function should return the string schema name that should be applied. To reset the schema to "none", return the symbol :data:`.BLANK_SCHEMA`. To effect no change, return ``None`` or :data:`.RETAIN_SCHEMA`. .. versionchanged:: 1.4.33 The ``referred_schema_fn`` function may return the :data:`.BLANK_SCHEMA` or :data:`.RETAIN_SCHEMA` symbols. E.g.:: def referred_schema_fn(table, to_schema, constraint, referred_schema): if referred_schema == 'base_tables': return referred_schema else: return to_schema new_table = table.to_metadata(m2, schema="alt_schema", referred_schema_fn=referred_schema_fn) .. versionadded:: 0.9.2 :param name: optional string name indicating the target table name. If not specified or None, the table name is retained. This allows a :class:`_schema.Table` to be copied to the same :class:`_schema.MetaData` target with a new name. .. versionadded:: 1.0.0 """ if name is None: name = self.name actual_schema: Optional[str] if schema is RETAIN_SCHEMA: actual_schema = self.schema elif schema is None: actual_schema = metadata.schema else: actual_schema = schema # type: ignore key = _get_table_key(name, actual_schema) if key in metadata.tables: util.warn( "Table '%s' already exists within the given " "MetaData - not copying." % self.description ) return metadata.tables[key] args = [] for col in self.columns: args.append(col._copy(schema=actual_schema)) table = Table( name, metadata, schema=actual_schema, comment=self.comment, *args, **self.kwargs, ) for const in self.constraints: if isinstance(const, ForeignKeyConstraint): referred_schema = const._referred_schema if referred_schema_fn: fk_constraint_schema = referred_schema_fn( self, actual_schema, const, referred_schema ) else: fk_constraint_schema = ( actual_schema if referred_schema == self.schema else None ) table.append_constraint( const._copy( schema=fk_constraint_schema, target_table=table ) ) elif not const._type_bound: # skip unique constraints that would be generated # by the 'unique' flag on Column if const._column_flag: continue table.append_constraint( const._copy(schema=actual_schema, target_table=table) ) for index in self.indexes: # skip indexes that would be generated # by the 'index' flag on Column if index._column_flag: continue Index( index.name, unique=index.unique, *[ _copy_expression(expr, self, table) for expr in index._table_bound_expressions ], _table=table, **index.kwargs, ) return self._schema_item_copy(table) class Column(DialectKWArgs, SchemaItem, ColumnClause[_T]): """Represents a column in a database table.""" __visit_name__ = "column" inherit_cache = True key: str def __init__( self, __name_pos: Optional[ Union[str, _TypeEngineArgument[_T], SchemaEventTarget] ] = None, __type_pos: Optional[ Union[_TypeEngineArgument[_T], SchemaEventTarget] ] = None, *args: SchemaEventTarget, name: Optional[str] = None, type_: Optional[_TypeEngineArgument[_T]] = None, autoincrement: _AutoIncrementType = "auto", default: Optional[Any] = None, doc: Optional[str] = None, key: Optional[str] = None, index: Optional[bool] = None, unique: Optional[bool] = None, info: Optional[_InfoType] = None, nullable: Optional[ Union[bool, Literal[SchemaConst.NULL_UNSPECIFIED]] ] = SchemaConst.NULL_UNSPECIFIED, onupdate: Optional[Any] = None, primary_key: bool = False, server_default: Optional[_ServerDefaultType] = None, server_onupdate: Optional[FetchedValue] = None, quote: Optional[bool] = None, system: bool = False, comment: Optional[str] = None, _proxies: Optional[Any] = None, **dialect_kwargs: Any, ): r""" Construct a new ``Column`` object. :param name: The name of this column as represented in the database. This argument may be the first positional argument, or specified via keyword. Names which contain no upper case characters will be treated as case insensitive names, and will not be quoted unless they are a reserved word. Names with any number of upper case characters will be quoted and sent exactly. Note that this behavior applies even for databases which standardize upper case names as case insensitive such as Oracle. The name field may be omitted at construction time and applied later, at any time before the Column is associated with a :class:`_schema.Table`. This is to support convenient usage within the :mod:`~sqlalchemy.ext.declarative` extension. :param type\_: The column's type, indicated using an instance which subclasses :class:`~sqlalchemy.types.TypeEngine`. If no arguments are required for the type, the class of the type can be sent as well, e.g.:: # use a type with arguments Column('data', String(50)) # use no arguments Column('level', Integer) The ``type`` argument may be the second positional argument or specified by keyword. If the ``type`` is ``None`` or is omitted, it will first default to the special type :class:`.NullType`. If and when this :class:`_schema.Column` is made to refer to another column using :class:`_schema.ForeignKey` and/or :class:`_schema.ForeignKeyConstraint`, the type of the remote-referenced column will be copied to this column as well, at the moment that the foreign key is resolved against that remote :class:`_schema.Column` object. .. versionchanged:: 0.9.0 Support for propagation of type to a :class:`_schema.Column` from its :class:`_schema.ForeignKey` object has been improved and should be more reliable and timely. :param \*args: Additional positional arguments include various :class:`.SchemaItem` derived constructs which will be applied as options to the column. These include instances of :class:`.Constraint`, :class:`_schema.ForeignKey`, :class:`.ColumnDefault`, :class:`.Sequence`, :class:`.Computed` :class:`.Identity`. In some cases an equivalent keyword argument is available such as ``server_default``, ``default`` and ``unique``. :param autoincrement: Set up "auto increment" semantics for an **integer primary key column with no foreign key dependencies** (see later in this docstring for a more specific definition). This may influence the :term:`DDL` that will be emitted for this column during a table create, as well as how the column will be considered when INSERT statements are compiled and executed. The default value is the string ``"auto"``, which indicates that a single-column (i.e. non-composite) primary key that is of an INTEGER type with no other client-side or server-side default constructs indicated should receive auto increment semantics automatically. Other values include ``True`` (force this column to have auto-increment semantics for a :term:`composite primary key` as well), ``False`` (this column should never have auto-increment semantics), and the string ``"ignore_fk"`` (special-case for foreign key columns, see below). The term "auto increment semantics" refers both to the kind of DDL that will be emitted for the column within a CREATE TABLE statement, when methods such as :meth:`.MetaData.create_all` and :meth:`.Table.create` are invoked, as well as how the column will be considered when an INSERT statement is compiled and emitted to the database: * **DDL rendering** (i.e. :meth:`.MetaData.create_all`, :meth:`.Table.create`): When used on a :class:`.Column` that has no other default-generating construct associated with it (such as a :class:`.Sequence` or :class:`.Identity` construct), the parameter will imply that database-specific keywords such as PostgreSQL ``SERIAL``, MySQL ``AUTO_INCREMENT``, or ``IDENTITY`` on SQL Server should also be rendered. Not every database backend has an "implied" default generator available; for example the Oracle backend always needs an explicit construct such as :class:`.Identity` to be included with a :class:`.Column` in order for the DDL rendered to include auto-generating constructs to also be produced in the database. * **INSERT semantics** (i.e. when a :func:`_sql.insert` construct is compiled into a SQL string and is then executed on a database using :meth:`_engine.Connection.execute` or equivalent): A single-row INSERT statement will be known to produce a new integer primary key value automatically for this column, which will be accessible after the statement is invoked via the :attr:`.CursorResult.inserted_primary_key` attribute upon the :class:`_result.Result` object. This also applies towards use of the ORM when ORM-mapped objects are persisted to the database, indicating that a new integer primary key will be available to become part of the :term:`identity key` for that object. This behavior takes place regardless of what DDL constructs are associated with the :class:`_schema.Column` and is independent of the "DDL Rendering" behavior discussed in the previous note above. The parameter may be set to ``True`` to indicate that a column which is part of a composite (i.e. multi-column) primary key should have autoincrement semantics, though note that only one column within a primary key may have this setting. It can also be set to ``True`` to indicate autoincrement semantics on a column that has a client-side or server-side default configured, however note that not all dialects can accommodate all styles of default as an "autoincrement". It can also be set to ``False`` on a single-column primary key that has a datatype of INTEGER in order to disable auto increment semantics for that column. .. versionchanged:: 1.1 The autoincrement flag now defaults to ``"auto"`` which indicates autoincrement semantics by default for single-column integer primary keys only; for composite (multi-column) primary keys, autoincrement is never implicitly enabled; as always, ``autoincrement=True`` will allow for at most one of those columns to be an "autoincrement" column. ``autoincrement=True`` may also be set on a :class:`_schema.Column` that has an explicit client-side or server-side default, subject to limitations of the backend database and dialect. The setting *only* has an effect for columns which are: * Integer derived (i.e. INT, SMALLINT, BIGINT). * Part of the primary key * Not referring to another column via :class:`_schema.ForeignKey`, unless the value is specified as ``'ignore_fk'``:: # turn on autoincrement for this column despite # the ForeignKey() Column('id', ForeignKey('other.id'), primary_key=True, autoincrement='ignore_fk') It is typically not desirable to have "autoincrement" enabled on a column that refers to another via foreign key, as such a column is required to refer to a value that originates from elsewhere. The setting has these effects on columns that meet the above criteria: * DDL issued for the column, if the column does not already include a default generating construct supported by the backend such as :class:`.Identity`, will include database-specific keywords intended to signify this column as an "autoincrement" column for specific backends. Behavior for primary SQLAlchemy dialects includes: * AUTO INCREMENT on MySQL and MariaDB * SERIAL on PostgreSQL * IDENTITY on MS-SQL - this occurs even without the :class:`.Identity` construct as the :paramref:`.Column.autoincrement` parameter pre-dates this construct. * SQLite - SQLite integer primary key columns are implicitly "auto incrementing" and no additional keywords are rendered; to render the special SQLite keyword ``AUTOINCREMENT`` is not included as this is unnecessary and not recommended by the database vendor. See the section :ref:`sqlite_autoincrement` for more background. * Oracle - The Oracle dialect has no default "autoincrement" feature available at this time, instead the :class:`.Identity` construct is recommended to achieve this (the :class:`.Sequence` construct may also be used). * Third-party dialects - consult those dialects' documentation for details on their specific behaviors. * When a single-row :func:`_sql.insert` construct is compiled and executed, which does not set the :meth:`_sql.Insert.inline` modifier, newly generated primary key values for this column will be automatically retrieved upon statement execution using a method specific to the database driver in use: * MySQL, SQLite - calling upon ``cursor.lastrowid()`` (see `https://www.python.org/dev/peps/pep-0249/#lastrowid `_) * PostgreSQL, SQL Server, Oracle - use RETURNING or an equivalent construct when rendering an INSERT statement, and then retrieving the newly generated primary key values after execution * PostgreSQL, Oracle for :class:`_schema.Table` objects that set :paramref:`_schema.Table.implicit_returning` to False - for a :class:`.Sequence` only, the :class:`.Sequence` is invoked explicitly before the INSERT statement takes place so that the newly generated primary key value is available to the client * SQL Server for :class:`_schema.Table` objects that set :paramref:`_schema.Table.implicit_returning` to False - the ``SELECT scope_identity()`` construct is used after the INSERT statement is invoked to retrieve the newly generated primary key value. * Third-party dialects - consult those dialects' documentation for details on their specific behaviors. * For multiple-row :func:`_sql.insert` constructs invoked with a list of parameters (i.e. "executemany" semantics), primary-key retrieving behaviors are generally disabled, however there may be special APIs that may be used to retrieve lists of new primary key values for an "executemany", such as the psycopg2 "fast insertmany" feature. Such features are very new and may not yet be well covered in documentation. :param default: A scalar, Python callable, or :class:`_expression.ColumnElement` expression representing the *default value* for this column, which will be invoked upon insert if this column is otherwise not specified in the VALUES clause of the insert. This is a shortcut to using :class:`.ColumnDefault` as a positional argument; see that class for full detail on the structure of the argument. Contrast this argument to :paramref:`_schema.Column.server_default` which creates a default generator on the database side. .. seealso:: :ref:`metadata_defaults_toplevel` :param doc: optional String that can be used by the ORM or similar to document attributes on the Python side. This attribute does **not** render SQL comments; use the :paramref:`_schema.Column.comment` parameter for this purpose. :param key: An optional string identifier which will identify this ``Column`` object on the :class:`_schema.Table`. When a key is provided, this is the only identifier referencing the ``Column`` within the application, including ORM attribute mapping; the ``name`` field is used only when rendering SQL. :param index: When ``True``, indicates that a :class:`_schema.Index` construct will be automatically generated for this :class:`_schema.Column`, which will result in a "CREATE INDEX" statement being emitted for the :class:`_schema.Table` when the DDL create operation is invoked. Using this flag is equivalent to making use of the :class:`_schema.Index` construct explicitly at the level of the :class:`_schema.Table` construct itself:: Table( "some_table", metadata, Column("x", Integer), Index("ix_some_table_x", "x") ) To add the :paramref:`_schema.Index.unique` flag to the :class:`_schema.Index`, set both the :paramref:`_schema.Column.unique` and :paramref:`_schema.Column.index` flags to True simultaneously, which will have the effect of rendering the "CREATE UNIQUE INDEX" DDL instruction instead of "CREATE INDEX". The name of the index is generated using the :ref:`default naming convention ` which for the :class:`_schema.Index` construct is of the form ``ix__``. As this flag is intended only as a convenience for the common case of adding a single-column, default configured index to a table definition, explicit use of the :class:`_schema.Index` construct should be preferred for most use cases, including composite indexes that encompass more than one column, indexes with SQL expressions or ordering, backend-specific index configuration options, and indexes that use a specific name. .. note:: the :attr:`_schema.Column.index` attribute on :class:`_schema.Column` **does not indicate** if this column is indexed or not, only if this flag was explicitly set here. To view indexes on a column, view the :attr:`_schema.Table.indexes` collection or use :meth:`_reflection.Inspector.get_indexes`. .. seealso:: :ref:`schema_indexes` :ref:`constraint_naming_conventions` :paramref:`_schema.Column.unique` :param info: Optional data dictionary which will be populated into the :attr:`.SchemaItem.info` attribute of this object. :param nullable: When set to ``False``, will cause the "NOT NULL" phrase to be added when generating DDL for the column. When ``True``, will normally generate nothing (in SQL this defaults to "NULL"), except in some very specific backend-specific edge cases where "NULL" may render explicitly. Defaults to ``True`` unless :paramref:`_schema.Column.primary_key` is also ``True`` or the column specifies a :class:`_sql.Identity`, in which case it defaults to ``False``. This parameter is only used when issuing CREATE TABLE statements. .. note:: When the column specifies a :class:`_sql.Identity` this parameter is in general ignored by the DDL compiler. The PostgreSQL database allows nullable identity column by setting this parameter to ``True`` explicitly. :param onupdate: A scalar, Python callable, or :class:`~sqlalchemy.sql.expression.ClauseElement` representing a default value to be applied to the column within UPDATE statements, which will be invoked upon update if this column is not present in the SET clause of the update. This is a shortcut to using :class:`.ColumnDefault` as a positional argument with ``for_update=True``. .. seealso:: :ref:`metadata_defaults` - complete discussion of onupdate :param primary_key: If ``True``, marks this column as a primary key column. Multiple columns can have this flag set to specify composite primary keys. As an alternative, the primary key of a :class:`_schema.Table` can be specified via an explicit :class:`.PrimaryKeyConstraint` object. :param server_default: A :class:`.FetchedValue` instance, str, Unicode or :func:`~sqlalchemy.sql.expression.text` construct representing the DDL DEFAULT value for the column. String types will be emitted as-is, surrounded by single quotes:: Column('x', Text, server_default="val") x TEXT DEFAULT 'val' A :func:`~sqlalchemy.sql.expression.text` expression will be rendered as-is, without quotes:: Column('y', DateTime, server_default=text('NOW()')) y DATETIME DEFAULT NOW() Strings and text() will be converted into a :class:`.DefaultClause` object upon initialization. This parameter can also accept complex combinations of contextually valid SQLAlchemy expressions or constructs:: from sqlalchemy import create_engine from sqlalchemy import Table, Column, MetaData, ARRAY, Text from sqlalchemy.dialects.postgresql import array engine = create_engine( 'postgresql+psycopg2://scott:tiger@localhost/mydatabase' ) metadata_obj = MetaData() tbl = Table( "foo", metadata_obj, Column("bar", ARRAY(Text), server_default=array(["biz", "bang", "bash"]) ) ) metadata_obj.create_all(engine) The above results in a table created with the following SQL:: CREATE TABLE foo ( bar TEXT[] DEFAULT ARRAY['biz', 'bang', 'bash'] ) Use :class:`.FetchedValue` to indicate that an already-existing column will generate a default value on the database side which will be available to SQLAlchemy for post-fetch after inserts. This construct does not specify any DDL and the implementation is left to the database, such as via a trigger. .. seealso:: :ref:`server_defaults` - complete discussion of server side defaults :param server_onupdate: A :class:`.FetchedValue` instance representing a database-side default generation function, such as a trigger. This indicates to SQLAlchemy that a newly generated value will be available after updates. This construct does not actually implement any kind of generation function within the database, which instead must be specified separately. .. warning:: This directive **does not** currently produce MySQL's "ON UPDATE CURRENT_TIMESTAMP()" clause. See :ref:`mysql_timestamp_onupdate` for background on how to produce this clause. .. seealso:: :ref:`triggered_columns` :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 unique: When ``True``, and the :paramref:`_schema.Column.index` parameter is left at its default value of ``False``, indicates that a :class:`_schema.UniqueConstraint` construct will be automatically generated for this :class:`_schema.Column`, which will result in a "UNIQUE CONSTRAINT" clause referring to this column being included in the ``CREATE TABLE`` statement emitted, when the DDL create operation for the :class:`_schema.Table` object is invoked. When this flag is ``True`` while the :paramref:`_schema.Column.index` parameter is simultaneously set to ``True``, the effect instead is that a :class:`_schema.Index` construct which includes the :paramref:`_schema.Index.unique` parameter set to ``True`` is generated. See the documentation for :paramref:`_schema.Column.index` for additional detail. Using this flag is equivalent to making use of the :class:`_schema.UniqueConstraint` construct explicitly at the level of the :class:`_schema.Table` construct itself:: Table( "some_table", metadata, Column("x", Integer), UniqueConstraint("x") ) The :paramref:`_schema.UniqueConstraint.name` parameter of the unique constraint object is left at its default value of ``None``; in the absence of a :ref:`naming convention ` for the enclosing :class:`_schema.MetaData`, the UNIQUE CONSTRAINT construct will be emitted as unnamed, which typically invokes a database-specific naming convention to take place. As this flag is intended only as a convenience for the common case of adding a single-column, default configured unique constraint to a table definition, explicit use of the :class:`_schema.UniqueConstraint` construct should be preferred for most use cases, including composite constraints that encompass more than one column, backend-specific index configuration options, and constraints that use a specific name. .. note:: the :attr:`_schema.Column.unique` attribute on :class:`_schema.Column` **does not indicate** if this column has a unique constraint or not, only if this flag was explicitly set here. To view indexes and unique constraints that may involve this column, view the :attr:`_schema.Table.indexes` and/or :attr:`_schema.Table.constraints` collections or use :meth:`_reflection.Inspector.get_indexes` and/or :meth:`_reflection.Inspector.get_unique_constraints` .. seealso:: :ref:`schema_unique_constraint` :ref:`constraint_naming_conventions` :paramref:`_schema.Column.index` :param system: When ``True``, indicates this is a "system" column, that is a column which is automatically made available by the database, and should not be included in the columns list for a ``CREATE TABLE`` statement. For more elaborate scenarios where columns should be conditionally rendered differently on different backends, consider custom compilation rules for :class:`.CreateColumn`. :param comment: Optional string that will render an SQL comment on table creation. .. versionadded:: 1.2 Added the :paramref:`_schema.Column.comment` parameter to :class:`_schema.Column`. """ # noqa: E501, RST201, RST202 l_args = [__name_pos, __type_pos] + list(args) del args if l_args: if isinstance(l_args[0], str): if name is not None: raise exc.ArgumentError( "May not pass name positionally and as a keyword." ) name = l_args.pop(0) # type: ignore elif l_args[0] is None: l_args.pop(0) if l_args: coltype = l_args[0] if hasattr(coltype, "_sqla_type"): if type_ is not None: raise exc.ArgumentError( "May not pass type_ positionally and as a keyword." ) type_ = l_args.pop(0) # type: ignore elif l_args[0] is None: l_args.pop(0) if name is not None: name = quoted_name(name, quote) elif quote is not None: raise exc.ArgumentError( "Explicit 'name' is required when " "sending 'quote' argument" ) # name = None is expected to be an interim state # note this use case is legacy now that ORM declarative has a # dedicated "column" construct local to the ORM super().__init__(name, type_) # type: ignore self.key = key if key is not None else name # type: ignore self.primary_key = primary_key self._user_defined_nullable = udn = nullable if udn is not NULL_UNSPECIFIED: self.nullable = udn else: self.nullable = not primary_key # these default to None because .index and .unique is *not* # an informational flag about Column - there can still be an # Index or UniqueConstraint referring to this Column. self.index = index self.unique = unique self.system = system self.doc = doc self.autoincrement: _AutoIncrementType = autoincrement self.constraints = set() self.foreign_keys = set() self.comment = comment self.computed = None self.identity = None # check if this Column is proxying another column if _proxies is not None: self._proxies = _proxies else: # otherwise, add DDL-related events self._set_type(self.type) if default is not None: if not isinstance(default, (ColumnDefault, Sequence)): default = ColumnDefault(default) self.default = default l_args.append(default) else: self.default = None if onupdate is not None: if not isinstance(onupdate, (ColumnDefault, Sequence)): onupdate = ColumnDefault(onupdate, for_update=True) self.onupdate = onupdate l_args.append(onupdate) else: self.onpudate = None self.server_default = server_default self.server_onupdate = server_onupdate if self.server_default is not None: if isinstance(self.server_default, FetchedValue): l_args.append(self.server_default._as_for_update(False)) else: l_args.append(DefaultClause(self.server_default)) if self.server_onupdate is not None: if isinstance(self.server_onupdate, FetchedValue): l_args.append(self.server_onupdate._as_for_update(True)) else: l_args.append( DefaultClause(self.server_onupdate, for_update=True) ) self._init_items(*cast(_typing_Sequence[SchemaItem], l_args)) util.set_creation_order(self) if info is not None: self.info = info self._extra_kwargs(**dialect_kwargs) table: Table constraints: Set[Constraint] foreign_keys: Set[ForeignKey] """A collection of all :class:`_schema.ForeignKey` marker objects associated with this :class:`_schema.Column`. Each object is a member of a :class:`_schema.Table`-wide :class:`_schema.ForeignKeyConstraint`. .. seealso:: :attr:`_schema.Table.foreign_keys` """ index: Optional[bool] """The value of the :paramref:`_schema.Column.index` parameter. Does not indicate if this :class:`_schema.Column` is actually indexed or not; use :attr:`_schema.Table.indexes`. .. seealso:: :attr:`_schema.Table.indexes` """ unique: Optional[bool] """The value of the :paramref:`_schema.Column.unique` parameter. Does not indicate if this :class:`_schema.Column` is actually subject to a unique constraint or not; use :attr:`_schema.Table.indexes` and :attr:`_schema.Table.constraints`. .. seealso:: :attr:`_schema.Table.indexes` :attr:`_schema.Table.constraints`. """ computed: Optional[Computed] identity: Optional[Identity] def _set_type(self, type_: TypeEngine[Any]) -> None: self.type = type_ if isinstance(self.type, SchemaEventTarget): self.type._set_parent_with_dispatch(self) for impl in self.type._variant_mapping.values(): if isinstance(impl, SchemaEventTarget): impl._set_parent_with_dispatch(self) @util.memoized_property def _gen_static_annotations_cache_key(self) -> bool: # type: ignore """special attribute used by cache key gen, if true, we will use a static cache key for the annotations dictionary, else we will generate a new cache key for annotations each time. Added for #8790 """ return self.table is not None and self.table._is_table def _extra_kwargs(self, **kwargs: Any) -> None: self._validate_dialect_kwargs(kwargs) def __str__(self) -> str: if self.name is None: return "(no name)" elif self.table is not None: if self.table.named_with_column: return self.table.description + "." + self.description else: return self.description else: return self.description def references(self, column: Column[Any]) -> bool: """Return True if this Column references the given column via foreign key.""" for fk in self.foreign_keys: if fk.column.proxy_set.intersection(column.proxy_set): return True else: return False def append_foreign_key(self, fk: ForeignKey) -> None: fk._set_parent_with_dispatch(self) def __repr__(self) -> str: kwarg = [] if self.key != self.name: kwarg.append("key") if self.primary_key: kwarg.append("primary_key") if not self.nullable: kwarg.append("nullable") if self.onupdate: kwarg.append("onupdate") if self.default: kwarg.append("default") if self.server_default: kwarg.append("server_default") if self.comment: kwarg.append("comment") return "Column(%s)" % ", ".join( [repr(self.name)] + [repr(self.type)] + [repr(x) for x in self.foreign_keys if x is not None] + [repr(x) for x in self.constraints] + [ ( self.table is not None and "table=<%s>" % self.table.description or "table=None" ) ] + ["%s=%s" % (k, repr(getattr(self, k))) for k in kwarg] ) def _set_parent( # type: ignore[override] self, parent: SchemaEventTarget, *, all_names: Dict[str, Column[Any]], allow_replacements: bool, **kw: Any, ) -> None: table = parent assert isinstance(table, Table) if not self.name: raise exc.ArgumentError( "Column must be constructed with a non-blank name or " "assign a non-blank .name before adding to a Table." ) self._reset_memoizations() if self.key is None: self.key = self.name existing = getattr(self, "table", None) if existing is not None and existing is not table: raise exc.ArgumentError( "Column object '%s' already assigned to Table '%s'" % (self.key, existing.description) ) extra_remove = None existing_col = None conflicts_on = "" if self.key in table._columns: existing_col = table._columns[self.key] if self.key == self.name: conflicts_on = "name" else: conflicts_on = "key" elif self.name in all_names: existing_col = all_names[self.name] extra_remove = {existing_col} conflicts_on = "name" if existing_col is not None: if existing_col is not self: if not allow_replacements: raise exc.DuplicateColumnError( f"A column with {conflicts_on} " f"""'{ self.key if conflicts_on == 'key' else self.name }' """ f"is already present in table '{table.name}'." ) for fk in existing_col.foreign_keys: table.foreign_keys.remove(fk) if fk.constraint in table.constraints: # this might have been removed # already, if it's a composite constraint # and more than one col being replaced table.constraints.remove(fk.constraint) if extra_remove and existing_col is not None and self.key == self.name: util.warn( f'Column with user-specified key "{existing_col.key}" is ' "being replaced with " f'plain named column "{self.name}", ' f'key "{existing_col.key}" is being removed. If this is a ' "reflection operation, specify autoload_replace=False to " "prevent this replacement." ) table._columns.replace(self, extra_remove=extra_remove) all_names[self.name] = self self.table = table if self.primary_key: table.primary_key._replace(self) elif self.key in table.primary_key: raise exc.ArgumentError( "Trying to redefine primary-key column '%s' as a " "non-primary-key column on table '%s'" % (self.key, table.fullname) ) if self.index: if isinstance(self.index, str): raise exc.ArgumentError( "The 'index' keyword argument on Column is boolean only. " "To create indexes with a specific name, create an " "explicit Index object external to the Table." ) table.append_constraint( Index( None, self.key, unique=bool(self.unique), _column_flag=True ) ) elif self.unique: if isinstance(self.unique, str): raise exc.ArgumentError( "The 'unique' keyword argument on Column is boolean " "only. To create unique constraints or indexes with a " "specific name, append an explicit UniqueConstraint to " "the Table's list of elements, or create an explicit " "Index object external to the Table." ) table.append_constraint( UniqueConstraint(self.key, _column_flag=True) ) self._setup_on_memoized_fks(lambda fk: fk._set_remote_table(table)) if self.identity and ( isinstance(self.default, Sequence) or isinstance(self.onupdate, Sequence) ): raise exc.ArgumentError( "An column cannot specify both Identity and Sequence." ) def _setup_on_memoized_fks(self, fn: Callable[..., Any]) -> None: fk_keys = [ ((self.table.key, self.key), False), ((self.table.key, self.name), True), ] for fk_key, link_to_name in fk_keys: if fk_key in self.table.metadata._fk_memos: for fk in self.table.metadata._fk_memos[fk_key]: if fk.link_to_name is link_to_name: fn(fk) def _on_table_attach(self, fn: Callable[..., Any]) -> None: if self.table is not None: fn(self, self.table) else: event.listen(self, "after_parent_attach", fn) @util.deprecated( "1.4", "The :meth:`_schema.Column.copy` method is deprecated " "and will be removed in a future release.", ) def copy(self, **kw: Any) -> Column[Any]: return self._copy(**kw) def _copy(self, **kw: Any) -> Column[Any]: """Create a copy of this ``Column``, uninitialized. This is used in :meth:`_schema.Table.to_metadata` and by the ORM. """ # Constraint objects plus non-constraint-bound ForeignKey objects args: List[SchemaItem] = [ c._copy(**kw) for c in self.constraints if not c._type_bound # type: ignore ] + [ c._copy(**kw) # type: ignore for c in self.foreign_keys if not c.constraint ] # ticket #5276 column_kwargs = {} for dialect_name in self.dialect_options: dialect_options = self.dialect_options[dialect_name]._non_defaults for ( dialect_option_key, dialect_option_value, ) in dialect_options.items(): column_kwargs[ dialect_name + "_" + dialect_option_key ] = dialect_option_value server_default = self.server_default server_onupdate = self.server_onupdate if isinstance(server_default, (Computed, Identity)): # TODO: likely should be copied in all cases args.append(server_default._copy(**kw)) server_default = server_onupdate = None type_ = self.type if isinstance(type_, SchemaEventTarget): type_ = type_.copy(**kw) # TODO: DefaultGenerator is not copied here! it's just used again # with _set_parent() pointing to the old column. see the new # use of _copy() in the new _merge() method c = self._constructor( name=self.name, type_=type_, key=self.key, primary_key=self.primary_key, unique=self.unique, system=self.system, # quote=self.quote, # disabled 2013-08-27 (commit 031ef080) index=self.index, autoincrement=self.autoincrement, default=self.default, server_default=server_default, onupdate=self.onupdate, server_onupdate=server_onupdate, doc=self.doc, comment=self.comment, *args, **column_kwargs, ) # copy the state of "nullable" exactly, to accommodate for # ORM flipping the .nullable flag directly c.nullable = self.nullable c._user_defined_nullable = self._user_defined_nullable return self._schema_item_copy(c) def _merge(self, other: Column[Any]) -> None: """merge the elements of another column into this one. this is used by ORM pep-593 merge and will likely need a lot of fixes. """ if self.primary_key: other.primary_key = True type_ = self.type if not type_._isnull and other.type._isnull: if isinstance(type_, SchemaEventTarget): type_ = type_.copy() other.type = type_ if isinstance(type_, SchemaEventTarget): type_._set_parent_with_dispatch(other) for impl in type_._variant_mapping.values(): if isinstance(impl, SchemaEventTarget): impl._set_parent_with_dispatch(other) if ( self._user_defined_nullable is not NULL_UNSPECIFIED and other._user_defined_nullable is NULL_UNSPECIFIED ): other.nullable = self.nullable other._user_defined_nullable = self._user_defined_nullable if self.default is not None and other.default is None: new_default = self.default._copy() new_default._set_parent(other) if self.server_default and other.server_default is None: new_server_default = self.server_default if isinstance(new_server_default, FetchedValue): new_server_default = new_server_default._copy() new_server_default._set_parent(other) else: other.server_default = new_server_default if self.server_onupdate and other.server_onupdate is None: new_server_onupdate = self.server_onupdate new_server_onupdate = new_server_onupdate._copy() new_server_onupdate._set_parent(other) if self.onupdate and other.onupdate is None: new_onupdate = self.onupdate._copy() new_onupdate._set_parent(other) if self.index and not other.index: other.index = True if self.unique and not other.unique: other.unique = True for const in self.constraints: if not const._type_bound: new_const = const._copy() new_const._set_parent(other) for fk in self.foreign_keys: if not fk.constraint: new_fk = fk._copy() new_fk._set_parent(other) def _make_proxy( self, selectable: FromClause, name: Optional[str] = None, key: Optional[str] = None, name_is_truncatable: bool = False, compound_select_cols: Optional[ _typing_Sequence[ColumnElement[Any]] ] = None, **kw: Any, ) -> Tuple[str, ColumnClause[_T]]: """Create a *proxy* for this column. This is a copy of this ``Column`` referenced by a different parent (such as an alias or select statement). The column should be used only in select scenarios, as its full DDL/default information is not transferred. """ fk = [ ForeignKey( col if col is not None else f._colspec, _unresolvable=col is None, _constraint=f.constraint, ) for f, col in [ (fk, fk._resolve_column(raiseerr=False)) for fk in self.foreign_keys ] ] if name is None and self.name is None: raise exc.InvalidRequestError( "Cannot initialize a sub-selectable" " with this Column object until its 'name' has " "been assigned." ) try: c = self._constructor( coercions.expect( roles.TruncatedLabelRole, name if name else self.name ) if name_is_truncatable else (name or self.name), self.type, # this may actually be ._proxy_key when the key is incoming key=key if key else name if name else self.key, primary_key=self.primary_key, nullable=self.nullable, _proxies=list(compound_select_cols) if compound_select_cols else [self], *fk, ) except TypeError as err: raise TypeError( "Could not create a copy of this %r object. " "Ensure the class includes a _constructor() " "attribute or method which accepts the " "standard Column constructor arguments, or " "references the Column class itself." % self.__class__ ) from err c.table = selectable c._propagate_attrs = selectable._propagate_attrs if selectable._is_clone_of is not None: c._is_clone_of = selectable._is_clone_of.columns.get(c.key) if self.primary_key: selectable.primary_key.add(c) # type: ignore if fk: selectable.foreign_keys.update(fk) # type: ignore return c.key, c class ForeignKey(DialectKWArgs, SchemaItem): """Defines a dependency between two columns. ``ForeignKey`` is specified as an argument to a :class:`_schema.Column` object, e.g.:: t = Table("remote_table", metadata, Column("remote_id", ForeignKey("main_table.id")) ) Note that ``ForeignKey`` is only a marker object that defines a dependency between two columns. The actual constraint is in all cases represented by the :class:`_schema.ForeignKeyConstraint` object. This object will be generated automatically when a ``ForeignKey`` is associated with a :class:`_schema.Column` which in turn is associated with a :class:`_schema.Table`. Conversely, when :class:`_schema.ForeignKeyConstraint` is applied to a :class:`_schema.Table`, ``ForeignKey`` markers are automatically generated to be present on each associated :class:`_schema.Column`, which are also associated with the constraint object. Note that you cannot define a "composite" foreign key constraint, that is a constraint between a grouping of multiple parent/child columns, using ``ForeignKey`` objects. To define this grouping, the :class:`_schema.ForeignKeyConstraint` object must be used, and applied to the :class:`_schema.Table`. The associated ``ForeignKey`` objects are created automatically. The ``ForeignKey`` objects associated with an individual :class:`_schema.Column` object are available in the `foreign_keys` collection of that column. Further examples of foreign key configuration are in :ref:`metadata_foreignkeys`. """ __visit_name__ = "foreign_key" parent: Column[Any] _table_column: Optional[Column[Any]] def __init__( self, column: _DDLColumnArgument, _constraint: Optional[ForeignKeyConstraint] = None, use_alter: bool = False, name: _ConstraintNameArgument = None, onupdate: Optional[str] = None, ondelete: Optional[str] = None, deferrable: Optional[bool] = None, initially: Optional[str] = None, link_to_name: bool = False, match: Optional[str] = None, info: Optional[_InfoType] = None, comment: Optional[str] = None, _unresolvable: bool = False, **dialect_kw: Any, ): r""" Construct a column-level FOREIGN KEY. The :class:`_schema.ForeignKey` object when constructed generates a :class:`_schema.ForeignKeyConstraint` which is associated with the parent :class:`_schema.Table` object's collection of constraints. :param column: A single target column for the key relationship. A :class:`_schema.Column` object or a column name as a string: ``tablename.columnkey`` or ``schema.tablename.columnkey``. ``columnkey`` is the ``key`` which has been assigned to the column (defaults to the column name itself), unless ``link_to_name`` is ``True`` in which case the rendered name of the column is used. :param name: Optional string. An in-database name for the key if `constraint` is not provided. :param onupdate: Optional string. If set, emit ON UPDATE when issuing DDL for this constraint. Typical values include CASCADE, DELETE and RESTRICT. :param ondelete: Optional string. If set, emit ON DELETE 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 initially: Optional string. If set, emit INITIALLY when issuing DDL for this constraint. :param link_to_name: if True, the string name given in ``column`` is the rendered name of the referenced column, not its locally assigned ``key``. :param use_alter: passed to the underlying :class:`_schema.ForeignKeyConstraint` to indicate the constraint should be generated/dropped externally from the CREATE TABLE/ DROP TABLE statement. See :paramref:`_schema.ForeignKeyConstraint.use_alter` for further description. .. seealso:: :paramref:`_schema.ForeignKeyConstraint.use_alter` :ref:`use_alter` :param match: Optional string. If set, emit MATCH when issuing DDL for this constraint. Typical values include SIMPLE, PARTIAL and FULL. :param info: Optional data dictionary which will be populated into the :attr:`.SchemaItem.info` attribute of this object. .. versionadded:: 1.0.0 :param comment: Optional string that will render an SQL comment on foreign key constraint creation. .. versionadded:: 2.0 :param \**dialect_kw: Additional keyword arguments are dialect specific, and passed in the form ``_``. The arguments are ultimately handled by a corresponding :class:`_schema.ForeignKeyConstraint`. See the documentation regarding an individual dialect at :ref:`dialect_toplevel` for detail on documented arguments. .. versionadded:: 0.9.2 """ self._colspec = coercions.expect(roles.DDLReferredColumnRole, column) self._unresolvable = _unresolvable if isinstance(self._colspec, str): self._table_column = None else: self._table_column = self._colspec if not isinstance( self._table_column.table, (type(None), TableClause) ): raise exc.ArgumentError( "ForeignKey received Column not bound " "to a Table, got: %r" % self._table_column.table ) # the linked ForeignKeyConstraint. # ForeignKey will create this when parent Column # is attached to a Table, *or* ForeignKeyConstraint # object passes itself in when creating ForeignKey # markers. self.constraint = _constraint # .parent is not Optional under normal use self.parent = None # type: ignore self.use_alter = use_alter self.name = name self.onupdate = onupdate self.ondelete = ondelete self.deferrable = deferrable self.initially = initially self.link_to_name = link_to_name self.match = match self.comment = comment if info: self.info = info self._unvalidated_dialect_kw = dialect_kw def __repr__(self) -> str: return "ForeignKey(%r)" % self._get_colspec() @util.deprecated( "1.4", "The :meth:`_schema.ForeignKey.copy` method is deprecated " "and will be removed in a future release.", ) def copy(self, *, schema: Optional[str] = None, **kw: Any) -> ForeignKey: return self._copy(schema=schema, **kw) def _copy(self, *, schema: Optional[str] = None, **kw: Any) -> ForeignKey: """Produce a copy of this :class:`_schema.ForeignKey` object. The new :class:`_schema.ForeignKey` will not be bound to any :class:`_schema.Column`. This method is usually used by the internal copy procedures of :class:`_schema.Column`, :class:`_schema.Table`, and :class:`_schema.MetaData`. :param schema: The returned :class:`_schema.ForeignKey` will reference the original table and column name, qualified by the given string schema name. """ fk = ForeignKey( self._get_colspec(schema=schema), use_alter=self.use_alter, name=self.name, onupdate=self.onupdate, ondelete=self.ondelete, deferrable=self.deferrable, initially=self.initially, link_to_name=self.link_to_name, match=self.match, comment=self.comment, **self._unvalidated_dialect_kw, ) return self._schema_item_copy(fk) def _get_colspec( self, schema: Optional[ Union[ str, Literal[SchemaConst.RETAIN_SCHEMA, SchemaConst.BLANK_SCHEMA], ] ] = None, table_name: Optional[str] = None, _is_copy: bool = False, ) -> str: """Return a string based 'column specification' for this :class:`_schema.ForeignKey`. This is usually the equivalent of the string-based "tablename.colname" argument first passed to the object's constructor. """ if schema not in (None, RETAIN_SCHEMA): _schema, tname, colname = self._column_tokens if table_name is not None: tname = table_name if schema is BLANK_SCHEMA: return "%s.%s" % (tname, colname) else: return "%s.%s.%s" % (schema, tname, colname) elif table_name: schema, tname, colname = self._column_tokens if schema: return "%s.%s.%s" % (schema, table_name, colname) else: return "%s.%s" % (table_name, colname) elif self._table_column is not None: if self._table_column.table is None: if _is_copy: raise exc.InvalidRequestError( f"Can't copy ForeignKey object which refers to " f"non-table bound Column {self._table_column!r}" ) else: return self._table_column.key return "%s.%s" % ( self._table_column.table.fullname, self._table_column.key, ) else: assert isinstance(self._colspec, str) return self._colspec @property def _referred_schema(self) -> Optional[str]: return self._column_tokens[0] def _table_key(self) -> Any: if self._table_column is not None: if self._table_column.table is None: return None else: return self._table_column.table.key else: schema, tname, colname = self._column_tokens return _get_table_key(tname, schema) target_fullname = property(_get_colspec) def references(self, table: Table) -> bool: """Return True if the given :class:`_schema.Table` is referenced by this :class:`_schema.ForeignKey`.""" return table.corresponding_column(self.column) is not None def get_referent(self, table: FromClause) -> Optional[Column[Any]]: """Return the :class:`_schema.Column` in the given :class:`_schema.Table` (or any :class:`.FromClause`) referenced by this :class:`_schema.ForeignKey`. Returns None if this :class:`_schema.ForeignKey` does not reference the given :class:`_schema.Table`. """ # our column is a Column, and any subquery etc. proxying us # would be doing so via another Column, so that's what would # be returned here return table.columns.corresponding_column(self.column) # type: ignore @util.memoized_property def _column_tokens(self) -> Tuple[Optional[str], str, Optional[str]]: """parse a string-based _colspec into its component parts.""" m = self._get_colspec().split(".") if m is None: raise exc.ArgumentError( "Invalid foreign key column specification: %s" % self._colspec ) if len(m) == 1: tname = m.pop() colname = None else: colname = m.pop() tname = m.pop() # A FK between column 'bar' and table 'foo' can be # specified as 'foo', 'foo.bar', 'dbo.foo.bar', # 'otherdb.dbo.foo.bar'. Once we have the column name and # the table name, treat everything else as the schema # name. Some databases (e.g. Sybase) support # inter-database foreign keys. See tickets#1341 and -- # indirectly related -- Ticket #594. This assumes that '.' # will never appear *within* any component of the FK. if len(m) > 0: schema = ".".join(m) else: schema = None return schema, tname, colname def _resolve_col_tokens(self) -> Tuple[Table, str, Optional[str]]: if self.parent is None: raise exc.InvalidRequestError( "this ForeignKey object does not yet have a " "parent Column associated with it." ) elif self.parent.table is None: raise exc.InvalidRequestError( "this ForeignKey's parent column is not yet associated " "with a Table." ) parenttable = self.parent.table if self._unresolvable: schema, tname, colname = self._column_tokens tablekey = _get_table_key(tname, schema) return parenttable, tablekey, colname # assertion # basically Column._make_proxy() sends the actual # target Column to the ForeignKey object, so the # string resolution here is never called. for c in self.parent.base_columns: if isinstance(c, Column): assert c.table is parenttable break else: assert False ###################### schema, tname, colname = self._column_tokens if schema is None and parenttable.metadata.schema is not None: schema = parenttable.metadata.schema tablekey = _get_table_key(tname, schema) return parenttable, tablekey, colname def _link_to_col_by_colstring( self, parenttable: Table, table: Table, colname: Optional[str] ) -> Column[Any]: _column = None if colname is None: # colname is None in the case that ForeignKey argument # was specified as table name only, in which case we # match the column name to the same column on the # parent. # this use case wasn't working in later 1.x series # as it had no test coverage; fixed in 2.0 parent = self.parent assert parent is not None key = parent.key _column = table.c.get(key, None) elif self.link_to_name: key = colname for c in table.c: if c.name == colname: _column = c else: key = colname _column = table.c.get(colname, None) if _column is None: raise exc.NoReferencedColumnError( "Could not initialize target column " "for ForeignKey '%s' on table '%s': " "table '%s' has no column named '%s'" % (self._colspec, parenttable.name, table.name, key), table.name, key, ) return _column def _set_target_column(self, column: Column[Any]) -> None: assert self.parent is not None # propagate TypeEngine to parent if it didn't have one if self.parent.type._isnull: self.parent.type = column.type # super-edgy case, if other FKs point to our column, # they'd get the type propagated out also. def set_type(fk: ForeignKey) -> None: if fk.parent.type._isnull: fk.parent.type = column.type self.parent._setup_on_memoized_fks(set_type) self.column = column # type: ignore @util.ro_memoized_property def column(self) -> Column[Any]: """Return the target :class:`_schema.Column` referenced by this :class:`_schema.ForeignKey`. If no target column has been established, an exception is raised. """ return self._resolve_column() @overload def _resolve_column(self, *, raiseerr: Literal[True] = ...) -> Column[Any]: ... @overload def _resolve_column( self, *, raiseerr: bool = ... ) -> Optional[Column[Any]]: ... def _resolve_column( self, *, raiseerr: bool = True ) -> Optional[Column[Any]]: _column: Column[Any] if isinstance(self._colspec, str): parenttable, tablekey, colname = self._resolve_col_tokens() if self._unresolvable or tablekey not in parenttable.metadata: if not raiseerr: return None raise exc.NoReferencedTableError( "Foreign key associated with column '%s' could not find " "table '%s' with which to generate a " "foreign key to target column '%s'" % (self.parent, tablekey, colname), tablekey, ) elif parenttable.key not in parenttable.metadata: if not raiseerr: return None raise exc.InvalidRequestError( "Table %s is no longer associated with its " "parent MetaData" % parenttable ) else: table = parenttable.metadata.tables[tablekey] return self._link_to_col_by_colstring( parenttable, table, colname ) elif hasattr(self._colspec, "__clause_element__"): _column = self._colspec.__clause_element__() return _column else: _column = self._colspec return _column def _set_parent(self, parent: SchemaEventTarget, **kw: Any) -> None: assert isinstance(parent, Column) if self.parent is not None and self.parent is not parent: raise exc.InvalidRequestError( "This ForeignKey already has a parent !" ) self.parent = parent self.parent.foreign_keys.add(self) self.parent._on_table_attach(self._set_table) def _set_remote_table(self, table: Table) -> None: parenttable, _, colname = self._resolve_col_tokens() _column = self._link_to_col_by_colstring(parenttable, table, colname) self._set_target_column(_column) assert self.constraint is not None self.constraint._validate_dest_table(table) def _remove_from_metadata(self, metadata: MetaData) -> None: parenttable, table_key, colname = self._resolve_col_tokens() fk_key = (table_key, colname) if self in metadata._fk_memos[fk_key]: # TODO: no test coverage for self not in memos metadata._fk_memos[fk_key].remove(self) def _set_table(self, column: Column[Any], table: Table) -> None: # standalone ForeignKey - create ForeignKeyConstraint # on the hosting Table when attached to the Table. assert isinstance(table, Table) if self.constraint is None: self.constraint = ForeignKeyConstraint( [], [], use_alter=self.use_alter, name=self.name, onupdate=self.onupdate, ondelete=self.ondelete, deferrable=self.deferrable, initially=self.initially, match=self.match, comment=self.comment, **self._unvalidated_dialect_kw, ) self.constraint._append_element(column, self) self.constraint._set_parent_with_dispatch(table) table.foreign_keys.add(self) # set up remote ".column" attribute, or a note to pick it # up when the other Table/Column shows up if isinstance(self._colspec, str): parenttable, table_key, colname = self._resolve_col_tokens() fk_key = (table_key, colname) if table_key in parenttable.metadata.tables: table = parenttable.metadata.tables[table_key] try: _column = self._link_to_col_by_colstring( parenttable, table, colname ) except exc.NoReferencedColumnError: # this is OK, we'll try later pass else: self._set_target_column(_column) parenttable.metadata._fk_memos[fk_key].append(self) elif hasattr(self._colspec, "__clause_element__"): _column = self._colspec.__clause_element__() self._set_target_column(_column) else: _column = self._colspec self._set_target_column(_column) if TYPE_CHECKING: def default_is_sequence( obj: Optional[DefaultGenerator], ) -> TypeGuard[Sequence]: ... def default_is_clause_element( obj: Optional[DefaultGenerator], ) -> TypeGuard[ColumnElementColumnDefault]: ... def default_is_scalar( obj: Optional[DefaultGenerator], ) -> TypeGuard[ScalarElementColumnDefault]: ... else: default_is_sequence = operator.attrgetter("is_sequence") default_is_clause_element = operator.attrgetter("is_clause_element") default_is_scalar = operator.attrgetter("is_scalar") class DefaultGenerator(Executable, SchemaItem): """Base class for column *default* values.""" __visit_name__ = "default_generator" _is_default_generator = True is_sequence = False is_server_default = False is_clause_element = False is_callable = False is_scalar = False column: Optional[Column[Any]] def __init__(self, for_update: bool = False) -> None: self.for_update = for_update def _set_parent(self, parent: SchemaEventTarget, **kw: Any) -> None: if TYPE_CHECKING: assert isinstance(parent, Column) self.column = parent if self.for_update: self.column.onupdate = self else: self.column.default = self def _copy(self) -> DefaultGenerator: raise NotImplementedError() def _execute_on_connection( self, connection: Connection, distilled_params: _CoreMultiExecuteParams, execution_options: CoreExecuteOptionsParameter, ) -> Any: util.warn_deprecated( "Using the .execute() method to invoke a " "DefaultGenerator object is deprecated; please use " "the .scalar() method.", "2.0", ) return self._execute_on_scalar( connection, distilled_params, execution_options ) def _execute_on_scalar( self, connection: Connection, distilled_params: _CoreMultiExecuteParams, execution_options: CoreExecuteOptionsParameter, ) -> Any: return connection._execute_default( self, distilled_params, execution_options ) class ColumnDefault(DefaultGenerator, ABC): """A plain default value on a column. This could correspond to a constant, a callable function, or a SQL clause. :class:`.ColumnDefault` is generated automatically whenever the ``default``, ``onupdate`` arguments of :class:`_schema.Column` are used. A :class:`.ColumnDefault` can be passed positionally as well. For example, the following:: Column('foo', Integer, default=50) Is equivalent to:: Column('foo', Integer, ColumnDefault(50)) """ arg: Any @overload def __new__( cls, arg: Callable[..., Any], for_update: bool = ... ) -> CallableColumnDefault: ... @overload def __new__( cls, arg: ColumnElement[Any], for_update: bool = ... ) -> ColumnElementColumnDefault: ... # if I return ScalarElementColumnDefault here, which is what's actually # returned, mypy complains that # overloads overlap w/ incompatible return types. @overload def __new__(cls, arg: object, for_update: bool = ...) -> ColumnDefault: ... def __new__( cls, arg: Any = None, for_update: bool = False ) -> ColumnDefault: """Construct a new :class:`.ColumnDefault`. :param arg: argument representing the default value. May be one of the following: * a plain non-callable Python value, such as a string, integer, boolean, or other simple type. The default value will be used as is each time. * a SQL expression, that is one which derives from :class:`_expression.ColumnElement`. The SQL expression will be rendered into the INSERT or UPDATE statement, or in the case of a primary key column when RETURNING is not used may be pre-executed before an INSERT within a SELECT. * A Python callable. The function will be invoked for each new row subject to an INSERT or UPDATE. The callable must accept exactly zero or one positional arguments. The one-argument form will receive an instance of the :class:`.ExecutionContext`, which provides contextual information as to the current :class:`_engine.Connection` in use as well as the current statement and parameters. """ if isinstance(arg, FetchedValue): raise exc.ArgumentError( "ColumnDefault may not be a server-side default type." ) elif callable(arg): cls = CallableColumnDefault elif isinstance(arg, ClauseElement): cls = ColumnElementColumnDefault elif arg is not None: cls = ScalarElementColumnDefault return object.__new__(cls) def __repr__(self) -> str: return f"{self.__class__.__name__}({self.arg!r})" class ScalarElementColumnDefault(ColumnDefault): """default generator for a fixed scalar Python value .. versionadded: 2.0 """ is_scalar = True def __init__(self, arg: Any, for_update: bool = False) -> None: self.for_update = for_update self.arg = arg def _copy(self) -> ScalarElementColumnDefault: return ScalarElementColumnDefault( arg=self.arg, for_update=self.for_update ) _SQLExprDefault = Union["ColumnElement[Any]", "TextClause"] class ColumnElementColumnDefault(ColumnDefault): """default generator for a SQL expression .. versionadded:: 2.0 """ is_clause_element = True arg: _SQLExprDefault def __init__( self, arg: _SQLExprDefault, for_update: bool = False, ) -> None: self.for_update = for_update self.arg = arg def _copy(self) -> ColumnElementColumnDefault: return ColumnElementColumnDefault( arg=self.arg, for_update=self.for_update ) @util.memoized_property @util.preload_module("sqlalchemy.sql.sqltypes") def _arg_is_typed(self) -> bool: sqltypes = util.preloaded.sql_sqltypes return not isinstance(self.arg.type, sqltypes.NullType) class _CallableColumnDefaultProtocol(Protocol): def __call__(self, context: ExecutionContext) -> Any: ... class CallableColumnDefault(ColumnDefault): """default generator for a callable Python function .. versionadded:: 2.0 """ is_callable = True arg: _CallableColumnDefaultProtocol def __init__( self, arg: Union[_CallableColumnDefaultProtocol, Callable[[], Any]], for_update: bool = False, ) -> None: self.for_update = for_update self.arg = self._maybe_wrap_callable(arg) def _copy(self) -> CallableColumnDefault: return CallableColumnDefault(arg=self.arg, for_update=self.for_update) def _maybe_wrap_callable( self, fn: Union[_CallableColumnDefaultProtocol, Callable[[], Any]] ) -> _CallableColumnDefaultProtocol: """Wrap callables that don't accept a context. This is to allow easy compatibility with default callables that aren't specific to accepting of a context. """ try: argspec = util.get_callable_argspec(fn, no_self=True) except TypeError: return util.wrap_callable(lambda ctx: fn(), fn) # type: ignore defaulted = argspec[3] is not None and len(argspec[3]) or 0 positionals = len(argspec[0]) - defaulted if positionals == 0: return util.wrap_callable(lambda ctx: fn(), fn) # type: ignore elif positionals == 1: return fn # type: ignore else: raise exc.ArgumentError( "ColumnDefault Python function takes zero or one " "positional arguments" ) class IdentityOptions: """Defines options for a named database sequence or an identity column. .. versionadded:: 1.3.18 .. seealso:: :class:`.Sequence` """ def __init__( self, start: Optional[int] = None, increment: Optional[int] = None, minvalue: Optional[int] = None, maxvalue: Optional[int] = None, nominvalue: Optional[bool] = None, nomaxvalue: Optional[bool] = None, cycle: Optional[bool] = None, cache: Optional[int] = None, order: Optional[bool] = None, ) -> None: """Construct a :class:`.IdentityOptions` object. See the :class:`.Sequence` documentation for a complete description of the parameters. :param start: the starting index of the sequence. :param increment: the increment value of the sequence. :param minvalue: the minimum value of the sequence. :param maxvalue: the maximum value of the sequence. :param nominvalue: no minimum value of the sequence. :param nomaxvalue: no maximum value of the sequence. :param cycle: allows the sequence to wrap around when the maxvalue or minvalue has been reached. :param cache: optional integer value; number of future values in the sequence which are calculated in advance. :param order: optional boolean value; if ``True``, renders the ORDER keyword. """ self.start = start self.increment = increment self.minvalue = minvalue self.maxvalue = maxvalue self.nominvalue = nominvalue self.nomaxvalue = nomaxvalue self.cycle = cycle self.cache = cache self.order = order class Sequence(HasSchemaAttr, IdentityOptions, DefaultGenerator): """Represents a named database sequence. The :class:`.Sequence` object represents the name and configurational parameters of a database sequence. It also represents a construct that can be "executed" by a SQLAlchemy :class:`_engine.Engine` or :class:`_engine.Connection`, rendering the appropriate "next value" function for the target database and returning a result. The :class:`.Sequence` is typically associated with a primary key column:: some_table = Table( 'some_table', metadata, Column('id', Integer, Sequence('some_table_seq', start=1), primary_key=True) ) When CREATE TABLE is emitted for the above :class:`_schema.Table`, if the target platform supports sequences, a CREATE SEQUENCE statement will be emitted as well. For platforms that don't support sequences, the :class:`.Sequence` construct is ignored. .. seealso:: :ref:`defaults_sequences` :class:`.CreateSequence` :class:`.DropSequence` """ __visit_name__ = "sequence" is_sequence = True column: Optional[Column[Any]] data_type: Optional[TypeEngine[int]] def __init__( self, name: str, start: Optional[int] = None, increment: Optional[int] = None, minvalue: Optional[int] = None, maxvalue: Optional[int] = None, nominvalue: Optional[bool] = None, nomaxvalue: Optional[bool] = None, cycle: Optional[bool] = None, schema: Optional[Union[str, Literal[SchemaConst.BLANK_SCHEMA]]] = None, cache: Optional[int] = None, order: Optional[bool] = None, data_type: Optional[_TypeEngineArgument[int]] = None, optional: bool = False, quote: Optional[bool] = None, metadata: Optional[MetaData] = None, quote_schema: Optional[bool] = None, for_update: bool = False, ) -> None: """Construct a :class:`.Sequence` object. :param name: the name of the sequence. :param start: the starting index of the sequence. This value is used when the CREATE SEQUENCE command is emitted to the database as the value of the "START WITH" clause. If ``None``, the clause is omitted, which on most platforms indicates a starting value of 1. .. versionchanged:: 2.0 The :paramref:`.Sequence.start` parameter is required in order to have DDL emit "START WITH". This is a reversal of a change made in version 1.4 which would implicitly render "START WITH 1" if the :paramref:`.Sequence.start` were not included. See :ref:`change_7211` for more detail. :param increment: the increment value of the sequence. This value is used when the CREATE SEQUENCE command is emitted to the database as the value of the "INCREMENT BY" clause. If ``None``, the clause is omitted, which on most platforms indicates an increment of 1. :param minvalue: the minimum value of the sequence. This value is used when the CREATE SEQUENCE command is emitted to the database as the value of the "MINVALUE" clause. If ``None``, the clause is omitted, which on most platforms indicates a minvalue of 1 and -2^63-1 for ascending and descending sequences, respectively. .. versionadded:: 1.0.7 :param maxvalue: the maximum value of the sequence. This value is used when the CREATE SEQUENCE command is emitted to the database as the value of the "MAXVALUE" clause. If ``None``, the clause is omitted, which on most platforms indicates a maxvalue of 2^63-1 and -1 for ascending and descending sequences, respectively. .. versionadded:: 1.0.7 :param nominvalue: no minimum value of the sequence. This value is used when the CREATE SEQUENCE command is emitted to the database as the value of the "NO MINVALUE" clause. If ``None``, the clause is omitted, which on most platforms indicates a minvalue of 1 and -2^63-1 for ascending and descending sequences, respectively. .. versionadded:: 1.0.7 :param nomaxvalue: no maximum value of the sequence. This value is used when the CREATE SEQUENCE command is emitted to the database as the value of the "NO MAXVALUE" clause. If ``None``, the clause is omitted, which on most platforms indicates a maxvalue of 2^63-1 and -1 for ascending and descending sequences, respectively. .. versionadded:: 1.0.7 :param cycle: allows the sequence to wrap around when the maxvalue or minvalue has been reached by an ascending or descending sequence respectively. This value is used when the CREATE SEQUENCE command is emitted to the database as the "CYCLE" clause. If the limit is reached, the next number generated will be the minvalue or maxvalue, respectively. If cycle=False (the default) any calls to nextval after the sequence has reached its maximum value will return an error. .. versionadded:: 1.0.7 :param schema: optional schema name for the sequence, if located in a schema other than the default. The rules for selecting the schema name when a :class:`_schema.MetaData` is also present are the same as that of :paramref:`_schema.Table.schema`. :param cache: optional integer value; number of future values in the sequence which are calculated in advance. Renders the CACHE keyword understood by Oracle and PostgreSQL. .. versionadded:: 1.1.12 :param order: optional boolean value; if ``True``, renders the ORDER keyword, understood by Oracle, indicating the sequence is definitively ordered. May be necessary to provide deterministic ordering using Oracle RAC. .. versionadded:: 1.1.12 :param data_type: The type to be returned by the sequence, for dialects that allow us to choose between INTEGER, BIGINT, etc. (e.g., mssql). .. versionadded:: 1.4.0 :param optional: boolean value, when ``True``, indicates that this :class:`.Sequence` object only needs to be explicitly generated on backends that don't provide another way to generate primary key identifiers. Currently, it essentially means, "don't create this sequence on the PostgreSQL backend, where the SERIAL keyword creates a sequence for us automatically". :param quote: boolean value, when ``True`` or ``False``, explicitly forces quoting of the :paramref:`_schema.Sequence.name` on or off. When left at its default of ``None``, normal quoting rules based on casing and reserved words take place. :param quote_schema: Set the quoting preferences for the ``schema`` name. :param metadata: optional :class:`_schema.MetaData` object which this :class:`.Sequence` will be associated with. A :class:`.Sequence` that is associated with a :class:`_schema.MetaData` gains the following capabilities: * The :class:`.Sequence` will inherit the :paramref:`_schema.MetaData.schema` parameter specified to the target :class:`_schema.MetaData`, which affects the production of CREATE / DROP DDL, if any. * The :meth:`.Sequence.create` and :meth:`.Sequence.drop` methods automatically use the engine bound to the :class:`_schema.MetaData` object, if any. * The :meth:`_schema.MetaData.create_all` and :meth:`_schema.MetaData.drop_all` methods will emit CREATE / DROP for this :class:`.Sequence`, even if the :class:`.Sequence` is not associated with any :class:`_schema.Table` / :class:`_schema.Column` that's a member of this :class:`_schema.MetaData`. The above behaviors can only occur if the :class:`.Sequence` is explicitly associated with the :class:`_schema.MetaData` via this parameter. .. seealso:: :ref:`sequence_metadata` - full discussion of the :paramref:`.Sequence.metadata` parameter. :param for_update: Indicates this :class:`.Sequence`, when associated with a :class:`_schema.Column`, should be invoked for UPDATE statements on that column's table, rather than for INSERT statements, when no value is otherwise present for that column in the statement. """ DefaultGenerator.__init__(self, for_update=for_update) IdentityOptions.__init__( self, start=start, increment=increment, minvalue=minvalue, maxvalue=maxvalue, nominvalue=nominvalue, nomaxvalue=nomaxvalue, cycle=cycle, cache=cache, order=order, ) self.column = None self.name = quoted_name(name, quote) self.optional = optional if schema is BLANK_SCHEMA: self.schema = schema = None elif metadata is not None and schema is None and metadata.schema: self.schema = schema = metadata.schema else: self.schema = quoted_name.construct(schema, quote_schema) self.metadata = metadata self._key = _get_table_key(name, schema) if metadata: self._set_metadata(metadata) if data_type is not None: self.data_type = to_instance(data_type) else: self.data_type = None @util.preload_module("sqlalchemy.sql.functions") def next_value(self) -> Function[int]: """Return a :class:`.next_value` function element which will render the appropriate increment function for this :class:`.Sequence` within any SQL expression. """ return util.preloaded.sql_functions.func.next_value(self) def _set_parent(self, parent: SchemaEventTarget, **kw: Any) -> None: column = parent assert isinstance(column, Column) super()._set_parent(column) column._on_table_attach(self._set_table) def _copy(self) -> Sequence: return Sequence( name=self.name, start=self.start, increment=self.increment, minvalue=self.minvalue, maxvalue=self.maxvalue, nominvalue=self.nominvalue, nomaxvalue=self.nomaxvalue, cycle=self.cycle, schema=self.schema, cache=self.cache, order=self.order, data_type=self.data_type, optional=self.optional, metadata=self.metadata, for_update=self.for_update, ) def _set_table(self, column: Column[Any], table: Table) -> None: self._set_metadata(table.metadata) def _set_metadata(self, metadata: MetaData) -> None: self.metadata = metadata self.metadata._sequences[self._key] = self def create(self, bind: _CreateDropBind, checkfirst: bool = True) -> None: """Creates this sequence in the database.""" bind._run_ddl_visitor(ddl.SchemaGenerator, self, checkfirst=checkfirst) def drop(self, bind: _CreateDropBind, checkfirst: bool = True) -> None: """Drops this sequence from the database.""" bind._run_ddl_visitor(ddl.SchemaDropper, self, checkfirst=checkfirst) def _not_a_column_expr(self) -> NoReturn: raise exc.InvalidRequestError( "This %s cannot be used directly " "as a column expression. Use func.next_value(sequence) " "to produce a 'next value' function that's usable " "as a column element." % self.__class__.__name__ ) @inspection._self_inspects class FetchedValue(SchemaEventTarget): """A marker for a transparent database-side default. Use :class:`.FetchedValue` when the database is configured to provide some automatic default for a column. E.g.:: Column('foo', Integer, FetchedValue()) Would indicate that some trigger or default generator will create a new value for the ``foo`` column during an INSERT. .. seealso:: :ref:`triggered_columns` """ is_server_default = True reflected = False has_argument = False is_clause_element = False column: Optional[Column[Any]] def __init__(self, for_update: bool = False) -> None: self.for_update = for_update def _as_for_update(self, for_update: bool) -> FetchedValue: if for_update == self.for_update: return self else: return self._clone(for_update) # type: ignore def _copy(self) -> FetchedValue: return FetchedValue(self.for_update) def _clone(self, for_update: bool) -> Self: n = self.__class__.__new__(self.__class__) n.__dict__.update(self.__dict__) n.__dict__.pop("column", None) n.for_update = for_update return n def _set_parent(self, parent: SchemaEventTarget, **kw: Any) -> None: column = parent assert isinstance(column, Column) self.column = column if self.for_update: self.column.server_onupdate = self else: self.column.server_default = self def __repr__(self) -> str: return util.generic_repr(self) class DefaultClause(FetchedValue): """A DDL-specified DEFAULT column value. :class:`.DefaultClause` is a :class:`.FetchedValue` that also generates a "DEFAULT" clause when "CREATE TABLE" is emitted. :class:`.DefaultClause` is generated automatically whenever the ``server_default``, ``server_onupdate`` arguments of :class:`_schema.Column` are used. A :class:`.DefaultClause` can be passed positionally as well. For example, the following:: Column('foo', Integer, server_default="50") Is equivalent to:: Column('foo', Integer, DefaultClause("50")) """ has_argument = True def __init__( self, arg: Union[str, ClauseElement, TextClause], for_update: bool = False, _reflected: bool = False, ) -> None: util.assert_arg_type(arg, (str, ClauseElement, TextClause), "arg") super().__init__(for_update) self.arg = arg self.reflected = _reflected def _copy(self) -> DefaultClause: return DefaultClause( arg=self.arg, for_update=self.for_update, _reflected=self.reflected ) def __repr__(self) -> str: return "DefaultClause(%r, for_update=%r)" % (self.arg, self.for_update) class Constraint(DialectKWArgs, HasConditionalDDL, SchemaItem): """A table-level SQL constraint. :class:`_schema.Constraint` serves as the base class for the series of constraint objects that can be associated with :class:`_schema.Table` objects, including :class:`_schema.PrimaryKeyConstraint`, :class:`_schema.ForeignKeyConstraint` :class:`_schema.UniqueConstraint`, and :class:`_schema.CheckConstraint`. """ __visit_name__ = "constraint" _creation_order: int _column_flag: bool def __init__( self, name: _ConstraintNameArgument = None, deferrable: Optional[bool] = None, initially: Optional[str] = None, info: Optional[_InfoType] = None, comment: Optional[str] = None, _create_rule: Optional[Any] = None, _type_bound: bool = False, **dialect_kw: Any, ) -> None: r"""Create a SQL constraint. :param name: Optional, the in-database name of this ``Constraint``. :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 when issuing DDL for this constraint. :param info: Optional data dictionary which will be populated into the :attr:`.SchemaItem.info` attribute of this object. .. versionadded:: 1.0.0 :param comment: Optional string that will render an SQL comment on foreign key constraint creation. .. versionadded:: 2.0 :param \**dialect_kw: Additional keyword arguments are dialect specific, and passed in the form ``_``. See the documentation regarding an individual dialect at :ref:`dialect_toplevel` for detail on documented arguments. :param _create_rule: used internally by some datatypes that also create constraints. :param _type_bound: used internally to indicate that this constraint is associated with a specific datatype. """ self.name = name self.deferrable = deferrable self.initially = initially if info: self.info = info self._create_rule = _create_rule self._type_bound = _type_bound util.set_creation_order(self) self._validate_dialect_kwargs(dialect_kw) self.comment = comment def _should_create_for_compiler( self, compiler: DDLCompiler, **kw: Any ) -> bool: if self._create_rule is not None and not self._create_rule(compiler): return False elif self._ddl_if is not None: return self._ddl_if._should_execute( ddl.CreateConstraint(self), self, None, compiler=compiler, **kw ) else: return True @property def table(self) -> Table: try: if isinstance(self.parent, Table): return self.parent except AttributeError: pass raise exc.InvalidRequestError( "This constraint is not bound to a table. Did you " "mean to call table.append_constraint(constraint) ?" ) def _set_parent(self, parent: SchemaEventTarget, **kw: Any) -> None: assert isinstance(parent, (Table, Column)) self.parent = parent parent.constraints.add(self) @util.deprecated( "1.4", "The :meth:`_schema.Constraint.copy` method is deprecated " "and will be removed in a future release.", ) def copy(self, **kw: Any) -> Self: return self._copy(**kw) # type: ignore def _copy(self, **kw: Any) -> Self: raise NotImplementedError() class ColumnCollectionMixin: """A :class:`_expression.ColumnCollection` of :class:`_schema.Column` objects. This collection represents the columns which are referred to by this object. """ _columns: DedupeColumnCollection[Column[Any]] _allow_multiple_tables = False _pending_colargs: List[Optional[Union[str, Column[Any]]]] if TYPE_CHECKING: def _set_parent_with_dispatch( self, parent: SchemaEventTarget, **kw: Any ) -> None: ... def __init__( self, *columns: _DDLColumnArgument, _autoattach: bool = True, _column_flag: bool = False, _gather_expressions: Optional[ List[Union[str, ColumnElement[Any]]] ] = None, ) -> None: self._column_flag = _column_flag self._columns = DedupeColumnCollection() processed_expressions: Optional[ List[Union[ColumnElement[Any], str]] ] = _gather_expressions if processed_expressions is not None: self._pending_colargs = [] for ( expr, _, _, add_element, ) in coercions.expect_col_expression_collection( roles.DDLConstraintColumnRole, columns ): self._pending_colargs.append(add_element) processed_expressions.append(expr) else: self._pending_colargs = [ coercions.expect(roles.DDLConstraintColumnRole, column) for column in columns ] if _autoattach and self._pending_colargs: self._check_attach() def _check_attach(self, evt: bool = False) -> None: col_objs = [c for c in self._pending_colargs if isinstance(c, Column)] cols_w_table = [c for c in col_objs if isinstance(c.table, Table)] cols_wo_table = set(col_objs).difference(cols_w_table) if cols_wo_table: # feature #3341 - place event listeners for Column objects # such that when all those cols are attached, we autoattach. assert not evt, "Should not reach here on event call" # issue #3411 - don't do the per-column auto-attach if some of the # columns are specified as strings. has_string_cols = { c for c in self._pending_colargs if c is not None }.difference(col_objs) if not has_string_cols: def _col_attached(column: Column[Any], table: Table) -> None: # this isinstance() corresponds with the # isinstance() above; only want to count Table-bound # columns if isinstance(table, Table): cols_wo_table.discard(column) if not cols_wo_table: self._check_attach(evt=True) self._cols_wo_table = cols_wo_table for col in cols_wo_table: col._on_table_attach(_col_attached) return columns = cols_w_table tables = {c.table for c in columns} if len(tables) == 1: self._set_parent_with_dispatch(tables.pop()) elif len(tables) > 1 and not self._allow_multiple_tables: table = columns[0].table others = [c for c in columns[1:] if c.table is not table] if others: raise exc.ArgumentError( "Column(s) %s are not part of table '%s'." % ( ", ".join("'%s'" % c for c in others), table.description, ) ) @util.ro_memoized_property def columns(self) -> ReadOnlyColumnCollection[str, Column[Any]]: return self._columns.as_readonly() @util.ro_memoized_property def c(self) -> ReadOnlyColumnCollection[str, Column[Any]]: return self._columns.as_readonly() def _col_expressions( self, parent: Union[Table, Column[Any]] ) -> List[Optional[Column[Any]]]: if isinstance(parent, Column): result: List[Optional[Column[Any]]] = [ c for c in self._pending_colargs if isinstance(c, Column) ] assert len(result) == len(self._pending_colargs) return result else: try: return [ parent.c[col] if isinstance(col, str) else col for col in self._pending_colargs ] except KeyError as ke: raise exc.ConstraintColumnNotFoundError( f"Can't create {self.__class__.__name__} " f"on table '{parent.description}': no column " f"named '{ke.args[0]}' is present." ) from ke def _set_parent(self, parent: SchemaEventTarget, **kw: Any) -> None: assert isinstance(parent, (Table, Column)) for col in self._col_expressions(parent): if col is not None: self._columns.add(col) class ColumnCollectionConstraint(ColumnCollectionMixin, Constraint): """A constraint that proxies a ColumnCollection.""" def __init__( self, *columns: _DDLColumnArgument, name: _ConstraintNameArgument = None, deferrable: Optional[bool] = None, initially: Optional[str] = None, info: Optional[_InfoType] = None, _autoattach: bool = True, _column_flag: bool = False, _gather_expressions: Optional[List[_DDLColumnArgument]] = None, **dialect_kw: Any, ) -> None: r""" :param \*columns: A sequence of column names or Column objects. :param name: Optional, the in-database name of this constraint. :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 when issuing DDL for this constraint. :param \**dialect_kw: other keyword arguments including dialect-specific arguments are propagated to the :class:`.Constraint` superclass. """ Constraint.__init__( self, name=name, deferrable=deferrable, initially=initially, info=info, **dialect_kw, ) ColumnCollectionMixin.__init__( self, *columns, _autoattach=_autoattach, _column_flag=_column_flag ) columns: ReadOnlyColumnCollection[str, Column[Any]] """A :class:`_expression.ColumnCollection` representing the set of columns for this constraint. """ def _set_parent(self, parent: SchemaEventTarget, **kw: Any) -> None: assert isinstance(parent, (Column, Table)) Constraint._set_parent(self, parent) ColumnCollectionMixin._set_parent(self, parent) def __contains__(self, x: Any) -> bool: return x in self._columns @util.deprecated( "1.4", "The :meth:`_schema.ColumnCollectionConstraint.copy` method " "is deprecated and will be removed in a future release.", ) def copy( self, *, target_table: Optional[Table] = None, **kw: Any, ) -> ColumnCollectionConstraint: return self._copy(target_table=target_table, **kw) def _copy( self, *, target_table: Optional[Table] = None, **kw: Any, ) -> ColumnCollectionConstraint: # ticket #5276 constraint_kwargs = {} for dialect_name in self.dialect_options: dialect_options = self.dialect_options[dialect_name]._non_defaults for ( dialect_option_key, dialect_option_value, ) in dialect_options.items(): constraint_kwargs[ dialect_name + "_" + dialect_option_key ] = dialect_option_value assert isinstance(self.parent, Table) c = self.__class__( name=self.name, deferrable=self.deferrable, initially=self.initially, *[ _copy_expression(expr, self.parent, target_table) for expr in self._columns ], comment=self.comment, **constraint_kwargs, ) return self._schema_item_copy(c) def contains_column(self, col: Column[Any]) -> bool: """Return True if this constraint contains the given column. Note that this object also contains an attribute ``.columns`` which is a :class:`_expression.ColumnCollection` of :class:`_schema.Column` objects. """ return self._columns.contains_column(col) def __iter__(self) -> Iterator[Column[Any]]: return iter(self._columns) def __len__(self) -> int: return len(self._columns) class CheckConstraint(ColumnCollectionConstraint): """A table- or column-level CHECK constraint. Can be included in the definition of a Table or Column. """ _allow_multiple_tables = True __visit_name__ = "table_or_column_check_constraint" @_document_text_coercion( "sqltext", ":class:`.CheckConstraint`", ":paramref:`.CheckConstraint.sqltext`", ) def __init__( self, sqltext: _TextCoercedExpressionArgument[Any], name: _ConstraintNameArgument = None, deferrable: Optional[bool] = None, initially: Optional[str] = None, table: Optional[Table] = None, info: Optional[_InfoType] = None, _create_rule: Optional[Any] = None, _autoattach: bool = True, _type_bound: bool = False, **dialect_kw: Any, ) -> None: r"""Construct a CHECK constraint. :param sqltext: A string containing the constraint definition, which will be used verbatim, or a SQL expression construct. If given as a string, the object is converted to a :func:`_expression.text` object. If the textual string includes a colon character, escape this using a backslash:: CheckConstraint(r"foo ~ E'a(?\:b|c)d") :param name: Optional, the in-database name of the constraint. :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 when issuing DDL for this constraint. :param info: Optional data dictionary which will be populated into the :attr:`.SchemaItem.info` attribute of this object. .. versionadded:: 1.0.0 """ self.sqltext = coercions.expect(roles.DDLExpressionRole, sqltext) columns: List[Column[Any]] = [] visitors.traverse(self.sqltext, {}, {"column": columns.append}) super().__init__( name=name, deferrable=deferrable, initially=initially, _create_rule=_create_rule, info=info, _type_bound=_type_bound, _autoattach=_autoattach, *columns, **dialect_kw, ) if table is not None: self._set_parent_with_dispatch(table) @property def is_column_level(self) -> bool: return not isinstance(self.parent, Table) @util.deprecated( "1.4", "The :meth:`_schema.CheckConstraint.copy` method is deprecated " "and will be removed in a future release.", ) def copy( self, *, target_table: Optional[Table] = None, **kw: Any ) -> CheckConstraint: return self._copy(target_table=target_table, **kw) def _copy( self, *, target_table: Optional[Table] = None, **kw: Any ) -> CheckConstraint: if target_table is not None: # note that target_table is None for the copy process of # a column-bound CheckConstraint, so this path is not reached # in that case. sqltext = _copy_expression(self.sqltext, self.table, target_table) else: sqltext = self.sqltext c = CheckConstraint( sqltext, name=self.name, initially=self.initially, deferrable=self.deferrable, _create_rule=self._create_rule, table=target_table, comment=self.comment, _autoattach=False, _type_bound=self._type_bound, ) return self._schema_item_copy(c) class ForeignKeyConstraint(ColumnCollectionConstraint): """A table-level FOREIGN KEY constraint. Defines a single column or composite FOREIGN KEY ... REFERENCES constraint. For a no-frills, single column foreign key, adding a :class:`_schema.ForeignKey` to the definition of a :class:`_schema.Column` is a shorthand equivalent for an unnamed, single column :class:`_schema.ForeignKeyConstraint`. Examples of foreign key configuration are in :ref:`metadata_foreignkeys`. """ __visit_name__ = "foreign_key_constraint" def __init__( self, columns: _typing_Sequence[_DDLColumnArgument], refcolumns: _typing_Sequence[_DDLColumnArgument], name: _ConstraintNameArgument = None, onupdate: Optional[str] = None, ondelete: Optional[str] = None, deferrable: Optional[bool] = None, initially: Optional[str] = None, use_alter: bool = False, link_to_name: bool = False, match: Optional[str] = None, table: Optional[Table] = None, info: Optional[_InfoType] = None, comment: Optional[str] = None, **dialect_kw: Any, ) -> None: r"""Construct a composite-capable FOREIGN KEY. :param columns: A sequence of local column names. The named columns must be defined and present in the parent Table. The names should match the ``key`` given to each column (defaults to the name) unless ``link_to_name`` is True. :param refcolumns: A sequence of foreign column names or Column objects. The columns must all be located within the same Table. :param name: Optional, the in-database name of the key. :param onupdate: Optional string. If set, emit ON UPDATE when issuing DDL for this constraint. Typical values include CASCADE, DELETE and RESTRICT. :param ondelete: Optional string. If set, emit ON DELETE 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 initially: Optional string. If set, emit INITIALLY when issuing DDL for this constraint. :param link_to_name: if True, the string name given in ``column`` is the rendered name of the referenced column, not its locally assigned ``key``. :param use_alter: If True, do not emit the DDL for this constraint as part of the CREATE TABLE definition. Instead, generate it via an ALTER TABLE statement issued after the full collection of tables have been created, and drop it via an ALTER TABLE statement before the full collection of tables are dropped. The use of :paramref:`_schema.ForeignKeyConstraint.use_alter` is particularly geared towards the case where two or more tables are established within a mutually-dependent foreign key constraint relationship; however, the :meth:`_schema.MetaData.create_all` and :meth:`_schema.MetaData.drop_all` methods will perform this resolution automatically, so the flag is normally not needed. .. versionchanged:: 1.0.0 Automatic resolution of foreign key cycles has been added, removing the need to use the :paramref:`_schema.ForeignKeyConstraint.use_alter` in typical use cases. .. seealso:: :ref:`use_alter` :param match: Optional string. If set, emit MATCH when issuing DDL for this constraint. Typical values include SIMPLE, PARTIAL and FULL. :param info: Optional data dictionary which will be populated into the :attr:`.SchemaItem.info` attribute of this object. .. versionadded:: 1.0.0 :param comment: Optional string that will render an SQL comment on foreign key constraint creation. .. versionadded:: 2.0 :param \**dialect_kw: Additional keyword arguments are dialect specific, and passed in the form ``_``. See the documentation regarding an individual dialect at :ref:`dialect_toplevel` for detail on documented arguments. .. versionadded:: 0.9.2 """ Constraint.__init__( self, name=name, deferrable=deferrable, initially=initially, info=info, comment=comment, **dialect_kw, ) self.onupdate = onupdate self.ondelete = ondelete self.link_to_name = link_to_name self.use_alter = use_alter self.match = match if len(set(columns)) != len(refcolumns): if len(set(columns)) != len(columns): # e.g. FOREIGN KEY (a, a) REFERENCES r (b, c) raise exc.ArgumentError( "ForeignKeyConstraint with duplicate source column " "references are not supported." ) else: # e.g. FOREIGN KEY (a) REFERENCES r (b, c) # paraphrasing # https://www.postgresql.org/docs/current/static/ddl-constraints.html raise exc.ArgumentError( "ForeignKeyConstraint number " "of constrained columns must match the number of " "referenced columns." ) # standalone ForeignKeyConstraint - create # associated ForeignKey objects which will be applied to hosted # Column objects (in col.foreign_keys), either now or when attached # to the Table for string-specified names self.elements = [ ForeignKey( refcol, _constraint=self, name=self.name, onupdate=self.onupdate, ondelete=self.ondelete, use_alter=self.use_alter, link_to_name=self.link_to_name, match=self.match, deferrable=self.deferrable, initially=self.initially, **self.dialect_kwargs, ) for refcol in refcolumns ] ColumnCollectionMixin.__init__(self, *columns) if table is not None: if hasattr(self, "parent"): assert table is self.parent self._set_parent_with_dispatch(table) def _append_element(self, column: Column[Any], fk: ForeignKey) -> None: self._columns.add(column) self.elements.append(fk) columns: ReadOnlyColumnCollection[str, Column[Any]] """A :class:`_expression.ColumnCollection` representing the set of columns for this constraint. """ elements: List[ForeignKey] """A sequence of :class:`_schema.ForeignKey` objects. Each :class:`_schema.ForeignKey` represents a single referring column/referred column pair. This collection is intended to be read-only. """ @property def _elements(self) -> util.OrderedDict[str, ForeignKey]: # legacy - provide a dictionary view of (column_key, fk) return util.OrderedDict(zip(self.column_keys, self.elements)) @property def _referred_schema(self) -> Optional[str]: for elem in self.elements: return elem._referred_schema else: return None @property def referred_table(self) -> Table: """The :class:`_schema.Table` object to which this :class:`_schema.ForeignKeyConstraint` references. This is a dynamically calculated attribute which may not be available if the constraint and/or parent table is not yet associated with a metadata collection that contains the referred table. .. versionadded:: 1.0.0 """ return self.elements[0].column.table def _validate_dest_table(self, table: Table) -> None: table_keys = {elem._table_key() for elem in self.elements} if None not in table_keys and len(table_keys) > 1: elem0, elem1 = sorted(table_keys)[0:2] raise exc.ArgumentError( "ForeignKeyConstraint on %s(%s) refers to " "multiple remote tables: %s and %s" % (table.fullname, self._col_description, elem0, elem1) ) @property def column_keys(self) -> _typing_Sequence[str]: """Return a list of string keys representing the local columns in this :class:`_schema.ForeignKeyConstraint`. This list is either the original string arguments sent to the constructor of the :class:`_schema.ForeignKeyConstraint`, or if the constraint has been initialized with :class:`_schema.Column` objects, is the string ``.key`` of each element. .. versionadded:: 1.0.0 """ if hasattr(self, "parent"): return self._columns.keys() else: return [ col.key if isinstance(col, ColumnElement) else str(col) for col in self._pending_colargs ] @property def _col_description(self) -> str: return ", ".join(self.column_keys) def _set_parent(self, parent: SchemaEventTarget, **kw: Any) -> None: table = parent assert isinstance(table, Table) Constraint._set_parent(self, table) ColumnCollectionConstraint._set_parent(self, table) for col, fk in zip(self._columns, self.elements): if not hasattr(fk, "parent") or fk.parent is not col: fk._set_parent_with_dispatch(col) self._validate_dest_table(table) @util.deprecated( "1.4", "The :meth:`_schema.ForeignKeyConstraint.copy` method is deprecated " "and will be removed in a future release.", ) def copy( self, *, schema: Optional[str] = None, target_table: Optional[Table] = None, **kw: Any, ) -> ForeignKeyConstraint: return self._copy(schema=schema, target_table=target_table, **kw) def _copy( self, *, schema: Optional[str] = None, target_table: Optional[Table] = None, **kw: Any, ) -> ForeignKeyConstraint: fkc = ForeignKeyConstraint( [x.parent.key for x in self.elements], [ x._get_colspec( schema=schema, table_name=target_table.name if target_table is not None and x._table_key() == x.parent.table.key else None, _is_copy=True, ) for x in self.elements ], name=self.name, onupdate=self.onupdate, ondelete=self.ondelete, use_alter=self.use_alter, deferrable=self.deferrable, initially=self.initially, link_to_name=self.link_to_name, match=self.match, comment=self.comment, ) for self_fk, other_fk in zip(self.elements, fkc.elements): self_fk._schema_item_copy(other_fk) return self._schema_item_copy(fkc) class PrimaryKeyConstraint(ColumnCollectionConstraint): """A table-level PRIMARY KEY constraint. The :class:`.PrimaryKeyConstraint` object is present automatically on any :class:`_schema.Table` object; it is assigned a set of :class:`_schema.Column` objects corresponding to those marked with the :paramref:`_schema.Column.primary_key` flag:: >>> my_table = Table('mytable', metadata, ... Column('id', Integer, primary_key=True), ... Column('version_id', Integer, primary_key=True), ... Column('data', String(50)) ... ) >>> my_table.primary_key PrimaryKeyConstraint( Column('id', Integer(), table=, primary_key=True, nullable=False), Column('version_id', Integer(), table=, primary_key=True, nullable=False) ) The primary key of a :class:`_schema.Table` can also be specified by using a :class:`.PrimaryKeyConstraint` object explicitly; in this mode of usage, the "name" of the constraint can also be specified, as well as other options which may be recognized by dialects:: my_table = Table('mytable', metadata, Column('id', Integer), Column('version_id', Integer), Column('data', String(50)), PrimaryKeyConstraint('id', 'version_id', name='mytable_pk') ) The two styles of column-specification should generally not be mixed. An warning is emitted if the columns present in the :class:`.PrimaryKeyConstraint` don't match the columns that were marked as ``primary_key=True``, if both are present; in this case, the columns are taken strictly from the :class:`.PrimaryKeyConstraint` declaration, and those columns otherwise marked as ``primary_key=True`` are ignored. This behavior is intended to be backwards compatible with previous behavior. .. versionchanged:: 0.9.2 Using a mixture of columns within a :class:`.PrimaryKeyConstraint` in addition to columns marked as ``primary_key=True`` now emits a warning if the lists don't match. The ultimate behavior of ignoring those columns marked with the flag only is currently maintained for backwards compatibility; this warning may raise an exception in a future release. For the use case where specific options are to be specified on the :class:`.PrimaryKeyConstraint`, but the usual style of using ``primary_key=True`` flags is still desirable, an empty :class:`.PrimaryKeyConstraint` may be specified, which will take on the primary key column collection from the :class:`_schema.Table` based on the flags:: my_table = Table('mytable', metadata, Column('id', Integer, primary_key=True), Column('version_id', Integer, primary_key=True), Column('data', String(50)), PrimaryKeyConstraint(name='mytable_pk', mssql_clustered=True) ) .. versionadded:: 0.9.2 an empty :class:`.PrimaryKeyConstraint` may now be specified for the purposes of establishing keyword arguments with the constraint, independently of the specification of "primary key" columns within the :class:`_schema.Table` itself; columns marked as ``primary_key=True`` will be gathered into the empty constraint's column collection. """ __visit_name__ = "primary_key_constraint" def __init__( self, *columns: _DDLColumnArgument, name: Optional[str] = None, deferrable: Optional[bool] = None, initially: Optional[str] = None, info: Optional[_InfoType] = None, _implicit_generated: bool = False, **dialect_kw: Any, ) -> None: self._implicit_generated = _implicit_generated super().__init__( *columns, name=name, deferrable=deferrable, initially=initially, info=info, **dialect_kw, ) def _set_parent(self, parent: SchemaEventTarget, **kw: Any) -> None: table = parent assert isinstance(table, Table) super()._set_parent(table) if table.primary_key is not self: table.constraints.discard(table.primary_key) table.primary_key = self # type: ignore table.constraints.add(self) table_pks = [c for c in table.c if c.primary_key] if ( self._columns and table_pks and set(table_pks) != set(self._columns) ): util.warn( "Table '%s' specifies columns %s as primary_key=True, " "not matching locally specified columns %s; setting the " "current primary key columns to %s. This warning " "may become an exception in a future release" % ( table.name, ", ".join("'%s'" % c.name for c in table_pks), ", ".join("'%s'" % c.name for c in self._columns), ", ".join("'%s'" % c.name for c in self._columns), ) ) table_pks[:] = [] for c in self._columns: c.primary_key = True if c._user_defined_nullable is NULL_UNSPECIFIED: c.nullable = False if table_pks: self._columns.extend(table_pks) def _reload(self, columns: Iterable[Column[Any]]) -> None: """repopulate this :class:`.PrimaryKeyConstraint` given a set of columns. Existing columns in the table that are marked as primary_key=True are maintained. Also fires a new event. This is basically like putting a whole new :class:`.PrimaryKeyConstraint` object on the parent :class:`_schema.Table` object without actually replacing the object. The ordering of the given list of columns is also maintained; these columns will be appended to the list of columns after any which are already present. """ # set the primary key flag on new columns. # note any existing PK cols on the table also have their # flag still set. for col in columns: col.primary_key = True self._columns.extend(columns) PrimaryKeyConstraint._autoincrement_column._reset(self) # type: ignore self._set_parent_with_dispatch(self.table) def _replace(self, col: Column[Any]) -> None: PrimaryKeyConstraint._autoincrement_column._reset(self) # type: ignore self._columns.replace(col) self.dispatch._sa_event_column_added_to_pk_constraint(self, col) @property def columns_autoinc_first(self) -> List[Column[Any]]: autoinc = self._autoincrement_column if autoinc is not None: return [autoinc] + [c for c in self._columns if c is not autoinc] else: return list(self._columns) @util.ro_memoized_property def _autoincrement_column(self) -> Optional[Column[int]]: def _validate_autoinc(col: Column[Any], autoinc_true: bool) -> bool: if col.type._type_affinity is None or not issubclass( col.type._type_affinity, ( type_api.INTEGERTYPE._type_affinity, type_api.NUMERICTYPE._type_affinity, ), ): if autoinc_true: raise exc.ArgumentError( "Column type %s on column '%s' is not " "compatible with autoincrement=True" % (col.type, col) ) else: return False elif ( not isinstance(col.default, (type(None), Sequence)) and not autoinc_true ): return False elif ( col.server_default is not None and not isinstance(col.server_default, Identity) and not autoinc_true ): return False elif col.foreign_keys and col.autoincrement not in ( True, "ignore_fk", ): return False return True if len(self._columns) == 1: col = list(self._columns)[0] if col.autoincrement is True: _validate_autoinc(col, True) return col elif col.autoincrement in ( "auto", "ignore_fk", ) and _validate_autoinc(col, False): return col else: return None else: autoinc = None for col in self._columns: if col.autoincrement is True: _validate_autoinc(col, True) if autoinc is not None: raise exc.ArgumentError( "Only one Column may be marked " "autoincrement=True, found both %s and %s." % (col.name, autoinc.name) ) else: autoinc = col return autoinc class UniqueConstraint(ColumnCollectionConstraint): """A table-level UNIQUE constraint. Defines a single column or composite UNIQUE constraint. For a no-frills, single column constraint, adding ``unique=True`` to the ``Column`` definition is a shorthand equivalent for an unnamed, single column UniqueConstraint. """ __visit_name__ = "unique_constraint" class Index( DialectKWArgs, ColumnCollectionMixin, HasConditionalDDL, SchemaItem ): """A table-level INDEX. Defines a composite (one or more column) INDEX. E.g.:: sometable = Table("sometable", metadata, Column("name", String(50)), Column("address", String(100)) ) Index("some_index", sometable.c.name) For a no-frills, single column index, adding :class:`_schema.Column` also supports ``index=True``:: sometable = Table("sometable", metadata, Column("name", String(50), index=True) ) For a composite index, multiple columns can be specified:: Index("some_index", sometable.c.name, sometable.c.address) Functional indexes are supported as well, typically by using the :data:`.func` construct in conjunction with table-bound :class:`_schema.Column` objects:: Index("some_index", func.lower(sometable.c.name)) An :class:`.Index` can also be manually associated with a :class:`_schema.Table`, either through inline declaration or using :meth:`_schema.Table.append_constraint`. When this approach is used, the names of the indexed columns can be specified as strings:: Table("sometable", metadata, Column("name", String(50)), Column("address", String(100)), Index("some_index", "name", "address") ) To support functional or expression-based indexes in this form, the :func:`_expression.text` construct may be used:: from sqlalchemy import text Table("sometable", metadata, Column("name", String(50)), Column("address", String(100)), Index("some_index", text("lower(name)")) ) .. versionadded:: 0.9.5 the :func:`_expression.text` construct may be used to specify :class:`.Index` expressions, provided the :class:`.Index` is explicitly associated with the :class:`_schema.Table`. .. seealso:: :ref:`schema_indexes` - General information on :class:`.Index`. :ref:`postgresql_indexes` - PostgreSQL-specific options available for the :class:`.Index` construct. :ref:`mysql_indexes` - MySQL-specific options available for the :class:`.Index` construct. :ref:`mssql_indexes` - MSSQL-specific options available for the :class:`.Index` construct. """ __visit_name__ = "index" table: Optional[Table] expressions: _typing_Sequence[Union[str, ColumnElement[Any]]] _table_bound_expressions: _typing_Sequence[ColumnElement[Any]] def __init__( self, name: Optional[str], *expressions: _DDLColumnArgument, unique: bool = False, quote: Optional[bool] = None, info: Optional[_InfoType] = None, _table: Optional[Table] = None, _column_flag: bool = False, **dialect_kw: Any, ) -> None: r"""Construct an index object. :param name: The name of the index :param \*expressions: Column expressions to include in the index. The expressions are normally instances of :class:`_schema.Column`, but may also be arbitrary SQL expressions which ultimately refer to a :class:`_schema.Column`. :param unique=False: Keyword only argument; if True, create a unique index. :param quote=None: Keyword only argument; whether to apply quoting to the name of the index. Works in the same manner as that of :paramref:`_schema.Column.quote`. :param info=None: Optional data dictionary which will be populated into the :attr:`.SchemaItem.info` attribute of this object. .. versionadded:: 1.0.0 :param \**dialect_kw: Additional keyword arguments not mentioned above are dialect specific, and passed in the form ``_``. See the documentation regarding an individual dialect at :ref:`dialect_toplevel` for detail on documented arguments. """ self.table = table = None self.name = quoted_name.construct(name, quote) self.unique = unique if info is not None: self.info = info # TODO: consider "table" argument being public, but for # the purpose of the fix here, it starts as private. if _table is not None: table = _table self._validate_dialect_kwargs(dialect_kw) self.expressions = [] # will call _set_parent() if table-bound column # objects are present ColumnCollectionMixin.__init__( self, *expressions, _column_flag=_column_flag, _gather_expressions=self.expressions, ) if table is not None: self._set_parent(table) def _set_parent(self, parent: SchemaEventTarget, **kw: Any) -> None: table = parent assert isinstance(table, Table) ColumnCollectionMixin._set_parent(self, table) if self.table is not None and table is not self.table: raise exc.ArgumentError( "Index '%s' is against table '%s', and " "cannot be associated with table '%s'." % (self.name, self.table.description, table.description) ) self.table = table table.indexes.add(self) expressions = self.expressions col_expressions = self._col_expressions(table) assert len(expressions) == len(col_expressions) exprs = [] for expr, colexpr in zip(expressions, col_expressions): if isinstance(expr, ClauseElement): exprs.append(expr) elif colexpr is not None: exprs.append(colexpr) else: assert False self.expressions = self._table_bound_expressions = exprs def create(self, bind: _CreateDropBind, checkfirst: bool = False) -> None: """Issue a ``CREATE`` statement for this :class:`.Index`, using the given :class:`.Connection` or :class:`.Engine`` for connectivity. .. seealso:: :meth:`_schema.MetaData.create_all`. """ bind._run_ddl_visitor(ddl.SchemaGenerator, self, checkfirst=checkfirst) def drop(self, bind: _CreateDropBind, checkfirst: bool = False) -> None: """Issue a ``DROP`` statement for this :class:`.Index`, using the given :class:`.Connection` or :class:`.Engine` for connectivity. .. seealso:: :meth:`_schema.MetaData.drop_all`. """ bind._run_ddl_visitor(ddl.SchemaDropper, self, checkfirst=checkfirst) def __repr__(self) -> str: exprs: _typing_Sequence[Any] # noqa: F842 return "Index(%s)" % ( ", ".join( [repr(self.name)] + [repr(e) for e in self.expressions] + (self.unique and ["unique=True"] or []) ) ) DEFAULT_NAMING_CONVENTION: util.immutabledict[str, str] = util.immutabledict( {"ix": "ix_%(column_0_label)s"} ) class MetaData(HasSchemaAttr): """A collection of :class:`_schema.Table` objects and their associated schema constructs. Holds a collection of :class:`_schema.Table` objects as well as an optional binding to an :class:`_engine.Engine` or :class:`_engine.Connection`. If bound, the :class:`_schema.Table` objects in the collection and their columns may participate in implicit SQL execution. The :class:`_schema.Table` objects themselves are stored in the :attr:`_schema.MetaData.tables` dictionary. :class:`_schema.MetaData` is a thread-safe object for read operations. Construction of new tables within a single :class:`_schema.MetaData` object, either explicitly or via reflection, may not be completely thread-safe. .. seealso:: :ref:`metadata_describing` - Introduction to database metadata """ __visit_name__ = "metadata" def __init__( self, schema: Optional[str] = None, quote_schema: Optional[bool] = None, naming_convention: Optional[Dict[str, str]] = None, info: Optional[_InfoType] = None, ) -> None: """Create a new MetaData object. :param schema: The default schema to use for the :class:`_schema.Table`, :class:`.Sequence`, and potentially other objects associated with this :class:`_schema.MetaData`. Defaults to ``None``. .. seealso:: :ref:`schema_metadata_schema_name` - details on how the :paramref:`_schema.MetaData.schema` parameter is used. :paramref:`_schema.Table.schema` :paramref:`.Sequence.schema` :param quote_schema: Sets the ``quote_schema`` flag for those :class:`_schema.Table`, :class:`.Sequence`, and other objects which make usage of the local ``schema`` name. :param info: Optional data dictionary which will be populated into the :attr:`.SchemaItem.info` attribute of this object. .. versionadded:: 1.0.0 :param naming_convention: a dictionary referring to values which will establish default naming conventions for :class:`.Constraint` and :class:`.Index` objects, for those objects which are not given a name explicitly. The keys of this dictionary may be: * a constraint or Index class, e.g. the :class:`.UniqueConstraint`, :class:`_schema.ForeignKeyConstraint` class, the :class:`.Index` class * a string mnemonic for one of the known constraint classes; ``"fk"``, ``"pk"``, ``"ix"``, ``"ck"``, ``"uq"`` for foreign key, primary key, index, check, and unique constraint, respectively. * the string name of a user-defined "token" that can be used to define new naming tokens. The values associated with each "constraint class" or "constraint mnemonic" key are string naming templates, such as ``"uq_%(table_name)s_%(column_0_name)s"``, which describe how the name should be composed. The values associated with user-defined "token" keys should be callables of the form ``fn(constraint, table)``, which accepts the constraint/index object and :class:`_schema.Table` as arguments, returning a string result. The built-in names are as follows, some of which may only be available for certain types of constraint: * ``%(table_name)s`` - the name of the :class:`_schema.Table` object associated with the constraint. * ``%(referred_table_name)s`` - the name of the :class:`_schema.Table` object associated with the referencing target of a :class:`_schema.ForeignKeyConstraint`. * ``%(column_0_name)s`` - the name of the :class:`_schema.Column` at index position "0" within the constraint. * ``%(column_0N_name)s`` - the name of all :class:`_schema.Column` objects in order within the constraint, joined without a separator. * ``%(column_0_N_name)s`` - the name of all :class:`_schema.Column` objects in order within the constraint, joined with an underscore as a separator. * ``%(column_0_label)s``, ``%(column_0N_label)s``, ``%(column_0_N_label)s`` - the label of either the zeroth :class:`_schema.Column` or all :class:`.Columns`, separated with or without an underscore * ``%(column_0_key)s``, ``%(column_0N_key)s``, ``%(column_0_N_key)s`` - the key of either the zeroth :class:`_schema.Column` or all :class:`.Columns`, separated with or without an underscore * ``%(referred_column_0_name)s``, ``%(referred_column_0N_name)s`` ``%(referred_column_0_N_name)s``, ``%(referred_column_0_key)s``, ``%(referred_column_0N_key)s``, ... column tokens which render the names/keys/labels of columns that are referenced by a :class:`_schema.ForeignKeyConstraint`. * ``%(constraint_name)s`` - a special key that refers to the existing name given to the constraint. When this key is present, the :class:`.Constraint` object's existing name will be replaced with one that is composed from template string that uses this token. When this token is present, it is required that the :class:`.Constraint` is given an explicit name ahead of time. * user-defined: any additional token may be implemented by passing it along with a ``fn(constraint, table)`` callable to the naming_convention dictionary. .. versionadded:: 1.3.0 - added new ``%(column_0N_name)s``, ``%(column_0_N_name)s``, and related tokens that produce concatenations of names, keys, or labels for all columns referred to by a given constraint. .. seealso:: :ref:`constraint_naming_conventions` - for detailed usage examples. """ if schema is not None and not isinstance(schema, str): raise exc.ArgumentError( "expected schema argument to be a string, " f"got {type(schema)}." ) self.tables = util.FacadeDict() self.schema = quoted_name.construct(schema, quote_schema) self.naming_convention = ( naming_convention if naming_convention else DEFAULT_NAMING_CONVENTION ) if info: self.info = info self._schemas: Set[str] = set() self._sequences: Dict[str, Sequence] = {} self._fk_memos: Dict[ Tuple[str, Optional[str]], List[ForeignKey] ] = collections.defaultdict(list) tables: util.FacadeDict[str, Table] """A dictionary of :class:`_schema.Table` objects keyed to their name or "table key". The exact key is that determined by the :attr:`_schema.Table.key` attribute; for a table with no :attr:`_schema.Table.schema` attribute, this is the same as :attr:`_schema.Table.name`. For a table with a schema, it is typically of the form ``schemaname.tablename``. .. seealso:: :attr:`_schema.MetaData.sorted_tables` """ def __repr__(self) -> str: return "MetaData()" def __contains__(self, table_or_key: Union[str, Table]) -> bool: if not isinstance(table_or_key, str): table_or_key = table_or_key.key return table_or_key in self.tables def _add_table( self, name: str, schema: Optional[str], table: Table ) -> None: key = _get_table_key(name, schema) self.tables._insert_item(key, table) if schema: self._schemas.add(schema) def _remove_table(self, name: str, schema: Optional[str]) -> None: key = _get_table_key(name, schema) removed = dict.pop(self.tables, key, None) # type: ignore if removed is not None: for fk in removed.foreign_keys: fk._remove_from_metadata(self) if self._schemas: self._schemas = { t.schema for t in self.tables.values() if t.schema is not None } def __getstate__(self) -> Dict[str, Any]: return { "tables": self.tables, "schema": self.schema, "schemas": self._schemas, "sequences": self._sequences, "fk_memos": self._fk_memos, "naming_convention": self.naming_convention, } def __setstate__(self, state: Dict[str, Any]) -> None: self.tables = state["tables"] self.schema = state["schema"] self.naming_convention = state["naming_convention"] self._sequences = state["sequences"] self._schemas = state["schemas"] self._fk_memos = state["fk_memos"] def clear(self) -> None: """Clear all Table objects from this MetaData.""" dict.clear(self.tables) # type: ignore self._schemas.clear() self._fk_memos.clear() def remove(self, table: Table) -> None: """Remove the given Table object from this MetaData.""" self._remove_table(table.name, table.schema) @property def sorted_tables(self) -> List[Table]: """Returns a list of :class:`_schema.Table` objects sorted in order of foreign key dependency. The sorting will place :class:`_schema.Table` objects that have dependencies first, before the dependencies themselves, representing the order in which they can be created. To get the order in which the tables would be dropped, use the ``reversed()`` Python built-in. .. warning:: The :attr:`.MetaData.sorted_tables` attribute cannot by itself accommodate automatic resolution of dependency cycles between tables, which are usually caused by mutually dependent foreign key constraints. When these cycles are detected, the foreign keys of these tables are omitted from consideration in the sort. A warning is emitted when this condition occurs, which will be an exception raise in a future release. Tables which are not part of the cycle will still be returned in dependency order. To resolve these cycles, the :paramref:`_schema.ForeignKeyConstraint.use_alter` parameter may be applied to those constraints which create a cycle. Alternatively, the :func:`_schema.sort_tables_and_constraints` function will automatically return foreign key constraints in a separate collection when cycles are detected so that they may be applied to a schema separately. .. versionchanged:: 1.3.17 - a warning is emitted when :attr:`.MetaData.sorted_tables` cannot perform a proper sort due to cyclical dependencies. This will be an exception in a future release. Additionally, the sort will continue to return other tables not involved in the cycle in dependency order which was not the case previously. .. seealso:: :func:`_schema.sort_tables` :func:`_schema.sort_tables_and_constraints` :attr:`_schema.MetaData.tables` :meth:`_reflection.Inspector.get_table_names` :meth:`_reflection.Inspector.get_sorted_table_and_fkc_names` """ return ddl.sort_tables( sorted(self.tables.values(), key=lambda t: t.key) # type: ignore ) @util.preload_module("sqlalchemy.engine.reflection") def reflect( self, bind: Union[Engine, Connection], schema: Optional[str] = None, views: bool = False, only: Optional[_typing_Sequence[str]] = None, extend_existing: bool = False, autoload_replace: bool = True, resolve_fks: bool = True, **dialect_kwargs: Any, ) -> None: r"""Load all available table definitions from the database. Automatically creates ``Table`` entries in this ``MetaData`` for any table available in the database but not yet present in the ``MetaData``. May be called multiple times to pick up tables recently added to the database, however no special action is taken if a table in this ``MetaData`` no longer exists in the database. :param bind: A :class:`.Connection` or :class:`.Engine` used to access the database. :param schema: Optional, query and reflect tables from an alternate schema. If None, the schema associated with this :class:`_schema.MetaData` is used, if any. :param views: If True, also reflect views (materialized and plain). :param only: Optional. Load only a sub-set of available named tables. May be specified as a sequence of names or a callable. If a sequence of names is provided, only those tables will be reflected. An error is raised if a table is requested but not available. Named tables already present in this ``MetaData`` are ignored. If a callable is provided, it will be used as a boolean predicate to filter the list of potential table names. The callable is called with a table name and this ``MetaData`` instance as positional arguments and should return a true value for any table to reflect. :param extend_existing: Passed along to each :class:`_schema.Table` as :paramref:`_schema.Table.extend_existing`. .. versionadded:: 0.9.1 :param autoload_replace: Passed along to each :class:`_schema.Table` as :paramref:`_schema.Table.autoload_replace`. .. versionadded:: 0.9.1 :param resolve_fks: if True, reflect :class:`_schema.Table` objects linked to :class:`_schema.ForeignKey` objects located in each :class:`_schema.Table`. For :meth:`_schema.MetaData.reflect`, this has the effect of reflecting related tables that might otherwise not be in the list of tables being reflected, for example if the referenced table is in a different schema or is omitted via the :paramref:`.MetaData.reflect.only` parameter. When False, :class:`_schema.ForeignKey` objects are not followed to the :class:`_schema.Table` in which they link, however if the related table is also part of the list of tables that would be reflected in any case, the :class:`_schema.ForeignKey` object will still resolve to its related :class:`_schema.Table` after the :meth:`_schema.MetaData.reflect` operation is complete. Defaults to True. .. versionadded:: 1.3.0 .. seealso:: :paramref:`_schema.Table.resolve_fks` :param \**dialect_kwargs: Additional keyword arguments not mentioned above are dialect specific, and passed in the form ``_``. See the documentation regarding an individual dialect at :ref:`dialect_toplevel` for detail on documented arguments. .. versionadded:: 0.9.2 - Added :paramref:`.MetaData.reflect.**dialect_kwargs` to support dialect-level reflection options for all :class:`_schema.Table` objects reflected. """ with inspection.inspect(bind)._inspection_context() as insp: reflect_opts: Any = { "autoload_with": insp, "extend_existing": extend_existing, "autoload_replace": autoload_replace, "resolve_fks": resolve_fks, "_extend_on": set(), } reflect_opts.update(dialect_kwargs) if schema is None: schema = self.schema if schema is not None: reflect_opts["schema"] = schema kind = util.preloaded.engine_reflection.ObjectKind.TABLE available: util.OrderedSet[str] = util.OrderedSet( insp.get_table_names(schema) ) if views: kind = util.preloaded.engine_reflection.ObjectKind.ANY available.update(insp.get_view_names(schema)) try: available.update(insp.get_materialized_view_names(schema)) except NotImplementedError: pass if schema is not None: available_w_schema: util.OrderedSet[str] = util.OrderedSet( [f"{schema}.{name}" for name in available] ) else: available_w_schema = available current = set(self.tables) if only is None: load = [ name for name, schname in zip(available, available_w_schema) if extend_existing or schname not in current ] elif callable(only): load = [ name for name, schname in zip(available, available_w_schema) if (extend_existing or schname not in current) and only(name, self) ] else: missing = [name for name in only if name not in available] if missing: s = schema and (" schema '%s'" % schema) or "" raise exc.InvalidRequestError( "Could not reflect: requested table(s) not available " "in %r%s: (%s)" % (bind.engine, s, ", ".join(missing)) ) load = [ name for name in only if extend_existing or name not in current ] # pass the available tables so the inspector can # choose to ignore the filter_names _reflect_info = insp._get_reflection_info( schema=schema, filter_names=load, available=available, kind=kind, scope=util.preloaded.engine_reflection.ObjectScope.ANY, **dialect_kwargs, ) reflect_opts["_reflect_info"] = _reflect_info for name in load: try: Table(name, self, **reflect_opts) except exc.UnreflectableTableError as uerr: util.warn("Skipping table %s: %s" % (name, uerr)) def create_all( self, bind: _CreateDropBind, tables: Optional[_typing_Sequence[Table]] = None, checkfirst: bool = True, ) -> None: """Create all tables stored in this metadata. Conditional by default, will not attempt to recreate tables already present in the target database. :param bind: A :class:`.Connection` or :class:`.Engine` used to access the database. :param tables: Optional list of ``Table`` objects, which is a subset of the total tables in the ``MetaData`` (others are ignored). :param checkfirst: Defaults to True, don't issue CREATEs for tables already present in the target database. """ bind._run_ddl_visitor( ddl.SchemaGenerator, self, checkfirst=checkfirst, tables=tables ) def drop_all( self, bind: _CreateDropBind, tables: Optional[_typing_Sequence[Table]] = None, checkfirst: bool = True, ) -> None: """Drop all tables stored in this metadata. Conditional by default, will not attempt to drop tables not present in the target database. :param bind: A :class:`.Connection` or :class:`.Engine` used to access the database. :param tables: Optional list of ``Table`` objects, which is a subset of the total tables in the ``MetaData`` (others are ignored). :param checkfirst: Defaults to True, only issue DROPs for tables confirmed to be present in the target database. """ bind._run_ddl_visitor( ddl.SchemaDropper, self, checkfirst=checkfirst, tables=tables ) class Computed(FetchedValue, SchemaItem): """Defines a generated column, i.e. "GENERATED ALWAYS AS" syntax. The :class:`.Computed` construct is an inline construct added to the argument list of a :class:`_schema.Column` object:: from sqlalchemy import Computed Table('square', metadata_obj, Column('side', Float, nullable=False), Column('area', Float, Computed('side * side')) ) See the linked documentation below for complete details. .. versionadded:: 1.3.11 .. seealso:: :ref:`computed_ddl` """ __visit_name__ = "computed_column" column: Optional[Column[Any]] @_document_text_coercion( "sqltext", ":class:`.Computed`", ":paramref:`.Computed.sqltext`" ) def __init__( self, sqltext: _DDLColumnArgument, persisted: Optional[bool] = None ) -> None: """Construct a GENERATED ALWAYS AS DDL construct to accompany a :class:`_schema.Column`. :param sqltext: A string containing the column generation expression, which will be used verbatim, or a SQL expression construct, such as a :func:`_expression.text` object. If given as a string, the object is converted to a :func:`_expression.text` object. :param persisted: Optional, controls how this column should be persisted by the database. Possible values are: * ``None``, the default, it will use the default persistence defined by the database. * ``True``, will render ``GENERATED ALWAYS AS ... STORED``, or the equivalent for the target database if supported. * ``False``, will render ``GENERATED ALWAYS AS ... VIRTUAL``, or the equivalent for the target database if supported. Specifying ``True`` or ``False`` may raise an error when the DDL is emitted to the target database if the database does not support that persistence option. Leaving this parameter at its default of ``None`` is guaranteed to succeed for all databases that support ``GENERATED ALWAYS AS``. """ self.sqltext = coercions.expect(roles.DDLExpressionRole, sqltext) self.persisted = persisted self.column = None def _set_parent(self, parent: SchemaEventTarget, **kw: Any) -> None: assert isinstance(parent, Column) if not isinstance( parent.server_default, (type(None), Computed) ) or not isinstance(parent.server_onupdate, (type(None), Computed)): raise exc.ArgumentError( "A generated column cannot specify a server_default or a " "server_onupdate argument" ) self.column = parent parent.computed = self self.column.server_onupdate = self self.column.server_default = self def _as_for_update(self, for_update: bool) -> FetchedValue: return self @util.deprecated( "1.4", "The :meth:`_schema.Computed.copy` method is deprecated " "and will be removed in a future release.", ) def copy( self, *, target_table: Optional[Table] = None, **kw: Any ) -> Computed: return self._copy(target_table=target_table, **kw) def _copy( self, *, target_table: Optional[Table] = None, **kw: Any ) -> Computed: sqltext = _copy_expression( self.sqltext, self.column.table if self.column is not None else None, target_table, ) g = Computed(sqltext, persisted=self.persisted) return self._schema_item_copy(g) class Identity(IdentityOptions, FetchedValue, SchemaItem): """Defines an identity column, i.e. "GENERATED { ALWAYS | BY DEFAULT } AS IDENTITY" syntax. The :class:`.Identity` construct is an inline construct added to the argument list of a :class:`_schema.Column` object:: from sqlalchemy import Identity Table('foo', metadata_obj, Column('id', Integer, Identity()) Column('description', Text), ) See the linked documentation below for complete details. .. versionadded:: 1.4 .. seealso:: :ref:`identity_ddl` """ __visit_name__ = "identity_column" def __init__( self, always: bool = False, on_null: Optional[bool] = None, start: Optional[int] = None, increment: Optional[int] = None, minvalue: Optional[int] = None, maxvalue: Optional[int] = None, nominvalue: Optional[bool] = None, nomaxvalue: Optional[bool] = None, cycle: Optional[bool] = None, cache: Optional[int] = None, order: Optional[bool] = None, ) -> None: """Construct a GENERATED { ALWAYS | BY DEFAULT } AS IDENTITY DDL construct to accompany a :class:`_schema.Column`. See the :class:`.Sequence` documentation for a complete description of most parameters. .. note:: MSSQL supports this construct as the preferred alternative to generate an IDENTITY on a column, but it uses non standard syntax that only support :paramref:`_schema.Identity.start` and :paramref:`_schema.Identity.increment`. All other parameters are ignored. :param always: A boolean, that indicates the type of identity column. If ``False`` is specified, the default, then the user-specified value takes precedence. If ``True`` is specified, a user-specified value is not accepted ( on some backends, like PostgreSQL, OVERRIDING SYSTEM VALUE, or similar, may be specified in an INSERT to override the sequence value). Some backends also have a default value for this parameter, ``None`` can be used to omit rendering this part in the DDL. It will be treated as ``False`` if a backend does not have a default value. :param on_null: Set to ``True`` to specify ON NULL in conjunction with a ``always=False`` identity column. This option is only supported on some backends, like Oracle. :param start: the starting index of the sequence. :param increment: the increment value of the sequence. :param minvalue: the minimum value of the sequence. :param maxvalue: the maximum value of the sequence. :param nominvalue: no minimum value of the sequence. :param nomaxvalue: no maximum value of the sequence. :param cycle: allows the sequence to wrap around when the maxvalue or minvalue has been reached. :param cache: optional integer value; number of future values in the sequence which are calculated in advance. :param order: optional boolean value; if true, renders the ORDER keyword. """ IdentityOptions.__init__( self, start=start, increment=increment, minvalue=minvalue, maxvalue=maxvalue, nominvalue=nominvalue, nomaxvalue=nomaxvalue, cycle=cycle, cache=cache, order=order, ) self.always = always self.on_null = on_null self.column = None def _set_parent(self, parent: SchemaEventTarget, **kw: Any) -> None: assert isinstance(parent, Column) if not isinstance( parent.server_default, (type(None), Identity) ) or not isinstance(parent.server_onupdate, type(None)): raise exc.ArgumentError( "A column with an Identity object cannot specify a " "server_default or a server_onupdate argument" ) if parent.autoincrement is False: raise exc.ArgumentError( "A column with an Identity object cannot specify " "autoincrement=False" ) self.column = parent parent.identity = self if parent._user_defined_nullable is NULL_UNSPECIFIED: parent.nullable = False parent.server_default = self def _as_for_update(self, for_update: bool) -> FetchedValue: return self @util.deprecated( "1.4", "The :meth:`_schema.Identity.copy` method is deprecated " "and will be removed in a future release.", ) def copy(self, **kw: Any) -> Identity: return self._copy(**kw) def _copy(self, **kw: Any) -> Identity: i = Identity( always=self.always, on_null=self.on_null, start=self.start, increment=self.increment, minvalue=self.minvalue, maxvalue=self.maxvalue, nominvalue=self.nominvalue, nomaxvalue=self.nomaxvalue, cycle=self.cycle, cache=self.cache, order=self.order, ) return self._schema_item_copy(i)