.. _inheritance_toplevel: Mapping Class Inheritance Hierarchies ====================================== SQLAlchemy supports three forms of inheritance: **single table inheritance**, where several types of classes are represented by a single table, **concrete table inheritance**, where each type of class is represented by independent tables, and **joined table inheritance**, where the class hierarchy is broken up among dependent tables, each class represented by its own table that only includes those attributes local to that class. The most common forms of inheritance are single and joined table, while concrete inheritance presents more configurational challenges. When mappers are configured in an inheritance relationship, SQLAlchemy has the ability to load elements :term:`polymorphically`, meaning that a single query can return objects of multiple types. Joined Table Inheritance ------------------------- In joined table inheritance, each class along a particular classes' list of parents is represented by a unique table. The total set of attributes for a particular instance is represented as a join along all tables in its inheritance path. Here, we first define the ``Employee`` class. This table will contain a primary key column (or columns), and a column for each attribute that's represented by ``Employee``. In this case it's just ``name``:: class Employee(Base): __tablename__ = 'employee' id = Column(Integer, primary_key=True) name = Column(String(50)) type = Column(String(50)) __mapper_args__ = { 'polymorphic_identity':'employee', 'polymorphic_on':type } The mapped table also has a column called ``type``. The purpose of this column is to act as the **discriminator**, and stores a value which indicates the type of object represented within the row. The column may be of any datatype, though string and integer are the most common. .. warning:: Currently, **only one discriminator column may be set**, typically on the base-most class in the hierarchy. "Cascading" polymorphic columns are not yet supported. The discriminator column is only needed if polymorphic loading is desired, as is usually the case. It is not strictly necessary that it be present directly on the base mapped table, and can instead be defined on a derived select statement that's used when the class is queried; however, this is a much more sophisticated configuration scenario. The mapping receives additional arguments via the ``__mapper_args__`` dictionary. Here the ``type`` column is explicitly stated as the discriminator column, and the **polymorphic identity** of ``employee`` is also given; this is the value that will be stored in the polymorphic discriminator column for instances of this class. We next define ``Engineer`` and ``Manager`` subclasses of ``Employee``. Each contains columns that represent the attributes unique to the subclass they represent. Each table also must contain a primary key column (or columns), and in most cases a foreign key reference to the parent table:: class Engineer(Employee): __tablename__ = 'engineer' id = Column(Integer, ForeignKey('employee.id'), primary_key=True) engineer_name = Column(String(30)) __mapper_args__ = { 'polymorphic_identity':'engineer', } class Manager(Employee): __tablename__ = 'manager' id = Column(Integer, ForeignKey('employee.id'), primary_key=True) manager_name = Column(String(30)) __mapper_args__ = { 'polymorphic_identity':'manager', } It is standard practice that the same column is used for both the role of primary key as well as foreign key to the parent table, and that the column is also named the same as that of the parent table. However, both of these practices are optional. Separate columns may be used for primary key and parent-relationship, the column may be named differently than that of the parent, and even a custom join condition can be specified between parent and child tables instead of using a foreign key. .. topic:: Joined inheritance primary keys One natural effect of the joined table inheritance configuration is that the identity of any mapped object can be determined entirely from the base table. This has obvious advantages, so SQLAlchemy always considers the primary key columns of a joined inheritance class to be those of the base table only. In other words, the ``id`` columns of both the ``engineer`` and ``manager`` tables are not used to locate ``Engineer`` or ``Manager`` objects - only the value in ``employee.id`` is considered. ``engineer.id`` and ``manager.id`` are still of course critical to the proper operation of the pattern overall as they are used to locate the joined row, once the parent row has been determined within a statement. With the joined inheritance mapping complete, querying against ``Employee`` will return a combination of ``Employee``, ``Engineer`` and ``Manager`` objects. Newly saved ``Engineer``, ``Manager``, and ``Employee`` objects will automatically populate the ``employee.type`` column with ``engineer``, ``manager``, or ``employee``, as appropriate. .. _with_polymorphic: Basic Control of Which Tables are Queried ++++++++++++++++++++++++++++++++++++++++++ The :func:`.orm.with_polymorphic` function and the :func:`~sqlalchemy.orm.query.Query.with_polymorphic` method of :class:`~sqlalchemy.orm.query.Query` affects the specific tables which the :class:`.Query` selects from. Normally, a query such as this:: session.query(Employee).all() ...selects only from the ``employee`` table. When loading fresh from the database, our joined-table setup will query from the parent table only, using SQL such as this: .. sourcecode:: python+sql {opensql} SELECT employee.id AS employee_id, employee.name AS employee_name, employee.type AS employee_type FROM employee [] As attributes are requested from those ``Employee`` objects which are represented in either the ``engineer`` or ``manager`` child tables, a second load is issued for the columns in that related row, if the data was not already loaded. So above, after accessing the objects you'd see further SQL issued along the lines of: .. sourcecode:: python+sql {opensql} SELECT manager.id AS manager_id, manager.manager_data AS manager_manager_data FROM manager WHERE ? = manager.id [5] SELECT engineer.id AS engineer_id, engineer.engineer_info AS engineer_engineer_info FROM engineer WHERE ? = engineer.id [2] This behavior works well when issuing searches for small numbers of items, such as when using :meth:`.Query.get`, since the full range of joined tables are not pulled in to the SQL statement unnecessarily. But when querying a larger span of rows which are known to be of many types, you may want to actively join to some or all of the joined tables. The ``with_polymorphic`` feature provides this. Telling our query to polymorphically load ``Engineer`` and ``Manager`` objects, we can use the :func:`.orm.with_polymorphic` function to create a new aliased class which represents a select of the base table combined with outer joins to each of the inheriting tables:: from sqlalchemy.orm import with_polymorphic eng_plus_manager = with_polymorphic(Employee, [Engineer, Manager]) query = session.query(eng_plus_manager) The above produces a query which joins the ``employee`` table to both the ``engineer`` and ``manager`` tables like the following: .. sourcecode:: python+sql query.all() {opensql} SELECT employee.id AS employee_id, engineer.id AS engineer_id, manager.id AS manager_id, employee.name AS employee_name, employee.type AS employee_type, engineer.engineer_info AS engineer_engineer_info, manager.manager_data AS manager_manager_data FROM employee LEFT OUTER JOIN engineer ON employee.id = engineer.id LEFT OUTER JOIN manager ON employee.id = manager.id [] The entity returned by :func:`.orm.with_polymorphic` is an :class:`.AliasedClass` object, which can be used in a :class:`.Query` like any other alias, including named attributes for those attributes on the ``Employee`` class. In our example, ``eng_plus_manager`` becomes the entity that we use to refer to the three-way outer join above. It also includes namespaces for each class named in the list of classes, so that attributes specific to those subclasses can be called upon as well. The following example illustrates calling upon attributes specific to ``Engineer`` as well as ``Manager`` in terms of ``eng_plus_manager``:: eng_plus_manager = with_polymorphic(Employee, [Engineer, Manager]) query = session.query(eng_plus_manager).filter( or_( eng_plus_manager.Engineer.engineer_info=='x', eng_plus_manager.Manager.manager_data=='y' ) ) :func:`.orm.with_polymorphic` accepts a single class or mapper, a list of classes/mappers, or the string ``'*'`` to indicate all subclasses: .. sourcecode:: python+sql # join to the engineer table entity = with_polymorphic(Employee, Engineer) # join to the engineer and manager tables entity = with_polymorphic(Employee, [Engineer, Manager]) # join to all subclass tables entity = query.with_polymorphic(Employee, '*') # use with Query session.query(entity).all() It also accepts a third argument ``selectable`` which replaces the automatic join creation and instead selects directly from the selectable given. This feature is normally used with "concrete" inheritance, described later, but can be used with any kind of inheritance setup in the case that specialized SQL should be used to load polymorphically:: # custom selectable employee = Employee.__table__ manager = Manager.__table__ engineer = Engineer.__table__ entity = with_polymorphic( Employee, [Engineer, Manager], employee.outerjoin(manager).outerjoin(engineer) ) # use with Query session.query(entity).all() Note that if you only need to load a single subtype, such as just the ``Engineer`` objects, :func:`.orm.with_polymorphic` is not needed since you would query against the ``Engineer`` class directly. :meth:`.Query.with_polymorphic` has the same purpose as :func:`.orm.with_polymorphic`, except is not as flexible in its usage patterns in that it only applies to the first full mapping, which then impacts all occurrences of that class or the target subclasses within the :class:`.Query`. For simple cases it might be considered to be more succinct:: session.query(Employee).with_polymorphic([Engineer, Manager]).\ filter(or_(Engineer.engineer_info=='w', Manager.manager_data=='q')) .. versionadded:: 0.8 :func:`.orm.with_polymorphic`, an improved version of :meth:`.Query.with_polymorphic` method. The mapper also accepts ``with_polymorphic`` as a configurational argument so that the joined-style load will be issued automatically. This argument may be the string ``'*'``, a list of classes, or a tuple consisting of either, followed by a selectable:: class Employee(Base): __tablename__ = 'employee' id = Column(Integer, primary_key=True) type = Column(String(20)) __mapper_args__ = { 'polymorphic_on':type, 'polymorphic_identity':'employee', 'with_polymorphic':'*' } class Engineer(Employee): __tablename__ = 'engineer' id = Column(Integer, ForeignKey('employee.id'), primary_key=True) __mapper_args__ = {'polymorphic_identity':'engineer'} class Manager(Employee): __tablename__ = 'manager' id = Column(Integer, ForeignKey('employee.id'), primary_key=True) __mapper_args__ = {'polymorphic_identity':'manager'} The above mapping will produce a query similar to that of ``with_polymorphic('*')`` for every query of ``Employee`` objects. Using :func:`.orm.with_polymorphic` or :meth:`.Query.with_polymorphic` will override the mapper-level ``with_polymorphic`` setting. .. autofunction:: sqlalchemy.orm.with_polymorphic Advanced Control of Which Tables are Queried +++++++++++++++++++++++++++++++++++++++++++++ The ``with_polymorphic`` functions work fine for simplistic scenarios. However, direct control of table rendering is called for, such as the case when one wants to render to only the subclass table and not the parent table. This use case can be achieved by using the mapped :class:`.Table` objects directly. For example, to query the name of employees with particular criterion:: engineer = Engineer.__table__ manager = Manager.__table__ session.query(Employee.name).\ outerjoin((engineer, engineer.c.employee_id==Employee.employee_id)).\ outerjoin((manager, manager.c.employee_id==Employee.employee_id)).\ filter(or_(Engineer.engineer_info=='w', Manager.manager_data=='q')) The base table, in this case the "employees" table, isn't always necessary. A SQL query is always more efficient with fewer joins. Here, if we wanted to just load information specific to manager or engineer, we can instruct :class:`.Query` to use only those tables. The ``FROM`` clause is determined by what's specified in the :meth:`.Session.query`, :meth:`.Query.filter`, or :meth:`.Query.select_from` methods:: session.query(Manager.manager_data).select_from(manager) session.query(engineer.c.id).\ filter(engineer.c.engineer_info==manager.c.manager_data) .. _of_type: Creating Joins to Specific Subtypes +++++++++++++++++++++++++++++++++++ The :func:`~sqlalchemy.orm.interfaces.PropComparator.of_type` method is a helper which allows the construction of joins along :func:`~sqlalchemy.orm.relationship` paths while narrowing the criterion to specific subclasses. Suppose the ``employees`` table represents a collection of employees which are associated with a ``Company`` object. We'll add a ``company_id`` column to the ``employees`` table and a new table ``companies``: .. sourcecode:: python+sql class Company(Base): __tablename__ = 'company' id = Column(Integer, primary_key=True) name = Column(String(50)) employees = relationship("Employee", backref='company', cascade='all, delete-orphan') class Employee(Base): __tablename__ = 'employee' id = Column(Integer, primary_key=True) type = Column(String(20)) company_id = Column(Integer, ForeignKey('company.id')) __mapper_args__ = { 'polymorphic_on':type, 'polymorphic_identity':'employee', 'with_polymorphic':'*' } class Engineer(Employee): __tablename__ = 'engineer' id = Column(Integer, ForeignKey('employee.id'), primary_key=True) engineer_info = Column(String(50)) __mapper_args__ = {'polymorphic_identity':'engineer'} class Manager(Employee): __tablename__ = 'manager' id = Column(Integer, ForeignKey('employee.id'), primary_key=True) manager_data = Column(String(50)) __mapper_args__ = {'polymorphic_identity':'manager'} When querying from ``Company`` onto the ``Employee`` relationship, the ``join()`` method as well as the ``any()`` and ``has()`` operators will create a join from ``company`` to ``employee``, without including ``engineer`` or ``manager`` in the mix. If we wish to have criterion which is specifically against the ``Engineer`` class, we can tell those methods to join or subquery against the joined table representing the subclass using the :meth:`~.orm.interfaces.PropComparator.of_type` operator:: session.query(Company).\ join(Company.employees.of_type(Engineer)).\ filter(Engineer.engineer_info=='someinfo') A longhand version of this would involve spelling out the full target selectable within a 2-tuple:: employee = Employee.__table__ engineer = Engineer.__table__ session.query(Company).\ join((employee.join(engineer), Company.employees)).\ filter(Engineer.engineer_info=='someinfo') :func:`~sqlalchemy.orm.interfaces.PropComparator.of_type` accepts a single class argument. More flexibility can be achieved either by joining to an explicit join as above, or by using the :func:`.orm.with_polymorphic` function to create a polymorphic selectable:: manager_and_engineer = with_polymorphic( Employee, [Manager, Engineer], aliased=True) session.query(Company).\ join(manager_and_engineer, Company.employees).\ filter( or_(manager_and_engineer.Engineer.engineer_info=='someinfo', manager_and_engineer.Manager.manager_data=='somedata') ) Above, we use the ``aliased=True`` argument with :func:`.orm.with_polymorhpic` so that the right hand side of the join between ``Company`` and ``manager_and_engineer`` is converted into an aliased subquery. Some backends, such as SQLite and older versions of MySQL can't handle a FROM clause of the following form:: FROM x JOIN (y JOIN z ON ) ON Using ``aliased=True`` instead renders it more like:: FROM x JOIN (SELECT * FROM y JOIN z ON ) AS anon_1 ON The above join can also be expressed more succinctly by combining ``of_type()`` with the polymorphic construct:: manager_and_engineer = with_polymorphic( Employee, [Manager, Engineer], aliased=True) session.query(Company).\ join(Company.employees.of_type(manager_and_engineer)).\ filter( or_(manager_and_engineer.Engineer.engineer_info=='someinfo', manager_and_engineer.Manager.manager_data=='somedata') ) The ``any()`` and ``has()`` operators also can be used with :func:`~sqlalchemy.orm.interfaces.PropComparator.of_type` when the embedded criterion is in terms of a subclass:: session.query(Company).\ filter( Company.employees.of_type(Engineer). any(Engineer.engineer_info=='someinfo') ).all() Note that the ``any()`` and ``has()`` are both shorthand for a correlated EXISTS query. To build one by hand looks like:: session.query(Company).filter( exists([1], and_(Engineer.engineer_info=='someinfo', employees.c.company_id==companies.c.company_id), from_obj=employees.join(engineers) ) ).all() The EXISTS subquery above selects from the join of ``employees`` to ``engineers``, and also specifies criterion which correlates the EXISTS subselect back to the parent ``companies`` table. .. versionadded:: 0.8 :func:`~sqlalchemy.orm.interfaces.PropComparator.of_type` accepts :func:`.orm.aliased` and :func:`.orm.with_polymorphic` constructs in conjunction with :meth:`.Query.join`, ``any()`` and ``has()``. .. _eagerloading_polymorphic_subtypes: Eager Loading of Specific or Polymorphic Subtypes ++++++++++++++++++++++++++++++++++++++++++++++++++ The :func:`.joinedload`, :func:`.subqueryload`, :func:`.contains_eager` and other loading-related options also support paths which make use of :func:`~sqlalchemy.orm.interfaces.PropComparator.of_type`. Below we load ``Company`` rows while eagerly loading related ``Engineer`` objects, querying the ``employee`` and ``engineer`` tables simultaneously:: session.query(Company).\ options( subqueryload(Company.employees.of_type(Engineer)). subqueryload("machines") ) ) As is the case with :meth:`.Query.join`, :meth:`~PropComparator.of_type` also can be used with eager loading and :func:`.orm.with_polymorphic` at the same time, so that all sub-attributes of all referenced subtypes can be loaded:: manager_and_engineer = with_polymorphic( Employee, [Manager, Engineer], aliased=True) session.query(Company).\ options( joinedload(Company.employees.of_type(manager_and_engineer)) ) ) .. versionadded:: 0.8 :func:`.joinedload`, :func:`.subqueryload`, :func:`.contains_eager` and related loader options support paths that are qualified with :func:`~sqlalchemy.orm.interfaces.PropComparator.of_type`, supporting single target types as well as :func:`.orm.with_polymorphic` targets. Another option for the above query is to state the two subtypes separately; the :func:`.joinedload` directive should detect this and create the above ``with_polymorphic`` construct automatically:: session.query(Company).\ options( joinedload(Company.employees.of_type(Manager)), joinedload(Company.employees.of_type(Engineer)), ) ) .. versionadded:: 1.0 Eager loaders such as :func:`.joinedload` will create a polymorphic entity when multiple overlapping :meth:`~PropComparator.of_type` directives are encountered. Single Table Inheritance ------------------------ Single table inheritance is where the attributes of the base class as well as all subclasses are represented within a single table. A column is present in the table for every attribute mapped to the base class and all subclasses; the columns which correspond to a single subclass are nullable. This configuration looks much like joined-table inheritance except there's only one table. In this case, a ``type`` column is required, as there would be no other way to discriminate between classes. The table is specified in the base mapper only; for the inheriting classes, leave their ``table`` parameter blank: .. sourcecode:: python+sql class Employee(Base): __tablename__ = 'employee' id = Column(Integer, primary_key=True) name = Column(String(50)) manager_data = Column(String(50)) engineer_info = Column(String(50)) type = Column(String(20)) __mapper_args__ = { 'polymorphic_on':type, 'polymorphic_identity':'employee' } class Manager(Employee): __mapper_args__ = { 'polymorphic_identity':'manager' } class Engineer(Employee): __mapper_args__ = { 'polymorphic_identity':'engineer' } Note that the mappers for the derived classes Manager and Engineer omit the ``__tablename__``, indicating they do not have a mapped table of their own. .. _concrete_inheritance: Concrete Table Inheritance -------------------------- .. note:: this section is currently using classical mappings. The Declarative system fully supports concrete inheritance however. See the links below for more information on using declarative with concrete table inheritance. This form of inheritance maps each class to a distinct table, as below: .. sourcecode:: python+sql employees_table = Table('employees', metadata, Column('employee_id', Integer, primary_key=True), Column('name', String(50)), ) managers_table = Table('managers', metadata, Column('employee_id', Integer, primary_key=True), Column('name', String(50)), Column('manager_data', String(50)), ) engineers_table = Table('engineers', metadata, Column('employee_id', Integer, primary_key=True), Column('name', String(50)), Column('engineer_info', String(50)), ) Notice in this case there is no ``type`` column. If polymorphic loading is not required, there's no advantage to using ``inherits`` here; you just define a separate mapper for each class. .. sourcecode:: python+sql mapper(Employee, employees_table) mapper(Manager, managers_table) mapper(Engineer, engineers_table) To load polymorphically, the ``with_polymorphic`` argument is required, along with a selectable indicating how rows should be loaded. In this case we must construct a UNION of all three tables. SQLAlchemy includes a helper function to create these called :func:`~sqlalchemy.orm.util.polymorphic_union`, which will map all the different columns into a structure of selects with the same numbers and names of columns, and also generate a virtual ``type`` column for each subselect: .. sourcecode:: python+sql pjoin = polymorphic_union({ 'employee': employees_table, 'manager': managers_table, 'engineer': engineers_table }, 'type', 'pjoin') employee_mapper = mapper(Employee, employees_table, with_polymorphic=('*', pjoin), polymorphic_on=pjoin.c.type, polymorphic_identity='employee') manager_mapper = mapper(Manager, managers_table, inherits=employee_mapper, concrete=True, polymorphic_identity='manager') engineer_mapper = mapper(Engineer, engineers_table, inherits=employee_mapper, concrete=True, polymorphic_identity='engineer') Upon select, the polymorphic union produces a query like this: .. sourcecode:: python+sql session.query(Employee).all() {opensql} SELECT pjoin.type AS pjoin_type, pjoin.manager_data AS pjoin_manager_data, pjoin.employee_id AS pjoin_employee_id, pjoin.name AS pjoin_name, pjoin.engineer_info AS pjoin_engineer_info FROM ( SELECT employees.employee_id AS employee_id, CAST(NULL AS VARCHAR(50)) AS manager_data, employees.name AS name, CAST(NULL AS VARCHAR(50)) AS engineer_info, 'employee' AS type FROM employees UNION ALL SELECT managers.employee_id AS employee_id, managers.manager_data AS manager_data, managers.name AS name, CAST(NULL AS VARCHAR(50)) AS engineer_info, 'manager' AS type FROM managers UNION ALL SELECT engineers.employee_id AS employee_id, CAST(NULL AS VARCHAR(50)) AS manager_data, engineers.name AS name, engineers.engineer_info AS engineer_info, 'engineer' AS type FROM engineers ) AS pjoin [] Concrete Inheritance with Declarative ++++++++++++++++++++++++++++++++++++++ .. versionadded:: 0.7.3 The :ref:`declarative_toplevel` module includes helpers for concrete inheritance. See :ref:`declarative_concrete_helpers` for more information. Using Relationships with Inheritance ------------------------------------ Both joined-table and single table inheritance scenarios produce mappings which are usable in :func:`~sqlalchemy.orm.relationship` functions; that is, it's possible to map a parent object to a child object which is polymorphic. Similarly, inheriting mappers can have :func:`~sqlalchemy.orm.relationship` objects of their own at any level, which are inherited to each child class. The only requirement for relationships is that there is a table relationship between parent and child. An example is the following modification to the joined table inheritance example, which sets a bi-directional relationship between ``Employee`` and ``Company``: .. sourcecode:: python+sql employees_table = Table('employees', metadata, Column('employee_id', Integer, primary_key=True), Column('name', String(50)), Column('company_id', Integer, ForeignKey('companies.company_id')) ) companies = Table('companies', metadata, Column('company_id', Integer, primary_key=True), Column('name', String(50))) class Company(object): pass mapper(Company, companies, properties={ 'employees': relationship(Employee, backref='company') }) Relationships with Concrete Inheritance +++++++++++++++++++++++++++++++++++++++ In a concrete inheritance scenario, mapping relationships is more challenging since the distinct classes do not share a table. In this case, you *can* establish a relationship from parent to child if a join condition can be constructed from parent to child, if each child table contains a foreign key to the parent: .. sourcecode:: python+sql companies = Table('companies', metadata, Column('id', Integer, primary_key=True), Column('name', String(50))) employees_table = Table('employees', metadata, Column('employee_id', Integer, primary_key=True), Column('name', String(50)), Column('company_id', Integer, ForeignKey('companies.id')) ) managers_table = Table('managers', metadata, Column('employee_id', Integer, primary_key=True), Column('name', String(50)), Column('manager_data', String(50)), Column('company_id', Integer, ForeignKey('companies.id')) ) engineers_table = Table('engineers', metadata, Column('employee_id', Integer, primary_key=True), Column('name', String(50)), Column('engineer_info', String(50)), Column('company_id', Integer, ForeignKey('companies.id')) ) mapper(Employee, employees_table, with_polymorphic=('*', pjoin), polymorphic_on=pjoin.c.type, polymorphic_identity='employee') mapper(Manager, managers_table, inherits=employee_mapper, concrete=True, polymorphic_identity='manager') mapper(Engineer, engineers_table, inherits=employee_mapper, concrete=True, polymorphic_identity='engineer') mapper(Company, companies, properties={ 'employees': relationship(Employee) }) The big limitation with concrete table inheritance is that :func:`~sqlalchemy.orm.relationship` objects placed on each concrete mapper do **not** propagate to child mappers. If you want to have the same :func:`~sqlalchemy.orm.relationship` objects set up on all concrete mappers, they must be configured manually on each. To configure back references in such a configuration the ``back_populates`` keyword may be used instead of ``backref``, such as below where both ``A(object)`` and ``B(A)`` bidirectionally reference ``C``:: ajoin = polymorphic_union({ 'a':a_table, 'b':b_table }, 'type', 'ajoin') mapper(A, a_table, with_polymorphic=('*', ajoin), polymorphic_on=ajoin.c.type, polymorphic_identity='a', properties={ 'some_c':relationship(C, back_populates='many_a') }) mapper(B, b_table,inherits=A, concrete=True, polymorphic_identity='b', properties={ 'some_c':relationship(C, back_populates='many_a') }) mapper(C, c_table, properties={ 'many_a':relationship(A, collection_class=set, back_populates='some_c'), }) Using Inheritance with Declarative ----------------------------------- Declarative makes inheritance configuration more intuitive. See the docs at :ref:`declarative_inheritance`.