.. _inheritance_loading_toplevel: .. currentmodule:: sqlalchemy.orm Loading Inheritance Hierarchies =============================== When classes are mapped in inheritance hierarchies using the "joined", "single", or "concrete" table inheritance styles as described at :ref:`inheritance_toplevel`, the usual behavior is that a query for a particular base class will also yield objects corresponding to subclasses as well. When a single query is capable of returning a result with a different class or subclasses per result row, we use the term "polymorphic loading". Within the realm of polymorphic loading, specifically with joined and single table inheritance, there is an additional problem of which subclass attributes are to be queried up front, and which are to be loaded later. When an attribute of a particular subclass is queried up front, we can use it in our query as something to filter on, and it also will be loaded when we get our objects back. If it's not queried up front, it gets loaded later when we first need to access it. Basic control of this behavior is provided using the :func:`.orm.with_polymorphic` function, as well as two variants, the mapper configuration :paramref:`.mapper.with_polymorphic` in conjunction with the :paramref:`.mapper.polymorphic_load` option, and the :class:`.Query` -level :meth:`.Query.with_polymorphic` method. The "with_polymorphic" family each provide a means of specifying which specific subclasses of a particular base class should be included within a query, which implies what columns and tables will be available in the SELECT. .. _with_polymorphic: Using with_polymorphic ---------------------- For the following sections, assume the ``Employee`` / ``Engineer`` / ``Manager`` examples introduced in :ref:`inheritance_toplevel`. Normally, when a :class:`.Query` specifies the base class of an inheritance hierarchy, only the columns that are local to that base class are queried:: session.query(Employee).all() Above, for both single and joined table inheritance, only the columns local to ``Employee`` will be present in the SELECT. We may get back instances of ``Engineer`` or ``Manager``, however they will not have the additional attributes loaded until we first access them, at which point a lazy load is emitted. Similarly, if we wanted to refer to columns mapped to ``Engineer`` or ``Manager`` in our query that's against ``Employee``, these columns aren't available directly in either the single or joined table inheritance case, since the ``Employee`` entity does not refer to these columns (note that for single-table inheritance, this is common if Declarative is used, but not for a classical mapping). To solve both of these issues, the :func:`.orm.with_polymorphic` function provides a special :class:`.AliasedClass` that represents a range of columns across subclasses. This object can be used in a :class:`.Query` like any other alias. When queried, it represents all the columns present in the classes given:: from sqlalchemy.orm import with_polymorphic eng_plus_manager = with_polymorphic(Employee, [Engineer, Manager]) query = session.query(eng_plus_manager) If the above mapping were using joined table inheritance, the SELECT statement for the above would be: .. 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 [] Where above, the additional tables / columns for "engineer" and "manager" are included. Similar behavior occurs in the case of single table inheritance. :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 # include columns for Engineer entity = with_polymorphic(Employee, Engineer) # include columns for Engineer, Manager entity = with_polymorphic(Employee, [Engineer, Manager]) # include columns for all mapped subclasses entity = with_polymorphic(Employee, '*') Using aliasing with with_polymorphic ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The :func:`.orm.with_polymorphic` function also provides "aliasing" of the polymorphic selectable itself, meaning, two different :func:`.orm.with_polymorphic` entities, referring to the same class hierarchy, can be used together. This is available using the :paramref:`.orm.with_polymorphic.aliased` flag. For a polymorphic selectable that is across multiple tables, the default behavior is to wrap the selectable into a subquery. Below we emit a query that will select for "employee or manager" paired with "employee or engineer" on employees with the same name: .. sourcecode:: python+sql engineer_employee = with_polymorphic( Employee, [Engineer], aliased=True) manager_employee = with_polymorphic( Employee, [Manager], aliased=True) q = s.query(engineer_employee, manager_employee).\ join( manager_employee, and_( engineer_employee.id > manager_employee.id, engineer_employee.name == manager_employee.name ) ) q.all() {opensql} SELECT anon_1.employee_id AS anon_1_employee_id, anon_1.employee_name AS anon_1_employee_name, anon_1.employee_type AS anon_1_employee_type, anon_1.engineer_id AS anon_1_engineer_id, anon_1.engineer_engineer_name AS anon_1_engineer_engineer_name, anon_2.employee_id AS anon_2_employee_id, anon_2.employee_name AS anon_2_employee_name, anon_2.employee_type AS anon_2_employee_type, anon_2.manager_id AS anon_2_manager_id, anon_2.manager_manager_name AS anon_2_manager_manager_name FROM ( SELECT employee.id AS employee_id, employee.name AS employee_name, employee.type AS employee_type, engineer.id AS engineer_id, engineer.engineer_name AS engineer_engineer_name FROM employee LEFT OUTER JOIN engineer ON employee.id = engineer.id ) AS anon_1 JOIN ( SELECT employee.id AS employee_id, employee.name AS employee_name, employee.type AS employee_type, manager.id AS manager_id, manager.manager_name AS manager_manager_name FROM employee LEFT OUTER JOIN manager ON employee.id = manager.id ) AS anon_2 ON anon_1.employee_id > anon_2.employee_id AND anon_1.employee_name = anon_2.employee_name The creation of subqueries above is very verbose. While it creates the best encapsulation of the two distinct queries, it may be inefficient. :func:`.orm.with_polymorphic` includes an additional flag to help with this situation, :paramref:`.orm.with_polymorphic.flat`, which will "flatten" the subquery / join combination into straight joins, applying aliasing to the individual tables instead. Setting :paramref:`.orm.with_polymorphic.flat` implies :paramref:`.orm.with_polymorphic.aliased`, so only one flag is necessary: .. sourcecode:: python+sql engineer_employee = with_polymorphic( Employee, [Engineer], flat=True) manager_employee = with_polymorphic( Employee, [Manager], flat=True) q = s.query(engineer_employee, manager_employee).\ join( manager_employee, and_( engineer_employee.id > manager_employee.id, engineer_employee.name == manager_employee.name ) ) q.all() {opensql} SELECT employee_1.id AS employee_1_id, employee_1.name AS employee_1_name, employee_1.type AS employee_1_type, engineer_1.id AS engineer_1_id, engineer_1.engineer_name AS engineer_1_engineer_name, employee_2.id AS employee_2_id, employee_2.name AS employee_2_name, employee_2.type AS employee_2_type, manager_1.id AS manager_1_id, manager_1.manager_name AS manager_1_manager_name FROM employee AS employee_1 LEFT OUTER JOIN engineer AS engineer_1 ON employee_1.id = engineer_1.id JOIN ( employee AS employee_2 LEFT OUTER JOIN manager AS manager_1 ON employee_2.id = manager_1.id ) ON employee_1.id > employee_2.id AND employee_1.name = employee_2.name Note above, when using :paramref:`.orm.with_polymorphic.flat`, it is often the case when used in conjunction with joined table inheritance that we get a right-nested JOIN in our statement. Some older databases, in particular older versions of SQLite, may have a problem with this syntax, although virtually all modern database versions now support this syntax. Referring to Specific Subclass Attributes ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 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 previous 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' ) ) .. _with_polymorphic_mapper_config: Setting with_polymorphic at mapper configuration time ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The :func:`.orm.with_polymorphic` function serves the purpose of allowing "eager" loading of attributes from subclass tables, as well as the ability to refer to the attributes from subclass tables at query time. Historically, the "eager loading" of columns has been the more important part of the equation. So just as eager loading for relationships can be specified as a configurational option, the :paramref:`.mapper.with_polymorphic` configuration parameter allows an entity to use a polymorphic load by default. We can add the parameter to our ``Employee`` mapping first introduced at :ref:`joined_inheritance`:: 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, 'with_polymorphic': '*' } Above is a common setting for :paramref:`.mapper.with_polymorphic`, which is to indicate an asterisk to load all subclass columns. In the case of joined table inheritance, this option should be used sparingly, as it implies that the mapping will always emit a (often large) series of LEFT OUTER JOIN to many tables, which is not efficient from a SQL perspective. For single table inheritance, specifying the asterisk is often a good idea as the load is still against a single table only, but an additional lazy load of subclass-mapped columns will be prevented. Using :func:`.orm.with_polymorphic` or :meth:`.Query.with_polymorphic` will override the mapper-level :paramref:`.mapper.with_polymorphic` setting. The :paramref:`.mapper.with_polymorphic` option also accepts a list of classes just like :func:`.orm.with_polymorphic` to polymorphically load among a subset of classes. However, when using Declarative, providing classes to this list is not directly possible as the subclasses we'd like to add are not available yet. Instead, we can specify on each subclass that they should individually participate in polymorphic loading by default using the :paramref:`.mapper.polymorphic_load` parameter:: class Engineer(Employee): __tablename__ = 'engineer' id = Column(Integer, ForeignKey('employee.id'), primary_key=True) engineer_info = Column(String(50)) __mapper_args__ = { 'polymorphic_identity':'engineer', 'polymorphic_load': 'inline' } class Manager(Employee): __tablename__ = 'manager' id = Column(Integer, ForeignKey('employee.id'), primary_key=True) manager_data = Column(String(50)) __mapper_args__ = { 'polymorphic_identity':'manager', 'polymorphic_load': 'inline' } Setting the :paramref:`.mapper.polymorphic_load` parameter to the value ``"inline"`` means that the ``Engineer`` and ``Manager`` classes above are part of the "polymorphic load" of the base ``Employee`` class by default, exactly as though they had been appended to the :paramref:`.mapper.with_polymorphic` list of classes. Setting with_polymorphic against a query ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The :func:`.orm.with_polymorphic` function evolved from a query-level method :meth:`.Query.with_polymorphic`. This method 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 entity of the :class:`.Query`. It then takes effect for all occurences of that entity, so that the entity (and its subclasses) can be referred to directly, rather than using an alias object. 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' ) ) The :meth:`.Query.with_polymorphic` method has a more complicated job than the :func:`.orm.with_polymorphic` function, as it needs to correctly transform entities like ``Engineer`` and ``Manager`` appropriately, but not interfere with other entities. If its flexibility is lacking, switch to using :func:`.orm.with_polymorphic`. .. _polymorphic_selectin: Polymorphic Selectin Loading ---------------------------- An alternative to using the :func:`.orm.with_polymorphic` family of functions to "eagerly" load the additional subclasses on an inheritance mapping, primarily when using joined table inheritance, is to use polymorphic "selectin" loading. This is an eager loading feature which works similarly to the :ref:`selectin_eager_loading` feature of relationship loading. Given our example mapping, we can instruct a load of ``Employee`` to emit an extra SELECT per subclass by using the :func:`.orm.selectin_polymorphic` loader option:: from sqlalchemy.orm import selectin_polymorphic query = session.query(Employee).options( selectin_polymorphic(Employee, [Manager, Engineer]) ) When the above query is run, two additional SELECT statements will be emitted: .. sourcecode:: python+sql {opensql}query.all() SELECT employee.id AS employee_id, employee.name AS employee_name, employee.type AS employee_type FROM employee () SELECT engineer.id AS engineer_id, employee.id AS employee_id, employee.type AS employee_type, engineer.engineer_name AS engineer_engineer_name FROM employee JOIN engineer ON employee.id = engineer.id WHERE employee.id IN (?, ?) ORDER BY employee.id (1, 2) SELECT manager.id AS manager_id, employee.id AS employee_id, employee.type AS employee_type, manager.manager_name AS manager_manager_name FROM employee JOIN manager ON employee.id = manager.id WHERE employee.id IN (?) ORDER BY employee.id (3,) We can similarly establish the above style of loading to take place by default by specifying the :paramref:`.mapper.polymorphic_load` parameter, using the value ``"selectin"`` on a per-subclass basis:: 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 } class Engineer(Employee): __tablename__ = 'engineer' id = Column(Integer, ForeignKey('employee.id'), primary_key=True) engineer_name = Column(String(30)) __mapper_args__ = { 'polymorphic_load': 'selectin', '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_load': 'selectin', 'polymorphic_identity': 'manager', } Unlike when using :func:`.orm.with_polymorphic`, when using the :func:`.orm.selectin_polymorphic` style of loading, we do **not** have the ability to refer to the ``Engineer`` or ``Manager`` entities within our main query as filter, order by, or other criteria, as these entities are not present in the initial query that is used to locate results. However, we can apply loader options that apply towards ``Engineer`` or ``Manager``, which will take effect when the secondary SELECT is emitted. Below we assume ``Manager`` has an additional relationship ``Manager.paperwork``, that we'd like to eagerly load as well. We can use any type of eager loading, such as joined eager loading via the :func:`.joinedload` function:: from sqlalchemy.orm import joinedload from sqlalchemy.orm import selectin_polymorphic query = session.query(Employee).options( selectin_polymorphic(Employee, [Manager, Engineer]), joinedload(Manager.paperwork) ) Using the query above, we get three SELECT statements emitted, however the one against ``Manager`` will be: .. sourcecode:: sql SELECT manager.id AS manager_id, employee.id AS employee_id, employee.type AS employee_type, manager.manager_name AS manager_manager_name, paperwork_1.id AS paperwork_1_id, paperwork_1.manager_id AS paperwork_1_manager_id, paperwork_1.data AS paperwork_1_data FROM employee JOIN manager ON employee.id = manager.id LEFT OUTER JOIN paperwork AS paperwork_1 ON manager.id = paperwork_1.manager_id WHERE employee.id IN (?) ORDER BY employee.id (3,) Note that selectin polymorphic loading has similar caveats as that of selectin relationship loading; for entities that make use of a composite primary key, the database in use must support tuples with "IN", currently known to work with MySQL and Postgresql. .. versionadded:: 1.2 .. warning:: The selectin polymorphic loading feature should be considered as **experimental** within early releases of the 1.2 series. .. _polymorphic_selectin_and_withpoly: Combining selectin and with_polymorphic ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ .. note:: works as of 1.2.0b3 With careful planning, selectin loading can be applied against a hierarchy that itself uses "with_polymorphic". A particular use case is that of using selectin loading to load a joined-inheritance subtable, which then uses "with_polymorphic" to refer to further sub-classes, which may be joined- or single-table inheritanace. If we added a class ``VicePresident`` that extends ``Manager`` using single-table inheritance, we could ensure that a load of ``Manager`` also fully loads ``VicePresident`` subtypes at the same time:: # use "Employee" example from the enclosing section class Manager(Employee): __tablename__ = 'manager' id = Column(Integer, ForeignKey('employee.id'), primary_key=True) manager_name = Column(String(30)) __mapper_args__ = { 'polymorphic_load': 'selectin', 'polymorphic_identity': 'manager', } class VicePresident(Manager): vp_info = Column(String(30)) __mapper_args__ = { "polymorphic_load": "inline", "polymorphic_identity": "vp" } Above, we add a ``vp_info`` column to the ``manager`` table, local to the ``VicePresident`` subclass. This subclass is linked to the polymorphic identity ``"vp"`` which refers to rows which have this data. By setting the load style to "inline", it means that a load of ``Manager`` objects will also ensure that the ``vp_info`` column is queried for in the same SELECT statement. A query against ``Employee`` that encounters a ``Manager`` row would emit similarly to the following: .. sourcecode:: sql SELECT employee.id AS employee_id, employee.name AS employee_name, employee.type AS employee_type FROM employee ) SELECT manager.id AS manager_id, employee.id AS employee_id, employee.type AS employee_type, manager.manager_name AS manager_manager_name, manager.vp_info AS manager_vp_info FROM employee JOIN manager ON employee.id = manager.id WHERE employee.id IN (?) ORDER BY employee.id (1,) Combining "selectin" polymorhic loading with query-time :func:`.orm.with_polymorphic` usage is also possible (though this is very outer-space stuff!); assuming the above mappings had no ``polymorphic_load`` set up, we could get the same result as follows:: from sqlalchemy.orm import with_polymorphic, selectin_polymorphic manager_poly = with_polymorphic(Manager, [VicePresident]) s.query(Employee).options( selectin_polymorphic(Employee, [manager_poly])).all() Referring to specific subtypes on relationships ----------------------------------------------- Mapped attributes which correspond to a :func:`.relationship` are used in querying in order to refer to the linkage between two mappings. Common uses for this are to refer to a :func:`.relationship` in :meth:`.Query.join` as well as in loader options like :func:`.joinedload`. When using :func:`.relationship` where the target class is an inheritance hierarchy, the API allows that the join, eager load, or other linkage should target a specific subclass, alias, or :func:`.orm.with_polymorphic` alias, of that class hierarchy, rather than the class directly targeted by the :func:`.relationship`. The :func:`~sqlalchemy.orm.interfaces.PropComparator.of_type` method allows the construction of joins along :func:`~sqlalchemy.orm.relationship` paths while narrowing the criterion to specific derived aliases or 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 class Company(Base): __tablename__ = 'company' id = Column(Integer, primary_key=True) name = Column(String(50)) employees = relationship("Employee", backref='company') 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', } 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 :meth:`.Query.join` method as well as operators like :meth:`.PropComparator.any` and :meth:`.PropComparator.has` 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 set of columns 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') Similarly, to join from ``Company`` to the polymorphic entity that includes both ``Engineer`` and ``Manager`` columns:: manager_and_engineer = with_polymorphic( Employee, [Manager, Engineer]) 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 :meth:`.PropComparator.any` and :meth:`.PropComparator.has` operators also can be used with :func:`~sqlalchemy.orm.interfaces.PropComparator.of_type`, such as 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() .. _eagerloading_polymorphic_subtypes: Eager Loading of Specific or Polymorphic Subtypes ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The :func:`.joinedload`, :func:`.subqueryload`, :func:`.contains_eager` and other eagerloader options support paths which make use of :func:`~.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(Engineer.machines) ) ) As is the case with :meth:`.Query.join`, :meth:`~.PropComparator.of_type` can be used to combine eager loading and :func:`.orm.with_polymorphic`, so that all sub-attributes of all referenced subtypes can be loaded:: manager_and_engineer = with_polymorphic( Employee, [Manager, Engineer], flat=True) session.query(Company).\ options( joinedload( Company.employees.of_type(manager_and_engineer) ) ) When using :func:`.with_polymorphic` in conjunction with :func:`.joinedload`, the :func:`.with_polymorphic` object must include the ``aliased=True`` or ``flat=True`` flag, so that the polymorphic selectable is aliased (an informative error message is raised otherwise). "flat" is an alternate form of aliasing that produces fewer subqueries. Once :meth:`~.PropComparator.of_type` is the target of the eager load, that's the entity we would use for subsequent chaining, not the original class or derived class. If we wanted to further eager load a collection on the eager-loaded ``Engineer`` class, we access this class from the namespace of the :func:`.orm.with_polymorphic` object:: session.query(Company).\ options( joinedload(Company.employees.of_type(manager_and_engineer)).\ subqueryload(manager_and_engineer.Engineer.computers) ) ) .. _loading_joined_inheritance: Loading objects with joined table inheritance --------------------------------------------- When using joined table inheritance, if we query for a specific subclass that represents a JOIN of two tables such as our ``Engineer`` example from the inheritance section, the SQL emitted is a join:: session.query(Engineer).all() The above query will emit SQL like: .. sourcecode:: python+sql {opensql} SELECT employee.id AS employee_id, employee.name AS employee_name, employee.type AS employee_type, engineer.name AS engineer_name FROM employee JOIN engineer ON employee.id = engineer.id We will then get a collection of ``Engineer`` objects back, which will contain all columns from ``employee`` and ``engineer`` loaded. However, when emitting a :class:`.Query` against a base class, the behavior is to load only from the base table:: session.query(Employee).all() Above, the default behavior would be to SELECT only from the ``employee`` table and not from any "sub" tables (``engineer`` and ``manager``, in our previous examples): .. sourcecode:: python+sql {opensql} SELECT employee.id AS employee_id, employee.name AS employee_name, employee.type AS employee_type FROM employee [] After a collection of ``Employee`` objects has been returned from the query, and 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] The :func:`.orm.with_polymorphic` function and related configuration options allow us to instead emit a JOIN up front which will conditionally load against ``employee``, ``engineer``, or ``manager``, very much like joined eager loading works for relationships, removing the necessity for a second per-entity load:: 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 section :ref:`with_polymorphic` discusses the :func:`.orm.with_polymorphic` function and its configurational variants. .. seealso:: :ref:`with_polymorphic` .. _loading_single_inheritance: Loading objects with single table inheritance --------------------------------------------- In modern Declarative, single inheritance mappings produce :class:`.Column` objects that are mapped only to a subclass, and not available from the superclass, even though they are present on the same table. In our example from :ref:`single_inheritance`, the ``Manager`` mapping for example had a :class:`.Column` specified:: class Manager(Employee): manager_data = Column(String(50)) __mapper_args__ = { 'polymorphic_identity':'manager' } Above, there would be no ``Employee.manager_data`` attribute, even though the ``employee`` table has a ``manager_data`` column. A query against ``Manager`` will include this column in the query, as well as an IN clause to limit rows only to ``Manager`` objects: .. sourcecode:: python+sql session.query(Manager).all() {opensql} SELECT employee.id AS employee_id, employee.name AS employee_name, employee.type AS employee_type, employee.manager_data AS employee_manager_data FROM employee WHERE employee.type IN (?) ('manager',) However, in a similar way to that of joined table inheritance, a query against ``Employee`` will only query for columns mapped to ``Employee``: .. sourcecode:: python+sql session.query(Employee).all() {opensql} SELECT employee.id AS employee_id, employee.name AS employee_name, employee.type AS employee_type FROM employee If we get back an instance of ``Manager`` from our result, accessing additional columns only mapped to ``Manager`` emits a lazy load for those columns, in a similar way to joined inheritance:: SELECT employee.manager_data AS employee_manager_data FROM employee WHERE employee.id = ? AND employee.type IN (?) The :func:`.orm.with_polymorphic` function serves a similar role as joined inheritance in the case of single inheritance; it allows both for eager loading of subclass attributes as well as specification of subclasses in a query, just without the overhead of using OUTER JOIN:: employee_poly = with_polymorphic(Employee, '*') q = session.query(employee_poly).filter( or_( employee_poly.name == 'a', employee_poly.Manager.manager_data == 'b' ) ) Above, our query remains against a single table however we can refer to the columns present in ``Manager`` or ``Engineer`` using the "polymorphic" namespace. Since we specified ``"*"`` for the entities, both ``Engineer`` and ``Manager`` will be loaded at once. SQL emitted would be: .. sourcecode:: python+sql q.all() {opensql} SELECT employee.id AS employee_id, employee.name AS employee_name, employee.type AS employee_type, employee.manager_data AS employee_manager_data, employee.engineer_info AS employee_engineer_info FROM employee WHERE employee.name = :name_1 OR employee.manager_data = :manager_data_1 Inheritance Loading API ----------------------- .. autofunction:: sqlalchemy.orm.with_polymorphic .. autofunction:: sqlalchemy.orm.selectin_polymorphic