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https://github.com/moparisthebest/SickRage
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908 lines
36 KiB
Python
908 lines
36 KiB
Python
# ext/automap.py
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# Copyright (C) 2005-2014 the SQLAlchemy authors and contributors <see AUTHORS file>
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#
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# This module is part of SQLAlchemy and is released under
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# the MIT License: http://www.opensource.org/licenses/mit-license.php
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"""Define an extension to the :mod:`sqlalchemy.ext.declarative` system
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which automatically generates mapped classes and relationships from a database
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schema, typically though not necessarily one which is reflected.
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.. versionadded:: 0.9.1 Added :mod:`sqlalchemy.ext.automap`.
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.. note::
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The :mod:`sqlalchemy.ext.automap` extension should be considered
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**experimental** as of 0.9.1. Featureset and API stability is
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not guaranteed at this time.
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It is hoped that the :class:`.AutomapBase` system provides a quick
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and modernized solution to the problem that the very famous
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`SQLSoup <https://sqlsoup.readthedocs.org/en/latest/>`_
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also tries to solve, that of generating a quick and rudimentary object
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model from an existing database on the fly. By addressing the issue strictly
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at the mapper configuration level, and integrating fully with existing
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Declarative class techniques, :class:`.AutomapBase` seeks to provide
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a well-integrated approach to the issue of expediently auto-generating ad-hoc
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mappings.
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Basic Use
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=========
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The simplest usage is to reflect an existing database into a new model.
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We create a new :class:`.AutomapBase` class in a similar manner as to how
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we create a declarative base class, using :func:`.automap_base`.
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We then call :meth:`.AutomapBase.prepare` on the resulting base class,
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asking it to reflect the schema and produce mappings::
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from sqlalchemy.ext.automap import automap_base
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from sqlalchemy.orm import Session
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from sqlalchemy import create_engine
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Base = automap_base()
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# engine, suppose it has two tables 'user' and 'address' set up
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engine = create_engine("sqlite:///mydatabase.db")
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# reflect the tables
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Base.prepare(engine, reflect=True)
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# mapped classes are now created with names by default
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# matching that of the table name.
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User = Base.classes.user
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Address = Base.classes.address
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session = Session(engine)
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# rudimentary relationships are produced
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session.add(Address(email_address="foo@bar.com", user=User(name="foo")))
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session.commit()
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# collection-based relationships are by default named "<classname>_collection"
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print (u1.address_collection)
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Above, calling :meth:`.AutomapBase.prepare` while passing along the
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:paramref:`.AutomapBase.prepare.reflect` parameter indicates that the
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:meth:`.MetaData.reflect` method will be called on this declarative base
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classes' :class:`.MetaData` collection; then, each viable
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:class:`.Table` within the :class:`.MetaData` will get a new mapped class
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generated automatically. The :class:`.ForeignKeyConstraint` objects which
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link the various tables together will be used to produce new, bidirectional
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:func:`.relationship` objects between classes. The classes and relationships
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follow along a default naming scheme that we can customize. At this point,
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our basic mapping consisting of related ``User`` and ``Address`` classes is ready
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to use in the traditional way.
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Generating Mappings from an Existing MetaData
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=============================================
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We can pass a pre-declared :class:`.MetaData` object to :func:`.automap_base`.
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This object can be constructed in any way, including programmatically, from
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a serialized file, or from itself being reflected using :meth:`.MetaData.reflect`.
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Below we illustrate a combination of reflection and explicit table declaration::
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from sqlalchemy import create_engine, MetaData, Table, Column, ForeignKey
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engine = create_engine("sqlite:///mydatabase.db")
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# produce our own MetaData object
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metadata = MetaData()
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# we can reflect it ourselves from a database, using options
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# such as 'only' to limit what tables we look at...
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metadata.reflect(engine, only=['user', 'address'])
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# ... or just define our own Table objects with it (or combine both)
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Table('user_order', metadata,
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Column('id', Integer, primary_key=True),
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Column('user_id', ForeignKey('user.id'))
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)
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# we can then produce a set of mappings from this MetaData.
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Base = automap_base(metadata=metadata)
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# calling prepare() just sets up mapped classes and relationships.
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Base.prepare()
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# mapped classes are ready
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User, Address, Order = Base.classes.user, Base.classes.address, Base.classes.user_order
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Specifying Classes Explcitly
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============================
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The :mod:`.sqlalchemy.ext.automap` extension allows classes to be defined
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explicitly, in a way similar to that of the :class:`.DeferredReflection` class.
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Classes that extend from :class:`.AutomapBase` act like regular declarative
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classes, but are not immediately mapped after their construction, and are instead
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mapped when we call :meth:`.AutomapBase.prepare`. The :meth:`.AutomapBase.prepare`
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method will make use of the classes we've established based on the table name
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we use. If our schema contains tables ``user`` and ``address``, we can define
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one or both of the classes to be used::
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from sqlalchemy.ext.automap import automap_base
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from sqlalchemy import create_engine
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# automap base
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Base = automap_base()
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# pre-declare User for the 'user' table
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class User(Base):
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__tablename__ = 'user'
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# override schema elements like Columns
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user_name = Column('name', String)
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# override relationships too, if desired.
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# we must use the same name that automap would use for the relationship,
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# and also must refer to the class name that automap will generate
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# for "address"
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address_collection = relationship("address", collection_class=set)
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# reflect
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engine = create_engine("sqlite:///mydatabase.db")
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Base.prepare(engine, reflect=True)
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# we still have Address generated from the tablename "address",
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# but User is the same as Base.classes.User now
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Address = Base.classes.address
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u1 = session.query(User).first()
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print (u1.address_collection)
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# the backref is still there:
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a1 = session.query(Address).first()
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print (a1.user)
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Above, one of the more intricate details is that we illustrated overriding
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one of the :func:`.relationship` objects that automap would have created.
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To do this, we needed to make sure the names match up with what automap
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would normally generate, in that the relationship name would be ``User.address_collection``
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and the name of the class referred to, from automap's perspective, is called
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``address``, even though we are referring to it as ``Address`` within our usage
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of this class.
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Overriding Naming Schemes
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=========================
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:mod:`.sqlalchemy.ext.automap` is tasked with producing mapped classes and
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relationship names based on a schema, which means it has decision points in how
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these names are determined. These three decision points are provided using
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functions which can be passed to the :meth:`.AutomapBase.prepare` method, and
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are known as :func:`.classname_for_table`,
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:func:`.name_for_scalar_relationship`,
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and :func:`.name_for_collection_relationship`. Any or all of these
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functions are provided as in the example below, where we use a "camel case"
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scheme for class names and a "pluralizer" for collection names using the
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`Inflect <https://pypi.python.org/pypi/inflect>`_ package::
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import re
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import inflect
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def camelize_classname(base, tablename, table):
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"Produce a 'camelized' class name, e.g. "
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"'words_and_underscores' -> 'WordsAndUnderscores'"
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return str(tablename[0].upper() + \\
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re.sub(r'_(\w)', lambda m: m.group(1).upper(), tablename[1:]))
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_pluralizer = inflect.engine()
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def pluralize_collection(base, local_cls, referred_cls, constraint):
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"Produce an 'uncamelized', 'pluralized' class name, e.g. "
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"'SomeTerm' -> 'some_terms'"
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referred_name = referred_cls.__name__
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uncamelized = referred_name[0].lower() + \\
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re.sub(r'\W',
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lambda m: "_%s" % m.group(0).lower(),
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referred_name[1:])
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pluralized = _pluralizer.plural(uncamelized)
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return pluralized
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from sqlalchemy.ext.automap import automap_base
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Base = automap_base()
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engine = create_engine("sqlite:///mydatabase.db")
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Base.prepare(engine, reflect=True,
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classname_for_table=camelize_classname,
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name_for_collection_relationship=pluralize_collection
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)
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From the above mapping, we would now have classes ``User`` and ``Address``,
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where the collection from ``User`` to ``Address`` is called ``User.addresses``::
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User, Address = Base.classes.User, Base.classes.Address
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u1 = User(addresses=[Address(email="foo@bar.com")])
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Relationship Detection
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======================
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The vast majority of what automap accomplishes is the generation of
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:func:`.relationship` structures based on foreign keys. The mechanism
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by which this works for many-to-one and one-to-many relationships is as follows:
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1. A given :class:`.Table`, known to be mapped to a particular class,
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is examined for :class:`.ForeignKeyConstraint` objects.
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2. From each :class:`.ForeignKeyConstraint`, the remote :class:`.Table`
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object present is matched up to the class to which it is to be mapped,
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if any, else it is skipped.
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3. As the :class:`.ForeignKeyConstraint` we are examining correponds to a reference
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from the immediate mapped class,
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the relationship will be set up as a many-to-one referring to the referred class;
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a corresponding one-to-many backref will be created on the referred class referring
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to this class.
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4. The names of the relationships are determined using the
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:paramref:`.AutomapBase.prepare.name_for_scalar_relationship` and
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:paramref:`.AutomapBase.prepare.name_for_collection_relationship`
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callable functions. It is important to note that the default relationship
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naming derives the name from the **the actual class name**. If you've
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given a particular class an explicit name by declaring it, or specified an
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alternate class naming scheme, that's the name from which the relationship
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name will be derived.
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5. The classes are inspected for an existing mapped property matching these
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names. If one is detected on one side, but none on the other side, :class:`.AutomapBase`
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attempts to create a relationship on the missing side, then uses the
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:paramref:`.relationship.back_populates` parameter in order to point
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the new relationship to the other side.
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6. In the usual case where no relationship is on either side,
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:meth:`.AutomapBase.prepare` produces a :func:`.relationship` on the "many-to-one"
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side and matches it to the other using the :paramref:`.relationship.backref`
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parameter.
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7. Production of the :func:`.relationship` and optionally the :func:`.backref`
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is handed off to the :paramref:`.AutomapBase.prepare.generate_relationship`
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function, which can be supplied by the end-user in order to augment
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the arguments passed to :func:`.relationship` or :func:`.backref` or to
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make use of custom implementations of these functions.
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Custom Relationship Arguments
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-----------------------------
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The :paramref:`.AutomapBase.prepare.generate_relationship` hook can be used
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to add parameters to relationships. For most cases, we can make use of the
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existing :func:`.automap.generate_relationship` function to return
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the object, after augmenting the given keyword dictionary with our own
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arguments.
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Below is an illustration of how to send
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:paramref:`.relationship.cascade` and
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:paramref:`.relationship.passive_deletes`
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options along to all one-to-many relationships::
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from sqlalchemy.ext.automap import generate_relationship
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def _gen_relationship(base, direction, return_fn,
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attrname, local_cls, referred_cls, **kw):
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if direction is interfaces.ONETOMANY:
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kw['cascade'] = 'all, delete-orphan'
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kw['passive_deletes'] = True
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# make use of the built-in function to actually return
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# the result.
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return generate_relationship(base, direction, return_fn,
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attrname, local_cls, referred_cls, **kw)
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from sqlalchemy.ext.automap import automap_base
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from sqlalchemy import create_engine
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# automap base
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Base = automap_base()
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engine = create_engine("sqlite:///mydatabase.db")
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Base.prepare(engine, reflect=True,
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generate_relationship=_gen_relationship)
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Many-to-Many relationships
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--------------------------
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:mod:`.sqlalchemy.ext.automap` will generate many-to-many relationships, e.g.
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those which contain a ``secondary`` argument. The process for producing these
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is as follows:
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1. A given :class:`.Table` is examined for :class:`.ForeignKeyConstraint` objects,
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before any mapped class has been assigned to it.
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2. If the table contains two and exactly two :class:`.ForeignKeyConstraint`
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objects, and all columns within this table are members of these two
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:class:`.ForeignKeyConstraint` objects, the table is assumed to be a
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"secondary" table, and will **not be mapped directly**.
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3. The two (or one, for self-referential) external tables to which the :class:`.Table`
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refers to are matched to the classes to which they will be mapped, if any.
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4. If mapped classes for both sides are located, a many-to-many bi-directional
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:func:`.relationship` / :func:`.backref` pair is created between the two
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classes.
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5. The override logic for many-to-many works the same as that of one-to-many/
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many-to-one; the :func:`.generate_relationship` function is called upon
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to generate the strucures and existing attributes will be maintained.
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Relationships with Inheritance
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------------------------------
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:mod:`.sqlalchemy.ext.automap` will not generate any relationships between
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two classes that are in an inheritance relationship. That is, with two classes
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given as follows::
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class Employee(Base):
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__tablename__ = 'employee'
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id = Column(Integer, primary_key=True)
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type = Column(String(50))
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__mapper_args__ = {
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'polymorphic_identity':'employee', 'polymorphic_on': type
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}
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class Engineer(Employee):
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__tablename__ = 'engineer'
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id = Column(Integer, ForeignKey('employee.id'), primary_key=True)
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__mapper_args__ = {
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'polymorphic_identity':'engineer',
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}
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The foreign key from ``Engineer`` to ``Employee`` is used not for a relationship,
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but to establish joined inheritance between the two classes.
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Note that this means automap will not generate *any* relationships
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for foreign keys that link from a subclass to a superclass. If a mapping
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has actual relationships from subclass to superclass as well, those
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need to be explicit. Below, as we have two separate foreign keys
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from ``Engineer`` to ``Employee``, we need to set up both the relationship
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we want as well as the ``inherit_condition``, as these are not things
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SQLAlchemy can guess::
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class Employee(Base):
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__tablename__ = 'employee'
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id = Column(Integer, primary_key=True)
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type = Column(String(50))
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__mapper_args__ = {
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'polymorphic_identity':'employee', 'polymorphic_on':type
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}
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class Engineer(Employee):
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__tablename__ = 'engineer'
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id = Column(Integer, ForeignKey('employee.id'), primary_key=True)
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favorite_employee_id = Column(Integer, ForeignKey('employee.id'))
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favorite_employee = relationship(Employee, foreign_keys=favorite_employee_id)
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__mapper_args__ = {
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'polymorphic_identity':'engineer',
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'inherit_condition': id == Employee.id
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}
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Using Automap with Explicit Declarations
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========================================
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As noted previously, automap has no dependency on reflection, and can make
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use of any collection of :class:`.Table` objects within a :class:`.MetaData`
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collection. From this, it follows that automap can also be used
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generate missing relationships given an otherwise complete model that fully defines
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table metadata::
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from sqlalchemy.ext.automap import automap_base
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from sqlalchemy import Column, Integer, String, ForeignKey
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Base = automap_base()
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class User(Base):
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__tablename__ = 'user'
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id = Column(Integer, primary_key=True)
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name = Column(String)
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class Address(Base):
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__tablename__ = 'address'
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id = Column(Integer, primary_key=True)
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email = Column(String)
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user_id = Column(ForeignKey('user.id'))
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# produce relationships
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Base.prepare()
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# mapping is complete, with "address_collection" and
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# "user" relationships
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a1 = Address(email='u1')
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a2 = Address(email='u2')
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u1 = User(address_collection=[a1, a2])
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assert a1.user is u1
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Above, given mostly complete ``User`` and ``Address`` mappings, the
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:class:`.ForeignKey` which we defined on ``Address.user_id`` allowed a
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bidirectional relationship pair ``Address.user`` and ``User.address_collection``
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to be generated on the mapped classes.
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Note that when subclassing :class:`.AutomapBase`, the :meth:`.AutomapBase.prepare`
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method is required; if not called, the classes we've declared are in an
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un-mapped state.
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"""
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from .declarative import declarative_base as _declarative_base
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from .declarative.base import _DeferredMapperConfig
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from ..sql import and_
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from ..schema import ForeignKeyConstraint
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from ..orm import relationship, backref, interfaces
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from .. import util
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def classname_for_table(base, tablename, table):
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"""Return the class name that should be used, given the name
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of a table.
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The default implementation is::
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return str(tablename)
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Alternate implementations can be specified using the
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:paramref:`.AutomapBase.prepare.classname_for_table`
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parameter.
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:param base: the :class:`.AutomapBase` class doing the prepare.
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:param tablename: string name of the :class:`.Table`.
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:param table: the :class:`.Table` object itself.
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:return: a string class name.
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.. note::
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In Python 2, the string used for the class name **must** be a non-Unicode
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object, e.g. a ``str()`` object. The ``.name`` attribute of
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:class:`.Table` is typically a Python unicode subclass, so the ``str()``
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function should be applied to this name, after accounting for any non-ASCII
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characters.
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"""
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return str(tablename)
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def name_for_scalar_relationship(base, local_cls, referred_cls, constraint):
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"""Return the attribute name that should be used to refer from one
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class to another, for a scalar object reference.
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The default implementation is::
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return referred_cls.__name__.lower()
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Alternate implementations can be specified using the
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:paramref:`.AutomapBase.prepare.name_for_scalar_relationship`
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parameter.
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:param base: the :class:`.AutomapBase` class doing the prepare.
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:param local_cls: the class to be mapped on the local side.
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:param referred_cls: the class to be mapped on the referring side.
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:param constraint: the :class:`.ForeignKeyConstraint` that is being
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inspected to produce this relationship.
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"""
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return referred_cls.__name__.lower()
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|
|
|
def name_for_collection_relationship(base, local_cls, referred_cls, constraint):
|
|
"""Return the attribute name that should be used to refer from one
|
|
class to another, for a collection reference.
|
|
|
|
The default implementation is::
|
|
|
|
return referred_cls.__name__.lower() + "_collection"
|
|
|
|
Alternate implementations
|
|
can be specified using the :paramref:`.AutomapBase.prepare.name_for_collection_relationship`
|
|
parameter.
|
|
|
|
:param base: the :class:`.AutomapBase` class doing the prepare.
|
|
|
|
:param local_cls: the class to be mapped on the local side.
|
|
|
|
:param referred_cls: the class to be mapped on the referring side.
|
|
|
|
:param constraint: the :class:`.ForeignKeyConstraint` that is being
|
|
inspected to produce this relationship.
|
|
|
|
"""
|
|
return referred_cls.__name__.lower() + "_collection"
|
|
|
|
def generate_relationship(base, direction, return_fn, attrname, local_cls, referred_cls, **kw):
|
|
"""Generate a :func:`.relationship` or :func:`.backref` on behalf of two
|
|
mapped classes.
|
|
|
|
An alternate implementation of this function can be specified using the
|
|
:paramref:`.AutomapBase.prepare.generate_relationship` parameter.
|
|
|
|
The default implementation of this function is as follows::
|
|
|
|
if return_fn is backref:
|
|
return return_fn(attrname, **kw)
|
|
elif return_fn is relationship:
|
|
return return_fn(referred_cls, **kw)
|
|
else:
|
|
raise TypeError("Unknown relationship function: %s" % return_fn)
|
|
|
|
:param base: the :class:`.AutomapBase` class doing the prepare.
|
|
|
|
:param direction: indicate the "direction" of the relationship; this will
|
|
be one of :data:`.ONETOMANY`, :data:`.MANYTOONE`, :data:`.MANYTOONE`.
|
|
|
|
:param return_fn: the function that is used by default to create the
|
|
relationship. This will be either :func:`.relationship` or :func:`.backref`.
|
|
The :func:`.backref` function's result will be used to produce a new
|
|
:func:`.relationship` in a second step, so it is critical that user-defined
|
|
implementations correctly differentiate between the two functions, if
|
|
a custom relationship function is being used.
|
|
|
|
:attrname: the attribute name to which this relationship is being assigned.
|
|
If the value of :paramref:`.generate_relationship.return_fn` is the
|
|
:func:`.backref` function, then this name is the name that is being
|
|
assigned to the backref.
|
|
|
|
:param local_cls: the "local" class to which this relationship or backref
|
|
will be locally present.
|
|
|
|
:param referred_cls: the "referred" class to which the relationship or backref
|
|
refers to.
|
|
|
|
:param \**kw: all additional keyword arguments are passed along to the
|
|
function.
|
|
|
|
:return: a :func:`.relationship` or :func:`.backref` construct, as dictated
|
|
by the :paramref:`.generate_relationship.return_fn` parameter.
|
|
|
|
"""
|
|
if return_fn is backref:
|
|
return return_fn(attrname, **kw)
|
|
elif return_fn is relationship:
|
|
return return_fn(referred_cls, **kw)
|
|
else:
|
|
raise TypeError("Unknown relationship function: %s" % return_fn)
|
|
|
|
class AutomapBase(object):
|
|
"""Base class for an "automap" schema.
|
|
|
|
The :class:`.AutomapBase` class can be compared to the "declarative base"
|
|
class that is produced by the :func:`.declarative.declarative_base`
|
|
function. In practice, the :class:`.AutomapBase` class is always used
|
|
as a mixin along with an actual declarative base.
|
|
|
|
A new subclassable :class:`.AutomapBase` is typically instantated
|
|
using the :func:`.automap_base` function.
|
|
|
|
.. seealso::
|
|
|
|
:ref:`automap_toplevel`
|
|
|
|
"""
|
|
__abstract__ = True
|
|
|
|
classes = None
|
|
"""An instance of :class:`.util.Properties` containing classes.
|
|
|
|
This object behaves much like the ``.c`` collection on a table. Classes
|
|
are present under the name they were given, e.g.::
|
|
|
|
Base = automap_base()
|
|
Base.prepare(engine=some_engine, reflect=True)
|
|
|
|
User, Address = Base.classes.User, Base.classes.Address
|
|
|
|
"""
|
|
|
|
@classmethod
|
|
def prepare(cls,
|
|
engine=None,
|
|
reflect=False,
|
|
classname_for_table=classname_for_table,
|
|
collection_class=list,
|
|
name_for_scalar_relationship=name_for_scalar_relationship,
|
|
name_for_collection_relationship=name_for_collection_relationship,
|
|
generate_relationship=generate_relationship):
|
|
|
|
"""Extract mapped classes and relationships from the :class:`.MetaData` and
|
|
perform mappings.
|
|
|
|
:param engine: an :class:`.Engine` or :class:`.Connection` with which
|
|
to perform schema reflection, if specified.
|
|
If the :paramref:`.AutomapBase.prepare.reflect` argument is False, this
|
|
object is not used.
|
|
|
|
:param reflect: if True, the :meth:`.MetaData.reflect` method is called
|
|
on the :class:`.MetaData` associated with this :class:`.AutomapBase`.
|
|
The :class:`.Engine` passed via :paramref:`.AutomapBase.prepare.engine` will
|
|
be used to perform the reflection if present; else, the :class:`.MetaData`
|
|
should already be bound to some engine else the operation will fail.
|
|
|
|
:param classname_for_table: callable function which will be used to
|
|
produce new class names, given a table name. Defaults to
|
|
:func:`.classname_for_table`.
|
|
|
|
:param name_for_scalar_relationship: callable function which will be used
|
|
to produce relationship names for scalar relationships. Defaults to
|
|
:func:`.name_for_scalar_relationship`.
|
|
|
|
:param name_for_collection_relationship: callable function which will be used
|
|
to produce relationship names for collection-oriented relationships. Defaults to
|
|
:func:`.name_for_collection_relationship`.
|
|
|
|
:param generate_relationship: callable function which will be used to
|
|
actually generate :func:`.relationship` and :func:`.backref` constructs.
|
|
Defaults to :func:`.generate_relationship`.
|
|
|
|
:param collection_class: the Python collection class that will be used
|
|
when a new :func:`.relationship` object is created that represents a
|
|
collection. Defaults to ``list``.
|
|
|
|
"""
|
|
if reflect:
|
|
cls.metadata.reflect(
|
|
engine,
|
|
extend_existing=True,
|
|
autoload_replace=False
|
|
)
|
|
|
|
table_to_map_config = dict(
|
|
(m.local_table, m)
|
|
for m in _DeferredMapperConfig.
|
|
classes_for_base(cls, sort=False)
|
|
)
|
|
|
|
many_to_many = []
|
|
|
|
for table in cls.metadata.tables.values():
|
|
lcl_m2m, rem_m2m, m2m_const = _is_many_to_many(cls, table)
|
|
if lcl_m2m is not None:
|
|
many_to_many.append((lcl_m2m, rem_m2m, m2m_const, table))
|
|
elif not table.primary_key:
|
|
continue
|
|
elif table not in table_to_map_config:
|
|
mapped_cls = type(
|
|
classname_for_table(cls, table.name, table),
|
|
(cls, ),
|
|
{"__table__": table}
|
|
)
|
|
map_config = _DeferredMapperConfig.config_for_cls(mapped_cls)
|
|
cls.classes[map_config.cls.__name__] = mapped_cls
|
|
table_to_map_config[table] = map_config
|
|
|
|
for map_config in table_to_map_config.values():
|
|
_relationships_for_fks(cls,
|
|
map_config,
|
|
table_to_map_config,
|
|
collection_class,
|
|
name_for_scalar_relationship,
|
|
name_for_collection_relationship,
|
|
generate_relationship)
|
|
|
|
for lcl_m2m, rem_m2m, m2m_const, table in many_to_many:
|
|
_m2m_relationship(cls, lcl_m2m, rem_m2m, m2m_const, table,
|
|
table_to_map_config,
|
|
collection_class,
|
|
name_for_scalar_relationship,
|
|
name_for_collection_relationship,
|
|
generate_relationship)
|
|
|
|
for map_config in _DeferredMapperConfig.classes_for_base(cls):
|
|
map_config.map()
|
|
|
|
|
|
_sa_decl_prepare = True
|
|
"""Indicate that the mapping of classes should be deferred.
|
|
|
|
The presence of this attribute name indicates to declarative
|
|
that the call to mapper() should not occur immediately; instead,
|
|
information about the table and attributes to be mapped are gathered
|
|
into an internal structure called _DeferredMapperConfig. These
|
|
objects can be collected later using classes_for_base(), additional
|
|
mapping decisions can be made, and then the map() method will actually
|
|
apply the mapping.
|
|
|
|
The only real reason this deferral of the whole
|
|
thing is needed is to support primary key columns that aren't reflected
|
|
yet when the class is declared; everything else can theoretically be
|
|
added to the mapper later. However, the _DeferredMapperConfig is a
|
|
nice interface in any case which exists at that not usually exposed point
|
|
at which declarative has the class and the Table but hasn't called
|
|
mapper() yet.
|
|
|
|
"""
|
|
|
|
def automap_base(declarative_base=None, **kw):
|
|
"""Produce a declarative automap base.
|
|
|
|
This function produces a new base class that is a product of the
|
|
:class:`.AutomapBase` class as well a declarative base produced by
|
|
:func:`.declarative.declarative_base`.
|
|
|
|
All parameters other than ``declarative_base`` are keyword arguments
|
|
that are passed directly to the :func:`.declarative.declarative_base`
|
|
function.
|
|
|
|
:param declarative_base: an existing class produced by
|
|
:func:`.declarative.declarative_base`. When this is passed, the function
|
|
no longer invokes :func:`.declarative.declarative_base` itself, and all other
|
|
keyword arguments are ignored.
|
|
|
|
:param \**kw: keyword arguments are passed along to
|
|
:func:`.declarative.declarative_base`.
|
|
|
|
"""
|
|
if declarative_base is None:
|
|
Base = _declarative_base(**kw)
|
|
else:
|
|
Base = declarative_base
|
|
|
|
return type(
|
|
Base.__name__,
|
|
(AutomapBase, Base,),
|
|
{"__abstract__": True, "classes": util.Properties({})}
|
|
)
|
|
|
|
def _is_many_to_many(automap_base, table):
|
|
fk_constraints = [const for const in table.constraints
|
|
if isinstance(const, ForeignKeyConstraint)]
|
|
if len(fk_constraints) != 2:
|
|
return None, None, None
|
|
|
|
cols = sum(
|
|
[[fk.parent for fk in fk_constraint.elements]
|
|
for fk_constraint in fk_constraints], [])
|
|
|
|
if set(cols) != set(table.c):
|
|
return None, None, None
|
|
|
|
return (
|
|
fk_constraints[0].elements[0].column.table,
|
|
fk_constraints[1].elements[0].column.table,
|
|
fk_constraints
|
|
)
|
|
|
|
def _relationships_for_fks(automap_base, map_config, table_to_map_config,
|
|
collection_class,
|
|
name_for_scalar_relationship,
|
|
name_for_collection_relationship,
|
|
generate_relationship):
|
|
local_table = map_config.local_table
|
|
local_cls = map_config.cls
|
|
|
|
if local_table is None:
|
|
return
|
|
for constraint in local_table.constraints:
|
|
if isinstance(constraint, ForeignKeyConstraint):
|
|
fks = constraint.elements
|
|
referred_table = fks[0].column.table
|
|
referred_cfg = table_to_map_config.get(referred_table, None)
|
|
if referred_cfg is None:
|
|
continue
|
|
referred_cls = referred_cfg.cls
|
|
|
|
if local_cls is not referred_cls and issubclass(local_cls, referred_cls):
|
|
continue
|
|
|
|
relationship_name = name_for_scalar_relationship(
|
|
automap_base,
|
|
local_cls,
|
|
referred_cls, constraint)
|
|
backref_name = name_for_collection_relationship(
|
|
automap_base,
|
|
referred_cls,
|
|
local_cls,
|
|
constraint
|
|
)
|
|
|
|
create_backref = backref_name not in referred_cfg.properties
|
|
|
|
if relationship_name not in map_config.properties:
|
|
if create_backref:
|
|
backref_obj = generate_relationship(automap_base,
|
|
interfaces.ONETOMANY, backref,
|
|
backref_name, referred_cls, local_cls,
|
|
collection_class=collection_class)
|
|
else:
|
|
backref_obj = None
|
|
rel = generate_relationship(automap_base,
|
|
interfaces.MANYTOONE,
|
|
relationship,
|
|
relationship_name,
|
|
local_cls, referred_cls,
|
|
foreign_keys=[fk.parent for fk in constraint.elements],
|
|
backref=backref_obj,
|
|
remote_side=[fk.column for fk in constraint.elements]
|
|
)
|
|
if rel is not None:
|
|
map_config.properties[relationship_name] = rel
|
|
if not create_backref:
|
|
referred_cfg.properties[backref_name].back_populates = relationship_name
|
|
elif create_backref:
|
|
rel = generate_relationship(automap_base,
|
|
interfaces.ONETOMANY,
|
|
relationship,
|
|
backref_name,
|
|
referred_cls, local_cls,
|
|
foreign_keys=[fk.parent for fk in constraint.elements],
|
|
back_populates=relationship_name,
|
|
collection_class=collection_class)
|
|
if rel is not None:
|
|
referred_cfg.properties[backref_name] = rel
|
|
map_config.properties[relationship_name].back_populates = backref_name
|
|
|
|
def _m2m_relationship(automap_base, lcl_m2m, rem_m2m, m2m_const, table,
|
|
table_to_map_config,
|
|
collection_class,
|
|
name_for_scalar_relationship,
|
|
name_for_collection_relationship,
|
|
generate_relationship):
|
|
|
|
map_config = table_to_map_config.get(lcl_m2m, None)
|
|
referred_cfg = table_to_map_config.get(rem_m2m, None)
|
|
if map_config is None or referred_cfg is None:
|
|
return
|
|
|
|
local_cls = map_config.cls
|
|
referred_cls = referred_cfg.cls
|
|
|
|
relationship_name = name_for_collection_relationship(
|
|
automap_base,
|
|
local_cls,
|
|
referred_cls, m2m_const[0])
|
|
backref_name = name_for_collection_relationship(
|
|
automap_base,
|
|
referred_cls,
|
|
local_cls,
|
|
m2m_const[1]
|
|
)
|
|
|
|
create_backref = backref_name not in referred_cfg.properties
|
|
|
|
if relationship_name not in map_config.properties:
|
|
if create_backref:
|
|
backref_obj = generate_relationship(automap_base,
|
|
interfaces.MANYTOMANY,
|
|
backref,
|
|
backref_name,
|
|
referred_cls, local_cls,
|
|
collection_class=collection_class
|
|
)
|
|
else:
|
|
backref_obj = None
|
|
rel = generate_relationship(automap_base,
|
|
interfaces.MANYTOMANY,
|
|
relationship,
|
|
relationship_name,
|
|
local_cls, referred_cls,
|
|
secondary=table,
|
|
primaryjoin=and_(fk.column == fk.parent for fk in m2m_const[0].elements),
|
|
secondaryjoin=and_(fk.column == fk.parent for fk in m2m_const[1].elements),
|
|
backref=backref_obj,
|
|
collection_class=collection_class
|
|
)
|
|
if rel is not None:
|
|
map_config.properties[relationship_name] = rel
|
|
|
|
if not create_backref:
|
|
referred_cfg.properties[backref_name].back_populates = relationship_name
|
|
elif create_backref:
|
|
rel = generate_relationship(automap_base,
|
|
interfaces.MANYTOMANY,
|
|
relationship,
|
|
backref_name,
|
|
referred_cls, local_cls,
|
|
secondary=table,
|
|
primaryjoin=and_(fk.column == fk.parent for fk in m2m_const[1].elements),
|
|
secondaryjoin=and_(fk.column == fk.parent for fk in m2m_const[0].elements),
|
|
back_populates=relationship_name,
|
|
collection_class=collection_class)
|
|
if rel is not None:
|
|
referred_cfg.properties[backref_name] = rel
|
|
map_config.properties[relationship_name].back_populates = backref_name
|