''' This module provides support for defining relationships between your Elixir entities. Elixir currently supports two syntaxes to do so: the default `Attribute-based syntax`_ which supports the following types of relationships: ManyToOne_, OneToMany_, OneToOne_ and ManyToMany_, as well as a `DSL-based syntax`_ which provides the following statements: belongs_to_, has_many_, has_one_ and has_and_belongs_to_many_. ====================== Attribute-based syntax ====================== The first argument to all these "normal" relationship classes is the name of the class (entity) you are relating to. Following that first mandatory argument, any number of additional keyword arguments can be specified for advanced behavior. See each relationship type for a list of their specific keyword arguments. At this point, we'll just note that all the arguments that are not specifically processed by Elixir, as mentioned in the documentation below are passed on to the SQLAlchemy ``relation`` function. So, please refer to the `SQLAlchemy relation function's documentation `_ for further detail about which keyword arguments are supported. You should keep in mind that the following keyword arguments are automatically generated by Elixir and should not be used unless you want to override the value provided by Elixir: ``uselist``, ``remote_side``, ``secondary``, ``primaryjoin`` and ``secondaryjoin``. Additionally, if you want a bidirectionnal relationship, you should define the inverse relationship on the other entity explicitly (as opposed to how SQLAlchemy's backrefs are defined). In non-ambiguous situations, Elixir will match relationships together automatically. If there are several relationships of the same type between two entities, Elixir is not able to determine which relationship is the inverse of which, so you have to disambiguate the situation by giving the name of the inverse relationship in the ``inverse`` keyword argument. Here is a detailed explanation of each relation type: `ManyToOne` ----------- Describes the child's side of a parent-child relationship. For example, a `Pet` object may belong to its owner, who is a `Person`. This could be expressed like so: .. sourcecode:: python class Pet(Entity): owner = ManyToOne('Person') Behind the scene, assuming the primary key of the `Person` entity is an integer column named `id`, the ``ManyToOne`` relationship will automatically add an integer column named `owner_id` to the entity, with a foreign key referencing the `id` column of the `Person` entity. In addition to the keyword arguments inherited from SQLAlchemy's relation function, ``ManyToOne`` relationships accept the following optional arguments which will be directed to the created column: +----------------------+------------------------------------------------------+ | Option Name | Description | +======================+======================================================+ | ``colname`` | Specify a custom name for the foreign key column(s). | | | This argument accepts either a single string or a | | | list of strings. The number of strings passed must | | | match the number of primary key columns of the target| | | entity. If this argument is not used, the name of the| | | column(s) is generated with the pattern | | | defined in options.FKCOL_NAMEFORMAT, which is, by | | | default: "%(relname)s_%(key)s", where relname is the | | | name of the ManyToOne relationship, and 'key' is the | | | name (key) of the primary column in the target | | | entity. That's with, in the above Pet/owner example, | | | the name of the column would be: "owner_id". | +----------------------+------------------------------------------------------+ | ``required`` | Specify whether or not this field can be set to None | | | (left without a value). Defaults to ``False``, | | | unless the field is a primary key. | +----------------------+------------------------------------------------------+ | ``primary_key`` | Specify whether or not the column(s) created by this | | | relationship should act as a primary_key. | | | Defaults to ``False``. | +----------------------+------------------------------------------------------+ | ``column_kwargs`` | A dictionary holding any other keyword argument you | | | might want to pass to the Column. | +----------------------+------------------------------------------------------+ | ``target_column`` | Name (or list of names) of the target column(s). | | | If this argument is not specified, the target entity | | | primary key column(s) are used. | +----------------------+------------------------------------------------------+ The following optional arguments are also supported to customize the ForeignKeyConstraint that is created: +----------------------+------------------------------------------------------+ | Option Name | Description | +======================+======================================================+ | ``use_alter`` | If True, SQLAlchemy will add the constraint in a | | | second SQL statement (as opposed to within the | | | create table statement). This permits to define | | | tables with a circular foreign key dependency | | | between them. | +----------------------+------------------------------------------------------+ | ``ondelete`` | Value for the foreign key constraint ondelete clause.| | | May be one of: ``cascade``, ``restrict``, | | | ``set null``, or ``set default``. | +----------------------+------------------------------------------------------+ | ``onupdate`` | Value for the foreign key constraint onupdate clause.| | | May be one of: ``cascade``, ``restrict``, | | | ``set null``, or ``set default``. | +----------------------+------------------------------------------------------+ | ``constraint_kwargs``| A dictionary holding any other keyword argument you | | | might want to pass to the Constraint. | +----------------------+------------------------------------------------------+ In some cases, you may want to declare the foreign key column explicitly, instead of letting it be generated automatically. There are several reasons to that: it could be because you want to declare it with precise arguments and using column_kwargs makes your code ugly, or because the name of your column conflicts with the property name (in which case an error is thrown). In those cases, you can use the ``field`` argument to specify an already-declared field to be used for the foreign key column. For example, for the Pet example above, if you want the database column (holding the foreign key) to be called 'owner', one should use the field parameter to specify the field manually. .. sourcecode:: python class Pet(Entity): owner_id = Field(Integer, colname='owner') owner = ManyToOne('Person', field=owner_id) +----------------------+------------------------------------------------------+ | Option Name | Description | +======================+======================================================+ | ``field`` | Specify the previously-declared field to be used for | | | the foreign key column. Use of this parameter is | | | mutually exclusive with the colname and column_kwargs| | | arguments. | +----------------------+------------------------------------------------------+ Additionally, Elixir supports the belongs_to_ statement as an alternative, DSL-based, syntax to define ManyToOne_ relationships. `OneToMany` ----------- Describes the parent's side of a parent-child relationship when there can be several children. For example, a `Person` object has many children, each of them being a `Person`. This could be expressed like so: .. sourcecode:: python class Person(Entity): parent = ManyToOne('Person') children = OneToMany('Person') Note that a ``OneToMany`` relationship **cannot exist** without a corresponding ``ManyToOne`` relationship in the other way. This is because the ``OneToMany`` relationship needs the foreign key created by the ``ManyToOne`` relationship. In addition to keyword arguments inherited from SQLAlchemy, ``OneToMany`` relationships accept the following optional (keyword) arguments: +--------------------+--------------------------------------------------------+ | Option Name | Description | +====================+========================================================+ | ``order_by`` | Specify which field(s) should be used to sort the | | | results given by accessing the relation field. | | | Note that this sort order is only applied when loading | | | objects from the database. Objects appended to the | | | collection afterwards are not re-sorted in-memory on | | | the fly. | | | This argument accepts either a string or a list of | | | strings, each corresponding to the name of a field in | | | the target entity. These field names can optionally be | | | prefixed by a minus (for descending order). | +--------------------+--------------------------------------------------------+ | ``filter`` | Specify a filter criterion (as a clause element) for | | | this relationship. This criterion will be ``and_`` ed | | | with the normal join criterion (primaryjoin) generated | | | by Elixir for the relationship. For example: | | | boston_addresses = | | | OneToMany('Address', filter=Address.city == 'Boston') | +--------------------+--------------------------------------------------------+ Additionally, Elixir supports an alternate, DSL-based, syntax to define OneToMany_ relationships, with the has_many_ statement. `OneToOne` ---------- Describes the parent's side of a parent-child relationship when there is only one child. For example, a `Car` object has one gear stick, which is represented as a `GearStick` object. This could be expressed like so: .. sourcecode:: python class Car(Entity): gear_stick = OneToOne('GearStick', inverse='car') class GearStick(Entity): car = ManyToOne('Car') Note that a ``OneToOne`` relationship **cannot exist** without a corresponding ``ManyToOne`` relationship in the other way. This is because the ``OneToOne`` relationship needs the foreign_key created by the ``ManyToOne`` relationship. Additionally, Elixir supports an alternate, DSL-based, syntax to define OneToOne_ relationships, with the has_one_ statement. `ManyToMany` ------------ Describes a relationship in which one kind of entity can be related to several objects of the other kind but the objects of that other kind can be related to several objects of the first kind. For example, an `Article` can have several tags, but the same `Tag` can be used on several articles. .. sourcecode:: python class Article(Entity): tags = ManyToMany('Tag') class Tag(Entity): articles = ManyToMany('Article') Behind the scene, the ``ManyToMany`` relationship will automatically create an intermediate table to host its data. Note that you don't necessarily need to define the inverse relationship. In our example, even though we want tags to be usable on several articles, we might not be interested in which articles correspond to a particular tag. In that case, we could have omitted the `Tag` side of the relationship. If your ``ManyToMany`` relationship is self-referencial, the entity containing it is autoloaded (and you don't intend to specify both the primaryjoin and secondaryjoin arguments manually), you must specify at least one of either the ``remote_colname`` or ``local_colname`` argument. In addition to keyword arguments inherited from SQLAlchemy, ``ManyToMany`` relationships accept the following optional (keyword) arguments: +--------------------+--------------------------------------------------------+ | Option Name | Description | +====================+========================================================+ | ``tablename`` | Specify a custom name for the intermediary table. This | | | can be used both when the tables needs to be created | | | and when the table is autoloaded/reflected from the | | | database. If this argument is not used, a name will be | | | automatically generated by Elixir depending on the name| | | of the tables of the two entities of the relationship, | | | the name of the relationship, and, if present, the name| | | of its inverse. Even though this argument is optional, | | | it is wise to use it if you are not sure what are the | | | exact consequence of using a generated table name. | +--------------------+--------------------------------------------------------+ | ``schema`` | Specify a custom schema for the intermediate table. | | | This can be used both when the tables needs to | | | be created and when the table is autoloaded/reflected | | | from the database. | +--------------------+--------------------------------------------------------+ | ``remote_colname`` | A string or list of strings specifying the names of | | | the column(s) in the intermediary table which | | | reference the "remote"/target entity's table. | +--------------------+--------------------------------------------------------+ | ``local_colname`` | A string or list of strings specifying the names of | | | the column(s) in the intermediary table which | | | reference the "local"/current entity's table. | +--------------------+--------------------------------------------------------+ | ``table`` | Use a manually created table. If this argument is | | | used, Elixir won't generate a table for this | | | relationship, and use the one given instead. | +--------------------+--------------------------------------------------------+ | ``order_by`` | Specify which field(s) should be used to sort the | | | results given by accessing the relation field. | | | Note that this sort order is only applied when loading | | | objects from the database. Objects appended to the | | | collection afterwards are not re-sorted in-memory on | | | the fly. | | | This argument accepts either a string or a list of | | | strings, each corresponding to the name of a field in | | | the target entity. These field names can optionally be | | | prefixed by a minus (for descending order). | +----------------------+------------------------------------------------------+ | ``ondelete`` | Value for the foreign key constraint ondelete clause. | | | May be one of: ``cascade``, ``restrict``, | | | ``set null``, or ``set default``. | +--------------------+--------------------------------------------------------+ | ``onupdate`` | Value for the foreign key constraint onupdate clause. | | | May be one of: ``cascade``, ``restrict``, | | | ``set null``, or ``set default``. | +--------------------+--------------------------------------------------------+ | ``table_kwargs`` | A dictionary holding any other keyword argument you | | | might want to pass to the underlying Table object. | +--------------------+--------------------------------------------------------+ | ``column_format`` | DEPRECATED. Specify an alternate format string for | | | naming the | | | columns in the mapping table. The default value is | | | defined in ``elixir.options.M2MCOL_NAMEFORMAT``. You | | | will be passed ``tablename``, ``key``, and ``entity`` | | | as arguments to the format string. | +--------------------+--------------------------------------------------------+ ================ DSL-based syntax ================ The following DSL statements provide an alternative way to define relationships between your entities. The first argument to all those statements is the name of the relationship, the second is the 'kind' of object you are relating to (it is usually given using the ``of_kind`` keyword). `belongs_to` ------------ The ``belongs_to`` statement is the DSL syntax equivalent to the ManyToOne_ relationship. As such, it supports all the same arguments as ManyToOne_ relationships. .. sourcecode:: python class Pet(Entity): belongs_to('feeder', of_kind='Person') belongs_to('owner', of_kind='Person', colname="owner_id") `has_many` ---------- The ``has_many`` statement is the DSL syntax equivalent to the OneToMany_ relationship. As such, it supports all the same arguments as OneToMany_ relationships. .. sourcecode:: python class Person(Entity): belongs_to('parent', of_kind='Person') has_many('children', of_kind='Person') There is also an alternate form of the ``has_many`` relationship that takes only two keyword arguments: ``through`` and ``via`` in order to encourage a richer form of many-to-many relationship that is an alternative to the ``has_and_belongs_to_many`` statement. Here is an example: .. sourcecode:: python class Person(Entity): has_field('name', Unicode) has_many('assignments', of_kind='Assignment') has_many('projects', through='assignments', via='project') class Assignment(Entity): has_field('start_date', DateTime) belongs_to('person', of_kind='Person') belongs_to('project', of_kind='Project') class Project(Entity): has_field('title', Unicode) has_many('assignments', of_kind='Assignment') In the above example, a `Person` has many `projects` through the `Assignment` relationship object, via a `project` attribute. `has_one` --------- The ``has_one`` statement is the DSL syntax equivalent to the OneToOne_ relationship. As such, it supports all the same arguments as OneToOne_ relationships. .. sourcecode:: python class Car(Entity): has_one('gear_stick', of_kind='GearStick', inverse='car') class GearStick(Entity): belongs_to('car', of_kind='Car') `has_and_belongs_to_many` ------------------------- The ``has_and_belongs_to_many`` statement is the DSL syntax equivalent to the ManyToMany_ relationship. As such, it supports all the same arguments as ManyToMany_ relationships. .. sourcecode:: python class Article(Entity): has_and_belongs_to_many('tags', of_kind='Tag') class Tag(Entity): has_and_belongs_to_many('articles', of_kind='Article') ''' import warnings from sqlalchemy import ForeignKeyConstraint, Column, Table, and_ from sqlalchemy.orm import relation, backref, class_mapper from sqlalchemy.ext.associationproxy import association_proxy import options from elixir.statements import ClassMutator from elixir.properties import Property from elixir.entity import EntityMeta, DEBUG __doc_all__ = [] class Relationship(Property): ''' Base class for relationships. ''' def __init__(self, of_kind, inverse=None, *args, **kwargs): super(Relationship, self).__init__() self.of_kind = of_kind self.inverse_name = inverse self._target = None self.property = None # sqlalchemy property self.backref = None # sqlalchemy backref #TODO: unused for now self.args = args self.kwargs = kwargs def attach(self, entity, name): super(Relationship, self).attach(entity, name) entity._descriptor.relationships.append(self) def create_pk_cols(self): self.create_keys(True) def create_non_pk_cols(self): self.create_keys(False) def create_keys(self, pk): ''' Subclasses (ie. concrete relationships) may override this method to create foreign keys. ''' def create_properties(self): if self.property or self.backref: return kwargs = self.get_prop_kwargs() if 'order_by' in kwargs: kwargs['order_by'] = \ self.target._descriptor.translate_order_by(kwargs['order_by']) # transform callable arguments for arg in ('primaryjoin', 'secondaryjoin', 'remote_side', 'foreign_keys'): kwarg = kwargs.get(arg, None) if hasattr(kwarg, '__call__'): kwargs[arg] = kwarg() # viewonly relationships need to create "standalone" relations (ie # shouldn't be a backref of another relation). if self.inverse and not kwargs.get('viewonly', False): # check if the inverse was already processed (and thus has already # defined a backref we can use) if self.inverse.backref: # let the user override the backref argument if 'backref' not in kwargs: kwargs['backref'] = self.inverse.backref else: # SQLAlchemy doesn't like when 'secondary' is both defined on # the relation and the backref kwargs.pop('secondary', None) # define backref for use by the inverse self.backref = backref(self.name, **kwargs) return self.property = relation(self.target, **kwargs) self.add_mapper_property(self.name, self.property) def target(self): if not self._target: if isinstance(self.of_kind, basestring): collection = self.entity._descriptor.collection self._target = collection.resolve(self.of_kind, self.entity) else: self._target = self.of_kind return self._target target = property(target) def inverse(self): if not hasattr(self, '_inverse'): if self.inverse_name: desc = self.target._descriptor inverse = desc.find_relationship(self.inverse_name) if inverse is None: raise Exception( "Couldn't find a relationship named '%s' in " "entity '%s' or its parent entities." % (self.inverse_name, self.target.__name__)) assert self.match_type_of(inverse), \ "Relationships '%s' in entity '%s' and '%s' in entity " \ "'%s' cannot be inverse of each other because their " \ "types do not form a valid combination." % \ (self.name, self.entity.__name__, self.inverse_name, self.target.__name__) else: check_reverse = not self.kwargs.get('viewonly', False) if isinstance(self.target, EntityMeta): inverse = self.target._descriptor.get_inverse_relation( self, check_reverse=check_reverse) else: inverse = None self._inverse = inverse if inverse and not self.kwargs.get('viewonly', False): inverse._inverse = self return self._inverse inverse = property(inverse) def match_type_of(self, other): return False def is_inverse(self, other): # viewonly relationships are not symmetrical: a viewonly relationship # should have exactly one inverse (a ManyToOne relationship), but that # inverse shouldn't have the viewonly relationship as its inverse. return not other.kwargs.get('viewonly', False) and \ other is not self and \ self.match_type_of(other) and \ self.entity == other.target and \ other.entity == self.target and \ (self.inverse_name == other.name or not self.inverse_name) and \ (other.inverse_name == self.name or not other.inverse_name) class ManyToOne(Relationship): ''' ''' def __init__(self, of_kind, column_kwargs=None, colname=None, required=None, primary_key=None, field=None, constraint_kwargs=None, use_alter=None, ondelete=None, onupdate=None, target_column=None, *args, **kwargs): # 1) handle column-related args # check that the column arguments don't conflict assert not (field and (column_kwargs or colname)), \ "ManyToOne can accept the 'field' argument or column " \ "arguments ('colname' or 'column_kwargs') but not both!" if colname and not isinstance(colname, list): colname = [colname] self.colname = colname or [] column_kwargs = column_kwargs or {} # kwargs go by default to the relation(), so we need to manually # extract those targeting the Column if required is not None: column_kwargs['nullable'] = not required if primary_key is not None: column_kwargs['primary_key'] = primary_key # by default, created columns will have an index. column_kwargs.setdefault('index', True) self.column_kwargs = column_kwargs if field and not isinstance(field, list): field = [field] self.field = field or [] # 2) handle constraint kwargs constraint_kwargs = constraint_kwargs or {} if use_alter is not None: constraint_kwargs['use_alter'] = use_alter if ondelete is not None: constraint_kwargs['ondelete'] = ondelete if onupdate is not None: constraint_kwargs['onupdate'] = onupdate self.constraint_kwargs = constraint_kwargs # 3) misc arguments if target_column and not isinstance(target_column, list): target_column = [target_column] self.target_column = target_column self.foreign_key = [] self.primaryjoin_clauses = [] super(ManyToOne, self).__init__(of_kind, *args, **kwargs) def match_type_of(self, other): return isinstance(other, (OneToMany, OneToOne)) def target_table(self): if isinstance(self.target, EntityMeta): return self.target._descriptor.table else: return class_mapper(self.target).local_table target_table = property(target_table) def create_keys(self, pk): ''' Find all primary keys on the target and create foreign keys on the source accordingly. ''' if self.foreign_key: return if self.column_kwargs.get('primary_key', False) != pk: return source_desc = self.entity._descriptor if isinstance(self.target, EntityMeta): # make sure the target has all its pk set up self.target._descriptor.create_pk_cols() #XXX: another option, instead of the FakeTable, would be to create an # EntityDescriptor for the SA class. target_table = self.target_table if source_desc.autoload: #TODO: allow target_column to be used as an alternative to # specifying primaryjoin, to be consistent with non-autoloaded # tables if self.colname: if 'primaryjoin' not in self.kwargs: self.primaryjoin_clauses = \ _get_join_clauses(self.entity.table, self.colname, None, target_table)[0] if not self.primaryjoin_clauses: colnames = ', '.join(self.colname) raise Exception( "Couldn't find a foreign key constraint in table " "'%s' using the following columns: %s." % (self.entity.table.name, colnames)) if self.field: raise NotImplementedError( "'field' argument not allowed on autoloaded table " "relationships.") else: fk_refcols = [] fk_colnames = [] if self.target_column is None: target_columns = target_table.primary_key.columns else: target_columns = [target_table.columns[col] for col in self.target_column] if not target_columns: raise Exception("No primary key found in target table ('%s') " "for the '%s' relationship of the '%s' entity." % (target_table.name, self.name, self.entity.__name__)) if self.colname and \ len(self.colname) != len(target_columns): raise Exception( "The number of column names provided in the colname " "keyword argument of the '%s' relationship of the " "'%s' entity is not the same as the number of columns " "of the primary key of '%s'." % (self.name, self.entity.__name__, self.target.__name__)) for key_num, target_col in enumerate(target_columns): if self.field: col = self.field[key_num].column else: if self.colname: colname = self.colname[key_num] else: colname = options.FKCOL_NAMEFORMAT % \ {'relname': self.name, 'key': target_col.key} # We can't add the column to the table directly as the # table might not be created yet. col = Column(colname, target_col.type, **self.column_kwargs) source_desc.add_column(col) # If the column name was specified, and it is the same as # this property's name, there is going to be a conflict. # Don't allow this to happen. if col.key == self.name: raise ValueError( "ManyToOne named '%s' in '%s' conficts " " with the column of the same name. " "You should probably define the foreign key " "field manually and use the 'field' " "argument on the ManyToOne relationship" % (self.name, self.entity.__name__)) # Build the list of local columns which will be part of # the foreign key self.foreign_key.append(col) # Store the names of those columns fk_colnames.append(col.key) # Build the list of column "paths" the foreign key will # point to fk_refcols.append("%s.%s" % \ (target_table.fullname, target_col.key)) # Build up the primary join. This is needed when you have # several ManyToOne relationships between two objects self.primaryjoin_clauses.append(col == target_col) if 'name' not in self.constraint_kwargs: # In some databases (at least MySQL) the constraint name needs # to be unique for the whole database, instead of per table. fk_name = options.CONSTRAINT_NAMEFORMAT % \ {'tablename': source_desc.tablename, 'colnames': '_'.join(fk_colnames)} self.constraint_kwargs['name'] = fk_name source_desc.add_constraint( ForeignKeyConstraint(fk_colnames, fk_refcols, **self.constraint_kwargs)) def get_prop_kwargs(self): kwargs = {'uselist': False} if self.entity.table is self.target_table: # this is needed because otherwise SA has no way to know what is # the direction of the relationship since both columns present in # the primaryjoin belong to the same table. In other words, it is # necessary to know if this particular relation # is the many-to-one side, or the one-to-xxx side. The foreignkey # doesn't help in this case. kwargs['remote_side'] = \ [col for col in self.target_table.primary_key.columns] if self.primaryjoin_clauses: kwargs['primaryjoin'] = and_(*self.primaryjoin_clauses) kwargs.update(self.kwargs) return kwargs class OneToOne(Relationship): uselist = False def __init__(self, of_kind, filter=None, *args, **kwargs): self.filter = filter if filter is not None: # We set viewonly to True by default for filtered relationships, # unless manually overridden. # This is not strictly necessary, as SQLAlchemy allows non viewonly # relationships with a custom join/filter. The example at: # SADOCS/05/mappers.html#advdatamapping_relation_customjoin # is not viewonly. Those relationships can be used as if the extra # filter wasn't present when inserting. This can lead to a # confusing behavior (if you insert data which doesn't match the # extra criterion it'll get inserted anyway but you won't see it # when you query back the attribute after a round-trip to the # database). if 'viewonly' not in kwargs: kwargs['viewonly'] = True super(OneToOne, self).__init__(of_kind, *args, **kwargs) def match_type_of(self, other): return isinstance(other, ManyToOne) def create_keys(self, pk): # make sure an inverse relationship exists if self.inverse is None: raise Exception( "Couldn't find any relationship in '%s' which " "match as inverse of the '%s' relationship " "defined in the '%s' entity. If you are using " "inheritance you " "might need to specify inverse relationships " "manually by using the 'inverse' argument." % (self.target, self.name, self.entity)) def get_prop_kwargs(self): kwargs = {'uselist': self.uselist} #TODO: for now, we don't break any test if we remove those 2 lines. # So, we should either complete the selfref test to prove that they # are indeed useful, or remove them. It might be they are indeed # useless because the remote_side is already setup in the other way # (ManyToOne). if self.entity.table is self.target.table: #FIXME: IF this code is of any use, it will probably break for # autoloaded tables kwargs['remote_side'] = self.inverse.foreign_key # Contrary to ManyToMany relationships, we need to specify the join # clauses even if this relationship is not self-referencial because # there could be several ManyToOne from the target class to us. joinclauses = self.inverse.primaryjoin_clauses if self.filter: # We need to make a copy of the joinclauses, to not add the filter # on the backref joinclauses = joinclauses[:] + [self.filter(self.target.table.c)] if joinclauses: kwargs['primaryjoin'] = and_(*joinclauses) kwargs.update(self.kwargs) return kwargs class OneToMany(OneToOne): uselist = True class ManyToMany(Relationship): uselist = True def __init__(self, of_kind, tablename=None, local_colname=None, remote_colname=None, ondelete=None, onupdate=None, table=None, schema=None, column_format=None, filter=None, table_kwargs=None, *args, **kwargs): self.user_tablename = tablename if local_colname and not isinstance(local_colname, list): local_colname = [local_colname] self.local_colname = local_colname or [] if remote_colname and not isinstance(remote_colname, list): remote_colname = [remote_colname] self.remote_colname = remote_colname or [] self.ondelete = ondelete self.onupdate = onupdate self.table = table self.schema = schema if column_format: warnings.warn("The 'column_format' argument on ManyToMany " "relationships is deprecated. Please use the 'local_colname' " "and/or 'remote_colname' arguments if you want custom " "column names for this table only, or modify " "options.M2MCOL_NAMEFORMAT if you want a custom format for " "all ManyToMany tables", DeprecationWarning, stacklevel=3) self.column_format = column_format or options.M2MCOL_NAMEFORMAT if not hasattr(self.column_format, '__call__'): # we need to store the format in a variable so that the # closure of the lambda is correct format = self.column_format self.column_format = lambda data: format % data if options.MIGRATION_TO_07_AID: self.column_format = \ migration_aid_m2m_column_formatter( lambda data: options.OLD_M2MCOL_NAMEFORMAT % data, self.column_format) self.filter = filter if filter is not None: # We set viewonly to True by default for filtered relationships, # unless manually overridden. if 'viewonly' not in kwargs: kwargs['viewonly'] = True self.table_kwargs = table_kwargs or {} self.primaryjoin_clauses = [] self.secondaryjoin_clauses = [] super(ManyToMany, self).__init__(of_kind, *args, **kwargs) def get_table(self): warnings.warn("The secondary_table attribute on ManyToMany objects is " "deprecated. You should rather use the table attribute.", DeprecationWarning, stacklevel=2) return self.table secondary_table = property(get_table) def match_type_of(self, other): return isinstance(other, ManyToMany) def create_tables(self): if self.table is not None: if 'primaryjoin' not in self.kwargs or \ 'secondaryjoin' not in self.kwargs: self._build_join_clauses() assert self.inverse is None or self.inverse.table is None or \ self.inverse.table is self.table return if self.inverse: inverse = self.inverse if inverse.table is not None: self.table = inverse.table self.primaryjoin_clauses = inverse.secondaryjoin_clauses self.secondaryjoin_clauses = inverse.primaryjoin_clauses return assert not inverse.user_tablename or not self.user_tablename or \ inverse.user_tablename == self.user_tablename assert not inverse.remote_colname or not self.local_colname or \ inverse.remote_colname == self.local_colname assert not inverse.local_colname or not self.remote_colname or \ inverse.local_colname == self.remote_colname assert not inverse.schema or not self.schema or \ inverse.schema == self.schema assert not inverse.table_kwargs or not self.table_kwargs or \ inverse.table_kwargs == self.table_kwargs self.user_tablename = inverse.user_tablename or self.user_tablename self.local_colname = inverse.remote_colname or self.local_colname self.remote_colname = inverse.local_colname or self.remote_colname self.schema = inverse.schema or self.schema self.local_colname = inverse.remote_colname or self.local_colname # compute table_kwargs complete_kwargs = options.options_defaults['table_options'].copy() complete_kwargs.update(self.table_kwargs) #needs: table_options['schema'], autoload, tablename, primary_keys, #entity.__name__, table_fullname e1_desc = self.entity._descriptor e2_desc = self.target._descriptor e1_schema = e1_desc.table_options.get('schema', None) e2_schema = e2_desc.table_options.get('schema', None) schema = (self.schema is not None) and self.schema or e1_schema assert e1_schema == e2_schema or self.schema, \ "Schema %r for entity %s differs from schema %r of entity %s." \ " Consider using the schema-parameter. "\ % (e1_schema, self.entity.__name__, e2_schema, self.target.__name__) # First, we compute the name of the table. Note that some of the # intermediary variables are reused later for the constraint # names. # We use the name of the relation for the first entity # (instead of the name of its primary key), so that we can # have two many-to-many relations between the same objects # without having a table name collision. source_part = "%s_%s" % (e1_desc.tablename, self.name) # And we use only the name of the table of the second entity # when there is no inverse, so that a many-to-many relation # can be defined without an inverse. if self.inverse: target_part = "%s_%s" % (e2_desc.tablename, self.inverse.name) else: target_part = e2_desc.tablename if self.user_tablename: tablename = self.user_tablename else: # We need to keep the table name consistent (independant of # whether this relation or its inverse is setup first). if self.inverse and source_part < target_part: #XXX: use a different scheme for selfref (to not include the # table name twice)? tablename = "%s__%s" % (target_part, source_part) else: tablename = "%s__%s" % (source_part, target_part) if options.MIGRATION_TO_07_AID: oldname = (self.inverse and e1_desc.tablename < e2_desc.tablename) and \ "%s__%s" % (target_part, source_part) or \ "%s__%s" % (source_part, target_part) if oldname != tablename: warnings.warn( "The generated table name for the '%s' relationship " "on the '%s' entity changed from '%s' (the name " "generated by Elixir 0.6.1 and earlier) to '%s'. " "You should either rename the table in the database " "to the new name or use the tablename argument on the " "relationship to force the old name: tablename='%s'!" % (self.name, self.entity.__name__, oldname, tablename, oldname)) if e1_desc.autoload: if not e2_desc.autoload: raise Exception( "Entity '%s' is autoloaded and its '%s' " "ManyToMany relationship points to " "the '%s' entity which is not autoloaded" % (self.entity.__name__, self.name, self.target.__name__)) self.table = Table(tablename, e1_desc.metadata, autoload=True, **complete_kwargs) if 'primaryjoin' not in self.kwargs or \ 'secondaryjoin' not in self.kwargs: self._build_join_clauses() else: # We pre-compute the names of the foreign key constraints # pointing to the source (local) entity's table and to the # target's table # In some databases (at least MySQL) the constraint names need # to be unique for the whole database, instead of per table. source_fk_name = "%s_fk" % source_part if self.inverse: target_fk_name = "%s_fk" % target_part else: target_fk_name = "%s_inverse_fk" % source_part columns = [] constraints = [] for num, desc, fk_name, rel, inverse, colnames, join_clauses in ( (0, e1_desc, source_fk_name, self, self.inverse, self.local_colname, self.primaryjoin_clauses), (1, e2_desc, target_fk_name, self.inverse, self, self.remote_colname, self.secondaryjoin_clauses)): fk_colnames = [] fk_refcols = [] if colnames: assert len(colnames) == len(desc.primary_keys) else: # The data generated here will be fed to the M2M column # formatter to generate the name of the columns of the # intermediate table for *one* side of the relationship, # that is, from the intermediate table to the current # entity, as stored in the "desc" variable. data = {# A) relationships info # the name of the rel going *from* the entity # we are currently generating a column pointing # *to*. This is generally *not* what you want to # use. eg in a "Post" and "Tag" example, with # relationships named 'tags' and 'posts', when # creating the columns from the intermediate # table to the "Post" entity, 'relname' will # contain 'tags'. 'relname': rel and rel.name or 'inverse', # the name of the inverse relationship. In the # above example, 'inversename' will contain # 'posts'. 'inversename': inverse and inverse.name or 'inverse', # is A == B? 'selfref': e1_desc is e2_desc, # provided for backward compatibility, DO NOT USE! 'num': num, # provided for backward compatibility, DO NOT USE! 'numifself': e1_desc is e2_desc and str(num + 1) or '', # B) target information (from the perspective of # the intermediate table) 'target': desc.entity, 'entity': desc.entity.__name__.lower(), 'tablename': desc.tablename, # C) current (intermediate) table name 'current_table': tablename } colnames = [] for pk_col in desc.primary_keys: data.update(key=pk_col.key) colnames.append(self.column_format(data)) for pk_col, colname in zip(desc.primary_keys, colnames): col = Column(colname, pk_col.type, primary_key=True) columns.append(col) # Build the list of local columns which will be part # of the foreign key. fk_colnames.append(colname) # Build the list of column "paths" the foreign key will # point to target_path = "%s.%s" % (desc.table_fullname, pk_col.key) fk_refcols.append(target_path) # Build join clauses (in case we have a self-ref) if self.entity is self.target: join_clauses.append(col == pk_col) onupdate = rel and rel.onupdate ondelete = rel and rel.ondelete #FIXME: fk_name is misleading constraints.append( ForeignKeyConstraint(fk_colnames, fk_refcols, name=fk_name, onupdate=onupdate, ondelete=ondelete)) args = columns + constraints self.table = Table(tablename, e1_desc.metadata, schema=schema, *args, **complete_kwargs) if DEBUG: print self.table.repr2() def _build_join_clauses(self): # In the case we have a self-reference, we need to build join clauses if self.entity is self.target: if not self.local_colname and not self.remote_colname: raise Exception( "Self-referential ManyToMany " "relationships in autoloaded entities need to have at " "least one of either 'local_colname' or 'remote_colname' " "argument specified. The '%s' relationship in the '%s' " "entity doesn't have either." % (self.name, self.entity.__name__)) self.primaryjoin_clauses, self.secondaryjoin_clauses = \ _get_join_clauses(self.table, self.local_colname, self.remote_colname, self.entity.table) def get_prop_kwargs(self): kwargs = {'secondary': self.table, 'uselist': self.uselist} if self.filter: # we need to make a copy of the joinclauses secondaryjoin_clauses = self.secondaryjoin_clauses[:] + \ [self.filter(self.target.table.c)] else: secondaryjoin_clauses = self.secondaryjoin_clauses if self.target is self.entity or self.filter: kwargs['primaryjoin'] = and_(*self.primaryjoin_clauses) kwargs['secondaryjoin'] = and_(*secondaryjoin_clauses) kwargs.update(self.kwargs) return kwargs def is_inverse(self, other): return super(ManyToMany, self).is_inverse(other) and \ (self.user_tablename == other.user_tablename or (not self.user_tablename and not other.user_tablename)) def migration_aid_m2m_column_formatter(oldformatter, newformatter): def debug_formatter(data): old_name = oldformatter(data) new_name = newformatter(data) if new_name != old_name: complete_data = data.copy() complete_data.update(old_name=old_name, new_name=new_name, targetname=data['target'].__name__) # Specifying a stacklevel is useless in this case as the name # generation is triggered by setup_all(), not by the declaration # of the offending relationship. warnings.warn("The '%(old_name)s' column in the " "'%(current_table)s' table, used as the " "intermediate table for the '%(relname)s' " "relationship on the '%(targetname)s' entity " "was renamed to '%(new_name)s'." % complete_data) return new_name return debug_formatter def _get_join_clauses(local_table, local_cols1, local_cols2, target_table): primary_join, secondary_join = [], [] cols1 = local_cols1[:] cols1.sort() cols1 = tuple(cols1) if local_cols2 is not None: cols2 = local_cols2[:] cols2.sort() cols2 = tuple(cols2) else: cols2 = None # Build a map of fk constraints pointing to the correct table. # The map is indexed on the local col names. constraint_map = {} for constraint in local_table.constraints: if isinstance(constraint, ForeignKeyConstraint): use_constraint = True fk_colnames = [] # if all columns point to the correct table, we use the constraint #TODO: check that it contains as many columns as the pk of the #target entity, or even that it points to the actual pk columns for fk in constraint.elements: if fk.references(target_table): # local column key fk_colnames.append(fk.parent.key) else: use_constraint = False if use_constraint: fk_colnames.sort() constraint_map[tuple(fk_colnames)] = constraint # Either the fk column names match explicitely with the columns given for # one of the joins (primary or secondary), or we assume the current # columns match because the columns for this join were not given and we # know the other join is either not used (is None) or has an explicit # match. #TODO: rewrite this. Even with the comment, I don't even understand it myself. for cols, constraint in constraint_map.iteritems(): if cols == cols1 or (cols != cols2 and not cols1 and (cols2 in constraint_map or cols2 is None)): join = primary_join elif cols == cols2 or (cols2 == () and cols1 in constraint_map): join = secondary_join else: continue for fk in constraint.elements: join.append(fk.parent == fk.column) return primary_join, secondary_join def rel_mutator_handler(target): def handler(entity, name, of_kind=None, through=None, via=None, *args, **kwargs): if through and via: setattr(entity, name, association_proxy(through, via, **kwargs)) return elif through or via: raise Exception("'through' and 'via' relationship keyword " "arguments should be used in combination.") rel = target(of_kind, *args, **kwargs) rel.attach(entity, name) return handler belongs_to = ClassMutator(rel_mutator_handler(ManyToOne)) has_one = ClassMutator(rel_mutator_handler(OneToOne)) has_many = ClassMutator(rel_mutator_handler(OneToMany)) has_and_belongs_to_many = ClassMutator(rel_mutator_handler(ManyToMany))