Collection Configuration and Techniques¶
The relationship()
function defines a linkage between two classes.
When the linkage defines a one-to-many or many-to-many relationship, it’s
represented as a Python collection when objects are loaded and manipulated.
This section presents additional information about collection configuration
and techniques.
Working with Large Collections¶
The default behavior of relationship()
is to fully load
the collection of items in, as according to the loading strategy of the
relationship. Additionally, the Session
by default only knows how to delete
objects which are actually present within the session. When a parent instance
is marked for deletion and flushed, the Session
loads its full list of child
items in so that they may either be deleted as well, or have their foreign key
value set to null; this is to avoid constraint violations. For large
collections of child items, there are several strategies to bypass full
loading of child items both at load time as well as deletion time.
Dynamic Relationship Loaders¶
A key feature to enable management of a large collection is the so-called “dynamic”
relationship. This is an optional form of relationship()
which
returns a Query
object in place of a collection
when accessed. filter()
criterion may be
applied as well as limits and offsets, either explicitly or via array slices:
class User(Base):
__tablename__ = 'user'
posts = relationship(Post, lazy="dynamic")
jack = session.query(User).get(id)
# filter Jack's blog posts
posts = jack.posts.filter(Post.headline=='this is a post')
# apply array slices
posts = jack.posts[5:20]
The dynamic relationship supports limited write operations, via the
append()
and remove()
methods:
oldpost = jack.posts.filter(Post.headline=='old post').one()
jack.posts.remove(oldpost)
jack.posts.append(Post('new post'))
Since the read side of the dynamic relationship always queries the
database, changes to the underlying collection will not be visible
until the data has been flushed. However, as long as “autoflush” is
enabled on the Session
in use, this will occur
automatically each time the collection is about to emit a
query.
To place a dynamic relationship on a backref, use the backref()
function in conjunction with lazy='dynamic'
:
class Post(Base):
__table__ = posts_table
user = relationship(User,
backref=backref('posts', lazy='dynamic')
)
Note that eager/lazy loading options cannot be used in conjunction dynamic relationships at this time.
Note
The dynamic_loader()
function is essentially the same
as relationship()
with the lazy='dynamic'
argument specified.
Warning
The “dynamic” loader applies to collections only. It is not valid to use “dynamic” loaders with many-to-one, one-to-one, or uselist=False relationships. Newer versions of SQLAlchemy emit warnings or exceptions in these cases.
Setting Noload, RaiseLoad¶
A “noload” relationship never loads from the database, even when
accessed. It is configured using lazy='noload'
:
class MyClass(Base):
__tablename__ = 'some_table'
children = relationship(MyOtherClass, lazy='noload')
Above, the children
collection is fully writeable, and changes to it will
be persisted to the database as well as locally available for reading at the
time they are added. However when instances of MyClass
are freshly loaded
from the database, the children
collection stays empty. The noload
strategy is also available on a query option basis using the
noload()
loader option.
Alternatively, a “raise”-loaded relationship will raise an
InvalidRequestError
where the attribute would normally
emit a lazy load:
class MyClass(Base):
__tablename__ = 'some_table'
children = relationship(MyOtherClass, lazy='raise')
Above, attribute access on the children
collection will raise an exception
if it was not previously eagerloaded. This includes read access but for
collections will also affect write access, as collections can’t be mutated
without first loading them. The rationale for this is to ensure that an
application is not emitting any unexpected lazy loads within a certain context.
Rather than having to read through SQL logs to determine that all necessary
attributes were eager loaded, the “raise” strategy will cause unloaded
attributes to raise immediately if accessed. The raise strategy is
also available on a query option basis using the raiseload()
loader option.
New in version 1.1: added the “raise” loader strategy.
Using Passive Deletes¶
See Using foreign key ON DELETE cascade with ORM relationships for this section.
Customizing Collection Access¶
Mapping a one-to-many or many-to-many relationship results in a collection of
values accessible through an attribute on the parent instance. By default,
this collection is a list
:
class Parent(Base):
__tablename__ = 'parent'
parent_id = Column(Integer, primary_key=True)
children = relationship(Child)
parent = Parent()
parent.children.append(Child())
print(parent.children[0])
Collections are not limited to lists. Sets, mutable sequences and almost any
other Python object that can act as a container can be used in place of the
default list, by specifying the relationship.collection_class
option on
relationship()
:
class Parent(Base):
__tablename__ = 'parent'
parent_id = Column(Integer, primary_key=True)
# use a set
children = relationship(Child, collection_class=set)
parent = Parent()
child = Child()
parent.children.add(child)
assert child in parent.children
Dictionary Collections¶
A little extra detail is needed when using a dictionary as a collection.
This because objects are always loaded from the database as lists, and a key-generation
strategy must be available to populate the dictionary correctly. The
attribute_mapped_collection()
function is by far the most common way
to achieve a simple dictionary collection. It produces a dictionary class that will apply a particular attribute
of the mapped class as a key. Below we map an Item
class containing
a dictionary of Note
items keyed to the Note.keyword
attribute:
from sqlalchemy import Column, Integer, String, ForeignKey
from sqlalchemy.orm import relationship
from sqlalchemy.orm.collections import attribute_mapped_collection
from sqlalchemy.ext.declarative import declarative_base
Base = declarative_base()
class Item(Base):
__tablename__ = 'item'
id = Column(Integer, primary_key=True)
notes = relationship("Note",
collection_class=attribute_mapped_collection('keyword'),
cascade="all, delete-orphan")
class Note(Base):
__tablename__ = 'note'
id = Column(Integer, primary_key=True)
item_id = Column(Integer, ForeignKey('item.id'), nullable=False)
keyword = Column(String)
text = Column(String)
def __init__(self, keyword, text):
self.keyword = keyword
self.text = text
Item.notes
is then a dictionary:
>>> item = Item()
>>> item.notes['a'] = Note('a', 'atext')
>>> item.notes.items()
{'a': <__main__.Note object at 0x2eaaf0>}
attribute_mapped_collection()
will ensure that
the .keyword
attribute of each Note
complies with the key in the
dictionary. Such as, when assigning to Item.notes
, the dictionary
key we supply must match that of the actual Note
object:
item = Item()
item.notes = {
'a': Note('a', 'atext'),
'b': Note('b', 'btext')
}
The attribute which attribute_mapped_collection()
uses as a key
does not need to be mapped at all! Using a regular Python @property
allows virtually
any detail or combination of details about the object to be used as the key, as
below when we establish it as a tuple of Note.keyword
and the first ten letters
of the Note.text
field:
class Item(Base):
__tablename__ = 'item'
id = Column(Integer, primary_key=True)
notes = relationship("Note",
collection_class=attribute_mapped_collection('note_key'),
backref="item",
cascade="all, delete-orphan")
class Note(Base):
__tablename__ = 'note'
id = Column(Integer, primary_key=True)
item_id = Column(Integer, ForeignKey('item.id'), nullable=False)
keyword = Column(String)
text = Column(String)
@property
def note_key(self):
return (self.keyword, self.text[0:10])
def __init__(self, keyword, text):
self.keyword = keyword
self.text = text
Above we added a Note.item
backref. Assigning to this reverse relationship, the Note
is added to the Item.notes
dictionary and the key is generated for us automatically:
>>> item = Item()
>>> n1 = Note("a", "atext")
>>> n1.item = item
>>> item.notes
{('a', 'atext'): <__main__.Note object at 0x2eaaf0>}
Other built-in dictionary types include column_mapped_collection()
,
which is almost like attribute_mapped_collection()
except given the Column
object directly:
from sqlalchemy.orm.collections import column_mapped_collection
class Item(Base):
__tablename__ = 'item'
id = Column(Integer, primary_key=True)
notes = relationship("Note",
collection_class=column_mapped_collection(Note.__table__.c.keyword),
cascade="all, delete-orphan")
as well as mapped_collection()
which is passed any callable function.
Note that it’s usually easier to use attribute_mapped_collection()
along
with a @property
as mentioned earlier:
from sqlalchemy.orm.collections import mapped_collection
class Item(Base):
__tablename__ = 'item'
id = Column(Integer, primary_key=True)
notes = relationship("Note",
collection_class=mapped_collection(lambda note: note.text[0:10]),
cascade="all, delete-orphan")
Dictionary mappings are often combined with the “Association Proxy” extension to produce streamlined dictionary views. See Proxying to Dictionary Based Collections and Composite Association Proxies for examples.
Dealing with Key Mutations and back-populating for Dictionary collections¶
When using attribute_mapped_collection()
, the “key” for the dictionary
is taken from an attribute on the target object. Changes to this key
are not tracked. This means that the key must be assigned towards when
it is first used, and if the key changes, the collection will not be mutated.
A typical example where this might be an issue is when relying upon backrefs
to populate an attribute mapped collection. Given the following:
class A(Base):
__tablename__ = "a"
id = Column(Integer, primary_key=True)
bs = relationship(
"B",
collection_class=attribute_mapped_collection("data"),
back_populates="a",
)
class B(Base):
__tablename__ = "b"
id = Column(Integer, primary_key=True)
a_id = Column(ForeignKey("a.id"))
data = Column(String)
a = relationship("A", back_populates="bs")
Above, if we create a B()
that refers to a specific A()
, the back
populates will then add the B()
to the A.bs
collection, however
if the value of B.data
is not set yet, the key will be None
:
>>> a1 = A()
>>> b1 = B(a=a1)
>>> a1.bs
{None: <test3.B object at 0x7f7b1023ef70>}
Setting b1.data
after the fact does not update the collection:
>>> b1.data = 'the key'
>>> a1.bs
{None: <test3.B object at 0x7f7b1023ef70>}
This can also be seen if one attempts to set up B()
in the constructor.
The order of arguments changes the result:
>>> B(a=a1, data='the key')
<test3.B object at 0x7f7b10114280>
>>> a1.bs
{None: <test3.B object at 0x7f7b10114280>}
vs:
>>> B(data='the key', a=a1)
<test3.B object at 0x7f7b10114340>
>>> a1.bs
{'the key': <test3.B object at 0x7f7b10114340>}
If backrefs are being used in this way, ensure that attributes are populated
in the correct order using an __init__
method.
An event handler such as the following may also be used to track changes in the collection as well:
from sqlalchemy import event
from sqlalchemy.orm import attributes
@event.listens_for(B.data, "set")
def set_item(obj, value, previous, initiator):
if obj.a is not None:
previous = None if previous == attributes.NO_VALUE else previous
obj.a.bs[value] = obj
obj.a.bs.pop(previous)
Object Name | Description |
---|---|
attribute_mapped_collection(attr_name) |
A dictionary-based collection type with attribute-based keying. |
column_mapped_collection(mapping_spec) |
A dictionary-based collection type with column-based keying. |
mapped_collection(keyfunc) |
A dictionary-based collection type with arbitrary keying. |
- function sqlalchemy.orm.collections.attribute_mapped_collection(attr_name)¶
A dictionary-based collection type with attribute-based keying.
Returns a
MappedCollection
factory with a keying based on the ‘attr_name’ attribute of entities in the collection, whereattr_name
is the string name of the attribute.Warning
the key value must be assigned to its final value before it is accessed by the attribute mapped collection. Additionally, changes to the key attribute are not tracked automatically, which means the key in the dictionary is not automatically synchronized with the key value on the target object itself. See the section Dealing with Key Mutations and back-populating for Dictionary collections for an example.
- function sqlalchemy.orm.collections.column_mapped_collection(mapping_spec)¶
A dictionary-based collection type with column-based keying.
Returns a
MappedCollection
factory with a keying function generated from mapping_spec, which may be a Column or a sequence of Columns.The key value must be immutable for the lifetime of the object. You can not, for example, map on foreign key values if those key values will change during the session, i.e. from None to a database-assigned integer after a session flush.
- function sqlalchemy.orm.collections.mapped_collection(keyfunc)¶
A dictionary-based collection type with arbitrary keying.
Returns a
MappedCollection
factory with a keying function generated from keyfunc, a callable that takes an entity and returns a key value.The key value must be immutable for the lifetime of the object. You can not, for example, map on foreign key values if those key values will change during the session, i.e. from None to a database-assigned integer after a session flush.
Custom Collection Implementations¶
You can use your own types for collections as well. In simple cases,
inheriting from list
or set
, adding custom behavior, is all that’s needed.
In other cases, special decorators are needed to tell SQLAlchemy more detail
about how the collection operates.
Collections in SQLAlchemy are transparently instrumented. Instrumentation
means that normal operations on the collection are tracked and result in
changes being written to the database at flush time. Additionally, collection
operations can fire events which indicate some secondary operation must take
place. Examples of a secondary operation include saving the child item in the
parent’s Session
(i.e. the save-update
cascade), as well as synchronizing the state of a bi-directional relationship
(i.e. a backref()
).
The collections package understands the basic interface of lists, sets and dicts and will automatically apply instrumentation to those built-in types and their subclasses. Object-derived types that implement a basic collection interface are detected and instrumented via duck-typing:
class ListLike(object):
def __init__(self):
self.data = []
def append(self, item):
self.data.append(item)
def remove(self, item):
self.data.remove(item)
def extend(self, items):
self.data.extend(items)
def __iter__(self):
return iter(self.data)
def foo(self):
return 'foo'
append
, remove
, and extend
are known list-like methods, and will
be instrumented automatically. __iter__
is not a mutator method and won’t
be instrumented, and foo
won’t be either.
Duck-typing (i.e. guesswork) isn’t rock-solid, of course, so you can be
explicit about the interface you are implementing by providing an
__emulates__
class attribute:
class SetLike(object):
__emulates__ = set
def __init__(self):
self.data = set()
def append(self, item):
self.data.add(item)
def remove(self, item):
self.data.remove(item)
def __iter__(self):
return iter(self.data)
This class looks list-like because of append
, but __emulates__
forces
it to set-like. remove
is known to be part of the set interface and will
be instrumented.
But this class won’t work quite yet: a little glue is needed to adapt it for
use by SQLAlchemy. The ORM needs to know which methods to use to append,
remove and iterate over members of the collection. When using a type like
list
or set
, the appropriate methods are well-known and used
automatically when present. This set-like class does not provide the expected
add
method, so we must supply an explicit mapping for the ORM via a
decorator.
Annotating Custom Collections via Decorators¶
Decorators can be used to tag the individual methods the ORM needs to manage collections. Use them when your class doesn’t quite meet the regular interface for its container type, or when you otherwise would like to use a different method to get the job done.
from sqlalchemy.orm.collections import collection
class SetLike(object):
__emulates__ = set
def __init__(self):
self.data = set()
@collection.appender
def append(self, item):
self.data.add(item)
def remove(self, item):
self.data.remove(item)
def __iter__(self):
return iter(self.data)
And that’s all that’s needed to complete the example. SQLAlchemy will add
instances via the append
method. remove
and __iter__
are the
default methods for sets and will be used for removing and iteration. Default
methods can be changed as well:
from sqlalchemy.orm.collections import collection
class MyList(list):
@collection.remover
def zark(self, item):
# do something special...
@collection.iterator
def hey_use_this_instead_for_iteration(self):
# ...
There is no requirement to be list-, or set-like at all. Collection classes can be any shape, so long as they have the append, remove and iterate interface marked for SQLAlchemy’s use. Append and remove methods will be called with a mapped entity as the single argument, and iterator methods are called with no arguments and must return an iterator.
Object Name | Description |
---|---|
Decorators for entity collection classes. |
- class sqlalchemy.orm.collections.collection¶
Decorators for entity collection classes.
The decorators fall into two groups: annotations and interception recipes.
The annotating decorators (appender, remover, iterator, linker, converter, internally_instrumented) indicate the method’s purpose and take no arguments. They are not written with parens:
@collection.appender def append(self, append): ...
The recipe decorators all require parens, even those that take no arguments:
Members
adds(), appender(), converter(), internally_instrumented(), iterator(), link(), linker(), remover(), removes(), removes_return(), replaces()
@collection.adds('entity') def insert(self, position, entity): ... @collection.removes_return() def popitem(self): ...
-
method
sqlalchemy.orm.collections.collection.
static adds(arg)¶ Mark the method as adding an entity to the collection.
Adds “add to collection” handling to the method. The decorator argument indicates which method argument holds the SQLAlchemy-relevant value. Arguments can be specified positionally (i.e. integer) or by name:
@collection.adds(1) def push(self, item): ... @collection.adds('entity') def do_stuff(self, thing, entity=None): ...
-
method
sqlalchemy.orm.collections.collection.
static appender(fn)¶ Tag the method as the collection appender.
The appender method is called with one positional argument: the value to append. The method will be automatically decorated with ‘adds(1)’ if not already decorated:
@collection.appender def add(self, append): ... # or, equivalently @collection.appender @collection.adds(1) def add(self, append): ... # for mapping type, an 'append' may kick out a previous value # that occupies that slot. consider d['a'] = 'foo'- any previous # value in d['a'] is discarded. @collection.appender @collection.replaces(1) def add(self, entity): key = some_key_func(entity) previous = None if key in self: previous = self[key] self[key] = entity return previous
If the value to append is not allowed in the collection, you may raise an exception. Something to remember is that the appender will be called for each object mapped by a database query. If the database contains rows that violate your collection semantics, you will need to get creative to fix the problem, as access via the collection will not work.
If the appender method is internally instrumented, you must also receive the keyword argument ‘_sa_initiator’ and ensure its promulgation to collection events.
-
method
sqlalchemy.orm.collections.collection.
static converter(fn)¶ Tag the method as the collection converter.
Deprecated since version 1.3: The
collection.converter()
handler is deprecated and will be removed in a future release. Please refer to thebulk_replace
listener interface in conjunction with thelisten()
function.This optional method will be called when a collection is being replaced entirely, as in:
myobj.acollection = [newvalue1, newvalue2]
The converter method will receive the object being assigned and should return an iterable of values suitable for use by the
appender
method. A converter must not assign values or mutate the collection, its sole job is to adapt the value the user provides into an iterable of values for the ORM’s use.The default converter implementation will use duck-typing to do the conversion. A dict-like collection will be convert into an iterable of dictionary values, and other types will simply be iterated:
@collection.converter def convert(self, other): ...
If the duck-typing of the object does not match the type of this collection, a TypeError is raised.
Supply an implementation of this method if you want to expand the range of possible types that can be assigned in bulk or perform validation on the values about to be assigned.
-
method
sqlalchemy.orm.collections.collection.
static internally_instrumented(fn)¶ Tag the method as instrumented.
This tag will prevent any decoration from being applied to the method. Use this if you are orchestrating your own calls to
collection_adapter()
in one of the basic SQLAlchemy interface methods, or to prevent an automatic ABC method decoration from wrapping your implementation:# normally an 'extend' method on a list-like class would be # automatically intercepted and re-implemented in terms of # SQLAlchemy events and append(). your implementation will # never be called, unless: @collection.internally_instrumented def extend(self, items): ...
-
method
sqlalchemy.orm.collections.collection.
static iterator(fn)¶ Tag the method as the collection remover.
The iterator method is called with no arguments. It is expected to return an iterator over all collection members:
@collection.iterator def __iter__(self): ...
-
method
sqlalchemy.orm.collections.collection.
static link(fn)¶ Synonym for
collection.linker()
.Deprecated since version 1.0: -
collection.link()
is deprecated and will be removed in a future release.
-
method
sqlalchemy.orm.collections.collection.
static linker(fn)¶ Tag the method as a “linked to attribute” event handler.
Deprecated since version 1.0: The
collection.linker()
handler is deprecated and will be removed in a future release. Please refer to theAttributeEvents.init_collection()
andAttributeEvents.dispose_collection()
event handlers.This optional event handler will be called when the collection class is linked to or unlinked from the InstrumentedAttribute. It is invoked immediately after the ‘_sa_adapter’ property is set on the instance. A single argument is passed: the collection adapter that has been linked, or None if unlinking.
-
method
sqlalchemy.orm.collections.collection.
static remover(fn)¶ Tag the method as the collection remover.
The remover method is called with one positional argument: the value to remove. The method will be automatically decorated with
removes_return()
if not already decorated:@collection.remover def zap(self, entity): ... # or, equivalently @collection.remover @collection.removes_return() def zap(self, ): ...
If the value to remove is not present in the collection, you may raise an exception or return None to ignore the error.
If the remove method is internally instrumented, you must also receive the keyword argument ‘_sa_initiator’ and ensure its promulgation to collection events.
-
method
sqlalchemy.orm.collections.collection.
static removes(arg)¶ Mark the method as removing an entity in the collection.
Adds “remove from collection” handling to the method. The decorator argument indicates which method argument holds the SQLAlchemy-relevant value to be removed. Arguments can be specified positionally (i.e. integer) or by name:
@collection.removes(1) def zap(self, item): ...
For methods where the value to remove is not known at call-time, use collection.removes_return.
-
method
sqlalchemy.orm.collections.collection.
static removes_return()¶ Mark the method as removing an entity in the collection.
Adds “remove from collection” handling to the method. The return value of the method, if any, is considered the value to remove. The method arguments are not inspected:
@collection.removes_return() def pop(self): ...
For methods where the value to remove is known at call-time, use collection.remove.
-
method
sqlalchemy.orm.collections.collection.
static replaces(arg)¶ Mark the method as replacing an entity in the collection.
Adds “add to collection” and “remove from collection” handling to the method. The decorator argument indicates which method argument holds the SQLAlchemy-relevant value to be added, and return value, if any will be considered the value to remove.
Arguments can be specified positionally (i.e. integer) or by name:
@collection.replaces(2) def __setitem__(self, index, item): ...
-
method
Custom Dictionary-Based Collections¶
The MappedCollection
class can be used as
a base class for your custom types or as a mix-in to quickly add dict
collection support to other classes. It uses a keying function to delegate to
__setitem__
and __delitem__
:
from sqlalchemy.util import OrderedDict
from sqlalchemy.orm.collections import MappedCollection
class NodeMap(OrderedDict, MappedCollection):
"""Holds 'Node' objects, keyed by the 'name' attribute with insert order maintained."""
def __init__(self, *args, **kw):
MappedCollection.__init__(self, keyfunc=lambda node: node.name)
OrderedDict.__init__(self, *args, **kw)
When subclassing MappedCollection
, user-defined versions
of __setitem__()
or __delitem__()
should be decorated
with collection.internally_instrumented()
, if they call down
to those same methods on MappedCollection
. This because the methods
on MappedCollection
are already instrumented - calling them
from within an already instrumented call can cause events to be fired off
repeatedly, or inappropriately, leading to internal state corruption in
rare cases:
from sqlalchemy.orm.collections import MappedCollection,\
collection
class MyMappedCollection(MappedCollection):
"""Use @internally_instrumented when your methods
call down to already-instrumented methods.
"""
@collection.internally_instrumented
def __setitem__(self, key, value, _sa_initiator=None):
# do something with key, value
super(MyMappedCollection, self).__setitem__(key, value, _sa_initiator)
@collection.internally_instrumented
def __delitem__(self, key, _sa_initiator=None):
# do something with key
super(MyMappedCollection, self).__delitem__(key, _sa_initiator)
The ORM understands the dict
interface just like lists and sets, and will
automatically instrument all dict-like methods if you choose to subclass
dict
or provide dict-like collection behavior in a duck-typed class. You
must decorate appender and remover methods, however- there are no compatible
methods in the basic dictionary interface for SQLAlchemy to use by default.
Iteration will go through itervalues()
unless otherwise decorated.
Note
Due to a bug in MappedCollection prior to version 0.7.6, this
workaround usually needs to be called before a custom subclass
of MappedCollection
which uses collection.internally_instrumented()
can be used:
from sqlalchemy.orm.collections import _instrument_class, MappedCollection
_instrument_class(MappedCollection)
This will ensure that the MappedCollection
has been properly
initialized with custom __setitem__()
and __delitem__()
methods before used in a custom subclass.
Object Name | Description |
---|---|
A basic dictionary-based collection class. |
- class sqlalchemy.orm.collections.MappedCollection(keyfunc)¶
A basic dictionary-based collection class.
Extends dict with the minimal bag semantics that collection classes require.
set
andremove
are implemented in terms of a keying function: any callable that takes an object and returns an object for use as a dictionary key.Members
__init__(), clear(), pop(), popitem(), remove(), set(), setdefault(), update()
Class signature
class
sqlalchemy.orm.collections.MappedCollection
(builtins.dict
)-
method
sqlalchemy.orm.collections.MappedCollection.
__init__(keyfunc)¶ Create a new collection with keying provided by keyfunc.
keyfunc may be any callable that takes an object and returns an object for use as a dictionary key.
The keyfunc will be called every time the ORM needs to add a member by value-only (such as when loading instances from the database) or remove a member. The usual cautions about dictionary keying apply-
keyfunc(object)
should return the same output for the life of the collection. Keying based on mutable properties can result in unreachable instances “lost” in the collection.
-
method
sqlalchemy.orm.collections.MappedCollection.
clear() None. Remove all items from D. ¶
-
method
sqlalchemy.orm.collections.MappedCollection.
pop(k[, d]) v, remove specified key and return the corresponding value. ¶ If the key is not found, return the default if given; otherwise, raise a KeyError.
-
method
sqlalchemy.orm.collections.MappedCollection.
popitem()¶ Remove and return a (key, value) pair as a 2-tuple.
Pairs are returned in LIFO (last-in, first-out) order. Raises KeyError if the dict is empty.
-
method
sqlalchemy.orm.collections.MappedCollection.
remove(value, _sa_initiator=None)¶ Remove an item by value, consulting the keyfunc for the key.
-
method
sqlalchemy.orm.collections.MappedCollection.
set(value, _sa_initiator=None)¶ Add an item by value, consulting the keyfunc for the key.
-
method
sqlalchemy.orm.collections.MappedCollection.
setdefault(key, default=None)¶ Insert key with a value of default if key is not in the dictionary.
Return the value for key if key is in the dictionary, else default.
-
method
sqlalchemy.orm.collections.MappedCollection.
update([E, ]**F) None. Update D from dict/iterable E and F. ¶ If E is present and has a .keys() method, then does: for k in E: D[k] = E[k] If E is present and lacks a .keys() method, then does: for k, v in E: D[k] = v In either case, this is followed by: for k in F: D[k] = F[k]
-
method
Instrumentation and Custom Types¶
Many custom types and existing library classes can be used as a entity collection type as-is without further ado. However, it is important to note that the instrumentation process will modify the type, adding decorators around methods automatically.
The decorations are lightweight and no-op outside of relationships, but they do add unneeded overhead when triggered elsewhere. When using a library class as a collection, it can be good practice to use the “trivial subclass” trick to restrict the decorations to just your usage in relationships. For example:
class MyAwesomeList(some.great.library.AwesomeList):
pass
# ... relationship(..., collection_class=MyAwesomeList)
The ORM uses this approach for built-ins, quietly substituting a trivial
subclass when a list
, set
or dict
is used directly.
Collection Internals¶
Various internal methods.
Object Name | Description |
---|---|
bulk_replace(values, existing_adapter, new_adapter[, initiator]) |
Load a new collection, firing events based on prior like membership. |
Decorators for entity collection classes. |
|
Fetch the |
|
Bridges between the ORM and arbitrary Python collections. |
|
An instrumented version of the built-in dict. |
|
An instrumented version of the built-in list. |
|
An instrumented version of the built-in set. |
|
prepare_instrumentation(factory) |
Prepare a callable for future use as a collection class factory. |
- function sqlalchemy.orm.collections.bulk_replace(values, existing_adapter, new_adapter, initiator=None)¶
Load a new collection, firing events based on prior like membership.
Appends instances in
values
onto thenew_adapter
. Events will be fired for any instance not present in theexisting_adapter
. Any instances inexisting_adapter
not present invalues
will have remove events fired upon them.- Parameters:
values – An iterable of collection member instances
existing_adapter – A
CollectionAdapter
of instances to be replacednew_adapter – An empty
CollectionAdapter
to load withvalues
- class sqlalchemy.orm.collections.collection¶
Decorators for entity collection classes.
The decorators fall into two groups: annotations and interception recipes.
The annotating decorators (appender, remover, iterator, linker, converter, internally_instrumented) indicate the method’s purpose and take no arguments. They are not written with parens:
@collection.appender def append(self, append): ...
The recipe decorators all require parens, even those that take no arguments:
@collection.adds('entity') def insert(self, position, entity): ... @collection.removes_return() def popitem(self): ...
- sqlalchemy.orm.collections.collection_adapter = operator.attrgetter('_sa_adapter')¶
Fetch the
CollectionAdapter
for a collection.
- class sqlalchemy.orm.collections.CollectionAdapter(attr, owner_state, data)¶
Bridges between the ORM and arbitrary Python collections.
Proxies base-level collection operations (append, remove, iterate) to the underlying Python collection, and emits add/remove events for entities entering or leaving the collection.
The ORM uses
CollectionAdapter
exclusively for interaction with entity collections.
- class sqlalchemy.orm.collections.InstrumentedDict¶
An instrumented version of the built-in dict.
Class signature
class
sqlalchemy.orm.collections.InstrumentedDict
(builtins.dict
)
- class sqlalchemy.orm.collections.InstrumentedList(iterable=(), /)¶
An instrumented version of the built-in list.
Class signature
class
sqlalchemy.orm.collections.InstrumentedList
(builtins.list
)
- class sqlalchemy.orm.collections.InstrumentedSet¶
An instrumented version of the built-in set.
Class signature
class
sqlalchemy.orm.collections.InstrumentedSet
(builtins.set
)
- function sqlalchemy.orm.collections.prepare_instrumentation(factory)¶
Prepare a callable for future use as a collection class factory.
Given a collection class factory (either a type or no-arg callable), return another factory that will produce compatible instances when called.
This function is responsible for converting collection_class=list into the run-time behavior of collection_class=InstrumentedList.