@Documented
@Retention(RUNTIME)
@Target(TYPE)
public @interface Entity
PrimaryIndex
can be used to store and access instances of that class.
Optionally, one or more SecondaryIndex
objects may be used to access
entity instances by secondary key.
Entity Subclasses and Superclasses
An entity class may have any number of subclasses and superclasses;
however, none of these may themselves be entity classes (annotated with
Entity
).
Entity superclasses (which must be annotated with Persistent
, not
Entity
) are used to share common definitions among entity classes.
Fields in an entity superclass may be defined as primary or secondary keys.
For example, the following BaseClass
defines the primary key for any
number of entity classes, using a single sequence to assign primary key
values that will be unique across all entity classes that use it. The
entity class Pet
extends the base class, implicitly defining a
primary index
@Persistent class BaseClass { @PrimaryKey(sequence="ID") long id; } @Entity class Pet extends BaseClass { @SecondaryKey(relate=ONE_TO_ONE) String name; float height; float weight; }
Entity subclasses (which must be annotated with Persistent
, not
Entity
) are used to provide polymorphism within a single
PrimaryIndex
. Instances of the entity class and its subclasses are stored
in the same PrimaryIndex
. For example, the entity class Pet
defines a primary index that will contain instances of it and its
subclasses, including Cat
which is defined below.
Fields in an entity subclass may be defined as secondary keys, and such
secondary keys can only be used to query instances of the subclass. For
example, although the primary key (id
) and secondary key (
name
) can be used to retrieve any Pet
instance, the entity subclass
Cat
defines a secondary key (finickyness
) that only applies
to Cat
instances. Querying by this key will never retrieve a
Dog
instance, if such a subclass existed, because a Dog
instance
will never contain a finickyness
key.
@Persistent class Cat extends Pet { @SecondaryKey(relate=MANY_TO_ONE) int finickyness; }
WARNING: Entity subclasses that define secondary keys must be registered prior to storing an instance of the class. This can be done in two ways:
registerClass
method may be called
to register the subclass before opening the entity store.getSubclassIndex
method may be
called to implicitly register the subclass after opening the entity
store.Persistent Fields and Types
All non-transient instance fields of an entity class, as well as its
superclasses and subclasses, are persistent. static
and
transient
fields are not persistent. The persistent fields of a class may
be private
, package-private (default access), protected
or
public
.
It is worthwhile to note the reasons that object persistence is defined in terms of fields rather than properties (getters and setters). This allows business methods (getters and setters) to be defined independently of the persistent state of an object; for example, a setter method may perform validation that could not be performed if it were called during object deserialization. Similarly, this allows public methods to evolve somewhat independently of the (typically non-public) persistent fields.
Persistent types are divided into simple types, enum types, complex types, and array types. Simple types and enum types are single valued, while array types may contain multiple elements and complex types may contain one or more named fields.
Simple types include:
boolean, char, byte, short, int, long,
float, double
BigDecimal
BigInteger
String
Date
When null values are required (for optional key fields, for example), primitive wrapper classes must be used instead of primitive types.
Simple types, enum types and array types do not require annotations to make them persistent.
Complex persistent classes must be annotated with Entity
or
Persistent
, or must be proxied by a persistent proxy class
(described below). This includes entity classes, subclasses and
superclasses, and all other complex classes referenced via fields of these
classes.
All complex persistent classes must have a default constructor. The
default constructor may be private
, package-private (default
access), protected
, or public
. Other constructors are
allowed but are not used by the persistence mechanism.
It is sometimes desirable to store instances of a type that is externally
defined and cannot be annotated or does not have a default constructor; for
example, a class defined in the Java standard libraries or a 3rd party
library. In this case, a PersistentProxy
class may be used to
represent the stored values for the externally defined type. The proxy
class itself must be annotated with Persistent
like other persistent
classes, and the Persistent.proxyFor()
property must be specified.
For convenience, built-in proxy classes are included for several common
classes (listed below) in the Java library. If you wish, you may define
your own PersistentProxy
to override these built-in proxies.
HashSet
TreeSet
HashMap
TreeMap
ArrayList
LinkedList
Complex persistent types should in general be application-defined classes. This gives the application control over the persistent state and its evolution over time.
Other Type Restrictions
Entity classes and subclasses may not be used in field declarations for
persistent types. Fields of entity classes and subclasses must be simple
types or non-entity persistent types (annotated with Persistent
not
with Entity
).
Entity classes, subclasses and superclasses may be abstract
and
may implement arbitrary interfaces. Interfaces do not need to be annotated
with Persistent
in order to be used in a persistent class, since
interfaces do not contain instance fields.
Persistent instances of static nested classes are allowed, but the nested
class must be annotated with Persistent
or Entity
. Inner
classes (non-static nested classes, including anonymous classes) are not
currently allowed as persistent types.
Arrays of simple and persistent complex types are allowed as fields of persistent types. Arrays may be multidimensional. However, an array may not be stored as a top level instance in a primary index. Only instances of entity classes and subclasses may be top level instances in a primary index.
Embedded Objects
As stated above, the embedded (or member) non-transient non-static fields of an entity class are themselves persistent and are stored along with their parent entity object. This allows embedded objects to be stored in an entity to an arbitrary depth.
There is no arbitrary limit to the nesting depth of embedded objects
within an entity; however, there is a practical limit. When an entity is
marshalled, each level of nesting is implemented internally via recursive
method calls. If the nesting depth is large enough, a
StackOverflowError
can occur. In practice, this has been observed with a
nesting depth of 12,000, using the default Java stack size.
This restriction on the nesting depth of embedded objects does not apply to cyclic references, since these are handled specially as described below.
Object Graphs
When an entity instance is stored, the graph of objects referenced via its fields is stored and retrieved as a graph. In other words, if a single instance is referenced by two or more fields when the entity is stored, the same will be true when the entity is retrieved.
When a reference to a particular object is stored as a member field inside that object or one of its embedded objects, this is called a cyclic reference. Because multiple references to a single object are stored as such, cycles are also represented correctly and do not cause infinite recursion or infinite processing loops. If an entity containing a cyclic reference is stored, the cyclic reference will be present when the entity is retrieved.
Note that the stored object graph is restricted in scope to a single entity instance. This is because each entity instance is stored separately. If two entities have a reference to the same object when stored, they will refer to two separate instances when the entities are retrieved.
Persistent
,
PrimaryKey
,
SecondaryKey
,
KeyField
Modifier and Type | Optional Element | Description |
---|---|---|
int |
version |
Identifies a new version of a class when an incompatible class change
has been made.
|
int version
Mutations
.
The first version of a class is version zero, if version()
is
not specified. When an incompatible class change is made, a version
number must be assigned using version()
that is higher than the
previous version number for the class. If this is not done, an IncompatibleClassException
will be thrown when the store is opened.
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