2. Using the Tutorial Examples
3. Getting Started with Web Applications
4. JavaServer Faces Technology
7. Using JavaServer Faces Technology in Web Pages
8. Using Converters, Listeners, and Validators
9. Developing with JavaServer Faces Technology
10. JavaServer Faces Technology: Advanced Concepts
11. Using Ajax with JavaServer Faces Technology
12. Composite Components: Advanced Topics and Example
13. Creating Custom UI Components and Other Custom Objects
14. Configuring JavaServer Faces Applications
16. Uploading Files with Java Servlet Technology
17. Internationalizing and Localizing Web Applications
18. Introduction to Web Services
19. Building Web Services with JAX-WS
20. Building RESTful Web Services with JAX-RS
21. JAX-RS: Advanced Topics and Example
23. Getting Started with Enterprise Beans
24. Running the Enterprise Bean Examples
25. A Message-Driven Bean Example
26. Using the Embedded Enterprise Bean Container
27. Using Asynchronous Method Invocation in Session Beans
Part V Contexts and Dependency Injection for the Java EE Platform
28. Introduction to Contexts and Dependency Injection for the Java EE Platform
29. Running the Basic Contexts and Dependency Injection Examples
30. Contexts and Dependency Injection for the Java EE Platform: Advanced Topics
31. Running the Advanced Contexts and Dependency Injection Examples
32. Introduction to the Java Persistence API
Requirements for Entity Classes
Persistent Fields and Properties in Entity Classes
Using Collections in Entity Fields and Properties
Validating Persistent Fields and Properties
Multiplicity in Entity Relationships
Direction in Entity Relationships
Queries and Relationship Direction
Cascade Operations and Relationships
Orphan Removal in Relationships
Embeddable Classes in Entities
Container-Managed Entity Managers
Application-Managed Entity Managers
Finding Entities Using the EntityManager
Managing an Entity Instance's Lifecycle
Synchronizing Entity Data to the Database
Further Information about Persistence
33. Running the Persistence Examples
34. The Java Persistence Query Language
35. Using the Criteria API to Create Queries
36. Creating and Using String-Based Criteria Queries
37. Controlling Concurrent Access to Entity Data with Locking
38. Using a Second-Level Cache with Java Persistence API Applications
39. Introduction to Security in the Java EE Platform
40. Getting Started Securing Web Applications
41. Getting Started Securing Enterprise Applications
42. Java EE Security: Advanced Topics
Part VIII Java EE Supporting Technologies
43. Introduction to Java EE Supporting Technologies
45. Resources and Resource Adapters
46. The Resource Adapter Example
47. Java Message Service Concepts
48. Java Message Service Examples
49. Bean Validation: Advanced Topics
50. Using Java EE Interceptors
51. Duke's Bookstore Case Study Example
52. Duke's Tutoring Case Study Example
53. Duke's Forest Case Study Example
Entity InheritanceEntities support class inheritance, polymorphic associations, and polymorphic queries. Entity classes can extend non-entity classes, and non-entity classes can extend entity classes. Entity classes can be both abstract and concrete.
The roster example application demonstrates entity inheritance, as described in Entity Inheritance in the roster Application.
Abstract EntitiesAn abstract class may be declared an entity by decorating the class with @Entity. Abstract entities are like concrete entities but cannot be instantiated.
Abstract entities can be queried just like concrete entities. If an abstract entity is the target of a query, the query operates on all the concrete subclasses of the abstract entity:
@Entity
public abstract class Employee {
@Id
protected Integer employeeId;
...
}
@Entity
public class FullTimeEmployee extends Employee {
protected Integer salary;
...
}
@Entity
public class PartTimeEmployee extends Employee {
protected Float hourlyWage;
} Mapped Superclasses
Entities may inherit from superclasses that contain persistent state and mapping information but are not entities. That is, the superclass is not decorated with the @Entity annotation and is not mapped as an entity by the Java Persistence provider. These superclasses are most often used when you have state and mapping information common to multiple entity classes.
Mapped superclasses are specified by decorating the class with the annotation javax.persistence.MappedSuperclass:
@MappedSuperclass
public class Employee {
@Id
protected Integer employeeId;
...
}
@Entity
public class FullTimeEmployee extends Employee {
protected Integer salary;
...
}
@Entity
public class PartTimeEmployee extends Employee {
protected Float hourlyWage;
...
}
Mapped superclasses cannot be queried and can’t be used in EntityManager or Query operations. You must use entity subclasses of the mapped superclass in EntityManager or Query operations. Mapped superclasses can’t be targets of entity relationships. Mapped superclasses can be abstract or concrete.
Mapped superclasses do not have any corresponding tables in the underlying datastore. Entities that inherit from the mapped superclass define the table mappings. For instance, in the preceding code sample, the underlying tables would be FULLTIMEEMPLOYEE and PARTTIMEEMPLOYEE, but there is no EMPLOYEE table.
Non-Entity SuperclassesEntities may have non-entity superclasses, and these superclasses can be either abstract or concrete. The state of non-entity superclasses is nonpersistent, and any state inherited from the non-entity superclass by an entity class is nonpersistent. Non-entity superclasses may not be used in EntityManager or Query operations. Any mapping or relationship annotations in non-entity superclasses are ignored.
Entity Inheritance Mapping StrategiesYou can configure how the Java Persistence provider maps inherited entities to the underlying datastore by decorating the root class of the hierarchy with the annotation javax.persistence.Inheritance. The following mapping strategies are used to map the entity data to the underlying database:
A single table per class hierarchy
A table per concrete entity class
A “join” strategy, whereby fields or properties that are specific to a subclass are mapped to a different table than the fields or properties that are common to the parent class
The strategy is configured by setting the strategy element of @Inheritance to one of the options defined in the javax.persistence.InheritanceType enumerated type:
public enum InheritanceType {
SINGLE_TABLE,
JOINED,
TABLE_PER_CLASS
};
The default strategy, InheritanceType.SINGLE_TABLE, is used if the @Inheritance annotation is not specified on the root class of the entity hierarchy.
The Single Table per Class Hierarchy StrategyWith this strategy, which corresponds to the default InheritanceType.SINGLE_TABLE, all classes in the hierarchy are mapped to a single table in the database. This table has a discriminator column containing a value that identifies the subclass to which the instance represented by the row belongs.
The discriminator column, whose elements are shown in Table 32-2, can be specified by using the javax.persistence.DiscriminatorColumn annotation on the root of the entity class hierarchy.
Table 32-2 @DiscriminatorColumn Elements
Type
Name
Description
String
name
The name of the column to be used as the discriminator column. The default is DTYPE. This element is optional.
DiscriminatorType
discriminatorType
The type of the column to be used as a discriminator column. The default is DiscriminatorType.STRING. This element is optional.
String
columnDefinition
The SQL fragment to use when creating the discriminator column. The default is generated by the Persistence provider and is implementation-specific. This element is optional.
String
length
The column length for String-based discriminator types. This element is ignored for non-String discriminator types. The default is 31. This element is optional.
The javax.persistence.DiscriminatorType enumerated type is used to set the type of the discriminator column in the database by setting the discriminatorType element of @DiscriminatorColumn to one of the defined types. DiscriminatorType is defined as:
public enum DiscriminatorType {
STRING,
CHAR,
INTEGER
};
If @DiscriminatorColumn is not specified on the root of the entity hierarchy and a discriminator column is required, the Persistence provider assumes a default column name of DTYPE and column type of DiscriminatorType.STRING.
The javax.persistence.DiscriminatorValue annotation may be used to set the value entered into the discriminator column for each entity in a class hierarchy. You may decorate only concrete entity classes with @DiscriminatorValue.
If @DiscriminatorValue is not specified on an entity in a class hierarchy that uses a discriminator column, the Persistence provider will provide a default, implementation-specific value. If the discriminatorType element of @DiscriminatorColumn is DiscriminatorType.STRING, the default value is the name of the entity.
This strategy provides good support for polymorphic relationships between entities and queries that cover the entire entity class hierarchy. However, this strategy requires the columns that contain the state of subclasses to be nullable.
The Table per Concrete Class StrategyIn this strategy, which corresponds to InheritanceType.TABLE_PER_CLASS, each concrete class is mapped to a separate table in the database. All fields or properties in the class, including inherited fields or properties, are mapped to columns in the class’s table in the database.
This strategy provides poor support for polymorphic relationships and usually requires either SQL UNION queries or separate SQL queries for each subclass for queries that cover the entire entity class hierarchy.
Support for this strategy is optional and may not be supported by all Java Persistence API providers. The default Java Persistence API provider in the GlassFish Server does not support this strategy.
The Joined Subclass StrategyIn this strategy, which corresponds to InheritanceType.JOINED, the root of the class hierarchy is represented by a single table, and each subclass has a separate table that contains only those fields specific to that subclass. That is, the subclass table does not contain columns for inherited fields or properties. The subclass table also has a column or columns that represent its primary key, which is a foreign key to the primary key of the superclass table.
This strategy provides good support for polymorphic relationships but requires one or more join operations to be performed when instantiating entity subclasses. This may result in poor performance for extensive class hierarchies. Similarly, queries that cover the entire class hierarchy require join operations between the subclass tables, resulting in decreased performance.
Some Java Persistence API providers, including the default provider in the GlassFish Server, require a discriminator column that corresponds to the root entity when using the joined subclass strategy. If you are not using automatic table creation in your application, make sure that the database table is set up correctly for the discriminator column defaults, or use the @DiscriminatorColumn annotation to match your database schema. For information on discriminator columns, see The Single Table per Class Hierarchy Strategy.
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