• JPA 教程


    Entities

    An entity is a lightweight persistence domain object. Typically an entity represents a table in a relational database, and each entity instance corresponds to a row in that table. The primary programming artifact of an entity is the entity class, although entities can use helper classes.

    The persistent state of an entity is represented either through persistent fields or persistent properties. These fields or properties use object/relational mapping annotations to map the entities and entity relationships to the relational data in the underlying data store.

    Requirements for Entity Classes

    An entity class must follow these requirements:

    • The class must be annotated with the javax.persistence.Entity annotation.

    • The class must have a public or protected, no-argument constructor. The class may have other constructors.

    • The class must not be declared final. No methods or persistent instance variables must be declared final.

    • If an entity instance be passed by value as a detached object, such as through a session bean’s remote business interface, the class must implement the Serializableinterface.

    • Entities may extend both entity and non-entity classes, and non-entity classes may extend entity classes.

    • Persistent instance variables must be declared private, protected, or package-private, and can only be accessed directly by the entity class’s methods. Clients must access the entity’s state through accessor or business methods.

    Persistent Fields and Properties in Entity Classes

    The persistent state of an entity can be accessed either through the entity’s instance variables or through JavaBeans-style properties. The fields or properties must be of the following Java language types:

    • Java primitive types

    • java.lang.String

    • Other serializable types including:

      • Wrappers of Java primitive types

      • java.math.BigInteger

      • java.math.BigDecimal

      • java.util.Date

      • java.util.Calendar

      • java.sql.Date

      • java.sql.Time

      • java.sql.TimeStamp

      • User-defined serializable types

      • byte[]

      • Byte[]

      • char[]

      • Character[]

    • Enumerated types

    • Other entities and/or collections of entities

    • Embeddable classes

    Entities may either use persistent fields or persistent properties. If the mapping annotations are applied to the entity’s instance variables, the entity uses persistent fields. If the mapping annotations are applied to the entity’s getter methods for JavaBeans-style properties, the entity uses persistent properties. You cannot apply mapping annotations to both fields and properties in a single entity.

    Persistent Fields

    If the entity class uses persistent fields, the Persistence runtime accesses entity class instance variables directly. All fields not annotated javax.persistence.Transient or not marked as Java transient will be persisted to the data store. The object/relational mapping annotations must be applied to the instance variables.

    Persistent Properties

    If the entity uses persistent properties, the entity must follow the method conventions of JavaBeans components. JavaBeans-style properties use getter and setter methods that are typically named after the entity class’s instance variable names. For every persistent property property of type Type of the entity, there is a getter method getProperty and setter method setProperty. If the property is a boolean, you may use isProperty instead of getProperty. For example, if a Customer entity uses persistent properties, and has a private instance variable called firstName, the class defines a getFirstName and setFirstName method for retrieving and setting the state of the firstName instance variable.

    The method signature for single-valued persistent properties are as follows:

    Type getProperty()
    void setProperty(Type type)

    Collection-valued persistent fields and properties must use the supported Java collection interfaces regardless of whether the entity uses persistent fields or properties. The following collection interfaces may be used:

    • java.util.Collection

    • java.util.Set

    • java.util.List

    • java.util.Map

    If the entity class uses persistent fields, the type in the above method signatures must be one of these collection types. Generic variants of these collection types may also be used. For example, if the Customer entity has a persistent property that contains a set of phone numbers, it would have the following methods:

    Set<PhoneNumber> getPhoneNumbers() {}
    void setPhoneNumbers(Set<PhoneNumber>) {}

    The object/relational mapping annotations for must be applied to the getter methods. Mapping annotations cannot be applied to fields or properties annotated @Transient or marked transient.

    Primary Keys in Entities

    Each entity has a unique object identifier. A customer entity, for example, might be identified by a customer number. The unique identifier, or primary key, enables clients to locate a particular entity instance. Every entity must have a primary key. An entity may have either a simple or a composite primary key.

    Simple primary keys use the javax.persistence.Id annotation to denote the primary key property or field.

    Composite primary keys must correspond to either a single persistent property or field, or to a set of single persistent properties or fields. Composite primary keys must be defined in a primary key class. Composite primary keys are denoted using the javax.persistence.EmbeddedId and javax.persistence.IdClass annotations.

    The primary key, or the property or field of a composite primary key, must be one of the following Java language types:

    • Java primitive types

    • Java primitive wrapper types

    • java.lang.String

    • java.util.Date (the temporal type should be DATE)

    • java.sql.Date

    Floating point types should never be used in primary keys. If you use a generated primary key, only integral types will be portable.

    Primary Key Classes

    A primary key class must meet these requirements:

    • The access control modifier of the class must be public.

    • The properties of the primary key class must be public or protected if property-based access is used.

    • The class must have a public default constructor.

    • The class must implement the hashCode() and equals(Object other) methods.

    • The class must be serializable.

    • A composite primary key must be represented and mapped to multiple fields or properties of the entity class, or must be represented and mapped as an embeddable class.

    • If the class is mapped to multiple fields or properties of the entity class, the names and types of the primary key fields or properties in the primary key class must match those of the entity class.

    The following primary key class is a composite key, the orderId and itemId fields together uniquely identify an entity.

    public final class LineItemKey implements Serializable {
        public Integer orderId;
        public int itemId;
    
        public LineItemKey() {}
    
        public LineItemKey(Integer orderId, int itemId) {
            this.orderId = orderId;
            this.itemId = itemId;
        }
    
        public boolean equals(Object otherOb) {
            if (this == otherOb) {
                return true;
            }
            if (!(otherOb instanceof LineItemKey)) {
                return false;
            }
            LineItemKey other = (LineItemKey) otherOb;
            return (
                        (orderId==null?other.orderId==null:orderId.equals
                        (other.orderId)
                        )
                        &&
                        (itemId == other.itemId)
                    );
        }
    
        public int hashCode() {
            return (
                        (orderId==null?0:orderId.hashCode())
                        ^
                        ((int) itemId)
                    );
        }
    
        public String toString() {
            return "" + orderId + "-" + itemId;
        }
    }

    Multiplicity in Entity Relationships

    There are four types of multiplicities: one-to-one, one-to-many, many-to-one, and many-to-many.

    One-to-one: Each entity instance is related to a single instance of another entity. For example, to model a physical warehouse in which each storage bin contains a single widget, StorageBin and Widget would have a one-to-one relationship. One-to-one relationships use the javax.persistence.OneToOne annotation on the corresponding persistent property or field.

    One-to-many: An entity instance can be related to multiple instances of the other entities. A sales order, for example, can have multiple line items. In the order application, Orderwould have a one-to-many relationship with LineItem. One-to-many relationships use the javax.persistence.OneToMany annotation on the corresponding persistent property or field.

    Many-to-one: Multiple instances of an entity can be related to a single instance of the other entity. This multiplicity is the opposite of a one-to-many relationship. In the example just mentioned, from the perspective of LineItem the relationship to Order is many-to-one. Many-to-one relationships use the javax.persistence.ManyToOne annotation on the corresponding persistent property or field.

    Many-to-many: The entity instances can be related to multiple instances of each other. For example, in college each course has many students, and every student may take several courses. Therefore, in an enrollment application, Course and Student would have a many-to-many relationship. Many-to-many relationships use thejavax.persistence.ManyToMany annotation on the corresponding persistent property or field.

    Direction in Entity Relationships

    The direction of a relationship can be either bidirectional or unidirectional. A bidirectional relationship has both an owning side and an inverse side. A unidirectional relationship has only an owning side. The owning side of a relationship determines how the Persistence runtime makes updates to the relationship in the database.

    Bidirectional Relationships

    In a bidirectional relationship, each entity has a relationship field or property that refers to the other entity. Through the relationship field or property, an entity class’s code can access its related object. If an entity has a related field, then the entity is said to “know” about its related object. For example, if Order knows what LineItem instances it has and if LineItem knows what Order it belongs to, then they have a bidirectional relationship.

    Bidirectional relationships must follow these rules:

    • The inverse side of a bidirectional relationship must refer to its owning side by using the mappedBy element of the @OneToOne@OneToMany, or @ManyToMany annotation. The mappedBy element designates the property or field in the entity that is the owner of the relationship.

    • The many side of many-to-one bidirectional relationships must not define the mappedBy element. The many side is always the owning side of the relationship.

    • For one-to-one bidirectional relationships, the owning side corresponds to the side that contains the corresponding foreign key.

    • For many-to-many bidirectional relationships either side may be the owning side.

    Unidirectional Relationships

    In a unidirectional relationship, only one entity has a relationship field or property that refers to the other. For example, LineItem would have a relationship field that identifiesProduct, but Product would not have a relationship field or property for LineItem. In other words, LineItem knows about Product, but Product doesn’t know whichLineItem instances refer to it.

    Queries and Relationship Direction

    Java Persistence query language queries often navigate across relationships. The direction of a relationship determines whether a query can navigate from one entity to another. For example, a query can navigate from LineItem to Product but cannot navigate in the opposite direction. For Order and LineItem, a query could navigate in both directions, because these two entities have a bidirectional relationship.

    Cascade Deletes and Relationships

    Entities that use relationships often have dependencies on the existence of the other entity in the relationship. For example, a line item is part of an order, and if the order is deleted, then the line item should also be deleted. This is called a cascade delete relationship.

    Cascade delete relationships are specified using the cascade=REMOVE element specification for @OneToOne and @OneToMany relationships. For example:

    @OneToMany(cascade=REMOVE, mappedBy="customer")
    public Set<Order> getOrders() { return orders; }

    Entity Inheritance

    Entities support class inheritance, polymorphic associations, and polymorphic queries. They 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, and is described in Entity Inheritance in the roster Application.

    Abstract Entities

    An abstract class may be declared an entity by decorating the class with @Entity. Abstract entities differ from concrete entities only in that they cannot be instantiated.

    Abstract entities can be queried just like concrete queries. 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 @Entityannotation, 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 javax.persistence.MappedSuperclass annotation.

    @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 are not queryable, and can’t be used in EntityManager or Query operations. You must use entity subclasses of the mapped superclass inEntityManager 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 code sample above the underlying tables would be FULLTIMEEMPLOYEE and PARTTIMEEMPLOYEE, but there is no EMPLOYEE table.

    Non-Entity Superclasses

    Entities may have non-entity superclasses, and these superclasses can be either abstract or concrete. The state of non-entity superclasses is non-persistent, and any state inherited from the non-entity superclass by an entity class is non-persistent. 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 Strategies

    You can configure how the Java Persistence provider maps inherited entities to the underlying datastore by decorating the root class of the hierarchy with thejavax.persistence.Inheritance annotation. There are three mapping strategies that 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, where 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 is InheritanceType.SINGLE_TABLE, and is used if the @Inheritance annotation is not specified on the root class of the entity hierarchy.

    The Single Table per Class Hierarchy Strategy

    With 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, a column that contains a value that identifies the subclass to which the instance represented by the row belongs.

    The discriminator column can be specified by using the javax.persistence.DiscriminatorColumn annotation on the root of the entity class hierarchy.

    Table 24-1 @DiscriminatorColumn Elements

    Type

    Name

    Description

    String

    name

    The name of the column in the table 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 isDiscriminatorType.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 discriminatorTypeelement 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 only decorate 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, it requires the columns that contain the state of subclasses to be nullable.

    The Table per Concrete Class Strategy

    In 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 Application Server does not support this strategy.

    The Joined Subclass Strategy

    In 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 only contains 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 Application Server, require a discriminator column in the table 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 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.

  • 相关阅读:
    cshtml 中的 AppState = Context.Application 和 控制器中的 Application 也相等
    HangFire快速入门 分布式后端作业调度框架服务
    用RSA加密实现Web登录密码加密传输
    c# MD5及盐值加密
    CentOS目录结构超详细版
    两篇文章带你走入.NET Core 世界:CentOS+Kestrel+Ngnix 虚拟机先走一遍(一)
    利用js实现 禁用浏览器后退
    在.Net Core WebAPI下给Swagger增加导出离线文档功能
    mysql 数据库扫描行数
    EFCore+Mysql仓储层建设(分页、多字段排序、部分字段更新)
  • 原文地址:https://www.cnblogs.com/goyier/p/4718360.html
Copyright © 2020-2023  润新知