Hibernate.orgCommunity Documentation

Chapter 5. Basic O/R Mapping

5.1. Mapping declaration
5.1.1. Entity
5.1.2. Identifiers
5.1.3. Optimistic locking properties (optional)
5.1.4. Property
5.1.5. Embedded objects (aka components)
5.1.6. Inheritance strategy
5.1.7. Mapping one to one and one to many associations
5.1.8. Natural-id
5.1.9. Any
5.1.10. Properties
5.1.11. Some hbm.xml specificities
5.2. Hibernate types
5.2.1. Entities and values
5.2.2. Basic value types
5.2.3. Custom value types
5.3. Mapping a class more than once
5.4. SQL quoted identifiers
5.5. Generated properties
5.6. Column transformers: read and write expressions
5.7. Auxiliary database objects

Object/relational mappings can be defined in three approaches:

Annotations are split in two categories, the logical mapping annotations (describing the object model, the association between two entities etc.) and the physical mapping annotations (describing the physical schema, tables, columns, indexes, etc). We will mix annotations from both categories in the following code examples.

JPA annotations are in the javax.persistence.* package. Hibernate specific extensions are in org.hibernate.annotations.*. You favorite IDE can auto-complete annotations and their attributes for you (even without a specific "JPA" plugin, since JPA annotations are plain Java 5 annotations).

Here is an example of mapping

package eg;


@Entity 
@Table(name="cats") @Inheritance(strategy=SINGLE_TABLE)
@DiscriminatorValue("C") @DiscriminatorColumn(name="subclass", discriminatorType=CHAR)
public class Cat {
   
   @Id @GeneratedValue
   public Integer getId() { return id; }
   public void setId(Integer id) { this.id = id; }
   private Integer id;
   public BigDecimal getWeight() { return weight; }
   public void setWeight(BigDecimal weight) { this.weight = weight; }
   private BigDecimal weight;
   @Temporal(DATE) @NotNull @Column(updatable=false)
   public Date getBirthdate() { return birthdate; }
   public void setBirthdate(Date birthdate) { this.birthdate = birthdate; }
   private Date birthdate;
   @org.hibernate.annotations.Type(type="eg.types.ColorUserType")
   @NotNull @Column(updatable=false)
   public ColorType getColor() { return color; }
   public void setColor(ColorType color) { this.color = color; }
   private ColorType color;
   @NotNull @Column(updatable=false)
   public String getSex() { return sex; }
   public void setSex(String sex) { this.sex = sex; }
   private String sex;
   @NotNull @Column(updatable=false)
   public Integer getLitterId() { return litterId; }
   public void setLitterId(Integer litterId) { this.litterId = litterId; }
   private Integer litterId;
   @ManyToOne @JoinColumn(name="mother_id", updatable=false)
   public Cat getMother() { return mother; }
   public void setMother(Cat mother) { this.mother = mother; }
   private Cat mother;
   @OneToMany(mappedBy="mother") @OrderBy("litterId")
   public Set<Cat> getKittens() { return kittens; }
   public void setKittens(Set<Cat> kittens) { this.kittens = kittens; }
   private Set<Cat> kittens = new HashSet<Cat>();
}
@Entity @DiscriminatorValue("D")
public class DomesticCat extends Cat {
   public String getName() { return name; }
   public void setName(String name) { this.name = name }
   private String name;
}
@Entity
public class Dog { ... }

The legacy hbm.xml approach uses an XML schema designed to be readable and hand-editable. The mapping language is Java-centric, meaning that mappings are constructed around persistent class declarations and not table declarations.

Please note that even though many Hibernate users choose to write the XML by hand, a number of tools exist to generate the mapping document. These include XDoclet, Middlegen and AndroMDA.

Here is an example mapping:


<?xml version="1.0"?>
<!DOCTYPE hibernate-mapping PUBLIC
      "-//Hibernate/Hibernate Mapping DTD 3.0//EN"
          "http://www.hibernate.org/dtd/hibernate-mapping-3.0.dtd">

<hibernate-mapping package="eg">

        <class name="Cat"
            table="cats"
            discriminator-value="C">

                <id name="id">
                        <generator class="native"/>
                </id>

                <discriminator column="subclass"
                     type="character"/>

                <property name="weight"/>

                <property name="birthdate"
                    type="date"
                    not-null="true"
                    update="false"/>

                <property name="color"
                    type="eg.types.ColorUserType"
                    not-null="true"
                    update="false"/>

                <property name="sex"
                    not-null="true"
                    update="false"/>

                <property name="litterId"
                    column="litterId"
                    update="false"/>

                <many-to-one name="mother"
                    column="mother_id"
                    update="false"/>

                <set name="kittens"
                    inverse="true"
                    order-by="litter_id">
                        <key column="mother_id"/>
                        <one-to-many class="Cat"/>
                </set>

                <subclass name="DomesticCat"
                    discriminator-value="D">

                        <property name="name"
                            type="string"/>

                </subclass>

        </class>

        <class name="Dog">
                <!-- mapping for Dog could go here -->
        </class>

</hibernate-mapping>

We will now discuss the concepts of the mapping documents (both annotations and XML). We will only describe, however, the document elements and attributes that are used by Hibernate at runtime. The mapping document also contains some extra optional attributes and elements that affect the database schemas exported by the schema export tool (for example, the not-null attribute).

An entity is a regular Java object (aka POJO) which will be persisted by Hibernate.

To mark an object as an entity in annotations, use the @Entity annotation.

@Entity

public class Flight implements Serializable {
    Long id;
    @Id
    public Long getId() { return id; }
    public void setId(Long id) { this.id = id; }
}         

That's pretty much it, the rest is optional. There are however any options to tweak your entity mapping, let's explore them.

@Table lets you define the table the entity will be persisted into. If undefined, the table name is the unqualified class name of the entity. You can also optionally define the catalog, the schema as well as unique constraints on the table.

@Entity

@Table(name="TBL_FLIGHT", 
       schema="AIR_COMMAND", 
       uniqueConstraints=
           @UniqueConstraint(
               name="flight_number", 
               columnNames={"comp_prefix", "flight_number"} ) )
public class Flight implements Serializable {
    @Column(name="comp_prefix")
    public String getCompagnyPrefix() { return companyPrefix; }
    @Column(name="flight_number")
    public String getNumber() { return number; }
}

The constraint name is optional (generated if left undefined). The column names composing the constraint correspond to the column names as defined before the Hibernate NamingStrategy is applied.

@Entity.name lets you define the shortcut name of the entity you can used in JP-QL and HQL queries. It defaults to the unqualified class name of the class.

Hibernate goes beyond the JPA specification and provide additional configurations. Some of them are hosted on @org.hibernate.annotations.Entity:

Some entities are not mutable. They cannot be updated or deleted by the application. This allows Hibernate to make some minor performance optimizations.. Use the @Immutable annotation.

You can also alter how Hibernate deals with lazy initialization for this class. On @Proxy, use lazy=false to disable lazy fetching (not recommended). You can also specify an interface to use for lazy initializing proxies (defaults to the class itself): use proxyClass on @Proxy. Hibernate will initially return proxies (Javassist or CGLIB) that implement the named interface. The persistent object will load when a method of the proxy is invoked. See "Initializing collections and proxies" below.

@BatchSize specifies a "batch size" for fetching instances of this class by identifier. Not yet loaded instances are loaded batch-size at a time (default 1).

You can specific an arbitrary SQL WHERE condition to be used when retrieving objects of this class. Use @Where for that.

In the same vein, @Check lets you define an SQL expression used to generate a multi-row check constraint for automatic schema generation.

There is no difference between a view and a base table for a Hibernate mapping. This is transparent at the database level, although some DBMS do not support views properly, especially with updates. Sometimes you want to use a view, but you cannot create one in the database (i.e. with a legacy schema). In this case, you can map an immutable and read-only entity to a given SQL subselect expression using @org.hibernate.annotations.Subselect:

@Entity

@Subselect("select item.name, max(bid.amount), count(*) "
        + "from item "
        + "join bid on bid.item_id = item.id "
        + "group by item.name")
@Synchronize( {"item", "bid"} ) //tables impacted
public class Summary {
    @Id
    public String getId() { return id; }
    ...
}

Declare the tables to synchronize this entity with, ensuring that auto-flush happens correctly and that queries against the derived entity do not return stale data. The <subselect> is available both as an attribute and a nested mapping element.

We will now explore the same options using the hbm.xml structure. You can declare a persistent class using the class element. For example:

<class
        name="(1)ClassName"
        table=(2)"tableName"
        discri(3)minator-value="discriminator_value"
        mutabl(4)e="true|false"
        schema(5)="owner"
        catalo(6)g="catalog"
        proxy=(7)"ProxyInterface"
        dynami(8)c-update="true|false"
        dynami(9)c-insert="true|false"
        select(10)-before-update="true|false"
        polymo(11)rphism="implicit|explicit"
        where=(12)"arbitrary sql where condition"
        persis(13)ter="PersisterClass"
        batch-(14)size="N"
        optimi(15)stic-lock="none|version|dirty|all"
        lazy="(16)true|false"
        entity(17)-name="EntityName"
        check=(18)"arbitrary sql check condition"
        rowid=(19)"rowid"
        subsel(20)ect="SQL expression"
        abstra(21)ct="true|false"
        node="element-name"
/>

1

name (optional): the fully qualified Java class name of the persistent class or interface. If this attribute is missing, it is assumed that the mapping is for a non-POJO entity.

2

table (optional - defaults to the unqualified class name): the name of its database table.

3

discriminator-value (optional - defaults to the class name): a value that distinguishes individual subclasses that is used for polymorphic behavior. Acceptable values include null and not null.

4

mutable (optional - defaults to true): specifies that instances of the class are (not) mutable.

5

schema (optional): overrides the schema name specified by the root <hibernate-mapping> element.

6

catalog (optional): overrides the catalog name specified by the root <hibernate-mapping> element.

7

proxy (optional): specifies an interface to use for lazy initializing proxies. You can specify the name of the class itself.

8

dynamic-update (optional - defaults to false): specifies that UPDATE SQL should be generated at runtime and can contain only those columns whose values have changed.

9

dynamic-insert (optional - defaults to false): specifies that INSERT SQL should be generated at runtime and contain only the columns whose values are not null.

10

select-before-update (optional - defaults to false): specifies that Hibernate should never perform an SQL UPDATE unless it is certain that an object is actually modified. Only when a transient object has been associated with a new session using update(), will Hibernate perform an extra SQL SELECT to determine if an UPDATE is actually required.

11

polymorphisms (optional - defaults to implicit): determines whether implicit or explicit query polymorphisms is used.

12

where (optional): specifies an arbitrary SQL WHERE condition to be used when retrieving objects of this class.

13

persister (optional): specifies a custom ClassPersister.

14

batch-size (optional - defaults to 1): specifies a "batch size" for fetching instances of this class by identifier.

15

optimistic-lock (optional - defaults to version): determines the optimistic locking strategy.

(16)

lazy (optional): lazy fetching can be disabled by setting lazy="false".

(17)

entity-name (optional - defaults to the class name): Hibernate3 allows a class to be mapped multiple times, potentially to different tables. It also allows entity mappings that are represented by Maps or XML at the Java level. In these cases, you should provide an explicit arbitrary name for the entity. See Section 4.4, “Dynamic models” and Chapter 20, XML Mapping for more information.

(18)

check (optional): an SQL expression used to generate a multi-row check constraint for automatic schema generation.

(19)

rowid (optional): Hibernate can use ROWIDs on databases. On Oracle, for example, Hibernate can use the rowid extra column for fast updates once this option has been set to rowid. A ROWID is an implementation detail and represents the physical location of a stored tuple.

(20)

subselect (optional): maps an immutable and read-only entity to a database subselect. This is useful if you want to have a view instead of a base table. See below for more information.

(21)

abstract (optional): is used to mark abstract superclasses in <union-subclass> hierarchies.

It is acceptable for the named persistent class to be an interface. You can declare implementing classes of that interface using the <subclass> element. You can persist any static inner class. Specify the class name using the standard form i.e. e.g.Foo$Bar.

Here is how to do a virtual view (subselect) in XML:


<class name="Summary">
    <subselect>
        select item.name, max(bid.amount), count(*)
        from item
        join bid on bid.item_id = item.id
        group by item.name
    </subselect>
    <synchronize table="item"/>
    <synchronize table="bid"/>
    <id name="name"/>
    ...
</class>

The <subselect> is available both as an attribute and a nested mapping element.

Mapped classes must declare the primary key column of the database table. Most classes will also have a JavaBeans-style property holding the unique identifier of an instance.

Mark the identifier property with @Id.

@Entity

public class Person {
   @Id Integer getId() { ... }
   ...
}

In hbm.xml, use the <id> element which defines the mapping from that property to the primary key column.

<id
        name="(1)propertyName"
        type="(2)typename"
        column(3)="column_name"
        unsave(4)d-value="null|any|none|undefined|id_value"
        access(5)="field|property|ClassName">
        node="element-name|@attribute-name|element/@attribute|."

        <generator class="generatorClass"/>
</id>

1

name (optional): the name of the identifier property.

2

type (optional): a name that indicates the Hibernate type.

3

column (optional - defaults to the property name): the name of the primary key column.

4

unsaved-value (optional - defaults to a "sensible" value): an identifier property value that indicates an instance is newly instantiated (unsaved), distinguishing it from detached instances that were saved or loaded in a previous session.

5

access (optional - defaults to property): the strategy Hibernate should use for accessing the property value.

If the name attribute is missing, it is assumed that the class has no identifier property.

The unsaved-value attribute is almost never needed in Hibernate3 and indeed has no corresponding element in annotations.

You can also declare the identifier as a composite identifier. This allows access to legacy data with composite keys. Its use is strongly discouraged for anything else.

You can define a composite primary key through several syntaxes:

As you can see the last case is far from obvious. It has been inherited from the dark ages of EJB 2 for backward compatibilities and we recommend you not to use it (for simplicity sake).

Let's explore all three cases using examples.

Here is a simple example of @EmbeddedId.

@Entity

class User {
   @EmbeddedId
   @AttributeOverride(name="firstName", column=@Column(name="fld_firstname")
   UserId id;
   Integer age;
}
@Embeddable
class UserId implements Serializable {
   String firstName;
   String lastName;
}

You can notice that the UserId class is serializable. To override the column mapping, use @AttributeOverride.

An embedded id can itself contains the primary key of an associated entity.

@Entity

class Customer {
   @EmbeddedId CustomerId id;
   boolean preferredCustomer;
   @MapsId("userId")
   @JoinColumns({
      @JoinColumn(name="userfirstname_fk", referencedColumnName="firstName"),
      @JoinColumn(name="userlastname_fk", referencedColumnName="lastName")
   })
   @OneToOne User user;
}
@Embeddable
class CustomerId implements Serializable {
   UserId userId;
   String customerNumber;
   //implements equals and hashCode
}
@Entity 
class User {
   @EmbeddedId UserId id;
   Integer age;
}
@Embeddable
class UserId implements Serializable {
   String firstName;
   String lastName;
   //implements equals and hashCode
}

In the embedded id object, the association is represented as the identifier of the associated entity. But you can link its value to a regular association in the entity via the @MapsId annotation. The @MapsId value correspond to the property name of the embedded id object containing the associated entity's identifier. In the database, it means that the Customer.user and the CustomerId.userId properties share the same underlying column (user_fk in this case).

In practice, your code only sets the Customer.user property and the user id value is copied by Hibernate into the CustomerId.userId property.

While not supported in JPA, Hibernate lets you place your association directly in the embedded id component (instead of having to use the @MapsId annotation).

@Entity

class Customer {
   @EmbeddedId CustomerId id;
   boolean preferredCustomer;
}
@Embeddable
class CustomerId implements Serializable {
   @OneToOne
   @JoinColumns({
      @JoinColumn(name="userfirstname_fk", referencedColumnName="firstName"),
      @JoinColumn(name="userlastname_fk", referencedColumnName="lastName")
   }) 
   User user;
   String customerNumber;
   //implements equals and hashCode
}
@Entity 
class User {
   @EmbeddedId UserId id;
   Integer age;
}
@Embeddable
class UserId implements Serializable {
   String firstName;
   String lastName;
   //implements equals and hashCode
}

Let's now rewrite these examples using the hbm.xml syntax.


<composite-id
        name="propertyName"
        class="ClassName"
        mapped="true|false"
        access="field|property|ClassName"
        node="element-name|.">

        <key-property name="propertyName" type="typename" column="column_name"/>
        <key-many-to-one name="propertyName" class="ClassName" column="column_name"/>
        ......
</composite-id>

First a simple example:


<class name="User">
   <composite-id name="id" class="UserId">
      <key-property name="firstName" column="fld_firstname"/>
      <key-property name="lastName"/>
   </composite-id>
</class>

Then an example showing how an association can be mapped.


<class name="Customer">
   <composite-id name="id" class="CustomerId">
      <key-property name="firstName" column="userfirstname_fk"/>
      <key-property name="lastName" column="userfirstname_fk"/>
      <key-property name="customerNumber"/>
   </composite-id>

   <property name="preferredCustomer"/>

   <many-to-one name="user">
      <column name="userfirstname_fk" updatable="false" insertable="false"/>
      <column name="userlastname_fk" updatable="false" insertable="false"/>
   </many-to-one>
</class>

<class name="User">
   <composite-id name="id" class="UserId">
      <key-property name="firstName"/>
      <key-property name="lastName"/>
   </composite-id>

   <property name="age"/>
</class>

Notice a few things in the previous example:

The last example shows how to map association directly in the embedded id component.


<class name="Customer">
   <composite-id name="id" class="CustomerId">
      <key-many-to-one name="user">
         <column name="userfirstname_fk"/>
         <column name="userlastname_fk"/>
      </key-many-to-one>
      <key-property name="customerNumber"/>
   </composite-id>

   <property name="preferredCustomer"/>
</class>

<class name="User">
   <composite-id name="id" class="UserId">
      <key-property name="firstName"/>
      <key-property name="lastName"/>
   </composite-id>

   <property name="age"/>
</class>

This is the recommended approach to map composite identifier. The following options should not be considered unless some constraint are present.

Another, arguably more natural, approach is to place @Id on multiple properties of your entity. This approach is only supported by Hibernate (not JPA compliant) but does not require an extra embeddable component.

@Entity

class Customer implements Serializable {
   @Id @OneToOne
   @JoinColumns({
      @JoinColumn(name="userfirstname_fk", referencedColumnName="firstName"),
      @JoinColumn(name="userlastname_fk", referencedColumnName="lastName")
   })
   User user;
  
   @Id String customerNumber;
   boolean preferredCustomer;
   //implements equals and hashCode
}
@Entity 
class User {
   @EmbeddedId UserId id;
   Integer age;
}
@Embeddable
class UserId implements Serializable {
   String firstName;
   String lastName;
   //implements equals and hashCode
}

In this case Customer is its own identifier representation: it must implement Serializable and must implement equals() and hashCode().

In hbm.xml, the same mapping is:


<class name="Customer">
   <composite-id>
      <key-many-to-one name="user">
         <column name="userfirstname_fk"/>
         <column name="userlastname_fk"/>
      </key-many-to-one>
      <key-property name="customerNumber"/>
   </composite-id>

   <property name="preferredCustomer"/>
</class>

<class name="User">
   <composite-id name="id" class="UserId">
      <key-property name="firstName"/>
      <key-property name="lastName"/>
   </composite-id>

   <property name="age"/>
</class>

@IdClass on an entity points to the class (component) representing the identifier of the class. The properties marked @Id on the entity must have their corresponding property on the @IdClass. The return type of search twin property must be either identical for basic properties or must correspond to the identifier class of the associated entity for an association.

@Entity

@IdClass(CustomerId.class)
class Customer implements Serializable {
   @Id @OneToOne
   @JoinColumns({
      @JoinColumn(name="userfirstname_fk", referencedColumnName="firstName"),
      @JoinColumn(name="userlastname_fk", referencedColumnName="lastName")
   }) 
   User user;
  
   @Id String customerNumber;
   boolean preferredCustomer;
}
class CustomerId implements Serializable {
   UserId user;
   String customerNumber;
   //implements equals and hashCode
}
@Entity 
class User {
   @EmbeddedId UserId id;
   Integer age;
   //implements equals and hashCode
}
@Embeddable
class UserId implements Serializable {
   String firstName;
   String lastName;
   //implements equals and hashCode
}

Customer and CustomerId do have the same properties customerNumber as well as user. CustomerId must be Serializable and implement equals() and hashCode().

While not JPA standard, Hibernate let's you declare the vanilla associated property in the @IdClass.

@Entity

@IdClass(CustomerId.class)
class Customer implements Serializable {
   @Id @OneToOne
   @JoinColumns({
      @JoinColumn(name="userfirstname_fk", referencedColumnName="firstName"),
      @JoinColumn(name="userlastname_fk", referencedColumnName="lastName")
   }) 
   User user;
  
   @Id String customerNumber;
   boolean preferredCustomer;
}
class CustomerId implements Serializable {
   @OneToOne User user;
   String customerNumber;
   //implements equals and hashCode
}
@Entity 
class User {
   @EmbeddedId UserId id;
   Integer age;
   //implements equals and hashCode
}
@Embeddable
class UserId implements Serializable {
  String firstName;
  String lastName;
}

This feature is of limited interest though as you are likely to have chosen the @IdClass approach to stay JPA compliant or you have a quite twisted mind.

Here are the equivalent on hbm.xml files:


<class name="Customer">
   <composite-id class="CustomerId" mapped="true">
      <key-many-to-one name="user">
         <column name="userfirstname_fk"/>
         <column name="userlastname_fk"/>
      </key-many-to-one>
      <key-property name="customerNumber"/>
   </composite-id>

   <property name="preferredCustomer"/>
</class>

<class name="User">
   <composite-id name="id" class="UserId">
      <key-property name="firstName"/>
      <key-property name="lastName"/>
   </composite-id>

   <property name="age"/>
</class>

Hibernate can generate and populate identifier values for you automatically. This is the recommended approach over "business" or "natural" id (especially composite ids).

Hibernate offers various generation strategies, let's explore the most common ones first that happens to be standardized by JPA:

To mark an id property as generated, use the @GeneratedValue annotation. You can specify the strategy used (default to AUTO) by setting strategy.

@Entity

public class Customer {
   @Id @GeneratedValue
   Integer getId() { ... };
}
@Entity 
public class Invoice {
   @Id @GeneratedValue(strategy=GenerationType.IDENTITY)
   Integer getId() { ... };
}

SEQUENCE and TABLE require additional configurations that you can set using @SequenceGenerator and @TableGenerator:

  • name: name of the generator

  • table / sequenceName: name of the table or the sequence (defaulting respectively to hibernate_sequences and hibernate_sequence)

  • catalog / schema:

  • initialValue: the value from which the id is to start generating

  • allocationSize: the amount to increment by when allocating id numbers from the generator

In addition, the TABLE strategy also let you customize:

  • pkColumnName: the column name containing the entity identifier

  • valueColumnName: the column name containing the identifier value

  • pkColumnValue: the entity identifier

  • uniqueConstraints: any potential column constraint on the table containing the ids

To link a table or sequence generator definition with an actual generated property, use the same name in both the definition name and the generator value generator as shown below.

@Id 

@GeneratedValue(
    strategy=GenerationType.SEQUENCE, 
    generator="SEQ_GEN")
@javax.persistence.SequenceGenerator(
    name="SEQ_GEN",
    sequenceName="my_sequence",
    allocationSize=20
)
public Integer getId() { ... }        

The scope of a generator definition can be the application or the class. Class-defined generators are not visible outside the class and can override application level generators. Application level generators are defined in JPA's XML deployment descriptors (see XXXXXX ???):

<table-generator name="EMP_GEN"

            table="GENERATOR_TABLE"
            pk-column-name="key"
            value-column-name="hi"
            pk-column-value="EMP"
            allocation-size="20"/>
//and the annotation equivalent
@javax.persistence.TableGenerator(
    name="EMP_GEN",
    table="GENERATOR_TABLE",
    pkColumnName = "key",
    valueColumnName = "hi"
    pkColumnValue="EMP",
    allocationSize=20
)
<sequence-generator name="SEQ_GEN" 
    sequence-name="my_sequence"
    allocation-size="20"/>
//and the annotation equivalent
@javax.persistence.SequenceGenerator(
    name="SEQ_GEN",
    sequenceName="my_sequence",
    allocationSize=20
)
         

If a JPA XML descriptor (like META-INF/orm.xml) is used to define the generators, EMP_GEN and SEQ_GEN are application level generators.

Note

Package level definition is not supported by the JPA specification. However, you can use the @GenericGenerator at the package level (see ???).

These are the four standard JPA generators. Hibernate goes beyond that and provide additional generators or additional options as we will see below. You can also write your own custom identifier generator by implementing org.hibernate.id.IdentifierGenerator.

To define a custom generator, use the @GenericGenerator annotation (and its plural counter part @GenericGenerators) that describes the class of the identifier generator or its short cut name (as described below) and a list of key/value parameters. When using @GenericGenerator and assigning it via @GeneratedValue.generator, the @GeneratedValue.strategy is ignored: leave it blank.

@Id @GeneratedValue(generator="system-uuid")

@GenericGenerator(name="system-uuid", strategy = "uuid")
public String getId() {
@Id @GeneratedValue(generator="trigger-generated")
@GenericGenerator(
    name="trigger-generated", 
    strategy = "select",
    parameters = @Parameter(name="key", value = "socialSecurityNumber")
)
public String getId() {

The hbm.xml approach uses the optional <generator> child element inside <id>. If any parameters are required to configure or initialize the generator instance, they are passed using the <param> element.


<id name="id" type="long" column="cat_id">
        <generator class="org.hibernate.id.TableHiLoGenerator">
                <param name="table">uid_table</param>
                <param name="column">next_hi_value_column</param>
        </generator>
</id>

All generators implement the interface org.hibernate.id.IdentifierGenerator. This is a very simple interface. Some applications can choose to provide their own specialized implementations, however, Hibernate provides a range of built-in implementations. The shortcut names for the built-in generators are as follows:

increment

generates identifiers of type long, short or int that are unique only when no other process is inserting data into the same table. Do not use in a cluster.

identity

supports identity columns in DB2, MySQL, MS SQL Server, Sybase and HypersonicSQL. The returned identifier is of type long, short or int.

sequence

uses a sequence in DB2, PostgreSQL, Oracle, SAP DB, McKoi or a generator in Interbase. The returned identifier is of type long, short or int

hilo

uses a hi/lo algorithm to efficiently generate identifiers of type long, short or int, given a table and column (by default hibernate_unique_key and next_hi respectively) as a source of hi values. The hi/lo algorithm generates identifiers that are unique only for a particular database.

seqhilo

uses a hi/lo algorithm to efficiently generate identifiers of type long, short or int, given a named database sequence.

uuid

Generates a 128-bit UUID based on a custom algorithm. The value generated is represented as a string of 32 hexidecimal digits. Users can also configure it to use a separator (config parameter "separator") which separates the hexidecimal digits into 8{sep}8{sep}4{sep}8{sep}4. Note specifically that this is different than the IETF RFC 4122 representation of 8-4-4-4-12. If you need RFC 4122 compliant UUIDs, consider using "uuid2" generator discussed below.

uuid2

Generates a IETF RFC 4122 compliant (variant 2) 128-bit UUID. The exact "version" (the RFC term) generated depends on the pluggable "generation strategy" used (see below). Capable of generating values as java.util.UUID, java.lang.String or as a byte array of length 16 (byte[16]). The "generation strategy" is defined by the interface org.hibernate.id.UUIDGenerationStrategy. The generator defines 2 configuration parameters for defining which generation strategy to use:

Out of the box, comes with the following strategies:

guid

uses a database-generated GUID string on MS SQL Server and MySQL.

native

selects identity, sequence or hilo depending upon the capabilities of the underlying database.

assigned

lets the application assign an identifier to the object before save() is called. This is the default strategy if no <generator> element is specified.

select

retrieves a primary key, assigned by a database trigger, by selecting the row by some unique key and retrieving the primary key value.

foreign

uses the identifier of another associated object. It is usually used in conjunction with a <one-to-one> primary key association.

sequence-identity

a specialized sequence generation strategy that utilizes a database sequence for the actual value generation, but combines this with JDBC3 getGeneratedKeys to return the generated identifier value as part of the insert statement execution. This strategy is only supported on Oracle 10g drivers targeted for JDK 1.4. Comments on these insert statements are disabled due to a bug in the Oracle drivers.

Starting with release 3.2.3, there are 2 new generators which represent a re-thinking of 2 different aspects of identifier generation. The first aspect is database portability; the second is optimization Optimization means that you do not have to query the database for every request for a new identifier value. These two new generators are intended to take the place of some of the named generators described above, starting in 3.3.x. However, they are included in the current releases and can be referenced by FQN.

The first of these new generators is org.hibernate.id.enhanced.SequenceStyleGenerator which is intended, firstly, as a replacement for the sequence generator and, secondly, as a better portability generator than native. This is because native generally chooses between identity and sequence which have largely different semantics that can cause subtle issues in applications eyeing portability. org.hibernate.id.enhanced.SequenceStyleGenerator, however, achieves portability in a different manner. It chooses between a table or a sequence in the database to store its incrementing values, depending on the capabilities of the dialect being used. The difference between this and native is that table-based and sequence-based storage have the same exact semantic. In fact, sequences are exactly what Hibernate tries to emulate with its table-based generators. This generator has a number of configuration parameters:

The second of these new generators is org.hibernate.id.enhanced.TableGenerator, which is intended, firstly, as a replacement for the table generator, even though it actually functions much more like org.hibernate.id.MultipleHiLoPerTableGenerator, and secondly, as a re-implementation of org.hibernate.id.MultipleHiLoPerTableGenerator that utilizes the notion of pluggable optimizers. Essentially this generator defines a table capable of holding a number of different increment values simultaneously by using multiple distinctly keyed rows. This generator has a number of configuration parameters:

  • table_name (optional - defaults to hibernate_sequences): the name of the table to be used.

  • value_column_name (optional - defaults to next_val): the name of the column on the table that is used to hold the value.

  • segment_column_name (optional - defaults to sequence_name): the name of the column on the table that is used to hold the "segment key". This is the value which identifies which increment value to use.

  • segment_value (optional - defaults to default): The "segment key" value for the segment from which we want to pull increment values for this generator.

  • segment_value_length (optional - defaults to 255): Used for schema generation; the column size to create this segment key column.

  • initial_value (optional - defaults to 1): The initial value to be retrieved from the table.

  • increment_size (optional - defaults to 1): The value by which subsequent calls to the table should differ.

  • optimizer (optional - defaults to ??): See Section 5.1.2.3.1, “Identifier generator optimization”.

For identifier generators that store values in the database, it is inefficient for them to hit the database on each and every call to generate a new identifier value. Instead, you can group a bunch of them in memory and only hit the database when you have exhausted your in-memory value group. This is the role of the pluggable optimizers. Currently only the two enhanced generators (Section 5.1.2.3, “Enhanced identifier generators” support this operation.

  • none (generally this is the default if no optimizer was specified): this will not perform any optimizations and hit the database for each and every request.

  • hilo: applies a hi/lo algorithm around the database retrieved values. The values from the database for this optimizer are expected to be sequential. The values retrieved from the database structure for this optimizer indicates the "group number". The increment_size is multiplied by that value in memory to define a group "hi value".

  • pooled: as with the case of hilo, this optimizer attempts to minimize the number of hits to the database. Here, however, we simply store the starting value for the "next group" into the database structure rather than a sequential value in combination with an in-memory grouping algorithm. Here, increment_size refers to the values coming from the database.

When using long transactions or conversations that span several database transactions, it is useful to store versioning data to ensure that if the same entity is updated by two conversations, the last to commit changes will be informed and not override the other conversation's work. It guarantees some isolation while still allowing for good scalability and works particularly well in read-often write-sometimes situations.

You can use two approaches: a dedicated version number or a timestamp.

A version or timestamp property should never be null for a detached instance. Hibernate will detect any instance with a null version or timestamp as transient, irrespective of what other unsaved-value strategies are specified. Declaring a nullable version or timestamp property is an easy way to avoid problems with transitive reattachment in Hibernate. It is especially useful for people using assigned identifiers or composite keys.

You can add optimistic locking capability to an entity using the @Version annotation:

@Entity

public class Flight implements Serializable {
...
    @Version
    @Column(name="OPTLOCK")
    public Integer getVersion() { ... }
}           

The version property will be mapped to the OPTLOCK column, and the entity manager will use it to detect conflicting updates (preventing lost updates you might otherwise see with the last-commit-wins strategy).

The version column may be a numeric. Hibernate supports any kind of type provided that you define and implement the appropriate UserVersionType.

The application must not alter the version number set up by Hibernate in any way. To artificially increase the version number, check in Hibernate Entity Manager's reference documentation LockModeType.OPTIMISTIC_FORCE_INCREMENT or LockModeType.PESSIMISTIC_FORCE_INCREMENT.

If the version number is generated by the database (via a trigger for example), make sure to use @org.hibernate.annotations.Generated(GenerationTime.ALWAYS).

To declare a version property in hbm.xml, use:

<version
        column(1)="version_column"
        name="(2)propertyName"
        type="(3)typename"
        access(4)="field|property|ClassName"
        unsave(5)d-value="null|negative|undefined"
        genera(6)ted="never|always"
        insert(7)="true|false"
        node="element-name|@attribute-name|element/@attribute|."
/>

1

column (optional - defaults to the property name): the name of the column holding the version number.

2

name: the name of a property of the persistent class.

3

type (optional - defaults to integer): the type of the version number.

4

access (optional - defaults to property): the strategy Hibernate uses to access the property value.

5

unsaved-value (optional - defaults to undefined): a version property value that indicates that an instance is newly instantiated (unsaved), distinguishing it from detached instances that were saved or loaded in a previous session. Undefined specifies that the identifier property value should be used.

6

generated (optional - defaults to never): specifies that this version property value is generated by the database. See the discussion of generated properties for more information.

7

insert (optional - defaults to true): specifies whether the version column should be included in SQL insert statements. It can be set to false if the database column is defined with a default value of 0.

Alternatively, you can use a timestamp. Timestamps are a less safe implementation of optimistic locking. However, sometimes an application might use the timestamps in other ways as well.

Simply mark a property of type Date or Calendar as @Version.

@Entity

public class Flight implements Serializable {
...
    @Version
    public Date getLastUpdate() { ... }
}           

When using timestamp versioning you can tell Hibernate where to retrieve the timestamp value from - database or JVM - by optionally adding the @org.hibernate.annotations.Source annotation to the property. Possible values for the value attribute of the annotation are org.hibernate.annotations.SourceType.VM and org.hibernate.annotations.SourceType.DB. The default is SourceType.DB which is also used in case there is no @Source annotation at all.

Like in the case of version numbers, the timestamp can also be generated by the database instead of Hibernate. To do that, use @org.hibernate.annotations.Generated(GenerationTime.ALWAYS).

In hbm.xml, use the <timestamp> element:

<timestamp
        column(1)="timestamp_column"
        name="(2)propertyName"
        access(3)="field|property|ClassName"
        unsave(4)d-value="null|undefined"
        source(5)="vm|db"
        genera(6)ted="never|always"
        node="element-name|@attribute-name|element/@attribute|."
/>

1

column (optional - defaults to the property name): the name of a column holding the timestamp.

2

name: the name of a JavaBeans style property of Java type Date or Timestamp of the persistent class.

3

access (optional - defaults to property): the strategy Hibernate uses for accessing the property value.

4

unsaved-value (optional - defaults to null): a version property value that indicates that an instance is newly instantiated (unsaved), distinguishing it from detached instances that were saved or loaded in a previous session. Undefined specifies that the identifier property value should be used.

5

source (optional - defaults to vm): Where should Hibernate retrieve the timestamp value from? From the database, or from the current JVM? Database-based timestamps incur an overhead because Hibernate must hit the database in order to determine the "next value". It is safer to use in clustered environments. Not all Dialects are known to support the retrieval of the database's current timestamp. Others may also be unsafe for usage in locking due to lack of precision (Oracle 8, for example).

6

generated (optional - defaults to never): specifies that this timestamp property value is actually generated by the database. See the discussion of generated properties for more information.

You need to decide which property needs to be made persistent in a given entity. This differs slightly between the annotation driven metadata and the hbm.xml files.

In the annotations world, every non static non transient property (field or method depending on the access type) of an entity is considered persistent, unless you annotate it as @Transient. Not having an annotation for your property is equivalent to the appropriate @Basic annotation.

The @Basic annotation allows you to declare the fetching strategy for a property. If set to LAZY, specifies that this property should be fetched lazily when the instance variable is first accessed. It requires build-time bytecode instrumentation, if your classes are not instrumented, property level lazy loading is silently ignored. The default is EAGER. You can also mark a property as not optional thanks to the @Basic.optional attribute. This will ensure that the underlying column are not nullable (if possible). Note that a better approach is to use the @NotNull annotation of the Bean Validation specification.

Let's look at a few examples:

public transient int counter; //transient property


private String firstname; //persistent property
@Transient
String getLengthInMeter() { ... } //transient property
String getName() {... } // persistent property
@Basic
int getLength() { ... } // persistent property
@Basic(fetch = FetchType.LAZY)
String getDetailedComment() { ... } // persistent property
@Temporal(TemporalType.TIME)
java.util.Date getDepartureTime() { ... } // persistent property           
@Enumerated(EnumType.STRING)
Starred getNote() { ... } //enum persisted as String in database

counter, a transient field, and lengthInMeter, a method annotated as @Transient, and will be ignored by the Hibernate. name, length, and firstname properties are mapped persistent and eagerly fetched (the default for simple properties). The detailedComment property value will be lazily fetched from the database once a lazy property of the entity is accessed for the first time. Usually you don't need to lazy simple properties (not to be confused with lazy association fetching). The recommended alternative is to use the projection capability of JP-QL (Java Persistence Query Language) or Criteria queries.

JPA support property mapping of all basic types supported by Hibernate (all basic Java types , their respective wrappers and serializable classes). Hibernate Annotations supports out of the box enum type mapping either into a ordinal column (saving the enum ordinal) or a string based column (saving the enum string representation): the persistence representation, defaulted to ordinal, can be overridden through the @Enumerated annotation as shown in the note property example.

In plain Java APIs, the temporal precision of time is not defined. When dealing with temporal data you might want to describe the expected precision in database. Temporal data can have DATE, TIME, or TIMESTAMP precision (ie the actual date, only the time, or both). Use the @Temporal annotation to fine tune that.

@Lob indicates that the property should be persisted in a Blob or a Clob depending on the property type: java.sql.Clob, Character[], char[] and java.lang.String will be persisted in a Clob. java.sql.Blob, Byte[], byte[] and Serializable type will be persisted in a Blob.

@Lob

public String getFullText() {
    return fullText;
}
@Lob
public byte[] getFullCode() {
    return fullCode;
}

If the property type implements java.io.Serializable and is not a basic type, and if the property is not annotated with @Lob, then the Hibernate serializable type is used.

You can also manually specify a type using the @org.hibernate.annotations.Type and some parameters if needed. @Type.type could be:

If you do not specify a type, Hibernate will use reflection upon the named property and guess the correct Hibernate type. Hibernate will attempt to interpret the name of the return class of the property getter using, in order, rules 2, 3, and 4.

@org.hibernate.annotations.TypeDef and @org.hibernate.annotations.TypeDefs allows you to declare type definitions. These annotations can be placed at the class or package level. Note that these definitions are global for the session factory (even when defined at the class level). If the type is used on a single entity, you can place the definition on the entity itself. Otherwise, it is recommended to place the definition at the package level. In the example below, when Hibernate encounters a property of class PhoneNumer, it delegates the persistence strategy to the custom mapping type PhoneNumberType. However, properties belonging to other classes, too, can delegate their persistence strategy to PhoneNumberType, by explicitly using the @Type annotation.

@TypeDef(

   name = "phoneNumber",
   defaultForType = PhoneNumber.class,
   typeClass = PhoneNumberType.class
)
@Entity
public class ContactDetails {
   [...]
   private PhoneNumber localPhoneNumber;
   @Type(type="phoneNumber")
   private OverseasPhoneNumber overseasPhoneNumber;
   [...]
}

The following example shows the usage of the parameters attribute to customize the TypeDef.

//in org/hibernate/test/annotations/entity/package-info.java

@TypeDefs(
    {
    @TypeDef(
        name="caster",
        typeClass = CasterStringType.class,
        parameters = {
            @Parameter(name="cast", value="lower")
        }
    )
    }
)
package org.hibernate.test.annotations.entity;
//in org/hibernate/test/annotations/entity/Forest.java
public class Forest {
    @Type(type="caster")
    public String getSmallText() {
    ...
}      

When using composite user type, you will have to express column definitions. The @Columns has been introduced for that purpose.

@Type(type="org.hibernate.test.annotations.entity.MonetaryAmountUserType")

@Columns(columns = {
    @Column(name="r_amount"),
    @Column(name="r_currency")
})
public MonetaryAmount getAmount() {
    return amount;
}
public class MonetaryAmount implements Serializable {
    private BigDecimal amount;
    private Currency currency;
    ...
}

By default the access type of a class hierarchy is defined by the position of the @Id or @EmbeddedId annotations. If these annotations are on a field, then only fields are considered for persistence and the state is accessed via the field. If there annotations are on a getter, then only the getters are considered for persistence and the state is accessed via the getter/setter. That works well in practice and is the recommended approach.

However in some situations, you need to:

The best use case is an embeddable class used by several entities that might not use the same access type. In this case it is better to force the access type at the embeddable class level.

To force the access type on a given class, use the @Access annotation as showed below:

@Entity

public class Order {
   @Id private Long id;
   public Long getId() { return id; }
   public void setId(Long id) { this.id = id; }
   @Embedded private Address address;
   public Address getAddress() { return address; }
   public void setAddress() { this.address = address; }
}
@Entity
public class User {
   private Long id;
   @Id public Long getId() { return id; }
   public void setId(Long id) { this.id = id; }
   private Address address;
   @Embedded public Address getAddress() { return address; }
   public void setAddress() { this.address = address; }
}
@Embeddable
@Access(AcessType.PROPERTY)
public class Address {
   private String street1;
   public String getStreet1() { return street1; }
   public void setStreet1() { this.street1 = street1; }
   private hashCode; //not persistent
}

You can also override the access type of a single property while keeping the other properties standard.

@Entity

public class Order {
   @Id private Long id;
   public Long getId() { return id; }
   public void setId(Long id) { this.id = id; }
   @Transient private String userId;
   @Transient private String orderId;
   @Access(AccessType.PROPERTY)
   public String getOrderNumber() { return userId + ":" + orderId; }
   public void setOrderNumber() { this.userId = ...; this.orderId = ...; }
}

In this example, the default access type is FIELD except for the orderNumber property. Note that the corresponding field, if any must be marked as @Transient or transient.

The column(s) used for a property mapping can be defined using the @Column annotation. Use it to override default values (see the JPA specification for more information on the defaults). You can use this annotation at the property level for properties that are:



@Entity
public class Flight implements Serializable {
...
@Column(updatable = false, name = "flight_name", nullable = false, length=50)
public String getName() { ... }
            

The name property is mapped to the flight_name column, which is not nullable, has a length of 50 and is not updatable (making the property immutable).

This annotation can be applied to regular properties as well as @Id or @Version properties.

@Column(
    name="colu(1)mnName";
    boolean un(2)ique() default false;
    boolean nu(3)llable() default true;
    boolean in(4)sertable() default true;
    boolean up(5)datable() default true;
    String col(6)umnDefinition() default "";
    String tab(7)le() default "";
    int length(8)() default 255;
    int precis(9)ion() default 0; // decimal precision
    int scale((10)) default 0; // decimal scale

1

name (optional): the column name (default to the property name)

2

unique (optional): set a unique constraint on this column or not (default false)

3

nullable (optional): set the column as nullable (default true).

4

insertable (optional): whether or not the column will be part of the insert statement (default true)

5

updatable (optional): whether or not the column will be part of the update statement (default true)

6

columnDefinition (optional): override the sql DDL fragment for this particular column (non portable)

7

table (optional): define the targeted table (default primary table)

8

length (optional): column length (default 255)

8

precision (optional): column decimal precision (default 0)

10

scale (optional): column decimal scale if useful (default 0)

The <property> element declares a persistent JavaBean style property of the class.

<property
        name="(1)propertyName"
        column(2)="column_name"
        type="(3)typename"
        update(4)="true|false"
        insert(4)="true|false"
        formul(5)a="arbitrary SQL expression"
        access(6)="field|property|ClassName"
        lazy="(7)true|false"
        unique(8)="true|false"
        not-nu(9)ll="true|false"
        optimi(10)stic-lock="true|false"
        genera(11)ted="never|insert|always"
        node="element-name|@attribute-name|element/@attribute|."
        index="index_name"
        unique_key="unique_key_id"
        length="L"
        precision="P"
        scale="S"
/>

1

name: the name of the property, with an initial lowercase letter.

2

column (optional - defaults to the property name): the name of the mapped database table column. This can also be specified by nested <column> element(s).

3

type (optional): a name that indicates the Hibernate type.

4

update, insert (optional - defaults to true): specifies that the mapped columns should be included in SQL UPDATE and/or INSERT statements. Setting both to false allows a pure "derived" property whose value is initialized from some other property that maps to the same column(s), or by a trigger or other application.

5

formula (optional): an SQL expression that defines the value for a computed property. Computed properties do not have a column mapping of their own.

6

access (optional - defaults to property): the strategy Hibernate uses for accessing the property value.

7

lazy (optional - defaults to false): specifies that this property should be fetched lazily when the instance variable is first accessed. It requires build-time bytecode instrumentation.

8

unique (optional): enables the DDL generation of a unique constraint for the columns. Also, allow this to be the target of a property-ref.

9

not-null (optional): enables the DDL generation of a nullability constraint for the columns.

10

optimistic-lock (optional - defaults to true): specifies that updates to this property do or do not require acquisition of the optimistic lock. In other words, it determines if a version increment should occur when this property is dirty.

11

generated (optional - defaults to never): specifies that this property value is actually generated by the database. See the discussion of generated properties for more information.

typename could be:

If you do not specify a type, Hibernate will use reflection upon the named property and guess the correct Hibernate type. Hibernate will attempt to interpret the name of the return class of the property getter using, in order, rules 2, 3, and 4. In certain cases you will need the type attribute. For example, to distinguish between Hibernate.DATE and Hibernate.TIMESTAMP, or to specify a custom type.

The access attribute allows you to control how Hibernate accesses the property at runtime. By default, Hibernate will call the property get/set pair. If you specify access="field", Hibernate will bypass the get/set pair and access the field directly using reflection. You can specify your own strategy for property access by naming a class that implements the interface org.hibernate.property.PropertyAccessor.

A powerful feature is derived properties. These properties are by definition read-only. The property value is computed at load time. You declare the computation as an SQL expression. This then translates to a SELECT clause subquery in the SQL query that loads an instance:



<property name="totalPrice"
    formula="( SELECT SUM (li.quantity*p.price) FROM LineItem li, Product p
                WHERE li.productId = p.productId
                AND li.customerId = customerId
                AND li.orderNumber = orderNumber )"/>

You can reference the entity table by not declaring an alias on a particular column. This would be customerId in the given example. You can also use the nested <formula> mapping element if you do not want to use the attribute.

Embeddable objects (or components) are objects whose properties are mapped to the same table as the owning entity's table. Components can, in turn, declare their own properties, components or collections

It is possible to declare an embedded component inside an entity and even override its column mapping. Component classes have to be annotated at the class level with the @Embeddable annotation. It is possible to override the column mapping of an embedded object for a particular entity using the @Embedded and @AttributeOverride annotation in the associated property:

@Entity

public class Person implements Serializable {
    // Persistent component using defaults
    Address homeAddress;
    @Embedded
    @AttributeOverrides( {
            @AttributeOverride(name="iso2", column = @Column(name="bornIso2") ),
            @AttributeOverride(name="name", column = @Column(name="bornCountryName") )
    } )
    Country bornIn;
    ...
}          
@Embeddable

public class Address implements Serializable {
    String city;
    Country nationality; //no overriding here
}            
@Embeddable

public class Country implements Serializable {
    private String iso2;
    @Column(name="countryName") private String name;
    public String getIso2() { return iso2; }
    public void setIso2(String iso2) { this.iso2 = iso2; }
    
    public String getName() { return name; }
    public void setName(String name) { this.name = name; }
    ...
}            

An embeddable object inherits the access type of its owning entity (note that you can override that using the @Access annotation).

The Person entity has two component properties, homeAddress and bornIn. homeAddress property has not been annotated, but Hibernate will guess that it is a persistent component by looking for the @Embeddable annotation in the Address class. We also override the mapping of a column name (to bornCountryName) with the @Embedded and @AttributeOverride annotations for each mapped attribute of Country. As you can see, Country is also a nested component of Address, again using auto-detection by Hibernate and JPA defaults. Overriding columns of embedded objects of embedded objects is through dotted expressions.

    @Embedded

    @AttributeOverrides( {
            @AttributeOverride(name="city", column = @Column(name="fld_city") ),
            @AttributeOverride(name="nationality.iso2", column = @Column(name="nat_Iso2") ),
            @AttributeOverride(name="nationality.name", column = @Column(name="nat_CountryName") )
            //nationality columns in homeAddress are overridden
    } )
    Address homeAddress;

Hibernate Annotations supports something that is not explicitly supported by the JPA specification. You can annotate a embedded object with the @MappedSuperclass annotation to make the superclass properties persistent (see @MappedSuperclass for more informations).

You can also use association annotations in an embeddable object (ie @OneToOne, @ManyToOne, @OneToMany or @ManyToMany). To override the association columns you can use @AssociationOverride.

If you want to have the same embeddable object type twice in the same entity, the column name defaulting will not work as several embedded objects would share the same set of columns. In plain JPA, you need to override at least one set of columns. Hibernate, however, allows you to enhance the default naming mechanism through the NamingStrategy interface. You can write a strategy that prevent name clashing in such a situation. DefaultComponentSafeNamingStrategy is an example of this.

If a property of the embedded object points back to the owning entity, annotate it with the @Parent annotation. Hibernate will make sure this property is properly loaded with the entity reference.

In XML, use the <component> element.

<component
        name="(1)propertyName"
        class=(2)"className"
        insert(3)="true|false"
        update(4)="true|false"
        access(5)="field|property|ClassName"
        lazy="(6)true|false"
        optimi(7)stic-lock="true|false"
        unique(8)="true|false"
        node="element-name|."
>

        <property ...../>
        <many-to-one .... />
        ........
</component>

1

name: the name of the property.

2

class (optional - defaults to the property type determined by reflection): the name of the component (child) class.

3

insert: do the mapped columns appear in SQL INSERTs?

4

update: do the mapped columns appear in SQL UPDATEs?

5

access (optional - defaults to property): the strategy Hibernate uses for accessing the property value.

6

lazy (optional - defaults to false): specifies that this component should be fetched lazily when the instance variable is first accessed. It requires build-time bytecode instrumentation.

7

optimistic-lock (optional - defaults to true): specifies that updates to this component either do or do not require acquisition of the optimistic lock. It determines if a version increment should occur when this property is dirty.

8

unique (optional - defaults to false): specifies that a unique constraint exists upon all mapped columns of the component.

The child <property> tags map properties of the child class to table columns.

The <component> element allows a <parent> subelement that maps a property of the component class as a reference back to the containing entity.

The <dynamic-component> element allows a Map to be mapped as a component, where the property names refer to keys of the map. See Section 9.5, “Dynamic components” for more information. This feature is not supported in annotations.

Java is a language supporting polymorphism: a class can inherit from another. Several strategies are possible to persist a class hierarchy:

With this approach the properties of all the subclasses in a given mapped class hierarchy are stored in a single table.

Each subclass declares its own persistent properties and subclasses. Version and id properties are assumed to be inherited from the root class. Each subclass in a hierarchy must define a unique discriminator value. If this is not specified, the fully qualified Java class name is used.

@Entity

@Inheritance(strategy=InheritanceType.SINGLE_TABLE)
@DiscriminatorColumn(
    name="planetype",
    discriminatorType=DiscriminatorType.STRING
)
@DiscriminatorValue("Plane")
public class Plane { ... }
@Entity
@DiscriminatorValue("A320")
public class A320 extends Plane { ... }          

In hbm.xml, for the table-per-class-hierarchy mapping strategy, the <subclass> declaration is used. For example:

<subclass
        name="(1)ClassName"
        discri(2)minator-value="discriminator_value"
        proxy=(3)"ProxyInterface"
        lazy="(4)true|false"
        dynamic-update="true|false"
        dynamic-insert="true|false"
        entity-name="EntityName"
        node="element-name"
        extends="SuperclassName">

        <property .... />
        .....
</subclass>

1

name: the fully qualified class name of the subclass.

2

discriminator-value (optional - defaults to the class name): a value that distinguishes individual subclasses.

3

proxy (optional): specifies a class or interface used for lazy initializing proxies.

4

lazy (optional - defaults to true): setting lazy="false" disables the use of lazy fetching.

For information about inheritance mappings see Chapter 10, Inheritance mapping.

Discriminators are required for polymorphic persistence using the table-per-class-hierarchy mapping strategy. It declares a discriminator column of the table. The discriminator column contains marker values that tell the persistence layer what subclass to instantiate for a particular row. Hibernate Core supports the follwoing restricted set of types as discriminator column: string, character, integer, byte, short, boolean, yes_no, true_false.

Use the @DiscriminatorColumn to define the discriminator column as well as the discriminator type.

You can also use @DiscriminatorFormula to express in SQL a virtual discriminator column. This is particularly useful when the discriminator value can be extracted from one or more columns of the table. Both @DiscriminatorColumn and @DiscriminatorFormula are to be set on the root entity (once per persisted hierarchy).

@org.hibernate.annotations.DiscriminatorOptions allows to optionally specify Hibernate specific discriminator options which are not standardized in JPA. The available options are force and insert. The force attribute is useful if the table contains rows with "extra" discriminator values that are not mapped to a persistent class. This could for example occur when working with a legacy database. If force is set to true Hibernate will specify the allowed discriminator values in the SELECT query, even when retrieving all instances of the root class. The second option - insert - tells Hibernate whether or not to include the discriminator column in SQL INSERTs. Usually the column should be part of the INSERT statement, but if your discriminator column is also part of a mapped composite identifier you have to set this option to false.

Finally, use @DiscriminatorValue on each class of the hierarchy to specify the value stored in the discriminator column for a given entity. If you do not set @DiscriminatorValue on a class, the fully qualified class name is used.

@Entity

@Inheritance(strategy=InheritanceType.SINGLE_TABLE)
@DiscriminatorColumn(
    name="planetype",
    discriminatorType=DiscriminatorType.STRING
)
@DiscriminatorValue("Plane")
public class Plane { ... }
@Entity
@DiscriminatorValue("A320")
public class A320 extends Plane { ... }          

In hbm.xml, the <discriminator> element is used to define the discriminator column or formula:

<discriminator
        column(1)="discriminator_column"
        type="(2)discriminator_type"
        force=(3)"true|false"
        insert(4)="true|false"
        formul(5)a="arbitrary sql expression"
/>

1

column (optional - defaults to class): the name of the discriminator column.

2

type (optional - defaults to string): a name that indicates the Hibernate type

3

force (optional - defaults to false): "forces" Hibernate to specify the allowed discriminator values, even when retrieving all instances of the root class.

4

insert (optional - defaults to true): set this to false if your discriminator column is also part of a mapped composite identifier. It tells Hibernate not to include the column in SQL INSERTs.

5

formula (optional): an arbitrary SQL expression that is executed when a type has to be evaluated. It allows content-based discrimination.

Actual values of the discriminator column are specified by the discriminator-value attribute of the <class> and <subclass> elements.

The formula attribute allows you to declare an arbitrary SQL expression that will be used to evaluate the type of a row. For example:


<discriminator
    formula="case when CLASS_TYPE in ('a', 'b', 'c') then 0 else 1 end"
    type="integer"/>

Each subclass can also be mapped to its own table. This is called the table-per-subclass mapping strategy. An inherited state is retrieved by joining with the table of the superclass. A discriminator column is not required for this mapping strategy. Each subclass must, however, declare a table column holding the object identifier. The primary key of this table is also a foreign key to the superclass table and described by the @PrimaryKeyJoinColumns or the <key> element.

@Entity @Table(name="CATS")

@Inheritance(strategy=InheritanceType.JOINED)
public class Cat implements Serializable { 
    @Id @GeneratedValue(generator="cat-uuid") 
    @GenericGenerator(name="cat-uuid", strategy="uuid")
    String getId() { return id; }
    ...
}
@Entity @Table(name="DOMESTIC_CATS")
@PrimaryKeyJoinColumn(name="CAT")
public class DomesticCat extends Cat { 
    public String getName() { return name; }
}            

In hbm.xml, use the <joined-subclass> element. For example:

<joined-subclass
        name="(1)ClassName"
        table=(2)"tablename"
        proxy=(3)"ProxyInterface"
        lazy="(4)true|false"
        dynamic-update="true|false"
        dynamic-insert="true|false"
        schema="schema"
        catalog="catalog"
        extends="SuperclassName"
        persister="ClassName"
        subselect="SQL expression"
        entity-name="EntityName"
        node="element-name">

        <key .... >

        <property .... />
        .....
</joined-subclass>

1

name: the fully qualified class name of the subclass.

2

table: the name of the subclass table.

3

proxy (optional): specifies a class or interface to use for lazy initializing proxies.

4

lazy (optional, defaults to true): setting lazy="false" disables the use of lazy fetching.

Use the <key> element to declare the primary key / foreign key column. The mapping at the start of the chapter would then be re-written as:


<?xml version="1.0"?>
<!DOCTYPE hibernate-mapping PUBLIC
        "-//Hibernate/Hibernate Mapping DTD//EN"
        "http://www.hibernate.org/dtd/hibernate-mapping-3.0.dtd">

<hibernate-mapping package="eg">

        <class name="Cat" table="CATS">
                <id name="id" column="uid" type="long">
                        <generator class="hilo"/>
                </id>
                <property name="birthdate" type="date"/>
                <property name="color" not-null="true"/>
                <property name="sex" not-null="true"/>
                <property name="weight"/>
                <many-to-one name="mate"/>
                <set name="kittens">
                        <key column="MOTHER"/>
                        <one-to-many class="Cat"/>
                </set>
                <joined-subclass name="DomesticCat" table="DOMESTIC_CATS">
                    <key column="CAT"/>
                    <property name="name" type="string"/>
                </joined-subclass>
        </class>

        <class name="eg.Dog">
                <!-- mapping for Dog could go here -->
        </class>

</hibernate-mapping>

For information about inheritance mappings see Chapter 10, Inheritance mapping.

This is sometimes useful to share common properties through a technical or a business superclass without including it as a regular mapped entity (ie no specific table for this entity). For that purpose you can map them as @MappedSuperclass.

@MappedSuperclass

public class BaseEntity {
    @Basic
    @Temporal(TemporalType.TIMESTAMP)
    public Date getLastUpdate() { ... }
    public String getLastUpdater() { ... }
    ...
}
@Entity class Order extends BaseEntity {
    @Id public Integer getId() { ... }
    ...
}

In database, this hierarchy will be represented as an Order table having the id, lastUpdate and lastUpdater columns. The embedded superclass property mappings are copied into their entity subclasses. Remember that the embeddable superclass is not the root of the hierarchy though.

You can override columns defined in entity superclasses at the root entity level using the @AttributeOverride annotation.

@MappedSuperclass

public class FlyingObject implements Serializable {
    public int getAltitude() {
        return altitude;
    }
    @Transient
    public int getMetricAltitude() {
        return metricAltitude;
    }
    @ManyToOne
    public PropulsionType getPropulsion() {
        return metricAltitude;
    }
    ...
}
@Entity
@AttributeOverride( name="altitude", column = @Column(name="fld_altitude") )
@AssociationOverride( 
   name="propulsion", 
   joinColumns = @JoinColumn(name="fld_propulsion_fk") 
)
public class Plane extends FlyingObject {
    ...
}

The altitude property will be persisted in an fld_altitude column of table Plane and the propulsion association will be materialized in a fld_propulsion_fk foreign key column.

You can define @AttributeOverride(s) and @AssociationOverride(s) on @Entity classes, @MappedSuperclass classes and properties pointing to an @Embeddable object.

In hbm.xml, simply map the properties of the superclass in the <class> element of the entity that needs to inherit them.

While not recommended for a fresh schema, some legacy databases force your to map a single entity on several tables.

Using the @SecondaryTable or @SecondaryTables class level annotations. To express that a column is in a particular table, use the table parameter of @Column or @JoinColumn.

@Entity

@Table(name="MainCat")
@SecondaryTables({
    @SecondaryTable(name="Cat1", pkJoinColumns={
        @PrimaryKeyJoinColumn(name="cat_id", referencedColumnName="id")
    ),
    @SecondaryTable(name="Cat2", uniqueConstraints={@UniqueConstraint(columnNames={"storyPart2"})})
})
public class Cat implements Serializable {
    private Integer id;
    private String name;
    private String storyPart1;
    private String storyPart2;
    @Id @GeneratedValue
    public Integer getId() {
        return id;
    }
    public String getName() {
        return name;
    }
    
    @Column(table="Cat1")
    public String getStoryPart1() {
        return storyPart1;
    }
    @Column(table="Cat2")
    public String getStoryPart2() {
        return storyPart2;
    }
}

In this example, name will be in MainCat. storyPart1 will be in Cat1 and storyPart2 will be in Cat2. Cat1 will be joined to MainCat using the cat_id as a foreign key, and Cat2 using id (ie the same column name, the MainCat id column has). Plus a unique constraint on storyPart2 has been set.

There is also additional tuning accessible via the @org.hibernate.annotations.Table annotation:

Make sure to use the secondary table name in the appliesto property

@Entity

@Table(name="MainCat")
@SecondaryTable(name="Cat1")
@org.hibernate.annotations.Table(
   appliesTo="Cat1",
   fetch=FetchMode.SELECT,
   optional=true)
public class Cat implements Serializable {
    private Integer id;
    private String name;
    private String storyPart1;
    private String storyPart2;
    @Id @GeneratedValue
    public Integer getId() {
        return id;
    }
    public String getName() {
        return name;
    }
    
    @Column(table="Cat1")
    public String getStoryPart1() {
        return storyPart1;
    }
    @Column(table="Cat2")
    public String getStoryPart2() {
        return storyPart2;
    }
}

In hbm.xml, use the <join> element.

<join
        table=(1)"tablename"
        schema(2)="owner"
        catalo(3)g="catalog"
        fetch=(4)"join|select"
        invers(5)e="true|false"
        option(6)al="true|false">

        <key ... />

        <property ... />
        ...
</join>

1

table: the name of the joined table.

2

schema (optional): overrides the schema name specified by the root <hibernate-mapping> element.

3

catalog (optional): overrides the catalog name specified by the root <hibernate-mapping> element.

4

fetch (optional - defaults to join): if set to join, the default, Hibernate will use an inner join to retrieve a <join> defined by a class or its superclasses. It will use an outer join for a <join> defined by a subclass. If set to select then Hibernate will use a sequential select for a <join> defined on a subclass. This will be issued only if a row represents an instance of the subclass. Inner joins will still be used to retrieve a <join> defined by the class and its superclasses.

5

inverse (optional - defaults to false): if enabled, Hibernate will not insert or update the properties defined by this join.

6

optional (optional - defaults to false): if enabled, Hibernate will insert a row only if the properties defined by this join are non-null. It will always use an outer join to retrieve the properties.

For example, address information for a person can be mapped to a separate table while preserving value type semantics for all properties:


<class name="Person"
    table="PERSON">

    <id name="id" column="PERSON_ID">...</id>

    <join table="ADDRESS">
        <key column="ADDRESS_ID"/>
        <property name="address"/>
        <property name="zip"/>
        <property name="country"/>
    </join>
    ...

This feature is often only useful for legacy data models. We recommend fewer tables than classes and a fine-grained domain model. However, it is useful for switching between inheritance mapping strategies in a single hierarchy, as explained later.

To link one entity to an other, you need to map the association property as a to one association. In the relational model, you can either use a foreign key or an association table, or (a bit less common) share the same primary key value between the two entities.

To mark an association, use either @ManyToOne or @OnetoOne.

@ManyToOne and @OneToOne have a parameter named targetEntity which describes the target entity name. You usually don't need this parameter since the default value (the type of the property that stores the association) is good in almost all cases. However this is useful when you want to use interfaces as the return type instead of the regular entity.

Setting a value of the cascade attribute to any meaningful value other than nothing will propagate certain operations to the associated object. The meaningful values are divided into three categories.

By default, single point associations are eagerly fetched in JPA 2. You can mark it as lazily fetched by using @ManyToOne(fetch=FetchType.LAZY) in which case Hibernate will proxy the association and load it when the state of the associated entity is reached. You can force Hibernate not to use a proxy by using @LazyToOne(NO_PROXY). In this case, the property is fetched lazily when the instance variable is first accessed. This requires build-time bytecode instrumentation. lazy="false" specifies that the association will always be eagerly fetched.

With the default JPA options, single-ended associations are loaded with a subsequent select if set to LAZY, or a SQL JOIN is used for EAGER associations. You can however adjust the fetching strategy, ie how data is fetched by using @Fetch. FetchMode can be SELECT (a select is triggered when the association needs to be loaded) or JOIN (use a SQL JOIN to load the association while loading the owner entity). JOIN overrides any lazy attribute (an association loaded through a JOIN strategy cannot be lazy).

An ordinary association to another persistent class is declared using a

and a foreign key in one table is referencing the primary key column(s) of the target table.

@Entity

public class Flight implements Serializable {
    @ManyToOne( cascade = {CascadeType.PERSIST, CascadeType.MERGE} )
    @JoinColumn(name="COMP_ID")
    public Company getCompany() {
        return company;
    }
    ...
}            

The @JoinColumn attribute is optional, the default value(s) is the concatenation of the name of the relationship in the owner side, _ (underscore), and the name of the primary key column in the owned side. In this example company_id because the property name is company and the column id of Company is id.

@Entity

public class Flight implements Serializable {
    @ManyToOne( cascade = {CascadeType.PERSIST, CascadeType.MERGE}, targetEntity=CompanyImpl.class )
    @JoinColumn(name="COMP_ID")
    public Company getCompany() {
        return company;
    }
    ...
}
public interface Company {
    ...
}

You can also map a to one association through an association table. This association table described by the @JoinTable annotation will contains a foreign key referencing back the entity table (through @JoinTable.joinColumns) and a a foreign key referencing the target entity table (through @JoinTable.inverseJoinColumns).

@Entity

public class Flight implements Serializable {
    @ManyToOne( cascade = {CascadeType.PERSIST, CascadeType.MERGE} )
    @JoinTable(name="Flight_Company",
        joinColumns = @JoinColumn(name="FLIGHT_ID"),
        inverseJoinColumns = @JoinColumn(name="COMP_ID")
    )
    public Company getCompany() {
        return company;
    }
    ...
}       

You can mark an association as mandatory by using the optional=false attribute. We recommend to use Bean Validation's @NotNull annotation as a better alternative however. As a consequence, the foreign key column(s) will be marked as not nullable (if possible).

When Hibernate cannot resolve the association because the expected associated element is not in database (wrong id on the association column), an exception is raised. This might be inconvenient for legacy and badly maintained schemas. You can ask Hibernate to ignore such elements instead of raising an exception using the @NotFound annotation.


Sometimes you want to delegate to your database the deletion of cascade when a given entity is deleted. In this case Hibernate generates a cascade delete constraint at the database level.


Foreign key constraints, while generated by Hibernate, have a fairly unreadable name. You can override the constraint name using @ForeignKey.


Sometimes, you want to link one entity to an other not by the target entity primary key but by a different unique key. You can achieve that by referencing the unique key column(s) in @JoinColumn.referenceColumnName.

@Entity

class Person {
   @Id Integer personNumber;
   String firstName;
   @Column(name="I")
   String initial;
   String lastName;
}
@Entity
class Home {
   @ManyToOne
   @JoinColumns({
      @JoinColumn(name="first_name", referencedColumnName="firstName"),
      @JoinColumn(name="init", referencedColumnName="I"),
      @JoinColumn(name="last_name", referencedColumnName="lastName"),
   })
   Person owner
}

This is not encouraged however and should be reserved to legacy mappings.

In hbm.xml, mapping an association is similar. The main difference is that a @OneToOne is mapped as <many-to-one unique="true"/>, let's dive into the subject.

<many-to-one
        name="(1)propertyName"
        column(2)="column_name"
        class=(3)"ClassName"
        cascad(4)e="cascade_style"
        fetch=(5)"join|select"
        update(6)="true|false"
        insert(6)="true|false"
        proper(7)ty-ref="propertyNameFromAssociatedClass"
        access(8)="field|property|ClassName"
        unique(9)="true|false"
        not-nu(10)ll="true|false"
        optimi(11)stic-lock="true|false"
        lazy="(12)proxy|no-proxy|false"
        not-fo(13)und="ignore|exception"
        entity(14)-name="EntityName"
        formul(15)a="arbitrary SQL expression"
        node="element-name|@attribute-name|element/@attribute|."
        embed-xml="true|false"
        index="index_name"
        unique_key="unique_key_id"
        foreign-key="foreign_key_name"
/>

1

name: the name of the property.

2

column (optional): the name of the foreign key column. This can also be specified by nested <column> element(s).

3

class (optional - defaults to the property type determined by reflection): the name of the associated class.

4

cascade (optional): specifies which operations should be cascaded from the parent object to the associated object.

5

fetch (optional - defaults to select): chooses between outer-join fetching or sequential select fetching.

6

update, insert (optional - defaults to true): specifies that the mapped columns should be included in SQL UPDATE and/or INSERT statements. Setting both to false allows a pure "derived" association whose value is initialized from another property that maps to the same column(s), or by a trigger or other application.

7

property-ref (optional): the name of a property of the associated class that is joined to this foreign key. If not specified, the primary key of the associated class is used.

8

access (optional - defaults to property): the strategy Hibernate uses for accessing the property value.

9

unique (optional): enables the DDL generation of a unique constraint for the foreign-key column. By allowing this to be the target of a property-ref, you can make the association multiplicity one-to-one.

10

not-null (optional): enables the DDL generation of a nullability constraint for the foreign key columns.

11

optimistic-lock (optional - defaults to true): specifies that updates to this property do or do not require acquisition of the optimistic lock. In other words, it determines if a version increment should occur when this property is dirty.

12

lazy (optional - defaults to proxy): by default, single point associations are proxied. lazy="no-proxy" specifies that the property should be fetched lazily when the instance variable is first accessed. This requires build-time bytecode instrumentation. lazy="false" specifies that the association will always be eagerly fetched.

13

not-found (optional - defaults to exception): specifies how foreign keys that reference missing rows will be handled. ignore will treat a missing row as a null association.

14

entity-name (optional): the entity name of the associated class.

15

formula (optional): an SQL expression that defines the value for a computed foreign key.

Setting a value of the cascade attribute to any meaningful value other than none will propagate certain operations to the associated object. The meaningful values are divided into three categories. First, basic operations, which include: persist, merge, delete, save-update, evict, replicate, lock and refresh; second, special values: delete-orphan; and third,all comma-separated combinations of operation names: cascade="persist,merge,evict" or cascade="all,delete-orphan". See Section 11.11, “Transitive persistence” for a full explanation. Note that single valued, many-to-one and one-to-one, associations do not support orphan delete.

Here is an example of a typical many-to-one declaration:


<many-to-one name="product" class="Product" column="PRODUCT_ID"/>

The property-ref attribute should only be used for mapping legacy data where a foreign key refers to a unique key of the associated table other than the primary key. This is a complicated and confusing relational model. For example, if the Product class had a unique serial number that is not the primary key. The unique attribute controls Hibernate's DDL generation with the SchemaExport tool.


<property name="serialNumber" unique="true" type="string" column="SERIAL_NUMBER"/>

Then the mapping for OrderItem might use:


<many-to-one name="product" property-ref="serialNumber" column="PRODUCT_SERIAL_NUMBER"/>

This is not encouraged, however.

If the referenced unique key comprises multiple properties of the associated entity, you should map the referenced properties inside a named <properties> element.

If the referenced unique key is the property of a component, you can specify a property path:


<many-to-one name="owner" property-ref="identity.ssn" column="OWNER_SSN"/>

The second approach is to ensure an entity and its associated entity share the same primary key. In this case the primary key column is also a foreign key and there is no extra column. These associations are always one to one.


Note

Many people got confused by these primary key based one to one associations. They can only be lazily loaded if Hibernate knows that the other side of the association is always present. To indicate to Hibernate that it is the case, use @OneToOne(optional=false).

In hbm.xml, use the following mapping.

<one-to-one
        name="(1)propertyName"
        class=(2)"ClassName"
        cascad(3)e="cascade_style"
        constr(4)ained="true|false"
        fetch=(5)"join|select"
        proper(6)ty-ref="propertyNameFromAssociatedClass"
        access(7)="field|property|ClassName"
        formul(8)a="any SQL expression"
        lazy="(9)proxy|no-proxy|false"
        entity(10)-name="EntityName"
        node="element-name|@attribute-name|element/@attribute|."
        embed-xml="true|false"
        foreign-key="foreign_key_name"
/>

1

name: the name of the property.

2

class (optional - defaults to the property type determined by reflection): the name of the associated class.

3

cascade (optional): specifies which operations should be cascaded from the parent object to the associated object.

4

constrained (optional): specifies that a foreign key constraint on the primary key of the mapped table and references the table of the associated class. This option affects the order in which save() and delete() are cascaded, and determines whether the association can be proxied. It is also used by the schema export tool.

5

fetch (optional - defaults to select): chooses between outer-join fetching or sequential select fetching.

6

property-ref (optional): the name of a property of the associated class that is joined to the primary key of this class. If not specified, the primary key of the associated class is used.

7

access (optional - defaults to property): the strategy Hibernate uses for accessing the property value.

8

formula (optional): almost all one-to-one associations map to the primary key of the owning entity. If this is not the case, you can specify another column, columns or expression to join on using an SQL formula. See org.hibernate.test.onetooneformula for an example.

9

lazy (optional - defaults to proxy): by default, single point associations are proxied. lazy="no-proxy" specifies that the property should be fetched lazily when the instance variable is first accessed. It requires build-time bytecode instrumentation. lazy="false" specifies that the association will always be eagerly fetched. Note that if constrained="false", proxying is impossible and Hibernate will eagerly fetch the association.

10

entity-name (optional): the entity name of the associated class.

Primary key associations do not need an extra table column. If two rows are related by the association, then the two table rows share the same primary key value. To relate two objects by a primary key association, ensure that they are assigned the same identifier value.

For a primary key association, add the following mappings to Employee and Person respectively:


<one-to-one name="person" class="Person"/>

<one-to-one name="employee" class="Employee" constrained="true"/>

Ensure that the primary keys of the related rows in the PERSON and EMPLOYEE tables are equal. You use a special Hibernate identifier generation strategy called foreign:


<class name="person" table="PERSON">
    <id name="id" column="PERSON_ID">
        <generator class="foreign">
            <param name="property">employee</param>
        </generator>
    </id>
    ...
    <one-to-one name="employee"
        class="Employee"
        constrained="true"/>
</class>

A newly saved instance of Person is assigned the same primary key value as the Employee instance referred with the employee property of that Person.

Although we recommend the use of surrogate keys as primary keys, you should try to identify natural keys for all entities. A natural key is a property or combination of properties that is unique and non-null. It is also immutable. Map the properties of the natural key as @NaturalId or map them inside the <natural-id> element. Hibernate will generate the necessary unique key and nullability constraints and, as a result, your mapping will be more self-documenting.

@Entity

public class Citizen {
    @Id
    @GeneratedValue
    private Integer id;
    private String firstname;
    private String lastname;
    
    @NaturalId
    @ManyToOne
    private State state;
    @NaturalId
    private String ssn;
    ...
}
//and later on query
List results = s.createCriteria( Citizen.class )
                .add( Restrictions.naturalId().set( "ssn", "1234" ).set( "state", ste ) )
                .list();

Or in XML,


<natural-id mutable="true|false"/>
        <property ... />
        <many-to-one ... />
        ......
</natural-id>

It is recommended that you implement equals() and hashCode() to compare the natural key properties of the entity.

This mapping is not intended for use with entities that have natural primary keys.

There is one more type of property mapping. The @Any mapping defines a polymorphic association to classes from multiple tables. This type of mapping requires more than one column. The first column contains the type of the associated entity. The remaining columns contain the identifier. It is impossible to specify a foreign key constraint for this kind of association. This is not the usual way of mapping polymorphic associations and you should use this only in special cases. For example, for audit logs, user session data, etc.

The @Any annotation describes the column holding the metadata information. To link the value of the metadata information and an actual entity type, The @AnyDef and @AnyDefs annotations are used. The metaType attribute allows the application to specify a custom type that maps database column values to persistent classes that have identifier properties of the type specified by idType. You must specify the mapping from values of the metaType to class names.

@Any( metaColumn = @Column( name = "property_type" ), fetch=FetchType.EAGER )

@AnyMetaDef( 
    idType = "integer", 
    metaType = "string", 
    metaValues = {
        @MetaValue( value = "S", targetEntity = StringProperty.class ),
        @MetaValue( value = "I", targetEntity = IntegerProperty.class )
    } )
@JoinColumn( name = "property_id" )
public Property getMainProperty() {
    return mainProperty;
}

Note that @AnyDef can be mutualized and reused. It is recommended to place it as a package metadata in this case.

//on a package

@AnyMetaDef( name="property" 
    idType = "integer", 
    metaType = "string", 
    metaValues = {
        @MetaValue( value = "S", targetEntity = StringProperty.class ),
        @MetaValue( value = "I", targetEntity = IntegerProperty.class )
    } )
package org.hibernate.test.annotations.any;
//in a class
    @Any( metaDef="property", metaColumn = @Column( name = "property_type" ), fetch=FetchType.EAGER )
    @JoinColumn( name = "property_id" )
    public Property getMainProperty() {
        return mainProperty;
    }

The hbm.xml equivalent is:


<any name="being" id-type="long" meta-type="string">
    <meta-value value="TBL_ANIMAL" class="Animal"/>
    <meta-value value="TBL_HUMAN" class="Human"/>
    <meta-value value="TBL_ALIEN" class="Alien"/>
    <column name="table_name"/>
    <column name="id"/>
</any>
<any
        name="(1)propertyName"
        id-typ(2)e="idtypename"
        meta-t(3)ype="metatypename"
        cascad(4)e="cascade_style"
        access(5)="field|property|ClassName"
        optimi(6)stic-lock="true|false"
>
        <meta-value ... />
        <meta-value ... />
        .....
        <column .... />
        <column .... />
        .....
</any>

1

name: the property name.

2

id-type: the identifier type.

3

meta-type (optional - defaults to string): any type that is allowed for a discriminator mapping.

4

cascade (optional- defaults to none): the cascade style.

5

access (optional - defaults to property): the strategy Hibernate uses for accessing the property value.

6

optimistic-lock (optional - defaults to true): specifies that updates to this property either do or do not require acquisition of the optimistic lock. It defines whether a version increment should occur if this property is dirty.

The <properties> element allows the definition of a named, logical grouping of the properties of a class. The most important use of the construct is that it allows a combination of properties to be the target of a property-ref. It is also a convenient way to define a multi-column unique constraint. For example:

<properties
        name="(1)logicalName"
        insert(2)="true|false"
        update(3)="true|false"
        optimi(4)stic-lock="true|false"
        unique(5)="true|false"
>

        <property ...../>
        <many-to-one .... />
        ........
</properties>

1

name: the logical name of the grouping. It is not an actual property name.

2

insert: do the mapped columns appear in SQL INSERTs?

3

update: do the mapped columns appear in SQL UPDATEs?

4

optimistic-lock (optional - defaults to true): specifies that updates to these properties either do or do not require acquisition of the optimistic lock. It determines if a version increment should occur when these properties are dirty.

5

unique (optional - defaults to false): specifies that a unique constraint exists upon all mapped columns of the component.

For example, if we have the following <properties> mapping:


<class name="Person">
    <id name="personNumber"/>

    ...
    <properties name="name"
            unique="true" update="false">
        <property name="firstName"/>
        <property name="initial"/>
        <property name="lastName"/>
    </properties>
</class>

You might have some legacy data association that refers to this unique key of the Person table, instead of to the primary key:


<many-to-one name="owner"
         class="Person" property-ref="name">
    <column name="firstName"/>
    <column name="initial"/>
    <column name="lastName"/>
</many-to-one>

The use of this outside the context of mapping legacy data is not recommended.

The hbm.xml structure has some specificities naturally not present when using annotations, let's describe them briefly.

All XML mappings should declare the doctype shown. The actual DTD can be found at the URL above, in the directory hibernate-x.x.x/src/org/hibernate , or in hibernate3.jar. Hibernate will always look for the DTD in its classpath first. If you experience lookups of the DTD using an Internet connection, check the DTD declaration against the contents of your classpath.

This element has several optional attributes. The schema and catalog attributes specify that tables referred to in this mapping belong to the named schema and/or catalog. If they are specified, tablenames will be qualified by the given schema and catalog names. If they are missing, tablenames will be unqualified. The default-cascade attribute specifies what cascade style should be assumed for properties and collections that do not specify a cascade attribute. By default, the auto-import attribute allows you to use unqualified class names in the query language.

<hibernate-mapping
         schem(1)a="schemaName"
         catal(2)og="catalogName"
         defau(3)lt-cascade="cascade_style"
         defau(4)lt-access="field|property|ClassName"
         defau(5)lt-lazy="true|false"
         auto-(6)import="true|false"
         packa(7)ge="package.name"
 />

1

schema (optional): the name of a database schema.

2

catalog (optional): the name of a database catalog.

3

default-cascade (optional - defaults to none): a default cascade style.

4

default-access (optional - defaults to property): the strategy Hibernate should use for accessing all properties. It can be a custom implementation of PropertyAccessor.

5

default-lazy (optional - defaults to true): the default value for unspecified lazy attributes of class and collection mappings.

6

auto-import (optional - defaults to true): specifies whether we can use unqualified class names of classes in this mapping in the query language.

7

package (optional): specifies a package prefix to use for unqualified class names in the mapping document.

If you have two persistent classes with the same unqualified name, you should set auto-import="false". An exception will result if you attempt to assign two classes to the same "imported" name.

The hibernate-mapping element allows you to nest several persistent <class> mappings, as shown above. It is, however, good practice (and expected by some tools) to map only a single persistent class, or a single class hierarchy, in one mapping file and name it after the persistent superclass. For example, Cat.hbm.xml, Dog.hbm.xml, or if using inheritance, Animal.hbm.xml.

The <key> element is featured a few times within this guide. It appears anywhere the parent mapping element defines a join to a new table that references the primary key of the original table. It also defines the foreign key in the joined table:

<key
        column(1)="columnname"
        on-del(2)ete="noaction|cascade"
        proper(3)ty-ref="propertyName"
        not-nu(4)ll="true|false"
        update(5)="true|false"
        unique(6)="true|false"
/>

1

column (optional): the name of the foreign key column. This can also be specified by nested <column> element(s).

2

on-delete (optional - defaults to noaction): specifies whether the foreign key constraint has database-level cascade delete enabled.

3

property-ref (optional): specifies that the foreign key refers to columns that are not the primary key of the original table. It is provided for legacy data.

4

not-null (optional): specifies that the foreign key columns are not nullable. This is implied whenever the foreign key is also part of the primary key.

5

update (optional): specifies that the foreign key should never be updated. This is implied whenever the foreign key is also part of the primary key.

6

unique (optional): specifies that the foreign key should have a unique constraint. This is implied whenever the foreign key is also the primary key.

For systems where delete performance is important, we recommend that all keys should be defined on-delete="cascade". Hibernate uses a database-level ON CASCADE DELETE constraint, instead of many individual DELETE statements. Be aware that this feature bypasses Hibernate's usual optimistic locking strategy for versioned data.

The not-null and update attributes are useful when mapping a unidirectional one-to-many association. If you map a unidirectional one-to-many association to a non-nullable foreign key, you must declare the key column using <key not-null="true">.

In relation to the persistence service, Java language-level objects are classified into two groups:

An entity exists independently of any other objects holding references to the entity. Contrast this with the usual Java model, where an unreferenced object is garbage collected. Entities must be explicitly saved and deleted. Saves and deletions, however, can be cascaded from a parent entity to its children. This is different from the ODMG model of object persistence by reachability and corresponds more closely to how application objects are usually used in large systems. Entities support circular and shared references. They can also be versioned.

An entity's persistent state consists of references to other entities and instances of value types. Values are primitives: collections (not what is inside a collection), components and certain immutable objects. Unlike entities, values in particular collections and components, are persisted and deleted by reachability. Since value objects and primitives are persisted and deleted along with their containing entity, they cannot be independently versioned. Values have no independent identity, so they cannot be shared by two entities or collections.

Until now, we have been using the term "persistent class" to refer to entities. We will continue to do that. Not all user-defined classes with a persistent state, however, are entities. A component is a user-defined class with value semantics. A Java property of type java.lang.String also has value semantics. Given this definition, all types (classes) provided by the JDK have value type semantics in Java, while user-defined types can be mapped with entity or value type semantics. This decision is up to the application developer. An entity class in a domain model will normally have shared references to a single instance of that class, while composition or aggregation usually translates to a value type.

We will revisit both concepts throughout this reference guide.

The challenge is to map the Java type system, and the developers' definition of entities and value types, to the SQL/database type system. The bridge between both systems is provided by Hibernate. For entities, <class>, <subclass> and so on are used. For value types we use <property>, <component>etc., that usually have a type attribute. The value of this attribute is the name of a Hibernate mapping type. Hibernate provides a range of mappings for standard JDK value types out of the box. You can write your own mapping types and implement your own custom conversion strategies.

With the exception of collections, all built-in Hibernate types support null semantics.

The built-in basic mapping types can be roughly categorized into the following:

integer, long, short, float, double, character, byte, boolean, yes_no, true_false

Type mappings from Java primitives or wrapper classes to appropriate (vendor-specific) SQL column types. boolean, yes_no and true_false are all alternative encodings for a Java boolean or java.lang.Boolean.

string

A type mapping from java.lang.String to VARCHAR (or Oracle VARCHAR2).

date, time, timestamp

Type mappings from java.util.Date and its subclasses to SQL types DATE, TIME and TIMESTAMP (or equivalent).

calendar, calendar_date

Type mappings from java.util.Calendar to SQL types TIMESTAMP and DATE (or equivalent).

big_decimal, big_integer

Type mappings from java.math.BigDecimal and java.math.BigInteger to NUMERIC (or Oracle NUMBER).

locale, timezone, currency

Type mappings from java.util.Locale, java.util.TimeZone and java.util.Currency to VARCHAR (or Oracle VARCHAR2). Instances of Locale and Currency are mapped to their ISO codes. Instances of TimeZone are mapped to their ID.

class

A type mapping from java.lang.Class to VARCHAR (or Oracle VARCHAR2). A Class is mapped to its fully qualified name.

binary

Maps byte arrays to an appropriate SQL binary type.

text

Maps long Java strings to a SQL LONGVARCHAR or TEXT type.

image

Maps long byte arrays to a SQL LONGVARBINARY.

serializable

Maps serializable Java types to an appropriate SQL binary type. You can also indicate the Hibernate type serializable with the name of a serializable Java class or interface that does not default to a basic type.

clob, blob

Type mappings for the JDBC classes java.sql.Clob and java.sql.Blob. These types can be inconvenient for some applications, since the blob or clob object cannot be reused outside of a transaction. Driver support is patchy and inconsistent.

materialized_clob

Maps long Java strings to a SQL CLOB type. When read, the CLOB value is immediately materialized into a Java string. Some drivers require the CLOB value to be read within a transaction. Once materialized, the Java string is available outside of the transaction.

materialized_blob

Maps long Java byte arrays to a SQL BLOB type. When read, the BLOB value is immediately materialized into a byte array. Some drivers require the BLOB value to be read within a transaction. Once materialized, the byte array is available outside of the transaction.

imm_date, imm_time, imm_timestamp, imm_calendar, imm_calendar_date, imm_serializable, imm_binary

Type mappings for what are considered mutable Java types. This is where Hibernate makes certain optimizations appropriate only for immutable Java types, and the application treats the object as immutable. For example, you should not call Date.setTime() for an instance mapped as imm_timestamp. To change the value of the property, and have that change made persistent, the application must assign a new, nonidentical, object to the property.

Unique identifiers of entities and collections can be of any basic type except binary, blob and clob. Composite identifiers are also allowed. See below for more information.

The basic value types have corresponding Type constants defined on org.hibernate.Hibernate. For example, Hibernate.STRING represents the string type.

It is relatively easy for developers to create their own value types. For example, you might want to persist properties of type java.lang.BigInteger to VARCHAR columns. Hibernate does not provide a built-in type for this. Custom types are not limited to mapping a property, or collection element, to a single table column. So, for example, you might have a Java property getName()/setName() of type java.lang.String that is persisted to the columns FIRST_NAME, INITIAL, SURNAME.

To implement a custom type, implement either org.hibernate.UserType or org.hibernate.CompositeUserType and declare properties using the fully qualified classname of the type. View org.hibernate.test.DoubleStringType to see the kind of things that are possible.


<property name="twoStrings" type="org.hibernate.test.DoubleStringType">
    <column name="first_string"/>
    <column name="second_string"/>
</property>

Notice the use of <column> tags to map a property to multiple columns.

The CompositeUserType, EnhancedUserType, UserCollectionType, and UserVersionType interfaces provide support for more specialized uses.

You can even supply parameters to a UserType in the mapping file. To do this, your UserType must implement the org.hibernate.usertype.ParameterizedType interface. To supply parameters to your custom type, you can use the <type> element in your mapping files.


<property name="priority">
    <type name="com.mycompany.usertypes.DefaultValueIntegerType">
        <param name="default">0</param>
    </type>
</property>

The UserType can now retrieve the value for the parameter named default from the Properties object passed to it.

If you regularly use a certain UserType, it is useful to define a shorter name for it. You can do this using the <typedef> element. Typedefs assign a name to a custom type, and can also contain a list of default parameter values if the type is parameterized.


<typedef class="com.mycompany.usertypes.DefaultValueIntegerType" name="default_zero">
    <param name="default">0</param>
</typedef>

<property name="priority" type="default_zero"/>

It is also possible to override the parameters supplied in a typedef on a case-by-case basis by using type parameters on the property mapping.

Even though Hibernate's rich range of built-in types and support for components means you will rarely need to use a custom type, it is considered good practice to use custom types for non-entity classes that occur frequently in your application. For example, a MonetaryAmount class is a good candidate for a CompositeUserType, even though it could be mapped as a component. One reason for this is abstraction. With a custom type, your mapping documents would be protected against changes to the way monetary values are represented.

It is possible to provide more than one mapping for a particular persistent class. In this case, you must specify an entity name to disambiguate between instances of the two mapped entities. By default, the entity name is the same as the class name. Hibernate lets you specify the entity name when working with persistent objects, when writing queries, or when mapping associations to the named entity.

<class name="Contract" table="Contracts"
        entity-name="CurrentContract">
    ...
    <set name="history" inverse="true"
            order-by="effectiveEndDate desc">
        <key column="currentContractId"/>
        <one-to-many entity-name="HistoricalContract"/>
    </set>
</class>

<class name="Contract" table="ContractHistory"
        entity-name="HistoricalContract">
    ...
    <many-to-one name="currentContract"
            column="currentContractId"
            entity-name="CurrentContract"/>
</class>

Associations are now specified using entity-name instead of class.

You can force Hibernate to quote an identifier in the generated SQL by enclosing the table or column name in backticks in the mapping document. Hibernate will use the correct quotation style for the SQL Dialect. This is usually double quotes, but the SQL Server uses brackets and MySQL uses backticks.


@Entity @Table(name="`Line Item`")
class LineItem {
   @id @Column(name="`Item Id`") Integer id;
   @Column(name="`Item #`") int itemNumber
}

<class name="LineItem" table="`Line Item`">
    <id name="id" column="`Item Id`"/><generator class="assigned"/></id>
    <property name="itemNumber" column="`Item #`"/>
    ...
</class>

Generated properties are properties that have their values generated by the database. Typically, Hibernate applications needed to refresh objects that contain any properties for which the database was generating values. Marking properties as generated, however, lets the application delegate this responsibility to Hibernate. When Hibernate issues an SQL INSERT or UPDATE for an entity that has defined generated properties, it immediately issues a select afterwards to retrieve the generated values.

Properties marked as generated must additionally be non-insertable and non-updateable. Only versions, timestamps, and simple properties, can be marked as generated.

never (the default): the given property value is not generated within the database.

insert: the given property value is generated on insert, but is not regenerated on subsequent updates. Properties like created-date fall into this category. Even though version and timestamp properties can be marked as generated, this option is not available.

always: the property value is generated both on insert and on update.

To mark a property as generated, use @Generated.

Hibernate allows you to customize the SQL it uses to read and write the values of columns mapped to simple properties. For example, if your database provides a set of data encryption functions, you can invoke them for individual columns like this:

@Entity

class CreditCard {
   @Column(name="credit_card_num")
   @ColumnTransformer(
      read="decrypt(credit_card_num)", 
      write="encrypt(?)")
   public String getCreditCardNumber() { return creditCardNumber; }
   public void setCreditCardNumber(String number) { this.creditCardNumber = number; }
   private String creditCardNumber;
}

or in XML


<property name="creditCardNumber">
        <column 
          name="credit_card_num"
          read="decrypt(credit_card_num)"
          write="encrypt(?)"/>
</property>

Note

You can use the plural form @ColumnTransformers if more than one columns need to define either of these rules.

If a property uses more that one column, you must use the forColumn attribute to specify which column, the expressions are targeting.

@Entity

class User {
   @Type(type="com.acme.type.CreditCardType")
   @Columns( {
      @Column(name="credit_card_num"),
      @Column(name="exp_date") } )
   @ColumnTransformer(
      forColumn="credit_card_num", 
      read="decrypt(credit_card_num)", 
      write="encrypt(?)")
   public CreditCard getCreditCard() { return creditCard; }
   public void setCreditCard(CreditCard card) { this.creditCard = card; }
   private CreditCard creditCard;
}

Hibernate applies the custom expressions automatically whenever the property is referenced in a query. This functionality is similar to a derived-property formula with two differences:

  • The property is backed by one or more columns that are exported as part of automatic schema generation.

  • The property is read-write, not read-only.

The write expression, if specified, must contain exactly one '?' placeholder for the value.

Auxiliary database objects allow for the CREATE and DROP of arbitrary database objects. In conjunction with Hibernate's schema evolution tools, they have the ability to fully define a user schema within the Hibernate mapping files. Although designed specifically for creating and dropping things like triggers or stored procedures, any SQL command that can be run via a java.sql.Statement.execute() method is valid (for example, ALTERs, INSERTS, etc.). There are essentially two modes for defining auxiliary database objects:

The first mode is to explicitly list the CREATE and DROP commands in the mapping file:


<hibernate-mapping>
    ...
    <database-object>
        <create>CREATE TRIGGER my_trigger ...</create>
        <drop>DROP TRIGGER my_trigger</drop>
    </database-object>
</hibernate-mapping>

The second mode is to supply a custom class that constructs the CREATE and DROP commands. This custom class must implement the org.hibernate.mapping.AuxiliaryDatabaseObject interface.


<hibernate-mapping>
    ...
    <database-object>
        <definition class="MyTriggerDefinition"/>
    </database-object>
</hibernate-mapping>

Additionally, these database objects can be optionally scoped so that they only apply when certain dialects are used.


<hibernate-mapping>
    ...
    <database-object>
        <definition class="MyTriggerDefinition"/>
        <dialect-scope name="org.hibernate.dialect.Oracle9iDialect"/>
        <dialect-scope name="org.hibernate.dialect.Oracle10gDialect"/>
    </database-object>
</hibernate-mapping>