TOC Special:Whatlinkshere_Creating_a_Relational_Descriptor_(ELUG)[Related Topics]
For information on how to create relational descriptors, see Creating a Relational Descriptor.
This table lists the default configurable options for a relational descriptor.
Option to Configure | Workbench | Java |
---|---|---|
For more information, see Introduction to Relational Descriptors.
Each relational class descriptor (see Creating Relational Class Descriptors) must be associated with a database table for storing instances of that class. This does not apply to relational aggregate descriptors (see Creating Relational Aggregate Descriptors).
To associate a descriptor with a database table, use this procedure:
-
Select a descriptor in the Navigator. Its properties appear in the Editor.
-
Click the Descriptor Info tab. The Descriptor Info tab appears. *_Descriptor Info Tab, Associated Table Options _*
-
Use the Associated Table list to select a database table for the descriptor. You must associate a descriptor with a database table before specifying primary keys.
See Also:
Sequencing allows EclipseLink to automatically assign the primary key or ID of an object when the object is inserted.
You configure EclipseLink sequencing at the project level or session level to tell EclipseLink how to obtain sequence values: that is, what type of sequences to use.
To enable sequencing, you must then configure EclipseLink sequencing at the descriptor level to tell EclipseLink into which table and column to write the sequence value when an instance of a descriptor’s reference class is created.
Only descriptors that have been configured with a sequence field and a sequence name will be assigned sequence numbers.
The sequence field is the database field that the sequence number will be assigned to: this is almost always the primary key field. The sequence name is the name of the sequence to be used for this descriptor. The purpose of the sequence name depends on the type of sequencing you are using:
When using table sequencing, the sequence name refers to the row’s SEQ_NAME value used to store this sequence.
When using Oracle native sequencing, the sequence name refers to the Oracle sequence object that has been created in the database. When using native sequencing on other databases, the sequence name does not have any direct meaning, but should still be set for compatibility.
The sequence name can also refer to a custom sequence defined in the project.
For more information, see Sequencing in Relational Projects.
To configure sequencing for a descriptor, use this procedure:
Use the following information to specify sequencing options:
Field
Description
Use Sequencing
Specify if this descriptor uses sequencing. If selected, specify the Name, Table, and Field for sequencing.
Name
Enter the name of the sequence.
For table sequencing: Enter the name of the value in the sequence name column (for default table sequencing, the column named SEQ_NAME) of the sequence table (for default table sequencing, the table named SEQUENCE) that EclipseLink uses to look up the corresponding sequence count value (for default table sequencing, the corresponding value in the SEQ_COUNT column) for this descriptor’s reference class. For more information, see Table Sequencing.
For native sequencing (Oracle platform): Enter the name of the sequence object that Oracle Database creates to manage sequencing for this descriptor’s reference class. For more information, see Native Sequencing with an Oracle Database Platform
For native sequencing (non-Oracle platform): For database compatibility, enter a generic name for the sequence, such as SEQ. For more information, see Native Sequencing with a Non-Oracle Database Platform.
Table
Specify the name of the database table that contains the field (see Field) into which EclipseLink is to write the sequence value when a new instance of this descriptor’s reference class is created. This is almost always this descriptor’s primary table.
Field
Specify the name of the field in the specified table (see Table) into which EclipseLink is to write the sequence value when a new instance of this descriptor’s reference class is created. This field is almost always the class’s primary key (see Configuring Primary Keys).
For native sequencing (non-Oracle platform): Ensure that your database schema specifies the correct type for this field (see Native Sequencing with a Non-Oracle Database Platform).
See Also:
Using Java, you can configure sequencing to use multiple different types of sequence for different descriptors. You configure the sequence objects on the session’s login and reference them from the descriptor by their name. The descriptor’s sequence name refers to the sequence object’s name you register in the session’s login.
The following examples assume the session sequence configuration shown in this example:
[Example 28-1]# Example Sequences
dbLogin.addSequence(new TableSequence("EMP_SEQ", 25));
dbLogin.addSequence(new DefaultSequence("PHONE_SEQ", 30));
dbLogin.addSequence(new UnaryTableSequence("ADD_SEQ", 55));
dbLogin.addSequence(new NativeSequence("NAT_SEQ", 10));
Using Java code, you can perform the following sequence configurations:
As the Associating a Sequence with a Descriptor
example shows, you associate a sequence with a descriptor by sequence
name. The sequence EMP_SEQ
was added to the login for this project
in the Example Sequences example. When a new
instance of the Employee
class is created, the EclipseLink runtime
will use the sequence named EMP_SEQ
(in this example, a
TableSequence
) to obtain a value for the EMP_ID
field.
[Example 28-2]# Associating a Sequence with a Descriptor
empDescriptor.setSequenceNumberFieldName("EMP_ID"); // primary key field
empDescriptor.setSequenceNumberName("EMP_SEQ");
As the Configuring a Sequence for Multiple
Descriptors example shows, you can associate the same sequence with
more than one descriptor. In this example, both the Employee
descriptor and Phone
descriptor use the same NativeSequence
.
Having descriptors share the same sequence can improve pre-allocation
performance. For more information on pre-allocation, see
Sequencing
and Preallocation Size.
[Example 28-3]# Configuring a Sequence for Multiple Descriptors
empDescriptor.setSequenceNumberFieldName("EMP_ID"); // primary key field
empDescriptor.setSequenceNumberName("NAT_SEQ");
phoneDescriptor.setSequenceNumberFieldName("PHONE_ID"); // primary key field
phoneDescriptor.setSequenceNumberName("NAT_SEQ");
In the Configuring a Default Sequence exmple, you
associate a nonexistent sequence (NEW_SEQ
) with a descriptor.
Because you did not add a sequence named NEW_SEQ
to the login for
this project in the Example Sequences example, the
EclipseLink runtime will create a DefaultSequence
named NEW_SEQ
for this descriptor. For more information about DefaultSequence
, see
Default
Sequencing.
[Example 28-4]# Configuring a Default Sequence
descriptor.setSequenceNumberFieldName("EMP_ID"); // primary key field
descriptor.setSequenceNumberName("NEW_SEQ");
You can use EclipseLink to define an SQL query for each basic persistence operation (insert, update, delete, read-object, read-all, or does-exist) so that when you query and modify your relational-mapped objects, the EclipseLink runtime will use the appropriate SQL query instead of the default SQL query.
SQL strings can include any fields that the descriptor maps, as well as
arguments. You specify arguments in the SQL string using
#<arg-name>
, such as:
select * from EMP where EMP_ID = #EMP_ID
The insert and update SQL strings can take any field that the descriptor maps as an argument.
The read-object, delete and does-exist SQL strings can only take the primary key fields as arguments.
The read-all SQL string must return all instances of the class and thus can take no arguments.
You can define a custom SQL string for insert, update, delete, read-object, and read-all using the Workbench.
You can define a custom SQL string or Call
object for insert,
update, delete, read-object, read-all, and does-exist
using
Java. Using a Call
, you can define more complex SQL strings and
invoke custom stored procedures.
Note: When you customize the update persistence operation for an application that uses optimistic locking (see Configuring Locking Policy), the custom update string must not write the object if the row version field has changed since the initial object was read. In addition, it must increment the version field if it writes the object successfully. For example:
update Employee set F_NAME = #F_NAME, VERSION = VERSION + 1 where (EMP_ID = #EMP_ID) AND (VERSION = #VERSION)
The update string must also maintain the row count of the database.
’Note: EclipseLink does not validate the SQL code that you enter. Enter the SQL code appropriate for your database platform (see Data Source Platform Types). |
To configure custom SQL queries for basic persistence operations:
Click the appropriate SQL function tab and type your own SQL string to control these actions for a descriptor. Use the following information to complete the tab:
Tab
Description
Insert
Defines the insert SQL that EclipseLink uses to insert a new object’s data into the database.
Update
Defines the update SQL that EclipseLink uses to update any changed existing object’s data in the database. When you define a descriptor’s update query, you must conform to the following:
If the application uses optimistic locking, you must ensure that the row is not written if the version field has changed since the object was read.
The update query must increment the version field if the row is written.
The update string must maintain the row count of the database.
Delete
Defines the delete SQL that EclipseLink uses to delete an object.
Read Object
Defines the read SQL that EclipseLink uses in any ReadObjectQuery, whose selection criteria is based on the object’s primary key. When you define a descriptor’s read-object query, your implementation overrides any ReadObjectQuery, whose selection criteria is based on the object’s primary key. EclipseLink generates dynamic SQL for all other Session readObject method signatures.
To customize other Session readObject method signatures, define additional named queries and use them in your application instead of the Session methods.
Read All
Defines the read-all SQL that EclipseLink uses when you call Session method readAllObjects(java.lang.Class) passing in the java.lang.Class that this descriptor represents. When you define a descriptor’s read-all query, your implementation overrides only the Session method readAll(java.lang.Class), not the version that takes a Class and Expression. As a result, this query reads every single instance. EclipseLink generates dynamic SQL for all other Session readAll method signatures.
To customize other Session readAll method signatures, define additional named queries and use them in your application instead of the Session methods.
The DescriptorQueryManager
generates default SQL for the following
persistence operations:
-
Insert
-
Update
-
Delete
-
Read-object
-
Read-all
-
Does-exist
Using Java code, you can use the descriptor query manager to provide custom SQL strings to perform these functions on a class-by-class basis.
Use ClassDescriptor
method getQueryManager
to acquire the
DescriptorQueryManager
, and then use the DescriptorQueryManager
methods that this table lists.
[Table 28-2]# Descriptor Query Manager Methods for Configuring Custom SQL
To Change the Default SQL for… | Use Descriptor Query Manager Method… |
---|---|
Insert |
|
|
|
|
|
Update |
|
|
|
|
|
Delete |
|
|
|
|
|
Read |
|
|
|
|
|
Read all |
|
|
|
|
|
Does exist |
|
|
|
|
The Configuring a Descriptor Query Manager with
Custom SQL Strings example shows how to implement an amendment method
to configure a descriptor query manager to use custom SQL strings.
Alternatively, using an SQLCall
, you can specify more complex SQL
strings using features such as in, out, and in-out parameters and
parameter types (see
Using a
SQLCall).
[Example 28-5]# Configuring a Descriptor Query Manager with Custom SQL Strings
public static void addToDescriptor(ClassDescriptor descriptor) {
// Read-object by primary key procedure
descriptor.getQueryManager().setReadObjectSQLString(
"select * from EMP where EMP_ID = #EMP_ID");
// Read-all instances procedure
descriptor.getQueryManager().setReadAllSQLString("select * from EMP");
// Insert procedure
descriptor.getQueryManager().setInsertSQLString(
"insert into EMP (EMP_ID, F_NAME, L_NAME, MGR_ID) values
(#EMP_ID, #F_NAME, #L_NAME, #MGR_ID)");
// Update procedure
descriptor.getQueryManager().setUpdateSQLString(
"update EMP set (F_NAME, L_NAME, MGR_ID) values
(#F_NAME, #L_NAME, #MGR_ID) where EMP_ID = #EMP_ID");
}
The Configuring a Descriptor Query Manager with
Custom Stored Procedure Calls example shows how to implement an
amendment method to configure a descriptor query manager to use Oracle
stored procedures using a StoredProcedureCall
(see
Using
a StoredProcedureCall). This example uses output cursors to return the
result set (see
Handling
Cursor and Stream Query Results).
[Example 28-6]# Configuring a Descriptor Query Manager with Custom Stored Procedure Calls
public static void addToDescriptor(ClassDescriptor descriptor) {
// Read-object by primary key procedure
StoredProcedureCall readCall = new StoredProcedureCall();
readCall.setProcedureName("READ_EMP");
readCall.addNamedArgument("P_EMP_ID", "EMP_ID");
readCall.useNamedCursorOutputAsResultSet("RESULT_CURSOR");
descriptor.getQueryManager().setReadObjectCall(readCall);
// Read-all instances procedure
StoredProcedureCall readAllCall = new StoredProcedureCall();
readAllCall.setProcedureName("READ_ALL_EMP");
readAllCall.useNamedCursorOutputAsResultSet("RESULT_CURSOR");
descriptor.getQueryManager().setReadAllCall(readAllCall );
// Insert procedure
StoredProcedureCall insertCall = new StoredProcedureCall();
insertCall.setProcedureName("INSERT_EMP");
insertCall.addNamedArgument("P_EMP_ID", "EMP_ID");
insertCall.addNamedArgument("P_F_NAME", "F_NAME");
insertCall.addNamedArgument("P_L_NAME", "L_NAME");
insertCall.addNamedArgument("P_MGR_ID", "MGR_ID");
descriptor.getQueryManager().setInsertCall(insertCall);
// Update procedure
StoredProcedureCall updateCall = new StoredProcedureCall();
updateCall.setProcedureName("UPDATE_EMP");
updateCall.addNamedArgument("P_EMP_ID", "EMP_ID");
updateCall.addNamedArgument("P_F_NAME", "F_NAME");
updateCall.addNamedArgument("P_L_NAME", "L_NAME");
updateCall.addNamedArgument("P_MGR_ID", "MGR_ID");
descriptor.getQueryManager().setUpdateCall(updateCall);
}
An interface alias allows an interface to be used to refer to a descriptor instead of the implementation class. This can be useful for classes that have public interface and the applications desire to refer to the class using the public interface. Specifying the interface alias allows any queries executed on an EclipseLink session to use the interface as the reference class instead of the implementation class.
Each descriptor can have one interface alias. Use the interface in queries and relationship mappings.
Note: If you use an interface alias, do not associate an interface descriptor with the interface. |
This section includes information on configuring an interface alias. Interfaces cannot be created in the Workbench; you must add the Java package or class to your Workbench project before configuring it.
To specify an interface alias, use this procedure:
-
In the Navigator, select a descriptor.If the Interface Alias advanced property is not visible for the descriptor, right-click the descriptor and choose Select Advanced Properties > Interface Alias from context menu or from the Selected menu.
-
In the Interface Alias field, click Browse and select an interface.
See Also:
To configure a descriptor with an interface alias using Java, create an
amendment method (see
Configuring
Amendment Methods) and use InterfacePolicy
method
addParentInterface
as this example shows.
[Example 28-7]# Configuring an Interface Alias
public static void addToDescriptor(Descriptor descriptor) {
descriptor.getInterfacePolicy().addParentInterface(MyInterface.class);
}
By default, when you add a Java class to a relational project (see Configuring Project Classpath), Workbench create a relational class descriptor for it. A class descriptor is applicable to any persistent object except an object that is owned by another in an aggregate relationship. In this case, you must describe the owned object with an aggregate descriptor. Using a class descriptor, you can configure any relational mapping except aggregate collection and aggregate object mappings.
An aggregate object is an object that is strictly dependent on its owning object. Aggregate descriptors do not define a table, primary key, or many of the standard descriptor options as they obtain these from their owning descriptor. If you want to configure an aggregate mapping to associate data members in a target object with fields in a source object’s underlying database tables (see Configuring a Relational Aggregate Collection Mapping and Configuring a Relational Aggregate Object Mapping), you must designate the target object’s descriptor as an aggregate.
Alternatively, you can remove the aggregate designation from a relational descriptor and return it to its default type.
You can configure inheritance for a descriptor designated as an aggregate (see Configuring Inheritance for a Child (Branch or Leaf) Class Descriptor), however, in this case, _all the descriptors in the inheritance tree must be aggregates. Aggregate and class descriptors cannot exist in the same inheritance tree. For more information, see Aggregate and Composite Descriptors and Inheritance.
For more information, see XML Descriptors and Aggregation.
To configure a relational descriptor as class or aggregate, use this procedure.
-
In the Navigator, select a relational descriptor.
-
Click the Class or Aggregate descriptor button on the mapping toolbar. You can also select the descriptor and choose Selected > Descriptor Type > Class or Aggregate from the menu or by right-clicking on the descriptor in the Navigator window and selecting Descriptor Type > Class or Aggregate from the context menu.
-
If you select Aggregate, specify each of the aggregate descriptor’s attributes as a direct to field mapping. See Configuring a Relational Direct-to-Field Mapping for more information.
Specify each of the aggregate descriptor’s attributes as a direct to field mapping. See Configuring a Relational Direct-to-Field Mapping for more information.
Although the attributes of a target class are not mapped directly to a data source until you configure an aggregate object mapping, you must still specify their mapping type in the target class’s descriptor. This tells EclipseLink what type of mapping to use when you do configure the aggregate mapping in the source object’s descriptor. For more information, see Aggregate and Composite Descriptors in Relational Projects.
See Also:
Using Java, to configure a relational descriptor as an aggregate, use
ClassDescriptor
method descriptorIsAggregate
.
To configure a relational descriptor for use in an aggregate collection
mapping, use ClassDescriptor
method
descriptorIsAggregateCollection
.
To configure a relational descriptor as a nonaggregate, use
ClassDescriptor
method descriptorIsNormal
.
Descriptors can use multiple tables in mappings. Use multiple tables when either of the following occurs:
-
A subclass is involved in inheritance, and its superclass is mapped to one table, while the subclass has additional attributes that are mapped to a second table.
-
A class is not involved in inheritance and its data is spread out across multiple tables.
When a descriptor has multiple tables, you must be able to join a row from the primary table to all the additional tables. By default, EclipseLink assumes that the primary key of the first, or primary, table is included in the additional tables, thereby joining the tables. EclipseLink also supports custom methods for joining tables. If the primary key field names of the multiple tables do not match, a foreign key can be used to join the tables. The foreign key can either be from the primary table to the secondary table, or from the secondary table to the primary table, or between two of the secondary tables (see How to Configure Multitable Information Using Workbench).
For complex multitable situations, a more complex join expression may be required. These include requiring the join to also check a type code, or using an outer-join. EclipseLink provides support for a multiple-table-join-expression for these cases (see How to Configure Multitable Information Using Java).
To associate multiple tables with a descriptor, use this procedure.
-
In the Navigator, select a descriptor.If the Multitable Info advanced property is not visible for the descriptor, right-click the descriptor and choose Select Advanced Properties > Multitable Info from the context menu or from the Selected menu.
-
Complete each field on the Multitable Info tab.
Use the following information to enter data in each field of the tab:
Field
Description
Primary Table
The primary table for this descriptor. This field is for display only.
Additional Tables
Use Add and Remove to add or remove additional tables.
Association to Primary Table
Specify how each Additional Table is associated to the Primary Table:
Primary Keys Have Same Names–when associating tables by identically named primary keys, EclipseLink requires no additional configuration.
Reference–when associating an additional table to the primary table with a Reference (that is, a foreign key), you can specify the Table Reference, as well as the Source and Target fields. Continue with Associating Tables with References.
Associating Tables with References
When associating a table using Reference, additional options appear. You must choose a reference that relates the correct fields in the primary table to the primary keys in the selected table.
[Figure 28-6]# Multitable Info Tab, Associated by Reference
image::multiref.gif[Multitable Info Tab, Associated by Reference,title="Multitable Info Tab, Associated by Reference"]
Choose a Table Reference that defines how the primary keys of the primary table relate to the primary keys of the selected table. Click Add to add a primary key association.
Using Java, configure a descriptor with multitable information using the
following org.eclipse.persistence.descriptors.ClassDescriptor
methods:
-
addTableName(java.lang.String tableName)
-
addForeignKeyFieldNameForMultipleTable(java.lang.String sourceForeignKeyFieldName, java.lang.String targetPrimaryKeyFieldName)
To specify a complex multiple-table-join-expression, create a descriptor
amendment method (see
Configuring
Amendment Methods) and add the join expression using
org.eclipse.persistence.descriptors.DescriptorQueryManager
method
setMultipleTableJoinExpression
. For more information, see
Appending
Additional Join Expressions.
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