See: Description
Interface | Description |
---|---|
EntityCursor<V> |
Traverses entity values or key values and allows deleting or updating the
entity at the current cursor position.
|
EntityIndex<K,V> |
The interface for accessing keys and entities via a primary or secondary
index.
|
ForwardCursor<V> |
Cursor operations limited to traversing forward.
|
Class | Description |
---|---|
EntityJoin<PK,E> |
Performs an equality join on two or more secondary keys.
|
EntityResult<V> |
Used to return an entity value from a 'get' operation along with an
OperationResult.
|
EntityStore |
A store for managing persistent entity objects.
|
PrimaryIndex<PK,E> |
The primary index for an entity class and its primary key.
|
SecondaryIndex<SK,PK,E> |
The secondary index for an entity class and a secondary key.
|
StoreConfig |
Configuration properties used with an
EntityStore or RawStore . |
StoreConfigBeanInfo |
Exception | Description |
---|---|
IndexNotAvailableException |
Thrown by the
getPrimaryIndex , getSecondaryIndex and getSubclassIndex when an index has not yet
been created. |
StoreExistsException |
Thrown by the
EntityStore constructor when the ExclusiveCreate configuration parameter is
true and the store's internal catalog database already exists. |
StoreNotFoundException |
Thrown by the
EntityStore constructor when the AllowCreate configuration parameter is false and
the store's internal catalog database does not exist. |
The Direct Persistence Layer (DPL) was designed to meet the following requirements.
PrimaryIndex<Long,Employer> employerById = ...; long employerId = ...; Employer employer = employerById.get(employerId);
private
,
package-private (default access), protected
, or public
. No
hand-coding of bindings is required. However, each persistent class must have
a default constructor. For example:
@Persistent class Address { String street; String city; String state; int zipCode; private Address() {} }
id
and the secondary key field name
:@Entity class Employer { @PrimaryKey(sequence="ID") long id; @SecondaryKey(relate=ONE_TO_ONE) String name; Address address; private Employer() {} }
java.util
collection. For example:
java.util.SortedMap<String,Employer> map = employerByName.sortedMap();
street2
field may be added to the
Address
class and the type of the zipCode
field may be changed
from int
to long
:
@Persistent class Address { String street; String street2; String city; String state; long zipCode; private Address() {} }Many incompatible class changes, such as renaming fields or refactoring a single class, can be performed using
Mutations
. Mutations are automatically
applied lazily as data is accessed, avoiding downtime to convert large
databases during a software upgrade.
Complex refactoring involving multiple classes may be performed using the a
store conversion. The DPL
always provides access to your data via a RawStore
, no matter what
changes have been made to persistent classes.
LockMode
parameter:
Employer employer = employerByName.get(null, "Gizmo Inc", LockMode.READ_UNCOMMITTED);For high performance applications,
DatabaseConfig
parameters may be used to tune the performance of the Berkeley
DB engine. For example, the size of an internal Btree node can be specified
as follows:
DatabaseConfig config = store.getPrimaryConfig(Employer.class); config.setNodeMaxEntries(64); store.setPrimaryConfig(config);
The DPL is intended for applications that represent persistent domain objects using Java classes. An entity class is an ordinary Java class that has a primary key and is stored and accessed using a primary index. It may also have any number of secondary keys, and entities may be accessed by secondary key using a secondary index.
An entity class may be defined with the Entity
annotation. For each entity class,
its primary key may be defined using the PrimaryKey
annotation and any number of
secondary keys may be defined using the SecondaryKey
annotation.
In the following example, the Person.ssn
(social security number)
field is the primary key and the Person.employerIds
field is a
many-to-many secondary key.
@Entity class Person { @PrimaryKey String ssn; String name; Address address; @SecondaryKey(relate=MANY_TO_MANY, relatedEntity=Employer.class) Set<Long> employerIds = new HashSet<Long>(); private Person() {} // For bindings }
A set of entity classes constitutes an entity model. In addition
to isolated entity classes, an entity model may contain relationships between
entities. Relationships may be defined using the SecondaryKey
annotation.
Many-to-one, one-to-many, many-to-many and one-to-one relationships are
supported, as well as foreign key constraints.
In the example above, a relationship between the Person
and Employer
entities is defined via the Person.employerIds
field. The
relatedEntity=Employer.class
annotation property establishes foreign
key constraints to guarantee that every element of the employerIds
set
is a valid Employer
primary key.
For more information on the entity model, see the AnnotationModel
and the Entity
annotation.
The root object in the DPL is the EntityStore
. An entity store manages any number of objects for each entity
class defined in the model. The store provides access to the primary and
secondary indices for each entity class, for example:
EntityStore store = new EntityStore(...); PrimaryIndex<String,Person> personBySsn = store.getPrimaryIndex(String.class, Person.class);
The following example shows how to define an entity model and how to store and access persistent objects. Exception handling is omitted for brevity.
import java.io.File; import java.util.HashSet; import java.util.Set; import com.sleepycat.je.DatabaseException; import com.sleepycat.je.Environment; import com.sleepycat.je.EnvironmentConfig; import com.sleepycat.persist.EntityCursor; import com.sleepycat.persist.EntityIndex; import com.sleepycat.persist.EntityStore; import com.sleepycat.persist.PrimaryIndex; import com.sleepycat.persist.SecondaryIndex; import com.sleepycat.persist.StoreConfig; import com.sleepycat.persist.model.Entity; import com.sleepycat.persist.model.Persistent; import com.sleepycat.persist.model.PrimaryKey; import com.sleepycat.persist.model.SecondaryKey; import static com.sleepycat.persist.model.DeleteAction.NULLIFY; import static com.sleepycat.persist.model.Relationship.ONE_TO_ONE; import static com.sleepycat.persist.model.Relationship.ONE_TO_MANY; import static com.sleepycat.persist.model.Relationship.MANY_TO_ONE; import static com.sleepycat.persist.model.Relationship.MANY_TO_MANY; // An entity class. // @Entity class Person { @PrimaryKey String ssn; String name; Address address; @SecondaryKey(relate=MANY_TO_ONE, relatedEntity=Person.class) String parentSsn; @SecondaryKey(relate=ONE_TO_MANY) Set<String> emailAddresses = new HashSet<String>();@SecondaryKey(relate=MANY_TO_MANY, relatedEntity=Employer.class, onRelatedEntityDelete=NULLIFY)
Set<Long> employerIds = new HashSet<Long>();
Person(String name, String ssn, String parentSsn) { this.name = name; this.ssn = ssn; this.parentSsn = parentSsn; } private Person() {} // For bindings } // Another entity class. // @Entity class Employer { @PrimaryKey(sequence="ID") long id; @SecondaryKey(relate=ONE_TO_ONE) String name; Address address; Employer(String name) { this.name = name; } private Employer() {} // For bindings } // A persistent class used in other classes. // @Persistent class Address { String street; String city; String state; int zipCode; private Address() {} // For bindings } // The data accessor class for the entity model. // class PersonAccessor { // Person accessors // PrimaryIndex<String,Person> personBySsn; SecondaryIndex<String,String,Person> personByParentSsn; SecondaryIndex<String,String,Person> personByEmailAddresses; SecondaryIndex<Long,String,Person> personByEmployerIds; // Employer accessors // PrimaryIndex<Long,Employer> employerById; SecondaryIndex<String,Long,Employer> employerByName; // Opens all primary and secondary indices. // public PersonAccessor(EntityStore store) throws DatabaseException { personBySsn = store.getPrimaryIndex( String.class, Person.class); personByParentSsn = store.getSecondaryIndex( personBySsn, String.class, "parentSsn"); personByEmailAddresses = store.getSecondaryIndex( personBySsn, String.class, "emailAddresses"); personByEmployerIds = store.getSecondaryIndex( personBySsn, Long.class, "employerIds"); employerById = store.getPrimaryIndex( Long.class, Employer.class); employerByName = store.getSecondaryIndex( employerById, String.class, "name"); } } // Open a transactional Berkeley DB engine environment. // EnvironmentConfig envConfig = new EnvironmentConfig(); envConfig.setAllowCreate(true); envConfig.setTransactional(true); Environment env = new Environment(new File("/my/data"), envConfig); // Open a transactional entity store. // StoreConfig storeConfig = new StoreConfig(); storeConfig.setAllowCreate(true); storeConfig.setTransactional(true); EntityStore store = new EntityStore(env, "PersonStore", storeConfig); // Initialize the data access object. // PersonAccessor dao = new PersonAccessor(store); // Add a parent and two children using the Person primary index. Specifying a // non-null parentSsn adds the child Person to the sub-index of children for // that parent key. // dao.personBySsn.put(new Person("Bob Smith", "111-11-1111", null)); dao.personBySsn.put(new Person("Mary Smith", "333-33-3333", "111-11-1111")); dao.personBySsn.put(new Person("Jack Smith", "222-22-2222", "111-11-1111")); // Print the children of a parent using a sub-index and a cursor. // EntityCursor<Person> children = dao.personByParentSsn.subIndex("111-11-1111").entities(); try { for (Person child : children) { System.out.println(child.ssn + ' ' + child.name); } } finally { children.close(); } // Get Bob by primary key using the primary index. // Person bob = dao.personBySsn.get("111-11-1111"); assert bob != null; // Create two employers. Their primary keys are assigned from a sequence. // Employer gizmoInc = new Employer("Gizmo Inc"); Employer gadgetInc = new Employer("Gadget Inc"); dao.employerById.put(gizmoInc); dao.employerById.put(gadgetInc); // Bob has two jobs and two email addresses. // bob.employerIds.add(gizmoInc.id); bob.employerIds.add(gadgetInc.id); bob.emailAddresses.add("bob@bob.com"); bob.emailAddresses.add("bob@gmail.com"); // Update Bob's record. // dao.personBySsn.put(bob); // Bob can now be found by both email addresses. // bob = dao.personByEmailAddresses.get("bob@bob.com"); assert bob != null; bob = dao.personByEmailAddresses.get("bob@gmail.com"); assert bob != null; // Bob can also be found as an employee of both employers. // EntityIndex<String,Person> employees; employees = dao.personByEmployerIds.subIndex(gizmoInc.id); assert employees.contains("111-11-1111"); employees = dao.personByEmployerIds.subIndex(gadgetInc.id); assert employees.contains("111-11-1111"); // When an employer is deleted, the onRelatedEntityDelete=NULLIFY for the // employerIds key causes the deleted ID to be removed from Bob's employerIds. // dao.employerById.delete(gizmoInc.id); bob = dao.personBySsn.get("111-11-1111"); assert !bob.employerIds.contains(gizmoInc.id); store.close(); env.close();
The example illustrates several characteristics of the DPL:
@Persistent public class ConstrainedValue { private int min; private int max; private int value; private ConstrainedValue() {} // For bindings public ConstrainedValue(int min, int max) { this.min = min; this.max = max; value = min; } public setValue(int value) { if (value < min || value > max) { throw new IllegalArgumentException("out of range"); } this.value = value; } }The above
setValue
method would not work if it were called during
object deserialization, since the order of setting fields is arbitrary. The
min
and max
fields may not be set before the value
is
set.
Explicit transactions may also be used to group multiple operations in a single transaction, and all access methods have optional transaction parameters. For example, the following two operations are performed atomically in a transaction:
Transaction txn = env.beginTransaction(null, null); dao.employerById.put(txn, gizmoInc); dao.employerById.put(txn, gadgetInc); txn.commit();
Queries are implemented by calling methods of the primary and secondary
indices. An EntityJoin
class is also
available for performing equality joins. For example, the following code
queries all of Bob's children that work for Gizmo Inc:
EntityJoin<String,Person> join = new EntityJoin(dao.personBySsn); join.addCondition(dao.personByParentSsn, "111-11-1111"); join.addCondition(dao.personByEmployerIds, gizmoInc.id); ForwardCursor<Person> results = join.entities(); try { for (Person person : results) { System.out.println(person.ssn + ' ' + person.name); } } finally { results.close(); }
Person
with a given
employer ID in its employerIds
set is stored, the Person
object
becomes part of the collection of employees for that employer. This collection
of employees is accessed using a SecondaryIndex.subIndex
for the
employer ID, as shown below:
EntityCursor<Person> employees = dao.personByEmployerIds.subIndex(gizmoInc.id).entities(); try { for (Person employee : employees) { System.out.println(employee.ssn + ' ' + employee.name); } } finally { employees.close(); }
Person
object for Bob is refetched to see the change to its employerIds
. This
is because objects are accessed by value, not by reference. In other words, no
object cache or "persistence context" is maintained by the DPL. The low level
caching of the embedded Berkeley DB engine, combined with lightweight object
bindings, provides maximum performance.The Berkeley DB engine has a Base API
, a Collections API
and a Direct Persistence Layer (DPL)
. Follow these guidelines if you are not sure
which API to use:
The DPL uses two features of Java 1.5: generic types and annotations. If you wish to avoid using these two Java 1.5 features, the DPL provides options for doing so.
Generic types are used to provide type safety, especially for the PrimaryIndex
, SecondaryIndex
, and EntityCursor
classes. If you don't wish to
use generic types, you can simply not declare your index and cursor objects
using generic type parameters. This is the same as using the Java 1.5
Collections Framework without using generic types.
If you don't wish to use annotations, you can provide another source of
metadata by implementing an EntityModel
class. For example, naming conventions, static members, or an XML
configuration file might be used as a source of metadata. However, if you
don't use annotations then you won't be able to use bytecode enhancement, which
is described next.
The persistent fields of a class may be private, package-private, protected or public. The DPL can access persistent fields either by bytecode enhancement or by reflection.
Bytecode enhancement may be used to fully optimize binding performance and to avoid the use of Java reflection. In applications that are CPU bound, avoiding Java reflection can have a significant performance impact.
Bytecode enhancement may be performed either at runtime or at build time (offline). When enhancement is performed at runtime, persistent classes are enhanced as they are loaded. When enhancement is performed offline, class files are enhanced during a post-compilation step. Both a main program and an Ant task are provided for performing offline enhancement. Enhanced classes are used to efficiently access all fields and default constructors, including non-public members.
See ClassEnhancer
for
bytecode enhancement configuration details.
If bytecode enhancement is not used as described above, the DPL will use
reflection for accessing persistent fields and the default constructor. The
AccessibleObject.setAccessible
method is called by the DPL to enable access to
non-public fields and constructors. If you are running under a Java security
manager you must configure your security policy to allow the following
permission:
permission java.lang.reflect.ReflectPermission "suppressAccessChecks";
There are three cases where setting the above permission is not required:
public
then
they can be accessed via reflection without special permissions, even when
running under a Java Security Manager. However, declaring public
instance fields is not recommended because it discourages encapsulation.It is well known that executing generated code is faster than reflection. However, this performance difference may or may not impact a given application since it may be overshadowed by other factors. Performance testing in a realistic usage scenario is the best way to determine the impact. If you are determined to avoid the use of reflection then option 3 above is recommended.
Copyright (c) 2002, 2017 Oracle and/or its affiliates. All rights reserved.