Berkeley DB
version 5.3.28

com.sleepycat.persist
Class SecondaryIndex<SK,PK,E>

java.lang.Object
  extended by com.sleepycat.persist.SecondaryIndex<SK,PK,E>
All Implemented Interfaces:
EntityIndex<SK,E>

public class SecondaryIndex<SK,PK,E>
extends Object

The secondary index for an entity class and a secondary key.

SecondaryIndex objects are thread-safe. Multiple threads may safely call the methods of a shared SecondaryIndex object.

SecondaryIndex implements EntityIndex to map the secondary key type (SK) to the entity type (E). In other words, entities are accessed by secondary key values.

The SecondaryKey annotation may be used to define a secondary key as shown in the following example.

 @Entity
 class Employee {

     @PrimaryKey
     long id;

     @SecondaryKey(relate=MANY_TO_ONE)
     String department;

     String name;

     private Employee() {}
 }

Before obtaining a SecondaryIndex, the PrimaryIndex must be obtained for the entity class. To obtain the SecondaryIndex call EntityStore.getSecondaryIndex, passing the primary index, the secondary key class and the secondary key name. For example:

 EntityStore store = new EntityStore(...);

 PrimaryIndex<Long, Employee> primaryIndex =
     store.getPrimaryIndex(Long.class, Employee.class);

 SecondaryIndex<String, Long, Employee> secondaryIndex =
     store.getSecondaryIndex(primaryIndex, String.class, "department");

Since SecondaryIndex implements the EntityIndex interface, it shares the common index methods for retrieving and deleting entities, opening cursors and using transactions. See EntityIndex for more information on these topics.

SecondaryIndex does not provide methods for inserting and updating entities. That must be done using the PrimaryIndex.

Note that a SecondaryIndex has three type parameters <SK, PK, E> or in the example <String, Long, Employee> while a PrimaryIndex has only two type parameters <PK, E> or <Long, Employee>. This is because a SecondaryIndex has an extra level of mapping: It maps from secondary key to primary key, and then from primary key to entity. For example, consider this entity:

IDDepartmentName
1EngineeringJane Smith

The PrimaryIndex maps from id directly to the entity, or from primary key 1 to the "Jane Smith" entity in the example. The SecondaryIndex maps from department to id, or from secondary key "Engineering" to primary key 1 in the example, and then uses the PrimaryIndex to map from the primary key to the entity.

Because of this extra type parameter and extra level of mapping, a SecondaryIndex can provide more than one mapping, or view, of the entities in the primary index. The main mapping of a SecondaryIndex is to map from secondary key (SK) to entity (E), or in the example, from the String department key to the Employee entity. The SecondaryIndex itself, by implementing EntityIndex<SK, E>, provides this mapping.

The second mapping provided by SecondaryIndex is from secondary key (SK) to primary key (PK), or in the example, from the String department key to the Long id key. The keysIndex method provides this mapping. When accessing the keys index, the primary key is returned rather than the entity. When only the primary key is needed and not the entire entity, using the keys index is less expensive than using the secondary index because the primary index does not have to be accessed.

The third mapping provided by SecondaryIndex is from primary key (PK) to entity (E), for the subset of entities having a given secondary key (SK). This mapping is provided by the subIndex(SK) method. A sub-index is convenient when you are interested in working with the subset of entities having a particular secondary key value, for example, all employees in a given department.

All three mappings, along with the mapping provided by the PrimaryIndex, are shown using example data in the EntityIndex interface documentation. See EntityIndex for more information.

Note that when using an index, keys and values are stored and retrieved by value not by reference. In other words, if an entity object is stored and then retrieved, or retrieved twice, each object will be a separate instance. For example, in the code below the assertion will always fail.

 MyKey key = ...;
 MyEntity entity1 = index.get(key);
 MyEntity entity2 = index.get(key);
 assert entity1 == entity2; // always fails!
 

One-to-One Relationships

A ONE_TO_ONE relationship, although less common than other types of relationships, is the simplest type of relationship. A single entity is related to a single secondary key value. For example:

 @Entity
 class Employee {

     @PrimaryKey
     long id;

     @SecondaryKey(relate=ONE_TO_ONE)
     String ssn;

     String name;

     private Employee() {}
 }

 SecondaryIndex<String, Long, Employee> employeeBySsn =
     store.getSecondaryIndex(primaryIndex, String.class, "ssn");

With a ONE_TO_ONE relationship, the secondary key must be unique; in other words, no two entities may have the same secondary key value. If an attempt is made to store an entity having the same secondary key value as another existing entity, a DatabaseException will be thrown.

Because the secondary key is unique, it is useful to lookup entities by secondary key using EntityIndex.get(K). For example:

 Employee employee = employeeBySsn.get(mySsn);

Many-to-One Relationships

A MANY_TO_ONE relationship is the most common type of relationship. One or more entities is related to a single secondary key value. For example:

 @Entity
 class Employee {

     @PrimaryKey
     long id;

     @SecondaryKey(relate=MANY_TO_ONE)
     String department;

     String name;

     private Employee() {}
 }

 SecondaryIndex<String, Long, Employee> employeeByDepartment =
     store.getSecondaryIndex(primaryIndex, String.class, "department");

With a MANY_TO_ONE relationship, the secondary key is not required to be unique; in other words, more than one entity may have the same secondary key value. In this example, more than one employee may belong to the same department.

The most convenient way to access the employees in a given department is by using a sub-index. For example:

 EntityIndex<Long, Entity> subIndex = employeeByDepartment.subIndex(myDept);
 EntityCursor<Employee> cursor = subIndex.entities();
 try {
     for (Employee entity : cursor) {
         // Do something with the entity...
     }
 } finally {
     cursor.close();
 }

One-to-Many Relationships

In a ONE_TO_MANY relationship, a single entity is related to one or more secondary key values. For example:

 @Entity
 class Employee {

     @PrimaryKey
     long id;

     @SecondaryKey(relate=ONE_TO_MANY)
     Set<String> emailAddresses = new HashSet<String>;

     String name;

     private Employee() {}
 }

 SecondaryIndex<String, Long, Employee> employeeByEmail =
     store.getSecondaryIndex(primaryIndex, String.class, "emailAddresses");

With a ONE_TO_MANY relationship, the secondary key must be unique; in other words, no two entities may have the same secondary key value. In this example, no two employees may have the same email address. If an attempt is made to store an entity having the same secondary key value as another existing entity, a DatabaseException will be thrown.

Because the secondary key is unique, it is useful to lookup entities by secondary key using EntityIndex.get(K). For example:

 Employee employee = employeeByEmail.get(myEmailAddress);

The secondary key field for a ONE_TO_MANY relationship must be an array or collection type. To access the email addresses of an employee, simply access the collection field directly. For example:

 Employee employee = primaryIndex.get(1); // Get the entity by primary key
 employee.emailAddresses.add(myNewEmail); // Add an email address
 primaryIndex.putNoReturn(1, employee);   // Update the entity

Many-to-Many Relationships

In a MANY_TO_MANY relationship, one or more entities is related to one or more secondary key values. For example:

 @Entity
 class Employee {

     @PrimaryKey
     long id;

     @SecondaryKey(relate=MANY_TO_MANY)
     Set<String> organizations = new HashSet<String>;

     String name;

     private Employee() {}
 }

 SecondaryIndex<String, Long, Employee> employeeByOrganization =
     store.getSecondaryIndex(primaryIndex, String.class, "organizations");

With a MANY_TO_MANY relationship, the secondary key is not required to be unique; in other words, more than one entity may have the same secondary key value. In this example, more than one employee may belong to the same organization.

The most convenient way to access the employees in a given organization is by using a sub-index. For example:

 EntityIndex<Long, Entity> subIndex = employeeByOrganization.subIndex(myOrg);
 EntityCursor<Employee> cursor = subIndex.entities();
 try {
     for (Employee entity : cursor) {
         // Do something with the entity...
     }
 } finally {
     cursor.close();
 }

The secondary key field for a MANY_TO_MANY relationship must be an array or collection type. To access the organizations of an employee, simply access the collection field directly. For example:

 Employee employee = primaryIndex.get(1); // Get the entity by primary key
 employee.organizations.remove(myOldOrg); // Remove an organization
 primaryIndex.putNoReturn(1, employee);   // Update the entity

Foreign Key Constraints for Related Entities

In all the examples above the secondary key is treated only as a simple value, such as a String department field. In many cases, that is sufficient. But in other cases, you may wish to constrain the secondary keys of one entity class to be valid primary keys of another entity class. For example, a Department entity may also be defined:

 @Entity
 class Department {

     @PrimaryKey
     String name;

     String missionStatement;

     private Department() {}
 }

You may wish to constrain the department field values of the Employee class in the examples above to be valid primary keys of the Department entity class. In other words, you may wish to ensure that the department field of an Employee will always refer to a valid Department entity.

You can implement this constraint yourself by validating the department field before you store an Employee. For example:

 PrimaryIndex<String, Department> departmentIndex =
     store.getPrimaryIndex(String.class, Department.class);

 void storeEmployee(Employee employee) throws DatabaseException {
     if (departmentIndex.contains(employee.department)) {
         primaryIndex.putNoReturn(employee);
     } else {
         throw new IllegalArgumentException("Department does not exist: " +
                                            employee.department);
     }
 }

Or, instead you could define the Employee department field as a foreign key, and this validation will be done for you when you attempt to store the Employee entity. For example:

 @Entity
 class Employee {

     @PrimaryKey
     long id;

     @SecondaryKey(relate=MANY_TO_ONE, relatedEntity=Department.class)
     String department;

     String name;

     private Employee() {}
 }

The relatedEntity=Department.class above defines the department field as a foreign key that refers to a Department entity. Whenever a Employee entity is stored, its department field value will be checked to ensure that a Department entity exists with that value as its primary key. If no such Department entity exists, then a DatabaseException is thrown, causing the transaction to be aborted (assuming that transactions are used).

This begs the question: What happens when a Department entity is deleted while one or more Employee entities have department fields that refer to the deleted department's primary key? If the department were allowed to be deleted, the foreign key constraint for the Employee department field would be violated, because the Employee department field would refer to a department that does not exist.

By default, when this situation arises the system does not allow the department to be deleted. Instead, a DatabaseException is thrown, causing the transaction to be aborted. In this case, in order to delete a department, the department field of all Employee entities must first be updated to refer to a different existing department, or set to null. This is the responsibility of the application.

There are two additional ways of handling deletion of a Department entity. These alternatives are configured using the SecondaryKey.onRelatedEntityDelete() annotation property. Setting this property to DeleteAction.NULLIFY causes the Employee department field to be automatically set to null when the department they refer to is deleted. This may or may not be desirable, depending on application policies. For example:

 @Entity
 class Employee {

     @PrimaryKey
     long id;

     @SecondaryKey(relate=MANY_TO_ONE, relatedEntity=Department.class,
                                       onRelatedEntityDelete=NULLIFY)
     String department;

     String name;

     private Employee() {}
 }

The DeleteAction.CASCADE value, on the other hand, causes the Employee entities to be automatically deleted when the department they refer to is deleted. This is probably not desirable in this particular example, but is useful for parent-child relationships. For example:

 @Entity
 class Order {

     @PrimaryKey
     long id;

     String description;

     private Order() {}
 }

 @Entity
 class OrderItem {

     @PrimaryKey
     long id;

     @SecondaryKey(relate=MANY_TO_ONE, relatedEntity=Order.class,
                                       onRelatedEntityDelete=CASCADE)
     long orderId;

     String description;

     private OrderItem() {}
 }

The OrderItem orderId field refers to its "parent" Order entity. When an Order entity is deleted, it may be useful to automatically delete its "child" OrderItem entities.

For more information, see SecondaryKey.onRelatedEntityDelete().

One-to-Many versus Many-to-One for Related Entities

When there is a conceptual Many-to-One relationship such as Employee to Department as illustrated in the examples above, the relationship may be implemented either as Many-to-One in the Employee class or as One-to-Many in the Department class.

Here is the Many-to-One approach.

 @Entity
 class Employee {

     @PrimaryKey
     long id;

     @SecondaryKey(relate=MANY_TO_ONE, relatedEntity=Department.class)
     String department;

     String name;

     private Employee() {}
 }

 @Entity
 class Department {

     @PrimaryKey
     String name;

     String missionStatement;

     private Department() {}
 }

And here is the One-to-Many approach.

 @Entity
 class Employee {

     @PrimaryKey
     long id;

     String name;

     private Employee() {}
 }

 @Entity
 class Department {

     @PrimaryKey
     String name;

     String missionStatement;

     @SecondaryKey(relate=ONE_TO_MANY, relatedEntity=Employee.class)
     Set<Long> employees = new HashSet<Long>;

     private Department() {}
 }

Which approach is best? The Many-to-One approach better handles large number of entities on the to-Many side of the relationship because it doesn't store a collection of keys as an entity field. With Many-to-One a Btree is used to store the collection of keys and the Btree can easily handle very large numbers of keys. With One-to-Many, each time a related key is added or removed the entity on the One side of the relationship, along with the complete collection of related keys, must be updated. Therefore, if large numbers of keys may be stored per relationship, Many-to-One is recommended.

If the number of entities per relationship is not a concern, then you may wish to choose the approach that is most natural in your application data model. For example, if you think of a Department as containing employees and you wish to modify the Department object each time an employee is added or removed, then you may wish to store a collection of Employee keys in the Department object (One-to-Many).

Note that if you have a One-to-Many relationship and there is no related entity, then you don't have a choice -- you have to use One-to-Many because there is no entity on the to-Many side of the relationship where a Many-to-One key could be defined. An example is the Employee to email addresses relationship discussed above:

 @Entity
 class Employee {

     @PrimaryKey
     long id;

     @SecondaryKey(relate=ONE_TO_MANY)
     Set<String> emailAddresses = new HashSet<String>;

     String name;

     private Employee() {}
 }

For sake of argument imagine that each employee has thousands of email addresses and employees frequently add and remove email addresses. To avoid the potential performance problems associated with updating the Employee entity every time an email address is added or removed, you could create an EmployeeEmailAddress entity and use a Many-to-One relationship as shown below:

 @Entity
 class Employee {

     @PrimaryKey
     long id;

     String name;

     private Employee() {}
 }

 @Entity
 class EmployeeEmailAddress {

     @PrimaryKey
     String emailAddress;

     @SecondaryKey(relate=MANY_TO_ONE, relatedEntity=Employee.class)
     long employeeId;

     private EmployeeEmailAddress() {}
 }

Key Placement with Many-to-Many for Related Entities

As discussed in the section above, one drawback of a to-Many relationship (One-to-Many was discussed above and Many-to-Many is discussed here) is that it requires storing a collection of keys in an entity. Each time a key is added or removed, the containing entity must be updated. This has potential performance problems when there are large numbers of entities on the to-Many side of the relationship, in other words, when there are large numbers of keys in each secondary key field collection.

If you have a Many-to-Many relationship with a reasonably small number of entities on one side of the relationship and a large number of entities on the other side, you can avoid the potential performance problems by defining the secondary key field on the side with a small number of entities.

For example, in an Employee-to-Organization relationship, the number of organizations per employee will normally be reasonably small but the number of employees per organization may be very large. Therefore, to avoid potential performance problems, the secondary key field should be defined in the Employee class as shown below.

 @Entity
 class Employee {

     @PrimaryKey
     long id;

     @SecondaryKey(relate=MANY_TO_MANY, relatedEntity=Organization.class)
     Set<String> organizations = new HashSet<String>;

     String name;

     private Employee() {}
 }

 @Entity
 class Organization {

     @PrimaryKey
     String name;

     String description;
 }

If instead a Set<Long> members key had been defined in the Organization class, this set could potentially have a large number of elements and performance problems could result.

Many-to-Many Versus a Relationship Entity

If you have a Many-to-Many relationship with a large number of entities on both sides of the relationship, you can avoid the potential performance problems by using a relationship entity. A relationship entity defines the relationship between two other entities using two Many-to-One relationships.

Imagine a relationship between cars and trucks indicating whenever a particular truck was passed on the road by a particular car. A given car may pass a large number of trucks and a given truck may be passed by a large number of cars. First look at a Many-to-Many relationship between these two entities:

 @Entity
 class Car {

     @PrimaryKey
     String licenseNumber;

     @SecondaryKey(relate=MANY_TO_MANY, relatedEntity=Truck.class)
     Set<String> trucksPassed = new HashSet<String>;

     String color;

     private Car() {}
 }

 @Entity
 class Truck {

     @PrimaryKey
     String licenseNumber;

     int tons;

     private Truck() {}
 }

With the Many-to-Many approach above, the trucksPassed set could potentially have a large number of elements and performance problems could result.

To apply the relationship entity approach we define a new entity class named CarPassedTruck representing a single truck passed by a single car. We remove the secondary key from the Car class and use two secondary keys in the CarPassedTruck class instead.

 @Entity
 class Car {

     @PrimaryKey
     String licenseNumber;

     String color;

     private Car() {}
 }

 @Entity
 class Truck {

     @PrimaryKey
     String licenseNumber;

     int tons;

     private Truck() {}
 }

 @Entity
 class CarPassedTruck {

     @PrimaryKey
     long id;

     @SecondaryKey(relate=MANY_TO_ONE, relatedEntity=Car.class)
     String carLicense;

     @SecondaryKey(relate=MANY_TO_ONE, relatedEntity=Truck.class)
     String truckLicense;

     private CarPassedTruck() {}
 }

The CarPassedTruck entity can be used to access the relationship by car license or by truck license.

You may use the relationship entity approach because of the potential performance problems mentioned above. Or, you may choose to use this approach in order to store other information about the relationship. For example, if for each car that passes a truck you wish to record how much faster the car was going than the truck, then a relationship entity is the logical place to store that property. In the example below the speedDifference property is added to the CarPassedTruck class.

 @Entity
 class CarPassedTruck {

     @PrimaryKey
     long id;

     @SecondaryKey(relate=MANY_TO_ONE, relatedEntity=Car.class)
     String carLicense;

     @SecondaryKey(relate=MANY_TO_ONE, relatedEntity=Truck.class)
     String truckLicense;

     int speedDifference;

     private CarPassedTruck() {}
 }

Be aware that the relationship entity approach adds overhead compared to Many-to-Many. There is one additional entity and one additional secondary key. These factors should be weighed against its advantages and the relevant application access patterns should be considered.


Constructor Summary
SecondaryIndex(SecondaryDatabase database, Database keysDatabase, PrimaryIndex<PK,E> primaryIndex, Class<SK> secondaryKeyClass, EntryBinding<SK> secondaryKeyBinding)
          Creates a secondary index without using an EntityStore.
 
Method Summary
 boolean contains(K key)
          Checks for existence of a key in this index.
 boolean contains(Transaction txn, K key, LockMode lockMode)
          Checks for existence of a key in this index.
 long count()
          Returns a non-transactional count of the entities in this index.
 boolean delete(K key)
          Deletes all entities with a given index key.
 boolean delete(Transaction txn, K key)
          Deletes all entities with a given index key.
 EntityCursor<E> entities()
          Opens a cursor for traversing all entities in this index.
 EntityCursor<E> entities(K fromKey, boolean fromInclusive, K toKey, boolean toInclusive)
          Opens a cursor for traversing entities in a key range.
 EntityCursor<E> entities(Transaction txn, CursorConfig config)
          Opens a cursor for traversing all entities in this index.
 EntityCursor<E> entities(Transaction txn, K fromKey, boolean fromInclusive, K toKey, boolean toInclusive, CursorConfig config)
          Opens a cursor for traversing entities in a key range.
 E get(SK key)
          Gets an entity via a key of this index.
 E get(Transaction txn, SK key, LockMode lockMode)
          Gets an entity via a key of this index.
 SecondaryDatabase getDatabase()
          Returns the underlying secondary database for this index.
 EntryBinding<SK> getKeyBinding()
          Returns the secondary key binding for the index.
 Class<SK> getKeyClass()
          Returns the secondary key class for this index.
 Database getKeysDatabase()
          Returns the underlying secondary database that is not associated with the primary database and is used for the keysIndex.
 PrimaryIndex<PK,E> getPrimaryIndex()
          Returns the primary index associated with this secondary index.
 EntityCursor<K> keys()
          Opens a cursor for traversing all keys in this index.
 EntityCursor<K> keys(K fromKey, boolean fromInclusive, K toKey, boolean toInclusive)
          Opens a cursor for traversing keys in a key range.
 EntityCursor<K> keys(Transaction txn, CursorConfig config)
          Opens a cursor for traversing all keys in this index.
 EntityCursor<K> keys(Transaction txn, K fromKey, boolean fromInclusive, K toKey, boolean toInclusive, CursorConfig config)
          Opens a cursor for traversing keys in a key range.
 EntityIndex<SK,PK> keysIndex()
          Returns a read-only keys index that maps secondary key to primary key.
 Map<SK,E> map()
          Returns a standard Java map based on this entity index.
 SortedMap<SK,E> sortedMap()
          Returns a standard Java sorted map based on this entity index.
 EntityIndex<PK,E> subIndex(SK key)
          Returns an index that maps primary key to entity for the subset of entities having a given secondary key (duplicates).
 
Methods inherited from class java.lang.Object
clone, equals, finalize, getClass, hashCode, notify, notifyAll, toString, wait, wait, wait
 

Constructor Detail

SecondaryIndex

public SecondaryIndex(SecondaryDatabase database,
                      Database keysDatabase,
                      PrimaryIndex<PK,E> primaryIndex,
                      Class<SK> secondaryKeyClass,
                      EntryBinding<SK> secondaryKeyBinding)
               throws DatabaseException
Creates a secondary index without using an EntityStore. When using an EntityStore, call getSecondaryIndex instead.

This constructor is not normally needed and is provided for applications that wish to use custom bindings along with the Direct Persistence Layer. Normally, getSecondaryIndex is used instead.

Parameters:
database - the secondary database used for all access other than via a keysIndex.
keysDatabase - another handle on the secondary database, opened without association to the primary, and used only for access via a keysIndex. If this argument is null and the keysIndex method is called, then the keys database will be opened automatically; however, the user is then responsible for closing the keys database. To get the keys database in order to close it, call getKeysDatabase().
primaryIndex - the primary index associated with this secondary index.
secondaryKeyClass - the class of the secondary key.
secondaryKeyBinding - the binding to be used for secondary keys.
Throws:
DatabaseException - the base class for all BDB exceptions.
Method Detail

getDatabase

public SecondaryDatabase getDatabase()
Returns the underlying secondary database for this index.

Returns:
the secondary database.

getKeysDatabase

public Database getKeysDatabase()
Returns the underlying secondary database that is not associated with the primary database and is used for the keysIndex.

Returns:
the keys database.

getPrimaryIndex

public PrimaryIndex<PK,E> getPrimaryIndex()
Returns the primary index associated with this secondary index.

Returns:
the primary index.

getKeyClass

public Class<SK> getKeyClass()
Returns the secondary key class for this index.

Returns:
the class.

getKeyBinding

public EntryBinding<SK> getKeyBinding()
Returns the secondary key binding for the index.

Returns:
the key binding.

keysIndex

public EntityIndex<SK,PK> keysIndex()
                             throws DatabaseException
Returns a read-only keys index that maps secondary key to primary key. When accessing the keys index, the primary key is returned rather than the entity. When only the primary key is needed and not the entire entity, using the keys index is less expensive than using the secondary index because the primary index does not have to be accessed.

Note the following in the unusual case that you are not using an EntityStore: This method will open the keys database, a second database handle for the secondary database, if it is not already open. In this case, if you are not using an EntityStore, then you are responsible for closing the database returned by getKeysDatabase() before closing the environment. If you are using an EntityStore, the keys database will be closed automatically by EntityStore.close().

Returns:
the keys index.
Throws:
DatabaseException - the base class for all BDB exceptions.

subIndex

public EntityIndex<PK,E> subIndex(SK key)
                           throws DatabaseException
Returns an index that maps primary key to entity for the subset of entities having a given secondary key (duplicates). A sub-index is convenient when you are interested in working with the subset of entities having a particular secondary key value.

When using a MANY_TO_ONE or MANY_TO_MANY secondary key, the sub-index represents the left (MANY) side of a relationship.

Parameters:
key - the secondary key that identifies the entities in the sub-index.
Returns:
the sub-index.
Throws:
DatabaseException - the base class for all BDB exceptions.

get

public E get(SK key)
      throws DatabaseException
Description copied from interface: EntityIndex
Gets an entity via a key of this index.

The operation will not be transaction protected, and LockMode.DEFAULT is used implicitly.

Parameters:
key - the key to search for.
Returns:
the value mapped to the given key, or null if the key is not present in the index.
Throws:
DatabaseException - the base class for all BDB exceptions.

get

public E get(Transaction txn,
             SK key,
             LockMode lockMode)
      throws DatabaseException
Description copied from interface: EntityIndex
Gets an entity via a key of this index.

Parameters:
txn - the transaction used to protect this operation, or null if the operation should not be transaction protected.
key - the key to search for.
lockMode - the lock mode to use for this operation, or null to use LockMode.DEFAULT.
Returns:
the value mapped to the given key, or null if the key is not present in the index.
Throws:
DatabaseException - the base class for all BDB exceptions.

map

public Map<SK,E> map()
Description copied from interface: EntityIndex
Returns a standard Java map based on this entity index. The StoredMap returned is defined by the Collections API. Stored collections conform to the standard Java collections framework interface.

Returns:
the map.

sortedMap

public SortedMap<SK,E> sortedMap()
Description copied from interface: EntityIndex
Returns a standard Java sorted map based on this entity index. The StoredSortedMap returned is defined by the Collections API. Stored collections conform to the standard Java collections framework interface.

Returns:
the map.

contains

public boolean contains(K key)
                 throws DatabaseException
Description copied from interface: EntityIndex
Checks for existence of a key in this index.

The operation will not be transaction protected, and LockMode.DEFAULT is used implicitly.

Specified by:
contains in interface EntityIndex<K,E>
Parameters:
key - the key to search for.
Returns:
whether the key exists in the index.
Throws:
DatabaseException - the base class for all BDB exceptions.

contains

public boolean contains(Transaction txn,
                        K key,
                        LockMode lockMode)
                 throws DatabaseException
Description copied from interface: EntityIndex
Checks for existence of a key in this index.

Specified by:
contains in interface EntityIndex<K,E>
Parameters:
txn - the transaction used to protect this operation, or null if the operation should not be transaction protected.
key - the key to search for.
lockMode - the lock mode to use for this operation, or null to use LockMode.DEFAULT.
Returns:
whether the key exists in the index.
Throws:
DatabaseException - the base class for all BDB exceptions.

count

public long count()
           throws DatabaseException
Description copied from interface: EntityIndex
Returns a non-transactional count of the entities in this index.

This operation is faster than obtaining a count by scanning the index manually, and will not perturb the current contents of the cache. However, the count is not guaranteed to be accurate if there are concurrent updates. Note that this method does scan a significant portion of the index and should be considered a fairly expensive operation.

Specified by:
count in interface EntityIndex<K,E>
Returns:
the number of entities in this index.
Throws:
DatabaseException - the base class for all BDB exceptions.

delete

public boolean delete(K key)
               throws DatabaseException
Description copied from interface: EntityIndex
Deletes all entities with a given index key.

Auto-commit is used implicitly if the store is transactional.

Specified by:
delete in interface EntityIndex<K,E>
Parameters:
key - the key to search for.
Returns:
whether any entities were deleted.
Throws:
DatabaseException - the base class for all BDB exceptions.

delete

public boolean delete(Transaction txn,
                      K key)
               throws DatabaseException
Description copied from interface: EntityIndex
Deletes all entities with a given index key.

Specified by:
delete in interface EntityIndex<K,E>
Parameters:
txn - the transaction used to protect this operation, null to use auto-commit, or null if the store is non-transactional.
key - the key to search for.
Returns:
whether any entities were deleted.
Throws:
DatabaseException - the base class for all BDB exceptions.

keys

public EntityCursor<K> keys()
                     throws DatabaseException
Description copied from interface: EntityIndex
Opens a cursor for traversing all keys in this index.

The operations performed with the cursor will not be transaction protected, and CursorConfig.DEFAULT is used implicitly. If the store is transactional, the cursor may not be used to update or delete entities.

Specified by:
keys in interface EntityIndex<K,E>
Returns:
the cursor.
Throws:
DatabaseException - the base class for all BDB exceptions.

keys

public EntityCursor<K> keys(Transaction txn,
                            CursorConfig config)
                     throws DatabaseException
Description copied from interface: EntityIndex
Opens a cursor for traversing all keys in this index.

Specified by:
keys in interface EntityIndex<K,E>
Parameters:
txn - the transaction used to protect all operations performed with the cursor, or null if the operations should not be transaction protected. If the store is non-transactional, null must be specified. For a transactional store the transaction is optional for read-only access and required for read-write access.
config - the cursor configuration that determines the default lock mode used for all cursor operations, or null to implicitly use CursorConfig.DEFAULT.
Returns:
the cursor.
Throws:
DatabaseException - the base class for all BDB exceptions.

entities

public EntityCursor<E> entities()
                         throws DatabaseException
Description copied from interface: EntityIndex
Opens a cursor for traversing all entities in this index.

The operations performed with the cursor will not be transaction protected, and CursorConfig.DEFAULT is used implicitly. If the store is transactional, the cursor may not be used to update or delete entities.

Specified by:
entities in interface EntityIndex<K,E>
Returns:
the cursor.
Throws:
DatabaseException - the base class for all BDB exceptions.

entities

public EntityCursor<E> entities(Transaction txn,
                                CursorConfig config)
                         throws DatabaseException
Description copied from interface: EntityIndex
Opens a cursor for traversing all entities in this index.

Specified by:
entities in interface EntityIndex<K,E>
Parameters:
txn - the transaction used to protect all operations performed with the cursor, or null if the operations should not be transaction protected. If the store is non-transactional, null must be specified. For a transactional store the transaction is optional for read-only access and required for read-write access.
config - the cursor configuration that determines the default lock mode used for all cursor operations, or null to implicitly use CursorConfig.DEFAULT.
Returns:
the cursor.
Throws:
DatabaseException - the base class for all BDB exceptions.

keys

public EntityCursor<K> keys(K fromKey,
                            boolean fromInclusive,
                            K toKey,
                            boolean toInclusive)
                     throws DatabaseException
Description copied from interface: EntityIndex
Opens a cursor for traversing keys in a key range.

The operations performed with the cursor will not be transaction protected, and CursorConfig.DEFAULT is used implicitly. If the store is transactional, the cursor may not be used to update or delete entities.

Specified by:
keys in interface EntityIndex<K,E>
Parameters:
fromKey - is the lower bound of the key range, or null if the range has no lower bound.
fromInclusive - is true if keys greater than or equal to fromKey should be included in the key range, or false if only keys greater than fromKey should be included.
toKey - is the upper bound of the key range, or null if the range has no upper bound.
toInclusive - is true if keys less than or equal to toKey should be included in the key range, or false if only keys less than toKey should be included.
Returns:
the cursor.
Throws:
DatabaseException - the base class for all BDB exceptions.

keys

public EntityCursor<K> keys(Transaction txn,
                            K fromKey,
                            boolean fromInclusive,
                            K toKey,
                            boolean toInclusive,
                            CursorConfig config)
                     throws DatabaseException
Description copied from interface: EntityIndex
Opens a cursor for traversing keys in a key range.

Specified by:
keys in interface EntityIndex<K,E>
Parameters:
txn - the transaction used to protect all operations performed with the cursor, or null if the operations should not be transaction protected. If the store is non-transactional, null must be specified. For a transactional store the transaction is optional for read-only access and required for read-write access.
fromKey - is the lower bound of the key range, or null if the range has no lower bound.
fromInclusive - is true if keys greater than or equal to fromKey should be included in the key range, or false if only keys greater than fromKey should be included.
toKey - is the upper bound of the key range, or null if the range has no upper bound.
toInclusive - is true if keys less than or equal to toKey should be included in the key range, or false if only keys less than toKey should be included.
config - the cursor configuration that determines the default lock mode used for all cursor operations, or null to implicitly use CursorConfig.DEFAULT.
Returns:
the cursor.
Throws:
DatabaseException - the base class for all BDB exceptions.

entities

public EntityCursor<E> entities(K fromKey,
                                boolean fromInclusive,
                                K toKey,
                                boolean toInclusive)
                         throws DatabaseException
Description copied from interface: EntityIndex
Opens a cursor for traversing entities in a key range.

The operations performed with the cursor will not be transaction protected, and CursorConfig.DEFAULT is used implicitly. If the store is transactional, the cursor may not be used to update or delete entities.

Specified by:
entities in interface EntityIndex<K,E>
Parameters:
fromKey - is the lower bound of the key range, or null if the range has no lower bound.
fromInclusive - is true if keys greater than or equal to fromKey should be included in the key range, or false if only keys greater than fromKey should be included.
toKey - is the upper bound of the key range, or null if the range has no upper bound.
toInclusive - is true if keys less than or equal to toKey should be included in the key range, or false if only keys less than toKey should be included.
Returns:
the cursor.
Throws:
DatabaseException - the base class for all BDB exceptions.

entities

public EntityCursor<E> entities(Transaction txn,
                                K fromKey,
                                boolean fromInclusive,
                                K toKey,
                                boolean toInclusive,
                                CursorConfig config)
                         throws DatabaseException
Description copied from interface: EntityIndex
Opens a cursor for traversing entities in a key range.

Specified by:
entities in interface EntityIndex<K,E>
Parameters:
txn - the transaction used to protect all operations performed with the cursor, or null if the operations should not be transaction protected. If the store is non-transactional, null must be specified. For a transactional store the transaction is optional for read-only access and required for read-write access.
fromKey - is the lower bound of the key range, or null if the range has no lower bound.
fromInclusive - is true if keys greater than or equal to fromKey should be included in the key range, or false if only keys greater than fromKey should be included.
toKey - is the upper bound of the key range, or null if the range has no upper bound.
toInclusive - is true if keys less than or equal to toKey should be included in the key range, or false if only keys less than toKey should be included.
config - the cursor configuration that determines the default lock mode used for all cursor operations, or null to implicitly use CursorConfig.DEFAULT.
Returns:
the cursor.
Throws:
DatabaseException - the base class for all BDB exceptions.

Berkeley DB
version 5.3.28

Copyright (c) 1996, 2013 Oracle and/or its affiliates. All rights reserved.