public interface EntityIndex<K,V>
EntityIndex
objects are thread-safe. Multiple threads may safely
call the methods of a shared EntityIndex
object.
An index is conceptually a map. {key:value} mappings are
stored in the index and accessed by key. In fact, for interoperability with
other libraries that use the standard Java Map
or SortedMap
interfaces, an EntityIndex
may be accessed via these standard
interfaces by calling the map()
or sortedMap()
methods.
EntityIndex
is an interface that is implemented by several
classes in this package for different purposes. Depending on the context,
the key type (K) and value type (V) of the index take on different meanings.
The different classes that implement EntityIndex
are:
PrimaryIndex
maps primary keys to entities.SecondaryIndex
maps secondary keys to entities.SecondaryIndex.keysIndex
maps secondary keys to primary
keys.SecondaryIndex.subIndex(SK)
maps primary keys to entities, for the
subset of entities having a specified secondary key.In all cases, the index key type (K) is a primary or secondary key class.
The index value type (V) is an entity class in all cases except for a SecondaryIndex.keysIndex
, when it is a primary key class.
In the following example, a Employee
entity with a MANY_TO_ONE
secondary key is defined.
@Entity class Employee { @PrimaryKey long id; @SecondaryKey(relate=MANY_TO_ONE) String department; String name; private Employee() {} }
Consider that we have stored the entities below:
Entities | ||
---|---|---|
ID | Department | Name |
1 | Engineering | Jane Smith |
2 | Sales | Joan Smith |
3 | Engineering | John Smith |
4 | Sales | Jim Smith |
PrimaryIndex
maps primary keys to entities:
PrimaryIndex<Long, Employee>
primaryIndex =
store.getPrimaryIndex(Long.class, Employee.class);
primaryIndex | |||
---|---|---|---|
Primary Key | Entity | ||
1 | 1 | Engineering | Jane Smith |
2 | 2 | Sales | Joan Smith |
3 | 3 | Engineering | John Smith |
4 | 4 | Sales | Jim Smith |
SecondaryIndex
maps secondary keys to entities:
SecondaryIndex<String, Long, Employee>
secondaryIndex =
store.getSecondaryIndex(primaryIndex, String.class, "department");
secondaryIndex | |||
---|---|---|---|
Secondary Key | Entity | ||
Engineering | 1 | Engineering | Jane Smith |
Engineering | 3 | Engineering | John Smith |
Sales | 2 | Sales | Joan Smith |
Sales | 4 | Sales | Jim Smith |
SecondaryIndex.keysIndex
maps secondary keys to primary
keys:
EntityIndex<String, Long>
keysIndex = secondaryIndex.keysIndex();
keysIndex | |||
---|---|---|---|
Secondary Key | Primary Key | ||
Engineering | 1 | ||
Engineering | 3 | ||
Sales | 2 | ||
Sales | 4 |
SecondaryIndex.subIndex(SK)
maps primary keys to entities, for the
subset of entities having a specified secondary key:
EntityIndex<Long, Entity>
subIndex = secondaryIndex.subIndex("Engineering");
subIndex | |||
---|---|---|---|
Primary Key | Entity | ||
1 | 1 | Engineering | Jane Smith |
3 | 3 | Engineering | John Smith |
An EntityIndex
provides a variety of methods for retrieving
entities from an index. It also provides methods for deleting entities.
However, it does not provide methods for inserting and updating. To insert
and update entities, use the PrimaryIndex.put(E)
family of methods in
the PrimaryIndex
class.
An EntityIndex
supports two mechanisms for retrieving
entities:
get(K)
method returns a single value for a given key. If there
are multiple values with the same secondary key (duplicates), it returns the
first entity in the duplicate set.EntityCursor
can be obtained using the keys()
and
entities()
family of methods. A cursor can be used to return all
values in the index, including duplicates. A cursor can also be used to
return values within a specified range of keys.Using the example entities above, calling get(K)
on the primary
index will always return the employee with the given ID, or null if no such
ID exists. But calling get(K)
on the secondary index will retrieve
the first employee in the given department, which may not be very
useful:
Employee emp = primaryIndex.get(1); // Returns by unique ID emp = secondaryIndex.get("Engineering"); // Returns first in department
Using a cursor, you can iterate through all duplicates in the secondary index:
EntityCursor<Employee>
cursor = secondaryIndex.entities();
try {
for (Employee entity : cursor) {
if (entity.department.equals("Engineering")) {
// Do something with the entity...
}
}
} finally {
cursor.close();
}
But for a large database it is much more efficient to iterate over only those entities with the secondary key you're searching for. This could be done by restricting a cursor to a range of keys:
EntityCursor<Employee>
cursor =
secondaryIndex.entities("Engineering", true, "Engineering", true);
try {
for (Employee entity : cursor) {
// Do something with the entity...
}
} finally {
cursor.close();
}
However, when you are interested only in the entities with a particular secondary key value, it is more convenient to use a sub-index:
EntityIndex<Long, Entity>
subIndex = secondaryIndex.subIndex("Engineering");EntityCursor<Employee>
cursor = subIndex.entities(); try { for (Employee entity : cursor) { // Do something with the entity... } } finally { cursor.close(); }
In addition to being more convenient than a cursor range, a sub-index allows retrieving by primary key:
Employee emp = subIndex.get(1);
When using a sub-index, all operations performed on the sub-index are restricted to the single key that was specified when the sub-index was created. For example, the following returns null because employee 2 is not in the Engineering department and therefore is not part of the sub-index:
Employee emp = subIndex.get(2);
For more information on using cursors and cursor ranges, see EntityCursor
.
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!
Any type of index may be used to delete entities with a specified key by
calling delete(K)
. The important thing to keep in mind is that
all entities with the specified key are deleted. In a primary index,
at most a single entity is deleted:
primaryIndex.delete(1); // Deletes a single employee by unique ID
But in a secondary index, multiple entities may be deleted:
secondaryIndex.delete("Engineering"); // Deletes all Engineering employees
This begs this question: How can a single entity be deleted without
knowing its primary key? The answer is to use cursors. After locating an
entity using a cursor, the entity can be deleted by calling EntityCursor.delete()
.
Transactions can be used to provide standard ACID (Atomicity, Consistency, Integrity and Durability) guarantees when retrieving, storing and deleting entities. This section provides a brief overview of how to use transactions with the Direct Persistence Layer. For more information on using transactions, see Writing Transactional Applications.
Transactions may be used only with a transactional EntityStore
,
which is one for which StoreConfig.setTransactional(true)
has been called. Likewise, a
transactional store may only be used with a transactional Environment
, which is one for which EnvironmentConfig.setTransactional(true)
has been called. For example:
EnvironmentConfig envConfig = new EnvironmentConfig(); envConfig.setTransactional(true); envConfig.setAllowCreate(true); Environment env = new Environment(new File("/my/data"), envConfig); StoreConfig storeConfig = new StoreConfig(); storeConfig.setTransactional(true); storeConfig.setAllowCreate(true); EntityStore store = new EntityStore(env, "myStore", storeConfig);
Transactions are represented by Transaction
objects, which are
part of the Base API
. Transactions are created
using the Environment.beginTransaction
method.
A transaction will include all operations for which the transaction
object is passed as a method argument. All retrieval, storage and deletion
methods have an optional Transaction
parameter for this purpose.
When a transaction is passed to a method that opens a cursor, all retrieval,
storage and deletion operations performed using that cursor will be included
in the transaction.
A transaction may be committed by calling Transaction.commit()
or
aborted by calling Transaction.abort()
. For example, two employees
may be deleted atomically with a transaction; other words, either both are
deleted or neither is deleted:
Transaction txn = env.beginTransaction(null, null); try { primaryIndex.delete(txn, 1); primaryIndex.delete(txn, 2); txn.commit(); txn = null; } finally { if (txn != null) { txn.abort(); } }
WARNING: Transactions must always be committed or aborted to
prevent resource leaks which could lead to the index becoming unusable or
cause an OutOfMemoryError
. To ensure that a transaction is
aborted in the face of exceptions, call Transaction.abort()
in a
finally block.
For a transactional store, storage and deletion operations are always transaction protected, whether or not a transaction is explicitly used. A null transaction argument means to perform the operation using auto-commit, or the implied thread transaction if an XAEnvironment is being used. A transaction is automatically started as part of the operation and is automatically committed if the operation completes successfully. The transaction is automatically aborted if an exception occurs during the operation, and the exception is re-thrown to the caller. For example, each employee is deleted using a an auto-commit transaction below, but it is possible that employee 1 will be deleted and employee 2 will not be deleted, if an error or crash occurs while deleting employee 2:
primaryIndex.delete(null, 1); primaryIndex.delete(null, 2);
When retrieving entities, a null transaction argument means to perform the operation non-transactionally. The operation is performed outside the scope of any transaction, without providing transactional ACID guarantees. If an implied thread transaction is present (i.e. if an XAEnvironment is being used), that transaction is used. When a non-transactional store is used, transactional ACID guarantees are also not provided.
For non-transactional and auto-commit usage, overloaded signatures for
retrieval, storage and deletion methods are provided to avoid having to pass
a null transaction argument. For example, delete(K)
may be called
instead of delete(Transaction,Object)
. For example, the following
code is equivalent to the code above where null was passed for the
transaction:
primaryIndex.delete(1); primaryIndex.delete(2);
For retrieval methods the overloaded signatures also include an optional
LockMode
parameter, and overloaded signatures for opening cursors
include an optional CursorConfig
parameter. These parameters are
described further below in the Locking and Lock Modes section.
There are two special consideration when using cursors with transactions.
First, for a transactional store, a non-null transaction must be passed to
methods that open a cursor if that cursor will be used to delete or update
entities. Cursors do not perform auto-commit when a null transaction is
explicitly passed or implied by the method signature. For example, the
following code will throw DatabaseException
when the EntityCursor.delete()
method is called:
// Does not work with a transactional store!
EntityCursor<Employee>
cursor = primaryIndex.entities();
try {
for (Employee entity : cursor) {
cursor.delete(); // Will throw DatabaseException.
}
} finally {
cursor.close();
}
Instead, the entities(Transaction,CursorConfig)
signature must
be used and a non-null transaction must be passed:
EntityCursor<Employee>
cursor = primaryIndex.entities(txn, null);
try {
for (Employee entity : cursor) {
cursor.delete();
}
} finally {
cursor.close();
}
The second consideration is that error handling is more complex when using both transactions and cursors, for the following reasons:
For example:
Transaction txn = env.beginTransaction(null, null);
EntityCursor<Employee>
cursor = null;
try {
cursor = primaryIndex.entities(txn, null);
for (Employee entity : cursor) {
cursor.delete();
}
cursor.close();
cursor = null;
txn.commit();
txn = null;
} finally {
if (cursor != null) {
cursor.close();
}
if (txn != null) {
txn.abort();
}
}
This section provides a brief overview of locking and describes how lock modes are used with the Direct Persistence Layer. For more information on locking, see Writing Transactional Applications.
When using transactions, locks are normally acquired on each entity that is retrieved or stored. The locks are used to isolate one transaction from another. Locks are normally released only when the transaction is committed or aborted.
When not using transactions, locks are also normally acquired on each entity that is retrieved or stored. However, these locks are released when the operation is complete. When using cursors, in order to provide cursor stability locks are held until the cursor is moved to a different entity or closed.
This default locking behavior provides full transactional ACID guarantees
and cursor stability. However, application performance can sometimes be
improved by compromising these guarantees. As described in Writing
Transactional Applications, the LockMode
and CursorConfig
parameters are two of the mechanisms that can be used to make
compromises.
For example, imagine that you need an approximate count of all entities
matching certain criterion, and it is acceptable for entities to be changed
by other threads or other transactions while performing this query. LockMode.READ_UNCOMMITTED
can be used to perform the retrievals without
acquiring any locks. This reduces memory consumption, does less processing,
and improves concurrency.
EntityCursor<Employee>
cursor = primaryIndex.entities(txn, null);
try {
Employee entity;
while ((entity = cursor.next(LockMode.READ_UNCOMMITTED)) != null) {
// Examine the entity and accumulate totals...
}
} finally {
cursor.close();
}
The LockMode
parameter specifies locking behavior on a
per-operation basis. If null or LockMode.DEFAULT
is specified, the
default lock mode is used.
It is also possible to specify the default locking behavior for a cursor
using CursorConfig
. The example below is equivalent to the example
above:
CursorConfig config = new CursorConfig();
config.setReadUncommitted(true);
EntityCursor<Employee>
cursor = primaryIndex.entities(txn, config);
try {
Employee entity;
while ((entity = cursor.next()) != null) {
// Examine the entity and accumulate totals...
}
} finally {
cursor.close();
}
Note that READ_UNCOMMITTED
can be used with a key cursor to
reduce I/O, potentially providing significant performance benefits. See Key Cursor Optimization with
READ_UNCOMMITTED
The use of other lock modes, cursor configuration, and transaction configuration are discussed in Writing Transactional Applications.
Lock conflict handling is another important topic discussed in Writing Transactional Applications. To go along with that material, here we show a lock conflict handling loop in the context of the Direct Persistence Layer. The example below shows deleting all entities in a primary index in a single transaction. If a lock conflict occurs, the transaction is aborted and the operation is retried.
This is a DPL version of the equivalent example code for the base API.
The following example code illustrates the recommended approach. Note
that the Environment.beginTransaction
and Transaction.commit
calls are intentially inside the try
block. When using JE-HA, this
will make it easy to add a catch
for other exceptions that can be
resolved by retrying the transaction, such as consistency exceptions.
void doTransaction(final Environment env, finalPrimaryIndex<Long, Employee>
primaryIndex, final int maxTries) throws DatabaseException { boolean success = false; long sleepMillis = 0; for (int i = 0; i < maxTries; i++) { // Sleep before retrying. if (sleepMillis != 0) { Thread.sleep(sleepMillis); sleepMillis = 0; } Transaction txn = null; try { txn = env.beginTransaction(null, null); finalEntityCursor<Employee>
cursor = primaryIndex.entities(txn, null); try { // INSERT APP-SPECIFIC CODE HERE: // Perform read and write operations, for example: for (Employee entity : cursor) { cursor.delete(); } } finally { cursor.close(); } txn.commit(); success = true; return; } catch (LockConflictException e) { sleepMillis = LOCK_CONFLICT_RETRY_SEC * 1000; continue; } finally { if (!success) { if (txn != null) { txn.abort(); } } } } // INSERT APP-SPECIFIC CODE HERE: // Transaction failed, despite retries. // Take some app-specific course of action. }
Each Direct Persistence Layer index is associated with an underlying
Database
or SecondaryDatabase
defined in the Base API
. At this level, an index is a Btree managed by
the Berkeley DB Java Edition transactional storage engine. Although you may
never need to work at the Base API
level, keep in mind that some
types of performance tuning can be done by configuring the underlying
databases. See the EntityStore
class for more information on
database and sequence configuration.
If you wish to access an index using the Base API
, you may call
the BasicIndex.getDatabase()
or SecondaryIndex.getDatabase()
method to get the underlying database. To translate between entity or key
objects and DatabaseEntry
objects at this level, use the bindings
returned by PrimaryIndex.getEntityBinding()
, PrimaryIndex.getKeyBinding()
, and SecondaryIndex.getKeyBinding()
.
Modifier and Type | Method and Description |
---|---|
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.
|
long |
count(long memoryLimit)
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.
|
OperationResult |
delete(Transaction txn,
K key,
WriteOptions options)
Deletes all entities with a given index key, using a WriteOptions
parameter and returning an OperationResult.
|
EntityCursor<V> |
entities()
Opens a cursor for traversing all entities in this index.
|
EntityCursor<V> |
entities(K fromKey,
boolean fromInclusive,
K toKey,
boolean toInclusive)
Opens a cursor for traversing entities in a key range.
|
EntityCursor<V> |
entities(Transaction txn,
CursorConfig config)
Opens a cursor for traversing all entities in this index.
|
EntityCursor<V> |
entities(Transaction txn,
K fromKey,
boolean fromInclusive,
K toKey,
boolean toInclusive,
CursorConfig config)
Opens a cursor for traversing entities in a key range.
|
V |
get(K key)
Gets an entity via a key of this index.
|
EntityResult<V> |
get(Transaction txn,
K key,
Get getType,
ReadOptions options)
Gets an entity via a key of this index, using Get type and ReadOptions
parameters, and returning an EntityResult.
|
V |
get(Transaction txn,
K key,
LockMode lockMode)
Gets an entity via a key of this index.
|
Database |
getDatabase()
Returns the underlying database for this 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.
|
java.util.Map<K,V> |
map()
Returns a standard Java map based on this entity index.
|
java.util.SortedMap<K,V> |
sortedMap()
Returns a standard Java sorted map based on this entity index.
|
Database getDatabase()
boolean contains(K key) throws DatabaseException
The operation will not be transaction protected, and LockMode.DEFAULT
is used implicitly.
READ_UNCOMMITTED
can be used with this method to reduce I/O,
since the record data item will not be read. This is the same benefit
as described in Key Cursor
Optimization with READ_UNCOMMITTED
key
- the key to search for.OperationFailureException
- if one of the Read Operation
Failures occurs.EnvironmentFailureException
- if an unexpected, internal or
environment-wide failure occurs.
DatabaseException
- the base class for all BDB exceptions.boolean contains(Transaction txn, K key, LockMode lockMode) throws DatabaseException
READ_UNCOMMITTED
can be used with this method to reduce I/O,
since the record data item will not be read. This is the same benefit
as described in Key Cursor
Optimization with READ_UNCOMMITTED
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
.OperationFailureException
- if one of the Read Operation
Failures occurs.EnvironmentFailureException
- if an unexpected, internal or
environment-wide failure occurs.
DatabaseException
- the base class for all BDB exceptions.V get(K key) throws DatabaseException
The operation will not be transaction protected, and LockMode.DEFAULT
is used implicitly.
key
- the key to search for.OperationFailureException
- if one of the Read Operation
Failures occurs.EnvironmentFailureException
- if an unexpected, internal or
environment-wide failure occurs.
DatabaseException
- the base class for all BDB exceptions.V get(Transaction txn, K key, LockMode lockMode) throws DatabaseException
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
.OperationFailureException
- if one of the Read Operation
Failures occurs.EnvironmentFailureException
- if an unexpected, internal or
environment-wide failure occurs.
DatabaseException
- the base class for all BDB exceptions.EntityResult<V> get(Transaction txn, K key, Get getType, ReadOptions options) throws DatabaseException
txn
- the transaction used to protect this operation, or null
if the operation should not be transaction protected.key
- the key to search for.getType
- must be Get.SEARCH
.options
- the ReadOptions, or null to use default options.OperationFailureException
- if one of the Read Operation
Failures occurs.EnvironmentFailureException
- if an unexpected, internal or
environment-wide failure occurs.DatabaseException
- the base class for all BDB exceptions.long count() throws DatabaseException
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.
This operation will disable deletion of log files by the JE log
cleaner during its execution and will consume a certain amount of
memory (but without affecting the memory that is available for the
JE cache). To avoid excessive memory consumption (and a potential
OutOfMemoryError
) this method places an internal limit on
its memory consumption. If this limit is reached, the method will
still work properly, but its performance will degrade. To specify
a different memory limit than the one used by this method, use the
count(long memoryLimit)
method.
OperationFailureException
- if one of the Read Operation
Failures occurs.EnvironmentFailureException
- if an unexpected, internal or
environment-wide failure occurs.
DatabaseException
- the base class for all BDB exceptions.long count(long memoryLimit) throws DatabaseException
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.
This operation will disable deletion of log files by the JE log
cleaner during its execution and will consume a certain amount of
memory (but without affecting the memory that is available for the
JE cache). To avoid excessive memory consumption (and a potential
OutOfMemoryError
) this method takes as input an upper bound
on the memory it may consume. If this limit is reached, the method
will still work properly, but its performance will degrade.
OperationFailureException
- if one of the Read Operation
Failures occurs.EnvironmentFailureException
- if an unexpected, internal or
environment-wide failure occurs.DatabaseException
- the base class for all BDB exceptions.boolean delete(K key) throws DatabaseException
Auto-commit is used implicitly if the store is transactional.
key
- the key to search for.OperationFailureException
- if one of the Write
Operation Failures occurs.EnvironmentFailureException
- if an unexpected, internal or
environment-wide failure occurs.
DatabaseException
- the base class for all BDB exceptions.boolean delete(Transaction txn, K key) throws DatabaseException
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.OperationFailureException
- if one of the Write
Operation Failures occurs.EnvironmentFailureException
- if an unexpected, internal or
environment-wide failure occurs.
DatabaseException
- the base class for all BDB exceptions.OperationResult delete(Transaction txn, K key, WriteOptions options) throws DatabaseException
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.options
- the WriteOptions, or null to use default options.OperationFailureException
- if one of the Write
Operation Failures occurs.EnvironmentFailureException
- if an unexpected, internal or
environment-wide failure occurs.DatabaseException
- the base class for all BDB exceptions.EntityCursor<K> keys() throws DatabaseException
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.
Note that READ_UNCOMMITTED
can be used with a key cursor to
reduce I/O, potentially providing significant performance benefits. See
Key Cursor Optimization with
READ_UNCOMMITTED
DatabaseException
- the base class for all BDB exceptions.EntityCursor<K> keys(Transaction txn, CursorConfig config) throws DatabaseException
Note that READ_UNCOMMITTED
can be used with a key cursor to
reduce I/O, potentially providing significant performance benefits. See
Key Cursor Optimization with
READ_UNCOMMITTED
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
.DatabaseException
- the base class for all BDB exceptions.EntityCursor<V> entities() throws DatabaseException
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.
DatabaseException
- the base class for all BDB exceptions.EntityCursor<V> entities(Transaction txn, CursorConfig config) throws DatabaseException
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
.DatabaseException
- the base class for all BDB exceptions.EntityCursor<K> keys(K fromKey, boolean fromInclusive, K toKey, boolean toInclusive) throws DatabaseException
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.
Note that READ_UNCOMMITTED
can be used with a key cursor to
reduce I/O, potentially providing significant performance benefits. See
Key Cursor Optimization with
READ_UNCOMMITTED
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.DatabaseException
- the base class for all BDB exceptions.EntityCursor<K> keys(Transaction txn, K fromKey, boolean fromInclusive, K toKey, boolean toInclusive, CursorConfig config) throws DatabaseException
Using a key cursor potentially has a large performance benefit when
the READ_UNCOMMITTED
isolation mode is used. In this case, if
the record data is not in the JE cache, it will not be read from disk.
The performance benefit is potentially large because random access disk
reads may be reduced. Examples are:
READ_UNCOMMITTED
isolation is acceptable.READ_UNCOMMITTED
isolation.For other isolation modes (READ_COMMITTED
, REPEATABLE_READ
and SERIALIZABLE
), the performance benefit of a
key cursor is not as significant. In this case, the data item must be
read into the JE cache if it is not already present, in order to lock
the record. The only performance benefit is that the data will not be
copied from the JE cache to the application's entry parameter, and will
not be unmarshalled into an entity object.
For information on specifying isolation modes, see LockMode
,
CursorConfig
and TransactionConfig
.
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
.DatabaseException
- the base class for all BDB exceptions.EntityCursor<V> entities(K fromKey, boolean fromInclusive, K toKey, boolean toInclusive) throws DatabaseException
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.
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.DatabaseException
- the base class for all BDB exceptions.EntityCursor<V> entities(Transaction txn, K fromKey, boolean fromInclusive, K toKey, boolean toInclusive, CursorConfig config) throws DatabaseException
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
.DatabaseException
- the base class for all BDB exceptions.java.util.Map<K,V> map()
StoredMap
returned is defined by the Collections API. Stored collections conform
to the standard Java collections framework interface.java.util.SortedMap<K,V> sortedMap()
StoredSortedMap
returned is defined by the Collections API. Stored collections conform
to the standard Java collections framework interface.Copyright (c) 2002, 2017 Oracle and/or its affiliates. All rights reserved.