K - the key type of map.V - the value type of map.public class MapProxyImpl<K,V> extends AbstractDistributedObject<MapService> implements EventJournalReader<EventJournalMapEvent<K,V>>
IMap interface.| Modifier and Type | Field and Description |
|---|---|
protected LocalMapStatsImpl |
localMapStats |
protected LockProxySupport |
lockSupport |
protected MapConfig |
mapConfig |
protected MapServiceContext |
mapServiceContext |
protected String |
name |
protected static String |
NULL_AGGREGATOR_IS_NOT_ALLOWED |
protected static String |
NULL_KEY_IS_NOT_ALLOWED |
protected static String |
NULL_KEYS_ARE_NOT_ALLOWED |
protected static String |
NULL_LISTENER_IS_NOT_ALLOWED |
protected static String |
NULL_PREDICATE_IS_NOT_ALLOWED |
protected static String |
NULL_PROJECTION_IS_NOT_ALLOWED |
protected static String |
NULL_VALUE_IS_NOT_ALLOWED |
protected MapOperationProvider |
operationProvider |
protected OperationService |
operationService |
protected IPartitionService |
partitionService |
protected PartitioningStrategy |
partitionStrategy |
protected SerializationService |
serializationService |
protected boolean |
statisticsEnabled |
protected Address |
thisAddress |
PARTITIONING_STRATEGY| Constructor and Description |
|---|
MapProxyImpl(String name,
MapService mapService,
NodeEngine nodeEngine,
MapConfig mapConfig) |
| Modifier and Type | Method and Description |
|---|---|
String |
addEntryListener(EntryListener listener,
boolean includeValue)
Adds an entry listener for this map.
|
String |
addEntryListener(EntryListener listener,
K key,
boolean includeValue)
Adds the specified entry listener for the specified key.
|
String |
addEntryListener(EntryListener listener,
Predicate<K,V> predicate,
boolean includeValue)
Adds an continuous entry listener for this map.
|
String |
addEntryListener(EntryListener listener,
Predicate<K,V> predicate,
K key,
boolean includeValue)
Adds an continuous entry listener for this map.
|
String |
addEntryListener(MapListener listener,
boolean includeValue)
Adds a
MapListener for this map. |
String |
addEntryListener(MapListener listener,
K key,
boolean includeValue)
Adds a
MapListener for this map. |
String |
addEntryListener(MapListener listener,
Predicate<K,V> predicate,
boolean includeValue)
Adds a
MapListener for this map. |
String |
addEntryListener(MapListener listener,
Predicate<K,V> predicate,
K key,
boolean includeValue)
Adds a
MapListener for this map. |
protected String |
addEntryListenerInternal(Object listener,
Data key,
boolean includeValue) |
protected String |
addEntryListenerInternal(Object listener,
Predicate predicate,
Data key,
boolean includeValue) |
void |
addIndex(String attribute,
boolean ordered)
Adds an index to this map for the specified entries so
that queries can run faster.
|
String |
addInterceptor(MapInterceptor interceptor)
Adds an interceptor for this map.
|
String |
addLocalEntryListener(EntryListener listener)
Adds a local entry listener for this map.
|
String |
addLocalEntryListener(EntryListener listener,
Predicate<K,V> predicate,
boolean includeValue)
Adds a local entry listener for this map.
|
String |
addLocalEntryListener(EntryListener listener,
Predicate<K,V> predicate,
K key,
boolean includeValue)
Adds a local entry listener for this map.
|
String |
addLocalEntryListener(MapListener listener)
Adds a
MapListener for this map. |
String |
addLocalEntryListener(MapListener listener,
Predicate<K,V> predicate,
boolean includeValue)
Adds a
MapListener for this map. |
String |
addLocalEntryListener(MapListener listener,
Predicate<K,V> predicate,
K key,
boolean includeValue)
Adds a local entry listener for this map.
|
String |
addLocalEntryListenerInternal(Object listener) |
String |
addLocalEntryListenerInternal(Object listener,
Predicate predicate,
Data key,
boolean includeValue) |
String |
addMapInterceptorInternal(MapInterceptor interceptor) |
String |
addPartitionLostListener(MapPartitionLostListener listener)
Adds a MapPartitionLostListener.
|
protected String |
addPartitionLostListenerInternal(MapPartitionLostListener listener) |
<R> R |
aggregate(Aggregator<Map.Entry<K,V>,R> aggregator)
Applies the aggregation logic on all map entries and returns the result
|
<R> R |
aggregate(Aggregator<Map.Entry<K,V>,R> aggregator,
Predicate<K,V> predicate)
Applies the aggregation logic on map entries filtered with the Predicated and returns the result
|
<SuppliedValue,Result> |
aggregate(Supplier<K,V,SuppliedValue> supplier,
Aggregation<K,SuppliedValue,Result> aggregation)
Executes a predefined aggregation on the maps data set.
|
<SuppliedValue,Result> |
aggregate(Supplier<K,V,SuppliedValue> supplier,
Aggregation<K,SuppliedValue,Result> aggregation,
JobTracker jobTracker)
Executes a predefined aggregation on the maps data set.
|
void |
clear()
This method clears the map and calls deleteAll on MapStore which if connected to a database,
will delete the records from that database.
|
void |
clearInternal() |
void |
clearMapOnly()
This method clears the map.
|
boolean |
containsKey(Object key)
Returns
true if this map contains an entry for the specified
key. |
protected boolean |
containsKeyInternal(Object key) |
boolean |
containsValue(Object value) |
boolean |
containsValueInternal(Data dataValue) |
protected Iterable<Data> |
convertToData(Iterable<K> keys) |
void |
delete(Object key)
Removes the mapping for a key from this map if it is present (optional operation).
|
protected void |
deleteInternal(Object key) |
Set<Map.Entry<K,V>> |
entrySet()
Returns a
Set clone of the mappings contained in this map. |
Set<Map.Entry<K,V>> |
entrySet(Predicate predicate)
Queries the map based on the specified predicate and returns the matching entries.
|
boolean |
evict(Object key)
Evicts the specified key from this map.
|
void |
evictAll()
Evicts all keys from this map except the locked ones.
|
protected void |
evictAllInternal() |
protected boolean |
evictInternal(Object key)
Evicts a key from a map.
|
Map<K,Object> |
executeOnEntries(EntryProcessor entryProcessor)
Applies the user defined EntryProcessor to the all entries in the map.
|
Map<K,Object> |
executeOnEntries(EntryProcessor entryProcessor,
Predicate predicate)
Applies the user defined EntryProcessor to the entries in the map which satisfies provided predicate.
|
void |
executeOnEntriesInternal(EntryProcessor entryProcessor,
Predicate predicate,
List<Data> result)
|
Object |
executeOnKey(K key,
EntryProcessor entryProcessor)
Applies the user defined EntryProcessor to the entry mapped by the key.
|
Data |
executeOnKeyInternal(Object key,
EntryProcessor entryProcessor) |
InternalCompletableFuture<Object> |
executeOnKeyInternal(Object key,
EntryProcessor entryProcessor,
ExecutionCallback<Object> callback) |
Map<K,Object> |
executeOnKeys(Set<K> keys,
EntryProcessor entryProcessor)
Applies the user defined EntryProcessor to the entries mapped by the collection of keys.
|
Map<K,Object> |
executeOnKeysInternal(Set<K> keys,
Set<Data> dataKeys,
EntryProcessor entryProcessor) |
protected void |
finalizePutAll(Map<?,?> map) |
void |
flush()
If this map has a MapStore, this method flushes
all the local dirty entries by calling MapStore.storeAll() and/or MapStore.deleteAll().
|
void |
forceUnlock(K key)
Releases the lock for the specified key regardless of the lock owner.
|
V |
get(Object key)
Returns the value for the specified key, or
null if this map does not contain this key. |
Map<K,V> |
getAll(Set<K> keys)
Returns the entries for the given keys.
|
protected void |
getAllInternal(Set<K> keys,
List<Data> dataKeys,
List<Object> resultingKeyValuePairs) |
ICompletableFuture<V> |
getAsync(K key)
Asynchronously gets the given key.
|
protected InternalCompletableFuture<Data> |
getAsyncInternal(Object key) |
EntryView<K,V> |
getEntryView(K key)
Returns the
EntryView for the specified key. |
protected EntryView |
getEntryViewInternal(Data key) |
protected Object |
getInternal(Object key) |
LocalMapStats |
getLocalMapStats()
Returns LocalMapStats for this map.
|
protected MapQueryEngine |
getMapQueryEngine() |
String |
getName()
Returns the unique name for this DistributedObject.
|
MapOperationProvider |
getOperationProvider() |
PartitioningStrategy |
getPartitionStrategy() |
QueryCache<K,V> |
getQueryCache(String name)
Returns corresponding
QueryCache instance for the supplied name or null. |
QueryCache<K,V> |
getQueryCache(String name,
MapListener listener,
Predicate<K,V> predicate,
boolean includeValue)
Creates an always up to date snapshot of this
IMap according to the supplied parameters. |
QueryCache<K,V> |
getQueryCache(String name,
Predicate<K,V> predicate,
boolean includeValue)
Creates an always up to date snapshot of this
IMap according to the supplied parameters. |
String |
getServiceName()
Returns the service name for this object.
|
int |
getTotalBackupCount() |
void |
initialize() |
protected Object |
invoke(Operation operation,
int partitionId) |
protected void |
invokePutAllOperationFactory(long size,
int[] partitions,
MapEntries[] entries) |
boolean |
isEmpty()
Returns true if this map contains no entries.
|
boolean |
isLocked(K key)
Checks the lock for the specified key.
|
protected boolean |
isMapStoreEnabled() |
Iterator<Map.Entry<K,V>> |
iterator(int fetchSize,
int partitionId,
boolean prefetchValues)
Returns an iterator for iterating entries in the
partitionId. |
<R> Iterator<R> |
iterator(int fetchSize,
int partitionId,
Projection<Map.Entry<K,V>,R> projection,
Predicate<K,V> predicate)
Returns an iterator for iterating the result of the projection on entries in the
partitionId which
satisfy the predicate. |
Set<K> |
keySet()
Returns a set clone of the keys contained in this map.
|
Set<K> |
keySet(Predicate predicate)
Queries the map based on the specified predicate and
returns the keys of matching entries.
|
void |
loadAll(boolean replaceExistingValues)
Loads all keys into the store.
|
void |
loadAll(Set<K> keys,
boolean replaceExistingValues)
Loads the given keys.
|
protected void |
loadAllInternal(boolean replaceExistingValues) |
protected void |
loadInternal(Set<K> keys,
Iterable<Data> dataKeys,
boolean replaceExistingValues)
Maps keys to corresponding partitions and sends operations to them.
|
Set<K> |
localKeySet()
Returns the locally owned set of keys.
|
Set<K> |
localKeySet(Predicate predicate)
Returns the keys of matching locally owned entries.
|
void |
lock(K key)
Acquires the lock for the specified key.
|
void |
lock(Object key,
long leaseTime,
TimeUnit timeUnit)
Acquires the lock for the specified key for the specified lease time.
|
protected boolean |
preDestroy() |
<R> Collection<R> |
project(Projection<Map.Entry<K,V>,R> projection)
Applies the projection logic on all map entries and returns the result
|
<R> Collection<R> |
project(Projection<Map.Entry<K,V>,R> projection,
Predicate<K,V> predicate)
Applies the projection logic on map entries filtered with the Predicated and returns the result
|
V |
put(K key,
V value)
Associates the specified value with the specified key in this map.
|
V |
put(K key,
V value,
long ttl,
TimeUnit timeunit)
Puts an entry into this map with a given TTL (time to live) value.
|
void |
putAll(Map<? extends K,? extends V> map) |
protected void |
putAllInternal(Map<?,?> map)
This method will group all puts per partition and send a
PutAllPartitionAwareOperationFactory per member. |
ICompletableFuture<V> |
putAsync(K key,
V value)
Asynchronously puts the given key and value.
|
ICompletableFuture<V> |
putAsync(K key,
V value,
long ttl,
TimeUnit timeunit)
Asynchronously puts the given key and value into this map with a given TTL (time to live) value.
|
protected InternalCompletableFuture<Data> |
putAsyncInternal(Object key,
Data value,
long ttl,
TimeUnit timeunit) |
V |
putIfAbsent(K key,
V value)
If the specified key is not already associated
with a value, associate it with the given value.
|
V |
putIfAbsent(K key,
V value,
long ttl,
TimeUnit timeunit)
Puts an entry into this map with a given TTL (time to live) value,
if the specified key is not already associated with a value.
|
protected Data |
putIfAbsentInternal(Object key,
Data value,
long ttl,
TimeUnit timeunit) |
protected Data |
putInternal(Object key,
Data value,
long ttl,
TimeUnit timeunit) |
void |
putTransient(K key,
V value,
long ttl,
TimeUnit timeunit)
Same as
#put(K, V, long, java.util.concurrent.TimeUnit) except that the MapStore, if defined,
will not be called to store/persist the entry. |
protected void |
putTransientInternal(Object key,
Data value,
long ttl,
TimeUnit timeunit) |
<T> ICompletableFuture<ReadResultSet<T>> |
readFromEventJournal(long startSequence,
int minSize,
int maxSize,
int partitionId,
Predicate<? super EventJournalMapEvent<K,V>> predicate,
Projection<? super EventJournalMapEvent<K,V>,T> projection)
Reads from the event journal.
|
V |
remove(Object key)
Removes the mapping for a key from this map if it is present.
|
boolean |
remove(Object key,
Object value)
Removes the entry for a key only if currently mapped to a given value.
|
void |
removeAll(Predicate<K,V> predicate)
Removes all entries which match with the supplied predicate.
|
protected void |
removeAllInternal(Predicate predicate) |
ICompletableFuture<V> |
removeAsync(K key)
Asynchronously removes the given key, returning an
ICompletableFuture on which
the caller can provide an ExecutionCallback to be invoked upon remove operation
completion or block waiting for the operation to complete with Future.get(). |
protected InternalCompletableFuture<Data> |
removeAsyncInternal(Object key) |
boolean |
removeEntryListener(String id)
Removes the specified entry listener.
|
protected boolean |
removeEntryListenerInternal(String id) |
void |
removeInterceptor(String id)
Removes the given interceptor for this map, so it will not intercept operations anymore.
|
protected Data |
removeInternal(Object key) |
protected boolean |
removeInternal(Object key,
Data value) |
void |
removeMapInterceptorInternal(String id) |
boolean |
removePartitionLostListener(String id)
Removes the specified map partition lost listener.
|
protected boolean |
removePartitionLostListenerInternal(String id) |
V |
replace(K key,
V value)
Replaces the entry for a key only if it is currently mapped to some value.
|
boolean |
replace(K key,
V oldValue,
V newValue)
Replaces the entry for a key only if currently mapped to a given value.
|
protected Data |
replaceInternal(Object key,
Data value) |
protected boolean |
replaceInternal(Object key,
Data expect,
Data update) |
void |
set(K key,
V value)
Puts an entry into this map without returning the old value
(which is more efficient than
put()). |
void |
set(K key,
V value,
long ttl,
TimeUnit timeunit)
Puts an entry into this map with a given TTL (time to live) value,
without returning the old value (which is more efficient than
put()). |
ICompletableFuture<Void> |
setAsync(K key,
V value)
Asynchronously puts the given key and value.
|
ICompletableFuture<Void> |
setAsync(K key,
V value,
long ttl,
TimeUnit timeunit)
Asynchronously puts an entry into this map with a given TTL (time to live) value,
without returning the old value (which is more efficient than
put()). |
protected InternalCompletableFuture<Data> |
setAsyncInternal(Object key,
Data value,
long ttl,
TimeUnit timeunit) |
protected void |
setInternal(Object key,
Data value,
long ttl,
TimeUnit timeunit) |
void |
setOperationProvider(MapOperationProvider operationProvider) |
int |
size()
Returns the number of entries in this map.
|
ICompletableFuture |
submitToKey(K key,
EntryProcessor entryProcessor)
Applies the user defined EntryProcessor to the entry mapped by the key.
|
void |
submitToKey(K key,
EntryProcessor entryProcessor,
ExecutionCallback callback)
Applies the user defined EntryProcessor to the entry mapped by the key with
specified ExecutionCallback to listen event status and returns immediately.
|
ICompletableFuture<EventJournalInitialSubscriberState> |
subscribeToEventJournal(int partitionId)
Subscribe to the event journal for this reader and a specific partition ID.
|
protected Data |
toData(Object object,
PartitioningStrategy partitioningStrategy) |
protected void |
toDataCollectionWithNonNullKeyValidation(Set<K> keys,
Collection<Data> dataKeys) |
protected Data |
toDataWithStrategy(Object object) |
protected <T> T |
toObject(Object object) |
String |
toString() |
boolean |
tryLock(K key)
Tries to acquire the lock for the specified key.
|
boolean |
tryLock(K key,
long time,
TimeUnit timeunit)
Tries to acquire the lock for the specified key.
|
boolean |
tryLock(K key,
long time,
TimeUnit timeunit,
long leaseTime,
TimeUnit leaseTimeUnit)
Tries to acquire the lock for the specified key for the specified lease time.
|
boolean |
tryPut(K key,
V value,
long timeout,
TimeUnit timeunit)
Tries to put the given key and value into this map within a specified
timeout value.
|
protected boolean |
tryPutInternal(Object key,
Data value,
long timeout,
TimeUnit timeunit) |
boolean |
tryRemove(K key,
long timeout,
TimeUnit timeunit)
Tries to remove the entry with the given key from this map
within the specified timeout value.
|
protected boolean |
tryRemoveInternal(Object key,
long timeout,
TimeUnit timeunit) |
void |
unlock(K key)
Releases the lock for the specified key.
|
Collection<V> |
values()
Returns a collection clone of the values contained in this map.
|
Collection<V> |
values(Predicate predicate)
Queries the map based on the specified predicate and returns the values of matching entries.
|
void |
waitUntilLoaded() |
destroy, equals, getDistributedObjectName, getNameAsPartitionAwareData, getNodeEngine, getOperationService, getPartitionId, getPartitionKey, getService, hashCode, invalidate, invokeOnPartition, postDestroy, throwNotActiveException, toDataclone, finalize, getClass, notify, notifyAll, wait, wait, waitcompute, computeIfAbsent, computeIfPresent, forEach, getOrDefault, merge, replaceAlldestroy, getPartitionKeyprotected static final String NULL_KEY_IS_NOT_ALLOWED
protected static final String NULL_KEYS_ARE_NOT_ALLOWED
protected static final String NULL_VALUE_IS_NOT_ALLOWED
protected static final String NULL_PREDICATE_IS_NOT_ALLOWED
protected static final String NULL_LISTENER_IS_NOT_ALLOWED
protected static final String NULL_AGGREGATOR_IS_NOT_ALLOWED
protected static final String NULL_PROJECTION_IS_NOT_ALLOWED
protected final String name
protected final LocalMapStatsImpl localMapStats
protected final LockProxySupport lockSupport
protected final PartitioningStrategy partitionStrategy
protected final MapServiceContext mapServiceContext
protected final IPartitionService partitionService
protected final Address thisAddress
protected final OperationService operationService
protected final SerializationService serializationService
protected final boolean statisticsEnabled
protected final MapConfig mapConfig
protected MapOperationProvider operationProvider
public MapProxyImpl(String name, MapService mapService, NodeEngine nodeEngine, MapConfig mapConfig)
public V get(Object key)
IMapnull if this map does not contain this key.
Warning 1:
This method returns a clone of the original value, so modifying the returned value does not change the actual value in the map. You should put the modified value back to make changes visible to all nodes.
V value = map.get(key);
value.updateSomeProperty();
map.put(key, value);
Warning 2:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
public V put(K key, V value)
IMapWarning 1:
This method returns a clone of the previous value, not the original (identically equal) value previously put into the map.
Warning 2:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
Warning 3:
If you have previously set a TTL for the key, the TTL remains unchanged and the entry will expire when the initial TTL has elapsed.
public V put(K key, V value, long ttl, TimeUnit timeunit)
IMapThe entry will expire and get evicted after the TTL. If the TTL is 0, then the entry lives forever. If the TTL is negative, then the TTL from the map configuration will be used (default: forever).
Warning 1:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
Warning 2:
This method returns a clone of the previous value, not the original (identically equal) value previously put into the map.
Warning 3:
Time resolution for TTL is seconds. The given TTL value is rounded to the next closest second value.
put in interface BaseMap<K,V>put in interface IMap<K,V>key - key of the entryvalue - value of the entryttl - maximum time for this entry to stay in the map (0 means infinite, negative means map config default)timeunit - time unit for the TTLpublic boolean tryPut(K key, V value, long timeout, TimeUnit timeunit)
IMapWarning 1:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
Warning 2:
If you have previously set a TTL for the key, the TTL remains unchanged and the entry will expire when the initial TTL has elapsed.
public V putIfAbsent(K key, V value)
IMap
if (!map.containsKey(key))
return map.put(key, value);
else
return map.get(key);
except that the action is performed atomically.
Note:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
Also, this method returns a clone of the previous value, not the original (identically equal) value previously put into the map.
putIfAbsent in interface BaseMap<K,V>putIfAbsent in interface IMap<K,V>putIfAbsent in interface ConcurrentMap<K,V>putIfAbsent in interface Map<K,V>key - The specified key.value - The value to associate with the key when there is no previous value.public V putIfAbsent(K key, V value, long ttl, TimeUnit timeunit)
IMapThe entry will expire and get evicted after the TTL. If the TTL is 0, then the entry lives forever. If the TTL is negative, then the TTL from the map configuration will be used (default: forever).
Warning 1:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
Warning 2:
This method returns a clone of the previous value, not the original (identically equal) value previously put into the map.
Warning 3:
Time resolution for TTL is seconds. The given TTL value is rounded to the next closest second value.
putIfAbsent in interface IMap<K,V>key - key of the entryvalue - value of the entryttl - maximum time for this entry to stay in the map (0 means infinite, negative means map config default)timeunit - time unit for the TTLpublic void putTransient(K key, V value, long ttl, TimeUnit timeunit)
IMap#put(K, V, long, java.util.concurrent.TimeUnit) except that the MapStore, if defined,
will not be called to store/persist the entry.
The entry will expire and get evicted after the TTL. If the TTL is 0, then the entry lives forever. If the TTL is negative, then the TTL from the map configuration will be used (default: forever).
Warning 1:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
Warning 2:
Time resolution for TTL is seconds. The given TTL value is rounded to next closest second value.
putTransient in interface IMap<K,V>key - key of the entryvalue - value of the entryttl - maximum time for this entry to stay in the map (0 means infinite, negative means map config default)timeunit - time unit for the TTLpublic boolean replace(K key, V oldValue, V newValue)
IMap
if (map.containsKey(key) && map.get(key).equals(oldValue)) {
map.put(key, newValue);
return true;
} else return false;
except that the action is performed atomically.
Warning:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
replace in interface BaseMap<K,V>replace in interface IMap<K,V>replace in interface ConcurrentMap<K,V>replace in interface Map<K,V>key - The specified key.oldValue - Replace the key value if it is the old value.newValue - The new value to replace the old value.true if the value was replaced.public V replace(K key, V value)
IMap
if (map.containsKey(key)) {
return map.put(key, value);
} else return null;
except that the action is performed atomically.
Warning 1:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
Warning 2:
This method returns a clone of the previous value, not the original (identically equal) value previously put into the map.
Warning 3:
If you have previously set a TTL for the key, the same TTL will be again set on the new value.
replace in interface BaseMap<K,V>replace in interface IMap<K,V>replace in interface ConcurrentMap<K,V>replace in interface Map<K,V>key - The specified key.value - The value to replace the previous value.key, or null
if there was no mapping for key.public void set(K key, V value)
IMapput()).
Warning 1:
This method breaks the contract of EntryListener. When an entry is updated by set(), it fires an EntryEvent with a null oldValue.
Warning 2:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
Warning 3:
If you have previously set a TTL for the key, the TTL remains unchanged and the entry will expire when the initial TTL has elapsed.
public void set(K key, V value, long ttl, TimeUnit timeunit)
IMapput()).
The entry will expire and get evicted after the TTL. If the TTL is 0, then the entry lives forever. If the TTL is negative, then the TTL from the map configuration will be used (default: forever).
Warning 1:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
Warning 2:
Time resolution for TTL is seconds. The given TTL value is rounded to the next closest second value.
public V remove(Object key)
IMapThe map will not contain a mapping for the specified key once the call returns.
Warning 1:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
This method returns a clone of the previous value, not the original (identically equal) value previously put into the map.
public boolean remove(Object key, Object value)
IMap
if (map.containsKey(key) && map.get(key).equals(value)) {
map.remove(key);
return true;
} else return false;
except that the action is performed atomically.
Warning:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
remove in interface BaseMap<K,V>remove in interface IMap<K,V>remove in interface ConcurrentMap<K,V>remove in interface Map<K,V>key - The specified key.value - Remove the key if it has this value.true if the value was removed.public void removeAll(Predicate<K,V> predicate)
IMapIf this map has index, matching entries will be found via index search, otherwise they will be found by full-scan.
Note that calling this method also removes all entries from callers Near Cache.
public void delete(Object key)
IMap
Unlike IMap.remove(Object), this operation does not return
the removed value, which avoids the serialization cost of the returned value.
If the removed value will not be used, a delete operation is preferred over a remove operation for better performance.
The map will not contain a mapping for the specified key once the call returns.
Warning:
This method breaks the contract of EntryListener. When an entry is removed by delete(), it fires an EntryEvent with a null oldValue.
Also, a listener with predicates will have null values, so only keys can be queried via predicates.
public boolean containsKey(Object key)
IMaptrue if this map contains an entry for the specified
key.
Warning:
This method uses hashCode and equals of the binary form of the key,
not the actual implementations of hashCode and equals defined in the key's class.
The key will first be searched for in memory. If the key is not found, and if a key is attributed,
a MapLoader will then attempt to load the key.
containsKey in interface BaseMap<K,V>containsKey in interface IMap<K,V>containsKey in interface Map<K,V>key - The specified key.true if this map contains an entry for the specified key.public boolean containsValue(Object value)
IMapcontainsValue in interface IMap<K,V>containsValue in interface Map<K,V>public void lock(K key)
IMapIf the lock is not available, then the current thread becomes disabled for thread scheduling purposes and lies dormant until the lock has been acquired.
You get a lock whether the value is present in the map or not. Other
threads (possibly on other systems) would block on their invoke of
lock() until the non-existent key is unlocked. If the lock
holder introduces the key to the map, the put() operation
is not blocked. If a thread not holding a lock on the non-existent key
tries to introduce the key while a lock exists on the non-existent key,
the put() operation blocks until it is unlocked.
Scope of the lock is this map only. Acquired lock is only for the key in this map.
Locks are re-entrant so if the key is locked N times then it should be unlocked N times before another thread can acquire it.
There is no lock timeout on this method. Locks will be held infinitely.
Warning:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
public void lock(Object key, long leaseTime, TimeUnit timeUnit)
IMapAfter lease time, the lock will be released.
If the lock is not available, then the current thread becomes disabled for thread scheduling purposes and lies dormant until the lock has been acquired.
Scope of the lock is this map only. Acquired lock is only for the key in this map.
Locks are re-entrant, so if the key is locked N times then it should be unlocked N times before another thread can acquire it.
Warning:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
public void unlock(K key)
IMap
If the current thread is the holder of this lock, then the hold
count is decremented. If the hold count is zero, then the lock
is released. If the current thread is not the holder of this
lock, then IllegalMonitorStateException is thrown.
Warning:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
public boolean tryRemove(K key, long timeout, TimeUnit timeunit)
IMapWarning:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
public ICompletableFuture<V> getAsync(K key)
IMapICompletableFuture future = map.getAsync(key); // do some other stuff, when ready get the result. Object value = future.get();
Future.get() will block until the actual map.get() completes.
If the application requires timely response,
then Future.get(long, TimeUnit) can be used.
try {
ICompletableFuture future = map.getAsync(key);
Object value = future.get(40, TimeUnit.MILLISECOND);
} catch (TimeoutException t) {
// time wasn't enough
}
Additionally, the client can schedule an ExecutionCallback to be invoked upon
completion of the ICompletableFuture via
ICompletableFuture.andThen(ExecutionCallback) or
ICompletableFuture.andThen(ExecutionCallback, Executor):
// assuming a IMap<String, String>
ICompletableFuture<String> future = map.getAsync("a");
future.andThen(new ExecutionCallback<String>() {
public void onResponse(String response) {
// do something with value in response
}
public void onFailure(Throwable t) {
// handle failure
}
});
ExecutionException is never thrown.
Warning:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
getAsync in interface IMap<K,V>getAsync in interface LegacyAsyncMap<K,V>key - the key of the map entryICompletableFuturepublic boolean isLocked(K key)
IMapIf the lock is acquired then returns true, else returns false.
Warning:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
public ICompletableFuture<V> putAsync(K key, V value)
IMapICompletableFuture future = map.putAsync(key, value); // do some other stuff, when ready get the result. Object oldValue = future.get();ICompletableFuture.get() will block until the actual map.put() completes. If the application requires a timely response, then you can use Future.get(timeout, timeunit).
try {
ICompletableFuture future = map.putAsync(key, newValue);
Object oldValue = future.get(40, TimeUnit.MILLISECOND);
} catch (TimeoutException t) {
// time wasn't enough
}
Additionally, the client can schedule an ExecutionCallback to be invoked upon
completion of the ICompletableFuture via ICompletableFuture.andThen(ExecutionCallback) or
ICompletableFuture.andThen(ExecutionCallback, Executor):
// assuming a IMap<String, String>
ICompletableFuture<String> future = map.putAsync("a", "b");
future.andThen(new ExecutionCallback<String>() {
public void onResponse(String response) {
// do something with the old value returned by put operation
}
public void onFailure(Throwable t) {
// handle failure
}
});
ExecutionException is never thrown.
Warning 1:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
Warning 2:
If you have previously set a TTL for the key, the TTL remains unchanged and the entry will expire when the initial TTL has elapsed.
putAsync in interface IMap<K,V>putAsync in interface LegacyAsyncMap<K,V>key - the key of the map entryvalue - the new value of the map entryICompletableFuturepublic ICompletableFuture<V> putAsync(K key, V value, long ttl, TimeUnit timeunit)
IMapThe entry will expire and get evicted after the TTL. If the TTL is 0, then the entry lives forever. If the TTL is negative, then the TTL from the map configuration will be used (default: forever).
ICompletableFuture future = map.putAsync(key, value, ttl, timeunit); // do some other stuff, when ready get the result Object oldValue = future.get();ICompletableFuture.get() will block until the actual map.put() completes. If your application requires a timely response, then you can use Future.get(timeout, timeunit).
try {
ICompletableFuture future = map.putAsync(key, newValue, ttl, timeunit);
Object oldValue = future.get(40, TimeUnit.MILLISECOND);
} catch (TimeoutException t) {
// time wasn't enough
}
The client can schedule an ExecutionCallback to be invoked upon
completion of the ICompletableFuture via ICompletableFuture.andThen(ExecutionCallback) or
ICompletableFuture.andThen(ExecutionCallback, Executor):
// assuming a IMap<String, String>
ICompletableFuture<String> future = map.putAsync("a", "b", 5, TimeUnit.MINUTES);
future.andThen(new ExecutionCallback<String>() {
public void onResponse(String response) {
// do something with old value returned by put operation
}
public void onFailure(Throwable t) {
// handle failure
}
});
ExecutionException is never thrown.
Warning 1:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
Warning 2:
Time resolution for TTL is seconds. The given TTL value is rounded to the next closest second value.
putAsync in interface IMap<K,V>putAsync in interface LegacyAsyncMap<K,V>key - the key of the map entryvalue - the new value of the map entryttl - maximum time for this entry to stay in the map (0 means infinite, negative means map config default)timeunit - time unit for the TTLICompletableFuturepublic ICompletableFuture<Void> setAsync(K key, V value)
IMapICompletableFuture<Void> future = map.setAsync(key, value); // do some other stuff, when ready wait for completion future.get();ICompletableFuture.get() will block until the actual map.set() operation completes. If your application requires a timely response, then you can use ICompletableFuture.get(timeout, timeunit).
try {
ICompletableFuture<Void> future = map.setAsync(key, newValue);
future.get(40, TimeUnit.MILLISECOND);
} catch (TimeoutException t) {
// time wasn't enough
}
You can also schedule an ExecutionCallback to be invoked upon
completion of the ICompletableFuture via ICompletableFuture.andThen(ExecutionCallback) or
ICompletableFuture.andThen(ExecutionCallback, Executor):
ICompletableFuture<Void> future = map.setAsync("a", "b");
future.andThen(new ExecutionCallback<String>() {
public void onResponse(Void response) {
// Set operation was completed
}
public void onFailure(Throwable t) {
// handle failure
}
});
ExecutionException is never thrown.
Warning 1:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
Warning 2:
If you have previously set a TTL for the key, the TTL remains unchanged and the entry will expire when the initial TTL has elapsed.
setAsync in interface IMap<K,V>setAsync in interface LegacyAsyncMap<K,V>key - the key of the map entryvalue - the new value of the map entryExecutionCallback to be invoked upon completionICompletableFuturepublic ICompletableFuture<Void> setAsync(K key, V value, long ttl, TimeUnit timeunit)
IMapput()).
The entry will expire and get evicted after the TTL. If the TTL is 0, then the entry lives forever. If the TTL is negative, then the TTL from the map configuration will be used (default: forever).
ICompletableFuture<Void> future = map.setAsync(key, value, ttl, timeunit); // do some other stuff, when you want to make sure set operation is complete: future.get();ICompletableFuture.get() will block until the actual map set operation completes. If your application requires a timely response, then you can use
Future.get(long, TimeUnit).
try {
ICompletableFuture future = map.setAsync(key, newValue, ttl, timeunit);
future.get(40, TimeUnit.MILLISECOND);
} catch (TimeoutException t) {
// time wasn't enough
}
You can also schedule an ExecutionCallback to be invoked upon
completion of the ICompletableFuture via ICompletableFuture.andThen(ExecutionCallback) or
ICompletableFuture.andThen(ExecutionCallback, Executor):
ICompletableFuture<Void> future = map.setAsync("a", "b", 5, TimeUnit.MINUTES);
future.andThen(new ExecutionCallback<String>() {
public void onResponse(Void response) {
// Set operation was completed
}
public void onFailure(Throwable t) {
// handle failure
}
});
ExecutionException is never thrown.
Warning 1:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
Warning 2:
Time resolution for TTL is seconds. The given TTL value is rounded to the next closest second value.
setAsync in interface IMap<K,V>setAsync in interface LegacyAsyncMap<K,V>key - the key of the map entryvalue - the new value of the map entryttl - maximum time for this entry to stay in the map (0 means infinite, negative means map config default)timeunit - time unit for the TTLExecutionCallback to be invoked upon set operation completionICompletableFuturepublic ICompletableFuture<V> removeAsync(K key)
IMapICompletableFuture on which
the caller can provide an ExecutionCallback to be invoked upon remove operation
completion or block waiting for the operation to complete with Future.get().
Warning:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
removeAsync in interface IMap<K,V>removeAsync in interface LegacyAsyncMap<K,V>key - The key of the map entry to removeICompletableFuture from which the value removed from the map can be retrievedICompletableFuturepublic Map<K,V> getAll(Set<K> keys)
IMapMapLoader.loadAll(java.util.Collection).
Warning 1:
The returned map is NOT backed by the original map, so changes to the original map are NOT reflected in the returned map, and vice-versa.
Warning 2:
This method uses hashCode and equals of the binary form of
the keys, not the actual implementations of hashCode and equals
defined in the key's class.
public void putAll(Map<? extends K,? extends V> map)
IMapNo atomicity guarantees are given. It could be that in case of failure some of the key/value-pairs get written, while others are not.
Warning:
If you have previously set a TTL for the key, the TTL remains unchanged and the entry will expire when the initial TTL has elapsed.
public boolean tryLock(K key)
IMapIf the lock is not available then the current thread doesn't wait and returns false immediately.
Warning:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
public boolean tryLock(K key, long time, TimeUnit timeunit) throws InterruptedException
IMapIf the lock is not available, then the current thread becomes disabled for thread scheduling purposes and lies dormant until one of two things happens:
Warning:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
tryLock in interface IMap<K,V>key - key to lock in this maptime - maximum time to wait for the locktimeunit - time unit of the time argumenttrue if the lock was acquired, false if the waiting time elapsed before the lock was acquiredInterruptedExceptionpublic boolean tryLock(K key, long time, TimeUnit timeunit, long leaseTime, TimeUnit leaseTimeUnit) throws InterruptedException
IMapAfter lease time, the lock will be released.
If the lock is not available, then the current thread becomes disabled for thread scheduling purposes and lies dormant until one of two things happens:
Warning:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
tryLock in interface IMap<K,V>key - key to lock in this maptime - maximum time to wait for the locktimeunit - time unit of the time argumentleaseTime - time to wait before releasing the lockleaseTimeUnit - unit of time to specify lease timetrue if the lock was acquired, false if the waiting time elapsed before the lock was acquiredInterruptedExceptionpublic void forceUnlock(K key)
IMapWarning:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
forceUnlock in interface IMap<K,V>key - the key to lockpublic String addInterceptor(MapInterceptor interceptor)
IMapAdded interceptor will intercept operations and execute user defined methods. They will cancel operations if the user defined method throws an exception.
addInterceptor in interface IMap<K,V>interceptor - map interceptorpublic void removeInterceptor(String id)
IMapremoveInterceptor in interface IMap<K,V>id - registration ID of the map interceptorpublic String addLocalEntryListener(MapListener listener)
IMapMapListener for this map. To receive an event, you should
implement a corresponding MapListener sub-interface for that event.
Note that entries in distributed map are partitioned across
the cluster members; each member owns and manages the some portion of the
entries. Owned entries are called local entries. This
listener will be listening for the events of local entries. Let's say
your cluster has member1 and member2. On member2 you added a local listener and from
member1, you call map.put(key2, value2).
If the key2 is owned by member2 then the local listener will be
notified for the add/update event. Also note that entries can migrate to
other nodes for load balancing and/or membership change.
addLocalEntryListener in interface IMap<K,V>listener - MapListener for this mapIMap.localKeySet(),
MapListenerpublic String addLocalEntryListener(EntryListener listener)
IMap
Note that entries in distributed map are partitioned across
the cluster members; each member owns and manages the some portion of the
entries. Owned entries are called local entries. This
listener will be listening for the events of local entries. Let's say
your cluster has member1 and member2. On member2 you added a local listener and from
member1, you call map.put(key2, value2).
If the key2 is owned by member2 then the local listener will be
notified for the add/update event. Also note that entries can migrate to
other nodes for load balancing and/or membership change.
addLocalEntryListener in interface IMap<K,V>listener - entry listenerIMap.localKeySet()public String addLocalEntryListener(MapListener listener, Predicate<K,V> predicate, boolean includeValue)
IMapMapListener for this map.
To receive an event, you should implement a corresponding MapListener sub-interface for that event.
The listener will get notified for map events filtered by the given predicate.
addLocalEntryListener in interface IMap<K,V>listener - MapListener for this mappredicate - predicate for filtering entriesincludeValue - true if EntryEvent should contain the valueMapListenerpublic String addLocalEntryListener(EntryListener listener, Predicate<K,V> predicate, boolean includeValue)
IMapThe added listener will only be listening for the events (add/remove/update/evict) of the locally owned entries. The listener will get notified for map add/remove/update/evict events filtered by the given predicate.
addLocalEntryListener in interface IMap<K,V>listener - entry listenerpredicate - predicate for filtering entriesincludeValue - true if EntryEvent should contain the valuepublic String addLocalEntryListener(MapListener listener, Predicate<K,V> predicate, K key, boolean includeValue)
IMapThe added listener will only be listening for the events (add/remove/update/evict) of the locally owned entries. The listener will get notified for map add/remove/update/evict events filtered by the given predicate.
addLocalEntryListener in interface IMap<K,V>listener - MapListener for this mappredicate - predicate for filtering entrieskey - key to listen forincludeValue - true if EntryEvent should contain the valueMapListenerpublic String addLocalEntryListener(EntryListener listener, Predicate<K,V> predicate, K key, boolean includeValue)
IMapThe added listener will only be listening for the events (add/remove/update/evict) of the locally owned entries. The listener will get notified for map add/remove/update/evict events filtered by the given predicate.
addLocalEntryListener in interface IMap<K,V>listener - entry listenerpredicate - predicate for filtering entrieskey - key to listen foincludeValue - true if EntryEvent should contain the valuepublic String addEntryListener(MapListener listener, boolean includeValue)
IMapMapListener for this map.
To receive an event, you should implement a corresponding MapListener sub-interface for that event.
addEntryListener in interface IMap<K,V>listener - MapListener for this mapincludeValue - true if EntryEvent should contain the valueMapListenerpublic String addEntryListener(EntryListener listener, boolean includeValue)
IMapThe listener will get notified for all map add/remove/update/evict events.
addEntryListener in interface IMap<K,V>listener - the added entry listener for this mapincludeValue - true if EntryEvent should contain the valuepublic String addEntryListener(MapListener listener, K key, boolean includeValue)
IMapMapListener for this map. To receive an event, you should
implement a corresponding MapListener sub-interface for that event.
Warning:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
addEntryListener in interface IMap<K,V>listener - MapListener for this mapkey - key to listen forincludeValue - true if EntryEvent should contain the valueMapListenerpublic String addEntryListener(EntryListener listener, K key, boolean includeValue)
IMapThe listener will get notified for all add/remove/update/evict events of the specified key only.
Warning:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
addEntryListener in interface IMap<K,V>listener - specified entry listenerkey - key to listen forincludeValue - true if EntryEvent should contain the valuepublic String addEntryListener(MapListener listener, Predicate<K,V> predicate, K key, boolean includeValue)
IMapMapListener for this map.
To receive an event, you should implement a corresponding MapListener sub-interface for that event.
addEntryListener in interface IMap<K,V>listener - the continuous MapListener for this mappredicate - predicate for filtering entrieskey - key to listen forincludeValue - true if EntryEvent should contain the valueMapListenerpublic String addEntryListener(EntryListener listener, Predicate<K,V> predicate, K key, boolean includeValue)
IMapThe listener will get notified for map add/remove/update/evict events filtered by the given predicate.
addEntryListener in interface IMap<K,V>listener - the continuous entry listener for this mappredicate - predicate for filtering entrieskey - key to listen forincludeValue - true if EntryEvent should contain the valuepublic String addEntryListener(MapListener listener, Predicate<K,V> predicate, boolean includeValue)
IMapMapListener for this map.
To receive an event, you should implement a corresponding MapListener sub-interface for that event.
addEntryListener in interface IMap<K,V>listener - the added continuous MapListener for this mappredicate - predicate for filtering entriesincludeValue - true if EntryEvent should contain the valueMapListenerpublic String addEntryListener(EntryListener listener, Predicate<K,V> predicate, boolean includeValue)
IMapThe listener will get notified for map add/remove/update/evict events filtered by the given predicate.
addEntryListener in interface IMap<K,V>listener - the added continuous entry listener for this mappredicate - predicate for filtering entriesincludeValue - true if EntryEvent should contain the valuepublic boolean removeEntryListener(String id)
IMapReturns silently if there is no such listener added before.
removeEntryListener in interface IMap<K,V>id - ID of registered listenerpublic String addPartitionLostListener(MapPartitionLostListener listener)
IMap
The addPartitionLostListener returns a register ID. This ID is needed to remove the MapPartitionLostListener using the
IMap.removePartitionLostListener(String) method.
There is no check for duplicate registrations, so if you register the listener twice, it will get events twice.
Warning 1:
Please see PartitionLostListener for weaknesses.
Warning 2:
Listeners registered from HazelcastClient may miss some of the map partition lost events due to design limitations.
addPartitionLostListener in interface IMap<K,V>listener - the added MapPartitionLostListenerIMap.removePartitionLostListener(String),
PartitionLostListenerpublic boolean removePartitionLostListener(String id)
IMapReturns silently if there is no such listener was added before.
removePartitionLostListener in interface IMap<K,V>id - ID of registered listenerpublic EntryView<K,V> getEntryView(K key)
IMapEntryView for the specified key.
Warning 1:
This method returns a clone of original mapping, modifying the returned value does not change the actual value in the map. One should put modified value back to make changes visible to all nodes.
Warning 2:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
getEntryView in interface IMap<K,V>key - the key of the entryEntryView of the specified keyEntryViewpublic boolean evict(Object key)
IMap
If a MapStore is defined for this map, then the entry is not
deleted from the underlying MapStore, evict only removes
the entry from the memory.
Warning:
This method uses hashCode and equals of the binary form of
the key, not the actual implementations of hashCode and equals
defined in the key's class.
public void evictAll()
IMap
If a MapStore is defined for this map, deleteAll is not called by this method.
If you do want to deleteAll to be called use the IMap.clear() method.
The EVICT_ALL event is fired for any registered listeners.
See MapEvictedListener.mapEvicted(MapEvent) .
evictAll in interface IMap<K,V>IMap.clear()public void loadAll(boolean replaceExistingValues)
IMappublic void loadAll(Set<K> keys, boolean replaceExistingValues)
IMappublic void clear()
If you wish to clear the map only without calling deleteAll, use #clearMapOnly.
public void clearMapOnly()
clear()public Set<K> keySet()
IMapWarning:
The set is NOT backed by the map, so changes to the map are NOT reflected in the set, and vice-versa.
This method is always executed by a distributed query,
so it may throw a QueryResultSizeExceededException
if GroupProperty.QUERY_RESULT_SIZE_LIMIT is configured.
public Set<K> keySet(Predicate predicate)
IMapSpecified predicate runs on all members in parallel.
Warning:
The set is NOT backed by the map, so changes to the map are NOT reflected in the set, and vice-versa.
This method is always executed by a distributed query,
so it may throw a QueryResultSizeExceededException
if GroupProperty.QUERY_RESULT_SIZE_LIMIT is configured.
public Set<Map.Entry<K,V>> entrySet()
IMapSet clone of the mappings contained in this map.
Warning:
The set is NOT backed by the map, so changes to the map are NOT reflected in the set, and vice-versa.
This method is always executed by a distributed query,
so it may throw a QueryResultSizeExceededException
if GroupProperty.QUERY_RESULT_SIZE_LIMIT is configured.
public Set<Map.Entry<K,V>> entrySet(Predicate predicate)
IMapSpecified predicate runs on all members in parallel.
Warning:
The set is NOT backed by the map, so changes to the map are NOT reflected in the set, and vice-versa.
This method is always executed by a distributed query,
so it may throw a QueryResultSizeExceededException
if GroupProperty.QUERY_RESULT_SIZE_LIMIT is configured.
entrySet in interface IMap<K,V>predicate - specified query criteriaGroupProperty.QUERY_RESULT_SIZE_LIMITpublic Collection<V> values()
IMapWarning:
The collection is NOT backed by the map, so changes to the map are NOT reflected in the collection, and vice-versa.
This method is always executed by a distributed query,
so it may throw a QueryResultSizeExceededException
if GroupProperty.QUERY_RESULT_SIZE_LIMIT is configured.
public Collection<V> values(Predicate predicate)
IMapSpecified predicate runs on all members in parallel.
Warning:
The collection is NOT backed by the map, so changes to the map are NOT reflected in the collection, and vice-versa.
This method is always executed by a distributed query,
so it may throw a QueryResultSizeExceededException
if GroupProperty.QUERY_RESULT_SIZE_LIMIT is configured.
public Set<K> localKeySet()
IMapEach key in this map is owned and managed by a specific member in the cluster.
Note that ownership of these keys might change over time so that key ownerships can be almost evenly distributed in the cluster.
Warning:
The set is NOT backed by the map, so changes to the map are NOT reflected in the set, and vice-versa.
This method is always executed by a distributed query,
so it may throw a QueryResultSizeExceededException
if GroupProperty.QUERY_RESULT_SIZE_LIMIT is configured.
localKeySet in interface IMap<K,V>GroupProperty.QUERY_RESULT_SIZE_LIMITpublic Set<K> localKeySet(Predicate predicate)
IMapEach key in this map is owned and managed by a specific member in the cluster.
Note that ownership of these keys might change over time so that key ownerships can be almost evenly distributed in the cluster.
Warning:
The set is NOT backed by the map, so changes to the map are NOT reflected in the set, and vice-versa.
This method is always executed by a distributed query,
so it may throw a QueryResultSizeExceededException
if GroupProperty.QUERY_RESULT_SIZE_LIMIT is configured.
localKeySet in interface IMap<K,V>predicate - specified query criteriaGroupProperty.QUERY_RESULT_SIZE_LIMITpublic Object executeOnKey(K key, EntryProcessor entryProcessor)
IMapThe EntryProcessor may implement the Offloadable and ReadOnly interfaces.
If the EntryProcessor implements the Offloadable interface the processing will be offloaded to the given ExecutorService allowing unblocking the partition-thread, which means that other partition-operations may proceed. The key will be locked for the time-span of the processing in order to not generate a write-conflict. In this case the threading looks as follows:
If the EntryProcessor implements only ReadOnly without implementing Offloadable the processing unit will not be offloaded, however, the EntryProcessor will not wait for the lock to be acquired, since the EP will not do any modifications.
Using offloading is useful if the EntryProcessor encompasses heavy logic that may stall the partition-thread.
If the EntryProcessor implements ReadOnly and modifies the entry it is processing an UnsupportedOperationException will be thrown.
Offloading will not be applied to backup partitions. It is possible to initialize the EntryBackupProcessor with some input provided by the EntryProcessor in the EntryProcessor.getBackupProcessor() method. The input allows providing context to the EntryBackupProcessor - for example the "delta" so that the EntryBackupProcessor does not have to calculate the "delta" but it may just apply it.
executeOnKey in interface IMap<K,V>Offloadable,
ReadOnlypublic Map<K,Object> executeOnKeys(Set<K> keys, EntryProcessor entryProcessor)
IMapexecuteOnKeys in interface IMap<K,V>public void submitToKey(K key, EntryProcessor entryProcessor, ExecutionCallback callback)
IMapThe EntryProcessor may implement the Offloadable and ReadOnly interfaces.
If the EntryProcessor implements the Offloadable interface the processing will be offloaded to the given ExecutorService allowing unblocking the partition-thread, which means that other partition-operations may proceed. The key will be locked for the time-span of the processing in order to not generate a write-conflict. In this case the threading looks as follows:
If the EntryProcessor implements only ReadOnly without implementing Offloadable the processing unit will not be offloaded, however, the EntryProcessor will not wait for the lock to be acquired, since the EP will not do any modifications.
If the EntryProcessor implements ReadOnly and modifies the entry it is processing an UnsupportedOperationException will be thrown.
Using offloading is useful if the EntryProcessor encompasses heavy logic that may stall the partition-thread.
Offloading will not be applied to backup partitions. It is possible to initialize the EntryBackupProcessor with some input provided by the EntryProcessor in the EntryProcessor.getBackupProcessor() method. The input allows providing context to the EntryBackupProcessor - for example the "delta" so that the EntryBackupProcessor does not have to calculate the "delta" but it may just apply it.
submitToKey in interface IMap<K,V>key - key to be processedentryProcessor - processor to process the keycallback - to listen whether operation is finished or notOffloadable,
ReadOnlypublic ICompletableFuture submitToKey(K key, EntryProcessor entryProcessor)
IMapEntryProcessor is not cancellable, so calling ICompletableFuture.cancel() method won't cancel the operation of EntryProcessor.
The EntryProcessor may implement the Offloadable and ReadOnly interfaces.
If the EntryProcessor implements the Offloadable interface the processing will be offloaded to the given ExecutorService allowing unblocking the partition-thread, which means that other partition-operations may proceed. The key will be locked for the time-span of the processing in order to not generate a write-conflict. In this case the threading looks as follows:
If the EntryProcessor implements only ReadOnly without implementing Offloadable the processing unit will not be offloaded, however, the EntryProcessor will not wait for the lock to be acquired, since the EP will not do any modifications.
If the EntryProcessor implements ReadOnly and modifies the entry it is processing a UnsupportedOperationException will be thrown.
Using offloading is useful if the EntryProcessor encompasses heavy logic that may stall the partition-thread.
Offloading will not be applied to backup partitions. It is possible to initialize the EntryBackupProcessor with some input provided by the EntryProcessor in the EntryProcessor.getBackupProcessor() method. The input allows providing context to the EntryBackupProcessor - for example the "delta" so that the EntryBackupProcessor does not have to calculate the "delta" but it may just apply it.
submitToKey in interface IMap<K,V>submitToKey in interface LegacyAsyncMap<K,V>key - key to be processedentryProcessor - processor to process the keyOffloadable,
ReadOnly,
ICompletableFuturepublic Map<K,Object> executeOnEntries(EntryProcessor entryProcessor)
IMapexecuteOnEntries in interface IMap<K,V>public Map<K,Object> executeOnEntries(EntryProcessor entryProcessor, Predicate predicate)
IMapexecuteOnEntries in interface IMap<K,V>public <R> R aggregate(Aggregator<Map.Entry<K,V>,R> aggregator)
IMapFast-Aggregations are the successor of the Map-Reduce Aggregators. They are equivalent to the Map-Reduce Aggregators in most of the use-cases, but instead of running on the Map-Reduce engine they run on the Query infrastructure. Their performance is tens to hundreds times better due to the fact that they run in parallel for each partition and are highly optimized for speed and low memory consumption.
public <R> R aggregate(Aggregator<Map.Entry<K,V>,R> aggregator, Predicate<K,V> predicate)
IMapFast-Aggregations are the successor of the Map-Reduce Aggregators. They are equivalent to the Map-Reduce Aggregators in most of the use-cases, but instead of running on the Map-Reduce engine they run on the Query infrastructure. Their performance is tens to hundreds times better due to the fact that they run in parallel for each partition and are highly optimized for speed and low memory consumption.
public <R> Collection<R> project(Projection<Map.Entry<K,V>,R> projection)
IMappublic <R> Collection<R> project(Projection<Map.Entry<K,V>,R> projection, Predicate<K,V> predicate)
IMappublic <SuppliedValue,Result> Result aggregate(Supplier<K,V,SuppliedValue> supplier, Aggregation<K,SuppliedValue,Result> aggregation)
IMapSupplier
is used to either select or to select and extract a (sub-)value. A predefined set of aggregations can be found in
Aggregations.aggregate in interface IMap<K,V>SuppliedValue - the final type emitted from the supplierResult - the resulting aggregation value typesupplier - the supplier to select and / or extract a (sub-)value from the mapaggregation - the aggregation that is being executed against the mappublic <SuppliedValue,Result> Result aggregate(Supplier<K,V,SuppliedValue> supplier, Aggregation<K,SuppliedValue,Result> aggregation, JobTracker jobTracker)
IMap
The Supplier is used to either select or to select and extract a (sub-)value.
A predefined set of aggregations can be found in Aggregations.
aggregate in interface IMap<K,V>SuppliedValue - the final type emitted from the supplierResult - the resulting aggregation value typesupplier - the supplier to select and / or extract a (sub-)value from the mapaggregation - the aggregation that is being executed against the mapjobTracker - the JobTracker instance to execute the aggregationprotected Object invoke(Operation operation, int partitionId) throws Throwable
Throwablepublic Iterator<Map.Entry<K,V>> iterator(int fetchSize, int partitionId, boolean prefetchValues)
partitionId. If prefetchValues is
true, all values will be sent along with the keys and no additional data will be fetched when
iterating. If false, the values will be fetched when iterating the entries.
The values are not fetched one-by-one but rather in batches.
You may control the size of the batch by changing the fetchSize parameter.
A too small fetchSize can affect performance since more data will have to be sent to and from the partition owner.
A too high fetchSize means that more data will be sent which can block other operations from being sent,
including internal operations.
The underlying implementation may send more values in one batch than fetchSize if it needs to get to
a "safepoint" to later resume iteration.
NOTE
Iterating the map should be done only when the IMap is not being
mutated and the cluster is stable (there are no migrations or membership changes).
In other cases, the iterator may not return some entries or may return an entry twice.
fetchSize - the size of the batches which will be sent when iterating the datapartitionId - the partition ID which is being iteratedpublic <R> Iterator<R> iterator(int fetchSize, int partitionId, Projection<Map.Entry<K,V>,R> projection, Predicate<K,V> predicate)
partitionId which
satisfy the predicate.
The values are not fetched one-by-one but rather in batches.
You may control the size of the batch by changing the fetchSize parameter.
A too small fetchSize can affect performance since more data will have to be sent to and from the partition owner.
A too high fetchSize means that more data will be sent which can block other operations from being sent,
including internal operations.
The underlying implementation may send more values in one batch than fetchSize if it needs to get to
a "safepoint" to later resume iteration.
Predicates of type PagingPredicate are not supported.
NOTE
Iterating the map should be done only when the IMap is not being
mutated and the cluster is stable (there are no migrations or membership changes).
In other cases, the iterator may not return some entries or may return an entry twice.
R - the return typefetchSize - the size of the batches which will be sent when iterating the datapartitionId - the partition ID which is being iteratedprojection - the projection to apply before returning the value. null value is not allowedpredicate - the predicate which the entries must match. null value is not allowedUnsupportedOperationException - when cluster version is less than Versions.V3_9IllegalArgumentException - if the predicate is of type PagingPredicatepublic ICompletableFuture<EventJournalInitialSubscriberState> subscribeToEventJournal(int partitionId)
EventJournalReadersubscribeToEventJournal in interface EventJournalReader<EventJournalMapEvent<K,V>>partitionId - the partition ID of the entries to which we are subscribingpublic <T> ICompletableFuture<ReadResultSet<T>> readFromEventJournal(long startSequence, int minSize, int maxSize, int partitionId, Predicate<? super EventJournalMapEvent<K,V>> predicate, Projection<? super EventJournalMapEvent<K,V>,T> projection)
UnsupportedOperationException
if the cluster version is lower than 3.9 or there is no event journal configured for this data structure.
NOTE:
Configuring evictions may cause unexpected results when reading from the event journal and
there are cluster changes (a backup replica is promoted into a partition owner). See
MapEventJournal or
CacheEventJournal for more details.
This implementation will skip cloning of the predicate and projection
for performance reasons. Because of this, the results of the projection
and predicate should not depend on any state that will be lost while
cloning. If you wish to get rid of user state, you may clone the predicate
and projection and keep them cached for all calls to this method to avoid
the overhead of cloning.
readFromEventJournal in interface EventJournalReader<EventJournalMapEvent<K,V>>T - the return type of the projection. It is equal to the journal event type
if the projection is null or it is the identity projectionstartSequence - the sequence of the first item to readmaxSize - the maximum number of items to readpartitionId - the partition ID of the entries in the journalpredicate - the predicate which the events must pass to be included in the response.
May be null in which case all events pass the predicateprojection - the projection which is applied to the events before returning.
May be null in which case the event is returned without being projectedpublic String toString()
toString in class AbstractDistributedObject<MapService>public QueryCache<K,V> getQueryCache(String name)
IMapQueryCache instance for the supplied name or null.
If there is a previously created QueryCache with the supplied name or if a declarative
configuration exists for the supplied name this method returns or creates the instance respectively,
otherwise returns null.
getQueryCache in interface IMap<K,V>name - the name of QueryCacheQueryCache instance or null if there is no corresponding QueryCacheConfigQueryCachepublic QueryCache<K,V> getQueryCache(String name, Predicate<K,V> predicate, boolean includeValue)
IMapIMap according to the supplied parameters.
If there is a previously created QueryCache with the supplied name, this method returns that
QueryCache and ignores predicate and includeValue parameters. Otherwise it creates and returns
a new QueryCache instance.
Also note that if there exists a QueryCacheConfig for the supplied
name, predicate and includeValue parameters will overwrite corresponding ones
in QueryCacheConfig.
getQueryCache in interface IMap<K,V>name - the name of QueryCachepredicate - the predicate for filtering entriesincludeValue - true if this QueryCache is allowed to cache values of entries, otherwise falseQueryCache instance with the supplied nameQueryCachepublic QueryCache<K,V> getQueryCache(String name, MapListener listener, Predicate<K,V> predicate, boolean includeValue)
IMapIMap according to the supplied parameters.
If there is a previously created QueryCache with the supplied name, this method returns that
QueryCache and ignores listener, predicate and includeValue parameters.
Otherwise it creates and returns a new QueryCache instance.
Also note that if there exists a QueryCacheConfig for the supplied
name, listener,predicate and includeValue parameters will overwrite corresponding ones
in QueryCacheConfig.
getQueryCache in interface IMap<K,V>name - the name of QueryCachelistener - the MapListener which will be used to listen this QueryCachepredicate - the predicate for filtering entriesincludeValue - true if this QueryCache is allowed to cache values of entries, otherwise falseQueryCache instance with the supplied nameQueryCachepublic final String getName()
DistributedObjectDistributedObjectUtil.getName(DistributedObject)
because this might be also a PrefixedDistributedObject.getName in interface DistributedObjectpublic final String getServiceName()
DistributedObjectgetServiceName in interface DistributedObjectgetServiceName in class AbstractDistributedObject<MapService>public void initialize()
initialize in interface InitializingObjectpublic PartitioningStrategy getPartitionStrategy()
public MapOperationProvider getOperationProvider()
public void setOperationProvider(MapOperationProvider operationProvider)
public int getTotalBackupCount()
protected MapQueryEngine getMapQueryEngine()
protected boolean isMapStoreEnabled()
protected InternalCompletableFuture<Data> getAsyncInternal(Object key)
protected boolean tryPutInternal(Object key, Data value, long timeout, TimeUnit timeunit)
protected Data putIfAbsentInternal(Object key, Data value, long ttl, TimeUnit timeunit)
protected void putTransientInternal(Object key, Data value, long ttl, TimeUnit timeunit)
protected InternalCompletableFuture<Data> putAsyncInternal(Object key, Data value, long ttl, TimeUnit timeunit)
protected InternalCompletableFuture<Data> setAsyncInternal(Object key, Data value, long ttl, TimeUnit timeunit)
protected boolean evictInternal(Object key)
key - the key to evicttrue if eviction was successful, false otherwiseprotected void evictAllInternal()
protected void loadAllInternal(boolean replaceExistingValues)
protected void loadInternal(Set<K> keys, Iterable<Data> dataKeys, boolean replaceExistingValues)
protected void deleteInternal(Object key)
protected void removeAllInternal(Predicate predicate)
protected InternalCompletableFuture<Data> removeAsyncInternal(Object key)
protected boolean containsKeyInternal(Object key)
public void waitUntilLoaded()
public int size()
BaseMappublic boolean containsValueInternal(Data dataValue)
public boolean isEmpty()
BaseMapprotected void getAllInternal(Set<K> keys, List<Data> dataKeys, List<Object> resultingKeyValuePairs)
protected void putAllInternal(Map<?,?> map)
PutAllPartitionAwareOperationFactory per member.
If there are e.g. five keys for a single member, there will only be a single remote invocation instead of having five remote invocations.
There is also an optional support for batching to send smaller packages.
Takes care about null checks for keys and values.
protected void invokePutAllOperationFactory(long size,
int[] partitions,
MapEntries[] entries)
throws Exception
Exceptionprotected void finalizePutAll(Map<?,?> map)
public void flush()
IMappublic void clearInternal()
public String addMapInterceptorInternal(MapInterceptor interceptor)
public void removeMapInterceptorInternal(String id)
public String addLocalEntryListenerInternal(Object listener, Predicate predicate, Data key, boolean includeValue)
protected String addEntryListenerInternal(Object listener, Data key, boolean includeValue)
protected String addEntryListenerInternal(Object listener, Predicate predicate, Data key, boolean includeValue)
protected boolean removeEntryListenerInternal(String id)
protected String addPartitionLostListenerInternal(MapPartitionLostListener listener)
protected boolean removePartitionLostListenerInternal(String id)
public Data executeOnKeyInternal(Object key, EntryProcessor entryProcessor)
public Map<K,Object> executeOnKeysInternal(Set<K> keys, Set<Data> dataKeys, EntryProcessor entryProcessor)
public InternalCompletableFuture<Object> executeOnKeyInternal(Object key, EntryProcessor entryProcessor, ExecutionCallback<Object> callback)
public void executeOnEntriesInternal(EntryProcessor entryProcessor, Predicate predicate, List<Data> result)
protected <T> T toObject(Object object)
protected Data toData(Object object, PartitioningStrategy partitioningStrategy)
public void addIndex(String attribute, boolean ordered)
IMapLet's say your map values are Employee objects.
public class Employee implements Serializable {
private boolean active = false;
private int age;
private String name = null;
// other fields
// getters setter
}
If you are querying your values mostly based on age and active then
you should consider indexing these fields.
IMap imap = Hazelcast.getMap("employees");
imap.addIndex("age", true); // ordered, since we have ranged queries for this field
imap.addIndex("active", false); // not ordered, because boolean field cannot have range
Index attribute should either have a getter method or be public.
You should also make sure to add the indexes before adding
entries to this map.
Time to Index
Indexing time is executed in parallel on each partition by operation threads. The Map is not blocked during this operation.
The time taken in proportional to the size of the Map and the number Members.
Searches while indexes are being built
Until the index finishes being created, any searches for the attribute will use a full Map scan, thus avoiding using a partially built index and returning incorrect results.
public LocalMapStats getLocalMapStats()
IMapLocalMapStats are the statistics for the local portion of this distributed map and contains information such as ownedEntryCount backupEntryCount, lastUpdateTime, lockedEntryCount.
Since this stats are only for the local portion of this map, if you need the cluster-wide MapStats then you need to get the LocalMapStats from all members of the cluster and combine them.
getLocalMapStats in interface IMap<K,V>protected boolean preDestroy()
preDestroy in class AbstractDistributedObject<MapService>protected void toDataCollectionWithNonNullKeyValidation(Set<K> keys, Collection<Data> dataKeys)
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