JCache API
This section explains the JCache API by providing simple examples and use cases. While walking through the examples, we will have a look at a couple of the standard API classes and see how these classes are used.
JCache API Application Example
The code in this subsection creates a small account application by providing a caching layer over an imagined database abstraction. The database layer is simulated using a single demo data in a simple DAO interface. To show the difference between the "database" access and retrieving values from the cache, a small waiting time is used in the DAO implementation to simulate network and database latency.
Creating User Class Example
Before we implement the JCache caching layer, let’s have a quick look at some basic classes we need for this example.
The User
class is the representation of a user table in the
database. To keep it simple, it has just two properties:
userId
and username
.
public class User implements Serializable {
private int userId;
private String username;
public User() {
}
Creating DAO Interface Example
The DAO interface is also kept easy in this example.
It provides a simple method to retrieve (find) a user by its userId
.
public interface UserDao {
User findUserById(int userId);
boolean storeUser(int userId, User user);
boolean removeUser(int userId);
Collection<Integer> allUserIds();
}
Configuring JCache Example
To show most of the standard features, the configuration example is a little more complex.
// Create javax.cache.configuration.CompleteConfiguration subclass
CompleteConfiguration<Integer, User> config =
new MutableConfiguration<Integer, User>()
// Configure the cache to be typesafe
.setTypes( Integer.class, User.class )
// Configure to expire entries 30 secs after creation in the cache
.setExpiryPolicyFactory( FactoryBuilder.factoryOf(
new AccessedExpiryPolicy( new Duration( TimeUnit.SECONDS, 30 ) )
) )
// Configure read-through of the underlying store
.setReadThrough( true )
// Configure write-through to the underlying store
.setWriteThrough( true )
// Configure the javax.cache.integration.CacheLoader
.setCacheLoaderFactory( FactoryBuilder.factoryOf(
new UserCacheLoader( userDao )
) )
// Configure the javax.cache.integration.CacheWriter
.setCacheWriterFactory( FactoryBuilder.factoryOf(
new UserCacheWriter( userDao )
) )
// Configure the javax.cache.event.CacheEntryListener with no
// javax.cache.event.CacheEntryEventFilter, to include old value
// and to be executed synchronously
.addCacheEntryListenerConfiguration(
new MutableCacheEntryListenerConfiguration<Integer, User>(
new UserCacheEntryListenerFactory(),
null, true, true
)
);
Let’s go through this configuration line by line.
Setting the Cache Type and Expire Policy
First, we set the expected types for the cache, which
is already known from the previous example. On the next line, a
javax.cache.expiry.ExpiryPolicy
is configured.
Almost all integration ExpiryPolicy
implementations are
configured using
javax.cache.configuration.Factory
instances. Factory
and
FactoryBuilder
are explained later in this chapter.
Configuring Read-Through and Write-Through
The next two lines configure the thread that are read-through
and write-through to the underlying backend resource that is configured
over the next few lines. The JCache API offers javax.cache.integration.CacheLoader
and javax.cache.integration.CacheWriter
to
implement adapter classes to any kind of backend resource, e.g., JPA, JDBC, or any
other backend technology implementable in Java.
The interface provides the typical CRUD operations like create
, get
,
update
, delete
and some bulk operation versions of those
common operations. We will look into the implementation of those implementations
later.
Configuring Entry Listeners
The last configuration setting defines entry listeners based on
sub-interfaces of javax.cache.event.CacheEntryListener
. This
config does not use a javax.cache.event.CacheEntryEventFilter
since the listener is meant to be fired on every change that
happens on the cache. Again we will look in the implementation
of the listener in later in this chapter.
Full Example Code
A full running example that is presented in this
subsection is available in the
code samples repository.
The application is built to be a command line app. It
offers a small shell to accept different commands. After startup, you can
enter help
to see all available commands and their descriptions.
JCache Base Classes
In the Example JCache Application section, we have already seen a couple of the base classes and explained how those work. The following are quick descriptions of them:
javax.cache.Caching
:
The access point into the JCache API. It retrieves the general
CachingProvider
backed by any compliant JCache
implementation, such as Hazelcast JCache.
javax.cache.spi.CachingProvider
:
The SPI that is implemented to bridge between the JCache API and the implementation itself. Hazelcast members and clients use different providers chosen as seen in the Configuring JCache Provider section which enable the JCache API to interact with Hazelcast clusters.
When a javax.cache.spi.CachingProvider.getCacheManager()
overload
that takes a java.lang.ClassLoader
argument is used, this
classloader will be a part of the scope of the created java.cache.Cache
,
and it is not possible to retrieve it on other members.
We advise not to use those overloads, as they are not meant to be used
in distributed environments!
javax.cache.CacheManager
:
The CacheManager
provides the capability to create new and
manage existing JCache caches.
A javax.cache.Cache instance created with key and
value types in the configuration
provides a type checking of those types at retrieval of the
cache. For that reason, all non-types retrieval methods like
getCache throw an exception because types cannot be checked.
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javax.cache.configuration.Configuration
, javax.cache.configuration.MutableConfiguration
:
These two classes are used to configure a cache prior to
retrieving it from a CacheManager
. The Configuration
interface,
therefore, acts as a common super type for all compatible
configuration classes such as MutableConfiguration
.
Hazelcast itself offers a special implementation
(com.hazelcast.config.CacheConfig
) of the Configuration
interface
which offers more options on the specific Hazelcast properties
that can be set to configure features like synchronous and asynchronous
backups counts or selecting the underlying in-memory format of the cache. For more information about this
configuration class, see the reference in the JCache Programmatic Configuration section.
javax.cache.Cache
:
This interface represents the cache instance itself.
It is comparable to java.util.Map
but offers special operations dedicated
to the caching use case. Therefore, for example javax.cache.Cache.put()
,
unlike java.util.Map.put()
, does not return the old
value previously assigned to the given key.
Bulk operations on the Cache interface guarantee atomicity
per entry but not over
all given keys in the same bulk operations since no transactional
behavior is applied over the whole batch process.
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Implementing Factory and FactoryBuilder
The javax.cache.configuration.Factory
implementations configure
features like CacheEntryListener
, ExpiryPolicy
and CacheLoader
s or CacheWriter
s.
These factory implementations are required to distribute the
different features to members in a cluster environment like Hazelcast.
Therefore, these factory implementations have to be serializable.
Factory
implementations are easy to do, as they follow the default
Provider- or Factory-Pattern. The example class
UserCacheEntryListenerFactory
shown below implements a custom JCache Factory
.
public class UserCacheEntryListenerFactory implements Factory<CacheEntryListener<Integer, User>> {
@Override
public CacheEntryListener<Integer, User> create() {
// just create a new listener instance
return new UserCacheEntryListener();
}
}
To simplify the process for the users, JCache API offers a set of
helper methods collected in javax.cache.
configuration.FactoryBuilder
. In the above configuration
example, FactoryBuilder.factoryOf()
creates a
singleton factory for the given instance.
Implementing CacheLoader
javax.cache.integration.CacheLoader
loads cache entries
from any external backend resource.
Cache read-through
If the cache is
configured to be read-through
, then CacheLoader.load()
is called transparently from the cache when the key or the value is not
yet found in the cache. If no value is found for a given key, it returns null.
If the cache is not configured to be read-through
, nothing is
loaded automatically. The user code must call
javax.cache.Cache.loadAll()
to load data for the given
set of keys into the cache.
For the bulk load operation (loadAll()
), some keys may not
be found in the returned result set. In this case, a
javax.cache.integration.CompletionListener
parameter can be used
as an asynchronous callback after all the key-value pairs are loaded
because loading many key-value pairs can take lots of time.
CacheLoader Example
Let’s look at the UserCacheLoader
implementation.
This implementation is quite straight forward.
-
It implements
CacheLoader
. -
It overrides the
load
method to compute or retrieve the value corresponding tokey
. -
It overrides the
loadAll
method to compute or retrieve the values corresponding tokeys
.
An important note is that
any kind of exception has to be wrapped into
javax.cache.integration.CacheLoaderException
.
public class UserCacheLoader implements CacheLoader<Integer, User>, Serializable {
private final UserDao userDao;
public UserCacheLoader(UserDao userDao) {
// store the dao instance created externally
this.userDao = userDao;
}
@Override
public User load(Integer key) throws CacheLoaderException {
// just call through into the dao
return userDao.findUserById(key);
}
@Override
public Map<Integer, User> loadAll(Iterable<? extends Integer> keys) throws CacheLoaderException {
// create the resulting map
Map<Integer, User> loaded = new HashMap<Integer, User>();
// for every key in the given set of keys
for (Integer key : keys) {
// try to retrieve the user
User user = userDao.findUserById(key);
// if user is not found do not add the key to the result set
if (user != null) {
loaded.put(key, user);
}
}
return loaded;
}
}
CacheWriter
You use a javax.cache.integration.CacheWriter
to update
an external backend resource. If the cache is configured to be
write-through
, this process is executed transparently to
the user’s code. Otherwise, there is currently no way to trigger
writing changed entries to the external resource to a user-defined
point in time.
If bulk operations throw an exception, java.util.Collection
has to be cleaned of all successfully written keys so
the cache implementation can determine what keys are written
and can be applied to the cache state.
The following example performs the following tasks:
-
It implements
CacheWriter
. -
It overrides the
write
method to write the specified entry to the underlying store. -
It overrides the
writeAll
method to write the specified entires to the underlying store. -
It overrides the
delete
method to delete the key entry from the store. -
It overrides the
deleteAll
method to delete the data and keys from the underlying store for the given collection of keys, if present.
public class UserCacheWriter implements CacheWriter<Integer, User>, Serializable {
private final UserDao userDao;
public UserCacheWriter(UserDao userDao) {
// store the dao instance created externally
this.userDao = userDao;
}
@Override
public void write(Cache.Entry<? extends Integer, ? extends User> entry) throws CacheWriterException {
// store the user using the dao
userDao.storeUser(entry.getKey(), entry.getValue());
}
@Override
public void writeAll(Collection<Cache.Entry<? extends Integer, ? extends User>> entries) throws CacheWriterException {
// retrieve the iterator to clean up the collection from written keys in case of an exception
Iterator<Cache.Entry<? extends Integer, ? extends User>> iterator = entries.iterator();
while (iterator.hasNext()) {
// write entry using dao
write(iterator.next());
// remove from collection of keys
iterator.remove();
}
}
@Override
public void delete(Object key) throws CacheWriterException {
// test for key type
if (!(key instanceof Integer)) {
throw new CacheWriterException("Illegal key type");
}
// remove user using dao
userDao.removeUser((Integer) key);
}
@Override
public void deleteAll(Collection<?> keys) throws CacheWriterException {
// retrieve the iterator to clean up the collection from written keys in case of an exception
Iterator<?> iterator = keys.iterator();
while (iterator.hasNext()) {
// write entry using dao
delete(iterator.next());
// remove from collection of keys
iterator.remove();
}
}
}
Again, the implementation is pretty straightforward and
also as above all exceptions thrown by the external resource,
like java.sql.SQLException
has to be wrapped into a
javax.cache.integration.CacheWriterException
. Note this is a different
exception from the one thrown by CacheLoader
.
Implementing EntryProcessor
With javax.cache.processor.EntryProcessor
, you can apply an
atomic function to a cache entry. In a distributed
environment like Hazelcast, you can move the mutating function
to the member that owns the key. If the value
object is big, it might prevent traffic by sending the object
to the mutator and sending it back to the owner to update it.
By default, Hazelcast JCache sends the complete changed value to the backup partition. Again, this can cause a lot of traffic if the object is big. The Hazelcast ICache extension can also prevent this. Further information is available at Implementing BackupAwareEntryProcessor.
An arbitrary number of arguments can be passed to the
Cache.invoke()
and Cache.invokeAll()
methods. All of those
arguments need
to be fully serializable because in a distributed environment
like Hazelcast, it is very likely that these arguments have to be passed around the cluster.
The following example performs the following tasks.
-
It implements
EntryProcessor
. -
It overrides the
process
method to process an entry.
public class UserUpdateEntryProcessor implements EntryProcessor<Integer, User, User> {
@Override
public User process(MutableEntry<Integer, User> entry, Object... arguments) throws EntryProcessorException {
// test arguments length
if (arguments.length < 1) {
throw new EntryProcessorException("One argument needed: username");
}
// get first argument and test for String type
Object argument = arguments[0];
if (!(argument instanceof String)) {
throw new EntryProcessorException("First argument has wrong type, required java.lang.String");
}
// retrieve the value from the MutableEntry
User user = entry.getValue();
// retrieve the new username from the first argument
String newUsername = (String) arguments[0];
// set the new username
user.setUsername(newUsername);
// set the changed user to mark the entry as dirty
entry.setValue(user);
// return the changed user to return it to the caller
return user;
}
}
By executing the bulk Cache.invokeAll() operation,
atomicity is only guaranteed for a
single cache entry. No transactional rules are applied to the bulk operation.
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JCache EntryProcessor implementations are not allowed to call
javax.cache.Cache methods. This prevents operations from
deadlocking between different calls.
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In addition, when using a Cache.invokeAll()
method, a
java.util.Map
is returned that maps the key to its
javax.cache.processor.EntryProcessorResult
, which itself
wraps the actual result or a thrown
javax.cache.processor.EntryProcessorException
.
CacheEntryListener
The javax.cache.event.CacheEntryListener
implementation is
straight forward. CacheEntryListener
is a super-interface that
is used as a marker for listener classes in JCache. The specification
brings a set of sub-interfaces.
-
CacheEntryCreatedListener
: Fires after a cache entry is added (even on read-through by aCacheLoader
) to the cache. -
CacheEntryUpdatedListener
: Fires after an already existing cache entry updates. -
CacheEntryRemovedListener
: Fires after a cache entry was removed (not expired) from the cache. -
CacheEntryExpiredListener
: Fires after a cache entry has been expired. Expiry does not have to be a parallel process-- Hazelcast JCache implementation detects and removes expired entries periodically. Therefore, the expiration event may not be fired as soon as the entry expires. See ExpiryPolicy for details.
To configure CacheEntryListener
, add a
javax.cache.configuration.CacheEntryListenerConfiguration
instance to
the JCache configuration class, as seen in the above example
configuration. In addition, listeners can be configured to be
executed synchronously (blocking the calling thread) or asynchronously
(fully running in parallel).
In this example application, the listener is implemented to print event information about the console. That visualizes what is going on in the cache. This application performs the following tasks:
-
It implements the
CacheEntryCreatedListener.onCreated
method to call after an entry is created. -
It implements the
CacheEntryUpdatedListener.onUpdated
method to call after an entry is updated. -
It implements the
CacheEntryRemovedListener.onRemoved
method to call after an entry is removed. -
It implements the
CacheEntryExpiredListener.onExpired
method to call after an entry expires. -
It implements
printEvents
to print event information about the console.
class UserCacheEntryListener implements CacheEntryCreatedListener<Integer, User>,
CacheEntryUpdatedListener<Integer, User>,
CacheEntryRemovedListener<Integer, User>,
CacheEntryExpiredListener<Integer, User> {
@Override
public void onCreated(Iterable<CacheEntryEvent<? extends Integer, ? extends User>> cacheEntryEvents)
throws CacheEntryListenerException {
printEvents(cacheEntryEvents);
}
@Override
public void onUpdated(Iterable<CacheEntryEvent<? extends Integer, ? extends User>> cacheEntryEvents)
throws CacheEntryListenerException {
printEvents(cacheEntryEvents);
}
@Override
public void onRemoved(Iterable<CacheEntryEvent<? extends Integer, ? extends User>> cacheEntryEvents)
throws CacheEntryListenerException {
printEvents(cacheEntryEvents);
}
@Override
public void onExpired(Iterable<CacheEntryEvent<? extends Integer, ? extends User>> cacheEntryEvents)
throws CacheEntryListenerException {
printEvents(cacheEntryEvents);
}
private void printEvents(Iterable<CacheEntryEvent<? extends Integer, ? extends User>> cacheEntryEvents) {
for (CacheEntryEvent<? extends Integer, ? extends User> event : cacheEntryEvents) {
System.out.println(event.getEventType());
}
}
}
ExpiryPolicy
In JCache, javax.cache.expiry.ExpiryPolicy
implementations are
used to automatically expire cache entries based on different rules.
JCache does not require expired entries to be removed from the cache immediately. It only enforces that expired entries are not returned from cache. Therefore, exact time of removal is implementation specific. Hazelcast complies JCache by checking the entries for expiration at the time of get operations (lazy expiration). In addition to that, Hazelcast uses a periodic task to detect and remove expired entries as soon as possible (eager expiration). Thanks to eager expiry, all expired entries are removed from the memory eventually even when they are not touched again. So the space used by such entries are released as well.
For a detailed explanation of interaction between expiry policies and
JCache API, see the table in the Expiry Policies
section of
JCache documentation.
Expiry timeouts are defined using javax.cache.expiry.Duration
,
which is a pair of java.util.concurrent.TimeUnit
, that
describes a time unit and a long, defining the timeout value.
The minimum allowed TimeUnit
is TimeUnit.MILLISECONDS
.
The long value durationAmount
must be equal or greater than zero.
A value of zero (or Duration.ZERO
) indicates that the
cache entry expires immediately.
By default, JCache delivers a set of predefined expiry strategies in the standard API.
-
AccessedExpiryPolicy
: Expires after a given set of time measured from creation of the cache entry. The expiry timeout is updated on accessing the key. -
CreatedExpiryPolicy
: Expires after a given set of time measured from creation of the cache entry. The expiry timeout is never updated. -
EternalExpiryPolicy
: Never expires. This is the default behavior, similar toExpiryPolicy
being set to null. -
ModifiedExpiryPolicy
: Expires after a given set of time measured from creation of the cache entry. The expiry timeout is updated on updating the key. -
TouchedExpiryPolicy
: Expires after a given set of time measured from creation of the cache entry. The expiry timeout is updated on accessing or updating the key.
Because EternalExpiryPolicy
does not expire cache entries,
it is still possible to evict values from memory if an underlying
CacheLoader
is defined.