zno2

一)如何开始 ehcache ?

官网地址

http://www.ehcache.org/

从哪开始

第一步优先下载

http://www.ehcache.org/downloads/

下载 Ehcache 2.10.0 .tar.gz 解压之后得到

ehcache.xml

<?xml version="1.0" encoding="UTF-8"?>

<!--
CacheManager Configuration
==========================
An ehcache.xml corresponds to a single CacheManager.

See instructions below or the ehcache schema (ehcache.xsd) on how to configure.

System property tokens can be specified in this file which are replaced when the configuration
is loaded. For example multicastGroupPort=${multicastGroupPort} can be replaced with the
System property either from an environment variable or a system property specified with a
command line switch such as -DmulticastGroupPort=4446. Another example, useful for Terracotta
server based deployments is <terracottaConfig url="${serverAndPort}"/ and specify a command line
switch of -Dserver36:9510

The attributes of <ehcache> are:
* name - an optional name for the CacheManager.  The name is optional and primarily used
for documentation or to distinguish Terracotta clustered cache state.  With Terracotta
clustered caches, a combination of CacheManager name and cache name uniquely identify a
particular cache store in the Terracotta clustered memory.
* updateCheck - an optional boolean flag specifying whether this CacheManager should check
for new versions of Ehcache over the Internet.  If not specified, updateCheck="true".
* dynamicConfig - an optional setting that can be used to disable dynamic configuration of caches
associated with this CacheManager.  By default this is set to true - i.e. dynamic configuration
is enabled.  Dynamically configurable caches can have their TTI, TTL and maximum disk and
in-memory capacity changed at runtime through the cache's configuration object.
* monitoring - an optional setting that determines whether the CacheManager should
automatically register the SampledCacheMBean with the system MBean server.

Currently, this monitoring is only useful when using Terracotta clustering and using the
Terracotta Developer Console. With the "autodetect" value, the presence of Terracotta clustering
will be detected and monitoring, via the Developer Console, will be enabled. Other allowed values
are "on" and "off".  The default is "autodetect". This setting does not perform any function when
used with JMX monitors.

* maxBytesLocalHeap - optional setting that constraints the memory usage of the Caches managed by the CacheManager
to use at most the specified number of bytes of the local VM's heap.
* maxBytesLocalOffHeap - optional setting that constraints the offHeap usage of the Caches managed by the CacheManager
to use at most the specified number of bytes of the local VM's offHeap memory.
* maxBytesLocalDisk - optional setting that constraints the disk usage of the Caches managed by the CacheManager
to use at most the specified number of bytes of the local disk.

These settings let you define "resource pools", caches will share. For instance setting maxBytesLocalHeap to 100M, will result in
all caches sharing 100 MegaBytes of ram. The CacheManager will balance these 100 MB across all caches based on their respective usage
patterns. You can allocate a precise amount of bytes to a particular cache by setting the appropriate maxBytes* attribute for that cache.
That amount will be subtracted from the CacheManager pools, so that if a cache a specified 30M requirement, the other caches will share
the remaining 70M.

Also, specifying a maxBytesLocalOffHeap at the CacheManager level will result in overflowToOffHeap to be true by default. If you don't want
a specific cache to overflow to off heap, you'll have to set overflowToOffHeap="false" explicitly

Here is an example of CacheManager level resource tuning, which will use up to 400M of heap and 2G of offHeap:

<ehcache xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
         xsi:noNamespaceSchemaLocation="ehcache.xsd"
         updateCheck="true" monitoring="autodetect"
         dynamicConfig="true" maxBytesLocalHeap="400M" maxBytesLocalOffHeap="2G">

-->
<ehcache xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
         xsi:noNamespaceSchemaLocation="ehcache.xsd"
         updateCheck="true" monitoring="autodetect"
         dynamicConfig="true">

    <!--
    Management Rest Service configuration
    =====================================
    
    The managementRESTService element is optional.  By default the REST service that exposes monitoring and
    management features for the caches within the cache manager is disabled.  Enabling this feature will
    affect cache performance.
    
    The 'bind' attribute defaults to "0.0.0.0:9888" and sets the IP Address and Port to bind the web service
    to.  "0.0.0.0" binds to all local addresses / network interfaces.

    If you provide the 'securityServiceLocation' attribute, this will also enable authentication and other
    security measures on the REST service - which are only available for the enterprise-edition of the
    service.  The location should be the URL to the Terracotta Management Server that is being used to
    manage the ehcache instance. Enabling security requires that the management REST service be provided with
    a terracotta keychain in the default location ${user.home}/.tc/mgmt/keychain or as defined by the system property
    com.tc.management.keychain.file. The keychain is expected to hold a secret shared by the management client
    and keyed with this REST service's URI.

    Related to the the enterprise-edition security setup is the 'securityServiceTimeout' attribute. Setting this
    value will allow adjustment of the connection timeout to the security service location. The default value is
    5000 millis.

    If the 'sslEnabled' attribute is set to true, this will enable a non-blocking ssl connection to the management
    REST service. Turning this ssl connection on requires an identity store be provided at the default location
    ${user.home}/.tc/mgmt/keystore and that the JKS passphrase be included in the REST service keychain, keyed with
    the identity store file URI, or that the keystore and passphrase be identified with the ssl system properties
    javax.net.ssl.keyStore and javax.net.ssl.keyStorePassword.

    The 'needClientAuth' attribute requires ssl client certificate authorization if the 'sslEnabled' attribute has been
    set to true. Otherwise, it will be ignored.  Setting this attribute to true will require that the client's
    identity is imported as trusted into a truststore which is provided in the default location
    ${user.home}/.tc/mgmt/keystore and that the JKS passphrase be included in the REST service keychain, keyed with
    the trust store file URI, or that the truststore and passphrase be identified with the ssl system properties
    javax.net.ssl.trustStore and javax.net.ssl.trustStorePassword.

    Finally, several attributes exist to configure sampling history.

    - 'sampleHistorySize' allows the configuration of how many statistical samples will be kept in memory for
    each cache. The default value is set to 30.
    - 'sampleIntervalSeconds' allows the configuration of how often cache statistics will be obtained in seconds.
    The default value is set to 1 second.
    - 'sampleSearchIntervalSeconds' allows the configuration of how often cache seach statistics will be obtained in
    seconds. The default value is set to 10 seconds.

    examples:
    
    <managementRESTService enabled="true" bind="0.0.0.0:9888" />

    <managementRESTService enabled="true" securityServiceLocation="http://localhost:9889/tmc/api/assertIdentity"  />
    
     -->
    
    <!--
    DiskStore configuration
    =======================

    The diskStore element is optional. To turn off disk store path creation, comment out the diskStore
    element below.

    Configure it if you have disk persistence enabled for any cache or if you use
    unclustered indexed search.

    If it is not configured, and a cache is created which requires a disk store, a warning will be
     issued and java.io.tmpdir will automatically be used.

    diskStore has only one attribute - "path". It is the path to the directory where
    any required disk files will be created.

    If the path is one of the following Java System Property it is replaced by its value in the
    running VM. For backward compatibility these should be specified without being enclosed in the ${token}
    replacement syntax.

    The following properties are translated:
    * user.home - User's home directory
    * user.dir - User's current working directory
    * java.io.tmpdir - Default temp file path
    * ehcache.disk.store.dir - A system property you would normally specify on the command line
      e.g. java -Dehcache.disk.store.dir=/u01/myapp/diskdir ...

    Subdirectories can be specified below the property e.g. java.io.tmpdir/one

    -->
    <diskStore path="java.io.tmpdir"/>

    <!--
    TransactionManagerLookup configuration
    ======================================
    This class is used by ehcache to lookup the JTA TransactionManager use in the application
    using an XA enabled ehcache. If no class is specified then DefaultTransactionManagerLookup
    will find the TransactionManager in the following order

     *GenericJNDI (i.e. jboss, where the property jndiName controls the name of the
                    TransactionManager object to look up)
     *Bitronix
     *Atomikos

    You can provide you own lookup class that implements the
    net.sf.ehcache.transaction.manager.TransactionManagerLookup interface.
    -->

    <transactionManagerLookup class="net.sf.ehcache.transaction.manager.DefaultTransactionManagerLookup"
                              properties="jndiName=java:/TransactionManager" propertySeparator=";"/>


    <!--
    CacheManagerEventListener
    =========================
    Specifies a CacheManagerEventListenerFactory which is notified when Caches are added
    or removed from the CacheManager.

    The attributes of CacheManagerEventListenerFactory are:
    * class - a fully qualified factory class name
    * properties - comma separated properties having meaning only to the factory.

    Sets the fully qualified class name to be registered as the CacheManager event listener.

    The events include:
    * adding a Cache
    * removing a Cache

    Callbacks to listener methods are synchronous and unsynchronized. It is the responsibility
    of the implementer to safely handle the potential performance and thread safety issues
    depending on what their listener is doing.

    If no class is specified, no listener is created. There is no default.
    -->
    <cacheManagerEventListenerFactory class="" properties=""/>


    <!--
    CacheManagerPeerProvider
    ========================
    (For distributed operation)

    Specifies a CacheManagerPeerProviderFactory which will be used to create a
    CacheManagerPeerProvider, which discovers other CacheManagers in the cluster.

    One or more providers can be configured. The first one in the ehcache.xml is the default, which is used
    for replication and bootstrapping.

    The attributes of cacheManagerPeerProviderFactory are:
    * class - a fully qualified factory class name
    * properties - comma separated properties having meaning only to the factory.

    Providers are available for RMI, JGroups and JMS as shown following.

    RMICacheManagerPeerProvider
    +++++++++++++++++++++++++++

    Ehcache comes with a built-in RMI-based distribution system with two means of discovery of
    CacheManager peers participating in the cluster:
    * automatic, using a multicast group. This one automatically discovers peers and detects
      changes such as peers entering and leaving the group
    * manual, using manual rmiURL configuration. A hardcoded list of peers is provided at
      configuration time.

    Configuring Automatic Discovery:
    Automatic discovery is configured as per the following example:
    <cacheManagerPeerProviderFactory
                        class="net.sf.ehcache.distribution.RMICacheManagerPeerProviderFactory"
                        properties="hostName=fully_qualified_hostname_or_ip,
                                    peerDiscovery=automatic, multicastGroupAddress=230.0.0.1,
                                    multicastGroupPort=4446, timeToLive=32"/>

    Valid properties are:
    * peerDiscovery (mandatory) - specify "automatic"
    * multicastGroupAddress (mandatory) - specify a valid multicast group address
    * multicastGroupPort (mandatory) - specify a dedicated port for the multicast heartbeat
      traffic
    * timeToLive - specify a value between 0 and 255 which determines how far the packets will
      propagate.

      By convention, the restrictions are:
      0   - the same host
      1   - the same subnet
      32  - the same site
      64  - the same region
      128 - the same continent
      255 - unrestricted

     * hostName - the hostname or IP of the interface to be used for sending and receiving multicast
       packets (relevant to multi-homed hosts only)

    Configuring Manual Discovery:
    Manual discovery requires a unique configuration per host. It is contains a list of rmiURLs for
    the peers, other than itself. So, if we have server1, server2 and server3 the configuration will
    be:

    In server1's configuration:
    <cacheManagerPeerProviderFactory class=
                          "net.sf.ehcache.distribution.RMICacheManagerPeerProviderFactory"
                          properties="peerDiscovery=manual,
                          rmiUrls=//server2:40000/sampleCache1|//server3:40000/sampleCache1
                          | //server2:40000/sampleCache2|//server3:40000/sampleCache2"
                          propertySeparator="," />

    In server2's configuration:
    <cacheManagerPeerProviderFactory class=
                          "net.sf.ehcache.distribution.RMICacheManagerPeerProviderFactory"
                          properties="peerDiscovery=manual,
                          rmiUrls=//server1:40000/sampleCache1|//server3:40000/sampleCache1
                          | //server1:40000/sampleCache2|//server3:40000/sampleCache2"
                          propertySeparator="," />

    In server3's configuration:
    <cacheManagerPeerProviderFactory class=
                          "net.sf.ehcache.distribution.RMICacheManagerPeerProviderFactory"
                          properties="peerDiscovery=manual,
                          rmiUrls=//server1:40000/sampleCache1|//server2:40000/sampleCache1
                          | //server1:40000/sampleCache2|//server2:40000/sampleCache2"
                          propertySeparator="," />


    Valid properties are:
    * peerDiscovery (mandatory) - specify "manual"
    * rmiUrls (mandatory) - specify a pipe separated list of rmiUrls, in the form
                            //hostname:port
    * hostname (optional) - the hostname is the hostname of the remote CacheManager peer. The port is the listening
      port of the RMICacheManagerPeerListener of the remote CacheManager peer.

    JGroupsCacheManagerPeerProvider
    +++++++++++++++++++++++++++++++
    <cacheManagerPeerProviderFactory
         class="net.sf.ehcache.distribution.jgroups.JGroupsCacheManagerPeerProviderFactory"
         properties="channel=ehcache^connect=UDP(mcast_addr=231.12.21.132;mcast_port=45566;ip_ttl=32;
         mcast_send_buf_size=150000;mcast_recv_buf_size=80000):
         PING(timeout=2000;num_initial_members=6):
         MERGE2(min_interval=5000;max_interval=10000):
         FD_SOCK:VERIFY_SUSPECT(timeout=1500):
         pbcast.NAKACK(gc_lag=10;retransmit_timeout=3000):
         UNICAST(timeout=5000):
         pbcast.STABLE(desired_avg_gossip=20000):
         FRAG:
         pbcast.GMS(join_timeout=5000;join_retry_timeout=2000;shun=false;print_local_addr=false)"
         propertySeparator="^"
     />
     JGroups configuration is done by providing a connect string using connect= as in the above example which uses
     multicast, or since version 1.4, a file= to specify the location of a JGroups configuration file.

     If neither a connect or file property is specified, the default JGroups JChannel will be used.

     Multiple JGroups clusters may be run on the same network by specifying a different CacheManager name. The name
     is used as the cluster name.

     Since version 1.4 you can specify a channelName to avoid conflicts.


    JMSCacheManagerPeerProviderFactory
    ++++++++++++++++++++++++++++++++++
    <cacheManagerPeerProviderFactory
            class="net.sf.ehcache.distribution.jms.JMSCacheManagerPeerProviderFactory"
            properties="..."
            propertySeparator=","
            />

    The JMS PeerProviderFactory uses JNDI to maintain message queue independence. Refer to the manual for full configuration
    examples using ActiveMQ and Open Message Queue.

    Valid properties are:
    * initialContextFactoryName (mandatory) - the name of the factory used to create the message queue initial context.
    * providerURL (mandatory) - the JNDI configuration information for the service provider to use.
    * topicConnectionFactoryBindingName (mandatory) - the JNDI binding name for the TopicConnectionFactory
    * topicBindingName (mandatory) - the JNDI binding name for the topic name
    * getQueueBindingName (mandatory only if using jmsCacheLoader) - the JNDI binding name for the queue name
    * securityPrincipalName - the JNDI java.naming.security.principal
    * securityCredentials - the JNDI java.naming.security.credentials
    * urlPkgPrefixes - the JNDI java.naming.factory.url.pkgs
    * userName - the user name to use when creating the TopicConnection to the Message Queue
    * password - the password to use when creating the TopicConnection to the Message Queue
    * acknowledgementMode - the JMS Acknowledgement mode for both publisher and subscriber. The available choices are
                            AUTO_ACKNOWLEDGE, DUPS_OK_ACKNOWLEDGE and SESSION_TRANSACTED. The default is AUTO_ACKNOWLEDGE.
    -->
    <cacheManagerPeerProviderFactory
            class="net.sf.ehcache.distribution.RMICacheManagerPeerProviderFactory"
            properties="peerDiscovery=automatic,
                        multicastGroupAddress=230.0.0.1,
                        multicastGroupPort=4446, timeToLive=1"
            propertySeparator=","
            />


    <!--
    CacheManagerPeerListener
    ========================
    (Enable for distributed operation)

    Specifies a CacheManagerPeerListenerFactory which will be used to create a
    CacheManagerPeerListener, which listens for messages from cache replicators participating in the cluster.

    The attributes of cacheManagerPeerListenerFactory are:
    class - a fully qualified factory class name
    properties - comma separated properties having meaning only to the factory.

    Ehcache comes with a built-in RMI-based distribution system. The listener component is
    RMICacheManagerPeerListener which is configured using
    RMICacheManagerPeerListenerFactory. It is configured as per the following example:

    <cacheManagerPeerListenerFactory
        class="net.sf.ehcache.distribution.RMICacheManagerPeerListenerFactory"
        properties="hostName=fully_qualified_hostname_or_ip,
                    port=40001,
                    remoteObjectPort=40002,
                    socketTimeoutMillis=120000"
                    propertySeparator="," />

    All properties are optional. They are:
    * hostName - the hostName of the host the listener is running on. Specify
      where the host is multihomed and you want to control the interface over which cluster
      messages are received. Defaults to the host name of the default interface if not
      specified.
    * port - the port the RMI Registry listener listens on. This defaults to a free port if not specified.
    * remoteObjectPort - the port number on which the remote objects bound in the registry receive calls.
                         This defaults to a free port if not specified.
    * socketTimeoutMillis - the number of ms client sockets will stay open when sending
      messages to the listener. This should be long enough for the slowest message.
      If not specified it defaults to 120000ms.

    -->
    <cacheManagerPeerListenerFactory
            class="net.sf.ehcache.distribution.RMICacheManagerPeerListenerFactory"/>

    <!--
    TerracottaConfig
    ========================
    (Enable for Terracotta clustered operation)

    Note: You need to install and run one or more Terracotta servers to use Terracotta clustering.
    See http://www.terracotta.org/web/display/orgsite/Download.

    Specifies a TerracottaConfig which will be used to configure the Terracotta
    runtime for this CacheManager.

    Configuration can be specified in two main ways: by reference to a source of
    configuration or by use of an embedded Terracotta configuration file.

    To specify a reference to a source (or sources) of configuration, use the url
    attribute.  The url attribute must contain a comma-separated list of:
    * path to Terracotta configuration file (usually named tc-config.xml)
    * URL to Terracotta configuration file
    * <server host>:<port> of running Terracotta Server instance

    Simplest example for pointing to a Terracotta server on this machine:
    <terracottaConfig url="localhost:9510"/>

    This element has one attribute "rejoin" which can take values of either "true" or "false":
    <terracottaConfig rejoin="true" url="localhost:9510" />

    By default, this attribute is false.

    Without rejoin, if the Terracotta Server is restarted the client cannot connect back to the
    server. When enabled, this allows the client to connect to the new cluster without the
    need to restart the node.

    Example using a path to Terracotta configuration file:
    <terracottaConfig url="/app/config/tc-config.xml"/>

    Example using a URL to a Terracotta configuration file:
    <terracottaConfig url="http://internal/ehcache/app/tc-config.xml"/>

    Example using multiple Terracotta server instance URLs (for fault tolerance):
    <terracottaConfig url="host1:9510,host2:9510,host3:9510"/>

    To embed a Terracotta configuration file within the ehcache configuration, simply
    place a normal Terracotta XML config within the <terracottaConfig> element.

    Example:
    <terracottaConfig>
        <tc-config>
            <servers>
                <server host="server1" name="s1"/>
                <server host="server2" name="s2"/>
            </servers>
            <clients>
                <logs>app/logs-%i</logs>
            </clients>
        </tc-config>
    </terracottaConfig>

    For more information on the Terracotta configuration, see the Terracotta documentation.
    -->

    <!--
    Cache configuration
    ===================

    The following attributes are required.

    name:
    Sets the name of the cache. This is used to identify the cache. It must be unique.

    The following attributes and elements are optional.

    maxEntriesLocalHeap:
    Sets the maximum number of objects that will be held on heap memory.  0 = no limit.

    maxEntriesLocalDisk:
    Sets the maximum number of objects that will be maintained in the DiskStore
    The default value is zero, meaning unlimited.

    eternal:
    Sets whether elements are eternal. If eternal,  timeouts are ignored and the
    element is never expired.

    maxEntriesInCache:
    This feature is applicable only to Terracotta distributed caches.
    Sets the maximum number of entries that can be stored in the cluster. 0 = no limit.
    Note that clustered cache will still perform eviction if resource usage requires it.
    This property can be modified dynamically while the cache is operating.

    overflowToOffHeap:
    (boolean) This feature is available only in enterprise versions of Ehcache.
    When set to true, enables the cache to utilize off-heap memory
    storage to improve performance. Off-heap memory is not subject to Java
    GC. The default value is false.

    maxBytesLocalHeap:
    Defines how many bytes the cache may use from the VM's heap. If a CacheManager
    maxBytesLocalHeap has been defined, this Cache's specified amount will be
    subtracted from the CacheManager. Other caches will share the remainder.
    This attribute's values are given as <number>k|K|m|M|g|G for
    kilobytes (k|K), megabytes (m|M), or gigabytes (g|G).
    For example, maxBytesLocalHeap="2g" allots 2 gigabytes of heap memory.
    If you specify a maxBytesLocalHeap, you can't use the maxEntriesLocalHeap attribute.
    maxEntriesLocalHeap can't be used if a CacheManager maxBytesLocalHeap is set.

    Elements put into the cache will be measured in size using net.sf.ehcache.pool.sizeof.SizeOf
    If you wish to ignore some part of the object graph, see net.sf.ehcache.pool.sizeof.annotations.IgnoreSizeOf

    maxBytesLocalOffHeap:
    This feature is available only in enterprise versions of Ehcache.
    Sets the amount of off-heap memory this cache can use, and will reserve.

    This setting will set overflowToOffHeap to true. Set explicitly to false to disable overflow behavior.

    Note that it is recommended to set maxEntriesLocalHeap to at least 100 elements
    when using an off-heap store, otherwise performance will be seriously degraded,
    and a warning will be logged.

    The minimum amount that can be allocated is 128MB. There is no maximum.

    maxBytesLocalDisk:
    As for maxBytesLocalHeap, but specifies the limit of disk storage this cache will ever use.

    timeToIdleSeconds:
    Sets the time to idle for an element before it expires.
    i.e. The maximum amount of time between accesses before an element expires
    Is only used if the element is not eternal.
    Optional attribute. A value of 0 means that an Element can idle for infinity.
    The default value is 0.

    timeToLiveSeconds:
    Sets the time to live for an element before it expires.
    i.e. The maximum time between creation time and when an element expires.
    Is only used if the element is not eternal.
    Optional attribute. A value of 0 means that and Element can live for infinity.
    The default value is 0.

    diskExpiryThreadIntervalSeconds:
    The number of seconds between runs of the disk expiry thread. The default value
    is 120 seconds.

    diskSpoolBufferSizeMB:
    This is the size to allocate the DiskStore for a spool buffer. Writes are made
    to this area and then asynchronously written to disk. The default size is 30MB.
    Each spool buffer is used only by its cache. If you get OutOfMemory errors consider
    lowering this value. To improve DiskStore performance consider increasing it. Trace level
    logging in the DiskStore will show if put back ups are occurring.

    clearOnFlush:
    whether the MemoryStore should be cleared when flush() is called on the cache.
    By default, this is true i.e. the MemoryStore is cleared.

    memoryStoreEvictionPolicy:
    Policy would be enforced upon reaching the maxEntriesLocalHeap limit. Default
    policy is Least Recently Used (specified as LRU). Other policies available -
    First In First Out (specified as FIFO) and Less Frequently Used
    (specified as LFU)

    copyOnRead:
    Whether an Element is copied when being read from a cache.
    By default this is false.

    copyOnWrite:
    Whether an Element is copied when being added to the cache.
    By default this is false.

    Cache persistence is configured through the persistence sub-element.  The attributes of the
    persistence element are:

    strategy:
    Configures the type of persistence provided by the configured cache.  This must be one of the
    following values:

    * localRestartable - Enables the RestartStore and copies all cache entries (on-heap and/or off-heap)
    to disk. This option provides fast restartability with fault tolerant cache persistence on disk.
    It is available for Enterprise Ehcache users only.

    * localTempSwap - Swaps cache entries (on-heap and/or off-heap) to disk when the cache is full.
    "localTempSwap" is not persistent.

    * none - Does not persist cache entries.

    * distributed - Defers to the <terracotta> configuration for persistence settings. This option
    is not applicable for standalone.
    
    synchronousWrites:
    When set to true write operations on the cache do not return until after the operations data has been
    successfully flushed to the disk storage.  This option is only valid when used with the "localRestartable"
    strategy, and defaults to false.

    The following example configuration shows a cache configured for localTempSwap restartability.

    <cache name="persistentCache" maxEntriesLocalHeap="1000">
        <persistence strategy="localTempSwap"/>
    </cache>

    Cache elements can also contain sub elements which take the same format of a factory class
    and properties. Defined sub-elements are:

    * cacheEventListenerFactory - Enables registration of listeners for cache events, such as
      put, remove, update, and expire.

    * bootstrapCacheLoaderFactory - Specifies a BootstrapCacheLoader, which is called by a
      cache on initialisation to prepopulate itself.

    * cacheExtensionFactory - Specifies a CacheExtension, a generic mechanism to tie a class
      which holds a reference to a cache to the cache lifecycle.

    * cacheExceptionHandlerFactory - Specifies a CacheExceptionHandler, which is called when
      cache exceptions occur.

    * cacheLoaderFactory - Specifies a CacheLoader, which can be used both asynchronously and
      synchronously to load objects into a cache. More than one cacheLoaderFactory element
      can be added, in which case the loaders form a chain which are executed in order. If a
      loader returns null, the next in chain is called.

    * copyStrategy - Specifies a fully qualified class which implements
      net.sf.ehcache.store.compound.CopyStrategy. This strategy will be used for copyOnRead
      and copyOnWrite in place of the default which is serialization.

    Example of cache level resource tuning:
    <cache name="memBound" maxBytesLocalHeap="100m" maxBytesLocalOffHeap="4g" maxBytesLocalDisk="200g" />


    Cache Event Listeners
    +++++++++++++++++++++

    All cacheEventListenerFactory elements can take an optional property listenFor that describes
    which events will be delivered in a clustered environment.  The listenFor attribute has the
    following allowed values:

    * all - the default is to deliver all local and remote events
    * local - deliver only events originating in the current node
    * remote - deliver only events originating in other nodes

    Example of setting up a logging listener for local cache events:

    <cacheEventListenerFactory class="my.company.log.CacheLogger"
        listenFor="local" />


    Search
    ++++++

    A <cache> can be made searchable by adding a <searchable/> sub-element. By default the keys
    and value objects of elements put into the cache will be attributes against which
    queries can be expressed.

    <cache>
        <searchable/>
    </cache>


    An "attribute" of the cache elements can also be defined to be searchable. In the example below
    an attribute with the name "age" will be available for use in queries. The value for the "age"
    attribute will be computed by calling the method "getAge()" on the value object of each element
    in the cache. See net.sf.ehcache.search.attribute.ReflectionAttributeExtractor for the format of
    attribute expressions. Attribute values must also conform to the set of types documented in the
    net.sf.ehcache.search.attribute.AttributeExtractor interface

    <cache>
        <searchable>
            <searchAttribute name="age" expression="value.getAge()"/>
        </searchable>
    </cache>


    Attributes may also be defined using a JavaBean style. With the following attribute declaration
    a public method getAge() will be expected to be found on either the key or value for cache elements

    <cache>
        <searchable>
            <searchAttribute name="age"/>
        </searchable>
    </cache>

    In more complex situations you can create your own attribute extractor by implementing the
    AttributeExtractor interface. Providing your extractor class is shown in the following example:

    <cache>
        <searchable>
            <searchAttribute name="age" class="com.example.MyAttributeExtractor"/>
        </searchable>
    </cache>

    Use properties to pass state to your attribute extractor if needed. Your implementation must provide
    a public constructor that takes a single java.util.Properties instance

    <cache>
        <searchable>
            <searchAttribute name="age" class="com.example.MyAttributeExtractor" properties="foo=1,bar=2"/>
        </searchable>
    </cache>
    
    Attributes may also be defined with an optional type constraint on their values. The type specified 
    must be one of the supported types, or resolve to an enum. It is possible to use either a fully 
    qualified name of the class that represents the type, or its shortened version when the type is not
    an enum. The type names are case sensitive, i.e. "double" is distinct from "Double".
    
    <cache>
        <searchable>
           <searchAttribute name="address" type="java.lang.String" expression="value.address.toString()"/>
           <searchAttribute name="income" type="Long"/>
           <searchAttribute name="age" type="int"/>
           <searchAttribute name="gender" expression="value.gender" type="com.example.Gender"/>
        <searchable>
    </cache>

    If you intend to use dynamic attribute extraction (see net.sf.ehcache.Cache.registerDynamicAttributesExtractor) then
    you need to enable it as follows:

    <cache>
        <searchable allowDynamicIndexing="true"/>
    </cache>


    RMI Cache Replication
    +++++++++++++++++++++

    Each cache that will be distributed needs to set a cache event listener which replicates
    messages to the other CacheManager peers. For the built-in RMI implementation this is done
    by adding a cacheEventListenerFactory element of type RMICacheReplicatorFactory to each
    distributed cache's configuration as per the following example:

    <cacheEventListenerFactory class="net.sf.ehcache.distribution.RMICacheReplicatorFactory"
         properties="replicateAsynchronously=true,
         replicatePuts=true,
         replicatePutsViaCopy=false,
         replicateUpdates=true,
         replicateUpdatesViaCopy=true,
         replicateRemovals=true,
         asynchronousReplicationIntervalMillis=<number of milliseconds>,
         asynchronousReplicationMaximumBatchSize=<number of operations>"
         propertySeparator="," />

    The RMICacheReplicatorFactory recognises the following properties:

    * replicatePuts=true|false - whether new elements placed in a cache are
      replicated to others. Defaults to true.

    * replicatePutsViaCopy=true|false - whether the new elements are
      copied to other caches (true), or whether a remove message is sent. Defaults to true.

    * replicateUpdates=true|false - whether new elements which override an
      element already existing with the same key are replicated. Defaults to true.

    * replicateRemovals=true - whether element removals are replicated. Defaults to true.

    * replicateAsynchronously=true | false - whether replications are
      asynchronous (true) or synchronous (false). Defaults to true.

    * replicateUpdatesViaCopy=true | false - whether the new elements are
      copied to other caches (true), or whether a remove message is sent. Defaults to true.

    * asynchronousReplicationIntervalMillis=<number of milliseconds> - The asynchronous
      replicator runs at a set interval of milliseconds. The default is 1000. The minimum
      is 10. This property is only applicable if replicateAsynchronously=true

    * asynchronousReplicationMaximumBatchSize=<number of operations> - The maximum
      number of operations that will be batch within a single RMI message.  The default
      is 1000. This property is only applicable if replicateAsynchronously=true

    JGroups Replication
    +++++++++++++++++++

    For the Jgroups replication this is done with:
    <cacheEventListenerFactory class="net.sf.ehcache.distribution.jgroups.JGroupsCacheReplicatorFactory"
                            properties="replicateAsynchronously=true, replicatePuts=true,
               replicateUpdates=true, replicateUpdatesViaCopy=false,
               replicateRemovals=true,asynchronousReplicationIntervalMillis=1000"/>
    This listener supports the same properties as the RMICacheReplicationFactory.


    JMS Replication
    +++++++++++++++

    For JMS-based replication this is done with:
    <cacheEventListenerFactory
          class="net.sf.ehcache.distribution.jms.JMSCacheReplicatorFactory"
          properties="replicateAsynchronously=true,
                       replicatePuts=true,
                       replicateUpdates=true,
                       replicateUpdatesViaCopy=true,
                       replicateRemovals=true,
                       asynchronousReplicationIntervalMillis=1000"
           propertySeparator=","/>

    This listener supports the same properties as the RMICacheReplicationFactory.

    Cluster Bootstrapping
    +++++++++++++++++++++

    Bootstrapping a cluster may use a different mechanism to replication. e.g you can mix
    JMS replication with bootstrap via RMI - just make sure you have the cacheManagerPeerProviderFactory
    and cacheManagerPeerListenerFactory configured.

    There are two bootstrapping mechanisms: RMI and JGroups.

    RMI Bootstrap

    The RMIBootstrapCacheLoader bootstraps caches in clusters where RMICacheReplicators are
    used. It is configured as per the following example:

    <bootstrapCacheLoaderFactory
        class="net.sf.ehcache.distribution.RMIBootstrapCacheLoaderFactory"
        properties="bootstrapAsynchronously=true, maximumChunkSizeBytes=5000000"
        propertySeparator="," />

    The RMIBootstrapCacheLoaderFactory recognises the following optional properties:

    * bootstrapAsynchronously=true|false - whether the bootstrap happens in the background
      after the cache has started. If false, bootstrapping must complete before the cache is
      made available. The default value is true.

    * maximumChunkSizeBytes=<integer> - Caches can potentially be very large, larger than the
      memory limits of the VM. This property allows the bootstraper to fetched elements in
      chunks. The default chunk size is 5000000 (5MB).

    JGroups Bootstrap

    Here is an example of bootstrap configuration using JGroups boostrap:

    <bootstrapCacheLoaderFactory class="net.sf.ehcache.distribution.jgroups.JGroupsBootstrapCacheLoaderFactory"
                                    properties="bootstrapAsynchronously=true"/>

    The configuration properties are the same as for RMI above. Note that JGroups bootstrap only supports
    asynchronous bootstrap mode.


    Cache Exception Handling
    ++++++++++++++++++++++++

    By default, most cache operations will propagate a runtime CacheException on failure. An
    interceptor, using a dynamic proxy, may be configured so that a CacheExceptionHandler can
    be configured to intercept Exceptions. Errors are not intercepted.

    It is configured as per the following example:

      <cacheExceptionHandlerFactory class="com.example.ExampleExceptionHandlerFactory"
                                      properties="logLevel=FINE"/>

    Caches with ExceptionHandling configured are not of type Cache, but are of type Ehcache only,
    and are not available using CacheManager.getCache(), but using CacheManager.getEhcache().


    Cache Loader
    ++++++++++++

    A default CacheLoader may be set which loads objects into the cache through asynchronous and
    synchronous methods on Cache. This is different to the bootstrap cache loader, which is used
    only in distributed caching.

    It is configured as per the following example:

        <cacheLoaderFactory class="com.example.ExampleCacheLoaderFactory"
                                      properties="type=int,startCounter=10"/>

    Element value comparator
    ++++++++++++++++++++++++

    These two cache atomic methods:
      removeElement(Element e)
      replace(Element old, Element element)

    rely on comparison of cached elements value. The default implementation relies on Object.equals()
    but that can be changed in case you want to use a different way to compute equality of two elements.

    This is configured as per the following example:

    <elementValueComparator class="com.company.xyz.MyElementComparator"/>

    The MyElementComparator class must implement the is net.sf.ehcache.store.ElementValueComparator
    interface. The default implementation is net.sf.ehcache.store.DefaultElementValueComparator.


    SizeOf Policy
    +++++++++++++

    Control how deep the SizeOf engine can go when sizing on-heap elements.

    This is configured as per the following example:

    <sizeOfPolicy maxDepth="100" maxDepthExceededBehavior="abort"/>

    maxDepth controls how many linked objects can be visited before the SizeOf engine takes any action.
    maxDepthExceededBehavior specifies what happens when the max depth is exceeded while sizing an object graph.
     "continue" makes the SizeOf engine log a warning and continue the sizing. This is the default.
     "abort"    makes the SizeOf engine abort the sizing, log a warning and mark the cache as not correctly tracking
                memory usage. This makes Ehcache.hasAbortedSizeOf() return true when this happens.

    The SizeOf policy can be configured at the cache manager level (directly under <ehcache>) and at
    the cache level (under <cache> or <defaultCache>). The cache policy always overrides the cache manager
    one if both are set. This element has no effect on distributed caches.
    
    Transactions
    ++++++++++++

    To enable an ehcache as transactions, set the transactionalMode

    transactionalMode="xa" - high performance JTA/XA implementation
    transactionalMode="xa_strict" - canonically correct JTA/XA implementation
    transactionMode="local" - high performance local transactions involving caches only
    transactionalMode="off" - the default, no transactions

    If set, all cache operations will need to be done through transactions.

    To prevent users keeping references on stored elements and modifying them outside of any transaction's control,
    transactions also require the cache to be configured copyOnRead and copyOnWrite.

    CacheWriter
    ++++++++++++

    A CacheWriter can be set to write to an underlying resource. Only one CacheWriter can be
    configured per cache.

    The following is an example of how to configure CacheWriter for write-through:

        <cacheWriter writeMode="write-through" notifyListenersOnException="true">
            <cacheWriterFactory class="net.sf.ehcache.writer.TestCacheWriterFactory"
                                properties="type=int,startCounter=10"/>
        </cacheWriter>

    The following is an example of how to configure CacheWriter for write-behind:

        <cacheWriter writeMode="write-behind" minWriteDelay="1" maxWriteDelay="5"
                     rateLimitPerSecond="5" writeCoalescing="true" writeBatching="true" writeBatchSize="1"
                     retryAttempts="2" retryAttemptDelaySeconds="1">
            <cacheWriterFactory class="net.sf.ehcache.writer.TestCacheWriterFactory"
                                properties="type=int,startCounter=10"/>
        </cacheWriter>

    The cacheWriter element has the following attributes:
    * writeMode: the write mode, write-through or write-behind

    These attributes only apply to write-through mode:
    * notifyListenersOnException: Sets whether to notify listeners when an exception occurs on a writer operation.

    These attributes only apply to write-behind mode:
    * minWriteDelay: Set the minimum number of seconds to wait before writing behind. If set to a value greater than 0,
      it permits operations to build up in the queue. This is different from the maximum write delay in that by waiting
      a minimum amount of time, work is always being built up. If the minimum write delay is set to zero and the
      CacheWriter performs its work very quickly, the overhead of processing the write behind queue items becomes very
      noticeable in a cluster since all the operations might be done for individual items instead of for a collection
      of them.
    * maxWriteDelay: Set the maximum number of seconds to wait before writing behind. If set to a value greater than 0,
      it permits operations to build up in the queue to enable effective coalescing and batching optimisations.
    * writeBatching: Sets whether to batch write operations. If set to true, writeAll and deleteAll will be called on
      the CacheWriter rather than write and delete being called for each key. Resources such as databases can perform
      more efficiently if updates are batched, thus reducing load.
    * writeBatchSize: Sets the number of operations to include in each batch when writeBatching is enabled. If there are
      less entries in the write-behind queue than the batch size, the queue length size is used.
    * rateLimitPerSecond: Sets the maximum number of write operations to allow per second when writeBatching is enabled.
    * writeCoalescing: Sets whether to use write coalescing. If set to true and multiple operations on the same key are
      present in the write-behind queue, only the latest write is done, as the others are redundant.
    * retryAttempts: Sets the number of times the operation is retried in the CacheWriter, this happens after the
      original operation.
    * retryAttemptDelaySeconds: Sets the number of seconds to wait before retrying an failed operation.

    Pinning
    +++++++

    Use this element when data should remain in the cache regardless of resource constraints.
    Unexpired entries can never be flushed to a lower tier or be evicted.

    This element has a required attribute (store) to specify which data tiers the cache should be pinned to:
    * localMemory: Cache data is pinned to the local heap (or off-heap for BigMemory Go and BigMemory Max).
    * inCache: Cache data is pinned in the cache, which can be in any tier cache data is stored.

    Example:
        <pinning store="inCache"/>

    Cache Extension
    +++++++++++++++

    CacheExtensions are a general purpose mechanism to allow generic extensions to a Cache.
    CacheExtensions are tied into the Cache lifecycle.

    CacheExtensions are created using the CacheExtensionFactory which has a
    <code>createCacheCacheExtension()</code> method which takes as a parameter a
    Cache and properties. It can thus call back into any public method on Cache, including, of
    course, the load methods.

    Extensions are added as per the following example:

         <cacheExtensionFactory class="com.example.FileWatchingCacheRefresherExtensionFactory"
                             properties="refreshIntervalMillis=18000, loaderTimeout=3000,
                                         flushPeriod=whatever, someOtherProperty=someValue ..."/>

    Cache Decorator Factory
    +++++++++++++++++++++++

    Cache decorators can be configured directly in ehcache.xml. The decorators will be created and added to the CacheManager.
    It accepts the name of a concrete class that extends net.sf.ehcache.constructs.CacheDecoratorFactory
    The properties will be parsed according to the delimiter (default is comma ',') and passed to the concrete factory's
    <code>createDecoratedEhcache(Ehcache cache, Properties properties)</code> method along with the reference to the owning cache.

    It is configured as per the following example:

        <cacheDecoratorFactory
      class="com.company.DecoratedCacheFactory"
      properties="property1=true ..." />

    Distributed Caching with Terracotta
    +++++++++++++++++++++++++++++++++++

    Distributed Caches connect to a Terracotta Server Array. They are configured with the <terracotta> sub-element.

    The <terracotta> sub-element has the following attributes:

    * clustered=true|false - indicates whether this cache should be clustered (distributed) with Terracotta. By
      default, if the <terracotta> element is included, clustered=true.

    * copyOnRead=true|false - indicates whether cache values are deserialized on every read or if the
      materialized cache value can be re-used between get() calls. This setting is useful if a cache
      is being shared by callers with disparate classloaders or to prevent local drift if keys/values
      are mutated locally without being put back in the cache.

      The default is false.

    * consistency=strong|eventual - Indicates whether this cache should have strong consistency or eventual
      consistency. The default is eventual. See the documentation for the meaning of these terms.

    * synchronousWrites=true|false

      Synchronous writes (synchronousWrites="true")  maximize data safety by blocking the client thread until
      the write has been written to the Terracotta Server Array.

      This option is only available with consistency=strong. The default is false.

    * concurrency - the number of segments that will be used by the map underneath the Terracotta Store.
      Its optional and has default value of 0, which means will use default values based on the internal
      Map being used underneath the store.

      This value cannot be changed programmatically once a cache is initialized.

    The <terracotta> sub-element also has a <nonstop> sub-element to allow configuration of cache behaviour if a distributed
    cache operation cannot be completed within a set time or in the event of a clusterOffline message. If this element does not appear, nonstop behavior is off.

    <nonstop> has the following attributes:

    *  enabled="true" - defaults to true.

    *  timeoutMillis - An SLA setting, so that if a cache operation takes longer than the allowed ms, it will timeout.

    *  searchTimeoutMillis - If a cache search operation in the nonstop mode takes longer than the allowed ms, it will timeout.

    *  immediateTimeout="true|false" - What to do on receipt of a ClusterOffline event indicating that communications
       with the Terracotta Server Array were interrupted.

    <nonstop> has one sub-element, <timeoutBehavior> which has the following attribute:

    *  type="noop|exception|localReads|localReadsAndExceptionOnWrite" - What to do when a timeout has occurred. Exception is the default.

    Simplest example to indicate clustering:
        <terracotta/>

    To indicate the cache should not be clustered (or remove the <terracotta> element altogether):
        <terracotta clustered="false"/>

    To indicate the cache should be clustered using "eventual" consistency mode for better performance :
        <terracotta clustered="true" consistency="eventual"/>

    To indicate the cache should be clustered using synchronous-write locking level:
        <terracotta clustered="true" synchronousWrites="true"/>
    -->

    <!--
    Default Cache configuration. These settings will be applied to caches
    created programmatically using CacheManager.add(String cacheName).
    This element is optional, and using CacheManager.add(String cacheName) when
    its not present will throw CacheException

    The defaultCache has an implicit name "default" which is a reserved cache name.
    -->
    <defaultCache
            maxEntriesLocalHeap="10000"
            eternal="false"
            timeToIdleSeconds="120"
            timeToLiveSeconds="120"
            diskSpoolBufferSizeMB="30"
            maxEntriesLocalDisk="10000000"
            diskExpiryThreadIntervalSeconds="120"
            memoryStoreEvictionPolicy="LRU">
        <persistence strategy="localTempSwap"/>
    </defaultCache>

    <!--
    Sample caches. Following are some example caches. Remove these before use.
    -->

    <!--
    Sample cache named sampleCache1
    This cache contains a maximum in memory of 10000 elements, and will expire
    an element if it is idle for more than 5 minutes and lives for more than
    10 minutes.

    If there are more than 10000 elements it will overflow to the
    disk cache, which in this configuration will go to wherever java.io.tmp is
    defined on your system. On a standard Linux system this will be /tmp"
    -->
    <cache name="sampleCache1"
           maxEntriesLocalHeap="10000"
           maxEntriesLocalDisk="1000"
           eternal="false"
           diskSpoolBufferSizeMB="20"
           timeToIdleSeconds="300"
           timeToLiveSeconds="600"
           memoryStoreEvictionPolicy="LFU"
           transactionalMode="off">
        <persistence strategy="localTempSwap"/>
    </cache>


    <!--
    Sample cache named sampleCache2
    This cache has a maximum of 1000 elements in memory. There is no overflow to disk, so 1000
    is also the maximum cache size. Note that when a cache is eternal, timeToLive and
    timeToIdle are not used and do not need to be specified.
    -->
    <cache name="sampleCache2"
           maxEntriesLocalHeap="1000"
           eternal="true"
           memoryStoreEvictionPolicy="FIFO"
            />


    <!--
    Sample cache named sampleCache3. This cache overflows to disk. The disk store is
    persistent between cache and VM restarts. The disk expiry thread interval is set to 10
    minutes, overriding the default of 2 minutes.
    -->
    <cache name="sampleCache3"
           maxEntriesLocalHeap="500"
           eternal="false"
           overflowToDisk="true"
           diskPersistent="true"
           timeToIdleSeconds="300"
           timeToLiveSeconds="600"
           diskExpiryThreadIntervalSeconds="1"
           memoryStoreEvictionPolicy="LFU">
    </cache>


    <!--
    Sample distributed cache named sampleReplicatedCache1.
    This cache replicates using defaults.
    It also bootstraps from the cluster, using default properties.
    -->
    <cache name="sampleReplicatedCache1"
           maxEntriesLocalHeap="10"
           eternal="false"
           timeToIdleSeconds="100"
           timeToLiveSeconds="100">

        <cacheEventListenerFactory
                class="net.sf.ehcache.distribution.RMICacheReplicatorFactory"/>
        <bootstrapCacheLoaderFactory
                class="net.sf.ehcache.distribution.RMIBootstrapCacheLoaderFactory"/>
    </cache>


    <!--
    Sample distributed cache named sampleReplicatedCache2.
    This cache replicates using specific properties.
    It only replicates updates and does so synchronously via copy
    -->
    <cache name="sampleRepicatedCache2"
           maxEntriesLocalHeap="10"
           eternal="false"
           timeToIdleSeconds="100"
           timeToLiveSeconds="100">
        <cacheEventListenerFactory
                class="net.sf.ehcache.distribution.RMICacheReplicatorFactory"
                properties="replicateAsynchronously=false, replicatePuts=false,
                            replicatePutsViaCopy=false, replicateUpdates=true,
                            replicateUpdatesViaCopy=true, replicateRemovals=false"/>
    </cache>

    <!--
    Sample distributed cache named sampleReplicatedCache3.
    This cache replicates using defaults except that the asynchronous replication
    interval is set to 200ms.
    This one includes / and # which were illegal in ehcache 1.5.
    -->
    <cache name="sampleReplicatedCache3"
           maxEntriesLocalHeap="10"
           eternal="false"
           timeToIdleSeconds="100"
           timeToLiveSeconds="100">
        <cacheEventListenerFactory
                class="net.sf.ehcache.distribution.RMICacheReplicatorFactory"
                properties="asynchronousReplicationIntervalMillis=200"/>
        <persistence strategy="localTempSwap"/>
    </cache>

    <!--
    Sample Terracotta clustered cache named sampleTerracottaCache.
    This cache uses Terracotta to cluster the contents of the cache.
    -->
    <!--
    <cache name="sampleTerracottaCache"
           maxBytesLocalHeap="10m"
           eternal="false"
           timeToIdleSeconds="3600"
           timeToLiveSeconds="1800">
        <terracotta/>
    </cache>
    -->

    <!--
      Sample xa enabled cache named xaCache
    <cache name="xaCache"
           maxEntriesLocalHeap="500"
           eternal="false"
           timeToIdleSeconds="300"
           timeToLiveSeconds="600"
           diskExpiryThreadIntervalSeconds="1"
           transactionalMode="xa_strict">
    </cache>
    -->

    <!--
      Sample copy on both read and write cache named copyCache
      using the default (explicitly configured here as an example) ReadWriteSerializationCopyStrategy
      class could be any implementation of net.sf.ehcache.store.compound.CopyStrategy
    <cache name="copyCache"
           maxEntriesLocalHeap="500"
           eternal="false"
           timeToIdleSeconds="300"
           timeToLiveSeconds="600"
           diskExpiryThreadIntervalSeconds="1"
           copyOnRead="true"
           copyOnWrite="true">
        <copyStrategy class="net.sf.ehcache.store.compound.ReadWriteSerializationCopyStrategy" />
    </cache>
    -->
    <!--
      Sample, for Enterprise Ehcache only, demonstrating a tiered cache with in-memory, off-heap and disk stores. In this example the in-memory (on-heap) store is limited to 10,000 items ... which for example for 1k items would use 10MB of memory, the off-heap store is limited to 4GB and the disk store is unlimited in size.
    <cache name="tieredCache"
           maxEntriesLocalHeap="10000"
           eternal="false"
           timeToLiveSeconds="600"
           overflowToOffHeap="true"
           maxBytesLocalOffHeap="4g"
           diskExpiryThreadIntervalSeconds="1">
        <persistence strategy="localTempSwap"/>
     </cache>
    -->
    <!--
      Sample, for Enterprise Ehcache only, demonstrating a restartable cache with in-memory and off-heap stores.
    <cache name="restartableCache"
           maxEntriesLocalHeap="10000"
           eternal="true"
           overflowToOffHeap="true"
           maxBytesLocalOffHeap="4g"
         <persistence strategy="localRestartable"/>
     </cache>
     -->
</ehcache>
查看文档

http://www.ehcache.org/ehcache.xsd

http://www.ehcache.org/ehcache.xml

推荐文档:http://www.ehcache.org/documentation/EhcacheUserGuide-1.2.3.pdf

 

posted on 2016-08-05 17:49  zno2  阅读(855)  评论(0编辑  收藏  举报

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