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Chapter 5. Using the JCache API
Data Grid provides an implementation of the JCache (JSR-107) API that specifies a standard Java API for caching temporary Java objects in memory. Caching Java objects can help get around bottlenecks arising from using data that is expensive to retrieve or data that is hard to calculate. Caching these type of objects in memory can help speed up application performance by retrieving the data directly from memory instead of doing an expensive roundtrip or recalculation.
5.1. Store and retrieve data
Even though JCache API does not extend neither java.util.Map not java.util.concurrent.ConcurrentMap, it providers a key/value API to store and retrieve data:
import javax.cache.*; import javax.cache.configuration.*; CacheManager cacheManager = Caching.getCachingProvider().getCacheManager(); Cache<String, String> cache = cacheManager.createCache("namedCache", new MutableConfiguration<String, String>()); cache.put("hello", "world"); // Notice that javax.cache.Cache.put(K) returns void! String value = cache.get("hello"); // Returns "world"
Contrary to standard java.util.Map, javax.cache.Cache comes with two basic put methods called put and getAndPut. The former returns void
whereas the latter returns the previous value associated with the key. So, the equivalent of java.util.Map.put(K) in JCache is javax.cache.Cache.getAndPut(K).
Even though JCache API only covers standalone caching, it can be plugged with a persistence store, and has been designed with clustering or distribution in mind. The reason why javax.cache.Cache offers two put methods is because standard java.util.Map put call forces implementors to calculate the previous value. When a persistent store is in use, or the cache is distributed, returning the previous value could be an expensive operation, and often users call standard java.util.Map.put(K) without using the return value. Hence, JCache users need to think about whether the return value is relevant to them, in which case they need to call javax.cache.Cache.getAndPut(K) , otherwise they can call java.util.Map.put(K, V) which avoids returning the potentially expensive operation of returning the previous value.
5.2. Comparing java.util.concurrent.ConcurrentMap and javax.cache.Cache APIs
Here’s a brief comparison of the data manipulation APIs provided by java.util.concurrent.ConcurrentMap and javax.cache.Cache APIs.
Operation | java.util.concurrent.ConcurrentMap<K, V> | javax.cache.Cache<K, V> |
---|---|---|
store and no return | N/A |
|
store and return previous value |
|
|
store if not present |
|
|
retrieve |
|
|
delete if present |
|
|
delete and return previous value |
|
|
delete conditional |
|
|
replace if present |
|
|
replace and return previous value |
|
|
replace conditional |
|
|
Comparing the two APIs, it’s obvious to see that, where possible, JCache avoids returning the previous value to avoid operations doing expensive network or IO operations. This is an overriding principle in the design of JCache API. In fact, there’s a set of operations that are present in java.util.concurrent.ConcurrentMap , but are not present in the javax.cache.Cache because they could be expensive to compute in a distributed cache. The only exception is iterating over the contents of the cache:
Operation | java.util.concurrent.ConcurrentMap<K, V> | javax.cache.Cache<K, V> |
---|---|---|
calculate size of cache |
| N/A |
return all keys in the cache |
| N/A |
return all values in the cache |
| N/A |
return all entries in the cache |
| N/A |
iterate over the cache |
use |
|
5.3. Clustering JCache instances
Data Grid JCache implementation goes beyond the specification in order to provide the possibility to cluster caches using the standard API. Given a Data Grid configuration file configured to replicate caches like this:
infinispan.xml
<infinispan> <cache-container default-cache="namedCache"> <transport cluster="jcache-cluster" /> <replicated-cache name="namedCache" /> </cache-container> </infinispan>
You can create a cluster of caches using this code:
import javax.cache.*; import java.net.URI; // For multiple Cache Managers to be constructed with the standard JCache API // and live in the same JVM, either their names, or their classloaders, must // be different. // This example shows how to force their classloaders to be different. // An alternative method would have been to duplicate the XML file and give // it a different name, but this results in unnecessary file duplication. ClassLoader tccl = Thread.currentThread().getContextClassLoader(); CacheManager cacheManager1 = Caching.getCachingProvider().getCacheManager( URI.create("infinispan-jcache-cluster.xml"), new TestClassLoader(tccl)); CacheManager cacheManager2 = Caching.getCachingProvider().getCacheManager( URI.create("infinispan-jcache-cluster.xml"), new TestClassLoader(tccl)); Cache<String, String> cache1 = cacheManager1.getCache("namedCache"); Cache<String, String> cache2 = cacheManager2.getCache("namedCache"); cache1.put("hello", "world"); String value = cache2.get("hello"); // Returns "world" if clustering is working // -- public static class TestClassLoader extends ClassLoader { public TestClassLoader(ClassLoader parent) { super(parent); } }