/* GENERATED SOURCE. DO NOT MODIFY. */
// © 2016 and later: Unicode, Inc. and others.
// License & terms of use: http://www.unicode.org/copyright.html
/*
*******************************************************************************
* Copyright (C) 2010-2016, International Business Machines
* Corporation and others. All Rights Reserved.
*******************************************************************************
*/
package android.icu.impl;
import java.util.concurrent.ConcurrentHashMap;
/**
* Generic, thread-safe cache implementation, usually storing cached instances
* in {@link java.lang.ref.Reference}s via {@link CacheValue}s.
* To use, instantiate a subclass which implements the createInstance() method,
* and call get() with the key and the data. The get() call will use the data
* only if it needs to call createInstance(), otherwise the data is ignored.
*
* When caching instances while the CacheValue "strength" is {@code SOFT},
* the Java runtime can later release these instances once they are not used any more at all.
* If such an instance is then requested again,
* the getInstance() method will call createInstance() again and reset the CacheValue.
* The cache holds on to its map of keys to CacheValues forever.
*
*
A value can be null if createInstance() returns null.
* In this case, it must do so consistently for the same key and data.
*
* @param Cache lookup key type
* @param Cache instance value type (must not be a CacheValue)
* @param Data type for creating a new instance value
*
* @author Markus Scherer, Mark Davis
* @hide Only a subset of ICU is exposed in Android
*/
public abstract class SoftCache extends CacheBase {
private ConcurrentHashMap map = new ConcurrentHashMap();
@SuppressWarnings("unchecked")
@Override
public final V getInstance(K key, D data) {
// We synchronize twice, once in the ConcurrentHashMap and
// once in valueRef.resetIfCleared(value),
// because we prefer the fine-granularity locking of the ConcurrentHashMap
// over coarser locking on the whole cache instance.
// We use a CacheValue (a second level of indirection) because
// ConcurrentHashMap.putIfAbsent() never replaces the key's value, and if it were
// a simple Reference we would not be able to reset its value after it has been cleared.
// (And ConcurrentHashMap.put() always replaces the value, which we don't want either.)
Object mapValue = map.get(key);
if(mapValue != null) {
if(!(mapValue instanceof CacheValue)) {
// The value was stored directly.
return (V)mapValue;
}
CacheValue cv = (CacheValue)mapValue;
if(cv.isNull()) {
return null;
}
V value = cv.get();
if(value != null) {
return value;
}
// The instance has been evicted, its Reference cleared.
// Create and set a new instance.
value = createInstance(key, data);
return cv.resetIfCleared(value);
} else /* valueRef == null */ {
// We had never cached an instance for this key.
V value = createInstance(key, data);
mapValue = (value != null && CacheValue.futureInstancesWillBeStrong()) ?
value : CacheValue.getInstance(value);
mapValue = map.putIfAbsent(key, mapValue);
if(mapValue == null) {
// Normal "put": Our new value is now cached.
return value;
}
// Race condition: Another thread beat us to putting a CacheValue
// into the map. Return its value, but just in case the garbage collector
// was aggressive, we also offer our new instance for caching.
if(!(mapValue instanceof CacheValue)) {
// The value was stored directly.
return (V)mapValue;
}
CacheValue cv = (CacheValue)mapValue;
return cv.resetIfCleared(value);
}
}
}