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/*
 * Copyright (c) 2011, 2019 Oracle and/or its affiliates. All rights reserved.
 *
 * This program and the accompanying materials are made available under the
 * terms of the Eclipse Public License v. 2.0 which is available at
 * http://www.eclipse.org/legal/epl-2.0,
 * or the Eclipse Distribution License v. 1.0 which is available at
 * http://www.eclipse.org/org/documents/edl-v10.php.
 *
 * SPDX-License-Identifier: EPL-2.0 OR BSD-3-Clause
 */

// Contributors:
//     Oracle - initial API and implementation
//     05/19/2014-2.6 Tomas Kraus
//       - 437578: Added cacheable field and updated setting isolation from parent.
package org.eclipse.persistence.descriptors;

import java.io.Serializable;
import java.util.HashMap;
import java.util.HashSet;
import java.util.List;
import java.util.Map;
import java.util.Set;

import org.eclipse.persistence.annotations.CacheCoordinationType;
import org.eclipse.persistence.annotations.CacheKeyType;
import org.eclipse.persistence.annotations.DatabaseChangeNotificationType;
import org.eclipse.persistence.config.CacheIsolationType;
import org.eclipse.persistence.exceptions.DescriptorException;
import org.eclipse.persistence.exceptions.ValidationException;
import org.eclipse.persistence.expressions.Expression;
import org.eclipse.persistence.internal.helper.ClassConstants;
import org.eclipse.persistence.internal.helper.DatabaseField;
import org.eclipse.persistence.internal.identitymaps.CacheId;
import org.eclipse.persistence.internal.identitymaps.CacheKey;
import org.eclipse.persistence.internal.security.PrivilegedAccessHelper;
import org.eclipse.persistence.internal.sessions.AbstractRecord;
import org.eclipse.persistence.internal.sessions.AbstractSession;
import org.eclipse.persistence.internal.sessions.ObjectChangeSet;
import org.eclipse.persistence.logging.SessionLog;
import org.eclipse.persistence.mappings.DatabaseMapping;
import org.eclipse.persistence.sessions.DatabaseSession;

/**
 * 

Purpose: * CachePolicy defines the cache configuration. * EclipseLink supports an integrated shared (L2) object cache. * Caching is enabled by default.
* To disable caching use:
* setCacheIsolation(CacheIsolationType.ISOLATED) * * @see ClassDescriptor */ public class CachePolicy implements Cloneable, Serializable { protected Class identityMapClass; protected int identityMapSize; protected boolean shouldAlwaysRefreshCache; protected boolean shouldOnlyRefreshCacheIfNewerVersion; protected boolean shouldDisableCacheHits; protected Class remoteIdentityMapClass; protected int remoteIdentityMapSize; protected boolean shouldAlwaysRefreshCacheOnRemote; protected boolean shouldDisableCacheHitsOnRemote; // Used only to evaluate cache isolation type in this class methods. /** * Entity @Cacheable annotation value. * This value contains Boolean value equal to annotation value or null when * no annotation was set for entity. Parent values are ignored, value refers * to current class only. * This value is set only when SharedCacheMode allows to override caching * on entity level (DISABLE_SELECTIVE or ENABLE_SELECTIVE). Default value * is null what means no annotation is present in current class. */ private Boolean cacheable = null; // this attribute is used to determine what classes should be isolated from the shared cache // and the severity of their isolation. protected CacheIsolationType cacheIsolation; /** Configures how objects will be sent via cache synchronization, if synchronization is enabled. */ protected int cacheSynchronizationType = UNDEFINED_OBJECT_CHANGE_BEHAVIOR; public static final int UNDEFINED_OBJECT_CHANGE_BEHAVIOR = 0; public static final int SEND_OBJECT_CHANGES = 1; public static final int INVALIDATE_CHANGED_OBJECTS = 2; public static final int SEND_NEW_OBJECTS_WITH_CHANGES = 3; public static final int DO_NOT_SEND_CHANGES = 4; /** Configures how the unit of work uses the session cache. */ protected int unitOfWorkCacheIsolationLevel = UNDEFINED_ISOLATATION; /* Required to resolve initialization. */ protected boolean wasDefaultUnitOfWorkCacheIsolationLevel; public static final int UNDEFINED_ISOLATATION = -1; public static final int USE_SESSION_CACHE_AFTER_TRANSACTION = 0; public static final int ISOLATE_NEW_DATA_AFTER_TRANSACTION = 1; // this is the default behaviour even when undefined. public static final int ISOLATE_CACHE_AFTER_TRANSACTION = 2; public static final int ISOLATE_FROM_CLIENT_SESSION = 3; // Entity Instances only exist in UOW and shared cache. public static final int ISOLATE_CACHE_ALWAYS = 4; /** Allow cache key type to be configured. */ protected CacheKeyType cacheKeyType; //Added for interceptor support. protected Class cacheInterceptorClass; //Added for interceptor support. protected String cacheInterceptorClassName; /** This flag controls how the MergeManager should merge an Entity when merging into the shared cache.*/ protected boolean fullyMergeEntity; /** * In certain cases and cache types it is more efficient to preFetch the cache keys from the cache when * building the results of the query. Set this flag to true to prefetch the results. */ protected boolean prefetchCacheKeys; protected Map, CacheIndex> cacheIndexes; /** Allows configuration of database change event notification. */ protected DatabaseChangeNotificationType databaseChangeNotificationType; /** * PUBLIC: * Return a new descriptor. */ public CachePolicy() { this.identityMapSize = -1; this.remoteIdentityMapSize = -1; } /** * Returns what type of database change notification an entity/descriptor should use. * This is only relevant if the persistence unit/session has been configured with a DatabaseEventListener, * such as the OracleChangeNotificationListener that receives database change events. * This allows for the EclipseLink cache to be invalidated or updated from database changes. */ public DatabaseChangeNotificationType getDatabaseChangeNotificationType() { return databaseChangeNotificationType; } /** * Configures what type of database change notification an entity/descriptor should use. * This is only relevant if the persistence unit/session has been configured with a DatabaseEventListener, * such as the OracleChangeNotificationListener that receives database change events. * This allows for the EclipseLink cache to be invalidated or updated from database changes. */ public void setDatabaseChangeNotificationType(DatabaseChangeNotificationType databaseChangeNotificationType) { this.databaseChangeNotificationType = databaseChangeNotificationType; } /** * INTERNAL: * Allow the inheritance properties of the descriptor to be initialized. * The descriptor's parent must first be initialized. */ public void initializeFromParent(CachePolicy parentPolicy, ClassDescriptor descriptor, ClassDescriptor descriptorDescriptor, AbstractSession session) throws DescriptorException { // If the parent is isolated, then the child must also be isolated. if (!parentPolicy.isSharedIsolation()) { // Do not override cache isolation when explicitly enabled by @Cacheable(true) annotation in current class. boolean copyParrent = cacheable == null || cacheable == false; if (!isIsolated() && (getCacheIsolation() != parentPolicy.getCacheIsolation()) && copyParrent) { session.log(SessionLog.WARNING, SessionLog.METADATA, "overriding_cache_isolation", new Object[]{descriptorDescriptor.getAlias(), parentPolicy.getCacheIsolation(), descriptor.getAlias(), getCacheIsolation()}); setCacheIsolation(parentPolicy.getCacheIsolation()); } } // Child must maintain the same indexes as the parent. for (CacheIndex index : parentPolicy.getCacheIndexes().values()) { addCacheIndex(index); } if ((getDatabaseChangeNotificationType() == null) && (parentPolicy.getDatabaseChangeNotificationType() != null)) { setDatabaseChangeNotificationType(parentPolicy.getDatabaseChangeNotificationType()); } if ((getCacheSynchronizationType() == UNDEFINED_OBJECT_CHANGE_BEHAVIOR) && (parentPolicy.getCacheSynchronizationType() != UNDEFINED_OBJECT_CHANGE_BEHAVIOR)) { setCacheSynchronizationType(parentPolicy.getCacheSynchronizationType()); } } /** * INTERNAL: * Initialize the cache isolation setting. * This may need to be called multiple times as notifyReferencingDescriptorsOfIsolation() can change the cache isolation. */ public void postInitialize(ClassDescriptor descriptor, AbstractSession session) throws DescriptorException { if (!isSharedIsolation()) { descriptor.notifyReferencingDescriptorsOfIsolation(session); } // PERF: If using isolated cache, then default uow isolation to always (avoids merge/double build). if ((getUnitOfWorkCacheIsolationLevel() == UNDEFINED_ISOLATATION) || this.wasDefaultUnitOfWorkCacheIsolationLevel) { this.wasDefaultUnitOfWorkCacheIsolationLevel = true; if (isIsolated()) { setUnitOfWorkCacheIsolationLevel(ISOLATE_CACHE_ALWAYS); } else if (isProtectedIsolation()) { setUnitOfWorkCacheIsolationLevel(ISOLATE_FROM_CLIENT_SESSION); } else { setUnitOfWorkCacheIsolationLevel(ISOLATE_NEW_DATA_AFTER_TRANSACTION); } } // Record that there is an isolated class in the project. if (!isSharedIsolation()) { session.getProject().setHasIsolatedClasses(true); } if (!shouldIsolateObjectsInUnitOfWork() && !descriptor.shouldBeReadOnly()) { session.getProject().setHasNonIsolatedUOWClasses(true); } } /** * INTERNAL: * Allow the inheritance properties of the descriptor to be initialized. * The descriptor's parent must first be initialized. */ public void initialize(ClassDescriptor descriptor, AbstractSession session) throws DescriptorException { if (hasCacheIndexes()) { for (CacheIndex index : getCacheIndexes().values()) { for (int count = 0; count < index.getFields().size(); count++) { index.getFields().set(count, descriptor.buildField(index.getFields().get(count))); } } } for (DatabaseMapping mapping : descriptor.getMappings()) { if (!mapping.isCacheable()) { if (isSharedIsolation()) { setCacheIsolation(CacheIsolationType.PROTECTED); } } if (mapping.isForeignReferenceMapping()) { ClassDescriptor referencedDescriptor = mapping.getReferenceDescriptor(); if (referencedDescriptor!= null) { if (isSharedIsolation() && !referencedDescriptor.getCachePolicy().isSharedIsolation()) { setCacheIsolation(CacheIsolationType.PROTECTED); } } } if (mapping.isAggregateObjectMapping()) { ClassDescriptor referencedDescriptor = mapping.getReferenceDescriptor(); if (referencedDescriptor != null) { if (isSharedIsolation() && !referencedDescriptor.getCachePolicy().isSharedIsolation()) { setCacheIsolation(CacheIsolationType.PROTECTED); } } } } if (this.databaseChangeNotificationType == null) { this.databaseChangeNotificationType = DatabaseChangeNotificationType.INVALIDATE; } if (this.cacheSynchronizationType == UNDEFINED_OBJECT_CHANGE_BEHAVIOR) { this.cacheSynchronizationType = SEND_OBJECT_CHANGES; } if ((this.databaseChangeNotificationType != DatabaseChangeNotificationType.NONE) && session.isDatabaseSession() && ((DatabaseSession)session).getDatabaseEventListener() != null) { ((DatabaseSession)session).getDatabaseEventListener().initialize(descriptor, session); } } /** * PUBLIC: * Return the cache index for the field names. */ public CacheIndex getCacheIndex(List fields) { return getCacheIndexes().get(fields); } /** * PUBLIC: * Add the cache index to the descriptor's cache settings. * This allows for cache hits to be obtained on non-primary key fields. * The primary key is always indexed in the cache. * Cache indexes are defined by their database column names. */ public void addCacheIndex(CacheIndex index) { getCacheIndexes().put(index.getFields(), index); } /** * PUBLIC: * Add the cache index to the descriptor's cache settings. * This allows for cache hits to be obtained on non-primary key fields. * The primary key is always indexed in the cache. * Cache indexes are defined by their database column names. */ public void addCacheIndex(String... fields) { addCacheIndex(new CacheIndex(fields)); } /** * PUBLIC: * Add the cache index to the descriptor's cache settings. * This allows for cache hits to be obtained on non-primary key fields. * The primary key is always indexed in the cache. * Cache indexes are defined by their database column names. */ public void addCacheIndex(DatabaseField fields[]) { addCacheIndex(new CacheIndex(fields)); } public boolean hasCacheIndexes() { return (this.cacheIndexes != null) && (!this.cacheIndexes.isEmpty()); } public Map, CacheIndex> getCacheIndexes() { if (this.cacheIndexes == null) { this.cacheIndexes = new HashMap<>(); } return this.cacheIndexes; } public void setCacheIndexes(Map, CacheIndex> cacheIndexes) { this.cacheIndexes = cacheIndexes; } @Override public CachePolicy clone() { try { return (CachePolicy)super.clone(); } catch (CloneNotSupportedException ignore) { throw new InternalError(ignore.getMessage()); } } /** * INTERNAL: * Some attributes have default values defined in Project. * If such the value for the attribute hasn't been set then the default value is assigned. */ public void assignDefaultValues(AbstractSession session) { if(this.identityMapSize == -1) { this.identityMapSize = session.getProject().getDefaultIdentityMapSize(); } if(this.identityMapClass == null) { this.identityMapClass = session.getProject().getDefaultIdentityMapClass(); } if(this.cacheIsolation == null) { this.cacheIsolation = session.getProject().getDefaultCacheIsolation(); } } /** * INTERNAL: * Convert all the class-name-based settings in this Descriptor to actual class-based * settings. This method is used when converting a project that has been built * with class names to a project with classes. * @param classLoader */ public void convertClassNamesToClasses(ClassLoader classLoader) { if (this.cacheInterceptorClass == null && this.cacheInterceptorClassName != null) { this.cacheInterceptorClass = PrivilegedAccessHelper.callDoPrivilegedWithException( () -> PrivilegedAccessHelper.getClassForName(this.cacheInterceptorClassName, true, classLoader), (ex) -> ValidationException.classNotFoundWhileConvertingClassNames(this.cacheInterceptorClassName, ex) ); } } /** * @return the fullyMergeEntity */ public boolean getFullyMergeEntity() { return fullyMergeEntity; } /** * ADVANCED: * Set what cache key type to use to store the object in the cache. */ public void setCacheKeyType(CacheKeyType cacheKeyType) { this.cacheKeyType = cacheKeyType; } /** * ADVANCED: * Return what cache key type to use to store the object in the cache. */ public CacheKeyType getCacheKeyType() { return cacheKeyType; } /** * A CacheInterceptor is an adaptor that when overridden and assigned to a Descriptor all interaction * between EclipseLink and the internal cache for that class will pass through the Interceptor. * Advanced users could use this interceptor to audit, profile or log cache access. This Interceptor * could also be used to redirect or augment the TopLink cache with an alternate cache mechanism. * EclipseLink's configurated IdentityMaps will be passed to the Interceptor constructor. * * As with IdentityMaps an entire class inheritance hierarchy will share the same interceptor. * @see org.eclipse.persistence.sessions.interceptors.CacheInterceptor */ public Class getCacheInterceptorClass(){ return this.cacheInterceptorClass; } /** * A CacheInterceptor is an adaptor that when overridden and assigned to a Descriptor all interaction * between EclipseLink and the internal cache for that class will pass through the Interceptor. * Advanced users could use this interceptor to audit, profile or log cache access. This Interceptor * could also be used to redirect or augment the TopLink cache with an alternate cache mechanism. * EclipseLink's configurated IdentityMaps will be passed to the Interceptor constructor. * * As with IdentityMaps an entire class inheritance hierarchy will share the same interceptor. * @see org.eclipse.persistence.sessions.interceptors.CacheInterceptor */ public String getCacheInterceptorClassName(){ return this.cacheInterceptorClassName; } /** * PUBLIC: * Get a value indicating the type of cache synchronization that will be used on objects of * this type. Possible values are: * SEND_OBJECT_CHANGES * INVALIDATE_CHANGED_OBJECTS * SEND_NEW_OBJECTS+WITH_CHANGES * DO_NOT_SEND_CHANGES * @return int * */ public int getCacheSynchronizationType() { return cacheSynchronizationType; } /** * INTERNAL: * Return the class of identity map to be used by this descriptor. * The default is the "SoftCacheWeakIdentityMap". */ public Class getIdentityMapClass() { return identityMapClass; } /** * PUBLIC: * Return the size of the identity map. */ public int getIdentityMapSize() { return identityMapSize; } /** * INTERNAL: * Return the class of identity map to be used by this descriptor. * The default is the "SoftCacheWeakIdentityMap". */ public Class getRemoteIdentityMapClass() { if (remoteIdentityMapClass == null) { remoteIdentityMapClass = getIdentityMapClass(); } return remoteIdentityMapClass; } /** * PUBLIC: * Return the size of the remote identity map. */ public int getRemoteIdentityMapSize() { if (remoteIdentityMapSize == -1) { remoteIdentityMapSize = getIdentityMapSize(); } return remoteIdentityMapSize; } /** * PUBLIC: * Return if for cache hits on primary key read object queries to be disabled. * * @see ClassDescriptor#disableCacheHits() */ public boolean shouldDisableCacheHits() { return shouldDisableCacheHits; } /** * PUBLIC: * Return if the remote server session cache hits on primary key read object queries is aloowed or not. * * @see ClassDescriptor#disableCacheHitsOnRemote() */ public boolean shouldDisableCacheHitsOnRemote() { return shouldDisableCacheHitsOnRemote; } /** * PUBLIC: * This method returns true if the ClassDescriptor is configured to only refresh the cache * if the data received from the database by a query is newer than the data in the cache (as determined by the * optimistic locking field). Otherwise, it returns false. * * @see #setShouldOnlyRefreshCacheIfNewerVersion */ public boolean shouldOnlyRefreshCacheIfNewerVersion() { return shouldOnlyRefreshCacheIfNewerVersion; } /** * PUBLIC: * This method returns true if the ClassDescriptor is configured to always refresh * the cache if data is received from the database by any query. Otherwise, it returns false. * * @see #setShouldAlwaysRefreshCache */ public boolean shouldAlwaysRefreshCache() { return shouldAlwaysRefreshCache; } /** * PUBLIC: * This method returns true if the ClassDescriptor is configured to always remotely * refresh the cache if data is received from the database by any query in a {@link org.eclipse.persistence.sessions.remote.RemoteSession}. * Otherwise, it returns false. * * @see #setShouldAlwaysRefreshCacheOnRemote */ public boolean shouldAlwaysRefreshCacheOnRemote() { return shouldAlwaysRefreshCacheOnRemote; } /** * PUBLIC: * Set if cache hits on primary key read object queries should be disabled. * * @see ClassDescriptor#alwaysRefreshCache() */ public void setShouldDisableCacheHits(boolean shouldDisableCacheHits) { this.shouldDisableCacheHits = shouldDisableCacheHits; } /** * PUBLIC: * Set if the remote session cache hits on primary key read object queries is allowed or not. * * @see ClassDescriptor#disableCacheHitsOnRemote() */ public void setShouldDisableCacheHitsOnRemote(boolean shouldDisableCacheHitsOnRemote) { this.shouldDisableCacheHitsOnRemote = shouldDisableCacheHitsOnRemote; } /** * PUBLIC: * When the shouldOnlyRefreshCacheIfNewerVersion argument passed into this method is true, * this method configures a ClassDescriptor to only refresh the cache if the data received from the database * by a query is newer than the data in the cache (as determined by the optimistic locking field) and as long as one of the following is true: * *

    *
  • the ClassDescriptor was configured by calling {@link ClassDescriptor#alwaysRefreshCache} or {@link ClassDescriptor#alwaysRefreshCacheOnRemote},
  • *
  • the query was configured by calling {@link org.eclipse.persistence.queries.ObjectLevelReadQuery#refreshIdentityMapResult}, or
  • *
  • the query was a call to {@link org.eclipse.persistence.sessions.Session#refreshObject}
  • *
*

* * However, if a query hits the cache, data is not refreshed regardless of how this setting is configured. For example, by default, * when a query for a single object based on its primary key is executed, OracleAS TopLink will first look in the cache for the object. * If the object is in the cache, the cached object is returned and data is not refreshed. To avoid cache hits, use * the {@link ClassDescriptor#disableCacheHits} method.

* * Also note that the {@link org.eclipse.persistence.sessions.UnitOfWork} will not refresh its registered objects.

* * When the shouldOnlyRefreshCacheIfNewerVersion argument passed into this method is false, this method * ensures that a ClassDescriptor is not configured to only refresh the cache if the data received from the database by a * query is newer than the data in the cache (as determined by the optimistic locking field). * * @see ClassDescriptor#onlyRefreshCacheIfNewerVersion * @see ClassDescriptor#dontOnlyRefreshCacheIfNewerVersion */ public void setShouldOnlyRefreshCacheIfNewerVersion(boolean shouldOnlyRefreshCacheIfNewerVersion) { this.shouldOnlyRefreshCacheIfNewerVersion = shouldOnlyRefreshCacheIfNewerVersion; } /** * PUBLIC: * When the shouldAlwaysRefreshCache argument passed into this method is true, * this method configures a ClassDescriptor to always refresh the cache if data is received from * the database by any query.

* * However, if a query hits the cache, data is not refreshed regardless of how this setting is configured. * For example, by default, when a query for a single object based on its primary key is executed, OracleAS TopLink * will first look in the cache for the object. If the object is in the cache, the cached object is returned and * data is not refreshed. To avoid cache hits, use the {@link ClassDescriptor#disableCacheHits} method.

* * Also note that the {@link org.eclipse.persistence.sessions.UnitOfWork} will not refresh its registered objects.

* * Use this property with caution because it can lead to poor performance and may refresh on queries when it is not desired. * Normally, if you require fresh data, it is better to configure a query with {@link org.eclipse.persistence.queries.ObjectLevelReadQuery#refreshIdentityMapResult}. * To ensure that refreshes are only done when required, use this method in conjunction with {@link ClassDescriptor#onlyRefreshCacheIfNewerVersion}.

* * When the shouldAlwaysRefreshCache argument passed into this method is false, this method * ensures that a ClassDescriptor is not configured to always refresh the cache if data is received from the database by any query. * * @see ClassDescriptor#alwaysRefreshCache * @see ClassDescriptor#dontAlwaysRefreshCache */ public void setShouldAlwaysRefreshCache(boolean shouldAlwaysRefreshCache) { this.shouldAlwaysRefreshCache = shouldAlwaysRefreshCache; } /** * PUBLIC: * When the shouldAlwaysRefreshCacheOnRemote argument passed into this method is true, * this method configures a ClassDescriptor to always remotely refresh the cache if data is received from * the database by any query in a {@link org.eclipse.persistence.sessions.remote.RemoteSession}. * * However, if a query hits the cache, data is not refreshed regardless of how this setting is configured. For * example, by default, when a query for a single object based on its primary key is executed, OracleAS TopLink * will first look in the cache for the object. If the object is in the cache, the cached object is returned and * data is not refreshed. To avoid cache hits, use the {@link ClassDescriptor#disableCacheHitsOnRemote} method.

* * Also note that the {@link org.eclipse.persistence.sessions.UnitOfWork} will not refresh its registered objects.

* * Use this property with caution because it can lead to poor performance and may refresh on queries when it is * not desired. Normally, if you require fresh data, it is better to configure a query with {@link org.eclipse.persistence.queries.ObjectLevelReadQuery#refreshIdentityMapResult}. * To ensure that refreshes are only done when required, use this method in conjunction with {@link ClassDescriptor#onlyRefreshCacheIfNewerVersion}.

* * When the shouldAlwaysRefreshCacheOnRemote argument passed into this method is false, * this method ensures that a ClassDescriptor is not configured to always remotely refresh the cache if data * is received from the database by any query in a {@link org.eclipse.persistence.sessions.remote.RemoteSession}. * * @see ClassDescriptor#alwaysRefreshCacheOnRemote * @see ClassDescriptor#dontAlwaysRefreshCacheOnRemote */ public void setShouldAlwaysRefreshCacheOnRemote(boolean shouldAlwaysRefreshCacheOnRemote) { this.shouldAlwaysRefreshCacheOnRemote = shouldAlwaysRefreshCacheOnRemote; } /** * PUBLIC: * Set the class of identity map to be used by this descriptor. * The default is the "FullIdentityMap". */ public void setRemoteIdentityMapClass(Class theIdentityMapClass) { remoteIdentityMapClass = theIdentityMapClass; } /** * PUBLIC: * Set the size of the identity map to be used by this descriptor. * The default is the 100. */ public void setRemoteIdentityMapSize(int identityMapSize) { remoteIdentityMapSize = identityMapSize; } /** * INTERNAL: * Set entity @Cacheable annotation value. * @param cacheable Entity @Cacheable annotation value for current class * or null if @Cacheable annotation is not set. Parent * values are ignored, value shall refer to current class only. */ public void setCacheable(Boolean cacheable) { this.cacheable = cacheable; } /** * PUBLIC: * Controls how the Entity instances will be cached. See the CacheIsolationType for details on the options. * @return the isolationType */ public CacheIsolationType getCacheIsolation() { return cacheIsolation; } /** * PUBLIC: * Controls how the Entity instances and data will be cached. See the CacheIsolationType for details on the options. * To disable all second level caching simply set CacheIsolationType.ISOLATED. Note that setting the isolation * will automatically set the corresponding cacheSynchronizationType. * ISOLATED = DO_NOT_SEND_CHANGES, PROTECTED and SHARED = SEND_OBJECT_CHANGES */ public void setCacheIsolation(CacheIsolationType isolationType) { this.cacheIsolation = isolationType; if (CacheIsolationType.ISOLATED == isolationType) { // bug 3587273 - set the cache synchronization type so isolated objects are not sent // do not call the setter method because it does not allow changing the cache synchronization // type of isolated objects cacheSynchronizationType = DO_NOT_SEND_CHANGES; } } /** * INTERNAL: * Return if the unit of work should by-pass the session cache. * Objects will be built in the unit of work, and never merged into the session cache. */ public boolean shouldIsolateObjectsInUnitOfWork() { return this.unitOfWorkCacheIsolationLevel == ISOLATE_CACHE_ALWAYS; } /** * INTERNAL: * Return if the unit of work should by-pass the IsolatedSession cache. * Objects will be built/merged into the unit of work and into the session cache. * but not built/merge into the IsolatedClientSession cache. */ public boolean shouldIsolateProtectedObjectsInUnitOfWork() { return this.unitOfWorkCacheIsolationLevel == ISOLATE_FROM_CLIENT_SESSION; } /** * INTERNAL: * Return if the unit of work should by-pass the session cache after an early transaction. */ public boolean shouldIsolateObjectsInUnitOfWorkEarlyTransaction() { return this.unitOfWorkCacheIsolationLevel == ISOLATE_CACHE_AFTER_TRANSACTION; } /** * INTERNAL: * Return if the unit of work should use the session cache after an early transaction. */ public boolean shouldUseSessionCacheInUnitOfWorkEarlyTransaction() { return this.unitOfWorkCacheIsolationLevel == USE_SESSION_CACHE_AFTER_TRANSACTION; } /** * ADVANCED: * Return the unit of work cache isolation setting. * This setting configures how the session cache will be used in a unit of work. * @see #setUnitOfWorkCacheIsolationLevel(int) */ public int getUnitOfWorkCacheIsolationLevel() { return unitOfWorkCacheIsolationLevel; } /** * ADVANCED: * This setting configures how the session cache will be used in a unit of work. * Most of the options only apply to a unit of work in an early transaction, * such as a unit of work that was flushed (writeChanges), issued a modify query, or acquired a pessimistic lock. *

USE_SESSION_CACHE_AFTER_TRANSACTION - Objects built from new data accessed after a unit of work early transaction are stored in the session cache. * This options is the most efficient as it allows the cache to be used after an early transaction. * This should only be used if it is known that this class is not modified in the transaction, * otherwise this could cause uncommitted data to be loaded into the session cache. * ISOLATE_NEW_DATA_AFTER_TRANSACTION - Default (when using caching): Objects built from new data accessed after a unit of work early transaction are only stored in the unit of work. * This still allows previously cached objects to be accessed in the unit of work after an early transaction, * but ensures uncommitted data will never be put in the session cache by storing any object built from new data only in the unit of work. * ISOLATE_CACHE_AFTER_TRANSACTION - After a unit of work early transaction the session cache is no longer used for this class. * Objects will be directly built from the database data and only stored in the unit of work, even if previously cached. * Note that this may lead to poor performance as the session cache is bypassed after an early transaction. * ISOLATE_CACHE_ALWAYS - Default (when using isolated cache): The session cache will never be used for this class. * Objects will be directly built from the database data and only stored in the unit of work. * New objects and changes will also never be merged into the session cache. * Note that this may lead to poor performance as the session cache is bypassed, * however if this class is isolated or pessimistic locked and always accessed in a transaction, this can avoid having to build two copies of the object. */ public void setUnitOfWorkCacheIsolationLevel(int unitOfWorkCacheIsolationLevel) { this.unitOfWorkCacheIsolationLevel = unitOfWorkCacheIsolationLevel; } /** * @param fullyMergeEntity the fullyMergeEntity to set */ public void setFullyMergeEntity(boolean fullyMergeEntity) { this.fullyMergeEntity = fullyMergeEntity; } /** * PUBLIC: * Set the class of identity map to be used by this descriptor. * The default is the "FullIdentityMap". */ public void setIdentityMapClass(Class theIdentityMapClass) { identityMapClass = theIdentityMapClass; } /** * PUBLIC: * Set the size of the identity map to be used by this descriptor. * The default is the 100. */ public void setIdentityMapSize(int identityMapSize) { this.identityMapSize = identityMapSize; } /** * OBSOLETE: * Set the type of cache coordination that will be used on objects of this type. Possible values * are:

    *
  • SEND_OBJECT_CHANGES *
  • INVALIDATE_CHANGED_OBJECTS *
  • SEND_NEW_OBJECTS_WITH_CHANGES *
  • DO_NOT_SEND_CHANGES
* Note: Cache Synchronization type cannot be altered for descriptors that are set as isolated using * the setIsIsolated method.

* This has been replaced by setCacheCoordinationType(). * @see #setCacheCoordinationType(CacheCoordinationType) * @param type int The synchronization type for this descriptor */ public void setCacheSynchronizationType(int type) { // bug 3587273 if (!isIsolated()) { cacheSynchronizationType = type; } } /** * PUBLIC: * Set the type of cache coordination that will be used on objects of this type. * Valid values defined in CacheCoordinationType. */ public void setCacheCoordinationType(CacheCoordinationType type) { if (type == null) { setCacheSynchronizationType(UNDEFINED_OBJECT_CHANGE_BEHAVIOR); } else if (type == CacheCoordinationType.SEND_OBJECT_CHANGES) { setCacheSynchronizationType(SEND_OBJECT_CHANGES); } else if (type == CacheCoordinationType.INVALIDATE_CHANGED_OBJECTS) { setCacheSynchronizationType(INVALIDATE_CHANGED_OBJECTS); } else if (type == CacheCoordinationType.SEND_NEW_OBJECTS_WITH_CHANGES) { setCacheSynchronizationType(SEND_NEW_OBJECTS_WITH_CHANGES); } else if (type == CacheCoordinationType.NONE) { setCacheSynchronizationType(DO_NOT_SEND_CHANGES); } } /** * PUBLIC: * A CacheInterceptor is an adaptor that when overridden and assigned to a Descriptor all interaction * between EclipseLink and the internal cache for that class will pass through the Interceptor. * Advanced users could use this interceptor to audit, profile or log cache access. This Interceptor * could also be used to redirect or augment the TopLink cache with an alternate cache mechanism. * EclipseLink's configurated IdentityMaps will be passed to the Interceptor constructor. * As with IdentityMaps an entire class inheritance hierarchy will share the same interceptor. * @see org.eclipse.persistence.sessions.interceptors.CacheInterceptor */ public void setCacheInterceptorClass(Class cacheInterceptorClass){ this.cacheInterceptorClass = cacheInterceptorClass; } /** * PUBLIC: * A CacheInterceptor is an adaptor that when overridden and assigned to a Descriptor all interaction * between EclipseLink and the internal cache for that class will pass through the Interceptor. * Advanced users could use this interceptor to audit, profile or log cache access. This Interceptor * could also be used to redirect or augment the TopLink cache with an alternate cache mechanism. * EclipseLink's configurated IdentityMaps will be passed to the Interceptor constructor. * As with IdentityMaps an entire class inheritance hierarchy will share the same interceptor. * @see org.eclipse.persistence.sessions.interceptors.CacheInterceptor */ public void setCacheInterceptorClassName(String cacheInterceptorClassName){ this.cacheInterceptorClassName = cacheInterceptorClassName; } /** * PUBLIC: * Returns true if the descriptor represents an isolated class */ public boolean isIsolated() { return CacheIsolationType.ISOLATED == this.cacheIsolation; } /** * PUBLIC: * Returns true if the descriptor represents a protected class. */ public boolean isProtectedIsolation() { return CacheIsolationType.PROTECTED ==this.cacheIsolation; } /** * PUBLIC: * Returns true if the descriptor represents a shared class. */ public boolean isSharedIsolation() { return this.cacheIsolation == null || CacheIsolationType.SHARED == this.cacheIsolation; } /** * INTERNAL: * Index the object by index in the cache using its row. */ public void indexObjectInCache(CacheKey cacheKey, AbstractRecord databaseRow, Object domainObject, ClassDescriptor descriptor, AbstractSession session, boolean refresh) { if (!hasCacheIndexes()) { return; } for (CacheIndex index : this.cacheIndexes.values()) { if (!refresh || index.isUpdateable()) { List fields = index.getFields(); int size = fields.size(); Object[] values = new Object[size]; for (int count = 0; count < size; count++) { values[count] = databaseRow.get(fields.get(count)); } CacheId indexValues = new CacheId(values); session.getIdentityMapAccessorInstance().putCacheKeyByIndex(index, indexValues, cacheKey, descriptor); } } } /** * INTERNAL: * Index the object by index in the cache using the object. */ public void indexObjectInCache(CacheKey cacheKey, Object object, ClassDescriptor descriptor, AbstractSession session, boolean refresh) { if (!hasCacheIndexes()) { return; } for (CacheIndex index : this.cacheIndexes.values()) { if (!refresh || index.isUpdateable()) { List fields = index.getFields(); int size = fields.size(); Object[] values = new Object[size]; for (int count = 0; count < size; count++) { values[count] = descriptor.getObjectBuilder().extractValueFromObjectForField(object, fields.get(count), session); } CacheId indexValues = new CacheId(values); session.getIdentityMapAccessorInstance().putCacheKeyByIndex(index, indexValues, cacheKey, descriptor); } } } /** * INTERNAL: * Index the object by index in the cache using its changeSet. */ public void indexObjectInCache(ObjectChangeSet changeSet, Object object, ClassDescriptor descriptor, AbstractSession session) { if (!hasCacheIndexes()) { return; } for (CacheIndex index : this.cacheIndexes.values()) { if ((changeSet == null) || (changeSet.isNew() && index.isInsertable()) || (!changeSet.isNew() && index.isUpdateable())) { List fields = index.getFields(); int size = fields.size(); Object[] values = new Object[size]; for (int count = 0; count < size; count++) { values[count] = descriptor.getObjectBuilder().extractValueFromObjectForField(object, fields.get(count), session); } CacheId indexValues = new CacheId(values); CacheKey cacheKey = null; Object id = null; if (changeSet != null) { cacheKey = changeSet.getActiveCacheKey(); if (cacheKey == null) { id = changeSet.getId(); } } else { id = descriptor.getObjectBuilder().extractPrimaryKeyFromObject(object, session); } if (cacheKey == null) { cacheKey = session.getIdentityMapAccessorInstance().getCacheKeyForObject(id, descriptor.getJavaClass(), descriptor, true); } session.getIdentityMapAccessorInstance().putCacheKeyByIndex(index, indexValues, cacheKey, descriptor); } } } /** * INTERNAL: * Lookup the expression in the cache if it contains any indexes. */ public CacheKey checkCacheByIndex(Expression expression, AbstractRecord translationRow, ClassDescriptor descriptor, AbstractSession session) { if (!hasCacheIndexes()) { return null; } AbstractRecord record = descriptor.getObjectBuilder().extractRowFromExpression(expression, translationRow, session); if (record == null) { return null; } for (CacheIndex index : this.cacheIndexes.values()) { List fields = index.getFields(); int size = fields.size(); Object[] values = new Object[size]; for (int count = 0; count < size; count++) { Object value = record.get(fields.get(count)); if (value == null) { break; } values[count] = value; } CacheId indexValues = new CacheId(values); CacheKey cacheKey = session.getIdentityMapAccessorInstance().getCacheKeyByIndex(index, indexValues, true, descriptor); if (cacheKey != null) { return cacheKey; } } return null; } /** * INTERNAL: * Lookup the expression in the cache if it contains any indexes. */ public boolean isIndexableExpression(Expression expression, ClassDescriptor descriptor, AbstractSession session) { if (!hasCacheIndexes()) { return false; } for (CacheIndex index : this.cacheIndexes.values()) { List searchFields = index.getFields(); int size = searchFields.size(); Set foundFields = new HashSet(size); boolean isValid = expression.extractFields(true, false, descriptor, searchFields, foundFields); if (isValid && (foundFields.size() == size)) { return true; } } return false; } /** * PUBLIC: * Set the class of identity map to be the full identity map. * This map caches all instances read and grows to accomodate them. * The default is the "SoftCacheWeakIdentityMap". */ public void useFullIdentityMap() { setIdentityMapClass(ClassConstants.FullIdentityMap_Class); } /** * PUBLIC: * Set the class of identity map to be the hard cache weak identity map. * This map uses weak references to only cache object in-memory. * It also includes a secondary fixed sized hard cache to improve caching performance. * This is provided because some Java VM's implement soft references differently. * The default is the "SoftCacheWeakIdentityMap". */ public void useHardCacheWeakIdentityMap() { setIdentityMapClass(ClassConstants.HardCacheWeakIdentityMap_Class); } /** * PUBLIC: * Set the class of identity map to be the soft identity map. * This map uses soft references to only cache all object in-memory, until memory is low. * Note that "low" is interpreted differently by different JVM's. * The default is the "SoftCacheWeakIdentityMap". */ public void useSoftIdentityMap() { setIdentityMapClass(ClassConstants.SoftIdentityMap_Class); } /** * PUBLIC: * Set the class of identity map to be the no identity map. * This map does no caching. * Note: This map does not maintain object identity. * In general if caching is not desired a WeakIdentityMap should be used with an isolated descriptor. * The default is the "SoftCacheWeakIdentityMap". * @see ClassDescriptor#setCacheIsolation(CacheIsolationType) */ public void useNoIdentityMap() { setIdentityMapClass(ClassConstants.NoIdentityMap_Class); } /** * PUBLIC: * Set the class of identity map to be the weak identity map. * The default is the "SoftCacheWeakIdentityMap". */ public void useWeakIdentityMap() { setIdentityMapClass(ClassConstants.WeakIdentityMap_Class); } public void setPrefetchCacheKeys(boolean prefetchCacheKeys) { this.prefetchCacheKeys = prefetchCacheKeys; } public boolean shouldPrefetchCacheKeys() { return this.prefetchCacheKeys ; } }





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