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 * glassfish/bootstrap/legal/CDDLv1.0.txt or 
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// Copyright (c) 1998, 2007, Oracle. All rights reserved.  
package oracle.toplink.essentials.internal.sessions;

import java.util.*;
import java.io.*;
import javax.persistence.EntityExistsException;
import oracle.toplink.essentials.internal.helper.*;
import oracle.toplink.essentials.internal.descriptors.*;
import oracle.toplink.essentials.internal.localization.ExceptionLocalization;
import oracle.toplink.essentials.platform.server.ServerPlatform;
import oracle.toplink.essentials.queryframework.*;
import oracle.toplink.essentials.internal.identitymaps.*;
import oracle.toplink.essentials.internal.databaseaccess.*;
import oracle.toplink.essentials.expressions.*;
import oracle.toplink.essentials.exceptions.*;
import oracle.toplink.essentials.internal.sequencing.Sequencing;
import oracle.toplink.essentials.logging.SessionLog;
import oracle.toplink.essentials.internal.localization.LoggingLocalization;
import oracle.toplink.essentials.sessions.SessionProfiler;
import oracle.toplink.essentials.sessions.UnitOfWork;
import oracle.toplink.essentials.internal.sessions.AbstractSession;
import oracle.toplink.essentials.descriptors.DescriptorEventManager;
import oracle.toplink.essentials.internal.sessions.AbstractRecord;
import oracle.toplink.essentials.internal.helper.IdentityHashtable;

import oracle.toplink.essentials.descriptors.ClassDescriptor;
import oracle.toplink.essentials.internal.queryframework.JoinedAttributeManager;

/**
 * Implementation of oracle.toplink.essentials.sessions.UnitOfWork
 * The public interface should be used by public API and testing, the implementation should be used internally.
 * @see oracle.toplink.essentials.sessions.UnitOfWork
 *
 * Purpose: To allow object level transactions.
 * 

* Description: The unit of work is a session that implements all of the normal * protocol of a TopLink session. It can be spawned from any other session including another unit of work. * Objects can be brought into the unit of work through reading them or through registering them. * The unit of work will opperate on its own object space, that is the objects within the unit of work * will be clones of the orignial objects. When the unit of work is commited, all changes to any objects * registered within the unit of work will be commited to the database. A minimal commit/update will * be performed and any foreign keys/circular reference/referencial integrity will be resolved. * If the commit to the database is successful the changed objects will be merged back into the unit of work * parent session. *

* Responsibilities: *

    *
  • Allow parallel transactions against a session's objects. *
  • Allow nested transactions. *
  • Not require the application to write objects that is changes, automatically determine what has changed. *
  • Perform a minimal commit/update of all changes that occured. *
  • Resolve foreign keys for newly created objects and maintain referencial integrity. *
  • Allow for the object transaction to use its own object space. *
*/ public class UnitOfWorkImpl extends AbstractSession implements oracle.toplink.essentials.sessions.UnitOfWork { /** Fix made for weak caches to avoid garbage collection of the originals. **/ /** As well as used as lookup in merge algorithm for aggregates and others **/ protected transient IdentityHashtable cloneToOriginals; protected transient AbstractSession parent; /** Hashtable of all the clones. The key contains the clone of the object. */ protected IdentityHashtable cloneMapping; protected IdentityHashtable newObjectsCloneToOriginal; protected IdentityHashtable newObjectsOriginalToClone; protected IdentityHashtable deletedObjects; /** This member variable contains a copy of all of the clones for this particular UOW */ protected IdentityHashtable allClones; protected IdentityHashtable objectsDeletedDuringCommit; protected IdentityHashtable removedObjects; protected IdentityHashtable unregisteredNewObjects; protected IdentityHashtable unregisteredExistingObjects; protected IdentityHashtable newAggregates; /** This method is used to store the current changeSet for this UnitOfWork. */ protected UnitOfWorkChangeSet unitOfWorkChangeSet; /** use to track pessimistic locked objects */ protected IdentityHashtable pessimisticLockedObjects; /** Used to store the list of locks that this UnitOfWork has acquired for this merge */ protected MergeManager lastUsedMergeManager; /** Read-only class can be used for reference data to avoid cloning when not required. */ protected Hashtable readOnlyClasses; /** Flag indicating that the transaction for this UOW was already begun. */ protected boolean wasTransactionBegunPrematurely; /** Allow for double merges of new objects by putting them into the cache. */ protected boolean shouldNewObjectsBeCached; /** Flag indicating that deletes should be performed before other updates. */ protected boolean shouldPerformDeletesFirst; /** Flag indicating how to deal with exceptions on conforming queries. **/ protected int shouldThrowConformExceptions; /** The amount of validation can be configured. */ protected int validationLevel; static public final int None = 0; static public final int Partial = 1; static public final int Full = 2; /** * With the new synchronized unit of work, need a lifecycle state variable to * track birth, commited, pending_merge and death. */ protected boolean isSynchronized; protected int lifecycle; public static final int Birth = 0; public static final int CommitPending = 1; // After a call to writeChanges() but before commit. public static final int CommitTransactionPending = 2; // After an unsuccessful call to writeChanges(). No recovery at all. public static final int WriteChangesFailed = 3; public static final int MergePending = 4; public static final int Death = 5; public static final int AfterExternalTransactionRolledBack = 6; /** Used for Conforming Queries */ public static final int DO_NOT_THROW_CONFORM_EXCEPTIONS = 0; public static final int THROW_ALL_CONFORM_EXCEPTIONS = 1; public static final String LOCK_QUERIES_PROPERTY = "LockQueriesProperties"; /** Used for merging dependent values without use of WL SessionAccessor */ protected static boolean SmartMerge = false; /** Kept reference of read lock objects*/ protected Hashtable optimisticReadLockObjects; /** lazy initialization done in storeModifyAllQuery. For UpdateAllQuery, only clones of all UpdateAllQuery's (deferred and non-deferred) are stored here for validation only.*/ protected List modifyAllQueries; /** Contains deferred ModifyAllQuery's that have translation row for execution only. At commit their clones will be added to modifyAllQueries for validation afterwards*/ //Bug4607551 protected List deferredModifyAllQueries; /** * Used during the cloning process to track the recursive depth in. This will * be used to determine at which point the process can begin to wait on locks * without being concerned about creating deadlock situations. */ protected int cloneDepth = 0; /** * This collection will be used to store those objects that are currently locked * for the clone process. It should be populated with an TopLinkIdentityHashMap */ protected Map objectsLockedForClone; /** * PERF: Stores the JTA transaction to optimize activeUnitOfWork lookup. */ protected Object transaction; /** * PERF: Cache the write-lock check to avoid cost of checking in every register/clone. */ protected boolean shouldCheckWriteLock; /** * True if UnitOfWork should be resumed on completion of transaction. * Used when UnitOfWork is Synchronized with external transaction control */ protected boolean resumeOnTransactionCompletion; /** * True if either DataModifyQuery or ModifyAllQuery was executed. * Gets reset on commit, effects DoesExistQuery behaviour and reading. */ protected boolean wasNonObjectLevelModifyQueryExecuted; /** * True if the value holder for the joined attribute should be triggered. * Required by ejb30 fetch join. */ protected boolean shouldCascadeCloneToJoinedRelationship; /** * INTERNAL: * Create and return a new unit of work with the sesson as its parent. */ public UnitOfWorkImpl(AbstractSession parent) { super(); this.name = parent.getName(); this.parent = parent; // 2612538 - the default size of IdentityHashtable (32) is appropriate this.cloneMapping = new IdentityHashtable(); // PERF: lazy-init hashtables (3286089) - cloneToOriginals, // newObjectsInParentOriginalToClone, objectsDeletedDuringCommit // removedObjects. this.project = parent.getProject(); this.profiler = parent.getProfiler(); this.isInProfile = parent.isInProfile; this.sessionLog = parent.getSessionLog(); this.eventManager = parent.getEventManager().clone(this); this.exceptionHandler = parent.getExceptionHandler(); // Initialize the readOnlyClasses variable. this.setReadOnlyClasses(parent.copyReadOnlyClasses()); this.wasTransactionBegunPrematurely = false; // False by default as this may screw up things for objects with 0, -1 or other non-null default keys. this.shouldNewObjectsBeCached = false; this.validationLevel = Partial; this.shouldPerformDeletesFirst = false; // for 3.0.x this conforming queries will not throw exceptions unless explicitly asked to this.shouldThrowConformExceptions = DO_NOT_THROW_CONFORM_EXCEPTIONS; // initialize lifecycle state variable this.isSynchronized = false; this.lifecycle = Birth; // PERF: Cache the write-lock check to avoid cost of checking in every register/clone. this.shouldCheckWriteLock = parent.getDatasourceLogin().shouldSynchronizedReadOnWrite() || parent.getDatasourceLogin().shouldSynchronizeWrites(); this.resumeOnTransactionCompletion = false; getEventManager().postAcquireUnitOfWork(); incrementProfile(SessionProfiler.UowCreated); } /** * PUBLIC: * Nested units of work are not supported in TopLink Essentials. */ public UnitOfWork acquireUnitOfWork() { throw ValidationException.notSupported("acquireUnitOfWork", getClass()); } /** * INTERNAL: * Register a new aggregate object with the unit of work. */ public void addNewAggregate(Object originalObject) { getNewAggregates().put(originalObject, originalObject); } /** * INTERNAL: * Add object deleted during root commit of unit of work. */ public void addObjectDeletedDuringCommit(Object object, ClassDescriptor descriptor) { // The object's key is keyed on the object, this avoids having to compute the key later on. getObjectsDeletedDuringCommit().put(object, keyFromObject(object, descriptor)); //bug 4730595: changed to add deleted objects to the changesets. ((UnitOfWorkChangeSet)getUnitOfWorkChangeSet()).addDeletedObject(object, this); } /** * PUBLIC: * Adds the given Java class to the receiver's set of read-only classes. * Cannot be called after objects have been registered in the unit of work. */ public void addReadOnlyClass(Class theClass) throws ValidationException { if (!canChangeReadOnlySet()) { throw ValidationException.cannotModifyReadOnlyClassesSetAfterUsingUnitOfWork(); } getReadOnlyClasses().put(theClass, theClass); ClassDescriptor descriptor = getDescriptor(theClass); // Also mark all subclasses as read-only. if (descriptor.hasInheritance()) { for (Enumeration childEnum = descriptor.getInheritancePolicy().getChildDescriptors().elements(); childEnum.hasMoreElements();) { ClassDescriptor childDescriptor = (ClassDescriptor)childEnum.nextElement(); addReadOnlyClass(childDescriptor.getJavaClass()); } } } /** * PUBLIC: * Adds the classes in the given Vector to the existing set of read-only classes. * Cannot be called after objects have been registered in the unit of work. */ public void addReadOnlyClasses(Vector classes) { for (Enumeration enumtr = classes.elements(); enumtr.hasMoreElements();) { Class theClass = (Class)enumtr.nextElement(); addReadOnlyClass(theClass); } } /** * INTERNAL: * Register that an object was removed in a nested unit of work. */ public void addRemovedObject(Object orignal) { getRemovedObjects().put(orignal, orignal);// Use as set. } /** * ADVANCED: * Assign sequence number to the object. * This allows for an object's id to be assigned before commit. * It can be used if the application requires to use the object id before the object exists on the database. * Normally all ids are assigned during the commit automatically. */ public void assignSequenceNumber(Object object) throws DatabaseException { //** sequencing refactoring startOperationProfile(SessionProfiler.AssignSequence); try { ObjectBuilder builder = getDescriptor(object).getObjectBuilder(); // This is done outside of a transaction to ensure optimial concurrency and deadlock avoidance in the sequence table. if (builder.getDescriptor().usesSequenceNumbers() && !getSequencing().shouldAcquireValueAfterInsert(object.getClass())) { Object implementation = builder.unwrapObject(object, this); builder.assignSequenceNumber(implementation, this); } } catch (RuntimeException exception) { handleException(exception); } endOperationProfile(SessionProfiler.AssignSequence); } /** * ADVANCED: * Assign sequence numbers to all new objects registered in this unit of work, * or any new objects reference by any objects registered. * This allows for an object's id to be assigned before commit. * It can be used if the application requires to use the object id before the object exists on the database. * Normally all ids are assigned during the commit automatically. */ public void assignSequenceNumbers() throws DatabaseException { // This should be done outside of a transaction to ensure optimal concurrency and deadlock avoidance in the sequence table. // discoverAllUnregisteredNewObjects() should be called no matter whether sequencing used // or not, because collectAndPrepareObjectsForCommit() method (which calls assignSequenceNumbers()) // needs it. // It would be logical to remove discoverAllUnregisteredNewObjects() from assignSequenceNumbers() // and make collectAndPrepareObjectsForCommit() to call discoverAllUnregisteredNewObjects() // first and assignSequenceNumbers() next, // but assignSequenceNumbers() is a public method which could be called by user - and // in this case discoverAllUnregisteredNewObjects() is needed again (though // if sequencing is not used the call will make no sense - but no harm, too). discoverAllUnregisteredNewObjects(); Sequencing sequencing = getSequencing(); if (sequencing == null) { return; } int whenShouldAcquireValueForAll = sequencing.whenShouldAcquireValueForAll(); if (whenShouldAcquireValueForAll == Sequencing.AFTER_INSERT) { return; } boolean shouldAcquireValueBeforeInsertForAll = whenShouldAcquireValueForAll == Sequencing.BEFORE_INSERT; startOperationProfile(SessionProfiler.AssignSequence); Enumeration unregisteredNewObjectsEnum = getUnregisteredNewObjects().keys(); while (unregisteredNewObjectsEnum.hasMoreElements()) { Object object = unregisteredNewObjectsEnum.nextElement(); if (getDescriptor(object).usesSequenceNumbers() && ((!isObjectRegistered(object)) || isCloneNewObject(object)) && (shouldAcquireValueBeforeInsertForAll || !sequencing.shouldAcquireValueAfterInsert(object.getClass()))) { getDescriptor(object).getObjectBuilder().assignSequenceNumber(object, this); } } Enumeration registeredNewObjectsEnum = getNewObjectsCloneToOriginal().keys(); while (registeredNewObjectsEnum.hasMoreElements()) { Object object = registeredNewObjectsEnum.nextElement(); if (getDescriptor(object).usesSequenceNumbers() && ((!isObjectRegistered(object)) || isCloneNewObject(object)) && (shouldAcquireValueBeforeInsertForAll || !sequencing.shouldAcquireValueAfterInsert(object.getClass()))) { getDescriptor(object).getObjectBuilder().assignSequenceNumber(object, this); } } endOperationProfile(SessionProfiler.AssignSequence); } /** * PUBLIC: * Tell the unit of work to begin a transaction now. * By default the unit of work will begin a transaction at commit time. * The default is the recommended approach, however sometimes it is * neccessary to start the transaction before commit time. When the * unit of work commits, this transcation will be commited. * * @see #commit() * @see #release() */ public void beginEarlyTransaction() throws DatabaseException { beginTransaction(); setWasTransactionBegunPrematurely(true); } /** * INTERNAL: * This is internal to the uow, transactions should not be used explictly in a uow. * The uow shares its parents transactions. */ public void beginTransaction() throws DatabaseException { getParent().beginTransaction(); } /** * INTERNAL: * Unregistered new objects have no original so we must create one for commit and resume and * to put into the parent. We can NEVER let the same copy of an object exist in multiple units of work. */ public Object buildOriginal(Object workingClone) { ClassDescriptor descriptor = getDescriptor(workingClone); ObjectBuilder builder = descriptor.getObjectBuilder(); Object original = builder.instantiateClone(workingClone, this); // If no original exists can mean any of the following: // -A RemoteUnitOfWork and cloneToOriginals is transient. // -A clone read while in transaction, and built directly from // the database row with no intermediary original. // -An unregistered new object if (checkIfAlreadyRegistered(workingClone, descriptor) != null) { getCloneToOriginals().put(workingClone, original); return original; } else { // Assume it is an unregisteredNewObject, but this is worrisome, as // it may be an unregistered existing object, not in the parent cache? Object backup = builder.instantiateClone(workingClone, this); // Original is fine for backup as state is the same. getCloneMapping().put(workingClone, backup); // Must register new instance / clone as the original. getNewObjectsCloneToOriginal().put(workingClone, original); getNewObjectsOriginalToClone().put(original, workingClone); // no need to register in identity map as the DatabaseQueryMechanism will have //placed the object in the identity map on insert. bug 3431586 } return original; } /** * INTERNAL: *

This Method is designed to calculate the changes for all objects * within the PendingObjects. */ public UnitOfWorkChangeSet calculateChanges(IdentityHashtable allObjects, UnitOfWorkChangeSet changeSet) { getEventManager().preCalculateUnitOfWorkChangeSet(); Enumeration objects = allObjects.elements(); while (objects.hasMoreElements()) { Object object = objects.nextElement(); //block of code removed because it will never be touched see bug # 2903565 ClassDescriptor descriptor = getDescriptor(object); //Block of code removed for code coverage, as it would never have been touched. bug # 2903600 // Use the object change policy to determine if we should run a comparison for this object - TGW if (descriptor.getObjectChangePolicy().shouldCompareForChange(object, this, descriptor)) { ObjectChangeSet changes = descriptor.getObjectChangePolicy().calculateChanges(object, getBackupClone(object), changeSet, this, descriptor, true); if ((changes != null) && changes.isNew()) { // add it to the new list as well so we do not loose it as it may not have a valid primary key // it will be moved to the standard list once it is inserted. changeSet.addNewObjectChangeSet(changes, this); } else { changeSet.addObjectChangeSet(changes); } } } getEventManager().postCalculateUnitOfWorkChangeSet(changeSet); return changeSet; } /** * INTERNAL: * Checks whether the receiver has been used. i.e. objects have been registered. * * @return true or false depending on whether the read-only set can be changed or not. */ protected boolean canChangeReadOnlySet() { return !hasCloneMapping() && !hasDeletedObjects(); } /** * INTERNAL: */ public boolean checkForUnregisteredExistingObject(Object object) { ClassDescriptor descriptor = getDescriptor(object.getClass()); Vector primaryKey = descriptor.getObjectBuilder().extractPrimaryKeyFromObject(object, this); DoesExistQuery existQuery = descriptor.getQueryManager().getDoesExistQuery(); existQuery = (DoesExistQuery)existQuery.clone(); existQuery.setObject(object); existQuery.setPrimaryKey(primaryKey); existQuery.setDescriptor(descriptor); existQuery.setCheckCacheFirst(true); if (((Boolean)executeQuery(existQuery)).booleanValue()) { return true; } else { return false; } } /** * INTERNAL: * Register the object and return the clone if it is existing otherwise return null if it is new. * The unit of work determines existence during registration, not during the commit. */ public Object checkExistence(Object object) { ClassDescriptor descriptor = getDescriptor(object.getClass()); Vector primaryKey = descriptor.getObjectBuilder().extractPrimaryKeyFromObject(object, this); // PERF: null primary key cannot exist. if (primaryKey.contains(null)) { return null; } DoesExistQuery existQuery = descriptor.getQueryManager().getDoesExistQuery(); existQuery = (DoesExistQuery)existQuery.clone(); existQuery.setObject(object); existQuery.setPrimaryKey(primaryKey); existQuery.setDescriptor(descriptor); existQuery.setCheckCacheFirst(true); if (((Boolean)executeQuery(existQuery)).booleanValue()) { //we know if it exists or not, now find or register it Object objectFromCache = getIdentityMapAccessorInstance().getFromIdentityMap(primaryKey, object.getClass(), descriptor, null); if (objectFromCache != null) { // Ensure that the registered object is the one from the parent cache. if (shouldPerformFullValidation()) { if ((objectFromCache != object) && (getParent().getIdentityMapAccessorInstance().getFromIdentityMap(primaryKey, object.getClass(), descriptor, null) != object)) { throw ValidationException.wrongObjectRegistered(object, objectFromCache); } } // Has already been cloned. if (!this.isObjectDeleted(objectFromCache)) return objectFromCache; } // This is a case where the object is not in the session cache, // so a new cache-key is used as there is no original to use for locking. return cloneAndRegisterObject(object, new CacheKey(primaryKey), null); } else { return null; } } /** * INTERNAL: * Return the value of the object if it already is registered, otherwise null. */ protected Object checkIfAlreadyRegistered(Object object, ClassDescriptor descriptor) { // Don't register read-only classes if (isClassReadOnly(object.getClass(), descriptor)) { return null; } // Check if the working copy is again being registered in which case we return the same working copy Object registeredObject = getCloneMapping().get(object); if (registeredObject != null) { return object; } // Check if object exists in my new objects if it is in the new objects cache then it means domain object is being // re-registered and we should return the same working clone. This check holds only for the new registered objects // PERF: Avoid initialization of new objects if none. if (hasNewObjects()) { registeredObject = getNewObjectsOriginalToClone().get(object); if (registeredObject != null) { return registeredObject; } } return null; } /** * ADVANCED: * Register the new object with the unit of work. * This will register the new object with cloning. * Normally the registerObject method should be used for all registration of new and existing objects. * This version of the register method can only be used for new objects. * This method should only be used if a new object is desired to be registered without an existence Check. * * @see #registerObject(Object) */ protected Object cloneAndRegisterNewObject(Object original) { ClassDescriptor descriptor = getDescriptor(original); ObjectBuilder builder = descriptor.getObjectBuilder(); // bug 2612602 create the working copy object. Object clone = builder.instantiateWorkingCopyClone(original, this); // Must put in the original to clone to resolv circular refs. getNewObjectsOriginalToClone().put(original, clone); // Must put in clone mapping. getCloneMapping().put(clone, clone); builder.populateAttributesForClone(original, clone, this, null); // Must reregister in both new objects. registerNewObjectClone(clone, original); //Build backup clone for DeferredChangeDetectionPolicy or ObjectChangeTrackingPolicy, //but not for AttributeChangeTrackingPolicy Object backupClone = descriptor.getObjectChangePolicy().buildBackupClone(clone, builder, this); getCloneMapping().put(clone, backupClone);// The backup clone must be updated. return clone; } /** * INTERNAL: * Clone and register the object. * The cache key must the cache key from the session cache, * as it will be used for locking. */ public Object cloneAndRegisterObject(Object original, CacheKey cacheKey, JoinedAttributeManager joinedAttributeManager) { ClassDescriptor descriptor = getDescriptor(original); ObjectBuilder builder = descriptor.getObjectBuilder(); Object workingClone = builder.instantiateWorkingCopyClone(original, this); // The cache/objects being registered must first be locked to ensure // that a merge or refresh does not oocur on the object while being cloned to // avoid cloning a partially merged/refreshed object. // If a cache isolation level is used, then lock the entire cache. // otherwise lock the object and it related objects (not using indirection) as a unit. // If just a simple object (all indirection) a simple read-lock can be used. // PERF: Cache if check to write is required. boolean identityMapLocked = this.shouldCheckWriteLock && getParent().getIdentityMapAccessorInstance().acquireWriteLock(); boolean rootOfCloneRecursion = false; if ((!identityMapLocked) && (this.objectsLockedForClone == null)) {//we may have locked all required objects already // PERF: If a simple object just acquire a simple read-lock. if (descriptor.shouldAcquireCascadedLocks()) { this.objectsLockedForClone = getParent().getIdentityMapAccessorInstance().getWriteLockManager().acquireLocksForClone(original, descriptor, cacheKey.getKey(), getParent()); } else { cacheKey.acquireReadLock(); } rootOfCloneRecursion = true; } try { // This must be registered before it is built to avoid really obscure cycles. getCloneMapping().put(workingClone, workingClone); //also clone the fetch group reference if applied if (descriptor.hasFetchGroupManager()) { descriptor.getFetchGroupManager().copyFetchGroupInto(original, workingClone); } //store this for look up later getCloneToOriginals().put(workingClone, original); // just clone it. populateAndRegisterObject(original, workingClone, cacheKey.getKey(), descriptor, cacheKey.getWriteLockValue(), cacheKey.getReadTime(), joinedAttributeManager); } finally { // If the entire cache was locke, release the cache lock, // otherwise either release the cache-key for a simple lock, // otherwise release the entire set of locks for related objects if this was the root. if (identityMapLocked) { getParent().getIdentityMapAccessorInstance().releaseWriteLock(); } else { if (rootOfCloneRecursion) { if (this.objectsLockedForClone == null) { cacheKey.releaseReadLock(); } else { for (Iterator iterator = this.objectsLockedForClone.values().iterator(); iterator.hasNext();) { ((CacheKey)iterator.next()).releaseReadLock(); } this.objectsLockedForClone = null; } } } } return workingClone; } /** * INTERNAL: * Prepare for commit. */ public IdentityHashtable collectAndPrepareObjectsForCommit() { IdentityHashtable changedObjects = new IdentityHashtable(1 + getCloneMapping().size()); // SPECJ: Avoid for CMP. if (! getProject().isPureCMP2Project()) { assignSequenceNumbers(); } //assignSequenceNumbers will collect the unregistered new objects and assign id's to all new // objects // Add any registered objects. for (Enumeration clonesEnum = getCloneMapping().keys(); clonesEnum.hasMoreElements();) { Object clone = clonesEnum.nextElement(); changedObjects.put(clone, clone); } for (Enumeration unregisteredNewObjectsEnum = getUnregisteredNewObjects().keys(); unregisteredNewObjectsEnum.hasMoreElements();) { Object newObject = unregisteredNewObjectsEnum.nextElement(); changedObjects.put(newObject, newObject); } return changedObjects; } /** * INTERNAL: * Prepare for merge in nested uow. */ public IdentityHashtable collectAndPrepareObjectsForNestedMerge() { IdentityHashtable changedObjects = new IdentityHashtable(1 + getCloneMapping().size()); discoverAllUnregisteredNewObjects(); //assignSequenceNumbers will collect the unregistered new objects and assign id's to all new // objects // Add any registered objects. for (Enumeration clonesEnum = getCloneMapping().keys(); clonesEnum.hasMoreElements();) { Object clone = clonesEnum.nextElement(); changedObjects.put(clone, clone); } for (Enumeration unregisteredNewObjectsEnum = getUnregisteredNewObjects().keys(); unregisteredNewObjectsEnum.hasMoreElements();) { Object newObject = unregisteredNewObjectsEnum.nextElement(); changedObjects.put(newObject, newObject); } return changedObjects; } /** * PUBLIC: * Commit the unit of work to its parent. * For a nested unit of work this will merge any changes to its objects * with its parents. * For a first level unit of work it will commit all changes to its objects * to the database as a single transaction. If successful the changes to its * objects will be merged to its parent's objects. If the commit fails the database * transaction will be rolledback, and the unit of work will be released. * If the commit is successful the unit of work is released, and a new unit of work * must be acquired if further changes are desired. * * @see #commitAndResumeOnFailure() * @see #commitAndResume() * @see #release() */ public void commit() throws DatabaseException, OptimisticLockException { //CR#2189 throwing exception if UOW try to commit again(XC) if (!isActive()) { throw ValidationException.cannotCommitUOWAgain(); } if (isAfterWriteChangesFailed()) { throw ValidationException.unitOfWorkAfterWriteChangesFailed("commit"); } if (!isNestedUnitOfWork()) { if (isSynchronized()) { // If we started the JTS transaction then we have to commit it as well. if (getParent().wasJTSTransactionInternallyStarted()) { commitInternallyStartedExternalTransaction(); } // Do not commit until the JTS wants to. return; } } if (getLifecycle() == CommitTransactionPending) { commitAfterWriteChanges(); return; } log(SessionLog.FINER, SessionLog.TRANSACTION, "begin_unit_of_work_commit");// bjv - correct spelling getEventManager().preCommitUnitOfWork(); setLifecycle(CommitPending); commitRootUnitOfWork(); getEventManager().postCommitUnitOfWork(); log(SessionLog.FINER, SessionLog.TRANSACTION, "end_unit_of_work_commit"); release(); } /** * PUBLIC: * Commit the unit of work to its parent. * For a nested unit of work this will merge any changes to its objects * with its parents. * For a first level unit of work it will commit all changes to its objects * to the database as a single transaction. If successful the changes to its * objects will be merged to its parent's objects. If the commit fails the database * transaction will be rolledback, and the unit of work will be released. * The normal commit releases the unit of work, forcing a new one to be acquired if further changes are desired. * The resuming feature allows for the same unit of work (and working copies) to be continued to be used. * * @see #commitAndResumeOnFailure() * @see #commit() * @see #release() */ public void commitAndResume() throws DatabaseException, OptimisticLockException { //CR#2189 throwing exception if UOW try to commit again(XC) if (!isActive()) { throw ValidationException.cannotCommitUOWAgain(); } if (isAfterWriteChangesFailed()) { throw ValidationException.unitOfWorkAfterWriteChangesFailed("commit"); } if (!isNestedUnitOfWork()) { if (isSynchronized()) { // JTA synchronized units of work, cannot be resumed as there is no // JTA transaction to register with after the commit, // technically this could be supported if the uow started the transaction, // but currently the after completion releases the uow and client session so not really possible. throw ValidationException.cannotCommitAndResumeSynchronizedUOW(this); } } if (getLifecycle() == CommitTransactionPending) { commitAndResumeAfterWriteChanges(); return; } log(SessionLog.FINER, SessionLog.TRANSACTION, "begin_unit_of_work_commit");// bjv - correct spelling getEventManager().preCommitUnitOfWork(); setLifecycle(CommitPending); commitRootUnitOfWork(); getEventManager().postCommitUnitOfWork(); log(SessionLog.FINER, SessionLog.TRANSACTION, "end_unit_of_work_commit"); log(SessionLog.FINER, SessionLog.TRANSACTION, "resume_unit_of_work"); synchronizeAndResume(); getEventManager().postResumeUnitOfWork(); } /** * INTERNAL: * This method is used by the MappingWorkbench for their read-only file feature * this method must not be exposed to or used by customers until it has been revised * and the feature revisited to support OptimisticLocking and Serialization */ public void commitAndResumeWithPreBuiltChangeSet(UnitOfWorkChangeSet uowChangeSet) throws DatabaseException, OptimisticLockException { if (!isNestedUnitOfWork()) { if (isSynchronized()) { // If we started the JTS transaction then we have to commit it as well. if (getParent().wasJTSTransactionInternallyStarted()) { commitInternallyStartedExternalTransaction(); } // Do not commit until the JTS wants to. return; } } log(SessionLog.FINER, SessionLog.TRANSACTION, "begin_unit_of_work_commit");// bjv - correct spelling getEventManager().preCommitUnitOfWork(); setLifecycle(CommitPending); commitRootUnitOfWorkWithPreBuiltChangeSet(uowChangeSet); getEventManager().postCommitUnitOfWork(); log(SessionLog.FINER, SessionLog.TRANSACTION, "end_unit_of_work_commit"); log(SessionLog.FINER, SessionLog.TRANSACTION, "resume_unit_of_work"); synchronizeAndResume(); getEventManager().postResumeUnitOfWork(); } /** * PUBLIC: * Commit the unit of work to its parent. * For a nested unit of work this will merge any changes to its objects * with its parents. * For a first level unit of work it will commit all changes to its objects * to the database as a single transaction. If successful the changes to its * objects will be merged to its parent's objects. If the commit fails the database * transaction will be rolledback, but the unit of work will remain active. * It can then be retried or released. * The normal commit failure releases the unit of work, forcing a new one to be acquired if further changes are desired. * The resuming feature allows for the same unit of work (and working copies) to be continued to be used if an error occurs. * * @see #commit() * @see #release() */ public void commitAndResumeOnFailure() throws DatabaseException, OptimisticLockException { // First clone the identity map, on failure replace the clone back as the cache. IdentityMapManager failureManager = (IdentityMapManager)getIdentityMapAccessorInstance().getIdentityMapManager().clone(); try { // Call commitAndResume. // Oct 13, 2000 - JED PRS #13551 // This method will always resume now. Calling commitAndResume will sync the cache // if successful. This method will take care of resuming if a failure occurs commitAndResume(); } catch (RuntimeException exception) { //reset unitOfWorkChangeSet. Needed for ObjectChangeTrackingPolicy and DeferredChangeDetectionPolicy setUnitOfWorkChangeSet(null); getIdentityMapAccessorInstance().setIdentityMapManager(failureManager); log(SessionLog.FINER, SessionLog.TRANSACTION, "resuming_unit_of_work_from_failure"); throw exception; } } /** * INTERNAL: * Commits a UnitOfWork where the commit process has already been * initiated by all call to writeChanges(). *

* a.k.a finalizeCommit() */ protected void commitAfterWriteChanges() { commitTransactionAfterWriteChanges(); mergeClonesAfterCompletion(); setDead(); release(); } /** * INTERNAL: * Commits and resumes a UnitOfWork where the commit process has already been * initiated by all call to writeChanges(). *

* a.k.a finalizeCommit() */ protected void commitAndResumeAfterWriteChanges() { commitTransactionAfterWriteChanges(); mergeClonesAfterCompletion(); log(SessionLog.FINER, SessionLog.TRANSACTION, "resume_unit_of_work"); synchronizeAndResume(); getEventManager().postResumeUnitOfWork(); } /** * PROTECTED: * Used in commit and commit-like methods to commit * internally started external transaction */ protected boolean commitInternallyStartedExternalTransaction() { boolean committed = false; if (!getParent().isInTransaction() || (wasTransactionBegunPrematurely() && (getParent().getTransactionMutex().getDepth() == 1))) { committed = getParent().commitExternalTransaction(); } return committed; } /** * INTERNAL: * Commit the changes to any objects to the parent. */ public void commitRootUnitOfWork() throws DatabaseException, OptimisticLockException { commitToDatabaseWithChangeSet(true); // Merge after commit mergeChangesIntoParent(); } /** * INTERNAL: * This method is used by the MappingWorkbench read-only files feature * It will commit a pre-built unitofwork change set to the database */ public void commitRootUnitOfWorkWithPreBuiltChangeSet(UnitOfWorkChangeSet uowChangeSet) throws DatabaseException, OptimisticLockException { //new code no need to check old commit commitToDatabaseWithPreBuiltChangeSet(uowChangeSet, true); // Merge after commit mergeChangesIntoParent(); } /** * INTERNAL: * CommitChanges To The Database from a calculated changeSet * @param commitTransaction false if called by writeChanges as intent is * not to finalize the transaction. */ protected void commitToDatabase(boolean commitTransaction) { try { //CR4202 - ported from 3.6.4 if (wasTransactionBegunPrematurely()) { // beginTransaction() has been already called setWasTransactionBegunPrematurely(false); } else { beginTransaction(); } if(commitTransaction) { setWasNonObjectLevelModifyQueryExecuted(false); } Vector deletedObjects = null;// PERF: Avoid deletion if nothing to delete. if (hasDeletedObjects()) { deletedObjects = new Vector(getDeletedObjects().size()); for (Enumeration objects = getDeletedObjects().keys(); objects.hasMoreElements();) { deletedObjects.addElement(objects.nextElement()); } } if (shouldPerformDeletesFirst) { if (hasDeletedObjects()) { // This must go to the commit manager because uow overrides to do normal deletion. getCommitManager().deleteAllObjects(deletedObjects); // Clear change sets of the deleted object to avoid redundant updates. for (Enumeration objects = getObjectsDeletedDuringCommit().keys(); objects.hasMoreElements();) { oracle.toplink.essentials.internal.sessions.ObjectChangeSet objectChangeSet = (oracle.toplink.essentials.internal.sessions.ObjectChangeSet)this.unitOfWorkChangeSet.getObjectChangeSetForClone(objects.nextElement()); if (objectChangeSet != null) { objectChangeSet.clear(); } } } // Let the commit manager figure out how to write the objects super.writeAllObjectsWithChangeSet(this.unitOfWorkChangeSet); // Issue all the SQL for the ModifyAllQuery's, don't touch the cache though issueModifyAllQueryList(); } else { // Let the commit manager figure out how to write the objects super.writeAllObjectsWithChangeSet(this.unitOfWorkChangeSet); if (hasDeletedObjects()) { // This must go to the commit manager because uow overrides to do normal deletion. getCommitManager().deleteAllObjects(deletedObjects); } // Issue all the SQL for the ModifyAllQuery's, don't touch the cache though issueModifyAllQueryList(); } // Issue prepare event. getEventManager().prepareUnitOfWork(); // writeChanges() does everything but this step. // do not lock objects unless we are at the commit s if (commitTransaction) { try{ // if we should be acquiring locks before commit let's do that here if (getDatasourceLogin().shouldSynchronizeObjectLevelReadWriteDatabase()){ setMergeManager(new MergeManager(this)); //If we are merging into the shared cache acquire all required locks before merging. getParent().getIdentityMapAccessorInstance().getWriteLockManager().acquireRequiredLocks(getMergeManager(), (UnitOfWorkChangeSet)getUnitOfWorkChangeSet()); } commitTransaction(); }catch (RuntimeException throwable){ if (getDatasourceLogin().shouldSynchronizeObjectLevelReadWriteDatabase() && (getMergeManager() != null)) { // exception occurred durring the commit. getParent().getIdentityMapAccessorInstance().getWriteLockManager().releaseAllAcquiredLocks(getMergeManager()); this.setMergeManager(null); } throw throwable; }catch (Error throwable){ if (getDatasourceLogin().shouldSynchronizeObjectLevelReadWriteDatabase() && (getMergeManager() != null)) { // exception occurred durring the commit. getParent().getIdentityMapAccessorInstance().getWriteLockManager().releaseAllAcquiredLocks(getMergeManager()); this.setMergeManager(null); } throw throwable; } }else{ setWasTransactionBegunPrematurely(true); } } catch (RuntimeException exception) { rollbackTransaction(commitTransaction); if (hasExceptionHandler()) { getExceptionHandler().handleException(exception); } else { throw exception; } } } /** * INTERNAL: * Commit the changes to any objects to the parent. * @param commitTransaction false if called by writeChanges as intent is * not to finalize the transaction. */ protected void commitToDatabaseWithChangeSet(boolean commitTransaction) throws DatabaseException, OptimisticLockException { try { startOperationProfile(SessionProfiler.UowCommit); // The sequence numbers are assigned outside of the commit transaction. // This improves concurrency, avoids deadlock and in the case of three-tier will // not leave invalid cached sequences on rollback. // Also must first set the commit manager active. getCommitManager().setIsActive(true); // This will assgin sequence numbers. IdentityHashtable allObjects = collectAndPrepareObjectsForCommit(); // Must clone because the commitManager will remove the objects from the collection // as the objects are written to the database. setAllClonesCollection((IdentityHashtable)allObjects.clone()); // Iterate over each clone and let the object build merge to clones into the originals. // The change set may already exist if using change tracking. if (getUnitOfWorkChangeSet() == null) { setUnitOfWorkChangeSet(new UnitOfWorkChangeSet()); } calculateChanges(getAllClones(), (UnitOfWorkChangeSet)getUnitOfWorkChangeSet()); // Bug 2834266 only commit to the database if changes were made, avoid begin/commit of transaction if (hasModifications()) { commitToDatabase(commitTransaction); } else { // CR#... need to commit the transaction if begun early. if (wasTransactionBegunPrematurely()) { if (commitTransaction) { // Must be set to false for release to know not to rollback. setWasTransactionBegunPrematurely(false); setWasNonObjectLevelModifyQueryExecuted(false); commitTransaction(); } } getCommitManager().setIsActive(false); } endOperationProfile(SessionProfiler.UowCommit); } catch (RuntimeException exception) { handleException((RuntimeException)exception); } } /** * INTERNAL: * Commit pre-built changeSet to the database changest to the database. */ protected void commitToDatabaseWithPreBuiltChangeSet(UnitOfWorkChangeSet uowChangeSet, boolean commitTransaction) throws DatabaseException, OptimisticLockException { try { // The sequence numbers are assigned outside of the commit transaction. // This improves concurrency, avoids deadlock and in the case of three-tier will // not leave invalid cached sequences on rollback. // Also must first set the commit manager active. getCommitManager().setIsActive(true); //Set empty collection in allClones for merge. setAllClonesCollection(new IdentityHashtable()); // Iterate over each clone and let the object build merge to clones into the originals. setUnitOfWorkChangeSet(uowChangeSet); commitToDatabase(commitTransaction); } catch (RuntimeException exception) { handleException((RuntimeException)exception); } } /** * INTERNAL: * This is internal to the uow, transactions should not be used explictly in a uow. * The uow shares its parents transactions. */ public void commitTransaction() throws DatabaseException { getParent().commitTransaction(); } /** * INTERNAL: * After writeChanges() everything has been done except for committing * the transaction. This allows that execution path to 'catch up'. */ protected void commitTransactionAfterWriteChanges() { setWasNonObjectLevelModifyQueryExecuted(false); if (hasModifications() || wasTransactionBegunPrematurely()) { try{ //gf934: ensuring release doesn't cause an extra rollback call if acquireRequiredLocks throws an exception setWasTransactionBegunPrematurely(false); // if we should be acquiring locks before commit let's do that here if (getDatasourceLogin().shouldSynchronizeObjectLevelReadWriteDatabase() && (getUnitOfWorkChangeSet() != null)) { setMergeManager(new MergeManager(this)); //If we are merging into the shared cache acquire all required locks before merging. getParent().getIdentityMapAccessorInstance().getWriteLockManager().acquireRequiredLocks(getMergeManager(), (UnitOfWorkChangeSet)getUnitOfWorkChangeSet()); } commitTransaction(); }catch (RuntimeException exception){ if (getDatasourceLogin().shouldSynchronizeObjectLevelReadWriteDatabase() && (getMergeManager() != null)) { // exception occurred durring the commit. getParent().getIdentityMapAccessorInstance().getWriteLockManager().releaseAllAcquiredLocks(getMergeManager()); this.setMergeManager(null); } rollbackTransaction(); release(); handleException(exception); }catch (Error throwable){ if (getDatasourceLogin().shouldSynchronizeObjectLevelReadWriteDatabase() && (getMergeManager() != null)) { // exception occurred durring the commit. getParent().getIdentityMapAccessorInstance().getWriteLockManager().releaseAllAcquiredLocks(getMergeManager()); this.setMergeManager(null); } throw throwable; } } } /** * INTERNAL: * Copy the read only classes from the unit of work. */ // Added Nov 8, 2000 JED for Patch 2.5.1.8, Ref: Prs 24502 public Vector copyReadOnlyClasses() { return Helper.buildVectorFromHashtableElements(getReadOnlyClasses()); } /** * PUBLIC: * Merge the attributes of the clone into the unit of work copy. * This can be used for objects that are returned from the client through * RMI serialization or other serialization mechanisms, because the RMI object will * be a clone this will merge its attributes correctly to preserve object identity * within the unit of work and record its changes. * Everything connected to this object (i.e. the entire object tree where rmiClone * is the root) is also merged. * * @return the registered version for the clone being merged. * @see #mergeClone(Object) * @see #shallowMergeClone(Object) */ public Object deepMergeClone(Object rmiClone) { return mergeClone(rmiClone, MergeManager.CASCADE_ALL_PARTS); } /** * PUBLIC: * Revert the object's attributes from the parent. * This reverts everything the object references. * * @return the object reverted. * @see #revertObject(Object) * @see #shallowRevertObject(Object) */ public Object deepRevertObject(Object clone) { return revertObject(clone, MergeManager.CASCADE_ALL_PARTS); } /** * ADVANCED: * Unregister the object with the unit of work. * This can be used to delete an object that was just created and is not yet persistent. * Delete object can also be used, but will result in inserting the object and then deleting it. * The method should be used carefully because it will delete all the reachable parts. */ public void deepUnregisterObject(Object clone) { unregisterObject(clone, DescriptorIterator.CascadeAllParts); } /** * PUBLIC: * Delete all of the objects and all of their privately owned parts in the database. * Delete operations are delayed in a unit of work until commit. */ public void deleteAllObjects(Vector domainObjects) { // This must be overriden to avoid dispatching to the commit manager. for (Enumeration objectsEnum = domainObjects.elements(); objectsEnum.hasMoreElements();) { deleteObject(objectsEnum.nextElement()); } } /** * INTERNAL: * Search for any objects in the parent that have not been registered. * These are required so that the nested unit of work does not add them to the parent * clone mapping on commit, causing possible incorrect insertions if they are dereferenced. */ protected void discoverAllUnregisteredNewObjects() { // 2612538 - the default size of IdentityHashtable (32) is appropriate IdentityHashtable visitedNodes = new IdentityHashtable(); IdentityHashtable newObjects = new IdentityHashtable(); IdentityHashtable existingObjects = new IdentityHashtable(); // Iterate over each clone. for (Enumeration clonesEnum = getCloneMapping().keys(); clonesEnum.hasMoreElements();) { Object clone = clonesEnum.nextElement(); discoverUnregisteredNewObjects(clone, newObjects, existingObjects, visitedNodes); } setUnregisteredNewObjects(newObjects); setUnregisteredExistingObjects(existingObjects); } /** * INTERNAL: * Traverse the object to find references to objects not registered in this unit of work. */ public void discoverUnregisteredNewObjects(Object clone, IdentityHashtable knownNewObjects, IdentityHashtable unregisteredExistingObjects, IdentityHashtable visitedObjects) { // This define an inner class for process the itteration operation, don't be scared, its just an inner class. DescriptorIterator iterator = new DescriptorIterator() { public void iterate(Object object) { // If the object is read-only the do not continue the traversal. if (isClassReadOnly(object.getClass(), this.getCurrentDescriptor())) { this.setShouldBreak(true); return; } /* CR3440: Steven Vo * Include the case that object is original then do nothing */ if (isSmartMerge() && isOriginalNewObject(object)) { return; } else if (!isObjectRegistered(object)) {// Don't need to check for aggregates, as iterator does not iterate on them by default. if ((shouldPerformNoValidation()) && (checkForUnregisteredExistingObject(object))) { // If no validation is performed and the object exists we need // To keep a record of this object to ignore it, also I need to // Stop iterating over it. ((IdentityHashtable)getUnregisteredExistingObjects()).put(object, object); this.setShouldBreak(true); return; } // This means it is a unregistered new object ((IdentityHashtable)getResult()).put(object, object); } } }; //set the collection in the UnitofWork to be this list setUnregisteredExistingObjects(unregisteredExistingObjects); iterator.setVisitedObjects(visitedObjects); iterator.setResult(knownNewObjects); iterator.setSession(this); // When using wrapper policy in EJB the iteration should stop on beans, // this is because EJB forces beans to be registered anyway and clone identity can be violated // and the violated clones references to session objects should not be traversed. iterator.setShouldIterateOverWrappedObjects(false); iterator.startIterationOn(clone); } /** * ADVANCED: * The unit of work performs validations such as, * ensuring multiple copies of the same object don't exist in the same unit of work, * ensuring deleted objects are not refered after commit, * ensures that objects from the parent cache are not refered in the unit of work cache. * The level of validation can be increased or decreased for debugging purposes or under * advanced situation where the application requires/desires to violate clone identity in the unit of work. * It is strongly suggested that clone identity not be violate in the unit of work. */ public void dontPerformValidation() { setValidationLevel(None); } /** * INTERNAL: * Override From session. Get the accessor based on the query, and execute call, * this is here for session broker. */ public Object executeCall(Call call, AbstractRecord translationRow, DatabaseQuery query) throws DatabaseException { Accessor accessor; if (query.getSessionName() == null) { accessor = query.getSession().getAccessor(query.getReferenceClass()); } else { accessor = query.getSession().getAccessor(query.getSessionName()); } query.setAccessor(accessor); try { return query.getAccessor().executeCall(call, translationRow, this); } finally { if (call.isFinished()) { query.setAccessor(null); } } } /** * ADVANCED: * Set optmistic read lock on the object. This feature is overide by normal optimistic lock. * when the object is changed in UnitOfWork. The cloneFromUOW must be the clone of from this * UnitOfWork and it must implements version locking or timestamp locking. * The SQL would look like the followings. * * If shouldModifyVersionField is true, * "UPDATE EMPLOYEE SET VERSION = 2 WHERE EMP_ID = 9 AND VERSION = 1" * * If shouldModifyVersionField is false, * "UPDATE EMPLOYEE SET VERSION = 1 WHERE EMP_ID = 9 AND VERSION = 1" */ public void forceUpdateToVersionField(Object lockObject, boolean shouldModifyVersionField) { ClassDescriptor descriptor = getDescriptor(lockObject); if (descriptor == null) { throw DescriptorException.missingDescriptor(lockObject.getClass().toString()); } getOptimisticReadLockObjects().put(descriptor.getObjectBuilder().unwrapObject(lockObject, this), new Boolean(shouldModifyVersionField)); } /** * INTERNAL: * The uow does not store a local accessor but shares its parents. */ public Accessor getAccessor() { return getParent().getAccessor(); } /** * INTERNAL: * The commit manager is used to resolve referncial integrity on commits of multiple objects. * The commit manage is lazy init from parent. */ public CommitManager getCommitManager() { // PERF: lazy init, not always required for release/commit with no changes. if (commitManager == null) { commitManager = new CommitManager(this); // Initialize the commit manager commitManager.setCommitOrder(getParent().getCommitManager().getCommitOrder()); } return commitManager; } /** * INTERNAL: * The uow does not store a local accessor but shares its parents. */ public Accessor getAccessor(Class domainClass) { return getParent().getAccessor(domainClass); } /** * INTERNAL: * The uow does not store a local accessor but shares its parents. */ public Accessor getAccessor(String sessionName) { return getParent().getAccessor(sessionName); } /** * PUBLIC: * Return the active unit of work for the current active external (JTS) transaction. * This should only be used with JTS and will return null if no external transaction exists. */ public oracle.toplink.essentials.sessions.UnitOfWork getActiveUnitOfWork() { /* Steven Vo: CR# 2517 This fixed the problem of returning null when this method is called on a UOW. UOW does not copy the parent session's external transaction controller when it is acquired but session does */ return getParent().getActiveUnitOfWork(); } /** * INTERNAL: * This method is used to get a copy of the collection of all clones in the UnitOfWork * @return oracle.toplink.essentials.internal.helper.IdentityHashtable */ protected IdentityHashtable getAllClones() { return this.allClones; } /** * INTERNAL: * Return any new objects matching the expression. * Used for in-memory querying. */ public Vector getAllFromNewObjects(Expression selectionCriteria, Class theClass, AbstractRecord translationRow, InMemoryQueryIndirectionPolicy valueHolderPolicy) { // If new object are in the cache then they will have already been queried. if (shouldNewObjectsBeCached()) { return new Vector(1); } // PERF: Avoid initialization of new objects if none. if (!hasNewObjects()) { return new Vector(1); } Vector objects = new Vector(); for (Enumeration newObjectsEnum = getNewObjectsOriginalToClone().elements(); newObjectsEnum.hasMoreElements();) { Object object = newObjectsEnum.nextElement(); if (theClass.isInstance(object)) { if (selectionCriteria == null) { objects.addElement(object); } else if (selectionCriteria.doesConform(object, this, translationRow, valueHolderPolicy)) { objects.addElement(object); } } } return objects; } /** * INTERNAL: * Return the backup clone for the working clone. */ public Object getBackupClone(Object clone) throws QueryException { Object backupClone = getCloneMapping().get(clone); if (backupClone != null) { return backupClone; } /* CR3440: Steven Vo * Smart merge if neccessary in isObjectRegistered() */ if (isObjectRegistered(clone)) { return getCloneMapping().get(clone); } else { ClassDescriptor descriptor = getDescriptor(clone); Vector primaryKey = keyFromObject(clone, descriptor); // This happens if clone was from the parent identity map. if (getParent().getIdentityMapAccessorInstance().containsObjectInIdentityMap(primaryKey, clone.getClass(), descriptor)) { //cr 3796 if ((getUnregisteredNewObjects().get(clone) != null) && isMergePending()) { //Another thread has read the new object before it has had a chance to //merge this object. // It also means it is an unregistered new object, so create a new backup clone for it. return descriptor.getObjectBuilder().buildNewInstance(); } if (hasObjectsDeletedDuringCommit() && getObjectsDeletedDuringCommit().containsKey(clone)) { throw QueryException.backupCloneIsDeleted(clone); } throw QueryException.backupCloneIsOriginalFromParent(clone); } // Also check that the object is not the original to a registered new object // (the original should not be referenced if not smart merge, this is an error. else if (hasNewObjects() && getNewObjectsOriginalToClone().containsKey(clone)) { /* CR3440: Steven Vo * Check case that clone is original */ if (isSmartMerge()) { backupClone = getCloneMapping().get(getNewObjectsOriginalToClone().get(clone)); } else { throw QueryException.backupCloneIsOriginalFromSelf(clone); } } else { // This means it is an unregistered new object, so create a new backup clone for it. backupClone = descriptor.getObjectBuilder().buildNewInstance(); } } return backupClone; } /** * INTERNAL: * Return the backup clone for the working clone. */ public Object getBackupCloneForCommit(Object clone) { Object backupClone = getBackupClone(clone); /* CR3440: Steven Vo * Build new instance only if it was not handled by getBackupClone() */ if (isCloneNewObject(clone)) { return getDescriptor(clone).getObjectBuilder().buildNewInstance(); } return backupClone; } /** * ADVANCED: * This method Will Calculate the chages for the UnitOfWork. Without assigning sequence numbers * This is a Computationaly intensive operation and should be avoided unless necessary. * A valid changeSet, with sequencenumbers can be collected from the UnitOfWork After the commit * is complete by calling unitOfWork.getUnitOfWorkChangeSet() */ public oracle.toplink.essentials.changesets.UnitOfWorkChangeSet getCurrentChanges() { IdentityHashtable allObjects = null; allObjects = collectAndPrepareObjectsForNestedMerge(); return calculateChanges(allObjects, new UnitOfWorkChangeSet()); } /** * INTERNAL: * Gets the next link in the chain of sessions followed by a query's check * early return, the chain of sessions with identity maps all the way up to * the root session. *

* Used for session broker which delegates to registered sessions, or UnitOfWork * which checks parent identity map also. * @param canReturnSelf true when method calls itself. If the path * starting at this is acceptable. Sometimes true if want to * move to the first valid session, i.e. executing on ClientSession when really * should be on ServerSession. * @param terminalOnly return the session we will execute the call on, not * the next step towards it. * @return this if there is no next link in the chain */ public AbstractSession getParentIdentityMapSession(DatabaseQuery query, boolean canReturnSelf, boolean terminalOnly) { if (canReturnSelf && !terminalOnly) { return this; } else { return getParent().getParentIdentityMapSession(query, true, terminalOnly); } } /** * INTERNAL: * Gets the session which this query will be executed on. * Generally will be called immediately before the call is translated, * which is immediately before session.executeCall. *

* Since the execution session also knows the correct datasource platform * to execute on, it is often used in the mappings where the platform is * needed for type conversion, or where calls are translated. *

* Is also the session with the accessor. Will return a ClientSession if * it is in transaction and has a write connection. * @return a session with a live accessor * @param query may store session name or reference class for brokers case */ public AbstractSession getExecutionSession(DatabaseQuery query) { // This optimization is only for when executing with a ClientSession in // transaction. In that case log with the UnitOfWork instead of the // ClientSession. // Note that if actually executing on ServerSession or a registered // session of a broker, must execute on that session directly. //bug 5201121 Always use the parent or execution session from the parent // should never use the unit of work as it does not controll the //accessors and with a sessioon broker it will not have the correct //login info return getParent().getExecutionSession(query); } /** * INTERNAL: * Return the clone mapping. * The clone mapping contains clone of all registered objects, * this is required to store the original state of the objects when registered * so that only what is changed will be commited to the database and the parent, * (this is required to support parralel unit of work). */ public IdentityHashtable getCloneMapping() { // PERF: lazy-init (3286089) if (cloneMapping == null) { // 2612538 - the default size of IdentityHashtable (32) is appropriate cloneMapping = new IdentityHashtable(); } return cloneMapping; } protected boolean hasCloneMapping() { return ((cloneMapping != null) && !cloneMapping.isEmpty()); } /** * INTERNAL: * Hashtable used to avoid garbage collection in weak caches. * ALSO, hashtable used as lookup when originals used for merge when original in * identitymap can not be found. As in a CacheIdentityMap */ public IdentityHashtable getCloneToOriginals() { //Helper.toDo("proper fix, collection merge can have objects disapear for original."); if (cloneToOriginals == null) {// Must lazy initialize for remote. // 2612538 - the default size of IdentityHashtable (32) is appropriate cloneToOriginals = new IdentityHashtable(); } return cloneToOriginals; } protected boolean hasCloneToOriginals() { return ((cloneToOriginals != null) && !cloneToOriginals.isEmpty()); } /** * INTERNAL: * Return if there are any registered new objects. * This is used for both newObjectsOriginalToClone and newObjectsCloneToOriginal as they are always in synch. * PERF: Used to avoid initialization of new objects hashtable unless required. */ public boolean hasNewObjects() { return ((newObjectsOriginalToClone != null) && !newObjectsOriginalToClone.isEmpty()); } /** * INTERNAL: Returns the set of read-only classes that gets assigned to each newly created UnitOfWork. * * @see oracle.toplink.essentials.sessions.Project#setDefaultReadOnlyClasses(Vector) */ public Vector getDefaultReadOnlyClasses() { return getParent().getDefaultReadOnlyClasses(); } /** * INTERNAL: * The deleted objects stores any objects removed during the unit of work. * On commit they will all be removed from the database. */ public IdentityHashtable getDeletedObjects() { if (deletedObjects == null) { // 2612538 - the default size of IdentityHashtable (32) is appropriate deletedObjects = new IdentityHashtable(); } return deletedObjects; } protected boolean hasDeletedObjects() { return ((deletedObjects != null) && !deletedObjects.isEmpty()); } /** * PUBLIC: * Return the descriptor for the alias. * UnitOfWork delegates this to the parent * Introduced because of Bug#2610803 */ public ClassDescriptor getDescriptorForAlias(String alias) { return getParent().getDescriptorForAlias(alias); } /** * PUBLIC: * Return all registered descriptors. * The unit of work inherits its parent's descriptors. The each descriptor's Java Class * is used as the key in the Hashtable returned. */ public Map getDescriptors() { return getParent().getDescriptors(); } /** * INTERNAL: * The life cycle tracks if the unit of work is active and is used for JTS. */ public int getLifecycle() { return lifecycle; } /** * A reference to the last used merge manager. This is used to track locked * objects. */ public MergeManager getMergeManager() { return this.lastUsedMergeManager; } /** * INTERNAL: * The hashtable stores any new aggregates that have been cloned. */ public IdentityHashtable getNewAggregates() { if (this.newAggregates == null) { // 2612538 - the default size of IdentityHashtable (32) is appropriate this.newAggregates = new IdentityHashtable(); } return newAggregates; } /** * INTERNAL: * The new objects stores any objects newly created during the unit of work. * On commit they will all be inserted into the database. */ public synchronized IdentityHashtable getNewObjectsCloneToOriginal() { if (newObjectsCloneToOriginal == null) { // 2612538 - the default size of IdentityHashtable (32) is appropriate newObjectsCloneToOriginal = new IdentityHashtable(); } return newObjectsCloneToOriginal; } /** * INTERNAL: * The new objects stores any objects newly created during the unit of work. * On commit they will all be inserted into the database. */ public synchronized IdentityHashtable getNewObjectsOriginalToClone() { if (newObjectsOriginalToClone == null) { // 2612538 - the default size of IdentityHashtable (32) is appropriate newObjectsOriginalToClone = new IdentityHashtable(); } return newObjectsOriginalToClone; } /** * INTERNAL: * Return the Sequencing object used by the session. */ public Sequencing getSequencing() { return getParent().getSequencing(); } /** * INTERNAL: * Marked internal as this is not customer API but helper methods for * accessing the server platform from within TopLink's other sessions types * (ie not DatabaseSession) */ public ServerPlatform getServerPlatform(){ return getParent().getServerPlatform(); } /** * INTERNAL: * Returns the type of session, its class. *

* Override to hide from the user when they are using an internal subclass * of a known class. *

* A user does not need to know that their UnitOfWork is a * non-deferred UnitOfWork, or that their ClientSession is an * IsolatedClientSession. */ public String getSessionTypeString() { return "UnitOfWork"; } /** * INTERNAL: * Called after transaction is completed (committed or rolled back) */ public void afterTransaction(boolean committed, boolean isExternalTransaction) { if (!committed && isExternalTransaction) { // In case jts transaction was internally started but rolled back // directly by TransactionManager this flag may still be true during afterCompletion getParent().setWasJTSTransactionInternallyStarted(false); //bug#4699614 -- added a new life cycle status so we know if the external transaction was rolledback and we don't try to rollback again later setLifecycle(AfterExternalTransactionRolledBack); } if ((getMergeManager() != null) && (getMergeManager().getAcquiredLocks() != null) && (!getMergeManager().getAcquiredLocks().isEmpty())) { //may have unreleased cache locks because of a rollback... getParent().getIdentityMapAccessorInstance().getWriteLockManager().releaseAllAcquiredLocks(getMergeManager()); this.setMergeManager(null); } getParent().afterTransaction(committed, isExternalTransaction); } /** * INTERNAL: * Return any new object matching the expression. * Used for in-memory querying. */ public Object getObjectFromNewObjects(Class theClass, Vector selectionKey) { // PERF: Avoid initialization of new objects if none. if (!hasNewObjects()) { return null; } ObjectBuilder objectBuilder = getDescriptor(theClass).getObjectBuilder(); for (Enumeration newObjectsEnum = getNewObjectsOriginalToClone().elements(); newObjectsEnum.hasMoreElements();) { Object object = newObjectsEnum.nextElement(); if (theClass.isInstance(object)) { // removed dead null check as this method is never called if selectionKey == null Vector primaryKey = objectBuilder.extractPrimaryKeyFromObject(object, this); if (new CacheKey(primaryKey).equals(new CacheKey(selectionKey))) { return object; } } } return null; } /** * INTERNAL: * Return any new object matching the expression. * Used for in-memory querying. */ public Object getObjectFromNewObjects(Expression selectionCriteria, Class theClass, AbstractRecord translationRow, InMemoryQueryIndirectionPolicy valueHolderPolicy) { // PERF: Avoid initialization of new objects if none. if (!hasNewObjects()) { return null; } for (Enumeration newObjectsEnum = getNewObjectsOriginalToClone().elements(); newObjectsEnum.hasMoreElements();) { Object object = newObjectsEnum.nextElement(); if (theClass.isInstance(object)) { if (selectionCriteria == null) { return object; } if (selectionCriteria.doesConform(object, this, translationRow, valueHolderPolicy)) { return object; } } } return null; } /** * INTERNAL: * Returns all the objects which are deleted during root commit of unit of work. */ public IdentityHashtable getObjectsDeletedDuringCommit() { // PERF: lazy-init (3286089) if (objectsDeletedDuringCommit == null) { // 2612538 - the default size of IdentityHashtable (32) is appropriate objectsDeletedDuringCommit = new IdentityHashtable(); } return objectsDeletedDuringCommit; } protected boolean hasObjectsDeletedDuringCommit() { return ((objectsDeletedDuringCommit != null) && !objectsDeletedDuringCommit.isEmpty()); } /** * INTERNAL: * Return optimistic read lock objects */ public Hashtable getOptimisticReadLockObjects() { if (optimisticReadLockObjects == null) { optimisticReadLockObjects = new Hashtable(2); } return optimisticReadLockObjects; } /** * INTERNAL: * Return the original version of the new object (working clone). */ public Object getOriginalVersionOfNewObject(Object workingClone) { // PERF: Avoid initialization of new objects if none. if (!hasNewObjects()) { return null; } return getNewObjectsCloneToOriginal().get(workingClone); } /** * ADVANCED: * Return the original version of the object(clone) from the parent's identity map. */ public Object getOriginalVersionOfObject(Object workingClone) { // Can be null when called from the mappings. if (workingClone == null) { return null; } ClassDescriptor descriptor = getDescriptor(workingClone); ObjectBuilder builder = descriptor.getObjectBuilder(); Object implementation = builder.unwrapObject(workingClone, this); Vector primaryKey = builder.extractPrimaryKeyFromObject(implementation, this); Object original = getParent().getIdentityMapAccessorInstance().getFromIdentityMap(primaryKey, implementation.getClass(), descriptor, null); if (original == null) { // Check if it is a registered new object. original = getOriginalVersionOfNewObject(implementation); } if (original == null) { // For bug 3013948 looking in the cloneToOriginals mapping will not help // if the object was never registered. if (isClassReadOnly(implementation.getClass(), descriptor)) { return implementation; } // The object could have been removed from the cache even though it was in the unit of work. // fix for 2.5.1.3 PWK (1360) if (hasCloneToOriginals()) { original = getCloneToOriginals().get(workingClone); } } if (original == null) { // This means that it must be an unregistered new object, so register a new clone as its original. original = buildOriginal(implementation); } return original; } /** * ADVANCED: * Return the original version of the object(clone) from the parent's identity map. */ public Object getOriginalVersionOfObjectOrNull(Object workingClone) { // Can be null when called from the mappings. if (workingClone == null) { return null; } ClassDescriptor descriptor = getDescriptor(workingClone); ObjectBuilder builder = descriptor.getObjectBuilder(); Object implementation = builder.unwrapObject(workingClone, this); Vector primaryKey = builder.extractPrimaryKeyFromObject(implementation, this); Object original = getParent().getIdentityMapAccessorInstance().getFromIdentityMap(primaryKey, implementation.getClass(), descriptor, null); if (original == null) { // Check if it is a registered new object. original = getOriginalVersionOfNewObject(implementation); } if (original == null) { // For bug 3013948 looking in the cloneToOriginals mapping will not help // if the object was never registered. if (isClassReadOnly(implementation.getClass(), descriptor)) { return implementation; } // The object could have been removed from the cache even though it was in the unit of work. // fix for 2.5.1.3 PWK (1360) if (hasCloneToOriginals()) { original = getCloneToOriginals().get(workingClone); } } return original; } /** * PUBLIC: * Return the parent. * This is a unit of work if nested, otherwise a database session or client session. */ public AbstractSession getParent() { return parent; } /** * INTERNAL: * Return the platform for a particular class. */ public Platform getPlatform(Class domainClass) { return getParent().getPlatform(domainClass); } /** * INTERNAL: * Return whether to throw exceptions on conforming queries */ public int getShouldThrowConformExceptions() { return shouldThrowConformExceptions; } /** * PUBLIC: * Return the query from the session pre-defined queries with the given name. * This allows for common queries to be pre-defined, reused and executed by name. */ public DatabaseQuery getQuery(String name, Vector arguments) { DatabaseQuery query = super.getQuery(name, arguments); if (query == null) { query = getParent().getQuery(name, arguments); } return query; } /** * PUBLIC: * Return the query from the session pre-defined queries with the given name. * This allows for common queries to be pre-defined, reused and executed by name. */ public DatabaseQuery getQuery(String name) { DatabaseQuery query = super.getQuery(name); if (query == null) { query = getParent().getQuery(name); } return query; } /** * INTERNAL: * Returns the set of read-only classes for the receiver. * Use this method with setReadOnlyClasses() to modify a UnitOfWork's set of read-only * classes before using the UnitOfWork. * @return Hashtable containing the Java Classes that are currently read-only. * @see #setReadOnlyClasses(Vector) */ public Hashtable getReadOnlyClasses() { return readOnlyClasses; } /** * INTERNAL: * The removed objects stores any newly registered objects removed during the nested unit of work. * On commit they will all be removed from the parent unit of work. */ protected IdentityHashtable getRemovedObjects() { // PERF: lazy-init (3286089) if (removedObjects == null) { // 2612538 - the default size of IdentityHashtable (32) is appropriate removedObjects = new IdentityHashtable(); } return removedObjects; } protected boolean hasRemovedObjects() { return ((removedObjects != null) && !removedObjects.isEmpty()); } protected boolean hasModifyAllQueries() { return ((modifyAllQueries != null) && !modifyAllQueries.isEmpty()); } protected boolean hasDeferredModifyAllQueries() { return ((deferredModifyAllQueries != null) && !deferredModifyAllQueries.isEmpty()); } /** * INTERNAL: * Find out what the lifecycle state of this UoW is in. */ public int getState() { return lifecycle; } /** * INTERNAL: * PERF: Return the associated external transaction. * Used to optimize activeUnitOfWork lookup. */ public Object getTransaction() { return transaction; } /** * INTERNAL: * PERF: Set the associated external transaction. * Used to optimize activeUnitOfWork lookup. */ public void setTransaction(Object transaction) { this.transaction = transaction; } /** * ADVANCED: * Returns the currentChangeSet from the UnitOfWork. * This is only valid after the UnitOfWOrk has commited successfully */ public oracle.toplink.essentials.changesets.UnitOfWorkChangeSet getUnitOfWorkChangeSet() { return unitOfWorkChangeSet; } /** * INTERNAL: * Used to lazy Initialize the unregistered existing Objects collection. * @return oracle.toplink.essentials.internal.helper.IdentityHashtable */ public oracle.toplink.essentials.internal.helper.IdentityHashtable getUnregisteredExistingObjects() { if (this.unregisteredExistingObjects == null) { // 2612538 - the default size of IdentityHashtable (32) is appropriate this.unregisteredExistingObjects = new IdentityHashtable(); } return unregisteredExistingObjects; } /** * INTERNAL: * This is used to store unregistred objects discovered in the parent so that the child * unit of work knows not to register them on commit. */ protected IdentityHashtable getUnregisteredNewObjects() { if (unregisteredNewObjects == null) { // 2612538 - the default size of IdentityHashtable (32) is appropriate unregisteredNewObjects = new IdentityHashtable(); } return unregisteredNewObjects; } /** * ADVANCED: * The unit of work performs validations such as, * ensuring multiple copies of the same object don't exist in the same unit of work, * ensuring deleted objects are not refered after commit, * ensures that objects from the parent cache are not refered in the unit of work cache. * The level of validation can be increased or decreased for debugging purposes or under * advanced situation where the application requires/desires to violate clone identity in the unit of work. * It is strongly suggested that clone identity not be violate in the unit of work. */ public int getValidationLevel() { return validationLevel; } /** * ADVANCED: * The Unit of work is capable of preprocessing to determine if any on the clone have been changed. * This is computationaly expensive and should be avoided on large object graphs. */ public boolean hasChanges() { if (hasNewObjects()) { return true; } IdentityHashtable allObjects = collectAndPrepareObjectsForNestedMerge(); //Using the nested merge prevent the UnitOfWork from assigning sequence numbers if (!getUnregisteredNewObjects().isEmpty()) { return true; } if (hasDeletedObjects()) { return true; } UnitOfWorkChangeSet changeSet = calculateChanges(allObjects, new UnitOfWorkChangeSet()); return changeSet.hasChanges(); } /** * INTERNAL: * Does this unit of work have any changes or anything that requires a write * to the database and a transaction to be started. * Should be called after changes are calculated internally by commit. *

* Note if a transaction was begun prematurely it still needs to be committed. */ protected boolean hasModifications() { if (getUnitOfWorkChangeSet().hasChanges() || hasDeletedObjects() || hasModifyAllQueries() || hasDeferredModifyAllQueries() || ((oracle.toplink.essentials.internal.sessions.UnitOfWorkChangeSet)getUnitOfWorkChangeSet()).hasForcedChanges()) { return true; } else { return false; } } /** * INTERNAL: * Set up the IdentityMapManager. This method allows subclasses of Session to override * the default IdentityMapManager functionality. */ public void initializeIdentityMapAccessor() { this.identityMapAccessor = new UnitOfWorkIdentityMapAccessor(this, new IdentityMapManager(this)); } /** * INTERNAL: * Return the results from exeucting the database query. * the arguments should be a database row with raw data values. */ public Object internalExecuteQuery(DatabaseQuery query, AbstractRecord databaseRow) throws DatabaseException, QueryException { if (!isActive()) { throw QueryException.querySentToInactiveUnitOfWork(query); } return query.executeInUnitOfWork(this, databaseRow); } /** * INTERNAL: * Register the object with the unit of work. * This does not perform wrapping or unwrapping. * This is used for internal registration in the merge manager. */ public Object internalRegisterObject(Object object, ClassDescriptor descriptor) { if (object == null) { return null; } if (descriptor.isAggregateDescriptor() || descriptor.isAggregateCollectionDescriptor()) { throw ValidationException.cannotRegisterAggregateObjectInUnitOfWork(object.getClass()); } Object registeredObject = checkIfAlreadyRegistered(object, descriptor); if (registeredObject == null) { registeredObject = checkExistence(object); if (registeredObject == null) { // This means that the object is not in the parent im, so was created under this unit of work. // This means that it must be new. registeredObject = cloneAndRegisterNewObject(object); } } return registeredObject; } /** * PUBLIC: * Return if the unit of work is active. (i.e. has not been released). */ public boolean isActive() { return !isDead(); } /** * PUBLIC: * Checks to see if the specified class or descriptor is read-only or not in this UnitOfWork. * * @return boolean, true if the class is read-only, false otherwise. */ public boolean isClassReadOnly(Class theClass, ClassDescriptor descriptor) { if ((descriptor != null) && (descriptor.shouldBeReadOnly())) { return true; } if ((theClass != null) && getReadOnlyClasses().containsKey(theClass)) { return true; } return false; } /** * INTERNAL: * Check if the object is already registered. */ public boolean isCloneNewObject(Object clone) { // PERF: Avoid initialization of new objects if none. if (!hasNewObjects()) { return false; } return getNewObjectsCloneToOriginal().containsKey(clone); } /** * INTERNAL: * Return if the unit of work is waiting to be committed or in the process of being committed. */ public boolean isCommitPending() { return getLifecycle() == CommitPending; } /** * INTERNAL: * Return if the unit of work is dead. */ public boolean isDead() { return getLifecycle() == Death; } /** * PUBLIC: * Return whether the session currently has a database transaction in progress. */ public boolean isInTransaction() { return getParent().isInTransaction(); } /** * INTERNAL: * Return if the unit of work is waiting to be merged or in the process of being merged. */ public boolean isMergePending() { return getLifecycle() == MergePending; } /** * INTERNAL: * Has writeChanges() been attempted on this UnitOfWork? It may have * either suceeded or failed but either way the UnitOfWork is in a highly * restricted state. */ public boolean isAfterWriteChangesButBeforeCommit() { return ((getLifecycle() == CommitTransactionPending) || (getLifecycle() == WriteChangesFailed)); } /** * INTERNAL: * Once writeChanges has failed all a user can do really is rollback. */ protected boolean isAfterWriteChangesFailed() { return getLifecycle() == WriteChangesFailed; } /** * PUBLIC: * Return whether this session is a nested unit of work or not. */ public boolean isNestedUnitOfWork() { return false; } /** * INTERNAL: * Return if the object has been deleted in this unit of work. */ public boolean isObjectDeleted(Object object) { boolean isDeleted = false; if (hasDeletedObjects()) { isDeleted = getDeletedObjects().containsKey(object); } if (getParent().isUnitOfWork()) { return isDeleted || ((UnitOfWorkImpl)getParent()).isObjectDeleted(object); } else { return isDeleted; } } /** * INTERNAL: * This method is used to determine if the clone is a new Object in the UnitOfWork */ public boolean isObjectNew(Object clone) { //CR3678 - ported from 4.0 return (isCloneNewObject(clone) || (!isObjectRegistered(clone) && !getReadOnlyClasses().contains(clone.getClass()) && !getUnregisteredExistingObjects().contains(clone))); } /** * INTERNAL: * Return whether the clone object is already registered. */ public boolean isObjectRegistered(Object clone) { if (getCloneMapping().containsKey(clone)) { return true; } // We do smart merge here if (isSmartMerge()){ ClassDescriptor descriptor = getDescriptor(clone); if (getParent().getIdentityMapAccessorInstance().containsObjectInIdentityMap(keyFromObject(clone, descriptor), clone.getClass(), descriptor) ) { mergeCloneWithReferences(clone); // don't put clone in clone mapping since it would result in duplicate clone return true; } } return false; } /** * INTERNAL: * Return whether the original object is new. * It was either registered as new or discovered as a new aggregate * within another new object. */ public boolean isOriginalNewObject(Object original) { return (hasNewObjects() && getNewObjectsOriginalToClone().containsKey(original)) || getNewAggregates().containsKey(original); } /** * INTERNAL: * Return the status of smart merge */ public static boolean isSmartMerge() { return SmartMerge; } /** * INTERNAL: * For synchronized units of work, dump SQL to database. * For cases where writes occur before the end of the transaction don't commit */ public void issueSQLbeforeCompletion() { issueSQLbeforeCompletion(true); } /** * INTERNAL: * For synchronized units of work, dump SQL to database. * For cases where writes occur before the end of the transaction don't commit */ public void issueSQLbeforeCompletion(boolean commitTransaction) { if (getLifecycle() == CommitTransactionPending) { commitTransactionAfterWriteChanges(); return; } // CR#... call event and log. log(SessionLog.FINER, SessionLog.TRANSACTION, "begin_unit_of_work_commit"); getEventManager().preCommitUnitOfWork(); setLifecycle(CommitPending); commitToDatabaseWithChangeSet(commitTransaction); } /** * INTERNAL: * Will notify all the deferred ModifyAllQuery's (excluding UpdateAllQuery's) and deferred UpdateAllQuery's to execute. */ protected void issueModifyAllQueryList() { if (deferredModifyAllQueries != null) { for (int i = 0; i < deferredModifyAllQueries.size(); i++) { Object[] queries = (Object[])deferredModifyAllQueries.get(i); ModifyAllQuery query = (ModifyAllQuery)queries[0]; AbstractRecord translationRow = (AbstractRecord)queries[1]; getParent().executeQuery(query, translationRow); } } } /** * INTERNAL: * Return if this session is a synchronized unit of work. */ public boolean isSynchronized() { return isSynchronized; } /** * PUBLIC: * Return if this session is a unit of work. */ public boolean isUnitOfWork() { return true; } /** * INTERNAL: Merge the changes to all objects to the parent. */ protected void mergeChangesIntoParent() { UnitOfWorkChangeSet uowChangeSet = (UnitOfWorkChangeSet)getUnitOfWorkChangeSet(); if (uowChangeSet == null) { // may be using the old commit prosess usesOldCommit() setUnitOfWorkChangeSet(new UnitOfWorkChangeSet()); uowChangeSet = (UnitOfWorkChangeSet)getUnitOfWorkChangeSet(); calculateChanges(getAllClones(), (UnitOfWorkChangeSet)getUnitOfWorkChangeSet()); } // 3286123 - if no work to be done, skip this part of uow.commit() if (hasModifications()) { setPendingMerge(); startOperationProfile(SessionProfiler.Merge); // Ensure concurrency if cache isolation requires. getParent().getIdentityMapAccessorInstance().acquireWriteLock(); MergeManager manager = getMergeManager(); if (manager == null){ // no MergeManager created for locks durring commit manager = new MergeManager(this); } try { if (!isNestedUnitOfWork()) { preMergeChanges(); } // Must clone the clone mapping because entries can be added to it during the merging, // and that can lead to concurrency problems. getParent().getEventManager().preMergeUnitOfWorkChangeSet(uowChangeSet); if (!isNestedUnitOfWork() && getDatasourceLogin().shouldSynchronizeObjectLevelReadWrite()) { setMergeManager(manager); //If we are merging into the shared cache acquire all required locks before merging. getParent().getIdentityMapAccessorInstance().getWriteLockManager().acquireRequiredLocks(getMergeManager(), (UnitOfWorkChangeSet)getUnitOfWorkChangeSet()); } Enumeration changeSetLists = ((UnitOfWorkChangeSet)getUnitOfWorkChangeSet()).getObjectChanges().elements(); while (changeSetLists.hasMoreElements()) { Hashtable objectChangesList = (Hashtable)((Hashtable)changeSetLists.nextElement()).clone(); if (objectChangesList != null) {// may be no changes for that class type. for (Enumeration pendingEnum = objectChangesList.elements(); pendingEnum.hasMoreElements();) { ObjectChangeSet changeSetToWrite = (ObjectChangeSet)pendingEnum.nextElement(); if (changeSetToWrite.hasChanges()) { Object objectToWrite = changeSetToWrite.getUnitOfWorkClone(); //bug#4154455 -- only merge into the shared cache if the object is new or if it already exists in the shared cache if (changeSetToWrite.isNew() || (getOriginalVersionOfObjectOrNull(objectToWrite) != null)) { manager.mergeChanges(objectToWrite, changeSetToWrite); } } else { // if no 'real' changes to the object change set, remove it from the // list so it won't be unnecessarily sent via cache sync. uowChangeSet.removeObjectChangeSet(changeSetToWrite); } } } } // Notify the queries to merge into the shared cache if (modifyAllQueries != null) { for (int i = 0; i < modifyAllQueries.size(); i++) { ModifyAllQuery query = (ModifyAllQuery)modifyAllQueries.get(i); query.setSession(getParent());// ensure the query knows which cache to update query.mergeChangesIntoSharedCache(); } } if (isNestedUnitOfWork()) { changeSetLists = ((UnitOfWorkChangeSet)getUnitOfWorkChangeSet()).getNewObjectChangeSets().elements(); while (changeSetLists.hasMoreElements()) { IdentityHashtable objectChangesList = (IdentityHashtable)((IdentityHashtable)changeSetLists.nextElement()).clone(); if (objectChangesList != null) {// may be no changes for that class type. for (Enumeration pendingEnum = objectChangesList.elements(); pendingEnum.hasMoreElements();) { ObjectChangeSet changeSetToWrite = (ObjectChangeSet)pendingEnum.nextElement(); if (changeSetToWrite.hasChanges()) { Object objectToWrite = changeSetToWrite.getUnitOfWorkClone(); manager.mergeChanges(objectToWrite, changeSetToWrite); } else { // if no 'real' changes to the object change set, remove it from the // list so it won't be unnecessarily sent via cache sync. uowChangeSet.removeObjectChangeSet(changeSetToWrite); } } } } } if (!isNestedUnitOfWork()) { //If we are merging into the shared cache release all of the locks that we acquired. getParent().getIdentityMapAccessorInstance().getWriteLockManager().releaseAllAcquiredLocks(manager); setMergeManager(null); postMergeChanges(); } } finally { if (!isNestedUnitOfWork() && !manager.getAcquiredLocks().isEmpty()) { // if the locks have not already been released (!acquiredLocks.empty) // then there must have been an error, release all of the locks. getParent().getIdentityMapAccessorInstance().getWriteLockManager().releaseAllAcquiredLocks(manager); setMergeManager(null); } getParent().getIdentityMapAccessorInstance().releaseWriteLock(); getParent().getEventManager().postMergeUnitOfWorkChangeSet(uowChangeSet); endOperationProfile(SessionProfiler.Merge); } } } /** * PUBLIC: * Merge the attributes of the clone into the unit of work copy. * This can be used for objects that are returned from the client through * RMI serialization (or another serialization mechanism), because the RMI object * will be a clone this will merge its attributes correctly to preserve object * identity within the unit of work and record its changes. * * The object and its private owned parts are merged. * * @return the registered version for the clone being merged. * @see #shallowMergeClone(Object) * @see #deepMergeClone(Object) */ public Object mergeClone(Object rmiClone) { return mergeClone(rmiClone, MergeManager.CASCADE_PRIVATE_PARTS); } /** * INTERNAL: * Merge the attributes of the clone into the unit of work copy. */ public Object mergeClone(Object rmiClone, int cascadeDepth) { if (rmiClone == null) { return null; } //CR#2272 logDebugMessage(rmiClone, "merge_clone"); startOperationProfile(SessionProfiler.Merge); ObjectBuilder builder = getDescriptor(rmiClone).getObjectBuilder(); Object implementation = builder.unwrapObject(rmiClone, this); MergeManager manager = new MergeManager(this); manager.mergeCloneIntoWorkingCopy(); manager.setCascadePolicy(cascadeDepth); Object merged = null; try { merged = manager.mergeChanges(implementation, null); } catch (RuntimeException exception) { merged = handleException(exception); } endOperationProfile(SessionProfiler.Merge); return merged; } /** * INTERNAL: * for synchronized units of work, merge changes into parent */ public void mergeClonesAfterCompletion() { mergeChangesIntoParent(); // CR#... call event and log. getEventManager().postCommitUnitOfWork(); log(SessionLog.FINER, SessionLog.TRANSACTION, "end_unit_of_work_commit"); } /** * PUBLIC: * Merge the attributes of the clone into the unit of work copy. * This can be used for objects that are returned from the client through * RMI serialization (or another serialization mechanism), because the RMI object * will be a clone this will merge its attributes correctly to preserve object * identity within the unit of work and record its changes. * * The object and its private owned parts are merged. This will include references from * dependent objects to independent objects. * * @return the registered version for the clone being merged. * @see #shallowMergeClone(Object) * @see #deepMergeClone(Object) */ public Object mergeCloneWithReferences(Object rmiClone) { return this.mergeCloneWithReferences(rmiClone, MergeManager.CASCADE_PRIVATE_PARTS); } /** * PUBLIC: * Merge the attributes of the clone into the unit of work copy. * This can be used for objects that are returned from the client through * RMI serialization (or another serialization mechanism), because the RMI object * will be a clone this will merge its attributes correctly to preserve object * identity within the unit of work and record its changes. * * The object and its private owned parts are merged. This will include references from * dependent objects to independent objects. * * @return the registered version for the clone being merged. * @see #shallowMergeClone(Object) * @see #deepMergeClone(Object) */ public Object mergeCloneWithReferences(Object rmiClone, int cascadePolicy) { return mergeCloneWithReferences(rmiClone, cascadePolicy, false); } /** * INTERNAL: * Merge the attributes of the clone into the unit of work copy. * This can be used for objects that are returned from the client through * RMI serialization (or another serialization mechanism), because the RMI object * will be a clone this will merge its attributes correctly to preserve object * identity within the unit of work and record its changes. * * The object and its private owned parts are merged. This will include references from * dependent objects to independent objects. * * @return the registered version for the clone being merged. * @see #shallowMergeClone(Object) * @see #deepMergeClone(Object) */ public Object mergeCloneWithReferences(Object rmiClone, int cascadePolicy, boolean forceCascade) { if (rmiClone == null) { return null; } ClassDescriptor descriptor = getDescriptor(rmiClone); if ((descriptor == null) || descriptor.isAggregateDescriptor() || descriptor.isAggregateCollectionDescriptor()) { if (cascadePolicy == MergeManager.CASCADE_BY_MAPPING){ throw new IllegalArgumentException(ExceptionLocalization.buildMessage("not_an_entity", new Object[]{rmiClone})); } return rmiClone; } //CR#2272 logDebugMessage(rmiClone, "merge_clone_with_references"); ObjectBuilder builder = descriptor.getObjectBuilder(); Object implementation = builder.unwrapObject(rmiClone, this); MergeManager manager = new MergeManager(this); manager.mergeCloneWithReferencesIntoWorkingCopy(); manager.setCascadePolicy(cascadePolicy); manager.setForceCascade(forceCascade); Object mergedObject = manager.mergeChanges(implementation, null); if (isSmartMerge()) { return builder.wrapObject(mergedObject, this); } else { return mergedObject; } } /** * PUBLIC: * Return a new instance of the class registered in this unit of work. * This can be used to ensure that new objects are registered correctly. */ public Object newInstance(Class theClass) { //CR#2272 logDebugMessage(theClass, "new_instance"); ClassDescriptor descriptor = getDescriptor(theClass); Object newObject = descriptor.getObjectBuilder().buildNewInstance(); return registerObject(newObject); } /** * INTERNAL: * This method will perform a delete operation on the provided objects pre-determing * the objects that will be deleted by a commit of the UnitOfWork including privately * owned objects. It does not execute a query for the deletion of these objects as the * normal deleteobject operation does. Mainly implemented to provide EJB 3.0 deleteObject * support. */ public void performRemove(Object toBeDeleted, IdentityHashtable visitedObjects){ try { if (toBeDeleted == null) { return; } ClassDescriptor descriptor = getDescriptor(toBeDeleted); if ((descriptor == null) || descriptor.isAggregateDescriptor() || descriptor.isAggregateCollectionDescriptor()) { throw new IllegalArgumentException(ExceptionLocalization.buildMessage("not_an_entity", new Object[]{toBeDeleted})); } logDebugMessage(toBeDeleted, "deleting_object"); startOperationProfile(SessionProfiler.DeletedObject); //bug 4568370+4599010; fix EntityManager.remove() to handle new objects if (getDeletedObjects().contains(toBeDeleted)){ return; } visitedObjects.put(toBeDeleted,toBeDeleted); Object registeredObject = checkIfAlreadyRegistered(toBeDeleted, descriptor); if (registeredObject == null) { Vector primaryKey = descriptor.getObjectBuilder().extractPrimaryKeyFromObject(toBeDeleted, this); DoesExistQuery existQuery = descriptor.getQueryManager().getDoesExistQuery(); existQuery = (DoesExistQuery)existQuery.clone(); existQuery.setObject(toBeDeleted); existQuery.setPrimaryKey(primaryKey); existQuery.setDescriptor(descriptor); existQuery.setCheckCacheFirst(true); if (((Boolean)executeQuery(existQuery)).booleanValue()){ throw new IllegalArgumentException(ExceptionLocalization.buildMessage("cannot_remove_detatched_entity", new Object[]{toBeDeleted})); }//else, it is a new or previously deleted object that should be ignored (and delete should cascade) }else{ //fire events only if this is a managed object if (descriptor.getEventManager().hasAnyEventListeners()) { oracle.toplink.essentials.descriptors.DescriptorEvent event = new oracle.toplink.essentials.descriptors.DescriptorEvent(toBeDeleted); event.setEventCode(DescriptorEventManager.PreRemoveEvent); event.setSession(this); descriptor.getEventManager().executeEvent(event); } if (hasNewObjects() && getNewObjectsOriginalToClone().contains(registeredObject)){ unregisterObject(registeredObject, DescriptorIterator.NoCascading); }else{ getDeletedObjects().put(toBeDeleted, toBeDeleted); } } descriptor.getObjectBuilder().cascadePerformRemove(toBeDeleted, this, visitedObjects); } finally { endOperationProfile(SessionProfiler.DeletedObject); } } /** * ADVANCED: * The unit of work performs validations such as, * ensuring multiple copies of the same object don't exist in the same unit of work, * ensuring deleted objects are not refered after commit, * ensures that objects from the parent cache are not refered in the unit of work cache. * The level of validation can be increased or decreased for debugging purposes or under * advanced situation where the application requires/desires to violate clone identity in the unit of work. * It is strongly suggested that clone identity not be violate in the unit of work. */ public void performFullValidation() { setValidationLevel(Full); } /** * ADVANCED: * The unit of work performs validations such as, * ensuring multiple copies of the same object don't exist in the same unit of work, * ensuring deleted objects are not refered after commit, * ensures that objects from the parent cache are not refered in the unit of work cache. * The level of validation can be increased or decreased for debugging purposes or under * advanced situation where the application requires/desires to violate clone identity in the unit of work. * It is strongly suggested that clone identity not be violate in the unit of work. */ public void performPartialValidation() { setValidationLevel(Partial); } /** * INTERNAL: * This method is called from clone and register. It includes the processing * required to clone an object, including populating attributes, putting in * UOW identitymap and building a backupclone */ protected void populateAndRegisterObject(Object original, Object workingClone, Vector primaryKey, ClassDescriptor descriptor, Object writeLockValue, long readTime, JoinedAttributeManager joinedAttributeManager) { // This must be registered before it is built to avoid cycles. getIdentityMapAccessorInstance().putInIdentityMap(workingClone, primaryKey, writeLockValue, readTime, descriptor); //Set ChangeListener for ObjectChangeTrackingPolicy and AttributeChangeTrackingPolicy, //but not DeferredChangeDetectionPolicy. Build backup clone for DeferredChangeDetectionPolicy //or ObjectChangeTrackingPolicy, but not for AttributeChangeTrackingPolicy. // - Set listener before populating attributes so aggregates can find the parent's listener descriptor.getObjectChangePolicy().setChangeListener(workingClone, this, descriptor); descriptor.getObjectChangePolicy().dissableEventProcessing(workingClone); ObjectBuilder builder = descriptor.getObjectBuilder(); builder.populateAttributesForClone(original, workingClone, this, joinedAttributeManager); Object backupClone = descriptor.getObjectChangePolicy().buildBackupClone(workingClone, builder, this); getCloneMapping().put(workingClone, backupClone); descriptor.getObjectChangePolicy().enableEventProcessing(workingClone); } /** * INTERNAL: * Remove objects from parent's identity map. */ protected void postMergeChanges() { //bug 4730595: objects removed during flush are not removed from the cache during commit if (!this.getUnitOfWorkChangeSet().getDeletedObjects().isEmpty()){ oracle.toplink.essentials.internal.helper.IdentityHashtable deletedObjects = this.getUnitOfWorkChangeSet().getDeletedObjects(); for (Enumeration removedObjects = deletedObjects.keys(); removedObjects.hasMoreElements(); ) { ObjectChangeSet removedObjectChangeSet = (ObjectChangeSet) removedObjects.nextElement(); java.util.Vector primaryKeys = removedObjectChangeSet.getPrimaryKeys(); getParent().getIdentityMapAccessor().removeFromIdentityMap(primaryKeys, removedObjectChangeSet.getClassType(this)); } } } /** * INTERNAL: * Remove objects deleted during commit from clone and new object cache so that these are not merged */ protected void preMergeChanges() { if (hasObjectsDeletedDuringCommit()) { for (Enumeration removedObjects = getObjectsDeletedDuringCommit().keys(); removedObjects.hasMoreElements();) { Object removedObject = removedObjects.nextElement(); getCloneMapping().remove(removedObject); getAllClones().remove(removedObject); // PERF: Avoid initialization of new objects if none. if (hasNewObjects()) { Object referenceObjectToRemove = getNewObjectsCloneToOriginal().get(removedObject); if (referenceObjectToRemove != null) { getNewObjectsCloneToOriginal().remove(removedObject); getNewObjectsOriginalToClone().remove(referenceObjectToRemove); } } } } } /** * PUBLIC: * Print the objects in the unit of work. * The output of this method will be logged to this unit of work's SessionLog at SEVERE level. */ public void printRegisteredObjects() { if (shouldLog(SessionLog.SEVERE, SessionLog.CACHE)) { basicPrintRegisteredObjects(); } } /** * INTERNAL: * This method is used to process delete queries that pass through the unitOfWork * It is extracted out of the internalExecuteQuery method to reduce duplication */ public Object processDeleteObjectQuery(DeleteObjectQuery deleteQuery) { // We must ensure that we delete the clone not the original, (this can happen in the mappings update) if (deleteQuery.getObject() == null) {// Must validate. throw QueryException.objectToModifyNotSpecified(deleteQuery); } ClassDescriptor descriptor = getDescriptor(deleteQuery.getObject()); ObjectBuilder builder = descriptor.getObjectBuilder(); Object implementation = builder.unwrapObject(deleteQuery.getObject(), this); if (isClassReadOnly(implementation.getClass(), descriptor)) { throw QueryException.cannotDeleteReadOnlyObject(implementation); } if (isCloneNewObject(implementation)) { unregisterObject(implementation); return implementation; } Vector primaryKey = builder.extractPrimaryKeyFromObject(implementation, this); Object clone = getIdentityMapAccessorInstance().getFromIdentityMap(primaryKey, implementation.getClass(), descriptor, null); if (clone == null) { clone = implementation; } // Register will wrap so must unwrap again. clone = builder.unwrapObject(clone, this); deleteQuery.setObject(clone); if (!getCommitManager().isActive()) { getDeletedObjects().put(clone, primaryKey); return clone; } else { // If the object has already been deleted i.e. private-owned + deleted then don't do it twice. if (hasObjectsDeletedDuringCommit()) { if (getObjectsDeletedDuringCommit().containsKey(clone)) { return clone; } } } return null; } /** * INTERNAL: * Print the objects in the unit of work. */ protected void basicPrintRegisteredObjects() { String cr = Helper.cr(); StringWriter writer = new StringWriter(); writer.write(LoggingLocalization.buildMessage("unitofwork_identity_hashcode", new Object[] { cr, String.valueOf(System.identityHashCode(this)) })); if (hasDeletedObjects()) { writer.write(cr + LoggingLocalization.buildMessage("deleted_objects")); for (Enumeration enumtr = getDeletedObjects().keys(); enumtr.hasMoreElements();) { Object object = enumtr.nextElement(); writer.write(LoggingLocalization.buildMessage("key_identity_hash_code_object", new Object[] { cr, Helper.printVector(getDescriptor(object).getObjectBuilder().extractPrimaryKeyFromObject(object, this)), "\t", String.valueOf(System.identityHashCode(object)), object })); } } writer.write(cr + LoggingLocalization.buildMessage("all_registered_clones")); for (Enumeration enumtr = getCloneMapping().keys(); enumtr.hasMoreElements();) { Object object = enumtr.nextElement(); writer.write(LoggingLocalization.buildMessage("key_identity_hash_code_object", new Object[] { cr, Helper.printVector(getDescriptor(object).getObjectBuilder().extractPrimaryKeyFromObject(object, this)), "\t", String.valueOf(System.identityHashCode(object)), object })); } log(SessionLog.SEVERE, SessionLog.TRANSACTION, writer.toString(), null, null, false); } /** * PUBLIC: * Register the objects with the unit of work. * All newly created root domain objects must be registered to be inserted on commit. * Also any existing objects that will be edited and were not read from this unit of work * must also be registered. * Once registered any changes to the objects will be commited to the database on commit. * * @return is the clones of the original objects, the return value must be used for editing. * Editing the original is not allowed in the unit of work. */ public Vector registerAllObjects(Collection domainObjects) { Vector clones = new Vector(domainObjects.size()); for (Iterator objectsEnum = domainObjects.iterator(); objectsEnum.hasNext();) { clones.addElement(registerObject(objectsEnum.next())); } return clones; } /** * PUBLIC: * Register the objects with the unit of work. * All newly created root domain objects must be registered to be inserted on commit. * Also any existing objects that will be edited and were not read from this unit of work * must also be registered. * Once registered any changes to the objects will be commited to the database on commit. * * @return is the clones of the original objects, the return value must be used for editing. * Editing the original is not allowed in the unit of work. */ public Vector registerAllObjects(Vector domainObjects) throws DatabaseException, OptimisticLockException { Vector clones = new Vector(domainObjects.size()); for (Enumeration objectsEnum = domainObjects.elements(); objectsEnum.hasMoreElements();) { clones.addElement(registerObject(objectsEnum.nextElement())); } return clones; } /** * INTERNAL: * Register the existing object with the unit of work. * This is a advanced API that can be used if the application can guarentee the object exists on the database. * When registerObject is called the unit of work determines existence through the descriptor's doesExist setting. * * @return The clone of the original object, the return value must be used for editing. * Editing the original is not allowed in the unit of work. */ public synchronized Object registerExistingObject(Object existingObject, JoinedAttributeManager joinedAttributeManager) { if (existingObject == null) { return null; } ClassDescriptor descriptor = getDescriptor(existingObject); if (descriptor == null) { throw DescriptorException.missingDescriptor(existingObject.getClass().toString()); } if (this.isClassReadOnly(descriptor.getJavaClass(), descriptor)) { return existingObject; } ObjectBuilder builder = descriptor.getObjectBuilder(); Object implementation = builder.unwrapObject(existingObject, this); Object registeredObject = this.registerExistingObject(implementation, descriptor, joinedAttributeManager); // Bug # 3212057 - workaround JVM bug (MWN) if (implementation != existingObject) { return builder.wrapObject(registeredObject, this); } else { return registeredObject; } } /** * ADVANCED: * Register the existing object with the unit of work. * This is a advanced API that can be used if the application can guarentee the object exists on the database. * When registerObject is called the unit of work determines existence through the descriptor's doesExist setting. * * @return The clone of the original object, the return value must be used for editing. * Editing the original is not allowed in the unit of work. */ public synchronized Object registerExistingObject(Object existingObject) { return registerExistingObject(existingObject, null); } /** * INTERNAL: * Register the existing object with the unit of work. * This is a advanced API that can be used if the application can guarentee the object exists on the database. * When registerObject is called the unit of work determines existence through the descriptor's doesExist setting. * * @return The clone of the original object, the return value must be used for editing. * Editing the original is not allowed in the unit of work. */ protected synchronized Object registerExistingObject(Object objectToRegister, ClassDescriptor descriptor, JoinedAttributeManager joinedAttributeManager) { if (isAfterWriteChangesButBeforeCommit()) { throw ValidationException.illegalOperationForUnitOfWorkLifecycle(getLifecycle(), "registerExistingObject"); } if (descriptor.isAggregateDescriptor() || descriptor.isAggregateCollectionDescriptor()) { throw ValidationException.cannotRegisterAggregateObjectInUnitOfWork(objectToRegister.getClass()); } //CR#2272 logDebugMessage(objectToRegister, "register_existing"); Object registeredObject; try { startOperationProfile(SessionProfiler.Register); registeredObject = checkIfAlreadyRegistered(objectToRegister, descriptor); if (registeredObject == null) { // Check if object is existing, if it is it must be cloned into the unit of work // otherwise it is a new object Vector primaryKey = descriptor.getObjectBuilder().extractPrimaryKeyFromObject(objectToRegister, this); // Always check the cache first. registeredObject = getIdentityMapAccessorInstance().getFromIdentityMap(primaryKey, objectToRegister.getClass(), descriptor, joinedAttributeManager); if (registeredObject == null) { // This is a case where the object is not in the session cache, // so a new cache-key is used as there is no original to use for locking. registeredObject = cloneAndRegisterObject(objectToRegister, new CacheKey(primaryKey), joinedAttributeManager); } } //bug3659327 //fetch group manager control fetch group support if (descriptor.hasFetchGroupManager()) { //if the object is already registered in uow, but it's partially fetched (fetch group case) if (descriptor.getFetchGroupManager().shouldWriteInto(objectToRegister, registeredObject)) { //there might be cases when reverting/refreshing clone is needed. descriptor.getFetchGroupManager().writePartialIntoClones(objectToRegister, registeredObject, this); } } } finally { endOperationProfile(SessionProfiler.Register); } return registeredObject; } /** * ADVANCED: * Register the new object with the unit of work. * This will register the new object without cloning. * Normally the registerObject method should be used for all registration of new and existing objects. * This version of the register method can only be used for new objects. * This method should only be used if a new object is desired to be registered without cloning. * * @see #registerObject(Object) */ public synchronized Object registerNewObject(Object newObject) { if (newObject == null) { return null; } ClassDescriptor descriptor = getDescriptor(newObject); if (descriptor == null) { throw DescriptorException.missingDescriptor(newObject.getClass().toString()); } ObjectBuilder builder = descriptor.getObjectBuilder(); Object implementation = builder.unwrapObject(newObject, this); this.registerNewObject(implementation, descriptor); if (implementation == newObject) { return newObject; } else { return builder.wrapObject(implementation, this); } } /** * INTERNAL: * Updated to allow passing in of the object's descriptor * * Register the new object with the unit of work. * This will register the new object without cloning. * Normally the registerObject method should be used for all registration of new and existing objects. * This version of the register method can only be used for new objects. * This method should only be used if a new object is desired to be registered without cloning. * * @see #registerObject(Object) */ protected synchronized Object registerNewObject(Object implementation, ClassDescriptor descriptor) { if (isAfterWriteChangesButBeforeCommit()) { throw ValidationException.illegalOperationForUnitOfWorkLifecycle(getLifecycle(), "registerNewObject"); } if (descriptor.isAggregateDescriptor() || descriptor.isAggregateCollectionDescriptor()) { throw ValidationException.cannotRegisterAggregateObjectInUnitOfWork(implementation.getClass()); } try { //CR#2272 logDebugMessage(implementation, "register_new"); startOperationProfile(SessionProfiler.Register); Object registeredObject = checkIfAlreadyRegistered(implementation, descriptor); if (registeredObject == null) { // Ensure that the registered object is the one from the parent cache. if (shouldPerformFullValidation()) { Vector primaryKey = descriptor.getObjectBuilder().extractPrimaryKeyFromObject(implementation, this); Object objectFromCache = getParent().getIdentityMapAccessorInstance().getFromIdentityMap(primaryKey, implementation.getClass(), descriptor, null); if (objectFromCache != null) { throw ValidationException.wrongObjectRegistered(implementation, objectFromCache); } } ObjectBuilder builder = descriptor.getObjectBuilder(); Object original = builder.buildNewInstance(); registerNewObjectClone(implementation, original); Object backupClone = builder.buildNewInstance(); getCloneMapping().put(implementation, backupClone); // Check if the new objects should be cached. registerNewObjectInIdentityMap(implementation, implementation); } } finally { endOperationProfile(SessionProfiler.Register); } //as this is register new return the object passed in. return implementation; } /** * INTERNAL: * * Register the new object with the unit of work. * This will register the new object without cloning. * Checks based on existence will be completed and the create will be cascaded based on the * object's mappings cascade requirements. This is specific to EJB 3.0 support and is * @see #registerObject(Object) */ public synchronized void registerNewObjectForPersist(Object newObject, IdentityHashtable visitedObjects) { try { if (newObject == null) { return; } ClassDescriptor descriptor = getDescriptor(newObject); if ((descriptor == null) || descriptor.isAggregateDescriptor() || descriptor.isAggregateCollectionDescriptor()) { throw new IllegalArgumentException(ExceptionLocalization.buildMessage("not_an_entity", new Object[]{newObject})); } startOperationProfile(SessionProfiler.Register); Object registeredObject = checkIfAlreadyRegistered(newObject, descriptor); if (registeredObject == null) { registerNotRegisteredNewObjectForPersist(newObject, descriptor); } else if (this.isObjectDeleted(newObject)){ //if object is deleted and a create is issued on the that object // then the object must be transitioned back to existing and not deleted this.undeleteObject(newObject); } descriptor.getObjectBuilder().cascadeRegisterNewForCreate(newObject, this, visitedObjects); } finally { endOperationProfile(SessionProfiler.Register); } } /** * INTERNAL: * Called only by registerNewObjectForPersist method, * and only if newObject is not already registered. * Could be overridden in subclasses. */ protected void registerNotRegisteredNewObjectForPersist(Object newObject, ClassDescriptor descriptor) { // Ensure that the registered object is not detached. newObject.getClass(); DoesExistQuery existQuery = descriptor.getQueryManager().getDoesExistQuery(); existQuery = (DoesExistQuery)existQuery.clone(); existQuery.setObject(newObject); existQuery.setDescriptor(descriptor); // only check the cache as we can wait until commit for the unique // constraint error to be thrown. This does ignore user's settings // on descriptor but calling persist() tells us the object is new. existQuery.checkCacheForDoesExist(); if (((Boolean)executeQuery(existQuery)).booleanValue()) { throw ValidationException.cannotPersistExistingObject(newObject, this); } logDebugMessage(newObject, "register_new_for_persist"); if (descriptor.getEventManager().hasAnyEventListeners()) { oracle.toplink.essentials.descriptors.DescriptorEvent event = new oracle.toplink.essentials.descriptors.DescriptorEvent(newObject); event.setEventCode(DescriptorEventManager.PrePersistEvent); event.setSession(this); descriptor.getEventManager().executeEvent(event); } ObjectBuilder builder = descriptor.getObjectBuilder(); Object original = builder.buildNewInstance(); registerNewObjectClone(newObject, original); Object backupClone = builder.buildNewInstance(); getCloneMapping().put(newObject, backupClone); assignSequenceNumber(newObject); // Check if the new objects should be cached. registerNewObjectInIdentityMap(newObject, newObject); } /** * INTERNAL: * Register the working copy of a new object and its original. * The user must edit the working copy and the original is used to merge into the parent. * This mapping is kept both ways because lookup is required in both directions. */ protected void registerNewObjectClone(Object clone, Object original) { // Check if the new objects should be cached. registerNewObjectInIdentityMap(clone, original); getNewObjectsCloneToOriginal().put(clone, original); getNewObjectsOriginalToClone().put(original, clone); } /** * INTERNAL: * Add the new object to the cache if set to. * This is useful for using mergeclone on new objects. */ protected void registerNewObjectInIdentityMap(Object clone, Object original) { // CR 2728 Added check for sequencing to allow zero primitives for id's if the client //is not using sequencing. Class cls = clone.getClass(); ClassDescriptor descriptor = getDescriptor(cls); boolean usesSequences = descriptor.usesSequenceNumbers(); if (shouldNewObjectsBeCached()) { // Also put it in the cache if it has a valid primary key, this allows for double new object merges Vector key = keyFromObject(clone, descriptor); boolean containsNull = false; // begin CR#2041 Unit Of Work incorrectly put new objects with a primitive primary key in its cache Object pkElement; for (int index = 0; index < key.size(); index++) { pkElement = key.elementAt(index); if (pkElement == null) { containsNull = true; } else if (usesSequences) { containsNull = getSequencing().shouldOverrideExistingValue(cls, pkElement); } } if (containsNull) { key = descriptor.getObjectBuilder().extractPrimaryKeyFromObject(original, this); containsNull = false; for (int index = 0; index < key.size(); index++) { pkElement = key.elementAt(index); if (pkElement == null) { containsNull = true; } else if (usesSequences) { containsNull = getSequencing().shouldOverrideExistingValue(cls, pkElement); } } } // end cr #2041 if (!containsNull) { getIdentityMapAccessorInstance().putInIdentityMap(clone, key, null, 0, descriptor); } } } /** * PUBLIC: * Register the object with the unit of work. * All newly created root domain objects must be registered to be inserted on commit. * Also any existing objects that will be edited and were not read from this unit of work * must also be registered. * Once registered any changes to the objects will be commited to the database on commit. * * @return the clone of the original object, the return value must be used for editing, * * ** Editing the original is not allowed in the unit of work. ** */ public synchronized Object registerObject(Object object) { if (object == null) { return null; } ClassDescriptor descriptor = getDescriptor(object); if (descriptor == null) { throw DescriptorException.missingDescriptor(object.getClass().toString()); } if (this.isClassReadOnly(descriptor.getJavaClass(), descriptor)) { return object; } ObjectBuilder builder = descriptor.getObjectBuilder(); Object implementation = builder.unwrapObject(object, this); boolean wasWrapped = implementation != object; Object registeredObject = this.registerObject(implementation, descriptor); if (wasWrapped) { return builder.wrapObject(registeredObject, this); } else { return registeredObject; } } /** * INTERNAL: * Allows for calling method to provide the descriptor information for this * object. Prevents double lookup of descriptor. * * * Register the object with the unit of work. * All newly created root domain objects must be registered to be inserted on commit. * Also any existing objects that will be edited and were not read from this unit of work * must also be registered. * Once registered any changes to the objects will be commited to the database on commit. * * calling this method will also sort the objects into different different groups * depending on if the object being registered is a bean or a regular Java * object and if its updates are deferred, non-deferred or if all modifications * are deferred. * * @return the clone of the original object, the return value must be used for editing, */ protected synchronized Object registerObject(Object object, ClassDescriptor descriptor) { if (this.isClassReadOnly(descriptor.getJavaClass(), descriptor)) { return object; } if (isAfterWriteChangesButBeforeCommit()) { throw ValidationException.illegalOperationForUnitOfWorkLifecycle(getLifecycle(), "registerObject"); } //CR#2272 logDebugMessage(object, "register"); Object registeredObject; try { startOperationProfile(SessionProfiler.Register); registeredObject = internalRegisterObject(object, descriptor); } finally { endOperationProfile(SessionProfiler.Register); } return registeredObject; } /** * INTERNAL: * Register this UnitOfWork against an external transaction controller */ public void registerWithTransactionIfRequired() { if (getParent().hasExternalTransactionController() && ! isSynchronized()) { boolean hasAlreadyStarted = getParent().wasJTSTransactionInternallyStarted(); getParent().getExternalTransactionController().registerSynchronizationListener(this, getParent()); // CR#2998 - registerSynchronizationListener may toggle the wasJTSTransactionInternallyStarted // flag. As a result, we must compare the states and if the state is changed, then we must set the // setWasTransactionBegunPrematurely flag to ensure that we handle the transaction depth count // appropriately if (!hasAlreadyStarted && getParent().wasJTSTransactionInternallyStarted()) { // registerSynchronizationListener caused beginTransaction() called // and an external transaction internally started. this.setWasTransactionBegunPrematurely(true); } } } /** * PUBLIC: * Release the unit of work. This terminates this unit of work. * Because the unit of work operates on its own object space (clones) no work is required. * The unit of work should no longer be used or referenced by the application beyond this point * so that it can be garbage collected. * * @see #commit() */ public void release() { log(SessionLog.FINER, SessionLog.TRANSACTION, "release_unit_of_work"); getEventManager().preReleaseUnitOfWork(); // If already succeeded at a writeChanges(), then transaction still open. // As already issued sql must at least mark the external transaction for rollback only. if (getLifecycle() == CommitTransactionPending) { if (hasModifications() || wasTransactionBegunPrematurely()) { rollbackTransaction(false); setWasTransactionBegunPrematurely(false); } } else if (wasTransactionBegunPrematurely() && (!isNestedUnitOfWork())) { rollbackTransaction(); setWasTransactionBegunPrematurely(false); } if ((getMergeManager() != null) && (getMergeManager().getAcquiredLocks() != null) && (!getMergeManager().getAcquiredLocks().isEmpty())) { //may have unreleased cache locks because of a rollback... As some //locks may be acquired durring commit. getParent().getIdentityMapAccessorInstance().getWriteLockManager().releaseAllAcquiredLocks(getMergeManager()); this.setMergeManager(null); } setDead(); if(shouldClearForCloseOnRelease()) { clearForClose(true); } getParent().releaseUnitOfWork(this); getEventManager().postReleaseUnitOfWork(); } /** * PUBLIC: * Empties the set of read-only classes. * It is illegal to call this method on nested UnitOfWork objects. A nested UnitOfWork * cannot have a subset of its parent's set of read-only classes. * Also removes classes which are read only because their descriptors are readonly */ public void removeAllReadOnlyClasses() throws ValidationException { if (isNestedUnitOfWork()) { throw ValidationException.cannotRemoveFromReadOnlyClassesInNestedUnitOfWork(); } getReadOnlyClasses().clear(); } /** * ADVANCED: * Remove optimistic read lock from the object * See forceUpdateToVersionField(Object) */ public void removeForceUpdateToVersionField(Object lockObject) { getOptimisticReadLockObjects().remove(lockObject); } /** * PUBLIC: * Removes a Class from the receiver's set of read-only classes. * It is illegal to try to send this method to a nested UnitOfWork. */ public void removeReadOnlyClass(Class theClass) throws ValidationException { if (!canChangeReadOnlySet()) { throw ValidationException.cannotModifyReadOnlyClassesSetAfterUsingUnitOfWork(); } if (isNestedUnitOfWork()) { throw ValidationException.cannotRemoveFromReadOnlyClassesInNestedUnitOfWork(); } getReadOnlyClasses().remove(theClass); } /** * INTERNAL: * Used in the resume to reset the all clones collection */ protected void resetAllCloneCollection() { this.allClones = null; } /** * PUBLIC: * Revert all changes made to any registered object. * Clear all deleted and new objects. * Revert should not be confused with release which it the normal compliment to commit. * Revert is more similar to commit and resume, however reverts all changes and resumes. * If you do not require to resume the unit of work release should be used instead. * * @see #commitAndResume() * @see #release() */ public void revertAndResume() { if (isAfterWriteChangesButBeforeCommit()) { throw ValidationException.illegalOperationForUnitOfWorkLifecycle(getLifecycle(), "revertAndResume"); } log(SessionLog.FINER, SessionLog.TRANSACTION, "revert_unit_of_work"); MergeManager manager = new MergeManager(this); manager.mergeOriginalIntoWorkingCopy(); manager.cascadeAllParts(); for (Enumeration cloneEnum = getCloneMapping().keys(); cloneEnum.hasMoreElements();) { Object clone = cloneEnum.nextElement(); // Revert each clone. manager.mergeChanges(clone, null); ClassDescriptor descriptor = this.getDescriptor(clone); //revert the tracking policy descriptor.getObjectChangePolicy().revertChanges(clone, descriptor, this, this.getCloneMapping()); } // PERF: Avoid initialization of new objects if none. if (hasNewObjects()) { for (Enumeration cloneEnum = getNewObjectsCloneToOriginal().keys(); cloneEnum.hasMoreElements();) { Object clone = cloneEnum.nextElement(); // De-register the object. getCloneMapping().remove(clone); } if (this.getUnitOfWorkChangeSet() != null){ ((UnitOfWorkChangeSet)this.getUnitOfWorkChangeSet()).getNewObjectChangeSets().clear(); } } // Clear new and deleted objects. setNewObjectsCloneToOriginal(null); setNewObjectsOriginalToClone(null); // Reset the all clones collection resetAllCloneCollection(); // 2612538 - the default size of IdentityHashtable (32) is appropriate setObjectsDeletedDuringCommit(new IdentityHashtable()); setDeletedObjects(new IdentityHashtable()); setRemovedObjects(new IdentityHashtable()); setUnregisteredNewObjects(new IdentityHashtable()); log(SessionLog.FINER, SessionLog.TRANSACTION, "resume_unit_of_work"); } /** * PUBLIC: * Revert the object's attributes from the parent. * This also reverts the object privately-owned parts. * * @return the object reverted. * @see #shallowRevertObject(Object) * @see #deepRevertObject(Object) */ public Object revertObject(Object clone) { return revertObject(clone, MergeManager.CASCADE_PRIVATE_PARTS); } /** * INTERNAL: * Revert the object's attributes from the parent. * This uses merging to merge the object changes. */ public Object revertObject(Object clone, int cascadeDepth) { if (clone == null) { return null; } //CR#2272 logDebugMessage(clone, "revert"); ClassDescriptor descriptor = getDescriptor(clone); ObjectBuilder builder = descriptor.getObjectBuilder(); Object implementation = builder.unwrapObject(clone, this); MergeManager manager = new MergeManager(this); manager.mergeOriginalIntoWorkingCopy(); manager.setCascadePolicy(cascadeDepth); try { manager.mergeChanges(implementation, null); } catch (RuntimeException exception) { return handleException(exception); } return clone; } /** * INTERNAL: * This is internal to the uow, transactions should not be used explictly in a uow. * The uow shares its parents transactions. */ public void rollbackTransaction() throws DatabaseException { incrementProfile(SessionProfiler.UowRollbacks); getParent().rollbackTransaction(); } /** * INTERNAL: * rollbackTransaction() with a twist for external transactions. *

* writeChanges() is called outside the JTA beforeCompletion(), so the * accompanying exception won't propogate up and cause a rollback by itself. *

* Instead must mark the transaction for rollback only here. *

* If internally started external transaction or no external transaction * can still rollback normally. * @param intendedToCommitTransaction whether we were inside a commit or just trying to * write out changes early. */ protected void rollbackTransaction(boolean intendedToCommitTransaction) throws DatabaseException { if (!intendedToCommitTransaction && getParent().hasExternalTransactionController() && !getParent().wasJTSTransactionInternallyStarted()) { getParent().getExternalTransactionController().markTransactionForRollback(); } rollbackTransaction(); } /** * INTERNAL: * Scans the UnitOfWork identity map for conforming instances. *

* Later this method can be made recursive to check all parent units of * work also. * @param selectionCriteria must be cloned and specially prepared for conforming * @return IdentityHashtable to facilitate merging with conforming instances * returned from a query on the database. */ public IdentityHashtable scanForConformingInstances(Expression selectionCriteria, Class referenceClass, AbstractRecord arguments, ObjectLevelReadQuery query) { // for bug 3568141 use the painstaking shouldTriggerIndirection if set InMemoryQueryIndirectionPolicy policy = query.getInMemoryQueryIndirectionPolicy(); if (!policy.shouldTriggerIndirection()) { policy = new InMemoryQueryIndirectionPolicy(InMemoryQueryIndirectionPolicy.SHOULD_IGNORE_EXCEPTION_RETURN_NOT_CONFORMED); } IdentityHashtable indexedInterimResult = new IdentityHashtable(); try { Vector fromCache = null; if (selectionCriteria != null) { // assume objects that have the compared relationship // untriggered do not conform as they have not been changed. // bug 2637555 fromCache = getIdentityMapAccessor().getAllFromIdentityMap(selectionCriteria, referenceClass, arguments, policy); for (Enumeration fromCacheEnum = fromCache.elements(); fromCacheEnum.hasMoreElements();) { Object object = fromCacheEnum.nextElement(); if (!isObjectDeleted(object)) { indexedInterimResult.put(object, object); } } } // Add any new objects that conform to the query. Vector newObjects = null; newObjects = getAllFromNewObjects(selectionCriteria, referenceClass, arguments, policy); for (Enumeration newObjectsEnum = newObjects.elements(); newObjectsEnum.hasMoreElements();) { Object object = newObjectsEnum.nextElement(); if (!isObjectDeleted(object)) { indexedInterimResult.put(object, object); } } } catch (QueryException exception) { if (getShouldThrowConformExceptions() == THROW_ALL_CONFORM_EXCEPTIONS) { throw exception; } } return indexedInterimResult; } /** * INTERNAL: * Used to set the collections of all objects in the UnitOfWork. * @param newUnregisteredExistingObjects oracle.toplink.essentials.internal.helper.IdentityHashtable */ protected void setAllClonesCollection(IdentityHashtable objects) { this.allClones = objects; } /** * INTERNAL: * Set the clone mapping. * The clone mapping contains clone of all registered objects, * this is required to store the original state of the objects when registered * so that only what is changed will be commited to the database and the parent, * (this is required to support parralel unit of work). */ protected void setCloneMapping(IdentityHashtable cloneMapping) { this.cloneMapping = cloneMapping; } /** * INTERNAL: * set UoW lifecycle state variable to DEATH */ public void setDead() { setLifecycle(Death); } /** * INTERNAL: * The deleted objects stores any objects removed during the unit of work. * On commit they will all be removed from the database. */ protected void setDeletedObjects(IdentityHashtable deletedObjects) { this.deletedObjects = deletedObjects; } /** * INTERNAL: * The life cycle tracks if the unit of work is active and is used for JTS. */ protected void setLifecycle(int lifecycle) { this.lifecycle = lifecycle; } /** * INTERNAL: * A reference to the last used merge manager. This is used to track locked * objects. */ public void setMergeManager(MergeManager mergeManager) { this.lastUsedMergeManager = mergeManager; } /** * INTERNAL: * The new objects stores any objects newly created during the unit of work. * On commit they will all be inserted into the database. */ protected void setNewObjectsCloneToOriginal(IdentityHashtable newObjects) { this.newObjectsCloneToOriginal = newObjects; } /** * INTERNAL: * The new objects stores any objects newly created during the unit of work. * On commit they will all be inserted into the database. */ protected void setNewObjectsOriginalToClone(IdentityHashtable newObjects) { this.newObjectsOriginalToClone = newObjects; } /** * INTERNAL: * Set the objects that have been deleted. */ public void setObjectsDeletedDuringCommit(IdentityHashtable deletedObjects) { objectsDeletedDuringCommit = deletedObjects; } /** * INTERNAL: * Set the parent. * This is a unit of work if nested, otherwise a database session or client session. */ public void setParent(AbstractSession parent) { this.parent = parent; } /** * INTERNAL: * set UoW lifecycle state variable to PENDING_MERGE */ public void setPendingMerge() { setLifecycle(MergePending); } /** * INTERNAL: * Gives a new set of read-only classes to the receiver. * This set of classes given are checked that subclasses of a read-only class are also * in the read-only set provided. */ public void setReadOnlyClasses(Vector classes) { this.readOnlyClasses = new Hashtable(classes.size() + 10); for (Enumeration enumtr = classes.elements(); enumtr.hasMoreElements();) { Class theClass = (Class)enumtr.nextElement(); addReadOnlyClass(theClass); } } /** * INTERNAL: * The removed objects stores any newly registered objects removed during the nested unit of work. * On commit they will all be removed from the parent unit of work. */ protected void setRemovedObjects(IdentityHashtable removedObjects) { this.removedObjects = removedObjects; } /** * INTERNAL: * Set if this UnitofWork should be resumed after the end of the transaction * Used when UnitOfWork is synchronized with external transaction control */ public void setResumeUnitOfWorkOnTransactionCompletion(boolean resumeUnitOfWork){ this.resumeOnTransactionCompletion = resumeUnitOfWork; } /** * INTERNAL: * True if the value holder for the joined attribute should be triggered. * Required by ejb30 fetch join. */ public void setShouldCascadeCloneToJoinedRelationship(boolean shouldCascadeCloneToJoinedRelationship) { this.shouldCascadeCloneToJoinedRelationship = shouldCascadeCloneToJoinedRelationship; } /** * ADVANCED: * By default new objects are not cached until the exist on the database. * Occasionally if mergeClone is used on new objects and is required to allow multiple merges * on the same new object, then if the new objects are not cached, each mergeClone will be * interpretted as a different new object. * By setting new objects to be cached mergeClone can be performed multiple times before commit. * New objects cannot be cached unless they have a valid assigned primary key before being registered. * New object with non-null invalid primary keys such as 0 or '' can cause problems and should not be used with this option. */ public void setShouldNewObjectsBeCached(boolean shouldNewObjectsBeCached) { this.shouldNewObjectsBeCached = shouldNewObjectsBeCached; } /** * ADVANCED: * By default deletes are performed last in a unit of work. * Sometimes you may want to have the deletes performed before other actions. */ public void setShouldPerformDeletesFirst(boolean shouldPerformDeletesFirst) { this.shouldPerformDeletesFirst = shouldPerformDeletesFirst; } /** * ADVANCED: * Conforming queries can be set to provide different levels of detail about the * exceptions they encounter * There are three levels: * DO_NOT_THROW_CONFORM_EXCEPTIONS = 0; * THROW_ALL_CONFORM_EXCEPTIONS = 1; */ public void setShouldThrowConformExceptions(int shouldThrowExceptions) { this.shouldThrowConformExceptions = shouldThrowExceptions; } /** * INTERNAL: * Set smart merge flag. This feature is used in WL to merge dependent values without SessionAccessor */ public static void setSmartMerge(boolean option) { SmartMerge = option; } /** * INTERNAL: * Set isSynchronized flag to indicate that this session is a synchronized unit of work. */ public void setSynchronized(boolean synched) { isSynchronized = synched; } /** * INTERNAL: * Sets the current UnitOfWork change set to be the one passed in. */ public void setUnitOfWorkChangeSet(UnitOfWorkChangeSet unitOfWorkChangeSet) { this.unitOfWorkChangeSet = unitOfWorkChangeSet; } /** * INTERNAL: * Used to set the unregistered existing objects vector used when validation has been turned off. * @param newUnregisteredExistingObjects oracle.toplink.essentials.internal.helper.IdentityHashtable */ protected void setUnregisteredExistingObjects(oracle.toplink.essentials.internal.helper.IdentityHashtable newUnregisteredExistingObjects) { unregisteredExistingObjects = newUnregisteredExistingObjects; } /** * INTERNAL: */ protected void setUnregisteredNewObjects(IdentityHashtable newObjects) { unregisteredNewObjects = newObjects; } /** * ADVANCED: * The unit of work performs validations such as, * ensuring multiple copies of the same object don't exist in the same unit of work, * ensuring deleted objects are not refered after commit, * ensures that objects from the parent cache are not refered in the unit of work cache. * The level of validation can be increased or decreased for debugging purposes or under * advanced situation where the application requires/desires to violate clone identity in the unit of work. * It is strongly suggested that clone identity not be violate in the unit of work. */ public void setValidationLevel(int validationLevel) { this.validationLevel = validationLevel; } /** * INTERNAL: * Set a flag in the root UOW to indicate that a pess. locking or non-selecting SQL query was executed * and forced a transaction to be started. */ public void setWasTransactionBegunPrematurely(boolean wasTransactionBegunPrematurely) { if (isNestedUnitOfWork()) { ((UnitOfWorkImpl)getParent()).setWasTransactionBegunPrematurely(wasTransactionBegunPrematurely); } this.wasTransactionBegunPrematurely = wasTransactionBegunPrematurely; } /** * PUBLIC: * Merge the attributes of the clone into the unit of work copy. * This can be used for objects that are returned from the client through * RMI serialization (or other serialization mechanisms), because the RMI object will * be a clone this will merge its attributes correctly to preserve object identity * within the unit of work and record its changes. * * Only direct attributes are merged. * * @return the registered version for the clone being merged. * @see #mergeClone(Object) * @see #deepMergeClone(Object) */ public Object shallowMergeClone(Object rmiClone) { return mergeClone(rmiClone, MergeManager.NO_CASCADE); } /** * PUBLIC: * Revert the object's attributes from the parent. * This only reverts the object's direct attributes. * * @return the object reverted. * @see #revertObject(Object) * @see #deepRevertObject(Object) */ public Object shallowRevertObject(Object clone) { return revertObject(clone, MergeManager.NO_CASCADE); } /** * ADVANCED: * Unregister the object with the unit of work. * This can be used to delete an object that was just created and is not yet persistent. * Delete object can also be used, but will result in inserting the object and then deleting it. * The method will only unregister the clone, none of its parts. */ public void shallowUnregisterObject(Object clone) { unregisterObject(clone, DescriptorIterator.NoCascading); } /** * INTERNAL: * True if the value holder for the joined attribute should be triggered. * Required by ejb30 fetch join. */ public boolean shouldCascadeCloneToJoinedRelationship() { return shouldCascadeCloneToJoinedRelationship; } /** * ADVANCED: * By default new objects are not cached until the exist on the database. * Occasionally if mergeClone is used on new objects and is required to allow multiple merges * on the same new object, then if the new objects are not cached, each mergeClone will be * interpretted as a different new object. * By setting new objects to be cached mergeClone can be performed multiple times before commit. * New objects cannot be cached unless they have a valid assigned primary key before being registered. * New object with non-null invalid primary keys such as 0 or '' can cause problems and should not be used with this option. */ public boolean shouldNewObjectsBeCached() { return shouldNewObjectsBeCached; } /** * ADVANCED: * By default all objects are inserted and updated in the database before * any object is deleted. If this flag is set to true, deletes will be * performed before inserts and updates */ public boolean shouldPerformDeletesFirst() { return shouldPerformDeletesFirst; } /** * ADVANCED: * The unit of work performs validations such as, * ensuring multiple copies of the same object don't exist in the same unit of work, * ensuring deleted objects are not refered after commit, * ensures that objects from the parent cache are not refered in the unit of work cache. * The level of validation can be increased or decreased for debugging purposes or under * advanced situation where the application requires/desires to violate clone identity in the unit of work. * It is strongly suggested that clone identity not be violate in the unit of work. */ public boolean shouldPerformFullValidation() { return getValidationLevel() == Full; } /** * ADVANCED: * The unit of work performs validations such as, * ensuring multiple copies of the same object don't exist in the same unit of work, * ensuring deleted objects are not refered after commit, * ensures that objects from the parent cache are not refered in the unit of work cache. * The level of validation can be increased or decreased for debugging purposes or under * advanced situation where the application requires/desires to violate clone identity in the unit of work. * It is strongly suggested that clone identity not be violate in the unit of work. */ public boolean shouldPerformNoValidation() { return getValidationLevel() == None; } /** * ADVANCED: * The unit of work performs validations such as, * ensuring multiple copies of the same object don't exist in the same unit of work, * ensuring deleted objects are not refered after commit, * ensures that objects from the parent cache are not refered in the unit of work cache. * The level of validation can be increased or decreased for debugging purposes or under * advanced situation where the application requires/desires to violate clone identity in the unit of work. * It is strongly suggested that clone identity not be violate in the unit of work. */ public boolean shouldPerformPartialValidation() { return getValidationLevel() == Partial; } /** * INTERNAL: * Returns true if this UnitofWork should be resumed after the end of the transaction * Used when UnitOfWork is synchronized with external transaction control */ public boolean shouldResumeUnitOfWorkOnTransactionCompletion(){ return this.resumeOnTransactionCompletion; } /** * INTERNAL: * Store the ModifyAllQuery's from the UoW in the list. They are always * deferred to commit time */ public void storeModifyAllQuery(DatabaseQuery query) { if (modifyAllQueries == null) { modifyAllQueries = new ArrayList(); } modifyAllQueries.add(query); } /** * INTERNAL: * Store the deferred UpdateAllQuery's from the UoW in the list. */ public void storeDeferredModifyAllQuery(DatabaseQuery query, AbstractRecord translationRow) { if (deferredModifyAllQueries == null) { deferredModifyAllQueries = new ArrayList(); } deferredModifyAllQueries.add(new Object[]{query, translationRow}); } /** * INTERNAL * Synchronize the clones and update their backup copies. * Called after commit and commit and resume. */ public void synchronizeAndResume() { // For pessimistic locking all locks were released by commit. getPessimisticLockedObjects().clear(); getProperties().remove(LOCK_QUERIES_PROPERTY); // find next power-of-2 size IdentityHashtable newCloneMapping = new IdentityHashtable(1 + getCloneMapping().size()); for (Enumeration cloneEnum = getCloneMapping().keys(); cloneEnum.hasMoreElements();) { Object clone = cloneEnum.nextElement(); // Do not add object that were deleted, what about private parts?? if ((!isObjectDeleted(clone)) && (!getRemovedObjects().containsKey(clone))) { ClassDescriptor descriptor = getDescriptor(clone); ObjectBuilder builder = descriptor.getObjectBuilder(); //Build backup clone for DeferredChangeDetectionPolicy or ObjectChangeTrackingPolicy, //but not for AttributeChangeTrackingPolicy descriptor.getObjectChangePolicy().revertChanges(clone, descriptor, this, newCloneMapping); } } setCloneMapping(newCloneMapping); if (hasObjectsDeletedDuringCommit()) { for (Enumeration removedObjects = getObjectsDeletedDuringCommit().keys(); removedObjects.hasMoreElements();) { Object removedObject = removedObjects.nextElement(); getIdentityMapAccessor().removeFromIdentityMap((Vector)getObjectsDeletedDuringCommit().get(removedObject), removedObject.getClass()); } } // New objects are not new anymore. // can not set multi clone for NestedUnitOfWork.CR#2015 - XC if (!isNestedUnitOfWork()) { //Need to move objects and clones from NewObjectsCloneToOriginal to CloneToOriginals for use in the continued uow if (hasNewObjects()) { for (Enumeration newClones = getNewObjectsCloneToOriginal().keys(); newClones.hasMoreElements();) { Object newClone = newClones.nextElement(); getCloneToOriginals().put(newClone, getNewObjectsCloneToOriginal().get(newClone)); } } setNewObjectsCloneToOriginal(null); setNewObjectsOriginalToClone(null); } //reset unitOfWorkChangeSet. Needed for ObjectChangeTrackingPolicy and DeferredChangeDetectionPolicy setUnitOfWorkChangeSet(null); // The collections of clones may change in the new UnitOfWork resetAllCloneCollection(); // 2612538 - the default size of IdentityHashtable (32) is appropriate setObjectsDeletedDuringCommit(new IdentityHashtable()); setDeletedObjects(new IdentityHashtable()); setRemovedObjects(new IdentityHashtable()); setUnregisteredNewObjects(new IdentityHashtable()); //Reset lifecycle this.lifecycle = Birth; this.isSynchronized = false; } /** * INTERNAL: * THis method is used to transition an object from the deleted objects list * to be simply be register. */ protected void undeleteObject(Object object){ getDeletedObjects().remove(object); if (getParent().isUnitOfWork()) { ((UnitOfWorkImpl)getParent()).undeleteObject(object); } } /** * PUBLIC: * Unregister the object with the unit of work. * This can be used to delete an object that was just created and is not yet persistent. * Delete object can also be used, but will result in inserting the object and then deleting it. * The method will only unregister the object and its privately owned parts */ public void unregisterObject(Object clone) { unregisterObject(clone, DescriptorIterator.CascadePrivateParts); } /** * INTERNAL: * Unregister the object with the unit of work. * This can be used to delete an object that was just created and is not yet persistent. * Delete object can also be used, but will result in inserting the object and then deleting it. */ public void unregisterObject(Object clone, int cascadeDepth) { // Allow register to be called with null and just return true if (clone == null) { return; } //CR#2272 logDebugMessage(clone, "unregister"); Object implementation = getDescriptor(clone).getObjectBuilder().unwrapObject(clone, this); // This define an inner class for process the itteration operation, don't be scared, its just an inner class. DescriptorIterator iterator = new DescriptorIterator() { public void iterate(Object object) { if (isClassReadOnly(object.getClass(), getCurrentDescriptor())) { setShouldBreak(true); return; } // Check if object exists in the IM. Vector primaryKey = getCurrentDescriptor().getObjectBuilder().extractPrimaryKeyFromObject(object, UnitOfWorkImpl.this); // If object exists in IM remove it from the IM and also from clone mapping. getIdentityMapAccessorInstance().removeFromIdentityMap(primaryKey, object.getClass(), getCurrentDescriptor()); getCloneMapping().remove(object); // Remove object from the new object cache // PERF: Avoid initialization of new objects if none. if (hasNewObjects()) { Object original = getNewObjectsCloneToOriginal().remove(object); if (original != null) { getNewObjectsOriginalToClone().remove(original); } } } }; iterator.setSession(this); iterator.setCascadeDepth(cascadeDepth); iterator.startIterationOn(implementation); } /** * INTERNAL: * This method is used internally to update the tracked objects if required */ public void updateChangeTrackersIfRequired(Object objectToWrite, ObjectChangeSet changeSetToWrite, UnitOfWorkImpl uow, ClassDescriptor descriptor) { //this is a no op in this unitOfWork Class see subclasses for implementation. } /** * ADVANCED: * This can be used to help debugging an object-space corruption. * An object-space corruption is when your application has incorrectly related a clone to an original object. * This method will validate that all registered objects are in a correct state and throw * an error if not, it will contain the full stack of object references in the error message. * If you call this method after each register or change you perform it will pin-point where the error was made. */ public void validateObjectSpace() { log(SessionLog.FINER, SessionLog.TRANSACTION, "validate_object_space"); // This define an inner class for process the itteration operation, don't be scared, its just an inner class. DescriptorIterator iterator = new DescriptorIterator() { public void iterate(Object object) { try { if (isClassReadOnly(object.getClass(), getCurrentDescriptor())) { setShouldBreak(true); return; } else { getBackupClone(object); } } catch (TopLinkException exception) { log(SessionLog.FINEST, SessionLog.TRANSACTION, "stack_of_visited_objects_that_refer_to_the_corrupt_object", getVisitedStack()); log(SessionLog.FINER, SessionLog.TRANSACTION, "corrupt_object_referenced_through_mapping", getCurrentMapping()); throw exception; } } }; iterator.setSession(this); for (Enumeration clonesEnum = getCloneMapping().keys(); clonesEnum.hasMoreElements();) { iterator.startIterationOn(clonesEnum.nextElement()); } } /** * INTERNAL: * Indicates if a transaction was begun by a pessimistic locking or non-selecting query. * Traverse to the root UOW to get value. */ // * 2.5.1.8 Nov 17, 2000 JED // * Prs 25751 Changed to make this method public public boolean wasTransactionBegunPrematurely() { if (isNestedUnitOfWork()) { return ((UnitOfWorkImpl)getParent()).wasTransactionBegunPrematurely(); } return wasTransactionBegunPrematurely; } /** * ADVANCED: Writes all changes now before commit(). * The commit process will begin and all changes will be written out to the datastore, but the datastore transaction will not * be committed, nor will changes be merged into the global cache. *

* A subsequent commit (on UnitOfWork or global transaction) will be required to finalize the commit process. *

* As the commit process has begun any attempt to register objects, or execute object-level queries will * generate an exception. Report queries, non-caching queries, and data read/modify queries are allowed. *

* On exception any global transaction will be rolled back or marked rollback only. No recovery of this UnitOfWork will be possible. *

* Can only be called once. It can not be used to write out changes in an incremental fashion. *

* Use to partially commit a transaction outside of a JTA transaction's callbacks. Allows you to get back any exception directly. *

* Use to commit a UnitOfWork in two stages. */ public void writeChanges() { if (!isActive()) { throw ValidationException.inActiveUnitOfWork("writeChanges"); } if (isAfterWriteChangesButBeforeCommit()) { throw ValidationException.cannotWriteChangesTwice(); } if (isNestedUnitOfWork()) { throw ValidationException.writeChangesOnNestedUnitOfWork(); } log(SessionLog.FINER, SessionLog.TRANSACTION, "begin_unit_of_work_commit"); getEventManager().preCommitUnitOfWork(); setLifecycle(CommitPending); try { commitToDatabaseWithChangeSet(false); } catch (RuntimeException e) { setLifecycle(WriteChangesFailed); throw e; } setLifecycle(CommitTransactionPending); } /** * INTERNAL: * This method notifies the accessor that a particular sets of writes has * completed. This notification can be used for such thing as flushing the * batch mechanism */ public void writesCompleted() { getParent().writesCompleted(); } /** * log the message and debug info if option is set. (reduce the duplicate codes) */ private void logDebugMessage(Object object, String debugMessage) { log(SessionLog.FINEST, SessionLog.TRANSACTION, debugMessage, object); } /** * INTERNAL: * Return the registered working copy from the unit of work identity map. * If not registered in the unit of work yet, return null */ public Object getWorkingCopyFromUnitOfWorkIdentityMap(Object object, Vector primaryKey) { //return the descriptor of the passed object ClassDescriptor descriptor = getDescriptor(object); if (descriptor == null) { throw DescriptorException.missingDescriptor(object.getClass().toString()); } //aggregated object cannot be registered directly, but through the parent owning object. if (descriptor.isAggregateDescriptor() || descriptor.isAggregateCollectionDescriptor()) { throw ValidationException.cannotRegisterAggregateObjectInUnitOfWork(object.getClass()); } // Check if the working copy is again being registered in which case we return the same working copy Object registeredObject = getCloneMapping().get(object); if (registeredObject != null) { return object; } //check the unit of work cache first to see if already registered. Object objectFromUOWCache = getIdentityMapAccessorInstance().getIdentityMapManager().getFromIdentityMap(primaryKey, object.getClass(), descriptor); if (objectFromUOWCache != null) { // Has already been cloned, return the working clone from the IM rather than the passed object. return objectFromUOWCache; } //not found, return null return null; } /** * INTERNAL: */ public IdentityHashtable getPessimisticLockedObjects() { if (pessimisticLockedObjects == null) { // 2612538 - the default size of IdentityHashtable (32) is appropriate pessimisticLockedObjects = new IdentityHashtable(); } return pessimisticLockedObjects; } /** * INTERNAL: */ public void addPessimisticLockedClone(Object clone) { log(SessionLog.FINEST, SessionLog.TRANSACTION, "tracking_pl_object", clone, new Integer(this.hashCode())); getPessimisticLockedObjects().put(clone, clone); } /** * INTERNAL: */ public boolean isPessimisticLocked(Object clone) { return getPessimisticLockedObjects().containsKey(clone); } /** * INTERNAL: * True if either DataModifyQuery or ModifyAllQuery was executed. * In absense of transaction the query execution starts one, therefore * the flag may only be true in transaction, it's reset on commit or rollback. */ public void setWasNonObjectLevelModifyQueryExecuted(boolean wasNonObjectLevelModifyQueryExecuted) { this.wasNonObjectLevelModifyQueryExecuted = wasNonObjectLevelModifyQueryExecuted; } /** * INTERNAL: * True if either DataModifyQuery or ModifyAllQuery was executed. */ public boolean wasNonObjectLevelModifyQueryExecuted() { return wasNonObjectLevelModifyQueryExecuted; } /** * INTERNAL: * Indicates whether readObject should return the object read from the db * in case there is no object in uow cache (as opposed to fetching the object from * parent's cache). Note that wasNonObjectLevelModifyQueryExecuted()==true implies inTransaction()==true. */ public boolean shouldReadFromDB() { return wasNonObjectLevelModifyQueryExecuted(); } /** * INTERNAL: * This method will clear all registered objects from this UnitOfWork. * If parameter value is 'true' then the cache(s) are cleared, too. */ public void clear(boolean shouldClearCache) { this.cloneToOriginals = null; this.cloneMapping = new IdentityHashtable(); this.newObjectsCloneToOriginal = null; this.newObjectsOriginalToClone = null; this.deletedObjects = null; this.allClones = null; this.objectsDeletedDuringCommit = null; this.removedObjects = null; this.unregisteredNewObjects = null; this.unregisteredExistingObjects = null; this.newAggregates = null; this.unitOfWorkChangeSet = null; this.pessimisticLockedObjects = null; this.optimisticReadLockObjects = null; if(shouldClearCache) { this.getIdentityMapAccessor().initializeIdentityMaps(); if (this.getParent() instanceof IsolatedClientSession) { this.getParent().getIdentityMapAccessor().initializeIdentityMaps(); } } } /** * INTERNAL: * Call this method if the uow will no longer used for comitting transactions: * all the changes sets will be dereferenced, and (optionally) the cache cleared. * If the uow is not released, but rather kept around for ValueHolders, then identity maps shouldn't be cleared: * the parameter value should be 'false'. The lifecycle set to Birth so that uow ValueHolder still could be used. * Alternatively, if called from release method then everything should go and therefore parameter value should be 'true'. * In this case lifecycle won't change - uow.release (optionally) calls this method when it (uow) is already dead. * The reason for calling this method from release is to free maximum memory right away: * the uow might still be referenced by objects using UOWValueHolders (though they shouldn't be around * they still might). */ public void clearForClose(boolean shouldClearCache) { clear(shouldClearCache); if(isActive()) { //Reset lifecycle this.lifecycle = Birth; this.isSynchronized = false; } } /** * INTERNAL: * Indicates whether clearForClose methor should be called by release method. */ public boolean shouldClearForCloseOnRelease() { return false; } }





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