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package oracle.toplink.essentials.mappings;

import java.util.*;
import oracle.toplink.essentials.exceptions.*;
import oracle.toplink.essentials.expressions.*;
import oracle.toplink.essentials.internal.descriptors.*;
import oracle.toplink.essentials.internal.helper.*;
import oracle.toplink.essentials.internal.identitymaps.*;
import oracle.toplink.essentials.internal.queryframework.*;
import oracle.toplink.essentials.internal.sessions.*;
import oracle.toplink.essentials.sessions.DatabaseRecord;
import oracle.toplink.essentials.descriptors.DescriptorEvent;
import oracle.toplink.essentials.descriptors.DescriptorEventManager;
import oracle.toplink.essentials.queryframework.*;
import oracle.toplink.essentials.indirection.ValueHolderInterface;
import oracle.toplink.essentials.internal.sessions.AbstractRecord;
import oracle.toplink.essentials.internal.sessions.UnitOfWorkImpl;
import oracle.toplink.essentials.internal.sessions.AbstractSession;
import oracle.toplink.essentials.descriptors.ClassDescriptor;

/**
 * 

Purpose: The aggregate collection mapping is used to represent the aggregate relationship between a single * source object and a collection of target objects. The target objects cannot exist without the existence of the * source object (privately owned) * Unlike the normal aggregate mapping, there is a target table being mapped from the target objects. * Unlike normal 1:m mapping, there is no 1:1 back reference mapping, as foreign key constraints have been resolved by the aggregation. * * @author King (Yaoping) Wang * @since TOPLink/Java 3.0 */ public class AggregateCollectionMapping extends CollectionMapping implements RelationalMapping { /** This is a key in the target table which is a foreign key in the target table. */ protected transient Vector targetForeignKeyFields; /** This is a primary key in the source table that is used as foreign key in the target table */ protected transient Vector sourceKeyFields; /** Foreign keys in the target table to the related keys in the source table */ protected transient Map targetForeignKeyToSourceKeys; /** * PUBLIC: * Default constructor. */ public AggregateCollectionMapping() { this.targetForeignKeyToSourceKeys = new HashMap(5); this.sourceKeyFields = oracle.toplink.essentials.internal.helper.NonSynchronizedVector.newInstance(1); this.targetForeignKeyFields = oracle.toplink.essentials.internal.helper.NonSynchronizedVector.newInstance(1); this.deleteAllQuery = new DeleteAllQuery(); //aggregates should always cascade all operations this.setCascadeAll(true); } /** * INTERNAL: */ public boolean isRelationalMapping() { return true; } /** * PUBLIC: * Define the target foreign key relationship in the 1-M aggregate collection mapping. * Both the target foreign key field name and the source primary key field name must be specified. */ public void addTargetForeignKeyFieldName(String targetForeignKey, String sourceKey) { getTargetForeignKeyFields().addElement(new DatabaseField(targetForeignKey)); getSourceKeyFields().addElement(new DatabaseField(sourceKey)); } /** * INTERNAL: * Used during building the backup shallow copy to copy the vector without re-registering the target objects. */ public Object buildBackupCloneForPartObject(Object attributeValue, Object clone, Object backup, UnitOfWorkImpl unitOfWork) { ContainerPolicy containerPolicy = getContainerPolicy(); if (attributeValue == null) { return containerPolicy.containerInstance(1); } Object clonedAttributeValue = containerPolicy.containerInstance(containerPolicy.sizeFor(attributeValue)); synchronized (attributeValue) { for (Object valuesIterator = containerPolicy.iteratorFor(attributeValue); containerPolicy.hasNext(valuesIterator);) { Object cloneValue = buildElementBackupClone(containerPolicy.next(valuesIterator, unitOfWork), unitOfWork); containerPolicy.addInto(cloneValue, clonedAttributeValue, unitOfWork); } } return clonedAttributeValue; } /** * INTERNAL: * Require for cloning, the part must be cloned. * Ignore the objects, use the attribute value. * this is identical to the super class except that the element must be added to the new * aggregates collection so that the referenced objects will be clonned correctly */ public Object buildCloneForPartObject(Object attributeValue, Object original, Object clone, UnitOfWorkImpl unitOfWork, boolean isExisting) { ContainerPolicy containerPolicy = getContainerPolicy(); if (attributeValue == null) { return containerPolicy.containerInstance(1); } Object clonedAttributeValue = containerPolicy.containerInstance(containerPolicy.sizeFor(attributeValue)); // I need to synchronize here to prevent the collection from changing while I am cloning it. // This will occur when I am merging into the cache and I am instantiating a UOW valueHolder at the same time // I can not synchronize around the clone, as this will cause deadlocks, so I will need to copy the collection then create the clones // I will use a temporary collection to help speed up the process Object temporaryCollection = null; synchronized (attributeValue) { temporaryCollection = containerPolicy.cloneFor(attributeValue); } for (Object valuesIterator = containerPolicy.iteratorFor(temporaryCollection); containerPolicy.hasNext(valuesIterator);) { Object originalElement = containerPolicy.next(valuesIterator, unitOfWork); //need to add to aggregate list in the case that there are related objects. if (unitOfWork.isOriginalNewObject(original)) { unitOfWork.addNewAggregate(originalElement); } Object cloneValue = buildElementClone(originalElement, unitOfWork, isExisting); containerPolicy.addInto(cloneValue, clonedAttributeValue, unitOfWork); } return clonedAttributeValue; } /** * INTERNAL: * Clone the aggregate collection, if necessary. */ protected Object buildElementBackupClone(Object element, UnitOfWorkImpl unitOfWork) { // Do not clone for read-only. if (unitOfWork.isClassReadOnly(element.getClass())) { return element; } ClassDescriptor aggregateDescriptor = getReferenceDescriptor(element.getClass(), unitOfWork); Object clonedElement = aggregateDescriptor.getObjectBuilder().buildBackupClone(element, unitOfWork); return clonedElement; } /** * INTERNAL: * Clone the aggregate collection, if necessary. */ protected Object buildElementClone(Object element, UnitOfWorkImpl unitOfWork, boolean isExisting) { // Do not clone for read-only. if (unitOfWork.isClassReadOnly(element.getClass())) { return element; } ClassDescriptor aggregateDescriptor = getReferenceDescriptor(element.getClass(), unitOfWork); // bug 2612602 as we are building the working copy make sure that we call to correct clone method. Object clonedElement = aggregateDescriptor.getObjectBuilder().instantiateWorkingCopyClone(element, unitOfWork); aggregateDescriptor.getObjectBuilder().populateAttributesForClone(element, clonedElement, unitOfWork, null); // CR 4155 add the originals to the UnitOfWork so that we can find it later in the merge // as aggregates have no identity. If we don't do this we will loose indirection information. unitOfWork.getCloneToOriginals().put(clonedElement, element); return clonedElement; } /** * INTERNAL: * Cascade registerNew for Create through mappings that require the cascade */ public void cascadeRegisterNewIfRequired(Object object, UnitOfWorkImpl uow, IdentityHashtable visitedObjects){ //aggregate objects are not registered but their mappings should be. Object cloneAttribute = null; cloneAttribute = getAttributeValueFromObject(object); if ((cloneAttribute == null) || (!getIndirectionPolicy().objectIsInstantiated(cloneAttribute))) { return; } ObjectBuilder builder = null; ContainerPolicy cp = getContainerPolicy(); Object cloneObjectCollection = null; cloneObjectCollection = getRealCollectionAttributeValueFromObject(object, uow); Object cloneIter = cp.iteratorFor(cloneObjectCollection); while (cp.hasNext(cloneIter)) { Object nextObject = cp.next(cloneIter, uow); if (nextObject != null && (! visitedObjects.contains(nextObject))){ visitedObjects.put(nextObject, nextObject); builder = getReferenceDescriptor(nextObject.getClass(), uow).getObjectBuilder(); builder.cascadeRegisterNewForCreate(nextObject, uow, visitedObjects); } } } /** * INTERNAL: * Cascade registerNew for Create through mappings that require the cascade */ public void cascadePerformRemoveIfRequired(Object object, UnitOfWorkImpl uow, IdentityHashtable visitedObjects){ //aggregate objects are not registered but their mappings should be. Object cloneAttribute = null; cloneAttribute = getAttributeValueFromObject(object); if ((cloneAttribute == null)) { return; } ObjectBuilder builder = null; ContainerPolicy cp = getContainerPolicy(); Object cloneObjectCollection = null; cloneObjectCollection = getRealCollectionAttributeValueFromObject(object, uow); Object cloneIter = cp.iteratorFor(cloneObjectCollection); while (cp.hasNext(cloneIter)) { Object nextObject = cp.next(cloneIter, uow); if (nextObject != null && ( ! visitedObjects.contains(nextObject) ) ){ visitedObjects.put(nextObject, nextObject); builder = getReferenceDescriptor(nextObject.getClass(), uow).getObjectBuilder(); builder.cascadePerformRemove(nextObject, uow, visitedObjects); } } } /** * INTERNAL: * The mapping clones itself to create deep copy. */ public Object clone() { AggregateCollectionMapping mappingObject = (AggregateCollectionMapping)super.clone(); mappingObject.setTargetForeignKeyToSourceKeys(new HashMap(getTargetForeignKeyToSourceKeys())); return mappingObject; } /** * INTERNAL: * This method is used to create a change record from comparing two aggregate collections * @return ChangeRecord */ public ChangeRecord compareForChange(Object clone, Object backUp, ObjectChangeSet owner, AbstractSession session) { Object cloneAttribute = null; Object backUpAttribute = null; cloneAttribute = getAttributeValueFromObject(clone); if ((cloneAttribute != null) && (!getIndirectionPolicy().objectIsInstantiated(cloneAttribute))) { //If the clone's valueholder was not triggered then no changes were made. return null; } if (!owner.isNew()) { backUpAttribute = getAttributeValueFromObject(backUp); if ((backUpAttribute == null) && (cloneAttribute == null)) { return null; } ContainerPolicy cp = getContainerPolicy(); Object backupCollection = null; Object cloneCollection = null; cloneCollection = getRealCollectionAttributeValueFromObject(clone, session); backupCollection = getRealCollectionAttributeValueFromObject(backUp, session); if (cp.sizeFor(backupCollection) != cp.sizeFor(cloneCollection)) { return convertToChangeRecord(cloneCollection, owner, session); } Object cloneIterator = cp.iteratorFor(cloneCollection); Object backUpIterator = cp.iteratorFor(backupCollection); boolean change = false; // For bug 2863721 must use a different UnitOfWorkChangeSet as here just // seeing if changes are needed. If changes are needed then a // real changeSet will be created later. UnitOfWorkChangeSet uowComparisonChangeSet = new UnitOfWorkChangeSet(); while (cp.hasNext(cloneIterator)) { Object cloneObject = cp.next(cloneIterator, session); // For CR#2285 assume that if null is added the collection has changed. if (cloneObject == null) { change = true; break; } Object backUpObject = null; if (cp.hasNext(backUpIterator)) { backUpObject = cp.next(backUpIterator, session); } else { change = true; break; } if (cloneObject.getClass().equals(backUpObject.getClass())) { ObjectBuilder builder = getReferenceDescriptor(cloneObject.getClass(), session).getObjectBuilder(); ObjectChangeSet initialChanges = builder.createObjectChangeSet(cloneObject, uowComparisonChangeSet, owner.isNew(), session); //compare for changes will return null if no change is detected and I need to remove the changeSet ObjectChangeSet changes = builder.compareForChange(cloneObject, backUpObject, uowComparisonChangeSet, session); if (changes != null) { change = true; break; } } else { change = true; break; } } if ((change == true) || (cp.hasNext(backUpIterator))) { return convertToChangeRecord(cloneCollection, owner, session); } else { return null; } } return convertToChangeRecord(getRealCollectionAttributeValueFromObject(clone, session), owner, session); } /** * INTERNAL: * Compare the attributes belonging to this mapping for the objects. */ public boolean compareObjects(Object firstObject, Object secondObject, AbstractSession session) { Object firstCollection = getRealCollectionAttributeValueFromObject(firstObject, session); Object secondCollection = getRealCollectionAttributeValueFromObject(secondObject, session); ContainerPolicy containerPolicy = getContainerPolicy(); if (containerPolicy.sizeFor(firstCollection) != containerPolicy.sizeFor(secondCollection)) { return false; } if (containerPolicy.sizeFor(firstCollection) == 0) { return true; } //iterator the first aggregate collection for (Object iterFirst = containerPolicy.iteratorFor(firstCollection); containerPolicy.hasNext(iterFirst);) { //fetch the next object from the first iterator. Object firstAggregateObject = containerPolicy.next(iterFirst, session); //iterator the second aggregate collection for (Object iterSecond = containerPolicy.iteratorFor(secondCollection); true;) { //fetch the next object from the second iterator. Object secondAggregateObject = containerPolicy.next(iterSecond, session); //matched object found, break to outer FOR loop if (getReferenceDescriptor().getObjectBuilder().compareObjects(firstAggregateObject, secondAggregateObject, session)) { break; } if (!containerPolicy.hasNext(iterSecond)) { return false; } } } return true; } /** * INTERNAL: * This method is used to convert the contents of an aggregateCollection into a * changeRecord * @return oracle.toplink.essentials.internal.sessions.AggregateCollectionChangeRecord the changerecord representing this AggregateCollectionMapping * @param owner oracle.toplink.essentials.internal.sessions.ObjectChangeSet the ChangeSet that uses this record * @param cloneCollection Object the collection to convert * @param session oracle.toplink.essentials.publicinterface.Session */ protected ChangeRecord convertToChangeRecord(Object cloneCollection, ObjectChangeSet owner, AbstractSession session) { ContainerPolicy cp = getContainerPolicy(); Object cloneIter = cp.iteratorFor(cloneCollection); Vector collectionChanges = new Vector(2); while (cp.hasNext(cloneIter)) { Object aggregateObject = cp.next(cloneIter, session); // For CR#2258 quietly ignore nulls inserted into a collection. if (aggregateObject != null) { ObjectChangeSet changes = getReferenceDescriptor(aggregateObject.getClass(), session).getObjectBuilder().compareForChange(aggregateObject, null, (UnitOfWorkChangeSet)owner.getUOWChangeSet(), session); collectionChanges.addElement(changes); } } //cr 3013 Removed if collection is empty return null block, which prevents recording clear() change AggregateCollectionChangeRecord changeRecord = new AggregateCollectionChangeRecord(owner); changeRecord.setAttribute(getAttributeName()); changeRecord.setMapping(this); changeRecord.setChangedValues(collectionChanges); return changeRecord; } /** * To delete all the entries matching the selection criteria from the table stored in the * referenced descriptor */ protected void deleteAll(WriteObjectQuery query) throws DatabaseException { Object referenceObjects = null; if(usesIndirection()) { Object attribute = getAttributeAccessor().getAttributeValueFromObject(query.getObject()); if(attribute == null || !((ValueHolderInterface)attribute).isInstantiated()) { // An empty Vector indicates to DeleteAllQuery that no objects should be removed from cache referenceObjects = new Vector(0); } } if(referenceObjects == null) { referenceObjects = this.getRealCollectionAttributeValueFromObject(query.getObject(), query.getSession()); } // Ensure that the query is prepare before cloning. ((DeleteAllQuery)getDeleteAllQuery()).executeDeleteAll(query.getSession().getSessionForClass(getReferenceClass()), query.getTranslationRow(), getContainerPolicy().vectorFor(referenceObjects, query.getSession())); } /** * INTERNAL: * Execute a descriptor event for the specified event code. */ protected void executeEvent(int eventCode, ObjectLevelModifyQuery query) { ClassDescriptor referenceDescriptor = getReferenceDescriptor(query.getObject().getClass(), query.getSession()); // PERF: Avoid events if no listeners. if (referenceDescriptor.getEventManager().hasAnyEventListeners()) { referenceDescriptor.getEventManager().executeEvent(new DescriptorEvent(eventCode, query)); } } /** * INTERNAL: * Extract the source primary key value from the target row. * Used for batch reading, most following same order and fields as in the mapping. */ protected Vector extractKeyFromTargetRow(AbstractRecord row, AbstractSession session) { Vector key = new Vector(getTargetForeignKeyFields().size()); for (int index = 0; index < getTargetForeignKeyFields().size(); index++) { DatabaseField targetField = (DatabaseField)getTargetForeignKeyFields().elementAt(index); DatabaseField sourceField = (DatabaseField)getSourceKeyFields().elementAt(index); Object value = row.get(targetField); // Must ensure the classificatin to get a cache hit. try { value = session.getDatasourcePlatform().getConversionManager().convertObject(value, getDescriptor().getObjectBuilder().getFieldClassification(sourceField)); } catch (ConversionException e) { throw ConversionException.couldNotBeConverted(this, getDescriptor(), e); } key.addElement(value); } return key; } /** * INTERNAL: * Extract the primary key value from the source row. * Used for batch reading, most following same order and fields as in the mapping. */ protected Vector extractPrimaryKeyFromRow(AbstractRecord row, AbstractSession session) { Vector key = new Vector(getSourceKeyFields().size()); for (Enumeration fieldEnum = getSourceKeyFields().elements(); fieldEnum.hasMoreElements();) { DatabaseField field = (DatabaseField)fieldEnum.nextElement(); Object value = row.get(field); // Must ensure the classificatin to get a cache hit. try { value = session.getDatasourcePlatform().getConversionManager().convertObject(value, getDescriptor().getObjectBuilder().getFieldClassification(field)); } catch (ConversionException e) { throw ConversionException.couldNotBeConverted(this, getDescriptor(), e); } key.addElement(value); } return key; } /** * INTERNAL: * return the aggregate databaseRow with the primary keys from the source table and targer table */ public AbstractRecord getAggregateRow(ObjectLevelModifyQuery query, Object object) { Vector referenceObjectKeys = getReferenceObjectKeys(query); AbstractRecord aggregateRow = new DatabaseRecord(); Vector keys = getTargetForeignKeyFields(); for (int keyIndex = 0; keyIndex < keys.size(); keyIndex++) { aggregateRow.put(keys.elementAt(keyIndex), referenceObjectKeys.elementAt(keyIndex)); } getReferenceDescriptor(object.getClass(), query.getSession()).getObjectBuilder().buildRow(aggregateRow, object, query.getSession()); return aggregateRow; } /** * Delete all criteria is created with target foreign keys and source keys. * This criteria is then used to delete target records from the table. */ protected Expression getDeleteAllCriteria(AbstractSession session) { Expression expression; Expression criteria = null; Expression builder = new ExpressionBuilder(); for (Iterator keys = getTargetForeignKeyToSourceKeys().keySet().iterator(); keys.hasNext();) { DatabaseField targetForeignKey = (DatabaseField)keys.next(); DatabaseField sourceKey = (DatabaseField)getTargetForeignKeyToSourceKeys().get(targetForeignKey); expression = builder.getField(targetForeignKey).equal(builder.getParameter(sourceKey)); criteria = expression.and(criteria); } return criteria; } /** * INTERNAL: * for inheritance purpose */ public ClassDescriptor getReferenceDescriptor(Class theClass, AbstractSession session) { if (getReferenceDescriptor().getJavaClass().equals(theClass)) { return getReferenceDescriptor(); } else { ClassDescriptor subclassDescriptor = session.getDescriptor(theClass); if (subclassDescriptor == null) { throw DescriptorException.noSubClassMatch(theClass, this); } else { return subclassDescriptor; } } } /** * INTERNAL: * get reference object keys */ public Vector getReferenceObjectKeys(ObjectLevelModifyQuery query) throws DatabaseException, OptimisticLockException { Vector referenceObjectKeys = new Vector(getSourceKeyFields().size()); //For CR#2587-S.M. For nested aggregate collections the source keys can easily be read from the original query. AbstractRecord translationRow = query.getTranslationRow(); for (Enumeration sourcekeys = getSourceKeyFields().elements(); sourcekeys.hasMoreElements();) { DatabaseField sourceKey = (DatabaseField)sourcekeys.nextElement(); // CR#2587. Try first to get the source key from the original query. If that fails try to get it from the object. Object referenceKey = null; if ((translationRow != null) && (translationRow.containsKey(sourceKey))) { referenceKey = translationRow.get(sourceKey); } else { referenceKey = getDescriptor().getObjectBuilder().extractValueFromObjectForField(query.getObject(), sourceKey, query.getSession()); } referenceObjectKeys.addElement(referenceKey); } return referenceObjectKeys; } /** * PUBLIC: * Return the source key field names associated with the mapping. * These are in-order with the targetForeignKeyFieldNames. */ public Vector getSourceKeyFieldNames() { Vector fieldNames = new Vector(getSourceKeyFields().size()); for (Enumeration fieldsEnum = getSourceKeyFields().elements(); fieldsEnum.hasMoreElements();) { fieldNames.addElement(((DatabaseField)fieldsEnum.nextElement()).getQualifiedName()); } return fieldNames; } /** * INTERNAL: * Return the source key names associated with the mapping */ public Vector getSourceKeyFields() { return sourceKeyFields; } /** * PUBLIC: * Return the target foregin key field names associated with the mapping. * These are in-order with the sourceKeyFieldNames. */ public Vector getTargetForeignKeyFieldNames() { Vector fieldNames = new Vector(getTargetForeignKeyFields().size()); for (Enumeration fieldsEnum = getTargetForeignKeyFields().elements(); fieldsEnum.hasMoreElements();) { fieldNames.addElement(((DatabaseField)fieldsEnum.nextElement()).getQualifiedName()); } return fieldNames; } /** * INTERNAL: * Return the target foregin key fields associated with the mapping */ public Vector getTargetForeignKeyFields() { return targetForeignKeyFields; } /** * INTERNAL: */ public Map getTargetForeignKeyToSourceKeys() { return targetForeignKeyToSourceKeys; } /** * INTERNAL: * For aggregate collection mapping the reference descriptor is cloned. The cloned descriptor is then * assigned primary keys and table names before initialize. Once cloned descriptor is initialized * it is assigned as reference descriptor in the aggregate mapping. This is a very specifiec * behaviour for aggregate mappings. The original descriptor is used only for creating clones and * after that mapping never uses it. * Some initialization is done in postInitialize to ensure the target descriptor's references are initialized. */ public void initialize(AbstractSession session) throws DescriptorException { super.initialize(session); if (!getReferenceDescriptor().isAggregateCollectionDescriptor()) { session.getIntegrityChecker().handleError(DescriptorException.referenceDescriptorIsNotAggregateCollection(getReferenceClass().getName(), this)); } if (shouldInitializeSelectionCriteria()) { if (isSourceKeySpecified()) { initializeTargetForeignKeyToSourceKeys(session); } else { initializeTargetForeignKeyToSourceKeysWithDefaults(session); } initializeSelectionCriteria(session); } // Aggregate 1:m never maintains cache as target objects are aggregates. getSelectionQuery().setShouldMaintainCache(false); initializeDeleteAllQuery(session); } /** * INTERNAL: * For aggregate mapping the reference descriptor is cloned. Also the involved inheritanced descriptor, its childern * and parents all need to be cloned. The cloned descriptors are then assigned primary keys and table names before * initialize. Once cloned descriptor is initialized it is assigned as reference descriptor in the aggregate mapping. * This is a very specifiec behaviour for aggregate mappings. The original descriptor is used only for creating clones * and after that mapping never uses it. * Some initialization is done in postInitialize to ensure the target descriptor's references are initialized. */ public void initializeChildInheritance(ClassDescriptor parentDescriptor, AbstractSession session) throws DescriptorException { //recursive call to the further childern descriptors if (parentDescriptor.getInheritancePolicy().hasChildren()) { //setFields(clonedChildDescriptor.getFields()); Vector childDescriptors = parentDescriptor.getInheritancePolicy().getChildDescriptors(); Vector cloneChildDescriptors = oracle.toplink.essentials.internal.helper.NonSynchronizedVector.newInstance(); for (Enumeration enumtr = childDescriptors.elements(); enumtr.hasMoreElements();) { ClassDescriptor clonedChildDescriptor = (ClassDescriptor)((ClassDescriptor)enumtr.nextElement()).clone(); if (!clonedChildDescriptor.isAggregateCollectionDescriptor()) { session.getIntegrityChecker().handleError(DescriptorException.referenceDescriptorIsNotAggregate(clonedChildDescriptor.getJavaClass().getName(), this)); } clonedChildDescriptor.getInheritancePolicy().setParentDescriptor(parentDescriptor); clonedChildDescriptor.preInitialize(session); clonedChildDescriptor.initialize(session); cloneChildDescriptors.addElement(clonedChildDescriptor); initializeChildInheritance(clonedChildDescriptor, session); } parentDescriptor.getInheritancePolicy().setChildDescriptors(cloneChildDescriptors); } } /** * INTERNAL: * Initialize delete all query. This query is used to delete the collection of objects from the * target table. */ protected void initializeDeleteAllQuery(AbstractSession session) { DeleteAllQuery query = (DeleteAllQuery)getDeleteAllQuery(); query.setReferenceClass(getReferenceClass()); query.setShouldMaintainCache(false); if (!hasCustomDeleteAllQuery()) { if (getSelectionCriteria() == null) { query.setSelectionCriteria(getDeleteAllCriteria(session)); } else { query.setSelectionCriteria(getSelectionCriteria()); } } } /** * INTERNAL: * For aggregate mapping the reference descriptor is cloned. Also the involved inheritanced descriptor, its childern * and parents all need to be cloned. The cloned descriptors are then assigned primary keys and table names before * initialize. Once cloned descriptor is initialized it is assigned as reference descriptor in the aggregate mapping. * This is a very specifiec behaviour for aggregate mappings. The original descriptor is used only for creating clones * and after that mapping never uses it. * Some initialization is done in postInitialize to ensure the target descriptor's references are initialized. */ public void initializeParentInheritance(ClassDescriptor parentDescriptor, ClassDescriptor childDescriptor, AbstractSession session) throws DescriptorException { if (!parentDescriptor.isAggregateCollectionDescriptor()) { session.getIntegrityChecker().handleError(DescriptorException.referenceDescriptorIsNotAggregateCollection(parentDescriptor.getJavaClass().getName(), this)); } ClassDescriptor clonedParentDescriptor = (ClassDescriptor)parentDescriptor.clone(); //recursive call to the further parent descriptors if (clonedParentDescriptor.getInheritancePolicy().isChildDescriptor()) { ClassDescriptor parentToParentDescriptor = session.getDescriptor(clonedParentDescriptor.getJavaClass()); initializeParentInheritance(parentToParentDescriptor, parentDescriptor, session); } Vector childern = oracle.toplink.essentials.internal.helper.NonSynchronizedVector.newInstance(1); childern.addElement(childDescriptor); clonedParentDescriptor.getInheritancePolicy().setChildDescriptors(childern); clonedParentDescriptor.preInitialize(session); clonedParentDescriptor.initialize(session); } /** * INTERNAL: * Selection criteria is created with target foreign keys and source keys. * This criteria is then used to read records from the target table. */ protected void initializeSelectionCriteria(AbstractSession session) { Expression expression; Expression criteria; Expression builder = new ExpressionBuilder(); for (Iterator keys = getTargetForeignKeyToSourceKeys().keySet().iterator(); keys.hasNext();) { DatabaseField targetForeignKey = (DatabaseField)keys.next(); DatabaseField sourceKey = (DatabaseField)getTargetForeignKeyToSourceKeys().get(targetForeignKey); expression = builder.getField(targetForeignKey).equal(builder.getParameter(sourceKey)); criteria = expression.and(getSelectionCriteria()); setSelectionCriteria(criteria); } } /** * INTERNAL: * The foreign keys and the primary key names are converted to DatabaseFields and stored. */ protected void initializeTargetForeignKeyToSourceKeys(AbstractSession session) throws DescriptorException { if (getTargetForeignKeyFields().isEmpty()) { throw DescriptorException.noTargetForeignKeysSpecified(this); } for (Enumeration keys = getTargetForeignKeyFields().elements(); keys.hasMoreElements();) { DatabaseField foreignKeyfield = (DatabaseField)keys.nextElement(); getReferenceDescriptor().buildField(foreignKeyfield); } for (Enumeration keys = getSourceKeyFields().elements(); keys.hasMoreElements();) { DatabaseField sourceKeyfield = (DatabaseField)keys.nextElement(); getDescriptor().buildField(sourceKeyfield); } if (getTargetForeignKeyFields().size() != getSourceKeyFields().size()) { throw DescriptorException.targetForeignKeysSizeMismatch(this); } Enumeration targetForeignKeysEnum = getTargetForeignKeyFields().elements(); Enumeration sourceKeysEnum = getSourceKeyFields().elements(); for (; targetForeignKeysEnum.hasMoreElements();) { getTargetForeignKeyToSourceKeys().put(targetForeignKeysEnum.nextElement(), sourceKeysEnum.nextElement()); } } /** * INTERNAL: * The foreign keys and the primary key names are converted to DatabaseFields and stored. The source keys * are not specified by the user so primary keys are extracted from the reference descriptor. */ protected void initializeTargetForeignKeyToSourceKeysWithDefaults(AbstractSession session) throws DescriptorException { if (getTargetForeignKeyFields().isEmpty()) { throw DescriptorException.noTargetForeignKeysSpecified(this); } List sourceKeys = getDescriptor().getPrimaryKeyFields(); setSourceKeyFields(oracle.toplink.essentials.internal.helper.NonSynchronizedVector.newInstance(sourceKeys)); for (Enumeration keys = getTargetForeignKeyFields().elements(); keys.hasMoreElements();) { DatabaseField foreignKeyfield = ((DatabaseField)keys.nextElement()); getReferenceDescriptor().buildField(foreignKeyfield); } if (getTargetForeignKeyFields().size() != sourceKeys.size()) { throw DescriptorException.targetForeignKeysSizeMismatch(this); } for (int index = 0; index < getTargetForeignKeyFields().size(); index++) { getTargetForeignKeyToSourceKeys().put(getTargetForeignKeyFields().get(index), sourceKeys.get(index)); } } /** * INTERNAL: * Iterate on the specified element. */ public void iterateOnElement(DescriptorIterator iterator, Object element) { // CR#... Aggregate collections must iterate as aggregates, not regular mappings. // For some reason the element can be null, this makes absolutly no sense, but we have a test case for it... if (element != null) { iterator.iterateForAggregateMapping(element, this, iterator.getSession().getDescriptor(element)); } } /** * INTERNAL: */ public boolean isAggregateCollectionMapping() { return true; } /** * INTERNAL: */ public boolean isPrivateOwned() { return true; } /** * Checks if source key is specified or not. */ protected boolean isSourceKeySpecified() { return !(getSourceKeyFields().isEmpty()); } /** * INTERNAL: * Merge changes from the source to the target object. * Because this is a collection mapping, values are added to or removed from the * collection based on the changeset */ public void mergeChangesIntoObject(Object target, ChangeRecord changeRecord, Object source, MergeManager mergeManager) { //Check to see if the target has an instantiated collection if (!isAttributeValueInstantiated(target)) { //Then do nothing. return; } ContainerPolicy containerPolicy = getContainerPolicy(); AbstractSession session = mergeManager.getSession(); Object valueOfTarget = null; //At this point the source's indirection must be instantiated or the changeSet would never have // been created Object sourceAggregate = null; //On a distributed cache if our changes are for the same version as the target object //then load the changes from database. // CR 4143 // CR 4155 Always replace the collection with the query results as we will not be able to // find the originals for merging and indirection information may be lost. if (mergeManager.shouldMergeChangesIntoDistributedCache()) { ClassDescriptor descriptor = getDescriptor(); AbstractRecord parentRow = descriptor.getObjectBuilder().extractPrimaryKeyRowFromObject(target, session); Object result = getIndirectionPolicy().valueFromQuery(getSelectionQuery(), parentRow, session);//fix for indirection setAttributeValueInObject(target, result); return; } // iterate over the changes and merge the collections Vector aggregateObjects = ((AggregateCollectionChangeRecord)changeRecord).getChangedValues(); valueOfTarget = containerPolicy.containerInstance(); // Next iterate over the changes and add them to the container ObjectChangeSet objectChanges = null; for (int i = 0; i < aggregateObjects.size(); ++i) { objectChanges = (ObjectChangeSet)aggregateObjects.elementAt(i); Class localClassType = objectChanges.getClassType(session); sourceAggregate = objectChanges.getUnitOfWorkClone(); // cr 4155 Load the target from the UnitOfWork. This will be the original // aggregate object that has the original indirection in it. Object targetAggregate = ((UnitOfWorkImpl)mergeManager.getSession()).getCloneToOriginals().get(sourceAggregate); if (targetAggregate == null) { targetAggregate = getReferenceDescriptor(localClassType, session).getObjectBuilder().buildNewInstance(); } getReferenceDescriptor(localClassType, session).getObjectBuilder().mergeChangesIntoObject(targetAggregate, objectChanges, sourceAggregate, mergeManager); containerPolicy.addInto(targetAggregate, valueOfTarget, session); } setRealAttributeValueInObject(target, valueOfTarget); } /** * INTERNAL: * Merge changes from the source to the target object. */ public void mergeIntoObject(Object target, boolean isTargetUnInitialized, Object source, MergeManager mergeManager) { if (isTargetUnInitialized) { // This will happen if the target object was removed from the cache before the commit was attempted if (mergeManager.shouldMergeWorkingCopyIntoOriginal() && (!isAttributeValueInstantiated(source))) { setAttributeValueInObject(target, getIndirectionPolicy().getOriginalIndirectionObject(getAttributeValueFromObject(source), mergeManager.getSession())); return; } } if (!shouldMergeCascadeReference(mergeManager)) { // This is only going to happen on mergeClone, and we should not attempt to merge the reference return; } if (mergeManager.shouldMergeOriginalIntoWorkingCopy()) { if (!isAttributeValueInstantiated(target)) { // This will occur when the clone's value has not been instantiated yet and we do not need // the refresh that attribute return; } } else if (!isAttributeValueInstantiated(source)) { // I am merging from a clone into an original. No need to do merge if the attribute was never // modified return; } ContainerPolicy containerPolicy = getContainerPolicy(); Object valueOfSource = getRealCollectionAttributeValueFromObject(source, mergeManager.getSession()); Object valueOfTarget = containerPolicy.containerInstance(containerPolicy.sizeFor(valueOfSource)); for (Object sourceValuesIterator = containerPolicy.iteratorFor(valueOfSource); containerPolicy.hasNext(sourceValuesIterator);) { Object sourceValue = containerPolicy.next(sourceValuesIterator, mergeManager.getSession()); //CR#2896 - TW Object originalValue = getReferenceDescriptor(sourceValue.getClass(), mergeManager.getSession()).getObjectBuilder().buildNewInstance(); getReferenceDescriptor(sourceValue.getClass(), mergeManager.getSession()).getObjectBuilder().mergeIntoObject(originalValue, true, sourceValue, mergeManager); containerPolicy.addInto(originalValue, valueOfTarget, mergeManager.getSession()); } // Must re-set variable to allow for set method to re-morph changes if the collection is not being stored directly. setRealAttributeValueInObject(target, valueOfTarget); } /** * INTERNAL: * An object was added to the collection during an update, insert it if private. */ protected void objectAddedDuringUpdate(ObjectLevelModifyQuery query, Object objectAdded, ObjectChangeSet changeSet) throws DatabaseException, OptimisticLockException { // Insert must not be done for uow or cascaded queries and we must cascade to cascade policy. InsertObjectQuery insertQuery = getAndPrepareModifyQueryForInsert(query, objectAdded); query.getSession().executeQuery(insertQuery, insertQuery.getTranslationRow()); } /** * INTERNAL: * An object was removed to the collection during an update, delete it if private. */ protected void objectRemovedDuringUpdate(ObjectLevelModifyQuery query, Object objectDeleted) throws DatabaseException, OptimisticLockException { // Delete must not be done for uow or cascaded queries and we must cascade to cascade policy. DeleteObjectQuery deleteQuery = new DeleteObjectQuery(); prepareModifyQueryForDelete(query, deleteQuery, objectDeleted); query.getSession().executeQuery(deleteQuery, deleteQuery.getTranslationRow()); } /** * INTERNAL: * An object is still in the collection, update it as it may have changed. */ protected void objectUnchangedDuringUpdate(ObjectLevelModifyQuery query, Object object, Hashtable backupCloneKeyedCache, CacheKey cachedKey) throws DatabaseException, OptimisticLockException { // Always write for updates, either private or in uow if calling this method. UpdateObjectQuery updateQuery = new UpdateObjectQuery(); Object backupclone = backupCloneKeyedCache.get(cachedKey); updateQuery.setBackupClone(backupclone); prepareModifyQueryForUpdate(query, updateQuery, object); query.getSession().executeQuery(updateQuery, updateQuery.getTranslationRow()); } /** * INTERNAL: * For aggregate collection mapping the reference descriptor is cloned. The cloned descriptor is then * assigned primary keys and table names before initialize. Once cloned descriptor is initialized * it is assigned as reference descriptor in the aggregate mapping. This is a very specifiec * behaviour for aggregate mappings. The original descriptor is used only for creating clones and * after that mapping never uses it. * Some initialization is done in postInitialize to ensure the target descriptor's references are initialized. */ public void postInitialize(AbstractSession session) throws DescriptorException { super.postInitialize(session); getReferenceDescriptor().postInitialize(session); } /** * INTERNAL: * Insert privately owned parts */ public void postInsert(WriteObjectQuery query) throws DatabaseException, OptimisticLockException { if (isReadOnly()) { return; } Object objects = getRealCollectionAttributeValueFromObject(query.getObject(), query.getSession()); // insert each object one by one ContainerPolicy cp = getContainerPolicy(); for (Object iter = cp.iteratorFor(objects); cp.hasNext(iter);) { Object object = cp.next(iter, query.getSession()); InsertObjectQuery insertQuery = getAndPrepareModifyQueryForInsert(query, object); query.getSession().executeQuery(insertQuery, insertQuery.getTranslationRow()); } } /** * INTERNAL: * Update the privately owned parts */ public void postUpdate(WriteObjectQuery writeQuery) throws DatabaseException, OptimisticLockException { if (isReadOnly()) { return; } // If objects are not instantiated that means they are not changed. if (!isAttributeValueInstantiated(writeQuery.getObject())) { return; } // Manage objects added and removed from the collection. Object objects = getRealCollectionAttributeValueFromObject(writeQuery.getObject(), writeQuery.getSession()); Object currentObjectsInDB = readPrivateOwnedForObject(writeQuery); if (currentObjectsInDB == null) { currentObjectsInDB = getContainerPolicy().containerInstance(1); } compareObjectsAndWrite(currentObjectsInDB, objects, writeQuery); } /** * INTERNAL: * Delete privately owned parts */ public void preDelete(WriteObjectQuery query) throws DatabaseException, OptimisticLockException { if (isReadOnly()) { return; } // if privately owned parts have their privately own parts, delete those one by one // else delete everything in one shot. if (getReferenceDescriptor().hasDependencyOnParts() || getReferenceDescriptor().usesOptimisticLocking() || (getReferenceDescriptor().hasInheritance() && getReferenceDescriptor().getInheritancePolicy().shouldReadSubclasses()) || getReferenceDescriptor().hasMultipleTables()) { Object objects = getRealCollectionAttributeValueFromObject(query.getObject(), query.getSession()); ContainerPolicy containerPolicy = getContainerPolicy(); for (Object iter = containerPolicy.iteratorFor(objects); containerPolicy.hasNext(iter);) { Object object = containerPolicy.next(iter, query.getSession()); DeleteObjectQuery deleteQuery = new DeleteObjectQuery(); prepareModifyQueryForDelete(query, deleteQuery, object); query.getSession().executeQuery(deleteQuery, deleteQuery.getTranslationRow()); } if (!query.getSession().isUnitOfWork()) { // This deletes any objects on the database, as the collection in memory may has been changed. // This is not required for unit of work, as the update would have already deleted these objects, // and the backup copy will include the same objects causing double deletes. verifyDeleteForUpdate(query); } } else { deleteAll(query); } } /** * INTERNAL: * The message is passed to its reference class descriptor. */ public void preInsert(WriteObjectQuery query) throws DatabaseException, OptimisticLockException { if (isReadOnly()) { return; } Object objects = getRealCollectionAttributeValueFromObject(query.getObject(), query.getSession()); // pre-insert each object one by one ContainerPolicy cp = getContainerPolicy(); for (Object iter = cp.iteratorFor(objects); cp.hasNext(iter);) { Object object = cp.next(iter, query.getSession()); InsertObjectQuery insertQuery = getAndPrepareModifyQueryForInsert(query, object); // aggregates do not actually use a query to write to the database so the pre-write must be called here executeEvent(DescriptorEventManager.PreWriteEvent, insertQuery); executeEvent(DescriptorEventManager.PreInsertEvent, insertQuery); getReferenceDescriptor().getQueryManager().preInsert(insertQuery); } } /** * INTERNAL: * Returns clone of InsertObjectQuery from the reference descriptor, if it is not set - create it. */ protected InsertObjectQuery getInsertObjectQuery(AbstractSession session, ClassDescriptor desc) { InsertObjectQuery insertQuery = desc.getQueryManager().getInsertQuery(); if (insertQuery == null) { insertQuery = new InsertObjectQuery(); desc.getQueryManager().setInsertQuery(insertQuery); } if (insertQuery.getModifyRow() == null) { AbstractRecord modifyRow = new DatabaseRecord(); for (int i = 0; i < getTargetForeignKeyFields().size(); i++) { DatabaseField field = (DatabaseField)getTargetForeignKeyFields().elementAt(i); modifyRow.put(field, null); } desc.getObjectBuilder().buildTemplateInsertRow(session, modifyRow); insertQuery.setModifyRow(modifyRow); } return insertQuery; } /** * INTERNAL: * setup the modifyQuery for post insert/update and pre delete */ public InsertObjectQuery getAndPrepareModifyQueryForInsert(ObjectLevelModifyQuery originalQuery, Object object) { AbstractSession session = originalQuery.getSession(); ClassDescriptor objReferenceDescriptor = getReferenceDescriptor(object.getClass(), session); InsertObjectQuery insertQueryFromDescriptor = getInsertObjectQuery(session, objReferenceDescriptor); insertQueryFromDescriptor.checkPrepare(session, insertQueryFromDescriptor.getModifyRow()); InsertObjectQuery insertQuery = (InsertObjectQuery)insertQueryFromDescriptor.clone(); insertQuery.setObject(object); AbstractRecord targetForeignKeyRow = new DatabaseRecord(); Vector referenceObjectKeys = getReferenceObjectKeys(originalQuery); for (int keyIndex = 0; keyIndex < getTargetForeignKeyFields().size(); keyIndex++) { targetForeignKeyRow.put(getTargetForeignKeyFields().elementAt(keyIndex), referenceObjectKeys.elementAt(keyIndex)); } insertQuery.setModifyRow(targetForeignKeyRow); insertQuery.setTranslationRow(targetForeignKeyRow); insertQuery.setSession(session); insertQuery.setCascadePolicy(originalQuery.getCascadePolicy()); insertQuery.dontMaintainCache(); // For bug 2863721 must set a backup clone for compatibility with // old event mechanism, even though for AggregateCollections there is no // way to get a backup directly from a clone. if (session.isUnitOfWork()) { Object backupAttributeValue = getReferenceDescriptor(object.getClass(), session).getObjectBuilder().buildNewInstance(); insertQuery.setBackupClone(backupAttributeValue); } return insertQuery; } /** * INTERNAL: * setup the modifyQuery for pre delete */ public void prepareModifyQueryForDelete(ObjectLevelModifyQuery originalQuery, ObjectLevelModifyQuery modifyQuery, Object object) { AbstractRecord aggregateRow = getAggregateRow(originalQuery, object); modifyQuery.setObject(object); modifyQuery.setPrimaryKey(getReferenceDescriptor().getObjectBuilder().extractPrimaryKeyFromRow(aggregateRow, originalQuery.getSession())); modifyQuery.setModifyRow(aggregateRow); modifyQuery.setTranslationRow(aggregateRow); modifyQuery.setSession(originalQuery.getSession()); if (originalQuery.shouldCascadeOnlyDependentParts()) { //This query is the result of being in a UnitOfWork therefor use the Aggregate Collection //specific cascade policy to prevent cascading the delete now modifyQuery.setCascadePolicy(DatabaseQuery.CascadeAggregateDelete); } else { modifyQuery.setCascadePolicy(originalQuery.getCascadePolicy()); } modifyQuery.dontMaintainCache(); } /** * INTERNAL: * setup the modifyQuery for update, */ public void prepareModifyQueryForUpdate(ObjectLevelModifyQuery originalQuery, ObjectLevelModifyQuery modifyQuery, Object object) { AbstractRecord aggregateRow = getAggregateRow(originalQuery, object); modifyQuery.setObject(object); modifyQuery.setPrimaryKey(getReferenceDescriptor().getObjectBuilder().extractPrimaryKeyFromRow(aggregateRow, originalQuery.getSession())); modifyQuery.setTranslationRow(aggregateRow); modifyQuery.setSession(originalQuery.getSession()); modifyQuery.setCascadePolicy(originalQuery.getCascadePolicy()); modifyQuery.dontMaintainCache(); } /** * PUBLIC: * Set the source key field names associated with the mapping. * These must be in-order with the targetForeignKeyFieldNames. */ public void setSourceKeyFieldNames(Vector fieldNames) { Vector fields = oracle.toplink.essentials.internal.helper.NonSynchronizedVector.newInstance(fieldNames.size()); for (Enumeration fieldNamesEnum = fieldNames.elements(); fieldNamesEnum.hasMoreElements();) { fields.addElement(new DatabaseField((String)fieldNamesEnum.nextElement())); } setSourceKeyFields(fields); } /** * INTERNAL: * set all the primary key names associated with this mapping */ public void setSourceKeyFields(Vector sourceKeyFields) { this.sourceKeyFields = sourceKeyFields; } /** * PUBLIC: * Set the target foregin key field names associated with the mapping. * These must be in-order with the sourceKeyFieldNames. */ public void setTargetForeignKeyFieldNames(Vector fieldNames) { Vector fields = oracle.toplink.essentials.internal.helper.NonSynchronizedVector.newInstance(fieldNames.size()); for (Enumeration fieldNamesEnum = fieldNames.elements(); fieldNamesEnum.hasMoreElements();) { fields.addElement(new DatabaseField((String)fieldNamesEnum.nextElement())); } setTargetForeignKeyFields(fields); } /** * INTERNAL: * set the target foregin key fields associated with the mapping */ public void setTargetForeignKeyFields(Vector targetForeignKeyFields) { this.targetForeignKeyFields = targetForeignKeyFields; } protected void setTargetForeignKeyToSourceKeys(Map targetForeignKeyToSourceKeys) { this.targetForeignKeyToSourceKeys = targetForeignKeyToSourceKeys; } /** * Returns true as any process leading to object modification should also affect its privately owned parts * Usually used by write, insert, update and delete. */ protected boolean shouldObjectModifyCascadeToParts(ObjectLevelModifyQuery query) { if (isReadOnly()) { return false; } return true; } /** * ADVANCED: * This method is used to have an object add to a collection once the changeSet is applied * The referenceKey parameter should only be used for direct Maps. PLEASE ENSURE that the changes * have been made in the object model first. */ public void simpleAddToCollectionChangeRecord(Object referenceKey, Object changeSetToAdd, ObjectChangeSet changeSet, AbstractSession session) { AggregateCollectionChangeRecord collectionChangeRecord = (AggregateCollectionChangeRecord)changeSet.getChangesForAttributeNamed(this.getAttributeName()); if (collectionChangeRecord == null) { //if there is no change for this attribute then create a changeSet for it. no need to modify the resulting // change record as it should be built from the clone which has the changes allready Object cloneObject = ((UnitOfWorkChangeSet)changeSet.getUOWChangeSet()).getUOWCloneForObjectChangeSet(changeSet); Object cloneCollection = this.getRealAttributeValueFromObject(cloneObject, session); collectionChangeRecord = (AggregateCollectionChangeRecord)convertToChangeRecord(cloneCollection, changeSet, session); changeSet.addChange(collectionChangeRecord); } else { collectionChangeRecord.getChangedValues().add(changeSetToAdd); } } /** * ADVANCED: * This method is used to have an object removed from a collection once the changeSet is applied * The referenceKey parameter should only be used for direct Maps. PLEASE ENSURE that the changes * have been made in the object model first. */ public void simpleRemoveFromCollectionChangeRecord(Object referenceKey, Object changeSetToRemove, ObjectChangeSet changeSet, AbstractSession session) { AggregateCollectionChangeRecord collectionChangeRecord = (AggregateCollectionChangeRecord)changeSet.getChangesForAttributeNamed(this.getAttributeName()); if (collectionChangeRecord == null) { //if there is no change for this attribute then create a changeSet for it. no need to modify the resulting // change record as it should be built from the clone which has the changes allready Object cloneObject = ((UnitOfWorkChangeSet)changeSet.getUOWChangeSet()).getUOWCloneForObjectChangeSet(changeSet); Object cloneCollection = this.getRealAttributeValueFromObject(cloneObject, session); collectionChangeRecord = (AggregateCollectionChangeRecord)convertToChangeRecord(cloneCollection, changeSet, session); changeSet.addChange(collectionChangeRecord); } else { collectionChangeRecord.getChangedValues().remove(changeSetToRemove); } } /** * INTERNAL: * Retrieves a value from the row for a particular query key */ protected Object valueFromRowInternal(AbstractRecord row, JoinedAttributeManager joinManager, AbstractSession executionSession) throws DatabaseException { // For CR#2587: a fix to allow the reading of nested aggregate collections that // use foreign keys as primary keys. // Even though foreign keys are not read in a read query insert them into the row that // is returned from the database to allow cascading of primary keys. // This row will eventually become the translation row which is used to read the aggregate collection. // The fix works by passing foreign key information between source and target queries via the translation row. // Must clone the row first, for due to prior optimizations the vector of fields is now part of // a prepared query! row = (AbstractRecord)row.clone(); int i = 0; for (Enumeration sourceKeys = getSourceKeyFields().elements(); sourceKeys.hasMoreElements(); i++) { DatabaseField sourceKey = (DatabaseField)sourceKeys.nextElement(); Object value = null; // First insure that the source foreign key field is in the row. // N.B. If get() is used and returns null it may just mean that the field exists but the value is null. int index = row.getFields().indexOf(sourceKey); if (index == -1) { //Line x: Retrieve the value from the source query's translation row. value = joinManager.getBaseQuery().getTranslationRow().get(sourceKey); row.add(sourceKey, value); } else { value = row.getValues().elementAt(index); } //Now duplicate the source key field values with target key fields, so children aggregate collections can later access them. //This will enable the later execution of the above line x. row.add((DatabaseField)getTargetForeignKeyFields().elementAt(i), value); } return super.valueFromRowInternal(row, joinManager, executionSession); } /** * INTERNAL: * Checks if object is deleted from the database or not. */ public boolean verifyDelete(Object object, AbstractSession session) throws DatabaseException { // Row is built for translation if (isReadOnly()) { return true; } AbstractRecord row = getDescriptor().getObjectBuilder().buildRowForTranslation(object, session); Object value = session.executeQuery(getSelectionQuery(), row); return getContainerPolicy().isEmpty(value); } /** * Verifying deletes make sure that all the records privately owned by this mapping are * actually removed. If such records are found than those are all read and removed one * by one taking their privately owned parts into account. */ protected void verifyDeleteForUpdate(WriteObjectQuery query) throws DatabaseException, OptimisticLockException { Object objects = readPrivateOwnedForObject(query); // Delete all these object one by one. ContainerPolicy cp = getContainerPolicy(); for (Object iter = cp.iteratorFor(objects); cp.hasNext(iter);) { query.getSession().deleteObject(cp.next(iter, query.getSession())); } } /** * INTERNAL: * Add a new value and its change set to the collection change record. This is used by * attribute change tracking. Currently it is not supported in AggregateCollectionMapping. */ public void addToCollectionChangeRecord(Object newKey, Object newValue, ObjectChangeSet objectChangeSet, UnitOfWorkImpl uow) throws DescriptorException { throw DescriptorException.invalidMappingOperation(this, "addToCollectionChangeRecord"); } /** * INTERNAL * Return true if this mapping supports cascaded version optimistic locking. */ public boolean isCascadedLockingSupported() { return true; } /** * INTERNAL: * Return if this mapping supports change tracking. */ public boolean isChangeTrackingSupported() { return false; } /** * INTERNAL: * Remove a value and its change set from the collection change record. This is used by * attribute change tracking. Currently it is not supported in AggregateCollectionMapping. */ public void removeFromCollectionChangeRecord(Object newKey, Object newValue, ObjectChangeSet objectChangeSet, UnitOfWorkImpl uow) throws DescriptorException { throw DescriptorException.invalidMappingOperation(this, "removeFromCollectionChangeRecord"); } }





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