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/*
 * Copyright (c) 1998, 2019 Oracle and/or its affiliates. All rights reserved.
 * Copyright (c) 2019 IBM Corporation. All rights reserved.
 *
 * This program and the accompanying materials are made available under the
 * terms of the Eclipse Public License v. 2.0 which is available at
 * http://www.eclipse.org/legal/epl-2.0,
 * or the Eclipse Distribution License v. 1.0 which is available at
 * http://www.eclipse.org/org/documents/edl-v10.php.
 *
 * SPDX-License-Identifier: EPL-2.0 OR BSD-3-Clause
 */

// Contributors:
//     Oracle - initial API and implementation from Oracle TopLink
//     07/19/2011-2.2.1 Guy Pelletier
//       - 338812: ManyToMany mapping in aggregate object violate integrity constraint on deletion
//     04/09/2012-2.4 Guy Pelletier
//       - 374377: OrderBy with ElementCollection doesn't work
//     14/05/2012-2.4 Guy Pelletier
//       - 376603: Provide for table per tenant support for multitenant applications
//     30/05/2012-2.4 Guy Pelletier
//       - 354678: Temp classloader is still being used during metadata processing
//     08/01/2012-2.5 Chris Delahunt
//       - 371950: Metadata caching
//     06/03/2013-2.5.1 Guy Pelletier
//       - 402380: 3 jpa21/advanced tests failed on server with
//         "java.lang.NoClassDefFoundError: org/eclipse/persistence/testing/models/jpa21/advanced/enums/Gender"
package org.eclipse.persistence.mappings;

import java.beans.PropertyChangeEvent;
import java.security.AccessController;
import java.security.PrivilegedActionException;
import java.util.*;

import org.eclipse.persistence.annotations.BatchFetchType;
import org.eclipse.persistence.descriptors.ClassDescriptor;
import org.eclipse.persistence.descriptors.TablePerMultitenantPolicy;
import org.eclipse.persistence.descriptors.changetracking.*;
import org.eclipse.persistence.internal.descriptors.changetracking.AttributeChangeListener;
import org.eclipse.persistence.internal.descriptors.changetracking.ObjectChangeListener;
import org.eclipse.persistence.exceptions.*;
import org.eclipse.persistence.expressions.*;
import org.eclipse.persistence.history.*;
import org.eclipse.persistence.indirection.IndirectCollection;
import org.eclipse.persistence.indirection.IndirectList;
import org.eclipse.persistence.indirection.ValueHolder;
import org.eclipse.persistence.internal.databaseaccess.DatasourcePlatform;
import org.eclipse.persistence.internal.databaseaccess.Platform;
import org.eclipse.persistence.internal.descriptors.*;
import org.eclipse.persistence.internal.expressions.*;
import org.eclipse.persistence.internal.helper.*;
import org.eclipse.persistence.internal.identitymaps.*;
import org.eclipse.persistence.internal.queries.*;
import org.eclipse.persistence.internal.sessions.remote.*;
import org.eclipse.persistence.internal.security.PrivilegedAccessHelper;
import org.eclipse.persistence.internal.security.PrivilegedClassForName;
import org.eclipse.persistence.internal.security.PrivilegedNewInstanceFromClass;
import org.eclipse.persistence.internal.sessions.*;
import org.eclipse.persistence.mappings.converters.*;
import org.eclipse.persistence.queries.*;
import org.eclipse.persistence.sessions.remote.*;
import org.eclipse.persistence.sessions.CopyGroup;
import org.eclipse.persistence.sessions.DatabaseRecord;

/**
 * 

Purpose: This mapping is used to store a collection of simple types (String, Number, Date, etc.) * into a single table. The table must store the value and a foreign key to the source object. * A converter can be used if the desired object type and the data type do not match. * * @see Converter * @see ObjectTypeConverter * @see TypeConversionConverter * @see SerializedObjectConverter * * @author Sati * @since TOPLink/Java 1.0 * * 09/18/2009-2.0 Michael O'Brien * - 266912: JPA 2.0 Metamodel API (part of the JSR-317 EJB 3.1 Criteria API) * add support for passing BasicMap value type to MapAttributeImpl via new attributeClassification field */ public class DirectCollectionMapping extends CollectionMapping implements RelationalMapping { /** Used for data modification events. */ protected static final String Delete = "delete"; protected static final String Insert = "insert"; protected static final String DeleteAll = "deleteAll"; protected static final String DeleteAtIndex = "deleteAtIndex"; protected static final String UpdateAtIndex = "updateAtIndex"; /** Allows user defined conversion between the object value and the database value. */ protected Converter valueConverter; protected String valueConverterClassName; protected List orderByExpressions; /** Stores the reference table*/ protected DatabaseTable referenceTable; /** The direct field name is converted and stored */ protected DatabaseField directField; protected Vector sourceKeyFields; protected Vector referenceKeyFields; /** Used for insertion for m-m and dc, not used in 1-m. */ protected DataModifyQuery insertQuery; /** Used for deletion when ChangeSets are used */ protected ModifyQuery changeSetDeleteQuery; protected transient ModifyQuery changeSetDeleteNullQuery; // Bug 306075 protected boolean hasCustomDeleteQuery; protected boolean hasCustomInsertQuery; protected HistoryPolicy historyPolicy; /** Used (only in case listOrderField != null) to delete object with particular orderFieldValue */ protected ModifyQuery deleteAtIndexQuery; /** Used (only in case listOrderField != null) to update orderFieldValue of object with particular orderFieldValue */ protected ModifyQuery updateAtIndexQuery; protected boolean hasCustomDeleteAtIndexQuery; protected boolean hasCustomUpdateAtIndexQuery; /** * @since Java Persistence API 2.0 * Referenced by MapAttributeImpl to pick up the BasicMap value parameter type * To specify the conversion type * */ protected transient Class attributeClassification; protected String attributeClassificationName; /** * PUBLIC: * Default constructor. */ public DirectCollectionMapping() { this.insertQuery = new DataModifyQuery(); this.orderByExpressions = new ArrayList(); this.sourceKeyFields = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(1); this.referenceKeyFields = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(1); this.selectionQuery = new DirectReadQuery(); this.hasCustomInsertQuery = false; this.isPrivateOwned = true; this.isListOrderFieldSupported = true; } /** * PUBLIC: * Provide ascending order support for this direct collection mapping. */ public void addAscendingOrdering() { this.hasOrderBy = true; orderByExpressions.add(new ExpressionBuilder().getField(getDirectFieldName()).ascending()); } /** * PUBLIC: * Provide descending order support for this direct collection mapping. */ public void addDescendingOrdering() { this.hasOrderBy = true; orderByExpressions.add(new ExpressionBuilder().getField(getDirectFieldName()).descending()); } /** * ADVANCED: * Used this method to add custom ordering expressions when fetching * the collection. This could be things like expressions using a functions * like UPPER or NULLS LAST etc. */ public void addOrdering(Expression expression) { this.orderByExpressions.add(expression); } @Override public boolean isRelationalMapping() { return true; } /** * PUBLIC: * Return the converter on the mapping. * A converter can be used to convert between the direct collection's object value and database value. */ public Converter getValueConverter() { return valueConverter; } /** * PUBLIC: * Set the converter on the mapping. * A converter can be used to convert between the direct collection's object value and database value. */ public void setValueConverter(Converter valueConverter) { this.valueConverter = valueConverter; } /** * PUBLIC: * Set the converter class name on the mapping. Initialized in * convertClassNamesToClasses. * A converter can be used to convert between the direct collection's object value and database value. */ public void setValueConverterClassName(String valueConverterClassName) { this.valueConverterClassName = valueConverterClassName; } /** * PUBLIC: * Add the reference key field. * This is used for composite reference keys. * This is the foreign key field in the direct table referencing the primary key of the source object. * Both the reference field and the source field that it references must be provided. */ public void addReferenceKeyField(DatabaseField referenceForeignKeyField, DatabaseField sourcePrimaryKeyField) { getSourceKeyFields().addElement(sourcePrimaryKeyField); getReferenceKeyFields().addElement(referenceForeignKeyField); } /** * PUBLIC: * Add the name of the reference key field. * This is used for composite reference keys. * This is the foreign key field in the direct table referencing the primary key of the source object. * Both the reference field name and the name of the source field that it references must be provided. */ public void addReferenceKeyFieldName(String referenceForeignKeyFieldName, String sourcePrimaryKeyFieldName) { addReferenceKeyField(new DatabaseField(referenceForeignKeyFieldName), new DatabaseField(sourcePrimaryKeyFieldName)); } /** * INTERNAL: * Clone and prepare the selection query as a nested batch read query. * This is used for nested batch reading. */ @Override public ReadQuery prepareNestedBatchQuery(ObjectLevelReadQuery query) { // For CR#2646-S.M. In case of inheritance the descriptor to use may not be that // of the source query (the base class descriptor), but that of the subclass, if the // attribute is only of the subclass. Thus in this case use the descriptor from the mapping. // Also: for Bug 5478648 - Do not switch the descriptor if the query's descriptor is an aggregate ClassDescriptor descriptorToUse = query.getDescriptor(); if ((descriptorToUse != this.descriptor) && (!descriptorToUse.getMappings().contains(this)) && (!this.descriptor.isDescriptorTypeAggregate())) { descriptorToUse = this.descriptor; } DataReadQuery batchQuery = new DataReadQuery(); batchQuery.setName(getAttributeName()); // Join the query where clause with the mappings, // this will cause a join that should bring in all of the target objects. ExpressionBuilder builder; Expression originalSelectionCriteria = null; // 2612538 - the default size of Map (32) is appropriate Map clonedExpressions = new IdentityHashMap(); builder = new ExpressionBuilder(); // For flashback. if (query.hasAsOfClause()) { builder.asOf(query.getAsOfClause()); } Expression batchSelectionCriteria = null; // Build the batch query, either using joining, or an exist sub-select. BatchFetchType batchType = query.getBatchFetchPolicy().getType(); if (this.batchFetchType != null) { batchType = this.batchFetchType; } if (batchType == BatchFetchType.EXISTS) { // Using a EXISTS sub-select (WHERE EXIST ( AND AND ) ExpressionBuilder subBuilder = new ExpressionBuilder(descriptorToUse.getJavaClass()); subBuilder.setQueryClassAndDescriptor(descriptorToUse.getJavaClass(), descriptorToUse); ReportQuery subQuery = new ReportQuery(descriptorToUse.getJavaClass(), subBuilder); subQuery.setDescriptor(descriptorToUse); subQuery.setShouldRetrieveFirstPrimaryKey(true); Expression subCriteria = subBuilder.twist(getSelectionCriteria(), builder); if (query.getSelectionCriteria() != null) { // For bug 2612567, any query can have batch attributes, so the // original selection criteria can be quite complex, with multiple // builders (i.e. for parallel selects). // Now uses cloneUsing(newBase) instead of rebuildOn(newBase). subCriteria = query.getSelectionCriteria().cloneUsing(subBuilder).and(subCriteria); } subQuery.setSelectionCriteria(subCriteria); batchSelectionCriteria = builder.exists(subQuery); } else if (batchType == BatchFetchType.IN) { // Using a IN with foreign key values (WHERE FK IN :QUERY_BATCH_PARAMETER) batchSelectionCriteria = buildBatchCriteria(builder, query); } else { // For 2729729 must clone the original selection criteria first, // otherwise the original query will be corrupted. if (query.getSelectionCriteria() != null) { originalSelectionCriteria = query.getSelectionCriteria().copiedVersionFrom(clonedExpressions); builder = originalSelectionCriteria.getBuilder(); } // Using a join, (WHERE AND ) if (this.selectionQuery.isReadAllQuery()) { batchSelectionCriteria = builder.twist(this.selectionQuery.getSelectionCriteria(), builder); } else { batchSelectionCriteria = builder.twist(this.selectionQuery.getSQLStatement().getWhereClause(), builder); } // For 2729729, rebuildOn is not needed as the base is still the same. if (originalSelectionCriteria != null) { batchSelectionCriteria = batchSelectionCriteria.and(originalSelectionCriteria); } if (descriptorToUse.getQueryManager().getAdditionalJoinExpression() != null) { batchSelectionCriteria = batchSelectionCriteria.and(query.getDescriptor().getQueryManager().getAdditionalJoinExpression().rebuildOn(builder)); } if (this.historyPolicy != null) { if (query.getSession().getAsOfClause() != null) { builder.asOf(query.getSession().getAsOfClause()); } else if (builder.getAsOfClause() == null) { builder.asOf(AsOfClause.NO_CLAUSE); } batchSelectionCriteria = batchSelectionCriteria.and(this.historyPolicy.additionalHistoryExpression(builder, builder)); } } SQLSelectStatement batchStatement = new SQLSelectStatement(); for (DatabaseField keyField : getReferenceKeyFields()) { batchStatement.addField(builder.getTable(this.referenceTable).getField(keyField)); } batchStatement.addField(builder.getTable(this.referenceTable).getField(this.directField)); batchStatement.setWhereClause(batchSelectionCriteria); batchQuery.setSQLStatement(batchStatement); this.containerPolicy.addAdditionalFieldsToQuery(batchQuery, getAdditionalFieldsBaseExpression(batchQuery)); batchStatement.normalize(query.getSession(), descriptorToUse, clonedExpressions); return batchQuery; } /** * INTERNAL: * Clone and prepare the joined direct query. * Since direct-collection does not build objects a nest query is not required. */ @Override public ObjectLevelReadQuery prepareNestedJoins(JoinedAttributeManager joinManager, ObjectBuildingQuery baseQuery, AbstractSession session) { return null; } /** * INTERNAL: * Return the value of the field from the row or a value holder on the query to obtain the object. */ @Override protected Object valueFromRowInternalWithJoin(AbstractRecord row, JoinedAttributeManager joinManager, ObjectBuildingQuery sourceQuery, CacheKey parentCacheKey, AbstractSession executionSession, boolean isTargetProtected) throws DatabaseException { ContainerPolicy policy = getContainerPolicy(); Object value = policy.containerInstance(); ObjectBuilder objectBuilder = this.descriptor.getObjectBuilder(); // Extract the primary key of the source object, to filter only the joined rows for that object. Object sourceKey = objectBuilder.extractPrimaryKeyFromRow(row, executionSession); // If the query was using joining, all of the result rows by primary key will have been computed. List rows = joinManager.getDataResultsByPrimaryKey().get(sourceKey); // If no 1-m rows were fetch joined, then get the value normally, // this can occur with pagination where the last row may not be complete. if (rows == null) { return valueFromRowInternal(row, joinManager, sourceQuery, executionSession); } int size = rows.size(); if(size > 0) { // A set of direct values must be maintained to avoid duplicates from multiple 1-m joins. Set directValues = new HashSet(); ArrayList directValuesList = null; ArrayList targetRows = null; boolean shouldAddAll = policy.shouldAddAll(); if(shouldAddAll) { directValuesList = new ArrayList(size); targetRows = new ArrayList(size); } Converter valueConverter = getValueConverter(); // indicates if collection contains null boolean containsNull = false; // For each rows, extract the target row and build the target object and add to the collection. for (int index = 0; index < size; index++) { AbstractRecord sourceRow = rows.get(index); AbstractRecord targetRow = sourceRow; // The field for many objects may be in the row, // so build the subpartion of the row through the computed values in the query, // this also helps the field indexing match. targetRow = trimRowForJoin(targetRow, joinManager, executionSession); // Partial object queries must select the primary key of the source and related objects. // If the target joined rows in null (outerjoin) means an empty collection. Object directValue = targetRow.get(this.directField); if (directValue == null) { if (size == 1) { // A null direct value means an empty collection returned as nulls from an outerjoin. return getIndirectionPolicy().valueFromRow(value); } else { containsNull = true; } } // Only build/add the target object once, skip duplicates from multiple 1-m joins. if (!directValues.contains(directValue)) { directValues.add(directValue); // Allow for value conversion. if (valueConverter != null) { directValue = valueConverter.convertDataValueToObjectValue(directValue, executionSession); } if (shouldAddAll) { directValuesList.add(directValue); targetRows.add(targetRow); } else { policy.addInto(directValue, value, executionSession, targetRow, sourceQuery, parentCacheKey, isTargetProtected); } } } if (shouldAddAll) { // if collection contains a single element which is null then return an empty collection if (!(containsNull && targetRows.size() == 1)) { policy.addAll(directValuesList, value, executionSession, targetRows, sourceQuery, parentCacheKey, isTargetProtected); } } else { // if collection contains a single element which is null then return an empty collection if (containsNull && policy.sizeFor(value) == 1) { policy.clear(value); } } } return getIndirectionPolicy().valueFromRow(value); } /** * INTERNAL: * Copy of the attribute of the object. * This is NOT used for unit of work but for templatizing an object. */ @Override public void buildCopy(Object copy, Object original, CopyGroup group) { Object attributeValue = getRealCollectionAttributeValueFromObject(original, group.getSession()); attributeValue = getContainerPolicy().cloneFor(attributeValue); // if value holder is used, then the value holder shared with original substituted for a new ValueHolder. getIndirectionPolicy().reset(copy); setRealAttributeValueInObject(copy, attributeValue); } /** * INTERNAL: * Clone the element, if necessary. * DirectCollections hold on to objects that do not have Descriptors * (e.g. int, String). These objects do not need to be cloned, unless they use a converter - they * are immutable. */ @Override public Object buildElementClone(Object element, Object parent, CacheKey parentCacheKey, Integer refreshCascade, AbstractSession cloningSession, boolean isExisting, boolean isFromSharedCache) { Object cloneValue = element; if ((getValueConverter() != null) && getValueConverter().isMutable()) { cloneValue = getValueConverter().convertDataValueToObjectValue(getValueConverter().convertObjectValueToDataValue(cloneValue, cloningSession), cloningSession); } return cloneValue; } /** * INTERNAL: * In case Query By Example is used, this method builds and returns an expression that * corresponds to a single attribute and it's value. */ public Expression buildExpression(Object queryObject, QueryByExamplePolicy policy, Expression expressionBuilder, Map processedObjects, AbstractSession session) { if (policy.shouldValidateExample()){ throw QueryException.unsupportedMappingQueryByExample(queryObject.getClass().getName(), this); } return null; } /** * INTERNAL: * Verifies listOrderField's table: it must be reference table. * Precondition: listOrderField != null. */ @Override protected void buildListOrderField() { if(this.listOrderField.hasTableName()) { if(!getReferenceTable().equals(this.listOrderField.getTable())) { throw DescriptorException.listOrderFieldTableIsWrong(this.getDescriptor(), this, this.listOrderField.getTable(), getReferenceTable()); } } else { this.listOrderField.setTable(getReferenceTable()); } this.listOrderField = getDescriptor().buildField(this.listOrderField, getReferenceTable()); } /** * INTERNAL: * Cascade perform delete through mappings that require the cascade */ @Override public void cascadePerformRemoveIfRequired(Object object, UnitOfWorkImpl uow, Map visitedObjects) { //as this mapping type references primitive objects this method does not apply } /** * INTERNAL: * Cascade perform removal of orphaned private owned objects from the UnitOfWorkChangeSet */ @Override public void cascadePerformRemovePrivateOwnedObjectFromChangeSetIfRequired(Object object, UnitOfWorkImpl uow, Map visitedObjects) { // as this mapping type references primitive objects this method does not apply } /** * INTERNAL: * Cascade registerNew for Create through mappings that require the cascade */ @Override public void cascadeRegisterNewIfRequired(Object object, UnitOfWorkImpl uow, Map visitedObjects) { //as this mapping type references primitive objects this method does not apply } /** * INTERNAL: * Cascade discover and persist new objects during commit. */ @Override public void cascadeDiscoverAndPersistUnregisteredNewObjects(Object object, Map newObjects, Map unregisteredExistingObjects, Map visitedObjects, UnitOfWorkImpl uow, Set cascadeErrors) { // Direct mappings do not require any cascading. } /** * INTERNAL: * The mapping clones itself to create deep copy. */ @Override public Object clone() { DirectCollectionMapping clone = (DirectCollectionMapping)super.clone(); clone.setSourceKeyFields(cloneFields(getSourceKeyFields())); clone.setReferenceKeyFields(cloneFields(getReferenceKeyFields())); if(this.changeSetDeleteQuery != null) { clone.changeSetDeleteQuery = (ModifyQuery)this.changeSetDeleteQuery.clone(); } // Bug 306075 if(this.changeSetDeleteNullQuery != null) { clone.changeSetDeleteNullQuery = (ModifyQuery)this.changeSetDeleteNullQuery.clone(); } if(this.deleteAtIndexQuery != null) { clone.deleteAtIndexQuery = (ModifyQuery)this.deleteAtIndexQuery.clone(); } if(this.updateAtIndexQuery != null) { clone.updateAtIndexQuery = (ModifyQuery)this.updateAtIndexQuery.clone(); } return clone; } /** * INTERNAL: * This method is used to calculate the differences between two collections. */ @Override public void compareCollectionsForChange(Object oldCollection, Object newCollection, ChangeRecord changeRecord, AbstractSession session) { if(this.listOrderField != null) { compareListsForChange((List)oldCollection, (List)newCollection, changeRecord, session); return; } ContainerPolicy cp = getContainerPolicy(); int numberOfNewNulls = 0; HashMap originalKeyValues = new HashMap(10); HashMap cloneKeyValues = new HashMap(10); if (oldCollection != null) { Object backUpIter = cp.iteratorFor(oldCollection); while (cp.hasNext(backUpIter)) {// Make a lookup of the objects Object secondObject = cp.next(backUpIter, session); // For CR#2258/CR#2378 handle null values inserted in a collection. if (secondObject == null) { numberOfNewNulls--; } else { Integer count = (Integer)originalKeyValues.get(secondObject); if (count == null) { originalKeyValues.put(secondObject, Integer.valueOf(1)); } else { originalKeyValues.put(secondObject, Integer.valueOf(count.intValue() + 1)); } } } } // should a removal occur this is the original count of objects on the database. // this value is used to determine how many objects to re-insert after the delete as a // delete will delete all of the objects not just one. HashMap databaseCount = (HashMap)originalKeyValues.clone(); int databaseNullCount = Math.abs(numberOfNewNulls); if (newCollection != null) { Object cloneIter = cp.iteratorFor(newCollection); /* The following code is used to compare objects in a direct collection. Because objects in a direct collection are primitives and may be the same object the following code must count the number of instances in the collection not just the existence of an object. */ while (cp.hasNext(cloneIter)) {//Compare them with the objects from the clone Object firstObject = cp.next(cloneIter, session); // For CR#2258/CR#2378 handle null values inserted in a collection. if (firstObject == null) { numberOfNewNulls++; } else { Integer count = (Integer)originalKeyValues.get(firstObject); if (count == null) {//the object was not in the backup Integer cloneCount = (Integer)cloneKeyValues.get(firstObject); //Add it to the additions hashtable if (cloneCount == null) { cloneKeyValues.put(firstObject, Integer.valueOf(1)); } else { cloneKeyValues.put(firstObject, Integer.valueOf(cloneCount.intValue() + 1)); } } else if (count.intValue() == 1) { //There is only one object so remove the whole reference originalKeyValues.remove(firstObject); } else { originalKeyValues.put(firstObject, Integer.valueOf(count.intValue() - 1)); } } } } if (cloneKeyValues.isEmpty() && originalKeyValues.isEmpty() && (numberOfNewNulls == 0) && (!changeRecord.getOwner().isNew())) { return; } ((DirectCollectionChangeRecord)changeRecord).clearChanges(); ((DirectCollectionChangeRecord)changeRecord).addAdditionChange(cloneKeyValues, databaseCount); ((DirectCollectionChangeRecord)changeRecord).addRemoveChange(originalKeyValues, databaseCount); ((DirectCollectionChangeRecord)changeRecord).setIsDeferred(false); ((DirectCollectionChangeRecord)changeRecord).setLatestCollection(null); //For CR#2258, produce a changeRecord which reflects the addition and removal of null values. if (numberOfNewNulls != 0) { ((DirectCollectionChangeRecord)changeRecord).getCommitAddMap().put(null, Integer.valueOf(databaseNullCount)); if (numberOfNewNulls > 0) { ((DirectCollectionChangeRecord)changeRecord).addAdditionChange(null, Integer.valueOf(numberOfNewNulls)); } else { numberOfNewNulls *= -1; ((DirectCollectionChangeRecord)changeRecord).addRemoveChange(null, Integer.valueOf(numberOfNewNulls)); } } } /** * INTERNAL: * This method is used to calculate the differences between two Lists. */ public void compareListsForChange(List oldList, List newList, ChangeRecord changeRecord, AbstractSession session) { // Maps objects (null included) in newList and oldList to an array of two Sets: // the first one contains indexes of the object in oldList, the second - in newList. // Contains only the objects for which the set of indexes in newList and oldList are different; // only changed indexes appear in the sets (therefore the old index set and new index set don't intersect). // Examples: // obj was first (index 0) in oldList; first and second (indexes 0 and 1)in newList: obj -> {{}, {1}}; // obj was not in oldList; first in newList: obj -> {null, {0}}; // obj was first in oldList; not in newList: obj -> {{0}, null}; // obj was first and second in oldList; first in newList: obj -> {{1}, {}}; // Note the difference between null and empty set: // empty set means there's at least one index (the same in oldList and newList - otherwise it would've been in the set); // null means there's no indexes. // That helps during deletion - if we know there is no remaining duplicates for the object to be removed // we can delete it without checking its index (which allows delete several duplicates in one sql). // Map entry sets with no new and no old indexes removed. int nOldSize = oldList == null ? 0 : oldList.size(); int nNewSize = newList == null ? 0 : newList.size(); HashMap changedIndexes = new HashMap<>(Math.max(nOldSize, nNewSize)); // for each object in oldList insert all its indexes in oldList into the old indexes set corresponding to each object. if (oldList != null) { for(int i=0; i < nOldSize; i++) { Object obj = oldList.get(i); Set[] indexes = changedIndexes.get(obj); if (indexes == null) { // the first index found for the object. indexes = new Set[]{new HashSet(), null}; changedIndexes.put(obj, indexes); } indexes[0].add(i); } } // helper set to store objects for which entries into changedIndexes has been removed: // if an entry for the object is created again, it will have an empty old indexes set (rather than null) // to indicate that the object has been on the oldList, too. HashSet removedFromChangedIndexes = new HashSet(); HashSet dummySet = new HashSet(0); // for each object in newList, for each its index in newList: // if the object has the same index in oldList - remove the index from old indexes set; // if the object doesn't have the same index in oldList - insert the index into new indexes set. if (newList != null) { for(int i=0; i < nNewSize; i++) { Object obj = newList.get(i); Set[] indexes = changedIndexes.get(obj); if (indexes == null) { // the first index found for the object - or was found and removed before. if(removedFromChangedIndexes.contains(obj)) { // the object also exists in oldList indexes = new Set[]{dummySet, new HashSet()}; } else { // the object does not exist in oldList indexes = new Set[]{null, new HashSet()}; } changedIndexes.put(obj, indexes); // the object doesn't have this index in oldList - add the index to new indexes set. indexes[1].add(i); } else { if(indexes[0] == null || !indexes[0].contains(i)) { // the object doesn't have this index in oldList - add the index to new indexes set. if(indexes[1] == null) { indexes[1] = new HashSet(); } indexes[1].add(i); } else { // the object has this index in oldList - remove the index from the old indexes set. indexes[0].remove(i); if(indexes[0].isEmpty()) { // no old indexes left for the object. if(indexes[1] == null || indexes[1].isEmpty()) { // no new indexes left, too - remove the entry for the object. changedIndexes.remove(obj); // store the object in case it has another index on newList removedFromChangedIndexes.add(obj); } } } } } } ((DirectCollectionChangeRecord)changeRecord).setChangedIndexes(changedIndexes); ((DirectCollectionChangeRecord)changeRecord).setOldSize(nOldSize); ((DirectCollectionChangeRecord)changeRecord).setNewSize(nNewSize); } /** * INTERNAL: * This method compares the changes between two direct collections. Comparisons are made on equality * not identity. */ @Override public ChangeRecord compareForChange(Object clone, Object backUp, ObjectChangeSet owner, AbstractSession session) { Object cloneAttribute = getAttributeValueFromObject(clone); Object backUpAttribute = null; if ((cloneAttribute != null) && (!getIndirectionPolicy().objectIsInstantiated(cloneAttribute))) { return null; } Object cloneObjectCollection = getRealCollectionAttributeValueFromObject(clone, session); Object backUpCollection = null; if (!owner.isNew()) { backUpAttribute = getAttributeValueFromObject(backUp); if ((backUpAttribute == null) && (cloneAttribute == null)) { return null; } backUpCollection = getRealCollectionAttributeValueFromObject(backUp, session); } DirectCollectionChangeRecord changeRecord = new DirectCollectionChangeRecord(owner); changeRecord.setAttribute(getAttributeName()); changeRecord.setMapping(this); if(this.listOrderField != null) { changeRecord.setLatestCollection(cloneObjectCollection); } compareCollectionsForChange(backUpCollection, cloneObjectCollection, changeRecord, session); if (changeRecord.hasChanges()) { changeRecord.setOriginalCollection(backUpCollection); return changeRecord; } return null; } /** * INTERNAL: * Compare the attributes belonging to this mapping for the objects. */ @Override public boolean compareObjects(Object firstObject, Object secondObject, AbstractSession session) { Object firstCollection = getRealCollectionAttributeValueFromObject(firstObject, session); Object secondCollection = getRealCollectionAttributeValueFromObject(secondObject, session); if(this.listOrderField != null) { return compareLists((List)firstCollection, (List)secondCollection); } ContainerPolicy containerPolicy = getContainerPolicy(); if (containerPolicy.sizeFor(firstCollection) != containerPolicy.sizeFor(secondCollection)) { return false; } HashMap firstCounter = new HashMap(); HashMap secondCounter = new HashMap(); for (Object iter = containerPolicy.iteratorFor(firstCollection); containerPolicy.hasNext(iter);) { Object object = containerPolicy.next(iter, session); if (firstCounter.containsKey(object)) { int count = ((Integer)firstCounter.get(object)).intValue(); firstCounter.put(object, Integer.valueOf(++count)); } else { firstCounter.put(object, Integer.valueOf(1)); } } for (Object iter = containerPolicy.iteratorFor(secondCollection); containerPolicy.hasNext(iter);) { Object object = containerPolicy.next(iter, session); if (secondCounter.containsKey(object)) { int count = ((Integer)secondCounter.get(object)).intValue(); secondCounter.put(object, Integer.valueOf(++count)); } else { secondCounter.put(object, Integer.valueOf(1)); } } for (Iterator iterator = firstCounter.keySet().iterator(); iterator.hasNext();) { Object object = iterator.next(); if (!secondCounter.containsKey(object) || (((Integer)secondCounter.get(object)).intValue() != ((Integer)firstCounter.get(object)).intValue())) { // containsKey(object) will fail when the objects are arrays. boolean found = false; for (Iterator ii = secondCounter.keySet().iterator(); ii.hasNext();) { Object otherObject = ii.next(); if(object == otherObject) { found = true; } else if(object == null || otherObject == null) { found = false; } else { found = Helper.comparePotentialArrays(object, otherObject); } if (found) { iterator.remove(); secondCounter.remove(otherObject); break; } } if (!found) { return false; } } else { iterator.remove(); secondCounter.remove(object); } } if (!firstCounter.isEmpty() || !secondCounter.isEmpty()) { return false; } return true; } /** * Compare two lists. For equality the order of the elements should be the same. * Used only if listOrderField != null */ protected boolean compareLists(List firstList, List secondList) { if (firstList.size() != secondList.size()) { return false; } int size = firstList.size(); for(int i=0; i < size; i++) { Object firstObject = firstList.get(i); Object secondObject = secondList.get(i); if(firstObject != secondObject) { if(firstObject==null || secondObject==null) { return false; } else { if(!firstObject.equals(secondObject)) { return false; } } } } return true; } /** * INTERNAL: * Convert all the class-name-based settings in this mapping to actual class-based * settings * This method is implemented by subclasses as necessary. * @param classLoader */ @Override public void convertClassNamesToClasses(ClassLoader classLoader) { super.convertClassNamesToClasses(classLoader); // Tell the direct field to convert any class names (type name). directField.convertClassNamesToClasses(classLoader); // Convert and any Converter class names. convertConverterClassNamesToClasses(valueConverter, classLoader); // Instantiate any custom converter class if (valueConverterClassName != null) { Class valueConverterClass; Converter valueConverter; try { if (PrivilegedAccessHelper.shouldUsePrivilegedAccess()){ try { valueConverterClass = AccessController.doPrivileged(new PrivilegedClassForName(valueConverterClassName, true, classLoader)); } catch (PrivilegedActionException exception) { throw ValidationException.classNotFoundWhileConvertingClassNames(valueConverterClassName, exception.getException()); } try { valueConverter = (Converter) AccessController.doPrivileged(new PrivilegedNewInstanceFromClass(valueConverterClass)); } catch (PrivilegedActionException exception) { throw ValidationException.classNotFoundWhileConvertingClassNames(valueConverterClassName, exception.getException()); } } else { valueConverterClass = PrivilegedAccessHelper.getClassForName(valueConverterClassName, true, classLoader); valueConverter = (Converter) PrivilegedAccessHelper.newInstanceFromClass(valueConverterClass); } } catch (ClassNotFoundException exc) { throw ValidationException.classNotFoundWhileConvertingClassNames(valueConverterClassName, exc); } catch (Exception e) { // Catches IllegalAccessException and InstantiationException throw ValidationException.classNotFoundWhileConvertingClassNames(valueConverterClassName, e); } setValueConverter(valueConverter); } // Check if the attribute classification is set (either directly or through a type conversion converter) if (attributeClassification == null) { // Look for an attribute classification name if (attributeClassificationName != null) { try { if (PrivilegedAccessHelper.shouldUsePrivilegedAccess()){ try { attributeClassification = AccessController.doPrivileged(new PrivilegedClassForName(attributeClassificationName, true, classLoader)); } catch (PrivilegedActionException pae) { throw ValidationException.classNotFoundWhileConvertingClassNames(attributeClassificationName, pae.getException()); } } else { attributeClassification = PrivilegedAccessHelper.getClassForName(attributeClassificationName, true, classLoader); } } catch (Exception exception) { throw ValidationException.classNotFoundWhileConvertingClassNames(attributeClassificationName, exception); } } else { // Still nothing, default to the type from the direct field. attributeClassification = getDirectField().getType(); } } } /** * INTERNAL: * Extract the source primary key value from the reference direct row. * Used for batch reading, most following same order and fields as in the mapping. */ @Override protected Object extractKeyFromTargetRow(AbstractRecord row, AbstractSession session) { int size = this.referenceKeyFields.size(); Object[] key = new Object[size]; ConversionManager conversionManager = session.getDatasourcePlatform().getConversionManager(); for (int index = 0; index < size; index++) { DatabaseField relationField = this.referenceKeyFields.get(index); DatabaseField sourceField = this.sourceKeyFields.get(index); Object value = row.get(relationField); // Must ensure the classification gets a cache hit. try { value = conversionManager.convertObject(value, sourceField.getType()); } catch (ConversionException e) { throw ConversionException.couldNotBeConverted(this, getDescriptor(), e); } key[index] = value; } return new CacheId(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. */ @Override protected Object extractBatchKeyFromRow(AbstractRecord row, AbstractSession session) { int size = this.sourceKeyFields.size(); Object[] key = new Object[size]; ConversionManager conversionManager = session.getDatasourcePlatform().getConversionManager(); for (int index = 0; index < size; index++) { DatabaseField field = this.sourceKeyFields.get(index); Object value = row.get(field); // Must ensure the classification to get a cache hit. try { value = conversionManager.convertObject(value, field.getType()); } catch (ConversionException exception) { throw ConversionException.couldNotBeConverted(this, this.descriptor, exception); } key[index] = value; } return new CacheId(key); } /** * INTERNAL: * Return the selection criteria used to IN batch fetching. */ @Override protected Expression buildBatchCriteria(ExpressionBuilder builder, ObjectLevelReadQuery query) { int size = this.referenceKeyFields.size(); Expression table = builder.getTable(this.referenceTable); if (size > 1) { // Support composite keys using nested IN. List fields = new ArrayList(size); for (DatabaseField referenceKeyField : this.referenceKeyFields) { fields.add(table.getField(referenceKeyField)); } return query.getSession().getPlatform().buildBatchCriteriaForComplexId(builder, fields); } else { return query.getSession().getPlatform().buildBatchCriteria(builder, table.getField(this.referenceKeyFields.get(0))); } } /** * INTERNAL: * Prepare and execute the batch query and store the * results for each source object in a map keyed by the * mappings source keys of the source objects. */ @Override protected void executeBatchQuery(DatabaseQuery query, CacheKey parentCacheKey, Map referenceDataByKey, AbstractSession session, AbstractRecord translationRow) { // Execute query and index resulting object sets by key. List rows = (List)session.executeQuery(query, translationRow); int size = rows.size(); if (this.containerPolicy.shouldAddAll()) { if (size > 0) { Map referenceDataAndRowsByKey = new HashMap(); for (int index = 0; index < size; index++) { AbstractRecord referenceRow = rows.get(index); Object referenceValue = referenceRow.get(this.directField); Object eachReferenceKey = extractKeyFromTargetRow(referenceRow, session); // Allow for value conversion. if (this.valueConverter != null) { referenceValue = this.valueConverter.convertDataValueToObjectValue(referenceValue, query.getSession()); } List[] valuesAndRows = referenceDataAndRowsByKey.get(eachReferenceKey); if (valuesAndRows == null) { valuesAndRows = new List[]{new ArrayList(), new ArrayList()}; referenceDataAndRowsByKey.put(eachReferenceKey, valuesAndRows); } valuesAndRows[0].add(referenceValue); valuesAndRows[1].add(referenceRow); } Iterator> iterator = referenceDataAndRowsByKey.entrySet().iterator(); while (iterator.hasNext()) { Map.Entry entry = iterator.next(); Object eachReferenceKey = entry.getKey(); List referenceValues = entry.getValue()[0]; List referenceRows = entry.getValue()[1]; Object container = this.containerPolicy.containerInstance(referenceValues.size()); this.containerPolicy.addAll(referenceValues, container, query.getSession(), referenceRows, (DataReadQuery)query, parentCacheKey, true); referenceDataByKey.put(eachReferenceKey, container); } } } else { for (int index = 0; index < size; index++) { AbstractRecord referenceRow = rows.get(index); Object referenceValue = referenceRow.get(this.directField); Object eachReferenceKey = extractKeyFromTargetRow(referenceRow, session); Object container = referenceDataByKey.get(eachReferenceKey); if ((container == null) || (container == Helper.NULL_VALUE)) { container = this.containerPolicy.containerInstance(); referenceDataByKey.put(eachReferenceKey, container); } // Allow for value conversion. if (this.valueConverter != null) { referenceValue = this.valueConverter.convertDataValueToObjectValue(referenceValue, query.getSession()); } this.containerPolicy.addInto(referenceValue, container, query.getSession()); } } } /** * INTERNAL: * At this point, we realize we don't have indirection; * so we need to replace the reference object(s) with * the corresponding object(s) from the remote session. * * The reference objects for a DirectCollectionMapping * are primitives, so they do not need to be replaced. */ @Override public void fixRealObjectReferences(Object object, Map objectInformation, Map processedObjects, ObjectLevelReadQuery query, DistributedSession session) { // do nothing } /** * PUBLIC: * Some databases do not properly support all of the base data types. For these databases, * the base data type must be explicitly specified in the mapping to tell EclipseLink to force * the instance variable value to that data type. * @since Java Persistence API 2.0 */ public Class getAttributeClassification() { return attributeClassification; } /** * INTERNAL: * Return the class name of the attribute type. * This is only used by the MW. * @since Java Persistence API 2.0 */ public String getAttributeClassificationName() { if ((null == attributeClassificationName) && (attributeClassification != null)) { attributeClassificationName = attributeClassification.getName(); } return attributeClassificationName; } protected ModifyQuery getDeleteQuery() { if (changeSetDeleteQuery == null) { changeSetDeleteQuery = new DataModifyQuery(); } return changeSetDeleteQuery; } // Bug 306075 protected ModifyQuery getDeleteNullQuery() { if (changeSetDeleteNullQuery == null) { changeSetDeleteNullQuery = new DataModifyQuery(); } return changeSetDeleteNullQuery; } protected ModifyQuery getDeleteAtIndexQuery() { if (deleteAtIndexQuery == null) { deleteAtIndexQuery = new DataModifyQuery(); } return deleteAtIndexQuery; } protected ModifyQuery getUpdateAtIndexQuery() { if (updateAtIndexQuery == null) { updateAtIndexQuery = new DataModifyQuery(); } return updateAtIndexQuery; } /** * INTERNAL: * Returns the set of fields that should be selected to build this mapping's value(s). * This is used by expressions to determine which fields to include in the select clause for non-object expressions. */ @Override public Vector getSelectFields() { Vector fields = new NonSynchronizedVector(2); fields.add(getDirectField()); return fields; } /** * INTERNAL: * Returns the table(s) that should be selected to build this mapping's value(s). * This is used by expressions to determine which tables to include in the from clause for non-object expressions. */ @Override public Vector getSelectTables() { Vector tables = new NonSynchronizedVector(0); tables.add(getReferenceTable()); return tables; } /** * INTERNAL: * Return the direct field. * This is the field in the direct table to store the values. */ public DatabaseField getDirectField() { return directField; } /** * PUBLIC: * Returns the name of the field name in the reference table. */ public String getDirectFieldName() { if (getDirectField() == null) { return null; } return getDirectField().getQualifiedName(); } protected DataModifyQuery getInsertQuery() { return insertQuery; } /** * INTERNAL: * Returns the join criteria stored in the mapping selection query. This criteria * is used to read reference objects across the tables from the database. */ @Override public Expression getJoinCriteria(ObjectExpression context, Expression base) { if (getHistoryPolicy() != null) { Expression result = super.getJoinCriteria(context, base); Expression historyCriteria = getHistoryPolicy().additionalHistoryExpression(context, base); if (result != null) { return result.and(historyCriteria); } else if (historyCriteria != null) { return historyCriteria; } else { return null; } } else { return super.getJoinCriteria(context, base); } } /** * INTERNAL: * return the object on the client corresponding to the specified object. * DirectCollections do not have to worry about * maintaining object identity. */ @Override public Object getObjectCorrespondingTo(Object object, DistributedSession session, Map objectDescriptors, Map processedObjects, ObjectLevelReadQuery query) { return object; } /** * PUBLIC: * Return the order by expression. */ public List getOrderByExpressions() { return orderByExpressions; } /** * INTERNAL: * Return null if this mapping is used in an order by. */ public List getOrderByNormalizedExpressions(Expression base) { return null; } /** * PUBLIC: * Allow history support on the reference table. */ public HistoryPolicy getHistoryPolicy() { return historyPolicy; } /** * INTERNAL: * Get the container policy from the selection query for this mapping. */ @Override protected ContainerPolicy getSelectionQueryContainerPolicy() { return ((DataReadQuery) getSelectionQuery()).getContainerPolicy(); } /** * INTERNAL: * This cannot be used with direct collection mappings. */ @Override public Class getReferenceClass() { return null; } @Override public String getReferenceClassName() { return null; } /** * INTERNAL: * There is none on direct collection. */ @Override public ClassDescriptor getReferenceDescriptor() { return null; } /** * INTERNAL: * Return the reference key field names associated with the mapping. * These are in-order with the sourceKeyFieldNames. */ public Vector getReferenceKeyFieldNames() { Vector fieldNames = new Vector(getReferenceKeyFields().size()); for (Enumeration fieldsEnum = getReferenceKeyFields().elements(); fieldsEnum.hasMoreElements();) { fieldNames.addElement(((DatabaseField)fieldsEnum.nextElement()).getQualifiedName()); } return fieldNames; } /** * INTERNAL: * Return the reference key fields. */ public Vector getReferenceKeyFields() { return referenceKeyFields; } /** * INTERNAL: * Return the direct table. * This is the table to store the values. */ public DatabaseTable getReferenceTable() { return referenceTable; } /** * PUBLIC: * Returns the name of the reference table */ public String getReferenceTableName() { if (getReferenceTable() == null) { return null; } return getReferenceTable().getName(); } //This method is added to include table qualifier. /** * PUBLIC: * Returns the qualified name of the reference table. */ public String getReferenceTableQualifiedName() {//CR#2407 if (getReferenceTable() == null) { return null; } return getReferenceTable().getQualifiedName(); } /** * INTERNAL: * Return the relationshipPartner mapping for this bi-directional mapping. If the relationshipPartner is null then * this is a uni-directional mapping. * DirectCollectionMapping can not be part of a bi-directional mapping */ @Override public DatabaseMapping getRelationshipPartner() { return null; } /** * PUBLIC: * Return the source key field names associated with the mapping. * These are in-order with the referenceKeyFieldNames. */ 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 fields. */ public Vector getSourceKeyFields() { return sourceKeyFields; } protected boolean hasCustomDeleteQuery() { return hasCustomDeleteQuery; } protected boolean hasCustomInsertQuery() { return hasCustomInsertQuery; } protected boolean hasCustomDeleteAtIndexQuery() { return hasCustomDeleteAtIndexQuery; } protected boolean hasCustomUpdateAtIndexQuery() { return hasCustomUpdateAtIndexQuery; } /** * INTERNAL: * Indicates whether the mapping (or at least one of its nested mappings, at any nested depth) * references an entity. * To return true the mapping (or nested mapping) should be ForeignReferenceMapping with non-null and non-aggregate reference descriptor. */ @Override public boolean hasNestedIdentityReference() { return false; } /** * INTERNAL: * Initialize and validate the mapping properties. */ @Override public void initialize(AbstractSession session) throws DescriptorException { if (session.hasBroker()) { if (getInsertQuery().hasSessionName()) { // substitute session that owns the mapping for the session that owns reference table. session = session.getBroker().getSessionForName(getInsertQuery().getSessionName()); } } if (isKeyForSourceSpecified()) { initializeSourceKeys(session); } else { initializeSourceKeysWithDefaults(session); } initializeReferenceTable(session); initializeReferenceKeys(session); initializeDirectField(session); if (getReferenceTable().getName().indexOf(' ') != -1) { //table names contains a space so needs to be quoted. String beginQuote = ((DatasourcePlatform)session.getDatasourcePlatform()).getStartDelimiter(); String endQuote = ((DatasourcePlatform)session.getDatasourcePlatform()).getEndDelimiter(); //Ensure this tablename hasn't already been quoted. if (getReferenceTable().getName().indexOf(beginQuote) == -1) { getReferenceTable().setName(beginQuote + getReferenceTable().getName() + endQuote); } } if (this.listOrderField != null) { this.initializeListOrderField(session); } getContainerPolicy().initialize(session, this.referenceTable); // Initialize the value converter sooner since it likely will finish // configuring field and attribute classifications. if (getValueConverter() != null) { getValueConverter().initialize(this, session); } if (!hasCustomSelectionQuery()){ initOrRebuildSelectQuery(); getSelectionQuery().setName(getAttributeName()); if (shouldInitializeSelectionCriteria()) { initializeSelectionCriteria(session); initializeSelectionStatement(session); } } if (!getSelectionQuery().hasSessionName()) { getSelectionQuery().setSessionName(session.getName()); } if (getSelectionQuery().getPartitioningPolicy() == null) { getSelectionQuery().setPartitioningPolicy(getPartitioningPolicy()); } getSelectionQuery().setSourceMapping(this); if ((getValueConverter() != null) && (getSelectionQuery() instanceof DirectReadQuery)) { ((DirectReadQuery)getSelectionQuery()).setValueConverter(getValueConverter()); } initializeDeleteAllQuery(session); initializeDeleteQuery(session); initializeDeleteNullQuery(session); // Bug 306075 initializeInsertQuery(session); initializeDeleteAtIndexQuery(session); initializeUpdateAtIndexQuery(session); if (getHistoryPolicy() != null) { getHistoryPolicy().initialize(session); } super.initialize(session); } /** * INTERNAL: * Initializes listOrderField. * Precondition: listOrderField != null. */ @Override protected void initializeListOrderField(AbstractSession session) { // This method is called twice. The second call (by CollectionMapping.initialize) should be ignored because initialization has been already done. if(!getContainerPolicy().isOrderedListPolicy() || ((OrderedListContainerPolicy)getContainerPolicy()).getListOrderField() == null) { super.initializeListOrderField(session); } } /** * Initialize delete all query. This query is used to delete the collection of objects from the * reference table. */ protected void initializeDeleteAllQuery(AbstractSession session) { if (!getDeleteAllQuery().hasSessionName()) { getDeleteAllQuery().setSessionName(session.getName()); } if (getDeleteAllQuery().getPartitioningPolicy() == null) { getDeleteAllQuery().setPartitioningPolicy(getPartitioningPolicy()); } if (hasCustomDeleteAllQuery()) { return; } Expression expression = null; Expression subExp1; Expression subExp2; Expression subExpression; Expression builder = new ExpressionBuilder(); SQLDeleteStatement statement = new SQLDeleteStatement(); // Construct an expression to delete from the relation table. for (int index = 0; index < getReferenceKeyFields().size(); index++) { DatabaseField referenceKey = getReferenceKeyFields().elementAt(index); DatabaseField sourceKey = getSourceKeyFields().elementAt(index); subExp1 = builder.getField(referenceKey); subExp2 = builder.getParameter(sourceKey); subExpression = subExp1.equal(subExp2); if (expression == null) { expression = subExpression; } else { expression = expression.and(subExpression); } } statement.setWhereClause(expression); statement.setTable(getReferenceTable()); getDeleteAllQuery().setSQLStatement(statement); } protected void initializeDeleteQuery(AbstractSession session) { if (!getDeleteQuery().hasSessionName()) { getDeleteQuery().setSessionName(session.getName()); } if (getDeleteQuery().getPartitioningPolicy() == null) { getDeleteQuery().setPartitioningPolicy(getPartitioningPolicy()); } if (hasCustomDeleteQuery()) { return; } SQLDeleteStatement statement = new SQLDeleteStatement(); ExpressionBuilder builder = new ExpressionBuilder(); Expression expression = createWhereClauseForDeleteQuery(builder); statement.setWhereClause(expression); statement.setTable(getReferenceTable()); getDeleteQuery().setSQLStatement(statement); } // Bug 306075 - for deleting a null value from a collection protected void initializeDeleteNullQuery(AbstractSession session) { if (!getDeleteNullQuery().hasSessionName()) { getDeleteNullQuery().setSessionName(session.getName()); } if (getDeleteNullQuery().getPartitioningPolicy() == null) { getDeleteNullQuery().setPartitioningPolicy(getPartitioningPolicy()); } SQLDeleteStatement statement = new SQLDeleteStatement(); ExpressionBuilder builder = new ExpressionBuilder(); Expression expression = createWhereClauseForDeleteNullQuery(builder); statement.setWhereClause(expression); statement.setTable(getReferenceTable()); getDeleteNullQuery().setSQLStatement(statement); } protected void initializeDeleteAtIndexQuery(AbstractSession session) { if (!getDeleteAtIndexQuery().hasSessionName()) { getDeleteAtIndexQuery().setSessionName(session.getName()); } if (getDeleteAtIndexQuery().getPartitioningPolicy() == null) { getDeleteAtIndexQuery().setPartitioningPolicy(getPartitioningPolicy()); } if (hasCustomDeleteAtIndexQuery()) { return; } SQLDeleteStatement statement = new SQLDeleteStatement(); ExpressionBuilder builder = new ExpressionBuilder(); Expression expression = createWhereClauseForDeleteQuery(builder); expression = expression.and(builder.getField(this.listOrderField).equal(builder.getParameter(this.listOrderField))); statement.setWhereClause(expression); statement.setTable(getReferenceTable()); getDeleteAtIndexQuery().setSQLStatement(statement); } protected void initializeUpdateAtIndexQuery(AbstractSession session) { if (!getUpdateAtIndexQuery().hasSessionName()) { getUpdateAtIndexQuery().setSessionName(session.getName()); } if (getUpdateAtIndexQuery().getPartitioningPolicy() == null) { getUpdateAtIndexQuery().setPartitioningPolicy(getPartitioningPolicy()); } if (hasCustomUpdateAtIndexQuery()) { return; } SQLUpdateStatement statement = new SQLUpdateStatement(); ExpressionBuilder builder = new ExpressionBuilder(); Expression expression = createWhereClauseForDeleteQuery(builder); expression = expression.and(builder.getField(this.listOrderField).equal(builder.getParameter(this.listOrderField))); statement.setWhereClause(expression); statement.setTable(getReferenceTable()); AbstractRecord modifyRow = new DatabaseRecord(); modifyRow.add(this.listOrderField, null); statement.setModifyRow(modifyRow); getUpdateAtIndexQuery().setSQLStatement(statement); } /** * INTERNAL: * Indicates whether getListOrderFieldExpression method should create field expression on table expression. */ @Override public boolean shouldUseListOrderFieldTableExpression() { return true; } protected Expression createWhereClauseForDeleteQuery(ExpressionBuilder builder) { Expression directExp = builder.getField(getDirectField()).equal(builder.getParameter(getDirectField())); Expression expression = null; // Construct an expression to delete from the relation table. for (int index = 0; index < getReferenceKeyFields().size(); index++) { DatabaseField referenceKey = getReferenceKeyFields().get(index); DatabaseField sourceKey = getSourceKeyFields().get(index); Expression subExp1 = builder.getField(referenceKey); Expression subExp2 = builder.getParameter(sourceKey); Expression subExpression = subExp1.equal(subExp2); expression = subExpression.and(expression); } expression = expression.and(directExp); return expression; } // Bug 306075 - for deleting a null value from a collection protected Expression createWhereClauseForDeleteNullQuery(ExpressionBuilder builder) { Expression directExp = builder.getField(getDirectField()).isNull(); Expression expression = null; // Construct an expression to delete from the relation table. for (int index = 0; index < getReferenceKeyFields().size(); index++) { DatabaseField referenceKey = getReferenceKeyFields().get(index); DatabaseField sourceKey = getSourceKeyFields().get(index); Expression subExp1 = builder.getField(referenceKey); Expression subExp2 = builder.getParameter(sourceKey); Expression subExpression = subExp1.equal(subExp2); expression = subExpression.and(expression); } expression = expression.and(directExp); return expression; } /** * The field name on the reference table is initialized and cached. */ protected void initializeDirectField(AbstractSession session) throws DescriptorException { if (getDirectField() == null) { throw DescriptorException.directFieldNameNotSet(this); } getDirectField().setTable(getReferenceTable()); getDirectField().setIndex(0); } /** * Initialize insert query. This query is used to insert the collection of objects into the * reference table. */ protected void initializeInsertQuery(AbstractSession session) { if (!getInsertQuery().hasSessionName()) { getInsertQuery().setSessionName(session.getName()); } if (getInsertQuery().getPartitioningPolicy() == null) { getInsertQuery().setPartitioningPolicy(getPartitioningPolicy()); } if (hasCustomInsertQuery()) { return; } SQLInsertStatement statement = new SQLInsertStatement(); statement.setTable(getReferenceTable()); AbstractRecord directRow = new DatabaseRecord(); for (Enumeration referenceEnum = getReferenceKeyFields().elements(); referenceEnum.hasMoreElements();) { directRow.put((DatabaseField)referenceEnum.nextElement(), null); } directRow.put(getDirectField(), null); if(listOrderField != null) { directRow.put(listOrderField, null); } statement.setModifyRow(directRow); getInsertQuery().setSQLStatement(statement); getInsertQuery().setModifyRow(directRow); } /** * There is no reference descriptor */ @Override protected void initializeReferenceDescriptor(AbstractSession session) { // no-op. } /** * The reference keys on the reference table are initialized */ protected void initializeReferenceKeys(AbstractSession session) throws DescriptorException { if (getReferenceKeyFields().size() == 0) { throw DescriptorException.noReferenceKeyIsSpecified(this); } for (Enumeration referenceEnum = getReferenceKeyFields().elements(); referenceEnum.hasMoreElements();) { DatabaseField field = (DatabaseField)referenceEnum.nextElement(); // Update the field first if the mapping is on a table per tenant entity. if (getDescriptor().hasTablePerMultitenantPolicy()) { field.setTable(((TablePerMultitenantPolicy) getDescriptor().getMultitenantPolicy()).getTable(field.getTable())); } if (field.hasTableName() && (!(field.getTableName().equals(getReferenceTable().getName())))) { throw DescriptorException.referenceKeyFieldNotProperlySpecified(field, this); } field.setTable(getReferenceTable()); } } /** * Set the table qualifier on the reference table if required */ protected void initializeReferenceTable(AbstractSession session) throws DescriptorException { Platform platform = session.getDatasourcePlatform(); if (getReferenceTable() == null) { throw DescriptorException.referenceTableNotSpecified(this); } if (platform.getTableQualifier().length() > 0) { if (getReferenceTable().getTableQualifier().length() == 0) { getReferenceTable().setTableQualifier(platform.getTableQualifier()); } } } protected void initializeSelectionCriteria(AbstractSession session) { Expression criteria = null; ExpressionBuilder base = new ExpressionBuilder(); TableExpression table = (TableExpression)base.getTable(getReferenceTable()); Iterator referenceKeys = getReferenceKeyFields().iterator(); Iterator sourceKeys = getSourceKeyFields().iterator(); while (referenceKeys.hasNext()) { DatabaseField referenceKey = referenceKeys.next(); DatabaseField sourceKey = sourceKeys.next(); Expression expression = table.getField(referenceKey).equal(base.getParameter(sourceKey)); if (criteria == null) { criteria = expression; } else { criteria = expression.and(criteria); } } setSelectionCriteria(criteria); } /** * The selection query is initialized */ @Override protected void initializeSelectionQuery(AbstractSession session) { // Nothing required. } protected void initializeSelectionStatement(AbstractSession session) { SQLSelectStatement statement = new SQLSelectStatement(); statement.addTable(getReferenceTable()); statement.addField(getDirectField().clone()); statement.setWhereClause(getSelectionCriteria()); statement.setOrderByExpressions(orderByExpressions); getSelectionQuery().setSQLStatement(statement); getContainerPolicy().addAdditionalFieldsToQuery(selectionQuery, getAdditionalFieldsBaseExpression(getSelectionQuery())); statement.normalize(session, null); } /** * The source keys are initialized */ protected void initializeSourceKeys(AbstractSession session) { for (int index = 0; index < getSourceKeyFields().size(); index++) { DatabaseField field = getDescriptor().buildField(getSourceKeyFields().get(index)); if (usesIndirection()) { field.setKeepInRow(true); } getSourceKeyFields().set(index, field); } } /** * INTERNAL: * If a user does not specify the source key then the primary keys of the source table are used. */ protected void initializeSourceKeysWithDefaults(AbstractSession session) { List primaryKeyFields = getDescriptor().getPrimaryKeyFields(); for (int index = 0; index < primaryKeyFields.size(); index++) { DatabaseField field = primaryKeyFields.get(index); if (usesIndirection()) { field.setKeepInRow(true); } getSourceKeyFields().addElement(field); } } /** * INTERNAL: * Return the base expression to use for adding fields to the query. * This is the reference table. */ @Override protected Expression getAdditionalFieldsBaseExpression(ReadQuery query) { if (query.isReadAllQuery()) { return ((ReadAllQuery)query).getExpressionBuilder(); } else { return ((DataReadQuery)query).getSQLStatement().getBuilder().getTable(getReferenceTable()); } } /** * INTERNAL: */ @Override public boolean isDirectCollectionMapping() { return true; } /** * INTERNAL: */ @Override public boolean isElementCollectionMapping() { return true; } /** * INTERNAL: * Return if this mapping support joining. */ @Override public boolean isJoiningSupported() { return true; } /** * INTERNAL: * Checks if source and target keys are mentioned by the user or not. */ protected boolean isKeyForSourceSpecified() { return !getSourceKeyFields().isEmpty(); } /** * INTERNAL: * Return whether this mapping should be traversed when we are locking * @return */ public boolean isLockableMapping(){ return false; } /** * INTERNAL: */ @Override public boolean isOwned(){ return true; } /** * INTERNAL: * Iterate on the attribute value. * The value holder has already been processed. * PERF: Avoid iteration if not required. */ @Override public void iterateOnRealAttributeValue(DescriptorIterator iterator, Object realAttributeValue) { if (iterator.shouldIterateOnPrimitives()) { super.iterateOnRealAttributeValue(iterator, realAttributeValue); } } /** * INTERNAL: * Iterate on the specified element. */ @Override public void iterateOnElement(DescriptorIterator iterator, Object element) { iterator.iteratePrimitiveForMapping(element, this); } /** * 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 */ @Override public void mergeChangesIntoObject(Object target, ChangeRecord changeRecord, Object source, MergeManager mergeManager, AbstractSession targetSession) { if (this.descriptor.getCachePolicy().isProtectedIsolation()&& !this.isCacheable && !targetSession.isProtectedSession()){ setAttributeValueInObject(target, this.indirectionPolicy.buildIndirectObject(new ValueHolder(null))); return; } ContainerPolicy containerPolicy = getContainerPolicy(); Object valueOfTarget = null; AbstractSession session = mergeManager.getSession(); DirectCollectionChangeRecord directCollectionChangeRecord = (DirectCollectionChangeRecord) changeRecord; //Check to see if the target has an instantiated collection if ((isAttributeValueInstantiated(target)) && (!changeRecord.getOwner().isNew())) { if (isSynchronizeOnMerge) { valueOfTarget = getRealCollectionAttributeValueFromObject(target, session); } else { valueOfTarget = containerPolicy.cloneFor(getRealCollectionAttributeValueFromObject(target, session)); } } else { //if not create an instance of the collection valueOfTarget = containerPolicy.containerInstance(directCollectionChangeRecord.getAddObjectMap().size()); } if (!isAttributeValueInstantiated(target)) { if (mergeManager.shouldMergeChangesIntoDistributedCache()) { return; } for (Object iterator = containerPolicy.iteratorFor(getRealCollectionAttributeValueFromObject(source, session)); containerPolicy.hasNext(iterator);) { containerPolicy.addInto(containerPolicy.next(iterator, session), valueOfTarget, session); } } else { Object synchronizationTarget = valueOfTarget; // For indirect containers the delegate must be synchronized on, // not the wrapper as the clone synchs on the delegate, see bug#5685287. if (valueOfTarget instanceof IndirectCollection) { synchronizationTarget = ((IndirectCollection)valueOfTarget).getDelegateObject(); if (((DirectCollectionChangeRecord)changeRecord).orderHasBeenRepaired() && (valueOfTarget instanceof IndirectList)) { ((IndirectList)valueOfTarget).setIsListOrderBrokenInDb(false); } } if (isSynchronizeOnMerge) { synchronized(synchronizationTarget) { mergeAddRemoveChanges(valueOfTarget, synchronizationTarget, directCollectionChangeRecord, mergeManager, session); } } else { mergeAddRemoveChanges(valueOfTarget, synchronizationTarget, directCollectionChangeRecord, mergeManager, session); } } setRealAttributeValueInObject(target, valueOfTarget); } /** * INTERNAL: * Merge changes by adding and removing from the change record to the * target object, and its delegate object if instance of IndirectCollection. * It will also reorder the collection if required. */ protected void mergeAddRemoveChanges(Object valueOfTarget, Object delegateTarget, DirectCollectionChangeRecord changeRecord, MergeManager mergeManager, AbstractSession session) { //collect the changes into a vector HashMap addObjects = changeRecord.getAddObjectMap(); HashMap removeObjects = changeRecord.getRemoveObjectMap(); // Next iterate over the changes and add them to the container for (Iterator iterator = addObjects.keySet().iterator(); iterator.hasNext();) { Object object = iterator.next(); int objectCount = ((Integer)addObjects.get(object)).intValue(); for (int i = 0; i < objectCount; ++i) { if (mergeManager.shouldMergeChangesIntoDistributedCache()) { //bug#4458089 and 4544532- check if collection contains new item before adding during merge into distributed cache if (!containerPolicy.contains(object, valueOfTarget, session)) { containerPolicy.addInto(object, valueOfTarget, session); } } else { containerPolicy.addInto(object, valueOfTarget, session); } } } for (Iterator iterator = removeObjects.keySet().iterator(); iterator.hasNext();) { Object object = iterator.next(); int objectCount = ((Integer)removeObjects.get(object)).intValue(); for (int i = 0; i < objectCount; ++i) { containerPolicy.removeFrom(object, valueOfTarget, session); } } if(this.listOrderField != null && changeRecord.getChangedIndexes() == null) { this.compareListsForChange((List)changeRecord.getOriginalCollection(), (List)changeRecord.getLatestCollection(), changeRecord, session); } if(changeRecord.getChangedIndexes() != null) { int oldSize = changeRecord.getOldSize(); int newSize = changeRecord.getNewSize(); int delta = newSize - oldSize; Object newTail[] = null; if(delta > 0) { newTail = new Object[delta]; } Iterator> it = changeRecord.getChangedIndexes().entrySet().iterator(); while(it.hasNext()) { Map.Entry entry = it.next(); Object value = entry.getKey(); Set[] indexes = entry.getValue(); Set indexesAfter = indexes[1]; if(indexesAfter != null) { Iterator itIndexesAfter = indexesAfter.iterator(); while(itIndexesAfter.hasNext()) { int index = itIndexesAfter.next(); if(index < oldSize) { ((List)delegateTarget).set(index, value); } else { newTail[index - oldSize] = value; } } } } if(delta > 0) { for(int i=0; i < delta; i++) { ((List)delegateTarget).add(newTail[i]); } } else if(delta < 0) { for(int i=oldSize -1 ; i >= newSize; i--) { ((List)delegateTarget).remove(i); } } } } /** * INTERNAL: * Merge changes from the source to the target object. */ @Override public void mergeIntoObject(Object target, boolean isTargetUnInitialized, Object source, MergeManager mergeManager, AbstractSession targetSession) { if (this.descriptor.getCachePolicy().isProtectedIsolation() && !this.isCacheable && !targetSession.isProtectedSession()){ setAttributeValueInObject(target, this.indirectionPolicy.buildIndirectObject(new ValueHolder(null))); return; } 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), targetSession)); return; } } if (!shouldMergeCascadeReference(mergeManager)) { // This is only going to happen on mergeClone, and we should not attempt to merge the reference return; } if (mergeManager.shouldRefreshRemoteObject() && usesIndirection()) { mergeRemoteValueHolder(target, source, mergeManager); return; } if (mergeManager.isForRefresh()) { 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 (!isAttributeValueInstantiatedOrChanged(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()); // trigger instantiation of target attribute Object valueOfTarget = getRealCollectionAttributeValueFromObject(target, mergeManager.getSession()); Object newContainer = containerPolicy.containerInstance(containerPolicy.sizeFor(valueOfSource)); boolean fireCollectionChangeEvents = false; boolean firePropertyChangeEvent = false; ObjectChangeListener listener = null; if ((this.descriptor.getObjectChangePolicy().isObjectChangeTrackingPolicy()) && (target instanceof ChangeTracker) && (((ChangeTracker)target)._persistence_getPropertyChangeListener() != null)) { listener = (ObjectChangeListener)((ChangeTracker)target)._persistence_getPropertyChangeListener(); if(this.listOrderField == null) { fireCollectionChangeEvents = true; //Collections may not be indirect list or may have been replaced with user collection. Object iterator = containerPolicy.iteratorFor(valueOfTarget); Integer zero = Integer.valueOf(0);//remove does not seem to use index. while (containerPolicy.hasNext(iterator)) { // Bug304251: let the containerPolicy build the proper remove CollectionChangeEvent CollectionChangeEvent event = containerPolicy.createChangeEvent(target, getAttributeName(), valueOfTarget, containerPolicy.next(iterator, mergeManager.getSession()), CollectionChangeEvent.REMOVE, zero, false); listener.internalPropertyChange(event); } if (newContainer instanceof ChangeTracker) { ((ChangeTracker)newContainer)._persistence_setPropertyChangeListener(((ChangeTracker)target)._persistence_getPropertyChangeListener()); } if (valueOfTarget instanceof ChangeTracker) { ((ChangeTracker)valueOfTarget)._persistence_setPropertyChangeListener(null);//remove listener } } else { firePropertyChangeEvent = true; } } Object originalValueOfTarget = valueOfTarget; valueOfTarget = newContainer; int i = 0; for (Object sourceValuesIterator = containerPolicy.iteratorFor(valueOfSource); containerPolicy.hasNext(sourceValuesIterator);) { Object sourceValue = containerPolicy.next(sourceValuesIterator, mergeManager.getSession()); if (fireCollectionChangeEvents) { // Bug304251: let the containerPolicy build the proper remove CollectionChangeEvent CollectionChangeEvent event = containerPolicy.createChangeEvent(target, getAttributeName(), valueOfTarget, sourceValue, CollectionChangeEvent.ADD, Integer.valueOf(i), false); listener.internalPropertyChange(event); } containerPolicy.addInto(sourceValue, valueOfTarget, mergeManager.getSession()); i++; } if (fireCollectionChangeEvents && (this.descriptor.getObjectChangePolicy().isAttributeChangeTrackingPolicy())) { // check that there were changes, if not then remove the record. ObjectChangeSet changeSet = ((AttributeChangeListener)((ChangeTracker)target)._persistence_getPropertyChangeListener()).getObjectChangeSet(); if (changeSet != null) { DirectCollectionChangeRecord changeRecord = (DirectCollectionChangeRecord)changeSet.getChangesForAttributeNamed(getAttributeName()); if (changeRecord != null) { if (!changeRecord.isDeferred()) { if (!changeRecord.hasChanges()) { changeSet.removeChange(getAttributeName()); } } else { // Must reset the latest collection. changeRecord.setLatestCollection(valueOfTarget); } } } } if(firePropertyChangeEvent) { ((ObjectChangeListener)((ChangeTracker)target)._persistence_getPropertyChangeListener()).internalPropertyChange(new PropertyChangeEvent(target, getAttributeName(), originalValueOfTarget, valueOfTarget)); if (valueOfTarget instanceof ChangeTracker) { ((ChangeTracker)valueOfTarget)._persistence_setPropertyChangeListener(((ChangeTracker)target)._persistence_getPropertyChangeListener()); } if (originalValueOfTarget instanceof ChangeTracker) { ((ChangeTracker)originalValueOfTarget)._persistence_setPropertyChangeListener(null);//remove listener } } // 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: * Perform the commit event. * This is used in the uow to delay data modifications. */ @Override public void performDataModificationEvent(Object[] event, AbstractSession session) throws DatabaseException, DescriptorException { // Hey I might actually want to use an inner class here... ok array for now. if (event[0] == Delete) { session.executeQuery((DataModifyQuery)event[1], (AbstractRecord)event[2]); if ((getHistoryPolicy() != null) && getHistoryPolicy().shouldHandleWrites()) { getHistoryPolicy().mappingLogicalDelete((DataModifyQuery)event[1], (AbstractRecord)event[2], session); } } else if (event[0] == Insert) { session.executeQuery((DataModifyQuery)event[1], (AbstractRecord)event[2]); if ((getHistoryPolicy() != null) && getHistoryPolicy().shouldHandleWrites()) { getHistoryPolicy().mappingLogicalInsert((DataModifyQuery)event[1], (AbstractRecord)event[2], session); } } else if (event[0] == DeleteAll) { preDelete((DeleteObjectQuery)event[1]); } else if (event[0] == DeleteAtIndex) { session.executeQuery((DataModifyQuery)event[1], (AbstractRecord)event[2]); } else if (event[0] == UpdateAtIndex) { DataModifyQuery updateAtIndexQuery = (DataModifyQuery)((DataModifyQuery)event[1]).clone(); updateAtIndexQuery.setModifyRow((AbstractRecord)event[3]); updateAtIndexQuery.setHasModifyRow(true); updateAtIndexQuery.setIsExecutionClone(true); session.executeQuery(updateAtIndexQuery, (AbstractRecord)event[2]); } else { throw DescriptorException.invalidDataModificationEventCode(event[0], this); } } /** * INTERNAL: * Overridden by mappings that require additional processing of the change record after the record has been calculated. */ @Override public void postCalculateChanges(org.eclipse.persistence.sessions.changesets.ChangeRecord changeRecord, UnitOfWorkImpl uow) { //no -op for this collection type } /** * INTERNAL: * Insert the private owned object. */ @Override public void postInsert(WriteObjectQuery query) throws DatabaseException { Object objects; AbstractRecord databaseRow = new DatabaseRecord(); if (isReadOnly()) { return; } objects = getRealCollectionAttributeValueFromObject(query.getObject(), query.getSession()); ContainerPolicy containerPolicy = getContainerPolicy(); if (containerPolicy.isEmpty(objects)) { return; } prepareTranslationRow(query.getTranslationRow(), query.getObject(), query.getDescriptor(), query.getSession()); // Extract primary key and value from the source. for (int index = 0; index < getReferenceKeyFields().size(); index++) { DatabaseField referenceKey = getReferenceKeyFields().get(index); DatabaseField sourceKey = getSourceKeyFields().get(index); Object sourceKeyValue = query.getTranslationRow().get(sourceKey); databaseRow.put(referenceKey, sourceKeyValue); } int orderIndex = 0; // Extract target field and its value. Construct insert statement and execute it for (Object iter = containerPolicy.iteratorFor(objects); containerPolicy.hasNext(iter);) { Object wrappedObject = containerPolicy.nextEntry(iter, query.getSession()); Object object = containerPolicy.unwrapIteratorResult(wrappedObject); if (getValueConverter() != null) { object = getValueConverter().convertObjectValueToDataValue(object, query.getSession()); } databaseRow.put(getDirectField(), object); // In the uow data queries are cached until the end of the commit. if (query.shouldCascadeOnlyDependentParts()) { // Hey I might actually want to use an inner class here... ok array for now. Object[] event = new Object[3]; event[0] = Insert; event[1] = getInsertQuery(); event[2] = databaseRow.clone(); if(listOrderField != null) { ((AbstractRecord)event[2]).put(listOrderField, orderIndex++); } query.getSession().getCommitManager().addDataModificationEvent(this, event); } else { query.getSession().executeQuery(getInsertQuery(), databaseRow); if ((getHistoryPolicy() != null) && getHistoryPolicy().shouldHandleWrites()) { getHistoryPolicy().mappingLogicalInsert(getInsertQuery(), databaseRow, query.getSession()); } } containerPolicy.propogatePostInsert(query, wrappedObject); } } /** * INTERNAL: * Convert the attribute value to a field value. * Process any converter if defined. */ public Object getFieldValue(Object attributeValue, AbstractSession session) { if (this.valueConverter != null) { return this.valueConverter.convertObjectValueToDataValue(attributeValue, session); } return attributeValue; } /** * INTERNAL: * Convert the field value to an attribute value. * Process any converter if defined. */ public Object getObjectValue(Object fieldValue, AbstractSession session) { if (this.valueConverter != null) { return this.valueConverter.convertDataValueToObjectValue(fieldValue, session); } return fieldValue; } /** * INTERNAL: * Return source key fields for translation by an AggregateObjectMapping */ @Override public Vector getFieldsForTranslationInAggregate() { return getSourceKeyFields(); } /** * INTERNAL: * Update private owned part. */ @Override public void postUpdate(WriteObjectQuery writeQuery) throws DatabaseException { if (isReadOnly()) { return; } if (writeQuery.getObjectChangeSet() != null) { if(this.listOrderField != null) { postUpdateWithChangeSetListOrder(writeQuery); } else { postUpdateWithChangeSet(writeQuery); } return; } // If objects are not instantiated that means they are not changed. if (!isAttributeValueInstantiatedOrChanged(writeQuery.getObject())) { return; } if (writeQuery.getSession().isUnitOfWork()) { if (compareObjects(writeQuery.getObject(), writeQuery.getBackupClone(), writeQuery.getSession())) { return;// Nothing has changed, no work required } } DeleteObjectQuery deleteQuery = new DeleteObjectQuery(); deleteQuery.setObject(writeQuery.getObject()); deleteQuery.setSession(writeQuery.getSession()); deleteQuery.setTranslationRow(writeQuery.getTranslationRow()); if (writeQuery.shouldCascadeOnlyDependentParts()) { // Hey I might actually want to use an inner class here... ok array for now. Object[] event = new Object[3]; event[0] = DeleteAll; event[1] = deleteQuery; writeQuery.getSession().getCommitManager().addDataModificationEvent(this, event); } else { preDelete(deleteQuery); } postInsert(writeQuery); } /** * INTERNAL: * Update private owned part. */ protected void postUpdateWithChangeSet(WriteObjectQuery writeQuery) throws DatabaseException { ObjectChangeSet changeSet = writeQuery.getObjectChangeSet(); DirectCollectionChangeRecord changeRecord = (DirectCollectionChangeRecord)changeSet.getChangesForAttributeNamed(this.getAttributeName()); if (changeRecord == null) { return; } for (int index = 0; index < getReferenceKeyFields().size(); index++) { DatabaseField referenceKey = getReferenceKeyFields().get(index); DatabaseField sourceKey = getSourceKeyFields().get(index); Object sourceKeyValue = writeQuery.getTranslationRow().get(sourceKey); writeQuery.getTranslationRow().put(referenceKey, sourceKeyValue); } for (Iterator iterator = changeRecord.getRemoveObjectMap().keySet().iterator(); iterator.hasNext();) { Object object = iterator.next(); AbstractRecord thisRow = writeQuery.getTranslationRow().clone(); Object value = getFieldValue(object, writeQuery.getSession()); // Hey I might actually want to use an inner class here... ok array for now. Object[] event = new Object[3]; event[0] = Delete; if (value == null) { // Bug 306075 - for deleting a null value from a collection event[1] = getDeleteNullQuery(); } else { thisRow.add(getDirectField(), value); event[1] = getDeleteQuery(); } event[2] = thisRow; writeQuery.getSession().getCommitManager().addDataModificationEvent(this, event); Integer count = (Integer)changeRecord.getCommitAddMap().get(object); if (count != null) { for (int counter = count.intValue(); counter > 0; --counter) { thisRow = writeQuery.getTranslationRow().clone(); thisRow.add(getDirectField(), value); // Hey I might actually want to use an inner class here... ok array for now. event = new Object[3]; event[0] = Insert; event[1] = getInsertQuery(); event[2] = thisRow; writeQuery.getSession().getCommitManager().addDataModificationEvent(this, event); } } } for (Iterator iterator = changeRecord.getAddObjectMap().keySet().iterator(); iterator.hasNext();) { Object object = iterator.next(); Integer count = (Integer)changeRecord.getAddObjectMap().get(object); for (int counter = count.intValue(); counter > 0; --counter) { AbstractRecord thisRow = writeQuery.getTranslationRow().clone(); Object value = object; if (getValueConverter() != null) { value = getValueConverter().convertObjectValueToDataValue(value, writeQuery.getSession()); } thisRow.add(getDirectField(), value); // Hey I might actually want to use an inner class here... ok array for now. Object[] event = new Object[3]; event[0] = Insert; event[1] = getInsertQuery(); event[2] = thisRow; writeQuery.getSession().getCommitManager().addDataModificationEvent(this, event); } } } /** * INTERNAL: * Update private owned part. */ protected void postUpdateWithChangeSetListOrder(WriteObjectQuery writeQuery) throws DatabaseException { ObjectChangeSet changeSet = writeQuery.getObjectChangeSet(); DirectCollectionChangeRecord changeRecord = (DirectCollectionChangeRecord)changeSet.getChangesForAttributeNamed(this.getAttributeName()); if (changeRecord == null) { return; } for (int index = 0; index < getReferenceKeyFields().size(); index++) { DatabaseField referenceKey = getReferenceKeyFields().get(index); DatabaseField sourceKey = getSourceKeyFields().get(index); Object sourceKeyValue = writeQuery.getTranslationRow().get(sourceKey); writeQuery.getTranslationRow().put(referenceKey, sourceKeyValue); } boolean shouldRepairOrder = false; if((List)changeRecord.getLatestCollection() instanceof IndirectList) { shouldRepairOrder = ((IndirectList)changeRecord.getLatestCollection()).isListOrderBrokenInDb(); } if(shouldRepairOrder) { // delete all members of collection DeleteObjectQuery deleteQuery = new DeleteObjectQuery(); deleteQuery.setObject(writeQuery.getObject()); deleteQuery.setSession(writeQuery.getSession()); deleteQuery.setTranslationRow(writeQuery.getTranslationRow()); // Hey I might actually want to use an inner class here... ok array for now. Object[] eventDeleteAll = new Object[2]; eventDeleteAll[0] = DeleteAll; eventDeleteAll[1] = deleteQuery; writeQuery.getSession().getCommitManager().addDataModificationEvent(this, eventDeleteAll); // re-insert them back for(int i=0; i < ((List)changeRecord.getLatestCollection()).size(); i++) { Object value = ((List)changeRecord.getLatestCollection()).get(i); value = getFieldValue(value, writeQuery.getSession()); AbstractRecord insertRow = writeQuery.getTranslationRow().clone(); insertRow.add(getDirectField(), value); insertRow.add(this.listOrderField, i); // Hey I might actually want to use an inner class here... ok array for now. Object[] event = new Object[3]; event[0] = Insert; event[1] = getInsertQuery(); event[2] = insertRow; writeQuery.getSession().getCommitManager().addDataModificationEvent(this, event); } ((IndirectList)changeRecord.getLatestCollection()).setIsListOrderBrokenInDb(false); changeRecord.setOrderHasBeenRepaired(true); return; } if(changeRecord.getChangedIndexes() == null) { compareListsForChange((List)changeRecord.getOriginalCollection(), (List)changeRecord.getLatestCollection(), changeRecord, writeQuery.getSession()); } Iterator> it = changeRecord.getChangedIndexes().entrySet().iterator(); while(it.hasNext()) { Map.Entry entry = it.next(); Object value = entry.getKey(); if (getValueConverter() != null) { value = getValueConverter().convertObjectValueToDataValue(value, writeQuery.getSession()); } Set[] indexes = entry.getValue(); Set indexesBefore = indexes[0]; Set indexesAfter = indexes[1]; if(indexesAfter == null) { // All copies of the target object deleted - don't need to verify order field contents. AbstractRecord deleteRow = writeQuery.getTranslationRow().clone(); // Hey I might actually want to use an inner class here... ok array for now. Object[] event = new Object[3]; event[0] = Delete; if (value == null) { // Bug 306075 - for deleting a null value from a collection event[1] = getDeleteNullQuery(); } else { deleteRow.add(getDirectField(), value); event[1] = getDeleteQuery(); } event[2] = deleteRow; writeQuery.getSession().getCommitManager().addDataModificationEvent(this, event); } else if(indexesAfter.isEmpty()) { // Some copies of the target objects should be deleted, some left in the db Iterator itBefore = indexesBefore.iterator(); while(itBefore.hasNext()) { AbstractRecord deleteAtIndexRow = writeQuery.getTranslationRow().clone(); deleteAtIndexRow.add(getDirectField(), value); deleteAtIndexRow.add(this.listOrderField, itBefore.next()); // Hey I might actually want to use an inner class here... ok array for now. Object[] event = new Object[3]; event[0] = DeleteAtIndex; event[1] = deleteAtIndexQuery; event[2] = deleteAtIndexRow; writeQuery.getSession().getCommitManager().addDataModificationEvent(this, event); } } else { if(indexesBefore == null || indexesBefore.isEmpty()) { // insert the object for each index in indexesAfter Iterator itAfter = indexesAfter.iterator(); while(itAfter.hasNext()) { AbstractRecord insertRow = writeQuery.getTranslationRow().clone(); insertRow.add(getDirectField(), value); insertRow.add(this.listOrderField, itAfter.next()); // Hey I might actually want to use an inner class here... ok array for now. Object[] event = new Object[3]; event[0] = Insert; event[1] = getInsertQuery(); event[2] = insertRow; writeQuery.getSession().getCommitManager().addDataModificationEvent(this, event); } } else { Iterator itBefore = indexesBefore.iterator(); Iterator itAfter = indexesAfter.iterator(); while(itBefore.hasNext() || itAfter.hasNext()) { if(itBefore.hasNext()) { if(itAfter.hasNext()) { // update the object changing index from indexBefore to indexAfter AbstractRecord updateAtIndexRow = writeQuery.getTranslationRow().clone(); updateAtIndexRow.add(getDirectField(), value); updateAtIndexRow.add(this.listOrderField, itBefore.next()); // Hey I might actually want to use an inner class here... ok array for now. Object[] event = new Object[4]; event[0] = UpdateAtIndex; event[1] = updateAtIndexQuery; event[2] = updateAtIndexRow; DatabaseRecord modifyRow = new DatabaseRecord(1); modifyRow.add(this.listOrderField, itAfter.next()); event[3] = modifyRow; writeQuery.getSession().getCommitManager().addDataModificationEvent(this, event); } else { // delete the object at indexBefore AbstractRecord deleteAtIndexRow = writeQuery.getTranslationRow().clone(); deleteAtIndexRow.add(getDirectField(), value); deleteAtIndexRow.add(this.listOrderField, itBefore.next()); // Hey I might actually want to use an inner class here... ok array for now. Object[] event = new Object[3]; event[0] = DeleteAtIndex; event[1] = deleteAtIndexQuery; event[2] = deleteAtIndexRow; writeQuery.getSession().getCommitManager().addDataModificationEvent(this, event); } } else { // itAfter.hasNext() must be true // insert the object at indexAfter AbstractRecord insertRow = writeQuery.getTranslationRow().clone(); insertRow.add(getDirectField(), value); insertRow.add(this.listOrderField, itAfter.next()); // Hey I might actually want to use an inner class here... ok array for now. Object[] event = new Object[3]; event[0] = Insert; event[1] = getInsertQuery(); event[2] = insertRow; writeQuery.getSession().getCommitManager().addDataModificationEvent(this, event); } } } } } } /** * INTERNAL: * Delete private owned part. Which is a collection of objects from the reference table. */ @Override public void preDelete(DeleteObjectQuery query) throws DatabaseException { if (this.isReadOnly) { return; } if (!this.isCascadeOnDeleteSetOnDatabase) { prepareTranslationRow(query.getTranslationRow(), query.getObject(), query.getDescriptor(), query.getSession()); query.getSession().executeQuery(this.deleteAllQuery, query.getTranslationRow()); } if ((this.historyPolicy != null) && this.historyPolicy.shouldHandleWrites()) { if (this.isCascadeOnDeleteSetOnDatabase) { prepareTranslationRow(query.getTranslationRow(), query.getObject(), query.getDescriptor(), query.getSession()); } this.historyPolicy.mappingLogicalDelete(this.deleteAllQuery, query.getTranslationRow(), query.getSession()); } } /** * INTERNAL: * The translation row may require additional fields than the primary key if the mapping in not on the primary key. */ @Override protected void prepareTranslationRow(AbstractRecord translationRow, Object object, ClassDescriptor descriptor, AbstractSession session) { // Make sure that each source key field is in the translation row. for (Enumeration sourceFieldsEnum = getSourceKeyFields().elements(); sourceFieldsEnum.hasMoreElements();) { DatabaseField sourceKey = (DatabaseField)sourceFieldsEnum.nextElement(); if (!translationRow.containsKey(sourceKey)) { Object value = descriptor.getObjectBuilder().extractValueFromObjectForField(object, sourceKey, session); translationRow.put(sourceKey, value); } } } /** * INTERNAL: * Used by DirectMapMapping to rebuild select query. */ protected void initOrRebuildSelectQuery() { this.selectionQuery.setSQLStatement(new SQLSelectStatement()); } /** * INTERNAL: * Overridden by mappings that require additional processing of the change record after the record has been calculated. */ @Override public void recordPrivateOwnedRemovals(Object object, UnitOfWorkImpl uow) { } /** * INTERNAL: * Once descriptors are serialized to the remote session. All its mappings and reference descriptors are traversed. Usually * mappings are initialized and serialized reference descriptors are replaced with local descriptors if they already exist on the * remote session. */ @Override public void remoteInitialization(DistributedSession session) { // Remote mappings is initialized here again because while serializing only the uninitialized data is passed // as the initialized data is not serializable. if (!isRemotelyInitialized()) { getAttributeAccessor().initializeAttributes(getDescriptor().getJavaClass()); remotelyInitialized(); } } /** * INTERNAL: * replace the value holders in the specified reference object(s) */ @Override public Map replaceValueHoldersIn(Object object, RemoteSessionController controller) { // do nothing, since direct collections do not hold onto other domain objects return null; } /** * PUBLIC: * Some databases do not properly support all of the base data types. For these databases, * the base data type must be explicitly specified in the mapping to tell EclipseLink to force * the instance variable value to that data type. * @since Java Persistence API 2.0 * Migrated from AbstractDirectMapping */ public void setAttributeClassification(Class attributeClassification) { this.attributeClassification = attributeClassification; } /** * INTERNAL: * Set the name of the class for MW usage. * @since Java Persistence API 2.0 * Migrated from AbstractDirectMapping */ public void setAttributeClassificationName(String attributeClassificationName) { this.attributeClassificationName = attributeClassificationName; } protected void setDeleteQuery(ModifyQuery query) { this.changeSetDeleteQuery = query; } /** * PUBLIC: * Set the receiver's delete SQL string. This allows the user to override the SQL * generated by TopLink, with there own SQL or procedure call. The arguments are * translated from the fields of the source row, through replacing the field names * marked by '#' with the values for those fields. * This SQL is responsible for doing the deletion required by the mapping, * such as deletion from join table for M-M. * Example, 'delete from RESPONS where EMP_ID = #EMP_ID and DESCRIP = #DESCRIP'. */ public void setDeleteSQLString(String sqlString) { DataModifyQuery query = new DataModifyQuery(); query.setSQLString(sqlString); setCustomDeleteQuery(query); } /** * ADVANCED: * Configure the mapping to use a container policy. * The policy manages the access to the collection. */ @Override public void setContainerPolicy(ContainerPolicy containerPolicy) { this.containerPolicy = containerPolicy; if (this.selectionQuery.isDataReadQuery()){ ((DataReadQuery) getSelectionQuery()).setContainerPolicy(containerPolicy); } } /** * PUBLIC: * The default delete query for this mapping can be overridden by specifying the new query. * This query is responsible for doing the deletion required by the mapping, * such as deletion from join table for M-M. The query should delete a specific row from the * DirectCollectionTable bases on the DirectField. */ public void setCustomDeleteQuery(ModifyQuery query) { setDeleteQuery(query); setHasCustomDeleteQuery(true); } /** * PUBLIC: * The default delete by index query for this mapping can be overridden by specifying the new query. * This query used (only in case listOrderField != null) to delete object with particular orderFieldValue. */ public void setCustomDeleteAtIndexQuery(ModifyQuery query) { this.deleteAtIndexQuery = query; hasCustomDeleteAtIndexQuery = true; } /** * PUBLIC: * The default insert query for mapping can be overridden by specifying the new query. * This query inserts the row into the direct table. */ public void setCustomInsertQuery(DataModifyQuery query) { setInsertQuery(query); setHasCustomInsertQuery(true); } /** * PUBLIC: * The default delete by index query for this mapping can be overridden by specifying the new query. * This query used (only in case listOrderField != null) to update orderFieldValue of object with particular orderFieldValue. */ public void setCustomUpdateAtIndexQuery(ModifyQuery query) { this.updateAtIndexQuery = query; hasCustomUpdateAtIndexQuery = true; } /** * PUBLIC: * Set the direct field in the reference table. * This is the field that the primitive data value is stored in. */ public void setDirectField(DatabaseField field) { directField = field; } /** * ADVANCED: * Set the class type of the field value. * This can be used if field value differs from the object value, * has specific typing requirements such as usage of java.sql.Blob or NChar. * This must be called after the field name has been set. */ public void setDirectFieldClassification(Class fieldType) { getDirectField().setType(fieldType); } /** * ADVANCED: * Set the class type of the field value. * This can be used if field value differs from the object value, * has specific typing requirements such as usage of java.sql.Blob or NChar. * This must be called after the field name has been set. */ public void setDirectFieldClassificationName(String className) { getDirectField().setTypeName(className); } /** * PUBLIC: * Set the direct field name in the reference table. * This is the field that the primitive data value is stored in. */ public void setDirectFieldName(String fieldName) { setDirectField(new DatabaseField(fieldName)); } protected void setHasCustomDeleteQuery(boolean bool) { hasCustomDeleteQuery = bool; } protected void setHasCustomInsertQuery(boolean bool) { hasCustomInsertQuery = bool; } protected void setInsertQuery(DataModifyQuery insertQuery) { this.insertQuery = insertQuery; } /** * PUBLIC: * Set the receiver's insert SQL string. This allows the user to override the SQL * generated by TopLink, with there own SQL or procedure call. The arguments are * translated from the fields of the source row, through replacing the field names * marked by '#' with the values for those fields. * This is used to insert an entry into the direct table. *

Example, 'insert into RESPONS (EMP_ID, RES_DESC) values (#EMP_ID, #RES_DESC)'. */ public void setInsertSQLString(String sqlString) { DataModifyQuery query = new DataModifyQuery(); query.setSQLString(sqlString); setCustomInsertQuery(query); } /** * INTERNAL: * This cannot be used with direct collection mappings. */ @Override public void setReferenceClass(Class referenceClass) { return; } @Override public void setReferenceClassName(String referenceClassName) { return; } /** * PUBLIC: * Set the name of the reference key field. * This is the foreign key field in the direct table referencing the primary key of the source object. * This method is used if the reference key consists of only a single field. */ public void setReferenceKeyFieldName(String fieldName) { getReferenceKeyFields().addElement(new DatabaseField(fieldName)); } /** * INTERNAL: * Set the reference key field names associated with the mapping. * These must be in-order with the sourceKeyFieldNames. */ public void setReferenceKeyFieldNames(Vector fieldNames) { Vector fields = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(fieldNames.size()); for (Enumeration fieldNamesEnum = fieldNames.elements(); fieldNamesEnum.hasMoreElements();) { fields.addElement(new DatabaseField((String)fieldNamesEnum.nextElement())); } setReferenceKeyFields(fields); } /** * INTERNAL: * Set the reference fields. */ public void setReferenceKeyFields(Vector aVector) { this.referenceKeyFields = aVector; } /** * INTERNAL: * Set the reference table. */ public void setReferenceTable(DatabaseTable table) { referenceTable = table; } /** * PUBLIC: * Sets the selection criteria to be used as a where clause to read * reference objects. This criteria is automatically generated by the * TopLink if not explicitly specified by the user. */ @Override public void setSelectionCriteria(Expression anExpression) { if (getSelectionQuery().isReadAllQuery()){ ((ReadAllQuery)getSelectionQuery()).setSelectionCriteria(anExpression); } else { getSelectionQuery().getSQLStatement().setWhereClause(anExpression); } } /** * PUBLIC: * Set the reference table name. */ public void setReferenceTableName(String tableName) { if (tableName == null) { setReferenceTable(null); } else { setReferenceTable(new DatabaseTable(tableName)); } } /** * INTERNAL: * Set the container policy on the selection query for this mapping. */ @Override protected void setSelectionQueryContainerPolicy(ContainerPolicy containerPolicy) { ((DataReadQuery) getSelectionQuery()).setContainerPolicy(containerPolicy); } /** * PUBLIC: * Support history on the reference table. */ public void setHistoryPolicy(HistoryPolicy policy) { this.historyPolicy = policy; if (policy != null) { policy.setMapping(this); } } /** * PUBLIC: * Set the name of the session to execute the mapping's queries under. * This can be used by the session broker to override the default session * to be used for the target class. */ @Override public void setSessionName(String name) { super.setSessionName(name); getInsertQuery().setSessionName(name); } /** * INTERNAL: * Set the source key field names associated with the mapping. * These must be in-order with the referenceKeyFieldNames. */ public void setSourceKeyFieldNames(Vector fieldNames) { Vector fields = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(fieldNames.size()); for (Enumeration fieldNamesEnum = fieldNames.elements(); fieldNamesEnum.hasMoreElements();) { fields.addElement(new DatabaseField((String)fieldNamesEnum.nextElement())); } setSourceKeyFields(fields); } /** * INTERNAL: * Set the source fields. */ public void setSourceKeyFields(Vector sourceKeyFields) { this.sourceKeyFields = sourceKeyFields; } /** * INTERNAL: * This method is used to store the FK fields that can be cached that correspond to noncacheable mappings * the FK field values will be used to re-issue the query when cloning the shared cache entity */ @Override public void collectQueryParameters(Set cacheFields){ for (DatabaseField field : getSourceKeyFields()) { cacheFields.add(field); } } /** * INTERNAL: * Used by AttributeLevelChangeTracking to update a changeRecord with calculated changes * as apposed to detected changes. If an attribute can not be change tracked it's * changes can be detected through this process. */ @Override public void calculateDeferredChanges(ChangeRecord changeRecord, AbstractSession session) { DirectCollectionChangeRecord collectionRecord = (DirectCollectionChangeRecord)changeRecord; // TODO: Handle events that fired after collection was replaced. compareCollectionsForChange(collectionRecord.getOriginalCollection(), collectionRecord.getLatestCollection(), collectionRecord, session); } /** * 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. */ @Override public void simpleAddToCollectionChangeRecord(Object referenceKey, Object objectToAdd, ObjectChangeSet changeSet, AbstractSession session) { simpleAddToCollectionChangeRecord(objectToAdd, null, false, changeSet, session, true); } protected void simpleAddToCollectionChangeRecord(Object objectToAdd, Integer index, boolean isSet, ObjectChangeSet changeSet, AbstractSession session, boolean isChangeApplied) { DirectCollectionChangeRecord collectionChangeRecord = (DirectCollectionChangeRecord)changeSet.getChangesForAttributeNamed(getAttributeName()); if (collectionChangeRecord == null) { collectionChangeRecord = new DirectCollectionChangeRecord(changeSet); collectionChangeRecord.setAttribute(getAttributeName()); collectionChangeRecord.setMapping(this); changeSet.addChange(collectionChangeRecord); Object collection = getRealAttributeValueFromObject(changeSet.getUnitOfWorkClone(), session); if(this.listOrderField != null) { List originalListCopy = new ArrayList((List)collection); // collection already contains the added object - to bring it to the original state it should be removed if(index == null) { originalListCopy.remove(originalListCopy.size() - 1); } else { // intValue() is essential - otherwise invokes remove(Object) originalListCopy.remove(index.intValue()); } collectionChangeRecord.setOriginalCollection(originalListCopy); collectionChangeRecord.setLatestCollection(collection); } else { collectionChangeRecord.storeDatabaseCounts(collection, getContainerPolicy(), session); collectionChangeRecord.setFirstToAddAlreadyInCollection(isChangeApplied); } } if(!collectionChangeRecord.isDeferred() && this.listOrderField == null) { collectionChangeRecord.addAdditionChange(objectToAdd, Integer.valueOf(1)); } } /** * 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. */ @Override public void simpleRemoveFromCollectionChangeRecord(Object referenceKey, Object objectToRemove, ObjectChangeSet changeSet, AbstractSession session) { simpleRemoveFromCollectionChangeRecord(objectToRemove, null, false, changeSet, session, true); } protected void simpleRemoveFromCollectionChangeRecord(Object objectToRemove, Integer index, boolean isSet, ObjectChangeSet changeSet, AbstractSession session, boolean isChangeApplied) { DirectCollectionChangeRecord collectionChangeRecord = (DirectCollectionChangeRecord)changeSet.getChangesForAttributeNamed(getAttributeName()); if (collectionChangeRecord == null) { collectionChangeRecord = new DirectCollectionChangeRecord(changeSet); collectionChangeRecord.setAttribute(getAttributeName()); collectionChangeRecord.setMapping(this); changeSet.addChange(collectionChangeRecord); Object collection = getRealAttributeValueFromObject(changeSet.getUnitOfWorkClone(), session); if(this.listOrderField != null) { List originalListCopy = new ArrayList((List)collection); // collection already doesn't contain the removed object - to bring it to the original state it should be added or set back. // index is not null because IndirectList does remove through indexOf. if(isSet) { originalListCopy.set(index, objectToRemove); } else { originalListCopy.add(index, objectToRemove); } collectionChangeRecord.setOriginalCollection(originalListCopy); collectionChangeRecord.setLatestCollection(collection); } else { collectionChangeRecord.storeDatabaseCounts(collection, getContainerPolicy(), session); collectionChangeRecord.setFirstToRemoveAlreadyOutCollection(isChangeApplied); if(isSet) { collectionChangeRecord.setFirstToAddAlreadyInCollection(isChangeApplied); } } } if(!collectionChangeRecord.isDeferred() && this.listOrderField == null) { collectionChangeRecord.addRemoveChange(objectToRemove, Integer.valueOf(1)); } } /** * INTERNAL: * Either create a new change record or update with the new value. This is used * by attribute change tracking. * Specifically in a collection mapping this will be called when the customer * Set a new collection. In this case we will need to mark the change record * with the new and the old versions of the collection. * And mark the ObjectChangeSet with the attribute name then when the changes are calculated * force a compare on the collections to determine changes. */ @Override public void updateChangeRecord(Object clone, Object newValue, Object oldValue, ObjectChangeSet objectChangeSet, UnitOfWorkImpl uow) { DirectCollectionChangeRecord collectionChangeRecord = (DirectCollectionChangeRecord)objectChangeSet.getChangesForAttributeNamed(this.getAttributeName()); if (collectionChangeRecord == null) { collectionChangeRecord = new DirectCollectionChangeRecord(objectChangeSet); collectionChangeRecord.setAttribute(getAttributeName()); collectionChangeRecord.setMapping(this); objectChangeSet.addChange(collectionChangeRecord); } collectionChangeRecord.setIsDeferred(true); objectChangeSet.deferredDetectionRequiredOn(getAttributeName()); if (collectionChangeRecord.getOriginalCollection() == null) { collectionChangeRecord.recreateOriginalCollection(oldValue, uow); } collectionChangeRecord.setLatestCollection(newValue); } /** * INTERNAL: * Add or removes a new value and its change set to the collection change record based on the event passed in. This is used by * attribute change tracking. */ @Override public void updateCollectionChangeRecord(CollectionChangeEvent event, ObjectChangeSet changeSet, UnitOfWorkImpl uow) { if (event != null ) { //Letting the mapping create and add the ChangeSet to the ChangeRecord rather // than the policy, since the policy doesn't know how to handle DirectCollectionChangeRecord. // if ordering is to be supported in the future, check how the method in CollectionMapping is implemented Object value = event.getNewValue(); if (event.getChangeType() == CollectionChangeEvent.ADD) { simpleAddToCollectionChangeRecord(value, event.getIndex(), event.isSet(), changeSet, uow, event.isChangeApplied()); } else if (event.getChangeType() == CollectionChangeEvent.REMOVE) { simpleRemoveFromCollectionChangeRecord(value, event.getIndex(), event.isSet(), changeSet, uow, event.isChangeApplied()); } else { throw ValidationException.wrongCollectionChangeEventType(event.getChangeType()); } } } /** * PUBLIC: * It is illegal to use a Map as the container of a DirectCollectionMapping. Only * Collection containers are supported for DirectCollectionMappings. * @see org.eclipse.persistence.mappings.DirectMapMapping */ public void useMapClass(Class concreteClass, String methodName) { throw ValidationException.illegalUseOfMapInDirectCollection(this, concreteClass, methodName); } /** * INTERNAL: * Return the value of the reference attribute or a value holder. * Check whether the mapping's attribute should be optimized through batch and joining. * Overridden to support flashback/historical queries. */ @Override public Object valueFromRow(AbstractRecord row, JoinedAttributeManager joinManager, ObjectBuildingQuery sourceQuery, CacheKey cacheKey, AbstractSession session, boolean isTargetProtected, Boolean[] wasCacheUsed) throws DatabaseException { if (this.descriptor.getCachePolicy().isProtectedIsolation()) { if (this.isCacheable && isTargetProtected && cacheKey != null) { //cachekey will be null when isolating to uow //used cached collection Object result = null; Object cached = cacheKey.getObject(); if (cached != null) { if (wasCacheUsed != null){ wasCacheUsed[0] = Boolean.TRUE; } return this.getAttributeValueFromObject(cached); } return result; } else if (!this.isCacheable && !isTargetProtected && cacheKey != null) { return this.indirectionPolicy.buildIndirectObject(new ValueHolder(null)); } } if (row.hasSopObject()) { return getAttributeValueFromObject(row.getSopObject()); } if (sourceQuery.isObjectLevelReadQuery() && (((ObjectLevelReadQuery)sourceQuery).isAttributeBatchRead(this.descriptor, getAttributeName()) || (sourceQuery.isReadAllQuery() && shouldUseBatchReading()))) { return batchedValueFromRow(row, (ObjectLevelReadQuery)sourceQuery, cacheKey); } if (shouldUseValueFromRowWithJoin(joinManager, sourceQuery)) { return valueFromRowInternalWithJoin(row, joinManager, sourceQuery, cacheKey, session, isTargetProtected); } // if the query uses batch reading, return a special value holder // or retrieve the object from the query property. ReadQuery targetQuery = getSelectionQuery(); boolean extendingPessimisticLockScope = isExtendingPessimisticLockScope(sourceQuery) && extendPessimisticLockScope == ExtendPessimisticLockScope.TARGET_QUERY; if ((getHistoryPolicy() != null) || (sourceQuery.getSession().getAsOfClause() != null) || ((sourceQuery.isObjectLevelReadQuery() && ((ObjectLevelReadQuery)sourceQuery).hasAsOfClause()) && (sourceQuery.shouldCascadeAllParts() || (sourceQuery.shouldCascadePrivateParts() && isPrivateOwned()) || (sourceQuery.shouldCascadeByMapping() && this.cascadeRefresh))) || extendingPessimisticLockScope) { targetQuery = (ReadQuery)targetQuery.clone(); // Code copied roughly from initializeSelectionStatement. SQLSelectStatement statement = new SQLSelectStatement(); statement.addTable(getReferenceTable()); statement.addField(getDirectField().clone()); if (isDirectMapMapping()) { statement.addField(((DirectMapMapping)this).getDirectKeyField().clone()); } statement.setWhereClause((Expression)getSelectionCriteria().clone()); if (sourceQuery.isObjectLevelReadQuery()) { statement.getBuilder().asOf(((ObjectLevelReadQuery)sourceQuery).getAsOfClause()); } if (extendingPessimisticLockScope) { statement.setLockingClause(new ForUpdateClause(sourceQuery.getLockMode())); } if (getHistoryPolicy() != null) { ExpressionBuilder builder = statement.getBuilder(); if (sourceQuery.getSession().getAsOfClause() != null) { builder.asOf(sourceQuery.getSession().getAsOfClause()); } else if (builder.getAsOfClause() == null) { builder.asOf(AsOfClause.NO_CLAUSE); } Expression temporalExpression = getHistoryPolicy().additionalHistoryExpression(builder, builder); statement.setWhereClause(statement.getWhereClause().and(temporalExpression)); if (builder.hasAsOfClause()) { statement.getTables().set(0, getHistoryPolicy().getHistoricalTables().get(0)); } } statement.normalize(sourceQuery.getSession(), null); targetQuery.setSQLStatement(statement); } return getIndirectionPolicy().valueFromQuery(targetQuery, row, sourceQuery.getSession()); } /** * INTERNAL: * Checks if object is deleted from the database or not. */ @Override 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); } /** * INTERNAL: * DirectCollectionMapping contents should not be considered for addition to the UnitOfWork * private owned objects list for removal. */ @Override public boolean isCandidateForPrivateOwnedRemoval() { return false; } /** * INTERNAL * Return true if this mapping supports cascaded version optimistic locking. */ @Override public boolean isCascadedLockingSupported() { return true; } }





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