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/*
 * Copyright (c) 1998, 2020 Oracle and/or its affiliates. All rights reserved.
 *
 * This program and the accompanying materials are made available under the
 * terms of the Eclipse Public License v. 2.0 which is available at
 * http://www.eclipse.org/legal/epl-2.0,
 * or the Eclipse Distribution License v. 1.0 which is available at
 * http://www.eclipse.org/org/documents/edl-v10.php.
 *
 * SPDX-License-Identifier: EPL-2.0 OR BSD-3-Clause
 */

// Contributors:
//     Oracle - initial API and implementation from Oracle TopLink
//     07/19/2011-2.2.1 Guy Pelletier
//       - 338812: ManyToMany mapping in aggregate object violate integrity constraint on deletion
package org.eclipse.persistence.mappings;

import java.util.*;

import org.eclipse.persistence.descriptors.ClassDescriptor;
import org.eclipse.persistence.exceptions.*;
import org.eclipse.persistence.expressions.*;
import org.eclipse.persistence.history.*;
import org.eclipse.persistence.internal.expressions.*;
import org.eclipse.persistence.internal.helper.*;
import org.eclipse.persistence.internal.identitymaps.CacheKey;
import org.eclipse.persistence.internal.queries.*;
import org.eclipse.persistence.internal.sessions.*;
import org.eclipse.persistence.mappings.foundation.MapComponentMapping;
import org.eclipse.persistence.sessions.DatabaseRecord;
import org.eclipse.persistence.queries.*;

/**
 * 

Purpose: Many to many mappings are used to represent the relationships * between a collection of source objects and a collection of target objects. * The mapping requires the creation of an intermediate table for managing the * associations between the source and target records. * * @author Sati * @since TOPLink/Java 1.0 */ public class ManyToManyMapping extends CollectionMapping implements RelationalMapping, MapComponentMapping { /** Used for data modification events. */ protected static final String PostInsert = "postInsert"; protected static final String ObjectRemoved = "objectRemoved"; protected static final String ObjectAdded = "objectAdded"; /** Mechanism holds relationTable and all fields and queries associated with it. */ protected RelationTableMechanism mechanism; protected HistoryPolicy historyPolicy; /** * 266912: Since: EclipseLink 2.0 for the Metamodel API * For 1:1 and m:m mappings - track the original externally defined mapping if different * Note: This field will provide differentiation for the following * external to internal representations for mapping types
* - A OneToManyMapping will be represented by a ManyToManyMapping if unidirectional
* - A ManyToOneMapping will be represented by a OneToOneMapping (without a FK constraint)
*/ protected boolean isDefinedAsOneToManyMapping = false; /** * PUBLIC: * Default constructor. */ public ManyToManyMapping() { this.mechanism = new RelationTableMechanism(); this.isListOrderFieldSupported = true; } /** * INTERNAL: */ @Override public boolean isOwned(){ return !isReadOnly; } /** * INTERNAL: */ @Override public boolean isRelationalMapping() { return true; } /** * PUBLIC: * Add the fields in the intermediate table that corresponds to the primary * key in the source table. This method is used if the keys are composite. */ public void addSourceRelationKeyField(DatabaseField sourceRelationKeyField, DatabaseField sourcePrimaryKeyField) { this.mechanism.addSourceRelationKeyField(sourceRelationKeyField, sourcePrimaryKeyField); } /** * PUBLIC: * Add the fields in the intermediate table that corresponds to the primary * key in the source table. This method is used if the keys are composite. */ public void addSourceRelationKeyFieldName(String sourceRelationKeyFieldName, String sourcePrimaryKeyFieldName) { this.mechanism.addSourceRelationKeyFieldName(sourceRelationKeyFieldName, sourcePrimaryKeyFieldName); } /** * PUBLIC: * Add the fields in the intermediate table that corresponds to the primary * key in the target table. This method is used if the keys are composite. */ public void addTargetRelationKeyField(DatabaseField targetRelationKeyField, DatabaseField targetPrimaryKeyField) { this.mechanism.addTargetRelationKeyField(targetRelationKeyField, targetPrimaryKeyField); } /** * PUBLIC: * Add the fields in the intermediate table that corresponds to the primary * key in the target table. This method is used if the keys are composite. */ public void addTargetRelationKeyFieldName(String targetRelationKeyFieldName, String targetPrimaryKeyFieldName) { this.mechanism.addTargetRelationKeyFieldName(targetRelationKeyFieldName, targetPrimaryKeyFieldName); } /** * 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){ this.mechanism.collectQueryParameters(cacheFields); } /** * INTERNAL: * The mapping clones itself to create deep copy. */ @Override public Object clone() { ManyToManyMapping clone = (ManyToManyMapping)super.clone(); clone.mechanism = (RelationTableMechanism)this.mechanism.clone(); return clone; } /** * INTERNAL: * Delete join tables before the start of the deletion process to avoid constraint errors. */ @Override public void earlyPreDelete(DeleteObjectQuery query, Object object) { AbstractSession querySession = query.getSession(); if (!this.isCascadeOnDeleteSetOnDatabase) { prepareTranslationRow(query.getTranslationRow(), query.getObject(), query.getDescriptor(), querySession); querySession.executeQuery(this.deleteAllQuery, query.getTranslationRow()); } if ((this.historyPolicy != null) && this.historyPolicy.shouldHandleWrites()) { if (this.isCascadeOnDeleteSetOnDatabase) { prepareTranslationRow(query.getTranslationRow(), query.getObject(), query.getDescriptor(), querySession); } this.historyPolicy.mappingLogicalDelete(this.deleteAllQuery, query.getTranslationRow(), querySession); } } /** * INTERNAL * Called when a DatabaseMapping is used to map the key in a collection. Returns the key. */ @Override public Object createMapComponentFromRow(AbstractRecord dbRow, ObjectBuildingQuery query, CacheKey parentCacheKey, AbstractSession session, boolean isTargetProtected){ return session.executeQuery(getSelectionQuery(), dbRow); } /** * INTERNAL: * Adds locking clause to the target query to extend pessimistic lock scope. */ @Override protected void extendPessimisticLockScopeInTargetQuery(ObjectLevelReadQuery targetQuery, ObjectBuildingQuery sourceQuery) { this.mechanism.setRelationTableLockingClause(targetQuery, sourceQuery); } /** * INTERNAL: * Called only if both * shouldExtendPessimisticLockScope and shouldExtendPessimisticLockScopeInSourceQuery are true. * Adds fields to be locked to the where clause of the source query. * Note that the sourceQuery must be ObjectLevelReadQuery so that it has ExpressionBuilder. * * This method must be implemented in subclasses that allow * setting shouldExtendPessimisticLockScopeInSourceQuery to true. */ @Override public void extendPessimisticLockScopeInSourceQuery(ObjectLevelReadQuery sourceQuery) { Expression exp = sourceQuery.getSelectionCriteria(); exp = this.mechanism.joinRelationTableField(exp, sourceQuery.getExpressionBuilder()); sourceQuery.setSelectionCriteria(exp); } /** * INTERNAL: * Extract the source primary key value from the relation row. * Used for batch reading, most following same order and fields as in the mapping. */ @Override protected Object extractKeyFromTargetRow(AbstractRecord row, AbstractSession session) { return this.mechanism.extractKeyFromTargetRow(row, session); } /** * 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) { return this.mechanism.extractBatchKeyFromRow(row, session); } /** * INTERNAL: * Return the selection criteria used to IN batch fetching. */ @Override protected Expression buildBatchCriteria(ExpressionBuilder builder, ObjectLevelReadQuery query) { return this.mechanism.buildBatchCriteria(builder, query); } /** * INTERNAL: * Add additional fields and check for history. */ @Override protected void postPrepareNestedBatchQuery(ReadQuery batchQuery, ObjectLevelReadQuery query) { super.postPrepareNestedBatchQuery(batchQuery, query); ReadAllQuery mappingBatchQuery = (ReadAllQuery)batchQuery; this.mechanism.postPrepareNestedBatchQuery(batchQuery, query); if (this.historyPolicy != null) { ExpressionBuilder builder = mappingBatchQuery.getExpressionBuilder(); Expression twisted = batchQuery.getSelectionCriteria(); if (query.getSession().getAsOfClause() != null) { builder.asOf(query.getSession().getAsOfClause()); } else if (builder.getAsOfClause() == null) { builder.asOf(AsOfClause.NO_CLAUSE); } twisted = twisted.and(this.historyPolicy.additionalHistoryExpression(builder, builder)); mappingBatchQuery.setSelectionCriteria(twisted); } } /** * INTERNAL: * Return the base expression to use for adding fields to the query. * Normally this is the query's builder, but may be the join table for m-m. */ @Override protected Expression getAdditionalFieldsBaseExpression(ReadQuery query) { return ((ReadAllQuery)query).getExpressionBuilder().getTable(getRelationTable()); } protected DataModifyQuery getDeleteQuery() { return this.mechanism.getDeleteQuery(); } /** * INTERNAL: * Should be overridden by subclass that allows setting * extendPessimisticLockScope to DEDICATED_QUERY. */ @Override protected ReadQuery getExtendPessimisticLockScopeDedicatedQuery(AbstractSession session, short lockMode) { if(this.mechanism != null) { return this.mechanism.getLockRelationTableQueryClone(session, lockMode); } else { return super.getExtendPessimisticLockScopeDedicatedQuery(session, lockMode); } } /** * INTERNAL: * Return source key fields for translation by an AggregateObjectMapping */ @Override public Collection getFieldsForTranslationInAggregate() { return getRelationTableMechanism().getSourceKeyFields(); } protected DataModifyQuery getInsertQuery() { return this.mechanism.getInsertQuery(); } /** * 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); } } /** * PUBLIC: * Allows history tracking on the m-m join table. */ public HistoryPolicy getHistoryPolicy() { return historyPolicy; } /** * PUBLIC: * Returns RelationTableMechanism that may be owned by the mapping. * Note that all RelationTableMechanism methods are accessible * through the mapping directly. * The only reason this method is provided * is to allow a uniform approach to RelationTableMechanism * in both ManyToManyMapping and OneToOneMapping * that uses RelationTableMechanism. */ public RelationTableMechanism getRelationTableMechanism() { return this.mechanism; } /** * INTERNAL: * Return the relation table associated with the mapping. */ public DatabaseTable getRelationTable() { return this.mechanism.getRelationTable(); } /** * PUBLIC: * Return the relation table name associated with the mapping. */ public String getRelationTableName() { return this.mechanism.getRelationTableName(); } //CR#2407 This method is added to include table qualifier. /** * PUBLIC: * Return the relation table qualified name associated with the mapping. */ public String getRelationTableQualifiedName() { return this.mechanism.getRelationTableQualifiedName(); } /** * PUBLIC: * Return the source key field names associated with the mapping. * These are in-order with the sourceRelationKeyFieldNames. */ public Vector getSourceKeyFieldNames() { return this.mechanism.getSourceKeyFieldNames(); } /** * INTERNAL: * Return all the source key fields associated with the mapping. */ public Vector getSourceKeyFields() { return this.mechanism.getSourceKeyFields(); } /** * PUBLIC: * Return the source relation key field names associated with the mapping. * These are in-order with the sourceKeyFieldNames. */ public Vector getSourceRelationKeyFieldNames() { return this.mechanism.getSourceRelationKeyFieldNames(); } /** * INTERNAL: * Return all the source relation key fields associated with the mapping. */ public Vector getSourceRelationKeyFields() { return this.mechanism.getSourceRelationKeyFields(); } /** * PUBLIC: * Return the target key field names associated with the mapping. * These are in-order with the targetRelationKeyFieldNames. */ public Vector getTargetKeyFieldNames() { return this.mechanism.getTargetKeyFieldNames(); } /** * INTERNAL: * Return all the target keys associated with the mapping. */ public Vector getTargetKeyFields() { return this.mechanism.getTargetKeyFields(); } /** * PUBLIC: * Return the target relation key field names associated with the mapping. * These are in-order with the targetKeyFieldNames. */ public Vector getTargetRelationKeyFieldNames() { return this.mechanism.getTargetRelationKeyFieldNames(); } /** * INTERNAL: * Return all the target relation key fields associated with the mapping. */ public Vector getTargetRelationKeyFields() { return this.mechanism.getTargetRelationKeyFields(); } protected boolean hasCustomDeleteQuery() { return this.mechanism.hasCustomDeleteQuery(); } protected boolean hasCustomInsertQuery() { return this.mechanism.hasCustomInsertQuery(); } /** * INTERNAL: * The join table is a dependency if not read-only. */ @Override public boolean hasDependency() { return this.isPrivateOwned || (!this.isReadOnly); } /** * INTERNAL: * Initialize mappings */ @Override public void initialize(AbstractSession session) throws DescriptorException { if (session.hasBroker()) { if (getReferenceClass() == null) { throw DescriptorException.referenceClassNotSpecified(this); } // substitute session that owns the mapping for the session that owns reference descriptor. session = session.getBroker().getSessionForClass(getReferenceClass()); } super.initialize(session); getDescriptor().addPreDeleteMapping(this); if(this.mechanism != null) { this.mechanism.initialize(session, this); } else { throw DescriptorException.noRelationTableMechanism(this); } if (shouldInitializeSelectionCriteria()) { if (shouldForceInitializationOfSelectionCriteria()) { initializeSelectionCriteriaAndAddFieldsToQuery(null); } else { initializeSelectionCriteriaAndAddFieldsToQuery(getSelectionCriteria()); } } if (!getSelectionQuery().hasSessionName()) { getSelectionQuery().setSessionName(session.getName()); } initializeDeleteAllQuery(session); if (getHistoryPolicy() != null) { getHistoryPolicy().initialize(session); } } /** * INTERNAL: * Verifies listOrderField's table: it must be relation table. * Precondition: listOrderField != null. */ @Override protected void buildListOrderField() { if(this.listOrderField.hasTableName()) { if(!getRelationTable().equals(this.listOrderField.getTable())) { throw DescriptorException.listOrderFieldTableIsWrong(this.getDescriptor(), this, this.listOrderField.getTable(), getRelationTable()); } } else { listOrderField.setTable(getRelationTable()); } this.listOrderField = getDescriptor().buildField(this.listOrderField, getRelationTable()); } /** * INTERNAL: * Indicates whether getListOrderFieldExpression method should create field expression on table expression. */ @Override public boolean shouldUseListOrderFieldTableExpression() { return true; } /** * INTERNAL: * Initialize changeOrderTargetQuery. */ @Override protected void initializeChangeOrderTargetQuery(AbstractSession session) { boolean hasChangeOrderTargetQuery = changeOrderTargetQuery != null; if(!hasChangeOrderTargetQuery) { changeOrderTargetQuery = new DataModifyQuery(); } changeOrderTargetQuery = new DataModifyQuery(); if (!changeOrderTargetQuery.hasSessionName()) { changeOrderTargetQuery.setSessionName(session.getName()); } if (hasChangeOrderTargetQuery) { return; } // Build where clause expression. Expression whereClause = null; Expression builder = new ExpressionBuilder(); List sourceRelationKeyFields = getSourceRelationKeyFields(); int size = sourceRelationKeyFields.size(); for (int index = 0; index < size; index++) { DatabaseField sourceRelationKeyField = sourceRelationKeyFields.get(index); Expression expression = builder.getField(sourceRelationKeyField).equal(builder.getParameter(sourceRelationKeyField)); whereClause = expression.and(whereClause); } List targetRelationKeyFields = getTargetRelationKeyFields(); size = targetRelationKeyFields.size(); for (int index = 0; index < size; index++) { DatabaseField targetRelationKeyField = targetRelationKeyFields.get(index); Expression expression = builder.getField(targetRelationKeyField).equal(builder.getParameter(targetRelationKeyField)); whereClause = expression.and(whereClause); } AbstractRecord modifyRow = new DatabaseRecord(); modifyRow.add(listOrderField, null); SQLUpdateStatement statement = new SQLUpdateStatement(); statement.setTable(listOrderField.getTable()); statement.setWhereClause(whereClause); statement.setModifyRow(modifyRow); changeOrderTargetQuery.setSQLStatement(statement); } /** * Initialize delete all query. This query is used to all relevant rows from the * relation table. */ protected void initializeDeleteAllQuery(AbstractSession session) { if (!getDeleteAllQuery().hasSessionName()) { getDeleteAllQuery().setSessionName(session.getName()); } getDeleteAllQuery().setName(getAttributeName()); if (getDeleteAllQuery().getPartitioningPolicy() == null) { getDeleteAllQuery().setPartitioningPolicy(getPartitioningPolicy()); } if (hasCustomDeleteAllQuery()) { return; } Expression expression = null; Expression subExpression; Expression builder = new ExpressionBuilder(); SQLDeleteStatement statement = new SQLDeleteStatement(); // Construct an expression to delete from the relation table. for (int index = 0; index < getSourceRelationKeyFields().size(); index++) { DatabaseField sourceRelationKey = getSourceRelationKeyFields().elementAt(index); DatabaseField sourceKey = getSourceKeyFields().elementAt(index); subExpression = builder.getField(sourceRelationKey).equal(builder.getParameter(sourceKey)); expression = subExpression.and(expression); } // All the entries are deleted in one shot. statement.setWhereClause(expression); statement.setTable(getRelationTable()); getDeleteAllQuery().setSQLStatement(statement); } /** * INTERNAL: * Initializes listOrderField's table. * Precondition: listOrderField != null. */ @Override protected void initializeListOrderFieldTable(AbstractSession session) { this.mechanism.initializeRelationTable(session, this); } /** * INTERNAL: * Selection criteria is created to read target records from the table. */ protected void initializeSelectionCriteriaAndAddFieldsToQuery(Expression startCriteria) { setSelectionCriteria(this.mechanism.buildSelectionCriteriaAndAddFieldsToQuery(this, startCriteria)); } /** * INTERNAL: * An object was added to the collection during an update, insert it. */ protected void insertAddedObjectEntry(ObjectLevelModifyQuery query, Object objectAdded, Map extraData) throws DatabaseException, OptimisticLockException { //cr 3819 added the line below to fix the translationtable to ensure that it // contains the required values prepareTranslationRow(query.getTranslationRow(), query.getObject(), query.getDescriptor(), query.getSession()); AbstractRecord databaseRow = this.mechanism.buildRelationTableSourceAndTargetRow(query.getTranslationRow(), containerPolicy.unwrapIteratorResult(objectAdded), query.getSession(), this); ContainerPolicy.copyMapDataToRow(getContainerPolicy().getKeyMappingDataForWriteQuery(objectAdded, query.getSession()), databaseRow); if(listOrderField != null && extraData != null) { databaseRow.put(listOrderField, extraData.get(listOrderField)); } query.getExecutionSession().executeQuery(this.mechanism.getInsertQuery(), databaseRow); if ((getHistoryPolicy() != null) && getHistoryPolicy().shouldHandleWrites()) { getHistoryPolicy().mappingLogicalInsert(this.mechanism.getInsertQuery(), databaseRow, query.getSession()); } } /** * INTERNAL: * Insert into relation table. This follows following steps. *

- Extract primary key and its value from the source object. *

- Extract target key and its value from the target object. *

- Construct a insert statement with above fields and values for relation table. *

- execute the statement. *

- Repeat above three statements until all the target objects are done. */ public void insertIntoRelationTable(WriteObjectQuery query) throws DatabaseException { if (isReadOnly()) { return; } ContainerPolicy cp = getContainerPolicy(); Object objects = getRealCollectionAttributeValueFromObject(query.getObject(), query.getSession()); if (cp.isEmpty(objects)) { return; } prepareTranslationRow(query.getTranslationRow(), query.getObject(), query.getDescriptor(), query.getSession()); AbstractRecord databaseRow = this.mechanism.buildRelationTableSourceRow(query.getTranslationRow()); int orderIndex = 0; // Extract target field and its value. Construct insert statement and execute it for (Object iter = cp.iteratorFor(objects); cp.hasNext(iter);) { Object wrappedObject = cp.nextEntry(iter, query.getSession()); Object object = cp.unwrapIteratorResult(wrappedObject); databaseRow = this.mechanism.addRelationTableTargetRow(object, query.getExecutionSession(), databaseRow, this); ContainerPolicy.copyMapDataToRow(cp.getKeyMappingDataForWriteQuery(wrappedObject, query.getSession()), databaseRow); if(listOrderField != null) { databaseRow.put(listOrderField, orderIndex++); } query.getExecutionSession().executeQuery(this.mechanism.getInsertQuery(), databaseRow); if ((getHistoryPolicy() != null) && getHistoryPolicy().shouldHandleWrites()) { getHistoryPolicy().mappingLogicalInsert(this.mechanism.getInsertQuery(), databaseRow, query.getSession()); } } } /** * INTERNAL: * Write the target objects if the cascade policy requires them to be written first. * They must be written within a unit of work to ensure that they exist. */ public void insertTargetObjects(WriteObjectQuery query) throws DatabaseException, OptimisticLockException { if (!shouldObjectModifyCascadeToParts(query)) { return; } // Only cascade dependents writes in uow. if (query.shouldCascadeOnlyDependentParts()) { return; } Object objects = getRealCollectionAttributeValueFromObject(query.getObject(), query.getSession()); ContainerPolicy cp = getContainerPolicy(); if (cp.isEmpty(objects)) { return; } // Write each of the target objects for (Object objectsIterator = cp.iteratorFor(objects); cp.hasNext(objectsIterator);) { Object wrappedObject = cp.next(objectsIterator, query.getSession()); Object object = cp.unwrapIteratorResult(wrappedObject); if (isPrivateOwned()) { // no need to set changeset as insert is a straight copy anyway InsertObjectQuery insertQuery = new InsertObjectQuery(); insertQuery.setIsExecutionClone(true); insertQuery.setObject(object); insertQuery.setCascadePolicy(query.getCascadePolicy()); query.getSession().executeQuery(insertQuery); } else { ObjectChangeSet changeSet = null; UnitOfWorkChangeSet uowChangeSet = null; if (query.getSession().isUnitOfWork() && (((UnitOfWorkImpl)query.getSession()).getUnitOfWorkChangeSet() != null)) { uowChangeSet = (UnitOfWorkChangeSet)((UnitOfWorkImpl)query.getSession()).getUnitOfWorkChangeSet(); changeSet = (ObjectChangeSet)uowChangeSet.getObjectChangeSetForClone(object); } WriteObjectQuery writeQuery = new WriteObjectQuery(); writeQuery.setIsExecutionClone(true); writeQuery.setObject(object); writeQuery.setObjectChangeSet(changeSet); writeQuery.setCascadePolicy(query.getCascadePolicy()); query.getSession().executeQuery(writeQuery); } cp.propogatePostInsert(query, wrappedObject); } } /** * INTERNAL: * Return whether this mapping was originally defined as a OneToMany. */ public boolean isDefinedAsOneToManyMapping() { return isDefinedAsOneToManyMapping; } /** * INTERNAL: * Return if this mapping support joining. */ @Override public boolean isJoiningSupported() { return true; } @Override public boolean isManyToManyMapping() { return true; } /** * INTERNAL: * Ensure the container policy is post initialized */ @Override public void postInitialize(AbstractSession session) { super.postInitialize(session); this.mustDeleteReferenceObjectsOneByOne = true; } /** * INTERNAL: * An object was added to the collection during an update, insert it if private. */ @Override protected void objectAddedDuringUpdate(ObjectLevelModifyQuery query, Object objectAdded, ObjectChangeSet changeSet, Map extraData) throws DatabaseException, OptimisticLockException { // First insert/update object. super.objectAddedDuringUpdate(query, objectAdded, changeSet, extraData); // 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[4]; event[0] = ObjectAdded; event[1] = query; event[2] = objectAdded; event[3] = extraData; query.getSession().getCommitManager().addDataModificationEvent(this, event); } else { insertAddedObjectEntry(query, objectAdded, extraData); } } /** * INTERNAL: * An object was removed to the collection during an update, delete it if private. */ @Override protected void objectRemovedDuringUpdate(ObjectLevelModifyQuery query, Object objectDeleted, Map extraData) throws DatabaseException, OptimisticLockException { Object unwrappedObjectDeleted = getContainerPolicy().unwrapIteratorResult(objectDeleted); AbstractRecord databaseRow = this.mechanism.buildRelationTableSourceAndTargetRow(query.getTranslationRow(), unwrappedObjectDeleted, query.getSession(), this); // 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] = ObjectRemoved; event[1] = this.mechanism.getDeleteQuery(); event[2] = databaseRow; query.getSession().getCommitManager().addDataModificationEvent(this, event); } else { query.getSession().executeQuery(this.mechanism.getDeleteQuery(), databaseRow); if ((getHistoryPolicy() != null) && getHistoryPolicy().shouldHandleWrites()) { getHistoryPolicy().mappingLogicalDelete(this.mechanism.getDeleteQuery(), databaseRow, query.getSession()); } } // Delete object after join entry is delete if private. super.objectRemovedDuringUpdate(query, objectDeleted, extraData); } @Override protected void objectOrderChangedDuringUpdate(WriteObjectQuery query, Object orderChangedObject, int orderIndex) { prepareTranslationRow(query.getTranslationRow(), query.getObject(), query.getDescriptor(), query.getSession()); AbstractRecord databaseRow = this.mechanism.buildRelationTableSourceAndTargetRow(query.getTranslationRow(), orderChangedObject, query.getSession(), this); databaseRow.put(listOrderField, orderIndex); query.getSession().executeQuery(changeOrderTargetQuery, databaseRow); } /** * 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] == PostInsert) { insertIntoRelationTable((WriteObjectQuery)event[1]); } else if (event[0] == ObjectRemoved) { 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] == ObjectAdded) { insertAddedObjectEntry((WriteObjectQuery)event[1], event[2], (Map)event[3]); } else { throw DescriptorException.invalidDataModificationEventCode(event[0], this); } } /** * INTERNAL: * Insert into relation table. This follows following steps. *

- Extract primary key and its value from the source object. *

- Extract target key and its value from the target object. *

- Construct a insert statement with above fields and values for relation table. *

- execute the statement. *

- Repeat above three statements until all the target objects are done. */ @Override public void postInsert(WriteObjectQuery query) throws DatabaseException { insertTargetObjects(query); // Batch data modification in the uow if (query.shouldCascadeOnlyDependentParts()) { // Hey I might actually want to use an inner class here... ok array for now. Object[] event = new Object[2]; event[0] = PostInsert; event[1] = query; query.getSession().getCommitManager().addDataModificationEvent(this, event); } else { insertIntoRelationTable(query); } } /** * INTERNAL: * Update the relation table with the entries related to this mapping. * Delete entries removed, insert entries added. * If private also insert/delete/update target objects. */ @Override public void postUpdate(WriteObjectQuery query) throws DatabaseException { if (this.isReadOnly) { return; } // If objects are not instantiated that means they are not changed. if (!isAttributeValueInstantiatedOrChanged(query.getObject())) { return; } if (query.getObjectChangeSet() != null) { // UnitOfWork writeChanges(query.getObjectChangeSet(), query); } else { // OLD COMMIT compareObjectsAndWrite(query); } } /** * INTERNAL: * Delete entries related to this mapping from the relation table. */ @Override public void preDelete(DeleteObjectQuery query) throws DatabaseException { AbstractSession session = query.getSession(); Object objectsIterator = null; ContainerPolicy containerPolicy = getContainerPolicy(); if (this.isReadOnly) { return; } Object objects = null; boolean cascade = shouldObjectModifyCascadeToParts(query); if (containerPolicy.propagatesEventsToCollection() || cascade) { // if processed during UnitOfWork commit process the private owned delete will occur during change calculation objects = getRealCollectionAttributeValueFromObject(query.getObject(), session); //this must be done up here because the select must be done before the entry in the relation table is deleted. // TODO: Hmm given the below code, the rows are already deleted, so this code is broken. // Assuming it was a cascade remove, it will have been instantiated, so may be ok? objectsIterator = containerPolicy.iteratorFor(objects); } // This has already been done in a unit of work. if (!session.isUnitOfWork()) { earlyPreDelete(query, query.getObject()); } // If privately owned delete the objects, this does not handle removed objects (i.e. verify delete, not req in uow). // Does not try to optimize delete all like 1-m, (rarely used and hard to do). if (containerPolicy.propagatesEventsToCollection() || cascade) { if (objects != null) { //objectsIterator will not be null because cascade check will still return true. while (containerPolicy.hasNext(objectsIterator)) { Object wrappedObject = containerPolicy.nextEntry(objectsIterator, session); Object object = containerPolicy.unwrapIteratorResult(wrappedObject); if (cascade){ // PERF: Avoid query execution if already deleted. if (!session.getCommitManager().isCommitCompletedInPostOrIgnore(object)) { DeleteObjectQuery deleteQuery = new DeleteObjectQuery(); deleteQuery.setIsExecutionClone(true); deleteQuery.setObject(object); deleteQuery.setCascadePolicy(query.getCascadePolicy()); session.executeQuery(deleteQuery); } } containerPolicy.propogatePreDelete(query, wrappedObject); } } } } /** * 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); } } } /** * PUBLIC: * The default delete query for mapping can be overridden by specifying the new query. * This query must delete the row from the M-M join table. */ public void setCustomDeleteQuery(DataModifyQuery query) { this.mechanism.setCustomDeleteQuery(query); } /** * PUBLIC: * The default insert query for mapping can be overridden by specifying the new query. * This query must insert the row into the M-M join table. */ public void setCustomInsertQuery(DataModifyQuery query) { this.mechanism.setCustomInsertQuery(query); } protected void setDeleteQuery(DataModifyQuery deleteQuery) { this.mechanism.setDeleteQuery(deleteQuery); } /** * 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 is used to delete a single entry from the M-M join table. * Example, 'delete from PROJ_EMP where PROJ_ID = #PROJ_ID AND EMP_ID = #EMP_ID'. */ public void setDeleteSQLString(String sqlString) { this.mechanism.setDeleteSQLString(sqlString); } /** * INTERNAL: * Set whether this mapping was originally defined as a OneToMany * @param isDefinedAsOneToManyMapping */ public void setDefinedAsOneToManyMapping(boolean isDefinedAsOneToManyMapping) { this.isDefinedAsOneToManyMapping = isDefinedAsOneToManyMapping; } /** * PUBLIC: * Set the receiver's delete Call. 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. * This is used to delete a single entry from the M-M join table. * Example, 'new SQLCall("delete from PROJ_EMP where PROJ_ID = #PROJ_ID AND EMP_ID = #EMP_ID")'. */ public void setDeleteCall(Call call) { this.mechanism.setDeleteCall(call); } protected void setInsertQuery(DataModifyQuery insertQuery) { this.mechanism.setInsertQuery(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 M-M join table. * Example, 'insert into PROJ_EMP (EMP_ID, PROJ_ID) values (#EMP_ID, #PROJ_ID)'. */ public void setInsertSQLString(String sqlString) { this.mechanism.setInsertSQLString(sqlString); } /** * PUBLIC: * Set the receiver's insert Call. 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. * This is used to insert an entry into the M-M join table. * Example, 'new SQLCall("insert into PROJ_EMP (EMP_ID, PROJ_ID) values (#EMP_ID, #PROJ_ID)")'. */ public void setInsertCall(Call call) { this.mechanism.setInsertCall(call); } /** * PUBLIC: * Allows to set RelationTableMechanism to be owned by the mapping. * It's not necessary to explicitly set the mechanism: * one is created by mapping's constructor. * The only reason this method is provided * is to allow a uniform approach to RelationTableMechanism * in both ManyToManyMapping and OneToOneMapping * that uses RelationTableMechanism. * ManyToManyMapping must have RelationTableMechanism, * never set it to null. */ void setRelationTableMechanism(RelationTableMechanism mechanism) { this.mechanism = mechanism; } /** * PUBLIC: * Set the relational table. * This is the join table that store both the source and target primary keys. */ public void setRelationTable(DatabaseTable relationTable) { this.mechanism.setRelationTable(relationTable); } /** * PUBLIC: * Enable history tracking on the m-m join table. */ public void setHistoryPolicy(HistoryPolicy policy) { this.historyPolicy = policy; if (policy != null) { policy.setMapping(this); } } /** * PUBLIC: * Set the name of the relational table. * This is the join table that store both the source and target primary keys. */ public void setRelationTableName(String tableName) { this.mechanism.setRelationTableName(tableName); } /** * 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); this.mechanism.setSessionName(name); } /** * PUBLIC: * Set the source key field names associated with the mapping. * These must be in-order with the sourceRelationKeyFieldNames. */ public void setSourceKeyFieldNames(Vector fieldNames) { this.mechanism.setSourceKeyFieldNames(fieldNames); } /** * INTERNAL: * Set the source fields. */ public void setSourceKeyFields(Vector sourceKeyFields) { this.mechanism.setSourceKeyFields(sourceKeyFields); } /** * PUBLIC: * Set the source key field in the relation table. * This is the name of the foreign key in the relation table to the source's primary key field. * This method is used if the source primary key is a singleton only. */ public void setSourceRelationKeyFieldName(String sourceRelationKeyFieldName) { this.mechanism.setSourceRelationKeyFieldName(sourceRelationKeyFieldName); } /** * PUBLIC: * Set the source relation key field names associated with the mapping. * These must be in-order with the sourceKeyFieldNames. */ public void setSourceRelationKeyFieldNames(Vector fieldNames) { this.mechanism.setSourceRelationKeyFieldNames(fieldNames); } /** * INTERNAL: * Set the source fields. */ public void setSourceRelationKeyFields(Vector sourceRelationKeyFields) { this.mechanism.setSourceRelationKeyFields(sourceRelationKeyFields); } /** * INTERNAL: * Set the target key field names associated with the mapping. * These must be in-order with the targetRelationKeyFieldNames. */ public void setTargetKeyFieldNames(Vector fieldNames) { this.mechanism.setTargetKeyFieldNames(fieldNames); } /** * INTERNAL: * Set the target fields. */ public void setTargetKeyFields(Vector targetKeyFields) { this.mechanism.setTargetKeyFields(targetKeyFields); } /** * PUBLIC: * Set the target key field in the relation table. * This is the name of the foreign key in the relation table to the target's primary key field. * This method is used if the target's primary key is a singleton only. */ public void setTargetRelationKeyFieldName(String targetRelationKeyFieldName) { this.mechanism.setTargetRelationKeyFieldName(targetRelationKeyFieldName); } /** * INTERNAL: * Set the target relation key field names associated with the mapping. * These must be in-order with the targetKeyFieldNames. */ public void setTargetRelationKeyFieldNames(Vector fieldNames) { this.mechanism.setTargetRelationKeyFieldNames(fieldNames); } /** * INTERNAL: * Set the target fields. */ public void setTargetRelationKeyFields(Vector targetRelationKeyFields) { this.mechanism.setTargetRelationKeyFields(targetRelationKeyFields); } /** * INTERNAL: * Append the temporal selection to the query selection criteria. */ @Override protected ReadQuery prepareHistoricalQuery(ReadQuery targetQuery, ObjectBuildingQuery sourceQuery, AbstractSession executionSession) { if (getHistoryPolicy() != null) { if (targetQuery == getSelectionQuery()) { targetQuery = (ObjectLevelReadQuery)targetQuery.clone(); targetQuery.setIsExecutionClone(true); } if (targetQuery.getSelectionCriteria() == getSelectionQuery().getSelectionCriteria()) { targetQuery.setSelectionCriteria((Expression)targetQuery.getSelectionCriteria().clone()); } if (sourceQuery.getSession().getAsOfClause() != null) { ((ObjectLevelReadQuery)targetQuery).setAsOfClause(sourceQuery.getSession().getAsOfClause()); } else if (((ObjectLevelReadQuery)targetQuery).getAsOfClause() == null) { ((ObjectLevelReadQuery)targetQuery).setAsOfClause(AsOfClause.NO_CLAUSE); } Expression temporalExpression = (this).getHistoryPolicy().additionalHistoryExpression(targetQuery.getSelectionCriteria().getBuilder(), targetQuery.getSelectionCriteria().getBuilder()); targetQuery.setSelectionCriteria(targetQuery.getSelectionCriteria().and(temporalExpression)); } return targetQuery; } }





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