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/*
 * Copyright (c) 1998, 2021 Oracle and/or its affiliates. All rights reserved.
 * Copyright (c) 1998, 2021 IBM 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
//     Thomas Spiegl - fix for bug 324406
//     10/15/2010-2.2 Guy Pelletier
//       - 322008: Improve usability of additional criteria applied to queries at the session/EM
//     05/10/2018-master Joe Grassel
//       - Github#93: Bug with bulk update processing involving version field update parameter
//     10/01/2018: Will Dazey
//       - #253: Add support for embedded constructor results with CriteriaBuilder
package org.eclipse.persistence.internal.queries;

import java.util.ArrayList;
import java.util.Collection;
import java.util.Enumeration;
import java.util.HashMap;
import java.util.HashSet;
import java.util.IdentityHashMap;
import java.util.Iterator;
import java.util.List;
import java.util.Map;
import java.util.Set;
import java.util.Vector;

import org.eclipse.persistence.descriptors.ClassDescriptor;
import org.eclipse.persistence.descriptors.DescriptorQueryManager;
import org.eclipse.persistence.descriptors.InheritancePolicy;
import org.eclipse.persistence.exceptions.DatabaseException;
import org.eclipse.persistence.exceptions.QueryException;
import org.eclipse.persistence.expressions.Expression;
import org.eclipse.persistence.expressions.ExpressionBuilder;
import org.eclipse.persistence.internal.databaseaccess.DatabaseCall;
import org.eclipse.persistence.internal.databaseaccess.DatasourceCall;
import org.eclipse.persistence.internal.databaseaccess.DatasourcePlatform;
import org.eclipse.persistence.internal.descriptors.OptimisticLockingPolicy;
import org.eclipse.persistence.internal.expressions.ConstantExpression;
import org.eclipse.persistence.internal.expressions.DataExpression;
import org.eclipse.persistence.internal.expressions.ExpressionIterator;
import org.eclipse.persistence.internal.expressions.FieldExpression;
import org.eclipse.persistence.internal.expressions.ObjectExpression;
import org.eclipse.persistence.internal.expressions.ParameterExpression;
import org.eclipse.persistence.internal.expressions.QueryKeyExpression;
import org.eclipse.persistence.internal.expressions.SQLDeleteAllStatement;
import org.eclipse.persistence.internal.expressions.SQLDeleteAllStatementForTempTable;
import org.eclipse.persistence.internal.expressions.SQLDeleteStatement;
import org.eclipse.persistence.internal.expressions.SQLInsertStatement;
import org.eclipse.persistence.internal.expressions.SQLModifyAllStatementForTempTable;
import org.eclipse.persistence.internal.expressions.SQLModifyStatement;
import org.eclipse.persistence.internal.expressions.SQLSelectStatement;
import org.eclipse.persistence.internal.expressions.SQLStatement;
import org.eclipse.persistence.internal.expressions.SQLUpdateAllStatement;
import org.eclipse.persistence.internal.expressions.SQLUpdateAllStatementForOracleAnonymousBlock;
import org.eclipse.persistence.internal.expressions.SQLUpdateAllStatementForTempTable;
import org.eclipse.persistence.internal.expressions.SQLUpdateStatement;
import org.eclipse.persistence.internal.helper.DatabaseField;
import org.eclipse.persistence.internal.helper.DatabaseTable;
import org.eclipse.persistence.internal.helper.Helper;
import org.eclipse.persistence.internal.helper.InvalidObject;
import org.eclipse.persistence.internal.helper.NonSynchronizedVector;
import org.eclipse.persistence.internal.identitymaps.CacheKey;
import org.eclipse.persistence.internal.sessions.AbstractRecord;
import org.eclipse.persistence.internal.sessions.AbstractSession;
import org.eclipse.persistence.internal.sessions.UnitOfWorkImpl;
import org.eclipse.persistence.logging.SessionLog;
import org.eclipse.persistence.mappings.AggregateCollectionMapping;
import org.eclipse.persistence.mappings.DatabaseMapping;
import org.eclipse.persistence.mappings.DirectCollectionMapping;
import org.eclipse.persistence.mappings.ForeignReferenceMapping;
import org.eclipse.persistence.mappings.ManyToManyMapping;
import org.eclipse.persistence.mappings.OneToOneMapping;
import org.eclipse.persistence.mappings.RelationTableMechanism;
import org.eclipse.persistence.queries.ConstructorReportItem;
import org.eclipse.persistence.queries.DatabaseQuery;
import org.eclipse.persistence.queries.DeleteAllQuery;
import org.eclipse.persistence.queries.DeleteObjectQuery;
import org.eclipse.persistence.queries.FetchGroup;
import org.eclipse.persistence.queries.InMemoryQueryIndirectionPolicy;
import org.eclipse.persistence.queries.ModifyAllQuery;
import org.eclipse.persistence.queries.ObjectLevelReadQuery;
import org.eclipse.persistence.queries.ReadAllQuery;
import org.eclipse.persistence.queries.ReadObjectQuery;
import org.eclipse.persistence.queries.ReportQuery;
import org.eclipse.persistence.queries.SQLCall;
import org.eclipse.persistence.queries.UpdateAllQuery;

/**
 * 

Purpose: * Mechanism used for all expression read queries. * ExpressionQueryInterface understands how to deal with expressions. *

Responsibilities: * Translates the expression and creates the appropriate SQL statements. * Retrieves the data from the database and return the results to the query. * * @author Yvon Lavoie * @since TOPLink/Java 1.0 */ public class ExpressionQueryMechanism extends StatementQueryMechanism { protected Expression selectionCriteria; public ExpressionQueryMechanism() { } /** * Initialize the state of the query * @param query - owner of mechanism */ public ExpressionQueryMechanism(DatabaseQuery query) { super(query); } /** * Initialize the state of the query * @param query - owner of mechanism * @param expression - selection criteria */ public ExpressionQueryMechanism(DatabaseQuery query, Expression expression) { super(query); this.selectionCriteria = expression; } /** * Alias the supplied fields with respect to the expression node. Return copies of the fields */ protected Vector aliasFields(ObjectExpression node, Vector fields) { Vector result = new Vector(fields.size()); for (Enumeration e = fields.elements(); e.hasMoreElements();) { DatabaseField eachField = ((DatabaseField)e.nextElement()).clone(); eachField.setTable(node.aliasForTable(eachField.getTable())); result.addElement(eachField); } return result; } /** * If the fields in the statement have breen pre-set, e.g. for a subset of the fields * in a partial attribute read, report query, or just a query for the class indicator, * then try to alias those. Right now this just guesses that they're all from the base. */ public Vector aliasPresetFields(SQLSelectStatement statement) { Vector fields = statement.getFields(); Expression exp = statement.getWhereClause(); if (exp == null) { return fields; } else { ExpressionBuilder base = exp.getBuilder(); return aliasFields(base, fields); } } /** * Create the appropriate where clause. * Since this is where the selection criteria gets cloned for the first time * (long after the owning query has been) many interesting things happen here. */ public Expression buildBaseSelectionCriteria(boolean isSubSelect, Map clonedExpressions) { return buildBaseSelectionCriteria(isSubSelect, clonedExpressions, true); } /** * Create the appropriate where clause. * Since this is where the selection criteria gets cloned for the first time * (long after the owning query has been) many interesting things happen here. * Ability to switch off AdditionalJoinExpression is required for DeleteAllQuery. */ public Expression buildBaseSelectionCriteria(boolean isSubSelect, Map clonedExpressions, boolean shouldUseAdditionalJoinExpression) { Expression expression = getSelectionCriteria(); // For Flashback: builder.asOf(value) counts as a non-trivial selection criteria. // Also for bug 2612185 try to preserve the original builder as far as possible. if ((expression == null) && getQuery().isObjectLevelReadQuery()) { expression = ((ObjectLevelReadQuery)getQuery()).getExpressionBuilder(); } // Subselects are not cloned, as they are cloned in the context of the parent expression. if ((!isSubSelect) && (expression != null)) { // For bug 2612185 specify the identity hashtable to be used in cloning so // it is not thrown away at the end of cloning. expression = expression.copiedVersionFrom(clonedExpressions); } if (expression != null && getQuery().isObjectLevelReadQuery()){ //reset any new ExpressionBuilders in the expression that do not belong to the query and are not //parallel ExpressionBuilder builder = ((ObjectLevelReadQuery)getQuery()).getExpressionBuilder(); if ((!isSubSelect) && (builder != null)) { builder = (ExpressionBuilder)builder.copiedVersionFrom(clonedExpressions); } expression.resetPlaceHolderBuilder(builder); } // Leaf inheritance and multiple table join. if (getDescriptor().shouldUseAdditionalJoinExpression()) { DescriptorQueryManager queryManager = getDescriptor().getQueryManager(); Expression additionalJoin; if (shouldUseAdditionalJoinExpression) { additionalJoin = queryManager.getAdditionalJoinExpression(); } else { additionalJoin = queryManager.getMultipleTableJoinExpression(); if (additionalJoin == null) { return expression; } } // If there's an expression, then we know we'll have to rebuild anyway, so don't clone. if (expression == null) { // Should never happen... expression = (Expression)additionalJoin.clone(); } else { if (query.isObjectLevelReadQuery()){ ExpressionBuilder builder = ((ObjectLevelReadQuery)query).getExpressionBuilder(); if ((additionalJoin.getBuilder() != builder) && (additionalJoin.getBuilder().getQueryClass() == null)) { if ((!isSubSelect) && (builder != null)) { builder = (ExpressionBuilder)builder.copiedVersionFrom(clonedExpressions); } additionalJoin = additionalJoin.rebuildOn(builder); } } expression = expression.and(additionalJoin); } // set wasAdditionalJoinCriteriaUsed on the addionalJoin because the expression may not have the correct builder as its left most builder additionalJoin.getBuilder().setWasAdditionJoinCriteriaUsed(true); } return expression; } /** * Return the appropriate select statement containing the fields in the table. */ public SQLSelectStatement buildBaseSelectStatement(boolean isSubSelect, Map clonedExpressions) { return buildBaseSelectStatement(isSubSelect, clonedExpressions, true); } /** * Return the appropriate select statement containing the fields in the table. * Ability to switch off AdditionalJoinExpression is required for DeleteAllQuery. */ public SQLSelectStatement buildBaseSelectStatement(boolean isSubSelect, Map clonedExpressions, boolean shouldUseAdditionalJoinExpression) { SQLSelectStatement selectStatement = new SQLSelectStatement(); ObjectLevelReadQuery query = (ObjectLevelReadQuery)getQuery(); selectStatement.setQuery(query); selectStatement.setLockingClause(query.getLockingClause()); selectStatement.setDistinctState(query.getDistinctState()); selectStatement.setTables((Vector)getDescriptor().getTables().clone()); selectStatement.setWhereClause(buildBaseSelectionCriteria(isSubSelect, clonedExpressions, shouldUseAdditionalJoinExpression)); //make sure we use the cloned builder and make sure we get the builder from the query if we have set the type. // If we use the expression builder and there are parallel builders and the query builder is on the 'right' //instead of the 'left' we will build the SQL using the wrong builder. if (query.hasDefaultBuilder() && !query.getExpressionBuilder().wasQueryClassSetInternally()){ selectStatement.setBuilder((ExpressionBuilder)query.getExpressionBuilder().copiedVersionFrom(clonedExpressions)); } //For bug 5900782, the clone of the OrderBy expressions needs to be used to ensure they are normalized //every time when select SQL statement gets re-prepared, which will further guarantee the calculation //of table alias always be correct if (query.hasOrderByExpressions()) { selectStatement.setOrderByExpressions(cloneExpressions(query.getOrderByExpressions(), clonedExpressions)); } if (query.hasNonFetchJoinedAttributeExpressions()) { selectStatement.setNonSelectFields(cloneExpressions(query.getNonFetchJoinAttributeExpressions(), clonedExpressions)); } if (query.hasUnionExpressions()) { selectStatement.setUnionExpressions(cloneExpressions(query.getUnionExpressions(), clonedExpressions)); } if (getQuery().isReadAllQuery() && ((ReadAllQuery)getQuery()).hasHierarchicalExpressions()) { ReadAllQuery readAllquery = (ReadAllQuery)query; Expression startsWith = readAllquery.getStartWithExpression(); if (startsWith != null) { startsWith.copiedVersionFrom(clonedExpressions); } selectStatement.setHierarchicalQueryExpressions( startsWith, readAllquery.getConnectByExpression().copiedVersionFrom(clonedExpressions), cloneExpressions(readAllquery.getOrderSiblingsByExpressions(), clonedExpressions), readAllquery.getDirection()); } selectStatement.setHintString(query.getHintString()); selectStatement.setTranslationRow(getTranslationRow()); return selectStatement; } /** * Return the appropriate select statement containing the fields in the table. * This is used as a second read to a concrete class with subclasses in an abstract-multiple table read. */ protected SQLSelectStatement buildConcreteSelectStatement() { // 2612538 - the default size of Map (32) is appropriate Map clonedExpressions = new IdentityHashMap(); SQLSelectStatement selectStatement = buildBaseSelectStatement(false, clonedExpressions); ClassDescriptor descriptor = getDescriptor(); InheritancePolicy policy = descriptor.getInheritancePolicy(); // The onlyInstances expression is only included on leaf descriptor base select, // so if a root or branch (!shouldReadSubclasses means leaf), then it must be appended. if (policy.shouldReadSubclasses()) { Expression indicatorExpression = null; // If the descriptor is a single table branch, then select the whole branch in a single query. if (this.query.isReadAllQuery() && policy.hasChildren() && !policy.hasMultipleTableChild()) { indicatorExpression = policy.getWithAllSubclassesExpression(); } else { indicatorExpression = policy.getOnlyInstancesExpression(); } if ((indicatorExpression != null) && (selectStatement.getWhereClause() != null)) { selectStatement.setWhereClause(selectStatement.getWhereClause().and(indicatorExpression)); } else if (indicatorExpression != null) { selectStatement.setWhereClause((Expression)indicatorExpression.clone()); } } selectStatement.setFields(getSelectionFields(selectStatement, false)); selectStatement.normalize(getSession(), descriptor, clonedExpressions); // Allow for joining indexes to be computed to ensure distinct rows. if (((ObjectLevelReadQuery)this.query).hasJoining()) { ((ObjectLevelReadQuery)this.query).getJoinedAttributeManager().computeJoiningMappingIndexes(false, getSession(), 0); } return selectStatement; } /** * Return the appropriate delete statement * Passing of a call/ statement pair is used because the same pair * may be used several times. * More elegant orangement of passing just a statement and creating the call * in the method was rejected because the same call would've been potentially * re-created several times. * Preconditions: * if selectCallForExist != null then selectStatementForExist != null; * if selectCallForNotExist != null then selectStatementForNotExist != null. * @return SQLDeleteStatement */ protected SQLDeleteStatement buildDeleteAllStatement(DatabaseTable table, Expression inheritanceExpression, SQLCall selectCallForExist, SQLSelectStatement selectStatementForExist, SQLCall selectCallForNotExist, SQLSelectStatement selectStatementForNotExist, Collection primaryKeyFields) { if(selectCallForExist == null && selectCallForNotExist == null) { return buildDeleteStatementForDeleteAllQuery(table, inheritanceExpression); } SQLDeleteAllStatement deleteAllStatement = new SQLDeleteAllStatement(); deleteAllStatement.setTable(table); deleteAllStatement.setTranslationRow(getTranslationRow()); if(selectCallForExist != null) { deleteAllStatement.setSelectCallForExist(selectCallForExist); // if selectStatementForExist doesn't require aliasing and targets the same // table as the statement to be built, // then instead of creating sql with "WHERE EXISTS(" // sql is created by extracting where clause from selectStatementForExist, // for instance: // DELETE FROM PROJECT WHERE (PROJ_NAME = ?) // instead of the wrong one: // DELETE FROM PROJECT WHERE EXISTS(SELECT PROJ_ID FROM PROJECT WHERE (PROJ_NAME = ?) AND PROJECT.PROJ_ID = PROJECT.PROJ_ID) deleteAllStatement.setShouldExtractWhereClauseFromSelectCallForExist(!selectStatementForExist.requiresAliases() && table.equals(selectStatementForExist.getTables().get(0))); deleteAllStatement.setTableAliasInSelectCallForExist(getAliasTableName(selectStatementForExist, table, getExecutionSession().getPlatform())); } else { // inheritanceExpression is irrelevant in case selectCallForExist != null if(inheritanceExpression != null) { deleteAllStatement.setInheritanceExpression((Expression)inheritanceExpression.clone()); } } if(selectCallForNotExist != null) { deleteAllStatement.setSelectCallForNotExist(selectCallForNotExist); deleteAllStatement.setTableAliasInSelectCallForNotExist(getAliasTableName(selectStatementForNotExist, table, getExecutionSession().getPlatform())); } deleteAllStatement.setPrimaryKeyFieldsForAutoJoin(primaryKeyFields); return deleteAllStatement; } /** * Create SQLDeleteAllStatements for mappings that may be responsible for references * to the objects to be deleted * in the tables NOT mapped to any class: ManyToManyMapping and DirectCollectionMapping * * NOTE: A similar pattern also used in method buildDeleteAllStatementsForMappingsWithTempTable(): * if you are updating this method consider applying a similar update to that method as well. * * @return {@code Vector} */ protected SQLDeleteStatement buildDeleteAllStatementForMapping(SQLCall selectCallForExist, SQLSelectStatement selectStatementForExist, Vector sourceFields, Vector targetFields) { DatabaseTable targetTable = ((DatabaseField)targetFields.firstElement()).getTable(); if(selectCallForExist == null) { return buildDeleteStatementForDeleteAllQuery(targetTable); } SQLDeleteAllStatement deleteAllStatement = new SQLDeleteAllStatement(); deleteAllStatement.setTable(targetTable); deleteAllStatement.setTranslationRow(getTranslationRow()); deleteAllStatement.setSelectCallForExist(selectCallForExist); DatabaseTable sourceTable = ((DatabaseField)sourceFields.firstElement()).getTable(); if(selectStatementForExist != null) { deleteAllStatement.setTableAliasInSelectCallForExist(getAliasTableName(selectStatementForExist, sourceTable, getExecutionSession().getPlatform())); } deleteAllStatement.setAliasedFieldsForJoin(sourceFields); deleteAllStatement.setOriginalFieldsForJoin(targetFields); return deleteAllStatement; } /** * Build delete statements with temporary table for ManyToMany and DirectCollection mappings. * * NOTE: A similar pattern also used in method buildDeleteAllStatementsForMappings(): * if you are updating this method consider applying a similar update to that method as well. * * @return {@code Vector} */ protected Vector buildDeleteAllStatementsForMappingsWithTempTable(ClassDescriptor descriptor, DatabaseTable rootTable, boolean dontCheckDescriptor) { Vector deleteStatements = new Vector(); for (DatabaseMapping mapping : descriptor.getMappings()) { if (mapping.isForeignReferenceMapping()) { List sourceFields = null; List targetFields = null; if (mapping.isDirectCollectionMapping()) { if (shouldBuildDeleteStatementForMapping((DirectCollectionMapping)mapping, dontCheckDescriptor, descriptor)) { sourceFields = ((DirectCollectionMapping)mapping).getSourceKeyFields(); targetFields = ((DirectCollectionMapping)mapping).getReferenceKeyFields(); } } else if (mapping.isAggregateCollectionMapping()) { if (shouldBuildDeleteStatementForMapping((AggregateCollectionMapping)mapping, dontCheckDescriptor, descriptor)) { sourceFields = ((AggregateCollectionMapping)mapping).getSourceKeyFields(); targetFields = ((AggregateCollectionMapping)mapping).getTargetForeignKeyFields(); } } else if (mapping.isManyToManyMapping()) { if (shouldBuildDeleteStatementForMapping((ManyToManyMapping)mapping, dontCheckDescriptor, descriptor)) { RelationTableMechanism relationTableMechanism = ((ManyToManyMapping)mapping).getRelationTableMechanism(); sourceFields = relationTableMechanism.getSourceKeyFields(); targetFields = relationTableMechanism.getSourceRelationKeyFields(); } } else if (mapping.isOneToOneMapping()) { RelationTableMechanism relationTableMechanism = ((OneToOneMapping)mapping).getRelationTableMechanism(); if (relationTableMechanism != null) { if (shouldBuildDeleteStatementForMapping((OneToOneMapping)mapping, dontCheckDescriptor, descriptor)) { sourceFields = relationTableMechanism.getSourceKeyFields(); targetFields = relationTableMechanism.getSourceRelationKeyFields(); } } } if (sourceFields != null) { DatabaseTable targetTable = targetFields.get(0).getTable(); SQLDeleteAllStatementForTempTable deleteStatement = buildDeleteAllStatementForTempTable(rootTable, sourceFields, targetTable, targetFields); deleteStatements.addElement(deleteStatement); } } } return deleteStatements; } protected boolean shouldBuildDeleteStatementForMapping(ForeignReferenceMapping frMapping, boolean dontCheckDescriptor, ClassDescriptor descriptor) { return (dontCheckDescriptor || frMapping.getDescriptor().equals(descriptor)) && !(frMapping.isCascadeOnDeleteSetOnDatabase()); } protected static String getAliasTableName(SQLSelectStatement selectStatement, DatabaseTable table, DatasourcePlatform platform) { if(!selectStatement.requiresAliases()) { return null; } HashSet aliasTables = new HashSet(); Iterator> itEntries = selectStatement.getTableAliases().entrySet().iterator(); DatabaseTable aliasTable = null; while(itEntries.hasNext()) { Map.Entry entry = itEntries.next(); if(table.equals(entry.getValue())) { aliasTable = entry.getKey(); aliasTables.add(aliasTable); } } if(aliasTables.isEmpty()) { return null; } else if(aliasTables.size() == 1) { return aliasTable.getQualifiedNameDelimited(platform); } // The table has several aliases, // remove the aliases that used by DataExpressions // with baseExpression NOT the expressionBuilder used by the statement ExpressionIterator expIterator = new ExpressionIterator() { @Override public void iterate(Expression each) { if(each instanceof DataExpression) { DataExpression dataExpression = (DataExpression)each; DatabaseField field = dataExpression.getField(); if(field != null) { if(dataExpression.getBaseExpression() != getStatement().getBuilder()) { ((Collection)getResult()).remove(dataExpression.getAliasedField().getTable()); } } } } @Override public boolean shouldIterateOverSubSelects() { return true; } }; expIterator.setStatement(selectStatement); expIterator.setResult(aliasTables); expIterator.iterateOn(selectStatement.getWhereClause()); if(aliasTables.size() == 1) { aliasTable = (DatabaseTable)aliasTables.iterator().next(); return aliasTable.getQualifiedName(); } else if(aliasTables.isEmpty()) { // should never happen return aliasTable.getQualifiedName(); } else { // should never happen aliasTable = (DatabaseTable)aliasTables.iterator().next(); return aliasTable.getQualifiedName(); } } /** * Used by DeleteAllQuery to create DeleteStatement in a simple case * when selectionCriteria==null. */ protected SQLDeleteStatement buildDeleteStatementForDeleteAllQuery(DatabaseTable table) { return buildDeleteStatementForDeleteAllQuery(table, null); } /** * Used by DeleteAllQuery to create DeleteStatement in a simple case * when selectionCriteria==null. */ protected SQLDeleteStatement buildDeleteStatementForDeleteAllQuery(DatabaseTable table, Expression inheritanceExpression) { SQLDeleteStatement deleteStatement = new SQLDeleteStatement(); if(inheritanceExpression != null) { deleteStatement.setWhereClause((Expression)inheritanceExpression.clone()); } deleteStatement.setTable(table); deleteStatement.setTranslationRow(getTranslationRow()); deleteStatement.setHintString(getQuery().getHintString()); return deleteStatement; } /** * Return the appropriate delete statement */ protected SQLDeleteStatement buildDeleteStatement(DatabaseTable table) { SQLDeleteStatement deleteStatement = new SQLDeleteStatement(); Expression whereClause; whereClause = getDescriptor().getObjectBuilder().buildDeleteExpression(table, getTranslationRow(), ((DeleteObjectQuery)getQuery()).usesOptimisticLocking()); deleteStatement.setWhereClause(whereClause); deleteStatement.setTable(table); deleteStatement.setTranslationRow(getTranslationRow()); deleteStatement.setHintString(getQuery().getHintString()); return deleteStatement; } /** * Return the appropriate insert statement */ protected SQLInsertStatement buildInsertStatement(DatabaseTable table) { SQLInsertStatement insertStatement = new SQLInsertStatement(); insertStatement.setTable(table); insertStatement.setModifyRow(getModifyRow()); if (getDescriptor().hasReturningPolicies() && getDescriptor().getReturnFieldsToGenerateInsert() != null) { // In case of RelationalDescriptor only return fields for current table must be used. Vector returnFieldsForTable = new NonSynchronizedVector<>(); for (DatabaseField item: getDescriptor().getReturnFieldsToGenerateInsert()) { if (table.equals(item.getTable())) { returnFieldsForTable.add(item); } } if (!returnFieldsForTable.isEmpty()) { insertStatement.setReturnFields(getDescriptor().getReturnFieldsToGenerateInsert()); } } insertStatement.setHintString(getQuery().getHintString()); return insertStatement; } /** * Return the appropriate select statement containing the fields in the table. */ protected SQLSelectStatement buildNormalSelectStatement() { // From bug 2612185 Remember the identity hashtable used in cloning the selection criteria even in the normal case // for performance, in case subqueries need it, or for order by expressions. // 2612538 - the default size of Map (32) is appropriate Map clonedExpressions = new IdentityHashMap(); SQLSelectStatement selectStatement = buildBaseSelectStatement(false, clonedExpressions); ObjectLevelReadQuery query = ((ObjectLevelReadQuery)getQuery()); // Case, normal read for branch inheritance class that reads subclasses all in its own table(s). boolean includeAllSubclassesFields = true; if (getDescriptor().hasInheritance()) { getDescriptor().getInheritancePolicy().appendWithAllSubclassesExpression(selectStatement); if ((!query.isReportQuery()) && query.shouldOuterJoinSubclasses()) { selectStatement.getExpressionBuilder().setShouldUseOuterJoinForMultitableInheritance(true); } // Bug 380929 - Find whether to include all subclass fields or not. includeAllSubclassesFields = shouldIncludeAllSubclassFields(selectStatement); } selectStatement.setFields(getSelectionFields(selectStatement, includeAllSubclassesFields)); selectStatement.normalize(getSession(), getDescriptor(), clonedExpressions); // Allow for joining indexes to be computed to ensure distinct rows. if (((ObjectLevelReadQuery)getQuery()).hasJoining()) { ((ObjectLevelReadQuery)getQuery()).getJoinedAttributeManager().computeJoiningMappingIndexes(true, getSession(), 0); } return selectStatement; } /** * Return whether to include all subclass fields in select statement or not. */ protected boolean shouldIncludeAllSubclassFields(SQLSelectStatement selectStatement) { ExpressionBuilder builder = selectStatement.getBuilder(); if (builder == null) { if (selectStatement.getWhereClause() == null) { return true; } else { builder = selectStatement.getWhereClause().getBuilder(); } } if (!builder.doesNotRepresentAnObjectInTheQuery()) { if (getDescriptor() != null && getDescriptor().hasInheritance()) { return !builder.isDowncast(getDescriptor(), getSession()); } } return true; } /** * Return the appropriate select statement containing the fields in the table. * Similar to super except the buildBaseSelectStatement will look after setting * the fields to select. */ protected SQLSelectStatement buildReportQuerySelectStatement(boolean isSubSelect) { return buildReportQuerySelectStatement(isSubSelect, false, null, true); } /** * Customary inheritance expression is required for DeleteAllQuery and UpdateAllQuery preparation. * Ability to switch off AdditionalJoinExpression is required for DeleteAllQuery. */ protected SQLSelectStatement buildReportQuerySelectStatement(boolean isSubSelect, boolean useCustomaryInheritanceExpression, Expression inheritanceExpression, boolean shouldUseAdditionalJoinExpression) { ReportQuery reportQuery = (ReportQuery)getQuery(); // For bug 2612185: Need to know which original bases were mapped to which cloned bases. // For sub-seclets the expressions have already been clones, and identity must be maintained with the outer expression. Map clonedExpressions = isSubSelect ? null : new IdentityHashMap(); SQLSelectStatement selectStatement = buildBaseSelectStatement(isSubSelect, clonedExpressions, shouldUseAdditionalJoinExpression); if (reportQuery.hasGroupByExpressions()) { selectStatement.setGroupByExpressions(cloneExpressions(reportQuery.getGroupByExpressions(), clonedExpressions)); } if (reportQuery.getHavingExpression() != null) { selectStatement.setHavingExpression(reportQuery.getHavingExpression().copiedVersionFrom(clonedExpressions)); } if (getDescriptor().hasInheritance()) { if (useCustomaryInheritanceExpression) { if (inheritanceExpression != null) { if (selectStatement.getWhereClause() == null) { selectStatement.setWhereClause((Expression)inheritanceExpression.clone()); } else { selectStatement.setWhereClause(selectStatement.getWhereClause().and(inheritanceExpression)); } } } else { getDescriptor().getInheritancePolicy().appendWithAllSubclassesExpression(selectStatement); if (reportQuery.shouldOuterJoinSubclasses()) { selectStatement.getExpressionBuilder().setShouldUseOuterJoinForMultitableInheritance(true); } } } Vector fieldExpressions = reportQuery.getQueryExpressions(); int itemOffset = fieldExpressions.size(); List items = reportQuery.getItems(); computeFieldExpressions(items, clonedExpressions, selectStatement, fieldExpressions); selectStatement.setFields(fieldExpressions); if (reportQuery.hasNonFetchJoinedAttributeExpressions()) { selectStatement.setNonSelectFields(cloneExpressions(reportQuery.getNonFetchJoinAttributeExpressions(), clonedExpressions)); } // Subselects must be normalized in the context of the parent statement. if (!isSubSelect) { selectStatement.normalize(getSession(), getDescriptor(), clonedExpressions); } items = reportQuery.getItems(); computeAndSetItemOffset(reportQuery, items, itemOffset); return selectStatement; } private void computeFieldExpressions(List items, Map clonedExpressions, SQLSelectStatement selectStatement, Vector fieldExpressions) { for (ReportItem item : items) { if (item.isConstructorItem()) { List reportItems = ((ConstructorReportItem) item).getReportItems(); computeFieldExpressions(reportItems, clonedExpressions, selectStatement, fieldExpressions); } else { extractStatementFromItem(item, clonedExpressions, selectStatement, fieldExpressions); } } } private void extractStatementFromItem(ReportItem item, Map clonedExpressions, SQLSelectStatement selectStatement, Vector fieldExpressions){ if (item.getAttributeExpression() != null) { // this allows us to modify the item expression without modifying the original in case of re-prepare Expression attributeExpression = item.getAttributeExpression(); ExpressionBuilder clonedBuilder = attributeExpression.getBuilder(); if (clonedBuilder.wasQueryClassSetInternally() && ((ReportQuery)getQuery()).getExpressionBuilder() != clonedBuilder) { // no class specified so use statement builder as it is non-parallel // must have same builder as it will be initialized clonedBuilder = selectStatement.getBuilder(); attributeExpression = attributeExpression.rebuildOn(clonedBuilder); } else if (clonedExpressions != null && clonedExpressions.get(clonedBuilder) != null) { Expression cloneExpression = (Expression)clonedExpressions.get(attributeExpression); if ((cloneExpression != null) && !cloneExpression.isExpressionBuilder()) { attributeExpression = cloneExpression; } else { //The builder has been cloned ensure that the cloned builder is used //in the items. clonedBuilder = (ExpressionBuilder)clonedBuilder.copiedVersionFrom(clonedExpressions); attributeExpression = attributeExpression.copiedVersionFrom(clonedExpressions); } } if (attributeExpression.isExpressionBuilder() && (item.getDescriptor().getQueryManager().getAdditionalJoinExpression() != null) && !(clonedBuilder.wasAdditionJoinCriteriaUsed())) { //Clone the standard join expression set on the descriptor's QueryManager Expression additionalJoinExpression = item.getDescriptor().getQueryManager().getAdditionalJoinExpression().rebuildOn(clonedBuilder); Expression whereClause = selectStatement.getWhereClause(); //'shouldUseOuterJoin' should have been set during query parsing; see ObjectExpression.leftJoin() //So we need to alter the additionalJoinExpression to account for NULL on the right side if(((ExpressionBuilder)attributeExpression).shouldUseOuterJoin()) { additionalJoinExpression = additionalJoinExpression.or(attributeExpression.isNull()); } if (whereClause == null ) { selectStatement.setWhereClause(additionalJoinExpression); } else { selectStatement.setWhereClause(whereClause.and(additionalJoinExpression)); } clonedBuilder.setWasAdditionJoinCriteriaUsed(true); } fieldExpressions.add(attributeExpression); if (item.hasJoining()){ fieldExpressions.addAll(item.getJoinedAttributeManager().getJoinedAttributeExpressions()); fieldExpressions.addAll(item.getJoinedAttributeManager().getJoinedMappingExpressions()); } } } /** * Return the appropriate select statement to perform a does exist check * @param field fields for does exist check. */ protected SQLSelectStatement buildSelectStatementForDoesExist(DatabaseField field) { // Build appropriate select statement SQLSelectStatement selectStatement; selectStatement = new SQLSelectStatement(); selectStatement.addField(field); selectStatement.setWhereClause(((Expression)getDescriptor().getObjectBuilder().getPrimaryKeyExpression().clone()).and(getDescriptor().getQueryManager().getAdditionalJoinExpression())); selectStatement.setTranslationRow(getTranslationRow()); selectStatement.normalize(getSession(), getQuery().getDescriptor()); selectStatement.setHintString(getQuery().getHintString()); return selectStatement; } protected SQLUpdateAllStatement buildUpdateAllStatement(DatabaseTable table, HashMap databaseFieldsToValues, SQLCall selectCallForExist, SQLSelectStatement selectStatementForExist, Collection primaryKeyFields) { SQLUpdateAllStatement updateAllStatement = new SQLUpdateAllStatement(); updateAllStatement.setTable(table); updateAllStatement.setTranslationRow(getTranslationRow()); HashMap databaseFieldsToValuesCopy = new HashMap(databaseFieldsToValues.size()); HashMap databaseFieldsToTableAliases = null; Iterator it = databaseFieldsToValues.entrySet().iterator(); while(it.hasNext()) { Map.Entry entry = (Map.Entry)it.next(); // for each table to be updated DatabaseField field = (DatabaseField)entry.getKey(); // here's a Map of left hand fields to right hand expressions Object value = entry.getValue(); if(value instanceof SQLSelectStatement) { SQLSelectStatement selStatement = (SQLSelectStatement)value; SQLCall selCall = (SQLCall)selStatement.buildCall(getSession()); databaseFieldsToValuesCopy.put(field, selCall); if(databaseFieldsToTableAliases == null) { databaseFieldsToTableAliases = new HashMap(); updateAllStatement.setPrimaryKeyFieldsForAutoJoin(primaryKeyFields); } databaseFieldsToTableAliases.put(field, getAliasTableName(selStatement, table, getExecutionSession().getPlatform())); } else { // should be Expression databaseFieldsToValuesCopy.put(field, value); } } updateAllStatement.setUpdateClauses(databaseFieldsToValuesCopy); updateAllStatement.setDatabaseFieldsToTableAliases(databaseFieldsToTableAliases); updateAllStatement.setSelectCallForExist(selectCallForExist); updateAllStatement.setShouldExtractWhereClauseFromSelectCallForExist(!selectStatementForExist.requiresAliases() && table.equals(selectStatementForExist.getTables().get(0))); updateAllStatement.setTableAliasInSelectCallForExist(getAliasTableName(selectStatementForExist, table, getExecutionSession().getPlatform())); updateAllStatement.setPrimaryKeyFieldsForAutoJoin(primaryKeyFields); return updateAllStatement; } /** * Return the appropriate update statement * @return SQLInsertStatement */ protected SQLUpdateStatement buildUpdateStatement(DatabaseTable table) { SQLUpdateStatement updateStatement = new SQLUpdateStatement(); updateStatement.setModifyRow(getModifyRow()); updateStatement.setTranslationRow(getTranslationRow()); if (getDescriptor().hasReturningPolicies() && getDescriptor().getReturnFieldsToGenerateUpdate() != null) { // In case of RelationalDescriptor only return fields for current table must be used. List returnFieldsForTable = new ArrayList<>(); for (DatabaseField item: getDescriptor().getReturnFieldsToGenerateUpdate()) { if (table.equals(item.getTable())) { returnFieldsForTable.add(item); } if (!returnFieldsForTable.isEmpty()) { updateStatement.setReturnFields(getDescriptor().getReturnFieldsToGenerateUpdate()); } } } updateStatement.setTable(table); updateStatement.setWhereClause(getDescriptor().getObjectBuilder().buildUpdateExpression(table, getTranslationRow(), getModifyRow())); updateStatement.setHintString(getQuery().getHintString()); return updateStatement; } /** * Perform a cache lookup for the query * This is only called from read object query. * The query has already checked that the cache should be checked. */ @Override public Object checkCacheForObject(AbstractRecord translationRow, AbstractSession session) { // For bug 2782991 a list of nearly 20 problems with this method have // been fixed. ReadObjectQuery query = getReadObjectQuery(); ClassDescriptor descriptor = getDescriptor(); boolean conforming = false; UnitOfWorkImpl uow = null; if (session.isUnitOfWork()) { conforming = query.shouldConformResultsInUnitOfWork() || descriptor.shouldAlwaysConformResultsInUnitOfWork(); uow = (UnitOfWorkImpl)session; } // Set the in memory query policy automatically for conforming queries, unless the // user specifies the most cautious one. int policyToUse = query.getInMemoryQueryIndirectionPolicyState(); if (conforming && (policyToUse != InMemoryQueryIndirectionPolicy.SHOULD_TRIGGER_INDIRECTION)) { // Bug 320764 - return not conformed by default, to avoid incorrect results being returned policyToUse = InMemoryQueryIndirectionPolicy.SHOULD_IGNORE_EXCEPTION_RETURN_NOT_CONFORMED; } Object cachedObject = null; Expression selectionCriteria = getSelectionCriteria(); // Perform a series of cache checks, in the following order... // 1: If selection key or selection object, lookup by primary key. // 1.5: If row has sopObject, lookup by its primary key. // 2: If selection criteria null, take the first instance in cache. // 3: If exact primary key expression, lookup by primary key. // 4: If inexact primary key expression, lookup by primary key and see if it conforms. // 5: Perform a linear search on the cache, calling doesConform on each object. // 6: (Conforming) Search through new objects. // Each check is more optimal than the next. // Finally: (Conforming) check that any positive result was not deleted in the UnitOfWork. // 1: If selection key or selection object, do lookup by primary key. Object selectionKey = query.getSelectionId(); Object selectionObject = query.getSelectionObject(); if ((selectionKey != null) || (selectionObject != null)) { if (selectionKey == null) { selectionKey = descriptor.getObjectBuilder().extractPrimaryKeyFromObject(selectionObject, session, true); if (selectionKey == null) { // Has a null primary key, so must not exist. return InvalidObject.instance; } // Must be checked separately as the expression and row is not yet set. query.setSelectionId(selectionKey); } if (query.requiresDeferredLocks()) { cachedObject = session.getIdentityMapAccessorInstance().getFromLocalIdentityMapWithDeferredLock(selectionKey, query.getReferenceClass(), false, descriptor); } else { cachedObject = session.getIdentityMapAccessorInstance().getFromLocalIdentityMap(selectionKey, query.getReferenceClass(), false, descriptor); } } else { // 1.5: If row has sopObject, lookup by its primary key. // if (translationRow != null && translationRow.hasSopObject()) { if (query.requiresDeferredLocks()) { cachedObject = session.getIdentityMapAccessorInstance().getFromLocalIdentityMapWithDeferredLock(descriptor.getObjectBuilder().extractPrimaryKeyFromObject(translationRow.getSopObject(), session), query.getReferenceClass(), false, descriptor); } else { cachedObject = session.getIdentityMapAccessorInstance().getFromLocalIdentityMap(descriptor.getObjectBuilder().extractPrimaryKeyFromObject(translationRow.getSopObject(), session), query.getReferenceClass(), false, descriptor); } } else { // 2: If selection criteria null, take any instance in cache. // if (selectionCriteria == null) { // In future would like to always return something from cache. if (query.shouldConformResultsInUnitOfWork() || descriptor.shouldAlwaysConformResultsInUnitOfWork() || query.shouldCheckCacheOnly() || query.shouldCheckCacheThenDatabase()) { cachedObject = session.getIdentityMapAccessorInstance().getFromIdentityMap(null, query.getReferenceClass(), translationRow, policyToUse, conforming, false, descriptor); } } else { // 3: If can extract exact primary key expression, do lookup by primary key. // selectionKey = descriptor.getObjectBuilder().extractPrimaryKeyFromExpression(true, selectionCriteria, translationRow, session); // If an exact primary key was extracted or should check cache by exact // primary key only this will become the final check. if ((selectionKey != null) || query.shouldCheckCacheByExactPrimaryKey()) { if (selectionKey != null) { // Check if key is invalid (null), cannot exist. if (selectionKey == InvalidObject.instance) { return selectionKey; } if (query.requiresDeferredLocks()) { cachedObject = session.getIdentityMapAccessorInstance().getFromLocalIdentityMapWithDeferredLock(selectionKey, query.getReferenceClass(), false, descriptor); } else { cachedObject = session.getIdentityMapAccessorInstance().getFromLocalIdentityMap(selectionKey, query.getReferenceClass(), false, descriptor); } // Because it was exact primary key if the lookup failed then it is not there. } } else { // 4: If can extract inexact primary key, find one object by primary key and // check if it conforms. Failure of this object to conform however does not // rule out a cache hit. Object inexactSelectionKey = descriptor.getObjectBuilder().extractPrimaryKeyFromExpression(false, selectionCriteria, translationRow, session);// Check for any primary key in expression, may have other stuff. if (inexactSelectionKey != null) { // Check if key is invalid (null), cannot exist. if (selectionKey == InvalidObject.instance) { return selectionKey; } // PERF: Only use deferred lock when required. if (query.requiresDeferredLocks()) { cachedObject = session.getIdentityMapAccessorInstance().getFromLocalIdentityMapWithDeferredLock(inexactSelectionKey, query.getReferenceClass(), false, descriptor); } else { cachedObject = session.getIdentityMapAccessorInstance().getFromLocalIdentityMap(inexactSelectionKey, query.getReferenceClass(), false, descriptor); } } else { CacheKey cacheKey = descriptor.getCachePolicy().checkCacheByIndex(selectionCriteria, translationRow, descriptor, session); if (cacheKey != null) { if (query.requiresDeferredLocks()) { cacheKey.checkDeferredLock(); } else { cacheKey.checkReadLock(); } cachedObject = cacheKey.getObject(); } } if (cachedObject != null) { // Must ensure that it matches the expression. try { // PERF: 3639015 - cloning the expression no longer required // when using the root session. ExpressionBuilder builder = selectionCriteria.getBuilder(); builder.setSession(session.getRootSession(null)); builder.setQueryClass(descriptor.getJavaClass()); if (!selectionCriteria.doesConform(cachedObject, session, translationRow, policyToUse)) { cachedObject = null; } } catch (QueryException exception) {// Ignore if expression too complex. if (query.shouldCheckCacheOnly()) {// Throw on only cache. throw exception; } cachedObject = null; } } // 5: Perform a linear search of the cache, calling expression.doesConform on each element. // This is a last resort linear time search of the identity map. // This can be avoided by setting check cache by (inexact/exact) primary key on the query. // That flag becomes invalid in the conforming case (bug 2609611: SUPPORT CONFORM RESULT IN UOW IN CONJUNCTION WITH OTHER IN-MEMORY FEATURES) // so if conforming must always do this linear search, but at least only on // objects registered in the UnitOfWork. // boolean conformingButOutsideUnitOfWork = ((query.shouldConformResultsInUnitOfWork() || descriptor.shouldAlwaysConformResultsInUnitOfWork()) && !session.isUnitOfWork()); if ((cachedObject == null) && (conforming || (!query.shouldCheckCacheByPrimaryKey() && !conformingButOutsideUnitOfWork))) { // PERF: 3639015 - cloning the expression no longer required // when using the root session if (selectionCriteria != null) { ExpressionBuilder builder = selectionCriteria.getBuilder(); builder.setSession(session.getRootSession(null)); builder.setQueryClass(descriptor.getJavaClass()); } try { cachedObject = session.getIdentityMapAccessorInstance().getFromIdentityMap(selectionCriteria, query.getReferenceClass(), translationRow, policyToUse, conforming, false, descriptor); } catch (QueryException exception) {// Ignore if expression too complex. if (query.shouldCheckCacheOnly()) {// Throw on only cache. throw exception; } } } } } } } // 6: If unit of work search through new objects. // if (conforming) { if (cachedObject == null) { if (selectionKey != null) { cachedObject = uow.getObjectFromNewObjects(query.getReferenceClass(), selectionKey); } else { // PERF: 3639015 - cloning the expression no longer required // when using the root session if (selectionCriteria != null) { ExpressionBuilder builder = selectionCriteria.getBuilder(); builder.setSession(session.getRootSession(null)); builder.setQueryClass(descriptor.getJavaClass()); } try { cachedObject = uow.getObjectFromNewObjects(selectionCriteria, query.getReferenceClass(), translationRow, policyToUse); } catch (QueryException exception) { // Ignore if expression too complex. } } } // Finally, check that a positive result is not deleted in the Unit Of Work. // if (cachedObject != null) { if (uow.isObjectDeleted(cachedObject)) { if (selectionKey != null) { // In this case return a special value, to notify // that the object was found but null must be returned. return InvalidObject.instance; } else { cachedObject = null; } } } } if (cachedObject != null) { // Fetch group check, ensure object is fetched. if (descriptor.hasFetchGroupManager()) { if (descriptor.getFetchGroupManager().isPartialObject(cachedObject)) { FetchGroup fetchGroup = query.getExecutionFetchGroup(descriptor); EntityFetchGroup entityFetchGroup = null; if (fetchGroup!= null){ entityFetchGroup = descriptor.getFetchGroupManager().getEntityFetchGroup(fetchGroup); } if (!descriptor.getFetchGroupManager().isObjectValidForFetchGroup(cachedObject, entityFetchGroup)) { //the cached object is partially fetched, and it's fetch group is not a superset of the one in the query, so the cached object is not valid for the query. cachedObject = null; } } } } // If only checking the cache, and empty, return invalid, unless it is a unit of work, // in which case the parent cache still needs to be checked. if ((cachedObject == null) && query.shouldCheckCacheOnly() && ((uow == null) || (!uow.isNestedUnitOfWork() && descriptor.getCachePolicy().shouldIsolateObjectsInUnitOfWork()))) { return InvalidObject.instance; } return cachedObject; } /** * The statement is no longer require after prepare so can be released. */ @Override public void clearStatement() { // Only clear the statement if it is an expression query, otherwise the statement may still be needed. setSQLStatement(null); setSQLStatements(null); } /** * Clone the mechanism for the specified query clone. * Should not try to clone statements. */ @Override public DatabaseQueryMechanism clone(DatabaseQuery queryClone) { DatabaseQueryMechanism clone = (DatabaseQueryMechanism)clone(); clone.setQuery(queryClone); return clone; } /** * Return an expression builder which is valid for us */ public ExpressionBuilder getExpressionBuilder() { if (getSelectionCriteria() != null) { return getSelectionCriteria().getBuilder(); } return null; } /** * Return the selection criteria of the query. */ @Override public Expression getSelectionCriteria() { return selectionCriteria; } /** * Return the fields required in the select clause. * This must now be called after normalization, so it will get the aliased fields */ public Vector getSelectionFields(SQLSelectStatement statement, boolean includeAllSubclassFields) { ObjectLevelReadQuery owner = (ObjectLevelReadQuery)getQuery(); if (owner.hasPartialAttributeExpressions()) { return owner.getPartialAttributeSelectionFields(false); } Vector fields = NonSynchronizedVector.newInstance(); if (owner.getExecutionFetchGroup() != null) { fields.addAll(owner.getFetchGroupSelectionFields()); } else { if (includeAllSubclassFields) { fields.addAll(getDescriptor().getAllSelectionFields(owner)); } else { fields.add(statement.getExpressionBuilder()); } } // Add joined fields. if (owner.hasJoining()) { owner.addJoinSelectionFields(fields, false); } if (owner.hasAdditionalFields()) { // Add additional fields, use for batch reading m-m. fields.addAll(owner.getAdditionalFields()); } return fields; } /** * Return true if this is an expression query mechanism. */ @Override public boolean isExpressionQueryMechanism() { return true; } /** * Return true if this is a statement query mechanism */ @Override public boolean isStatementQueryMechanism() { return false; } /** * Override super to do nothing. */ @Override public void prepare() throws QueryException { // Do nothing. } /** * Pre-build the SQL statement from the expression. */ @Override public void prepareCursorSelectAllRows() { if (getQuery().isReportQuery()) { SQLSelectStatement statement = buildReportQuerySelectStatement(false); setSQLStatement(statement); // For bug 2718118 inheritance with cursors is supported provided there is a read all subclasses view. } else if (getDescriptor().hasInheritance() && getDescriptor().getInheritancePolicy().requiresMultipleTableSubclassRead() && getDescriptor().getInheritancePolicy().hasView()) { InheritancePolicy inheritancePolicy = getDescriptor().getInheritancePolicy(); SQLSelectStatement statement = inheritancePolicy.buildViewSelectStatement((ObjectLevelReadQuery)getQuery()); setSQLStatement(statement); } else { setSQLStatement(buildNormalSelectStatement()); } super.prepareCursorSelectAllRows(); } /** * Pre-build the SQL statement from the expression. */ @Override public void prepareDeleteAll() { prepareDeleteAll(null, false); } /** * Pre-build the SQL statement from the expression. * * NOTE: A similar pattern also used in method buildDeleteAllStatementsForTempTable(): * if you are updating this method consider applying a similar update to that method as well. */ protected void prepareDeleteAll(List tablesToIgnore, boolean isWhereClauseRequired) { List tablesInInsertOrder; ClassDescriptor descriptor = getDescriptor(); if (tablesToIgnore == null) { // It's original (not a nested) method call. tablesInInsertOrder = descriptor.getMultipleTableInsertOrder(); } else { // It's a nested method call: tableInInsertOrder filled with descriptor's tables (in insert order), // the tables found in tablesToIgnore are thrown away - // they have already been taken care of by the caller. // In Employee example, query with reference class Project gets here // to handle LPROJECT table; tablesToIgnore contains PROJECT table. tablesInInsertOrder = new ArrayList(descriptor.getMultipleTableInsertOrder().size()); for (DatabaseTable table : descriptor.getMultipleTableInsertOrder()) { if (!tablesToIgnore.contains(table)) { tablesInInsertOrder.add(table); } } } // cache the flag - used many times boolean hasInheritance = descriptor.hasInheritance(); if (!tablesInInsertOrder.isEmpty()) { Expression whereClause = getSelectionCriteria(); if (tablesToIgnore == null) { // It's original (not a nested) method call. // Ignore the passed dummy value of isWhereClauseRequired and calculate it here. // This value will be passed to all other tables. isWhereClauseRequired = whereClause != null; if (!isWhereClauseRequired) { Expression additionalExpression = descriptor.getQueryManager().getAdditionalJoinExpression(); if (additionalExpression != null) { if (!additionalExpression.equals(descriptor.getQueryManager().getMultipleTableJoinExpression())) { isWhereClauseRequired = true; } } } } SQLCall selectCallForExist = null; // Most databases support delete cascade constraints by specifying a ON DELETE CASCADE option when defining foreign key constraints. // However some databases which don't support foreign key constraints cannot use delete cascade constraints. // Therefore each delete operation should be executed in such a database platform instead of delegating delete cascade constraints. boolean supportForeignKeyConstraints = getSession().getPlatform().supportsForeignKeyConstraints(); boolean supportCascadeOnDelete = supportForeignKeyConstraints && descriptor.isCascadeOnDeleteSetOnDatabaseOnSecondaryTables(); boolean isSelectCallForNotExistRequired = (tablesToIgnore == null) && (tablesInInsertOrder.size() > 1) && (!supportCascadeOnDelete); SQLSelectStatement selectStatementForNotExist = null; SQLCall selectCallForNotExist = null; // inheritanceExpression is always null in a nested method call. Expression inheritanceExpression = null; if (tablesToIgnore == null) { // It's original (not a nested) method call. if (hasInheritance) { if (descriptor.getInheritancePolicy().shouldReadSubclasses()) { inheritanceExpression = descriptor.getInheritancePolicy().getWithAllSubclassesExpression(); } else { inheritanceExpression = descriptor.getInheritancePolicy().getOnlyInstancesExpression(); } } } SQLSelectStatement selectStatementForExist = createSQLSelectStatementForModifyAll(whereClause); // Main Case: Descriptor is mapped to more than one table and/or the query references other tables boolean isMainCase = selectStatementForExist.requiresAliases(); if (isMainCase) { if (isWhereClauseRequired) { if (getExecutionSession().getPlatform().shouldAlwaysUseTempStorageForModifyAll() && tablesToIgnore == null) { // currently DeleteAll using Oracle anonymous block is not implemented if(!getExecutionSession().getPlatform().isOracle()) { prepareDeleteAllUsingTempStorage(); return; } } if (isSelectCallForNotExistRequired) { selectStatementForNotExist = createSQLSelectStatementForModifyAll(null, null, descriptor, true, false); selectCallForNotExist = (SQLCall)selectStatementForNotExist.buildCall(getSession()); } } else { //whereClause = null if (getExecutionSession().getPlatform().shouldAlwaysUseTempStorageForModifyAll() && tablesToIgnore == null) { // currently DeleteAll using Oracle anonymous block is not implemented if (!getExecutionSession().getPlatform().isOracle()) { // the only case to handle without temp storage is inheritance root without inheritanceExpression: // in this case all generated delete calls will have no where clauses. if (hasInheritance && !(inheritanceExpression == null && descriptor.getInheritancePolicy().isRootParentDescriptor())) { prepareDeleteAllUsingTempStorage(); return; } } } } } else { // simple case: Descriptor is mapped to a single table and the query references no other tables. if (isWhereClauseRequired) { if (getExecutionSession().getPlatform().shouldAlwaysUseTempStorageForModifyAll() && tablesToIgnore == null) { // currently DeleteAll using Oracle anonymous block is not implemented if (!getExecutionSession().getPlatform().isOracle()) { // if there are derived classes with additional tables - use temporary storage if (hasInheritance && descriptor.getInheritancePolicy().hasMultipleTableChild()) { prepareDeleteAllUsingTempStorage(); return; } } } } } // Don't use selectCallForExist in case there is no whereClause - // a simpler sql will be created if possible. if (isWhereClauseRequired) { selectCallForExist = (SQLCall)selectStatementForExist.buildCall(getSession()); } if (isMainCase) { // Main case: Descriptor is mapped to more than one table and/or the query references other tables // // Add and prepare to a call a delete statement for each table. // In the case of multiple tables, build the sql statements list in insert order. When the // actual SQL calls are sent they are sent in the reverse of this order. for (DatabaseTable table : tablesInInsertOrder) { Collection primaryKeyFields = getPrimaryKeyFieldsForTable(table); SQLDeleteStatement deleteStatement; // In Employee example, query with reference class: // Employee will build "EXISTS" for SALARY and "NOT EXISTS" for EMPLOYEE; // LargeProject will build "EXISTS" for LPROJECT and "NOT EXISTS" for Project. // The situation is a bit more complex if more than two levels of inheritance is involved: // both "EXISTS" and "NOT EXISTS" used for the "intermediate" (not first and not last) tables. if (!isSelectCallForNotExistRequired) { // isSelectCallForNotExistRequired == false: // either tablesToIgnore != null: it's a nested method call. // Example: // In Employee example, query with reference class // Project will get here to handle LPROJECT table // or tablesInInsertOrder.size() == 1: there is only one table, // but there is joining to at least one other table (otherwise would've been isMainCase==false). // // Note that buildDeleteAllStatement ignores inheritanceExpression if selectCallForExist!=null. deleteStatement = buildDeleteAllStatement(table, inheritanceExpression, selectCallForExist, selectStatementForExist, null, null, primaryKeyFields); } else { // isSelectCallForNotExistRequired==true: original call, multiple tables. // indicates whether the table is the last in insertion order boolean isLastTable = table.equals(tablesInInsertOrder.get(tablesInInsertOrder.size() - 1)); if (inheritanceExpression == null) { if(isLastTable) { // In Employee example, query with reference class Employee calls this for SALARY table; deleteStatement = buildDeleteAllStatement(table, null, selectCallForExist, selectStatementForExist, null, null, primaryKeyFields); } else { // In Employee example, query with reference class Employee calls this for EMPLOYEE table deleteStatement = buildDeleteAllStatement(table, null, null, null, selectCallForNotExist, selectStatementForNotExist, primaryKeyFields); } } else { // there is inheritance if (table.equals(descriptor.getMultipleTableInsertOrder().get(0))) { // This is the highest table in inheritance hierarchy - the one that contains conditions // (usually class indicator fields) that defines the class identity. // inheritanceExpression is for this table (it doesn't reference any other tables). // In Employee example, query with reference class LargeProject calls this for PROJECT table deleteStatement = buildDeleteAllStatement(table, inheritanceExpression, null, null, selectCallForNotExist, selectStatementForNotExist, primaryKeyFields); } else { ClassDescriptor desc = getHighestDescriptorMappingTable(table); if (desc == descriptor) { if (isLastTable) { // In Employee example, query with reference class LargeProject calls this for LPROJECT table; deleteStatement = buildDeleteAllStatement(table, null, selectCallForExist, selectStatementForExist, null, null, primaryKeyFields); } else { // Class has multiple tables that are not inherited. // In extended Employee example: // Employee2 class inherits from Employee and // mapped to two additional tables: EMPLOYEE2 and SALARY2. // Query with reference class Employee2 calls this for EMPLOYEE2 table. deleteStatement = buildDeleteAllStatement(table, null, null, null, selectCallForNotExist, selectStatementForNotExist, primaryKeyFields); } } else { // This table is mapped through descriptor that stands higher in inheritance hierarchy // (but not the highest one - this is taken care in another case). // // inheritanceSelectStatementForExist is created for the higher descriptor, // but the inheritance expression from the current descriptor is used. // Note that this trick doesn't work in case the higher descriptor was defined with // inheritance policy set not to read subclasses // (descriptor.getInheritancePolicy().dontReadSubclassesOnQueries()). // In that case inheritance expression for the higher descriptor can't // be removed - it still appears in the sql and collides with the inheritance // expression from the current descriptor - the selection expression is never true. // // In extended Employee example: // VeryLargeProject inherits from LargeProject, // mapped to an additional table VLPROJECT; // VeryVeryLargeProject inherits from VeryLargeProject, // mapped to the same tables as it's parent. // // Note that this doesn't work in case LargeProject descriptor was set not to read subclasses: // in that case the selection expression will have (PROJ_TYPE = 'L') AND (PROJ_TYPE = 'V') // //bug 413765: this can only be called when selectCallForExist!=null. Other classes might use this table // and be deleted if the inheritance info isn't included. if(isLastTable && selectCallForExist!=null) { // In extended Employee example: // Query with reference class VeryVeryLargeProject calls this for VLPROJECT table. deleteStatement = buildDeleteAllStatement(table, null, selectCallForExist, selectStatementForExist, null, null, primaryKeyFields); } else { // In extended Employee example: // Query with reference class VeryLargeProject calls this for LPROJECT table. // Note that both EXISTS and NOT EXISTS clauses created. SQLSelectStatement inheritanceSelectStatementForExist = createSQLSelectStatementForModifyAll(null, inheritanceExpression, desc, true, true); SQLCall inheritanceSelectCallForExist = (SQLCall)inheritanceSelectStatementForExist.buildCall(getSession()); deleteStatement = buildDeleteAllStatement(table, null, inheritanceSelectCallForExist, inheritanceSelectStatementForExist, selectCallForNotExist, selectStatementForNotExist, primaryKeyFields); } } } } } if (descriptor.getTables().size() > 1) { getSQLStatements().add(deleteStatement); } else { setSQLStatement(deleteStatement); } // Only delete from first table if delete is cascaded on the database. if (supportCascadeOnDelete) { break; } } } else { // A simple case: // there is only one table mapped to the descriptor, and // selection criteria doesn't reference any other tables // A simple sql call with no subselect should be built. // In Employee example, query with reference class: // Project will build a simple sql call for PROJECT(and will make nested method calls for LargeProject and SmallProject); // SmallProject will build a simple sql call for PROJECT setSQLStatement(buildDeleteAllStatement(descriptor.getDefaultTable(), inheritanceExpression, selectCallForExist, selectStatementForExist, null, null, null)); } if (selectCallForExist == null) { // Getting there means there is no whereClause. // To handle the mappings selectCallForExist may be required in this case, too. if (hasInheritance && (tablesToIgnore != null || inheritanceExpression != null)) { // The only case NOT to create the call for no whereClause is either no inheritance, // or it's an original (not a nested) method call and there is no inheritance expression. // In Employee example: // query with reference class Project and no where clause for m-to-m mapping generates: // DELETE FROM EMP_PROJ; // as opposed to query with reference class SmallProject: // DELETE FROM EMP_PROJ WHERE EXISTS(SELECT PROJ_ID FROM PROJECT WHERE (PROJ_TYPE = ?) AND PROJ_ID = EMP_PROJ.PROJ_ID). // selectCallForExist = (SQLCall)selectStatementForExist.buildCall(getSession()); } } // Add statements for ManyToMany and DirectCollection mappings List deleteStatementsForMappings = buildDeleteAllStatementsForMappings(selectCallForExist, selectStatementForExist, tablesToIgnore == null); if(!deleteStatementsForMappings.isEmpty()) { if(getSQLStatement() != null) { getSQLStatements().add(getSQLStatement()); setSQLStatement(null); } getSQLStatements().addAll(deleteStatementsForMappings); } } // Indicates whether the descriptor has children using extra tables. boolean hasChildrenWithExtraTables = hasInheritance && descriptor.getInheritancePolicy().hasChildren() && descriptor.getInheritancePolicy().hasMultipleTableChild(); // TBD: should we ignore subclasses in case descriptor doesn't want us to read them in? //** Currently in this code we do ignore. //** If it will be decided that we need to handle children in all cases //** the following statement should be changed to: boolean shouldHandleChildren = hasChildrenWithExtraTables; boolean shouldHandleChildren = hasChildrenWithExtraTables && descriptor.getInheritancePolicy().shouldReadSubclasses(); // Perform a nested method call for each child if (shouldHandleChildren) { // In Employee example: query for Project will make nested calls to // LargeProject and SmallProject and ask them to ignore PROJECT table List tablesToIgnoreForChildren = new ArrayList(); // The tables this descriptor has ignored, its children also should ignore. if (tablesToIgnore != null) { tablesToIgnoreForChildren.addAll(tablesToIgnore); } // If the descriptor reads subclasses there is no need for // subclasses to process its tables for the second time. if (descriptor.getInheritancePolicy().shouldReadSubclasses()) { tablesToIgnoreForChildren.addAll(tablesInInsertOrder); } Iterator it = descriptor.getInheritancePolicy().getChildDescriptors().iterator(); while (it.hasNext()) { // Define the same query for the child ClassDescriptor childDescriptor = it.next(); // Most databases support delete cascade constraints by specifying a ON DELETE CASCADE option when defining foreign key constraints. // However some databases which don't support foreign key constraints cannot use delete cascade constraints. // Therefore each delete operation should be executed in such a database platform instead of delegating delete cascade constraints. boolean supportForeignKeyConstraints = getSession().getPlatform().supportsForeignKeyConstraints(); boolean supportCascadeOnDelete = supportForeignKeyConstraints && childDescriptor.isCascadeOnDeleteSetOnDatabaseOnSecondaryTables(); // Need to process only "multiple tables" child descriptors if (((!supportCascadeOnDelete) && childDescriptor.getTables().size() > descriptor.getTables().size()) || (childDescriptor.getInheritancePolicy().hasMultipleTableChild())) { DeleteAllQuery childQuery = new DeleteAllQuery(); childQuery.setReferenceClass(childDescriptor.getJavaClass()); childQuery.setSelectionCriteria(getSelectionCriteria()); childQuery.setDescriptor(childDescriptor); childQuery.setSession(getSession()); ExpressionQueryMechanism childMechanism = (ExpressionQueryMechanism)childQuery.getQueryMechanism(); // nested call childMechanism.prepareDeleteAll(tablesToIgnoreForChildren, isWhereClauseRequired); // Copy the statements from child query mechanism. // In Employee example query for Project will pick up a statement for // LPROJECT table from LargeProject and nothing from SmallProject. List childStatements = new ArrayList(); if (childMechanism.getCall() != null) { childStatements.add(childMechanism.getSQLStatement()); } else if(childMechanism.getSQLStatements() != null) { childStatements.addAll(childMechanism.getSQLStatements()); } if (!childStatements.isEmpty()) { if (getSQLStatement() != null) { getSQLStatements().add(getSQLStatement()); setSQLStatement(null); } getSQLStatements().addAll(childStatements); } } } } // Nested method call doesn't need to call this. if (tablesToIgnore == null) { ((DeleteAllQuery)getQuery()).setIsPreparedUsingTempStorage(false); super.prepareDeleteAll(); } } protected void prepareDeleteAllUsingTempStorage() { if(getExecutionSession().getPlatform().supportsTempTables()) { prepareDeleteAllUsingTempTables(); } else { throw QueryException.tempTablesNotSupported(getQuery(), Helper.getShortClassName(getExecutionSession().getPlatform())); } } protected void prepareDeleteAllUsingTempTables() { getSQLStatements().addAll(buildStatementsForDeleteAllForTempTables()); ((DeleteAllQuery)getQuery()).setIsPreparedUsingTempStorage(true); super.prepareDeleteAll(); } // Create SQLDeleteAllStatements for mappings that may be responsible for references // to the objects to be deleted // in the tables NOT mapped to any class: ManyToManyMapping and DirectCollectionMapping /** * * NOTE: A similar pattern also used in method buildDeleteAllStatementsForMappingsWithTempTable: * if you are updating this method consider applying a similar update to that method as well. * * @return {@code Vector} */ protected Vector buildDeleteAllStatementsForMappings(SQLCall selectCallForExist, SQLSelectStatement selectStatementForExist, boolean dontCheckDescriptor) { Vector deleteStatements = new Vector(); ClassDescriptor descriptor = getDescriptor(); for (DatabaseMapping mapping : descriptor.getMappings()) { if (mapping.isForeignReferenceMapping()) { Vector sourceFields = null; Vector targetFields = null; if (mapping.isDirectCollectionMapping()) { if (shouldBuildDeleteStatementForMapping((DirectCollectionMapping)mapping, dontCheckDescriptor, descriptor)) { sourceFields = ((DirectCollectionMapping)mapping).getSourceKeyFields(); targetFields = ((DirectCollectionMapping)mapping).getReferenceKeyFields(); } } else if (mapping.isAggregateCollectionMapping()) { if (shouldBuildDeleteStatementForMapping((AggregateCollectionMapping)mapping, dontCheckDescriptor, descriptor)) { sourceFields = ((AggregateCollectionMapping)mapping).getSourceKeyFields(); targetFields = ((AggregateCollectionMapping)mapping).getTargetForeignKeyFields(); } } else if (mapping.isManyToManyMapping()) { if (shouldBuildDeleteStatementForMapping((ManyToManyMapping)mapping, dontCheckDescriptor, descriptor)) { RelationTableMechanism relationTableMechanism = ((ManyToManyMapping)mapping).getRelationTableMechanism(); sourceFields = relationTableMechanism.getSourceKeyFields(); targetFields = relationTableMechanism.getSourceRelationKeyFields(); } } else if (mapping.isOneToOneMapping()) { RelationTableMechanism relationTableMechanism = ((OneToOneMapping)mapping).getRelationTableMechanism(); if (relationTableMechanism != null) { if (shouldBuildDeleteStatementForMapping((OneToOneMapping)mapping, dontCheckDescriptor, descriptor)) { sourceFields = relationTableMechanism.getSourceKeyFields(); targetFields = relationTableMechanism.getSourceRelationKeyFields(); } } } if (sourceFields != null) { deleteStatements.add(buildDeleteAllStatementForMapping(selectCallForExist, selectStatementForExist, sourceFields, targetFields)); } } } return deleteStatements; } protected SQLSelectStatement createSQLSelectStatementForModifyAll(Expression whereClause) { return createSQLSelectStatementForModifyAll(whereClause, null, getDescriptor(), false, true); } /** * Customary inheritance expression is required for DeleteAllQuery and UpdateAllQuery preparation. * Ability to switch off AdditionalJoinExpression is required for DeleteAllQuery. */ protected SQLSelectStatement createSQLSelectStatementForModifyAll(Expression whereClause, Expression inheritanceExpression, ClassDescriptor desc, boolean useCustomaryInheritanceExpression, boolean shouldUseAdditionalJoinExpression) { ExpressionBuilder builder; if(whereClause != null) { whereClause = (Expression)whereClause.clone(); builder = whereClause.getBuilder(); } else { builder = new ExpressionBuilder(); } ReportQuery reportQuery = new ReportQuery(desc.getJavaClass(), builder); reportQuery.setDescriptor(desc); reportQuery.setShouldRetrieveFirstPrimaryKey(true); reportQuery.setSelectionCriteria(whereClause); reportQuery.setSession(getSession()); SQLSelectStatement selectStatement = ((ExpressionQueryMechanism)reportQuery.getQueryMechanism()).buildReportQuerySelectStatement(false, useCustomaryInheritanceExpression, inheritanceExpression, shouldUseAdditionalJoinExpression); reportQuery.setSession(null); return selectStatement; } protected SQLSelectStatement createSQLSelectStatementForAssignedExpressionForUpdateAll(Expression value) { ReportQuery reportQuery = new ReportQuery(getQuery().getReferenceClass(), value.getBuilder()); reportQuery.setDescriptor(getQuery().getDescriptor()); reportQuery.setSession(getSession()); reportQuery.addAttribute("", value); SQLSelectStatement selectStatement = ((ExpressionQueryMechanism)reportQuery.getQueryMechanism()).buildReportQuerySelectStatement(false); reportQuery.setSession(null); return selectStatement; } /** * This method return the clones of the list of expressions. */ private List cloneExpressions(List originalExpressions, Map clonedExpressions){ if ((originalExpressions == null) || (originalExpressions.size() == 0) || (clonedExpressions == null)) { return originalExpressions; } List newExpressions = new ArrayList<>(originalExpressions.size()); for (Expression expression : originalExpressions) { newExpressions.add(expression.copiedVersionFrom(clonedExpressions)); } return newExpressions; } /** * Pre-build the SQL statement from the expression. */ @Override public void prepareDeleteObject() { ClassDescriptor descriptor = getDescriptor(); if (descriptor.usesFieldLocking() && (getTranslationRow() == null)) { return; } // Add and prepare to a call a delete statement for each table. // In the case of multiple tables, build the sql statements Vector in insert order. When the // actual SQL calls are sent they are sent in the reverse of this order. for (DatabaseTable table : descriptor.getMultipleTableInsertOrder()) { SQLDeleteStatement deleteStatement = buildDeleteStatement(table); if (descriptor.getTables().size() > 1) { getSQLStatements().add(deleteStatement); } else { setSQLStatement(deleteStatement); } // Most databases support delete cascade constraints by specifying a ON DELETE CASCADE option when defining foreign key constraints. // However some databases which don't support foreign key constraints cannot use delete cascade constraints. // Therefore each delete operation should be executed in such a database platform instead of delegating delete cascade constraints. boolean supportForeignKeyConstraints = getSession().getPlatform().supportsForeignKeyConstraints(); boolean supportCascadeOnDelete = supportForeignKeyConstraints && descriptor.isCascadeOnDeleteSetOnDatabaseOnSecondaryTables(); if (supportCascadeOnDelete) { break; } } super.prepareDeleteObject(); } /** * Pre-build the SQL statement from the expression. */ @Override public void prepareDoesExist(DatabaseField field) { setSQLStatement(buildSelectStatementForDoesExist(field)); super.prepareDoesExist(field); } /** * Pre-build the SQL statement from the expression. */ @Override public void prepareInsertObject() { // Require modify row to prepare. if (getModifyRow() == null) { return; } // Add and prepare to a call a update statement for each table. // In the case of multiple tables, build the sql statements in insert order. ClassDescriptor descriptor = getDescriptor(); if (descriptor.getTables().size() == 1) { setSQLStatement(buildInsertStatement(descriptor.getTables().get(0))); } else { for (DatabaseTable table : descriptor.getMultipleTableInsertOrder()) { SQLInsertStatement insertStatement = buildInsertStatement(table); getSQLStatements().addElement(insertStatement); } } super.prepareInsertObject(); } /** * Pre-build the SQL statement from the expression. */ @Override public void prepareReportQuerySelectAllRows() { SQLSelectStatement statement = buildReportQuerySelectStatement(false); setSQLStatement(statement); setCallFromStatement(); // The statement is no longer require so can be released. setSQLStatement(null); getCall().returnManyRows(); prepareCall(); } /** * Pre-build the SQL statement from the expression. * This is used for subselects, so does not normalize or generate the SQL as it needs the outer expression for this. */ @Override public void prepareReportQuerySubSelect() { setSQLStatement(buildReportQuerySelectStatement(true)); // The expression is no longer require so can be released. setSelectionCriteria(null); } /** * Pre-build the SQL statement from the expression. */ @Override public void prepareSelectAllRows() { // Check for multiple table inheritance which may require multiple queries. if (!getDescriptor().hasInheritance() || !getDescriptor().getInheritancePolicy().requiresMultipleTableSubclassRead()){ setSQLStatement(buildNormalSelectStatement()); super.prepareSelectAllRows(); } else { InheritancePolicy policy = getDescriptor().getInheritancePolicy(); if (policy.hasView()){ // CR#3158703 if the descriptor has a view, then it requires a single select, // so can be prepared. setSQLStatement(getDescriptor().getInheritancePolicy().buildViewSelectStatement((ObjectLevelReadQuery)getQuery())); super.prepareSelectAllRows(); } else if ( ((ObjectLevelReadQuery)getQuery()).shouldOuterJoinSubclasses() ){ //outer join into a single select that can be built normally setSQLStatement(buildNormalSelectStatement()); super.prepareSelectAllRows(); } else if (!getDescriptor().getInheritancePolicy().hasClassExtractor()) { // CR#3158703 otherwise if using a type indicator at least the type select can be prepared. setSQLStatement(getDescriptor().getInheritancePolicy().buildClassIndicatorSelectStatement((ObjectLevelReadQuery)getQuery())); super.prepareSelectAllRows(); } } } /** * Pre-build the SQL statement from the expression. */ @Override public void prepareSelectOneRow() { // Check for multiple table inheritance which may require multiple queries. if (!getDescriptor().hasInheritance() || !getDescriptor().getInheritancePolicy().requiresMultipleTableSubclassRead()){ setSQLStatement(buildNormalSelectStatement()); super.prepareSelectOneRow(); } else { InheritancePolicy policy = getDescriptor().getInheritancePolicy(); if (policy.hasView()){ // CR#3158703 if the descriptor has a view, then it requires a single select, // so can be prepared. setSQLStatement(getDescriptor().getInheritancePolicy().buildViewSelectStatement((ObjectLevelReadQuery)getQuery())); super.prepareSelectOneRow(); } else if ( ((ObjectLevelReadQuery)getQuery()).shouldOuterJoinSubclasses() ){ //outer join into a single select that can be built normally setSQLStatement(buildNormalSelectStatement()); super.prepareSelectOneRow(); } else if (!getDescriptor().getInheritancePolicy().hasClassExtractor()) { // CR#3158703 otherwise if using a type indicator at least the type select can be prepared. setSQLStatement(getDescriptor().getInheritancePolicy().buildClassIndicatorSelectStatement((ObjectLevelReadQuery)getQuery())); super.prepareSelectOneRow(); } } } /** * Pre-build the SQL statement from the expression. */ @Override public void prepareUpdateObject() { // Require modify row to prepare. if (getModifyRow() == null) { return; } // EL Bug 319759 AbstractRecord row = getQuery().getTranslationRow(); boolean useCache = (row == null || !(getQuery().shouldValidateUpdateCallCacheUse() && row.hasNullValueInFields())); // PERF: Check the descriptor update SQL call cache for a matching update with the same fields. Vector updateCalls = getDescriptor().getQueryManager().getCachedUpdateCalls(getModifyRow().getFields()); // If the calls were cached then don't need to prepare. if (updateCalls != null && useCache == true) { int updateCallsSize = updateCalls.size(); if (updateCallsSize == 1) { // clone call, to be able to set query on clone DatasourceCall existingCall = (DatasourceCall)updateCalls.get(0); DatasourceCall clonedCall = (DatasourceCall)existingCall.clone(); setCall(clonedCall); } else { // clone calls Vector clonedCalls = new Vector(updateCallsSize); for (int i = 0; i < updateCallsSize; i++) { DatasourceCall existingCall = (DatasourceCall)updateCalls.get(i); clonedCalls.add(existingCall.clone()); } setCalls(clonedCalls); } return; } // Add and prepare to a call a update statement for each table. int tablesSize = getDescriptor().getTables().size(); for (int index = 0; index < tablesSize; index++) { DatabaseTable table = getDescriptor().getTables().get(index); SQLUpdateStatement updateStatement = buildUpdateStatement(table); if (tablesSize > 1) { getSQLStatements().addElement(updateStatement); } else { setSQLStatement(updateStatement); } } super.prepareUpdateObject(); // PERF: Cache the update SQL call to avoid regeneration. if (useCache == true) { // EL Bug 319759 if (hasMultipleCalls()) { updateCalls = getCalls(); } else { updateCalls = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(1); if (getCall() != null) { updateCalls.add(getCall()); } } getDescriptor().getQueryManager().putCachedUpdateCalls(getModifyRow().getFields(), updateCalls); } } private boolean isFieldInUpdate(Expression writeLock, HashMap updateClauses) { if (!(writeLock instanceof FieldExpression)) { return false; } final FieldExpression fe = (FieldExpression) writeLock; final DatabaseField targetField = fe.getField(); final Set keys = updateClauses.keySet(); for (Object key : keys) { if (!(key instanceof QueryKeyExpression)) { continue; } QueryKeyExpression qke = (QueryKeyExpression) key; DatabaseField qkField = getDescriptor().getObjectBuilder().getFieldForQueryKeyName(qke.getName()); if (qkField == targetField) { return true; } } return false; } /** * Pre-build the SQL statement from the expressions. */ @Override public void prepareUpdateAll() { ExpressionBuilder builder = ((UpdateAllQuery)getQuery()).getExpressionBuilder(); HashMap updateClauses = ((UpdateAllQuery)getQuery()).getUpdateClauses(); boolean updateClausesHasBeenCloned = false; // Add a statement to update the optimistic locking field if their is one. OptimisticLockingPolicy policy = getDescriptor().getOptimisticLockingPolicy(); if (policy != null) { if(policy.getWriteLockField() != null) { Expression writeLock = builder.getField(policy.getWriteLockField()); // Note: The spec allows for version fields to be updated in bulk updates. Adding the writeLockUpdateExpression when there is already // a QueryKeyExpression associated with the version column will result in a scenario where one wins out by virtue of order of iteration // of updateClauses's entrySet. So we need to check the updateClause to see if the database fields in the writeLock expression are // already targeted for update. if (!isFieldInUpdate(writeLock, updateClauses)) { Expression writeLockUpdateExpression = policy.getWriteLockUpdateExpression(builder, getQuery().getSession()); if (writeLockUpdateExpression != null) { // clone it to keep user's original data intact updateClauses = (HashMap)updateClauses.clone(); updateClausesHasBeenCloned = true; updateClauses.put(writeLock, writeLockUpdateExpression); } } } } if (getDescriptor().hasSerializedObjectPolicy()) { if (!updateClausesHasBeenCloned) { // clone it to keep user's original data intact updateClauses = (HashMap)updateClauses.clone(); updateClausesHasBeenCloned = true; } Expression sopFieldExpression = builder.getField(getDescriptor().getSerializedObjectPolicy().getField()); updateClauses.put(sopFieldExpression, new ConstantExpression(null, sopFieldExpression)); } HashMap tables_databaseFieldsToValues = new HashMap(); HashMap> tablesToPrimaryKeyFields = new HashMap(); Iterator it = updateClauses.entrySet().iterator(); while(it.hasNext()) { Map.Entry entry = (Map.Entry)it.next(); Object fieldObject = entry.getKey(); DataExpression fieldExpression = null; Expression baseExpression = null; // QueryKeyExpression or FieldExpression of the field String attributeName = null; if(fieldObject instanceof String) { attributeName = (String)fieldObject; } else { // it should be either QueryKeyExpression or FieldExpression fieldExpression = (DataExpression)fieldObject; } DatabaseField field = null; DatabaseMapping mapping = null; if(attributeName != null) { mapping = getDescriptor().getObjectBuilder().getMappingForAttributeName(attributeName); if (mapping != null && !mapping.getFields().isEmpty()) { field = mapping.getFields().get(0); } if(field == null) { throw QueryException.updateAllQueryAddUpdateDoesNotDefineField(getDescriptor(), getQuery(), attributeName); } baseExpression = ((UpdateAllQuery)getQuery()).getExpressionBuilder().get(attributeName); } else if (fieldExpression != null) { // it should be either QueryKeyExpression or ExpressionBuilder if (fieldExpression.getBaseExpression() instanceof ExpressionBuilder) { field = getDescriptor().getObjectBuilder().getFieldForQueryKeyName(fieldExpression.getName()); } if(field == null) { DataExpression fieldExpressionClone = (DataExpression)fieldExpression.clone(); fieldExpressionClone.getBuilder().setQueryClass(getQuery().getReferenceClass()); fieldExpressionClone.getBuilder().setSession(getSession().getRootSession(null)); field = fieldExpressionClone.getField(); if(field == null) { throw QueryException.updateAllQueryAddUpdateDoesNotDefineField(getDescriptor(), getQuery(), fieldExpression.toString()); } } mapping = getDescriptor().getObjectBuilder().getMappingForField(field); baseExpression = fieldExpression; } Object valueObject = entry.getValue(); Vector fields; Vector values; Vector baseExpressions; if(mapping != null && mapping.isOneToOneMapping()) { fields = mapping.getFields(); int fieldsSize = fields.size(); values = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(fieldsSize); baseExpressions = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(fieldsSize); for(int i=0; i primaryKeyFields = tablesToPrimaryKeyFields.values().iterator().next(); setSQLStatement(buildUpdateAllStatement(table, databaseFieldsToValues, selectCallForExist, selectStatementForExist, primaryKeyFields)); } else { // To figure out the order of statements we need to find dependencies // between updating of tables. // Here's an example: // All objects with nameA = "Clob" should be changed so that nameA = "Alex" and nameB = "Bob"; // nameA is mapped to A.name and nameB mapped to B.name: // UPDATE B SET B.name = "Bob" WHERE A.name = "Clob" and A.id = B.id; // UPDATE A SET A.name = "Alex" WHERE A.name = "Clob" and A.id = B.id; // The order can't be altered - or there will be no updating of B. // To formalize that: for each table we'll gather two Collections: // leftFields - all the table's fields to receive a new value; // rightFields - all the fields either in assigned or selecton expression. // A_leftFields = {A.name}; A_rightFields = {A.name}. // B_leftFields = {B.name}; B_rightFields = {A.name}. // There are several comparison outcomes: // 1. A_leftFields doesn't intersect B_rightFields and // B_leftFields doesn't intersect A_rightFields // There is no dependency - doesn't matter which update goes first; // 2. A_leftFields intersects B_rightFields and // B_leftFields doesn't intersect A_rightFields // B should be updated before A (the case in the example). // 3. A_leftFields intersects B_rightFields and // B_leftFields intersects A_rightFields // Ordering conflict that can't be resolved without using transitionary storage. // // This ExpressionIterator will be used for collecting fields from // selection criteria and assigned expressions. ExpressionIterator expIterator = new ExpressionIterator() { @Override public void iterate(Expression each) { if(each instanceof DataExpression) { DataExpression dataExpression = (DataExpression)each; DatabaseField field = dataExpression.getField(); if(field != null) { ((Collection)getResult()).add(field); } } } @Override public boolean shouldIterateOverSubSelects() { return true; } }; // This will hold collection of fields from selection criteria expression. HashSet selectCallForExistFields = new HashSet(); if(selectCallForExist != null) { expIterator.setResult(selectCallForExistFields); expIterator.iterateOn(selectStatementForExist.getWhereClause()); } // Left of the assignment operator that is - the fields acquiring new values HashMap tablesToLeftFields = new HashMap(); // The fields right of the assignment operator AND the fields from whereClause HashMap tablesToRightFields = new HashMap(); // before and after vectors work together: n-th member of beforeTable should // be updated before than n-th member of afterTable Vector beforeTables = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(); Vector afterTables = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(); // Both keys and values are tables. // An entry indicates a timing conflict between the key and the value: // both key should be updated before value and value before key. HashMap simpleConflicts = new HashMap(); it = tables_databaseFieldsToValues.entrySet().iterator(); while(it.hasNext()) { Map.Entry entry = (Map.Entry)it.next(); // for each table to be updated DatabaseTable table = (DatabaseTable)entry.getKey(); // here's a Map of left hand fields to right hand expressions HashMap databaseFieldsToValues = (HashMap)entry.getValue(); // This will contain all the left hand fields HashSet leftFields = new HashSet(databaseFieldsToValues.size()); // This will contain all the left hand fields plus fields form selection criteria HashSet rightFields = (HashSet)selectCallForExistFields.clone(); expIterator.setResult(rightFields); Iterator itDatabaseFieldsToValues = databaseFieldsToValues.entrySet().iterator(); while(itDatabaseFieldsToValues.hasNext()) { // for each left hand - right hand expression pair Map.Entry databaseFieldValueEntry = (Map.Entry)itDatabaseFieldsToValues.next(); // here's the left hand database field DatabaseField field = (DatabaseField)databaseFieldValueEntry.getKey(); leftFields.add(field); // here's the right hand expression Object value = databaseFieldValueEntry.getValue(); if(value instanceof Expression) { Expression valueExpression = (Expression)value; // use iterator to extract all the fields expIterator.iterateOn(valueExpression); } else { // It should be SQLSelectStatement with a single field SQLSelectStatement selStatement = (SQLSelectStatement)value; // first one is the normalized value to be assigned expIterator.iterateOn((Expression)selStatement.getFields().get(0)); // whereClause - generated during normalization expIterator.iterateOn(selStatement.getWhereClause()); } } // now let's compare the table with the already processed tables Iterator itProcessedTables = tablesToLeftFields.keySet().iterator(); while(itProcessedTables.hasNext()) { DatabaseTable processedTable = (DatabaseTable)itProcessedTables.next(); HashSet processedTableLeftFields = (HashSet)tablesToLeftFields.get(processedTable); HashSet processedTableRightFields = (HashSet)tablesToRightFields.get(processedTable); boolean tableBeforeProcessedTable = false; Iterator itProcessedTableLeftField = processedTableLeftFields.iterator(); while(itProcessedTableLeftField.hasNext()) { if(rightFields.contains(itProcessedTableLeftField.next())) { tableBeforeProcessedTable = true; break; } } boolean processedTableBeforeTable = false; Iterator itLeftField = leftFields.iterator(); while(itLeftField.hasNext()) { if(processedTableRightFields.contains(itLeftField.next())) { processedTableBeforeTable = true; break; } } if(tableBeforeProcessedTable && !processedTableBeforeTable) { // table should be updated before processedTable beforeTables.add(table); afterTables.add(processedTable); } else if (!tableBeforeProcessedTable && processedTableBeforeTable) { // processedTable should be updated before table beforeTables.add(processedTable); afterTables.add(table); } else if (tableBeforeProcessedTable && processedTableBeforeTable) { // there is an order conflict between table and processTable simpleConflicts.put(processedTable, table); } } tablesToLeftFields.put(table, leftFields); tablesToRightFields.put(table, rightFields); } if(!simpleConflicts.isEmpty()) { prepareUpdateAllUsingTempStorage(tables_databaseFieldsToValuesOriginal, tablesToPrimaryKeyFields); return; } // This will contain tables in update order Vector orderedTables = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(tables_databaseFieldsToValues.size()); // first process the tables found in beforeTables / afterTables while(!beforeTables.isEmpty()) { // Find firstTable - the one that appears in beforeTables, but not afterTables. // That means there is no requirement to update it after any other table and we // can put it first in update order. There could be several such tables - // it doesn't matter which one will be picked. DatabaseTable firstTable = null; for(int i=0; i < beforeTables.size(); i++) { DatabaseTable beforeTable = (DatabaseTable)beforeTables.elementAt(i); if(!afterTables.contains(beforeTable)) { firstTable = beforeTable; break; } } if(firstTable == null) { // There is no firstTable - it's an order conflict between three or more tables prepareUpdateAllUsingTempStorage(tables_databaseFieldsToValuesOriginal, tablesToPrimaryKeyFields); return; } else { // Remove first table from beforeTables - there could be several entries. // Also remove the corresponding entries from afterTable. for(int i=beforeTables.size()-1; i>=0; i--) { if(beforeTables.elementAt(i).equals(firstTable)) { beforeTables.remove(i); afterTables.remove(i); } } // Add firstTable to orderedTables orderedTables.addElement(firstTable); } } // now all the remaining ones - there are no dependencies between them // so the order is arbitrary. Iterator itTables = tables_databaseFieldsToValues.keySet().iterator(); while(itTables.hasNext()) { DatabaseTable table = (DatabaseTable)itTables.next(); if(!orderedTables.contains(table)) { orderedTables.add(table); } } // finally create statements for(int i=0; i < orderedTables.size(); i++) { DatabaseTable table = (DatabaseTable)orderedTables.elementAt(i); HashMap databaseFieldsToValues = (HashMap)tables_databaseFieldsToValues.get(table); Collection primaryKeyFields = tablesToPrimaryKeyFields.get(table); getSQLStatements().addElement(buildUpdateAllStatement(table, databaseFieldsToValues, selectCallForExist, selectStatementForExist, primaryKeyFields)); } } ((UpdateAllQuery)getQuery()).setIsPreparedUsingTempStorage(false); super.prepareUpdateAll(); } protected SQLSelectStatement createSQLSelectStatementForUpdateAllForOracleAnonymousBlock(HashMap tables_databaseFieldsToValues) { ExpressionBuilder builder = ((UpdateAllQuery)getQuery()).getExpressionBuilder(); Expression whereClause = getSelectionCriteria(); ReportQuery reportQuery = new ReportQuery(getDescriptor().getJavaClass(), builder); reportQuery.setDescriptor(getDescriptor()); reportQuery.setSelectionCriteria(whereClause); reportQuery.setSession(getSession()); reportQuery.setShouldRetrievePrimaryKeys(true); Iterator itDatabaseFieldsToValues = tables_databaseFieldsToValues.values().iterator(); while(itDatabaseFieldsToValues.hasNext()) { HashMap databaseFieldsToValues = (HashMap)itDatabaseFieldsToValues.next(); Iterator itValues = databaseFieldsToValues.values().iterator(); while(itValues.hasNext()) { reportQuery.addAttribute("", (Expression)itValues.next()); } } SQLSelectStatement selectStatement = ((ExpressionQueryMechanism)reportQuery.getQueryMechanism()).buildReportQuerySelectStatement(false); reportQuery.setSession(null); return selectStatement; } protected SQLSelectStatement createSQLSelectStatementForModifyAllForTempTable(HashMap databaseFieldsToValues) { ExpressionBuilder builder = ((ModifyAllQuery)getQuery()).getExpressionBuilder(); Expression whereClause = getSelectionCriteria(); ReportQuery reportQuery = new ReportQuery(getDescriptor().getJavaClass(), builder); reportQuery.setDescriptor(getDescriptor()); reportQuery.setSelectionCriteria(whereClause); reportQuery.setSession(getSession()); reportQuery.setShouldRetrievePrimaryKeys(true); if(databaseFieldsToValues != null) { Iterator itValues = databaseFieldsToValues.values().iterator(); while(itValues.hasNext()) { reportQuery.addAttribute("", (Expression)itValues.next()); } } SQLSelectStatement selectStatement = ((ExpressionQueryMechanism)reportQuery.getQueryMechanism()).buildReportQuerySelectStatement(false); reportQuery.setSession(null); return selectStatement; } protected SQLModifyStatement buildUpdateAllStatementForOracleAnonymousBlock(HashMap tables_databaseFieldsToValues, HashMap tablesToPrimaryKeyFields) { SQLSelectStatement selectStatement = createSQLSelectStatementForUpdateAllForOracleAnonymousBlock(tables_databaseFieldsToValues); SQLCall selectCall = (SQLCall)selectStatement.buildCall(getSession()); SQLUpdateAllStatementForOracleAnonymousBlock updateAllStatement = new SQLUpdateAllStatementForOracleAnonymousBlock(); updateAllStatement.setTranslationRow(getTranslationRow()); updateAllStatement.setSelectCall(selectCall); updateAllStatement.setTables_databaseFieldsToValues(tables_databaseFieldsToValues); updateAllStatement.setTablesToPrimaryKeyFields(tablesToPrimaryKeyFields); updateAllStatement.setTable(getDescriptor().getTables().firstElement()); return updateAllStatement; } protected void prepareUpdateAllUsingTempStorage(HashMap tables_databaseFieldsToValues, HashMap> tablesToPrimaryKeyFields) { if(getExecutionSession().getPlatform().supportsTempTables()) { prepareUpdateAllUsingTempTables(tables_databaseFieldsToValues, tablesToPrimaryKeyFields); } else if(getExecutionSession().getPlatform().isOracle()) { prepareUpdateAllUsingOracleAnonymousBlock(tables_databaseFieldsToValues, tablesToPrimaryKeyFields); } else { throw QueryException.tempTablesNotSupported(getQuery(), Helper.getShortClassName(getExecutionSession().getPlatform())); } } /** * Pre-build the SQL statement from the expressions. */ protected void prepareUpdateAllUsingOracleAnonymousBlock(HashMap tables_databaseFieldsToValues, HashMap tablesToPrimaryKeyFields) { setSQLStatement(buildUpdateAllStatementForOracleAnonymousBlock(tables_databaseFieldsToValues, tablesToPrimaryKeyFields)); ((UpdateAllQuery)getQuery()).setIsPreparedUsingTempStorage(true); super.prepareUpdateAll(); } /** * Pre-build the SQL statement from the expressions. */ protected void prepareUpdateAllUsingTempTables(HashMap tables_databaseFieldsToValues, HashMap> tablesToPrimaryKeyFields) { int nTables = tables_databaseFieldsToValues.size(); Vector createTableStatements = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(nTables); Vector selectStatements = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(nTables); Vector updateStatements = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(nTables); Vector cleanupStatements = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(nTables); Iterator itEntrySets = tables_databaseFieldsToValues.entrySet().iterator(); while(itEntrySets.hasNext()) { Map.Entry entry = (Map.Entry)itEntrySets.next(); DatabaseTable table = (DatabaseTable)entry.getKey(); HashMap databaseFieldsToValues = (HashMap)entry.getValue(); List primaryKeyFields = tablesToPrimaryKeyFields.get(table); Vector statementsForTable = buildStatementsForUpdateAllForTempTables(table, databaseFieldsToValues, primaryKeyFields); createTableStatements.add(statementsForTable.elementAt(0)); selectStatements.add(statementsForTable.elementAt(1)); updateStatements.add(statementsForTable.elementAt(2)); cleanupStatements.add(statementsForTable.elementAt(3)); } getSQLStatements().addAll(createTableStatements); getSQLStatements().addAll(selectStatements); getSQLStatements().addAll(updateStatements); getSQLStatements().addAll(cleanupStatements); if (getExecutionSession().getPlatform().dontBindUpdateAllQueryUsingTempTables()) { if(getQuery().shouldBindAllParameters() || (getQuery().shouldIgnoreBindAllParameters() && getExecutionSession().getPlatform().shouldBindAllParameters())) { getQuery().setShouldBindAllParameters(false); getSession().warning("update_all_query_cannot_use_binding_on_this_platform", SessionLog.QUERY); } } ((UpdateAllQuery)getQuery()).setIsPreparedUsingTempStorage(true); super.prepareUpdateAll(); } /** * Build SQLStatements for delete all using temporary table. * @return {@code Vector} */ protected Vector buildStatementsForDeleteAllForTempTables() { Vector statements = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(); // retrieve rootTable and its primary key fields for composing temporary table DatabaseTable rootTable = getDescriptor().getMultipleTableInsertOrder().get(0); List rootTablePrimaryKeyFields = getPrimaryKeyFieldsForTable(rootTable); ClassDescriptor rootDescriptor = getDescriptor(); if(getDescriptor().hasInheritance()) { rootDescriptor = rootDescriptor.getInheritancePolicy().getRootParentDescriptor(); } Vector allFields = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(); Iterator it = rootDescriptor.getFields().iterator(); while(it.hasNext()) { DatabaseField field = it.next(); if(rootTable.equals(field.getTable())) { allFields.add(field); } } // statements will be executed in reverse order // statement for temporary table cleanup (Drop table or Delete from temp_table) SQLDeleteAllStatementForTempTable cleanupStatement = new SQLDeleteAllStatementForTempTable(); cleanupStatement.setMode(SQLModifyAllStatementForTempTable.CLEANUP_TEMP_TABLE); cleanupStatement.setTable(rootTable); statements.addElement(cleanupStatement); // delete statements using temporary table Vector deleteStatements = buildDeleteAllStatementsForTempTable(getDescriptor(), rootTable, rootTablePrimaryKeyFields, null); statements.addAll(deleteStatements); // Insert statement populating temporary table with criteria SQLSelectStatement selectStatement = createSQLSelectStatementForModifyAllForTempTable(null); SQLCall selectCall = (SQLCall)selectStatement.buildCall(getSession()); SQLDeleteAllStatementForTempTable insertStatement = new SQLDeleteAllStatementForTempTable(); insertStatement.setMode(SQLModifyAllStatementForTempTable.INSERT_INTO_TEMP_TABLE); insertStatement.setTable(rootTable); insertStatement.setTranslationRow(getTranslationRow()); insertStatement.setSelectCall(selectCall); insertStatement.setPrimaryKeyFields(rootTablePrimaryKeyFields); statements.addElement(insertStatement); // Create temporary table statement SQLDeleteAllStatementForTempTable createTempTableStatement = new SQLDeleteAllStatementForTempTable(); createTempTableStatement.setMode(SQLModifyAllStatementForTempTable.CREATE_TEMP_TABLE); createTempTableStatement.setTable(rootTable); createTempTableStatement.setAllFields(allFields); createTempTableStatement.setPrimaryKeyFields(rootTablePrimaryKeyFields); statements.addElement(createTempTableStatement); return statements; } /** * Build delete all SQLStatements using temporary table. * This is recursively called for multiple table child descriptors. * * NOTE: A similar pattern also used in method prepareDeleteAll(): * if you are updating this method consider applying a similar update to that method as well. * * @return {@code Vector} */ private Vector buildDeleteAllStatementsForTempTable(ClassDescriptor descriptor, DatabaseTable rootTable, List rootTablePrimaryKeyFields, Vector tablesToIgnore) { Vector statements = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(); List tablesInInsertOrder; if (tablesToIgnore == null) { // It's original (not a nested) method call. tablesInInsertOrder = descriptor.getMultipleTableInsertOrder(); } else { // It's a nested method call: tableInInsertOrder filled with descriptor's tables (in insert order), // the tables found in tablesToIgnore are thrown away - // they have already been taken care of by the caller. // In Employee example, query with reference class Project gets here // to handle LPROJECT table; tablesToIgnore contains PROJECT table. tablesInInsertOrder = new ArrayList(descriptor.getMultipleTableInsertOrder().size()); for (DatabaseTable table : descriptor.getMultipleTableInsertOrder()) { if (!tablesToIgnore.contains(table)) { tablesInInsertOrder.add(table); } } } if (!tablesInInsertOrder.isEmpty()) { for (DatabaseTable table : tablesInInsertOrder) { SQLDeleteAllStatementForTempTable deleteStatement = buildDeleteAllStatementForTempTable(rootTable, rootTablePrimaryKeyFields, table, getPrimaryKeyFieldsForTable(descriptor, table)); statements.add(deleteStatement); // Most databases support delete cascade constraints by specifying a ON DELETE CASCADE option when defining foreign key constraints. // However some databases which don't support foreign key constraints cannot use delete cascade constraints. // Therefore each delete operation should be executed in such a database platform instead of delegating delete cascade constraints. boolean supportForeignKeyConstraints = getSession().getPlatform().supportsForeignKeyConstraints(); boolean supportCascadeOnDelete = supportForeignKeyConstraints && descriptor.isCascadeOnDeleteSetOnDatabaseOnSecondaryTables(); // Only delete from first table if delete is cascaded on the database. if (supportCascadeOnDelete) { break; } } // Add statements for ManyToMany and DirectCollection mappings Vector deleteStatementsForMappings = buildDeleteAllStatementsForMappingsWithTempTable(descriptor, rootTable, tablesToIgnore == null); statements.addAll(deleteStatementsForMappings); } // Indicates whether the descriptor has children using extra tables. boolean hasChildrenWithExtraTables = descriptor.hasInheritance() && descriptor.getInheritancePolicy().hasChildren() && descriptor.getInheritancePolicy().hasMultipleTableChild(); // TBD: should we ignore subclasses in case descriptor doesn't want us to read them in? //** Currently in this code we do ignore. //** If it will be decided that we need to handle children in all cases //** the following statement should be changed to: boolean shouldHandleChildren = hasChildrenWithExtraTables; boolean shouldHandleChildren = hasChildrenWithExtraTables && descriptor.getInheritancePolicy().shouldReadSubclasses(); // Perform a nested method call for each child if (shouldHandleChildren) { // In Employee example: query for Project will make nested calls to // LargeProject and SmallProject and ask them to ignore PROJECT table Vector tablesToIgnoreForChildren = new Vector(); // The tables this descriptor has ignored, its children also should ignore. if (tablesToIgnore != null) { tablesToIgnoreForChildren.addAll(tablesToIgnore); } // If the descriptor reads subclasses there is no need for // subclasses to process its tables for the second time. if (descriptor.getInheritancePolicy().shouldReadSubclasses()) { tablesToIgnoreForChildren.addAll(tablesInInsertOrder); } Iterator it = descriptor.getInheritancePolicy().getChildDescriptors().iterator(); while (it.hasNext()) { ClassDescriptor childDescriptor = it.next(); // Need to process only "multiple tables" child descriptors if ((childDescriptor.getTables().size() > descriptor.getTables().size()) || (childDescriptor.getInheritancePolicy().hasMultipleTableChild())) { //recursively build for child desciptors Vector childStatements = buildDeleteAllStatementsForTempTable(childDescriptor, rootTable, rootTablePrimaryKeyFields, tablesToIgnoreForChildren); statements.addAll(childStatements); } } } return statements; } /** * Build SQL delete statement which delete from target table using temporary table. * @return SQLDeleteAllStatementForTempTable */ private SQLDeleteAllStatementForTempTable buildDeleteAllStatementForTempTable(DatabaseTable rootTable, List rootTablePrimaryKeyFields, DatabaseTable targetTable, List targetTablePrimaryKeyFields) { SQLDeleteAllStatementForTempTable deleteStatement = new SQLDeleteAllStatementForTempTable(); deleteStatement.setMode(SQLModifyAllStatementForTempTable.UPDATE_ORIGINAL_TABLE); deleteStatement.setTable(rootTable); deleteStatement.setPrimaryKeyFields(rootTablePrimaryKeyFields); deleteStatement.setTargetTable(targetTable); deleteStatement.setTargetPrimaryKeyFields(targetTablePrimaryKeyFields); return deleteStatement; } protected Vector buildStatementsForUpdateAllForTempTables(DatabaseTable table, HashMap databaseFieldsToValues, List primaryKeyFields) { Vector statements = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(4); Vector allFields = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(); Iterator it = getDescriptor().getFields().iterator(); while(it.hasNext()) { DatabaseField field = it.next(); if(table.equals(field.getTable())) { allFields.add(field); } } Collection assignedFields = databaseFieldsToValues.keySet(); HashMap databaseFieldsToValuesForInsert = databaseFieldsToValues; Collection assignedFieldsForInsert = assignedFields; // The platform doesn't allow nulls in select clause. // Remove all the constant expressions with value null: // can do that because all fields initialized to null when temp. table created. if(!getExecutionSession().getPlatform().isNullAllowedInSelectClause()) { databaseFieldsToValuesForInsert = new HashMap(databaseFieldsToValues.size()); Iterator itEntries = databaseFieldsToValues.entrySet().iterator(); while(itEntries.hasNext()) { Map.Entry entry = (Map.Entry)itEntries.next(); if(entry.getValue() instanceof ConstantExpression) { ConstantExpression constExp = (ConstantExpression)entry.getValue(); if(constExp.getValue() == null) { continue; } } databaseFieldsToValuesForInsert.put(entry.getKey(), entry.getValue()); } assignedFieldsForInsert = databaseFieldsToValuesForInsert.keySet(); } SQLUpdateAllStatementForTempTable createTempTableStatement = new SQLUpdateAllStatementForTempTable(); createTempTableStatement.setMode(SQLModifyAllStatementForTempTable.CREATE_TEMP_TABLE); createTempTableStatement.setTable(table); createTempTableStatement.setAllFields(allFields); createTempTableStatement.setAssignedFields(assignedFields); createTempTableStatement.setPrimaryKeyFields(primaryKeyFields); statements.addElement(createTempTableStatement); SQLSelectStatement selectStatement = createSQLSelectStatementForModifyAllForTempTable(databaseFieldsToValuesForInsert); SQLCall selectCall = (SQLCall)selectStatement.buildCall(getSession(), getQuery()); SQLUpdateAllStatementForTempTable insertStatement = new SQLUpdateAllStatementForTempTable(); insertStatement.setMode(SQLModifyAllStatementForTempTable.INSERT_INTO_TEMP_TABLE); insertStatement.setTable(table); insertStatement.setTranslationRow(getTranslationRow()); insertStatement.setSelectCall(selectCall); insertStatement.setAssignedFields(assignedFieldsForInsert); insertStatement.setPrimaryKeyFields(primaryKeyFields); statements.addElement(insertStatement); SQLUpdateAllStatementForTempTable updateStatement = new SQLUpdateAllStatementForTempTable(); updateStatement.setMode(SQLModifyAllStatementForTempTable.UPDATE_ORIGINAL_TABLE); updateStatement.setTable(table); updateStatement.setTranslationRow(getTranslationRow()); updateStatement.setAssignedFields(assignedFields); updateStatement.setPrimaryKeyFields(primaryKeyFields); statements.addElement(updateStatement); SQLUpdateAllStatementForTempTable cleanupStatement = new SQLUpdateAllStatementForTempTable(); cleanupStatement.setMode(SQLModifyAllStatementForTempTable.CLEANUP_TEMP_TABLE); cleanupStatement.setTable(table); statements.addElement(cleanupStatement); return statements; } protected List getPrimaryKeyFieldsForTable(DatabaseTable table) { return getPrimaryKeyFieldsForTable(getDescriptor(), table); } protected List getPrimaryKeyFieldsForTable(ClassDescriptor descriptor, DatabaseTable table) { List mainTablePrimaryKeyFields = descriptor.getPrimaryKeyFields(); if(table.equals(descriptor.getTables().firstElement())) { return mainTablePrimaryKeyFields; } else { List primaryKeyFields; Map additionalPksMap = descriptor.getAdditionalTablePrimaryKeyFields().get(table); primaryKeyFields = new ArrayList(additionalPksMap.size()); for (DatabaseField field : mainTablePrimaryKeyFields) { primaryKeyFields.add(additionalPksMap.get(field)); } return primaryKeyFields; } } /** * INTERNAL * Read all rows from the database. The code to retrieve the full inheritance hierarchy was removed. * * @return Vector containing the database rows. * @exception DatabaseException - an error has occurred on the database. */ @Override public Vector selectAllReportQueryRows() throws DatabaseException { return selectAllRowsFromTable(); } /** * Read all rows from the database. * @return Vector containing the database rows. * @exception DatabaseException - an error has occurred on the database. */ @Override public Vector selectAllRows() throws DatabaseException { // Check for multiple table inheritance which may require multiple queries. if (!((ObjectLevelReadQuery)this.query).shouldOuterJoinSubclasses()) { ClassDescriptor descriptor = getDescriptor(); if (descriptor.hasInheritance() && descriptor.getInheritancePolicy().requiresMultipleTableSubclassRead() && (!descriptor.getInheritancePolicy().hasView())) { return descriptor.getInheritancePolicy().selectAllRowUsingMultipleTableSubclassRead((ObjectLevelReadQuery)this.query); } } return selectAllRowsFromTable(); } /** * Read all rows from the database. * This is used only from query mechanism on a abstract-multiple table read. */ public Vector selectAllRowsFromConcreteTable() throws DatabaseException { ObjectLevelReadQuery query = (ObjectLevelReadQuery)this.query; // PERF: First check the subclass calls cache for the prepared call. // Must clear the translation row to avoid in-lining parameters unless not a prepared query. boolean shouldPrepare = query.shouldPrepare(); DatabaseCall call = null; if (shouldPrepare) { call = query.getConcreteSubclassCalls().get(query.getReferenceClass()); } if (call == null) { AbstractRecord translationRow = query.getTranslationRow(); if (shouldPrepare) { query.setTranslationRow(null); } setSQLStatement(buildConcreteSelectStatement()); // Must also build the call. super.prepareSelectAllRows(); if (shouldPrepare) { if (query.hasJoining()) { query.getConcreteSubclassJoinedMappingIndexes().put(query.getReferenceClass(), query.getJoinedAttributeManager().getJoinedMappingIndexes_()); } query.getConcreteSubclassCalls().put(query.getReferenceClass(), (DatabaseCall)this.call); query.setTranslationRow(translationRow); } } else { setCall(call); if (shouldPrepare && query.hasJoining()) { query.getJoinedAttributeManager().setJoinedMappingIndexes_(query.getConcreteSubclassJoinedMappingIndexes().get(query.getReferenceClass())); } } return super.selectAllRows(); } /** * Read all rows from the database. * @return Vector containing the database rows. * @exception DatabaseException - an error has occurred on the database. */ public Vector selectAllRowsFromTable() throws DatabaseException { return super.selectAllRows(); } /** * Read a single row from the database. Create an SQL statement object, * use it to create an SQL command string, and delegate row building * responsibility to the accessor. */ @Override public AbstractRecord selectOneRow() throws DatabaseException { // Check for multiple table inheritance which may require multiple queries. if (!getReadObjectQuery().shouldOuterJoinSubclasses()) { ClassDescriptor descriptor = getDescriptor(); if (descriptor.hasInheritance() && descriptor.getInheritancePolicy().requiresMultipleTableSubclassRead() && (!descriptor.getInheritancePolicy().hasView())) { return descriptor.getInheritancePolicy().selectOneRowUsingMultipleTableSubclassRead((ReadObjectQuery)this.query); } } return selectOneRowFromTable(); } /** * Read a single row from the database. * This is used from query mechanism during an abstract-multiple table read. */ public AbstractRecord selectOneRowFromConcreteTable() throws DatabaseException { ObjectLevelReadQuery query = (ObjectLevelReadQuery)this.query; // PERF: First check the subclass calls cache for the prepared call. // Must clear the translation row to avoid in-lining parameters unless not a prepared query. boolean shouldPrepare = query.shouldPrepare(); DatabaseCall call = null; if (shouldPrepare) { call = query.getConcreteSubclassCalls().get(query.getReferenceClass()); } if (call == null) { AbstractRecord translationRow = query.getTranslationRow(); if (shouldPrepare) { query.setTranslationRow(null); } setSQLStatement(buildConcreteSelectStatement()); // Must also build the call. super.prepareSelectOneRow(); if (shouldPrepare) { if (query.hasJoining()) { query.getConcreteSubclassJoinedMappingIndexes().put(query.getReferenceClass(), query.getJoinedAttributeManager().getJoinedMappingIndexes_()); } query.getConcreteSubclassCalls().put(query.getReferenceClass(), (DatabaseCall)this.call); query.setTranslationRow(translationRow); } } else { setCall(call); if (shouldPrepare && query.hasJoining()) { query.getJoinedAttributeManager().setJoinedMappingIndexes_(query.getConcreteSubclassJoinedMappingIndexes().get(query.getReferenceClass())); } } return super.selectOneRow(); } /** * Read a single row from the database. Create an SQL statement object, * use it to create an SQL command string, and delegate row building * responsibility to the accessor. */ public AbstractRecord selectOneRowFromTable() throws DatabaseException { return super.selectOneRow(); } /** * Set the selection criteria of the query. */ public void setSelectionCriteria(Expression expression) { this.selectionCriteria = expression; } /** * Pass to this method a table mapped by query's descriptor. * Returns the highest descriptor in inheritance hierarchy that mapps this table. */ protected ClassDescriptor getHighestDescriptorMappingTable(DatabaseTable table) { // find the highest descriptor in inheritance hierarchy mapped to the table ClassDescriptor desc = getDescriptor(); ClassDescriptor parentDescriptor = getDescriptor().getInheritancePolicy().getParentDescriptor(); while(parentDescriptor != null && parentDescriptor.getTables().contains(table)) { desc = parentDescriptor; parentDescriptor = parentDescriptor.getInheritancePolicy().getParentDescriptor(); } return desc; } }





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