/*******************************************************************************
* Copyright (c) 1998, 2009 Oracle. All rights reserved.
* This program and the accompanying materials are made available under the
* terms of the Eclipse Public License v1.0 and Eclipse Distribution License v. 1.0
* which accompanies this distribution.
* The Eclipse Public License is available at http://www.eclipse.org/legal/epl-v10.html
* and the Eclipse Distribution License is available at
* http://www.eclipse.org/org/documents/edl-v10.php.
*
* Contributors:
* Oracle - initial API and implementation from Oracle TopLink
******************************************************************************/
package org.eclipse.persistence.mappings;
import java.security.AccessController;
import java.security.PrivilegedActionException;
import java.util.*;
import org.eclipse.persistence.descriptors.ClassDescriptor;
import org.eclipse.persistence.descriptors.changetracking.*;
import org.eclipse.persistence.internal.descriptors.changetracking.AttributeChangeListener;
import org.eclipse.persistence.internal.descriptors.changetracking.ObjectChangeListener;
import org.eclipse.persistence.exceptions.*;
import org.eclipse.persistence.expressions.*;
import org.eclipse.persistence.history.*;
import org.eclipse.persistence.indirection.IndirectCollection;
import org.eclipse.persistence.internal.databaseaccess.DatasourcePlatform;
import org.eclipse.persistence.internal.databaseaccess.Platform;
import org.eclipse.persistence.internal.descriptors.*;
import org.eclipse.persistence.internal.expressions.*;
import org.eclipse.persistence.internal.helper.*;
import org.eclipse.persistence.internal.identitymaps.*;
import org.eclipse.persistence.internal.queries.*;
import org.eclipse.persistence.internal.sessions.remote.*;
import org.eclipse.persistence.internal.security.PrivilegedAccessHelper;
import org.eclipse.persistence.internal.security.PrivilegedClassForName;
import org.eclipse.persistence.internal.security.PrivilegedNewInstanceFromClass;
import org.eclipse.persistence.internal.sessions.*;
import org.eclipse.persistence.mappings.converters.*;
import org.eclipse.persistence.mappings.foundation.MapComponentMapping;
import org.eclipse.persistence.queries.*;
import org.eclipse.persistence.sessions.remote.*;
import org.eclipse.persistence.sessions.ObjectCopyingPolicy;
import org.eclipse.persistence.sessions.DatabaseRecord;
/**
* <p><b>Purpose</b>: This mapping is used to store a collection of simple types (String, Number, Date, etc.)
* into a single table. The table must store the value and a foreign key to the source object.
* A converter can be used if the desired object type and the data type do not match.
*
* @see Converter
* @see ObjectTypeConverter
* @see TypeConversionConverter
* @see SerializedObjectConverter
*
* @author Sati
* @since TOPLink/Java 1.0
*/
public class DirectCollectionMapping extends CollectionMapping implements RelationalMapping, MapComponentMapping {
/** Used for data modification events. */
protected static final String Delete = "delete";
protected static final String Insert = "insert";
protected static final String DeleteAll = "deleteAll";
/** Allows user defined conversion between the object value and the database value. */
protected Converter valueConverter;
protected String valueConverterClassName;
/** Stores the reference table*/
protected transient DatabaseTable referenceTable;
/** The direct field name is converted and stored */
protected transient DatabaseField directField;
protected transient Vector<DatabaseField> sourceKeyFields;
protected transient Vector<DatabaseField> referenceKeyFields;
/** Used for insertion for m-m and dc, not used in 1-m. */
protected transient DataModifyQuery insertQuery;
/** Used for deletion when ChangeSets are used */
protected transient ModifyQuery changeSetDeleteQuery;
protected transient boolean hasCustomDeleteQuery;
protected transient boolean hasCustomInsertQuery;
protected HistoryPolicy historyPolicy;
/**
* PUBLIC:
* Default constructor.
*/
public DirectCollectionMapping() {
this.insertQuery = new DataModifyQuery();
this.sourceKeyFields = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(1);
this.referenceKeyFields = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(1);
this.selectionQuery = new DirectReadQuery();
this.hasCustomInsertQuery = false;
this.isPrivateOwned = true;
}
public boolean isRelationalMapping() {
return true;
}
/**
* PUBLIC:
* Return the converter on the mapping.
* A converter can be used to convert between the direct collection's object value and database value.
*/
public Converter getValueConverter() {
return valueConverter;
}
/**
* PUBLIC:
* Set the converter on the mapping.
* A converter can be used to convert between the direct collection's object value and database value.
*/
public void setValueConverter(Converter valueConverter) {
this.valueConverter = valueConverter;
}
/**
* PUBLIC:
* Set the converter class name on the mapping. Initialized in
* convertClassNamesToClasses.
* A converter can be used to convert between the direct collection's object value and database value.
*/
public void setValueConverterClassName(String valueConverterClassName) {
this.valueConverterClassName = valueConverterClassName;
}
/**
* PUBLIC:
* Add the reference key field.
* This is used for composite reference keys.
* This is the foreign key field in the direct table referencing the primary key of the source object.
* Both the reference field and the source field that it references must be provided.
*/
public void addReferenceKeyField(DatabaseField referenceForeignKeyField, DatabaseField sourcePrimaryKeyField) {
getSourceKeyFields().addElement(sourcePrimaryKeyField);
getReferenceKeyFields().addElement(referenceForeignKeyField);
}
/**
* PUBLIC:
* Add the name of the reference key field.
* This is used for composite reference keys.
* This is the foreign key field in the direct table referencing the primary key of the source object.
* Both the reference field name and the name of the source field that it references must be provided.
*/
public void addReferenceKeyFieldName(String referenceForeignKeyFieldName, String sourcePrimaryKeyFieldName) {
addReferenceKeyField(new DatabaseField(referenceForeignKeyFieldName), new DatabaseField(sourcePrimaryKeyFieldName));
}
/**
* INTERNAL:
* Clone and prepare the selection query as a nested batch read query.
* This is used for nested batch reading.
*/
public ReadQuery prepareNestedBatchQuery(ReadAllQuery query) {
DataReadQuery batchQuery = new DataReadQuery();
// Join the query where clause with the mappings,
// this will cause a join that should bring in all of the target objects.
ExpressionBuilder builder;
Expression originalSelectionCriteria = null;
// 2612538 - the default size of Map (32) is appropriate
Map clonedExpressions = new IdentityHashMap();
if (query.getSelectionCriteria() == null) {
builder = new ExpressionBuilder();
// S.M. For flashback.
if (query.hasAsOfClause()) {
builder.asOf(query.getAsOfClause());
}
} else {
// For 2729729 must clone the original selection criteria first,
// otherwise the original query will be corrupted.
originalSelectionCriteria = query.getSelectionCriteria().copiedVersionFrom(clonedExpressions);
builder = originalSelectionCriteria.getBuilder();
}
Expression twisted = builder.twist(getSelectionQuery().getSQLStatement().getWhereClause(), builder);
// For 2729729, rebuildOn is not needed as the base is still the same.
if (originalSelectionCriteria != null) {
twisted = twisted.and(originalSelectionCriteria);
}
if (query.getDescriptor().getQueryManager().getAdditionalJoinExpression() != null) {
twisted = twisted.and(query.getDescriptor().getQueryManager().getAdditionalJoinExpression().rebuildOn(builder));
}
if (getHistoryPolicy() != null) {
if (query.getSession().getAsOfClause() != null) {
builder.asOf(query.getSession().getAsOfClause());
} else if (builder.getAsOfClause() == null) {
builder.asOf(AsOfClause.NO_CLAUSE);
}
twisted = twisted.and(getHistoryPolicy().additionalHistoryExpression(builder));
}
SQLSelectStatement batchStatement = new SQLSelectStatement();
for (Enumeration enumtr = getReferenceKeyFields().elements(); enumtr.hasMoreElements();) {
batchStatement.addField(builder.getTable(getReferenceTable()).getField((DatabaseField)enumtr.nextElement()));
}
// For 3256419, add key field for DirectMapMapping
if (this instanceof DirectMapMapping) {
batchStatement.addField(builder.getTable(getReferenceTable()).getField(((DirectMapMapping)this).getDirectKeyField()));
}
batchStatement.addField(builder.getTable(getReferenceTable()).getField(getDirectField()));
batchStatement.setWhereClause(twisted);
batchStatement.normalize(query.getSession(), getDescriptor(), clonedExpressions);
batchQuery.setSQLStatement(batchStatement);
return batchQuery;
}
/**
* INTERNAL:
* Clone and prepare the joined direct query.
* Since direct-collection does not build objects a nest query is not required.
*/
public ObjectLevelReadQuery prepareNestedJoins(JoinedAttributeManager joinManager, ObjectBuildingQuery baseQuery, AbstractSession session) {
return null;
}
/**
* INTERNAL:
* Return the value of the field from the row or a value holder on the query to obtain the object.
*/
protected Object valueFromRowInternalWithJoin(AbstractRecord row, JoinedAttributeManager joinManager, ObjectBuildingQuery sourceQuery, AbstractSession executionSession) throws DatabaseException {
ContainerPolicy policy = getContainerPolicy();
Object value = policy.containerInstance();
ObjectBuilder objectBuilder = getDescriptor().getObjectBuilder();
// Extract the primary key of the source object, to filter only the joined rows for that object.
Vector sourceKey = objectBuilder.extractPrimaryKeyFromRow(row, executionSession);
CacheKey sourceCacheKey = new CacheKey(sourceKey);
// If the query was using joining, all of the result rows by primary key will have been computed.
List rows = joinManager.getDataResultsByPrimaryKey().get(sourceCacheKey);
// A set of direct values must be maintained to avoid duplicates from multiple 1-m joins.
Set directValues = new HashSet();
Converter valueConverter = getValueConverter();
// For each rows, extract the target row and build the target object and add to the collection.
for (int index = 0; index < rows.size(); index++) {
AbstractRecord sourceRow = (AbstractRecord)rows.get(index);
AbstractRecord targetRow = sourceRow;
// The field for many objects may be in the row,
// so build the subpartion of the row through the computed values in the query,
// this also helps the field indexing match.
targetRow = trimRowForJoin(targetRow, joinManager, executionSession);
// Partial object queries must select the primary key of the source and related objects.
// If the target joined rows in null (outerjoin) means an empty collection.
Object directValue = targetRow.get(getDirectField());
if (directValue == null) {
// A null direct value means an empty collection returned as nulls from an outerjoin.
return getIndirectionPolicy().valueFromRow(value);
}
// Only build/add the taregt object once, skip duplicates from multiple 1-m joins.
if (!directValues.contains(directValue)) {
directValues.add(directValue);
// Allow for value conversion.
if (valueConverter != null) {
directValue = valueConverter.convertDataValueToObjectValue(directValue, executionSession);
}
policy.addInto(directValue, value, executionSession);
}
}
return getIndirectionPolicy().valueFromRow(value);
}
/**
* INTERNAL:
* Copy of the attribute of the object.
* This is NOT used for unit of work but for templatizing an object.
*/
public void buildCopy(Object copy, Object original, ObjectCopyingPolicy policy) {
Object attributeValue = getRealCollectionAttributeValueFromObject(original, policy.getSession());
attributeValue = getContainerPolicy().cloneFor(attributeValue);
setRealAttributeValueInObject(copy, attributeValue);
}
/**
* INTERNAL:
* Clone the element, if necessary.
* DirectCollections hold on to objects that do not have Descriptors
* (e.g. int, String). These objects do not need to be cloned, unless they use a converter - they
* are immutable.
*/
protected Object buildElementClone(Object element, UnitOfWorkImpl unitOfWork, boolean isExisting) {
Object cloneValue = element;
if ((getValueConverter() != null) && getValueConverter().isMutable()) {
cloneValue = getValueConverter().convertDataValueToObjectValue(getValueConverter().convertObjectValueToDataValue(cloneValue, unitOfWork), unitOfWork);
}
return cloneValue;
}
/**
* INTERNAL:
* Cascade perform delete through mappings that require the cascade
*/
public void cascadePerformRemoveIfRequired(Object object, UnitOfWorkImpl uow, Map visitedObjects) {
//as this mapping type references primitive objects this method does not apply
}
/**
* INTERNAL:
* Cascade perform removal of orphaned private owned objects from the UnitOfWorkChangeSet
*/
public void cascadePerformRemovePrivateOwnedObjectFromChangeSetIfRequired(Object object, UnitOfWorkImpl uow, Map visitedObjects) {
// as this mapping type references primitive objects this method does not apply
}
/**
* INTERNAL:
* Cascade registerNew for Create through mappings that require the cascade
*/
public void cascadeRegisterNewIfRequired(Object object, UnitOfWorkImpl uow, Map visitedObjects) {
//as this mapping type references primitive objects this method does not apply
}
/**
* INTERNAL:
* Cascade discover and persist new objects during commit.
*/
public void cascadeDiscoverAndPersistUnregisteredNewObjects(Object object, Map newObjects, Map unregisteredExistingObjects, Map visitedObjects, UnitOfWorkImpl uow) {
// Direct mappings do not require any cascading.
}
/**
* INTERNAL:
* The mapping clones itself to create deep copy.
*/
public Object clone() {
DirectCollectionMapping clone = (DirectCollectionMapping)super.clone();
clone.setSourceKeyFields(cloneFields(getSourceKeyFields()));
clone.setReferenceKeyFields(cloneFields(getReferenceKeyFields()));
return clone;
}
/**
* INTERNAL:
* This method is used to calculate the differences between two collections.
*/
public void compareCollectionsForChange(Object oldCollection, Object newCollection, ChangeRecord changeRecord, AbstractSession session) {
ContainerPolicy cp = getContainerPolicy();
int numberOfNewNulls = 0;
HashMap originalKeyValues = new HashMap(10);
HashMap cloneKeyValues = new HashMap(10);
if (oldCollection != null) {
Object backUpIter = cp.iteratorFor(oldCollection);
while (cp.hasNext(backUpIter)) {// Make a lookup of the objects
Object secondObject = cp.next(backUpIter, session);
// For CR#2258/CR#2378 handle null values inserted in a collection.
if (secondObject == null) {
numberOfNewNulls--;
} else {
Integer count = (Integer)originalKeyValues.get(secondObject);
if (count == null) {
originalKeyValues.put(secondObject, new Integer(1));
} else {
originalKeyValues.put(secondObject, new Integer(count.intValue() + 1));
}
}
}
}
// should a removal occur this is the original count of objects on the database.
// this value is used to determine how many objects to re-insert after the delete as a
// delete will delete all of the objects not just one.
HashMap databaseCount = (HashMap)originalKeyValues.clone();
int databaseNullCount = Math.abs(numberOfNewNulls);
if (newCollection != null) {
Object cloneIter = cp.iteratorFor(newCollection);
/* The following code is used to compare objects in a direct collection.
Because objects in a direct collection are primitives and may be the same object
the following code must count the number of instances in the collection not just the
existence of an object.
*/
while (cp.hasNext(cloneIter)) {//Compare them with the objects from the clone
Object firstObject = cp.next(cloneIter, session);
// For CR#2258/CR#2378 handle null values inserted in a collection.
if (firstObject == null) {
numberOfNewNulls++;
} else {
Integer count = (Integer)originalKeyValues.get(firstObject);
if (count == null) {//the object was not in the backup
Integer cloneCount = (Integer)cloneKeyValues.get(firstObject);
//Add it to the additions hashtable
if (cloneCount == null) {
cloneKeyValues.put(firstObject, new Integer(1));
} else {
cloneKeyValues.put(firstObject, new Integer(cloneCount.intValue() + 1));
}
} else if (count.intValue() == 1) {
//There is only one object so remove the whole reference
originalKeyValues.remove(firstObject);
} else {
originalKeyValues.put(firstObject, new Integer(count.intValue() - 1));
}
}
}
}
if (cloneKeyValues.isEmpty() && originalKeyValues.isEmpty() && (numberOfNewNulls == 0) && (!changeRecord.getOwner().isNew())) {
return;
}
((DirectCollectionChangeRecord)changeRecord).addAdditionChange(cloneKeyValues, databaseCount);
((DirectCollectionChangeRecord)changeRecord).addRemoveChange(originalKeyValues, databaseCount);
//For CR#2258, produce a changeRecord which reflects the addition and removal of null values.
if (numberOfNewNulls != 0) {
((DirectCollectionChangeRecord)changeRecord).getCommitAddMap().put(DirectCollectionChangeRecord.Null, new Integer(databaseNullCount));
if (numberOfNewNulls > 0) {
((DirectCollectionChangeRecord)changeRecord).addAdditionChange(DirectCollectionChangeRecord.Null, new Integer(numberOfNewNulls));
} else {
numberOfNewNulls *= -1;
((DirectCollectionChangeRecord)changeRecord).addRemoveChange(DirectCollectionChangeRecord.Null, new Integer(numberOfNewNulls));
}
}
}
/**
* INTERNAL:
* This method compares the changes between two direct collections. Comparisons are made on equality
* not identity.
*/
public ChangeRecord compareForChange(Object clone, Object backUp, ObjectChangeSet owner, AbstractSession session) {
Object cloneAttribute = getAttributeValueFromObject(clone);
Object backUpAttribute = null;
if ((cloneAttribute != null) && (!getIndirectionPolicy().objectIsInstantiated(cloneAttribute))) {
return null;
}
Object cloneObjectCollection = getRealCollectionAttributeValueFromObject(clone, session);
Object backUpCollection = null;
if (!owner.isNew()) {
backUpAttribute = getAttributeValueFromObject(backUp);
if ((backUpAttribute == null) && (cloneAttribute == null)) {
return null;
}
backUpCollection = getRealCollectionAttributeValueFromObject(backUp, session);
}
DirectCollectionChangeRecord changeRecord = new DirectCollectionChangeRecord(owner);
changeRecord.setAttribute(getAttributeName());
changeRecord.setMapping(this);
compareCollectionsForChange(backUpCollection, cloneObjectCollection, changeRecord, session);
if (changeRecord.hasChanges()) {
return changeRecord;
}
return null;
}
/**
* INTERNAL:
* Compare the attributes belonging to this mapping for the objects.
*/
public boolean compareObjects(Object firstObject, Object secondObject, AbstractSession session) {
Object firstCollection = getRealCollectionAttributeValueFromObject(firstObject, session);
Object secondCollection = getRealCollectionAttributeValueFromObject(secondObject, session);
ContainerPolicy containerPolicy = getContainerPolicy();
if (containerPolicy.sizeFor(firstCollection) != containerPolicy.sizeFor(secondCollection)) {
return false;
}
HashMap firstCounter = new HashMap();
HashMap secondCounter = new HashMap();
for (Object iter = containerPolicy.iteratorFor(firstCollection);
containerPolicy.hasNext(iter);) {
Object object = containerPolicy.next(iter, session);
if (firstCounter.containsKey(object)) {
int count = ((Integer)firstCounter.get(object)).intValue();
firstCounter.put(object, new Integer(++count));
} else {
firstCounter.put(object, new Integer(1));
}
}
for (Object iter = containerPolicy.iteratorFor(secondCollection);
containerPolicy.hasNext(iter);) {
Object object = containerPolicy.next(iter, session);
if (secondCounter.containsKey(object)) {
int count = ((Integer)secondCounter.get(object)).intValue();
secondCounter.put(object, new Integer(++count));
} else {
secondCounter.put(object, new Integer(1));
}
}
for (Iterator iterator = firstCounter.keySet().iterator(); iterator.hasNext();) {
Object object = iterator.next();
if (!secondCounter.containsKey(object) || (((Integer)secondCounter.get(object)).intValue() != ((Integer)firstCounter.get(object)).intValue())) {
return false;
} else {
iterator.remove();
secondCounter.remove(object);
}
}
if (!firstCounter.isEmpty() || !secondCounter.isEmpty()) {
return false;
}
return true;
}
/**
* INTERNAL:
* Convert all the class-name-based settings in this mapping to actual class-based
* settings
* This method is implemented by subclasses as necessary.
* @param classLoader
*/
public void convertClassNamesToClasses(ClassLoader classLoader){
super.convertClassNamesToClasses(classLoader);
if (valueConverter != null) {
if (valueConverter instanceof TypeConversionConverter){
((TypeConversionConverter)valueConverter).convertClassNamesToClasses(classLoader);
} else if (valueConverter instanceof ObjectTypeConverter) {
// To avoid 1.5 dependencies with the EnumTypeConverter check
// against ObjectTypeConverter.
((ObjectTypeConverter) valueConverter).convertClassNamesToClasses(classLoader);
}
}
// Instantiate any custom converter class
if (valueConverterClassName != null) {
Class valueConverterClass;
Converter valueConverter;
try {
if (PrivilegedAccessHelper.shouldUsePrivilegedAccess()){
try {
valueConverterClass = (Class) AccessController.doPrivileged(new PrivilegedClassForName(valueConverterClassName, true, classLoader));
} catch (PrivilegedActionException exception) {
throw ValidationException.classNotFoundWhileConvertingClassNames(valueConverterClassName, exception.getException());
}
try {
valueConverter = (Converter) AccessController.doPrivileged(new PrivilegedNewInstanceFromClass(valueConverterClass));
} catch (PrivilegedActionException exception) {
throw ValidationException.classNotFoundWhileConvertingClassNames(valueConverterClassName, exception.getException());
}
} else {
valueConverterClass = org.eclipse.persistence.internal.security.PrivilegedAccessHelper.getClassForName(valueConverterClassName, true, classLoader);
valueConverter = (Converter) org.eclipse.persistence.internal.security.PrivilegedAccessHelper.newInstanceFromClass(valueConverterClass);
}
} catch (ClassNotFoundException exc) {
throw ValidationException.classNotFoundWhileConvertingClassNames(valueConverterClassName, exc);
} catch (Exception e) {
// Catches IllegalAccessException and InstantiationException
throw ValidationException.classNotFoundWhileConvertingClassNames(valueConverterClassName, e);
}
setValueConverter(valueConverter);
}
};
/**
* INTERNAL:
* Extract the source primary key value from the reference direct row.
* Used for batch reading, most following same order and fields as in the mapping.
*/
protected Vector extractKeyFromReferenceRow(AbstractRecord row, AbstractSession session) {
Vector key = new Vector(getReferenceKeyFields().size());
for (int index = 0; index < getReferenceKeyFields().size(); index++) {
DatabaseField relationField = getReferenceKeyFields().elementAt(index);
DatabaseField sourceField = getSourceKeyFields().elementAt(index);
Object value = row.get(relationField);
// Must ensure the classification gets a cache hit.
try {
value = session.getDatasourcePlatform().getConversionManager().convertObject(value, getDescriptor().getObjectBuilder().getFieldClassification(sourceField));
} catch (ConversionException e) {
throw ConversionException.couldNotBeConverted(this, getDescriptor(), e);
}
key.addElement(value);
}
return key;
}
/**
* INTERNAL:
* Extract the primary key value from the source row.
* Used for batch reading, most following same order and fields as in the mapping.
*/
protected Vector extractPrimaryKeyFromRow(AbstractRecord row, AbstractSession session) {
Vector key = new Vector(getSourceKeyFields().size());
for (Enumeration fieldEnum = getSourceKeyFields().elements(); fieldEnum.hasMoreElements();) {
DatabaseField field = (DatabaseField)fieldEnum.nextElement();
Object value = row.get(field);
// Must ensure the classification to get a cache hit.
try {
value = session.getDatasourcePlatform().getConversionManager().convertObject(value, getDescriptor().getObjectBuilder().getFieldClassification(field));
} catch (ConversionException e) {
throw ConversionException.couldNotBeConverted(this, getDescriptor(), e);
}
key.addElement(value);
}
return key;
}
/**
* INTERNAL:
* Extract the value from the batch optimized query.
*/
public Object extractResultFromBatchQuery(DatabaseQuery query, AbstractRecord databaseRow, AbstractSession session, AbstractRecord argumentRow) {
//this can be null, because either one exists in the query or it will be created
Hashtable referenceDataByKey = null;
ContainerPolicy mappingContainerPolicy = getContainerPolicy();
synchronized (query) {
referenceDataByKey = getBatchReadObjects(query, session);
mappingContainerPolicy = getContainerPolicy();
if (referenceDataByKey == null) {
Vector rows = (Vector)session.executeQuery(query, argumentRow);
referenceDataByKey = new Hashtable();
for (Enumeration rowsEnum = rows.elements(); rowsEnum.hasMoreElements();) {
AbstractRecord referenceRow = (AbstractRecord)rowsEnum.nextElement();
Object referenceValue = referenceRow.get(getDirectField());
CacheKey eachReferenceKey = new CacheKey(extractKeyFromReferenceRow(referenceRow, session));
Object container = referenceDataByKey.get(eachReferenceKey);
if (container == null) {
container = mappingContainerPolicy.containerInstance();
referenceDataByKey.put(eachReferenceKey, container);
}
// Allow for value conversion.
if (getValueConverter() != null) {
referenceValue = getValueConverter().convertDataValueToObjectValue(referenceValue, query.getSession());
}
mappingContainerPolicy.addInto(referenceValue, container, query.getSession());
}
setBatchReadObjects(referenceDataByKey, query, session);
}
}
Object result = referenceDataByKey.get(new CacheKey(extractPrimaryKeyFromRow(databaseRow, session)));
// The source object might not have any target objects
if (result == null) {
return mappingContainerPolicy.containerInstance();
} else {
return result;
}
}
/**
* INTERNAL:
* At this point, we realize we don't have indirection;
* so we need to replace the reference object(s) with
* the corresponding object(s) from the remote session.
*
* The reference objects for a DirectCollectionMapping
* are primitives, so they do not need to be replaced.
*/
public void fixRealObjectReferences(Object object, Map objectInformation, Map processedObjects, ObjectLevelReadQuery query, RemoteSession session) {
// do nothing
}
protected ModifyQuery getDeleteQuery() {
if (changeSetDeleteQuery == null) {
changeSetDeleteQuery = new DataModifyQuery();
}
return changeSetDeleteQuery;
}
/**
* INTERNAL:
* Returns the set of fields that should be selected to build this mapping's value(s).
* This is used by expressions to determine which fields to include in the select clause for non-object expressions.
*/
public Vector getSelectFields() {
Vector fields = new NonSynchronizedVector(2);
fields.add(getDirectField());
return fields;
}
/**
* INTERNAL:
* Returns the table(s) that should be selected to build this mapping's value(s).
* This is used by expressions to determine which tables to include in the from clause for non-object expressions.
*/
public Vector getSelectTables() {
Vector tables = new NonSynchronizedVector(0);
tables.add(getReferenceTable());
return tables;
}
/**
* INTERNAL:
* Return the direct field.
* This is the field in the direct table to store the values.
*/
public DatabaseField getDirectField() {
return directField;
}
/**
* PUBLIC:
* Returns the name of the field name in the reference table.
*/
public String getDirectFieldName() {
if (getDirectField() == null) {
return null;
}
return getDirectField().getQualifiedName();
}
protected DataModifyQuery getInsertQuery() {
return insertQuery;
}
/**
* INTERNAL:
* Returns the join criteria stored in the mapping selection query. This criteria
* is used to read reference objects across the tables from the database.
*/
public Expression getJoinCriteria(QueryKeyExpression exp) {
if (getHistoryPolicy() != null) {
Expression result = super.getJoinCriteria(exp);
Expression historyCriteria = getHistoryPolicy().additionalHistoryExpression(exp);
if (result != null) {
return result.and(historyCriteria);
} else if (historyCriteria != null) {
return historyCriteria;
} else {
return null;
}
} else {
return super.getJoinCriteria(exp);
}
}
/**
* INTERNAL:
* return the object on the client corresponding to the specified object.
* DirectCollections do not have to worry about
* maintaining object identity.
*/
public Object getObjectCorrespondingTo(Object object, RemoteSession session, Map objectDescriptors, Map processedObjects, ObjectLevelReadQuery query) {
return object;
}
/**
* PUBLIC:
*/
public HistoryPolicy getHistoryPolicy() {
return historyPolicy;
}
/**
* INTERNAL:
* This cannot be used with direct collection mappings.
*/
public Class getReferenceClass() {
return null;
}
public String getReferenceClassName() {
return null;
}
/**
* INTERNAL:
* There is none on direct collection.
*/
public ClassDescriptor getReferenceDescriptor() {
return null;
}
/**
* INTERNAL:
* Return the reference key field names associated with the mapping.
* These are in-order with the sourceKeyFieldNames.
*/
public Vector getReferenceKeyFieldNames() {
Vector fieldNames = new Vector(getReferenceKeyFields().size());
for (Enumeration fieldsEnum = getReferenceKeyFields().elements();
fieldsEnum.hasMoreElements();) {
fieldNames.addElement(((DatabaseField)fieldsEnum.nextElement()).getQualifiedName());
}
return fieldNames;
}
/**
* INTERNAL:
* Return the reference key fields.
*/
public Vector<DatabaseField> getReferenceKeyFields() {
return referenceKeyFields;
}
/**
* INTERNAL:
* Return the direct table.
* This is the table to store the values.
*/
public DatabaseTable getReferenceTable() {
return referenceTable;
}
/**
* PUBLIC:
* Returns the name of the reference table
*/
public String getReferenceTableName() {
if (getReferenceTable() == null) {
return null;
}
return getReferenceTable().getName();
}
//This method is added to include table qualifier.
/**
* PUBLIC:
* Returns the qualified name of the reference table.
*/
public String getReferenceTableQualifiedName() {//CR#2407
if (getReferenceTable() == null) {
return null;
}
return getReferenceTable().getQualifiedName();
}
/**
* INTERNAL:
* Return the relationshipPartner mapping for this bi-directional mapping. If the relationshipPartner is null then
* this is a uni-directional mapping.
* DirectCollectionMapping can not be part of a bi-directional mapping
*/
public DatabaseMapping getRelationshipPartner() {
return null;
}
/**
* PUBLIC:
* Return the source key field names associated with the mapping.
* These are in-order with the referenceKeyFieldNames.
*/
public Vector getSourceKeyFieldNames() {
Vector fieldNames = new Vector(getSourceKeyFields().size());
for (Enumeration fieldsEnum = getSourceKeyFields().elements();
fieldsEnum.hasMoreElements();) {
fieldNames.addElement(((DatabaseField)fieldsEnum.nextElement()).getQualifiedName());
}
return fieldNames;
}
/**
* INTERNAL:
* Return the source key fields.
*/
public Vector<DatabaseField> getSourceKeyFields() {
return sourceKeyFields;
}
protected boolean hasCustomDeleteQuery() {
return hasCustomDeleteQuery;
}
protected boolean hasCustomInsertQuery() {
return hasCustomInsertQuery;
}
/**
* INTERNAL:
* Initialize and validate the mapping properties.
*/
public void initialize(AbstractSession session) throws DescriptorException {
if (isKeyForSourceSpecified()) {
initializeSourceKeys(session);
} else {
initializeSourceKeysWithDefaults(session);
}
initializeReferenceTable(session);
initializeReferenceKeys(session);
initializeDirectField(session);
if (getReferenceTable().getName().indexOf(' ') != -1) {
//table names contains a space so needs to be quoted.
String quoteChar = ((DatasourcePlatform)session.getDatasourcePlatform()).getIdentifierQuoteCharacter();
//Ensure this tablename hasn't already been quoted.
if (getReferenceTable().getName().indexOf(quoteChar) == -1) {
getReferenceTable().setName(quoteChar + getReferenceTable().getName() + quoteChar);
}
}
if (shouldInitializeSelectionCriteria()) {
initializeSelectionCriteria(session);
initializeSelectionStatement(session);
}
if (!getSelectionQuery().hasSessionName()) {
getSelectionQuery().setSessionName(session.getName());
}
if ((getValueConverter() != null) && (getSelectionQuery() instanceof DirectReadQuery)) {
((DirectReadQuery)getSelectionQuery()).setValueConverter(getValueConverter());
}
initializeDeleteAllQuery(session);
initializeDeleteQuery(session);
initializeInsertQuery(session);
if (getHistoryPolicy() != null) {
getHistoryPolicy().initialize(session);
}
if (getValueConverter() != null) {
getValueConverter().initialize(this, session);
}
super.initialize(session);
}
/**
* Initialize delete all query. This query is used to delete the collection of objects from the
* reference table.
*/
protected void initializeDeleteAllQuery(AbstractSession session) {
if (!getDeleteAllQuery().hasSessionName()) {
getDeleteAllQuery().setSessionName(session.getName());
}
if (hasCustomDeleteAllQuery()) {
return;
}
Expression expression = null;
Expression subExp1;
Expression subExp2;
Expression subExpression;
Expression builder = new ExpressionBuilder();
SQLDeleteStatement statement = new SQLDeleteStatement();
// Construct an expression to delete from the relation table.
for (int index = 0; index < getReferenceKeyFields().size(); index++) {
DatabaseField referenceKey = getReferenceKeyFields().elementAt(index);
DatabaseField sourceKey = getSourceKeyFields().elementAt(index);
subExp1 = builder.getField(referenceKey);
subExp2 = builder.getParameter(sourceKey);
subExpression = subExp1.equal(subExp2);
if (expression == null) {
expression = subExpression;
} else {
expression = expression.and(subExpression);
}
}
statement.setWhereClause(expression);
statement.setTable(getReferenceTable());
getDeleteAllQuery().setSQLStatement(statement);
}
protected void initializeDeleteQuery(AbstractSession session) {
if (!getDeleteQuery().hasSessionName()) {
getDeleteQuery().setSessionName(session.getName());
}
if (hasCustomDeleteQuery()) {
return;
}
Expression builder = new ExpressionBuilder();
Expression directExp = builder.getField(getDirectField()).equal(builder.getParameter(getDirectField()));
Expression expression = null;
SQLDeleteStatement statement = new SQLDeleteStatement();
// Construct an expression to delete from the relation table.
for (int index = 0; index < getReferenceKeyFields().size(); index++) {
DatabaseField referenceKey = getReferenceKeyFields().get(index);
DatabaseField sourceKey = getSourceKeyFields().get(index);
Expression subExp1 = builder.getField(referenceKey);
Expression subExp2 = builder.getParameter(sourceKey);
Expression subExpression = subExp1.equal(subExp2);
expression = subExpression.and(expression);
}
expression = expression.and(directExp);
statement.setWhereClause(expression);
statement.setTable(getReferenceTable());
getDeleteQuery().setSQLStatement(statement);
}
/**
* The field name on the reference table is initialized and cached.
*/
protected void initializeDirectField(AbstractSession session) throws DescriptorException {
if (getDirectField() == null) {
throw DescriptorException.directFieldNameNotSet(this);
}
getDirectField().setTable(getReferenceTable());
getDirectField().setIndex(0);
}
/**
* Initialize insert query. This query is used to insert the collection of objects into the
* reference table.
*/
protected void initializeInsertQuery(AbstractSession session) {
if (!getInsertQuery().hasSessionName()) {
getInsertQuery().setSessionName(session.getName());
}
if (hasCustomInsertQuery()) {
return;
}
SQLInsertStatement statement = new SQLInsertStatement();
statement.setTable(getReferenceTable());
AbstractRecord directRow = new DatabaseRecord();
for (Enumeration referenceEnum = getReferenceKeyFields().elements();
referenceEnum.hasMoreElements();) {
directRow.put((DatabaseField)referenceEnum.nextElement(), null);
}
directRow.put(getDirectField(), null);
statement.setModifyRow(directRow);
getInsertQuery().setSQLStatement(statement);
getInsertQuery().setModifyRow(directRow);
}
/**
* There is no reference descriptor
*/
protected void initializeReferenceDescriptor(AbstractSession session) {
;
}
/**
* The reference keys on the reference table are initialized
*/
protected void initializeReferenceKeys(AbstractSession session) throws DescriptorException {
if (getReferenceKeyFields().size() == 0) {
throw DescriptorException.noReferenceKeyIsSpecified(this);
}
for (Enumeration referenceEnum = getReferenceKeyFields().elements();
referenceEnum.hasMoreElements();) {
DatabaseField field = (DatabaseField)referenceEnum.nextElement();
if (field.hasTableName() && (!(field.getTableName().equals(getReferenceTable().getName())))) {
throw DescriptorException.referenceKeyFieldNotProperlySpecified(field, this);
}
field.setTable(getReferenceTable());
}
}
/**
* Set the table qualifier on the reference table if required
*/
protected void initializeReferenceTable(AbstractSession session) throws DescriptorException {
Platform platform = session.getDatasourcePlatform();
if (getReferenceTable() == null) {
throw DescriptorException.referenceTableNotSpecified(this);
}
if (platform.getTableQualifier().length() > 0) {
if (getReferenceTable().getTableQualifier().length() == 0) {
getReferenceTable().setTableQualifier(platform.getTableQualifier());
}
}
}
protected void initializeSelectionCriteria(AbstractSession session) {
Expression exp1;
Expression exp2;
Expression expression;
Expression criteria = null;
Enumeration referenceKeysEnum;
Enumeration sourceKeysEnum;
ExpressionBuilder base = new ExpressionBuilder();
TableExpression table = (TableExpression)base.getTable(getReferenceTable());
referenceKeysEnum = getReferenceKeyFields().elements();
sourceKeysEnum = getSourceKeyFields().elements();
for (; referenceKeysEnum.hasMoreElements();) {
DatabaseField referenceKey = (DatabaseField)referenceKeysEnum.nextElement();
DatabaseField sourceKey = (DatabaseField)sourceKeysEnum.nextElement();
exp1 = table.getField(referenceKey);
exp2 = base.getParameter(sourceKey);
expression = exp1.equal(exp2);
if (criteria == null) {
criteria = expression;
} else {
criteria = expression.and(criteria);
}
}
setSelectionCriteria(criteria);
}
/**
* The selection query is initialized
*/
protected void initializeSelectionQuery(AbstractSession session) {
// Nothing required.
}
protected void initializeSelectionStatement(AbstractSession session) {
SQLSelectStatement statement = new SQLSelectStatement();
statement.addTable(getReferenceTable());
statement.addField((DatabaseField)getDirectField().clone());
statement.setWhereClause(getSelectionCriteria());
statement.normalize(session, null);
getSelectionQuery().setSQLStatement(statement);
}
/**
* The source keys are initialized
*/
protected void initializeSourceKeys(AbstractSession session) {
for (int index = 0; index < getSourceKeyFields().size(); index++) {
DatabaseField field = getDescriptor().buildField(getSourceKeyFields().get(index));
getSourceKeyFields().set(index, field);
}
}
/**
* INTERNAL:
* If a user does not specify the source key then the primary keys of the source table are used.
*/
protected void initializeSourceKeysWithDefaults(AbstractSession session) {
List<DatabaseField> primaryKeyFields = getDescriptor().getPrimaryKeyFields();
for (int index = 0; index < primaryKeyFields.size(); index++) {
getSourceKeyFields().addElement(primaryKeyFields.get(index));
}
}
/**
* INTERNAL:
*/
public boolean isDirectCollectionMapping() {
return true;
}
/**
* INTERNAL:
* Return if this mapping support joining.
*/
public boolean isJoiningSupported() {
return true;
}
/**
* INTERNAL:
* Checks if source and target keys are mentioned by the user or not.
*/
protected boolean isKeyForSourceSpecified() {
return !getSourceKeyFields().isEmpty();
}
/**
* INTERNAL:
* Direct collection is always private owned.
*/
public boolean isPrivateOwned() {
return true;
}
/**
* INTERNAL:
* Iterate on the attribute value.
* The value holder has already been processed.
* PERF: Avoid iteration if not required.
*/
public void iterateOnRealAttributeValue(DescriptorIterator iterator, Object realAttributeValue) {
if (iterator.shouldIterateOnPrimitives()) {
super.iterateOnRealAttributeValue(iterator, realAttributeValue);
}
}
/**
* INTERNAL:
* Iterate on the specified element.
*/
public void iterateOnElement(DescriptorIterator iterator, Object element) {
iterator.iteratePrimitiveForMapping(element, this);
}
/**
* INTERNAL:
* Merge changes from the source to the target object.
* Because this is a collection mapping, values are added to or removed from the
* collection based on the changeset
*/
public void mergeChangesIntoObject(Object target, ChangeRecord changeRecord, Object source, MergeManager mergeManager) {
ContainerPolicy containerPolicy = getContainerPolicy();
Object valueOfTarget = null;
AbstractSession session = mergeManager.getSession();
//collect the changes into a vector
HashMap addObjects = ((DirectCollectionChangeRecord)changeRecord).getAddObjectMap();
HashMap removeObjects = ((DirectCollectionChangeRecord)changeRecord).getRemoveObjectMap();
//Check to see if the target has an instantiated collection
if ((isAttributeValueInstantiated(target)) && (!changeRecord.getOwner().isNew())) {
valueOfTarget = getRealCollectionAttributeValueFromObject(target, session);
} else {
//if not create an instance of the collection
valueOfTarget = containerPolicy.containerInstance(addObjects.size());
}
if (!isAttributeValueInstantiated(target)) {
if (mergeManager.shouldMergeChangesIntoDistributedCache()) {
return;
}
for (Object iterator = containerPolicy.iteratorFor(getRealCollectionAttributeValueFromObject(source, session));
containerPolicy.hasNext(iterator);) {
containerPolicy.addInto(containerPolicy.next(iterator, session), valueOfTarget, session);
}
} else {
Object synchronizationTarget = valueOfTarget;
// For indirect containers the delegate must be synchronized on,
// not the wrapper as the clone synchs on the delegate, see bug#5685287.
if (valueOfTarget instanceof IndirectCollection) {
synchronizationTarget = ((IndirectCollection)valueOfTarget).getDelegateObject();
}
synchronized (synchronizationTarget) {
// Next iterate over the changes and add them to the container
for (Iterator iterator = addObjects.keySet().iterator(); iterator.hasNext();) {
Object object = iterator.next();
int objectCount = ((Integer)addObjects.get(object)).intValue();
for (int i = 0; i < objectCount; ++i) {
if (mergeManager.shouldMergeChangesIntoDistributedCache()) {
//bug#4458089 and 4454532- check if collection contains new item before adding during merge into distributed cache
if (!containerPolicy.contains(object, valueOfTarget, session)) {
containerPolicy.addInto(object, valueOfTarget, session);
}
} else {
containerPolicy.addInto(object, valueOfTarget, session);
}
}
}
for (Iterator iterator = removeObjects.keySet().iterator(); iterator.hasNext();) {
Object object = iterator.next();
int objectCount = ((Integer)removeObjects.get(object)).intValue();
for (int i = 0; i < objectCount; ++i) {
containerPolicy.removeFrom(object, valueOfTarget, session);
}
}
}
}
setRealAttributeValueInObject(target, valueOfTarget);
}
/**
* INTERNAL:
* Merge changes from the source to the target object.
*/
public void mergeIntoObject(Object target, boolean isTargetUnInitialized, Object source, MergeManager mergeManager) {
if (isTargetUnInitialized) {
// This will happen if the target object was removed from the cache before the commit was attempted
if (mergeManager.shouldMergeWorkingCopyIntoOriginal() && (!isAttributeValueInstantiated(source))) {
setAttributeValueInObject(target, getIndirectionPolicy().getOriginalIndirectionObject(getAttributeValueFromObject(source), mergeManager.getSession()));
return;
}
}
if (!shouldMergeCascadeReference(mergeManager)) {
// This is only going to happen on mergeClone, and we should not attempt to merge the reference
return;
}
if (mergeManager.shouldRefreshRemoteObject() && usesIndirection()) {
mergeRemoteValueHolder(target, source, mergeManager);
return;
}
if (mergeManager.shouldMergeOriginalIntoWorkingCopy()) {
if (!isAttributeValueInstantiated(target)) {
// This will occur when the clone's value has not been instantiated yet and we do not need
// the refresh that attribute
return;
}
} else if (!isAttributeValueInstantiatedOrChanged(source)) {
// I am merging from a clone into an original. No need to do merge if the attribute was never
// modified
return;
}
ContainerPolicy containerPolicy = getContainerPolicy();
Object valueOfSource = getRealCollectionAttributeValueFromObject(source, mergeManager.getSession());
// trigger instantiation of target attribute
Object valueOfTarget = getRealCollectionAttributeValueFromObject(target, mergeManager.getSession());
Object newContainer = containerPolicy.containerInstance(containerPolicy.sizeFor(valueOfSource));
boolean fireChangeEvents = false;
if ((this.descriptor.getObjectChangePolicy().isObjectChangeTrackingPolicy()) && (target instanceof ChangeTracker) && (((ChangeTracker)target)._persistence_getPropertyChangeListener() != null)) {
fireChangeEvents = true;
//Collections may not be indirect list or may have been replaced with user collection.
Object iterator = containerPolicy.iteratorFor(valueOfTarget);
while (containerPolicy.hasNext(iterator)) {
((ObjectChangeListener)((ChangeTracker)target)._persistence_getPropertyChangeListener()).internalPropertyChange(new CollectionChangeEvent(target, getAttributeName(), valueOfTarget, containerPolicy.next(iterator, mergeManager.getSession()), CollectionChangeEvent.REMOVE));// make the remove change event fire.
}
if (newContainer instanceof ChangeTracker) {
((ChangeTracker)newContainer)._persistence_setPropertyChangeListener(((ChangeTracker)target)._persistence_getPropertyChangeListener());
}
if (valueOfTarget instanceof ChangeTracker) {
((ChangeTracker)valueOfTarget)._persistence_setPropertyChangeListener(null);//remove listener
}
}
valueOfTarget = newContainer;
for (Object sourceValuesIterator = containerPolicy.iteratorFor(valueOfSource);
containerPolicy.hasNext(sourceValuesIterator);) {
Object sourceValue = containerPolicy.next(sourceValuesIterator, mergeManager.getSession());
if (fireChangeEvents) {
//Collections may not be indirect list or may have been replaced with user collection.
((ObjectChangeListener)((ChangeTracker)target)._persistence_getPropertyChangeListener()).internalPropertyChange(new CollectionChangeEvent(target, getAttributeName(), valueOfTarget, sourceValue, CollectionChangeEvent.ADD));// make the add change event fire.
}
containerPolicy.addInto(sourceValue, valueOfTarget, mergeManager.getSession());
}
if (fireChangeEvents && (this.descriptor.getObjectChangePolicy().isAttributeChangeTrackingPolicy())) {
// check that there were changes, if not then remove the record.
ObjectChangeSet changeSet = ((AttributeChangeListener)((ChangeTracker)target)._persistence_getPropertyChangeListener()).getObjectChangeSet();
if (changeSet != null) {
DirectCollectionChangeRecord changeRecord = (DirectCollectionChangeRecord)changeSet.getChangesForAttributeNamed(getAttributeName());
if (changeRecord != null) {
if (!changeRecord.isDeferred()) {
if (!changeRecord.hasChanges()) {
changeSet.removeChange(getAttributeName());
}
} else {
// Must reset the latest collection.
changeRecord.setLatestCollection(valueOfTarget);
}
}
}
}
// Must re-set variable to allow for set method to re-morph changes if the collection is not being stored directly.
setRealAttributeValueInObject(target, valueOfTarget);
}
/**
* INTERNAL:
* Perform the commit event.
* This is used in the uow to delay data modifications.
*/
public void performDataModificationEvent(Object[] event, AbstractSession session) throws DatabaseException, DescriptorException {
// Hey I might actually want to use an inner class here... ok array for now.
if (event[0] == Delete) {
session.executeQuery((DataModifyQuery)event[1], (AbstractRecord)event[2]);
if ((getHistoryPolicy() != null) && getHistoryPolicy().shouldHandleWrites()) {
getHistoryPolicy().mappingLogicalDelete((DataModifyQuery)event[1], (AbstractRecord)event[2], session);
}
} else if (event[0] == Insert) {
session.executeQuery((DataModifyQuery)event[1], (AbstractRecord)event[2]);
if ((getHistoryPolicy() != null) && getHistoryPolicy().shouldHandleWrites()) {
getHistoryPolicy().mappingLogicalInsert((DataModifyQuery)event[1], (AbstractRecord)event[2], session);
}
} else if (event[0] == DeleteAll) {
preDelete((DeleteObjectQuery)event[1]);
} else {
throw DescriptorException.invalidDataModificationEventCode(event[0], this);
}
}
/**
* INTERNAL:
* Insert the private owned object.
*/
public void postInsert(WriteObjectQuery query) throws DatabaseException {
Object objects;
AbstractRecord databaseRow = new DatabaseRecord();
if (isReadOnly()) {
return;
}
objects = getRealCollectionAttributeValueFromObject(query.getObject(), query.getSession());
ContainerPolicy containerPolicy = getContainerPolicy();
if (containerPolicy.isEmpty(objects)) {
return;
}
prepareTranslationRow(query.getTranslationRow(), query.getObject(), query.getSession());
// Extract primary key and value from the source.
for (int index = 0; index < getReferenceKeyFields().size(); index++) {
DatabaseField referenceKey = getReferenceKeyFields().get(index);
DatabaseField sourceKey = getSourceKeyFields().get(index);
Object sourceKeyValue = query.getTranslationRow().get(sourceKey);
databaseRow.put(referenceKey, sourceKeyValue);
}
// Extract target field and its value. Construct insert statement and execute it
for (Object iter = containerPolicy.iteratorFor(objects); containerPolicy.hasNext(iter);) {
Object object = containerPolicy.next(iter, query.getSession());
if (getValueConverter() != null) {
object = getValueConverter().convertObjectValueToDataValue(object, query.getSession());
}
databaseRow.put(getDirectField(), object);
// In the uow data queries are cached until the end of the commit.
if (query.shouldCascadeOnlyDependentParts()) {
// Hey I might actually want to use an inner class here... ok array for now.
Object[] event = new Object[3];
event[0] = Insert;
event[1] = getInsertQuery();
event[2] = databaseRow.clone();
query.getSession().getCommitManager().addDataModificationEvent(this, event);
} else {
query.getSession().executeQuery(getInsertQuery(), databaseRow);
if ((getHistoryPolicy() != null) && getHistoryPolicy().shouldHandleWrites()) {
getHistoryPolicy().mappingLogicalInsert(getInsertQuery(), databaseRow, query.getSession());
}
}
}
}
/**
* INTERNAL:
* Update private owned part.
*/
public void postUpdate(WriteObjectQuery writeQuery) throws DatabaseException {
if (isReadOnly()) {
return;
}
if (writeQuery.getObjectChangeSet() != null) {
postUpdateWithChangeSet(writeQuery);
return;
}
// If objects are not instantiated that means they are not changed.
if (!isAttributeValueInstantiatedOrChanged(writeQuery.getObject())) {
return;
}
if (writeQuery.getSession().isUnitOfWork()) {
if (compareObjects(writeQuery.getObject(), writeQuery.getBackupClone(), writeQuery.getSession())) {
return;// Nothing has changed, no work required
}
}
DeleteObjectQuery deleteQuery = new DeleteObjectQuery();
deleteQuery.setObject(writeQuery.getObject());
deleteQuery.setSession(writeQuery.getSession());
deleteQuery.setTranslationRow(writeQuery.getTranslationRow());
if (writeQuery.shouldCascadeOnlyDependentParts()) {
// Hey I might actually want to use an inner class here... ok array for now.
Object[] event = new Object[3];
event[0] = DeleteAll;
event[1] = deleteQuery;
writeQuery.getSession().getCommitManager().addDataModificationEvent(this, event);
} else {
preDelete(deleteQuery);
}
postInsert(writeQuery);
}
/**
* INTERNAL:
* Update private owned part.
*/
protected void postUpdateWithChangeSet(WriteObjectQuery writeQuery) throws DatabaseException {
ObjectChangeSet changeSet = writeQuery.getObjectChangeSet();
DirectCollectionChangeRecord changeRecord = (DirectCollectionChangeRecord)changeSet.getChangesForAttributeNamed(this.getAttributeName());
if (changeRecord == null) {
return;
}
for (int index = 0; index < getReferenceKeyFields().size(); index++) {
DatabaseField referenceKey = getReferenceKeyFields().get(index);
DatabaseField sourceKey = getSourceKeyFields().get(index);
Object sourceKeyValue = writeQuery.getTranslationRow().get(sourceKey);
writeQuery.getTranslationRow().put(referenceKey, sourceKeyValue);
}
for (Iterator iterator = changeRecord.getRemoveObjectMap().keySet().iterator();
iterator.hasNext();) {
Object object = iterator.next();
AbstractRecord thisRow = (AbstractRecord)writeQuery.getTranslationRow().clone();
Object value = object;
if (getValueConverter() != null) {
value = getValueConverter().convertObjectValueToDataValue(value, writeQuery.getSession());
}
if (value == DirectCollectionChangeRecord.Null) {
thisRow.add(getDirectField(), null);
} else {
thisRow.add(getDirectField(), value);
}
// Hey I might actually want to use an inner class here... ok array for now.
Object[] event = new Object[3];
event[0] = Delete;
event[1] = getDeleteQuery();
event[2] = thisRow;
writeQuery.getSession().getCommitManager().addDataModificationEvent(this, event);
Integer count = (Integer)changeRecord.getCommitAddMap().get(object);
if (count != null) {
for (int counter = count.intValue(); counter > 0; --counter) {
thisRow = (AbstractRecord)writeQuery.getTranslationRow().clone();
thisRow.add(getDirectField(), value);
// Hey I might actually want to use an inner class here... ok array for now.
event = new Object[3];
event[0] = Insert;
event[1] = getInsertQuery();
event[2] = thisRow;
writeQuery.getSession().getCommitManager().addDataModificationEvent(this, event);
}
}
}
for (Iterator iterator = changeRecord.getAddObjectMap().keySet().iterator();
iterator.hasNext();) {
Object object = iterator.next();
Integer count = (Integer)changeRecord.getAddObjectMap().get(object);
for (int counter = count.intValue(); counter > 0; --counter) {
AbstractRecord thisRow = (AbstractRecord)writeQuery.getTranslationRow().clone();
Object value = object;
if (getValueConverter() != null) {
value = getValueConverter().convertObjectValueToDataValue(value, writeQuery.getSession());
}
if (value == DirectCollectionChangeRecord.Null) {//special placeholder for nulls
thisRow.add(getDirectField(), null);
} else {
thisRow.add(getDirectField(), value);
}
// Hey I might actually want to use an inner class here... ok array for now.
Object[] event = new Object[3];
event[0] = Insert;
event[1] = getInsertQuery();
event[2] = thisRow;
writeQuery.getSession().getCommitManager().addDataModificationEvent(this, event);
}
}
}
/**
* INTERNAL:
* Delete private owned part. Which is a collection of objects from the reference table.
*/
public void preDelete(DeleteObjectQuery query) throws DatabaseException {
if (isReadOnly()) {
return;
}
prepareTranslationRow(query.getTranslationRow(), query.getObject(), query.getSession());
query.getSession().executeQuery(getDeleteAllQuery(), query.getTranslationRow());
if ((getHistoryPolicy() != null) && getHistoryPolicy().shouldHandleWrites()) {
getHistoryPolicy().mappingLogicalDelete(getDeleteAllQuery(), query.getTranslationRow(), query.getSession());
}
}
/**
* INTERNAL:
* The translation row may require additional fields than the primary key if the mapping in not on the primary key.
*/
protected void prepareTranslationRow(AbstractRecord translationRow, Object object, AbstractSession session) {
// Make sure that each source key field is in the translation row.
for (Enumeration sourceFieldsEnum = getSourceKeyFields().elements();
sourceFieldsEnum.hasMoreElements();) {
DatabaseField sourceKey = (DatabaseField)sourceFieldsEnum.nextElement();
if (!translationRow.containsKey(sourceKey)) {
Object value = getDescriptor().getObjectBuilder().extractValueFromObjectForField(object, sourceKey, session);
translationRow.put(sourceKey, value);
}
}
}
/**
* INTERNAL:
* Once descriptors are serialized to the remote session. All its mappings and reference descriptors are traversed. Usually
* mappings are initialized and serialized reference descriptors are replaced with local descriptors if they already exist on the
* remote session.
*/
public void remoteInitialization(DistributedSession session) {
// Remote mappings is initialized here again because while serializing only the uninitialized data is passed
// as the initialized data is not serializable.
if (!isRemotelyInitialized()) {
getAttributeAccessor().initializeAttributes(getDescriptor().getJavaClass());
remotelyInitialized();
}
}
/**
* INTERNAL:
* replace the value holders in the specified reference object(s)
*/
public Map replaceValueHoldersIn(Object object, RemoteSessionController controller) {
// do nothing, since direct collections do not hold onto other domain objects
return null;
}
protected void setDeleteQuery(ModifyQuery query) {
this.changeSetDeleteQuery = query;
}
/**
* PUBLIC:
* Set the receiver's delete SQL string. This allows the user to override the SQL
* generated by TopLink, with there own SQL or procedure call. The arguments are
* translated from the fields of the source row, through replacing the field names
* marked by '#' with the values for those fields.
* This SQL is responsible for doing the deletion required by the mapping,
* such as deletion from join table for M-M.
* Example, 'delete from RESPONS where EMP_ID = #EMP_ID and DESCRIP = #DESCRIP'.
*/
public void setDeleteSQLString(String sqlString) {
DataModifyQuery query = new DataModifyQuery();
query.setSQLString(sqlString);
setCustomDeleteQuery(query);
}
/**
* ADVANCED:
* Configure the mapping to use a container policy.
* The policy manages the access to the collection.
*/
public void setContainerPolicy(ContainerPolicy containerPolicy) {
this.containerPolicy = containerPolicy;
((DataReadQuery) getSelectionQuery()).setContainerPolicy(containerPolicy);
}
/**
* PUBLIC:
* The default delete query for this mapping can be overridden by specifying the new query.
* This query is responsible for doing the deletion required by the mapping,
* such as deletion from join table for M-M. The query should delete a specific row from the
* DirectCollectionTable bases on the DirectField.
*/
public void setCustomDeleteQuery(ModifyQuery query) {
setDeleteQuery(query);
setHasCustomDeleteQuery(true);
}
/**
* PUBLIC:
* The default insert query for mapping can be overridden by specifying the new query.
* This query inserts the row into the direct table.
*/
public void setCustomInsertQuery(DataModifyQuery query) {
setInsertQuery(query);
setHasCustomInsertQuery(true);
}
/**
* PUBLIC:
* Set the direct field in the reference table.
* This is the field that the primitive data value is stored in.
*/
public void setDirectField(DatabaseField field) {
directField = field;
}
/**
* ADVANCED:
* Set the class type of the field value.
* This can be used if field value differs from the object value,
* has specific typing requirements such as usage of java.sql.Blob or NChar.
* This must be called after the field name has been set.
*/
public void setDirectFieldClassification(Class fieldType) {
getDirectField().setType(fieldType);
}
/**
* PUBLIC:
* Set the direct field name in the reference table.
* This is the field that the primitive data value is stored in.
*/
public void setDirectFieldName(String fieldName) {
setDirectField(new DatabaseField(fieldName));
}
protected void setHasCustomDeleteQuery(boolean bool) {
hasCustomDeleteQuery = bool;
}
protected void setHasCustomInsertQuery(boolean bool) {
hasCustomInsertQuery = bool;
}
protected void setInsertQuery(DataModifyQuery insertQuery) {
this.insertQuery = insertQuery;
}
/**
* PUBLIC:
* Set the receiver's insert SQL string. This allows the user to override the SQL
* generated by TopLink, with there own SQL or procedure call. The arguments are
* translated from the fields of the source row, through replacing the field names
* marked by '#' with the values for those fields.
* This is used to insert an entry into the direct table.
* <p>Example, 'insert into RESPONS (EMP_ID, RES_DESC) values (#EMP_ID, #RES_DESC)'.
*/
public void setInsertSQLString(String sqlString) {
DataModifyQuery query = new DataModifyQuery();
query.setSQLString(sqlString);
setCustomInsertQuery(query);
}
/**
* INTERNAL:
* This cannot be used with direct collection mappings.
*/
public void setReferenceClass(Class referenceClass) {
return;
}
public void setReferenceClassName(String referenceClassName) {
return;
}
/**
* PUBLIC:
* Set the name of the reference key field.
* This is the foreign key field in the direct table referencing the primary key of the source object.
* This method is used if the reference key consists of only a single field.
*/
public void setReferenceKeyFieldName(String fieldName) {
getReferenceKeyFields().addElement(new DatabaseField(fieldName));
}
/**
* INTERNAL:
* Set the reference key field names associated with the mapping.
* These must be in-order with the sourceKeyFieldNames.
*/
public void setReferenceKeyFieldNames(Vector fieldNames) {
Vector fields = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(fieldNames.size());
for (Enumeration fieldNamesEnum = fieldNames.elements(); fieldNamesEnum.hasMoreElements();) {
fields.addElement(new DatabaseField((String)fieldNamesEnum.nextElement()));
}
setReferenceKeyFields(fields);
}
/**
* INTERNAL:
* Set the reference fields.
*/
public void setReferenceKeyFields(Vector<DatabaseField> aVector) {
this.referenceKeyFields = aVector;
}
/**
* INTERNAL:
* Set the reference table.
*/
public void setReferenceTable(DatabaseTable table) {
referenceTable = table;
}
/**
* PUBLIC:
* Set the reference table name.
*/
public void setReferenceTableName(String tableName) {
if (tableName == null) {
setReferenceTable(null);
} else {
setReferenceTable(new DatabaseTable(tableName));
}
}
/**
* INTERNAL:
* Set the container policy on the selection query for this mapping.
*/
protected void setSelectionQueryContainerPolicy(ContainerPolicy containerPolicy) {
((DataReadQuery) getSelectionQuery()).setContainerPolicy(containerPolicy);
}
/**
* PUBLIC:
*/
public void setHistoryPolicy(HistoryPolicy policy) {
this.historyPolicy = policy;
if (policy != null) {
policy.setMapping(this);
}
}
/**
* PUBLIC:
* Set the name of the session to execute the mapping's queries under.
* This can be used by the session broker to override the default session
* to be used for the target class.
*/
public void setSessionName(String name) {
super.setSessionName(name);
getInsertQuery().setSessionName(name);
}
/**
* INTERNAL:
* Set the source key field names associated with the mapping.
* These must be in-order with the referenceKeyFieldNames.
*/
public void setSourceKeyFieldNames(Vector fieldNames) {
Vector fields = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(fieldNames.size());
for (Enumeration fieldNamesEnum = fieldNames.elements(); fieldNamesEnum.hasMoreElements();) {
fields.addElement(new DatabaseField((String)fieldNamesEnum.nextElement()));
}
setSourceKeyFields(fields);
}
/**
* INTERNAL:
* Set the source fields.
*/
public void setSourceKeyFields(Vector<DatabaseField> sourceKeyFields) {
this.sourceKeyFields = sourceKeyFields;
}
/**
* INTERNAL:
* Used by AttributeLevelChangeTracking to update a changeRecord with calculated changes
* as apposed to detected changes. If an attribute can not be change tracked it's
* changes can be detected through this process.
*/
public void calculateDeferredChanges(ChangeRecord changeRecord, AbstractSession session) {
DirectCollectionChangeRecord collectionRecord = (DirectCollectionChangeRecord)changeRecord;
// TODO: Handle events that fired after collection was replaced.
compareCollectionsForChange(collectionRecord.getOriginalCollection(), collectionRecord.getLatestCollection(), collectionRecord, session);
}
/**
* ADVANCED:
* This method is used to have an object add to a collection once the changeSet is applied
* The referenceKey parameter should only be used for direct Maps.
*/
public void simpleAddToCollectionChangeRecord(Object referenceKey, Object objectToAdd, ObjectChangeSet changeSet, AbstractSession session) {
DirectCollectionChangeRecord collectionChangeRecord = (DirectCollectionChangeRecord)changeSet.getChangesForAttributeNamed(getAttributeName());
if (collectionChangeRecord == null) {
collectionChangeRecord = new DirectCollectionChangeRecord(changeSet);
collectionChangeRecord.setAttribute(getAttributeName());
collectionChangeRecord.setMapping(this);
changeSet.addChange(collectionChangeRecord);
Object collection = getRealAttributeValueFromObject(changeSet.getUnitOfWorkClone(), session);
collectionChangeRecord.storeDatabaseCounts(collection, getContainerPolicy(), session);
}
collectionChangeRecord.addAdditionChange(objectToAdd, new Integer(1));
}
/**
* ADVANCED:
* This method is used to have an object removed from a collection once the changeSet is applied
* The referenceKey parameter should only be used for direct Maps.
*/
public void simpleRemoveFromCollectionChangeRecord(Object referenceKey, Object objectToRemove, ObjectChangeSet changeSet, AbstractSession session) {
DirectCollectionChangeRecord collectionChangeRecord = (DirectCollectionChangeRecord)changeSet.getChangesForAttributeNamed(getAttributeName());
if (collectionChangeRecord == null) {
collectionChangeRecord = new DirectCollectionChangeRecord(changeSet);
collectionChangeRecord.setAttribute(getAttributeName());
collectionChangeRecord.setMapping(this);
changeSet.addChange(collectionChangeRecord);
Object collection = getRealAttributeValueFromObject(changeSet.getUnitOfWorkClone(), session);
collectionChangeRecord.storeDatabaseCounts(collection, getContainerPolicy(), session);
}
collectionChangeRecord.addRemoveChange(objectToRemove, new Integer(1));
}
/**
* INTERNAL:
* Either create a new change record or update with the new value. This is used
* by attribute change tracking.
* Specifically in a collection mapping this will be called when the customer
* Set a new collection. In this case we will need to mark the change record
* with the new and the old versions of the collection.
* And mark the ObjectChangeSet with the attribute name then when the changes are calculated
* force a compare on the collections to determine changes.
*/
public void updateChangeRecord(Object clone, Object newValue, Object oldValue, ObjectChangeSet objectChangeSet, UnitOfWorkImpl uow) {
DirectCollectionChangeRecord collectionChangeRecord = (DirectCollectionChangeRecord)objectChangeSet.getChangesForAttributeNamed(this.getAttributeName());
if (collectionChangeRecord == null) {
collectionChangeRecord = new DirectCollectionChangeRecord(objectChangeSet);
collectionChangeRecord.setAttribute(getAttributeName());
collectionChangeRecord.setMapping(this);
objectChangeSet.addChange(collectionChangeRecord);
}
if (collectionChangeRecord.getOriginalCollection() == null) {
collectionChangeRecord.setOriginalCollection(oldValue);
}
collectionChangeRecord.setLatestCollection(newValue);
collectionChangeRecord.setIsDeferred(true);
objectChangeSet.deferredDetectionRequiredOn(getAttributeName());
}
/**
* INTERNAL:
* Add or removes a new value and its change set to the collection change record based on the event passed in. This is used by
* attribute change tracking.
*/
public void updateCollectionChangeRecord(CollectionChangeEvent event, ObjectChangeSet changeSet, UnitOfWorkImpl uow) {
if (event != null ) {
//Letting the mapping create and add the ChangeSet to the ChangeRecord rather
// than the policy, since the policy doesn't know how to handle DirectCollectionChangeRecord.
// if ordering is to be supported in the future, check how the method in CollectionMapping is implemented
Object key = null;
if (event.getClass().equals(ClassConstants.MapChangeEvent_Class)){
key = ((MapChangeEvent)event).getKey();
}
if (event.getChangeType() == CollectionChangeEvent.ADD) {
addToCollectionChangeRecord(key, event.getNewValue(), changeSet, uow);
} else if (event.getChangeType() == CollectionChangeEvent.REMOVE) {
removeFromCollectionChangeRecord(key, event.getNewValue(), changeSet, uow);
} else {
throw ValidationException.wrongCollectionChangeEventType(event.getChangeType());
}
}
}
/**
* PUBLIC:
* Configure the mapping to use an instance of the specified container class
* to hold the target objects.
* <p>The container class must implement (directly or indirectly) the Collection interface.
*/
public void useCollectionClass(Class concreteClass) {
ContainerPolicy policy = ContainerPolicy.buildPolicyFor(concreteClass);
setContainerPolicy(policy);
}
/**
* PUBLIC:
* It is illegal to use a Map as the container of a DirectCollectionMapping. Only
* Collection containers are supported for DirectCollectionMappings.
* @see org.eclipse.persistence.mappings.DirectMapMapping
*/
public void useMapClass(Class concreteClass, String methodName) {
throw ValidationException.illegalUseOfMapInDirectCollection(this, concreteClass, methodName);
}
/**
* INTERNAL:
* Return the value of the reference attribute or a value holder.
* Check whether the mapping's attribute should be optimized through batch and joining.
* Overridden to support flashback/historical queries.
*/
public Object valueFromRow(AbstractRecord row, JoinedAttributeManager joinManager, ObjectBuildingQuery sourceQuery, AbstractSession session) throws DatabaseException {
// if the query uses batch reading, return a special value holder
// or retrieve the object from the query property.
if (sourceQuery.isReadAllQuery() && (((ReadAllQuery)sourceQuery).isAttributeBatchRead(getDescriptor(), getAttributeName()) || shouldUseBatchReading())) {
return batchedValueFromRow(row, (ReadAllQuery)sourceQuery);
}
ReadQuery targetQuery = getSelectionQuery();
if ((getHistoryPolicy() != null) || (sourceQuery.getSession().getAsOfClause() != null) || ((sourceQuery.isObjectLevelReadQuery() && ((ObjectLevelReadQuery)sourceQuery).hasAsOfClause()) && (sourceQuery.shouldCascadeAllParts() || (sourceQuery.shouldCascadePrivateParts() && isPrivateOwned()) || (sourceQuery.shouldCascadeByMapping() && this.cascadeRefresh)))) {
targetQuery = (ReadQuery)targetQuery.clone();
// Code copied roughly from initializeSelectionStatement.
SQLSelectStatement statement = new SQLSelectStatement();
statement.addTable(getReferenceTable());
statement.addField((DatabaseField)getDirectField().clone());
if (isDirectMapMapping()) {
statement.addField((DatabaseField)((DirectMapMapping)this).getDirectKeyField().clone());
}
statement.setWhereClause((Expression)getSelectionCriteria().clone());
statement.getBuilder().asOf(((ObjectLevelReadQuery)sourceQuery).getAsOfClause());
if (getHistoryPolicy() != null) {
ExpressionBuilder builder = statement.getBuilder();
if (sourceQuery.getSession().getAsOfClause() != null) {
builder.asOf(sourceQuery.getSession().getAsOfClause());
} else if (builder.getAsOfClause() == null) {
builder.asOf(AsOfClause.NO_CLAUSE);
}
Expression temporalExpression = getHistoryPolicy().additionalHistoryExpression(builder);
statement.setWhereClause(statement.getWhereClause().and(temporalExpression));
if (builder.hasAsOfClause()) {
statement.getTables().set(0, getHistoryPolicy().getHistoricalTables().elementAt(0));
}
}
statement.normalize(sourceQuery.getSession(), null);
targetQuery.setSQLStatement(statement);
}
return getIndirectionPolicy().valueFromQuery(targetQuery, row, sourceQuery.getSession());
}
/**
* INTERNAL:
* Checks if object is deleted from the database or not.
*/
public boolean verifyDelete(Object object, AbstractSession session) throws DatabaseException {
// Row is built for translation
if (isReadOnly()) {
return true;
}
AbstractRecord row = getDescriptor().getObjectBuilder().buildRowForTranslation(object, session);
Object value = session.executeQuery(getSelectionQuery(), row);
return getContainerPolicy().isEmpty(value);
}
/**
* INTERNAL:
* Add a new value and its change set to the collection change record. This is used by
* attribute change tracking.
*/
public void addToCollectionChangeRecord(Object newKey, Object newValue, ObjectChangeSet objectChangeSet, UnitOfWorkImpl uow) {
if (newValue == null) {
newValue = DirectCollectionChangeRecord.Null;
}
simpleAddToCollectionChangeRecord(newKey, newValue, objectChangeSet, uow);
}
/**
* INTERNAL:
* DirectCollectionMapping contents should not be considered for addition to the UnitOfWork
* private owned objects list for removal.
*/
public boolean isCandidateForPrivateOwnedRemoval() {
return false;
}
/**
* INTERNAL
* Return true if this mapping supports cascaded version optimistic locking.
*/
public boolean isCascadedLockingSupported() {
return true;
}
/**
* INTERNAL:
* Remove a value and its change set from the collection change record. This is used by
* attribute change tracking.
*/
public void removeFromCollectionChangeRecord(Object newKey, Object newValue, ObjectChangeSet objectChangeSet, UnitOfWorkImpl uow) {
if (newValue == null) {
newValue = DirectCollectionChangeRecord.Null;
}
simpleRemoveFromCollectionChangeRecord(newKey, newValue, objectChangeSet, uow);
}
}