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org.eclipse.persistence.mappings.OneToOneMapping Maven / Gradle / Ivy
/*
* Copyright (c) 1998, 2021 Oracle and/or its affiliates. All rights reserved.
* Copyright (c) 2020 IBM Corporation. All rights reserved.
*
* This program and the accompanying materials are made available under the
* terms of the Eclipse Public License v. 2.0 which is available at
* http://www.eclipse.org/legal/epl-2.0,
* or the Eclipse Distribution License v. 1.0 which is available at
* http://www.eclipse.org/org/documents/edl-v10.php.
*
* SPDX-License-Identifier: EPL-2.0 OR BSD-3-Clause
*/
// Contributors:
// Oracle - initial API and implementation from Oracle TopLink
// 05/14/2012-2.4 Guy Pelletier
// - 376603: Provide for table per tenant support for multitenant applications
// 02/11/2013-2.5 Guy Pelletier
// - 365931: @JoinColumn(name="FK_DEPT",insertable = false, updatable = true) causes INSERT statement to include this data value that it is associated with
package org.eclipse.persistence.mappings;
import java.util.*;
import org.eclipse.persistence.annotations.CacheKeyType;
import org.eclipse.persistence.descriptors.ClassDescriptor;
import org.eclipse.persistence.exceptions.*;
import org.eclipse.persistence.expressions.*;
import org.eclipse.persistence.internal.helper.*;
import org.eclipse.persistence.internal.identitymaps.*;
import org.eclipse.persistence.internal.indirection.ProxyIndirectionPolicy;
import org.eclipse.persistence.internal.queries.ContainerPolicy;
import org.eclipse.persistence.internal.queries.JoinedAttributeManager;
import org.eclipse.persistence.internal.queries.MappedKeyMapContainerPolicy;
import org.eclipse.persistence.internal.sessions.*;
import org.eclipse.persistence.sessions.DatabaseRecord;
import org.eclipse.persistence.queries.*;
import org.eclipse.persistence.internal.descriptors.CascadeLockingPolicy;
import org.eclipse.persistence.internal.descriptors.DescriptorIterator;
import org.eclipse.persistence.internal.descriptors.ObjectBuilder;
import org.eclipse.persistence.internal.expressions.ConstantExpression;
import org.eclipse.persistence.internal.expressions.ObjectExpression;
import org.eclipse.persistence.internal.expressions.FieldExpression;
import org.eclipse.persistence.internal.expressions.ParameterExpression;
import org.eclipse.persistence.internal.expressions.QueryKeyExpression;
import org.eclipse.persistence.internal.expressions.SQLSelectStatement;
import org.eclipse.persistence.mappings.foundation.MapKeyMapping;
import org.eclipse.persistence.mappings.querykeys.OneToOneQueryKey;
import org.eclipse.persistence.mappings.querykeys.QueryKey;
/**
* Purpose : One to one mappings are used to represent a pointer references
* between two java objects. This mappings is usually represented by a single pointer
* (stored in an instance variable) between the source and target objects. In the relational
* database tables, these mappings are normally implemented using foreign keys.
*
* @author Sati
* @since TOPLink/Java 1.0
*/
public class OneToOneMapping extends ObjectReferenceMapping implements RelationalMapping, MapKeyMapping {
/** Maps the source foreign/primary key fields to the target primary/foreign key fields. */
protected Map sourceToTargetKeyFields;
/** Maps the target primary/foreign key fields to the source foreign/primary key fields. */
protected Map targetToSourceKeyFields;
/** Keeps track of which fields are foreign keys on a per field basis (can have mixed foreign key relationships). */
/** These are used for non-unit of work modification to check if the value of the 1-1 was changed and a deletion is required. */
protected boolean shouldVerifyDelete;
protected transient Expression privateOwnedCriteria;
public DatabaseTable keyTableForMapKey = null;
protected static final String setObject = "setObject";
/** Mechanism holds relationTable and all fields and queries associated with it. */
protected RelationTableMechanism mechanism;
/**
* Define if this mapping is really for a OneToOne relationship.
* This is a backward compatibility issue, in that before the ManyToOneMapping
* was created OneToOneMapping was used for both.
*/
protected boolean isOneToOneRelationship = false;
/**
* Defines if this mapping was built using primary key join columns.
*/
protected boolean isOneToOnePrimaryKeyRelationship = false;
/**
* Keep track of which fields are insertable and updatable.
*/
protected HashSet insertableFields = new HashSet<>();
protected HashSet updatableFields = new HashSet<>();
/**
* Keep a reference to the source and target expressions to post initialize
* when building a selection criteria early.
*/
protected transient List sourceExpressionsToPostInitialize;
protected transient List targetExpressionsToPostInitialize;
/**
* Mode for writeFromObjectIntoRowInternal method
*/
protected enum ShallowMode {
Insert,
UpdateAfterInsert,
UpdateBeforeDelete
}
/**
* PUBLIC:
* Default constructor.
*/
public OneToOneMapping() {
this.selectionQuery = new ReadObjectQuery();
this.sourceToTargetKeyFields = new HashMap(2);
this.targetToSourceKeyFields = new HashMap(2);
this.foreignKeyFields = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(1);
this.sourceExpressionsToPostInitialize = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(1);
this.targetExpressionsToPostInitialize = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(1);
this.isForeignKeyRelationship = false;
this.shouldVerifyDelete = true;
}
/**
* INTERNAL:
*/
@Override
public boolean isRelationalMapping() {
return true;
}
/**
* INTERNAL:
* Used when initializing queries for mappings that use a Map.
* Called when the selection query is being initialized to add the fields for the map key to the query.
*/
@Override
public void addAdditionalFieldsToQuery(ReadQuery selectionQuery, Expression baseExpression){
for (DatabaseField field : getForeignKeyFields()) {
if (selectionQuery.isObjectLevelReadQuery()){
((ObjectLevelReadQuery)selectionQuery).addAdditionalField(baseExpression.getField(field));
} else if (selectionQuery.isDataReadQuery()){
((SQLSelectStatement) selectionQuery.getSQLStatement()).addField(field);
}
}
}
/**
* INTERNAL:
* Used when initializing queries for mappings that use a Map
* Called when the insert query is being initialized to ensure the fields for the map key are in the insert query
*/
@Override
public void addFieldsForMapKey(AbstractRecord joinRow){
Iterator i = getForeignKeyFields().iterator();
while (i.hasNext()){
joinRow.put(i.next(), null);
}
}
/**
* PUBLIC:
* Define the foreign key relationship in the 1-1 mapping.
* This method is used for composite foreign key relationships,
* that is the source object's table has multiple foreign key fields to
* the target object's primary key fields.
* Both the source foreign key field and the target foreign key field must
* be specified.
* When a foreign key is specified TopLink will automatically populate the
* value for that field from the target object when the object is written to
* the database. If the foreign key is also mapped through a direct-to-field
* then the direct-to-field must be set read-only.
*/
@Override
public void addForeignKeyField(DatabaseField sourceForeignKeyField, DatabaseField targetPrimaryKeyField) {
setIsForeignKeyRelationship(true);
getForeignKeyFields().addElement(sourceForeignKeyField);
getSourceToTargetKeyFields().put(sourceForeignKeyField, targetPrimaryKeyField);
getTargetToSourceKeyFields().put(targetPrimaryKeyField, sourceForeignKeyField);
}
/**
* PUBLIC:
* Define the foreign key relationship in the 1-1 mapping.
* This method is used for composite foreign key relationships,
* that is the source object's table has multiple foreign key fields to
* the target object's primary key fields.
* Both the source foreign key field name and the target foreign key field
* name must be specified.
* When a foreign key is specified TopLink will automatically populate the
* value for that field from the target object when the object is written to
* the database. If the foreign key is also mapped through a direct-to-field
* then the direct-to-field must be set read-only.
*/
public void addForeignKeyFieldName(String sourceForeignKeyFieldName, String targetPrimaryKeyFieldName) {
addForeignKeyField(new DatabaseField(sourceForeignKeyFieldName), new DatabaseField(targetPrimaryKeyFieldName));
}
/**
* PUBLIC:
* Define the target foreign key relationship in the 1-1 mapping.
* This method is used for composite target foreign key relationships,
* that is the target object's table has multiple foreign key fields to
* the source object's primary key fields.
* Both the target foreign key field and the source primary key field must
* be specified.
* The distinction between a foreign key and target foreign key is that the
* 1-1 mapping will not populate the target foreign key value when written
* (because it is in the target table). Normally 1-1's are through foreign
* keys but in bi-directional 1-1's the back reference will be a target
* foreign key. In obscure composite legacy data models a 1-1 may consist of
* a foreign key part and a target foreign key part, in this case both
* method will be called with the correct parts.
*/
@Override
public void addTargetForeignKeyField(DatabaseField targetForeignKeyField, DatabaseField sourcePrimaryKeyField) {
getSourceToTargetKeyFields().put(sourcePrimaryKeyField, targetForeignKeyField);
getTargetToSourceKeyFields().put(targetForeignKeyField, sourcePrimaryKeyField);
}
/**
* PUBLIC:
* Define the target foreign key relationship in the 1-1 mapping.
* This method is used for composite target foreign key relationships,
* that is the target object's table has multiple foreign key fields to
* the source object's primary key fields.
* Both the target foreign key field name and the source primary key field
* name must be specified.
* The distinction between a foreign key and target foreign key is that the
* 1-1 mapping will not populate the target foreign key value when written
* (because it is in the target table). Normally 1-1's are through foreign
* keys but in bi-directional 1-1's the back reference will be a target
* foreign key. In obscure composite legacy data models a 1-1 may consist of
* a foreign key part and a target foreign key part, in this case both
* method will be called with the correct parts.
*/
public void addTargetForeignKeyFieldName(String targetForeignKeyFieldName, String sourcePrimaryKeyFieldName) {
addTargetForeignKeyField(new DatabaseField(targetForeignKeyFieldName), new DatabaseField(sourcePrimaryKeyFieldName));
}
/**
* INTERNAL:
* For mappings used as MapKeys in MappedKeyContainerPolicy. Add the target of this mapping to the deleted
* objects list if necessary
*
* This method is used for removal of private owned relationships.
*/
@Override
public void addKeyToDeletedObjectsList(Object object, Map deletedObjects){
deletedObjects.put(object, object);
}
/**
* Build a clone of the given element in a unitOfWork.
*/
@Override
public Object buildElementClone(Object attributeValue, Object parent, CacheKey cacheKey, Integer refreshCascade, AbstractSession cloningSession, boolean isExisting, boolean isFromSharedCache){
return buildCloneForPartObject(attributeValue, null, cacheKey, parent, cloningSession, refreshCascade, isExisting, isFromSharedCache);
}
/**
* INTERNAL:
* Used to allow object level comparisons.
*/
@Override
public Expression buildObjectJoinExpression(Expression expression, Object value, AbstractSession session) {
Expression base = ((ObjectExpression)expression).getBaseExpression();
Expression foreignKeyJoin = null;
if(this.mechanism == null) {
// Allow for equal null.
if (value == null) {
if (!isForeignKeyRelationship()) {
// ELBug#331352
// Need to do a join and compare target foreign key to null.
for (DatabaseField field : getSourceToTargetKeyFields().values()) {
Expression join = null;
join = expression.getField(field).equal(null);
if (foreignKeyJoin == null) {
foreignKeyJoin = join;
} else {
foreignKeyJoin = foreignKeyJoin.and(join);
}
}
} else {
for (DatabaseField field : getSourceToTargetKeyFields().keySet()) {
Expression join = null;
join = base.getField(field).equal(null);
if (foreignKeyJoin == null) {
foreignKeyJoin = join;
} else {
foreignKeyJoin = foreignKeyJoin.and(join);
}
}
}
} else {
if (!getReferenceDescriptor().getJavaClass().isInstance(value)) {
// Bug 3894351 - ensure any proxys are triggered so we can do a proper class comparison
value = ProxyIndirectionPolicy.getValueFromProxy(value);
if (!getReferenceDescriptor().getJavaClass().isInstance(value)) {
throw QueryException.incorrectClassForObjectComparison(base, value, this);
}
}
Iterator keyIterator = Arrays.asList(((CacheId)extractKeyFromReferenceObject(value, session)).getPrimaryKey()).iterator();
for (DatabaseField field : getSourceToTargetKeyFields().keySet()) {
Expression join = null;
join = base.getField(field).equal(keyIterator.next());
if (foreignKeyJoin == null) {
foreignKeyJoin = join;
} else {
foreignKeyJoin = foreignKeyJoin.and(join);
}
}
}
} else {
int size = this.mechanism.sourceKeyFields.size();
Object key = null;
if (value != null) {
if (!getReferenceDescriptor().getJavaClass().isInstance(value)) {
// Bug 3894351 - ensure any proxys are triggered so we can do a proper class comparison
value = ProxyIndirectionPolicy.getValueFromProxy(value);
if (!getReferenceDescriptor().getJavaClass().isInstance(value)) {
throw QueryException.incorrectClassForObjectComparison(base, value, this);
}
}
key = extractKeyFromReferenceObject(value, session);
boolean allNulls = true;
for (int i=0; i < size; i++) {
if (((CacheId)key).getPrimaryKey()[i] != null) {
allNulls = false;
break;
}
}
// the same case
if (allNulls) {
value = null;
}
}
if (value != null) {
for(int i=0; i < size; i++) {
DatabaseField field = this.mechanism.sourceKeyFields.get(i);
Expression join = null;
join = base.getField(field).equal(((CacheId)key).getPrimaryKey()[i]);
if (foreignKeyJoin == null) {
foreignKeyJoin = join;
} else {
foreignKeyJoin = foreignKeyJoin.and(join);
}
}
} else {
ReportQuery subQuery = new ReportQuery(this.descriptor.getJavaClass(), new ExpressionBuilder());
Expression relationTableExp = subQuery.getExpressionBuilder().getTable(this.mechanism.relationTable);
Expression subSelectExp = null;
for(int i=0; i < size; i++) {
subSelectExp = relationTableExp.getField(this.mechanism.sourceRelationKeyFields.get(i)).equal(base.getField(this.mechanism.sourceKeyFields.get(i))).and(subSelectExp);
}
subQuery.setSelectionCriteria(subSelectExp);
subQuery.dontRetrievePrimaryKeys();
subQuery.addAttribute("", subQuery.getExpressionBuilder().getField(this.mechanism.sourceKeyFields.get(0)));
foreignKeyJoin = base.notExists(subQuery);
}
}
return foreignKeyJoin;
}
/**
* INTERNAL:
* Used to allow object level comparisons.
*/
@Override
public Expression buildObjectJoinExpression(Expression expression, Expression argument, AbstractSession session) {
Expression base = ((org.eclipse.persistence.internal.expressions.ObjectExpression)expression).getBaseExpression();
Expression foreignKeyJoin = null;
if(this.mechanism == null) {
if (expression==argument){
for (Iterator sourceFieldsEnum = getSourceToTargetKeyFields().keySet().iterator();
sourceFieldsEnum.hasNext();) {
DatabaseField field = sourceFieldsEnum.next();
Expression join = base.getField(field);
join = join.equal(join);
if (foreignKeyJoin == null) {
foreignKeyJoin = join;
} else {
foreignKeyJoin = foreignKeyJoin.and(join);
}
}
}else{
Iterator targetFieldsEnum = getSourceToTargetKeyFields().values().iterator();
for (Iterator sourceFieldsEnum = getSourceToTargetKeyFields().keySet().iterator();
sourceFieldsEnum.hasNext();) {
DatabaseField sourceField = sourceFieldsEnum.next();
DatabaseField targetField = targetFieldsEnum.next();
Expression join = null;
join = base.getField(sourceField).equal(argument.getField(targetField));
if (foreignKeyJoin == null) {
foreignKeyJoin = join;
} else {
foreignKeyJoin = foreignKeyJoin.and(join);
}
}
}
} else {
if (expression==argument){
foreignKeyJoin = (new ConstantExpression(0, base)).equal(new ConstantExpression(0, base));
}else{
int size = this.mechanism.sourceKeyFields.size();
Expression relTable = base.getTable(this.mechanism.getRelationTable());
for(int i=0; i < size; i++) {
Expression source = base.getField(this.mechanism.sourceKeyFields.get(i));
Expression sourceRel = relTable.getField(this.mechanism.sourceRelationKeyFields.get(i));
Expression targetRel = relTable.getField(this.mechanism.targetRelationKeyFields.get(i));
Expression target = argument.getField(this.mechanism.targetKeyFields.get(i));
foreignKeyJoin = source.equal(sourceRel).and(targetRel.equal(target)).and(foreignKeyJoin);
}
}
}
return foreignKeyJoin;
}
/**
* INTERNAL:
* Certain key mappings favor different types of selection query. Return the appropriate
* type of selectionQuery
*/
@Override
public ReadQuery buildSelectionQueryForDirectCollectionKeyMapping(ContainerPolicy containerPolicy){
DataReadQuery query = new DataReadQuery();
query.setSQLStatement(new SQLSelectStatement());
query.setContainerPolicy(containerPolicy);
return query;
}
/**
* INTERNAL:
* This methods clones all the fields and ensures that each collection refers to
* the same clones.
*/
@Override
public Object clone() {
OneToOneMapping clone = (OneToOneMapping)super.clone();
if(this.mechanism == null) {
clone.setForeignKeyFields(org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(getForeignKeyFields().size()));
clone.setSourceToTargetKeyFields(new HashMap(getSourceToTargetKeyFields().size()));
clone.setTargetToSourceKeyFields(new HashMap(getTargetToSourceKeyFields().size()));
// DatabaseField overrides equals, so we need to use an IdentifyHashMap for this implementation
// to make sure we are using the object references to lookup clone references
AbstractMap fieldToCloneMap = new IdentityHashMap<>(getTargetToSourceKeyFields().size());
//clone foreign keys and save the clones in a lookup table
for (Enumeration enumtr = getForeignKeyFields().elements(); enumtr.hasMoreElements();) {
DatabaseField field = enumtr.nextElement();
DatabaseField fieldClone = field.clone();
fieldToCloneMap.put(field, fieldClone);
clone.getForeignKeyFields().addElement(fieldClone);
}
// lookup references in the map to get the associated clone reference. If it doesn't exist, create a new one.
for (Iterator sourceEnum = getSourceToTargetKeyFields().keySet().iterator();
sourceEnum.hasNext();) {
DatabaseField sourceField = sourceEnum.next();
DatabaseField targetField = getSourceToTargetKeyFields().get(sourceField);
DatabaseField targetClone;
DatabaseField sourceClone;
targetClone = fieldToCloneMap.get(targetField);
if (targetClone == null) {
targetClone = targetField.clone();
fieldToCloneMap.put(targetField, targetClone);
}
sourceClone = fieldToCloneMap.get(sourceField);
if (sourceClone == null) {
sourceClone = sourceField.clone();
fieldToCloneMap.put(sourceField, sourceClone);
}
clone.getSourceToTargetKeyFields().put(sourceClone, targetClone);
}
// lookup references in the map to get the associated clone reference. If it doesn't exist, create a new one.
for (Iterator targetEnum = getTargetToSourceKeyFields().keySet().iterator();
targetEnum.hasNext();) {
DatabaseField targetField = targetEnum.next();
DatabaseField sourceField = getTargetToSourceKeyFields().get(targetField);
DatabaseField targetClone;
DatabaseField sourceClone;
targetClone = fieldToCloneMap.get(targetField);
if (targetClone == null) {
targetClone = targetField.clone();
fieldToCloneMap.put(targetField, targetClone);
}
sourceClone = fieldToCloneMap.get(sourceField);
if (sourceClone == null) {
sourceClone = sourceField.clone();
fieldToCloneMap.put(sourceField, sourceClone);
}
clone.getTargetToSourceKeyFields().put(targetClone, sourceClone);
}
} else {
clone.mechanism = (RelationTableMechanism)this.mechanism.clone();
}
return clone;
}
@Override
public void collectQueryParameters(Set cacheFields){
for (DatabaseField field : sourceToTargetKeyFields.keySet()) {
cacheFields.add(field);
}
}
/**
* INTERNAL
* Called when a DatabaseMapping is used to map the key in a collection. Returns the key.
*/
@Override
public Object createMapComponentFromRow(AbstractRecord dbRow, ObjectBuildingQuery query, CacheKey parentCacheKey, AbstractSession session, boolean isTargetProtected){
return session.executeQuery(getSelectionQuery(), dbRow);
}
/**
* INTERNAL:
* Creates the Array of simple types used to recreate this map.
*/
@Override
public Object createSerializableMapKeyInfo(Object key, AbstractSession session){
return referenceDescriptor.getObjectBuilder().extractPrimaryKeyFromObject(key, session);
}
/**
* INTERNAL:
* Create an instance of the Key object from the key information extracted from the map.
* This may return the value directly in case of a simple key or will be used as the FK to load a related entity.
*/
@Override
public List createMapComponentsFromSerializableKeyInfo(Object[] keyInfo, AbstractSession session){
List orderedResult = new ArrayList<>(keyInfo.length);
Map fromCache = session.getIdentityMapAccessorInstance().getAllFromIdentityMapWithEntityPK(keyInfo, referenceDescriptor);
List foreignKeyValues = new ArrayList(keyInfo.length - fromCache.size());
CacheKeyType cacheKeyType = referenceDescriptor.getCachePolicy().getCacheKeyType();
for (int index = 0; index < keyInfo.length; ++index){
Object pk = keyInfo[index];
if (!fromCache.containsKey(pk)){
if (cacheKeyType == CacheKeyType.CACHE_ID){
foreignKeyValues.add(Arrays.asList(((CacheId)pk).getPrimaryKey()));
}else{
foreignKeyValues.add(pk);
}
}
}
if (!foreignKeyValues.isEmpty()){
ReadAllQuery query = new ReadAllQuery(referenceDescriptor.getJavaClass());
query.setIsExecutionClone(true);
query.addArgument(ForeignReferenceMapping.QUERY_BATCH_PARAMETER);
query.addArgumentValue(foreignKeyValues);
query.setSession(session);
query.setSelectionCriteria(referenceDescriptor.buildBatchCriteriaByPK(query.getExpressionBuilder(), query));
Collection temp = (Collection) session.executeQuery(query);
for (Object element: temp){
Object pk = referenceDescriptor.getObjectBuilder().extractPrimaryKeyFromObject(element, session);
fromCache.put(pk, element);
}
}
for(Object key : keyInfo){
orderedResult.add(fromCache.get(key));
}
return orderedResult;
}
/**
* INTERNAL:
* Create an instance of the Key object from the key information extracted from the map.
* This key object may be a shallow stub of the actual object if the key is an Entity type.
*/
@Override
public Object createStubbedMapComponentFromSerializableKeyInfo(Object keyInfo, AbstractSession session) {
ObjectBuilder builder = this.referenceDescriptor.getObjectBuilder();
ObjectBuildingQuery clonedQuery = (ObjectBuildingQuery) getSelectionQuery().clone();
clonedQuery.setSession(session);
Object newObject = referenceDescriptor.getInstantiationPolicy().buildNewInstance();
builder.buildPrimaryKeyAttributesIntoObject(newObject, builder.buildRowFromPrimaryKeyValues(keyInfo, session), clonedQuery, session);
return newObject;
}
/**
* INTERNAL
* Called when a DatabaseMapping is used to map the key in a collection. Returns the key.
*/
@Override
public Object createMapComponentFromJoinedRow(AbstractRecord dbRow, JoinedAttributeManager joinManager, ObjectBuildingQuery query, CacheKey parentCacheKey, AbstractSession session, boolean isTargetProtected){
return valueFromRowInternalWithJoin(dbRow, joinManager, query, parentCacheKey, session, isTargetProtected);
}
/**
* INTERNAL:
* Create a query key that links to the map key
*/
@Override
public QueryKey createQueryKeyForMapKey(){
OneToOneQueryKey key = new OneToOneQueryKey();
key.setDescriptor(getReferenceDescriptor());
key.setReferenceClass(getReferenceClass());
key.setJoinCriteria(getAdditionalSelectionCriteriaForMapKey());
return key;
}
/**
* INTERNAL:
* For mappings used as MapKeys in MappedKeyContainerPolicy, Delete the passed object if necessary.
*
* This method is used for removal of private owned relationships
*
*/
@Override
public void deleteMapKey(Object objectDeleted, AbstractSession session){
session.deleteObject(objectDeleted);
}
/**
* INTERNAL:
* Adds locking clause to the target query to extend pessimistic lock scope.
*/
@Override
protected void extendPessimisticLockScopeInTargetQuery(ObjectLevelReadQuery targetQuery, ObjectBuildingQuery sourceQuery) {
if(this.mechanism == null) {
super.extendPessimisticLockScopeInTargetQuery(targetQuery, sourceQuery);
} else {
this.mechanism.setRelationTableLockingClause(targetQuery, sourceQuery);
}
}
/**
* INTERNAL:
* Called only if both
* shouldExtendPessimisticLockScope and shouldExtendPessimisticLockScopeInSourceQuery are true.
* Adds fields to be locked to the where clause of the source query.
* Note that the sourceQuery must be ObjectLevelReadQuery so that it has ExpressionBuilder.
*
* This method must be implemented in subclasses that allow
* setting shouldExtendPessimisticLockScopeInSourceQuery to true.
*/
@Override
public void extendPessimisticLockScopeInSourceQuery(ObjectLevelReadQuery sourceQuery) {
Expression exp = sourceQuery.getSelectionCriteria();
if(this.mechanism == null) {
ExpressionBuilder builder = sourceQuery.getExpressionBuilder();
Iterator> it = this.getSourceToTargetKeyFields().entrySet().iterator();
Map.Entry entry = it.next();
exp = builder.getField(entry.getKey()).equal(builder.get(this.getAttributeName()).getField(entry.getValue())).and(exp);
} else {
exp = this.mechanism.joinRelationTableField(exp, sourceQuery.getExpressionBuilder());
}
sourceQuery.setSelectionCriteria(exp);
}
/**
* INTERNAL:
* Extract the foreign key value from the source row.
*/
@Override
protected Object extractBatchKeyFromRow(AbstractRecord row, AbstractSession session) {
if (this.mechanism != null) {
return this.mechanism.extractBatchKeyFromRow(row, session);
}
Object[] key;
ConversionManager conversionManager = session.getDatasourcePlatform().getConversionManager();
key = new Object[this.sourceToTargetKeyFields.size()];
int index = 0;
for (DatabaseField field : this.sourceToTargetKeyFields.keySet()) {
Object value = row.get(field);
if (value == null) {
return null;
}
// Must ensure the classification gets a cache hit.
try {
value = conversionManager.convertObject(value, field.getType());
} catch (ConversionException exception) {
throw ConversionException.couldNotBeConverted(this, this.descriptor, exception);
}
key[index] = value;
index++;
}
return new CacheId(key);
}
/**
* INTERNAL:
* Extract the fields for the Map key from the object to use in a query
*/
@Override
public Map extractIdentityFieldsForQuery(Object object, AbstractSession session){
Map keyFields = new HashMap();
for (int index = 0; index < getForeignKeyFields().size(); index++) {
DatabaseField targetRelationField = getForeignKeyFields().elementAt(index);
DatabaseField targetKey = getSourceToTargetKeyFields().get(targetRelationField);
Object value = getReferenceDescriptor().getObjectBuilder().extractValueFromObjectForField(object, targetKey, session);
keyFields.put(targetRelationField, value);
}
return keyFields;
}
/**
* INTERNAL:
* Extract the key value from the reference object.
*/
protected Object extractKeyFromReferenceObject(Object object, AbstractSession session) {
ObjectBuilder objectBuilder = getReferenceDescriptor().getObjectBuilder();
Object[] key;
if (this.mechanism == null) {
key = new Object[getSourceToTargetKeyFields().size()];
int index = 0;
for (DatabaseField field : getSourceToTargetKeyFields().values()) {
if (object == null) {
key[index] = null;
} else {
key[index] = objectBuilder.extractValueFromObjectForField(object, field, session);
}
index++;
}
} else {
int size = this.mechanism.targetKeyFields.size();
key = new Object[size];
for (int i = 0; i < size; i++) {
if (object == null) {
key[i] = null;
} else {
DatabaseField field = this.mechanism.targetKeyFields.get(i);
key[i] = objectBuilder.extractValueFromObjectForField(object, field, session);
}
}
}
return new CacheId(key);
}
/**
* INTERNAL:
* Return the primary key for the reference object (i.e. the object
* object referenced by domainObject and specified by mapping).
* This key will be used by a RemoteValueHolder.
*/
@Override
public Object extractPrimaryKeysForReferenceObjectFromRow(AbstractRecord row) {
List primaryKeyFields = getReferenceDescriptor().getPrimaryKeyFields();
Object[] result = new Object[primaryKeyFields.size()];
for (int index = 0; index < primaryKeyFields.size(); index++) {
DatabaseField targetKeyField = primaryKeyFields.get(index);
DatabaseField sourceKeyField = getTargetToSourceKeyFields().get(targetKeyField);
if (sourceKeyField == null) {
return null;
}
result[index] = row.get(sourceKeyField);
if (getReferenceDescriptor().getCachePolicy().getCacheKeyType() == CacheKeyType.ID_VALUE) {
return result[index];
}
}
return new CacheId(result);
}
/**
* INTERNAL:
* Allow the mapping the do any further batch preparation.
*/
@Override
protected void postPrepareNestedBatchQuery(ReadQuery batchQuery, ObjectLevelReadQuery query) {
super.postPrepareNestedBatchQuery(batchQuery, query);
// Force a distinct to filter out m-1 duplicates.
// Only set if really a m-1, not a 1-1
if (!this.isOneToOneRelationship && ((ObjectLevelReadQuery)batchQuery).getBatchFetchPolicy().isJOIN()) {
if (!((ObjectLevelReadQuery)batchQuery).isDistinctComputed() && (batchQuery.getSession().getPlatform().isLobCompatibleWithDistinct() || !Helper.hasLob(batchQuery.getDescriptor().getSelectionFields((ObjectLevelReadQuery)batchQuery)))) {
((ObjectLevelReadQuery)batchQuery).useDistinct();
}
}
if (this.mechanism != null) {
this.mechanism.postPrepareNestedBatchQuery(batchQuery, query);
}
}
/**
* INTERNAL:
* Return the selection criteria used to IN batch fetching.
*/
@Override
protected Expression buildBatchCriteria(ExpressionBuilder builder, ObjectLevelReadQuery query) {
if (this.mechanism == null) {
int size = this.sourceToTargetKeyFields.size();
if (size > 1) {
// Support composite keys using nested IN.
List fields = new ArrayList<>(size);
for (DatabaseField targetForeignKeyField : this.sourceToTargetKeyFields.values()) {
fields.add(builder.getField(targetForeignKeyField));
}
return query.getSession().getPlatform().buildBatchCriteriaForComplexId(builder, fields);
} else {
return query.getSession().getPlatform().buildBatchCriteria(builder, builder.getField(this.sourceToTargetKeyFields.values().iterator().next()));
}
} else {
return this.mechanism.buildBatchCriteria(builder, query);
}
}
/**
* INTERNAL:
* Prepare and execute the batch query and store the
* results for each source object in a map keyed by the
* mappings source keys of the source objects.
*/
@Override
protected void executeBatchQuery(DatabaseQuery query, CacheKey parentCacheKey, Map referenceObjectsByKey, AbstractSession session, AbstractRecord translationRow) {
// Execute query and index resulting objects by key.
List results;
ObjectBuilder builder = query.getDescriptor().getObjectBuilder();
if (this.mechanism == null) {
results = (List)session.executeQuery(query, translationRow);
for (Object eachReferenceObject : results) {
Object eachReferenceKey = extractKeyFromReferenceObject(eachReferenceObject, session);
referenceObjectsByKey.put(eachReferenceKey, builder.wrapObject(eachReferenceObject, session));
}
} else {
ComplexQueryResult complexResult = (ComplexQueryResult)session.executeQuery(query, translationRow);
results = (List)complexResult.getResult();
List rows = (List)complexResult.getData();
int size = results.size();
for (int index = 0; index < size; index++) {
AbstractRecord row = rows.get(index);
Object key = this.mechanism.extractKeyFromTargetRow(row, session);
referenceObjectsByKey.put(key, builder.wrapObject(results.get(index), session));
}
}
}
/**
* INTERNAL:
* Check if the target object is in the cache if possible based on the target key value.
* Return null if the target key is not the primary key, or if the query is refreshing.
*/
@Override
protected Object checkCacheForBatchKey(AbstractRecord sourceRow, Object foreignKey, Map batchObjects, ReadQuery batchQuery, ObjectLevelReadQuery originalQuery, AbstractSession session) {
if (((ReadAllQuery)batchQuery).shouldRefreshIdentityMapResult() || (!batchQuery.shouldMaintainCache())) {
return null;
}
// Check the cache using the source row and selection query.
Object cachedObject = this.selectionQuery.checkEarlyReturn(session, sourceRow);
if ((cachedObject != null) && (batchObjects != null)) {
batchObjects.put(foreignKey, cachedObject);
}
return cachedObject;
}
/**
* INTERNAL:
* Return the selection criteria necessary to select the target object when this mapping
* is a map key.
*/
@Override
public Expression getAdditionalSelectionCriteriaForMapKey(){
return buildSelectionCriteria(false, false);
}
/**
* INTERNAL:
* Return any tables that will be required when this mapping is used as part of a join query
*/
@Override
public List getAdditionalTablesForJoinQuery(){
List tables = new ArrayList<>(getReferenceDescriptor().getTables().size() + 1);
tables.addAll(getReferenceDescriptor().getTables());
if (keyTableForMapKey != null){
tables.add(keyTableForMapKey);
}
return tables;
}
/**
* INTERNAL:
* Should be overridden by subclass that allows setting
* extendPessimisticLockScope to DEDICATED_QUERY.
*/
@Override
protected ReadQuery getExtendPessimisticLockScopeDedicatedQuery(AbstractSession session, short lockMode) {
if(this.mechanism != null) {
return this.mechanism.getLockRelationTableQueryClone(session, lockMode);
} else {
return super.getExtendPessimisticLockScopeDedicatedQuery(session, lockMode);
}
}
/**
* INTERNAL:
* Return the classification for the field contained in the mapping.
* This is used to convert the row value to a consistent java value.
*/
@Override
public Class> getFieldClassification(DatabaseField fieldToClassify) throws DescriptorException {
DatabaseField fieldInTarget = getSourceToTargetKeyFields().get(fieldToClassify);
if (fieldInTarget == null) {
return null;// Can be registered as multiple table secondary field mapping
}
DatabaseMapping mapping = getReferenceDescriptor().getObjectBuilder().getMappingForField(fieldInTarget);
if (mapping == null) {
return null;// Means that the mapping is read-only
}
return mapping.getFieldClassification(fieldInTarget);
}
/**
* PUBLIC:
* Return the foreign key field names associated with the mapping.
* These are only the source fields that are writable.
*/
public Vector getForeignKeyFieldNames() {
Vector fieldNames = new Vector(getForeignKeyFields().size());
for (Enumeration fieldsEnum = getForeignKeyFields().elements();
fieldsEnum.hasMoreElements();) {
fieldNames.addElement(fieldsEnum.nextElement().getQualifiedName());
}
return fieldNames;
}
/**
* INTERNAL:
* Return source key fields for translation by an AggregateObjectMapping
*/
@Override
public Collection getFieldsForTranslationInAggregate() {
return getSourceToTargetKeyFields().keySet();
}
/**
* Return the appropriate map that maps the "foreign keys"
* to the "primary keys".
*/
protected Map getForeignKeysToPrimaryKeys() {
if (this.isForeignKeyRelationship()) {
return this.getSourceToTargetKeyFields();
} else {
return this.getTargetToSourceKeyFields();
}
}
/**
* INTERNAL:
* Return a Map of any foreign keys defined within the the MapKey
*/
@Override
public Map getForeignKeyFieldsForMapKey(){
return getSourceToTargetKeyFields();
}
/**
* INTERNAL:
* Return the fields that make up the identity of the mapped object. For mappings with
* a primary key, it will be the set of fields in the primary key. For mappings without
* a primary key it will likely be all the fields
*/
@Override
public List getIdentityFieldsForMapKey(){
return getForeignKeyFields();
}
/**
* INTERNAL:
* Return the query that is used when this mapping is part of a joined relationship
*
* This method is used when this mapping is used to map the key in a Map
*/
@Override
public ObjectLevelReadQuery getNestedJoinQuery(JoinedAttributeManager joinManager, ObjectLevelReadQuery query, AbstractSession session){
return prepareNestedJoins(joinManager, query, session);
}
/**
* INTERNAL:
* Get all the fields for the map key
*/
@Override
public List getAllFieldsForMapKey(){
List fields = new ArrayList(getReferenceDescriptor().getAllSelectionFields().size() + getForeignKeyFields().size());
fields.addAll(getReferenceDescriptor().getAllSelectionFields());
fields.addAll(getForeignKeyFields());
return fields;
}
/**
* INTERNAL:
* Return a vector of the foreign key fields in the same order
* as the corresponding primary key fields are in their descriptor.
*/
public Vector getOrderedForeignKeyFields() {
List primaryKeyFields = getPrimaryKeyDescriptor().getPrimaryKeyFields();
Vector result = new Vector(primaryKeyFields.size());
for (int index = 0; index < primaryKeyFields.size(); index++) {
DatabaseField pkField = primaryKeyFields.get(index);
boolean found = false;
for (Iterator fkStream = this.getForeignKeysToPrimaryKeys().keySet().iterator();
fkStream.hasNext();) {
DatabaseField fkField = (DatabaseField)fkStream.next();
if (this.getForeignKeysToPrimaryKeys().get(fkField).equals(pkField)) {
found = true;
result.addElement(fkField);
break;
}
}
if (!found) {
throw DescriptorException.missingForeignKeyTranslation(this, pkField);
}
}
return result;
}
/**
* Return the descriptor for whichever side of the
* relation has the "primary key".
*/
protected ClassDescriptor getPrimaryKeyDescriptor() {
if (this.isForeignKeyRelationship()) {
return this.getReferenceDescriptor();
} else {
return this.getDescriptor();
}
}
/**
* INTERNAL:
* The private owned criteria is only used outside of the unit of work to compare the previous value of the reference.
*/
public Expression getPrivateOwnedCriteria() {
if (privateOwnedCriteria == null) {
initializePrivateOwnedCriteria();
}
return privateOwnedCriteria;
}
/**
* INTERNAL:
* Return a collection of the source to target field value associations.
*/
public Vector getSourceToTargetKeyFieldAssociations() {
Vector associations = new Vector(getSourceToTargetKeyFields().size());
Iterator sourceFieldEnum = getSourceToTargetKeyFields().keySet().iterator();
Iterator targetFieldEnum = getSourceToTargetKeyFields().values().iterator();
while (sourceFieldEnum.hasNext()) {
Object fieldValue = sourceFieldEnum.next().getQualifiedName();
Object attributeValue = targetFieldEnum.next().getQualifiedName();
associations.addElement(new Association(fieldValue, attributeValue));
}
return associations;
}
/**
* INTERNAL:
* Returns the source keys to target keys fields association.
*/
public Map getSourceToTargetKeyFields() {
return sourceToTargetKeyFields;
}
/**
* INTERNAL:
* Returns the target keys to source keys fields association.
*/
public Map getTargetToSourceKeyFields() {
return targetToSourceKeyFields;
}
/**
* INTERNAL:
* If required, get the targetVersion of the source object from the merge manager
*
* Used with MapKeyContainerPolicy to abstract getting the target version of a source key
*/
@Override
public Object getTargetVersionOfSourceObject(Object object, Object parent, MergeManager mergeManager, AbstractSession targetSession){
return mergeManager.getTargetVersionOfSourceObject(object, referenceDescriptor, targetSession);
}
/**
* INTERNAL:
* Return the class this key mapping maps or the descriptor for it
*/
@Override
public Class> getMapKeyTargetType(){
return getReferenceClass();
}
/**
* INTERNAL:
* Initialize the mapping.
*/
@Override
public void initialize(AbstractSession session) throws DescriptorException {
if (session.hasBroker()) {
if (getReferenceClass() == null) {
throw DescriptorException.referenceClassNotSpecified(this);
}
// substitute session that owns the mapping for the session that owns reference descriptor.
session = session.getBroker().getSessionForClass(getReferenceClass());
}
super.initialize(session);
if (isForeignKeyRelationship() && !isMapKeyMapping()) {
getDescriptor().addPreDeleteMapping(this);
}
// Capture our foreign key field specifications here. We need to build
// the fields first to ensure they have a table associated with them.
// Also must be careful to not set the flags based on a previously
// built field (multiple mappings to the same field) since we need to
// capture the flags from the field set directly on this mapping.
for (DatabaseField field : getForeignKeyFields()) {
DatabaseField builtField = getDescriptor().buildField(field, keyTableForMapKey);
if (builtField == field || builtField.isTranslated()) {
// same instance or translated, look at the built field.
updateInsertableAndUpdatableFields(builtField);
} else {
// previously built field and not translated, look at the original field.
updateInsertableAndUpdatableFields(field);
}
}
if (this.mechanism != null) {
if (this.mechanism.hasRelationTable()) {
if(!this.foreignKeyFields.isEmpty() || !this.sourceToTargetKeyFields.isEmpty() || !this.targetToSourceKeyFields.isEmpty()) {
throw DescriptorException.oneToOneMappingConflict(this.getDescriptor(), this);
}
this.foreignKeyFields = null;
this.sourceToTargetKeyFields = null;
this.targetToSourceKeyFields = null;
this.mechanism.initialize(session, this);
} else {
this.mechanism = null;
}
}
if (this.mechanism == null) {
// Must set table of foreign keys.
for (int index = 0; index < getForeignKeyFields().size(); index++) {
DatabaseField foreignKeyField = getForeignKeyFields().get(index);
foreignKeyField = getDescriptor().buildField(foreignKeyField, keyTableForMapKey);
getForeignKeyFields().set(index, foreignKeyField);
}
// If only a selection criteria is specified then the foreign keys do not have to be initialized.
if (!(getTargetToSourceKeyFields().isEmpty() && getSourceToTargetKeyFields().isEmpty())) {
if (getTargetToSourceKeyFields().isEmpty() || getSourceToTargetKeyFields().isEmpty()) {
initializeForeignKeysWithDefaults(session);
} else {
initializeForeignKeys(session);
}
}
// Check if any foreign keys reference a secondary table.
if (getReferenceDescriptor().getTables().size() > 1) {
DatabaseTable firstTable = getReferenceDescriptor().getTables().get(0);
for (DatabaseField field : getSourceToTargetKeyFields().values()) {
if (!field.getTable().equals(firstTable)) {
getReferenceDescriptor().setHasMultipleTableConstraintDependecy(true);
}
}
}
// Check if any foreign keys reference a secondary table.
if (getDescriptor().getTables().size() > 1) {
DatabaseTable firstTable = getDescriptor().getTables().get(0);
for (DatabaseField field : getSourceToTargetKeyFields().keySet()) {
if (!field.getTable().equals(firstTable)) {
getDescriptor().setHasMultipleTableConstraintDependecy(true);
}
}
}
}
if (shouldInitializeSelectionCriteria()) {
if (shouldForceInitializationOfSelectionCriteria()) {
setSelectionCriteria(buildSelectionCriteria());
} else {
setSelectionCriteria(buildSelectionCriteria(true, true));
}
} else {
setShouldVerifyDelete(false);
}
setFields(collectFields());
}
/**
* INTERNAL:
* The foreign keys primary keys are stored as database fields in the map.
*/
protected void initializeForeignKeys(AbstractSession session) {
HashMap newSourceToTargetKeyFields = new HashMap(getSourceToTargetKeyFields().size());
HashMap newTargetToSourceKeyFields = new HashMap(getTargetToSourceKeyFields().size());
Iterator> iterator = getSourceToTargetKeyFields().entrySet().iterator();
while (iterator.hasNext()) {
Map.Entry entry = iterator.next();
DatabaseField sourceField = entry.getKey();
sourceField = getDescriptor().buildField(sourceField, keyTableForMapKey);
if (usesIndirection()) {
sourceField.setKeepInRow(true);
}
DatabaseField targetField = entry.getValue();
targetField = getReferenceDescriptor().buildField(targetField, keyTableForMapKey);
newSourceToTargetKeyFields.put(sourceField, targetField);
newTargetToSourceKeyFields.put(targetField, sourceField);
}
setSourceToTargetKeyFields(newSourceToTargetKeyFields);
setTargetToSourceKeyFields(newTargetToSourceKeyFields);
}
/**
* INTERNAL:
* The foreign keys primary keys are stored as database fields in the map.
*/
protected void initializeForeignKeysWithDefaults(AbstractSession session) {
if (isForeignKeyRelationship()) {
if (getSourceToTargetKeyFields().size() != 1) {
throw DescriptorException.foreignKeysDefinedIncorrectly(this);
}
List targetKeys = getReferenceDescriptor().getPrimaryKeyFields();
if (targetKeys.size() != 1) {
//target and source keys are not the same size.
throw DescriptorException.sizeMismatchOfForeignKeys(this);
}
//grab the only element out of the map
DatabaseField sourceField = getSourceToTargetKeyFields().keySet().iterator().next();
sourceField = getDescriptor().buildField(sourceField);
if (usesIndirection()) {
sourceField.setKeepInRow(true);
}
getSourceToTargetKeyFields().clear();
getTargetToSourceKeyFields().clear();
getSourceToTargetKeyFields().put(sourceField, targetKeys.get(0));
getTargetToSourceKeyFields().put(targetKeys.get(0), sourceField);
} else {
if (getTargetToSourceKeyFields().size() != 1) {
throw DescriptorException.foreignKeysDefinedIncorrectly(this);
}
List sourceKeys = getDescriptor().getPrimaryKeyFields();
if (sourceKeys.size() != 1) {
//target and source keys are not the same size.
throw DescriptorException.sizeMismatchOfForeignKeys(this);
}
//grab the only element out of the map
DatabaseField targetField = getTargetToSourceKeyFields().keySet().iterator().next();
targetField = getReferenceDescriptor().buildField(targetField);
getSourceToTargetKeyFields().clear();
getTargetToSourceKeyFields().clear();
getTargetToSourceKeyFields().put(targetField, sourceKeys.get(0));
getSourceToTargetKeyFields().put(sourceKeys.get(0), targetField);
}
}
/**
* INTERNAL:
* Selection criteria is created with source foreign keys and target keys.
*/
protected void initializePrivateOwnedCriteria() {
if (!isForeignKeyRelationship()) {
setPrivateOwnedCriteria(getSelectionCriteria());
} else {
Expression pkCriteria = getDescriptor().getObjectBuilder().getPrimaryKeyExpression();
ExpressionBuilder builder = new ExpressionBuilder();
Expression backRef = builder.getManualQueryKey(getAttributeName() + "-back-ref", getDescriptor());
Expression newPKCriteria = pkCriteria.rebuildOn(backRef);
Expression twistedSelection = backRef.twist(getSelectionCriteria(), builder);
if (getDescriptor().getQueryManager().getAdditionalJoinExpression() != null) {
// We don't have to twist the additional join because it's all against the same node, which is our base
// but we do have to rebuild it onto the manual query key
Expression rebuiltAdditional = getDescriptor().getQueryManager().getAdditionalJoinExpression().rebuildOn(backRef);
if (twistedSelection == null) {
twistedSelection = rebuiltAdditional;
} else {
twistedSelection = twistedSelection.and(rebuiltAdditional);
}
}
setPrivateOwnedCriteria(newPKCriteria.and(twistedSelection));
}
}
/**
* INTERNAL:
* Making any mapping changes necessary to use a the mapping as a map key prior to initializing the mapping
*/
@Override
public void preinitializeMapKey(DatabaseTable table) throws DescriptorException {
keyTableForMapKey = table;
}
/**
* INTERNAL:
* Need to set the field type for the foreign key fields for a map key, as the fields are not contained in any descriptor.
*/
@Override
public void postInitializeMapKey(MappedKeyMapContainerPolicy policy) {
for (DatabaseField foreignKey : getSourceToTargetKeyFields().keySet()) {
if (foreignKey.getType() == null) {
foreignKey.setType(getFieldClassification(foreignKey));
}
}
}
/**
* INTERNAL:
* Post-initialize source and target expression fields created when a mapping's selectionCriteria
* is created early with only partly initialized fields.
*/
@Override
public void postInitializeSourceAndTargetExpressions() {
// EL Bug 426500
// postInitialize and set source expression fields using my descriptor
if (this.sourceExpressionsToPostInitialize != null && this.sourceExpressionsToPostInitialize.size() > 0) {
ClassDescriptor descriptor = getDescriptor();
ObjectBuilder objectBuilder = descriptor.getObjectBuilder();
for (Iterator expressions = this.sourceExpressionsToPostInitialize.iterator(); expressions.hasNext();) {
Expression expression = expressions.next();
DatabaseField field = null;
if (expression.isParameterExpression()) {
field = ((ParameterExpression)expression).getField();
} else if (expression.isFieldExpression()) {
field = ((FieldExpression)expression).getField();
}
if (field != null && (field.getType() == null || field.getTypeName() == null)) {
field.setType(objectBuilder.getFieldClassification(field));
}
}
}
// postInitialize and set target expression fields using my reference descriptor
if (this.targetExpressionsToPostInitialize != null && this.targetExpressionsToPostInitialize.size() > 0) {
ClassDescriptor descriptor = getReferenceDescriptor();
ObjectBuilder objectBuilder = descriptor.getObjectBuilder();
for (Iterator expressions = this.targetExpressionsToPostInitialize.iterator(); expressions.hasNext();) {
Expression expression = expressions.next();
DatabaseField field = null;
if (expression.isParameterExpression()) {
field = ((ParameterExpression)expression).getField();
} else if (expression.isFieldExpression()) {
field = ((FieldExpression)expression).getField();
}
if (field != null && (field.getType() == null || field.getTypeName() == null)) {
field.setType(objectBuilder.getFieldClassification(field));
}
}
}
}
/**
* INTERNAL:
* Prepare a cascade locking policy.
*/
@Override
public void prepareCascadeLockingPolicy() {
CascadeLockingPolicy policy = new CascadeLockingPolicy(getDescriptor(), getReferenceDescriptor());
policy.setQueryKeyFields(getSourceToTargetKeyFields(), ! isForeignKeyRelationship());
getReferenceDescriptor().addCascadeLockingPolicy(policy);
}
/**
* This method would allow customers to get the potential selection criteria for a mapping
* prior to initialization. This would allow them to more easily create an amendment method
* that would amend the SQL for the join.
*/
public Expression buildSelectionCriteria() {
return buildSelectionCriteria(true, false);
}
/**
* INTERNAL:
* Build the selection criteria for this mapping. Allows several variations.
*
* Either a parameter can be used for the join or simply the database field
*
* The existing selection criteria can be built upon or a whole new criteria can be built.
*/
public Expression buildSelectionCriteria(boolean useParameter, boolean usePreviousSelectionCriteria){
Expression criteria = null;
if (usePreviousSelectionCriteria){
criteria = getSelectionCriteria();
}
if(this.mechanism == null) {
Expression builder = new ExpressionBuilder();
// CR3922
if (getSourceToTargetKeyFields().isEmpty()) {
throw DescriptorException.noForeignKeysAreSpecified(this);
}
for (Iterator keys = getSourceToTargetKeyFields().keySet().iterator(); keys.hasNext();) {
DatabaseField foreignKey = keys.next();
DatabaseField targetKey = getSourceToTargetKeyFields().get(foreignKey);
Expression targetKeyExpression = builder.getField(targetKey);
Expression sourceKeyExpression = null;
if (useParameter){
sourceKeyExpression = builder.getParameter(foreignKey);
} else {
sourceKeyExpression = builder.getField(foreignKey);
}
if (usePreviousSelectionCriteria == false) {
this.sourceExpressionsToPostInitialize.add(sourceKeyExpression);
this.targetExpressionsToPostInitialize.add(targetKeyExpression);
}
Expression expression = targetKeyExpression.equal(sourceKeyExpression);
criteria = expression.and(criteria);
}
} else {
criteria = this.mechanism.buildSelectionCriteria(this, criteria);
}
return criteria;
}
/**
* INTERNAL:
* Builds a shallow original object. Only direct attributes and primary
* keys are populated. In this way the minimum original required for
* instantiating a working copy clone can be built without placing it in
* the shared cache (no concern over cycles).
*/
@Override
public void buildShallowOriginalFromRow(AbstractRecord databaseRow, Object original, JoinedAttributeManager joinManager, ObjectBuildingQuery query, AbstractSession executionSession) {
// Now we are only building this original so we can extract the primary
// key out of it. If the primary key is stored across a 1-1 a value
// holder needs to be built/triggered to get at it.
// In this case recursively build the shallow original across the 1-1.
// We only need the primary key for that object, and we know
// what that primary key is: it is the foreign key in our row.
ClassDescriptor descriptor = getReferenceDescriptor();
AbstractRecord targetRow = new DatabaseRecord();
for (Iterator keys = getSourceToTargetKeyFields().keySet().iterator(); keys.hasNext();) {
DatabaseField foreignKey = keys.next();
DatabaseField targetKey = getSourceToTargetKeyFields().get(foreignKey);
targetRow.put(targetKey, databaseRow.get(foreignKey));
}
Object targetObject = descriptor.getObjectBuilder().buildNewInstance();
descriptor.getObjectBuilder().buildAttributesIntoShallowObject(targetObject, targetRow, query);
targetObject = getIndirectionPolicy().valueFromRow(targetObject);
setAttributeValueInObject(original, targetObject);
}
/**
* INTERNAL:
*/
@Override
public boolean isOneToOneMapping() {
return true;
}
/**
* INTERNAL:
*/
@Override
public boolean isOwned(){
return this.hasRelationTable() && ! this.isReadOnly;
}
/**
* INTERNAL:
* Reads the private owned object.
*/
@Override
protected Object readPrivateOwnedForObject(ObjectLevelModifyQuery modifyQuery) throws DatabaseException {
if (modifyQuery.getSession().isUnitOfWork()) {
return super.readPrivateOwnedForObject(modifyQuery);
} else {
if (!shouldVerifyDelete()) {
return null;
}
ReadObjectQuery readQuery = (ReadObjectQuery)getSelectionQuery().clone();
readQuery.setSelectionCriteria(getPrivateOwnedCriteria());
return modifyQuery.getSession().executeQuery(readQuery, modifyQuery.getTranslationRow());
}
}
/**
* INTERNAL:
* Rehash any map based on fields.
* This is used to clone descriptors for aggregates, which hammer field names,
* it is probably better not to hammer the field name and this should be refactored.
*/
@Override
public void rehashFieldDependancies(AbstractSession session) {
setSourceToTargetKeyFields(Helper.rehashMap(getSourceToTargetKeyFields()));
// Go through the fks again and make updates for any translated fields.
for (DatabaseField field : getSourceToTargetKeyFields().keySet()) {
if (field.isTranslated()) {
updateInsertableAndUpdatableFields(field);
}
}
}
/**
* INTERNAL:
* Return whether this mapping requires extra queries to update the rows if it is
* used as a key in a map. This will typically be true if there are any parts to this mapping
* that are not read-only.
*/
@Override
public boolean requiresDataModificationEventsForMapKey() {
return true;
}
/**
* Return if this mapping is really for a OneToOne relationship.
* This is a backward compatibility issue, in that before the ManyToOneMapping
* was created OneToOneMapping was used for both.
* false means it may be a OneToOne or a ManyToOne (unknown).
*/
public boolean isOneToOneRelationship() {
return isOneToOneRelationship;
}
/**
* Return if this mapping is mapped using primary key join columns.
*/
public boolean isOneToOnePrimaryKeyRelationship() {
return isOneToOnePrimaryKeyRelationship;
}
/**
* Define if this mapping is really for a OneToOne relationship.
* This is a backward compatibility issue, in that before the ManyToOneMapping
* was created OneToOneMapping was used for both.
*/
public void setIsOneToOneRelationship(boolean isOneToOneRelationship) {
this.isOneToOneRelationship = isOneToOneRelationship;
}
/**
* Set if this mapping is defined using primary key join columns.
*/
public void setIsOneToOnePrimaryKeyRelationship(boolean isOneToOnePrimaryKeyRelationship) {
this.isOneToOnePrimaryKeyRelationship = isOneToOnePrimaryKeyRelationship;
}
/**
* PUBLIC:
* Define the foreign key relationship in the 1-1 mapping.
* This method is used for singleton foreign key relationships only,
* that is the source object's table has a foreign key field to
* the target object's primary key field.
* Only the source foreign key field name is specified.
* When a foreign key is specified TopLink will automatically populate the value
* for that field from the target object when the object is written to the database.
* If the foreign key is also mapped through a direct-to-field then the direct-to-field must
* be set read-only.
*/
public void setForeignKeyFieldName(String sourceForeignKeyFieldName) {
DatabaseField sourceField = new DatabaseField(sourceForeignKeyFieldName);
setIsForeignKeyRelationship(true);
getForeignKeyFields().addElement(sourceField);
getSourceToTargetKeyFields().put(sourceField, new DatabaseField());
}
/**
* PUBLIC:
* Return the foreign key field names associated with the mapping.
* These are only the source fields that are writable.
*/
public void setForeignKeyFieldNames(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()));
}
setForeignKeyFields(fields);
}
/**
* INTERNAL:
* Private owned criteria is used to verify the deletion of the target.
* It joins from the source table on the foreign key to the target table,
* with a parameterization of the primary key of the source object.
*/
protected void setPrivateOwnedCriteria(Expression expression) {
privateOwnedCriteria = expression;
}
/**
* PUBLIC:
* Verify delete is used during delete and update on private 1:1's outside of a unit of work only.
* It checks for the previous value of the target object through joining the source and target tables.
* By default it is always done, but may be disabled for performance on distributed database reasons.
* In the unit of work the previous value is obtained from the backup-clone so it is never used.
*/
public void setShouldVerifyDelete(boolean shouldVerifyDelete) {
this.shouldVerifyDelete = shouldVerifyDelete;
}
/**
* INTERNAL:
* Set a collection of the source to target field associations.
*/
public void setSourceToTargetKeyFieldAssociations(Vector sourceToTargetKeyFieldAssociations) {
setSourceToTargetKeyFields(new HashMap(sourceToTargetKeyFieldAssociations.size() + 1));
setTargetToSourceKeyFields(new HashMap(sourceToTargetKeyFieldAssociations.size() + 1));
for (Enumeration associationsEnum = sourceToTargetKeyFieldAssociations.elements();
associationsEnum.hasMoreElements();) {
Association association = (Association)associationsEnum.nextElement();
DatabaseField sourceField = new DatabaseField((String)association.getKey());
DatabaseField targetField = new DatabaseField((String)association.getValue());
getSourceToTargetKeyFields().put(sourceField, targetField);
getTargetToSourceKeyFields().put(targetField, sourceField);
}
}
/**
* INTERNAL:
* Set the source keys to target keys fields association.
*/
public void setSourceToTargetKeyFields(Map sourceToTargetKeyFields) {
this.sourceToTargetKeyFields = sourceToTargetKeyFields;
}
/**
* PUBLIC:
* Define the target foreign key relationship in the 1-1 mapping.
* This method is used for singleton target foreign key relationships only,
* that is the target object's table has a foreign key field to
* the source object's primary key field.
* The target foreign key field name is specified.
* The distinction between a foreign key and target foreign key is that the 1-1
* mapping will not populate the target foreign key value when written (because it is in the target table).
* Normally 1-1's are through foreign keys but in bi-directional 1-1's
* the back reference will be a target foreign key.
*/
public void setTargetForeignKeyFieldName(String targetForeignKeyFieldName) {
DatabaseField targetField = new DatabaseField(targetForeignKeyFieldName);
getTargetToSourceKeyFields().put(targetField, new DatabaseField());
}
/**
* INTERNAL:
* Set the target keys to source keys fields association.
*/
public void setTargetToSourceKeyFields(Map targetToSourceKeyFields) {
this.targetToSourceKeyFields = targetToSourceKeyFields;
}
/**
* PUBLIC:
* Verify delete is used during delete and update outside of a unit of work only.
* It checks for the previous value of the target object through joining the source and target tables.
*/
public boolean shouldVerifyDelete() {
return shouldVerifyDelete;
}
/**
* INTERNAL:
* By default returns true. Will also return true if:
* 1 - WriteType is INSERT and the field is insertable.
* 2 - WriteType is UPDATE and the field is updatable.
*/
protected boolean shouldWriteField(DatabaseField field, WriteType writeType) {
if (writeType.equals(WriteType.INSERT)) {
return insertableFields.contains(field);
} else if (writeType.equals(WriteType.UPDATE)) {
return updatableFields.contains(field);
} else {
return true; // UNDEFINED, default is to write.
}
}
/**
* INTERNAL
* Return true if this mapping supports cascaded version optimistic locking.
*/
@Override
public boolean isCascadedLockingSupported() {
return true;
}
/**
* INTERNAL:
* Return if this mapping support joining.
*/
@Override
public boolean isJoiningSupported() {
return true;
}
/**
* INTERNAL:
* Called when iterating through descriptors to handle iteration on this mapping when it is used as a MapKey
*/
@Override
public void iterateOnMapKey(DescriptorIterator iterator, Object element){
this.getIndirectionPolicy().iterateOnAttributeValue(iterator, element);
}
/**
* INTERNAL:
* Allow the key mapping to unwrap the object.
*/
@Override
public Object unwrapKey(Object key, AbstractSession session){
return getDescriptor().getObjectBuilder().unwrapObject(key, session);
}
/**
* INTERNAL:
* Add the field to the updatable and/or insertable list. Remove any
* previous field under the same name, otherwise shouldn't matter if we
* leave an old name (before translation) in the list as it should 'never'
* be used anyway.
*/
protected void updateInsertableAndUpdatableFields(DatabaseField field) {
insertableFields.remove(field);
updatableFields.remove(field);
if (field.isInsertable()) {
insertableFields.add(field);
}
if (field.isUpdatable()) {
updatableFields.add(field);
}
}
/**
* INTERNAL:
* Allow the key mapping to wrap the object.
*/
@Override
public Object wrapKey(Object key, AbstractSession session){
return getDescriptor().getObjectBuilder().wrapObject(key, session);
}
/**
* INTERNAL:
* A subclass should implement this method if it wants different behavior.
* Write the foreign key values from the attribute to the row.
*/
@Override
public void writeFromAttributeIntoRow(Object attribute, AbstractRecord row, AbstractSession session)
{
for (Enumeration fieldsEnum = getForeignKeyFields().elements(); fieldsEnum.hasMoreElements();) {
DatabaseField sourceKey = fieldsEnum.nextElement();
DatabaseField targetKey = getSourceToTargetKeyFields().get(sourceKey);
Object referenceValue = null;
// If privately owned part is null then method cannot be invoked.
if (attribute != null) {
referenceValue = getReferenceDescriptor().getObjectBuilder().extractValueFromObjectForField(attribute, targetKey, session);
}
row.add(sourceKey, referenceValue);
}
}
/**
* INTERNAL:
* Get a value from the object and set that in the respective field of the row.
*/
@Override
public Object valueFromObject(Object object, DatabaseField field, AbstractSession session) {
// First check if the value can be obtained from the value holder's row.
Object attributeValue = getAttributeValueFromObject(object);
AbstractRecord referenceRow = this.indirectionPolicy.extractReferenceRow(attributeValue);
if (referenceRow != null) {
Object value = referenceRow.get(field);
Class> type = getFieldClassification(field);
if ((value == null) || (value.getClass() != type)) {
// Must ensure the classification to get a cache hit.
try {
value = session.getDatasourcePlatform().convertObject(value, type);
} catch (ConversionException exception) {
throw ConversionException.couldNotBeConverted(this, getDescriptor(), exception);
}
}
return value;
}
Object referenceObject = getRealAttributeValueFromAttribute(attributeValue, object, session);
if (referenceObject == null) {
return null;
}
DatabaseField targetField;
if(this.mechanism == null) {
targetField = this.sourceToTargetKeyFields.get(field);
} else {
targetField = this.mechanism.targetKeyFields.get(this.mechanism.sourceKeyFields.indexOf(field));
}
return this.referenceDescriptor.getObjectBuilder().extractValueFromObjectForField(referenceObject, targetField, session);
}
/**
* INTERNAL:
* Return the value of the field from the row or a value holder on the query to obtain the object.
* Check for batch + aggregation reading.
*/
@Override
protected Object valueFromRowInternalWithJoin(AbstractRecord row, JoinedAttributeManager joinManager, ObjectBuildingQuery sourceQuery, CacheKey parentCacheKey, AbstractSession executionSession, boolean isTargetProtected) throws DatabaseException {
// PERF: Direct variable access.
Object referenceObject;
// CR #... 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.
AbstractRecord targetRow = trimRowForJoin(row, joinManager, executionSession);
// PERF: Only check for null row if an outer-join was used.
if (((joinManager != null) && joinManager.hasOuterJoinedAttributeQuery()) && !sourceQuery.hasPartialAttributeExpressions()) {
Object key = this.referenceDescriptor.getObjectBuilder().extractPrimaryKeyFromRow(targetRow, executionSession);
if (key == null) {
return this.indirectionPolicy.nullValueFromRow();
}
}
// A nested query must be built to pass to the descriptor that looks like the real query execution would,
// these should be cached on the query during prepare.
ObjectLevelReadQuery nestedQuery = prepareNestedJoinQueryClone(row, null, joinManager, sourceQuery, executionSession);
nestedQuery.setTranslationRow(targetRow);
nestedQuery.setRequiresDeferredLocks(sourceQuery.requiresDeferredLocks());
nestedQuery.setPrefetchedCacheKeys(sourceQuery.getPrefetchedCacheKeys());
nestedQuery.setShouldRefreshIdentityMapResult(sourceQuery.shouldRefreshIdentityMapResult());
referenceObject = this.referenceDescriptor.getObjectBuilder().buildObject(nestedQuery, targetRow);
// For bug 3641713 buildObject doesn't wrap if called on a UnitOfWork for performance reasons,
// must wrap here as this is the last time we can look at the query and tell whether to wrap or not.
if (nestedQuery.shouldUseWrapperPolicy() && executionSession.isUnitOfWork()) {
referenceObject = this.referenceDescriptor.getObjectBuilder().wrapObject(referenceObject, executionSession);
}
return this.indirectionPolicy.valueFromRow(referenceObject);
}
/**
* INTERNAL:
* Return the value of the field from the row or a value holder on the query to obtain the object.
* Check for batch + aggregation reading.
*/
@Override
protected Object valueFromRowInternal(AbstractRecord row, JoinedAttributeManager joinManager, ObjectBuildingQuery sourceQuery, AbstractSession executionSession, boolean shouldUseSopObject) throws DatabaseException {
// If any field in the foreign key is null then it means there are no referenced objects
// Skip for partial objects as fk may not be present.
if (!shouldUseSopObject) {
int size = this.fields.size();
for (int index = 0; index < size; index++) {
DatabaseField field = this.fields.get(index);
if (row.get(field) == null) {
return this.indirectionPolicy.nullValueFromRow();
}
}
}
// Call the default which executes the selection query,
// or wraps the query with a value holder.
return super.valueFromRowInternal(row, joinManager, sourceQuery, executionSession, shouldUseSopObject);
}
/**
* INTERNAL:
* Get a value from the object and set that in the respective field of the row.
*/
@Override
public void writeFromObjectIntoRow(Object object, AbstractRecord databaseRow, AbstractSession session, WriteType writeType) {
if (this.isReadOnly || (!this.isForeignKeyRelationship)) {
return;
}
writeFromObjectIntoRowInternal(object, databaseRow, session, null, writeType);
}
/**
* INTERNAL:
* Get a value from the object and set that in the respective field of the row.
* The fields and the values added to the row depend on ShallowMode mode:
* null - all fields with their values from object;
* Insert - nullable fields added with value null, non nullable fields added with their values from object;
* UpdateAfterInsert - nullable fields added with with their non-null values from object, non nullable fields (and nullable with null values) are ignored;
* UpdateBeforeDelete - the same fields as for UpdateAfterShallowInsert - but all values are nulls.
*/
protected void writeFromObjectIntoRowInternal(Object object, AbstractRecord databaseRow, AbstractSession session, ShallowMode mode, WriteType writeType) {
List foreignKeyFields = getForeignKeyFields();
if (mode != null) {
List nonNullableFields = null;
for (DatabaseField field : foreignKeyFields) {
if (field.isNullable()) {
if (mode == ShallowMode.Insert && shouldWriteField(field, writeType)) {
// add a nullable field with a null value
databaseRow.add(field, null);
}
} else {
if (nonNullableFields == null) {
nonNullableFields = new ArrayList<>();
}
nonNullableFields.add(field);
}
}
if (nonNullableFields == null) {
// all foreignKeyFields are nullable
if (mode == ShallowMode.Insert) {
// nothing else to do
return;
}
// UpdateAfterInsert or UpdateBeforeDelete: all nullable foreignKeyFields will be processed
} else {
if (mode == ShallowMode.Insert) {
// all non nullable foreignKeyFields will be processed
foreignKeyFields = nonNullableFields;
} else {
// UpdateAfterInsert or UpdateBeforeDelete
if (foreignKeyFields.size() == nonNullableFields.size()) {
// all fields are non nullable - nothing else to do
return;
} else {
// all nullable foreignKeyFields will be processed
foreignKeyFields = new ArrayList<>(foreignKeyFields);
foreignKeyFields.removeAll(nonNullableFields);
}
}
}
}
Object attributeValue = getAttributeValueFromObject(object);
// If the value holder has the row, avoid instantiation and just use it.
AbstractRecord referenceRow = this.indirectionPolicy.extractReferenceRow(attributeValue);
if (referenceRow == null) {
// Extract from object.
Object referenceObject = getRealAttributeValueFromAttribute(attributeValue, object, session);
for (DatabaseField sourceKey : foreignKeyFields) {
Object referenceValue = null;
// If privately owned part is null then method cannot be invoked.
if (referenceObject != null) {
DatabaseField targetKey = this.sourceToTargetKeyFields.get(sourceKey);
referenceValue = this.referenceDescriptor.getObjectBuilder().extractValueFromObjectForField(referenceObject, targetKey, session);
}
if (mode == null) {
// EL Bug 319759 - if a field is null, then the update call cache should not be used
if (referenceValue == null) {
databaseRow.setNullValueInFields(true);
}
} else {
if (referenceValue == null) {
if (mode != ShallowMode.Insert) {
// both UpdateAfterInsert and UpdateBeforeDelete ignore null values
continue;
}
} else {
if (mode == ShallowMode.UpdateBeforeDelete) {
// UpdateBeforeDelete adds nulls instead of non nulls
referenceValue = null;
}
}
}
// Check updatable and insertable based on the write type.
if (shouldWriteField(sourceKey, writeType)) {
databaseRow.add(sourceKey, referenceValue);
}
}
} else {
for (DatabaseField sourceKey : foreignKeyFields) {
Object referenceValue = referenceRow.get(sourceKey);
if (mode == null) {
// EL Bug 319759 - if a field is null, then the update call cache should not be used
if (referenceValue == null) {
databaseRow.setNullValueInFields(true);
}
} else {
if (referenceValue == null) {
if (mode != ShallowMode.Insert) {
// both UpdateAfterInsert and UpdateBeforeDelete ignore null values
continue;
}
} else {
if (mode == ShallowMode.UpdateBeforeDelete) {
// UpdateBeforeDelete adds nulls instead of non nulls
referenceValue = null;
}
}
}
// Check updatable and insertable based on the write type.
if (shouldWriteField(sourceKey, writeType)) {
databaseRow.add(sourceKey, referenceValue);
}
}
}
}
/**
* INTERNAL:
* This row is built for shallow insert which happens in case of bidirectional inserts.
* The foreign keys must be set to null to avoid constraints.
*/
@Override
public void writeFromObjectIntoRowForShallowInsert(Object object, AbstractRecord databaseRow, AbstractSession session) {
if (this.isReadOnly || (!this.isForeignKeyRelationship)) {
return;
}
writeFromObjectIntoRowInternal(object, databaseRow, session, ShallowMode.Insert, WriteType.INSERT);
}
/**
* INTERNAL:
* This row is built for update after shallow insert which happens in case of bidirectional inserts.
* It contains the foreign keys with non null values that were set to null for shallow insert.
*/
@Override
public void writeFromObjectIntoRowForUpdateAfterShallowInsert(Object object, AbstractRecord databaseRow, AbstractSession session, DatabaseTable table) {
if (this.isReadOnly || (!this.isForeignKeyRelationship) || !getFields().get(0).getTable().equals(table) || isPrimaryKeyMapping()) {
return;
}
writeFromObjectIntoRowInternal(object, databaseRow, session, ShallowMode.UpdateAfterInsert, WriteType.UNDEFINED);
}
/**
* INTERNAL:
* This row is built for update before shallow delete which happens in case of bidirectional inserts.
* It contains the same fields as the row built by writeFromObjectIntoRowForUpdateAfterShallowInsert, but all the values are null.
*/
@Override
public void writeFromObjectIntoRowForUpdateBeforeShallowDelete(Object object, AbstractRecord databaseRow, AbstractSession session, DatabaseTable table) {
if (this.isReadOnly || (!this.isForeignKeyRelationship) || !getFields().get(0).getTable().equals(table) || isPrimaryKeyMapping()) {
return;
}
writeFromObjectIntoRowInternal(object, databaseRow, session, ShallowMode.UpdateBeforeDelete, WriteType.UNDEFINED);
}
/**
* INTERNAL:
* Get a value from the object and set that in the respective field of the row.
* Validation preventing primary key updates is implemented here.
*/
@Override
public void writeFromObjectIntoRowWithChangeRecord(ChangeRecord changeRecord, AbstractRecord databaseRow, AbstractSession session, WriteType writeType) {
if ((!this.isReadOnly) && this.isPrimaryKeyMapping && (!changeRecord.getOwner().isNew())) {
throw ValidationException.primaryKeyUpdateDisallowed(changeRecord.getOwner().getClassName(), changeRecord.getAttribute());
}
// The object must be used here as the foreign key may include more than just the
// primary key of the referenced object and the changeSet may not have the required information.
Object object = ((ObjectChangeSet)changeRecord.getOwner()).getUnitOfWorkClone();
writeFromObjectIntoRow(object, databaseRow, session, writeType);
}
/**
* INTERNAL:
* This row is built for shallow insert which happens in case of bidirectional inserts.
* The foreign keys must be set to null to avoid constraints.
*/
@Override
public void writeFromObjectIntoRowForShallowInsertWithChangeRecord(ChangeRecord ChangeRecord, AbstractRecord databaseRow, AbstractSession session) {
if (isReadOnly() || (!isForeignKeyRelationship())) {
return;
}
for (Enumeration fieldsEnum = getForeignKeyFields().elements();
fieldsEnum.hasMoreElements();) {
DatabaseField sourceKey = fieldsEnum.nextElement();
databaseRow.add(sourceKey, null);
}
}
/**
* INTERNAL:
* Write fields needed for insert into the template for with null values.
*/
@Override
public void writeInsertFieldsIntoRow(AbstractRecord databaseRow, AbstractSession session) {
if (isReadOnly() || (!isForeignKeyRelationship())) {
return;
}
for (Enumeration fieldsEnum = getForeignKeyFields().elements(); fieldsEnum.hasMoreElements();) {
DatabaseField sourceKey = fieldsEnum.nextElement();
if (shouldWriteField(sourceKey, WriteType.INSERT)) {
databaseRow.add(sourceKey, null);
}
}
}
/**
* PUBLIC:
* Indicates whether the mapping has RelationTableMechanism.
*/
@Override
public boolean hasRelationTableMechanism() {
return this.mechanism != null;
}
/**
* PUBLIC:
* Indicates whether the mapping has RelationTable.
*/
public boolean hasRelationTable() {
return this.mechanism != null && this.mechanism.hasRelationTable();
}
/**
* PUBLIC:
* Returns RelationTableMechanism that may be owned by the mapping,
* that allows to configure the mapping to use relation table (just like ManyToManyMapping).
* By default its null, should be created and set into the mapping before use.
*/
public RelationTableMechanism getRelationTableMechanism() {
return this.mechanism;
}
/**
* PUBLIC:
* Set the relational table.
* This is the join table that store both the source and target primary keys.
*/
public void setRelationTable(DatabaseTable relationTable) {
this.mechanism.setRelationTable(relationTable);
}
/**
* PUBLIC:
* Set RelationTableMechanism into the mapping,
* that allows to configure the mapping to use relation table (just like ManyToManyMapping).
*/
public void setRelationTableMechanism(RelationTableMechanism mechanism) {
this.mechanism = mechanism;
}
/**
* PUBLIC:
* Return RelationTable.
*/
public DatabaseTable getRelationTable() {
if(this.mechanism != null) {
return this.mechanism.getRelationTable();
} else {
return null;
}
}
/**
* INTERNAL:
* Delete privately owned parts
*/
@Override
public void preDelete(DeleteObjectQuery query) throws DatabaseException, OptimisticLockException {
if ((this.mechanism != null) && !this.isReadOnly && !this.isCascadeOnDeleteSetOnDatabase) {
AbstractRecord sourceRow = this.mechanism.buildRelationTableSourceRow(query.getObject(), query.getSession(), this);
query.getSession().executeQuery(this.mechanism.deleteQuery, sourceRow);
}
super.preDelete(query);
}
/**
* INTERNAL:
* Insert into relation table. This follows following steps.
* - Extract primary key and its value from the source object.
*
- Extract target key and its value from the target object.
*
- Construct a insert statement with above fields and values for relation table.
*
- execute the statement.
*/
@Override
public void postInsert(WriteObjectQuery query) throws DatabaseException {
super.postInsert(query);
if(this.mechanism != null && !isReadOnly()) {
Object targetObject = getRealAttributeValueFromObject(query.getObject(), query.getSession());
if (targetObject == null) {
return;
}
// Batch data modification in the uow
if (query.shouldCascadeOnlyDependentParts()) {
// Hey I might actually want to use an inner class here... ok array for now.
Object[] event = new Object[3];
event[0] = setObject;
event[1] = this.mechanism.buildRelationTableSourceRow(query.getObject(), query.getSession(), this);
// targetObject may not have pk yet - wait to extract targetRow until the event is processed
event[2] = targetObject;
query.getSession().getCommitManager().addDataModificationEvent(this, event);
} else {
AbstractRecord sourceAndTargetRow = this.mechanism.buildRelationTableSourceAndTargetRow(query.getObject(), targetObject, query.getSession(), this);
query.getSession().executeQuery(this.mechanism.insertQuery, sourceAndTargetRow);
}
}
}
/**
* INTERNAL:
* Update the relation table with the entries related to this mapping.
* Delete entries removed, insert entries added.
* If private also insert/delete/update target objects.
*/
@Override
public void postUpdate(WriteObjectQuery query) throws DatabaseException {
if(this.mechanism == null) {
super.postUpdate(query);
} else {
// If object is not instantiated then it's not changed.
if (!isAttributeValueInstantiated(query.getObject())) {
return;
}
AbstractRecord sourceRow = null;
if(!isReadOnly()) {
sourceRow = this.mechanism.buildRelationTableSourceRow(query.getObject(), query.getSession(), this);
query.getSession().executeQuery(this.mechanism.deleteQuery, sourceRow);
}
super.postUpdate(query);
if(sourceRow != null) {
Object targetObject = getRealAttributeValueFromObject(query.getObject(), query.getSession());
if (targetObject == null) {
return;
}
// Batch data modification in the uow
if (query.shouldCascadeOnlyDependentParts()) {
// Hey I might actually want to use an inner class here... ok array for now.
Object[] event = new Object[3];
event[0] = setObject;
event[1] = sourceRow;
// targetObject may not have pk yet - wait to extract targetRow until the event is processed
event[2] = targetObject;
query.getSession().getCommitManager().addDataModificationEvent(this, event);
} else {
AbstractRecord sourceAndTargetRow = this.mechanism.addRelationTableTargetRow(targetObject, query.getExecutionSession(), sourceRow, this);
query.getSession().executeQuery(this.mechanism.insertQuery, sourceAndTargetRow);
}
}
}
}
/**
* INTERNAL:
* Perform the commit event.
* This is used in the uow to delay data modifications.
*/
@Override
public void performDataModificationEvent(Object[] event, AbstractSession session) throws DatabaseException, DescriptorException {
// Hey I might actually want to use an inner class here... ok array for now.
if (event[0] == setObject) {
AbstractRecord sourceAndTargetRow = this.mechanism.addRelationTableTargetRow(event[2], session, (AbstractRecord)event[1], this);
session.executeQuery(this.mechanism.insertQuery, sourceAndTargetRow);
} else {
throw DescriptorException.invalidDataModificationEventCode(event[0], this);
}
}
/**
* INTERNAL:
* Return all the fields populated by this mapping, these are foreign keys only.
*/
@Override
protected Vector collectFields() {
if(this.mechanism != null) {
return new Vector(0);
} else {
return super.collectFields();
}
}
/**
* INTERNAL:
* Order by foreign key fields if a foreign key mapping (avoids joins).
*/
@Override
public List getOrderByNormalizedExpressions(Expression base) {
if (this.foreignKeyFields.size() > 0) {
List orderBys = new ArrayList(this.foreignKeyFields.size());
for (DatabaseField field : this.foreignKeyFields) {
orderBys.add(((QueryKeyExpression)base).getBaseExpression().getField(field));
}
return orderBys;
}
return super.getOrderByNormalizedExpressions(base);
}
}