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

// Contributors:
//     Oracle - initial API and implementation from Oracle TopLink
//     11/10/2011-2.4 Guy Pelletier
//       - 357474: Address primaryKey option from tenant discriminator column
//     30/05/2012-2.4 Guy Pelletier
//       - 354678: Temp classloader is still being used during metadata processing
//     06/03/2013-2.5.1 Guy Pelletier
//       - 402380: 3 jpa21/advanced tests failed on server with
//         "java.lang.NoClassDefFoundError: org/eclipse/persistence/testing/models/jpa21/advanced/enums/Gender"
package org.eclipse.persistence.mappings;

import java.beans.PropertyChangeListener;
import java.io.Serializable;
import java.security.AccessController;
import java.security.PrivilegedActionException;
import java.sql.ResultSet;
import java.sql.ResultSetMetaData;
import java.sql.SQLException;
import java.util.ArrayList;
import java.util.Enumeration;
import java.util.HashMap;
import java.util.Iterator;
import java.util.List;
import java.util.Map;
import java.util.Set;
import java.util.Vector;

import org.eclipse.persistence.core.mappings.CoreMapping;
import org.eclipse.persistence.descriptors.ClassDescriptor;
import org.eclipse.persistence.exceptions.DatabaseException;
import org.eclipse.persistence.exceptions.DescriptorException;
import org.eclipse.persistence.exceptions.QueryException;
import org.eclipse.persistence.exceptions.ValidationException;
import org.eclipse.persistence.expressions.Expression;
import org.eclipse.persistence.expressions.ExpressionBuilder;
import org.eclipse.persistence.indirection.ValueHolderInterface;
import org.eclipse.persistence.internal.databaseaccess.DatabaseAccessor;
import org.eclipse.persistence.internal.databaseaccess.DatabasePlatform;
import org.eclipse.persistence.internal.descriptors.ClassNameConversionRequired;
import org.eclipse.persistence.internal.descriptors.DescriptorIterator;
import org.eclipse.persistence.internal.descriptors.InstanceVariableAttributeAccessor;
import org.eclipse.persistence.internal.descriptors.MethodAttributeAccessor;
import org.eclipse.persistence.internal.expressions.ObjectExpression;
import org.eclipse.persistence.internal.expressions.QueryKeyExpression;
import org.eclipse.persistence.internal.helper.ConversionManager;
import org.eclipse.persistence.internal.helper.DatabaseField;
import org.eclipse.persistence.internal.helper.DatabaseTable;
import org.eclipse.persistence.internal.helper.IdentityHashSet;
import org.eclipse.persistence.internal.helper.NonSynchronizedVector;
import org.eclipse.persistence.internal.identitymaps.CacheKey;
import org.eclipse.persistence.internal.indirection.DatabaseValueHolder;
import org.eclipse.persistence.internal.queries.AttributeItem;
import org.eclipse.persistence.internal.queries.ContainerPolicy;
import org.eclipse.persistence.internal.queries.JoinedAttributeManager;
import org.eclipse.persistence.internal.security.PrivilegedAccessHelper;
import org.eclipse.persistence.internal.security.PrivilegedClassForName;
import org.eclipse.persistence.internal.sessions.AbstractRecord;
import org.eclipse.persistence.internal.sessions.AbstractSession;
import org.eclipse.persistence.internal.sessions.ChangeRecord;
import org.eclipse.persistence.internal.sessions.MergeManager;
import org.eclipse.persistence.internal.sessions.ObjectChangeSet;
import org.eclipse.persistence.internal.sessions.UnitOfWorkChangeSet;
import org.eclipse.persistence.internal.sessions.UnitOfWorkImpl;
import org.eclipse.persistence.internal.sessions.remote.RemoteSessionController;
import org.eclipse.persistence.internal.sessions.remote.RemoteValueHolder;
import org.eclipse.persistence.mappings.converters.Converter;
import org.eclipse.persistence.queries.DeleteObjectQuery;
import org.eclipse.persistence.queries.ObjectBuildingQuery;
import org.eclipse.persistence.queries.ObjectLevelModifyQuery;
import org.eclipse.persistence.queries.ObjectLevelReadQuery;
import org.eclipse.persistence.queries.QueryByExamplePolicy;
import org.eclipse.persistence.queries.WriteObjectQuery;
import org.eclipse.persistence.sessions.CopyGroup;
import org.eclipse.persistence.sessions.Project;
import org.eclipse.persistence.sessions.remote.DistributedSession;

/**
 * 

Purpose: Defines how an attribute of an object maps to and from the database * *

Responsibilities:

    *
  • Define type of relationship (1:1/1:M/M:M/etc.) *
  • Define instance variable name and fields names required *
  • Define any additional properties (ownership, indirection, read only, etc.) *
  • Control building the value for the instance variable from the database row *
  • Control building the database fields from the object *
  • Control any pre/post updating/inserting/deleting required to maintain the relationship *
  • Merges object changes for unit of work. *
  • Clones objects for unit of work. *
  • cache computed information to optimize performance *
* * @author Sati * @since TOPLink/Java 1.0 */ public abstract class DatabaseMapping extends CoreMapping implements Cloneable, Serializable { public enum WriteType { INSERT, UPDATE, UNDEFINED } /** Used to reduce memory for mappings with no fields. */ protected static final Vector NO_FIELDS = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(0); /** Used to share integer instance to reduce memory. */ protected static final Integer NO_WEIGHT = Integer.valueOf(Integer.MAX_VALUE); protected static final Integer WEIGHT_DIRECT = Integer.valueOf(1); protected static final Integer WEIGHT_TRANSFORM = Integer.valueOf(100); protected static final Integer WEIGHT_AGGREGATE = Integer.valueOf(200); protected static final Integer WEIGHT_TO_ONE = Integer.valueOf(400); /** ClassDescriptor to which this mapping belongs to */ protected ClassDescriptor descriptor; /** Wrapper to store the reference objects. */ protected AttributeAccessor attributeAccessor; /** Makes this mapping read only. No write are performed on it. Default is false */ protected boolean isReadOnly; /** Specifies whether this mapping is optional (i.e. field may be null). Used for DDL generation. */ protected boolean isOptional; /** Specifies whether this mapping is lazy, this means not included in the default fetch group. */ protected Boolean isLazy; /** Fields associated with the mappings are cached */ protected Vector fields; /** It is needed only in remote initialization and mapping is in parent descriptor */ protected boolean isRemotelyInitialized; /** This is a TopLink defined attribute that allows us to sort the mappings */ protected Integer weight = NO_WEIGHT; /** Allow user defined properties. */ protected Map properties; /** Allow the user to defined un-converted properties which will be initialized at runtime. */ protected Map> unconvertedProperties; /** * Used by the CMP3Policy to see if this mapping should be used in * processing pk classes for find methods */ protected boolean derivesId; /** * */ protected boolean isJPAId = false; /** * A mapsId value. */ protected String mapsIdValue; /** * The id mapping this mapping derives. Used by the CMP3Policy to see if * this mapping should be used in processing pk classes for find methods. */ protected DatabaseMapping derivedIdMapping; /** * PERF: Used as a quick check to see if this mapping is a primary key mapping, * set by the object builder during initialization. */ protected boolean isPrimaryKeyMapping = false; /** * PERF: Cache the mappings attribute name. */ protected String attributeName; /** * Records if this mapping is being used as a MapKeyMapping. This is important for recording main mappings */ protected boolean isMapKeyMapping = false; //used by the object build/merge code to control building/merging into the //shared cache. protected boolean isCacheable = true; /** * Irrelevant (and not set) unless descriptor has SerializedObjectPolicy (SOP). * If descriptor has SOP, then ObjectLevelReadQuery (with shouldUseSerializedObjectPolicy flag set to true) * reads in row that contain both field/value pairs and sopObject. * This flag indicates whether the data for this mapping is contained in the row's sopObject or in fields/values. * Boolean.TRUE - sopObject (in sopObject) * Boolean.FALSE - fields/values (out sopObject); * null - both sopObject and fields/values (both in and out sopObject). * While writing to the data base the mapping will be used for writing into sopObject unless this flag is set to Boolean.FALSE; */ protected Boolean isInSopObject; /** * PUBLIC: * Default constructor. */ public DatabaseMapping() { this.isOptional = true; this.isReadOnly = false; this.attributeAccessor = new InstanceVariableAttributeAccessor(); } /** * PUBLIC: * Add an unconverted property (to be initialiazed at runtime) */ public void addUnconvertedProperty(String propertyName, String propertyValue, String propertyType) { List valuePair = new ArrayList<>(2); valuePair.add(propertyValue); valuePair.add(propertyType); getUnconvertedProperties().put(propertyName, valuePair); } /** * INTERNAL: * Clone the attribute from the clone and assign it to the backup. */ public abstract void buildBackupClone(Object clone, Object backup, UnitOfWorkImpl unitOfWork); /** * INTERNAL: * Require for cloning, the part must be cloned. */ public Object buildBackupCloneForPartObject(Object attributeValue, Object clone, Object backup, UnitOfWorkImpl unitOfWork) { throw DescriptorException.invalidMappingOperation(this, "buildBackupCloneForPartObject"); } /** * INTERNAL: * Clone the attribute from the original and assign it to the clone. */ public abstract void buildClone(Object original, CacheKey cacheKey, Object clone, Integer refreshCascade, AbstractSession cloningSession); /** * INTERNAL: * A combination of readFromRowIntoObject and buildClone. *

* buildClone assumes the attribute value exists on the original and can * simply be copied. *

* readFromRowIntoObject assumes that one is building an original. *

* Both of the above assumptions are false in this method, and actually * attempts to do both at the same time. *

* Extract value from the row and set the attribute to this value in the * working copy clone. * In order to bypass the shared cache when in transaction a UnitOfWork must * be able to populate working copies directly from the row. */ public abstract void buildCloneFromRow(AbstractRecord databaseRow, JoinedAttributeManager joinManager, Object clone, CacheKey sharedCacheKey, ObjectBuildingQuery sourceQuery, UnitOfWorkImpl unitOfWork, AbstractSession executionSession); /** * 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). */ public void buildShallowOriginalFromRow(AbstractRecord databaseRow, Object original, JoinedAttributeManager joinManager, ObjectBuildingQuery query, AbstractSession executionSession) { return; } /** * INTERNAL: * Require for cloning, the part must be cloned. */ public Object buildCloneForPartObject(Object attributeValue, Object original, CacheKey cacheKey, Object clone, AbstractSession cloningSession, Integer refreshCascade, boolean isExisting, boolean isFromSharedCache) { throw DescriptorException.invalidMappingOperation(this, "buildCloneForPartObject"); } /** * INTERNAL: * Performs a first level clone of the attribute. This generally means on the container will be cloned. */ public Object buildContainerClone(Object attributeValue, AbstractSession cloningSession){ return attributeValue; } /** * 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, CopyGroup group) { } /** * INTERNAL: * In case Query By Example is used, this method builds and returns an expression that * corresponds to a single attribue and it's value. */ public Expression buildExpression(Object queryObject, QueryByExamplePolicy policy, Expression expressionBuilder, Map processedObjects, AbstractSession session) { if (policy.shouldValidateExample()){ throw QueryException.unsupportedMappingQueryByExample(queryObject.getClass().getName(), this); } return null; } /** * INTERNAL: * Used to allow object level comparisons. */ public Expression buildObjectJoinExpression(Expression base, Object value, AbstractSession session) { throw QueryException.unsupportedMappingForObjectComparison(this, base); } /** * INTERNAL: * Used to allow object level comparisons. */ public Expression buildObjectJoinExpression(Expression base, Expression argument, AbstractSession session) { throw QueryException.unsupportedMappingForObjectComparison(this, base); } /** * INTERNAL: * Cascade registerNew for Create through mappings that require the cascade */ abstract public void cascadePerformRemoveIfRequired(Object object, UnitOfWorkImpl uow, Map visitedObjects); /** * INTERNAL: * Cascade removal of orphaned private owned objects from the UnitOfWorkChangeSet */ public void cascadePerformRemovePrivateOwnedObjectFromChangeSetIfRequired(Object object, UnitOfWorkImpl uow, Map visitedObjects) { // no-op by default } /** * INTERNAL: * Cascade registerNew for Create through mappings that require the cascade */ abstract public void cascadeRegisterNewIfRequired(Object object, UnitOfWorkImpl uow, Map visitedObjects); /** * INTERNAL: * Cascade discover and persist new objects during commit. */ public void cascadeDiscoverAndPersistUnregisteredNewObjects(Object object, Map newObjects, Map unregisteredExistingObjects, Map visitedObjects, UnitOfWorkImpl uow, Set cascadeErrors) { // Do nothing by default, (direct and xml mappings do not require anything). } /** * 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){ throw DescriptorException.invalidMappingOperation(this, "calculatedDeferredChanges"); } /** * INTERNAL: * Clones itself. */ @Override public Object clone() { // Bug 3037701 - clone the AttributeAccessor DatabaseMapping mapping = null; try { mapping = (DatabaseMapping)super.clone(); } catch (CloneNotSupportedException e) { throw new InternalError(); } mapping.setAttributeAccessor((AttributeAccessor)attributeAccessor.clone()); return mapping; } /** * INTERNAL: * Helper method to clone vector of fields (used in aggregate initialization cloning). */ protected Vector cloneFields(Vector fields) { Vector clonedFields = org.eclipse.persistence.internal.helper.NonSynchronizedVector.newInstance(); for (Enumeration fieldsEnum = fields.elements(); fieldsEnum.hasMoreElements();) { clonedFields.addElement(((DatabaseField)fieldsEnum.nextElement()).clone()); } return clonedFields; } /** * This method must be overwritten in the subclasses to return a vector of all the * fields this mapping represents. */ protected Vector collectFields() { return NO_FIELDS; } /** * INTERNAL: * This method is used to store the FK fields that can be cached that correspond to noncacheable mappings * the FK field values will be used to re-issue the query when cloning the shared cache entity */ public void collectQueryParameters(Set record){ //no-op for mappings that do not support PROTECTED cache isolation } /** * INTERNAL: * Mapping callback for post-initialization of source and target expression fields * created when a mapping's selectionCriteria is created early with uninitialized fields. * @see OneToOneMapping#postInitializeSourceAndTargetExpressions() * @see OneToManyMapping#postInitializeSourceAndTargetExpressions() */ public void postInitializeSourceAndTargetExpressions() { // no-op by default // EL Bug 426500 } /** * INTERNAL: * This method was created in VisualAge. * @return prototype.changeset.ChangeRecord */ abstract public ChangeRecord compareForChange(Object clone, Object backup, ObjectChangeSet owner, AbstractSession session); /** * INTERNAL: * Compare the attributes belonging to this mapping for the objects. */ public abstract boolean compareObjects(Object firstObject, Object secondObject, AbstractSession session); /** * 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) { if (hasUnconvertedProperties()) { for (String propertyName : getUnconvertedProperties().keySet()) { List valuePair = getUnconvertedProperties().get(propertyName); String value = valuePair.get(0); String valueTypeName = valuePair.get(1); Class valueType = null; // Have to initialize the valueType now try { if (PrivilegedAccessHelper.shouldUsePrivilegedAccess()) { try { valueType = AccessController.doPrivileged(new PrivilegedClassForName(valueTypeName, true, classLoader)); } catch (PrivilegedActionException exception) { throw ValidationException.classNotFoundWhileConvertingClassNames(valueTypeName, exception.getException()); } } else { valueType = PrivilegedAccessHelper.getClassForName(valueTypeName, true, classLoader); } } catch (Exception exception) { throw ValidationException.classNotFoundWhileConvertingClassNames(valueTypeName, exception); } // Add the converted property. If the value type is the same // as the source (value) type, no conversion is made. getProperties().put(propertyName, ConversionManager.getDefaultManager().convertObject(value, valueType)); } } } /** * Convenience method to ensure converters have an opportunity to convert * any class names to classes during project setup. */ protected void convertConverterClassNamesToClasses(Converter converter, ClassLoader classLoader) { if (converter != null && converter instanceof ClassNameConversionRequired) { ((ClassNameConversionRequired)converter).convertClassNamesToClasses(classLoader); } } /** * INTERNAL: * Builder the unit of work value holder. * @param buildDirectlyFromRow indicates that we are building the clone directly * from a row as opposed to building the original from the row, putting it in * the shared cache, and then cloning the original. */ public DatabaseValueHolder createCloneValueHolder(ValueHolderInterface attributeValue, Object original, Object clone, AbstractRecord row, AbstractSession cloningSession, boolean buildDirectlyFromRow) { throw DescriptorException.invalidMappingOperation(this, "createUnitOfWorkValueHolder"); } /** * ADVANCED: * Returns true if the mapping references a JPA ID attribute for the CMP3Policy and JPA ID classes. */ public boolean derivesId() { return derivesId; } /** * INTERNAL: * This method is called to update collection tables prior to commit. */ public void earlyPreDelete(DeleteObjectQuery query, Object object) { } /** * INTERNAL: * Extract the nested attribute expressions that apply to this mapping. * This is used for partial objects, and batch fetching. */ protected List extractNestedExpressions(List expressions, ExpressionBuilder newRoot) { List nestedExpressions = new ArrayList(expressions.size()); /* * If the expression closest to to the Builder is for this mapping, that expression is rebuilt using * newRoot and added to the nestedExpressions list. */ for (Expression next : expressions) { // The expressionBuilder can be one of the locked expressions in // the ForUpdateOfClause. if (!next.isQueryKeyExpression()) { continue; } QueryKeyExpression expression = (QueryKeyExpression)next; ObjectExpression base = expression; boolean afterBase = false; while (!base.getBaseExpression().isExpressionBuilder()) { base = (ObjectExpression)base.getBaseExpression(); afterBase = true; } if (base.getName().equals(getAttributeName())) { // Only add the nested expressions for the mapping (not the mapping itself). if (afterBase) { nestedExpressions.add(expression.rebuildOn(base, newRoot)); } } } return nestedExpressions; } /** * INTERNAL: * Extract the nested attribute expressions that apply to this mapping. * This is used for joining, and locking. * For aggregates return the nested foreign reference mapping, not the aggregate, as the aggregates are not joined, * and share their parent's query. * @param rootExpressionsAllowed true if newRoot itself can be one of the * expressions returned (used for locking) */ protected List extractNestedNonAggregateExpressions(List expressions, ExpressionBuilder newRoot, boolean rootExpressionsAllowed) { List nestedExpressions = new ArrayList(expressions.size()); /* * need to work on all expressions with at least 2 nestings off the base expression builder, excluding * aggregateObjectMapping expressions from the count (only ForeignReferenceMapping expressions count). For those * expressions, If the expression closest to to the Builder is for this mapping, that expression is rebuilt using * newRoot and added to the nestedExpressions list. */ for (Expression next : expressions) { // The expressionBuilder can be one of the locked expressions in // the ForUpdateOfClause. if (!next.isQueryKeyExpression()) { continue; } QueryKeyExpression expression = (QueryKeyExpression)next; ObjectExpression base = expression; boolean afterBase = false; boolean done = false; ObjectExpression prevExpression = base; while (!base.getBaseExpression().isExpressionBuilder()&& !done) { base = (ObjectExpression)base.getBaseExpression(); while (!base.isExpressionBuilder() && (base.getMapping() != null && base.getMapping().isAggregateObjectMapping())) { base = (ObjectExpression)base.getBaseExpression(); } if (base.isExpressionBuilder()){ done = true; //use the one closest to the expression builder that wasn't an aggregate base = prevExpression; } else { prevExpression = base; afterBase = true; } } if (afterBase && base.getName().equals(getAttributeName())) { nestedExpressions.add(expression.rebuildOn(base, newRoot)); } else if (rootExpressionsAllowed && expression.getBaseExpression().isExpressionBuilder() && expression.getName().equals(getAttributeName())) { nestedExpressions.add(newRoot); } } return nestedExpressions; } /** * INTERNAL: * If there is root expression in the list then indicates whether it shouldUseOuterJoin, * otherwise return false. */ protected boolean hasRootExpressionThatShouldUseOuterJoin(List expressions) { for (Iterator expressionsEnum = expressions.iterator(); expressionsEnum.hasNext();) { Expression next = (Expression)expressionsEnum.next(); // The expressionBuilder can be one of the locked expressions in // the ForUpdateOfClause. if (!next.isQueryKeyExpression()) { continue; } QueryKeyExpression expression = (QueryKeyExpression)next; if (expression.getBaseExpression().isExpressionBuilder() && expression.getName().equals(getAttributeName())) { return expression.shouldUseOuterJoin(); } } return false; } /** * INTERNAL: * Used to store un-converted properties, which are subsequenctly converted * at runtime (through the convertClassNamesToClasses method. */ public boolean hasUnconvertedProperties() { return unconvertedProperties != null; } /** * INTERNAL: * An object has been serialized from the server to the client. * Replace the transient attributes of the remote value holders * with client-side objects. */ public abstract void fixObjectReferences(Object object, Map objectDescriptors, Map processedObjects, ObjectLevelReadQuery query, DistributedSession session); /** * 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 default is to do nothing. */ public void fixRealObjectReferences(Object object, Map objectInformation, Map processedObjects, ObjectLevelReadQuery query, DistributedSession session) { // do nothing } /** * ADVANCED: * Return the attributeAccessor. * The attribute accessor is responsible for setting and retrieving the attribute value * from the object for this mapping. */ @Override public AttributeAccessor getAttributeAccessor() { return attributeAccessor; } /** * PUBLIC: * The classification type for the attribute this mapping represents */ @Override public Class getAttributeClassification() { return null; } /** * PUBLIC: * Return the name of the attribute set in the mapping. */ @Override public String getAttributeName() { // The attribute name on the attributeAccessor will always override any attribute already set // Use the attributeAccessor attribute over the current attribute name if (attributeName == null) { attributeName = getAttributeAccessor().getAttributeName(); } return attributeName; } /** * INTERNAL: * Return the value of an attribute which this mapping represents for an object. */ @Override public Object getAttributeValueFromObject(Object object) throws DescriptorException { try { // PERF: direct-access. return this.attributeAccessor.getAttributeValueFromObject(object); } catch (DescriptorException exception) { exception.setMapping(this); throw exception; } } /** * INTERNAL: * Return the mapping's containerPolicy. */ @Override public ContainerPolicy getContainerPolicy() { throw DescriptorException.invalidMappingOperation(this, "getContainerPolicy"); } /** * ADVANCED: * Set the maps id value */ public DatabaseMapping getDerivedIdMapping() { return derivedIdMapping; } /** * INTERNAL: * Return the descriptor to which this mapping belongs */ @Override public ClassDescriptor getDescriptor() { return descriptor; } /** * INTERNAL: * Return the field associated with this mapping if there is exactly one. * This is required for object relational mapping to print them, but because * they are defined in in an Enterprise context they cannot be cast to. * Mappings that have a field include direct mappings and object relational mappings. */ @Override public DatabaseField getField() { return null; } /** * INTERNAL: * Return the classification for the field contained in the mapping. * This is used to convert the row value to a consistent java value. * By default this is unknown. */ public Class getFieldClassification(DatabaseField fieldToClassify) { return null; } /** * 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() { return getFields(); } /** * 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() { return new NonSynchronizedVector(0); } /** * INTERNAL: * Returns a vector of all the fields this mapping represents. */ @Override public Vector getFields() { return this.fields; } /** * INTERNAL: * Return the list of fields that should be used if this mapping is used in an order by. * null means this mapping does not need to normalize it fields (it is a field). */ public List getOrderByNormalizedExpressions(Expression base) { return null; } /** * PUBLIC: * This method is invoked reflectively on the reference object to return the value of the * attribute in the object. This method returns the name of the getMethodName or null if not using method access. */ public String getGetMethodName() { if (!getAttributeAccessor().isMethodAttributeAccessor()) { return null; } return ((MethodAttributeAccessor)getAttributeAccessor()).getGetMethodName(); } /** * ADVANCED: * Set the mapped by id value */ public boolean hasMapsIdValue() { return mapsIdValue != null; } /** * ADVANCED: * Set the mapped by id value */ public String getMapsIdValue() { return mapsIdValue; } /** * INTERNAL: * return the object on the client corresponding to the specified object. * The default is to simply return the object itself, without worrying about * maintaining object identity. */ public Object getObjectCorrespondingTo(Object object, DistributedSession session, Map objectDescriptors, Map processedObjects, ObjectLevelReadQuery query) { return object; } /** * INTERNAL: * used as a temporary store for custom SDK usage */ public Map getProperties() { if (properties == null) {//Lazy initialize to conserve space and allocation time. properties = new HashMap(5); } return properties; } /** * ADVANCED: * Allow user defined properties. */ public Object getProperty(Object property) { if (properties == null) { return null; } return getProperties().get(property); } /** * INTERNAL: * Return the value of an attribute unwrapping value holders if required. */ public Object getRealAttributeValueFromObject(Object object, AbstractSession session) throws DescriptorException { return getRealAttributeValueFromAttribute(getAttributeValueFromObject(object), object, session); } /** * INTERNAL: * Return the value of an attribute unwrapping value holders if required. */ public Object getRealAttributeValueFromAttribute(Object attributeValue, Object object, AbstractSession session) throws DescriptorException { return attributeValue; } /** * INTERNAL: * Trigger the instantiation of the attribute if lazy. */ public void instantiateAttribute(Object object, AbstractSession session) { // Not lazy by default. } /** * INTERNAL: * Return whether the specified object is instantiated. */ public boolean isAttributeValueFromObjectInstantiated(Object object) { return true; } /** * INTERNAL: * Return the value of an attribute, unwrapping value holders if necessary. * If the value is null, build a new container. */ public Object getRealCollectionAttributeValueFromObject(Object object, AbstractSession session) throws DescriptorException { throw DescriptorException.invalidMappingOperation(this, "getRealCollectionAttributeValueFromObject"); } /** * PUBLIC: * Return the referenceDescriptor. This is a descriptor which is associated with * the reference class. */ @Override public ClassDescriptor getReferenceDescriptor() { return null; } /** * INTERNAL: * Return the relationshipPartner mapping for this bi-directional mapping. If the relationshipPartner is null then * this is a uni-directional mapping. */ public DatabaseMapping getRelationshipPartner() { return null; } /** * PUBLIC: * This method is invoked reflectively on the reference object to set the value of the * attribute in the object. This method returns the name of the setMethodName or null if not using method access. */ public String getSetMethodName() { if (!getAttributeAccessor().isMethodAttributeAccessor()) { return null; } return ((MethodAttributeAccessor)getAttributeAccessor()).getSetMethodName(); } /** * INTERNAL: * Used to store un-converted properties, which are subsequenctly converted * at runtime (through the convertClassNamesToClasses method. */ public Map> getUnconvertedProperties() { if (unconvertedProperties == null) { unconvertedProperties = new HashMap<>(5); } return unconvertedProperties; } /** * INTERNAL: * extract and return the appropriate value from the * specified remote value holder */ public Object getValueFromRemoteValueHolder(RemoteValueHolder remoteValueHolder) { throw DescriptorException.invalidMappingOperation(this, "getValueFromRemoteValueHolder"); } /** * INTERNAL: * Return the weight of the mapping, used to sort mappings to ensure that * DirectToField Mappings get merged first */ public Integer getWeight() { return this.weight; } /** * INTERNAL: * The returns if the mapping has any constraint dependencies, such as foreign keys and join tables. */ public boolean hasConstraintDependency() { return false; } /** * PUBLIC: * Return if method access is used. */ public boolean isUsingMethodAccess() { return getAttributeAccessor().isMethodAttributeAccessor(); } /** * INTERNAL: * Return if the mapping has any ownership or other dependency over its target object(s). */ public boolean hasDependency() { return false; } /** * INTERNAL: * The returns if the mapping has any inverse constraint dependencies, such as foreign keys and join tables. */ public boolean hasInverseConstraintDependency() { return false; } /** * INTERNAL: * Allow for initialization of properties and validation. */ public void initialize(AbstractSession session) throws DescriptorException { } /** * INTERNAL: * Related mapping should implement this method to return true. */ public boolean isAggregateCollectionMapping() { return false; } /** * INTERNAL: * Related mapping should implement this method to return true. */ public boolean isAggregateMapping() { return false; } /** * INTERNAL: * Related mapping should implement this method to return true. */ public boolean isAggregateObjectMapping() { return false; } /** * INTERNAL: * Related mapping should implement this method to return true. */ @Override public boolean isCollectionMapping() { return false; } /** * INTERNAL: */ public boolean isDatabaseMapping() { return true; } /** * INTERNAL: * Related mapping should implement this method to return true. */ public boolean isDirectCollectionMapping() { return false; } /** * INTERNAL: * Related mapping should implement this method to return true. */ public boolean isDirectMapMapping() { return false; } /** * INTERNAL: * Related mapping should implement this method to return true. */ @Override public boolean isDirectToFieldMapping() { return false; } /** * INTERNAL: * Related mapping should implement this method to return true. */ public boolean isElementCollectionMapping() { return false; } /** * INTERNAL: * Related mapping should implement this method to return true. */ public boolean isForeignReferenceMapping() { return false; } /** * INTERNAL: * Return whether this mapping should be traversed when we are locking * @return */ public boolean isLockableMapping(){ return false; } /** * INTERNAL: * Related mapping should implement this method to return true. */ public boolean isManyToManyMapping() { return false; } /** * @return the isMapKeyMapping */ public boolean isMapKeyMapping() { return isMapKeyMapping; } /** * INTERNAL */ public boolean isMultitenantPrimaryKeyMapping() { return false; } /** * @param isMapKeyMapping the isMapKeyMapping to set */ public void setIsMapKeyMapping(boolean isMapKeyMapping) { this.isMapKeyMapping = isMapKeyMapping; } /** * INTERNAL: * Related mapping should implement this method to return true. */ public boolean isNestedTableMapping() { return false; } /** * INTERNAL: * Related mapping should implement this method to return true. */ public boolean isObjectReferenceMapping() { return false; } /** * INTERNAL: * Related mapping should implement this method to return true. */ public boolean isOneToManyMapping() { return false; } /** * INTERNAL: * Related mapping should implement this method to return true. */ public boolean isOneToOneMapping() { return false; } /** * INTERNAL: * Related mapping should implement this method to return true. */ public boolean isManyToOneMapping() { return false; } /** * Return whether the value of this mapping is optional (that is, can be * null). This is a hint and is used when generating DDL. */ public boolean isOptional() { return isOptional; } /** * Returns true if this mapping is owned by the parent descriptor. This is generally based on mapping type */ public boolean isOwned(){ return false; } /** * INTERNAL: * Flags that this mapping is part of a JPA id mapping. It should be * temporary though, as the CMP3Policy should be able to figure things * out on its own. The problem being that the JPA mapped superclass * descriptors are not initialized and do not have a CMP3Policy set by * default. */ public boolean isJPAId() { return isJPAId; } /** * Return if this mapping is lazy. * Lazy has different meaning for different mappings. * For basic/direct mappings, this can be used exclude it from the descriptor's * default fetch group. This means that queries will not include the field(s) required * by this mapping by default. * This can only be used if the descriptor has a FetchGroupManager and class implements * the FetchGroupTracker interface (or is weaved). *

* For relationship mappings this should normally be the same value as indirection, * however for eager relationships this can be used with indirection to allow * indirection locking and change tracking, but still always force instantiation. */ public boolean isLazy() { if (isLazy == null) { // False by default for mappings without indirection. isLazy = Boolean.FALSE; } return isLazy; } /** * INTERNAL: * Flags that this mapping is part of a JPA id mapping. It should be * temporary though, as the CMP3Policy should be able to figure things * out on its own. The problem being that the JPA mapped superclass * descriptors are not initialized and do not have a CMP3Policy set by * default. */ public void setIsJPAId() { this.isJPAId = true; } /** * Set if this mapping is lazy. * This can be used for any mapping type to exclude it from the descriptor's * default fetch group. This means that queries will not include the field(s) required * by this mapping by default. * This can only be used if the descriptor has a FetchGroupManager and class implements * the FetchGroupTracker interface (or is weaved). * This is not the same as indirection on relationships (lazy relationships), * as it defers the loading of the source object fields, not the relationship. */ public void setIsLazy(boolean isLazy) { this.isLazy = isLazy; } /** * INTERNAL: * All EIS mappings should implement this method to return true. */ public boolean isEISMapping() { return false; } /** * INTERNAL: * All relational mappings should implement this method to return true. */ public boolean isRelationalMapping() { return false; } /** * INTERNAL: * All relational mappings should implement this method to return true. */ public boolean isXMLMapping() { return false; } /** * INTERNAL: * Related mapping should implement this method to return true. */ @Override public boolean isAbstractDirectMapping() { return false; } /** * INTERNAL: */ public boolean isAbstractColumnMapping() { return false; } /** * INTERNAL: * Related mapping should implement this method to return true. */ @Override public boolean isAbstractCompositeDirectCollectionMapping() { return false; } /** * INTERNAL: * Related mapping should implement this method to return true. */ @Override public boolean isAbstractCompositeObjectMapping() { return false; } /** * INTERNAL: * Related mapping should implement this method to return true. */ @Override public boolean isAbstractCompositeCollectionMapping() { return false; } /** * INTERNAL: * Return if this mapping support joining. */ public boolean isJoiningSupported() { return false; } /** * INTERNAL: * Return if this mapping requires its attribute value to be cloned. */ public boolean isCloningRequired() { return true; } /** * INTERNAL: * Set by the Object builder during initialization returns true if this mapping * is used as a primary key mapping. */ public boolean isPrimaryKeyMapping() { return this.isPrimaryKeyMapping; } /** * INTERNAL: * Returns true if the mapping should be added to the UnitOfWork's list of private owned * objects for private owned orphan removal. */ public boolean isCandidateForPrivateOwnedRemoval() { return isPrivateOwned(); } /** * INTERNAL: * Used when determining if a mapping supports cascaded version optimistic * locking. */ public boolean isCascadedLockingSupported() { return false; } /** * INTERNAL: * Return if this mapping supports change tracking. */ public boolean isChangeTrackingSupported(Project project) { return false; } /** * INTERNAL: * Return if the mapping has ownership over its target object(s). */ public boolean isPrivateOwned() { return false; } /** * Used to signal that this mapping references a protected/isolated entity and requires * special merge/object building behaviour. * */ public boolean isCacheable() { return this.isCacheable; } /** * Used to signal that this mapping references a protected/isolated entity and requires * special merge/object building behaviour. */ public void setIsCacheable(boolean cacheable) { if (!cacheable) { throw ValidationException.operationNotSupported("setIsCacheable"); } } /** * INTERNAL: * Returns true if mapping is read only else false. */ @Override public boolean isReadOnly() { return isReadOnly; } /** * INTERNAL: * Related mapping should implement this method to return true. */ @Override public boolean isReferenceMapping() { return false; } protected boolean isRemotelyInitialized() { return isRemotelyInitialized; } /** * INTERNAL: * Related mapping should implement this method to return true. */ public boolean isStructureMapping() { return false; } /** * INTERNAL: * Related mapping should implement this method to return true. */ @Override public boolean isTransformationMapping() { return false; } /** * INTERNAL: */ public boolean isUnidirectionalOneToManyMapping() { return false; } /** * INTERNAL: * Related mapping should implement this method to return true. */ public boolean isVariableOneToOneMapping() { return false; } /** * INTERNAL: * Related mapping should implement this method to return true. */ public boolean isDirectToXMLTypeMapping() { return false; } /** * INTERNAL: * Some mappings support no attribute (transformation and multitenant primary key). */ @Override public boolean isWriteOnly() { return false; } /** * INTERNAL: * Iterate on the appropriate attribute value. */ public abstract void iterate(DescriptorIterator iterator); /** * INTERNAL: * Iterate on the attribute value. * The value holder has already been processed. */ public void iterateOnRealAttributeValue(DescriptorIterator iterator, Object realAttributeValue) { throw DescriptorException.invalidMappingOperation(this, "iterateOnRealAttributeValue"); } /** * Force instantiation of the load group. */ public void load(final Object object, AttributeItem item, final AbstractSession session, final boolean fromFetchGroup) { // Do nothing by default. } /** * Force instantiation of all indirections. */ public void loadAll(Object object, AbstractSession session, IdentityHashSet loaded) { // Do nothing by default. } /** * INTERNAL: * Merge changes from the source to the target object. */ public abstract void mergeChangesIntoObject(Object target, ChangeRecord changeRecord, Object source, MergeManager mergeManager, AbstractSession targetSession); /** * INTERNAL: * Merge changes from the source to the target object. */ public abstract void mergeIntoObject(Object target, boolean isTargetUninitialized, Object source, MergeManager mergeManager, AbstractSession targetSession); /** * 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 { throw DescriptorException.invalidDataModificationEvent(this); } /** * INTERNAL: * A subclass should implement this method if it wants different behavior. * Recurse thru the parts to delete the reference objects after the actual object is deleted. */ public void postDelete(DeleteObjectQuery query) throws DatabaseException { return; } /** * INTERNAL: * Allow for initialization of properties and validation that have dependecies no the descriptor * being initialized. */ public void postInitialize(AbstractSession session) throws DescriptorException { // Nothing by default. } /** * INTERNAL: * A subclass should implement this method if it wants different behavior. * Recurse thru the parts to insert the reference objects after the actual object is inserted. */ public void postInsert(WriteObjectQuery query) throws DatabaseException { return; } /** * INTERNAL: * A subclass should implement this method if it wants different behavior. * Recurse thru the parts to update the reference objects after the actual object is updated. */ public void postUpdate(WriteObjectQuery query) throws DatabaseException { return; } /** * INTERNAL: * A subclass should implement this method if it wants different behavior. * Recurse thru the parts to delete the reference objects before the actual object is deleted. */ public void preDelete(DeleteObjectQuery query) throws DatabaseException { return; } /** * INTERNAL: * Allow for initialization of properties and validation. */ public void preInitialize(AbstractSession session) throws DescriptorException { try { getAttributeAccessor().initializeAttributes(getDescriptor().getJavaClass()); } catch (DescriptorException exception) { exception.setMapping(this); session.getIntegrityChecker().handleError(exception); } } /** * INTERNAL: * A subclass should implement this method if it wants different behavior. * Recurse thru the parts to insert the reference objects before the actual object is inserted. */ public void preInsert(WriteObjectQuery query) throws DatabaseException { return; } /** * INTERNAL: * A subclass that supports cascade version optimistic locking should * implement this method to properly prepare the locking policy for their * mapping type. */ public void prepareCascadeLockingPolicy() { return; } /** * INTERNAL: * A subclass should implement this method if it wants different behavior. * Recurse thru the parts to update the reference objects before the actual object is updated. */ public void preUpdate(WriteObjectQuery query) throws DatabaseException { return; } /** * INTERNAL: * Extract value from the row and set the attribute to this value in the object. * return value as this value will have been converted to the appropriate type for * the object. */ public Object readFromRowIntoObject(AbstractRecord databaseRow, JoinedAttributeManager joinManager, Object targetObject, CacheKey parentCacheKey, ObjectBuildingQuery sourceQuery, AbstractSession executionSession, boolean isTargetProtected) throws DatabaseException { Object attributeValue = valueFromRow(databaseRow, joinManager, sourceQuery, parentCacheKey, executionSession, isTargetProtected, null); setAttributeValueInObject(targetObject, attributeValue); return attributeValue; } /** * INTERNAL: * Extract values directly from the result-set. * PERF: This is used for optimized object building directly from the result-set. */ public Object readFromResultSetIntoObject(ResultSet resultSet, Object targetObject, ObjectBuildingQuery query, AbstractSession session, DatabaseAccessor accessor, ResultSetMetaData metaData, int columnNumber, DatabasePlatform platform) throws SQLException { Object attributeValue = valueFromResultSet(resultSet, query, session, accessor, metaData, columnNumber, platform); setAttributeValueInObject(targetObject, attributeValue); return attributeValue; } /** * PUBLIC: * To make mapping read only. * Read-only mappings can be used if two attributes map to the same field. * Read-only mappings cannot be used for the primary key or other required fields. */ public void readOnly() { setIsReadOnly(true); } /** * PUBLIC: * The mapping can be dynamically made either readOnly or readWriteOnly. This makes mapping go back to * default mode. */ public void readWrite() { setIsReadOnly(false); } /** * INTERNAL: * Rehash any hashtables 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. */ public void rehashFieldDependancies(AbstractSession session) { // Should be overwritten by any mapping with fields. } /** * INTERNAL: * Once descriptors are serialized to the remote session. All its mappings and reference descriptors are traversed. Usually * mappings are initilaized 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 initilaized 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(); } } /** * Set the mapping to be initialized for the remote session. */ protected void remotelyInitialized() { isRemotelyInitialized = true; } /** * INTERNAL: * replace the value holders in the specified reference object(s) */ public Map replaceValueHoldersIn(Object object, RemoteSessionController controller) { // by default, do nothing return null; } /** * ADVANCED: * Set the attributeAccessor. * The attribute accessor is responsible for setting and retrieving the attribute value * from the object for this mapping. * This can be set to an implementor of AttributeAccessor if the attribute * requires advanced conversion of the mapping value, or a real attribute does not exist. */ @Override public void setAttributeAccessor(AttributeAccessor attributeAccessor) { String attributeName = getAttributeName(); this.attributeAccessor = attributeAccessor; if (attributeAccessor.getAttributeName() == null) { attributeAccessor.setAttributeName(attributeName); } this.attributeName = null; } /** * PUBLIC: * Sets the name of the attribute in the mapping. */ @Override public void setAttributeName(String attributeName) { getAttributeAccessor().setAttributeName(attributeName); // Clear the mapping attribute name until a getAttributeName() call copies the accessor attributeName this.attributeName = null; } /** * INTERNAL: * Set the value of the attribute mapped by this mapping. */ @Override public void setAttributeValueInObject(Object object, Object value) throws DescriptorException { // PERF: Direct variable access. try { this.attributeAccessor.setAttributeValueInObject(object, value); } catch (DescriptorException exception) { exception.setMapping(this); throw exception; } } /** * INTERNAL: * Set the value of the attribute mapped by this mapping, * placing it inside a value holder if necessary. */ public void setRealAttributeValueInObject(Object object, Object value) throws DescriptorException { try { this.setAttributeValueInObject(object, value); } catch (DescriptorException exception) { exception.setMapping(this); throw exception; } } /** * INTERNAL: * Set the descriptor to which this mapping belongs */ @Override public void setDescriptor(ClassDescriptor descriptor) { this.descriptor = descriptor; } /** * INTERNAL: * Set the mapping's field collection. */ @Override protected void setFields(Vector fields) { this.fields = fields; } /** * PUBLIC: * This method is invoked reflectively on the reference object to return the value of the * attribute in the object. This method sets the name of the getMethodName. */ public void setGetMethodName(String methodName) { if (methodName == null) { return; } // This is done because setting attribute name by defaults create InstanceVariableAttributeAccessor if (getAttributeAccessor() instanceof InstanceVariableAttributeAccessor) { String attributeName = this.attributeAccessor.getAttributeName(); setAttributeAccessor(new MethodAttributeAccessor()); getAttributeAccessor().setAttributeName(attributeName); } ((MethodAttributeAccessor)getAttributeAccessor()).setGetMethodName(methodName); } /** * Used to specify whether the value of this mapping may be null. * This is used when generating DDL. */ public void setIsOptional(boolean isOptional) { this.isOptional = isOptional; } /** * INTERNAL: * Set by the Object builder during initialization returns true if this mapping * is used as a primary key mapping. */ public void setIsPrimaryKeyMapping(boolean isPrimaryKeyMapping) { this.isPrimaryKeyMapping = isPrimaryKeyMapping; } /** * PUBLIC: * Set this mapping to be read only. * Read-only mappings can be used if two attributes map to the same field. * Read-only mappings cannot be used for the primary key or other required fields. */ public void setIsReadOnly(boolean aBoolean) { isReadOnly = aBoolean; } /** * ADVANCED: * Set the maps id value */ public void setMapsIdValue(String mapsIdValue) { this.mapsIdValue = mapsIdValue; } /** * INTERNAL: * Allow user defined properties. */ public void setProperties(Map properties) { this.properties = properties; } /** * ADVANCED: * Allow user defined properties. */ public void setProperty(Object property, Object value) { getProperties().put(property, value); } /** * PUBLIC: * Set the methodName used to set the value for the mapping's attribute into the object. */ public void setSetMethodName(String methodName) { if (methodName == null) { return; } // This is done because setting attribute name by defaults create InstanceVariableAttributeAccessor if (!getAttributeAccessor().isMethodAttributeAccessor()) { String attributeName = this.attributeAccessor.getAttributeName(); setAttributeAccessor(new MethodAttributeAccessor()); getAttributeAccessor().setAttributeName(attributeName); } ((MethodAttributeAccessor)getAttributeAccessor()).setSetMethodName(methodName); } /** * ADVANCED: * Set the weight of the mapping, used to sort mappings * DirectToField Mappings have a default weight of 1 while all other Mappings have a * default weight of MAXINT. Ordering of Mappings can be achieved by setting the weight of * a particular mapping to a value within the above mentioned limits. By ordering mappings * the user can control what order relationships are processed by TopLink. */ // CR 4097 public void setWeight(Integer newWeight) { this.weight = newWeight; } /** * ADVANCED: * This method is used to add an object to a collection once the changeSet is applied. * The referenceKey parameter should only be used for direct Maps. */ public void simpleAddToCollectionChangeRecord(Object referenceKey, Object changeSetToAdd, ObjectChangeSet changeSet, AbstractSession session) throws DescriptorException { throw DescriptorException.invalidMappingOperation(this, "simpleAddToCollectionChangeRecord"); } /** * ADVANCED: * This method is used to remove an object from a collection once the changeSet is applied. * The referenceKey parameter should only be used for direct Maps. */ public void simpleRemoveFromCollectionChangeRecord(Object referenceKey, Object changeSetToAdd, ObjectChangeSet changeSet, AbstractSession session) throws DescriptorException { throw DescriptorException.invalidMappingOperation(this, "simpleRemoveFromCollectionChangeRecord"); } /** * INTERNAL: * Print the mapping attribute name, this is used in error messages. */ @Override public String toString() { return getClass().getName() + "[" + getAttributeName() + "]"; } /** * INTERNAL: * Allow for subclasses to perform validation. */ public void validateAfterInitialization(AbstractSession session) throws DescriptorException { } /** * INTERNAL: * Allow for subclasses to perform validation. */ public void validateBeforeInitialization(AbstractSession session) throws DescriptorException { } /** * INTERNAL: * A subclass should extract the value from the object for the field, if it does not map the field then * it should return null. * Return the Value from the object. */ @Override public Object valueFromObject(Object anObject, DatabaseField field, AbstractSession session) { return null; } /** * INTERNAL: * A subclass should implement this method if it wants different behavior. * Returns the value for the mapping from the database row. */ public Object valueFromRow(AbstractRecord row, JoinedAttributeManager joinManager, ObjectBuildingQuery query, boolean isTargetProtected) throws DatabaseException { return valueFromRow(row, joinManager, query, null, query.getExecutionSession(), isTargetProtected, null); } /** * INTERNAL: * A subclass should implement this method if it wants different behavior. * Returns the value for the mapping from the database row. * The execution session is the session the query was executed on, * and its platform should be used for data conversion. */ public Object valueFromRow(AbstractRecord row, JoinedAttributeManager joinManager, ObjectBuildingQuery query, CacheKey cacheKey, AbstractSession session, boolean isTargetProtected, Boolean[] wasCacheUsed) throws DatabaseException { return null; } /** * INTERNAL: * Indicates whether the mapping is in SerializedObjectPolicy's sopObject. */ public boolean isInSopObject() { return this.isInSopObject == null || this.isInSopObject; } /** * INTERNAL: * Indicates whether the mapping is in SerializedObjectPolicy's sopObject and not out of it. */ public boolean isInOnlySopObject() { return this.isInSopObject != null && this.isInSopObject; } /** * INTERNAL: * Indicates whether the mapping is out of SerializedObjectPolicy's sopObject. */ public boolean isOutSopObject() { return this.isInSopObject == null || !this.isInSopObject; } /** * INTERNAL: * Indicates whether the mapping is out of SerializedObjectPolicy's sopObject and not in it. */ public boolean isOutOnlySopObject() { return this.isInSopObject != null && !this.isInSopObject; } /** * INTERNAL: * Indicates whether the mapping is both in and out of SerializedObjectPolicy's sopObject. */ public boolean isInAndOutSopObject() { return this.isInSopObject == null; } /** * INTERNAL: * Set the mapping is in SerializedObjectPolicy's sopObject. */ public void setIsInSopObject() { this.isInSopObject = Boolean.TRUE; } /** * INTERNAL: * Set the mapping is out of SerializedObjectPolicy's sopObject. */ public void setIsOutSopObject() { this.isInSopObject = Boolean.FALSE; } /** * INTERNAL: * Set the mapping is both in and out of SerializedObjectPolicy's sopObject */ public void setIsInAndOutSopObject() { this.isInSopObject = null; } /** * INTERNAL: * Indicates whether the mapping (or at least one of its nested mappings, at any nested depth) * references an entity. * To return true the mapping (or nested mapping) should be ForeignReferenceMapping with non-null and non-aggregate reference descriptor. */ public boolean hasNestedIdentityReference() { return false; } /** * INTERNAL: * Returns the value for the mapping directly from the result-set. * PERF: Used for optimized object building. */ public Object valueFromResultSet(ResultSet resultSet, ObjectBuildingQuery query, AbstractSession session, DatabaseAccessor accessor, ResultSetMetaData metaData, int columnNumber, DatabasePlatform platform) throws SQLException { throw DescriptorException.invalidMappingOperation(this, "valueFromResultSet"); } /** * INTERNAL: * To verify if the specified object has been deleted or not. */ public boolean verifyDelete(Object object, AbstractSession session) throws DatabaseException { return true; } /** * INTERNAL: * A subclass should implement this method if it wants different behavior. * Write the foreign key values from the attribute to the row. */ public void writeFromAttributeIntoRow(Object attribute, AbstractRecord row, AbstractSession session) { // Do nothing by default. } /** * INTERNAL: * A subclass should implement this method if it wants different behavior. * Write the attribute value from the object to the row. */ public void writeFromObjectIntoRow(Object object, AbstractRecord row, AbstractSession session, WriteType writeType) { // Do nothing by default. } /** * INTERNAL: * This row is built for shallow insert which happens in case of bidirectional inserts. * If mapping overrides this method it must override writeFromObjectIntoRowForUpdateAfterShallowInsert method, too. */ public void writeFromObjectIntoRowForShallowInsert(Object object, AbstractRecord row, AbstractSession session) { writeFromObjectIntoRow(object, row, session, 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. * If mapping overrides writeFromObjectIntoRowForShallowInsert method it must override this one, too. */ public void writeFromObjectIntoRowForUpdateAfterShallowInsert(Object object, AbstractRecord databaseRow, AbstractSession session, DatabaseTable table) { // Do nothing by default. } /** * 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. */ public void writeFromObjectIntoRowForUpdateBeforeShallowDelete(Object object, AbstractRecord databaseRow, AbstractSession session, DatabaseTable table) { // Do nothing by default. } /** * INTERNAL: * A subclass should implement this method if it wants different behavior. * Write the attribute value from the object to the row. */ public void writeFromObjectIntoRowWithChangeRecord(ChangeRecord changeRecord, AbstractRecord row, AbstractSession session, WriteType writeType) { // Do nothing by default. } /** * INTERNAL: * This row is built for shallow insert which happens in case of bidirectional inserts. */ public void writeFromObjectIntoRowForShallowInsertWithChangeRecord(ChangeRecord changeRecord, AbstractRecord row, AbstractSession session) { writeFromObjectIntoRowWithChangeRecord(changeRecord, row, session, WriteType.INSERT); } /** * INTERNAL: */ public void writeFromObjectIntoRowForUpdate(WriteObjectQuery query, AbstractRecord row) { writeFromObjectIntoRow(query.getObject(), row, query.getSession(), WriteType.UPDATE); } /** * INTERNAL: * A subclass should implement this method if it wants different behavior. * Write the attribute value from the object to the row. */ public void writeFromObjectIntoRowForWhereClause(ObjectLevelModifyQuery query, AbstractRecord row) { Object object; if (query.isDeleteObjectQuery()) { object = query.getObject(); } else { object = query.getBackupClone(); } writeFromObjectIntoRow(object, row, query.getSession(), WriteType.UNDEFINED); } /** * INTERNAL: * Write fields needed for insert into the template for with null values. */ public void writeInsertFieldsIntoRow(AbstractRecord databaseRow, AbstractSession session) { // Do nothing by default. } /** * INTERNAL: * Write fields needed for update into the template for with null values. * By default inserted fields are used. */ public void writeUpdateFieldsIntoRow(AbstractRecord databaseRow, AbstractSession session) { writeInsertFieldsIntoRow(databaseRow, session); } /** * INTERNAL: * Either create a new change record or update the change record with the new value. * This is used by attribute change tracking. */ public void updateChangeRecord(Object clone, Object newValue, Object oldValue, ObjectChangeSet objectChangeSet, UnitOfWorkImpl uow) throws DescriptorException { throw DescriptorException.invalidMappingOperation(this, "updateChangeRecord"); } /** * 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(org.eclipse.persistence.descriptors.changetracking.CollectionChangeEvent event, ObjectChangeSet objectChangeSet, UnitOfWorkImpl uow) throws DescriptorException { throw DescriptorException.invalidMappingOperation(this, "updateCollectionChangeRecord"); } /** * INTERNAL: * Set the change listener if required. * This is required for collections and aggregates or other change tracked mutable objects. * This is used for resuming or flushing units of work. */ public void setChangeListener(Object clone, PropertyChangeListener listener, UnitOfWorkImpl uow) { // Nothing by default. } /** * ADVANCED: * Used to indicate the mapping references a JPA ID or MapsId attribute * for the CMP3Policy and JPA Id classes (as well as Embeddable Id classes). * This is different from isPrimaryKeyMapping, as an ID mapping is user * specified and can be read only, as long as another writable mapping for * the field exists. */ public void setDerivesId(boolean derivesId) { this.derivesId = derivesId; } /** * ADVANCED: * Used to indicate the mapping references a JPA ID or MapsId attribute * for the CMP3Policy and JPA Id classes (as well as Embeddable Id classes). * This is different from isPrimaryKeyMapping, as an ID mapping is user * specified and can be read only, as long as another writable mapping for * the field exists. */ public void setDerivedIdMapping(DatabaseMapping derivedIdMapping) { this.derivedIdMapping = derivedIdMapping; } /** * INTERNAL: * Directly build a change record without comparison */ public ChangeRecord buildChangeRecord(Object newValue, ObjectChangeSet owner, AbstractSession session) throws DescriptorException { throw DescriptorException.invalidMappingOperation(this, "buildChangeRecord"); } /** * INTERNAL: * Overridden by mappings that require additional processing of the change record after the record has been calculated. */ public void postCalculateChanges(org.eclipse.persistence.sessions.changesets.ChangeRecord changeRecord, UnitOfWorkImpl uow) { } /** * INTERNAL: * Overridden by mappings that require objects to be deleted contribute to change set creation. */ public void postCalculateChangesOnDeleted(Object deletedObject, UnitOfWorkChangeSet uowChangeSet, UnitOfWorkImpl uow) { } /** * INTERNAL: * Overridden by mappings that require objects to be deleted contribute to change set creation. */ public void recordPrivateOwnedRemovals(Object object, UnitOfWorkImpl uow) { } }





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