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This is the core library for Active Objects. It is generic and can be embedded in any environment. As such it is generic and won't contain all connection pooling, etc.

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/*
 * Copyright 2007 Daniel Spiewak
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 *      http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */
package net.java.ao;

import com.atlassian.plugin.util.PluginKeyStack;
import com.atlassian.util.profiling.Ticker;
import com.google.common.base.Throwables;
import com.google.common.cache.CacheBuilder;
import com.google.common.cache.CacheLoader;
import com.google.common.cache.LoadingCache;
import com.google.common.util.concurrent.ExecutionError;
import com.google.common.util.concurrent.UncheckedExecutionException;
import net.java.ao.db.MySQLDatabaseProvider;
import net.java.ao.db.PostgreSQLDatabaseProvider;
import net.java.ao.schema.CachingNameConverters;
import net.java.ao.schema.FieldNameConverter;
import net.java.ao.schema.NameConverters;
import net.java.ao.schema.SchemaGenerator;
import net.java.ao.schema.TableNameConverter;
import net.java.ao.schema.info.EntityInfo;
import net.java.ao.schema.info.EntityInfoResolver;
import net.java.ao.schema.info.FieldInfo;
import net.java.ao.types.LogicalType;
import net.java.ao.types.TypeInfo;
import net.java.ao.util.StringUtils;
import org.apache.commons.lang3.Validate;
import org.slf4j.Logger;
import org.slf4j.LoggerFactory;

import java.lang.reflect.Array;
import java.lang.reflect.Proxy;
import java.sql.Connection;
import java.sql.PreparedStatement;
import java.sql.ResultSet;
import java.sql.ResultSetMetaData;
import java.sql.SQLException;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.Collection;
import java.util.HashMap;
import java.util.HashSet;
import java.util.LinkedList;
import java.util.List;
import java.util.Map;
import java.util.Set;
import java.util.concurrent.ExecutionException;
import java.util.concurrent.locks.ReadWriteLock;
import java.util.concurrent.locks.ReentrantReadWriteLock;
import java.util.stream.Collectors;
import java.util.stream.StreamSupport;

import static com.atlassian.util.profiling.Metrics.metric;
import static java.lang.String.format;
import static java.util.Objects.requireNonNull;
import static java.util.stream.Collectors.joining;
import static java.util.stream.Collectors.toSet;
import static net.java.ao.Common.getValueFieldsNames;
import static net.java.ao.Common.preloadValue;
import static net.java.ao.sql.SqlUtils.closeQuietly;
import static org.apache.commons.lang3.ArrayUtils.contains;

/**
 * 

The root control class for the entire ActiveObjects API. EntityManager is the source of all {@link * RawEntity} objects, as well as the dispatch layer between the entities, the pluggable table name converters, and the * database abstraction layers. This is the entry point for any use of the API.

* *

EntityManager is designed to be used in an instance fashion with each instance corresponding to a * single database. Thus, rather than a singleton instance or a static factory method, EntityManager does * have a proper constructor. Any static instance management is left up to the developer using the API.

* * @author Daniel Spiewak */ public class EntityManager { private static final String DB_AO_ENTITY_MANAGER_TIMER_NAME = "db.ao.entityManager"; private static final String ENTITY_TYPE_TAG = "entityType"; private static final Logger log = LoggerFactory.getLogger(EntityManager.class); private final DatabaseProvider provider; private final EntityManagerConfiguration configuration; private final SchemaConfiguration schemaConfiguration; private final NameConverters nameConverters; private final EntityInfoResolver entityInfoResolver; private PolymorphicTypeMapper typeMapper; private final ReadWriteLock typeMapperLock = new ReentrantReadWriteLock(true); private final LoadingCache>, ValueGenerator> valGenCache; /** * Creates a new instance of EntityManager using the specified {@link DatabaseProvider}. * * @param provider the {@link DatabaseProvider} to use in all database operations. * @param configuration the configuration for this entity manager */ public EntityManager(DatabaseProvider provider, EntityManagerConfiguration configuration) { this.provider = requireNonNull(provider, "provider can't be null"); this.configuration = requireNonNull(configuration); valGenCache = CacheBuilder.newBuilder().build(new CacheLoader>, ValueGenerator>() { @Override public ValueGenerator load(Class> generatorClass) throws Exception { return generatorClass.newInstance(); } }); // TODO: move caching out of there! nameConverters = new CachingNameConverters(configuration.getNameConverters()); schemaConfiguration = requireNonNull(configuration.getSchemaConfiguration(), "schema configuration can't be null"); typeMapper = new DefaultPolymorphicTypeMapper(new HashMap>, String>()); entityInfoResolver = requireNonNull(configuration.getEntityInfoResolverFactory().create(nameConverters, provider.getTypeManager()), "entityInfoResolver"); } /** * Convenience method to create the schema for the specified entities using the current settings (table/field name * converter and database provider). * * @param entities the "list" of entity classes to consider for migration. * @see SchemaGenerator#migrate(DatabaseProvider, SchemaConfiguration, NameConverters, boolean, Class[]) */ public void migrate(Class>... entities) throws SQLException { SchemaGenerator.migrate(provider, schemaConfiguration, nameConverters, false, entities); } /** * Convenience method to create the schema for the specified entities using the current settings (table/field name * converter and database provider). Note that if the given entities do not include the full set of entities, or * those entities have removed any fields, then the corresponding tables or columns will be dropped, and any data * they contained will be lost. Use this at your own risk. * * @param entities the "list" of entity classes to consider for migration. * @see SchemaGenerator#migrate(DatabaseProvider, SchemaConfiguration, NameConverters, boolean, Class[]) */ public void migrateDestructively(Class>... entities) throws SQLException { SchemaGenerator.migrate(provider, schemaConfiguration, nameConverters, true, entities); } /** * @deprecated since 0.23. EntityManager now no longer caches entities. * use {@link #flush(RawEntity[])} to flush values for individual entities */ @Deprecated public void flushAll() { // no-op } /** * @deprecated since 0.23. EntityManager now no longer caches entities. * use {@link #flush(RawEntity[])} to flush values for individual entities */ @Deprecated public void flushEntityCache() { // no-op } /** * @deprecated since 0.25. Entities and values now no longer cached. */ @Deprecated public void flush(RawEntity... entities) { // no-op } /** *

Returns an array of entities of the specified type corresponding to the * varargs primary keys. If an in-memory reference already exists to a corresponding * entity (of the specified type and key), it is returned rather than creating * a new instance.

* *

If the entity is known to exist in the database, then no checks are performed * and the method returns extremely quickly. However, for any key which has not * already been verified, a query to the database is performed to determine whether * or not the entity exists. If the entity does not exist, then null * is returned.

* * @param type The type of the entities to retrieve. * @param keys The primary keys corresponding to the entities to retrieve. All * keys must be typed according to the generic type parameter of the entity's * {@link RawEntity} inheritence (if inheriting from {@link Entity}, this is Integer * or int). Thus, the keys array is type-checked at compile * time. * @return An array of entities of the given type corresponding with the specified * primary keys. Any entities which are non-existent will correspond to a null * value in the resulting array. */ public , K> T[] get(final Class type, K... keys) throws SQLException { try (Ticker ignored = metric(DB_AO_ENTITY_MANAGER_TIMER_NAME+".get") .tag(ENTITY_TYPE_TAG, type.getCanonicalName()) .withAnalytics() .invokerPluginKey(PluginKeyStack.getFirstPluginKey()) .startTimer()) { EntityInfo entityInfo = resolveEntityInfo(type); final String primaryKeyField = entityInfo.getPrimaryKey().getName(); return get(type, findByPrimaryKey(type, primaryKeyField), keys); } } private , K> Function findByPrimaryKey(final Class type, final String primaryKeyField) { return new Function() { @Override public T invoke(K k) throws SQLException { final T[] ts = find(type, primaryKeyField + " = ?", k); if (ts.length == 1) { return ts[0]; } else if (ts.length == 0) { return null; } else { throw new ActiveObjectsException("Found more that one object of type '" + type.getName() + "' for key '" + k + "'"); } } }; } protected , K> T[] peer(final EntityInfo entityInfo, K... keys) throws SQLException { return get(entityInfo.getEntityType(), new Function() { public T invoke(K key) { return getAndInstantiate(entityInfo, key); } }, keys); } private , K> T[] get(Class type, Function create, K... keys) throws SQLException { //noinspection unchecked T[] back = (T[]) Array.newInstance(type, keys.length); int index = 0; for (K key : keys) { back[index++] = create.invoke(key); } return back; } /** * Creates a new instance of the entity of the specified type corresponding to the given primary key. This is used * by {@link #get(Class, Object[])}} to create the entity. * * @param entityInfo The type of the entity to create. * @param key The primary key corresponding to the entity instance required. * @return An entity instance of the specified type and primary key. */ protected , K> T getAndInstantiate(EntityInfo entityInfo, K key) { Class type = entityInfo.getEntityType(); EntityProxy proxy = new EntityProxy(this, entityInfo, key); T entity = type.cast(Proxy.newProxyInstance(type.getClassLoader(), new Class[]{type, EntityProxyAccessor.class}, proxy)); return entity; } /** * Cleverly overloaded method to return a single entity of the specified type rather than an array in the case where * only one ID is passed. This method meerly delegates the call to the overloaded get method and * functions as syntactical sugar. * * @param type The type of the entity instance to retrieve. * @param key The primary key corresponding to the entity to be retrieved. * @return An entity instance of the given type corresponding to the specified primary key, or null if * the entity does not exist in the database. * @see #get(Class, Object[]) */ public , K> T get(Class type, K key) throws SQLException { return get(type, toArray(key))[0]; } protected , K> T peer(EntityInfo entityInfo, K key) throws SQLException { if (null == key) { return null; } return peer(entityInfo, toArray(key))[0]; } @SuppressWarnings("unchecked") private static K[] toArray(K key) { return (K[]) new Object[]{key}; } /** *

Creates a new entity of the specified type with the optionally specified * initial parameters. This method actually inserts a row into the table represented * by the entity type and returns the entity instance which corresponds to that * row.

* *

The {@link DBParam} object parameters are designed to allow the creation * of entities which have non-null fields which have no defalut or auto-generated * value. Insertion of a row without such field values would of course fail, * thus the need for db params. The db params can also be used to set * the values for any field in the row, leading to more compact code under * certain circumstances.

* *

Unless within a transaction, this method will commit to the database * immediately and exactly once per call. Thus, care should be taken in * the creation of large numbers of entities. There doesn't seem to be a more * efficient way to create large numbers of entities, however one should still * be aware of the performance implications.

* *

This method delegates the action INSERT action to * {@link DatabaseProvider#insertReturningKey}. * This is necessary because not all databases support the JDBC RETURN_GENERATED_KEYS * constant (e.g. PostgreSQL and HSQLDB). Thus, the database provider itself is * responsible for handling INSERTion and retrieval of the correct primary key * value.

* * @param type The type of the entity to INSERT. * @param params An optional varargs array of initial values for the fields in the row. These * values will be passed to the database within the INSERT statement. * @return The new entity instance corresponding to the INSERTed row. * @see net.java.ao.DBParam */ public , K> T create(Class type, DBParam... params) throws SQLException { try (Ticker ignored = metric(DB_AO_ENTITY_MANAGER_TIMER_NAME+".create") .tag(ENTITY_TYPE_TAG, type.getCanonicalName()) .withAnalytics() .invokerPluginKey(PluginKeyStack.getFirstPluginKey()) .startTimer()) { T back = null; EntityInfo entityInfo = resolveEntityInfo(type); final String table = entityInfo.getName(); Set listParams = new HashSet<>(); listParams.addAll(Arrays.asList(params)); final Collection fieldsInfoWithGenerators = entityInfo.getFields() .stream() .filter(FieldInfo.HAS_GENERATOR) .collect(toSet()); for (FieldInfo fieldInfo : fieldsInfoWithGenerators) { ValueGenerator generator; try { generator = valGenCache.get(fieldInfo.getGeneratorType()); } catch (ExecutionException e) { throw Throwables.propagate(e.getCause()); } catch (UncheckedExecutionException e) { throw Throwables.propagate(e.getCause()); } catch (ExecutionError e) { throw Throwables.propagate(e.getCause()); } listParams.add(new DBParam(fieldInfo.getName(), generator.generateValue(this))); } final Set requiredFields = entityInfo.getFields() .stream() .filter(FieldInfo.IS_REQUIRED) .collect(toSet()); for (DBParam param : listParams) { FieldInfo field = entityInfo.getField(param.getField()); requireNonNull(field, format("Entity %s does not have field %s", type.getName(), param.getField())); if (field.isPrimary()) { //noinspection unchecked Common.validatePrimaryKey(field, param.getValue()); } else if (!field.isNullable()) { Validate.isTrue(param.getValue() != null, "Cannot set non-null field %s to null", param.getField()); if (param.getValue() instanceof String) { Validate.isTrue(!StringUtils.isBlank((String) param.getValue()), "Cannot set non-null String field %s to ''", param.getField()); } } requiredFields.remove(field); final TypeInfo dbType = field.getTypeInfo(); if (dbType != null && param.getValue() != null) { dbType.getLogicalType().validate(param.getValue()); } } if (!requiredFields.isEmpty()) { final String requiredFieldsAsString = requiredFields .stream() .map(Object::toString) .collect(joining(", ")); throw new IllegalArgumentException("The follow required fields were not set when trying to create entity '" + type.getName() + "', those fields are: " + requiredFieldsAsString); } Connection connection = null; try { connection = provider.getConnection(); back = peer(entityInfo, provider.insertReturningKey(this, connection, type, entityInfo.getPrimaryKey().getJavaType(), entityInfo.getPrimaryKey().getName(), entityInfo.getPrimaryKey().hasAutoIncrement(), table, listParams.toArray(new DBParam[listParams.size()]))); } finally { closeQuietly(connection); } back.init(); return back; } } /** * Creates and INSERTs a new entity of the specified type with the given map of parameters. This method merely * delegates to the {@link #create(Class, DBParam...)} method. The idea behind having a separate convenience method * taking a map is in circumstances with large numbers of parameters or for people familiar with the anonymous inner * class constructor syntax who might be more comfortable with creating a map than with passing a number of * objects. * * @param type The type of the entity to INSERT. * @param params A map of parameters to pass to the INSERT. * @return The new entity instance corresponding to the INSERTed row. * @see #create(Class, DBParam...) */ public , K> T create(Class type, Map params) throws SQLException { DBParam[] arrParams = new DBParam[params.size()]; int i = 0; for (String key : params.keySet()) { arrParams[i++] = new DBParam(key, params.get(key)); } return create(type, arrParams); } /** * Creates and INSERTs a batch of new entities represented by {@code rows} of the given type. Each entity * corresponds to a single row. * * @param type The type of the entity to INSERT. * @param rows A list of rows to be INSERTed. A row is represented as a map from column name to its value. * All rows must have the same columns. */ public , K> void create(Class type, List> rows) throws SQLException { try (Ticker ignored = metric(DB_AO_ENTITY_MANAGER_TIMER_NAME+".create") .tag(ENTITY_TYPE_TAG, type.getCanonicalName()) .withAnalytics() .invokerPluginKey(PluginKeyStack.getFirstPluginKey()) .startTimer()) { EntityInfo entityInfo = resolveEntityInfo(type); final String table = entityInfo.getName(); List> injectedRows = injectAutoGeneratedFields(rows, entityInfo); validateRequiredFields(injectedRows, entityInfo); try (Connection connection = provider.getConnection()) { provider.insertBatch(this, connection, type, entityInfo.getPrimaryKey().getJavaType(), entityInfo.getPrimaryKey().getName(), entityInfo.getPrimaryKey().hasAutoIncrement(), table, injectedRows); } } } private , K> void validateRequiredFields(List> rows, EntityInfo entityInfo) { for (Map row : rows) { Set requiredFields = entityInfo.getFields() .stream() .filter(FieldInfo.IS_REQUIRED) .collect(toSet()); for (Map.Entry entry : row.entrySet()) { FieldInfo field = entityInfo.getField(entry.getKey()); requireNonNull(field, format("Entity %s does not have field %s", entityInfo.getEntityType().getName(), entry.getKey())); if (field.isPrimary()) { //noinspection unchecked Common.validatePrimaryKey(field, entry.getValue()); } else if (!field.isNullable()) { requireNonNull(entry.getValue(), format("Cannot set non-null field %s to null", entry.getKey())); if (entry.getValue() instanceof String) { Validate.isTrue(!StringUtils.isBlank((String) entry.getValue()), "Cannot set non-null String field %s to blank", entry.getKey()); } } requiredFields.remove(field); final TypeInfo dbType = field.getTypeInfo(); if (dbType != null && entry.getValue() != null) { dbType.getLogicalType().validate(entry.getValue()); } } if (!requiredFields.isEmpty()) { throw new IllegalArgumentException("The following required fields were not set when trying to create entity '" + entityInfo.getEntityType().getName() + "': " + requiredFields .stream() .map(Object::toString) .collect(joining(", "))); } } } private , K> List> injectAutoGeneratedFields(List> rows, EntityInfo entityInfo) { List autoGeneratedFields = entityInfo.getFields().stream() .filter(FieldInfo.HAS_GENERATOR::apply) .collect(Collectors.toList()); List> result = rows.stream() .map(HashMap::new) .collect(Collectors.toList()); for (FieldInfo fieldInfo : autoGeneratedFields) { ValueGenerator generator; try { generator = valGenCache.get(fieldInfo.getGeneratorType()); } catch (ExecutionException | UncheckedExecutionException | ExecutionError e) { throw Throwables.propagate(e.getCause()); } result.forEach(row -> row.put(fieldInfo.getName(), generator.generateValue(this))); } return result; } /** *

Deletes the specified entities from the database. DELETE statements are called on the rows in the * corresponding tables. The entity instances themselves are not invalidated, but it doesn't even make sense to * continue using the instance without a row with which it is paired.

* *

This method does attempt to group the DELETE statements on a per-type basis. Thus, if you pass 5 instances of * EntityA and two instances of EntityB, the following SQL prepared statements will be * invoked:

* *
DELETE FROM entityA WHERE id IN (?,?,?,?,?);
     * DELETE FROM entityB WHERE id IN (?,?);
* *

Thus, this method scales very well for large numbers of entities grouped into types. However, the execution * time increases linearly for each entity of unique type.

* * @param entities A varargs array of entities to delete. Method returns immediately if length == 0. */ @SuppressWarnings("unchecked") public void delete(RawEntity... entities) throws SQLException { if (entities.length == 0) { return; } Map>, List>> organizedEntities = new HashMap>, List>>(); for (RawEntity entity : entities) { verify(entity); Class> type = getProxyForEntity(entity).getType(); if (!organizedEntities.containsKey(type)) { organizedEntities.put(type, new LinkedList>()); } organizedEntities.get(type).add(entity); } Connection conn = null; PreparedStatement stmt = null; try { conn = provider.getConnection(); for (Class type : organizedEntities.keySet()) { try (Ticker ignored = metric(DB_AO_ENTITY_MANAGER_TIMER_NAME+".delete") .tag(ENTITY_TYPE_TAG, type.getCanonicalName()) .withAnalytics() .invokerPluginKey(PluginKeyStack.getFirstPluginKey()) .startTimer()) { EntityInfo entityInfo = resolveEntityInfo(type); List> entityList = organizedEntities.get(type); StringBuilder sql = new StringBuilder("DELETE FROM "); sql.append(provider.withSchema(entityInfo.getName())); sql.append(" WHERE ").append(provider.processID(entityInfo.getPrimaryKey().getName())).append(" IN (?"); for (int i = 1; i < entityList.size(); i++) { sql.append(",?"); } sql.append(')'); stmt = provider.preparedStatement(conn, sql); int index = 1; for (RawEntity entity : entityList) { TypeInfo typeInfo = entityInfo.getPrimaryKey().getTypeInfo(); typeInfo.getLogicalType().putToDatabase(this, stmt, index++, Common.getPrimaryKeyValue(entity), typeInfo.getJdbcWriteType()); } stmt.executeUpdate(); } } } finally { closeQuietly(stmt); closeQuietly(conn); } } /** *

Deletes rows from the table corresponding to {@code type}. In contrast to {@link #delete(RawEntity[])}, this * method allows you to delete rows without creating entities for them first.

* *

Example:

* *
manager.deleteWithSQL(Person.class, "name = ?", "Charlie")
* *

The SQL in {@code criteria} is not parsed or modified in any way by ActiveObjects, and is simply appended to * the DELETE statement in a WHERE clause. The above example would cause an SQL statement similar to the following * to be executed:

* *
DELETE FROM people WHERE name = 'Charlie';
* *

If {@code criteria} is {@code null}, this method deletes all rows from the table corresponding to {@code * type}.

* *

This method does not attempt to determine the set of entities affected by the statement.

* * @param type The entity type corresponding to the table to delete from. * @param criteria An optional SQL fragment specifying which rows to delete. * @param parameters A varargs array of parameters to be passed to the executed prepared statement. The length of * this array must match the number of parameters (denoted by the '?' char) in {@code criteria}. * @return The number of rows deleted from the table. * @see #delete(RawEntity...) * @see #find(Class, String, Object...) * @see #findWithSQL(Class, String, String, Object...) */ public int deleteWithSQL(Class> type, String criteria, Object... parameters) throws SQLException { try (Ticker ignored = metric(DB_AO_ENTITY_MANAGER_TIMER_NAME+".deleteWithSQL") .tag(ENTITY_TYPE_TAG, type.getCanonicalName()) .withAnalytics() .invokerPluginKey(PluginKeyStack.getFirstPluginKey()) .startTimer()) { int rowCount = 0; StringBuilder sql = new StringBuilder("DELETE FROM "); sql.append(provider.withSchema(nameConverters.getTableNameConverter().getName(type))); if (criteria != null) { sql.append(" WHERE "); sql.append(provider.processWhereClause(criteria)); } final Connection connection = provider.getConnection(); try { final PreparedStatement stmt = provider.preparedStatement(connection, sql); try { putStatementParameters(stmt, parameters); rowCount = stmt.executeUpdate(); } finally { stmt.close(); } } finally { connection.close(); } return rowCount; } } /** * Returns all entities of the given type. This actually peers the call to the {@link #find(Class, Query)} method. * * @param type The type of entity to retrieve. * @return An array of all entities which correspond to the given type. */ public , K> T[] find(Class type) throws SQLException { return find(type, Query.select()); } /** *

Convenience method to select all entities of the given type with the specified, parameterized criteria. The * criteria String specified is appended to the SQL prepared statement immediately following the * WHERE.

* *

Example:

* *
manager.find(Person.class, "name LIKE ? OR age > ?", "Joe", 9);
* *

This actually delegates the call to the {@link #find(Class, Query)} method, properly parameterizing the {@link * Query} object.

* * @param type The type of the entities to retrieve. * @param criteria A parameterized WHERE statement used to determine the results. * @param parameters A varargs array of parameters to be passed to the executed prepared statement. The length of * this array must match the number of parameters (denoted by the '?' char) in the criteria. * @return An array of entities of the given type which match the specified criteria. */ public , K> T[] find(Class type, String criteria, Object... parameters) throws SQLException { return find(type, Query.select().where(criteria, parameters)); } /** *

Convenience method to select a single entity of the given type with the specified, parameterized criteria. The * criteria String specified is appended to the SQL prepared statement immediately following the * WHERE.

* *

Example:

* *
manager.findSingleEntity(Person.class, "name LIKE ? OR age > ?", "Joe", 9);
* *

This actually delegates the call to the {@link #find(Class, String, Object...)} method, properly * parameterizing the {@link Object} object.

* * @param type The type of the entities to retrieve. * @param criteria A parameterized WHERE statement used to determine the results. * @param parameters A varargs array of parameters to be passed to the executed prepared statement. The length of * this array must match the number of parameters (denoted by the '?' char) in the criteria. * @return A single entity of the given type which match the specified criteria or null if none returned */ public , K> T findSingleEntity(Class type, String criteria, Object... parameters) throws SQLException { T[] entities = find(type, criteria, parameters); if (entities.length < 1) { return null; } else if (entities.length > 1) { throw new IllegalStateException("Found more than one entities of type '" + type.getSimpleName() + "' that matched the criteria '" + criteria + "' and parameters '" + parameters.toString() + "'."); } return entities[0]; } /** *

Selects all entities matching the given type and {@link Query}. By default, the entities will be created * based on the values within the primary key field for the specified type (this is usually the desired * behavior).

* *

Example:

* *
manager.find(Person.class, Query.select().where("name LIKE ? OR age > ?", "Joe", 9).limit(10));
* *

This method delegates the call to {@link #find(Class, String, Query)}, passing the primary key field for the * given type as the String parameter.

* *

Note that in the case of calling this function with a {@link net.java.ao.Query} with select fields, the * first field will be passed to {@link #find(Class, String, Query)}. If this is not the intention, a direct * call to {@link #find(Class, String, Query)} should be made instead, with the primary key field specified * and present in the select fields.

* * @param type The type of the entities to retrieve. * @param query The {@link Query} instance to be used to determine the results. * @return An array of entities of the given type which match the specified query. */ public , K> T[] find(Class type, Query query) throws SQLException { EntityInfo entityInfo = resolveEntityInfo(type); query.resolvePrimaryKey(entityInfo.getPrimaryKey()); String selectField = entityInfo.getPrimaryKey().getName(); final List queryFields = StreamSupport .stream(query.getFields().spliterator(), false) .collect(Collectors.toList()); if (queryFields.size() == 1) { selectField = queryFields.get(0); } return find(type, selectField, query); } /** *

Selects all entities of the specified type which match the given Query. This method creates a * PreparedStatement using the Query instance specified against the table represented by * the given type. This query is then executed (with the parameters specified in the query). The method then * iterates through the result set and extracts the specified field, mapping an entity of the given type to each * row. This array of entities is returned.

* * @param type The type of the entities to retrieve. * @param field The field value to use in the creation of the entities. This is usually the primary key field of * the corresponding table. * @param query The {@link Query} instance to use in determining the results. * @return An array of entities of the given type which match the specified query. */ public , K> T[] find(Class type, String field, Query query) throws SQLException { try (Ticker ignored = metric(DB_AO_ENTITY_MANAGER_TIMER_NAME+".find") .tag(ENTITY_TYPE_TAG, type.getCanonicalName()) .withAnalytics() .invokerPluginKey(PluginKeyStack.getFirstPluginKey()) .startTimer()) { List back = new ArrayList(); EntityInfo entityInfo = resolveEntityInfo(type); query.resolvePrimaryKey(entityInfo.getPrimaryKey()); final Preload preloadAnnotation = type.getAnnotation(Preload.class); final Set selectedFields; if (preloadAnnotation == null || contains(preloadAnnotation.value(), Preload.ALL)) { // select all fields from the table - no preload is specified or the user has specified all selectedFields = getValueFieldsNames(entityInfo, nameConverters.getFieldNameConverter()); } else { // select user's selection, as well as any specific preloads selectedFields = new HashSet(preloadValue(preloadAnnotation, nameConverters.getFieldNameConverter())); for (String existingField : query.getFields()) { selectedFields.add(existingField); } } query.setFields(selectedFields.toArray(new String[selectedFields.size()])); Connection conn = null; PreparedStatement stmt = null; ResultSet res = null; try { conn = provider.getConnection(); final String sql = query.toSQL(entityInfo, provider, getTableNameConverter(), false); stmt = provider.preparedStatement(conn, sql, ResultSet.TYPE_SCROLL_INSENSITIVE, ResultSet.CONCUR_READ_ONLY); provider.setQueryStatementProperties(stmt, query); query.setParameters(this, stmt); res = stmt.executeQuery(); provider.setQueryResultSetProperties(res, query); final TypeInfo fieldType = entityInfo.getField(field).getTypeInfo(); final Class fieldClassType = entityInfo.getField(field).getJavaType(); final String[] canonicalFields = query.getCanonicalFields(entityInfo); while (res.next()) { final T entity = peer(entityInfo, fieldType.getLogicalType().pullFromDatabase(this, res, fieldClassType, field)); final Map values = new HashMap(); for (String name : canonicalFields) { final FieldInfo fieldInfo = entityInfo.getField(name); final TypeInfo typeInfo = fieldInfo.getTypeInfo(); final LogicalType logicalType = typeInfo.getLogicalType(); values.put(name, logicalType.pullFromDatabase(this, res, fieldInfo.getJavaType(), name)); } if (!values.isEmpty()) { final EntityProxy proxy = getProxyForEntity(entity); proxy.updateValues(values); } back.add(entity); } } finally { closeQuietly(res, stmt, conn); } return back.toArray((T[]) Array.newInstance(type, back.size())); } } /** *

Executes the specified SQL and extracts the given key field, wrapping each row into a instance of the * specified type. The SQL itself is executed as a {@link PreparedStatement} with the given parameters.

* *

Example:

* *
manager.findWithSQL(Person.class, "personID", "SELECT personID FROM chairs WHERE position < ? LIMIT ?",
     * 10,
     * 5);
* *

The SQL is not parsed or modified in any way by ActiveObjects. As such, it is possible to execute * database-specific queries using this method without realizing it. For example, the above query will not run on * MS SQL Server or Oracle, due to the lack of a LIMIT clause in their SQL implementation. As such, be extremely * careful about what SQL is executed using this method, or else be conscious of the fact that you may be locking * yourself to a specific DBMS.

* * @param type The type of the entities to retrieve. * @param keyField The field value to use in the creation of the entities. This is usually the primary key field of * the corresponding table. * @param sql The SQL statement to execute. * @param parameters A varargs array of parameters to be passed to the executed prepared statement. The length of * this array must match the number of parameters (denoted by the '?' char) in the criteria. * @return An array of entities of the given type which match the specified query. */ @SuppressWarnings("unchecked") public , K> T[] findWithSQL(Class type, String keyField, String sql, Object... parameters) throws SQLException { List back = new ArrayList(); EntityInfo entityInfo = resolveEntityInfo(type); Connection connection = null; PreparedStatement stmt = null; ResultSet res = null; try { connection = provider.getConnection(); stmt = provider.preparedStatement(connection, sql); putStatementParameters(stmt, parameters); res = stmt.executeQuery(); while (res.next()) { back.add(peer(entityInfo, entityInfo.getPrimaryKey().getTypeInfo().getLogicalType().pullFromDatabase(this, res, (Class) type, keyField))); } } finally { closeQuietly(res); closeQuietly(stmt); closeQuietly(connection); } return back.toArray((T[]) Array.newInstance(type, back.size())); } /** *

Optimised read for large datasets. This method will stream all rows for the given type to the given * callback.

* *

Please see {@link #stream(Class, Query, EntityStreamCallback)} for details / limitations. * * @param type The type of the entities to retrieve. * @param streamCallback The receiver of the data, will be passed one entity per returned row */ public , K> void stream(Class type, EntityStreamCallback streamCallback) throws SQLException { final EntityInfo entityInfo = resolveEntityInfo(type); final Set valueFields = getValueFieldsNames(entityInfo, nameConverters.getFieldNameConverter()); final Query query = Query.select(); query.setFields(valueFields.toArray(new String[valueFields.size()])); stream(type, query, streamCallback); } /** *

Selects all entities of the given type and feeds them to the callback, one by one. The entities are slim, * read-only representations of the data. They only supports getters or designated {@link Accessor} * methods. Calling setters * or

save
will * result in an exception. Other method calls will be ignored. The proxies do not support lazy-loading of related * entities.

* *

Only the fields specified in the Query are loaded. Since lazy loading is not supported, calls to unspecified * getters will return null (or AO's defaults in case of primitives)

* *

This call is optimised for efficient read operations on large datasets. For best memory usage, do not buffer * the entities passed to the callback but process and discard them directly.

* *

Unlike regular Entities, the read only implementations do not support flushing/refreshing. The data is a * snapshot view at the time of query.

* * @param type The type of the entities to retrieve. * @param query * @param streamCallback The receiver of the data, will be passed one entity per returned row */ public , K> void stream(Class type, Query query, EntityStreamCallback streamCallback) throws SQLException { try (Ticker ignored = metric(DB_AO_ENTITY_MANAGER_TIMER_NAME+".stream") .tag(ENTITY_TYPE_TAG, type.getCanonicalName()) .withAnalytics() .invokerPluginKey(PluginKeyStack.getFirstPluginKey()) .startTimer()) { EntityInfo entityInfo = resolveEntityInfo(type); query.resolvePrimaryKey(entityInfo.getPrimaryKey()); final String[] canonicalFields = query.getCanonicalFields(entityInfo); // Execute the query Connection conn = null; PreparedStatement stmt = null; ResultSet res = null; try { conn = provider.getConnection(); final String sql = query.toSQL(entityInfo, provider, getTableNameConverter(), false); stmt = provider.preparedStatement(conn, sql, ResultSet.TYPE_SCROLL_INSENSITIVE, ResultSet.CONCUR_READ_ONLY); provider.setQueryStatementProperties(stmt, query); query.setParameters(this, stmt); res = stmt.executeQuery(); provider.setQueryResultSetProperties(res, query); ProxyCreationHandler proxyCreationHandler = null; while (res.next()) { if (proxyCreationHandler == null) { proxyCreationHandler = returnCreationProxyHandler(entityInfo, res); } ReadOnlyEntityProxy proxy = proxyCreationHandler.create(entityInfo, res); T entity = castFromReadOnlyProxyToEntity(type, proxy); // transfer the values from the result set into the local proxy value store. We're not caching the proxy itself anywhere, since // it's designated as a read-only snapshot view of the data and thus doesn't need flushing. for (String fieldName : canonicalFields) { proxy.addValue(fieldName, res); } // forward the proxy to the callback for the client to consume streamCallback.onRowRead(entity); } } finally { closeQuietly(res, stmt, conn); } } } private , K> T castFromReadOnlyProxyToEntity(Class entityClass, ReadOnlyEntityProxy proxy) { return entityClass.cast(Proxy.newProxyInstance(entityClass.getClassLoader(), new Class[]{entityClass}, proxy)); } private , K> boolean resourceContainsIdColumn(EntityInfo entityInfo, ResultSet res) throws SQLException { ResultSetMetaData resultSetMetaData = res.getMetaData(); for (int columnNumber = 1; columnNumber <= resultSetMetaData.getColumnCount(); columnNumber++) { if (resultSetMetaData.getColumnName(columnNumber) .equals(entityInfo.getPrimaryKey().getName())) { return true; } } return false; } /* * This method returns method which handles creation of proxy. * It is done once so if we can't find id column we will just ignore it every time. */ private , K> ProxyCreationHandler returnCreationProxyHandler(EntityInfo entityInfo, ResultSet res) throws SQLException { if (resourceContainsIdColumn(entityInfo, res)) { return (_entityInfo, _res) -> { K primaryKey = _entityInfo.getPrimaryKey().getTypeInfo().getLogicalType().pullFromDatabase(this, _res, _entityInfo.getPrimaryKey().getJavaType(), _entityInfo.getPrimaryKey().getName()); return createReadOnlyProxy(_entityInfo, primaryKey); }; } else { log.debug("Id not found in column list, assuming no id"); return (_entityInfo, _res) -> createReadOnlyProxy(_entityInfo, null); } } private , K> ReadOnlyEntityProxy createReadOnlyProxy(EntityInfo entityInfo, K primaryKey) { return new ReadOnlyEntityProxy(this, entityInfo, primaryKey); } /** * Counts all entities of the specified type. This method is actually a delegate for: count(Class<? * extends Entity>, Query) * * @param type The type of the entities which should be counted. * @return The number of entities of the specified type. */ public int count(Class> type) throws SQLException { return count(type, Query.select()); } /** * Counts all entities of the specified type matching the given criteria and parameters. This is a convenience * method for: count(type, Query.select().where(criteria, parameters)) * * @param type The type of the entities which should be counted. * @param criteria A parameterized WHERE statement used to determine the result set which will be counted. * @param parameters A varargs array of parameters to be passed to the executed prepared statement. The length of * this array must match the number of parameters (denoted by the '?' char) in the criteria. * @return The number of entities of the given type which match the specified criteria. */ public int count(Class> type, String criteria, Object... parameters) throws SQLException { return count(type, Query.select().where(criteria, parameters)); } /** * Counts all entities of the specified type matching the given {@link Query} instance. The SQL runs as a * SELECT COUNT(*) to ensure maximum performance. * * @param type The type of the entities which should be counted. * @param query The {@link Query} instance used to determine the result set which will be counted. * @return The number of entities of the given type which match the specified query. */ public int count(Class> type, Query query) throws SQLException { try (Ticker ignored = metric(DB_AO_ENTITY_MANAGER_TIMER_NAME+".count") .tag(ENTITY_TYPE_TAG, type.getCanonicalName()) .withAnalytics() .invokerPluginKey(PluginKeyStack.getFirstPluginKey()) .startTimer()) { EntityInfo entityInfo = resolveEntityInfo(type); Connection connection = null; PreparedStatement stmt = null; ResultSet res = null; try { connection = provider.getConnection(); final String sql = query.toSQL(entityInfo, provider, getTableNameConverter(), true); stmt = provider.preparedStatement(connection, sql); provider.setQueryStatementProperties(stmt, query); query.setParameters(this, stmt); res = stmt.executeQuery(); return res.next() ? res.getInt(1) : -1; } finally { closeQuietly(res); closeQuietly(stmt); closeQuietly(connection); } } } /** * Gives an approximate count of all entities of the specified type to avoid performance issues. *

* DO NOT use this API if you need an exact count. For a guaranteed accurate count, use {@link EntityManager#count(Class)}. *

* Accuracy may depend on how long the last DB cleanup job was run * * @param type The type of the entities which should be counted * @throws FailedFastCountException means something went wrong while attempting to get a fast count * @return The approximate number of entities of the given type * @since 4.1 and 5.3 but not in 5.0 or 5.1 * */ public int getFastCountEstimate(Class> type) throws SQLException, FailedFastCountException { EntityInfo entityInfo = resolveEntityInfo(type); String tableName = entityInfo.getName(); try { if (provider instanceof PostgreSQLDatabaseProvider) { return runQuery(format("SELECT reltuples " + "FROM pg_catalog.pg_class " + "WHERE relname = '%s'", tableName)); } if (provider instanceof MySQLDatabaseProvider) { return runQuery(format("SELECT table_rows " + "FROM information_schema.tables " + "WHERE table_name = '%s';", tableName)); } } catch (SQLException e) { throw new FailedFastCountException(e); } return count(type); } private int runQuery(String sqlQuery) throws SQLException { Connection connection = null; PreparedStatement stmt = null; ResultSet res = null; try { connection = provider.getConnection(); stmt = provider.preparedStatement(connection, sqlQuery); res = stmt.executeQuery(); return res.next() ? res.getInt(1): -1; } finally { closeQuietly(res); closeQuietly(stmt); closeQuietly(connection); } } public NameConverters getNameConverters() { return nameConverters; } protected , K> EntityInfo resolveEntityInfo(Class type) { return entityInfoResolver.resolve(type); } /** * Retrieves the {@link TableNameConverter} instance used for name conversion of all entity types. */ public TableNameConverter getTableNameConverter() { return nameConverters.getTableNameConverter(); } /** * Retrieves the {@link FieldNameConverter} instance used for name conversion of all entity methods. */ public FieldNameConverter getFieldNameConverter() { return nameConverters.getFieldNameConverter(); } /** * Specifies the {@link PolymorphicTypeMapper} instance to use for all flag value conversion of polymorphic types. * The default type mapper is an empty {@link DefaultPolymorphicTypeMapper} instance (thus using the fully qualified * classname for all values). * * @see #getPolymorphicTypeMapper() */ public void setPolymorphicTypeMapper(PolymorphicTypeMapper typeMapper) { typeMapperLock.writeLock().lock(); try { this.typeMapper = typeMapper; if (typeMapper instanceof DefaultPolymorphicTypeMapper) { ((DefaultPolymorphicTypeMapper) typeMapper).resolveMappings(getTableNameConverter()); } } finally { typeMapperLock.writeLock().unlock(); } } /** * Retrieves the {@link PolymorphicTypeMapper} instance used for flag value conversion of polymorphic types. * * @see #setPolymorphicTypeMapper(PolymorphicTypeMapper) */ public PolymorphicTypeMapper getPolymorphicTypeMapper() { typeMapperLock.readLock().lock(); try { if (typeMapper == null) { throw new RuntimeException("No polymorphic type mapper was specified"); } return typeMapper; } finally { typeMapperLock.readLock().unlock(); } } /** *

Retrieves the database provider used by this EntityManager for all database operations. This * method can be used reliably to obtain a database provider and hence a {@link Connection} instance which can be * used for JDBC operations outside of ActiveObjects. Thus:

* *
Connection conn = manager.getProvider().getConnection();
     * try {
     *     // ...
     * } finally {
     *     conn.close();
     * }
*/ public DatabaseProvider getProvider() { return provider; } /** * Retrieves {@link SchemaConfiguration} used by this entity manager. * * @return the {@link SchemaConfiguration} */ public SchemaConfiguration getSchemaConfiguration() { return schemaConfiguration; } , K> EntityProxy getProxyForEntity(T entity) { return ((EntityProxyAccessor) entity).getEntityProxy(); } private void verify(RawEntity entity) { if (entity.getEntityManager() != this) { throw new RuntimeException("Entities can only be used with a single EntityManager instance"); } } private void putStatementParameters(PreparedStatement stmt, Object... parameters) throws SQLException { for (int i = 0; i < parameters.length; ++i) { Object parameter = parameters[i]; Class entityTypeOrClass = (parameter instanceof RawEntity) ? ((RawEntity) parameter).getEntityType() : parameter.getClass(); @SuppressWarnings("unchecked") TypeInfo typeInfo = provider.getTypeManager().getType(entityTypeOrClass); typeInfo.getLogicalType().putToDatabase(this, stmt, i + 1, parameter, typeInfo.getJdbcWriteType()); } } private interface Function { R invoke(F formals) throws SQLException; } private interface ProxyCreationHandler, K> { ReadOnlyEntityProxy create(EntityInfo entityInfo, ResultSet res) throws SQLException; } }