All Downloads are FREE. Search and download functionalities are using the official Maven repository.

com.datastax.driver.mapping.Mapper Maven / Gradle / Ivy

There is a newer version: 3.11.5
Show newest version
/*
 * Copyright (C) 2012-2017 DataStax Inc.
 *
 * 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 com.datastax.driver.mapping;

import com.datastax.driver.core.*;
import com.datastax.driver.core.querybuilder.BuiltStatement;
import com.datastax.driver.core.querybuilder.Delete;
import com.datastax.driver.core.querybuilder.Insert;
import com.datastax.driver.core.querybuilder.QueryBuilder;
import com.datastax.driver.core.utils.MoreObjects;
import com.datastax.driver.mapping.Mapper.Option.SaveNullFields;
import com.datastax.driver.mapping.annotations.Accessor;
import com.datastax.driver.mapping.annotations.Computed;
import com.google.common.base.Function;
import com.google.common.base.Functions;
import com.google.common.base.Preconditions;
import com.google.common.collect.ImmutableSet;
import com.google.common.util.concurrent.*;
import org.slf4j.Logger;
import org.slf4j.LoggerFactory;

import java.util.*;
import java.util.concurrent.ConcurrentHashMap;
import java.util.concurrent.ConcurrentMap;
import java.util.concurrent.ExecutionException;

import static com.datastax.driver.mapping.Mapper.Option.Type.SAVE_NULL_FIELDS;
import static com.google.common.base.Preconditions.checkArgument;

/**
 * An object handling the mapping of a particular class.
 * 

* A {@code Mapper} object is obtained from a {@code MappingManager} using the * {@link MappingManager#mapper} method. */ public class Mapper { private static final Logger logger = LoggerFactory.getLogger(Mapper.class); private static final Function TO_NULL = Functions.constant(null); private final MappingManager manager; private final Class klass; private final EntityMapper mapper; private final TableMetadata tableMetadata; // Cache prepared statements for each type of query we use. private final ConcurrentMap> preparedQueries = new ConcurrentHashMap>(); private volatile EnumMap defaultSaveOptions; private volatile EnumMap defaultGetOptions; private volatile EnumMap defaultDeleteOptions; private static final EnumMap NO_OPTIONS = new EnumMap(Option.Type.class); private final Function mapOneFunction; final Function mapOneFunctionWithoutAliases; final Function> mapAllFunctionWithoutAliases; Mapper(MappingManager manager, Class klass, EntityMapper mapper) { this.manager = manager; this.klass = klass; this.mapper = mapper; KeyspaceMetadata keyspace = session().getCluster().getMetadata().getKeyspace(mapper.keyspace); this.tableMetadata = keyspace == null ? null : keyspace.getTable(mapper.table); this.mapOneFunction = new Function() { @Override public T apply(ResultSet rs) { return Mapper.this.map(rs).one(); } }; this.mapOneFunctionWithoutAliases = new Function() { @Override public T apply(ResultSet rs) { return Mapper.this.map(rs).one(); } }; this.mapAllFunctionWithoutAliases = new Function>() { @Override public Result apply(ResultSet rs) { return Mapper.this.map(rs); } }; this.defaultSaveOptions = NO_OPTIONS; this.defaultGetOptions = NO_OPTIONS; this.defaultDeleteOptions = NO_OPTIONS; } Session session() { return manager.getSession(); } ListenableFuture getPreparedQueryAsync(QueryType type, Set columns, EnumMap options) { final MapperQueryKey pqk = new MapperQueryKey(type, columns, options); ListenableFuture existingFuture = preparedQueries.get(pqk); if (existingFuture == null) { final SettableFuture future = SettableFuture.create(); ListenableFuture old = preparedQueries.putIfAbsent(pqk, future); if (old != null) { return old; } else { final String queryString = type.makePreparedQueryString(tableMetadata, mapper, manager, columns, options.values()); logger.debug("Preparing query {}", queryString); SimpleStatement s = new SimpleStatement(queryString); // all queries generated by the mapper are idempotent s.setIdempotent(true); Futures.addCallback(session().prepareAsync(s), new FutureCallback() { @Override public void onSuccess(PreparedStatement stmt) { future.set(stmt); } @Override public void onFailure(Throwable t) { future.setException(t); // do not keep a failed future in the query cache preparedQueries.remove(pqk, future); logger.error("Query preparation failed: " + queryString, t); } }); return future; } } else { return existingFuture; } } ListenableFuture getPreparedQueryAsync(QueryType type, EnumMap options) { return getPreparedQueryAsync(type, Collections.emptySet(), options); } Class getMappedClass() { return klass; } /** * The {@code TableMetadata} for this mapper. * * @return the {@code TableMetadata} for this mapper or {@code null} if keyspace is not set. */ public TableMetadata getTableMetadata() { return tableMetadata; } /** * The {@code MappingManager} managing this mapper. * * @return the {@code MappingManager} managing this mapper. */ public MappingManager getManager() { return manager; } /** * Creates a query that can be used to save the provided entity. *

* This method is useful if you want to setup a number of options (tracing, * consistency level, ...) of the returned statement before executing it manually * or need access to the {@code ResultSet} object after execution (to get the * trace, the execution info, ...), but in other cases, calling {@link #save} * or {@link #saveAsync} is shorter. *

* Note: this method might block if the query is not prepared yet. * * @param entity the entity to save. * @return a query that saves {@code entity} (based on its defined mapping). */ public Statement saveQuery(T entity) { checkNotInEventLoop(); try { return Uninterruptibles.getUninterruptibly(saveQueryAsync(entity, this.defaultSaveOptions)); } catch (ExecutionException e) { throw DriverThrowables.propagateCause(e); } } /** * Creates a query that can be used to save the provided entity. *

* This method is useful if you want to setup a number of options (tracing, * consistency level, ...) of the returned statement before executing it manually * or need access to the {@code ResultSet} object after execution (to get the * trace, the execution info, ...), but in other cases, calling {@link #save} * or {@link #saveAsync} is shorter. * This method allows you to provide a suite of {@link Option} to include in * the SAVE query. Options currently supported for SAVE are : *

    *
  • Timestamp
  • *
  • Time-to-live (ttl)
  • *
  • Consistency level
  • *
  • Tracing
  • *
* Note: this method might block if the query is not prepared yet. * * @param entity the entity to save. * @return a query that saves {@code entity} (based on its defined mapping). */ public Statement saveQuery(T entity, Option... options) { checkNotInEventLoop(); try { return Uninterruptibles.getUninterruptibly(saveQueryAsync(entity, toMapWithDefaults(options, this.defaultSaveOptions))); } catch (ExecutionException e) { throw DriverThrowables.propagateCause(e); } } private ListenableFuture saveQueryAsync(T entity, final EnumMap options) { final Map columnToValue = new HashMap(); final boolean useUnsetForNullValue = !shouldSaveNullFields(options) && manager.protocolVersionAsInt >= 4; final boolean includeColumnsWithNullValue = shouldSaveNullFields(options) || useUnsetForNullValue; for (AliasedMappedProperty col : mapper.allColumns) { Object value = col.mappedProperty.getValue(entity); if (!col.mappedProperty.isComputed() && (includeColumnsWithNullValue || value != null)) { columnToValue.put(col, value); } } return Futures.transform(getPreparedQueryAsync(QueryType.SAVE, columnToValue.keySet(), options), new Function() { @Override public BoundStatement apply(PreparedStatement input) { BoundStatement bs = input.bind(); int i = 0; for (Map.Entry entry : columnToValue.entrySet()) { AliasedMappedProperty mapper = entry.getKey(); Object value = entry.getValue(); setObject(bs, i++, value, mapper, useUnsetForNullValue); } if (mapper.writeConsistency != null) bs.setConsistencyLevel(mapper.writeConsistency); for (Option option : options.values()) { option.validate(QueryType.SAVE, manager); i = option.apply(bs, i); } return bs; } }); } private static boolean shouldSaveNullFields(EnumMap options) { SaveNullFields option = (SaveNullFields) options.get(SAVE_NULL_FIELDS); return option == null || option.saveNullFields; } private static void setObject(BoundStatement bs, int i, T value, AliasedMappedProperty mapper, boolean saveNullFieldsAsUnset) { @SuppressWarnings("unchecked") TypeCodec customCodec = (TypeCodec) mapper.mappedProperty.getCustomCodec(); if (saveNullFieldsAsUnset && value == null) bs.unset(i); else if (customCodec != null) bs.set(i, value, customCodec); else bs.set(i, value, mapper.mappedProperty.getPropertyType()); } /** * Saves an entity mapped by this mapper. *

* This method is basically equivalent to: {@code getManager().getSession().execute(saveQuery(entity))}. *

* Note: this method will block until the entity is fully saved. * * @param entity the entity to save. */ public void save(T entity) { checkNotInEventLoop(); try { Uninterruptibles.getUninterruptibly(saveAsync(entity)); } catch (ExecutionException e) { throw DriverThrowables.propagateCause(e); } } /** * Saves an entity mapped by this mapper and using special options for save. * This method allows you to provide a suite of {@link Option} to include in * the SAVE query. Options currently supported for SAVE are : *

    *
  • Timestamp
  • *
  • Time-to-live (ttl)
  • *
  • Consistency level
  • *
  • Tracing
  • *
* Note: this method will block until the entity is fully saved. * * @param entity the entity to save. * @param options the options object specified defining special options when saving. */ public void save(T entity, Option... options) { checkNotInEventLoop(); try { Uninterruptibles.getUninterruptibly(saveAsync(entity, options)); } catch (ExecutionException e) { throw DriverThrowables.propagateCause(e); } } /** * Saves an entity mapped by this mapper asynchronously. *

* This method is basically equivalent to: {@code getManager().getSession().executeAsync(saveQuery(entity))}. * * @param entity the entity to save. * @return a future on the completion of the save operation. */ public ListenableFuture saveAsync(T entity) { return submitVoidQueryAsync(saveQueryAsync(entity, this.defaultSaveOptions)); } /** * Save an entity mapped by this mapper asynchronously using special options for save. *

* This method is basically equivalent to: {@code getManager().getSession().executeAsync(saveQuery(entity, options))}. * * @param entity the entity to save. * @param options the options object specified defining special options when saving. * @return a future on the completion of the save operation. */ public ListenableFuture saveAsync(T entity, Option... options) { return submitVoidQueryAsync(saveQueryAsync(entity, toMapWithDefaults(options, this.defaultSaveOptions))); } private ListenableFuture submitVoidQueryAsync(ListenableFuture bsFuture) { ListenableFuture rsFuture = GuavaCompatibility.INSTANCE.transformAsync(bsFuture, new AsyncFunction() { @Override public ListenableFuture apply(BoundStatement bs) throws Exception { return session().executeAsync(bs); } }); return Futures.transform(rsFuture, TO_NULL); } /** * Creates a query to fetch entity given its PRIMARY KEY. *

* The values provided must correspond to the columns composing the PRIMARY * KEY (in the order of said primary key). *

* This method is useful if you want to setup a number of options (tracing, * consistency level, ...) of the returned statement before executing it manually, * but in other cases, calling {@link #get} or {@link #getAsync} is shorter. *

* This method allows you to provide a suite of {@link Option} to include in * the GET query. Options currently supported for GET are : *

    *
  • Consistency level
  • *
  • Tracing
  • *
* Note: this method might block if the query is not prepared yet. * * @param objects the primary key of the entity to fetch, or more precisely * the values for the columns of said primary key in the order of the primary key. * Can be followed by {@link Option} to include in the DELETE query. * @return a query that fetch the entity of PRIMARY KEY {@code objects}. * @throws IllegalArgumentException if the number of value provided differ from * the number of columns composing the PRIMARY KEY of the mapped class, or if * at least one of those values is {@code null}. */ public Statement getQuery(Object... objects) { checkNotInEventLoop(); try { return Uninterruptibles.getUninterruptibly(getQueryAsync(objects)); } catch (ExecutionException e) { throw DriverThrowables.propagateCause(e); } } private ListenableFuture getQueryAsync(Object... objects) { // Order and duplicates matter for primary keys List pks = new ArrayList(); EnumMap options = new EnumMap(defaultGetOptions); for (Object o : objects) { if (o instanceof Option) { Option option = (Option) o; options.put(option.type, option); } else { pks.add(o); } } return getQueryAsync(pks, options); } private ListenableFuture getQueryAsync(final List primaryKeys, final EnumMap options) { if (primaryKeys.size() != mapper.primaryKeySize()) throw new IllegalArgumentException(String.format("Invalid number of PRIMARY KEY columns provided, %d expected but got %d", mapper.primaryKeySize(), primaryKeys.size())); return Futures.transform(getPreparedQueryAsync(QueryType.GET, options), new Function() { @Override public BoundStatement apply(PreparedStatement input) { BoundStatement bs = new MapperBoundStatement(input); int i = 0; for (Object value : primaryKeys) { AliasedMappedProperty column = mapper.getPrimaryKeyColumn(i); if (value == null) { throw new IllegalArgumentException( String.format("Invalid null value for PRIMARY KEY column %s (argument %d)", column.mappedProperty.getMappedName(), i)); } setObject(bs, i++, value, column, false); } if (mapper.readConsistency != null) bs.setConsistencyLevel(mapper.readConsistency); for (Option option : options.values()) { option.validate(QueryType.GET, manager); i = option.apply(bs, i); } return bs; } }); } /** * Fetch an entity based on its primary key. *

* This method is basically equivalent to: {@code map(getManager().getSession().execute(getQuery(objects))).one()}. *

* Note: this method will block until the entity is fully fetched. * * @param objects the primary key of the entity to fetch, or more precisely * the values for the columns of said primary key in the order of the primary key. * Can be followed by {@link Option} to include in the DELETE query. * @return the entity fetched or {@code null} if it doesn't exist. * @throws IllegalArgumentException if the number of value provided differ from * the number of columns composing the PRIMARY KEY of the mapped class, or if * at least one of those values is {@code null}. */ public T get(Object... objects) { checkNotInEventLoop(); try { return Uninterruptibles.getUninterruptibly(getAsync(objects)); } catch (ExecutionException e) { throw DriverThrowables.propagateCause(e); } } /** * Fetch an entity based on its primary key asynchronously. *

* This method is basically equivalent to mapping the result of: {@code getManager().getSession().executeAsync(getQuery(objects))}. * * @param objects the primary key of the entity to fetch, or more precisely * the values for the columns of said primary key in the order of the primary key. * Can be followed by {@link Option} to include in the DELETE query. * @return a future on the fetched entity. The return future will yield * {@code null} if said entity doesn't exist. * @throws IllegalArgumentException if the number of value provided differ from * the number of columns composing the PRIMARY KEY of the mapped class, or if * at least one of those values is {@code null}. */ public ListenableFuture getAsync(final Object... objects) { ListenableFuture bsFuture = getQueryAsync(objects); ListenableFuture rsFuture = GuavaCompatibility.INSTANCE.transformAsync(bsFuture, new AsyncFunction() { @Override public ListenableFuture apply(BoundStatement bs) throws Exception { return session().executeAsync(bs); } }); return Futures.transform(rsFuture, mapOneFunction); } /** * Creates a query that can be used to delete the provided entity. *

* This method is a shortcut that extract the PRIMARY KEY from the * provided entity and call {@link #deleteQuery(Object...)} with it. * This method allows you to provide a suite of {@link Option} to include in * the DELETE query. Note : currently, only {@link com.datastax.driver.mapping.Mapper.Option.Timestamp} * is supported for DELETE queries. *

* This method is useful if you want to setup a number of options (tracing, * consistency level, ...) of the returned statement before executing it manually * or need access to the {@code ResultSet} object after execution (to get the * trace, the execution info, ...), but in other cases, calling {@link #delete} * or {@link #deleteAsync} is shorter. *

* This method allows you to provide a suite of {@link Option} to include in * the DELETE query. Options currently supported for DELETE are : *

    *
  • Timestamp
  • *
  • Consistency level
  • *
  • Tracing
  • *
* Note: this method might block if the query is not prepared yet. * * @param entity the entity to delete. * @param options the options to add to the DELETE query. * @return a query that delete {@code entity} (based on its defined mapping) with * provided USING options. */ public Statement deleteQuery(T entity, Option... options) { checkNotInEventLoop(); try { return Uninterruptibles.getUninterruptibly(deleteQueryAsync(entity, toMapWithDefaults(options, defaultDeleteOptions))); } catch (ExecutionException e) { throw DriverThrowables.propagateCause(e); } } /** * Creates a query that can be used to delete the provided entity. *

* This method is a shortcut that extract the PRIMARY KEY from the * provided entity and call {@link #deleteQuery(Object...)} with it. *

* This method is useful if you want to setup a number of options (tracing, * consistency level, ...) of the returned statement before executing it manually * or need access to the {@code ResultSet} object after execution (to get the * trace, the execution info, ...), but in other cases, calling {@link #delete} * or {@link #deleteAsync} is shorter. *

* Note: this method might block if the query is not prepared yet. * * @param entity the entity to delete. * @return a query that delete {@code entity} (based on its defined mapping). */ public Statement deleteQuery(T entity) { checkNotInEventLoop(); try { return Uninterruptibles.getUninterruptibly(deleteQueryAsync(entity, defaultDeleteOptions)); } catch (ExecutionException e) { throw DriverThrowables.propagateCause(e); } } /** * Creates a query that can be used to delete an entity given its PRIMARY KEY. *

* The values provided must correspond to the columns composing the PRIMARY * KEY (in the order of said primary key). The values can also contain, after * specifying the primary keys columns, a suite of {@link Option} to include in * the DELETE query. Note : currently, only {@link com.datastax.driver.mapping.Mapper.Option.Timestamp} * is supported for DELETE queries. *

* This method is useful if you want to setup a number of options (tracing, * consistency level, ...) of the returned statement before executing it manually * or need access to the {@code ResultSet} object after execution (to get the * trace, the execution info, ...), but in other cases, calling {@link #delete} * or {@link #deleteAsync} is shorter. * This method allows you to provide a suite of {@link Option} to include in * the DELETE query. Options currently supported for DELETE are : *

    *
  • Timestamp
  • *
  • Consistency level
  • *
  • Tracing
  • *
* Note: this method might block if the query is not prepared yet. * * @param objects the primary key of the entity to delete, or more precisely * the values for the columns of said primary key in the order of the primary key. * Can be followed by {@link Option} to include in the DELETE * query. * @return a query that delete the entity of PRIMARY KEY {@code primaryKey}. * @throws IllegalArgumentException if the number of value provided differ from * the number of columns composing the PRIMARY KEY of the mapped class, or if * at least one of those values is {@code null}. */ public Statement deleteQuery(Object... objects) { checkNotInEventLoop(); try { return Uninterruptibles.getUninterruptibly(deleteQueryAsync(objects)); } catch (ExecutionException e) { throw DriverThrowables.propagateCause(e); } } private ListenableFuture deleteQueryAsync(T entity, EnumMap options) { List pks = new ArrayList(); for (int i = 0; i < mapper.primaryKeySize(); i++) { pks.add(mapper.getPrimaryKeyColumn(i).mappedProperty.getValue(entity)); } return deleteQueryAsync(pks, options); } private ListenableFuture deleteQueryAsync(Object... objects) { // Order and duplicates matter for primary keys List pks = new ArrayList(); EnumMap options = new EnumMap(defaultDeleteOptions); for (Object o : objects) { if (o instanceof Option) { Option option = (Option) o; options.put(option.type, option); } else { pks.add(o); } } return deleteQueryAsync(pks, options); } private ListenableFuture deleteQueryAsync(final List primaryKey, final EnumMap options) { if (primaryKey.size() != mapper.primaryKeySize()) throw new IllegalArgumentException(String.format("Invalid number of PRIMARY KEY columns provided, %d expected but got %d", mapper.primaryKeySize(), primaryKey.size())); return Futures.transform(getPreparedQueryAsync(QueryType.DEL, options), new Function() { @Override public BoundStatement apply(PreparedStatement input) { BoundStatement bs = input.bind(); if (mapper.writeConsistency != null) bs.setConsistencyLevel(mapper.writeConsistency); int i = 0; for (Option option : options.values()) { option.validate(QueryType.DEL, manager); i = option.apply(bs, i); } int columnNumber = 0; for (Object value : primaryKey) { @SuppressWarnings("unchecked") AliasedMappedProperty column = mapper.getPrimaryKeyColumn(columnNumber); if (value == null) { throw new IllegalArgumentException(String.format("Invalid null value for PRIMARY KEY column %s (argument %d)", column.mappedProperty.getMappedName(), i)); } setObject(bs, i++, value, column, false); columnNumber++; } return bs; } }); } /** * Deletes an entity mapped by this mapper. *

* This method is basically equivalent to: {@code getManager().getSession().execute(deleteQuery(entity))}. *

* Note: this method will block until the entity is fully deleted. * * @param entity the entity to delete. */ public void delete(T entity) { checkNotInEventLoop(); try { Uninterruptibles.getUninterruptibly(deleteAsync(entity)); } catch (ExecutionException e) { throw DriverThrowables.propagateCause(e); } } /** * Deletes an entity mapped by this mapper using provided options. *

* This method is basically equivalent to: {@code getManager().getSession().execute(deleteQuery(entity, options))}. *

* Note: this method will block until the entity is fully deleted. * * @param entity the entity to delete. * @param options the options to add to the DELETE query. */ public void delete(T entity, Option... options) { checkNotInEventLoop(); try { Uninterruptibles.getUninterruptibly(deleteAsync(entity, options)); } catch (ExecutionException e) { throw DriverThrowables.propagateCause(e); } } /** * Deletes an entity mapped by this mapper asynchronously. *

* This method is basically equivalent to: {@code getManager().getSession().executeAsync(deleteQuery(entity))}. * * @param entity the entity to delete. * @return a future on the completion of the deletion. */ public ListenableFuture deleteAsync(T entity) { return submitVoidQueryAsync(deleteQueryAsync(entity, defaultDeleteOptions)); } /** * Deletes an entity mapped by this mapper asynchronously using provided options. *

* This method is basically equivalent to: {@code getManager().getSession().executeAsync(deleteQuery(entity, options))}. * * @param entity the entity to delete. * @param options the options to add to the DELETE query. * @return a future on the completion of the deletion. */ public ListenableFuture deleteAsync(T entity, Option... options) { return submitVoidQueryAsync(deleteQueryAsync(entity, toMapWithDefaults(options, defaultDeleteOptions))); } /** * Deletes an entity based on its primary key. *

* This method is basically equivalent to: {@code getManager().getSession().execute(deleteQuery(objects))}. *

* Note: this method will block until the entity is fully deleted. * * @param objects the primary key of the entity to delete, or more precisely * the values for the columns of said primary key in the order * of the primary key.Can be followed by {@link Option} to include * in the DELETE query. * @throws IllegalArgumentException if the number of value provided differ from * the number of columns composing the PRIMARY KEY of the mapped class, or if * at least one of those values is {@code null}. */ public void delete(Object... objects) { checkNotInEventLoop(); try { Uninterruptibles.getUninterruptibly(deleteAsync(objects)); } catch (ExecutionException e) { throw DriverThrowables.propagateCause(e); } } /** * Deletes an entity based on its primary key asynchronously. *

* This method is basically equivalent to: {@code getManager().getSession().executeAsync(deleteQuery(objects))}. * * @param objects the primary key of the entity to delete, or more precisely * the values for the columns of said primary key in the order * of the primary key. Can be followed by {@link Option} to include * in the DELETE query. * @throws IllegalArgumentException if the number of value provided differ from * the number of columns composing the PRIMARY KEY of the mapped class, or if * at least one of those values is {@code null}. */ public ListenableFuture deleteAsync(Object... objects) { return submitVoidQueryAsync(deleteQueryAsync(objects)); } /** * Maps the rows from a {@code ResultSet} into the class this is a mapper of. *

* If the query was user-generated (that is, passed directly to {@code session.execute()} or configured with * {@link com.datastax.driver.mapping.annotations.Query @Query} in an * {@link com.datastax.driver.mapping.annotations.Accessor @Accessor}-annotated interface), then only the columns * present in the result set will be mapped to the corresponding fields, and {@link Computed} fields will not be * populated. *

* If the query was generated by the mapper (for example with {@link #getQuery(Object...)}), all fields will be * mapped, as if the object came from a direct {@link #get(Object...)} call. * * @param resultSet the {@code ResultSet} to map. * @return the mapped result set. Note that the returned mapped result set * will encapsulate {@code resultSet} and so consuming results from this * returned mapped result set will consume results from {@code resultSet} * and vice-versa. */ public Result map(ResultSet resultSet) { boolean useAlias = (manager.protocolVersionAsInt > 1) && isFromMapperQuery(resultSet); return new Result(resultSet, mapper, useAlias); } /** * Asynchronously maps the rows from a {@link ResultSetFuture} into the class this is a mapper of. *

* Use this method to map a {@link ResultSetFuture} that was not generated by the mapper * (e.g. a {@link ResultSetFuture} coming from a manual query or an {@link Accessor} method). * It expects that the result set contains all column mapped in the target class, * and that they are not aliased. {@link Computed} fields will not be filled in mapped objects. * * @param resultSetFuture the {@link ResultSetFuture} to map. * @return the mapped result set future. Note that the returned mapped result set * will encapsulate the result set returned by {@code resultSetFuture} and so consuming results from this * returned mapped result set will consume results from that result set * and vice-versa. */ public ListenableFuture> mapAsync(ResultSetFuture resultSetFuture) { return Futures.transform(resultSetFuture, new Function>() { @Override public Result apply(ResultSet rs) { return map(rs); } }); } private boolean isFromMapperQuery(ResultSet resultSet) { return resultSet.getExecutionInfo().getStatement() instanceof MapperBoundStatement; } /** * @deprecated you no longer need to specify whether a result set is aliased, it will be detected automatically. Use * {@link #map(ResultSet)} instead of this method. */ @Deprecated public Result mapAliased(ResultSet resultSet) { return (manager.protocolVersionAsInt == 1) ? map(resultSet) // no aliases : new Result(resultSet, mapper, true); } /** * Set the default save {@link Option} for this object mapper, that will be used * in all save operations unless overridden. Refer to {@link Mapper#save(Object, Option...)})} * to check available save options. * * @param options the options to set. To reset, use {@link Mapper#resetDefaultSaveOptions}. */ public void setDefaultSaveOptions(Option... options) { this.defaultSaveOptions = toMap(options); } /** * Reset the default save options for this object mapper. */ public void resetDefaultSaveOptions() { this.defaultSaveOptions = NO_OPTIONS; } /** * Set the default get {@link Option} for this object mapper, that will be used * in all get operations unless overridden. Refer to {@link Mapper#get(Object...)} )} to check available * get options. * * @param options the options to set. To reset, use {@link Mapper#resetDefaultGetOptions}. */ public void setDefaultGetOptions(Option... options) { this.defaultGetOptions = toMap(options); } /** * Reset the default save options for this object mapper. */ public void resetDefaultGetOptions() { this.defaultGetOptions = NO_OPTIONS; } /** * Set the default delete {@link Option} for this object mapper, that will be used * in all delete operations unless overridden. Refer to {@link Mapper#delete(Object...)} )} * to check available delete options. * * @param options the options to set. To reset, use {@link Mapper#resetDefaultDeleteOptions}. */ public void setDefaultDeleteOptions(Option... options) { this.defaultDeleteOptions = toMap(options); } /** * Reset the default delete options for this object mapper. */ public void resetDefaultDeleteOptions() { this.defaultDeleteOptions = NO_OPTIONS; } private static EnumMap toMap(Option[] options) { EnumMap result = new EnumMap(Option.Type.class); for (Option option : options) { result.put(option.type, option); } return result; } private static EnumMap toMapWithDefaults(Option[] options, EnumMap defaults) { EnumMap result = new EnumMap(defaults); for (Option option : options) { result.put(option.type, option); } return result; } private void checkNotInEventLoop() { Session session = manager.getSession(); if (session instanceof AbstractSession) { ((AbstractSession) session).checkNotInEventLoop(); } } /** * An option for a mapper operation. *

* Options can be passed to individual operations: *

     *     mapper.save(myObject, Option.ttl(3600));
     * 
*

* The mapper can also have defaults, that will apply to all operations that do not * override these particular option: *

     *     mapper.setDefaultSaveOptions(Option.ttl(3600));
     *     mapper.save(myObject);
     * 
*

*

* See the static methods in this class for available options. */ public static abstract class Option { enum Type {TTL, TIMESTAMP, CL, TRACING, SAVE_NULL_FIELDS, IF_NOT_EXISTS} /** * Creates a new Option object to add time-to-live to a mapper operation. This is * only valid for save operations. *

* Note that this option is only available if using {@link ProtocolVersion#V2} or above. * * @param ttl the TTL (in seconds). * @return the option. */ public static Option ttl(int ttl) { return new Ttl(ttl); } /** * Creates a new Option object to add a timestamp to a mapper operation. This is * only valid for save and delete operations. *

* Note that this option is only available if using {@link ProtocolVersion#V2} or above. * * @param timestamp the timestamp (in microseconds). * @return the option. */ public static Option timestamp(long timestamp) { return new Timestamp(timestamp); } /** * Creates a new Option object to add a consistency level value to a mapper operation. This * is valid for save, delete and get operations. *

* Note that the consistency level can also be defined at the mapper level, as a parameter * of the {@link com.datastax.driver.mapping.annotations.Table} annotation (this is redundant * for backward compatibility). This option, whether defined on a specific call or as the * default, will always take precedence over the annotation. * * @param cl the {@link com.datastax.driver.core.ConsistencyLevel} to use for the operation. * @return the option. */ public static Option consistencyLevel(ConsistencyLevel cl) { return new ConsistencyLevelOption(cl); } /** * Creates a new Option object to enable query tracing for a mapper operation. This * is valid for save, delete and get operations. * * @param enabled whether to enable tracing. * @return the option. */ public static Option tracing(boolean enabled) { return new Tracing(enabled); } /** * Creates a new Option object to specify whether null entity fields should be included in * insert queries. This option is valid only for save operations. *

* If this option is not specified, it defaults to {@code true} (null fields are saved). * * @param enabled whether to include null fields in queries. * @return the option. */ public static Option saveNullFields(boolean enabled) { return new SaveNullFields(enabled); } /** * Creates a new Option object to specify whether an IF NOT EXISTS clause should be included in * insert queries. This option is valid only for save operations. *

* If this option is not specified, it defaults to {@code false} (IF NOT EXISTS statements are not used). * * @param enabled whether to include an IF NOT EXISTS clause in queries. * @return the option. */ public static Option ifNotExists(boolean enabled) { return new IfNotExists(enabled); } final Type type; protected Option(Type type) { this.type = type; } /** * @deprecated This method is public for backward compatibility only. It should not be accessible since it leaks * a package-private type. */ @Deprecated public Type getType() { return type; } /** * Checks that the option is allowed for a given query type, in a given manager. * * @throws IllegalArgumentException if the option is not valid */ abstract void validate(QueryType qt, MappingManager manager); /** * Whether the option has any impact on the prepared query string. */ abstract boolean modifiesQueryString(); /** * Appends the option to the prepared statement associated to the mapper operation * (might be a no-op, not all options affect the query string). */ abstract void modifyQueryString(BuiltStatement query); /** * Applies the option to the bound statement before the request gets executed (might be a * no-op). *

* If the option's value is set as a bound variable, then this must be done at the given * index, and the method should return the new position. *

* Options may also affect the statement itself, not a bound variable; in that case, the * method must return the index unchanged. */ abstract int apply(BoundStatement bs, int currentIndex); /** * A key to represent the option in the prepared statement cache. *

* If the same option with different values produces different query strings, this should * be the option itself. * Otherwise this should be the option type. */ abstract Object asCacheKey(); static class Ttl extends Option { private final int ttlValue; Ttl(int value) { super(Type.TTL); this.ttlValue = value; } @Override void validate(QueryType qt, MappingManager manager) { checkArgument(!(manager.protocolVersionAsInt < 2), "TTL option requires native protocol v2 or above"); checkArgument(qt == QueryType.SAVE, "TTL option is only allowed in save queries"); } @Override boolean modifiesQueryString() { return true; } @Override void modifyQueryString(BuiltStatement query) { ((Insert) query).using().and( QueryBuilder.ttl(QueryBuilder.bindMarker())); } @Override int apply(BoundStatement bs, int currentIndex) { bs.setInt(currentIndex, this.ttlValue); return currentIndex + 1; } @Override Object asCacheKey() { // ttl is set as a bound variable "TTL(?)", so different values yield the same prepared query return Type.TTL; } @Override public boolean equals(Object other) { return other == this || (other instanceof Ttl && this.ttlValue == ((Ttl) other).ttlValue); } @Override public int hashCode() { return ttlValue; } } static class Timestamp extends Option { private final long tsValue; Timestamp(long value) { super(Type.TIMESTAMP); this.tsValue = value; } @Override void validate(QueryType qt, MappingManager manager) { checkArgument(!(manager.protocolVersionAsInt < 2), "Timestamp option requires native protocol v2 or above"); checkArgument(qt == QueryType.SAVE || qt == QueryType.DEL, "Timestamp option is only allowed in save and delete queries"); } @Override boolean modifiesQueryString() { return true; } @Override void modifyQueryString(BuiltStatement query) { if (query instanceof Insert) { ((Insert) query).using().and(QueryBuilder.timestamp(QueryBuilder.bindMarker())); } else if (query instanceof Delete) { ((Delete) query).using().and(QueryBuilder.timestamp(QueryBuilder.bindMarker())); } else { throw new AssertionError("Unexpected query type: " + query.getClass()); } } @Override int apply(BoundStatement bs, int currentIndex) { bs.setLong(currentIndex, this.tsValue); return currentIndex + 1; } @Override Object asCacheKey() { // timestamp is set as a bound variable "USING TIMESTAMP ?", so different values // yield the same prepared query return Type.TIMESTAMP; } @Override public boolean equals(Object other) { return other == this || (other instanceof Timestamp && this.tsValue == ((Timestamp) other).tsValue); } @Override public int hashCode() { return (int) (tsValue ^ (tsValue >>> 32)); } } static class ConsistencyLevelOption extends Option { private final ConsistencyLevel cl; ConsistencyLevelOption(ConsistencyLevel cl) { super(Type.CL); this.cl = cl; } @Override void validate(QueryType qt, MappingManager manager) { } @Override boolean modifiesQueryString() { return false; } @Override void modifyQueryString(BuiltStatement query) { // nothing to do, CL is set on the bound statement } @Override int apply(BoundStatement bs, int currentIndex) { bs.setConsistencyLevel(cl); return currentIndex; } @Override Object asCacheKey() { // does not modify the query string return Type.CL; } @Override public boolean equals(Object other) { return other == this || (other instanceof ConsistencyLevelOption && this.cl == ((ConsistencyLevelOption) other).cl); } @Override public int hashCode() { return cl.hashCode(); } } static class Tracing extends Option { private final boolean tracing; Tracing(boolean tracing) { super(Type.TRACING); this.tracing = tracing; } @Override void validate(QueryType qt, MappingManager manager) { } @Override boolean modifiesQueryString() { return false; } @Override void modifyQueryString(BuiltStatement query) { // nothing to do, tracing is enabled on the prepared statement } @Override int apply(BoundStatement bs, int currentIndex) { if (this.tracing) { bs.enableTracing(); } return currentIndex; } @Override Object asCacheKey() { // does not modify the query string return Type.TRACING; } @Override public boolean equals(Object other) { return other == this || (other instanceof Tracing && this.tracing == ((Tracing) other).tracing); } @Override public int hashCode() { return tracing ? 1231 : 1237; } } static class SaveNullFields extends Option { private final boolean saveNullFields; SaveNullFields(boolean saveNullFields) { super(SAVE_NULL_FIELDS); this.saveNullFields = saveNullFields; } @Override void validate(QueryType qt, MappingManager manager) { checkArgument(qt == QueryType.SAVE, "SaveNullFields option is only allowed in save queries"); } @Override boolean modifiesQueryString() { return false; } @Override void modifyQueryString(BuiltStatement query) { // nothing to do } @Override int apply(BoundStatement bs, int currentIndex) { return currentIndex; } @Override Object asCacheKey() { // does not modify the query string return Type.SAVE_NULL_FIELDS; } @Override public boolean equals(Object other) { return other == this || (other instanceof SaveNullFields && this.saveNullFields == ((SaveNullFields) other).saveNullFields); } @Override public int hashCode() { return saveNullFields ? 1231 : 1237; } } static class IfNotExists extends Option { boolean ifNotExists; IfNotExists(boolean ifNotExists) { super(Type.IF_NOT_EXISTS); this.ifNotExists = ifNotExists; } @Override void validate(QueryType qt, MappingManager manager) { checkArgument(qt == QueryType.SAVE, "IfNotExists option is only allowed in save queries"); } @Override boolean modifiesQueryString() { return true; } @Override void modifyQueryString(BuiltStatement query) { if (ifNotExists) { ((Insert) query).ifNotExists(); } } @Override int apply(BoundStatement bs, int currentIndex) { return currentIndex; } @Override Object asCacheKey() { // Different values do change the query string ("IF NOT EXIST" clause present or not) return this; } @Override public boolean equals(Object other) { return other == this || (other instanceof IfNotExists && this.ifNotExists == ((IfNotExists) other).ifNotExists); } @Override public int hashCode() { return (ifNotExists) ? 1231 : 1237; } } } private static class MapperQueryKey { private final QueryType queryType; private final Set optionKeys; private final Set columns; MapperQueryKey(QueryType queryType, Set aliasedMappedProperties, EnumMap allOptions) { Preconditions.checkNotNull(queryType); Preconditions.checkNotNull(allOptions); Preconditions.checkNotNull(aliasedMappedProperties); this.queryType = queryType; this.columns = aliasedMappedProperties; ImmutableSet.Builder optionKeysBuilder = ImmutableSet.builder(); for (Option option : allOptions.values()) { if (option.modifiesQueryString()) { optionKeysBuilder.add(option.asCacheKey()); } } this.optionKeys = optionKeysBuilder.build(); } @Override public boolean equals(Object other) { if (this == other) return true; if (other instanceof MapperQueryKey) { MapperQueryKey that = (MapperQueryKey) other; return this.queryType.equals(that.queryType) && this.optionKeys.equals(that.optionKeys) && this.columns.equals(that.columns); } return false; } @Override public int hashCode() { return MoreObjects.hashCode(queryType, optionKeys, columns); } } }