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The Apache Cassandra Project develops a highly scalable second-generation distributed database, bringing together Dynamo's fully distributed design and Bigtable's ColumnFamily-based data model.

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/*
 * Licensed to the Apache Software Foundation (ASF) under one
 * or more contributor license agreements.  See the NOTICE file
 * distributed with this work for additional information
 * regarding copyright ownership.  The ASF licenses this file
 * to you 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 org.apache.cassandra.index;

import java.lang.reflect.Constructor;
import java.util.*;
import java.util.concurrent.*;
import java.util.function.Function;
import java.util.stream.Collectors;
import java.util.stream.Stream;

import com.google.common.annotations.VisibleForTesting;
import com.google.common.base.Joiner;
import com.google.common.base.Strings;
import com.google.common.collect.ImmutableSet;
import com.google.common.collect.Iterables;
import com.google.common.collect.Maps;
import com.google.common.collect.Sets;
import com.google.common.primitives.Longs;
import com.google.common.util.concurrent.Futures;
import com.google.common.util.concurrent.MoreExecutors;
import org.apache.commons.lang3.StringUtils;
import org.slf4j.Logger;
import org.slf4j.LoggerFactory;

import org.apache.cassandra.concurrent.JMXEnabledThreadPoolExecutor;
import org.apache.cassandra.concurrent.NamedThreadFactory;
import org.apache.cassandra.concurrent.StageManager;
import org.apache.cassandra.config.ColumnDefinition;
import org.apache.cassandra.config.DatabaseDescriptor;
import org.apache.cassandra.cql3.statements.IndexTarget;
import org.apache.cassandra.db.*;
import org.apache.cassandra.db.compaction.CompactionManager;
import org.apache.cassandra.db.filter.RowFilter;
import org.apache.cassandra.db.lifecycle.SSTableSet;
import org.apache.cassandra.db.lifecycle.View;
import org.apache.cassandra.db.partitions.*;
import org.apache.cassandra.db.rows.*;
import org.apache.cassandra.exceptions.InvalidRequestException;
import org.apache.cassandra.index.internal.CassandraIndex;
import org.apache.cassandra.index.transactions.*;
import org.apache.cassandra.io.sstable.ReducingKeyIterator;
import org.apache.cassandra.io.sstable.format.SSTableReader;
import org.apache.cassandra.schema.IndexMetadata;
import org.apache.cassandra.schema.Indexes;
import org.apache.cassandra.service.pager.SinglePartitionPager;
import org.apache.cassandra.tracing.Tracing;
import org.apache.cassandra.transport.Server;
import org.apache.cassandra.utils.FBUtilities;
import org.apache.cassandra.utils.concurrent.OpOrder;
import org.apache.cassandra.utils.concurrent.Refs;

import static org.apache.cassandra.utils.ExecutorUtils.awaitTermination;
import static org.apache.cassandra.utils.ExecutorUtils.shutdown;
import static org.apache.cassandra.utils.ExecutorUtils.shutdownNow;

/**
 * Handles the core maintenance functionality associated with indexes: adding/removing them to or from
 * a table, (re)building during bootstrap or other streaming operations, flushing, reloading metadata
 * and so on.
 *
 * The Index interface defines a number of methods which return Callable. These are primarily the
 * management tasks for an index implementation. Most of them are currently executed in a blocking
 * fashion via submission to SIM's blockingExecutor. This provides the desired behaviour in pretty
 * much all cases, as tasks like flushing an index needs to be executed synchronously to avoid potentially
 * deadlocking on the FlushWriter or PostFlusher. Several of these Callable returning methods on Index could
 * then be defined with as void and called directly from SIM (rather than being run via the executor service).
 * Separating the task defintion from execution gives us greater flexibility though, so that in future, for example,
 * if the flush process allows it we leave open the possibility of executing more of these tasks asynchronously.
 *
 * The primary exception to the above is the Callable returned from Index#addIndexedColumn. This may
 * involve a significant effort, building a new index over any existing data. We perform this task asynchronously;
 * as it is called as part of a schema update, which we do not want to block for a long period. Building non-custom
 * indexes is performed on the CompactionManager.
 *
 * This class also provides instances of processors which listen to updates to the base table and forward to
 * registered Indexes the info required to keep those indexes up to date.
 * There are two variants of these processors, each with a factory method provided by SIM:
 *      IndexTransaction: deals with updates generated on the regular write path.
 *      CleanupTransaction: used when partitions are modified during compaction or cleanup operations.
 * Further details on their usage and lifecycles can be found in the interface definitions below.
 *
 * Finally, the bestIndexFor method is used at query time to identify the most selective index of those able
 * to satisfy any search predicates defined by a ReadCommand's RowFilter. It returns a thin IndexAccessor object
 * which enables the ReadCommand to access the appropriate functions of the Index at various stages in its lifecycle.
 * e.g. the getEstimatedResultRows is required when StorageProxy calculates the initial concurrency factor for
 * distributing requests to replicas, whereas a Searcher instance is needed when the ReadCommand is executed locally on
 * a target replica.
 */
public class SecondaryIndexManager implements IndexRegistry
{
    private static final Logger logger = LoggerFactory.getLogger(SecondaryIndexManager.class);

    // default page size (in rows) when rebuilding the index for a whole partition
    public static final int DEFAULT_PAGE_SIZE = 10000;

    private Map indexes = Maps.newConcurrentMap();

    /**
     * The indexes that are ready to server requests.
     */
    private Set builtIndexes = Sets.newConcurrentHashSet();

    // executes tasks returned by Indexer#addIndexColumn which may require index(es) to be (re)built
    private static final ExecutorService asyncExecutor =
        new JMXEnabledThreadPoolExecutor(1,
                                         StageManager.KEEPALIVE,
                                         TimeUnit.SECONDS,
                                         new LinkedBlockingQueue<>(),
                                         new NamedThreadFactory("SecondaryIndexManagement"),
                                         "internal");

    // executes all blocking tasks produced by Indexers e.g. getFlushTask, getMetadataReloadTask etc
    private static final ExecutorService blockingExecutor = MoreExecutors.newDirectExecutorService();

    /**
     * The underlying column family containing the source data for these indexes
     */
    public final ColumnFamilyStore baseCfs;

    public SecondaryIndexManager(ColumnFamilyStore baseCfs)
    {
        this.baseCfs = baseCfs;
    }


    /**
     * Drops and adds new indexes associated with the underlying CF
     */
    public void reload()
    {
        // figure out what needs to be added and dropped.
        Indexes tableIndexes = baseCfs.metadata.getIndexes();
        indexes.keySet()
               .stream()
               .filter(indexName -> !tableIndexes.has(indexName))
               .forEach(this::removeIndex);

        // we call add for every index definition in the collection as
        // some may not have been created here yet, only added to schema
        for (IndexMetadata tableIndex : tableIndexes)
            addIndex(tableIndex);
    }

    private Future reloadIndex(IndexMetadata indexDef)
    {
        Index index = indexes.get(indexDef.name);
        Callable reloadTask = index.getMetadataReloadTask(indexDef);
        return reloadTask == null
               ? Futures.immediateFuture(null)
               : blockingExecutor.submit(reloadTask);
    }

    private Future createIndex(IndexMetadata indexDef)
    {
        Index index = createInstance(indexDef);
        index.register(this);

        // if the index didn't register itself, we can probably assume that no initialization needs to happen
        final Callable initialBuildTask = indexes.containsKey(indexDef.name)
                                           ? index.getInitializationTask()
                                           : null;
        if (initialBuildTask == null)
        {
            // We need to make sure that the index is marked as built in the case where the initialBuildTask
            // does not need to be run (if the index didn't register itself or if the base table was empty).
            markIndexBuilt(indexDef.name);
            return Futures.immediateFuture(null);
        }
        return asyncExecutor.submit(index.getInitializationTask());
    }

    /**
     * Adds and builds a index
     * @param indexDef the IndexMetadata describing the index
     */
    public synchronized Future addIndex(IndexMetadata indexDef)
    {
        if (indexes.containsKey(indexDef.name))
            return reloadIndex(indexDef);
        else
            return createIndex(indexDef);
    }

    /**
     * Checks if the specified index is queryable.
     *
     * @param index the index
     * @return true if the specified index is queryable, false otherwise
     */
    public boolean isIndexQueryable(Index index)
    {
        return builtIndexes.contains(index.getIndexMetadata().name);
    }

    public synchronized void removeIndex(String indexName)
    {
        Index index = unregisterIndex(indexName);
        if (null != index)
        {
            markIndexRemoved(indexName);
            executeBlocking(index.getInvalidateTask());
        }
    }


    public Set getDependentIndexes(ColumnDefinition column)
    {
        if (indexes.isEmpty())
            return Collections.emptySet();

        Set dependentIndexes = new HashSet<>();
        for (Index index : indexes.values())
            if (index.dependsOn(column))
                dependentIndexes.add(index.getIndexMetadata());

        return dependentIndexes;
    }

    /**
     * Called when dropping a Table
     */
    public void markAllIndexesRemoved()
    {
       getBuiltIndexNames().forEach(this::markIndexRemoved);
    }

    /**
    * Does a full, blocking rebuild of the indexes specified by columns from the sstables.
    * Caller must acquire and release references to the sstables used here.
    * Note also that only this method of (re)building indexes:
    *   a) takes a set of index *names* rather than Indexers
    *   b) marks exsiting indexes removed prior to rebuilding
    *
    * @param sstables the data to build from
    * @param indexNames the list of indexes to be rebuilt
    */
    public void rebuildIndexesBlocking(Collection sstables, Set indexNames)
    {
        Set toRebuild = indexes.values().stream()
                                               .filter(index -> indexNames.contains(index.getIndexMetadata().name))
                                               .filter(Index::shouldBuildBlocking)
                                               .collect(Collectors.toSet());
        if (toRebuild.isEmpty())
        {
            logger.info("No defined indexes with the supplied names: {}", Joiner.on(',').join(indexNames));
            return;
        }

        toRebuild.forEach(indexer -> markIndexRemoved(indexer.getIndexMetadata().name));

        buildIndexesBlocking(sstables, toRebuild);

        toRebuild.forEach(indexer -> markIndexBuilt(indexer.getIndexMetadata().name));
    }

    public void buildAllIndexesBlocking(Collection sstables)
    {
        buildIndexesBlocking(sstables, indexes.values()
                                              .stream()
                                              .filter(Index::shouldBuildBlocking)
                                              .collect(Collectors.toSet()));
    }

    // For convenience, may be called directly from Index impls
    public void buildIndexBlocking(Index index)
    {
        if (index.shouldBuildBlocking())
        {
            try (ColumnFamilyStore.RefViewFragment viewFragment = baseCfs.selectAndReference(View.selectFunction(SSTableSet.CANONICAL));
                 Refs sstables = viewFragment.refs)
            {
                buildIndexesBlocking(sstables, Collections.singleton(index));
                markIndexBuilt(index.getIndexMetadata().name);
            }
        }
    }

    /**
     * Checks if the specified {@link ColumnFamilyStore} is a secondary index.
     *
     * @param cfs the ColumnFamilyStore to check.
     * @return true if the specified ColumnFamilyStore is a secondary index,
     * false otherwise.
     */
    public static boolean isIndexColumnFamilyStore(ColumnFamilyStore cfs)
    {
        return isIndexColumnFamily(cfs.name);
    }

    /**
     * Checks if the specified {@link ColumnFamilyStore} is the one secondary index.
     *
     * @param cfName the name of the ColumnFamilyStore to check.
     * @return true if the specified ColumnFamilyStore is a secondary index,
     * false otherwise.
     */
    public static boolean isIndexColumnFamily(String cfName)
    {
        return cfName.contains(Directories.SECONDARY_INDEX_NAME_SEPARATOR);
    }

    /**
     * Returns the parent of the specified {@link ColumnFamilyStore}.
     *
     * @param cfs the ColumnFamilyStore
     * @return the parent of the specified ColumnFamilyStore
     */
    public static ColumnFamilyStore getParentCfs(ColumnFamilyStore cfs)
    {
        String parentCfs = getParentCfsName(cfs.name);
        return cfs.keyspace.getColumnFamilyStore(parentCfs);
    }

    /**
     * Returns the parent name of the specified {@link ColumnFamilyStore}.
     *
     * @param cfName the ColumnFamilyStore name
     * @return the parent name of the specified ColumnFamilyStore
     */
    public static String getParentCfsName(String cfName)
    {
        assert isIndexColumnFamily(cfName);
        return StringUtils.substringBefore(cfName, Directories.SECONDARY_INDEX_NAME_SEPARATOR);
    }

    /**
     * Returns the index name
     *
     * @param cfs the ColumnFamilyStore
     * @return the index name
     */
    public static String getIndexName(ColumnFamilyStore cfs)
    {
        return getIndexName(cfs.name);
    }

    /**
     * Returns the index name
     *
     * @param cfName the ColumnFamilyStore name
     * @return the index name
     */
    public static String getIndexName(String cfName)
    {
        assert isIndexColumnFamily(cfName);
        return StringUtils.substringAfter(cfName, Directories.SECONDARY_INDEX_NAME_SEPARATOR);
    }

    private void buildIndexesBlocking(Collection sstables, Set indexes)
    {
        if (indexes.isEmpty())
            return;

        logger.info("Submitting index build of {} for data in {}",
                    indexes.stream().map(i -> i.getIndexMetadata().name).collect(Collectors.joining(",")),
                    sstables.stream().map(SSTableReader::toString).collect(Collectors.joining(",")));

        SecondaryIndexBuilder builder = new SecondaryIndexBuilder(baseCfs,
                                                                  indexes,
                                                                  new ReducingKeyIterator(sstables));
        Future future = CompactionManager.instance.submitIndexBuild(builder);
        FBUtilities.waitOnFuture(future);

        flushIndexesBlocking(indexes);
        logger.info("Index build of {} complete",
                    indexes.stream().map(i -> i.getIndexMetadata().name).collect(Collectors.joining(",")));
    }

    /**
     * Marks the specified index as build.
     * 

This method is public as it need to be accessible from the {@link Index} implementations

* @param indexName the index name */ public void markIndexBuilt(String indexName) { builtIndexes.add(indexName); if (DatabaseDescriptor.isDaemonInitialized()) SystemKeyspace.setIndexBuilt(baseCfs.keyspace.getName(), indexName); } /** * Marks the specified index as removed. *

This method is public as it need to be accessible from the {@link Index} implementations

* @param indexName the index name */ public void markIndexRemoved(String indexName) { SystemKeyspace.setIndexRemoved(baseCfs.keyspace.getName(), indexName); } public Index getIndexByName(String indexName) { return indexes.get(indexName); } private Index createInstance(IndexMetadata indexDef) { Index newIndex; if (indexDef.isCustom()) { assert indexDef.options != null; String className = indexDef.options.get(IndexTarget.CUSTOM_INDEX_OPTION_NAME); assert ! Strings.isNullOrEmpty(className); try { Class indexClass = FBUtilities.classForName(className, "Index"); Constructor ctor = indexClass.getConstructor(ColumnFamilyStore.class, IndexMetadata.class); newIndex = (Index)ctor.newInstance(baseCfs, indexDef); } catch (Exception e) { throw new RuntimeException(e); } } else { newIndex = CassandraIndex.newIndex(baseCfs, indexDef); } return newIndex; } /** * Truncate all indexes */ public void truncateAllIndexesBlocking(final long truncatedAt) { executeAllBlocking(indexes.values().stream(), (index) -> index.getTruncateTask(truncatedAt)); } /** * Remove all indexes */ public void invalidateAllIndexesBlocking() { markAllIndexesRemoved(); executeAllBlocking(indexes.values().stream(), Index::getInvalidateTask); } /** * Perform a blocking flush all indexes */ public void flushAllIndexesBlocking() { flushIndexesBlocking(ImmutableSet.copyOf(indexes.values())); } /** * Perform a blocking flush of selected indexes */ public void flushIndexesBlocking(Set indexes) { if (indexes.isEmpty()) return; List> wait = new ArrayList<>(); List nonCfsIndexes = new ArrayList<>(); // for each CFS backed index, submit a flush task which we'll wait on for completion // for the non-CFS backed indexes, we'll flush those while we wait. synchronized (baseCfs.getTracker()) { indexes.forEach(index -> index.getBackingTable() .map(cfs -> wait.add(cfs.forceFlush())) .orElseGet(() -> nonCfsIndexes.add(index))); } executeAllBlocking(nonCfsIndexes.stream(), Index::getBlockingFlushTask); FBUtilities.waitOnFutures(wait); } /** * Performs a blocking flush of all custom indexes */ public void flushAllNonCFSBackedIndexesBlocking() { executeAllBlocking(indexes.values() .stream() .filter(index -> !index.getBackingTable().isPresent()), Index::getBlockingFlushTask); } /** * @return all indexes which are marked as built and ready to use */ public List getBuiltIndexNames() { Set allIndexNames = new HashSet<>(); indexes.values().stream() .map(i -> i.getIndexMetadata().name) .forEach(allIndexNames::add); return SystemKeyspace.getBuiltIndexes(baseCfs.keyspace.getName(), allIndexNames); } /** * @return all backing Tables used by registered indexes */ public Set getAllIndexColumnFamilyStores() { Set backingTables = new HashSet<>(); indexes.values().forEach(index -> index.getBackingTable().ifPresent(backingTables::add)); return backingTables; } /** * @return if there are ANY indexes registered for this table */ public boolean hasIndexes() { return !indexes.isEmpty(); } /** * When building an index against existing data in sstables, add the given partition to the index */ public void indexPartition(DecoratedKey key, Set indexes, int pageSize) { if (logger.isTraceEnabled()) logger.trace("Indexing partition {}", baseCfs.metadata.getKeyValidator().getString(key.getKey())); if (!indexes.isEmpty()) { SinglePartitionReadCommand cmd = SinglePartitionReadCommand.fullPartitionRead(baseCfs.metadata, FBUtilities.nowInSeconds(), key); int nowInSec = cmd.nowInSec(); boolean readStatic = false; SinglePartitionPager pager = new SinglePartitionPager(cmd, null, Server.CURRENT_VERSION); while (!pager.isExhausted()) { try (ReadOrderGroup readGroup = cmd.startOrderGroup(); OpOrder.Group writeGroup = Keyspace.writeOrder.start(); UnfilteredPartitionIterator page = pager.fetchPageUnfiltered(baseCfs.metadata, pageSize, readGroup)) { if (!page.hasNext()) break; try (UnfilteredRowIterator partition = page.next()) { Set indexers = indexes.stream() .map(index -> index.indexerFor(key, partition.columns(), nowInSec, writeGroup, IndexTransaction.Type.UPDATE)) .filter(Objects::nonNull) .collect(Collectors.toSet()); // Short-circuit empty partitions if static row is processed or isn't read if (!readStatic && partition.isEmpty() && partition.staticRow().isEmpty()) break; indexers.forEach(Index.Indexer::begin); if (!readStatic) { if (!partition.staticRow().isEmpty()) indexers.forEach(indexer -> indexer.insertRow(partition.staticRow())); indexers.forEach((Index.Indexer i) -> i.partitionDelete(partition.partitionLevelDeletion())); readStatic = true; } MutableDeletionInfo.Builder deletionBuilder = MutableDeletionInfo.builder(partition.partitionLevelDeletion(), baseCfs.getComparator(), false); while (partition.hasNext()) { Unfiltered unfilteredRow = partition.next(); if (unfilteredRow.isRow()) { Row row = (Row) unfilteredRow; indexers.forEach(indexer -> indexer.insertRow(row)); } else { assert unfilteredRow.isRangeTombstoneMarker(); RangeTombstoneMarker marker = (RangeTombstoneMarker) unfilteredRow; deletionBuilder.add(marker); } } MutableDeletionInfo deletionInfo = deletionBuilder.build(); if (deletionInfo.hasRanges()) { Iterator iter = deletionInfo.rangeIterator(false); while (iter.hasNext()) { RangeTombstone rt = iter.next(); indexers.forEach(indexer -> indexer.rangeTombstone(rt)); } } indexers.forEach(Index.Indexer::finish); } } } } } /** * Return the page size used when indexing an entire partition */ public int calculateIndexingPageSize() { if (Boolean.getBoolean("cassandra.force_default_indexing_page_size")) return DEFAULT_PAGE_SIZE; double targetPageSizeInBytes = 32 * 1024 * 1024; double meanPartitionSize = baseCfs.getMeanPartitionSize(); if (meanPartitionSize <= 0) return DEFAULT_PAGE_SIZE; int meanCellsPerPartition = baseCfs.getMeanColumns(); if (meanCellsPerPartition <= 0) return DEFAULT_PAGE_SIZE; int columnsPerRow = baseCfs.metadata.partitionColumns().regulars.size(); if (columnsPerRow <= 0) return DEFAULT_PAGE_SIZE; int meanRowsPerPartition = meanCellsPerPartition / columnsPerRow; double meanRowSize = meanPartitionSize / meanRowsPerPartition; int pageSize = (int) Math.max(1, Math.min(DEFAULT_PAGE_SIZE, targetPageSizeInBytes / meanRowSize)); logger.trace("Calculated page size {} for indexing {}.{} ({}/{}/{}/{})", pageSize, baseCfs.metadata.ksName, baseCfs.metadata.cfName, meanPartitionSize, meanCellsPerPartition, meanRowsPerPartition, meanRowSize); return pageSize; } /** * Delete all data from all indexes for this partition. * For when cleanup rips a partition out entirely. * * TODO : improve cleanup transaction to batch updates & perform them async */ public void deletePartition(UnfilteredRowIterator partition, int nowInSec) { // we need to acquire memtable lock because secondary index deletion may // cause a race (see CASSANDRA-3712). This is done internally by the // index transaction when it commits CleanupTransaction indexTransaction = newCleanupTransaction(partition.partitionKey(), partition.columns(), nowInSec); indexTransaction.start(); indexTransaction.onPartitionDeletion(new DeletionTime(FBUtilities.timestampMicros(), nowInSec)); indexTransaction.commit(); while (partition.hasNext()) { Unfiltered unfiltered = partition.next(); if (unfiltered.kind() != Unfiltered.Kind.ROW) continue; indexTransaction = newCleanupTransaction(partition.partitionKey(), partition.columns(), nowInSec); indexTransaction.start(); indexTransaction.onRowDelete((Row)unfiltered); indexTransaction.commit(); } } /** * Called at query time to choose which (if any) of the registered index implementations to use for a given query. * * This is a two step processes, firstly compiling the set of searchable indexes then choosing the one which reduces * the search space the most. * * In the first phase, if the command's RowFilter contains any custom index expressions, the indexes that they * specify are automatically included. Following that, the registered indexes are filtered to include only those * which support the standard expressions in the RowFilter. * * The filtered set then sorted by selectivity, as reported by the Index implementations' getEstimatedResultRows * method. * * Implementation specific validation of the target expression, either custom or standard, by the selected * index should be performed in the searcherFor method to ensure that we pick the right index regardless of * the validity of the expression. * * This method is only called once during the lifecycle of a ReadCommand and the result is * cached for future use when obtaining a Searcher, getting the index's underlying CFS for * ReadOrderGroup, or an estimate of the result size from an average index query. * * @param rowFilter RowFilter of the command to be executed * @return an Index instance, ready to use during execution of the command, or null if none * of the registered indexes can support the command. */ public Index getBestIndexFor(RowFilter rowFilter) { if (indexes.isEmpty() || rowFilter.isEmpty()) return null; Set searchableIndexes = new HashSet<>(); for (RowFilter.Expression expression : rowFilter) { if (expression.isCustom()) { // Only a single custom expression is allowed per query and, if present, // we want to always favour the index specified in such an expression RowFilter.CustomExpression customExpression = (RowFilter.CustomExpression)expression; logger.trace("Command contains a custom index expression, using target index {}", customExpression.getTargetIndex().name); Tracing.trace("Command contains a custom index expression, using target index {}", customExpression.getTargetIndex().name); return indexes.get(customExpression.getTargetIndex().name); } else { indexes.values().stream() .filter(index -> index.supportsExpression(expression.column(), expression.operator())) .forEach(searchableIndexes::add); } } if (searchableIndexes.isEmpty()) { logger.trace("No applicable indexes found"); Tracing.trace("No applicable indexes found"); return null; } Index selected = searchableIndexes.size() == 1 ? Iterables.getOnlyElement(searchableIndexes) : searchableIndexes.stream() .min((a, b) -> Longs.compare(a.getEstimatedResultRows(), b.getEstimatedResultRows())) .orElseThrow(() -> new AssertionError("Could not select most selective index")); // pay for an additional threadlocal get() rather than build the strings unnecessarily if (Tracing.isTracing()) { Tracing.trace("Index mean cardinalities are {}. Scanning with {}.", searchableIndexes.stream().map(i -> i.getIndexMetadata().name + ':' + i.getEstimatedResultRows()) .collect(Collectors.joining(",")), selected.getIndexMetadata().name); } return selected; } /** * Called at write time to ensure that values present in the update * are valid according to the rules of all registered indexes which * will process it. The partition key as well as the clustering and * cell values for each row in the update may be checked by index * implementations * @param update PartitionUpdate containing the values to be validated by registered Index implementations * @throws InvalidRequestException */ public void validate(PartitionUpdate update) throws InvalidRequestException { for (Index index : indexes.values()) index.validate(update); } /** * IndexRegistry methods */ public void registerIndex(Index index) { String name = index.getIndexMetadata().name; indexes.put(name, index); logger.trace("Registered index {}", name); } public void unregisterIndex(Index index) { unregisterIndex(index.getIndexMetadata().name); } private Index unregisterIndex(String name) { Index removed = indexes.remove(name); builtIndexes.remove(name); logger.trace(removed == null ? "Index {} was not registered" : "Removed index {} from registry", name); return removed; } public Index getIndex(IndexMetadata metadata) { return indexes.get(metadata.name); } public Collection listIndexes() { return ImmutableSet.copyOf(indexes.values()); } /** * Handling of index updates. * Implementations of the various IndexTransaction interfaces, for keeping indexes in sync with base data * during updates, compaction and cleanup. Plus factory methods for obtaining transaction instances. */ /** * Transaction for updates on the write path. */ public UpdateTransaction newUpdateTransaction(PartitionUpdate update, OpOrder.Group opGroup, int nowInSec) { if (!hasIndexes()) return UpdateTransaction.NO_OP; Index.Indexer[] indexers = indexes.values().stream() .map(i -> i.indexerFor(update.partitionKey(), update.columns(), nowInSec, opGroup, IndexTransaction.Type.UPDATE)) .filter(Objects::nonNull) .toArray(Index.Indexer[]::new); return indexers.length == 0 ? UpdateTransaction.NO_OP : new WriteTimeTransaction(indexers); } /** * Transaction for use when merging rows during compaction */ public CompactionTransaction newCompactionTransaction(DecoratedKey key, PartitionColumns partitionColumns, int versions, int nowInSec) { // the check for whether there are any registered indexes is already done in CompactionIterator return new IndexGCTransaction(key, partitionColumns, versions, nowInSec, listIndexes()); } /** * Transaction for use when removing partitions during cleanup */ public CleanupTransaction newCleanupTransaction(DecoratedKey key, PartitionColumns partitionColumns, int nowInSec) { if (!hasIndexes()) return CleanupTransaction.NO_OP; return new CleanupGCTransaction(key, partitionColumns, nowInSec, listIndexes()); } /** * A single use transaction for processing a partition update on the regular write path */ private static final class WriteTimeTransaction implements UpdateTransaction { private final Index.Indexer[] indexers; private WriteTimeTransaction(Index.Indexer...indexers) { // don't allow null indexers, if we don't need any use a NullUpdater object for (Index.Indexer indexer : indexers) assert indexer != null; this.indexers = indexers; } public void start() { for (Index.Indexer indexer : indexers) indexer.begin(); } public void onPartitionDeletion(DeletionTime deletionTime) { for (Index.Indexer indexer : indexers) indexer.partitionDelete(deletionTime); } public void onRangeTombstone(RangeTombstone tombstone) { for (Index.Indexer indexer : indexers) indexer.rangeTombstone(tombstone); } public void onInserted(Row row) { for (Index.Indexer indexer : indexers) indexer.insertRow(row); } public void onUpdated(Row existing, Row updated) { final Row.Builder toRemove = BTreeRow.sortedBuilder(); toRemove.newRow(existing.clustering()); toRemove.addPrimaryKeyLivenessInfo(existing.primaryKeyLivenessInfo()); toRemove.addRowDeletion(existing.deletion()); final Row.Builder toInsert = BTreeRow.sortedBuilder(); toInsert.newRow(updated.clustering()); toInsert.addPrimaryKeyLivenessInfo(updated.primaryKeyLivenessInfo()); toInsert.addRowDeletion(updated.deletion()); // diff listener collates the columns to be added & removed from the indexes RowDiffListener diffListener = new RowDiffListener() { public void onPrimaryKeyLivenessInfo(int i, Clustering clustering, LivenessInfo merged, LivenessInfo original) { } public void onDeletion(int i, Clustering clustering, Row.Deletion merged, Row.Deletion original) { } public void onComplexDeletion(int i, Clustering clustering, ColumnDefinition column, DeletionTime merged, DeletionTime original) { } public void onCell(int i, Clustering clustering, Cell merged, Cell original) { if (merged != null && !merged.equals(original)) toInsert.addCell(merged); if (merged == null || (original != null && shouldCleanupOldValue(original, merged))) toRemove.addCell(original); } }; Rows.diff(diffListener, updated, existing); Row oldRow = toRemove.build(); Row newRow = toInsert.build(); for (Index.Indexer indexer : indexers) indexer.updateRow(oldRow, newRow); } public void commit() { for (Index.Indexer indexer : indexers) indexer.finish(); } private boolean shouldCleanupOldValue(Cell oldCell, Cell newCell) { // If either the value or timestamp is different, then we // should delete from the index. If not, then we can infer that // at least one of the cells is an ExpiringColumn and that the // difference is in the expiry time. In this case, we don't want to // delete the old value from the index as the tombstone we insert // will just hide the inserted value. // Completely identical cells (including expiring columns with // identical ttl & localExpirationTime) will not get this far due // to the oldCell.equals(newCell) in StandardUpdater.update return !oldCell.value().equals(newCell.value()) || oldCell.timestamp() != newCell.timestamp(); } } /** * A single-use transaction for updating indexes for a single partition during compaction where the only * operation is to merge rows * TODO : make this smarter at batching updates so we can use a single transaction to process multiple rows in * a single partition */ private static final class IndexGCTransaction implements CompactionTransaction { private final DecoratedKey key; private final PartitionColumns columns; private final int versions; private final int nowInSec; private final Collection indexes; private Row[] rows; private IndexGCTransaction(DecoratedKey key, PartitionColumns columns, int versions, int nowInSec, Collection indexes) { this.key = key; this.columns = columns; this.versions = versions; this.indexes = indexes; this.nowInSec = nowInSec; } public void start() { if (versions > 0) rows = new Row[versions]; } public void onRowMerge(Row merged, Row...versions) { // Diff listener constructs rows representing deltas between the merged and original versions // These delta rows are then passed to registered indexes for removal processing final Row.Builder[] builders = new Row.Builder[versions.length]; RowDiffListener diffListener = new RowDiffListener() { public void onPrimaryKeyLivenessInfo(int i, Clustering clustering, LivenessInfo merged, LivenessInfo original) { if (original != null && (merged == null || !merged.isLive(nowInSec))) getBuilder(i, clustering).addPrimaryKeyLivenessInfo(original); } public void onDeletion(int i, Clustering clustering, Row.Deletion merged, Row.Deletion original) { } public void onComplexDeletion(int i, Clustering clustering, ColumnDefinition column, DeletionTime merged, DeletionTime original) { } public void onCell(int i, Clustering clustering, Cell merged, Cell original) { if (original != null && (merged == null || !merged.isLive(nowInSec))) getBuilder(i, clustering).addCell(original); } private Row.Builder getBuilder(int index, Clustering clustering) { if (builders[index] == null) { builders[index] = BTreeRow.sortedBuilder(); builders[index].newRow(clustering); } return builders[index]; } }; Rows.diff(diffListener, merged, versions); for(int i = 0; i < builders.length; i++) if (builders[i] != null) rows[i] = builders[i].build(); } public void commit() { if (rows == null) return; try (OpOrder.Group opGroup = Keyspace.writeOrder.start()) { for (Index index : indexes) { Index.Indexer indexer = index.indexerFor(key, columns, nowInSec, opGroup, Type.COMPACTION); if (indexer == null) continue; indexer.begin(); for (Row row : rows) if (row != null) indexer.removeRow(row); indexer.finish(); } } } } /** * A single-use transaction for updating indexes for a single partition during cleanup, where * partitions and rows are only removed * TODO : make this smarter at batching updates so we can use a single transaction to process multiple rows in * a single partition */ private static final class CleanupGCTransaction implements CleanupTransaction { private final DecoratedKey key; private final PartitionColumns columns; private final int nowInSec; private final Collection indexes; private Row row; private DeletionTime partitionDelete; private CleanupGCTransaction(DecoratedKey key, PartitionColumns columns, int nowInSec, Collection indexes) { this.key = key; this.columns = columns; this.indexes = indexes; this.nowInSec = nowInSec; } public void start() { } public void onPartitionDeletion(DeletionTime deletionTime) { partitionDelete = deletionTime; } public void onRowDelete(Row row) { this.row = row; } public void commit() { if (row == null && partitionDelete == null) return; try (OpOrder.Group opGroup = Keyspace.writeOrder.start()) { for (Index index : indexes) { Index.Indexer indexer = index.indexerFor(key, columns, nowInSec, opGroup, Type.CLEANUP); if (indexer == null) continue; indexer.begin(); if (partitionDelete != null) indexer.partitionDelete(partitionDelete); if (row != null) indexer.removeRow(row); indexer.finish(); } } } } private static void executeBlocking(Callable task) { if (null != task) FBUtilities.waitOnFuture(blockingExecutor.submit(task)); } private static void executeAllBlocking(Stream indexers, Function> function) { List> waitFor = new ArrayList<>(); indexers.forEach(indexer -> { Callable task = function.apply(indexer); if (null != task) waitFor.add(blockingExecutor.submit(task)); }); FBUtilities.waitOnFutures(waitFor); } @VisibleForTesting public static void shutdownAndWait(long timeout, TimeUnit unit) throws InterruptedException, TimeoutException { ExecutorService[] executors = new ExecutorService[]{ asyncExecutor, blockingExecutor }; shutdown(executors); awaitTermination(timeout, unit, executors); } }




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