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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.hadoop.hbase.regionserver;

import java.io.IOException;
import java.io.InterruptedIOException;
import java.net.InetSocketAddress;
import java.util.ArrayList;
import java.util.Collection;
import java.util.Collections;
import java.util.HashMap;
import java.util.HashSet;
import java.util.Iterator;
import java.util.List;
import java.util.Map;
import java.util.Map.Entry;
import java.util.NavigableSet;
import java.util.Optional;
import java.util.OptionalDouble;
import java.util.OptionalInt;
import java.util.OptionalLong;
import java.util.Set;
import java.util.concurrent.Callable;
import java.util.concurrent.CompletionService;
import java.util.concurrent.ConcurrentHashMap;
import java.util.concurrent.ExecutionException;
import java.util.concurrent.ExecutorCompletionService;
import java.util.concurrent.Future;
import java.util.concurrent.ThreadPoolExecutor;
import java.util.concurrent.atomic.AtomicBoolean;
import java.util.concurrent.atomic.AtomicInteger;
import java.util.concurrent.atomic.AtomicLong;
import java.util.concurrent.atomic.LongAdder;
import java.util.concurrent.locks.ReentrantLock;
import java.util.concurrent.locks.ReentrantReadWriteLock;
import java.util.function.Predicate;
import java.util.function.ToLongFunction;
import java.util.stream.Collectors;
import java.util.stream.LongStream;

import org.apache.hadoop.conf.Configuration;
import org.apache.hadoop.fs.FileSystem;
import org.apache.hadoop.fs.Path;
import org.apache.hadoop.fs.permission.FsAction;
import org.apache.hadoop.hbase.Cell;
import org.apache.hadoop.hbase.CellComparator;
import org.apache.hadoop.hbase.CellUtil;
import org.apache.hadoop.hbase.CompoundConfiguration;
import org.apache.hadoop.hbase.HConstants;
import org.apache.hadoop.hbase.MemoryCompactionPolicy;
import org.apache.hadoop.hbase.TableName;
import org.apache.hadoop.hbase.backup.FailedArchiveException;
import org.apache.hadoop.hbase.client.ColumnFamilyDescriptor;
import org.apache.hadoop.hbase.client.RegionInfo;
import org.apache.hadoop.hbase.client.Scan;
import org.apache.hadoop.hbase.conf.ConfigurationManager;
import org.apache.hadoop.hbase.conf.PropagatingConfigurationObserver;
import org.apache.hadoop.hbase.io.HeapSize;
import org.apache.hadoop.hbase.io.compress.Compression;
import org.apache.hadoop.hbase.io.crypto.Encryption;
import org.apache.hadoop.hbase.io.hfile.CacheConfig;
import org.apache.hadoop.hbase.io.hfile.HFile;
import org.apache.hadoop.hbase.io.hfile.HFileContext;
import org.apache.hadoop.hbase.io.hfile.HFileContextBuilder;
import org.apache.hadoop.hbase.io.hfile.HFileDataBlockEncoder;
import org.apache.hadoop.hbase.io.hfile.HFileDataBlockEncoderImpl;
import org.apache.hadoop.hbase.io.hfile.HFileScanner;
import org.apache.hadoop.hbase.io.hfile.InvalidHFileException;
import org.apache.hadoop.hbase.log.HBaseMarkers;
import org.apache.hadoop.hbase.monitoring.MonitoredTask;
import org.apache.hadoop.hbase.quotas.RegionSizeStore;
import org.apache.hadoop.hbase.regionserver.compactions.CompactionContext;
import org.apache.hadoop.hbase.regionserver.compactions.CompactionLifeCycleTracker;
import org.apache.hadoop.hbase.regionserver.compactions.CompactionProgress;
import org.apache.hadoop.hbase.regionserver.compactions.CompactionRequestImpl;
import org.apache.hadoop.hbase.regionserver.compactions.DefaultCompactor;
import org.apache.hadoop.hbase.regionserver.compactions.OffPeakHours;
import org.apache.hadoop.hbase.regionserver.querymatcher.ScanQueryMatcher;
import org.apache.hadoop.hbase.regionserver.throttle.ThroughputController;
import org.apache.hadoop.hbase.regionserver.wal.WALUtil;
import org.apache.hadoop.hbase.security.EncryptionUtil;
import org.apache.hadoop.hbase.security.User;
import org.apache.hadoop.hbase.util.Bytes;
import org.apache.hadoop.hbase.util.ClassSize;
import org.apache.hadoop.hbase.util.CommonFSUtils;
import org.apache.hadoop.hbase.util.EnvironmentEdgeManager;
import org.apache.hadoop.hbase.util.Pair;
import org.apache.hadoop.hbase.util.ReflectionUtils;
import org.apache.hadoop.util.StringUtils;
import org.apache.hadoop.util.StringUtils.TraditionalBinaryPrefix;
import org.apache.yetus.audience.InterfaceAudience;
import org.slf4j.Logger;
import org.slf4j.LoggerFactory;

import org.apache.hbase.thirdparty.com.google.common.base.Preconditions;
import org.apache.hbase.thirdparty.com.google.common.collect.ImmutableCollection;
import org.apache.hbase.thirdparty.com.google.common.collect.ImmutableList;
import org.apache.hbase.thirdparty.com.google.common.collect.Lists;
import org.apache.hbase.thirdparty.com.google.common.collect.Maps;
import org.apache.hbase.thirdparty.com.google.common.collect.Sets;
import org.apache.hbase.thirdparty.org.apache.commons.collections4.CollectionUtils;
import org.apache.hbase.thirdparty.org.apache.commons.collections4.IterableUtils;

import org.apache.hadoop.hbase.shaded.protobuf.ProtobufUtil;
import org.apache.hadoop.hbase.shaded.protobuf.generated.WALProtos.CompactionDescriptor;

/**
 * A Store holds a column family in a Region.  Its a memstore and a set of zero
 * or more StoreFiles, which stretch backwards over time.
 *
 * 

There's no reason to consider append-logging at this level; all logging * and locking is handled at the HRegion level. Store just provides * services to manage sets of StoreFiles. One of the most important of those * services is compaction services where files are aggregated once they pass * a configurable threshold. * *

Locking and transactions are handled at a higher level. This API should * not be called directly but by an HRegion manager. */ @InterfaceAudience.Private public class HStore implements Store, HeapSize, StoreConfigInformation, PropagatingConfigurationObserver { public static final String MEMSTORE_CLASS_NAME = "hbase.regionserver.memstore.class"; public static final String COMPACTCHECKER_INTERVAL_MULTIPLIER_KEY = "hbase.server.compactchecker.interval.multiplier"; public static final String BLOCKING_STOREFILES_KEY = "hbase.hstore.blockingStoreFiles"; public static final String BLOCK_STORAGE_POLICY_KEY = "hbase.hstore.block.storage.policy"; // keep in accordance with HDFS default storage policy public static final String DEFAULT_BLOCK_STORAGE_POLICY = "HOT"; public static final int DEFAULT_COMPACTCHECKER_INTERVAL_MULTIPLIER = 1000; public static final int DEFAULT_BLOCKING_STOREFILE_COUNT = 16; // HBASE-24428 : Update compaction priority for recently split daughter regions // so as to prioritize their compaction. // Any compaction candidate with higher priority than compaction of newly split daugher regions // should have priority value < (Integer.MIN_VALUE + 1000) private static final int SPLIT_REGION_COMPACTION_PRIORITY = Integer.MIN_VALUE + 1000; private static final Logger LOG = LoggerFactory.getLogger(HStore.class); protected final MemStore memstore; // This stores directory in the filesystem. private final HRegion region; protected Configuration conf; private long lastCompactSize = 0; volatile boolean forceMajor = false; /* how many bytes to write between status checks */ static int closeCheckInterval = 0; private AtomicLong storeSize = new AtomicLong(); private AtomicLong totalUncompressedBytes = new AtomicLong(); private LongAdder memstoreOnlyRowReadsCount = new LongAdder(); // rows that has cells from both memstore and files (or only files) private LongAdder mixedRowReadsCount = new LongAdder(); private boolean cacheOnWriteLogged; /** * RWLock for store operations. * Locked in shared mode when the list of component stores is looked at: * - all reads/writes to table data * - checking for split * Locked in exclusive mode when the list of component stores is modified: * - closing * - completing a compaction */ final ReentrantReadWriteLock lock = new ReentrantReadWriteLock(); /** * Lock specific to archiving compacted store files. This avoids races around * the combination of retrieving the list of compacted files and moving them to * the archive directory. Since this is usually a background process (other than * on close), we don't want to handle this with the store write lock, which would * block readers and degrade performance. * * Locked by: * - CompactedHFilesDispatchHandler via closeAndArchiveCompactedFiles() * - close() */ final ReentrantLock archiveLock = new ReentrantLock(); private final boolean verifyBulkLoads; /** * Use this counter to track concurrent puts. If TRACE-log is enabled, if we are over the * threshold set by hbase.region.store.parallel.put.print.threshold (Default is 50) we will * log a message that identifies the Store experience this high-level of concurrency. */ private final AtomicInteger currentParallelPutCount = new AtomicInteger(0); private final int parallelPutCountPrintThreshold; private ScanInfo scanInfo; // All access must be synchronized. // TODO: ideally, this should be part of storeFileManager, as we keep passing this to it. private final List filesCompacting = Lists.newArrayList(); // All access must be synchronized. private final Set changedReaderObservers = Collections.newSetFromMap(new ConcurrentHashMap()); private HFileDataBlockEncoder dataBlockEncoder; final StoreEngine storeEngine; private static final AtomicBoolean offPeakCompactionTracker = new AtomicBoolean(); private volatile OffPeakHours offPeakHours; private static final int DEFAULT_FLUSH_RETRIES_NUMBER = 10; private int flushRetriesNumber; private int pauseTime; private long blockingFileCount; private int compactionCheckMultiplier; private AtomicLong flushedCellsCount = new AtomicLong(); private AtomicLong compactedCellsCount = new AtomicLong(); private AtomicLong majorCompactedCellsCount = new AtomicLong(); private AtomicLong flushedCellsSize = new AtomicLong(); private AtomicLong flushedOutputFileSize = new AtomicLong(); private AtomicLong compactedCellsSize = new AtomicLong(); private AtomicLong majorCompactedCellsSize = new AtomicLong(); private final StoreContext storeContext; /** * Constructor * @param family HColumnDescriptor for this column * @param confParam configuration object failed. Can be null. */ protected HStore(final HRegion region, final ColumnFamilyDescriptor family, final Configuration confParam, boolean warmup) throws IOException { // 'conf' renamed to 'confParam' b/c we use this.conf in the constructor // CompoundConfiguration will look for keys in reverse order of addition, so we'd // add global config first, then table and cf overrides, then cf metadata. this.conf = new CompoundConfiguration() .add(confParam) .addBytesMap(region.getTableDescriptor().getValues()) .addStringMap(family.getConfiguration()) .addBytesMap(family.getValues()); this.region = region; this.storeContext = initializeStoreContext(family); // Assemble the store's home directory and Ensure it exists. region.getRegionFileSystem().createStoreDir(family.getNameAsString()); // set block storage policy for store directory String policyName = family.getStoragePolicy(); if (null == policyName) { policyName = this.conf.get(BLOCK_STORAGE_POLICY_KEY, DEFAULT_BLOCK_STORAGE_POLICY); } region.getRegionFileSystem().setStoragePolicy(family.getNameAsString(), policyName.trim()); this.dataBlockEncoder = new HFileDataBlockEncoderImpl(family.getDataBlockEncoding()); // used by ScanQueryMatcher long timeToPurgeDeletes = Math.max(conf.getLong("hbase.hstore.time.to.purge.deletes", 0), 0); LOG.trace("Time to purge deletes set to {}ms in {}", timeToPurgeDeletes, this); // Get TTL long ttl = determineTTLFromFamily(family); // Why not just pass a HColumnDescriptor in here altogether? Even if have // to clone it? scanInfo = new ScanInfo(conf, family, ttl, timeToPurgeDeletes, region.getCellComparator()); this.memstore = getMemstore(); this.offPeakHours = OffPeakHours.getInstance(conf); this.verifyBulkLoads = conf.getBoolean("hbase.hstore.bulkload.verify", false); this.blockingFileCount = conf.getInt(BLOCKING_STOREFILES_KEY, DEFAULT_BLOCKING_STOREFILE_COUNT); this.compactionCheckMultiplier = conf.getInt( COMPACTCHECKER_INTERVAL_MULTIPLIER_KEY, DEFAULT_COMPACTCHECKER_INTERVAL_MULTIPLIER); if (this.compactionCheckMultiplier <= 0) { LOG.error("Compaction check period multiplier must be positive, setting default: {}", DEFAULT_COMPACTCHECKER_INTERVAL_MULTIPLIER); this.compactionCheckMultiplier = DEFAULT_COMPACTCHECKER_INTERVAL_MULTIPLIER; } if (HStore.closeCheckInterval == 0) { HStore.closeCheckInterval = conf.getInt( "hbase.hstore.close.check.interval", 10*1000*1000 /* 10 MB */); } this.storeEngine = createStoreEngine(this, this.conf, region.getCellComparator()); List hStoreFiles = loadStoreFiles(warmup); // Move the storeSize calculation out of loadStoreFiles() method, because the secondary read // replica's refreshStoreFiles() will also use loadStoreFiles() to refresh its store files and // update the storeSize in the completeCompaction(..) finally (just like compaction) , so // no need calculate the storeSize twice. this.storeSize.addAndGet(getStorefilesSize(hStoreFiles, sf -> true)); this.totalUncompressedBytes.addAndGet(getTotalUncompressedBytes(hStoreFiles)); this.storeEngine.getStoreFileManager().loadFiles(hStoreFiles); flushRetriesNumber = conf.getInt( "hbase.hstore.flush.retries.number", DEFAULT_FLUSH_RETRIES_NUMBER); pauseTime = conf.getInt(HConstants.HBASE_SERVER_PAUSE, HConstants.DEFAULT_HBASE_SERVER_PAUSE); if (flushRetriesNumber <= 0) { throw new IllegalArgumentException( "hbase.hstore.flush.retries.number must be > 0, not " + flushRetriesNumber); } int confPrintThreshold = this.conf.getInt("hbase.region.store.parallel.put.print.threshold", 50); if (confPrintThreshold < 10) { confPrintThreshold = 10; } this.parallelPutCountPrintThreshold = confPrintThreshold; LOG.info("Store={}, memstore type={}, storagePolicy={}, verifyBulkLoads={}, " + "parallelPutCountPrintThreshold={}, encoding={}, compression={}", this, memstore.getClass().getSimpleName(), policyName, verifyBulkLoads, parallelPutCountPrintThreshold, family.getDataBlockEncoding(), family.getCompressionType()); cacheOnWriteLogged = false; } private StoreContext initializeStoreContext(ColumnFamilyDescriptor family) throws IOException { return new StoreContext.Builder() .withBlockSize(family.getBlocksize()) .withEncryptionContext(EncryptionUtil.createEncryptionContext(conf, family)) .withBloomType(family.getBloomFilterType()) .withCacheConfig(createCacheConf(family)) .withCellComparator(region.getCellComparator()) .withColumnFamilyDescriptor(family) .withCompactedFilesSupplier(this::getCompactedFiles) .withRegionFileSystem(region.getRegionFileSystem()) .withFavoredNodesSupplier(this::getFavoredNodes) .withFamilyStoreDirectoryPath(region.getRegionFileSystem() .getStoreDir(family.getNameAsString())) .withRegionCoprocessorHost(region.getCoprocessorHost()) .build(); } private InetSocketAddress[] getFavoredNodes() { InetSocketAddress[] favoredNodes = null; if (region.getRegionServerServices() != null) { favoredNodes = region.getRegionServerServices().getFavoredNodesForRegion( region.getRegionInfo().getEncodedName()); } return favoredNodes; } /** * @return MemStore Instance to use in this store. */ private MemStore getMemstore() { MemStore ms = null; // Check if in-memory-compaction configured. Note MemoryCompactionPolicy is an enum! MemoryCompactionPolicy inMemoryCompaction = null; if (this.getTableName().isSystemTable()) { inMemoryCompaction = MemoryCompactionPolicy .valueOf(conf.get("hbase.systemtables.compacting.memstore.type", "NONE").toUpperCase()); } else { inMemoryCompaction = getColumnFamilyDescriptor().getInMemoryCompaction(); } if (inMemoryCompaction == null) { inMemoryCompaction = MemoryCompactionPolicy.valueOf(conf.get(CompactingMemStore.COMPACTING_MEMSTORE_TYPE_KEY, CompactingMemStore.COMPACTING_MEMSTORE_TYPE_DEFAULT).toUpperCase()); } switch (inMemoryCompaction) { case NONE: ms = ReflectionUtils.newInstance(DefaultMemStore.class, new Object[] { conf, getComparator(), this.getHRegion().getRegionServicesForStores()}); break; default: Class clz = conf.getClass(MEMSTORE_CLASS_NAME, CompactingMemStore.class, CompactingMemStore.class); ms = ReflectionUtils.newInstance(clz, new Object[]{conf, getComparator(), this, this.getHRegion().getRegionServicesForStores(), inMemoryCompaction}); } return ms; } /** * Creates the cache config. * @param family The current column family. */ protected CacheConfig createCacheConf(final ColumnFamilyDescriptor family) { CacheConfig cacheConf = new CacheConfig(conf, family, region.getBlockCache(), region.getRegionServicesForStores().getByteBuffAllocator()); LOG.info("Created cacheConfig: {}, for column family {} of region {} ", cacheConf, family.getNameAsString(), region.getRegionInfo().getEncodedName()); return cacheConf; } /** * Creates the store engine configured for the given Store. * @param store The store. An unfortunate dependency needed due to it * being passed to coprocessors via the compactor. * @param conf Store configuration. * @param kvComparator KVComparator for storeFileManager. * @return StoreEngine to use. */ protected StoreEngine createStoreEngine(HStore store, Configuration conf, CellComparator kvComparator) throws IOException { return StoreEngine.create(store, conf, kvComparator); } /** * @return TTL in seconds of the specified family */ public static long determineTTLFromFamily(final ColumnFamilyDescriptor family) { // HCD.getTimeToLive returns ttl in seconds. Convert to milliseconds. long ttl = family.getTimeToLive(); if (ttl == HConstants.FOREVER) { // Default is unlimited ttl. ttl = Long.MAX_VALUE; } else if (ttl == -1) { ttl = Long.MAX_VALUE; } else { // Second -> ms adjust for user data ttl *= 1000; } return ttl; } StoreContext getStoreContext() { return storeContext; } @Override public String getColumnFamilyName() { return this.storeContext.getFamily().getNameAsString(); } @Override public TableName getTableName() { return this.getRegionInfo().getTable(); } @Override public FileSystem getFileSystem() { return storeContext.getRegionFileSystem().getFileSystem(); } public HRegionFileSystem getRegionFileSystem() { return storeContext.getRegionFileSystem(); } /* Implementation of StoreConfigInformation */ @Override public long getStoreFileTtl() { // TTL only applies if there's no MIN_VERSIONs setting on the column. return (this.scanInfo.getMinVersions() == 0) ? this.scanInfo.getTtl() : Long.MAX_VALUE; } @Override public long getMemStoreFlushSize() { // TODO: Why is this in here? The flushsize of the region rather than the store? St.Ack return this.region.memstoreFlushSize; } @Override public MemStoreSize getFlushableSize() { return this.memstore.getFlushableSize(); } @Override public MemStoreSize getSnapshotSize() { return this.memstore.getSnapshotSize(); } @Override public long getCompactionCheckMultiplier() { return this.compactionCheckMultiplier; } @Override public long getBlockingFileCount() { return blockingFileCount; } /* End implementation of StoreConfigInformation */ /** * @return how many bytes to write between status checks */ public static int getCloseCheckInterval() { return closeCheckInterval; } @Override public ColumnFamilyDescriptor getColumnFamilyDescriptor() { return this.storeContext.getFamily(); } @Override public OptionalLong getMaxSequenceId() { return StoreUtils.getMaxSequenceIdInList(this.getStorefiles()); } @Override public OptionalLong getMaxMemStoreTS() { return StoreUtils.getMaxMemStoreTSInList(this.getStorefiles()); } /** * @param tabledir {@link Path} to where the table is being stored * @param hri {@link RegionInfo} for the region. * @param family {@link ColumnFamilyDescriptor} describing the column family * @return Path to family/Store home directory. * @deprecated Since 05/05/2013, HBase-7808, hbase-1.0.0 */ @Deprecated public static Path getStoreHomedir(final Path tabledir, final RegionInfo hri, final byte[] family) { return getStoreHomedir(tabledir, hri.getEncodedName(), family); } /** * @param tabledir {@link Path} to where the table is being stored * @param encodedName Encoded region name. * @param family {@link ColumnFamilyDescriptor} describing the column family * @return Path to family/Store home directory. * @deprecated Since 05/05/2013, HBase-7808, hbase-1.0.0 */ @Deprecated public static Path getStoreHomedir(final Path tabledir, final String encodedName, final byte[] family) { return new Path(tabledir, new Path(encodedName, Bytes.toString(family))); } /** * @return the data block encoder */ public HFileDataBlockEncoder getDataBlockEncoder() { return dataBlockEncoder; } /** * Should be used only in tests. * @param blockEncoder the block delta encoder to use */ void setDataBlockEncoderInTest(HFileDataBlockEncoder blockEncoder) { this.dataBlockEncoder = blockEncoder; } /** * Creates an unsorted list of StoreFile loaded in parallel * from the given directory. */ private List loadStoreFiles(boolean warmup) throws IOException { Collection files = getRegionFileSystem().getStoreFiles(getColumnFamilyName()); return openStoreFiles(files, warmup); } private List openStoreFiles(Collection files, boolean warmup) throws IOException { if (CollectionUtils.isEmpty(files)) { return Collections.emptyList(); } // initialize the thread pool for opening store files in parallel.. ThreadPoolExecutor storeFileOpenerThreadPool = this.region.getStoreFileOpenAndCloseThreadPool("StoreFileOpener-" + this.getColumnFamilyName()); CompletionService completionService = new ExecutorCompletionService<>(storeFileOpenerThreadPool); int totalValidStoreFile = 0; for (StoreFileInfo storeFileInfo : files) { // open each store file in parallel completionService.submit(() -> this.createStoreFileAndReader(storeFileInfo)); totalValidStoreFile++; } Set compactedStoreFiles = new HashSet<>(); ArrayList results = new ArrayList<>(files.size()); IOException ioe = null; try { for (int i = 0; i < totalValidStoreFile; i++) { try { HStoreFile storeFile = completionService.take().get(); if (storeFile != null) { LOG.debug("loaded {}", storeFile); results.add(storeFile); compactedStoreFiles.addAll(storeFile.getCompactedStoreFiles()); } } catch (InterruptedException e) { if (ioe == null) { ioe = new InterruptedIOException(e.getMessage()); } } catch (ExecutionException e) { if (ioe == null) { ioe = new IOException(e.getCause()); } } } } finally { storeFileOpenerThreadPool.shutdownNow(); } if (ioe != null) { // close StoreFile readers boolean evictOnClose = getCacheConfig() != null? getCacheConfig().shouldEvictOnClose(): true; for (HStoreFile file : results) { try { if (file != null) { file.closeStoreFile(evictOnClose); } } catch (IOException e) { LOG.warn("Could not close store file {}", file, e); } } throw ioe; } // Should not archive the compacted store files when region warmup. See HBASE-22163. if (!warmup) { // Remove the compacted files from result List filesToRemove = new ArrayList<>(compactedStoreFiles.size()); for (HStoreFile storeFile : results) { if (compactedStoreFiles.contains(storeFile.getPath().getName())) { LOG.warn("Clearing the compacted storefile {} from {}", storeFile, this); storeFile.getReader().close(storeFile.getCacheConf() != null ? storeFile.getCacheConf().shouldEvictOnClose() : true); filesToRemove.add(storeFile); } } results.removeAll(filesToRemove); if (!filesToRemove.isEmpty() && this.isPrimaryReplicaStore()) { LOG.debug("Moving the files {} to archive", filesToRemove); getRegionFileSystem().removeStoreFiles(this.getColumnFamilyDescriptor().getNameAsString(), filesToRemove); } } return results; } @Override public void refreshStoreFiles() throws IOException { Collection newFiles = getRegionFileSystem().getStoreFiles(getColumnFamilyName()); refreshStoreFilesInternal(newFiles); } /** * Replaces the store files that the store has with the given files. Mainly used by secondary * region replicas to keep up to date with the primary region files. */ public void refreshStoreFiles(Collection newFiles) throws IOException { List storeFiles = new ArrayList<>(newFiles.size()); for (String file : newFiles) { storeFiles.add(getRegionFileSystem().getStoreFileInfo(getColumnFamilyName(), file)); } refreshStoreFilesInternal(storeFiles); } /** * Checks the underlying store files, and opens the files that have not * been opened, and removes the store file readers for store files no longer * available. Mainly used by secondary region replicas to keep up to date with * the primary region files. */ private void refreshStoreFilesInternal(Collection newFiles) throws IOException { StoreFileManager sfm = storeEngine.getStoreFileManager(); Collection currentFiles = sfm.getStorefiles(); Collection compactedFiles = sfm.getCompactedfiles(); if (currentFiles == null) { currentFiles = Collections.emptySet(); } if (newFiles == null) { newFiles = Collections.emptySet(); } if (compactedFiles == null) { compactedFiles = Collections.emptySet(); } HashMap currentFilesSet = new HashMap<>(currentFiles.size()); for (HStoreFile sf : currentFiles) { currentFilesSet.put(sf.getFileInfo(), sf); } HashMap compactedFilesSet = new HashMap<>(compactedFiles.size()); for (HStoreFile sf : compactedFiles) { compactedFilesSet.put(sf.getFileInfo(), sf); } Set newFilesSet = new HashSet(newFiles); // Exclude the files that have already been compacted newFilesSet = Sets.difference(newFilesSet, compactedFilesSet.keySet()); Set toBeAddedFiles = Sets.difference(newFilesSet, currentFilesSet.keySet()); Set toBeRemovedFiles = Sets.difference(currentFilesSet.keySet(), newFilesSet); if (toBeAddedFiles.isEmpty() && toBeRemovedFiles.isEmpty()) { return; } LOG.info("Refreshing store files for " + this + " files to add: " + toBeAddedFiles + " files to remove: " + toBeRemovedFiles); Set toBeRemovedStoreFiles = new HashSet<>(toBeRemovedFiles.size()); for (StoreFileInfo sfi : toBeRemovedFiles) { toBeRemovedStoreFiles.add(currentFilesSet.get(sfi)); } // try to open the files List openedFiles = openStoreFiles(toBeAddedFiles, false); // propogate the file changes to the underlying store file manager replaceStoreFiles(toBeRemovedStoreFiles, openedFiles); //won't throw an exception // Advance the memstore read point to be at least the new store files seqIds so that // readers might pick it up. This assumes that the store is not getting any writes (otherwise // in-flight transactions might be made visible) if (!toBeAddedFiles.isEmpty()) { // we must have the max sequence id here as we do have several store files region.getMVCC().advanceTo(this.getMaxSequenceId().getAsLong()); } completeCompaction(toBeRemovedStoreFiles); } protected HStoreFile createStoreFileAndReader(final Path p) throws IOException { StoreFileInfo info = new StoreFileInfo(conf, this.getFileSystem(), p, isPrimaryReplicaStore()); return createStoreFileAndReader(info); } private HStoreFile createStoreFileAndReader(StoreFileInfo info) throws IOException { info.setRegionCoprocessorHost(this.region.getCoprocessorHost()); HStoreFile storeFile = new HStoreFile(info, getColumnFamilyDescriptor().getBloomFilterType(), getCacheConfig()); storeFile.initReader(); return storeFile; } /** * This message intends to inform the MemStore that next coming updates * are going to be part of the replaying edits from WAL */ public void startReplayingFromWAL(){ this.memstore.startReplayingFromWAL(); } /** * This message intends to inform the MemStore that the replaying edits from WAL * are done */ public void stopReplayingFromWAL(){ this.memstore.stopReplayingFromWAL(); } /** * Adds a value to the memstore */ public void add(final Cell cell, MemStoreSizing memstoreSizing) { lock.readLock().lock(); try { if (this.currentParallelPutCount.getAndIncrement() > this.parallelPutCountPrintThreshold) { LOG.trace("tableName={}, encodedName={}, columnFamilyName={} is too busy!", this.getTableName(), this.getRegionInfo().getEncodedName(), this.getColumnFamilyName()); } this.memstore.add(cell, memstoreSizing); } finally { lock.readLock().unlock(); currentParallelPutCount.decrementAndGet(); } } /** * Adds the specified value to the memstore */ public void add(final Iterable cells, MemStoreSizing memstoreSizing) { lock.readLock().lock(); try { if (this.currentParallelPutCount.getAndIncrement() > this.parallelPutCountPrintThreshold) { LOG.trace("tableName={}, encodedName={}, columnFamilyName={} is too busy!", this.getTableName(), this.getRegionInfo().getEncodedName(), this.getColumnFamilyName()); } memstore.add(cells, memstoreSizing); } finally { lock.readLock().unlock(); currentParallelPutCount.decrementAndGet(); } } @Override public long timeOfOldestEdit() { return memstore.timeOfOldestEdit(); } /** * @return All store files. */ @Override public Collection getStorefiles() { return this.storeEngine.getStoreFileManager().getStorefiles(); } @Override public Collection getCompactedFiles() { return this.storeEngine.getStoreFileManager().getCompactedfiles(); } /** * This throws a WrongRegionException if the HFile does not fit in this region, or an * InvalidHFileException if the HFile is not valid. */ public void assertBulkLoadHFileOk(Path srcPath) throws IOException { HFile.Reader reader = null; try { LOG.info("Validating hfile at " + srcPath + " for inclusion in " + this); FileSystem srcFs = srcPath.getFileSystem(conf); srcFs.access(srcPath, FsAction.READ_WRITE); reader = HFile.createReader(srcFs, srcPath, getCacheConfig(), isPrimaryReplicaStore(), conf); Optional firstKey = reader.getFirstRowKey(); Preconditions.checkState(firstKey.isPresent(), "First key can not be null"); Optional lk = reader.getLastKey(); Preconditions.checkState(lk.isPresent(), "Last key can not be null"); byte[] lastKey = CellUtil.cloneRow(lk.get()); if (LOG.isDebugEnabled()) { LOG.debug("HFile bounds: first=" + Bytes.toStringBinary(firstKey.get()) + " last=" + Bytes.toStringBinary(lastKey)); LOG.debug("Region bounds: first=" + Bytes.toStringBinary(getRegionInfo().getStartKey()) + " last=" + Bytes.toStringBinary(getRegionInfo().getEndKey())); } if (!this.getRegionInfo().containsRange(firstKey.get(), lastKey)) { throw new WrongRegionException( "Bulk load file " + srcPath.toString() + " does not fit inside region " + this.getRegionInfo().getRegionNameAsString()); } if(reader.length() > conf.getLong(HConstants.HREGION_MAX_FILESIZE, HConstants.DEFAULT_MAX_FILE_SIZE)) { LOG.warn("Trying to bulk load hfile " + srcPath + " with size: " + reader.length() + " bytes can be problematic as it may lead to oversplitting."); } if (verifyBulkLoads) { long verificationStartTime = EnvironmentEdgeManager.currentTime(); LOG.info("Full verification started for bulk load hfile: {}", srcPath); Cell prevCell = null; HFileScanner scanner = reader.getScanner(false, false, false); scanner.seekTo(); do { Cell cell = scanner.getCell(); if (prevCell != null) { if (getComparator().compareRows(prevCell, cell) > 0) { throw new InvalidHFileException("Previous row is greater than" + " current row: path=" + srcPath + " previous=" + CellUtil.getCellKeyAsString(prevCell) + " current=" + CellUtil.getCellKeyAsString(cell)); } if (CellComparator.getInstance().compareFamilies(prevCell, cell) != 0) { throw new InvalidHFileException("Previous key had different" + " family compared to current key: path=" + srcPath + " previous=" + Bytes.toStringBinary(prevCell.getFamilyArray(), prevCell.getFamilyOffset(), prevCell.getFamilyLength()) + " current=" + Bytes.toStringBinary(cell.getFamilyArray(), cell.getFamilyOffset(), cell.getFamilyLength())); } } prevCell = cell; } while (scanner.next()); LOG.info("Full verification complete for bulk load hfile: " + srcPath.toString() + " took " + (EnvironmentEdgeManager.currentTime() - verificationStartTime) + " ms"); } } finally { if (reader != null) { reader.close(); } } } /** * This method should only be called from Region. It is assumed that the ranges of values in the * HFile fit within the stores assigned region. (assertBulkLoadHFileOk checks this) * * @param seqNum sequence Id associated with the HFile */ public Pair preBulkLoadHFile(String srcPathStr, long seqNum) throws IOException { Path srcPath = new Path(srcPathStr); return getRegionFileSystem().bulkLoadStoreFile(getColumnFamilyName(), srcPath, seqNum); } public Path bulkLoadHFile(byte[] family, String srcPathStr, Path dstPath) throws IOException { Path srcPath = new Path(srcPathStr); try { getRegionFileSystem().commitStoreFile(srcPath, dstPath); } finally { if (this.getCoprocessorHost() != null) { this.getCoprocessorHost().postCommitStoreFile(family, srcPath, dstPath); } } LOG.info("Loaded HFile " + srcPath + " into " + this + " as " + dstPath + " - updating store file list."); HStoreFile sf = createStoreFileAndReader(dstPath); bulkLoadHFile(sf); LOG.info("Successfully loaded {} into {} (new location: {})", srcPath, this, dstPath); return dstPath; } public void bulkLoadHFile(StoreFileInfo fileInfo) throws IOException { HStoreFile sf = createStoreFileAndReader(fileInfo); bulkLoadHFile(sf); } private void bulkLoadHFile(HStoreFile sf) throws IOException { StoreFileReader r = sf.getReader(); this.storeSize.addAndGet(r.length()); this.totalUncompressedBytes.addAndGet(r.getTotalUncompressedBytes()); // Append the new storefile into the list this.lock.writeLock().lock(); try { this.storeEngine.getStoreFileManager().insertNewFiles(Lists.newArrayList(sf)); } finally { // We need the lock, as long as we are updating the storeFiles // or changing the memstore. Let us release it before calling // notifyChangeReadersObservers. See HBASE-4485 for a possible // deadlock scenario that could have happened if continue to hold // the lock. this.lock.writeLock().unlock(); } LOG.info("Loaded HFile " + sf.getFileInfo() + " into " + this); if (LOG.isTraceEnabled()) { String traceMessage = "BULK LOAD time,size,store size,store files [" + EnvironmentEdgeManager.currentTime() + "," + r.length() + "," + storeSize + "," + storeEngine.getStoreFileManager().getStorefileCount() + "]"; LOG.trace(traceMessage); } } /** * Close all the readers We don't need to worry about subsequent requests because the Region holds * a write lock that will prevent any more reads or writes. * @return the {@link StoreFile StoreFiles} that were previously being used. * @throws IOException on failure */ public ImmutableCollection close() throws IOException { this.archiveLock.lock(); this.lock.writeLock().lock(); try { // Clear so metrics doesn't find them. ImmutableCollection result = storeEngine.getStoreFileManager().clearFiles(); Collection compactedfiles = storeEngine.getStoreFileManager().clearCompactedFiles(); // clear the compacted files if (CollectionUtils.isNotEmpty(compactedfiles)) { removeCompactedfiles(compactedfiles, getCacheConfig() != null ? getCacheConfig().shouldEvictOnClose() : true); } if (!result.isEmpty()) { // initialize the thread pool for closing store files in parallel. ThreadPoolExecutor storeFileCloserThreadPool = this.region .getStoreFileOpenAndCloseThreadPool("StoreFileCloser-" + this.getColumnFamilyName()); // close each store file in parallel CompletionService completionService = new ExecutorCompletionService<>(storeFileCloserThreadPool); for (HStoreFile f : result) { completionService.submit(new Callable() { @Override public Void call() throws IOException { boolean evictOnClose = getCacheConfig() != null? getCacheConfig().shouldEvictOnClose(): true; f.closeStoreFile(evictOnClose); return null; } }); } IOException ioe = null; try { for (int i = 0; i < result.size(); i++) { try { Future future = completionService.take(); future.get(); } catch (InterruptedException e) { if (ioe == null) { ioe = new InterruptedIOException(); ioe.initCause(e); } } catch (ExecutionException e) { if (ioe == null) { ioe = new IOException(e.getCause()); } } } } finally { storeFileCloserThreadPool.shutdownNow(); } if (ioe != null) { throw ioe; } } LOG.trace("Closed {}", this); return result; } finally { this.lock.writeLock().unlock(); this.archiveLock.unlock(); } } /** * Snapshot this stores memstore. Call before running * {@link #flushCache(long, MemStoreSnapshot, MonitoredTask, ThroughputController, * FlushLifeCycleTracker)} * so it has some work to do. */ void snapshot() { this.lock.writeLock().lock(); try { this.memstore.snapshot(); } finally { this.lock.writeLock().unlock(); } } /** * Write out current snapshot. Presumes {@link #snapshot()} has been called previously. * @param logCacheFlushId flush sequence number * @return The path name of the tmp file to which the store was flushed * @throws IOException if exception occurs during process */ protected List flushCache(final long logCacheFlushId, MemStoreSnapshot snapshot, MonitoredTask status, ThroughputController throughputController, FlushLifeCycleTracker tracker) throws IOException { // If an exception happens flushing, we let it out without clearing // the memstore snapshot. The old snapshot will be returned when we say // 'snapshot', the next time flush comes around. // Retry after catching exception when flushing, otherwise server will abort // itself StoreFlusher flusher = storeEngine.getStoreFlusher(); IOException lastException = null; for (int i = 0; i < flushRetriesNumber; i++) { try { List pathNames = flusher.flushSnapshot(snapshot, logCacheFlushId, status, throughputController, tracker); Path lastPathName = null; try { for (Path pathName : pathNames) { lastPathName = pathName; validateStoreFile(pathName); } return pathNames; } catch (Exception e) { LOG.warn("Failed validating store file {}, retrying num={}", lastPathName, i, e); if (e instanceof IOException) { lastException = (IOException) e; } else { lastException = new IOException(e); } } } catch (IOException e) { LOG.warn("Failed flushing store file for {}, retrying num={}", this, i, e); lastException = e; } if (lastException != null && i < (flushRetriesNumber - 1)) { try { Thread.sleep(pauseTime); } catch (InterruptedException e) { IOException iie = new InterruptedIOException(); iie.initCause(e); throw iie; } } } throw lastException; } public HStoreFile tryCommitRecoveredHFile(Path path) throws IOException { LOG.info("Validating recovered hfile at {} for inclusion in store {}", path, this); FileSystem srcFs = path.getFileSystem(conf); srcFs.access(path, FsAction.READ_WRITE); try (HFile.Reader reader = HFile.createReader(srcFs, path, getCacheConfig(), isPrimaryReplicaStore(), conf)) { Optional firstKey = reader.getFirstRowKey(); Preconditions.checkState(firstKey.isPresent(), "First key can not be null"); Optional lk = reader.getLastKey(); Preconditions.checkState(lk.isPresent(), "Last key can not be null"); byte[] lastKey = CellUtil.cloneRow(lk.get()); if (!this.getRegionInfo().containsRange(firstKey.get(), lastKey)) { throw new WrongRegionException("Recovered hfile " + path.toString() + " does not fit inside region " + this.getRegionInfo().getRegionNameAsString()); } } Path dstPath = getRegionFileSystem().commitStoreFile(getColumnFamilyName(), path); HStoreFile sf = createStoreFileAndReader(dstPath); StoreFileReader r = sf.getReader(); this.storeSize.addAndGet(r.length()); this.totalUncompressedBytes.addAndGet(r.getTotalUncompressedBytes()); this.lock.writeLock().lock(); try { this.storeEngine.getStoreFileManager().insertNewFiles(Lists.newArrayList(sf)); } finally { this.lock.writeLock().unlock(); } LOG.info("Loaded recovered hfile to {}, entries={}, sequenceid={}, filesize={}", sf, r.getEntries(), r.getSequenceID(), TraditionalBinaryPrefix.long2String(r.length(), "B", 1)); return sf; } /** * @param path The pathname of the tmp file into which the store was flushed * @return store file created. */ private HStoreFile commitFile(Path path, long logCacheFlushId, MonitoredTask status) throws IOException { // Write-out finished successfully, move into the right spot Path dstPath = getRegionFileSystem().commitStoreFile(getColumnFamilyName(), path); status.setStatus("Flushing " + this + ": reopening flushed file"); HStoreFile sf = createStoreFileAndReader(dstPath); StoreFileReader r = sf.getReader(); this.storeSize.addAndGet(r.length()); this.totalUncompressedBytes.addAndGet(r.getTotalUncompressedBytes()); if (LOG.isInfoEnabled()) { LOG.info("Added " + sf + ", entries=" + r.getEntries() + ", sequenceid=" + logCacheFlushId + ", filesize=" + TraditionalBinaryPrefix.long2String(r.length(), "", 1)); } return sf; } public StoreFileWriter createWriterInTmp(long maxKeyCount, Compression.Algorithm compression, boolean isCompaction, boolean includeMVCCReadpoint, boolean includesTag, boolean shouldDropBehind) throws IOException { return createWriterInTmp(maxKeyCount, compression, isCompaction, includeMVCCReadpoint, includesTag, shouldDropBehind, -1, HConstants.EMPTY_STRING); } /** * @param compression Compression algorithm to use * @param isCompaction whether we are creating a new file in a compaction * @param includeMVCCReadpoint - whether to include MVCC or not * @param includesTag - includesTag or not * @return Writer for a new StoreFile in the tmp dir. */ // TODO : allow the Writer factory to create Writers of ShipperListener type only in case of // compaction public StoreFileWriter createWriterInTmp(long maxKeyCount, Compression.Algorithm compression, boolean isCompaction, boolean includeMVCCReadpoint, boolean includesTag, boolean shouldDropBehind, long totalCompactedFilesSize, String fileStoragePolicy) throws IOException { // creating new cache config for each new writer final CacheConfig cacheConf = getCacheConfig(); final CacheConfig writerCacheConf = new CacheConfig(cacheConf); if (isCompaction) { // Don't cache data on write on compactions, unless specifically configured to do so // Cache only when total file size remains lower than configured threshold final boolean cacheCompactedBlocksOnWrite = getCacheConfig().shouldCacheCompactedBlocksOnWrite(); // if data blocks are to be cached on write // during compaction, we should forcefully // cache index and bloom blocks as well if (cacheCompactedBlocksOnWrite && totalCompactedFilesSize <= cacheConf .getCacheCompactedBlocksOnWriteThreshold()) { writerCacheConf.enableCacheOnWrite(); if (!cacheOnWriteLogged) { LOG.info("For {} , cacheCompactedBlocksOnWrite is true, hence enabled " + "cacheOnWrite for Data blocks, Index blocks and Bloom filter blocks", this); cacheOnWriteLogged = true; } } else { writerCacheConf.setCacheDataOnWrite(false); if (totalCompactedFilesSize > cacheConf.getCacheCompactedBlocksOnWriteThreshold()) { // checking condition once again for logging LOG.debug( "For {}, setting cacheCompactedBlocksOnWrite as false as total size of compacted " + "files - {}, is greater than cacheCompactedBlocksOnWriteThreshold - {}", this, totalCompactedFilesSize, cacheConf.getCacheCompactedBlocksOnWriteThreshold()); } } } else { final boolean shouldCacheDataOnWrite = cacheConf.shouldCacheDataOnWrite(); if (shouldCacheDataOnWrite) { writerCacheConf.enableCacheOnWrite(); if (!cacheOnWriteLogged) { LOG.info("For {} , cacheDataOnWrite is true, hence enabled cacheOnWrite for " + "Index blocks and Bloom filter blocks", this); cacheOnWriteLogged = true; } } } Encryption.Context encryptionContext = storeContext.getEncryptionContext(); HFileContext hFileContext = createFileContext(compression, includeMVCCReadpoint, includesTag, encryptionContext); Path familyTempDir = new Path(getRegionFileSystem().getTempDir(), getColumnFamilyName()); StoreFileWriter.Builder builder = new StoreFileWriter.Builder(conf, writerCacheConf, getFileSystem()) .withOutputDir(familyTempDir) .withBloomType(storeContext.getBloomFilterType()) .withMaxKeyCount(maxKeyCount) .withFavoredNodes(storeContext.getFavoredNodes()) .withFileContext(hFileContext) .withShouldDropCacheBehind(shouldDropBehind) .withCompactedFilesSupplier(storeContext.getCompactedFilesSupplier()) .withFileStoragePolicy(fileStoragePolicy); return builder.build(); } private HFileContext createFileContext(Compression.Algorithm compression, boolean includeMVCCReadpoint, boolean includesTag, Encryption.Context encryptionContext) { if (compression == null) { compression = HFile.DEFAULT_COMPRESSION_ALGORITHM; } ColumnFamilyDescriptor family = getColumnFamilyDescriptor(); HFileContext hFileContext = new HFileContextBuilder() .withIncludesMvcc(includeMVCCReadpoint) .withIncludesTags(includesTag) .withCompression(compression) .withCompressTags(family.isCompressTags()) .withChecksumType(StoreUtils.getChecksumType(conf)) .withBytesPerCheckSum(StoreUtils.getBytesPerChecksum(conf)) .withBlockSize(family.getBlocksize()) .withHBaseCheckSum(true) .withDataBlockEncoding(family.getDataBlockEncoding()) .withEncryptionContext(encryptionContext) .withCreateTime(EnvironmentEdgeManager.currentTime()) .withColumnFamily(getColumnFamilyDescriptor().getName()) .withTableName(getTableName().getName()) .withCellComparator(getComparator()) .build(); return hFileContext; } private long getTotalSize(Collection sfs) { return sfs.stream().mapToLong(sf -> sf.getReader().length()).sum(); } /** * Change storeFiles adding into place the Reader produced by this new flush. * @param sfs Store files * @return Whether compaction is required. */ private boolean updateStorefiles(List sfs, long snapshotId) throws IOException { this.lock.writeLock().lock(); try { this.storeEngine.getStoreFileManager().insertNewFiles(sfs); if (snapshotId > 0) { this.memstore.clearSnapshot(snapshotId); } } finally { // We need the lock, as long as we are updating the storeFiles // or changing the memstore. Let us release it before calling // notifyChangeReadersObservers. See HBASE-4485 for a possible // deadlock scenario that could have happened if continue to hold // the lock. this.lock.writeLock().unlock(); } // notify to be called here - only in case of flushes notifyChangedReadersObservers(sfs); if (LOG.isTraceEnabled()) { long totalSize = getTotalSize(sfs); String traceMessage = "FLUSH time,count,size,store size,store files [" + EnvironmentEdgeManager.currentTime() + "," + sfs.size() + "," + totalSize + "," + storeSize + "," + storeEngine.getStoreFileManager().getStorefileCount() + "]"; LOG.trace(traceMessage); } return needsCompaction(); } /** * Notify all observers that set of Readers has changed. */ private void notifyChangedReadersObservers(List sfs) throws IOException { for (ChangedReadersObserver o : this.changedReaderObservers) { List memStoreScanners; this.lock.readLock().lock(); try { memStoreScanners = this.memstore.getScanners(o.getReadPoint()); } finally { this.lock.readLock().unlock(); } o.updateReaders(sfs, memStoreScanners); } } /** * Get all scanners with no filtering based on TTL (that happens further down the line). * @param cacheBlocks cache the blocks or not * @param usePread true to use pread, false if not * @param isCompaction true if the scanner is created for compaction * @param matcher the scan query matcher * @param startRow the start row * @param stopRow the stop row * @param readPt the read point of the current scan * @return all scanners for this store */ public List getScanners(boolean cacheBlocks, boolean isGet, boolean usePread, boolean isCompaction, ScanQueryMatcher matcher, byte[] startRow, byte[] stopRow, long readPt) throws IOException { return getScanners(cacheBlocks, usePread, isCompaction, matcher, startRow, true, stopRow, false, readPt); } /** * Get all scanners with no filtering based on TTL (that happens further down the line). * @param cacheBlocks cache the blocks or not * @param usePread true to use pread, false if not * @param isCompaction true if the scanner is created for compaction * @param matcher the scan query matcher * @param startRow the start row * @param includeStartRow true to include start row, false if not * @param stopRow the stop row * @param includeStopRow true to include stop row, false if not * @param readPt the read point of the current scan * @return all scanners for this store */ public List getScanners(boolean cacheBlocks, boolean usePread, boolean isCompaction, ScanQueryMatcher matcher, byte[] startRow, boolean includeStartRow, byte[] stopRow, boolean includeStopRow, long readPt) throws IOException { Collection storeFilesToScan; List memStoreScanners; this.lock.readLock().lock(); try { storeFilesToScan = this.storeEngine.getStoreFileManager().getFilesForScan(startRow, includeStartRow, stopRow, includeStopRow); memStoreScanners = this.memstore.getScanners(readPt); } finally { this.lock.readLock().unlock(); } try { // First the store file scanners // TODO this used to get the store files in descending order, // but now we get them in ascending order, which I think is // actually more correct, since memstore get put at the end. List sfScanners = StoreFileScanner .getScannersForStoreFiles(storeFilesToScan, cacheBlocks, usePread, isCompaction, false, matcher, readPt); List scanners = new ArrayList<>(sfScanners.size() + 1); scanners.addAll(sfScanners); // Then the memstore scanners scanners.addAll(memStoreScanners); return scanners; } catch (Throwable t) { clearAndClose(memStoreScanners); throw t instanceof IOException ? (IOException) t : new IOException(t); } } private static void clearAndClose(List scanners) { if (scanners == null) { return; } for (KeyValueScanner s : scanners) { s.close(); } scanners.clear(); } /** * Create scanners on the given files and if needed on the memstore with no filtering based on TTL * (that happens further down the line). * @param files the list of files on which the scanners has to be created * @param cacheBlocks cache the blocks or not * @param usePread true to use pread, false if not * @param isCompaction true if the scanner is created for compaction * @param matcher the scan query matcher * @param startRow the start row * @param stopRow the stop row * @param readPt the read point of the current scan * @param includeMemstoreScanner true if memstore has to be included * @return scanners on the given files and on the memstore if specified */ public List getScanners(List files, boolean cacheBlocks, boolean isGet, boolean usePread, boolean isCompaction, ScanQueryMatcher matcher, byte[] startRow, byte[] stopRow, long readPt, boolean includeMemstoreScanner) throws IOException { return getScanners(files, cacheBlocks, usePread, isCompaction, matcher, startRow, true, stopRow, false, readPt, includeMemstoreScanner); } /** * Create scanners on the given files and if needed on the memstore with no filtering based on TTL * (that happens further down the line). * @param files the list of files on which the scanners has to be created * @param cacheBlocks ache the blocks or not * @param usePread true to use pread, false if not * @param isCompaction true if the scanner is created for compaction * @param matcher the scan query matcher * @param startRow the start row * @param includeStartRow true to include start row, false if not * @param stopRow the stop row * @param includeStopRow true to include stop row, false if not * @param readPt the read point of the current scan * @param includeMemstoreScanner true if memstore has to be included * @return scanners on the given files and on the memstore if specified */ public List getScanners(List files, boolean cacheBlocks, boolean usePread, boolean isCompaction, ScanQueryMatcher matcher, byte[] startRow, boolean includeStartRow, byte[] stopRow, boolean includeStopRow, long readPt, boolean includeMemstoreScanner) throws IOException { List memStoreScanners = null; if (includeMemstoreScanner) { this.lock.readLock().lock(); try { memStoreScanners = this.memstore.getScanners(readPt); } finally { this.lock.readLock().unlock(); } } try { List sfScanners = StoreFileScanner .getScannersForStoreFiles(files, cacheBlocks, usePread, isCompaction, false, matcher, readPt); List scanners = new ArrayList<>(sfScanners.size() + 1); scanners.addAll(sfScanners); // Then the memstore scanners if (memStoreScanners != null) { scanners.addAll(memStoreScanners); } return scanners; } catch (Throwable t) { clearAndClose(memStoreScanners); throw t instanceof IOException ? (IOException) t : new IOException(t); } } /** * @param o Observer who wants to know about changes in set of Readers */ public void addChangedReaderObserver(ChangedReadersObserver o) { this.changedReaderObservers.add(o); } /** * @param o Observer no longer interested in changes in set of Readers. */ public void deleteChangedReaderObserver(ChangedReadersObserver o) { // We don't check if observer present; it may not be (legitimately) this.changedReaderObservers.remove(o); } ////////////////////////////////////////////////////////////////////////////// // Compaction ////////////////////////////////////////////////////////////////////////////// /** * Compact the StoreFiles. This method may take some time, so the calling * thread must be able to block for long periods. * *

During this time, the Store can work as usual, getting values from * StoreFiles and writing new StoreFiles from the memstore. * * Existing StoreFiles are not destroyed until the new compacted StoreFile is * completely written-out to disk. * *

The compactLock prevents multiple simultaneous compactions. * The structureLock prevents us from interfering with other write operations. * *

We don't want to hold the structureLock for the whole time, as a compact() * can be lengthy and we want to allow cache-flushes during this period. * *

Compaction event should be idempotent, since there is no IO Fencing for * the region directory in hdfs. A region server might still try to complete the * compaction after it lost the region. That is why the following events are carefully * ordered for a compaction: * 1. Compaction writes new files under region/.tmp directory (compaction output) * 2. Compaction atomically moves the temporary file under region directory * 3. Compaction appends a WAL edit containing the compaction input and output files. * Forces sync on WAL. * 4. Compaction deletes the input files from the region directory. * * Failure conditions are handled like this: * - If RS fails before 2, compaction wont complete. Even if RS lives on and finishes * the compaction later, it will only write the new data file to the region directory. * Since we already have this data, this will be idempotent but we will have a redundant * copy of the data. * - If RS fails between 2 and 3, the region will have a redundant copy of the data. The * RS that failed won't be able to finish sync() for WAL because of lease recovery in WAL. * - If RS fails after 3, the region region server who opens the region will pick up the * the compaction marker from the WAL and replay it by removing the compaction input files. * Failed RS can also attempt to delete those files, but the operation will be idempotent * * See HBASE-2231 for details. * * @param compaction compaction details obtained from requestCompaction() * @return Storefile we compacted into or null if we failed or opted out early. */ public List compact(CompactionContext compaction, ThroughputController throughputController, User user) throws IOException { assert compaction != null; CompactionRequestImpl cr = compaction.getRequest(); try { // Do all sanity checking in here if we have a valid CompactionRequestImpl // because we need to clean up after it on the way out in a finally // block below long compactionStartTime = EnvironmentEdgeManager.currentTime(); assert compaction.hasSelection(); Collection filesToCompact = cr.getFiles(); assert !filesToCompact.isEmpty(); synchronized (filesCompacting) { // sanity check: we're compacting files that this store knows about // TODO: change this to LOG.error() after more debugging Preconditions.checkArgument(filesCompacting.containsAll(filesToCompact)); } // Ready to go. Have list of files to compact. LOG.info("Starting compaction of " + filesToCompact + " into tmpdir=" + getRegionFileSystem().getTempDir() + ", totalSize=" + TraditionalBinaryPrefix.long2String(cr.getSize(), "", 1)); return doCompaction(cr, filesToCompact, user, compactionStartTime, compaction.compact(throughputController, user)); } finally { finishCompactionRequest(cr); } } protected List doCompaction(CompactionRequestImpl cr, Collection filesToCompact, User user, long compactionStartTime, List newFiles) throws IOException { // Do the steps necessary to complete the compaction. setStoragePolicyFromFileName(newFiles); List sfs = moveCompactedFilesIntoPlace(cr, newFiles, user); writeCompactionWalRecord(filesToCompact, sfs); replaceStoreFiles(filesToCompact, sfs); if (cr.isMajor()) { majorCompactedCellsCount.addAndGet(getCompactionProgress().getTotalCompactingKVs()); majorCompactedCellsSize.addAndGet(getCompactionProgress().totalCompactedSize); } else { compactedCellsCount.addAndGet(getCompactionProgress().getTotalCompactingKVs()); compactedCellsSize.addAndGet(getCompactionProgress().totalCompactedSize); } long outputBytes = getTotalSize(sfs); // At this point the store will use new files for all new scanners. completeCompaction(filesToCompact); // update store size. long now = EnvironmentEdgeManager.currentTime(); if (region.getRegionServerServices() != null && region.getRegionServerServices().getMetrics() != null) { region.getRegionServerServices().getMetrics().updateCompaction( region.getTableDescriptor().getTableName().getNameAsString(), cr.isMajor(), now - compactionStartTime, cr.getFiles().size(), newFiles.size(), cr.getSize(), outputBytes); } logCompactionEndMessage(cr, sfs, now, compactionStartTime); return sfs; } // Set correct storage policy from the file name of DTCP. // Rename file will not change the storage policy. private void setStoragePolicyFromFileName(List newFiles) throws IOException { String prefix = HConstants.STORAGE_POLICY_PREFIX; for (Path newFile : newFiles) { if (newFile.getParent().getName().startsWith(prefix)) { CommonFSUtils.setStoragePolicy(getRegionFileSystem().getFileSystem(), newFile, newFile.getParent().getName().substring(prefix.length())); } } } private List moveCompactedFilesIntoPlace(CompactionRequestImpl cr, List newFiles, User user) throws IOException { List sfs = new ArrayList<>(newFiles.size()); for (Path newFile : newFiles) { assert newFile != null; HStoreFile sf = moveFileIntoPlace(newFile); if (this.getCoprocessorHost() != null) { getCoprocessorHost().postCompact(this, sf, cr.getTracker(), cr, user); } assert sf != null; sfs.add(sf); } return sfs; } // Package-visible for tests HStoreFile moveFileIntoPlace(Path newFile) throws IOException { validateStoreFile(newFile); // Move the file into the right spot Path destPath = getRegionFileSystem().commitStoreFile(getColumnFamilyName(), newFile); return createStoreFileAndReader(destPath); } /** * Writes the compaction WAL record. * @param filesCompacted Files compacted (input). * @param newFiles Files from compaction. */ private void writeCompactionWalRecord(Collection filesCompacted, Collection newFiles) throws IOException { if (region.getWAL() == null) { return; } List inputPaths = filesCompacted.stream().map(HStoreFile::getPath).collect(Collectors.toList()); List outputPaths = newFiles.stream().map(HStoreFile::getPath).collect(Collectors.toList()); RegionInfo info = this.region.getRegionInfo(); CompactionDescriptor compactionDescriptor = ProtobufUtil.toCompactionDescriptor(info, getColumnFamilyDescriptor().getName(), inputPaths, outputPaths, getRegionFileSystem().getStoreDir(getColumnFamilyDescriptor().getNameAsString())); // Fix reaching into Region to get the maxWaitForSeqId. // Does this method belong in Region altogether given it is making so many references up there? // Could be Region#writeCompactionMarker(compactionDescriptor); WALUtil.writeCompactionMarker(this.region.getWAL(), this.region.getReplicationScope(), this.region.getRegionInfo(), compactionDescriptor, this.region.getMVCC()); } void replaceStoreFiles(Collection compactedFiles, Collection result) throws IOException { this.lock.writeLock().lock(); try { this.storeEngine.getStoreFileManager().addCompactionResults(compactedFiles, result); synchronized (filesCompacting) { filesCompacting.removeAll(compactedFiles); } // These may be null when the RS is shutting down. The space quota Chores will fix the Region // sizes later so it's not super-critical if we miss these. RegionServerServices rsServices = region.getRegionServerServices(); if (rsServices != null && rsServices.getRegionServerSpaceQuotaManager() != null) { updateSpaceQuotaAfterFileReplacement( rsServices.getRegionServerSpaceQuotaManager().getRegionSizeStore(), getRegionInfo(), compactedFiles, result); } } finally { this.lock.writeLock().unlock(); } } /** * Updates the space quota usage for this region, removing the size for files compacted away * and adding in the size for new files. * * @param sizeStore The object tracking changes in region size for space quotas. * @param regionInfo The identifier for the region whose size is being updated. * @param oldFiles Files removed from this store's region. * @param newFiles Files added to this store's region. */ void updateSpaceQuotaAfterFileReplacement( RegionSizeStore sizeStore, RegionInfo regionInfo, Collection oldFiles, Collection newFiles) { long delta = 0; if (oldFiles != null) { for (HStoreFile compactedFile : oldFiles) { if (compactedFile.isHFile()) { delta -= compactedFile.getReader().length(); } } } if (newFiles != null) { for (HStoreFile newFile : newFiles) { if (newFile.isHFile()) { delta += newFile.getReader().length(); } } } sizeStore.incrementRegionSize(regionInfo, delta); } /** * Log a very elaborate compaction completion message. * @param cr Request. * @param sfs Resulting files. * @param compactionStartTime Start time. */ private void logCompactionEndMessage( CompactionRequestImpl cr, List sfs, long now, long compactionStartTime) { StringBuilder message = new StringBuilder( "Completed" + (cr.isMajor() ? " major" : "") + " compaction of " + cr.getFiles().size() + (cr.isAllFiles() ? " (all)" : "") + " file(s) in " + this + " of " + this.getRegionInfo().getShortNameToLog() + " into "); if (sfs.isEmpty()) { message.append("none, "); } else { for (HStoreFile sf: sfs) { message.append(sf.getPath().getName()); message.append("(size="); message.append(TraditionalBinaryPrefix.long2String(sf.getReader().length(), "", 1)); message.append("), "); } } message.append("total size for store is ") .append(StringUtils.TraditionalBinaryPrefix.long2String(storeSize.get(), "", 1)) .append(". This selection was in queue for ") .append(StringUtils.formatTimeDiff(compactionStartTime, cr.getSelectionTime())) .append(", and took ").append(StringUtils.formatTimeDiff(now, compactionStartTime)) .append(" to execute."); LOG.info(message.toString()); if (LOG.isTraceEnabled()) { int fileCount = storeEngine.getStoreFileManager().getStorefileCount(); long resultSize = getTotalSize(sfs); String traceMessage = "COMPACTION start,end,size out,files in,files out,store size," + "store files [" + compactionStartTime + "," + now + "," + resultSize + "," + cr.getFiles().size() + "," + sfs.size() + "," + storeSize + "," + fileCount + "]"; LOG.trace(traceMessage); } } /** * Call to complete a compaction. Its for the case where we find in the WAL a compaction * that was not finished. We could find one recovering a WAL after a regionserver crash. * See HBASE-2231. */ public void replayCompactionMarker(CompactionDescriptor compaction, boolean pickCompactionFiles, boolean removeFiles) throws IOException { LOG.debug("Completing compaction from the WAL marker"); List compactionInputs = compaction.getCompactionInputList(); List compactionOutputs = Lists.newArrayList(compaction.getCompactionOutputList()); // The Compaction Marker is written after the compaction is completed, // and the files moved into the region/family folder. // // If we crash after the entry is written, we may not have removed the // input files, but the output file is present. // (The unremoved input files will be removed by this function) // // If we scan the directory and the file is not present, it can mean that: // - The file was manually removed by the user // - The file was removed as consequence of subsequent compaction // so, we can't do anything with the "compaction output list" because those // files have already been loaded when opening the region (by virtue of // being in the store's folder) or they may be missing due to a compaction. String familyName = this.getColumnFamilyName(); Set inputFiles = new HashSet<>(); for (String compactionInput : compactionInputs) { Path inputPath = getRegionFileSystem().getStoreFilePath(familyName, compactionInput); inputFiles.add(inputPath.getName()); } //some of the input files might already be deleted List inputStoreFiles = new ArrayList<>(compactionInputs.size()); for (HStoreFile sf : this.getStorefiles()) { if (inputFiles.contains(sf.getPath().getName())) { inputStoreFiles.add(sf); } } // check whether we need to pick up the new files List outputStoreFiles = new ArrayList<>(compactionOutputs.size()); if (pickCompactionFiles) { for (HStoreFile sf : this.getStorefiles()) { compactionOutputs.remove(sf.getPath().getName()); } for (String compactionOutput : compactionOutputs) { StoreFileInfo storeFileInfo = getRegionFileSystem().getStoreFileInfo(getColumnFamilyName(), compactionOutput); HStoreFile storeFile = createStoreFileAndReader(storeFileInfo); outputStoreFiles.add(storeFile); } } if (!inputStoreFiles.isEmpty() || !outputStoreFiles.isEmpty()) { LOG.info("Replaying compaction marker, replacing input files: " + inputStoreFiles + " with output files : " + outputStoreFiles); this.replaceStoreFiles(inputStoreFiles, outputStoreFiles); this.completeCompaction(inputStoreFiles); } } /** * This method tries to compact N recent files for testing. * Note that because compacting "recent" files only makes sense for some policies, * e.g. the default one, it assumes default policy is used. It doesn't use policy, * but instead makes a compaction candidate list by itself. * @param N Number of files. */ public void compactRecentForTestingAssumingDefaultPolicy(int N) throws IOException { List filesToCompact; boolean isMajor; this.lock.readLock().lock(); try { synchronized (filesCompacting) { filesToCompact = Lists.newArrayList(storeEngine.getStoreFileManager().getStorefiles()); if (!filesCompacting.isEmpty()) { // exclude all files older than the newest file we're currently // compacting. this allows us to preserve contiguity (HBASE-2856) HStoreFile last = filesCompacting.get(filesCompacting.size() - 1); int idx = filesToCompact.indexOf(last); Preconditions.checkArgument(idx != -1); filesToCompact.subList(0, idx + 1).clear(); } int count = filesToCompact.size(); if (N > count) { throw new RuntimeException("Not enough files"); } filesToCompact = filesToCompact.subList(count - N, count); isMajor = (filesToCompact.size() == storeEngine.getStoreFileManager().getStorefileCount()); filesCompacting.addAll(filesToCompact); Collections.sort(filesCompacting, storeEngine.getStoreFileManager() .getStoreFileComparator()); } } finally { this.lock.readLock().unlock(); } try { // Ready to go. Have list of files to compact. List newFiles = ((DefaultCompactor)this.storeEngine.getCompactor()) .compactForTesting(filesToCompact, isMajor); for (Path newFile: newFiles) { // Move the compaction into place. HStoreFile sf = moveFileIntoPlace(newFile); if (this.getCoprocessorHost() != null) { this.getCoprocessorHost().postCompact(this, sf, null, null, null); } replaceStoreFiles(filesToCompact, Collections.singletonList(sf)); completeCompaction(filesToCompact); } } finally { synchronized (filesCompacting) { filesCompacting.removeAll(filesToCompact); } } } @Override public boolean hasReferences() { // Grab the read lock here, because we need to ensure that: only when the atomic // replaceStoreFiles(..) finished, we can get all the complete store file list. this.lock.readLock().lock(); try { // Merge the current store files with compacted files here due to HBASE-20940. Collection allStoreFiles = new ArrayList<>(getStorefiles()); allStoreFiles.addAll(getCompactedFiles()); return StoreUtils.hasReferences(allStoreFiles); } finally { this.lock.readLock().unlock(); } } /** * getter for CompactionProgress object * @return CompactionProgress object; can be null */ public CompactionProgress getCompactionProgress() { return this.storeEngine.getCompactor().getProgress(); } @Override public boolean shouldPerformMajorCompaction() throws IOException { for (HStoreFile sf : this.storeEngine.getStoreFileManager().getStorefiles()) { // TODO: what are these reader checks all over the place? if (sf.getReader() == null) { LOG.debug("StoreFile {} has null Reader", sf); return false; } } return storeEngine.getCompactionPolicy().shouldPerformMajorCompaction( this.storeEngine.getStoreFileManager().getStorefiles()); } public Optional requestCompaction() throws IOException { return requestCompaction(NO_PRIORITY, CompactionLifeCycleTracker.DUMMY, null); } public Optional requestCompaction(int priority, CompactionLifeCycleTracker tracker, User user) throws IOException { // don't even select for compaction if writes are disabled if (!this.areWritesEnabled()) { return Optional.empty(); } // Before we do compaction, try to get rid of unneeded files to simplify things. removeUnneededFiles(); final CompactionContext compaction = storeEngine.createCompaction(); CompactionRequestImpl request = null; this.lock.readLock().lock(); try { synchronized (filesCompacting) { // First, see if coprocessor would want to override selection. if (this.getCoprocessorHost() != null) { final List candidatesForCoproc = compaction.preSelect(this.filesCompacting); boolean override = getCoprocessorHost().preCompactSelection(this, candidatesForCoproc, tracker, user); if (override) { // Coprocessor is overriding normal file selection. compaction.forceSelect(new CompactionRequestImpl(candidatesForCoproc)); } } // Normal case - coprocessor is not overriding file selection. if (!compaction.hasSelection()) { boolean isUserCompaction = priority == Store.PRIORITY_USER; boolean mayUseOffPeak = offPeakHours.isOffPeakHour() && offPeakCompactionTracker.compareAndSet(false, true); try { compaction.select(this.filesCompacting, isUserCompaction, mayUseOffPeak, forceMajor && filesCompacting.isEmpty()); } catch (IOException e) { if (mayUseOffPeak) { offPeakCompactionTracker.set(false); } throw e; } assert compaction.hasSelection(); if (mayUseOffPeak && !compaction.getRequest().isOffPeak()) { // Compaction policy doesn't want to take advantage of off-peak. offPeakCompactionTracker.set(false); } } if (this.getCoprocessorHost() != null) { this.getCoprocessorHost().postCompactSelection( this, ImmutableList.copyOf(compaction.getRequest().getFiles()), tracker, compaction.getRequest(), user); } // Finally, we have the resulting files list. Check if we have any files at all. request = compaction.getRequest(); Collection selectedFiles = request.getFiles(); if (selectedFiles.isEmpty()) { return Optional.empty(); } addToCompactingFiles(selectedFiles); // If we're enqueuing a major, clear the force flag. this.forceMajor = this.forceMajor && !request.isMajor(); // Set common request properties. // Set priority, either override value supplied by caller or from store. final int compactionPriority = (priority != Store.NO_PRIORITY) ? priority : getCompactPriority(); request.setPriority(compactionPriority); if (request.isAfterSplit()) { // If the store belongs to recently splitted daughter regions, better we consider // them with the higher priority in the compaction queue. // Override priority if it is lower (higher int value) than // SPLIT_REGION_COMPACTION_PRIORITY final int splitHousekeepingPriority = Math.min(compactionPriority, SPLIT_REGION_COMPACTION_PRIORITY); request.setPriority(splitHousekeepingPriority); LOG.info("Keeping/Overriding Compaction request priority to {} for CF {} since it" + " belongs to recently split daughter region {}", splitHousekeepingPriority, this.getColumnFamilyName(), getRegionInfo().getRegionNameAsString()); } request.setDescription(getRegionInfo().getRegionNameAsString(), getColumnFamilyName()); request.setTracker(tracker); } } finally { this.lock.readLock().unlock(); } if (LOG.isDebugEnabled()) { LOG.debug(this + " is initiating " + (request.isMajor() ? "major" : "minor") + " compaction" + (request.isAllFiles() ? " (all files)" : "")); } this.region.reportCompactionRequestStart(request.isMajor()); return Optional.of(compaction); } /** Adds the files to compacting files. filesCompacting must be locked. */ private void addToCompactingFiles(Collection filesToAdd) { if (CollectionUtils.isEmpty(filesToAdd)) { return; } // Check that we do not try to compact the same StoreFile twice. if (!Collections.disjoint(filesCompacting, filesToAdd)) { Preconditions.checkArgument(false, "%s overlaps with %s", filesToAdd, filesCompacting); } filesCompacting.addAll(filesToAdd); Collections.sort(filesCompacting, storeEngine.getStoreFileManager().getStoreFileComparator()); } private void removeUnneededFiles() throws IOException { if (!conf.getBoolean("hbase.store.delete.expired.storefile", true)) { return; } if (getColumnFamilyDescriptor().getMinVersions() > 0) { LOG.debug("Skipping expired store file removal due to min version of {} being {}", this, getColumnFamilyDescriptor().getMinVersions()); return; } this.lock.readLock().lock(); Collection delSfs = null; try { synchronized (filesCompacting) { long cfTtl = getStoreFileTtl(); if (cfTtl != Long.MAX_VALUE) { delSfs = storeEngine.getStoreFileManager().getUnneededFiles( EnvironmentEdgeManager.currentTime() - cfTtl, filesCompacting); addToCompactingFiles(delSfs); } } } finally { this.lock.readLock().unlock(); } if (CollectionUtils.isEmpty(delSfs)) { return; } Collection newFiles = Collections.emptyList(); // No new files. writeCompactionWalRecord(delSfs, newFiles); replaceStoreFiles(delSfs, newFiles); completeCompaction(delSfs); LOG.info("Completed removal of " + delSfs.size() + " unnecessary (expired) file(s) in " + this + "; total size is " + TraditionalBinaryPrefix.long2String(storeSize.get(), "", 1)); } public void cancelRequestedCompaction(CompactionContext compaction) { finishCompactionRequest(compaction.getRequest()); } private void finishCompactionRequest(CompactionRequestImpl cr) { this.region.reportCompactionRequestEnd(cr.isMajor(), cr.getFiles().size(), cr.getSize()); if (cr.isOffPeak()) { offPeakCompactionTracker.set(false); cr.setOffPeak(false); } synchronized (filesCompacting) { filesCompacting.removeAll(cr.getFiles()); } } /** * Validates a store file by opening and closing it. In HFileV2 this should not be an expensive * operation. * @param path the path to the store file */ private void validateStoreFile(Path path) throws IOException { HStoreFile storeFile = null; try { storeFile = createStoreFileAndReader(path); } catch (IOException e) { LOG.error("Failed to open store file : {}, keeping it in tmp location", path, e); throw e; } finally { if (storeFile != null) { storeFile.closeStoreFile(false); } } } /** * Update counts. * @param compactedFiles list of files that were compacted */ protected void completeCompaction(Collection compactedFiles) // Rename this method! TODO. throws IOException { this.storeSize.set(0L); this.totalUncompressedBytes.set(0L); for (HStoreFile hsf : this.storeEngine.getStoreFileManager().getStorefiles()) { StoreFileReader r = hsf.getReader(); if (r == null) { LOG.warn("StoreFile {} has a null Reader", hsf); continue; } this.storeSize.addAndGet(r.length()); this.totalUncompressedBytes.addAndGet(r.getTotalUncompressedBytes()); } } /* * @param wantedVersions How many versions were asked for. * @return wantedVersions or this families' {@link HConstants#VERSIONS}. */ int versionsToReturn(final int wantedVersions) { if (wantedVersions <= 0) { throw new IllegalArgumentException("Number of versions must be > 0"); } // Make sure we do not return more than maximum versions for this store. int maxVersions = getColumnFamilyDescriptor().getMaxVersions(); return wantedVersions > maxVersions ? maxVersions: wantedVersions; } @Override public boolean canSplit() { // Not split-able if we find a reference store file present in the store. boolean result = !hasReferences(); if (!result) { LOG.trace("Not splittable; has references: {}", this); } return result; } /** * Determines if Store should be split. */ public Optional getSplitPoint() { this.lock.readLock().lock(); try { // Should already be enforced by the split policy! assert !this.getRegionInfo().isMetaRegion(); // Not split-able if we find a reference store file present in the store. if (hasReferences()) { LOG.trace("Not splittable; has references: {}", this); return Optional.empty(); } return this.storeEngine.getStoreFileManager().getSplitPoint(); } catch(IOException e) { LOG.warn("Failed getting store size for {}", this, e); } finally { this.lock.readLock().unlock(); } return Optional.empty(); } @Override public long getLastCompactSize() { return this.lastCompactSize; } @Override public long getSize() { return storeSize.get(); } public void triggerMajorCompaction() { this.forceMajor = true; } ////////////////////////////////////////////////////////////////////////////// // File administration ////////////////////////////////////////////////////////////////////////////// /** * Return a scanner for both the memstore and the HStore files. Assumes we are not in a * compaction. * @param scan Scan to apply when scanning the stores * @param targetCols columns to scan * @return a scanner over the current key values * @throws IOException on failure */ public KeyValueScanner getScanner(Scan scan, final NavigableSet targetCols, long readPt) throws IOException { lock.readLock().lock(); try { ScanInfo scanInfo; if (this.getCoprocessorHost() != null) { scanInfo = this.getCoprocessorHost().preStoreScannerOpen(this, scan); } else { scanInfo = getScanInfo(); } return createScanner(scan, scanInfo, targetCols, readPt); } finally { lock.readLock().unlock(); } } // HMobStore will override this method to return its own implementation. protected KeyValueScanner createScanner(Scan scan, ScanInfo scanInfo, NavigableSet targetCols, long readPt) throws IOException { return scan.isReversed() ? new ReversedStoreScanner(this, scanInfo, scan, targetCols, readPt) : new StoreScanner(this, scanInfo, scan, targetCols, readPt); } /** * Recreates the scanners on the current list of active store file scanners * @param currentFileScanners the current set of active store file scanners * @param cacheBlocks cache the blocks or not * @param usePread use pread or not * @param isCompaction is the scanner for compaction * @param matcher the scan query matcher * @param startRow the scan's start row * @param includeStartRow should the scan include the start row * @param stopRow the scan's stop row * @param includeStopRow should the scan include the stop row * @param readPt the read point of the current scane * @param includeMemstoreScanner whether the current scanner should include memstorescanner * @return list of scanners recreated on the current Scanners */ public List recreateScanners(List currentFileScanners, boolean cacheBlocks, boolean usePread, boolean isCompaction, ScanQueryMatcher matcher, byte[] startRow, boolean includeStartRow, byte[] stopRow, boolean includeStopRow, long readPt, boolean includeMemstoreScanner) throws IOException { this.lock.readLock().lock(); try { Map name2File = new HashMap<>(getStorefilesCount() + getCompactedFilesCount()); for (HStoreFile file : getStorefiles()) { name2File.put(file.getFileInfo().getActiveFileName(), file); } Collection compactedFiles = getCompactedFiles(); for (HStoreFile file : IterableUtils.emptyIfNull(compactedFiles)) { name2File.put(file.getFileInfo().getActiveFileName(), file); } List filesToReopen = new ArrayList<>(); for (KeyValueScanner kvs : currentFileScanners) { assert kvs.isFileScanner(); if (kvs.peek() == null) { continue; } filesToReopen.add(name2File.get(kvs.getFilePath().getName())); } if (filesToReopen.isEmpty()) { return null; } return getScanners(filesToReopen, cacheBlocks, false, false, matcher, startRow, includeStartRow, stopRow, includeStopRow, readPt, false); } finally { this.lock.readLock().unlock(); } } @Override public String toString() { return this.getRegionInfo().getShortNameToLog()+ "/" + this.getColumnFamilyName(); } @Override public int getStorefilesCount() { return this.storeEngine.getStoreFileManager().getStorefileCount(); } @Override public int getCompactedFilesCount() { return this.storeEngine.getStoreFileManager().getCompactedFilesCount(); } private LongStream getStoreFileAgeStream() { return this.storeEngine.getStoreFileManager().getStorefiles().stream().filter(sf -> { if (sf.getReader() == null) { LOG.warn("StoreFile {} has a null Reader", sf); return false; } else { return true; } }).filter(HStoreFile::isHFile).mapToLong(sf -> sf.getFileInfo().getCreatedTimestamp()) .map(t -> EnvironmentEdgeManager.currentTime() - t); } @Override public OptionalLong getMaxStoreFileAge() { return getStoreFileAgeStream().max(); } @Override public OptionalLong getMinStoreFileAge() { return getStoreFileAgeStream().min(); } @Override public OptionalDouble getAvgStoreFileAge() { return getStoreFileAgeStream().average(); } @Override public long getNumReferenceFiles() { return this.storeEngine.getStoreFileManager().getStorefiles().stream() .filter(HStoreFile::isReference).count(); } @Override public long getNumHFiles() { return this.storeEngine.getStoreFileManager().getStorefiles().stream() .filter(HStoreFile::isHFile).count(); } @Override public long getStoreSizeUncompressed() { return this.totalUncompressedBytes.get(); } @Override public long getStorefilesSize() { // Include all StoreFiles return getStorefilesSize(this.storeEngine.getStoreFileManager().getStorefiles(), sf -> true); } @Override public long getHFilesSize() { // Include only StoreFiles which are HFiles return getStorefilesSize(this.storeEngine.getStoreFileManager().getStorefiles(), HStoreFile::isHFile); } private long getTotalUncompressedBytes(List files) { return files.stream() .mapToLong(file -> getStorefileFieldSize(file, StoreFileReader::getTotalUncompressedBytes)) .sum(); } private long getStorefilesSize(Collection files, Predicate predicate) { return files.stream().filter(predicate) .mapToLong(file -> getStorefileFieldSize(file, StoreFileReader::length)).sum(); } private long getStorefileFieldSize(HStoreFile file, ToLongFunction f) { if (file == null) { return 0L; } StoreFileReader reader = file.getReader(); if (reader == null) { return 0L; } return f.applyAsLong(reader); } private long getStorefilesFieldSize(ToLongFunction f) { return this.storeEngine.getStoreFileManager().getStorefiles().stream() .mapToLong(file -> getStorefileFieldSize(file, f)).sum(); } @Override public long getStorefilesRootLevelIndexSize() { return getStorefilesFieldSize(StoreFileReader::indexSize); } @Override public long getTotalStaticIndexSize() { return getStorefilesFieldSize(StoreFileReader::getUncompressedDataIndexSize); } @Override public long getTotalStaticBloomSize() { return getStorefilesFieldSize(StoreFileReader::getTotalBloomSize); } @Override public MemStoreSize getMemStoreSize() { return this.memstore.size(); } @Override public int getCompactPriority() { int priority = this.storeEngine.getStoreFileManager().getStoreCompactionPriority(); if (priority == PRIORITY_USER) { LOG.warn("Compaction priority is USER despite there being no user compaction"); } return priority; } public boolean throttleCompaction(long compactionSize) { return storeEngine.getCompactionPolicy().throttleCompaction(compactionSize); } public HRegion getHRegion() { return this.region; } public RegionCoprocessorHost getCoprocessorHost() { return this.region.getCoprocessorHost(); } @Override public RegionInfo getRegionInfo() { return getRegionFileSystem().getRegionInfo(); } @Override public boolean areWritesEnabled() { return this.region.areWritesEnabled(); } @Override public long getSmallestReadPoint() { return this.region.getSmallestReadPoint(); } /** * Adds or replaces the specified KeyValues. *

* For each KeyValue specified, if a cell with the same row, family, and qualifier exists in * MemStore, it will be replaced. Otherwise, it will just be inserted to MemStore. *

* This operation is atomic on each KeyValue (row/family/qualifier) but not necessarily atomic * across all of them. * @param readpoint readpoint below which we can safely remove duplicate KVs */ public void upsert(Iterable cells, long readpoint, MemStoreSizing memstoreSizing) throws IOException { this.lock.readLock().lock(); try { this.memstore.upsert(cells, readpoint, memstoreSizing); } finally { this.lock.readLock().unlock(); } } public StoreFlushContext createFlushContext(long cacheFlushId, FlushLifeCycleTracker tracker) { return new StoreFlusherImpl(cacheFlushId, tracker); } private final class StoreFlusherImpl implements StoreFlushContext { private final FlushLifeCycleTracker tracker; private final long cacheFlushSeqNum; private MemStoreSnapshot snapshot; private List tempFiles; private List committedFiles; private long cacheFlushCount; private long cacheFlushSize; private long outputFileSize; private StoreFlusherImpl(long cacheFlushSeqNum, FlushLifeCycleTracker tracker) { this.cacheFlushSeqNum = cacheFlushSeqNum; this.tracker = tracker; } /** * This is not thread safe. The caller should have a lock on the region or the store. * If necessary, the lock can be added with the patch provided in HBASE-10087 */ @Override public MemStoreSize prepare() { // passing the current sequence number of the wal - to allow bookkeeping in the memstore this.snapshot = memstore.snapshot(); this.cacheFlushCount = snapshot.getCellsCount(); this.cacheFlushSize = snapshot.getDataSize(); committedFiles = new ArrayList<>(1); return snapshot.getMemStoreSize(); } @Override public void flushCache(MonitoredTask status) throws IOException { RegionServerServices rsService = region.getRegionServerServices(); ThroughputController throughputController = rsService == null ? null : rsService.getFlushThroughputController(); tempFiles = HStore.this.flushCache(cacheFlushSeqNum, snapshot, status, throughputController, tracker); } @Override public boolean commit(MonitoredTask status) throws IOException { if (CollectionUtils.isEmpty(this.tempFiles)) { return false; } List storeFiles = new ArrayList<>(this.tempFiles.size()); for (Path storeFilePath : tempFiles) { try { HStoreFile sf = HStore.this.commitFile(storeFilePath, cacheFlushSeqNum, status); outputFileSize += sf.getReader().length(); storeFiles.add(sf); } catch (IOException ex) { LOG.error("Failed to commit store file {}", storeFilePath, ex); // Try to delete the files we have committed before. for (HStoreFile sf : storeFiles) { Path pathToDelete = sf.getPath(); try { sf.deleteStoreFile(); } catch (IOException deleteEx) { LOG.error(HBaseMarkers.FATAL, "Failed to delete store file we committed, " + "halting {}", pathToDelete, ex); Runtime.getRuntime().halt(1); } } throw new IOException("Failed to commit the flush", ex); } } for (HStoreFile sf : storeFiles) { if (HStore.this.getCoprocessorHost() != null) { HStore.this.getCoprocessorHost().postFlush(HStore.this, sf, tracker); } committedFiles.add(sf.getPath()); } HStore.this.flushedCellsCount.addAndGet(cacheFlushCount); HStore.this.flushedCellsSize.addAndGet(cacheFlushSize); HStore.this.flushedOutputFileSize.addAndGet(outputFileSize); // Add new file to store files. Clear snapshot too while we have the Store write lock. return HStore.this.updateStorefiles(storeFiles, snapshot.getId()); } @Override public long getOutputFileSize() { return outputFileSize; } @Override public List getCommittedFiles() { return committedFiles; } /** * Similar to commit, but called in secondary region replicas for replaying the * flush cache from primary region. Adds the new files to the store, and drops the * snapshot depending on dropMemstoreSnapshot argument. * @param fileNames names of the flushed files * @param dropMemstoreSnapshot whether to drop the prepared memstore snapshot */ @Override public void replayFlush(List fileNames, boolean dropMemstoreSnapshot) throws IOException { List storeFiles = new ArrayList<>(fileNames.size()); for (String file : fileNames) { // open the file as a store file (hfile link, etc) StoreFileInfo storeFileInfo = getRegionFileSystem().getStoreFileInfo(getColumnFamilyName(), file); HStoreFile storeFile = createStoreFileAndReader(storeFileInfo); storeFiles.add(storeFile); HStore.this.storeSize.addAndGet(storeFile.getReader().length()); HStore.this.totalUncompressedBytes .addAndGet(storeFile.getReader().getTotalUncompressedBytes()); if (LOG.isInfoEnabled()) { LOG.info(this + " added " + storeFile + ", entries=" + storeFile.getReader().getEntries() + ", sequenceid=" + storeFile.getReader().getSequenceID() + ", filesize=" + TraditionalBinaryPrefix.long2String(storeFile.getReader().length(), "", 1)); } } long snapshotId = -1; // -1 means do not drop if (dropMemstoreSnapshot && snapshot != null) { snapshotId = snapshot.getId(); snapshot.close(); } HStore.this.updateStorefiles(storeFiles, snapshotId); } /** * Abort the snapshot preparation. Drops the snapshot if any. */ @Override public void abort() throws IOException { if (snapshot != null) { //We need to close the snapshot when aborting, otherwise, the segment scanner //won't be closed. If we are using MSLAB, the chunk referenced by those scanners //can't be released, thus memory leak snapshot.close(); HStore.this.updateStorefiles(Collections.emptyList(), snapshot.getId()); } } } @Override public boolean needsCompaction() { List filesCompactingClone = null; synchronized (filesCompacting) { filesCompactingClone = Lists.newArrayList(filesCompacting); } return this.storeEngine.needsCompaction(filesCompactingClone); } /** * Used for tests. * @return cache configuration for this Store. */ public CacheConfig getCacheConfig() { return storeContext.getCacheConf(); } public static final long FIXED_OVERHEAD = ClassSize.estimateBase(HStore.class, false); public static final long DEEP_OVERHEAD = ClassSize.align(FIXED_OVERHEAD + ClassSize.OBJECT + ClassSize.REENTRANT_LOCK + ClassSize.CONCURRENT_SKIPLISTMAP + ClassSize.CONCURRENT_SKIPLISTMAP_ENTRY + ClassSize.OBJECT + ScanInfo.FIXED_OVERHEAD); @Override public long heapSize() { MemStoreSize memstoreSize = this.memstore.size(); return DEEP_OVERHEAD + memstoreSize.getHeapSize() + storeContext.heapSize(); } @Override public CellComparator getComparator() { return storeContext.getComparator(); } public ScanInfo getScanInfo() { return scanInfo; } /** * Set scan info, used by test * @param scanInfo new scan info to use for test */ void setScanInfo(ScanInfo scanInfo) { this.scanInfo = scanInfo; } @Override public boolean hasTooManyStoreFiles() { return getStorefilesCount() > this.blockingFileCount; } @Override public long getFlushedCellsCount() { return flushedCellsCount.get(); } @Override public long getFlushedCellsSize() { return flushedCellsSize.get(); } @Override public long getFlushedOutputFileSize() { return flushedOutputFileSize.get(); } @Override public long getCompactedCellsCount() { return compactedCellsCount.get(); } @Override public long getCompactedCellsSize() { return compactedCellsSize.get(); } @Override public long getMajorCompactedCellsCount() { return majorCompactedCellsCount.get(); } @Override public long getMajorCompactedCellsSize() { return majorCompactedCellsSize.get(); } /** * Returns the StoreEngine that is backing this concrete implementation of Store. * @return Returns the {@link StoreEngine} object used internally inside this HStore object. */ public StoreEngine getStoreEngine() { return this.storeEngine; } protected OffPeakHours getOffPeakHours() { return this.offPeakHours; } /** * {@inheritDoc} */ @Override public void onConfigurationChange(Configuration conf) { this.conf = new CompoundConfiguration() .add(conf) .addBytesMap(getColumnFamilyDescriptor().getValues()); this.storeEngine.compactionPolicy.setConf(conf); this.offPeakHours = OffPeakHours.getInstance(conf); } /** * {@inheritDoc} */ @Override public void registerChildren(ConfigurationManager manager) { // No children to register } /** * {@inheritDoc} */ @Override public void deregisterChildren(ConfigurationManager manager) { // No children to deregister } @Override public double getCompactionPressure() { return storeEngine.getStoreFileManager().getCompactionPressure(); } @Override public boolean isPrimaryReplicaStore() { return getRegionInfo().getReplicaId() == RegionInfo.DEFAULT_REPLICA_ID; } /** * Sets the store up for a region level snapshot operation. * @see #postSnapshotOperation() */ public void preSnapshotOperation() { archiveLock.lock(); } /** * Perform tasks needed after the completion of snapshot operation. * @see #preSnapshotOperation() */ public void postSnapshotOperation() { archiveLock.unlock(); } /** * Closes and archives the compacted files under this store */ public synchronized void closeAndArchiveCompactedFiles() throws IOException { // ensure other threads do not attempt to archive the same files on close() archiveLock.lock(); try { lock.readLock().lock(); Collection copyCompactedfiles = null; try { Collection compactedfiles = this.getStoreEngine().getStoreFileManager().getCompactedfiles(); if (CollectionUtils.isNotEmpty(compactedfiles)) { // Do a copy under read lock copyCompactedfiles = new ArrayList<>(compactedfiles); } else { LOG.trace("No compacted files to archive"); } } finally { lock.readLock().unlock(); } if (CollectionUtils.isNotEmpty(copyCompactedfiles)) { removeCompactedfiles(copyCompactedfiles, true); } } finally { archiveLock.unlock(); } } /** * Archives and removes the compacted files * @param compactedfiles The compacted files in this store that are not active in reads * @param evictOnClose true if blocks should be evicted from the cache when an HFile reader is * closed, false if not */ private void removeCompactedfiles(Collection compactedfiles, boolean evictOnClose) throws IOException { final List filesToRemove = new ArrayList<>(compactedfiles.size()); final List storeFileSizes = new ArrayList<>(compactedfiles.size()); for (final HStoreFile file : compactedfiles) { synchronized (file) { try { StoreFileReader r = file.getReader(); if (r == null) { LOG.debug("The file {} was closed but still not archived", file); // HACK: Temporarily re-open the reader so we can get the size of the file. Ideally, // we should know the size of an HStoreFile without having to ask the HStoreFileReader // for that. long length = getStoreFileSize(file); filesToRemove.add(file); storeFileSizes.add(length); continue; } if (file.isCompactedAway() && !file.isReferencedInReads()) { // Even if deleting fails we need not bother as any new scanners won't be // able to use the compacted file as the status is already compactedAway LOG.trace("Closing and archiving the file {}", file); // Copy the file size before closing the reader final long length = r.length(); r.close(evictOnClose); // Just close and return filesToRemove.add(file); // Only add the length if we successfully added the file to `filesToRemove` storeFileSizes.add(length); } else { LOG.info("Can't archive compacted file " + file.getPath() + " because of either isCompactedAway=" + file.isCompactedAway() + " or file has reference, isReferencedInReads=" + file.isReferencedInReads() + ", refCount=" + r.getRefCount() + ", skipping for now."); } } catch (Exception e) { LOG.error("Exception while trying to close the compacted store file {}", file.getPath(), e); } } } if (this.isPrimaryReplicaStore()) { // Only the primary region is allowed to move the file to archive. // The secondary region does not move the files to archive. Any active reads from // the secondary region will still work because the file as such has active readers on it. if (!filesToRemove.isEmpty()) { LOG.debug("Moving the files {} to archive", filesToRemove); // Only if this is successful it has to be removed try { getRegionFileSystem() .removeStoreFiles(this.getColumnFamilyDescriptor().getNameAsString(), filesToRemove); } catch (FailedArchiveException fae) { // Even if archiving some files failed, we still need to clear out any of the // files which were successfully archived. Otherwise we will receive a // FileNotFoundException when we attempt to re-archive them in the next go around. Collection failedFiles = fae.getFailedFiles(); Iterator iter = filesToRemove.iterator(); Iterator sizeIter = storeFileSizes.iterator(); while (iter.hasNext()) { sizeIter.next(); if (failedFiles.contains(iter.next().getPath())) { iter.remove(); sizeIter.remove(); } } if (!filesToRemove.isEmpty()) { clearCompactedfiles(filesToRemove); } throw fae; } } } if (!filesToRemove.isEmpty()) { // Clear the compactedfiles from the store file manager clearCompactedfiles(filesToRemove); // Try to send report of this archival to the Master for updating quota usage faster reportArchivedFilesForQuota(filesToRemove, storeFileSizes); } } /** * Computes the length of a store file without succumbing to any errors along the way. If an * error is encountered, the implementation returns {@code 0} instead of the actual size. * * @param file The file to compute the size of. * @return The size in bytes of the provided {@code file}. */ long getStoreFileSize(HStoreFile file) { long length = 0; try { file.initReader(); length = file.getReader().length(); } catch (IOException e) { LOG.trace("Failed to open reader when trying to compute store file size for {}, ignoring", file, e); } finally { try { file.closeStoreFile( file.getCacheConf() != null ? file.getCacheConf().shouldEvictOnClose() : true); } catch (IOException e) { LOG.trace("Failed to close reader after computing store file size for {}, ignoring", file, e); } } return length; } public Long preFlushSeqIDEstimation() { return memstore.preFlushSeqIDEstimation(); } @Override public boolean isSloppyMemStore() { return this.memstore.isSloppy(); } private void clearCompactedfiles(List filesToRemove) throws IOException { LOG.trace("Clearing the compacted file {} from this store", filesToRemove); try { lock.writeLock().lock(); this.getStoreEngine().getStoreFileManager().removeCompactedFiles(filesToRemove); } finally { lock.writeLock().unlock(); } } @Override public int getCurrentParallelPutCount() { return currentParallelPutCount.get(); } public int getStoreRefCount() { return this.storeEngine.getStoreFileManager().getStorefiles().stream() .filter(sf -> sf.getReader() != null).filter(HStoreFile::isHFile) .mapToInt(HStoreFile::getRefCount).sum(); } /** * @return get maximum ref count of storeFile among all compacted HStore Files for the HStore */ public int getMaxCompactedStoreFileRefCount() { OptionalInt maxCompactedStoreFileRefCount = this.storeEngine.getStoreFileManager() .getCompactedfiles() .stream() .filter(sf -> sf.getReader() != null) .filter(HStoreFile::isHFile) .mapToInt(HStoreFile::getRefCount) .max(); return maxCompactedStoreFileRefCount.isPresent() ? maxCompactedStoreFileRefCount.getAsInt() : 0; } void reportArchivedFilesForQuota(List archivedFiles, List fileSizes) { // Sanity check from the caller if (archivedFiles.size() != fileSizes.size()) { throw new RuntimeException("Coding error: should never see lists of varying size"); } RegionServerServices rss = this.region.getRegionServerServices(); if (rss == null) { return; } List> filesWithSizes = new ArrayList<>(archivedFiles.size()); Iterator fileSizeIter = fileSizes.iterator(); for (StoreFile storeFile : archivedFiles) { final long fileSize = fileSizeIter.next(); if (storeFile.isHFile() && fileSize != 0) { filesWithSizes.add(Maps.immutableEntry(storeFile.getPath().getName(), fileSize)); } } if (LOG.isTraceEnabled()) { LOG.trace("Files archived: " + archivedFiles + ", reporting the following to the Master: " + filesWithSizes); } boolean success = rss.reportFileArchivalForQuotas(getTableName(), filesWithSizes); if (!success) { LOG.warn("Failed to report archival of files: " + filesWithSizes); } } @Override public long getMemstoreOnlyRowReadsCount() { return memstoreOnlyRowReadsCount.sum(); } @Override public long getMixedRowReadsCount() { return mixedRowReadsCount.sum(); } void updateMetricsStore(boolean memstoreRead) { if (memstoreRead) { memstoreOnlyRowReadsCount.increment(); } else { mixedRowReadsCount.increment(); } } }





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