HRegion

/*
 *
 * 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.EOFException;
import java.io.IOException;
import java.io.InterruptedIOException;
import java.io.UnsupportedEncodingException;
import java.lang.reflect.Constructor;
import java.text.ParseException;
import java.util.AbstractList;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.Collection;
import java.util.Collections;
import java.util.HashMap;
import java.util.List;
import java.util.Map;
import java.util.NavigableMap;
import java.util.NavigableSet;
import java.util.Random;
import java.util.Set;
import java.util.TreeMap;
import java.util.UUID;
import java.util.concurrent.Callable;
import java.util.concurrent.CompletionService;
import java.util.concurrent.ConcurrentHashMap;
import java.util.concurrent.ConcurrentSkipListMap;
import java.util.concurrent.CountDownLatch;
import java.util.concurrent.ExecutionException;
import java.util.concurrent.ExecutorCompletionService;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;
import java.util.concurrent.Future;
import java.util.concurrent.FutureTask;
import java.util.concurrent.ThreadFactory;
import java.util.concurrent.ThreadPoolExecutor;
import java.util.concurrent.TimeUnit;
import java.util.concurrent.TimeoutException;
import java.util.concurrent.atomic.AtomicBoolean;
import java.util.concurrent.atomic.AtomicInteger;
import java.util.concurrent.atomic.AtomicLong;
import java.util.concurrent.locks.Lock;
import java.util.concurrent.locks.ReentrantReadWriteLock;

import org.apache.commons.logging.Log;
import org.apache.commons.logging.LogFactory;
import org.apache.hadoop.classification.InterfaceAudience;
import org.apache.hadoop.conf.Configuration;
import org.apache.hadoop.fs.FileStatus;
import org.apache.hadoop.fs.FileSystem;
import org.apache.hadoop.fs.Path;
import org.apache.hadoop.hbase.Cell;
import org.apache.hadoop.hbase.CompoundConfiguration;
import org.apache.hadoop.hbase.HBaseConfiguration;
import org.apache.hadoop.hbase.HColumnDescriptor;
import org.apache.hadoop.hbase.HConstants;
import org.apache.hadoop.hbase.HConstants.OperationStatusCode;
import org.apache.hadoop.hbase.HDFSBlocksDistribution;
import org.apache.hadoop.hbase.HRegionInfo;
import org.apache.hadoop.hbase.HTableDescriptor;
import org.apache.hadoop.hbase.KeyValue;
import org.apache.hadoop.hbase.KeyValueUtil;
import org.apache.hadoop.hbase.backup.HFileArchiver;
import org.apache.hadoop.hbase.client.Append;
import org.apache.hadoop.hbase.client.Delete;
import org.apache.hadoop.hbase.client.Durability;
import org.apache.hadoop.hbase.client.Get;
import org.apache.hadoop.hbase.client.Increment;
import org.apache.hadoop.hbase.client.IsolationLevel;
import org.apache.hadoop.hbase.client.Mutation;
import org.apache.hadoop.hbase.client.Put;
import org.apache.hadoop.hbase.client.Result;
import org.apache.hadoop.hbase.client.Row;
import org.apache.hadoop.hbase.client.RowMutations;
import org.apache.hadoop.hbase.client.Scan;
import org.apache.hadoop.hbase.errorhandling.ForeignExceptionSnare;
import org.apache.hadoop.hbase.exceptions.DroppedSnapshotException;
import org.apache.hadoop.hbase.exceptions.FailedSanityCheckException;
import org.apache.hadoop.hbase.exceptions.NoSuchColumnFamilyException;
import org.apache.hadoop.hbase.exceptions.NotServingRegionException;
import org.apache.hadoop.hbase.exceptions.RegionInRecoveryException;
import org.apache.hadoop.hbase.exceptions.RegionTooBusyException;
import org.apache.hadoop.hbase.exceptions.UnknownProtocolException;
import org.apache.hadoop.hbase.exceptions.UnknownScannerException;
import org.apache.hadoop.hbase.exceptions.WrongRegionException;
import org.apache.hadoop.hbase.filter.ByteArrayComparable;
import org.apache.hadoop.hbase.filter.CompareFilter.CompareOp;
import org.apache.hadoop.hbase.filter.Filter;
import org.apache.hadoop.hbase.filter.FilterWrapper;
import org.apache.hadoop.hbase.filter.IncompatibleFilterException;
import org.apache.hadoop.hbase.io.HeapSize;
import org.apache.hadoop.hbase.io.TimeRange;
import org.apache.hadoop.hbase.io.hfile.BlockCache;
import org.apache.hadoop.hbase.io.hfile.CacheConfig;
import org.apache.hadoop.hbase.ipc.RpcServer;
import org.apache.hadoop.hbase.ipc.RpcCallContext;
import org.apache.hadoop.hbase.monitoring.MonitoredTask;
import org.apache.hadoop.hbase.monitoring.TaskMonitor;
import org.apache.hadoop.hbase.protobuf.generated.AdminProtos.GetRegionInfoResponse.CompactionState;
import org.apache.hadoop.hbase.protobuf.generated.ClientProtos.CoprocessorServiceCall;
import org.apache.hadoop.hbase.protobuf.generated.HBaseProtos.SnapshotDescription;
import org.apache.hadoop.hbase.protobuf.generated.WALProtos.CompactionDescriptor;
import org.apache.hadoop.hbase.regionserver.MultiVersionConsistencyControl.WriteEntry;
import org.apache.hadoop.hbase.regionserver.compactions.CompactionContext;
import org.apache.hadoop.hbase.regionserver.wal.HLog;
import org.apache.hadoop.hbase.regionserver.wal.HLogFactory;
import org.apache.hadoop.hbase.regionserver.wal.HLogKey;
import org.apache.hadoop.hbase.regionserver.wal.HLogUtil;
import org.apache.hadoop.hbase.regionserver.wal.WALEdit;
import org.apache.hadoop.hbase.snapshot.SnapshotDescriptionUtils;
import org.apache.hadoop.hbase.util.Bytes;
import org.apache.hadoop.hbase.util.CancelableProgressable;
import org.apache.hadoop.hbase.util.ClassSize;
import org.apache.hadoop.hbase.util.CompressionTest;
import org.apache.hadoop.hbase.util.EnvironmentEdgeManager;
import org.apache.hadoop.hbase.util.FSUtils;
import org.apache.hadoop.hbase.util.HashedBytes;
import org.apache.hadoop.hbase.util.Pair;
import org.apache.hadoop.hbase.util.Threads;
import org.apache.hadoop.io.MultipleIOException;
import org.apache.hadoop.util.StringUtils;
import org.cliffc.high_scale_lib.Counter;

import com.google.common.base.Preconditions;
import com.google.common.collect.Lists;
import com.google.common.collect.Maps;
import com.google.common.io.Closeables;
import com.google.protobuf.Descriptors;
import com.google.protobuf.Message;
import com.google.protobuf.RpcCallback;
import com.google.protobuf.RpcController;
import com.google.protobuf.Service;

/**
 * HRegion stores data for a certain region of a table.  It stores all columns
 * for each row. A given table consists of one or more HRegions.
 *
 * <p>We maintain multiple HStores for a single HRegion.
 *
 * <p>An Store is a set of rows with some column data; together,
 * they make up all the data for the rows.
 *
 * <p>Each HRegion has a 'startKey' and 'endKey'.
 * <p>The first is inclusive, the second is exclusive (except for
 * the final region)  The endKey of region 0 is the same as
 * startKey for region 1 (if it exists).  The startKey for the
 * first region is null. The endKey for the final region is null.
 *
 * <p>Locking at the HRegion level serves only one purpose: preventing the
 * region from being closed (and consequently split) while other operations
 * are ongoing. Each row level operation obtains both a row lock and a region
 * read lock for the duration of the operation. While a scanner is being
 * constructed, getScanner holds a read lock. If the scanner is successfully
 * constructed, it holds a read lock until it is closed. A close takes out a
 * write lock and consequently will block for ongoing operations and will block
 * new operations from starting while the close is in progress.
 *
 * <p>An HRegion is defined by its table and its key extent.
 *
 * <p>It consists of at least one Store.  The number of Stores should be
 * configurable, so that data which is accessed together is stored in the same
 * Store.  Right now, we approximate that by building a single Store for
 * each column family.  (This config info will be communicated via the
 * tabledesc.)
 *
 * <p>The HTableDescriptor contains metainfo about the HRegion's table.
 * regionName is a unique identifier for this HRegion. (startKey, endKey]
 * defines the keyspace for this HRegion.
 */
@InterfaceAudience.Private
public class HRegion implements HeapSize { // , Writable{
  public static final Log LOG = LogFactory.getLog(HRegion.class);

  public static final String LOAD_CFS_ON_DEMAND_CONFIG_KEY =
      "hbase.hregion.scan.loadColumnFamiliesOnDemand";

  final AtomicBoolean closed = new AtomicBoolean(false);
  /* Closing can take some time; use the closing flag if there is stuff we don't
   * want to do while in closing state; e.g. like offer this region up to the
   * master as a region to close if the carrying regionserver is overloaded.
   * Once set, it is never cleared.
   */
  final AtomicBoolean closing = new AtomicBoolean(false);

  protected long completeSequenceId = -1L;

  /**
   * Operation enum is used in {@link HRegion#startRegionOperation} to provide operation context for
   * startRegionOperation to possibly invoke different checks before any region operations. Not all
   * operations have to be defined here. It's only needed when a special check is need in
   * startRegionOperation
   */
  protected enum Operation {
    ANY, GET, PUT, DELETE, SCAN, APPEND, INCREMENT, SPLIT_REGION, MERGE_REGION
  }

  //////////////////////////////////////////////////////////////////////////////
  // Members
  //////////////////////////////////////////////////////////////////////////////

  private final ConcurrentHashMap<HashedBytes, CountDownLatch> lockedRows =
    new ConcurrentHashMap<HashedBytes, CountDownLatch>();
  private final ConcurrentHashMap<Integer, HashedBytes> lockIds =
    new ConcurrentHashMap<Integer, HashedBytes>();
  private final AtomicInteger lockIdGenerator = new AtomicInteger(1);
  static private Random rand = new Random();

  protected final Map<byte[], Store> stores = new ConcurrentSkipListMap<byte[], Store>(
      Bytes.BYTES_RAWCOMPARATOR);

  // TODO: account for each registered handler in HeapSize computation
  private Map<String, Service> coprocessorServiceHandlers = Maps.newHashMap();

  public final AtomicLong memstoreSize = new AtomicLong(0);

  // Debug possible data loss due to WAL off
  final Counter numPutsWithoutWAL = new Counter();
  final Counter dataInMemoryWithoutWAL = new Counter();

  // Debug why CAS operations are taking a while.
  final Counter checkAndMutateChecksPassed = new Counter();
  final Counter checkAndMutateChecksFailed = new Counter();

  //Number of requests
  final Counter readRequestsCount = new Counter();
  final Counter writeRequestsCount = new Counter();

  //How long operations were blocked by a memstore over highwater.
  final Counter updatesBlockedMs = new Counter();

  private final HLog log;
  private final HRegionFileSystem fs;
  protected final Configuration conf;
  private final Configuration baseConf;
  private final KeyValue.KVComparator comparator;
  private final int rowLockWaitDuration;
  static final int DEFAULT_ROWLOCK_WAIT_DURATION = 30000;

  // The internal wait duration to acquire a lock before read/update
  // from the region. It is not per row. The purpose of this wait time
  // is to avoid waiting a long time while the region is busy, so that
  // we can release the IPC handler soon enough to improve the
  // availability of the region server. It can be adjusted by
  // tuning configuration "hbase.busy.wait.duration".
  final long busyWaitDuration;
  static final long DEFAULT_BUSY_WAIT_DURATION = HConstants.DEFAULT_HBASE_RPC_TIMEOUT;

  // If updating multiple rows in one call, wait longer,
  // i.e. waiting for busyWaitDuration * # of rows. However,
  // we can limit the max multiplier.
  final int maxBusyWaitMultiplier;

  // Max busy wait duration. There is no point to wait longer than the RPC
  // purge timeout, when a RPC call will be terminated by the RPC engine.
  final long maxBusyWaitDuration;

  // negative number indicates infinite timeout
  static final long DEFAULT_ROW_PROCESSOR_TIMEOUT = 60 * 1000L;
  final ExecutorService rowProcessorExecutor = Executors.newCachedThreadPool();

  private final ConcurrentHashMap<RegionScanner, Long> scannerReadPoints;

  /**
   * The sequence ID that was encountered when this region was opened.
   */
  private long openSeqNum = HConstants.NO_SEQNUM;

  /**
   * The default setting for whether to enable on-demand CF loading for
   * scan requests to this region. Requests can override it.
   */
  private boolean isLoadingCfsOnDemandDefault = false;

  private final AtomicInteger majorInProgress = new AtomicInteger(0);
  private final AtomicInteger minorInProgress = new AtomicInteger(0);

  /**
   * Min sequence id stored in store files of a region when opening the region
   */
  private long minSeqIdForLogReplay = -1;

  /**
   * @return The smallest mvcc readPoint across all the scanners in this
   * region. Writes older than this readPoint, are included  in every
   * read operation.
   */
  public long getSmallestReadPoint() {
    long minimumReadPoint;
    // We need to ensure that while we are calculating the smallestReadPoint
    // no new RegionScanners can grab a readPoint that we are unaware of.
    // We achieve this by synchronizing on the scannerReadPoints object.
    synchronized(scannerReadPoints) {
      minimumReadPoint = mvcc.memstoreReadPoint();

      for (Long readPoint: this.scannerReadPoints.values()) {
        if (readPoint < minimumReadPoint) {
          minimumReadPoint = readPoint;
        }
      }
    }
    return minimumReadPoint;
  }
  /*
   * Data structure of write state flags used coordinating flushes,
   * compactions and closes.
   */
  static class WriteState {
    // Set while a memstore flush is happening.
    volatile boolean flushing = false;
    // Set when a flush has been requested.
    volatile boolean flushRequested = false;
    // Number of compactions running.
    volatile int compacting = 0;
    // Gets set in close. If set, cannot compact or flush again.
    volatile boolean writesEnabled = true;
    // Set if region is read-only
    volatile boolean readOnly = false;

    /**
     * Set flags that make this region read-only.
     *
     * @param onOff flip value for region r/o setting
     */
    synchronized void setReadOnly(final boolean onOff) {
      this.writesEnabled = !onOff;
      this.readOnly = onOff;
    }

    boolean isReadOnly() {
      return this.readOnly;
    }

    boolean isFlushRequested() {
      return this.flushRequested;
    }

    static final long HEAP_SIZE = ClassSize.align(
        ClassSize.OBJECT + 5 * Bytes.SIZEOF_BOOLEAN);
  }

  final WriteState writestate = new WriteState();

  long memstoreFlushSize;
  final long timestampSlop;
  final long rowProcessorTimeout;
  private volatile long lastFlushTime;
  final RegionServerServices rsServices;
  private RegionServerAccounting rsAccounting;
  private List<Pair<Long, Long>> recentFlushes = new ArrayList<Pair<Long,Long>>();
  private long flushCheckInterval;
  private long blockingMemStoreSize;
  final long threadWakeFrequency;
  // Used to guard closes
  final ReentrantReadWriteLock lock =
    new ReentrantReadWriteLock();

  // Stop updates lock
  private final ReentrantReadWriteLock updatesLock =
    new ReentrantReadWriteLock();
  private boolean splitRequest;
  private byte[] explicitSplitPoint = null;

  private final MultiVersionConsistencyControl mvcc =
      new MultiVersionConsistencyControl();

  // Coprocessor host
  private RegionCoprocessorHost coprocessorHost;

  private HTableDescriptor htableDescriptor = null;
  private RegionSplitPolicy splitPolicy;

  private final MetricsRegion metricsRegion;
  private final MetricsRegionWrapperImpl metricsRegionWrapper;
  private final boolean deferredLogSyncDisabled;

  /**
   * HRegion constructor. This constructor should only be used for testing and
   * extensions.  Instances of HRegion should be instantiated with the
   * {@link HRegion#createHRegion} or {@link HRegion#openHRegion} method.
   *
   * @param tableDir qualified path of directory where region should be located,
   * usually the table directory.
   * @param log The HLog is the outbound log for any updates to the HRegion
   * (There's a single HLog for all the HRegions on a single HRegionServer.)
   * The log file is a logfile from the previous execution that's
   * custom-computed for this HRegion. The HRegionServer computes and sorts the
   * appropriate log info for this HRegion. If there is a previous log file
   * (implying that the HRegion has been written-to before), then read it from
   * the supplied path.
   * @param fs is the filesystem.
   * @param confParam is global configuration settings.
   * @param regionInfo - HRegionInfo that describes the region
   * is new), then read them from the supplied path.
   * @param htd the table descriptor
   * @param rsServices reference to {@link RegionServerServices} or null
   */
  @Deprecated
  public HRegion(final Path tableDir, final HLog log, final FileSystem fs,
      final Configuration confParam, final HRegionInfo regionInfo,
      final HTableDescriptor htd, final RegionServerServices rsServices) {
    this(new HRegionFileSystem(confParam, fs, tableDir, regionInfo),
      log, confParam, htd, rsServices);
  }

  /**
   * HRegion constructor. This constructor should only be used for testing and
   * extensions.  Instances of HRegion should be instantiated with the
   * {@link HRegion#createHRegion} or {@link HRegion#openHRegion} method.
   *
   * @param fs is the filesystem.
   * @param log The HLog is the outbound log for any updates to the HRegion
   * (There's a single HLog for all the HRegions on a single HRegionServer.)
   * The log file is a logfile from the previous execution that's
   * custom-computed for this HRegion. The HRegionServer computes and sorts the
   * appropriate log info for this HRegion. If there is a previous log file
   * (implying that the HRegion has been written-to before), then read it from
   * the supplied path.
   * @param confParam is global configuration settings.
   * @param htd the table descriptor
   * @param rsServices reference to {@link RegionServerServices} or null
   */
  public HRegion(final HRegionFileSystem fs, final HLog log, final Configuration confParam,
      final HTableDescriptor htd, final RegionServerServices rsServices) {
    if (htd == null) {
      throw new IllegalArgumentException("Need table descriptor");
    }

    if (confParam instanceof CompoundConfiguration) {
      throw new IllegalArgumentException("Need original base configuration");
    }

    this.comparator = fs.getRegionInfo().getComparator();
    this.log = log;
    this.fs = fs;

    // 'conf' renamed to 'confParam' b/c we use this.conf in the constructor
    this.baseConf = confParam;
    this.conf = new CompoundConfiguration()
      .add(confParam)
      .addStringMap(htd.getConfiguration())
      .addWritableMap(htd.getValues());
    this.flushCheckInterval = conf.getInt(MEMSTORE_PERIODIC_FLUSH_INTERVAL,
        DEFAULT_CACHE_FLUSH_INTERVAL);
    this.rowLockWaitDuration = conf.getInt("hbase.rowlock.wait.duration",
                    DEFAULT_ROWLOCK_WAIT_DURATION);

    this.isLoadingCfsOnDemandDefault = conf.getBoolean(LOAD_CFS_ON_DEMAND_CONFIG_KEY, true);
    this.htableDescriptor = htd;
    this.rsServices = rsServices;
    this.threadWakeFrequency = conf.getLong(HConstants.THREAD_WAKE_FREQUENCY, 10 * 1000);
    setHTableSpecificConf();
    this.scannerReadPoints = new ConcurrentHashMap<RegionScanner, Long>();

    this.busyWaitDuration = conf.getLong(
      "hbase.busy.wait.duration", DEFAULT_BUSY_WAIT_DURATION);
    this.maxBusyWaitMultiplier = conf.getInt("hbase.busy.wait.multiplier.max", 2);
    if (busyWaitDuration * maxBusyWaitMultiplier <= 0L) {
      throw new IllegalArgumentException("Invalid hbase.busy.wait.duration ("
        + busyWaitDuration + ") or hbase.busy.wait.multiplier.max ("
        + maxBusyWaitMultiplier + "). Their product should be positive");
    }
    this.maxBusyWaitDuration = conf.getLong("ipc.client.call.purge.timeout",
      2 * HConstants.DEFAULT_HBASE_RPC_TIMEOUT);

    /*
     * timestamp.slop provides a server-side constraint on the timestamp. This
     * assumes that you base your TS around currentTimeMillis(). In this case,
     * throw an error to the user if the user-specified TS is newer than now +
     * slop. LATEST_TIMESTAMP == don't use this functionality
     */
    this.timestampSlop = conf.getLong(
        "hbase.hregion.keyvalue.timestamp.slop.millisecs",
        HConstants.LATEST_TIMESTAMP);

    /**
     * Timeout for the process time in processRowsWithLocks().
     * Use -1 to switch off time bound.
     */
    this.rowProcessorTimeout = conf.getLong(
        "hbase.hregion.row.processor.timeout", DEFAULT_ROW_PROCESSOR_TIMEOUT);
    // When hbase.regionserver.optionallogflushinterval <= 0 , deferred log sync is disabled.
    this.deferredLogSyncDisabled = conf.getLong("hbase.regionserver.optionallogflushinterval",
        1 * 1000) <= 0;

    if (rsServices != null) {
      this.rsAccounting = this.rsServices.getRegionServerAccounting();
      // don't initialize coprocessors if not running within a regionserver
      // TODO: revisit if coprocessors should load in other cases
      this.coprocessorHost = new RegionCoprocessorHost(this, rsServices, conf);
      this.metricsRegionWrapper = new MetricsRegionWrapperImpl(this);
      this.metricsRegion = new MetricsRegion(this.metricsRegionWrapper);
    } else {
      this.metricsRegionWrapper = null;
      this.metricsRegion = null;
    }
    if (LOG.isDebugEnabled()) {
      // Write out region name as string and its encoded name.
      LOG.debug("Instantiated " + this);
    }
  }

  void setHTableSpecificConf() {
    if (this.htableDescriptor == null) return;
    long flushSize = this.htableDescriptor.getMemStoreFlushSize();

    if (flushSize <= 0) {
      flushSize = conf.getLong(HConstants.HREGION_MEMSTORE_FLUSH_SIZE,
        HTableDescriptor.DEFAULT_MEMSTORE_FLUSH_SIZE);
    }
    this.memstoreFlushSize = flushSize;
    this.blockingMemStoreSize = this.memstoreFlushSize *
        conf.getLong("hbase.hregion.memstore.block.multiplier", 2);
  }

  /**
   * Initialize this region.
   * Used only by tests and SplitTransaction to reopen the region.
   * You should use createHRegion() or openHRegion()
   * @return What the next sequence (edit) id should be.
   * @throws IOException e
   * @deprecated use HRegion.createHRegion() or HRegion.openHRegion()
   */
  @Deprecated
  public long initialize() throws IOException {
    return initialize(null);
  }

  /**
   * Initialize this region.
   *
   * @param reporter Tickle every so often if initialize is taking a while.
   * @return What the next sequence (edit) id should be.
   * @throws IOException e
   */
  private long initialize(final CancelableProgressable reporter) throws IOException {
    MonitoredTask status = TaskMonitor.get().createStatus("Initializing region " + this);
    long nextSeqId = -1;
    try {
      nextSeqId = initializeRegionInternals(reporter, status);
      return nextSeqId;
    } finally {
      // nextSeqid will be -1 if the initialization fails.
      // At least it will be 0 otherwise.
      if (nextSeqId == -1) {
        status
            .abort("Exception during region " + this.getRegionNameAsString() + " initialization.");
      }
    }
  }

  private long initializeRegionInternals(final CancelableProgressable reporter,
      final MonitoredTask status) throws IOException, UnsupportedEncodingException {
    if (coprocessorHost != null) {
      status.setStatus("Running coprocessor pre-open hook");
      coprocessorHost.preOpen();
    }

    // Write HRI to a file in case we need to recover .META.
    status.setStatus("Writing region info on filesystem");
    fs.checkRegionInfoOnFilesystem();

    // Remove temporary data left over from old regions
    status.setStatus("Cleaning up temporary data from old regions");
    fs.cleanupTempDir();

    // Initialize all the HStores
    status.setStatus("Initializing all the Stores");
    long maxSeqId = initializeRegionStores(reporter, status);

    status.setStatus("Cleaning up detritus from prior splits");
    // Get rid of any splits or merges that were lost in-progress.  Clean out
    // these directories here on open.  We may be opening a region that was
    // being split but we crashed in the middle of it all.
    fs.cleanupAnySplitDetritus();
    fs.cleanupMergesDir();

    this.writestate.setReadOnly(this.htableDescriptor.isReadOnly());
    this.writestate.flushRequested = false;
    this.writestate.compacting = 0;

    // Initialize split policy
    this.splitPolicy = RegionSplitPolicy.create(this, conf);

    this.lastFlushTime = EnvironmentEdgeManager.currentTimeMillis();
    // Use maximum of log sequenceid or that which was found in stores
    // (particularly if no recovered edits, seqid will be -1).
    long nextSeqid = maxSeqId + 1;
    LOG.info("Onlined " + this.toString() + "; next sequenceid=" + nextSeqid);

    // A region can be reopened if failed a split; reset flags
    this.closing.set(false);
    this.closed.set(false);

    if (coprocessorHost != null) {
      status.setStatus("Running coprocessor post-open hooks");
      coprocessorHost.postOpen();
    }

    status.markComplete("Region opened successfully");
    return nextSeqid;
  }

  private long initializeRegionStores(final CancelableProgressable reporter, MonitoredTask status)
      throws IOException, UnsupportedEncodingException {
    // Load in all the HStores.
    //
    // Context: During replay we want to ensure that we do not lose any data. So, we
    // have to be conservative in how we replay logs. For each store, we calculate
    // the maxSeqId up to which the store was flushed. And, skip the edits which
    // is equal to or lower than maxSeqId for each store.
    Map<byte[], Long> maxSeqIdInStores = new TreeMap<byte[], Long>(Bytes.BYTES_COMPARATOR);
    long maxSeqId = -1;
    // initialized to -1 so that we pick up MemstoreTS from column families
    long maxMemstoreTS = -1;

    if (!htableDescriptor.getFamilies().isEmpty()) {
      // initialize the thread pool for opening stores in parallel.
      ThreadPoolExecutor storeOpenerThreadPool =
        getStoreOpenAndCloseThreadPool(
          "StoreOpenerThread-" + this.getRegionNameAsString());
      CompletionService<HStore> completionService =
        new ExecutorCompletionService<HStore>(storeOpenerThreadPool);

      // initialize each store in parallel
      for (final HColumnDescriptor family : htableDescriptor.getFamilies()) {
        status.setStatus("Instantiating store for column family " + family);
        completionService.submit(new Callable<HStore>() {
          public HStore call() throws IOException {
            return instantiateHStore(family);
          }
        });
      }
      try {
        for (int i = 0; i < htableDescriptor.getFamilies().size(); i++) {
          Future<HStore> future = completionService.take();
          HStore store = future.get();

          this.stores.put(store.getColumnFamilyName().getBytes(), store);
          // Do not include bulk loaded files when determining seqIdForReplay
          long storeSeqIdForReplay = store.getMaxSequenceId(false);
          maxSeqIdInStores.put(store.getColumnFamilyName().getBytes(),
              storeSeqIdForReplay);
          if (this.minSeqIdForLogReplay == -1 || storeSeqIdForReplay < this.minSeqIdForLogReplay) {
            this.minSeqIdForLogReplay = storeSeqIdForReplay;
          }
          // Include bulk loaded files when determining seqIdForAssignment
          long storeSeqIdForAssignment = store.getMaxSequenceId(true);
          if (maxSeqId == -1 || storeSeqIdForAssignment > maxSeqId) {
            maxSeqId = storeSeqIdForAssignment;
          }
          long maxStoreMemstoreTS = store.getMaxMemstoreTS();
          if (maxStoreMemstoreTS > maxMemstoreTS) {
            maxMemstoreTS = maxStoreMemstoreTS;
          }
        }
      } catch (InterruptedException e) {
        throw new IOException(e);
      } catch (ExecutionException e) {
        throw new IOException(e.getCause());
      } finally {
        storeOpenerThreadPool.shutdownNow();
      }
    }
    mvcc.initialize(maxMemstoreTS + 1);
    // Recover any edits if available.
    maxSeqId = Math.max(maxSeqId, replayRecoveredEditsIfAny(
        this.fs.getRegionDir(), maxSeqIdInStores, reporter, status));
    return maxSeqId;
  }

  /**
   * @return True if this region has references.
   */
  public boolean hasReferences() {
    for (Store store : this.stores.values()) {
      if (store.hasReferences()) return true;
    }
    return false;
  }

  /**
   * This function will return the HDFS blocks distribution based on the data
   * captured when HFile is created
   * @return The HDFS blocks distribution for the region.
   */
  public HDFSBlocksDistribution getHDFSBlocksDistribution() {
    HDFSBlocksDistribution hdfsBlocksDistribution =
      new HDFSBlocksDistribution();
    synchronized (this.stores) {
      for (Store store : this.stores.values()) {
        for (StoreFile sf : store.getStorefiles()) {
          HDFSBlocksDistribution storeFileBlocksDistribution =
            sf.getHDFSBlockDistribution();
          hdfsBlocksDistribution.add(storeFileBlocksDistribution);
        }
      }
    }
    return hdfsBlocksDistribution;
  }

  /**
   * This is a helper function to compute HDFS block distribution on demand
   * @param conf configuration
   * @param tableDescriptor HTableDescriptor of the table
   * @param regionInfo encoded name of the region
   * @return The HDFS blocks distribution for the given region.
   * @throws IOException
   */
  public static HDFSBlocksDistribution computeHDFSBlocksDistribution(final Configuration conf,
      final HTableDescriptor tableDescriptor, final HRegionInfo regionInfo) throws IOException {
    HDFSBlocksDistribution hdfsBlocksDistribution = new HDFSBlocksDistribution();
    Path tablePath = FSUtils.getTablePath(FSUtils.getRootDir(conf), tableDescriptor.getName());
    FileSystem fs = tablePath.getFileSystem(conf);

    HRegionFileSystem regionFs = new HRegionFileSystem(conf, fs, tablePath, regionInfo);
    for (HColumnDescriptor family: tableDescriptor.getFamilies()) {
      Collection<StoreFileInfo> storeFiles = regionFs.getStoreFiles(family.getNameAsString());
      if (storeFiles == null) continue;

      for (StoreFileInfo storeFileInfo : storeFiles) {
        hdfsBlocksDistribution.add(storeFileInfo.computeHDFSBlocksDistribution(fs));
      }
    }
    return hdfsBlocksDistribution;
  }

  public AtomicLong getMemstoreSize() {
    return memstoreSize;
  }

  /**
   * Increase the size of mem store in this region and the size of global mem
   * store
   * @param memStoreSize
   * @return the size of memstore in this region
   */
  public long addAndGetGlobalMemstoreSize(long memStoreSize) {
    if (this.rsAccounting != null) {
      rsAccounting.addAndGetGlobalMemstoreSize(memStoreSize);
    }
    return this.memstoreSize.getAndAdd(memStoreSize);
  }

  /** @return a HRegionInfo object for this region */
  public HRegionInfo getRegionInfo() {
    return this.fs.getRegionInfo();
  }

  /**
   * @return Instance of {@link RegionServerServices} used by this HRegion.
   * Can be null.
   */
  RegionServerServices getRegionServerServices() {
    return this.rsServices;
  }

  /** @return readRequestsCount for this region */
  long getReadRequestsCount() {
    return this.readRequestsCount.get();
  }

  /** @return writeRequestsCount for this region */
  long getWriteRequestsCount() {
    return this.writeRequestsCount.get();
  }

  MetricsRegion getMetrics() {
    return metricsRegion;
  }

  /** @return true if region is closed */
  public boolean isClosed() {
    return this.closed.get();
  }

  /**
   * @return True if closing process has started.
   */
  public boolean isClosing() {
    return this.closing.get();
  }

  /**
   * Reset recovering state of current region
   * @param newState
   */
  public void setRecovering(boolean newState) {
    this.getRegionInfo().setRecovering(newState);
  }

  /**
   * @return True if current region is in recovering
   */
  public boolean isRecovering() {
    return this.getRegionInfo().isRecovering();
  }

  /** @return true if region is available (not closed and not closing) */
  public boolean isAvailable() {
    return !isClosed() && !isClosing();
  }

  /** @return true if region is splittable */
  public boolean isSplittable() {
    return isAvailable() && !hasReferences();
  }

  /**
   * @return true if region is mergeable
   */
  public boolean isMergeable() {
    if (!isAvailable()) {
      LOG.debug("Region " + this.getRegionNameAsString()
          + " is not mergeable because it is closing or closed");
      return false;
    }
    if (hasReferences()) {
      LOG.debug("Region " + this.getRegionNameAsString()
          + " is not mergeable because it has references");
      return false;
    }

    return true;
  }

  public boolean areWritesEnabled() {
    synchronized(this.writestate) {
      return this.writestate.writesEnabled;
    }
  }

   public MultiVersionConsistencyControl getMVCC() {
     return mvcc;
   }

   public boolean isLoadingCfsOnDemandDefault() {
     return this.isLoadingCfsOnDemandDefault;
   }

  /**
   * Close down this HRegion.  Flush the cache, shut down each HStore, don't
   * service any more calls.
   *
   * <p>This method could take some time to execute, so don't call it from a
   * time-sensitive thread.
   *
   * @return Vector of all the storage files that the HRegion's component
   * HStores make use of.  It's a list of all HStoreFile objects. Returns empty
   * vector if already closed and null if judged that it should not close.
   *
   * @throws IOException e
   */
  public Map<byte[], List<StoreFile>> close() throws IOException {
    return close(false);
  }

  private final Object closeLock = new Object();

  /** Conf key for the periodic flush interval */
  public static final String MEMSTORE_PERIODIC_FLUSH_INTERVAL =
      "hbase.regionserver.optionalcacheflushinterval";
  /** Default interval for the memstore flush */
  public static final int DEFAULT_CACHE_FLUSH_INTERVAL = 3600000;

  /**
   * Close down this HRegion.  Flush the cache unless abort parameter is true,
   * Shut down each HStore, don't service any more calls.
   *
   * This method could take some time to execute, so don't call it from a
   * time-sensitive thread.
   *
   * @param abort true if server is aborting (only during testing)
   * @return Vector of all the storage files that the HRegion's component
   * HStores make use of.  It's a list of HStoreFile objects.  Can be null if
   * we are not to close at this time or we are already closed.
   *
   * @throws IOException e
   */
  public Map<byte[], List<StoreFile>> close(final boolean abort) throws IOException {
    // Only allow one thread to close at a time. Serialize them so dual
    // threads attempting to close will run up against each other.
    MonitoredTask status = TaskMonitor.get().createStatus(
        "Closing region " + this +
        (abort ? " due to abort" : ""));

    status.setStatus("Waiting for close lock");
    try {
      synchronized (closeLock) {
        return doClose(abort, status);
      }
    } finally {
      status.cleanup();
    }
  }

  private Map<byte[], List<StoreFile>> doClose(final boolean abort, MonitoredTask status)
      throws IOException {
    if (isClosed()) {
      LOG.warn("Region " + this + " already closed");
      return null;
    }

    if (coprocessorHost != null) {
      status.setStatus("Running coprocessor pre-close hooks");
      this.coprocessorHost.preClose(abort);
    }

    status.setStatus("Disabling compacts and flushes for region");
    boolean wasFlushing = false;
    synchronized (writestate) {
      // Disable compacting and flushing by background threads for this
      // region.
      writestate.writesEnabled = false;
      wasFlushing = writestate.flushing;
      LOG.debug("Closing " + this + ": disabling compactions & flushes");
      waitForFlushesAndCompactions();
    }
    // If we were not just flushing, is it worth doing a preflush...one
    // that will clear out of the bulk of the memstore before we put up
    // the close flag?
    if (!abort && !wasFlushing && worthPreFlushing()) {
      status.setStatus("Pre-flushing region before close");
      LOG.info("Running close preflush of " + this.getRegionNameAsString());
      internalFlushcache(status);
    }

    this.closing.set(true);
    status.setStatus("Disabling writes for close");
    // block waiting for the lock for closing
    lock.writeLock().lock();
    try {
      if (this.isClosed()) {
        status.abort("Already got closed by another process");
        // SplitTransaction handles the null
        return null;
      }
      LOG.debug("Updates disabled for region " + this);
      // Don't flush the cache if we are aborting
      if (!abort) {
        internalFlushcache(status);
      }

      Map<byte[], List<StoreFile>> result =
        new TreeMap<byte[], List<StoreFile>>(Bytes.BYTES_COMPARATOR);
      if (!stores.isEmpty()) {
        // initialize the thread pool for closing stores in parallel.
        ThreadPoolExecutor storeCloserThreadPool =
          getStoreOpenAndCloseThreadPool("StoreCloserThread-" + this.getRegionNameAsString());
        CompletionService<Pair<byte[], Collection<StoreFile>>> completionService =
          new ExecutorCompletionService<Pair<byte[], Collection<StoreFile>>>(storeCloserThreadPool);

        // close each store in parallel
        for (final Store store : stores.values()) {
          completionService
              .submit(new Callable<Pair<byte[], Collection<StoreFile>>>() {
                public Pair<byte[], Collection<StoreFile>> call() throws IOException {
                  return new Pair<byte[], Collection<StoreFile>>(
                    store.getFamily().getName(), store.close());
                }
              });
        }
        try {
          for (int i = 0; i < stores.size(); i++) {
            Future<Pair<byte[], Collection<StoreFile>>> future = completionService.take();
            Pair<byte[], Collection<StoreFile>> storeFiles = future.get();
            List<StoreFile> familyFiles = result.get(storeFiles.getFirst());
            if (familyFiles == null) {
              familyFiles = new ArrayList<StoreFile>();
              result.put(storeFiles.getFirst(), familyFiles);
            }
            familyFiles.addAll(storeFiles.getSecond());
          }
        } catch (InterruptedException e) {
          throw new IOException(e);
        } catch (ExecutionException e) {
          throw new IOException(e.getCause());
        } finally {
          storeCloserThreadPool.shutdownNow();
        }
      }
      this.closed.set(true);

       if (coprocessorHost != null) {
         status.setStatus("Running coprocessor post-close hooks");
         this.coprocessorHost.postClose(abort);
       }
       if ( this.metricsRegion != null) {
         this.metricsRegion.close();
       }
       if ( this.metricsRegionWrapper != null) {
         Closeables.closeQuietly(this.metricsRegionWrapper);
       }
       status.markComplete("Closed");
       LOG.info("Closed " + this);
       return result;
     } finally {
       lock.writeLock().unlock();
     }
   }

   /**
    * Wait for all current flushes and compactions of the region to complete.
    * <p>
    * Exposed for TESTING.
    */
   public void waitForFlushesAndCompactions() {
     synchronized (writestate) {
       while (writestate.compacting > 0 || writestate.flushing) {
         LOG.debug("waiting for " + writestate.compacting + " compactions"
             + (writestate.flushing ? " & cache flush" : "") + " to complete for region " + this);
         try {
           writestate.wait();
         } catch (InterruptedException iex) {
           // essentially ignore and propagate the interrupt back up
           Thread.currentThread().interrupt();
         }
       }
     }
   }

   protected ThreadPoolExecutor getStoreOpenAndCloseThreadPool(
       final String threadNamePrefix) {
     int numStores = Math.max(1, this.htableDescriptor.getFamilies().size());
     int maxThreads = Math.min(numStores,
         conf.getInt(HConstants.HSTORE_OPEN_AND_CLOSE_THREADS_MAX,
             HConstants.DEFAULT_HSTORE_OPEN_AND_CLOSE_THREADS_MAX));
     return getOpenAndCloseThreadPool(maxThreads, threadNamePrefix);
   }

   protected ThreadPoolExecutor getStoreFileOpenAndCloseThreadPool(
       final String threadNamePrefix) {
     int numStores = Math.max(1, this.htableDescriptor.getFamilies().size());
     int maxThreads = Math.max(1,
         conf.getInt(HConstants.HSTORE_OPEN_AND_CLOSE_THREADS_MAX,
             HConstants.DEFAULT_HSTORE_OPEN_AND_CLOSE_THREADS_MAX)
             / numStores);
     return getOpenAndCloseThreadPool(maxThreads, threadNamePrefix);
   }

   static ThreadPoolExecutor getOpenAndCloseThreadPool(int maxThreads,
       final String threadNamePrefix) {
     return Threads.getBoundedCachedThreadPool(maxThreads, 30L, TimeUnit.SECONDS,
       new ThreadFactory() {
         private int count = 1;

         public Thread newThread(Runnable r) {
           return new Thread(r, threadNamePrefix + "-" + count++);
         }
       });
   }

    /**
     * @return True if its worth doing a flush before we put up the close flag.
     */
   private boolean worthPreFlushing() {
     return this.memstoreSize.get() >
       this.conf.getLong("hbase.hregion.preclose.flush.size", 1024 * 1024 * 5);
   }

   //////////////////////////////////////////////////////////////////////////////
   // HRegion accessors
   //////////////////////////////////////////////////////////////////////////////

   /** @return start key for region */
   public byte [] getStartKey() {
     return this.getRegionInfo().getStartKey();
   }

   /** @return end key for region */
   public byte [] getEndKey() {
     return this.getRegionInfo().getEndKey();
   }

   /** @return region id */
   public long getRegionId() {
     return this.getRegionInfo().getRegionId();
   }

   /** @return region name */
   public byte [] getRegionName() {
     return this.getRegionInfo().getRegionName();
   }

   /** @return region name as string for logging */
   public String getRegionNameAsString() {
     return this.getRegionInfo().getRegionNameAsString();
   }

   /** @return HTableDescriptor for this region */
   public HTableDescriptor getTableDesc() {
     return this.htableDescriptor;
   }

   /** @return HLog in use for this region */
   public HLog getLog() {
     return this.log;
   }

   /**
    * A split takes the config from the parent region & passes it to the daughter
    * region's constructor. If 'conf' was passed, you would end up using the HTD
    * of the parent region in addition to the new daughter HTD. Pass 'baseConf'
    * to the daughter regions to avoid this tricky dedupe problem.
    * @return Configuration object
    */
   Configuration getBaseConf() {
     return this.baseConf;
   }

   /** @return {@link FileSystem} being used by this region */
   public FileSystem getFilesystem() {
     return fs.getFileSystem();
   }

   /** @return the {@link HRegionFileSystem} used by this region */
   public HRegionFileSystem getRegionFileSystem() {
     return this.fs;
   }

   /** @return the last time the region was flushed */
   public long getLastFlushTime() {
     return this.lastFlushTime;
   }

   //////////////////////////////////////////////////////////////////////////////
   // HRegion maintenance.
   //
   // These methods are meant to be called periodically by the HRegionServer for
   // upkeep.
   //////////////////////////////////////////////////////////////////////////////

   /** @return returns size of largest HStore. */
   public long getLargestHStoreSize() {
     long size = 0;
     for (Store h : stores.values()) {
       long storeSize = h.getSize();
       if (storeSize > size) {
         size = storeSize;
       }
     }
     return size;
   }

   /*
    * Do preparation for pending compaction.
    * @throws IOException
    */
   protected void doRegionCompactionPrep() throws IOException {
   }

   void triggerMajorCompaction() {
     for (Store h : stores.values()) {
       h.triggerMajorCompaction();
     }
   }

   /**
    * This is a helper function that compact all the stores synchronously
    * It is used by utilities and testing
    *
    * @param majorCompaction True to force a major compaction regardless of thresholds
    * @throws IOException e
    */
   public void compactStores(final boolean majorCompaction)
   throws IOException {
     if (majorCompaction) {
       this.triggerMajorCompaction();
     }
     compactStores();
   }

   /**
    * This is a helper function that compact all the stores synchronously
    * It is used by utilities and testing
    *
    * @throws IOException e
    */
   public void compactStores() throws IOException {
     for (Store s : getStores().values()) {
       CompactionContext compaction = s.requestCompaction();
       if (compaction != null) {
         compact(compaction, s);
       }
     }
   }

   /*
    * Called by compaction thread and after region is opened to compact the
    * HStores if necessary.
    *
    * <p>This operation could block for a long time, so don't call it from a
    * time-sensitive thread.
    *
    * Note that no locking is necessary at this level because compaction only
    * conflicts with a region split, and that cannot happen because the region
    * server does them sequentially and not in parallel.
    *
    * @param cr Compaction details, obtained by requestCompaction()
    * @return whether the compaction completed
    * @throws IOException e
    */
   public boolean compact(CompactionContext compaction, Store store) throws IOException {
     assert compaction != null && compaction.hasSelection();
     assert !compaction.getRequest().getFiles().isEmpty();
     if (this.closing.get() || this.closed.get()) {
       LOG.debug("Skipping compaction on " + this + " because closing/closed");
       store.cancelRequestedCompaction(compaction);
       return false;
     }
     MonitoredTask status = null;
     boolean didPerformCompaction = false;
     // block waiting for the lock for compaction
     lock.readLock().lock();
     try {
       status = TaskMonitor.get().createStatus("Compacting " + store + " in " + this);
       if (this.closed.get()) {
         String msg = "Skipping compaction on " + this + " because closed";
         LOG.debug(msg);
         status.abort(msg);
         return false;
       }
       boolean wasStateSet = false;
       try {
         synchronized (writestate) {
           if (writestate.writesEnabled) {
             wasStateSet = true;
             ++writestate.compacting;
           } else {
             String msg = "NOT compacting region " + this + ". Writes disabled.";
             LOG.info(msg);
             status.abort(msg);
             return false;
           }
         }
         LOG.info("Starting compaction on " + store + " in region " + this
             + (compaction.getRequest().isOffPeak()?" as an off-peak compaction":""));
         doRegionCompactionPrep();
         try {
           status.setStatus("Compacting store " + store);
           didPerformCompaction = true;
           store.compact(compaction);
         } catch (InterruptedIOException iioe) {
           String msg = "compaction interrupted";
           LOG.info(msg, iioe);
           status.abort(msg);
           return false;
         }
       } finally {
         if (wasStateSet) {
           synchronized (writestate) {
             --writestate.compacting;
             if (writestate.compacting <= 0) {
               writestate.notifyAll();
             }
           }
         }
       }
       status.markComplete("Compaction complete");
       return true;
     } finally {
       try {
         if (!didPerformCompaction) store.cancelRequestedCompaction(compaction);
         if (status != null) status.cleanup();
       } finally {
         lock.readLock().unlock();
       }
     }
   }

   /**
    * Flush the cache.
    *
    * When this method is called the cache will be flushed unless:
    * <ol>
    *   <li>the cache is empty</li>
    *   <li>the region is closed.</li>
    *   <li>a flush is already in progress</li>
    *   <li>writes are disabled</li>
    * </ol>
    *
    * <p>This method may block for some time, so it should not be called from a
    * time-sensitive thread.
    *
    * @return true if cache was flushed
    *
    * @throws IOException general io exceptions
    * @throws DroppedSnapshotException Thrown when replay of hlog is required
    * because a Snapshot was not properly persisted.
    */
   public boolean flushcache() throws IOException {
     // fail-fast instead of waiting on the lock
     if (this.closing.get()) {
       LOG.debug("Skipping flush on " + this + " because closing");
       return false;
     }
     MonitoredTask status = TaskMonitor.get().createStatus("Flushing " + this);
     status.setStatus("Acquiring readlock on region");
     // block waiting for the lock for flushing cache
     lock.readLock().lock();
     try {
       if (this.closed.get()) {
         LOG.debug("Skipping flush on " + this + " because closed");
         status.abort("Skipped: closed");
         return false;
       }
       if (coprocessorHost != null) {
         status.setStatus("Running coprocessor pre-flush hooks");
         coprocessorHost.preFlush();
       }
       if (numPutsWithoutWAL.get() > 0) {
         numPutsWithoutWAL.set(0);
         dataInMemoryWithoutWAL.set(0);
       }
       synchronized (writestate) {
         if (!writestate.flushing && writestate.writesEnabled) {
           this.writestate.flushing = true;
         } else {
           if (LOG.isDebugEnabled()) {
             LOG.debug("NOT flushing memstore for region " + this
                 + ", flushing=" + writestate.flushing + ", writesEnabled="
                 + writestate.writesEnabled);
           }
           status.abort("Not flushing since "
               + (writestate.flushing ? "already flushing"
                   : "writes not enabled"));
           return false;
         }
       }
       try {
         boolean result = internalFlushcache(status);

         if (coprocessorHost != null) {
           status.setStatus("Running post-flush coprocessor hooks");
           coprocessorHost.postFlush();
         }

         status.markComplete("Flush successful");
         return result;
       } finally {
         synchronized (writestate) {
           writestate.flushing = false;
           this.writestate.flushRequested = false;
           writestate.notifyAll();
         }
       }
     } finally {
       lock.readLock().unlock();
       status.cleanup();
     }
   }

   /**
    * Should the memstore be flushed now
    */
   boolean shouldFlush() {
     if (flushCheckInterval <= 0) { //disabled
       return false;
     }
     long now = EnvironmentEdgeManager.currentTimeMillis();
     //if we flushed in the recent past, we don't need to do again now
     if ((now - getLastFlushTime() < flushCheckInterval)) {
       return false;
     }
     //since we didn't flush in the recent past, flush now if certain conditions
     //are met. Return true on first such memstore hit.
     for (Store s : this.getStores().values()) {
       if (s.timeOfOldestEdit() < now - flushCheckInterval) {
         // we have an old enough edit in the memstore, flush
         return true;
       }
     }
     return false;
   }

   /**
    * Flush the memstore.
    *
    * Flushing the memstore is a little tricky. We have a lot of updates in the
    * memstore, all of which have also been written to the log. We need to
    * write those updates in the memstore out to disk, while being able to
    * process reads/writes as much as possible during the flush operation. Also,
    * the log has to state clearly the point in time at which the memstore was
    * flushed. (That way, during recovery, we know when we can rely on the
    * on-disk flushed structures and when we have to recover the memstore from
    * the log.)
    *
    * <p>So, we have a three-step process:
    *
    * <ul><li>A. Flush the memstore to the on-disk stores, noting the current
    * sequence ID for the log.<li>
    *
    * <li>B. Write a FLUSHCACHE-COMPLETE message to the log, using the sequence
    * ID that was current at the time of memstore-flush.</li>
    *
    * <li>C. Get rid of the memstore structures that are now redundant, as
    * they've been flushed to the on-disk HStores.</li>
    * </ul>
    * <p>This method is protected, but can be accessed via several public
    * routes.
    *
    * <p> This method may block for some time.
    * @param status
    *
    * @return true if the region needs compacting
    *
    * @throws IOException general io exceptions
    * @throws DroppedSnapshotException Thrown when replay of hlog is required
    * because a Snapshot was not properly persisted.
    */
   protected boolean internalFlushcache(MonitoredTask status)
       throws IOException {
     return internalFlushcache(this.log, -1, status);
   }

   /**
    * @param wal Null if we're NOT to go via hlog/wal.
    * @param myseqid The seqid to use if <code>wal</code> is null writing out
    * flush file.
    * @param status
    * @return true if the region needs compacting
    * @throws IOException
    * @see #internalFlushcache(MonitoredTask)
    */
   protected boolean internalFlushcache(
       final HLog wal, final long myseqid, MonitoredTask status)
   throws IOException {
     if (this.rsServices != null && this.rsServices.isAborted()) {
       // Don't flush when server aborting, it's unsafe
       throw new IOException("Aborting flush because server is abortted...");
     }
     final long startTime = EnvironmentEdgeManager.currentTimeMillis();
     // Clear flush flag.
     // Record latest flush time
     this.lastFlushTime = startTime;
     // If nothing to flush, return and avoid logging start/stop flush.
     if (this.memstoreSize.get() <= 0) {
       return false;
     }
     if (LOG.isDebugEnabled()) {
       LOG.debug("Started memstore flush for " + this +
         ", current region memstore size " +
         StringUtils.humanReadableInt(this.memstoreSize.get()) +
         ((wal != null)? "": "; wal is null, using passed sequenceid=" + myseqid));
     }

     // Stop updates while we snapshot the memstore of all stores. We only have
     // to do this for a moment.  Its quick.  The subsequent sequence id that
     // goes into the HLog after we've flushed all these snapshots also goes
     // into the info file that sits beside the flushed files.
     // We also set the memstore size to zero here before we allow updates
     // again so its value will represent the size of the updates received
     // during the flush
     MultiVersionConsistencyControl.WriteEntry w = null;

     // We have to take a write lock during snapshot, or else a write could
     // end up in both snapshot and memstore (makes it difficult to do atomic
     // rows then)
     status.setStatus("Obtaining lock to block concurrent updates");
     // block waiting for the lock for internal flush
     this.updatesLock.writeLock().lock();
     long flushsize = this.memstoreSize.get();
     status.setStatus("Preparing to flush by snapshotting stores");
     List<StoreFlushContext> storeFlushCtxs = new ArrayList<StoreFlushContext>(stores.size());
     long flushSeqId = -1L;
     try {
       // Record the mvcc for all transactions in progress.
       w = mvcc.beginMemstoreInsert();
       mvcc.advanceMemstore(w);

       if (wal != null) {
         Long startSeqId = wal.startCacheFlush(this.getRegionInfo().getEncodedNameAsBytes());
         if (startSeqId == null) {
           status.setStatus("Flush will not be started for [" + this.getRegionInfo().getEncodedName()
               + "] - WAL is going away");
           return false;
         }
         flushSeqId = startSeqId.longValue();
       } else {
         flushSeqId = myseqid;
       }

       for (Store s : stores.values()) {
         storeFlushCtxs.add(s.createFlushContext(flushSeqId));
       }

       // prepare flush (take a snapshot)
       for (StoreFlushContext flush : storeFlushCtxs) {
         flush.prepare();
       }
     } finally {
       this.updatesLock.writeLock().unlock();
     }
     String s = "Finished snapshotting " + this +
       ", commencing wait for mvcc, flushsize=" + flushsize;
     status.setStatus(s);
     LOG.debug(s);

     // sync unflushed WAL changes when deferred log sync is enabled
     // see HBASE-8208 for details
     if (wal != null && isDeferredLogSyncEnabled()) {
       wal.sync();
     }

     // wait for all in-progress transactions to commit to HLog before
     // we can start the flush. This prevents
     // uncommitted transactions from being written into HFiles.
     // We have to block before we start the flush, otherwise keys that
     // were removed via a rollbackMemstore could be written to Hfiles.
     mvcc.waitForRead(w);

     status.setStatus("Flushing stores");
     LOG.debug("Finished snapshotting, commencing flushing stores");

     // Any failure from here on out will be catastrophic requiring server
     // restart so hlog content can be replayed and put back into the memstore.
     // Otherwise, the snapshot content while backed up in the hlog, it will not
     // be part of the current running servers state.
     boolean compactionRequested = false;
     try {
       // A.  Flush memstore to all the HStores.
       // Keep running vector of all store files that includes both old and the
       // just-made new flush store file. The new flushed file is still in the
       // tmp directory.

       for (StoreFlushContext flush : storeFlushCtxs) {
         flush.flushCache(status);
       }

       // Switch snapshot (in memstore) -> new hfile (thus causing
       // all the store scanners to reset/reseek).
       for (StoreFlushContext flush : storeFlushCtxs) {
         boolean needsCompaction = flush.commit(status);
         if (needsCompaction) {
           compactionRequested = true;
         }
       }
       storeFlushCtxs.clear();

       // Set down the memstore size by amount of flush.
       this.addAndGetGlobalMemstoreSize(-flushsize);
     } catch (Throwable t) {
       // An exception here means that the snapshot was not persisted.
       // The hlog needs to be replayed so its content is restored to memstore.
       // Currently, only a server restart will do this.
       // We used to only catch IOEs but its possible that we'd get other
       // exceptions -- e.g. HBASE-659 was about an NPE -- so now we catch
       // all and sundry.
       if (wal != null) {
         wal.abortCacheFlush(this.getRegionInfo().getEncodedNameAsBytes());
       }
       DroppedSnapshotException dse = new DroppedSnapshotException("region: " +
           Bytes.toStringBinary(getRegionName()));
       dse.initCause(t);
       status.abort("Flush failed: " + StringUtils.stringifyException(t));
       throw dse;
     }

     // If we get to here, the HStores have been written.
     if (wal != null) {
       wal.completeCacheFlush(this.getRegionInfo().getEncodedNameAsBytes());
     }

     // Update the last flushed sequence id for region
     if (this.rsServices != null) {
       completeSequenceId = flushSeqId;
     }

     // C. Finally notify anyone waiting on memstore to clear:
     // e.g. checkResources().
     synchronized (this) {
       notifyAll(); // FindBugs NN_NAKED_NOTIFY
     }

     long time = EnvironmentEdgeManager.currentTimeMillis() - startTime;
     long memstoresize = this.memstoreSize.get();
     String msg = "Finished memstore flush of ~" +
       StringUtils.humanReadableInt(flushsize) + "/" + flushsize +
       ", currentsize=" +
       StringUtils.humanReadableInt(memstoresize) + "/" + memstoresize +
       " for region " + this + " in " + time + "ms, sequenceid=" + flushSeqId +
       ", compaction requested=" + compactionRequested +
       ((wal == null)? "; wal=null": "");
     LOG.info(msg);
     status.setStatus(msg);
     this.recentFlushes.add(new Pair<Long,Long>(time/1000, flushsize));

     return compactionRequested;
   }

   //////////////////////////////////////////////////////////////////////////////
   // get() methods for client use.
   //////////////////////////////////////////////////////////////////////////////
   /**
    * Return all the data for the row that matches <i>row</i> exactly,
    * or the one that immediately preceeds it, at or immediately before
    * <i>ts</i>.
    *
    * @param row row key
    * @return map of values
    * @throws IOException
    */
   Result getClosestRowBefore(final byte [] row)
   throws IOException{
     return getClosestRowBefore(row, HConstants.CATALOG_FAMILY);
   }

   /**
    * Return all the data for the row that matches <i>row</i> exactly,
    * or the one that immediately preceeds it, at or immediately before
    * <i>ts</i>.
    *
    * @param row row key
    * @param family column family to find on
    * @return map of values
    * @throws IOException read exceptions
    */
   public Result getClosestRowBefore(final byte [] row, final byte [] family)
   throws IOException {
     if (coprocessorHost != null) {
       Result result = new Result();
       if (coprocessorHost.preGetClosestRowBefore(row, family, result)) {
         return result;
       }
     }
     // look across all the HStores for this region and determine what the
     // closest key is across all column families, since the data may be sparse
     checkRow(row, "getClosestRowBefore");
     startRegionOperation(Operation.GET);
     this.readRequestsCount.increment();
     try {
       Store store = getStore(family);
       // get the closest key. (HStore.getRowKeyAtOrBefore can return null)
       KeyValue key = store.getRowKeyAtOrBefore(row);
       Result result = null;
       if (key != null) {
         Get get = new Get(key.getRow());
         get.addFamily(family);
         result = get(get);
       }
       if (coprocessorHost != null) {
         coprocessorHost.postGetClosestRowBefore(row, family, result);
       }
       return result;
     } finally {
       closeRegionOperation();
     }
   }

   /**
    * Return an iterator that scans over the HRegion, returning the indicated
    * columns and rows specified by the {@link Scan}.
    * <p>
    * This Iterator must be closed by the caller.
    *
    * @param scan configured {@link Scan}
    * @return RegionScanner
    * @throws IOException read exceptions
    */
   public RegionScanner getScanner(Scan scan) throws IOException {
    return getScanner(scan, null);
   }

   void prepareScanner(Scan scan) throws IOException {
     if(!scan.hasFamilies()) {
       // Adding all families to scanner
       for(byte[] family: this.htableDescriptor.getFamiliesKeys()){
         scan.addFamily(family);
       }
     }
   }

   protected RegionScanner getScanner(Scan scan,
       List<KeyValueScanner> additionalScanners) throws IOException {
     startRegionOperation(Operation.SCAN);
     try {
       // Verify families are all valid
       prepareScanner(scan);
       if(scan.hasFamilies()) {
         for(byte [] family : scan.getFamilyMap().keySet()) {
           checkFamily(family);
         }
       }
       return instantiateRegionScanner(scan, additionalScanners);
     } finally {
       closeRegionOperation();
     }
   }

   protected RegionScanner instantiateRegionScanner(Scan scan,
       List<KeyValueScanner> additionalScanners) throws IOException {
     return new RegionScannerImpl(scan, additionalScanners, this);
   }

   /*
    * @param delete The passed delete is modified by this method. WARNING!
    */
   void prepareDelete(Delete delete) throws IOException {
     // Check to see if this is a deleteRow insert
     if(delete.getFamilyMap().isEmpty()){
       for(byte [] family : this.htableDescriptor.getFamiliesKeys()){
         // Don't eat the timestamp
         delete.deleteFamily(family, delete.getTimeStamp());
       }
     } else {
       for(byte [] family : delete.getFamilyMap().keySet()) {
         if(family == null) {
           throw new NoSuchColumnFamilyException("Empty family is invalid");
         }
         checkFamily(family);
       }
     }
   }

   //////////////////////////////////////////////////////////////////////////////
   // set() methods for client use.
   //////////////////////////////////////////////////////////////////////////////
   /**
    * @param delete delete object
    * @throws IOException read exceptions
    */
   public void delete(Delete delete)
   throws IOException {
     checkReadOnly();
     checkResources();
     startRegionOperation(Operation.DELETE);
     this.writeRequestsCount.increment();
     try {
       delete.getRow();
       // All edits for the given row (across all column families) must happen atomically.
       doBatchMutate(delete, null);
     } finally {
       closeRegionOperation();
     }
   }

   /**
    * Row needed by below method.
    */
   private static final byte [] FOR_UNIT_TESTS_ONLY = Bytes.toBytes("ForUnitTestsOnly");
   /**
    * This is used only by unit tests. Not required to be a public API.
    * @param familyMap map of family to edits for the given family.
    * @param clusterId
    * @param durability
    * @throws IOException
    */
   void delete(NavigableMap<byte[], List<? extends Cell>> familyMap, UUID clusterId,
       Durability durability) throws IOException {
     Delete delete = new Delete(FOR_UNIT_TESTS_ONLY);
     delete.setFamilyMap(familyMap);
     delete.setClusterId(clusterId);
     delete.setDurability(durability);
     doBatchMutate(delete, null);
   }

   /**
    * Setup correct timestamps in the KVs in Delete object.
    * Caller should have the row and region locks.
    * @param familyMap
    * @param byteNow
    * @throws IOException
    */
   void prepareDeleteTimestamps(Map<byte[], List<? extends Cell>> familyMap, byte[] byteNow)
       throws IOException {
     for (Map.Entry<byte[], List<? extends Cell>> e : familyMap.entrySet()) {

       byte[] family = e.getKey();
       List<? extends Cell> cells = e.getValue();
       Map<byte[], Integer> kvCount = new TreeMap<byte[], Integer>(Bytes.BYTES_COMPARATOR);

       for (Cell cell: cells) {
         KeyValue kv = KeyValueUtil.ensureKeyValue(cell);
         //  Check if time is LATEST, change to time of most recent addition if so
         //  This is expensive.
         if (kv.isLatestTimestamp() && kv.isDeleteType()) {
           byte[] qual = kv.getQualifier();
           if (qual == null) qual = HConstants.EMPTY_BYTE_ARRAY;

           Integer count = kvCount.get(qual);
           if (count == null) {
             kvCount.put(qual, 1);
           } else {
             kvCount.put(qual, count + 1);
           }
           count = kvCount.get(qual);

           Get get = new Get(kv.getRow());
           get.setMaxVersions(count);
           get.addColumn(family, qual);

           List<KeyValue> result = get(get, false);

           if (result.size() < count) {
             // Nothing to delete
             kv.updateLatestStamp(byteNow);
             continue;
           }
           if (result.size() > count) {
             throw new RuntimeException("Unexpected size: " + result.size());
           }
           KeyValue getkv = result.get(count - 1);
           Bytes.putBytes(kv.getBuffer(), kv.getTimestampOffset(),
               getkv.getBuffer(), getkv.getTimestampOffset(), Bytes.SIZEOF_LONG);
         } else {
           kv.updateLatestStamp(byteNow);
         }
       }
     }
   }

   /**
    * @param put
    * @throws IOException
    */
   public void put(Put put)
   throws IOException {
     checkReadOnly();

     // Do a rough check that we have resources to accept a write.  The check is
     // 'rough' in that between the resource check and the call to obtain a
     // read lock, resources may run out.  For now, the thought is that this
     // will be extremely rare; we'll deal with it when it happens.
     checkResources();
     startRegionOperation(Operation.PUT);
     this.writeRequestsCount.increment();
     try {
       // All edits for the given row (across all column families) must happen atomically.
       doBatchMutate(put, null);
     } finally {
       closeRegionOperation();
     }
   }

   /**
    * Struct-like class that tracks the progress of a batch operation,
    * accumulating status codes and tracking the index at which processing
    * is proceeding.
    */
   private static class BatchOperationInProgress<T> {
     T[] operations;
     int nextIndexToProcess = 0;
     OperationStatus[] retCodeDetails;
     WALEdit[] walEditsFromCoprocessors;

     public BatchOperationInProgress(T[] operations) {
       this.operations = operations;
       this.retCodeDetails = new OperationStatus[operations.length];
       this.walEditsFromCoprocessors = new WALEdit[operations.length];
       Arrays.fill(this.retCodeDetails, OperationStatus.NOT_RUN);
     }

     public boolean isDone() {
       return nextIndexToProcess == operations.length;
     }
   }

   /**
    * Perform a batch put with no pre-specified locks
    * @see HRegion#batchMutate(Pair[])
    */
   public OperationStatus[] put(Put[] puts) throws IOException {
     @SuppressWarnings("unchecked")
     Pair<Mutation, Integer> putsAndLocks[] = new Pair[puts.length];

     for (int i = 0; i < puts.length; i++) {
       putsAndLocks[i] = new Pair<Mutation, Integer>(puts[i], null);
     }
     return batchMutate(putsAndLocks);
   }

   /**
    * Perform a batch of mutations.
    * It supports only Put and Delete mutations and will ignore other types passed.
    * @param mutationsAndLocks
    *          the list of mutations paired with their requested lock IDs.
    * @return an array of OperationStatus which internally contains the
    *         OperationStatusCode and the exceptionMessage if any.
    * @throws IOException
    */
   public OperationStatus[] batchMutate(
       Pair<Mutation, Integer>[] mutationsAndLocks) throws IOException {
     return batchMutate(mutationsAndLocks, false);
   }

   /**
    * Perform a batch of mutations.
    * It supports only Put and Delete mutations and will ignore other types passed.
    * @param mutationsAndLocks
    *          the list of mutations paired with their requested lock IDs.
    * @return an array of OperationStatus which internally contains the
    *         OperationStatusCode and the exceptionMessage if any.
    * @throws IOException
    */
   OperationStatus[] batchMutate(Pair<Mutation, Integer>[] mutationsAndLocks, boolean isReplay)
       throws IOException {
     BatchOperationInProgress<Pair<Mutation, Integer>> batchOp =
       new BatchOperationInProgress<Pair<Mutation,Integer>>(mutationsAndLocks);

     boolean initialized = false;

     while (!batchOp.isDone()) {
       if (!isReplay) {
         checkReadOnly();
       }
       checkResources();

       long newSize;
       startRegionOperation();

       try {
         if (!initialized) {
           if (!isReplay) {
             this.writeRequestsCount.increment();
             doPreMutationHook(batchOp);
           }
           initialized = true;
         }
         long addedSize = doMiniBatchMutation(batchOp, isReplay);
         newSize = this.addAndGetGlobalMemstoreSize(addedSize);
       } finally {
         closeRegionOperation();
       }
       if (isFlushSize(newSize)) {
         requestFlush();
       }
     }
     return batchOp.retCodeDetails;
   }


   private void doPreMutationHook(BatchOperationInProgress<Pair<Mutation, Integer>> batchOp)
       throws IOException {
     /* Run coprocessor pre hook outside of locks to avoid deadlock */
     WALEdit walEdit = new WALEdit();
     if (coprocessorHost != null) {
       for (int i = 0 ; i < batchOp.operations.length; i++) {
         Pair<Mutation, Integer> nextPair = batchOp.operations[i];
         Mutation m = nextPair.getFirst();
         if (m instanceof Put) {
           if (coprocessorHost.prePut((Put) m, walEdit, m.getDurability())) {
             // pre hook says skip this Put
             // mark as success and skip in doMiniBatchMutation
             batchOp.retCodeDetails[i] = OperationStatus.SUCCESS;
           }
         } else if (m instanceof Delete) {
           if (coprocessorHost.preDelete((Delete) m, walEdit, m.getDurability())) {
             // pre hook says skip this Delete
             // mark as success and skip in doMiniBatchMutation
             batchOp.retCodeDetails[i] = OperationStatus.SUCCESS;
           }
         } else {
           // In case of passing Append mutations along with the Puts and Deletes in batchMutate
           // mark the operation return code as failure so that it will not be considered in
           // the doMiniBatchMutation
           batchOp.retCodeDetails[i] = new OperationStatus(OperationStatusCode.FAILURE,
               "Put/Delete mutations only supported in batchMutate() now");
         }
         if (!walEdit.isEmpty()) {
           batchOp.walEditsFromCoprocessors[i] = walEdit;
           walEdit = new WALEdit();
         }
       }
     }
   }

   @SuppressWarnings("unchecked")
   private long doMiniBatchMutation(BatchOperationInProgress<Pair<Mutation, Integer>> batchOp,
       boolean isInReplay) throws IOException {

     // variable to note if all Put items are for the same CF -- metrics related
     boolean putsCfSetConsistent = true;
     //The set of columnFamilies first seen for Put.
     Set<byte[]> putsCfSet = null;
     // variable to note if all Delete items are for the same CF -- metrics related
     boolean deletesCfSetConsistent = true;
     //The set of columnFamilies first seen for Delete.
     Set<byte[]> deletesCfSet = null;

     WALEdit walEdit = new WALEdit(isInReplay);
     MultiVersionConsistencyControl.WriteEntry w = null;
     long txid = 0;
     boolean walSyncSuccessful = false;
     boolean locked = false;

     /** Keep track of the locks we hold so we can release them in finally clause */
     List<Integer> acquiredLocks = Lists.newArrayListWithCapacity(batchOp.operations.length);
     // reference family maps directly so coprocessors can mutate them if desired
     Map<byte[], List<? extends Cell>>[] familyMaps = new Map[batchOp.operations.length];
     // We try to set up a batch in the range [firstIndex,lastIndexExclusive)
     int firstIndex = batchOp.nextIndexToProcess;
     int lastIndexExclusive = firstIndex;
     boolean success = false;
     int noOfPuts = 0, noOfDeletes = 0;
     try {
       // ------------------------------------
       // STEP 1. Try to acquire as many locks as we can, and ensure
       // we acquire at least one.
       // ----------------------------------
       int numReadyToWrite = 0;
       long now = EnvironmentEdgeManager.currentTimeMillis();
       while (lastIndexExclusive < batchOp.operations.length) {
         Pair<Mutation, Integer> nextPair = batchOp.operations[lastIndexExclusive];
         Mutation mutation = nextPair.getFirst();
         boolean isPutMutation = mutation instanceof Put;
         Integer providedLockId = nextPair.getSecond();

         Map<byte[], List<? extends Cell>> familyMap = mutation.getFamilyMap();
         // store the family map reference to allow for mutations
         familyMaps[lastIndexExclusive] = familyMap;

         // skip anything that "ran" already
         if (batchOp.retCodeDetails[lastIndexExclusive].getOperationStatusCode()
             != OperationStatusCode.NOT_RUN) {
           lastIndexExclusive++;
           continue;
         }

         try {
           if (isPutMutation) {
             // Check the families in the put. If bad, skip this one.
             if (isInReplay) {
               removeNonExistentColumnFamilyForReplay(familyMap);
             } else {
               checkFamilies(familyMap.keySet());
             }
             checkTimestamps(mutation.getFamilyMap(), now);
           } else {
             prepareDelete((Delete) mutation);
           }
         } catch (NoSuchColumnFamilyException nscf) {
           LOG.warn("No such column family in batch mutation", nscf);
           batchOp.retCodeDetails[lastIndexExclusive] = new OperationStatus(
               OperationStatusCode.BAD_FAMILY, nscf.getMessage());
           lastIndexExclusive++;
           continue;
         } catch (FailedSanityCheckException fsce) {
           LOG.warn("Batch Mutation did not pass sanity check", fsce);
           batchOp.retCodeDetails[lastIndexExclusive] = new OperationStatus(
               OperationStatusCode.SANITY_CHECK_FAILURE, fsce.getMessage());
           lastIndexExclusive++;
           continue;
         }
         // If we haven't got any rows in our batch, we should block to
         // get the next one.
         boolean shouldBlock = numReadyToWrite == 0;
         Integer acquiredLockId = null;
         try {
           acquiredLockId = getLock(providedLockId, mutation.getRow(),
               shouldBlock);
         } catch (IOException ioe) {
           LOG.warn("Failed getting lock in batch put, row="
                   + Bytes.toStringBinary(mutation.getRow()), ioe);
         }
         if (acquiredLockId == null) {
           // We failed to grab another lock
           assert !shouldBlock : "Should never fail to get lock when blocking";
           break; // stop acquiring more rows for this batch
         }
         if (providedLockId == null) {
           acquiredLocks.add(acquiredLockId);
         }
         lastIndexExclusive++;
         numReadyToWrite++;

         if (isPutMutation) {
           // If Column Families stay consistent through out all of the
           // individual puts then metrics can be reported as a mutliput across
           // column families in the first put.
           if (putsCfSet == null) {
             putsCfSet = mutation.getFamilyMap().keySet();
           } else {
             putsCfSetConsistent = putsCfSetConsistent
                 && mutation.getFamilyMap().keySet().equals(putsCfSet);
           }
         } else {
           if (deletesCfSet == null) {
             deletesCfSet = mutation.getFamilyMap().keySet();
           } else {
             deletesCfSetConsistent = deletesCfSetConsistent
                 && mutation.getFamilyMap().keySet().equals(deletesCfSet);
           }
         }
       }

       // we should record the timestamp only after we have acquired the rowLock,
       // otherwise, newer puts/deletes are not guaranteed to have a newer timestamp
       now = EnvironmentEdgeManager.currentTimeMillis();
       byte[] byteNow = Bytes.toBytes(now);

       // Nothing to put/delete -- an exception in the above such as NoSuchColumnFamily?
       if (numReadyToWrite <= 0) return 0L;

       // We've now grabbed as many mutations off the list as we can

       // ------------------------------------
       // STEP 2. Update any LATEST_TIMESTAMP timestamps
       // ----------------------------------
       for (int i = firstIndex; i < lastIndexExclusive; i++) {
         // skip invalid
         if (batchOp.retCodeDetails[i].getOperationStatusCode()
             != OperationStatusCode.NOT_RUN) continue;

         Mutation mutation = batchOp.operations[i].getFirst();
         if (mutation instanceof Put) {
           updateKVTimestamps(familyMaps[i].values(), byteNow);
           noOfPuts++;
         } else {
           prepareDeleteTimestamps(familyMaps[i], byteNow);
           noOfDeletes++;
         }
       }

       lock(this.updatesLock.readLock(), numReadyToWrite);
       locked = true;

       //
       // ------------------------------------
       // Acquire the latest mvcc number
       // ----------------------------------
       w = mvcc.beginMemstoreInsert();

       // calling the pre CP hook for batch mutation
       if (!isInReplay && coprocessorHost != null) {
         MiniBatchOperationInProgress<Pair<Mutation, Integer>> miniBatchOp =
           new MiniBatchOperationInProgress<Pair<Mutation, Integer>>(batchOp.operations,
           batchOp.retCodeDetails, batchOp.walEditsFromCoprocessors, firstIndex, lastIndexExclusive);
         if (coprocessorHost.preBatchMutate(miniBatchOp)) return 0L;
       }

       // ------------------------------------
       // STEP 3. Write back to memstore
       // Write to memstore. It is ok to write to memstore
       // first without updating the HLog because we do not roll
       // forward the memstore MVCC. The MVCC will be moved up when
       // the complete operation is done. These changes are not yet
       // visible to scanners till we update the MVCC. The MVCC is
       // moved only when the sync is complete.
       // ----------------------------------
       long addedSize = 0;
       for (int i = firstIndex; i < lastIndexExclusive; i++) {
         if (batchOp.retCodeDetails[i].getOperationStatusCode()
             != OperationStatusCode.NOT_RUN) {
           continue;
         }
         addedSize += applyFamilyMapToMemstore(familyMaps[i], w);
       }

       // ------------------------------------
       // STEP 4. Build WAL edit
       // ----------------------------------
       Durability durability = Durability.USE_DEFAULT;
       for (int i = firstIndex; i < lastIndexExclusive; i++) {
         // Skip puts that were determined to be invalid during preprocessing
         if (batchOp.retCodeDetails[i].getOperationStatusCode()
             != OperationStatusCode.NOT_RUN) {
           continue;
         }
         batchOp.retCodeDetails[i] = OperationStatus.SUCCESS;

         Mutation m = batchOp.operations[i].getFirst();
         Durability tmpDur = m.getDurability();
         if (tmpDur.ordinal() > durability.ordinal()) {
           durability = tmpDur;
         }
         if (tmpDur == Durability.SKIP_WAL) {
           if (m instanceof Put) {
             recordPutWithoutWal(m.getFamilyMap());
           }
           continue;
         }

         // Add WAL edits by CP
         WALEdit fromCP = batchOp.walEditsFromCoprocessors[i];
         if (fromCP != null) {
           for (KeyValue kv : fromCP.getKeyValues()) {
             walEdit.add(kv);
           }
         }
         addFamilyMapToWALEdit(familyMaps[i], walEdit);
       }

       // -------------------------
       // STEP 5. Append the edit to WAL. Do not sync wal.
       // -------------------------
       Mutation first = batchOp.operations[firstIndex].getFirst();
       txid = this.log.appendNoSync(this.getRegionInfo(), this.htableDescriptor.getName(),
                walEdit, first.getClusterId(), now, this.htableDescriptor);

       // -------------------------------
       // STEP 6. Release row locks, etc.
       // -------------------------------
       if (locked) {
         this.updatesLock.readLock().unlock();
         locked = false;
       }
       if (acquiredLocks != null) {
         for (Integer toRelease : acquiredLocks) {
           releaseRowLock(toRelease);
         }
         acquiredLocks = null;
       }
       // -------------------------
       // STEP 7. Sync wal.
       // -------------------------
       if (walEdit.size() > 0) {
         syncOrDefer(txid, durability);
       }
       walSyncSuccessful = true;
       // calling the post CP hook for batch mutation
       if (!isInReplay && coprocessorHost != null) {
         MiniBatchOperationInProgress<Pair<Mutation, Integer>> miniBatchOp =
           new MiniBatchOperationInProgress<Pair<Mutation, Integer>>(batchOp.operations,
           batchOp.retCodeDetails, batchOp.walEditsFromCoprocessors, firstIndex, lastIndexExclusive);
         coprocessorHost.postBatchMutate(miniBatchOp);
       }

       // ------------------------------------------------------------------
       // STEP 8. Advance mvcc. This will make this put visible to scanners and getters.
       // ------------------------------------------------------------------
       if (w != null) {
         mvcc.completeMemstoreInsert(w);
         w = null;
       }

       // ------------------------------------
       // STEP 9. Run coprocessor post hooks. This should be done after the wal is
       // synced so that the coprocessor contract is adhered to.
       // ------------------------------------
       if (!isInReplay && coprocessorHost != null) {
         for (int i = firstIndex; i < lastIndexExclusive; i++) {
           // only for successful puts
           if (batchOp.retCodeDetails[i].getOperationStatusCode()
               != OperationStatusCode.SUCCESS) {
             continue;
           }
           Mutation m = batchOp.operations[i].getFirst();
           if (m instanceof Put) {
             coprocessorHost.postPut((Put) m, walEdit, m.getDurability());
           } else {
             coprocessorHost.postDelete((Delete) m, walEdit, m.getDurability());
           }
         }
       }

       success = true;
       return addedSize;
     } finally {

       // if the wal sync was unsuccessful, remove keys from memstore
       if (!walSyncSuccessful) {
         rollbackMemstore(batchOp, familyMaps, firstIndex, lastIndexExclusive);
       }
       if (w != null) mvcc.completeMemstoreInsert(w);

       if (locked) {
         this.updatesLock.readLock().unlock();
       }

       if (acquiredLocks != null) {
         for (Integer toRelease : acquiredLocks) {
           releaseRowLock(toRelease);
         }
       }

       // See if the column families were consistent through the whole thing.
       // if they were then keep them. If they were not then pass a null.
       // null will be treated as unknown.
       // Total time taken might be involving Puts and Deletes.
       // Split the time for puts and deletes based on the total number of Puts and Deletes.

       if (noOfPuts > 0) {
         // There were some Puts in the batch.
         if (this.metricsRegion != null) {
           this.metricsRegion.updatePut();
         }
       }
       if (noOfDeletes > 0) {
         // There were some Deletes in the batch.
         if (this.metricsRegion != null) {
           this.metricsRegion.updateDelete();
         }
       }
       if (!success) {
         for (int i = firstIndex; i < lastIndexExclusive; i++) {
           if (batchOp.retCodeDetails[i].getOperationStatusCode() == OperationStatusCode.NOT_RUN) {
             batchOp.retCodeDetails[i] = OperationStatus.FAILURE;
           }
         }
       }
       batchOp.nextIndexToProcess = lastIndexExclusive;
     }
   }

   //TODO, Think that gets/puts and deletes should be refactored a bit so that
   //the getting of the lock happens before, so that you would just pass it into
   //the methods. So in the case of checkAndMutate you could just do lockRow,
   //get, put, unlockRow or something
   /**
    *
    * @param row
    * @param family
    * @param qualifier
    * @param compareOp
    * @param comparator
    * @param w
    * @param writeToWAL
    * @throws IOException
    * @return true if the new put was executed, false otherwise
    */
   public boolean checkAndMutate(byte [] row, byte [] family, byte [] qualifier,
       CompareOp compareOp, ByteArrayComparable comparator, Mutation w,
       boolean writeToWAL)
   throws IOException{
     checkReadOnly();
     //TODO, add check for value length or maybe even better move this to the
     //client if this becomes a global setting
     checkResources();
     boolean isPut = w instanceof Put;
     if (!isPut && !(w instanceof Delete))
       throw new org.apache.hadoop.hbase.exceptions.DoNotRetryIOException("Action must be Put or Delete");
     Row r = (Row)w;
     if (!Bytes.equals(row, r.getRow())) {
       throw new org.apache.hadoop.hbase.exceptions.DoNotRetryIOException("Action's getRow must match the passed row");
     }

     startRegionOperation();
     try {
       Get get = new Get(row);
       checkFamily(family);
       get.addColumn(family, qualifier);

       // Lock row
       Integer lid = getLock(null, get.getRow(), true);
       // wait for all previous transactions to complete (with lock held)
       mvcc.completeMemstoreInsert(mvcc.beginMemstoreInsert());
       List<KeyValue> result = null;
       try {
         result = get(get, false);

         boolean valueIsNull = comparator.getValue() == null ||
           comparator.getValue().length == 0;
         boolean matches = false;
         if (result.size() == 0 && valueIsNull) {
           matches = true;
         } else if (result.size() > 0 && result.get(0).getValue().length == 0 &&
             valueIsNull) {
           matches = true;
         } else if (result.size() == 1 && !valueIsNull) {
           KeyValue kv = result.get(0);
           int compareResult = comparator.compareTo(kv.getBuffer(),
               kv.getValueOffset(), kv.getValueLength());
           switch (compareOp) {
           case LESS:
             matches = compareResult <= 0;
             break;
           case LESS_OR_EQUAL:
             matches = compareResult < 0;
             break;
           case EQUAL:
             matches = compareResult == 0;
             break;
           case NOT_EQUAL:
             matches = compareResult != 0;
             break;
           case GREATER_OR_EQUAL:
             matches = compareResult > 0;
             break;
           case GREATER:
             matches = compareResult >= 0;
             break;
           default:
             throw new RuntimeException("Unknown Compare op " + compareOp.name());
           }
         }
         //If matches put the new put or delete the new delete
         if (matches) {
           // All edits for the given row (across all column families) must
           // happen atomically.
           doBatchMutate((Mutation)w, lid);
           this.checkAndMutateChecksPassed.increment();
           return true;
         }
         this.checkAndMutateChecksFailed.increment();
         return false;
       } finally {
         releaseRowLock(lid);
       }
     } finally {
       closeRegionOperation();
     }
   }

   @SuppressWarnings("unchecked")
   private void doBatchMutate(Mutation mutation, Integer lid) throws IOException,
       org.apache.hadoop.hbase.exceptions.DoNotRetryIOException {
     Pair<Mutation, Integer>[] mutateWithLocks = new Pair[] {
       new Pair<Mutation, Integer>(mutation, lid)
     };
     OperationStatus[] batchMutate = this.batchMutate(mutateWithLocks);
     if (batchMutate[0].getOperationStatusCode().equals(OperationStatusCode.SANITY_CHECK_FAILURE)) {
       throw new FailedSanityCheckException(batchMutate[0].getExceptionMsg());
     } else if (batchMutate[0].getOperationStatusCode().equals(OperationStatusCode.BAD_FAMILY)) {
       throw new NoSuchColumnFamilyException(batchMutate[0].getExceptionMsg());
     }
   }

   /**
    * Complete taking the snapshot on the region. Writes the region info and adds references to the
    * working snapshot directory.
    *
    * TODO for api consistency, consider adding another version with no {@link ForeignExceptionSnare}
    * arg.  (In the future other cancellable HRegion methods could eventually add a
    * {@link ForeignExceptionSnare}, or we could do something fancier).
    *
    * @param desc snasphot description object
    * @param exnSnare ForeignExceptionSnare that captures external exeptions in case we need to
    *   bail out.  This is allowed to be null and will just be ignored in that case.
    * @throws IOException if there is an external or internal error causing the snapshot to fail
    */
   public void addRegionToSnapshot(SnapshotDescription desc,
       ForeignExceptionSnare exnSnare) throws IOException {
     // This should be "fast" since we don't rewrite store files but instead
     // back up the store files by creating a reference
     Path rootDir = FSUtils.getRootDir(this.rsServices.getConfiguration());
     Path snapshotDir = SnapshotDescriptionUtils.getWorkingSnapshotDir(desc, rootDir);

     // 1. dump region meta info into the snapshot directory
     LOG.debug("Storing region-info for snapshot.");
     HRegionFileSystem snapshotRegionFs = HRegionFileSystem.createRegionOnFileSystem(conf,
         this.fs.getFileSystem(), snapshotDir, getRegionInfo());

     // 2. iterate through all the stores in the region
     LOG.debug("Creating references for hfiles");

     // This ensures that we have an atomic view of the directory as long as we have < ls limit
     // (batch size of the files in a directory) on the namenode. Otherwise, we get back the files in
     // batches and may miss files being added/deleted. This could be more robust (iteratively
     // checking to see if we have all the files until we are sure), but the limit is currently 1000
     // files/batch, far more than the number of store files under a single column family.
     for (Store store : stores.values()) {
       // 2.1. build the snapshot reference directory for the store
       Path dstStoreDir = snapshotRegionFs.getStoreDir(store.getFamily().getNameAsString());
       List<StoreFile> storeFiles = new ArrayList<StoreFile>(store.getStorefiles());
       if (LOG.isDebugEnabled()) {
         LOG.debug("Adding snapshot references for " + storeFiles  + " hfiles");
       }

       // 2.2. iterate through all the store's files and create "references".
       int sz = storeFiles.size();
       for (int i = 0; i < sz; i++) {
         if (exnSnare != null) {
           exnSnare.rethrowException();
         }
         Path file = storeFiles.get(i).getPath();
         // create "reference" to this store file.  It is intentionally an empty file -- all
         // necessary infomration is captured by its fs location and filename.  This allows us to
         // only figure out what needs to be done via a single nn operation (instead of having to
         // open and read the files as well).
         LOG.debug("Creating reference for file (" + (i+1) + "/" + sz + ") : " + file);
         Path referenceFile = new Path(dstStoreDir, file.getName());
         boolean success = fs.getFileSystem().createNewFile(referenceFile);
         if (!success) {
           throw new IOException("Failed to create reference file:" + referenceFile);
         }
       }
     }
   }

   /**
    * Replaces any KV timestamps set to {@link HConstants#LATEST_TIMESTAMP} with the
    * provided current timestamp.
    */
   void updateKVTimestamps(final Iterable<List<? extends Cell>> keyLists, final byte[] now) {
     for (List<? extends Cell> cells: keyLists) {
       if (cells == null) continue;
       for (Cell cell : cells) {
         KeyValue kv = KeyValueUtil.ensureKeyValue(cell);
         kv.updateLatestStamp(now);
       }
     }
   }

   /*
    * Check if resources to support an update.
    *
    * Here we synchronize on HRegion, a broad scoped lock.  Its appropriate
    * given we're figuring in here whether this region is able to take on
    * writes.  This is only method with a synchronize (at time of writing),
    * this and the synchronize on 'this' inside in internalFlushCache to send
    * the notify.
    */
   private void checkResources()
       throws RegionTooBusyException, InterruptedIOException {

     // If catalog region, do not impose resource constraints or block updates.
     if (this.getRegionInfo().isMetaRegion()) return;

     boolean blocked = false;
     long startTime = 0;
     while (this.memstoreSize.get() > this.blockingMemStoreSize) {
       requestFlush();
       if (!blocked) {
         startTime = EnvironmentEdgeManager.currentTimeMillis();
         LOG.info("Blocking updates for '" + Thread.currentThread().getName() +
           "' on region " + Bytes.toStringBinary(getRegionName()) +
           ": memstore size " +
           StringUtils.humanReadableInt(this.memstoreSize.get()) +
           " is >= than blocking " +
           StringUtils.humanReadableInt(this.blockingMemStoreSize) + " size");
       }
       long now = EnvironmentEdgeManager.currentTimeMillis();
       long timeToWait = startTime + busyWaitDuration - now;
       if (timeToWait <= 0L) {
         final long totalTime = now - startTime;
         this.updatesBlockedMs.add(totalTime);
         LOG.info("Failed to unblock updates for region " + this + " '"
           + Thread.currentThread().getName() + "' in " + totalTime
           + "ms. The region is still busy.");
         throw new RegionTooBusyException("region is flushing");
       }
       blocked = true;
       synchronized(this) {
         try {
           wait(Math.min(timeToWait, threadWakeFrequency));
         } catch (InterruptedException ie) {
           final long totalTime = EnvironmentEdgeManager.currentTimeMillis() - startTime;
           if (totalTime > 0) {
             this.updatesBlockedMs.add(totalTime);
           }
           LOG.info("Interrupted while waiting to unblock updates for region "
             + this + " '" + Thread.currentThread().getName() + "'");
           InterruptedIOException iie = new InterruptedIOException();
           iie.initCause(ie);
           throw iie;
         }
       }
     }
     if (blocked) {
       // Add in the blocked time if appropriate
       final long totalTime = EnvironmentEdgeManager.currentTimeMillis() - startTime;
       if(totalTime > 0 ){
         this.updatesBlockedMs.add(totalTime);
       }
       LOG.info("Unblocking updates for region " + this + " '"
           + Thread.currentThread().getName() + "'");
     }
   }

   /**
    * @throws IOException Throws exception if region is in read-only mode.
    */
   protected void checkReadOnly() throws IOException {
     if (this.writestate.isReadOnly()) {
       throw new IOException("region is read only");
     }
   }

   /**
    * Add updates first to the hlog and then add values to memstore.
    * Warning: Assumption is caller has lock on passed in row.
    * @param family
    * @param edits Cell updates by column
    * @praram now
    * @throws IOException
    */
   private void put(final byte [] row, byte [] family, List<? extends Cell> edits)
   throws IOException {
     NavigableMap<byte[], List<? extends Cell>> familyMap;
     familyMap = new TreeMap<byte[], List<? extends Cell>>(Bytes.BYTES_COMPARATOR);

     familyMap.put(family, edits);
     Put p = new Put(row);
     p.setFamilyMap(familyMap);
     p.setClusterId(HConstants.DEFAULT_CLUSTER_ID);
     doBatchMutate(p, null);
   }

   /**
    * Atomically apply the given map of family->edits to the memstore.
    * This handles the consistency control on its own, but the caller
    * should already have locked updatesLock.readLock(). This also does
    * <b>not</b> check the families for validity.
    *
    * @param familyMap Map of kvs per family
    * @param localizedWriteEntry The WriteEntry of the MVCC for this transaction.
    *        If null, then this method internally creates a mvcc transaction.
    * @return the additional memory usage of the memstore caused by the
    * new entries.
    */
   private long applyFamilyMapToMemstore(Map<byte[], List<? extends Cell>> familyMap,
     MultiVersionConsistencyControl.WriteEntry localizedWriteEntry) {
     long size = 0;
     boolean freemvcc = false;

     try {
       if (localizedWriteEntry == null) {
         localizedWriteEntry = mvcc.beginMemstoreInsert();
         freemvcc = true;
       }

       for (Map.Entry<byte[], List<? extends Cell>> e : familyMap.entrySet()) {
         byte[] family = e.getKey();
         List<? extends Cell> cells = e.getValue();

         Store store = getStore(family);
         for (Cell cell: cells) {
           KeyValue kv = KeyValueUtil.ensureKeyValue(cell);
           kv.setMemstoreTS(localizedWriteEntry.getWriteNumber());
           size += store.add(kv);
         }
       }
     } finally {
       if (freemvcc) {
         mvcc.completeMemstoreInsert(localizedWriteEntry);
       }
     }

      return size;
    }

   /**
    * Remove all the keys listed in the map from the memstore. This method is
    * called when a Put/Delete has updated memstore but subequently fails to update
    * the wal. This method is then invoked to rollback the memstore.
    */
   private void rollbackMemstore(BatchOperationInProgress<Pair<Mutation, Integer>> batchOp,
                                 Map<byte[], List<? extends Cell>>[] familyMaps,
                                 int start, int end) {
     int kvsRolledback = 0;
     for (int i = start; i < end; i++) {
       // skip over request that never succeeded in the first place.
       if (batchOp.retCodeDetails[i].getOperationStatusCode()
             != OperationStatusCode.SUCCESS) {
         continue;
       }

       // Rollback all the kvs for this row.
       Map<byte[], List<? extends Cell>> familyMap  = familyMaps[i];
       for (Map.Entry<byte[], List<? extends Cell>> e : familyMap.entrySet()) {
         byte[] family = e.getKey();
         List<? extends Cell> cells = e.getValue();

         // Remove those keys from the memstore that matches our
         // key's (row, cf, cq, timestamp, memstoreTS). The interesting part is
         // that even the memstoreTS has to match for keys that will be rolleded-back.
         Store store = getStore(family);
         for (Cell cell: cells) {
           store.rollback(KeyValueUtil.ensureKeyValue(cell));
           kvsRolledback++;
         }
       }
     }
     LOG.debug("rollbackMemstore rolled back " + kvsRolledback +
         " keyvalues from start:" + start + " to end:" + end);
   }

   /**
    * Check the collection of families for validity.
    * @throws NoSuchColumnFamilyException if a family does not exist.
    */
   void checkFamilies(Collection<byte[]> families)
   throws NoSuchColumnFamilyException {
     for (byte[] family : families) {
       checkFamily(family);
     }
   }

   /**
    * During replay, there could exist column families which are removed between region server
    * failure and replay
    */
   private void removeNonExistentColumnFamilyForReplay(
       final Map<byte[], List<? extends Cell>> familyMap) {
     List<byte[]> nonExistentList = null;
     for (byte[] family : familyMap.keySet()) {
       if (!this.htableDescriptor.hasFamily(family)) {
         if (nonExistentList == null) {
           nonExistentList = new ArrayList<byte[]>();
         }
         nonExistentList.add(family);
       }
     }
     if (nonExistentList != null) {
       for (byte[] family : nonExistentList) {
         // Perhaps schema was changed between crash and replay
         LOG.info("No family for " + Bytes.toString(family) + " omit from reply.");
         familyMap.remove(family);
       }
     }
   }

   void checkTimestamps(final Map<byte[], List<? extends Cell>> familyMap,
       long now) throws FailedSanityCheckException {
     if (timestampSlop == HConstants.LATEST_TIMESTAMP) {
       return;
     }
     long maxTs = now + timestampSlop;
     for (List<? extends Cell> kvs : familyMap.values()) {
       for (Cell cell : kvs) {
         // see if the user-side TS is out of range. latest = server-side
         KeyValue kv = KeyValueUtil.ensureKeyValue(cell);
         if (!kv.isLatestTimestamp() && kv.getTimestamp() > maxTs) {
           throw new FailedSanityCheckException("Timestamp for KV out of range "
               + cell + " (too.new=" + timestampSlop + ")");
         }
       }
     }
   }

   /**
    * Append the given map of family->edits to a WALEdit data structure.
    * This does not write to the HLog itself.
    * @param familyMap map of family->edits
    * @param walEdit the destination entry to append into
    */
   private void addFamilyMapToWALEdit(Map<byte[], List<? extends Cell>> familyMap,
       WALEdit walEdit) {
     for (List<? extends Cell> edits : familyMap.values()) {
       for (Cell cell : edits) {
         walEdit.add(KeyValueUtil.ensureKeyValue(cell));
       }
     }
   }

   private void requestFlush() {
     if (this.rsServices == null) {
       return;
     }
     synchronized (writestate) {
       if (this.writestate.isFlushRequested()) {
         return;
       }
       writestate.flushRequested = true;
     }
     // Make request outside of synchronize block; HBASE-818.
     this.rsServices.getFlushRequester().requestFlush(this);
     if (LOG.isDebugEnabled()) {
       LOG.debug("Flush requested on " + this);
     }
   }

   /*
    * @param size
    * @return True if size is over the flush threshold
    */
   private boolean isFlushSize(final long size) {
     return size > this.memstoreFlushSize;
   }

   /**
    * Read the edits log put under this region by wal log splitting process.  Put
    * the recovered edits back up into this region.
    *
    * <p>We can ignore any log message that has a sequence ID that's equal to or
    * lower than minSeqId.  (Because we know such log messages are already
    * reflected in the HFiles.)
    *
    * <p>While this is running we are putting pressure on memory yet we are
    * outside of our usual accounting because we are not yet an onlined region
    * (this stuff is being run as part of Region initialization).  This means
    * that if we're up against global memory limits, we'll not be flagged to flush
    * because we are not online. We can't be flushed by usual mechanisms anyways;
    * we're not yet online so our relative sequenceids are not yet aligned with
    * HLog sequenceids -- not till we come up online, post processing of split
    * edits.
    *
    * <p>But to help relieve memory pressure, at least manage our own heap size
    * flushing if are in excess of per-region limits.  Flushing, though, we have
    * to be careful and avoid using the regionserver/hlog sequenceid.  Its running
    * on a different line to whats going on in here in this region context so if we
    * crashed replaying these edits, but in the midst had a flush that used the
    * regionserver log with a sequenceid in excess of whats going on in here
    * in this region and with its split editlogs, then we could miss edits the
    * next time we go to recover. So, we have to flush inline, using seqids that
    * make sense in a this single region context only -- until we online.
    *
    * @param regiondir
    * @param maxSeqIdInStores Any edit found in split editlogs needs to be in excess of
    * the maxSeqId for the store to be applied, else its skipped.
    * @param reporter
    * @return the sequence id of the last edit added to this region out of the
    * recovered edits log or <code>minSeqId</code> if nothing added from editlogs.
    * @throws UnsupportedEncodingException
    * @throws IOException
    */
   protected long replayRecoveredEditsIfAny(final Path regiondir,
       Map<byte[], Long> maxSeqIdInStores,
       final CancelableProgressable reporter, final MonitoredTask status)
       throws UnsupportedEncodingException, IOException {
     long minSeqIdForTheRegion = -1;
     for (Long maxSeqIdInStore : maxSeqIdInStores.values()) {
       if (maxSeqIdInStore < minSeqIdForTheRegion || minSeqIdForTheRegion == -1) {
         minSeqIdForTheRegion = maxSeqIdInStore;
       }
     }
     long seqid = minSeqIdForTheRegion;

     FileSystem fs = this.fs.getFileSystem();
     NavigableSet<Path> files = HLogUtil.getSplitEditFilesSorted(fs, regiondir);
     if (files == null || files.isEmpty()) return seqid;

     for (Path edits: files) {
       if (edits == null || !fs.exists(edits)) {
         LOG.warn("Null or non-existent edits file: " + edits);
         continue;
       }
       if (isZeroLengthThenDelete(fs, edits)) continue;

       long maxSeqId = Long.MAX_VALUE;
       String fileName = edits.getName();
       maxSeqId = Math.abs(Long.parseLong(fileName));
       if (maxSeqId <= minSeqIdForTheRegion) {
         String msg = "Maximum sequenceid for this log is " + maxSeqId
             + " and minimum sequenceid for the region is " + minSeqIdForTheRegion
             + ", skipped the whole file, path=" + edits;
         LOG.debug(msg);
         continue;
       }

       try {
         seqid = replayRecoveredEdits(edits, maxSeqIdInStores, reporter);
       } catch (IOException e) {
         boolean skipErrors = conf.getBoolean(
             HConstants.HREGION_EDITS_REPLAY_SKIP_ERRORS,
             conf.getBoolean(
                 "hbase.skip.errors",
                 HConstants.DEFAULT_HREGION_EDITS_REPLAY_SKIP_ERRORS));
         if (conf.get("hbase.skip.errors") != null) {
           LOG.warn(
               "The property 'hbase.skip.errors' has been deprecated. Please use " +
               HConstants.HREGION_EDITS_REPLAY_SKIP_ERRORS + " instead.");
         }
         if (skipErrors) {
           Path p = HLogUtil.moveAsideBadEditsFile(fs, edits);
           LOG.error(HConstants.HREGION_EDITS_REPLAY_SKIP_ERRORS
               + "=true so continuing. Renamed " + edits +
               " as " + p, e);
         } else {
           throw e;
         }
       }
       // The edits size added into rsAccounting during this replaying will not
       // be required any more. So just clear it.
       if (this.rsAccounting != null) {
         this.rsAccounting.clearRegionReplayEditsSize(this.getRegionName());
       }
     }
     if (seqid > minSeqIdForTheRegion) {
       // Then we added some edits to memory. Flush and cleanup split edit files.
       internalFlushcache(null, seqid, status);
     }
     // Now delete the content of recovered edits.  We're done w/ them.
     for (Path file: files) {
       if (!fs.delete(file, false)) {
         LOG.error("Failed delete of " + file);
       } else {
         LOG.debug("Deleted recovered.edits file=" + file);
       }
     }
     return seqid;
   }

   /*
    * @param edits File of recovered edits.
    * @param maxSeqIdInStores Maximum sequenceid found in each store.  Edits in log
    * must be larger than this to be replayed for each store.
    * @param reporter
    * @return the sequence id of the last edit added to this region out of the
    * recovered edits log or <code>minSeqId</code> if nothing added from editlogs.
    * @throws IOException
    */
   private long replayRecoveredEdits(final Path edits,
       Map<byte[], Long> maxSeqIdInStores, final CancelableProgressable reporter)
     throws IOException {
     String msg = "Replaying edits from " + edits;
     LOG.info(msg);
     MonitoredTask status = TaskMonitor.get().createStatus(msg);
     FileSystem fs = this.fs.getFileSystem();

     status.setStatus("Opening logs");
     HLog.Reader reader = null;
     try {
       reader = HLogFactory.createReader(fs, edits, conf);
       long currentEditSeqId = -1;
       long firstSeqIdInLog = -1;
       long skippedEdits = 0;
       long editsCount = 0;
       long intervalEdits = 0;
       HLog.Entry entry;
       Store store = null;
       boolean reported_once = false;

       try {
         // How many edits seen before we check elapsed time
         int interval = this.conf.getInt("hbase.hstore.report.interval.edits",
             2000);
         // How often to send a progress report (default 1/2 master timeout)
         int period = this.conf.getInt("hbase.hstore.report.period",
             this.conf.getInt("hbase.master.assignment.timeoutmonitor.timeout",
                 180000) / 2);
         long lastReport = EnvironmentEdgeManager.currentTimeMillis();

         while ((entry = reader.next()) != null) {
           HLogKey key = entry.getKey();
           WALEdit val = entry.getEdit();

           if (reporter != null) {
             intervalEdits += val.size();
             if (intervalEdits >= interval) {
               // Number of edits interval reached
               intervalEdits = 0;
               long cur = EnvironmentEdgeManager.currentTimeMillis();
               if (lastReport + period <= cur) {
                 status.setStatus("Replaying edits..." +
                     " skipped=" + skippedEdits +
                     " edits=" + editsCount);
                 // Timeout reached
                 if(!reporter.progress()) {
                   msg = "Progressable reporter failed, stopping replay";
                   LOG.warn(msg);
                   status.abort(msg);
                   throw new IOException(msg);
                 }
                 reported_once = true;
                 lastReport = cur;
               }
             }
           }

           // Start coprocessor replay here. The coprocessor is for each WALEdit
           // instead of a KeyValue.
           if (coprocessorHost != null) {
             status.setStatus("Running pre-WAL-restore hook in coprocessors");
             if (coprocessorHost.preWALRestore(this.getRegionInfo(), key, val)) {
               // if bypass this log entry, ignore it ...
               continue;
             }
           }

           if (firstSeqIdInLog == -1) {
             firstSeqIdInLog = key.getLogSeqNum();
           }
           boolean flush = false;
           for (KeyValue kv: val.getKeyValues()) {
             // Check this edit is for me. Also, guard against writing the special
             // METACOLUMN info such as HBASE::CACHEFLUSH entries
             if (kv.matchingFamily(WALEdit.METAFAMILY) ||
                 !Bytes.equals(key.getEncodedRegionName(),
                   this.getRegionInfo().getEncodedNameAsBytes())) {
               //this is a special edit, we should handle it
               CompactionDescriptor compaction = WALEdit.getCompaction(kv);
               if (compaction != null) {
                 //replay the compaction
                 completeCompactionMarker(compaction);
               }

               skippedEdits++;
               continue;
             }
             // Figure which store the edit is meant for.
             if (store == null || !kv.matchingFamily(store.getFamily().getName())) {
               store = this.stores.get(kv.getFamily());
             }
             if (store == null) {
               // This should never happen.  Perhaps schema was changed between
               // crash and redeploy?
               LOG.warn("No family for " + kv);
               skippedEdits++;
               continue;
             }
             // Now, figure if we should skip this edit.
             if (key.getLogSeqNum() <= maxSeqIdInStores.get(store.getFamily()
                 .getName())) {
               skippedEdits++;
               continue;
             }
             currentEditSeqId = key.getLogSeqNum();
             // Once we are over the limit, restoreEdit will keep returning true to
             // flush -- but don't flush until we've played all the kvs that make up
             // the WALEdit.
             flush = restoreEdit(store, kv);
             editsCount++;
           }
           if (flush) internalFlushcache(null, currentEditSeqId, status);

           if (coprocessorHost != null) {
             coprocessorHost.postWALRestore(this.getRegionInfo(), key, val);
           }
         }
       } catch (EOFException eof) {
         Path p = HLogUtil.moveAsideBadEditsFile(fs, edits);
         msg = "Encountered EOF. Most likely due to Master failure during " +
             "log spliting, so we have this data in another edit.  " +
             "Continuing, but renaming " + edits + " as " + p;
         LOG.warn(msg, eof);
         status.abort(msg);
       } catch (IOException ioe) {
         // If the IOE resulted from bad file format,
         // then this problem is idempotent and retrying won't help
         if (ioe.getCause() instanceof ParseException) {
           Path p = HLogUtil.moveAsideBadEditsFile(fs, edits);
           msg = "File corruption encountered!  " +
               "Continuing, but renaming " + edits + " as " + p;
           LOG.warn(msg, ioe);
           status.setStatus(msg);
         } else {
           status.abort(StringUtils.stringifyException(ioe));
           // other IO errors may be transient (bad network connection,
           // checksum exception on one datanode, etc).  throw & retry
           throw ioe;
         }
       }
       if (reporter != null && !reported_once) {
         reporter.progress();
       }
       msg = "Applied " + editsCount + ", skipped " + skippedEdits +
         ", firstSequenceidInLog=" + firstSeqIdInLog +
         ", maxSequenceidInLog=" + currentEditSeqId + ", path=" + edits;
       status.markComplete(msg);
       LOG.debug(msg);
       return currentEditSeqId;
     } finally {
       status.cleanup();
       if (reader != null) {
          reader.close();
       }
     }
   }

   /**
    * 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-2331.
    * @param fs
    * @param compaction
    */
   void completeCompactionMarker(CompactionDescriptor compaction)
       throws IOException {
     Store store = this.getStore(compaction.getFamilyName().toByteArray());
     if (store == null) {
       LOG.warn("Found Compaction WAL edit for deleted family:" +
           Bytes.toString(compaction.getFamilyName().toByteArray()));
       return;
     }
     store.completeCompactionMarker(compaction);
   }

   /**
    * Used by tests
    * @param s Store to add edit too.
    * @param kv KeyValue to add.
    * @return True if we should flush.
    */
   protected boolean restoreEdit(final Store s, final KeyValue kv) {
     long kvSize = s.add(kv);
     if (this.rsAccounting != null) {
       rsAccounting.addAndGetRegionReplayEditsSize(this.getRegionName(), kvSize);
     }
     return isFlushSize(this.addAndGetGlobalMemstoreSize(kvSize));
   }

   /*
    * @param fs
    * @param p File to check.
    * @return True if file was zero-length (and if so, we'll delete it in here).
    * @throws IOException
    */
   private static boolean isZeroLengthThenDelete(final FileSystem fs, final Path p)
       throws IOException {
     FileStatus stat = fs.getFileStatus(p);
     if (stat.getLen() > 0) return false;
     LOG.warn("File " + p + " is zero-length, deleting.");
     fs.delete(p, false);
     return true;
   }

   protected HStore instantiateHStore(final HColumnDescriptor family) throws IOException {
     return new HStore(this, family, this.conf);
   }

   /**
    * Return HStore instance.
    * Use with caution.  Exposed for use of fixup utilities.
    * @param column Name of column family hosted by this region.
    * @return Store that goes with the family on passed <code>column</code>.
    * TODO: Make this lookup faster.
    */
   public Store getStore(final byte[] column) {
     return this.stores.get(column);
   }

   public Map<byte[], Store> getStores() {
     return this.stores;
   }

   /**
    * Return list of storeFiles for the set of CFs.
    * Uses closeLock to prevent the race condition where a region closes
    * in between the for loop - closing the stores one by one, some stores
    * will return 0 files.
    * @return List of storeFiles.
    */
   public List<String> getStoreFileList(final byte [][] columns)
     throws IllegalArgumentException {
     List<String> storeFileNames = new ArrayList<String>();
     synchronized(closeLock) {
       for(byte[] column : columns) {
         Store store = this.stores.get(column);
         if (store == null) {
           throw new IllegalArgumentException("No column family : " +
               new String(column) + " available");
         }
         for (StoreFile storeFile: store.getStorefiles()) {
           storeFileNames.add(storeFile.getPath().toString());
         }
       }
     }
     return storeFileNames;
   }
   //////////////////////////////////////////////////////////////////////////////
   // Support code
   //////////////////////////////////////////////////////////////////////////////

   /** Make sure this is a valid row for the HRegion */
   void checkRow(final byte [] row, String op) throws IOException {
     if (!rowIsInRange(getRegionInfo(), row)) {
       throw new WrongRegionException("Requested row out of range for " +
           op + " on HRegion " + this + ", startKey='" +
           Bytes.toStringBinary(getStartKey()) + "', getEndKey()='" +
           Bytes.toStringBinary(getEndKey()) + "', row='" +
           Bytes.toStringBinary(row) + "'");
     }
   }

   /**
    * Obtain a lock on the given row.  Blocks until success.
    *
    * I know it's strange to have two mappings:
    * <pre>
    *   ROWS  ==> LOCKS
    * </pre>
    * as well as
    * <pre>
    *   LOCKS ==> ROWS
    * </pre>
    * <p>It would be more memory-efficient to just have one mapping;
    * maybe we'll do that in the future.
    *
    * @param row Name of row to lock.
    * @throws IOException
    * @return The id of the held lock.
    */
   public Integer obtainRowLock(final byte [] row) throws IOException {
     startRegionOperation();
     this.writeRequestsCount.increment();
     try {
       return internalObtainRowLock(row, true);
     } finally {
       closeRegionOperation();
     }
   }

   /**
    * Obtains or tries to obtain the given row lock.
    * @param waitForLock if true, will block until the lock is available.
    *        Otherwise, just tries to obtain the lock and returns
    *        null if unavailable.
    */
   private Integer internalObtainRowLock(final byte[] row, boolean waitForLock)
   throws IOException {
     checkRow(row, "row lock");
     startRegionOperation();
     try {
       HashedBytes rowKey = new HashedBytes(row);
       CountDownLatch rowLatch = new CountDownLatch(1);

       // loop until we acquire the row lock (unless !waitForLock)
       while (true) {
         CountDownLatch existingLatch = lockedRows.putIfAbsent(rowKey, rowLatch);
         if (existingLatch == null) {
           break;
         } else {
           // row already locked
           if (!waitForLock) {
             return null;
           }
           try {
             if (!existingLatch.await(this.rowLockWaitDuration,
                             TimeUnit.MILLISECONDS)) {
               throw new IOException("Timed out on getting lock for row="
                   + Bytes.toStringBinary(row));
             }
           } catch (InterruptedException ie) {
             LOG.warn("internalObtainRowLock interrupted for row=" + Bytes.toStringBinary(row));
             InterruptedIOException iie = new InterruptedIOException();
             iie.initCause(ie);
             throw iie;
           }
         }
       }

       // loop until we generate an unused lock id
       while (true) {
         Integer lockId = lockIdGenerator.incrementAndGet();
         HashedBytes existingRowKey = lockIds.putIfAbsent(lockId, rowKey);
         if (existingRowKey == null) {
           return lockId;
         } else {
           // lockId already in use, jump generator to a new spot
           lockIdGenerator.set(rand.nextInt());
         }
       }
     } finally {
       closeRegionOperation();
     }
   }

   /**
    * Release the row lock!
    * @param lockId  The lock ID to release.
    */
   public void releaseRowLock(final Integer lockId) {
     if (lockId == null) return; // null lock id, do nothing
     HashedBytes rowKey = lockIds.remove(lockId);
     if (rowKey == null) {
       LOG.warn("Release unknown lockId: " + lockId);
       return;
     }
     CountDownLatch rowLatch = lockedRows.remove(rowKey);
     if (rowLatch == null) {
       LOG.error("Releases row not locked, lockId: " + lockId + " row: "
           + rowKey);
       return;
     }
     rowLatch.countDown();
   }

   /**
    * See if row is currently locked.
    * @param lockId
    * @return boolean
    */
   boolean isRowLocked(final Integer lockId) {
     return lockIds.containsKey(lockId);
   }

   /**
    * Returns existing row lock if found, otherwise
    * obtains a new row lock and returns it.
    * @param lockid requested by the user, or null if the user didn't already hold lock
    * @param row the row to lock
    * @param waitForLock if true, will block until the lock is available, otherwise will
    * simply return null if it could not acquire the lock.
    * @return lockid or null if waitForLock is false and the lock was unavailable.
    */
   public Integer getLock(Integer lockid, byte [] row, boolean waitForLock)
   throws IOException {
     Integer lid = null;
     if (lockid == null) {
       lid = internalObtainRowLock(row, waitForLock);
     } else {
       if (!isRowLocked(lockid)) {
         throw new IOException("Invalid row lock");
       }
       lid = lockid;
     }
     return lid;
   }

   /**
    * Determines whether multiple column families are present
    * Precondition: familyPaths is not null
    *
    * @param familyPaths List of Pair<byte[] column family, String hfilePath>
    */
   private static boolean hasMultipleColumnFamilies(
       List<Pair<byte[], String>> familyPaths) {
     boolean multipleFamilies = false;
     byte[] family = null;
     for (Pair<byte[], String> pair : familyPaths) {
       byte[] fam = pair.getFirst();
       if (family == null) {
         family = fam;
       } else if (!Bytes.equals(family, fam)) {
         multipleFamilies = true;
         break;
       }
     }
     return multipleFamilies;
   }


   public boolean bulkLoadHFiles(List<Pair<byte[], String>> familyPaths,
                                 boolean assignSeqId) throws IOException {
     return bulkLoadHFiles(familyPaths, assignSeqId, null);
   }

   /**
    * Attempts to atomically load a group of hfiles.  This is critical for loading
    * rows with multiple column families atomically.
    *
    * @param familyPaths List of Pair<byte[] column family, String hfilePath>
    * @param bulkLoadListener Internal hooks enabling massaging/preparation of a
    * file about to be bulk loaded
    * @param assignSeqId
    * @return true if successful, false if failed recoverably
    * @throws IOException if failed unrecoverably.
    */
   public boolean bulkLoadHFiles(List<Pair<byte[], String>> familyPaths, boolean assignSeqId,
       BulkLoadListener bulkLoadListener) throws IOException {
     Preconditions.checkNotNull(familyPaths);
     // we need writeLock for multi-family bulk load
     startBulkRegionOperation(hasMultipleColumnFamilies(familyPaths));
     try {
       this.writeRequestsCount.increment();

       // There possibly was a split that happend between when the split keys
       // were gathered and before the HReiogn's write lock was taken.  We need
       // to validate the HFile region before attempting to bulk load all of them
       List<IOException> ioes = new ArrayList<IOException>();
       List<Pair<byte[], String>> failures = new ArrayList<Pair<byte[], String>>();
       for (Pair<byte[], String> p : familyPaths) {
         byte[] familyName = p.getFirst();
         String path = p.getSecond();

         Store store = getStore(familyName);
         if (store == null) {
           IOException ioe = new org.apache.hadoop.hbase.exceptions.DoNotRetryIOException(
               "No such column family " + Bytes.toStringBinary(familyName));
           ioes.add(ioe);
         } else {
           try {
             store.assertBulkLoadHFileOk(new Path(path));
           } catch (WrongRegionException wre) {
             // recoverable (file doesn't fit in region)
             failures.add(p);
           } catch (IOException ioe) {
             // unrecoverable (hdfs problem)
             ioes.add(ioe);
           }
         }
       }

       // validation failed because of some sort of IO problem.
       if (ioes.size() != 0) {
         IOException e = MultipleIOException.createIOException(ioes);
         LOG.error("There were one or more IO errors when checking if the bulk load is ok.", e);
         throw e;
       }

       // validation failed, bail out before doing anything permanent.
       if (failures.size() != 0) {
         StringBuilder list = new StringBuilder();
         for (Pair<byte[], String> p : failures) {
           list.append("\n").append(Bytes.toString(p.getFirst())).append(" : ")
             .append(p.getSecond());
         }
         // problem when validating
         LOG.warn("There was a recoverable bulk load failure likely due to a" +
             " split.  These (family, HFile) pairs were not loaded: " + list);
         return false;
       }

       for (Pair<byte[], String> p : familyPaths) {
         byte[] familyName = p.getFirst();
         String path = p.getSecond();
         Store store = getStore(familyName);
         try {
           String finalPath = path;
           if(bulkLoadListener != null) {
             finalPath = bulkLoadListener.prepareBulkLoad(familyName, path);
           }
           store.bulkLoadHFile(finalPath, assignSeqId ? this.log.obtainSeqNum() : -1);
           if(bulkLoadListener != null) {
             bulkLoadListener.doneBulkLoad(familyName, path);
           }
         } catch (IOException ioe) {
           // A failure here can cause an atomicity violation that we currently
           // cannot recover from since it is likely a failed HDFS operation.

           // TODO Need a better story for reverting partial failures due to HDFS.
           LOG.error("There was a partial failure due to IO when attempting to" +
               " load " + Bytes.toString(p.getFirst()) + " : "+ p.getSecond(), ioe);
           if(bulkLoadListener != null) {
             try {
               bulkLoadListener.failedBulkLoad(familyName, path);
             } catch (Exception ex) {
               LOG.error("Error while calling failedBulkLoad for family "+
                   Bytes.toString(familyName)+" with path "+path, ex);
             }
           }
           throw ioe;
         }
       }
       return true;
     } finally {
       closeBulkRegionOperation();
     }
   }

   @Override
   public boolean equals(Object o) {
     if (!(o instanceof HRegion)) {
       return false;
     }
     return Bytes.equals(this.getRegionName(), ((HRegion) o).getRegionName());
   }

   @Override
   public int hashCode() {
     return Bytes.hashCode(this.getRegionName());
   }

   @Override
   public String toString() {
     return this.getRegionNameAsString();
   }

   /**
    * RegionScannerImpl is used to combine scanners from multiple Stores (aka column families).
    */
   class RegionScannerImpl implements RegionScanner {
     // Package local for testability
     KeyValueHeap storeHeap = null;
     /** Heap of key-values that are not essential for the provided filters and are thus read
      * on demand, if on-demand column family loading is enabled.*/
     KeyValueHeap joinedHeap = null;
     /**
      * If the joined heap data gathering is interrupted due to scan limits, this will
      * contain the row for which we are populating the values.*/
     private KeyValue joinedContinuationRow = null;
     // KeyValue indicating that limit is reached when scanning
     private final KeyValue KV_LIMIT = new KeyValue();
     private final byte [] stopRow;
     private Filter filter;
     private int batch;
     private int isScan;
     private boolean filterClosed = false;
     private long readPt;
     private long maxResultSize;
     private HRegion region;

     public HRegionInfo getRegionInfo() {
       return region.getRegionInfo();
     }

     RegionScannerImpl(Scan scan, List<KeyValueScanner> additionalScanners, HRegion region)
         throws IOException {
       // DebugPrint.println("HRegionScanner.<init>");
       this.region = region;
       this.maxResultSize = scan.getMaxResultSize();
       if (scan.hasFilter()) {
         this.filter = new FilterWrapper(scan.getFilter());
       } else {
         this.filter = null;
       }

       this.batch = scan.getBatch();
       if (Bytes.equals(scan.getStopRow(), HConstants.EMPTY_END_ROW) && !scan.isGetScan()) {
         this.stopRow = null;
       } else {
         this.stopRow = scan.getStopRow();
       }
       // If we are doing a get, we want to be [startRow,endRow] normally
       // it is [startRow,endRow) and if startRow=endRow we get nothing.
       this.isScan = scan.isGetScan() ? -1 : 0;

       // synchronize on scannerReadPoints so that nobody calculates
       // getSmallestReadPoint, before scannerReadPoints is updated.
       IsolationLevel isolationLevel = scan.getIsolationLevel();
       synchronized(scannerReadPoints) {
         if (isolationLevel == IsolationLevel.READ_UNCOMMITTED) {
           // This scan can read even uncommitted transactions
           this.readPt = Long.MAX_VALUE;
           MultiVersionConsistencyControl.setThreadReadPoint(this.readPt);
         } else {
           this.readPt = MultiVersionConsistencyControl.resetThreadReadPoint(mvcc);
         }
         scannerReadPoints.put(this, this.readPt);
       }

       // Here we separate all scanners into two lists - scanner that provide data required
       // by the filter to operate (scanners list) and all others (joinedScanners list).
       List<KeyValueScanner> scanners = new ArrayList<KeyValueScanner>();
       List<KeyValueScanner> joinedScanners = new ArrayList<KeyValueScanner>();
       if (additionalScanners != null) {
         scanners.addAll(additionalScanners);
       }

       for (Map.Entry<byte[], NavigableSet<byte[]>> entry :
           scan.getFamilyMap().entrySet()) {
         Store store = stores.get(entry.getKey());
         KeyValueScanner scanner = store.getScanner(scan, entry.getValue());
         if (this.filter == null || !scan.doLoadColumnFamiliesOnDemand()
           || this.filter.isFamilyEssential(entry.getKey())) {
           scanners.add(scanner);
         } else {
           joinedScanners.add(scanner);
         }
       }
       this.storeHeap = new KeyValueHeap(scanners, comparator);
       if (!joinedScanners.isEmpty()) {
         this.joinedHeap = new KeyValueHeap(joinedScanners, comparator);
       }
     }

     RegionScannerImpl(Scan scan, HRegion region) throws IOException {
       this(scan, null, region);
     }

     @Override
     public long getMaxResultSize() {
       return maxResultSize;
     }

     @Override
     public long getMvccReadPoint() {
       return this.readPt;
     }

     /**
      * Reset both the filter and the old filter.
      *
      * @throws IOException in case a filter raises an I/O exception.
      */
     protected void resetFilters() throws IOException {
       if (filter != null) {
         filter.reset();
       }
     }

     @Override
     public boolean next(List<KeyValue> outResults)
         throws IOException {
       // apply the batching limit by default
       return next(outResults, batch);
     }

     @Override
     public synchronized boolean next(List<KeyValue> outResults, int limit) throws IOException {
       if (this.filterClosed) {
         throw new UnknownScannerException("Scanner was closed (timed out?) " +
             "after we renewed it. Could be caused by a very slow scanner " +
             "or a lengthy garbage collection");
       }
       startRegionOperation(Operation.SCAN);
       readRequestsCount.increment();
       try {

         // This could be a new thread from the last time we called next().
         MultiVersionConsistencyControl.setThreadReadPoint(this.readPt);

         return nextRaw(outResults, limit);
       } finally {
         closeRegionOperation();
       }
     }

     @Override
     public boolean nextRaw(List<KeyValue> outResults)
         throws IOException {
       return nextRaw(outResults, batch);
     }

     @Override
     public boolean nextRaw(List<KeyValue> outResults, int limit) throws IOException {
       boolean returnResult;
       if (outResults.isEmpty()) {
         // Usually outResults is empty. This is true when next is called
         // to handle scan or get operation.
         returnResult = nextInternal(outResults, limit);
       } else {
         List<KeyValue> tmpList = new ArrayList<KeyValue>();
         returnResult = nextInternal(tmpList, limit);
         outResults.addAll(tmpList);
       }
       resetFilters();
       if (isFilterDone()) {
         return false;
       }
       if (region != null && region.metricsRegion != null) {
         long totalSize = 0;
         if (outResults != null) {
           for(KeyValue kv:outResults) {
             totalSize += kv.getLength();
           }
         }
         region.metricsRegion.updateScanNext(totalSize);
       }
       return returnResult;
     }


     private void populateFromJoinedHeap(List<KeyValue> results, int limit)
         throws IOException {
       assert joinedContinuationRow != null;
       KeyValue kv = populateResult(results, this.joinedHeap, limit,
           joinedContinuationRow.getBuffer(), joinedContinuationRow.getRowOffset(),
           joinedContinuationRow.getRowLength());
       if (kv != KV_LIMIT) {
         // We are done with this row, reset the continuation.
         joinedContinuationRow = null;
       }
       // As the data is obtained from two independent heaps, we need to
       // ensure that result list is sorted, because Result relies on that.
       Collections.sort(results, comparator);
     }

     /**
      * Fetches records with currentRow into results list, until next row or limit (if not -1).
      * @param results
      * @param heap KeyValueHeap to fetch data from.It must be positioned on correct row before call.
      * @param limit Max amount of KVs to place in result list, -1 means no limit.
      * @param currentRow Byte array with key we are fetching.
      * @param offset offset for currentRow
      * @param length length for currentRow
      * @return KV_LIMIT if limit reached, next KeyValue otherwise.
      */
     private KeyValue populateResult(List<KeyValue> results, KeyValueHeap heap, int limit,
         byte[] currentRow, int offset, short length) throws IOException {
       KeyValue nextKv;
       do {
         heap.next(results, limit - results.size());
         if (limit > 0 && results.size() == limit) {
           return KV_LIMIT;
         }
         nextKv = heap.peek();
       } while (nextKv != null && nextKv.matchingRow(currentRow, offset, length));

       return nextKv;
     }

     /*
      * @return True if a filter rules the scanner is over, done.
      */
     public synchronized boolean isFilterDone() throws IOException {
       return this.filter != null && this.filter.filterAllRemaining();
     }

     private boolean nextInternal(List<KeyValue> results, int limit)
     throws IOException {
       if (!results.isEmpty()) {
         throw new IllegalArgumentException("First parameter should be an empty list");
       }
       RpcCallContext rpcCall = RpcServer.getCurrentCall();
       // The loop here is used only when at some point during the next we determine
       // that due to effects of filters or otherwise, we have an empty row in the result.
       // Then we loop and try again. Otherwise, we must get out on the first iteration via return,
       // "true" if there's more data to read, "false" if there isn't (storeHeap is at a stop row,
       // and joinedHeap has no more data to read for the last row (if set, joinedContinuationRow).
       while (true) {
         if (rpcCall != null) {
           // If a user specifies a too-restrictive or too-slow scanner, the
           // client might time out and disconnect while the server side
           // is still processing the request. We should abort aggressively
           // in that case.
           rpcCall.throwExceptionIfCallerDisconnected();
         }

         // Let's see what we have in the storeHeap.
         KeyValue current = this.storeHeap.peek();

         byte[] currentRow = null;
         int offset = 0;
         short length = 0;
         if (current != null) {
           currentRow = current.getBuffer();
           offset = current.getRowOffset();
           length = current.getRowLength();
         }
         boolean stopRow = isStopRow(currentRow, offset, length);
         // Check if we were getting data from the joinedHeap and hit the limit.
         // If not, then it's main path - getting results from storeHeap.
         if (joinedContinuationRow == null) {
           // First, check if we are at a stop row. If so, there are no more results.
           if (stopRow) {
             if (filter != null && filter.hasFilterRow()) {
               filter.filterRow(results);
             }
             return false;
           }

           // Check if rowkey filter wants to exclude this row. If so, loop to next.
           // Technically, if we hit limits before on this row, we don't need this call.
           if (filterRowKey(currentRow, offset, length)) {
             boolean moreRows = nextRow(currentRow, offset, length);
             if (!moreRows) return false;
             results.clear();
             continue;
           }

           KeyValue nextKv = populateResult(results, this.storeHeap, limit, currentRow, offset,
               length);
           // Ok, we are good, let's try to get some results from the main heap.
           if (nextKv == KV_LIMIT) {
             if (this.filter != null && filter.hasFilterRow()) {
               throw new IncompatibleFilterException(
                 "Filter whose hasFilterRow() returns true is incompatible with scan with limit!");
             }
             return true; // We hit the limit.
           }

           stopRow = nextKv == null ||
               isStopRow(nextKv.getBuffer(), nextKv.getRowOffset(), nextKv.getRowLength());
           // save that the row was empty before filters applied to it.
           final boolean isEmptyRow = results.isEmpty();

           // We have the part of the row necessary for filtering (all of it, usually).
           // First filter with the filterRow(List).
           if (filter != null && filter.hasFilterRow()) {
             filter.filterRow(results);
           }
           if (isEmptyRow) {
             boolean moreRows = nextRow(currentRow, offset, length);
             if (!moreRows) return false;
             results.clear();
             // This row was totally filtered out, if this is NOT the last row,
             // we should continue on. Otherwise, nothing else to do.
             if (!stopRow) continue;
             return false;
           }

           // Ok, we are done with storeHeap for this row.
           // Now we may need to fetch additional, non-essential data into row.
           // These values are not needed for filter to work, so we postpone their
           // fetch to (possibly) reduce amount of data loads from disk.
           if (this.joinedHeap != null) {
             KeyValue nextJoinedKv = joinedHeap.peek();
             // If joinedHeap is pointing to some other row, try to seek to a correct one.
             boolean mayHaveData =
               (nextJoinedKv != null && nextJoinedKv.matchingRow(currentRow, offset, length))
               || (this.joinedHeap.requestSeek(KeyValue.createFirstOnRow(currentRow, offset, length),
                 true, true)
                 && joinedHeap.peek() != null
                 && joinedHeap.peek().matchingRow(currentRow, offset, length));
             if (mayHaveData) {
               joinedContinuationRow = current;
               populateFromJoinedHeap(results, limit);
             }
           }
         } else {
           // Populating from the joined heap was stopped by limits, populate some more.
           populateFromJoinedHeap(results, limit);
         }

         // We may have just called populateFromJoinedMap and hit the limits. If that is
         // the case, we need to call it again on the next next() invocation.
         if (joinedContinuationRow != null) {
           return true;
         }

         // Finally, we are done with both joinedHeap and storeHeap.
         // Double check to prevent empty rows from appearing in result. It could be
         // the case when SingleColumnValueExcludeFilter is used.
         if (results.isEmpty()) {
           boolean moreRows = nextRow(currentRow, offset, length);
           if (!moreRows) return false;
           if (!stopRow) continue;
         }

         // We are done. Return the result.
         return !stopRow;
       }
     }

     private boolean filterRowKey(byte[] row, int offset, short length) throws IOException {
       return filter != null
           && filter.filterRowKey(row, offset, length);
     }

     protected boolean nextRow(byte [] currentRow, int offset, short length) throws IOException {
       assert this.joinedContinuationRow == null: "Trying to go to next row during joinedHeap read.";
       KeyValue next;
       while ((next = this.storeHeap.peek()) != null &&
              next.matchingRow(currentRow, offset, length)) {
         this.storeHeap.next(MOCKED_LIST);
       }
       resetFilters();
       // Calling the hook in CP which allows it to do a fast forward
       if (this.region.getCoprocessorHost() != null) {
         return this.region.getCoprocessorHost().postScannerFilterRow(this, currentRow);
       }
       return true;
     }

     private boolean isStopRow(byte [] currentRow, int offset, short length) {
       return currentRow == null ||
           (stopRow != null &&
           comparator.compareRows(stopRow, 0, stopRow.length,
             currentRow, offset, length) <= isScan);
     }

     @Override
     public synchronized void close() {
       if (storeHeap != null) {
         storeHeap.close();
         storeHeap = null;
       }
       if (joinedHeap != null) {
         joinedHeap.close();
         joinedHeap = null;
       }
       // no need to sychronize here.
       scannerReadPoints.remove(this);
       this.filterClosed = true;
     }

     KeyValueHeap getStoreHeapForTesting() {
       return storeHeap;
     }

     @Override
     public synchronized boolean reseek(byte[] row) throws IOException {
       if (row == null) {
         throw new IllegalArgumentException("Row cannot be null.");
       }
       boolean result = false;
       startRegionOperation();
       try {
         // This could be a new thread from the last time we called next().
         MultiVersionConsistencyControl.setThreadReadPoint(this.readPt);
         KeyValue kv = KeyValue.createFirstOnRow(row);
         // use request seek to make use of the lazy seek option. See HBASE-5520
         result = this.storeHeap.requestSeek(kv, true, true);
         if (this.joinedHeap != null) {
           result = this.joinedHeap.requestSeek(kv, true, true) || result;
         }
       } finally {
         closeRegionOperation();
       }
       return result;
     }
   }

   // Utility methods
   /**
    * A utility method to create new instances of HRegion based on the
    * {@link HConstants#REGION_IMPL} configuration property.
    * @param tableDir qualified path of directory where region should be located,
    * usually the table directory.
    * @param log The HLog is the outbound log for any updates to the HRegion
    * (There's a single HLog for all the HRegions on a single HRegionServer.)
    * The log file is a logfile from the previous execution that's
    * custom-computed for this HRegion. The HRegionServer computes and sorts the
    * appropriate log info for this HRegion. If there is a previous log file
    * (implying that the HRegion has been written-to before), then read it from
    * the supplied path.
    * @param fs is the filesystem.
    * @param conf is global configuration settings.
    * @param regionInfo - HRegionInfo that describes the region
    * is new), then read them from the supplied path.
    * @param htd the table descriptor
    * @param rsServices
    * @return the new instance
    */
   static HRegion newHRegion(Path tableDir, HLog log, FileSystem fs,
       Configuration conf, HRegionInfo regionInfo, final HTableDescriptor htd,
       RegionServerServices rsServices) {
     try {
       @SuppressWarnings("unchecked")
       Class<? extends HRegion> regionClass =
           (Class<? extends HRegion>) conf.getClass(HConstants.REGION_IMPL, HRegion.class);

       Constructor<? extends HRegion> c =
           regionClass.getConstructor(Path.class, HLog.class, FileSystem.class,
               Configuration.class, HRegionInfo.class, HTableDescriptor.class,
               RegionServerServices.class);

       return c.newInstance(tableDir, log, fs, conf, regionInfo, htd, rsServices);
     } catch (Throwable e) {
       // todo: what should I throw here?
       throw new IllegalStateException("Could not instantiate a region instance.", e);
     }
   }

   /**
    * Convenience method creating new HRegions. Used by createTable and by the
    * bootstrap code in the HMaster constructor.
    * Note, this method creates an {@link HLog} for the created region. It
    * needs to be closed explicitly.  Use {@link HRegion#getLog()} to get
    * access.  <b>When done with a region created using this method, you will
    * need to explicitly close the {@link HLog} it created too; it will not be
    * done for you.  Not closing the log will leave at least a daemon thread
    * running.</b>  Call {@link #closeHRegion(HRegion)} and it will do
    * necessary cleanup for you.
    * @param info Info for region to create.
    * @param rootDir Root directory for HBase instance
    * @param conf
    * @param hTableDescriptor
    * @return new HRegion
    *
    * @throws IOException
    */
   public static HRegion createHRegion(final HRegionInfo info, final Path rootDir,
       final Configuration conf, final HTableDescriptor hTableDescriptor)
   throws IOException {
     return createHRegion(info, rootDir, conf, hTableDescriptor, null);
   }

   /**
    * This will do the necessary cleanup a call to
    * {@link #createHRegion(HRegionInfo, Path, Configuration, HTableDescriptor)}
    * requires.  This method will close the region and then close its
    * associated {@link HLog} file.  You use it if you call the other createHRegion,
    * the one that takes an {@link HLog} instance but don't be surprised by the
    * call to the {@link HLog#closeAndDelete()} on the {@link HLog} the
    * HRegion was carrying.
    * @param r
    * @throws IOException
    */
   public static void closeHRegion(final HRegion r) throws IOException {
     if (r == null) return;
     r.close();
     if (r.getLog() == null) return;
     r.getLog().closeAndDelete();
   }

   /**
    * Convenience method creating new HRegions. Used by createTable.
    * The {@link HLog} for the created region needs to be closed explicitly.
    * Use {@link HRegion#getLog()} to get access.
    *
    * @param info Info for region to create.
    * @param rootDir Root directory for HBase instance
    * @param conf
    * @param hTableDescriptor
    * @param hlog shared HLog
    * @param initialize - true to initialize the region
    * @return new HRegion
    *
    * @throws IOException
    */
   public static HRegion createHRegion(final HRegionInfo info, final Path rootDir,
                                       final Configuration conf,
                                       final HTableDescriptor hTableDescriptor,
                                       final HLog hlog,
                                       final boolean initialize)
       throws IOException {
     return createHRegion(info, rootDir, conf, hTableDescriptor,
         hlog, initialize, false);
   }

   /**
    * Convenience method creating new HRegions. Used by createTable.
    * The {@link HLog} for the created region needs to be closed
    * explicitly, if it is not null.
    * Use {@link HRegion#getLog()} to get access.
    *
    * @param info Info for region to create.
    * @param rootDir Root directory for HBase instance
    * @param conf
    * @param hTableDescriptor
    * @param hlog shared HLog
    * @param initialize - true to initialize the region
    * @param ignoreHLog - true to skip generate new hlog if it is null, mostly for createTable
    * @return new HRegion
    * @throws IOException
    */
   public static HRegion createHRegion(final HRegionInfo info, final Path rootDir,
                                       final Configuration conf,
                                       final HTableDescriptor hTableDescriptor,
                                       final HLog hlog,
                                       final boolean initialize, final boolean ignoreHLog)
       throws IOException {
     LOG.info("creating HRegion " + info.getTableNameAsString()
         + " HTD == " + hTableDescriptor + " RootDir = " + rootDir +
         " Table name == " + info.getTableNameAsString());

     Path tableDir = HTableDescriptor.getTableDir(rootDir, info.getTableName());
     FileSystem fs = FileSystem.get(conf);
     HRegionFileSystem rfs = HRegionFileSystem.createRegionOnFileSystem(conf, fs, tableDir, info);
     HLog effectiveHLog = hlog;
     if (hlog == null && !ignoreHLog) {
       effectiveHLog = HLogFactory.createHLog(fs, rfs.getRegionDir(),
                                              HConstants.HREGION_LOGDIR_NAME, conf);
     }
     HRegion region = HRegion.newHRegion(tableDir,
         effectiveHLog, fs, conf, info, hTableDescriptor, null);
     if (initialize) {
       region.initialize();
     }
     return region;
   }

   public static HRegion createHRegion(final HRegionInfo info, final Path rootDir,
                                       final Configuration conf,
                                       final HTableDescriptor hTableDescriptor,
                                       final HLog hlog)
     throws IOException {
     return createHRegion(info, rootDir, conf, hTableDescriptor, hlog, true);
   }


   /**
    * Open a Region.
    * @param info Info for region to be opened.
    * @param wal HLog for region to use. This method will call
    * HLog#setSequenceNumber(long) passing the result of the call to
    * HRegion#getMinSequenceId() to ensure the log id is properly kept
    * up.  HRegionStore does this every time it opens a new region.
    * @param conf
    * @return new HRegion
    *
    * @throws IOException
    */
   public static HRegion openHRegion(final HRegionInfo info,
       final HTableDescriptor htd, final HLog wal,
       final Configuration conf)
   throws IOException {
     return openHRegion(info, htd, wal, conf, null, null);
   }

   /**
    * Open a Region.
    * @param info Info for region to be opened
    * @param htd the table descriptor
    * @param wal HLog for region to use. This method will call
    * HLog#setSequenceNumber(long) passing the result of the call to
    * HRegion#getMinSequenceId() to ensure the log id is properly kept
    * up.  HRegionStore does this every time it opens a new region.
    * @param conf The Configuration object to use.
    * @param rsServices An interface we can request flushes against.
    * @param reporter An interface we can report progress against.
    * @return new HRegion
    *
    * @throws IOException
    */
   public static HRegion openHRegion(final HRegionInfo info,
     final HTableDescriptor htd, final HLog wal, final Configuration conf,
     final RegionServerServices rsServices,
     final CancelableProgressable reporter)
   throws IOException {
     return openHRegion(FSUtils.getRootDir(conf), info, htd, wal, conf, rsServices, reporter);
   }

   /**
    * Open a Region.
    * @param rootDir Root directory for HBase instance
    * @param info Info for region to be opened.
    * @param htd the table descriptor
    * @param wal HLog for region to use. This method will call
    * HLog#setSequenceNumber(long) passing the result of the call to
    * HRegion#getMinSequenceId() to ensure the log id is properly kept
    * up.  HRegionStore does this every time it opens a new region.
    * @param conf The Configuration object to use.
    * @return new HRegion
    * @throws IOException
    */
   public static HRegion openHRegion(Path rootDir, final HRegionInfo info,
       final HTableDescriptor htd, final HLog wal, final Configuration conf)
   throws IOException {
     return openHRegion(rootDir, info, htd, wal, conf, null, null);
   }

   /**
    * Open a Region.
    * @param rootDir Root directory for HBase instance
    * @param info Info for region to be opened.
    * @param htd the table descriptor
    * @param wal HLog for region to use. This method will call
    * HLog#setSequenceNumber(long) passing the result of the call to
    * HRegion#getMinSequenceId() to ensure the log id is properly kept
    * up.  HRegionStore does this every time it opens a new region.
    * @param conf The Configuration object to use.
    * @param rsServices An interface we can request flushes against.
    * @param reporter An interface we can report progress against.
    * @return new HRegion
    * @throws IOException
    */
   public static HRegion openHRegion(final Path rootDir, final HRegionInfo info,
       final HTableDescriptor htd, final HLog wal, final Configuration conf,
       final RegionServerServices rsServices,
       final CancelableProgressable reporter)
   throws IOException {
     FileSystem fs = null;
     if (rsServices != null) {
       fs = rsServices.getFileSystem();
     }
     if (fs == null) {
       fs = FileSystem.get(conf);
     }
     return openHRegion(conf, fs, rootDir, info, htd, wal, rsServices, reporter);
   }

   /**
    * Open a Region.
    * @param conf The Configuration object to use.
    * @param fs Filesystem to use
    * @param rootDir Root directory for HBase instance
    * @param info Info for region to be opened.
    * @param htd the table descriptor
    * @param wal HLog for region to use. This method will call
    * HLog#setSequenceNumber(long) passing the result of the call to
    * HRegion#getMinSequenceId() to ensure the log id is properly kept
    * up.  HRegionStore does this every time it opens a new region.
    * @return new HRegion
    * @throws IOException
    */
   public static HRegion openHRegion(final Configuration conf, final FileSystem fs,
       final Path rootDir, final HRegionInfo info, final HTableDescriptor htd, final HLog wal)
       throws IOException {
     return openHRegion(conf, fs, rootDir, info, htd, wal, null, null);
   }

   /**
    * Open a Region.
    * @param conf The Configuration object to use.
    * @param fs Filesystem to use
    * @param rootDir Root directory for HBase instance
    * @param info Info for region to be opened.
    * @param htd the table descriptor
    * @param wal HLog for region to use. This method will call
    * HLog#setSequenceNumber(long) passing the result of the call to
    * HRegion#getMinSequenceId() to ensure the log id is properly kept
    * up.  HRegionStore does this every time it opens a new region.
    * @param rsServices An interface we can request flushes against.
    * @param reporter An interface we can report progress against.
    * @return new HRegion
    * @throws IOException
    */
   public static HRegion openHRegion(final Configuration conf, final FileSystem fs,
       final Path rootDir, final HRegionInfo info, final HTableDescriptor htd, final HLog wal,
       final RegionServerServices rsServices, final CancelableProgressable reporter)
       throws IOException {
     if (info == null) throw new NullPointerException("Passed region info is null");
     LOG.info("HRegion.openHRegion Region name ==" + info.getRegionNameAsString());
     if (LOG.isDebugEnabled()) {
       LOG.debug("Opening region: " + info);
     }
     Path dir = HTableDescriptor.getTableDir(rootDir, info.getTableName());
     HRegion r = HRegion.newHRegion(dir, wal, fs, conf, info, htd, rsServices);
     return r.openHRegion(reporter);
   }

   /**
    * Useful when reopening a closed region (normally for unit tests)
    * @param other original object
    * @param reporter An interface we can report progress against.
    * @return new HRegion
    * @throws IOException
    */
   public static HRegion openHRegion(final HRegion other, final CancelableProgressable reporter)
       throws IOException {
     HRegionFileSystem regionFs = other.getRegionFileSystem();
     HRegion r = newHRegion(regionFs.getTableDir(), other.getLog(), regionFs.getFileSystem(),
         other.baseConf, other.getRegionInfo(), other.getTableDesc(), null);
     return r.openHRegion(reporter);
   }

   /**
    * Open HRegion.
    * Calls initialize and sets sequenceid.
    * @param reporter
    * @return Returns <code>this</code>
    * @throws IOException
    */
   protected HRegion openHRegion(final CancelableProgressable reporter)
   throws IOException {
     checkCompressionCodecs();

     this.openSeqNum = initialize(reporter);
     if (this.log != null) {
       this.log.setSequenceNumber(this.openSeqNum);
     }

     return this;
   }

   private void checkCompressionCodecs() throws IOException {
     for (HColumnDescriptor fam: this.htableDescriptor.getColumnFamilies()) {
       CompressionTest.testCompression(fam.getCompression());
       CompressionTest.testCompression(fam.getCompactionCompression());
     }
   }

   /**
    * Create a daughter region from given a temp directory with the region data.
    * @param hri Spec. for daughter region to open.
    * @throws IOException
    */
   HRegion createDaughterRegionFromSplits(final HRegionInfo hri) throws IOException {
     HRegion r = HRegion.newHRegion(this.fs.getTableDir(), this.getLog(), fs.getFileSystem(),
         this.getBaseConf(), hri, this.getTableDesc(), rsServices);
     r.readRequestsCount.set(this.getReadRequestsCount() / 2);
     r.writeRequestsCount.set(this.getWriteRequestsCount() / 2);
     fs.commitDaughterRegion(hri);
     return r;
   }

   /**
    * Create a merged region given a temp directory with the region data.
    * @param mergedRegionInfo
    * @param region_b another merging region
    * @return merged hregion
    * @throws IOException
    */
   HRegion createMergedRegionFromMerges(final HRegionInfo mergedRegionInfo,
       final HRegion region_b) throws IOException {
     HRegion r = HRegion.newHRegion(this.fs.getTableDir(), this.getLog(),
         fs.getFileSystem(), this.getBaseConf(), mergedRegionInfo,
         this.getTableDesc(), this.rsServices);
     r.readRequestsCount.set(this.getReadRequestsCount()
         + region_b.getReadRequestsCount());
     r.writeRequestsCount.set(this.getWriteRequestsCount()
         + region_b.getWriteRequestsCount());
     this.fs.commitMergedRegion(mergedRegionInfo);
     return r;
   }

   /**
    * Inserts a new region's meta information into the passed
    * <code>meta</code> region. Used by the HMaster bootstrap code adding
    * new table to META table.
    *
    * @param meta META HRegion to be updated
    * @param r HRegion to add to <code>meta</code>
    *
    * @throws IOException
    */
   // TODO remove since only test and merge use this
   public static void addRegionToMETA(final HRegion meta, final HRegion r) throws IOException {
     meta.checkResources();
     // The row key is the region name
     byte[] row = r.getRegionName();
     final long now = EnvironmentEdgeManager.currentTimeMillis();
     final List<KeyValue> cells = new ArrayList<KeyValue>(2);
     cells.add(new KeyValue(row, HConstants.CATALOG_FAMILY,
       HConstants.REGIONINFO_QUALIFIER, now,
       r.getRegionInfo().toByteArray()));
     // Set into the root table the version of the meta table.
     cells.add(new KeyValue(row, HConstants.CATALOG_FAMILY,
       HConstants.META_VERSION_QUALIFIER, now,
       Bytes.toBytes(HConstants.META_VERSION)));
     meta.put(row, HConstants.CATALOG_FAMILY, cells);
   }

   /**
    * Computes the Path of the HRegion
    *
    * @param tabledir qualified path for table
    * @param name ENCODED region name
    * @return Path of HRegion directory
    */
   @Deprecated
   public static Path getRegionDir(final Path tabledir, final String name) {
     return new Path(tabledir, name);
   }

   /**
    * Computes the Path of the HRegion
    *
    * @param rootdir qualified path of HBase root directory
    * @param info HRegionInfo for the region
    * @return qualified path of region directory
    */
   @Deprecated
   public static Path getRegionDir(final Path rootdir, final HRegionInfo info) {
     return new Path(
       HTableDescriptor.getTableDir(rootdir, info.getTableName()),
                                    info.getEncodedName());
   }

   /**
    * Determines if the specified row is within the row range specified by the
    * specified HRegionInfo
    *
    * @param info HRegionInfo that specifies the row range
    * @param row row to be checked
    * @return true if the row is within the range specified by the HRegionInfo
    */
   public static boolean rowIsInRange(HRegionInfo info, final byte [] row) {
     return ((info.getStartKey().length == 0) ||
         (Bytes.compareTo(info.getStartKey(), row) <= 0)) &&
         ((info.getEndKey().length == 0) ||
             (Bytes.compareTo(info.getEndKey(), row) > 0));
   }

   /**
    * Merge two HRegions.  The regions must be adjacent and must not overlap.
    *
    * @param srcA
    * @param srcB
    * @return new merged HRegion
    * @throws IOException
    */
   public static HRegion mergeAdjacent(final HRegion srcA, final HRegion srcB)
   throws IOException {
     HRegion a = srcA;
     HRegion b = srcB;

     // Make sure that srcA comes first; important for key-ordering during
     // write of the merged file.
     if (srcA.getStartKey() == null) {
       if (srcB.getStartKey() == null) {
         throw new IOException("Cannot merge two regions with null start key");
       }
       // A's start key is null but B's isn't. Assume A comes before B
     } else if ((srcB.getStartKey() == null) ||
       (Bytes.compareTo(srcA.getStartKey(), srcB.getStartKey()) > 0)) {
       a = srcB;
       b = srcA;
     }

     if (!(Bytes.compareTo(a.getEndKey(), b.getStartKey()) == 0)) {
       throw new IOException("Cannot merge non-adjacent regions");
     }
     return merge(a, b);
   }

   /**
    * Merge two regions whether they are adjacent or not.
    *
    * @param a region a
    * @param b region b
    * @return new merged region
    * @throws IOException
    */
   public static HRegion merge(final HRegion a, final HRegion b) throws IOException {
     if (!a.getRegionInfo().getTableNameAsString().equals(
         b.getRegionInfo().getTableNameAsString())) {
       throw new IOException("Regions do not belong to the same table");
     }

     FileSystem fs = a.getRegionFileSystem().getFileSystem();
     // Make sure each region's cache is empty
     a.flushcache();
     b.flushcache();

     // Compact each region so we only have one store file per family
     a.compactStores(true);
     if (LOG.isDebugEnabled()) {
       LOG.debug("Files for region: " + a);
       a.getRegionFileSystem().logFileSystemState(LOG);
     }
     b.compactStores(true);
     if (LOG.isDebugEnabled()) {
       LOG.debug("Files for region: " + b);
       b.getRegionFileSystem().logFileSystemState(LOG);
     }

     RegionMergeTransaction rmt = new RegionMergeTransaction(a, b, true);
     if (!rmt.prepare(null)) {
       throw new IOException("Unable to merge regions " + a + " and " + b);
     }
     HRegionInfo mergedRegionInfo = rmt.getMergedRegionInfo();
     LOG.info("starting merge of regions: " + a + " and " + b
         + " into new region " + mergedRegionInfo.getRegionNameAsString()
         + " with start key <"
         + Bytes.toStringBinary(mergedRegionInfo.getStartKey())
         + "> and end key <"
         + Bytes.toStringBinary(mergedRegionInfo.getEndKey()) + ">");
     HRegion dstRegion = null;
     try {
       dstRegion = rmt.execute(null, null);
     } catch (IOException ioe) {
       rmt.rollback(null, null);
       throw new IOException("Failed merging region " + a + " and " + b
           + ", and succssfully rolled back");
     }
     dstRegion.compactStores(true);

     if (LOG.isDebugEnabled()) {
       LOG.debug("Files for new region");
       dstRegion.getRegionFileSystem().logFileSystemState(LOG);
     }

     if (dstRegion.getRegionFileSystem().hasReferences(dstRegion.getTableDesc())) {
       throw new IOException("Merged region " + dstRegion
           + " still has references after the compaction, is compaction canceled?");
     }

     // Archiving the 'A' region
     HFileArchiver.archiveRegion(a.getBaseConf(), fs, a.getRegionInfo());
     // Archiving the 'B' region
     HFileArchiver.archiveRegion(b.getBaseConf(), fs, b.getRegionInfo());

     LOG.info("merge completed. New region is " + dstRegion);
     return dstRegion;
   }

   /**
    * @return True if needs a major compaction.
    * @throws IOException
    */
   boolean isMajorCompaction() throws IOException {
     for (Store store : this.stores.values()) {
       if (store.isMajorCompaction()) {
         return true;
       }
     }
     return false;
   }

   //
   // HBASE-880
   //
   /**
    * @param get get object
    * @return result
    * @throws IOException read exceptions
    */
   public Result get(final Get get) throws IOException {
     checkRow(get.getRow(), "Get");
     // Verify families are all valid
     if (get.hasFamilies()) {
       for (byte [] family: get.familySet()) {
         checkFamily(family);
       }
     } else { // Adding all families to scanner
       for (byte[] family: this.htableDescriptor.getFamiliesKeys()) {
         get.addFamily(family);
       }
     }
     List<KeyValue> results = get(get, true);
     return new Result(results);
   }

   /*
    * Do a get based on the get parameter.
    * @param withCoprocessor invoke coprocessor or not. We don't want to
    * always invoke cp for this private method.
    */
   private List<KeyValue> get(Get get, boolean withCoprocessor)
   throws IOException {

     List<KeyValue> results = new ArrayList<KeyValue>();

     // pre-get CP hook
     if (withCoprocessor && (coprocessorHost != null)) {
        if (coprocessorHost.preGet(get, results)) {
          return results;
        }
     }

     Scan scan = new Scan(get);

     RegionScanner scanner = null;
     try {
       scanner = getScanner(scan);
       scanner.next(results);
     } finally {
       if (scanner != null)
         scanner.close();
     }

     // post-get CP hook
     if (withCoprocessor && (coprocessorHost != null)) {
       coprocessorHost.postGet(get, results);
     }

     // do after lock
     if (this.metricsRegion != null) {
       long totalSize = 0l;
       if (results != null) {
         for (KeyValue kv:results) {
           totalSize += kv.getLength();
         }
       }
       this.metricsRegion.updateGet(totalSize);
     }

     return results;
   }

   public void mutateRow(RowMutations rm) throws IOException {
     mutateRowsWithLocks(rm.getMutations(), Collections.singleton(rm.getRow()));
   }

   /**
    * Perform atomic mutations within the region.
    * @param mutations The list of mutations to perform.
    * <code>mutations</code> can contain operations for multiple rows.
    * Caller has to ensure that all rows are contained in this region.
    * @param rowsToLock Rows to lock
    * If multiple rows are locked care should be taken that
    * <code>rowsToLock</code> is sorted in order to avoid deadlocks.
    * @throws IOException
    */
   public void mutateRowsWithLocks(Collection<Mutation> mutations,
       Collection<byte[]> rowsToLock) throws IOException {

     MultiRowMutationProcessor proc =
         new MultiRowMutationProcessor(mutations, rowsToLock);
     processRowsWithLocks(proc, -1);
   }

   /**
    * Performs atomic multiple reads and writes on a given row.
    *
    * @param processor The object defines the reads and writes to a row.
    */
   public void processRowsWithLocks(RowProcessor<?,?> processor)
       throws IOException {
     processRowsWithLocks(processor, rowProcessorTimeout);
   }

   /**
    * Performs atomic multiple reads and writes on a given row.
    *
    * @param processor The object defines the reads and writes to a row.
    * @param timeout The timeout of the processor.process() execution
    *                Use a negative number to switch off the time bound
    */
   public void processRowsWithLocks(RowProcessor<?,?> processor, long timeout)
       throws IOException {

     for (byte[] row : processor.getRowsToLock()) {
       checkRow(row, "processRowsWithLocks");
     }
     if (!processor.readOnly()) {
       checkReadOnly();
     }
     checkResources();

     startRegionOperation();
     WALEdit walEdit = new WALEdit();

     // 1. Run pre-process hook
     processor.preProcess(this, walEdit);

     // Short circuit the read only case
     if (processor.readOnly()) {
       try {
         long now = EnvironmentEdgeManager.currentTimeMillis();
         doProcessRowWithTimeout(
             processor, now, this, null, null, timeout);
         processor.postProcess(this, walEdit);
       } catch (IOException e) {
         throw e;
       } finally {
         closeRegionOperation();
       }
       return;
     }

     MultiVersionConsistencyControl.WriteEntry writeEntry = null;
     boolean locked = false;
     boolean walSyncSuccessful = false;
     List<Integer> acquiredLocks = null;
     long addedSize = 0;
     List<KeyValue> mutations = new ArrayList<KeyValue>();
     Collection<byte[]> rowsToLock = processor.getRowsToLock();
     try {
       // 2. Acquire the row lock(s)
       acquiredLocks = new ArrayList<Integer>(rowsToLock.size());
       for (byte[] row : rowsToLock) {
         // Attempt to lock all involved rows, fail if one lock times out
         Integer lid = getLock(null, row, true);
         if (lid == null) {
           throw new IOException("Failed to acquire lock on "
               + Bytes.toStringBinary(row));
         }
         acquiredLocks.add(lid);
       }
       // 3. Region lock
       lock(this.updatesLock.readLock(), acquiredLocks.size());
       locked = true;

       long now = EnvironmentEdgeManager.currentTimeMillis();
       try {
         // 4. Let the processor scan the rows, generate mutations and add
         //    waledits
         doProcessRowWithTimeout(
             processor, now, this, mutations, walEdit, timeout);

         if (!mutations.isEmpty()) {
           // 5. Get a mvcc write number
           writeEntry = mvcc.beginMemstoreInsert();
           // 6. Apply to memstore
           for (KeyValue kv : mutations) {
             kv.setMemstoreTS(writeEntry.getWriteNumber());
             byte[] family = kv.getFamily();
             checkFamily(family);
             addedSize += stores.get(family).add(kv);
           }

           long txid = 0;
           // 7. Append no sync
           if (!walEdit.isEmpty()) {
             txid = this.log.appendNoSync(this.getRegionInfo(),
                 this.htableDescriptor.getName(), walEdit,
                 processor.getClusterId(), now, this.htableDescriptor);
           }
           // 8. Release region lock
           if (locked) {
             this.updatesLock.readLock().unlock();
             locked = false;
           }

           // 9. Release row lock(s)
           if (acquiredLocks != null) {
             for (Integer lid : acquiredLocks) {
               releaseRowLock(lid);
             }
             acquiredLocks = null;
           }
           // 10. Sync edit log
           if (txid != 0) {
             syncOrDefer(txid, processor.useDurability());
           }
           walSyncSuccessful = true;
         }
       } finally {
         if (!mutations.isEmpty() && !walSyncSuccessful) {
           LOG.warn("Wal sync failed. Roll back " + mutations.size() +
               " memstore keyvalues for row(s):" +
               processor.getRowsToLock().iterator().next() + "...");
           for (KeyValue kv : mutations) {
             stores.get(kv.getFamily()).rollback(kv);
           }
         }
         // 11. Roll mvcc forward
         if (writeEntry != null) {
           mvcc.completeMemstoreInsert(writeEntry);
           writeEntry = null;
         }
         if (locked) {
           this.updatesLock.readLock().unlock();
           locked = false;
         }
         if (acquiredLocks != null) {
           for (Integer lid : acquiredLocks) {
             releaseRowLock(lid);
           }
         }

       }

       // 12. Run post-process hook
       processor.postProcess(this, walEdit);

     } catch (IOException e) {
       throw e;
     } finally {
       closeRegionOperation();
       if (!mutations.isEmpty() &&
           isFlushSize(this.addAndGetGlobalMemstoreSize(addedSize))) {
         requestFlush();
       }
     }
   }

   private void doProcessRowWithTimeout(final RowProcessor<?,?> processor,
                                        final long now,
                                        final HRegion region,
                                        final List<KeyValue> mutations,
                                        final WALEdit walEdit,
                                        final long timeout) throws IOException {
     // Short circuit the no time bound case.
     if (timeout < 0) {
       try {
         processor.process(now, region, mutations, walEdit);
       } catch (IOException e) {
         LOG.warn("RowProcessor:" + processor.getClass().getName() +
             " throws Exception on row(s):" +
             Bytes.toStringBinary(
               processor.getRowsToLock().iterator().next()) + "...", e);
         throw e;
       }
       return;
     }

     // Case with time bound
     FutureTask<Void> task =
       new FutureTask<Void>(new Callable<Void>() {
         @Override
         public Void call() throws IOException {
           try {
             processor.process(now, region, mutations, walEdit);
             return null;
           } catch (IOException e) {
             LOG.warn("RowProcessor:" + processor.getClass().getName() +
                 " throws Exception on row(s):" +
                 Bytes.toStringBinary(
                     processor.getRowsToLock().iterator().next()) + "...", e);
             throw e;
           }
         }
       });
     rowProcessorExecutor.execute(task);
     try {
       task.get(timeout, TimeUnit.MILLISECONDS);
     } catch (TimeoutException te) {
       LOG.error("RowProcessor timeout:" + timeout + " ms on row(s):" +
           Bytes.toStringBinary(processor.getRowsToLock().iterator().next()) +
           "...");
       throw new IOException(te);
     } catch (Exception e) {
       throw new IOException(e);
     }
   }

   // TODO: There's a lot of boiler plate code identical
   // to increment... See how to better unify that.
   /**
    * Perform one or more append operations on a row.
    *
    * @param append
    * @return new keyvalues after increment
    * @throws IOException
    */
   public Result append(Append append)
       throws IOException {
     byte[] row = append.getRow();
     checkRow(row, "append");
     boolean flush = false;
     boolean writeToWAL = append.getDurability() != Durability.SKIP_WAL;
     WALEdit walEdits = null;
     List<KeyValue> allKVs = new ArrayList<KeyValue>(append.size());
     Map<Store, List<KeyValue>> tempMemstore = new HashMap<Store, List<KeyValue>>();

     long size = 0;
     long txid = 0;

     checkReadOnly();
     // Lock row
     startRegionOperation(Operation.APPEND);
     this.writeRequestsCount.increment();
     WriteEntry w = null;
     try {
       Integer lid = getLock(null, row, true);
       lock(this.updatesLock.readLock());
       // wait for all prior MVCC transactions to finish - while we hold the row lock
       // (so that we are guaranteed to see the latest state)
       mvcc.completeMemstoreInsert(mvcc.beginMemstoreInsert());
       // now start my own transaction
       w = mvcc.beginMemstoreInsert();
       try {
         long now = EnvironmentEdgeManager.currentTimeMillis();
         // Process each family
         for (Map.Entry<byte[], List<? extends Cell>> family : append.getFamilyMap().entrySet()) {

           Store store = stores.get(family.getKey());
           List<KeyValue> kvs = new ArrayList<KeyValue>(family.getValue().size());

           // Get previous values for all columns in this family
           Get get = new Get(row);
           for (Cell cell : family.getValue()) {
             KeyValue kv = KeyValueUtil.ensureKeyValue(cell);
             get.addColumn(family.getKey(), kv.getQualifier());
           }
           List<KeyValue> results = get(get, false);

           // Iterate the input columns and update existing values if they were
           // found, otherwise add new column initialized to the append value

           // Avoid as much copying as possible. Every byte is copied at most
           // once.
           // Would be nice if KeyValue had scatter/gather logic
           int idx = 0;
           for (Cell cell : family.getValue()) {
             KeyValue kv = KeyValueUtil.ensureKeyValue(cell);
             KeyValue newKV;
             if (idx < results.size()
                 && results.get(idx).matchingQualifier(kv.getBuffer(),
                     kv.getQualifierOffset(), kv.getQualifierLength())) {
               KeyValue oldKv = results.get(idx);
               // allocate an empty kv once
               newKV = new KeyValue(row.length, kv.getFamilyLength(),
                   kv.getQualifierLength(), now, KeyValue.Type.Put,
                   oldKv.getValueLength() + kv.getValueLength());
               // copy in the value
               System.arraycopy(oldKv.getBuffer(), oldKv.getValueOffset(),
                   newKV.getBuffer(), newKV.getValueOffset(),
                   oldKv.getValueLength());
               System.arraycopy(kv.getBuffer(), kv.getValueOffset(),
                   newKV.getBuffer(),
                   newKV.getValueOffset() + oldKv.getValueLength(),
                   kv.getValueLength());
               idx++;
             } else {
               // allocate an empty kv once
               newKV = new KeyValue(row.length, kv.getFamilyLength(),
                   kv.getQualifierLength(), now, KeyValue.Type.Put,
                   kv.getValueLength());
               // copy in the value
               System.arraycopy(kv.getBuffer(), kv.getValueOffset(),
                   newKV.getBuffer(), newKV.getValueOffset(),
                   kv.getValueLength());
             }
             // copy in row, family, and qualifier
             System.arraycopy(kv.getBuffer(), kv.getRowOffset(),
                 newKV.getBuffer(), newKV.getRowOffset(), kv.getRowLength());
             System.arraycopy(kv.getBuffer(), kv.getFamilyOffset(),
                 newKV.getBuffer(), newKV.getFamilyOffset(),
                 kv.getFamilyLength());
             System.arraycopy(kv.getBuffer(), kv.getQualifierOffset(),
                 newKV.getBuffer(), newKV.getQualifierOffset(),
                 kv.getQualifierLength());

             newKV.setMemstoreTS(w.getWriteNumber());
             kvs.add(newKV);

             // Append update to WAL
             if (writeToWAL) {
               if (walEdits == null) {
                 walEdits = new WALEdit();
               }
               walEdits.add(newKV);
             }
           }

           //store the kvs to the temporary memstore before writing HLog
           tempMemstore.put(store, kvs);
         }

         // Actually write to WAL now
         if (writeToWAL) {
           // Using default cluster id, as this can only happen in the orginating
           // cluster. A slave cluster receives the final value (not the delta)
           // as a Put.
           txid = this.log.appendNoSync(this.getRegionInfo(),
               this.htableDescriptor.getName(), walEdits,
               HConstants.DEFAULT_CLUSTER_ID, EnvironmentEdgeManager.currentTimeMillis(),
               this.htableDescriptor);
         }

         //Actually write to Memstore now
         for (Map.Entry<Store, List<KeyValue>> entry : tempMemstore.entrySet()) {
           Store store = entry.getKey();
           if (store.getFamily().getMaxVersions() == 1) {
             // upsert if VERSIONS for this CF == 1
             size += store.upsert(entry.getValue(), getSmallestReadPoint());
           } else {
             // otherwise keep older versions around
             for (Cell cell: entry.getValue()) {
               KeyValue kv = KeyValueUtil.ensureKeyValue(cell);
               size += store.add(kv);
             }
           }
           allKVs.addAll(entry.getValue());
         }
         size = this.addAndGetGlobalMemstoreSize(size);
         flush = isFlushSize(size);
       } finally {
         this.updatesLock.readLock().unlock();
         releaseRowLock(lid);
       }
       if (writeToWAL) {
         // sync the transaction log outside the rowlock
         syncOrDefer(txid, append.getDurability());
       }
     } finally {
       if (w != null) {
         mvcc.completeMemstoreInsert(w);
       }
       closeRegionOperation();
     }

     if (this.metricsRegion != null) {
       this.metricsRegion.updateAppend();
     }

     if (flush) {
       // Request a cache flush. Do it outside update lock.
       requestFlush();
     }


     return append.isReturnResults() ? new Result(allKVs) : null;
   }

   /**
    * Perform one or more increment operations on a row.
    * @param increment
    * @return new keyvalues after increment
    * @throws IOException
    */
   public Result increment(Increment increment)
   throws IOException {
     byte [] row = increment.getRow();
     checkRow(row, "increment");
     TimeRange tr = increment.getTimeRange();
     boolean flush = false;
     boolean writeToWAL = increment.getDurability() != Durability.SKIP_WAL;
     WALEdit walEdits = null;
     List<KeyValue> allKVs = new ArrayList<KeyValue>(increment.size());
     Map<Store, List<KeyValue>> tempMemstore = new HashMap<Store, List<KeyValue>>();

     long size = 0;
     long txid = 0;

     checkReadOnly();
     // Lock row
     startRegionOperation(Operation.INCREMENT);
     this.writeRequestsCount.increment();
     WriteEntry w = null;
     try {
       Integer lid = getLock(null, row, true);
       lock(this.updatesLock.readLock());
       // wait for all prior MVCC transactions to finish - while we hold the row lock
       // (so that we are guaranteed to see the latest state)
       mvcc.completeMemstoreInsert(mvcc.beginMemstoreInsert());
       // now start my own transaction
       w = mvcc.beginMemstoreInsert();
       try {
         long now = EnvironmentEdgeManager.currentTimeMillis();
         // Process each family
         for (Map.Entry<byte [], List<? extends Cell>> family:
             increment.getFamilyMap().entrySet()) {

           Store store = stores.get(family.getKey());
           List<KeyValue> kvs = new ArrayList<KeyValue>(family.getValue().size());

           // Get previous values for all columns in this family
           Get get = new Get(row);
           for (Cell cell: family.getValue()) {
             KeyValue kv = KeyValueUtil.ensureKeyValue(cell);
             get.addColumn(family.getKey(), kv.getQualifier());
           }
           get.setTimeRange(tr.getMin(), tr.getMax());
           List<KeyValue> results = get(get, false);

           // Iterate the input columns and update existing values if they were
           // found, otherwise add new column initialized to the increment amount
           int idx = 0;
           for (Cell cell: family.getValue()) {
             KeyValue kv = KeyValueUtil.ensureKeyValue(cell);
             long amount = Bytes.toLong(kv.getValue());
             byte [] qualifier = kv.getQualifier();
             if (idx < results.size() && results.get(idx).matchingQualifier(qualifier)) {
               kv = results.get(idx);
               if(kv.getValueLength() == Bytes.SIZEOF_LONG) {
                 amount += Bytes.toLong(kv.getBuffer(), kv.getValueOffset(), Bytes.SIZEOF_LONG);
               } else {
                 // throw DoNotRetryIOException instead of IllegalArgumentException
                 throw new org.apache.hadoop.hbase.exceptions.DoNotRetryIOException(
                     "Attempted to increment field that isn't 64 bits wide");
               }
               idx++;
             }

             // Append new incremented KeyValue to list
             KeyValue newKV =
               new KeyValue(row, family.getKey(), qualifier, now, Bytes.toBytes(amount));
             newKV.setMemstoreTS(w.getWriteNumber());
             kvs.add(newKV);

             // Prepare WAL updates
             if (writeToWAL) {
               if (walEdits == null) {
                 walEdits = new WALEdit();
               }
               walEdits.add(newKV);
             }
           }

           //store the kvs to the temporary memstore before writing HLog
           tempMemstore.put(store, kvs);
         }

         // Actually write to WAL now
         if (writeToWAL) {
           // Using default cluster id, as this can only happen in the orginating
           // cluster. A slave cluster receives the final value (not the delta)
           // as a Put.
           txid = this.log.appendNoSync(this.getRegionInfo(), this.htableDescriptor.getName(),
               walEdits, HConstants.DEFAULT_CLUSTER_ID, EnvironmentEdgeManager.currentTimeMillis(),
               this.htableDescriptor);
         }

         //Actually write to Memstore now
         for (Map.Entry<Store, List<KeyValue>> entry : tempMemstore.entrySet()) {
           Store store = entry.getKey();
           if (store.getFamily().getMaxVersions() == 1) {
             // upsert if VERSIONS for this CF == 1
             size += store.upsert(entry.getValue(), getSmallestReadPoint());
           } else {
             // otherwise keep older versions around
             for (Cell cell : entry.getValue()) {
               KeyValue kv = KeyValueUtil.ensureKeyValue(cell);
               size += store.add(kv);
             }
           }
           allKVs.addAll(entry.getValue());
         }
         size = this.addAndGetGlobalMemstoreSize(size);
         flush = isFlushSize(size);
       } finally {
         this.updatesLock.readLock().unlock();
         releaseRowLock(lid);
       }
       if (writeToWAL) {
         // sync the transaction log outside the rowlock
         syncOrDefer(txid, increment.getDurability());
       }
     } finally {
       if (w != null) {
         mvcc.completeMemstoreInsert(w);
       }
       closeRegionOperation();
       if (this.metricsRegion != null) {
         this.metricsRegion.updateIncrement();
       }
     }

     if (flush) {
       // Request a cache flush.  Do it outside update lock.
       requestFlush();
     }

     return new Result(allKVs);
   }

   //
   // New HBASE-880 Helpers
   //

   private void checkFamily(final byte [] family)
   throws NoSuchColumnFamilyException {
     if (!this.htableDescriptor.hasFamily(family)) {
       throw new NoSuchColumnFamilyException("Column family " +
           Bytes.toString(family) + " does not exist in region " + this
           + " in table " + this.htableDescriptor);
     }
   }

   public static final long FIXED_OVERHEAD = ClassSize.align(
       ClassSize.OBJECT +
       ClassSize.ARRAY +
       38 * ClassSize.REFERENCE + 2 * Bytes.SIZEOF_INT +
       (12 * Bytes.SIZEOF_LONG) +
       Bytes.SIZEOF_BOOLEAN);

   public static final long DEEP_OVERHEAD = FIXED_OVERHEAD +
       ClassSize.OBJECT + // closeLock
       (2 * ClassSize.ATOMIC_BOOLEAN) + // closed, closing
       (3 * ClassSize.ATOMIC_LONG) + // memStoreSize, numPutsWithoutWAL, dataInMemoryWithoutWAL
       ClassSize.ATOMIC_INTEGER + // lockIdGenerator
       (3 * ClassSize.CONCURRENT_HASHMAP) +  // lockedRows, lockIds, scannerReadPoints
       WriteState.HEAP_SIZE + // writestate
       ClassSize.CONCURRENT_SKIPLISTMAP + ClassSize.CONCURRENT_SKIPLISTMAP_ENTRY + // stores
       (2 * ClassSize.REENTRANT_LOCK) + // lock, updatesLock
       ClassSize.ARRAYLIST + // recentFlushes
       MultiVersionConsistencyControl.FIXED_SIZE // mvcc
       ;

   @Override
   public long heapSize() {
     long heapSize = DEEP_OVERHEAD;
     for (Store store : this.stores.values()) {
       heapSize += store.heapSize();
     }
     // this does not take into account row locks, recent flushes, mvcc entries
     return heapSize;
   }

   /*
    * This method calls System.exit.
    * @param message Message to print out.  May be null.
    */
   private static void printUsageAndExit(final String message) {
     if (message != null && message.length() > 0) System.out.println(message);
     System.out.println("Usage: HRegion CATLALOG_TABLE_DIR [major_compact]");
     System.out.println("Options:");
     System.out.println(" major_compact  Pass this option to major compact " +
       "passed region.");
     System.out.println("Default outputs scan of passed region.");
     System.exit(1);
   }

   /**
    * Registers a new protocol buffer {@link Service} subclass as a coprocessor endpoint to
    * be available for handling
    * {@link HRegion#execService(com.google.protobuf.RpcController,
    *    org.apache.hadoop.hbase.protobuf.generated.ClientProtos.CoprocessorServiceCall)}} calls.
    *
    * <p>
    * Only a single instance may be registered per region for a given {@link Service} subclass (the
    * instances are keyed on {@link com.google.protobuf.Descriptors.ServiceDescriptor#getFullName()}.
    * After the first registration, subsequent calls with the same service name will fail with
    * a return value of {@code false}.
    * </p>
    * @param instance the {@code Service} subclass instance to expose as a coprocessor endpoint
    * @return {@code true} if the registration was successful, {@code false}
    * otherwise
    */
   public boolean registerService(Service instance) {
     /*
      * No stacking of instances is allowed for a single service name
      */
     Descriptors.ServiceDescriptor serviceDesc = instance.getDescriptorForType();
     if (coprocessorServiceHandlers.containsKey(serviceDesc.getFullName())) {
       LOG.error("Coprocessor service "+serviceDesc.getFullName()+
           " already registered, rejecting request from "+instance
       );
       return false;
     }

     coprocessorServiceHandlers.put(serviceDesc.getFullName(), instance);
     if (LOG.isDebugEnabled()) {
       LOG.debug("Registered coprocessor service: region="+
           Bytes.toStringBinary(getRegionName())+" service="+serviceDesc.getFullName());
     }
     return true;
   }

   /**
    * Executes a single protocol buffer coprocessor endpoint {@link Service} method using
    * the registered protocol handlers.  {@link Service} implementations must be registered via the
    * {@link HRegion#registerService(com.google.protobuf.Service)}
    * method before they are available.
    *
    * @param controller an {@code RpcContoller} implementation to pass to the invoked service
    * @param call a {@code CoprocessorServiceCall} instance identifying the service, method,
    *     and parameters for the method invocation
    * @return a protocol buffer {@code Message} instance containing the method's result
    * @throws IOException if no registered service handler is found or an error
    *     occurs during the invocation
    * @see org.apache.hadoop.hbase.regionserver.HRegion#registerService(com.google.protobuf.Service)
    */
   public Message execService(RpcController controller, CoprocessorServiceCall call)
       throws IOException {
     String serviceName = call.getServiceName();
     String methodName = call.getMethodName();
     if (!coprocessorServiceHandlers.containsKey(serviceName)) {
       throw new UnknownProtocolException(null,
           "No registered coprocessor service found for name "+serviceName+
           " in region "+Bytes.toStringBinary(getRegionName()));
     }

     Service service = coprocessorServiceHandlers.get(serviceName);
     Descriptors.ServiceDescriptor serviceDesc = service.getDescriptorForType();
     Descriptors.MethodDescriptor methodDesc = serviceDesc.findMethodByName(methodName);
     if (methodDesc == null) {
       throw new UnknownProtocolException(service.getClass(),
           "Unknown method "+methodName+" called on service "+serviceName+
               " in region "+Bytes.toStringBinary(getRegionName()));
     }

     Message request = service.getRequestPrototype(methodDesc).newBuilderForType()
         .mergeFrom(call.getRequest()).build();
     final Message.Builder responseBuilder =
         service.getResponsePrototype(methodDesc).newBuilderForType();
     service.callMethod(methodDesc, controller, request, new RpcCallback<Message>() {
       @Override
       public void run(Message message) {
         if (message != null) {
           responseBuilder.mergeFrom(message);
         }
       }
     });

     return responseBuilder.build();
   }

   /*
    * Process table.
    * Do major compaction or list content.
    * @param fs
    * @param p
    * @param log
    * @param c
    * @param majorCompact
    * @throws IOException
    */
   private static void processTable(final FileSystem fs, final Path p,
       final HLog log, final Configuration c,
       final boolean majorCompact)
   throws IOException {
     HRegion region = null;
     String metaStr = Bytes.toString(HConstants.META_TABLE_NAME);
     // Currently expects tables have one region only.
     if (p.getName().startsWith(metaStr)) {
       region = HRegion.newHRegion(p, log, fs, c,
         HRegionInfo.FIRST_META_REGIONINFO, HTableDescriptor.META_TABLEDESC, null);
     } else {
       throw new IOException("Not a known catalog table: " + p.toString());
     }
     try {
       region.initialize();
       if (majorCompact) {
         region.compactStores(true);
       } else {
         // Default behavior
         Scan scan = new Scan();
         // scan.addFamily(HConstants.CATALOG_FAMILY);
         RegionScanner scanner = region.getScanner(scan);
         try {
           List<KeyValue> kvs = new ArrayList<KeyValue>();
           boolean done = false;
           do {
             kvs.clear();
             done = scanner.next(kvs);
             if (kvs.size() > 0) LOG.info(kvs);
           } while (done);
         } finally {
           scanner.close();
         }
       }
     } finally {
       region.close();
     }
   }

   boolean shouldForceSplit() {
     return this.splitRequest;
   }

   byte[] getExplicitSplitPoint() {
     return this.explicitSplitPoint;
   }

   void forceSplit(byte[] sp) {
     // NOTE : this HRegion will go away after the forced split is successfull
     //        therefore, no reason to clear this value
     this.splitRequest = true;
     if (sp != null) {
       this.explicitSplitPoint = sp;
     }
   }

   void clearSplit_TESTS_ONLY() {
     this.splitRequest = false;
   }

   /**
    * Give the region a chance to prepare before it is split.
    */
   protected void prepareToSplit() {
     // nothing
   }

   /**
    * Return the splitpoint. null indicates the region isn't splittable
    * If the splitpoint isn't explicitly specified, it will go over the stores
    * to find the best splitpoint. Currently the criteria of best splitpoint
    * is based on the size of the store.
    */
   public byte[] checkSplit() {
     // Can't split META
     if (this.getRegionInfo().isMetaTable()) {
       if (shouldForceSplit()) {
         LOG.warn("Cannot split meta region in HBase 0.20 and above");
       }
       return null;
     }

     if (!splitPolicy.shouldSplit()) {
       return null;
     }

     byte[] ret = splitPolicy.getSplitPoint();

     if (ret != null) {
       try {
         checkRow(ret, "calculated split");
       } catch (IOException e) {
         LOG.error("Ignoring invalid split", e);
         return null;
       }
     }
     return ret;
   }

   /**
    * @return The priority that this region should have in the compaction queue
    */
   public int getCompactPriority() {
     int count = Integer.MAX_VALUE;
     for (Store store : stores.values()) {
       count = Math.min(count, store.getCompactPriority());
     }
     return count;
   }

   /**
    * Checks every store to see if one has too many
    * store files
    * @return true if any store has too many store files
    */
   public boolean needsCompaction() {
     for (Store store : stores.values()) {
       if(store.needsCompaction()) {
         return true;
       }
     }
     return false;
   }

   /** @return the coprocessor host */
   public RegionCoprocessorHost getCoprocessorHost() {
     return coprocessorHost;
   }

   /** @param coprocessorHost the new coprocessor host */
   public void setCoprocessorHost(final RegionCoprocessorHost coprocessorHost) {
     this.coprocessorHost = coprocessorHost;
   }

   /**
    * This method needs to be called before any public call that reads or
    * modifies data. It has to be called just before a try.
    * #closeRegionOperation needs to be called in the try's finally block
    * Acquires a read lock and checks if the region is closing or closed.
    * @throws NotServingRegionException when the region is closing or closed
    * @throws RegionTooBusyException if failed to get the lock in time
    * @throws InterruptedIOException if interrupted while waiting for a lock
    */
   public void startRegionOperation()
       throws NotServingRegionException, RegionTooBusyException, InterruptedIOException {
     startRegionOperation(Operation.ANY);
   }

   /**
    * @param op The operation is about to be taken on the region
    * @throws NotServingRegionException
    * @throws RegionTooBusyException
    * @throws InterruptedIOException
    */
   protected void startRegionOperation(Operation op) throws NotServingRegionException,
       RegionTooBusyException, InterruptedIOException {
     switch (op) {
     case INCREMENT:
     case APPEND:
     case GET:
     case SCAN:
     case SPLIT_REGION:
     case MERGE_REGION:
       // when a region is in recovering state, no read, split or merge is allowed
       if (this.isRecovering()) {
         throw new RegionInRecoveryException(this.getRegionNameAsString()
             + " is recovering");
       }
       break;
       default:
         break;
     }
     if (op == Operation.MERGE_REGION || op == Operation.SPLIT_REGION) {
       // split or merge region doesn't need to check the closing/closed state or lock the region
       return;
     }
     if (this.closing.get()) {
       throw new NotServingRegionException(getRegionNameAsString() + " is closing");
     }
     lock(lock.readLock());
     if (this.closed.get()) {
       lock.readLock().unlock();
       throw new NotServingRegionException(getRegionNameAsString() + " is closed");
     }
   }

   /**
    * Closes the lock. This needs to be called in the finally block corresponding
    * to the try block of #startRegionOperation
    */
   public void closeRegionOperation() {
     lock.readLock().unlock();
   }

   /**
    * This method needs to be called before any public call that reads or
    * modifies stores in bulk. It has to be called just before a try.
    * #closeBulkRegionOperation needs to be called in the try's finally block
    * Acquires a writelock and checks if the region is closing or closed.
    * @throws NotServingRegionException when the region is closing or closed
    * @throws RegionTooBusyException if failed to get the lock in time
    * @throws InterruptedIOException if interrupted while waiting for a lock
    */
   private void startBulkRegionOperation(boolean writeLockNeeded)
       throws NotServingRegionException, RegionTooBusyException, InterruptedIOException {
     if (this.closing.get()) {
       throw new NotServingRegionException(getRegionNameAsString() + " is closing");
     }
     if (writeLockNeeded) lock(lock.writeLock());
     else lock(lock.readLock());
     if (this.closed.get()) {
       if (writeLockNeeded) lock.writeLock().unlock();
       else lock.readLock().unlock();
       throw new NotServingRegionException(getRegionNameAsString() + " is closed");
     }
   }

   /**
    * Closes the lock. This needs to be called in the finally block corresponding
    * to the try block of #startRegionOperation
    */
   private void closeBulkRegionOperation(){
     if (lock.writeLock().isHeldByCurrentThread()) lock.writeLock().unlock();
     else lock.readLock().unlock();
   }

   /**
    * Update counters for numer of puts without wal and the size of possible data loss.
    * These information are exposed by the region server metrics.
    */
   private void recordPutWithoutWal(final Map<byte [], List<? extends Cell>> familyMap) {
     numPutsWithoutWAL.increment();
     if (numPutsWithoutWAL.get() <= 1) {
       LOG.info("writing data to region " + this +
                " with WAL disabled. Data may be lost in the event of a crash.");
     }

     long putSize = 0;
     for (List<? extends Cell> cells: familyMap.values()) {
       for (Cell cell : cells) {
         KeyValue kv = KeyValueUtil.ensureKeyValue(cell);
         putSize += kv.getKeyLength() + kv.getValueLength();
       }
     }

     dataInMemoryWithoutWAL.add(putSize);
   }

   private void lock(final Lock lock)
       throws RegionTooBusyException, InterruptedIOException {
     lock(lock, 1);
   }

   /**
    * Try to acquire a lock.  Throw RegionTooBusyException
    * if failed to get the lock in time. Throw InterruptedIOException
    * if interrupted while waiting for the lock.
    */
   private void lock(final Lock lock, final int multiplier)
       throws RegionTooBusyException, InterruptedIOException {
     try {
       final long waitTime = Math.min(maxBusyWaitDuration,
         busyWaitDuration * Math.min(multiplier, maxBusyWaitMultiplier));
       if (!lock.tryLock(waitTime, TimeUnit.MILLISECONDS)) {
         throw new RegionTooBusyException(
           "failed to get a lock in " + waitTime + "ms");
       }
     } catch (InterruptedException ie) {
       LOG.info("Interrupted while waiting for a lock");
       InterruptedIOException iie = new InterruptedIOException();
       iie.initCause(ie);
       throw iie;
     }
   }

   /**
    * Calls sync with the given transaction ID if the region's table is not
    * deferring it.
    * @param txid should sync up to which transaction
    * @throws IOException If anything goes wrong with DFS
    */
   private void syncOrDefer(long txid, Durability durability) throws IOException {
     if (this.getRegionInfo().isMetaRegion()) {
       this.log.sync(txid);
     } else {
       switch(durability) {
       case USE_DEFAULT:
         // do what CF defaults to
         if (!isDeferredLogSyncEnabled()) {
           this.log.sync(txid);
         }
         break;
       case SKIP_WAL:
         // nothing do to
         break;
       case ASYNC_WAL:
         // defer the sync, unless we globally can't
         if (this.deferredLogSyncDisabled) {
           this.log.sync(txid);
         }
         break;
       case SYNC_WAL:
       case FSYNC_WAL:
         // sync the WAL edit (SYNC and FSYNC treated the same for now)
         this.log.sync(txid);
         break;
       }
     }
   }

   /**
    * check if current region is deferred sync enabled.
    */
   private boolean isDeferredLogSyncEnabled() {
     return (this.htableDescriptor.isDeferredLogFlush() && !this.deferredLogSyncDisabled);
   }

   /**
    * A mocked list implementaion - discards all updates.
    */
   private static final List<KeyValue> MOCKED_LIST = new AbstractList<KeyValue>() {

     @Override
     public void add(int index, KeyValue element) {
       // do nothing
     }

     @Override
     public boolean addAll(int index, Collection<? extends KeyValue> c) {
       return false; // this list is never changed as a result of an update
     }

     @Override
     public KeyValue get(int index) {
       throw new UnsupportedOperationException();
     }

     @Override
     public int size() {
       return 0;
     }
   };

   /**
    * Facility for dumping and compacting catalog tables.
    * Only does catalog tables since these are only tables we for sure know
    * schema on.  For usage run:
    * <pre>
    *   ./bin/hbase org.apache.hadoop.hbase.regionserver.HRegion
    * </pre>
    * @param args
    * @throws IOException
    */
   public static void main(String[] args) throws IOException {
     if (args.length < 1) {
       printUsageAndExit(null);
     }
     boolean majorCompact = false;
     if (args.length > 1) {
       if (!args[1].toLowerCase().startsWith("major")) {
         printUsageAndExit("ERROR: Unrecognized option <" + args[1] + ">");
       }
       majorCompact = true;
     }
     final Path tableDir = new Path(args[0]);
     final Configuration c = HBaseConfiguration.create();
     final FileSystem fs = FileSystem.get(c);
     final Path logdir = new Path(c.get("hbase.tmp.dir"));
     final String logname = "hlog" + tableDir.getName()
       + EnvironmentEdgeManager.currentTimeMillis();

     final HLog log = HLogFactory.createHLog(fs, logdir, logname, c);
     try {
       processTable(fs, tableDir, log, c, majorCompact);
     } finally {
        log.close();
        // TODO: is this still right?
        BlockCache bc = new CacheConfig(c).getBlockCache();
        if (bc != null) bc.shutdown();
     }
   }

   /**
    * Gets the latest sequence number that was read from storage when this region was opened.
    */
   public long getOpenSeqNum() {
     return this.openSeqNum;
   }

   /**
    * Gets the min sequence number that was read from storage when this region was opened. WAL Edits
    * with smaller sequence number will be skipped from replay.
    */
   public long getMinSeqIdForLogReplay() {
     return this.minSeqIdForLogReplay;
   }

   /**
    * @return if a given region is in compaction now.
    */
   public CompactionState getCompactionState() {
     boolean hasMajor = majorInProgress.get() > 0, hasMinor = minorInProgress.get() > 0;
     return (hasMajor ? (hasMinor ? CompactionState.MAJOR_AND_MINOR : CompactionState.MAJOR)
         : (hasMinor ? CompactionState.MINOR : CompactionState.NONE));
   }

   public void reportCompactionRequestStart(boolean isMajor){
     (isMajor ? majorInProgress : minorInProgress).incrementAndGet();
   }

   public void reportCompactionRequestEnd(boolean isMajor){
     int newValue = (isMajor ? majorInProgress : minorInProgress).decrementAndGet();
     assert newValue >= 0;
   }

   /**
    * Listener class to enable callers of
    * bulkLoadHFile() to perform any necessary
    * pre/post processing of a given bulkload call
    */
   public static interface BulkLoadListener {

     /**
      * Called before an HFile is actually loaded
      * @param family family being loaded to
      * @param srcPath path of HFile
      * @return final path to be used for actual loading
      * @throws IOException
      */
     String prepareBulkLoad(byte[] family, String srcPath) throws IOException;

     /**
      * Called after a successful HFile load
      * @param family family being loaded to
      * @param srcPath path of HFile
      * @throws IOException
      */
     void doneBulkLoad(byte[] family, String srcPath) throws IOException;

     /**
      * Called after a failed HFile load
      * @param family family being loaded to
      * @param srcPath path of HFile
      * @throws IOException
      */
     void failedBulkLoad(byte[] family, String srcPath) throws IOException;
   }
 }