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The Apache Cassandra Project develops a highly scalable second-generation distributed database, bringing together Dynamo's fully distributed design and Bigtable's ColumnFamily-based data model.
/*
* 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
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* KIND, either express or implied. See the License for the
* specific language governing permissions and limitations
* under the License.
*/
package org.apache.cassandra.db.commitlog;
import java.io.File;
import java.io.IOException;
import java.util.*;
import java.util.concurrent.Future;
import java.util.concurrent.atomic.AtomicInteger;
import com.google.common.annotations.VisibleForTesting;
import com.google.common.base.Predicate;
import com.google.common.collect.HashMultimap;
import com.google.common.collect.Iterables;
import com.google.common.collect.Multimap;
import com.google.common.collect.Ordering;
import org.apache.commons.lang3.StringUtils;
import org.cliffc.high_scale_lib.NonBlockingHashSet;
import org.slf4j.Logger;
import org.slf4j.LoggerFactory;
import org.apache.cassandra.concurrent.Stage;
import org.apache.cassandra.config.Config;
import org.apache.cassandra.config.DatabaseDescriptor;
import org.apache.cassandra.db.ColumnFamilyStore;
import org.apache.cassandra.db.Keyspace;
import org.apache.cassandra.db.Mutation;
import org.apache.cassandra.db.SystemKeyspace;
import org.apache.cassandra.db.partitions.PartitionUpdate;
import org.apache.cassandra.io.sstable.format.SSTableReader;
import org.apache.cassandra.io.util.FileUtils;
import org.apache.cassandra.io.util.RandomAccessReader;
import org.apache.cassandra.schema.Schema;
import org.apache.cassandra.schema.SchemaConstants;
import org.apache.cassandra.schema.TableId;
import org.apache.cassandra.schema.TableMetadataRef;
import org.apache.cassandra.service.StorageService;
import org.apache.cassandra.utils.FBUtilities;
import org.apache.cassandra.utils.WrappedRunnable;
public class CommitLogReplayer implements CommitLogReadHandler
{
@VisibleForTesting
public static long MAX_OUTSTANDING_REPLAY_BYTES = Long.getLong("cassandra.commitlog_max_outstanding_replay_bytes", 1024 * 1024 * 64);
@VisibleForTesting
public static MutationInitiator mutationInitiator = new MutationInitiator();
static final String IGNORE_REPLAY_ERRORS_PROPERTY = Config.PROPERTY_PREFIX + "commitlog.ignorereplayerrors";
private static final Logger logger = LoggerFactory.getLogger(CommitLogReplayer.class);
private static final int MAX_OUTSTANDING_REPLAY_COUNT = Integer.getInteger(Config.PROPERTY_PREFIX + "commitlog_max_outstanding_replay_count", 1024);
private final Set keyspacesReplayed;
private final Queue> futures;
private final AtomicInteger replayedCount;
private final Map> cfPersisted;
private final CommitLogPosition globalPosition;
// Used to throttle speed of replay of mutations if we pass the max outstanding count
private long pendingMutationBytes = 0;
private final ReplayFilter replayFilter;
private final CommitLogArchiver archiver;
@VisibleForTesting
protected boolean sawCDCMutation;
@VisibleForTesting
protected CommitLogReader commitLogReader;
CommitLogReplayer(CommitLog commitLog,
CommitLogPosition globalPosition,
Map> cfPersisted,
ReplayFilter replayFilter)
{
this.keyspacesReplayed = new NonBlockingHashSet<>();
this.futures = new ArrayDeque<>();
// count the number of replayed mutation. We don't really care about atomicity, but we need it to be a reference.
this.replayedCount = new AtomicInteger();
this.cfPersisted = cfPersisted;
this.globalPosition = globalPosition;
this.replayFilter = replayFilter;
this.archiver = commitLog.archiver;
this.commitLogReader = new CommitLogReader();
}
public static CommitLogReplayer construct(CommitLog commitLog, UUID localHostId)
{
// compute per-CF and global replay intervals
Map> cfPersisted = new HashMap<>();
ReplayFilter replayFilter = ReplayFilter.create();
for (ColumnFamilyStore cfs : ColumnFamilyStore.all())
{
// but, if we've truncated the cf in question, then we need to need to start replay after the truncation
CommitLogPosition truncatedAt = SystemKeyspace.getTruncatedPosition(cfs.metadata.id);
if (truncatedAt != null)
{
// Point in time restore is taken to mean that the tables need to be replayed even if they were
// deleted at a later point in time. Any truncation record after that point must thus be cleared prior
// to replay (CASSANDRA-9195).
long restoreTime = commitLog.archiver.restorePointInTime;
long truncatedTime = SystemKeyspace.getTruncatedAt(cfs.metadata.id);
if (truncatedTime > restoreTime)
{
if (replayFilter.includes(cfs.metadata))
{
logger.info("Restore point in time is before latest truncation of table {}.{}. Clearing truncation record.",
cfs.metadata.keyspace,
cfs.metadata.name);
SystemKeyspace.removeTruncationRecord(cfs.metadata.id);
truncatedAt = null;
}
}
}
IntervalSet filter = persistedIntervals(cfs.getLiveSSTables(), truncatedAt, localHostId);
cfPersisted.put(cfs.metadata.id, filter);
}
CommitLogPosition globalPosition = firstNotCovered(cfPersisted.values());
logger.debug("Global replay position is {} from columnfamilies {}", globalPosition, FBUtilities.toString(cfPersisted));
return new CommitLogReplayer(commitLog, globalPosition, cfPersisted, replayFilter);
}
public void replayPath(File file, boolean tolerateTruncation) throws IOException
{
sawCDCMutation = false;
commitLogReader.readCommitLogSegment(this, file, globalPosition, CommitLogReader.ALL_MUTATIONS, tolerateTruncation);
if (sawCDCMutation)
handleCDCReplayCompletion(file);
}
public void replayFiles(File[] clogs) throws IOException
{
List filteredLogs = CommitLogReader.filterCommitLogFiles(clogs);
int i = 0;
for (File file: filteredLogs)
{
i++;
sawCDCMutation = false;
commitLogReader.readCommitLogSegment(this, file, globalPosition, i == filteredLogs.size());
if (sawCDCMutation)
handleCDCReplayCompletion(file);
}
}
/**
* Upon replay completion, CDC needs to hard-link files in the CDC folder and calculate index files so consumers can
* begin their work.
*/
private void handleCDCReplayCompletion(File f) throws IOException
{
// Can only reach this point if CDC is enabled, thus we have a CDCSegmentManager
((CommitLogSegmentManagerCDC)CommitLog.instance.segmentManager).addCDCSize(f.length());
File dest = new File(DatabaseDescriptor.getCDCLogLocation(), f.getName());
// If hard link already exists, assume it's from a previous node run. If people are mucking around in the cdc_raw
// directory that's on them.
if (!dest.exists())
FileUtils.createHardLink(f, dest);
// The reader has already verified we can deserialize the descriptor.
CommitLogDescriptor desc;
try(RandomAccessReader reader = RandomAccessReader.open(f))
{
desc = CommitLogDescriptor.readHeader(reader, DatabaseDescriptor.getEncryptionContext());
assert desc != null;
assert f.length() < Integer.MAX_VALUE;
CommitLogSegment.writeCDCIndexFile(desc, (int)f.length(), true);
}
}
/**
* Flushes all keyspaces associated with this replayer in parallel, blocking until their flushes are complete.
* @return the number of mutations replayed
*/
public int blockForWrites()
{
for (Map.Entry entry : commitLogReader.getInvalidMutations())
logger.warn("Skipped {} mutations from unknown (probably removed) CF with id {}", entry.getValue(), entry.getKey());
// wait for all the writes to finish on the mutation stage
FBUtilities.waitOnFutures(futures);
logger.trace("Finished waiting on mutations from recovery");
// flush replayed keyspaces
futures.clear();
boolean flushingSystem = false;
List> futures = new ArrayList>();
for (Keyspace keyspace : keyspacesReplayed)
{
if (keyspace.getName().equals(SchemaConstants.SYSTEM_KEYSPACE_NAME))
flushingSystem = true;
futures.addAll(keyspace.flush());
}
// also flush batchlog incase of any MV updates
if (!flushingSystem)
futures.add(Keyspace.open(SchemaConstants.SYSTEM_KEYSPACE_NAME).getColumnFamilyStore(SystemKeyspace.BATCHES).forceFlush());
FBUtilities.waitOnFutures(futures);
return replayedCount.get();
}
/*
* Wrapper around initiating mutations read from the log to make it possible
* to spy on initiated mutations for test
*/
@VisibleForTesting
public static class MutationInitiator
{
protected Future initiateMutation(final Mutation mutation,
final long segmentId,
final int serializedSize,
final int entryLocation,
final CommitLogReplayer commitLogReplayer)
{
Runnable runnable = new WrappedRunnable()
{
public void runMayThrow()
{
if (Schema.instance.getKeyspaceMetadata(mutation.getKeyspaceName()) == null)
return;
if (commitLogReplayer.pointInTimeExceeded(mutation))
return;
final Keyspace keyspace = Keyspace.open(mutation.getKeyspaceName());
// Rebuild the mutation, omitting column families that
// a) the user has requested that we ignore,
// b) have already been flushed,
// or c) are part of a cf that was dropped.
// Keep in mind that the cf.name() is suspect. do every thing based on the cfid instead.
Mutation.PartitionUpdateCollector newPUCollector = null;
for (PartitionUpdate update : commitLogReplayer.replayFilter.filter(mutation))
{
if (Schema.instance.getTableMetadata(update.metadata().id) == null)
continue; // dropped
// replay if current segment is newer than last flushed one or,
// if it is the last known segment, if we are after the commit log segment position
if (commitLogReplayer.shouldReplay(update.metadata().id, new CommitLogPosition(segmentId, entryLocation)))
{
if (newPUCollector == null)
newPUCollector = new Mutation.PartitionUpdateCollector(mutation.getKeyspaceName(), mutation.key());
newPUCollector.add(update);
commitLogReplayer.replayedCount.incrementAndGet();
}
}
if (newPUCollector != null)
{
assert !newPUCollector.isEmpty();
Keyspace.open(newPUCollector.getKeyspaceName()).apply(newPUCollector.build(), false, true, false);
commitLogReplayer.keyspacesReplayed.add(keyspace);
}
}
};
return Stage.MUTATION.submit(runnable, serializedSize);
}
}
/**
* A set of known safe-to-discard commit log replay positions, based on
* the range covered by on disk sstables and those prior to the most recent truncation record
*/
public static IntervalSet persistedIntervals(Iterable onDisk,
CommitLogPosition truncatedAt,
UUID localhostId)
{
IntervalSet.Builder builder = new IntervalSet.Builder<>();
List skippedSSTables = new ArrayList<>();
for (SSTableReader reader : onDisk)
{
UUID originatingHostId = reader.getSSTableMetadata().originatingHostId;
if (originatingHostId != null && originatingHostId.equals(localhostId))
builder.addAll(reader.getSSTableMetadata().commitLogIntervals);
else
skippedSSTables.add(reader.getFilename());
}
if (!skippedSSTables.isEmpty()) {
logger.warn("Origin of {} sstables is unknown or doesn't match the local node; commitLogIntervals for them were ignored", skippedSSTables.size());
logger.debug("Ignored commitLogIntervals from the following sstables: {}", skippedSSTables);
}
if (truncatedAt != null)
builder.add(CommitLogPosition.NONE, truncatedAt);
return builder.build();
}
/**
* Find the earliest commit log position that is not covered by the known flushed ranges for some table.
*
* For efficiency this assumes that the first contiguously flushed interval we know of contains the moment that the
* given table was constructed* and hence we can start replay from the end of that interval.
*
* If such an interval is not known, we must replay from the beginning.
*
* * This is not true only until if the very first flush of a table stalled or failed, while the second or latter
* succeeded. The chances of this happening are at most very low, and if the assumption does prove to be
* incorrect during replay there is little chance that the affected deployment is in production.
*/
public static CommitLogPosition firstNotCovered(Collection> ranges)
{
return ranges.stream()
.map(intervals -> Iterables.getFirst(intervals.ends(), CommitLogPosition.NONE))
.min(Ordering.natural())
.get(); // iteration is per known-CF, there must be at least one.
}
abstract static class ReplayFilter
{
public abstract Iterable filter(Mutation mutation);
public abstract boolean includes(TableMetadataRef metadata);
public static ReplayFilter create()
{
// If no replaylist is supplied an empty array of strings is used to replay everything.
if (System.getProperty("cassandra.replayList") == null)
return new AlwaysReplayFilter();
Multimap toReplay = HashMultimap.create();
for (String rawPair : System.getProperty("cassandra.replayList").split(","))
{
String[] pair = StringUtils.split(rawPair.trim(), '.');
if (pair.length != 2)
throw new IllegalArgumentException("Each table to be replayed must be fully qualified with keyspace name, e.g., 'system.peers'");
Keyspace ks = Schema.instance.getKeyspaceInstance(pair[0]);
if (ks == null)
throw new IllegalArgumentException("Unknown keyspace " + pair[0]);
ColumnFamilyStore cfs = ks.getColumnFamilyStore(pair[1]);
if (cfs == null)
throw new IllegalArgumentException(String.format("Unknown table %s.%s", pair[0], pair[1]));
toReplay.put(pair[0], pair[1]);
}
return new CustomReplayFilter(toReplay);
}
}
private static class AlwaysReplayFilter extends ReplayFilter
{
public Iterable filter(Mutation mutation)
{
return mutation.getPartitionUpdates();
}
public boolean includes(TableMetadataRef metadata)
{
return true;
}
}
private static class CustomReplayFilter extends ReplayFilter
{
private Multimap toReplay;
public CustomReplayFilter(Multimap toReplay)
{
this.toReplay = toReplay;
}
public Iterable filter(Mutation mutation)
{
final Collection cfNames = toReplay.get(mutation.getKeyspaceName());
if (cfNames == null)
return Collections.emptySet();
return Iterables.filter(mutation.getPartitionUpdates(), new Predicate()
{
public boolean apply(PartitionUpdate upd)
{
return cfNames.contains(upd.metadata().name);
}
});
}
public boolean includes(TableMetadataRef metadata)
{
return toReplay.containsEntry(metadata.keyspace, metadata.name);
}
}
/**
* consult the known-persisted ranges for our sstables;
* if the position is covered by one of them it does not need to be replayed
*
* @return true iff replay is necessary
*/
private boolean shouldReplay(TableId tableId, CommitLogPosition position)
{
return !cfPersisted.get(tableId).contains(position);
}
protected boolean pointInTimeExceeded(Mutation fm)
{
long restoreTarget = archiver.restorePointInTime;
for (PartitionUpdate upd : fm.getPartitionUpdates())
{
if (archiver.precision.toMillis(upd.maxTimestamp()) > restoreTarget)
return true;
}
return false;
}
public void handleMutation(Mutation m, int size, int entryLocation, CommitLogDescriptor desc)
{
if (DatabaseDescriptor.isCDCEnabled() && m.trackedByCDC())
sawCDCMutation = true;
pendingMutationBytes += size;
futures.offer(mutationInitiator.initiateMutation(m,
desc.id,
size,
entryLocation,
this));
// If there are finished mutations, or too many outstanding bytes/mutations
// drain the futures in the queue
while (futures.size() > MAX_OUTSTANDING_REPLAY_COUNT
|| pendingMutationBytes > MAX_OUTSTANDING_REPLAY_BYTES
|| (!futures.isEmpty() && futures.peek().isDone()))
{
pendingMutationBytes -= FBUtilities.waitOnFuture(futures.poll());
}
}
public boolean shouldSkipSegmentOnError(CommitLogReadException exception) throws IOException
{
if (exception.permissible)
logger.error("Ignoring commit log replay error likely due to incomplete flush to disk", exception);
else if (Boolean.getBoolean(IGNORE_REPLAY_ERRORS_PROPERTY))
logger.error("Ignoring commit log replay error", exception);
else if (!CommitLog.handleCommitError("Failed commit log replay", exception))
{
logger.error("Replay stopped. If you wish to override this error and continue starting the node ignoring " +
"commit log replay problems, specify -D" + IGNORE_REPLAY_ERRORS_PROPERTY + "=true " +
"on the command line");
throw new CommitLogReplayException(exception.getMessage(), exception);
}
return false;
}
/**
* The logic for whether or not we throw on an error is identical for the replayer between recoverable or non.
*/
public void handleUnrecoverableError(CommitLogReadException exception) throws IOException
{
// Don't care about return value, use this simply to throw exception as appropriate.
shouldSkipSegmentOnError(exception);
}
@SuppressWarnings("serial")
public static class CommitLogReplayException extends IOException
{
public CommitLogReplayException(String message, Throwable cause)
{
super(message, cause);
}
public CommitLogReplayException(String message)
{
super(message);
}
}
}