use of io.druid.segment.realtime.appenderator.FiniteAppenderatorDriver in project druid by druid-io.
the class KafkaIndexTask method run.
@Override
public TaskStatus run(final TaskToolbox toolbox) throws Exception {
log.info("Starting up!");
startTime = DateTime.now();
mapper = toolbox.getObjectMapper();
status = Status.STARTING;
if (chatHandlerProvider.isPresent()) {
log.info("Found chat handler of class[%s]", chatHandlerProvider.get().getClass().getName());
chatHandlerProvider.get().register(getId(), this, false);
} else {
log.warn("No chat handler detected");
}
runThread = Thread.currentThread();
// Set up FireDepartmentMetrics
final FireDepartment fireDepartmentForMetrics = new FireDepartment(dataSchema, new RealtimeIOConfig(null, null, null), null);
fireDepartmentMetrics = fireDepartmentForMetrics.getMetrics();
toolbox.getMonitorScheduler().addMonitor(new RealtimeMetricsMonitor(ImmutableList.of(fireDepartmentForMetrics), ImmutableMap.of(DruidMetrics.TASK_ID, new String[] { getId() })));
try (final Appenderator appenderator0 = newAppenderator(fireDepartmentMetrics, toolbox);
final FiniteAppenderatorDriver driver = newDriver(appenderator0, toolbox, fireDepartmentMetrics);
final KafkaConsumer<byte[], byte[]> consumer = newConsumer()) {
appenderator = appenderator0;
final String topic = ioConfig.getStartPartitions().getTopic();
// Start up, set up initial offsets.
final Object restoredMetadata = driver.startJob();
if (restoredMetadata == null) {
nextOffsets.putAll(ioConfig.getStartPartitions().getPartitionOffsetMap());
} else {
final Map<String, Object> restoredMetadataMap = (Map) restoredMetadata;
final KafkaPartitions restoredNextPartitions = toolbox.getObjectMapper().convertValue(restoredMetadataMap.get(METADATA_NEXT_PARTITIONS), KafkaPartitions.class);
nextOffsets.putAll(restoredNextPartitions.getPartitionOffsetMap());
// Sanity checks.
if (!restoredNextPartitions.getTopic().equals(ioConfig.getStartPartitions().getTopic())) {
throw new ISE("WTF?! Restored topic[%s] but expected topic[%s]", restoredNextPartitions.getTopic(), ioConfig.getStartPartitions().getTopic());
}
if (!nextOffsets.keySet().equals(ioConfig.getStartPartitions().getPartitionOffsetMap().keySet())) {
throw new ISE("WTF?! Restored partitions[%s] but expected partitions[%s]", nextOffsets.keySet(), ioConfig.getStartPartitions().getPartitionOffsetMap().keySet());
}
}
// Set up sequenceNames.
final Map<Integer, String> sequenceNames = Maps.newHashMap();
for (Integer partitionNum : nextOffsets.keySet()) {
sequenceNames.put(partitionNum, String.format("%s_%s", ioConfig.getBaseSequenceName(), partitionNum));
}
// Set up committer.
final Supplier<Committer> committerSupplier = new Supplier<Committer>() {
@Override
public Committer get() {
final Map<Integer, Long> snapshot = ImmutableMap.copyOf(nextOffsets);
return new Committer() {
@Override
public Object getMetadata() {
return ImmutableMap.of(METADATA_NEXT_PARTITIONS, new KafkaPartitions(ioConfig.getStartPartitions().getTopic(), snapshot));
}
@Override
public void run() {
// Do nothing.
}
};
}
};
Set<Integer> assignment = assignPartitionsAndSeekToNext(consumer, topic);
// Main loop.
// Could eventually support leader/follower mode (for keeping replicas more in sync)
boolean stillReading = !assignment.isEmpty();
status = Status.READING;
try {
while (stillReading) {
if (possiblyPause(assignment)) {
// The partition assignments may have changed while paused by a call to setEndOffsets() so reassign
// partitions upon resuming. This is safe even if the end offsets have not been modified.
assignment = assignPartitionsAndSeekToNext(consumer, topic);
if (assignment.isEmpty()) {
log.info("All partitions have been fully read");
publishOnStop = true;
stopRequested = true;
}
}
if (stopRequested) {
break;
}
// The retrying business is because the KafkaConsumer throws OffsetOutOfRangeException if the seeked-to
// offset is not present in the topic-partition. This can happen if we're asking a task to read from data
// that has not been written yet (which is totally legitimate). So let's wait for it to show up.
ConsumerRecords<byte[], byte[]> records = ConsumerRecords.empty();
try {
records = consumer.poll(POLL_TIMEOUT);
} catch (OffsetOutOfRangeException e) {
log.warn("OffsetOutOfRangeException with message [%s]", e.getMessage());
possiblyResetOffsetsOrWait(e.offsetOutOfRangePartitions(), consumer, toolbox);
stillReading = ioConfig.isPauseAfterRead() || !assignment.isEmpty();
}
for (ConsumerRecord<byte[], byte[]> record : records) {
if (log.isTraceEnabled()) {
log.trace("Got topic[%s] partition[%d] offset[%,d].", record.topic(), record.partition(), record.offset());
}
if (record.offset() < endOffsets.get(record.partition())) {
if (record.offset() != nextOffsets.get(record.partition())) {
throw new ISE("WTF?! Got offset[%,d] after offset[%,d] in partition[%d].", record.offset(), nextOffsets.get(record.partition()), record.partition());
}
try {
final byte[] valueBytes = record.value();
if (valueBytes == null) {
throw new ParseException("null value");
}
final InputRow row = Preconditions.checkNotNull(parser.parse(ByteBuffer.wrap(valueBytes)), "row");
if (!ioConfig.getMinimumMessageTime().isPresent() || !ioConfig.getMinimumMessageTime().get().isAfter(row.getTimestamp())) {
final SegmentIdentifier identifier = driver.add(row, sequenceNames.get(record.partition()), committerSupplier);
if (identifier == null) {
// If we allow continuing, then consider blacklisting the interval for a while to avoid constant checks.
throw new ISE("Could not allocate segment for row with timestamp[%s]", row.getTimestamp());
}
fireDepartmentMetrics.incrementProcessed();
} else {
fireDepartmentMetrics.incrementThrownAway();
}
} catch (ParseException e) {
if (tuningConfig.isReportParseExceptions()) {
throw e;
} else {
log.debug(e, "Dropping unparseable row from partition[%d] offset[%,d].", record.partition(), record.offset());
fireDepartmentMetrics.incrementUnparseable();
}
}
nextOffsets.put(record.partition(), record.offset() + 1);
}
if (nextOffsets.get(record.partition()).equals(endOffsets.get(record.partition())) && assignment.remove(record.partition())) {
log.info("Finished reading topic[%s], partition[%,d].", record.topic(), record.partition());
assignPartitions(consumer, topic, assignment);
stillReading = ioConfig.isPauseAfterRead() || !assignment.isEmpty();
}
}
}
} finally {
// persist pending data
driver.persist(committerSupplier.get());
}
synchronized (statusLock) {
if (stopRequested && !publishOnStop) {
throw new InterruptedException("Stopping without publishing");
}
status = Status.PUBLISHING;
}
final TransactionalSegmentPublisher publisher = new TransactionalSegmentPublisher() {
@Override
public boolean publishSegments(Set<DataSegment> segments, Object commitMetadata) throws IOException {
final KafkaPartitions finalPartitions = toolbox.getObjectMapper().convertValue(((Map) commitMetadata).get(METADATA_NEXT_PARTITIONS), KafkaPartitions.class);
// Sanity check, we should only be publishing things that match our desired end state.
if (!endOffsets.equals(finalPartitions.getPartitionOffsetMap())) {
throw new ISE("WTF?! Driver attempted to publish invalid metadata[%s].", commitMetadata);
}
final SegmentTransactionalInsertAction action;
if (ioConfig.isUseTransaction()) {
action = new SegmentTransactionalInsertAction(segments, new KafkaDataSourceMetadata(ioConfig.getStartPartitions()), new KafkaDataSourceMetadata(finalPartitions));
} else {
action = new SegmentTransactionalInsertAction(segments, null, null);
}
log.info("Publishing with isTransaction[%s].", ioConfig.isUseTransaction());
return toolbox.getTaskActionClient().submit(action).isSuccess();
}
};
final SegmentsAndMetadata published = driver.finish(publisher, committerSupplier.get());
if (published == null) {
throw new ISE("Transaction failure publishing segments, aborting");
} else {
log.info("Published segments[%s] with metadata[%s].", Joiner.on(", ").join(Iterables.transform(published.getSegments(), new Function<DataSegment, String>() {
@Override
public String apply(DataSegment input) {
return input.getIdentifier();
}
})), published.getCommitMetadata());
}
} catch (InterruptedException | RejectedExecutionException e) {
// handle the InterruptedException that gets wrapped in a RejectedExecutionException
if (e instanceof RejectedExecutionException && (e.getCause() == null || !(e.getCause() instanceof InterruptedException))) {
throw e;
}
// if we were interrupted because we were asked to stop, handle the exception and return success, else rethrow
if (!stopRequested) {
Thread.currentThread().interrupt();
throw e;
}
log.info("The task was asked to stop before completing");
} finally {
if (chatHandlerProvider.isPresent()) {
chatHandlerProvider.get().unregister(getId());
}
}
return success();
}
use of io.druid.segment.realtime.appenderator.FiniteAppenderatorDriver in project druid by druid-io.
the class IndexTask method generateAndPublishSegments.
private boolean generateAndPublishSegments(final TaskToolbox toolbox, final DataSchema dataSchema, final Map<Interval, List<ShardSpec>> shardSpecs, final String version, final FirehoseFactory firehoseFactory) throws IOException, InterruptedException {
final GranularitySpec granularitySpec = dataSchema.getGranularitySpec();
final FireDepartment fireDepartmentForMetrics = new FireDepartment(dataSchema, new RealtimeIOConfig(null, null, null), null);
final FireDepartmentMetrics fireDepartmentMetrics = fireDepartmentForMetrics.getMetrics();
final Map<String, ShardSpec> sequenceNameToShardSpecMap = Maps.newHashMap();
if (toolbox.getMonitorScheduler() != null) {
toolbox.getMonitorScheduler().addMonitor(new RealtimeMetricsMonitor(ImmutableList.of(fireDepartmentForMetrics), ImmutableMap.of(DruidMetrics.TASK_ID, new String[] { getId() })));
}
final SegmentAllocator segmentAllocator;
if (ingestionSchema.getIOConfig().isAppendToExisting()) {
segmentAllocator = new ActionBasedSegmentAllocator(toolbox.getTaskActionClient(), dataSchema);
} else {
segmentAllocator = new SegmentAllocator() {
@Override
public SegmentIdentifier allocate(DateTime timestamp, String sequenceName, String previousSegmentId) throws IOException {
Optional<Interval> interval = granularitySpec.bucketInterval(timestamp);
if (!interval.isPresent()) {
throw new ISE("Could not find interval for timestamp [%s]", timestamp);
}
ShardSpec shardSpec = sequenceNameToShardSpecMap.get(sequenceName);
if (shardSpec == null) {
throw new ISE("Could not find ShardSpec for sequenceName [%s]", sequenceName);
}
return new SegmentIdentifier(getDataSource(), interval.get(), version, shardSpec);
}
};
}
try (final Appenderator appenderator = newAppenderator(fireDepartmentMetrics, toolbox, dataSchema);
final FiniteAppenderatorDriver driver = newDriver(appenderator, toolbox, segmentAllocator, fireDepartmentMetrics);
final Firehose firehose = firehoseFactory.connect(dataSchema.getParser())) {
final Supplier<Committer> committerSupplier = Committers.supplierFromFirehose(firehose);
final Map<Interval, ShardSpecLookup> shardSpecLookups = Maps.newHashMap();
if (driver.startJob() != null) {
driver.clear();
}
try {
while (firehose.hasMore()) {
try {
final InputRow inputRow = firehose.nextRow();
final Optional<Interval> optInterval = granularitySpec.bucketInterval(inputRow.getTimestamp());
if (!optInterval.isPresent()) {
fireDepartmentMetrics.incrementThrownAway();
continue;
}
final Interval interval = optInterval.get();
if (!shardSpecLookups.containsKey(interval)) {
final List<ShardSpec> intervalShardSpecs = shardSpecs.get(interval);
if (intervalShardSpecs == null || intervalShardSpecs.isEmpty()) {
throw new ISE("Failed to get shardSpec for interval[%s]", interval);
}
shardSpecLookups.put(interval, intervalShardSpecs.get(0).getLookup(intervalShardSpecs));
}
final ShardSpec shardSpec = shardSpecLookups.get(interval).getShardSpec(inputRow.getTimestampFromEpoch(), inputRow);
final String sequenceName = String.format("index_%s_%s_%d", interval, version, shardSpec.getPartitionNum());
if (!sequenceNameToShardSpecMap.containsKey(sequenceName)) {
final ShardSpec shardSpecForPublishing = ingestionSchema.getTuningConfig().isForceExtendableShardSpecs() || ingestionSchema.getIOConfig().isAppendToExisting() ? new NumberedShardSpec(shardSpec.getPartitionNum(), shardSpecs.get(interval).size()) : shardSpec;
sequenceNameToShardSpecMap.put(sequenceName, shardSpecForPublishing);
}
final SegmentIdentifier identifier = driver.add(inputRow, sequenceName, committerSupplier);
if (identifier == null) {
throw new ISE("Could not allocate segment for row with timestamp[%s]", inputRow.getTimestamp());
}
fireDepartmentMetrics.incrementProcessed();
} catch (ParseException e) {
if (ingestionSchema.getTuningConfig().isReportParseExceptions()) {
throw e;
} else {
fireDepartmentMetrics.incrementUnparseable();
}
}
}
} finally {
driver.persist(committerSupplier.get());
}
final TransactionalSegmentPublisher publisher = new TransactionalSegmentPublisher() {
@Override
public boolean publishSegments(Set<DataSegment> segments, Object commitMetadata) throws IOException {
final SegmentTransactionalInsertAction action = new SegmentTransactionalInsertAction(segments, null, null);
return toolbox.getTaskActionClient().submit(action).isSuccess();
}
};
final SegmentsAndMetadata published = driver.finish(publisher, committerSupplier.get());
if (published == null) {
log.error("Failed to publish segments, aborting!");
return false;
} else {
log.info("Published segments[%s]", Joiner.on(", ").join(Iterables.transform(published.getSegments(), new Function<DataSegment, String>() {
@Override
public String apply(DataSegment input) {
return input.getIdentifier();
}
})));
return true;
}
}
}
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