Java tutorial
/* * Copyright 2015 Cask Data, Inc. * * Licensed 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 co.cask.cdap.template.etl.realtime.kafka; import co.cask.cdap.api.common.Bytes; import co.cask.cdap.api.data.format.StructuredRecord; import co.cask.cdap.template.etl.api.Emitter; import co.cask.cdap.template.etl.api.realtime.RealtimeContext; import co.cask.cdap.template.etl.api.realtime.SourceState; import co.cask.cdap.template.etl.realtime.source.KafkaSource; import com.google.common.base.Charsets; import com.google.common.base.Function; import com.google.common.base.Preconditions; import com.google.common.collect.ImmutableMap; import com.google.common.collect.Maps; import com.google.common.reflect.TypeToken; import com.google.common.util.concurrent.Service; import org.apache.twill.kafka.client.TopicPartition; import org.slf4j.Logger; import org.slf4j.LoggerFactory; import java.lang.reflect.GenericArrayType; import java.lang.reflect.ParameterizedType; import java.lang.reflect.Type; import java.nio.ByteBuffer; import java.util.Iterator; import java.util.Map; import javax.annotation.Nullable; /** * <p> * Wrapper class for {@code Apache Kafka} consumer using the simple APIs to manage the last offset for a particular * partition of a topic. * * Most of the code are borrowed from the {@code cdap-kafka-pack} project and modified to be suit the stream source. * </p> * * @param <KEY> Type of message key * @param <PAYLOAD> Type of message value * @param <OFFSET> Type of offset object */ public abstract class KafkaSimpleApiConsumer<KEY, PAYLOAD, OFFSET> { private static final Logger LOG = LoggerFactory.getLogger(KafkaSimpleApiConsumer.class); protected static final int SO_TIMEOUT = 5 * 1000; // 5 seconds. protected final KafkaSource kafkaSource; private final Function<KafkaConsumerInfo<OFFSET>, OFFSET> consumerToOffset = new Function<KafkaConsumerInfo<OFFSET>, OFFSET>() { @Override public OFFSET apply(KafkaConsumerInfo<OFFSET> input) { return input.getReadOffset(); } }; private Function<ByteBuffer, KEY> keyDecoder; private Function<ByteBuffer, PAYLOAD> payloadDecoder; private KafkaConfig kafkaConfig; private Map<String, byte[]> offsetStore; private RealtimeContext sourceContext; private DefaultKafkaConfigurer kafkaConfigurer; private volatile Map<TopicPartition, KafkaConsumerInfo<OFFSET>> consumerInfos; protected KafkaSimpleApiConsumer(KafkaSource kafkaSource) { this.kafkaSource = kafkaSource; } /** * <p> * The method should be called to initialized the consumer when being used by the {@code RealtimeSource} * </p> * * @param context * @throws Exception */ public void initialize(RealtimeContext context) throws Exception { sourceContext = context; // Tries to detect key and payload decoder based on the class parameterized type. Type superType = TypeToken.of(getClass()).getSupertype(KafkaSimpleApiConsumer.class).getType(); // Tries to detect Key and Payload type for creating decoder for them if (superType instanceof ParameterizedType) { // Extract Key and Payload types Type[] typeArgs = ((ParameterizedType) superType).getActualTypeArguments(); keyDecoder = createKeyDecoder(typeArgs[0]); payloadDecoder = createPayloadDecoder(typeArgs[1]); } // Configure kafka kafkaConfigurer = new DefaultKafkaConfigurer(); configureKafka(kafkaConfigurer); if (kafkaConfigurer.getZookeeper() == null && kafkaConfigurer.getBrokers() == null) { throw new IllegalStateException("Kafka not configured. Must provide either zookeeper or broker list."); } kafkaConfig = new KafkaConfig(kafkaConfigurer.getZookeeper(), kafkaConfigurer.getBrokers()); } /** * Return the {@link RealtimeContext} for this Kafka source. * * @return instance of {@link RealtimeContext} */ RealtimeContext getContext() { return sourceContext; } /** * * @return the name of this Kafka realtime source. Default would be the simple class name. */ public String getName() { return getClass().getSimpleName(); } /** * @return the internal state of topic partitions offset */ public Map<String, byte[]> getSavedState() { return Maps.newHashMap(offsetStore); } /** * Set the internal state for the Topic partition. */ public void saveState(SourceState currentState) { // Update the internal state offsetStore = currentState.getState(); } /** * Will be called by external source to start poll the Kafka messages one at the time. * * @param emitter instance of {@link Emitter} to emit the messages. */ public void pollMessages(Emitter<StructuredRecord> emitter) { // Configure consumers late to read from Adapter SourceState if (consumerInfos == null) { consumerInfos = createConsumerInfos(kafkaConfigurer.getTopicPartitions()); } boolean infosUpdated = false; // Poll for messages from Kafka for (KafkaConsumerInfo<OFFSET> info : consumerInfos.values()) { Iterator<KafkaMessage<OFFSET>> iterator = readMessages(info); while (iterator.hasNext()) { KafkaMessage<OFFSET> message = iterator.next(); processMessage(message, emitter); // Update the read offset info.setReadOffset(message.getNextOffset()); } if (info.hasPendingChanges()) { infosUpdated = true; } } // Save new offset if there is at least one message processed, or even if the offset simply changed. if (infosUpdated) { saveReadOffsets(Maps.transformValues(consumerInfos, consumerToOffset)); } } /** * Configure Kafka consumer. This method will be called during the initialize phase * * @param configurer for configuring consuming from Kafka */ protected abstract void configureKafka(KafkaConfigurer configurer); /** * Read messages from Kafka. * * @param consumerInfo Contains information about where to fetch messages from * @return An {@link Iterator} containing sequence of messages read from Kafka. The first message must * has offset no earlier than the {@link KafkaConsumerInfo#getReadOffset()} as given in the parameter. */ protected abstract Iterator<KafkaMessage<OFFSET>> readMessages(KafkaConsumerInfo<OFFSET> consumerInfo); /** * Returns the read offsets to start with for the given {@link TopicPartition}. */ protected abstract OFFSET getBeginOffset(TopicPartition topicPartition); /** * Persists read offsets for all topic-partition that this Flowlet consumes from Kafka. */ protected abstract void saveReadOffsets(Map<TopicPartition, OFFSET> offsets); /** * Should be called for clean up. */ public void destroy() { // no-op } /** * Returns a Kafka configuration. */ protected final KafkaConfig getKafkaConfig() { return kafkaConfig; } /** * Overrides this method if interested in the raw Kafka message. * * @param message The message fetched from Kafka. * @param emitter The emitter to push the message */ protected void processMessage(KafkaMessage<OFFSET> message, Emitter<StructuredRecord> emitter) { // Should only receive messages from partitions that it can process int partition = message.getTopicPartition().getPartition(); Preconditions.checkArgument((partition % getContext().getInstanceCount()) == getContext().getInstanceId(), "Received unexpected partition " + partition); if (message.getKey() == null) { processMessage(decodePayload(message.getPayload()), emitter); } else { processMessage(decodeKey(message.getKey()), decodePayload(message.getPayload()), emitter); } } /** * Override this method if interested in both the key and payload of a message read from Kafka. * * @param key Key decoded from the message * @param payload Payload decoded from the message * @param emitter The emitter to push the message */ protected void processMessage(KEY key, PAYLOAD payload, Emitter<StructuredRecord> emitter) { processMessage(payload, emitter); } /** * Override this method if only interested in the payload of a message read from Kafka. * * @param payload Payload decoded from the message * @param emitter The emitter to push the message */ protected abstract void processMessage(PAYLOAD payload, Emitter<StructuredRecord> emitter); /** * Returns the default value of offset to start with when encounter a new broker for a given topic partition. * <p/> * By default, it is {@link kafka.api.OffsetRequest#EarliestTime()}. Sub-classes can override this to return * different value (for example {@link kafka.api.OffsetRequest#LatestTime()}). */ protected abstract long getDefaultOffset(TopicPartition topicPartition); /** * Override this method to provide custom decoding of a message key. * * @param buffer The bytes representing the key in the Kafka message * @return The decoded key */ @Nullable protected KEY decodeKey(ByteBuffer buffer) { return (keyDecoder != null) ? keyDecoder.apply(buffer) : null; } /** * Override this method to provide custom decoding of a message payload. * * @param buffer The bytes representing the payload in the Kafka message * @return The decoded payload */ @Nullable protected PAYLOAD decodePayload(ByteBuffer buffer) { return (payloadDecoder != null) ? payloadDecoder.apply(buffer) : null; } /** * Stops a {@link Service} and waits for the completion. If there is exception during stop, it will get logged. */ protected final void stopService(Service service) { try { service.stopAndWait(); } catch (Throwable t) { LOG.error("Failed when stopping service {}", service, t); } } /** * Returns the key to be used when persisting offsets into the {@link SourceState}. */ protected String getStoreKey(TopicPartition topicPartition) { return topicPartition.getTopic() + ":" + topicPartition.getPartition(); } protected Map<String, byte[]> getOffsetStore() { return offsetStore; } protected StructuredRecord byteBufferToStructuredRecord(@Nullable String key, ByteBuffer payload) { return kafkaSource.byteBufferToStructuredRecord(key, payload); } /** * Creates a decoder for the key type. * * @param type type to decode to */ private Function<ByteBuffer, KEY> createKeyDecoder(Type type) { return createDecoder(type, "No decoder for decoding message key"); } /** * Creates a decoder for the payload type. * * @param type type to decode to */ private Function<ByteBuffer, PAYLOAD> createPayloadDecoder(Type type) { return createDecoder(type, "No decoder for decoding message payload"); } /** * Creates a decoder for decoding {@link ByteBuffer} for known type. It supports * <p/> * <pre> * - String (assuming UTF-8) * - byte[] * - ByteBuffer * </pre> * * @param type type to decode to * @param failureDecodeMessage message for the exception if decoding of the given type is not supported * @param <T> Type of the decoded type * @return A {@link Function} that decode {@link ByteBuffer} into the given type or a failure decoder created through * {@link #createFailureDecoder(String)} if the type is not support */ @SuppressWarnings("unchecked") private <T> Function<ByteBuffer, T> createDecoder(Type type, String failureDecodeMessage) { if (String.class.equals(type)) { return (Function<ByteBuffer, T>) createStringDecoder(); } if (ByteBuffer.class.equals(type)) { return (Function<ByteBuffer, T>) createByteBufferDecoder(); } if (byte[].class.equals(type) || (type instanceof GenericArrayType && byte.class.equals(((GenericArrayType) type).getGenericComponentType()))) { return (Function<ByteBuffer, T>) createBytesDecoder(); } return createFailureDecoder(failureDecodeMessage); } /** * Creates a decoder that convert the input {@link ByteBuffer} into UTF-8 String. The input {@link ByteBuffer} * will not be consumed after the call. */ private Function<ByteBuffer, String> createStringDecoder() { return new Function<ByteBuffer, String>() { @Override public String apply(ByteBuffer input) { input.mark(); String result = Bytes.toString(input, Charsets.UTF_8); input.reset(); return result; } }; } /** * Creates a decoder that returns the same input {@link ByteBuffer}. */ private Function<ByteBuffer, ByteBuffer> createByteBufferDecoder() { return new Function<ByteBuffer, ByteBuffer>() { @Override public ByteBuffer apply(ByteBuffer input) { return input; } }; } /** * Creates a decoder that reads {@link ByteBuffer} content and return it as {@code byte[]}. The * input {@link ByteBuffer} will not be consumed after the call. */ private Function<ByteBuffer, byte[]> createBytesDecoder() { return new Function<ByteBuffer, byte[]>() { @Override public byte[] apply(ByteBuffer input) { byte[] bytes = new byte[input.remaining()]; input.mark(); input.get(bytes); input.reset(); return bytes; } }; } /** * Creates a decoder that always decode fail by raising an {@link IllegalStateException}. */ private <T> Function<ByteBuffer, T> createFailureDecoder(final String failureMessage) { return new Function<ByteBuffer, T>() { @Override public T apply(ByteBuffer input) { throw new IllegalStateException(failureMessage); } }; } /** * Helper method to create new {@link KafkaConsumerInfo} for map of topic partitions. * * @param config * @return KafkaConsumerInfo mapped to TopicPartitions */ private Map<TopicPartition, KafkaConsumerInfo<OFFSET>> createConsumerInfos( Map<TopicPartition, Integer> config) { ImmutableMap.Builder<TopicPartition, KafkaConsumerInfo<OFFSET>> consumers = ImmutableMap.builder(); for (Map.Entry<TopicPartition, Integer> entry : config.entrySet()) { consumers.put(entry.getKey(), new KafkaConsumerInfo<>(entry.getKey(), entry.getValue(), getBeginOffset(entry.getKey()))); } return consumers.build(); } }