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EventDeduplicationLambdaIntegrationTest.java
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EventDeduplicationLambdaIntegrationTest.java
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/*
* Copyright Confluent 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 io.confluent.examples.streams;
import org.apache.kafka.common.serialization.Serdes;
import org.apache.kafka.common.serialization.StringDeserializer;
import org.apache.kafka.common.serialization.StringSerializer;
import org.apache.kafka.streams.KeyValue;
import org.apache.kafka.streams.StreamsBuilder;
import org.apache.kafka.streams.StreamsConfig;
import org.apache.kafka.streams.TopologyTestDriver;
import org.apache.kafka.streams.kstream.KStream;
import org.apache.kafka.streams.kstream.KeyValueMapper;
import org.apache.kafka.streams.kstream.Transformer;
import org.apache.kafka.streams.processor.ProcessorContext;
import org.apache.kafka.streams.state.StoreBuilder;
import org.apache.kafka.streams.state.Stores;
import org.apache.kafka.streams.state.WindowStore;
import org.apache.kafka.streams.state.WindowStoreIterator;
import org.apache.kafka.test.TestUtils;
import org.junit.Test;
import java.time.Duration;
import java.util.Arrays;
import java.util.List;
import java.util.Properties;
import java.util.UUID;
import java.util.stream.Collectors;
import static org.assertj.core.api.Assertions.assertThat;
/**
* End-to-end integration test that demonstrates how to remove duplicate records from an input
* stream.
* <p>
* Here, a stateful {@link org.apache.kafka.streams.kstream.Transformer} (from the Processor API)
* detects and discards duplicate input records based on an "event id" that is embedded in each
* input record. This transformer is then included in a topology defined via the DSL.
* <p>
* In this simplified example, the values of input records represent the event ID by which
* duplicates will be detected. In practice, record values would typically be a more complex data
* structure, with perhaps one of the fields being such an event ID. De-duplication by an event ID
* is but one example of how to perform de-duplication in general. The code example below can be
* adapted to other de-duplication approaches.
* <p>
* IMPORTANT: Kafka including its Streams API support exactly-once semantics since version 0.11.
* With this feature available, most use cases will no longer need to worry about duplicate messages
* or duplicate processing. That said, there will still be some use cases where you have your own
* business rules that define when two events are considered to be "the same" and need to be
* de-duplicated (e.g. two events having the same payload but different timestamps). The example
* below demonstrates how to implement your own business rules for event de-duplication.
* <p>
* Note: This example uses lambda expressions and thus works with Java 8+ only.
*/
public class EventDeduplicationLambdaIntegrationTest {
private static final String storeName = "eventId-store";
/**
* Discards duplicate records from the input stream.
* <p>
* Duplicate records are detected based on an event ID; in this simplified example, the record
* value is the event ID. The transformer remembers known event IDs in an associated window state
* store, which automatically purges/expires event IDs from the store after a certain amount of
* time has passed to prevent the store from growing indefinitely.
* <p>
* Note: This code is for demonstration purposes and was not tested for production usage.
*/
private static class DeduplicationTransformer<K, V, E> implements Transformer<K, V, KeyValue<K, V>> {
private ProcessorContext context;
/**
* Key: event ID
* Value: timestamp (event-time) of the corresponding event when the event ID was seen for the
* first time
*/
private WindowStore<E, Long> eventIdStore;
private final long leftDurationMs;
private final long rightDurationMs;
private final KeyValueMapper<K, V, E> idExtractor;
/**
* @param maintainDurationPerEventInMs how long to "remember" a known event (or rather, an event
* ID), during the time of which any incoming duplicates of
* the event will be dropped, thereby de-duplicating the
* input.
* @param idExtractor extracts a unique identifier from a record by which we de-duplicate input
* records; if it returns null, the record will not be considered for
* de-duping but forwarded as-is.
*/
DeduplicationTransformer(final long maintainDurationPerEventInMs, final KeyValueMapper<K, V, E> idExtractor) {
if (maintainDurationPerEventInMs < 1) {
throw new IllegalArgumentException("maintain duration per event must be >= 1");
}
leftDurationMs = maintainDurationPerEventInMs / 2;
rightDurationMs = maintainDurationPerEventInMs - leftDurationMs;
this.idExtractor = idExtractor;
}
@Override
@SuppressWarnings("unchecked")
public void init(final ProcessorContext context) {
this.context = context;
eventIdStore = (WindowStore<E, Long>) context.getStateStore(storeName);
}
public KeyValue<K, V> transform(final K key, final V value) {
final E eventId = idExtractor.apply(key, value);
if (eventId == null) {
return KeyValue.pair(key, value);
} else {
final KeyValue<K, V> output;
if (isDuplicate(eventId)) {
output = null;
updateTimestampOfExistingEventToPreventExpiry(eventId, context.timestamp());
} else {
output = KeyValue.pair(key, value);
rememberNewEvent(eventId, context.timestamp());
}
return output;
}
}
private boolean isDuplicate(final E eventId) {
final long eventTime = context.timestamp();
final WindowStoreIterator<Long> timeIterator = eventIdStore.fetch(
eventId,
eventTime - leftDurationMs,
eventTime + rightDurationMs);
final boolean isDuplicate = timeIterator.hasNext();
timeIterator.close();
return isDuplicate;
}
private void updateTimestampOfExistingEventToPreventExpiry(final E eventId, final long newTimestamp) {
eventIdStore.put(eventId, newTimestamp, newTimestamp);
}
private void rememberNewEvent(final E eventId, final long timestamp) {
eventIdStore.put(eventId, timestamp, timestamp);
}
@Override
public void close() {
// Note: The store should NOT be closed manually here via `eventIdStore.close()`!
// The Kafka Streams API will automatically close stores when necessary.
}
}
@Test
public void shouldRemoveDuplicatesFromTheInput() {
final String firstId = UUID.randomUUID().toString(); // e.g. "4ff3cb44-abcb-46e3-8f9a-afb7cc74fbb8"
final String secondId = UUID.randomUUID().toString();
final String thirdId = UUID.randomUUID().toString();
final List<String> inputValues = Arrays.asList(firstId, secondId, firstId, firstId, secondId, thirdId,
thirdId, firstId, secondId);
final List<String> expectedValues = Arrays.asList(firstId, secondId, thirdId);
//
// Step 1: Configure and start the processor topology.
//
final StreamsBuilder builder = new StreamsBuilder();
final Properties streamsConfiguration = new Properties();
streamsConfiguration.put(StreamsConfig.APPLICATION_ID_CONFIG, "deduplication-lambda-integration-test");
streamsConfiguration.put(StreamsConfig.BOOTSTRAP_SERVERS_CONFIG, "dummy config");
streamsConfiguration.put(StreamsConfig.DEFAULT_KEY_SERDE_CLASS_CONFIG, Serdes.ByteArray().getClass().getName());
streamsConfiguration.put(StreamsConfig.DEFAULT_VALUE_SERDE_CLASS_CONFIG, Serdes.String().getClass().getName());
// Use a temporary directory for storing state, which will be automatically removed after the test.
streamsConfiguration.put(StreamsConfig.STATE_DIR_CONFIG, TestUtils.tempDirectory().getAbsolutePath());
// How long we "remember" an event. During this time, any incoming duplicates of the event
// will be, well, dropped, thereby de-duplicating the input data.
//
// The actual value depends on your use case. To reduce memory and disk usage, you could
// decrease the size to purge old windows more frequently at the cost of potentially missing out
// on de-duplicating late-arriving records.
final Duration windowSize = Duration.ofMinutes(10);
// retention period must be at least window size -- for this use case, we don't need a longer retention period
// and thus just use the window size as retention time
final Duration retentionPeriod = windowSize;
final StoreBuilder<WindowStore<String, Long>> dedupStoreBuilder = Stores.windowStoreBuilder(
Stores.persistentWindowStore(storeName,
retentionPeriod,
windowSize,
false
),
Serdes.String(),
Serdes.Long());
builder.addStateStore(dedupStoreBuilder);
final String inputTopic = "inputTopic";
final String outputTopic = "outputTopic";
final KStream<byte[], String> input = builder.stream(inputTopic);
final KStream<byte[], String> deduplicated = input.transform(
// In this example, we assume that the record value as-is represents a unique event ID by
// which we can perform de-duplication. If your records are different, adapt the extractor
// function as needed.
() -> new DeduplicationTransformer<>(windowSize.toMillis(), (key, value) -> value),
storeName);
deduplicated.to(outputTopic);
try (final TopologyTestDriver topologyTestDriver = new TopologyTestDriver(builder.build(), streamsConfiguration)) {
//
// Step 2: Produce some input data to the input topic.
//
IntegrationTestUtils.produceKeyValuesSynchronously(
inputTopic,
inputValues.stream().map(v -> new KeyValue<>(null, v)).collect(Collectors.toList()),
topologyTestDriver,
new IntegrationTestUtils.NothingSerde<>(),
new StringSerializer()
);
//
// Step 3: Verify the application's output data.
//
final List<String> actualValues = IntegrationTestUtils.drainStreamOutput(
outputTopic,
topologyTestDriver,
new IntegrationTestUtils.NothingSerde<>(),
new StringDeserializer()
).stream().map(kv -> kv.value).collect(Collectors.toList());
assertThat(actualValues).containsExactlyElementsOf(expectedValues);
}
}
}