public class StickyAssignor
extends org.apache.kafka.clients.consumer.internals.AbstractPartitionAssignor
The sticky assignor serves two purposes. First, it guarantees an assignment that is as balanced as possible, meaning either:
Starting fresh it would work by distributing the partitions over consumers as evenly as possible. Even though this may sound similar to how round robin assignor works, the second example below shows that it is not. During a reassignment it would perform the reassignment in such a way that in the new assignment
Example 1. Suppose there are three consumers C0
, C1
, C2
,
four topics t0,
t1
, t2
, t3
, and each topic has 2 partitions,
resulting in partitions t0p0
, t0p1
, t1p0
, t1p1
, t2p0
,
t2p1
, t3p0
, t3p1
. Each consumer is subscribed to all three topics.
The assignment with both sticky and round robin assignors will be:
C0: [t0p0, t1p1, t3p0]
C1: [t0p1, t2p0, t3p1]
C2: [t1p0, t2p1]
C1
is removed and a reassignment is about to happen. The round robin assignor would produce:
C0: [t0p0, t1p0, t2p0, t3p0]
C2: [t0p1, t1p1, t2p1, t3p1]
C0 [t0p0, t1p1, t3p0, t2p0]
C2 [t1p0, t2p1, t0p1, t3p1]
Example 2. There are three consumers C0
, C1
, C2
,
and three topics t0
, t1
, t2
, with 1, 2, and 3 partitions respectively.
Therefore, the partitions are t0p0
, t1p0
, t1p1
, t2p0
,
t2p1
, t2p2
. C0
is subscribed to t0
; C1
is subscribed to
t0
, t1
; and C2
is subscribed to t0
, t1
, t2
.
The round robin assignor would come up with the following assignment:
C0 [t0p0]
C1 [t1p0]
C2 [t1p1, t2p0, t2p1, t2p2]
C0 [t0p0]
C1 [t1p0, t1p1]
C2 [t2p0, t2p1, t2p2]
C0
is removed, these two assignors would produce the following assignments.
Round Robin (preserves 3 partition assignments):
C1 [t0p0, t1p1]
C2 [t1p0, t2p0, t2p1, t2p2]
C1 [t1p0, t1p1, t0p0]
C2 [t2p0, t2p1, t2p2]
ConsumerRebalanceListener
onPartitionsRevoked()
callback listeners. The cleanup code is placed in that callback listener
because the consumer has no assumption or hope of preserving any of its assigned partitions after a rebalance when it
is using range or round robin assignor. The listener code would look like this:
class TheOldRebalanceListener implements ConsumerRebalanceListener {
void onPartitionsRevoked(Collection<TopicPartition> partitions) {
for (TopicPartition partition: partitions) {
commitOffsets(partition);
cleanupState(partition);
}
}
void onPartitionsAssigned(Collection<TopicPartition> partitions) {
for (TopicPartition partition: partitions) {
initializeState(partition);
initializeOffset(partition);
}
}
}
As mentioned above, one advantage of the sticky assignor is that, in general, it reduces the number of partitions that
actually move from one consumer to another during a reassignment. Therefore, it allows consumers to do their cleanup
more efficiently. Of course, they still can perform the partition cleanup in the onPartitionsRevoked()
listener, but they can be more efficient and make a note of their partitions before and after the rebalance, and do the
cleanup after the rebalance only on the partitions they have lost (which is normally not a lot). The code snippet below
clarifies this point:
class TheNewRebalanceListener implements ConsumerRebalanceListener {
Collection<TopicPartition> lastAssignment = Collections.emptyList();
void onPartitionsRevoked(Collection<TopicPartition> partitions) {
for (TopicPartition partition: partitions)
commitOffsets(partition);
}
void onPartitionsAssigned(Collection<TopicPartition> assignment) {
for (TopicPartition partition: difference(lastAssignment, assignment))
cleanupState(partition);
for (TopicPartition partition: difference(assignment, lastAssignment))
initializeState(partition);
for (TopicPartition partition: assignment)
initializeOffset(partition);
this.lastAssignment = assignment;
}
}
Any consumer that uses sticky assignment can leverage this listener like this:
consumer.subscribe(topics, new TheNewRebalanceListener());
Constructor | Description |
---|---|
StickyAssignor() |
Modifier and Type | Method | Description |
---|---|---|
java.util.Map<java.lang.String,java.util.List<TopicPartition>> |
assign(java.util.Map<java.lang.String,java.lang.Integer> partitionsPerTopic,
java.util.Map<java.lang.String,org.apache.kafka.clients.consumer.internals.PartitionAssignor.Subscription> subscriptions) |
|
java.lang.String |
name() |
|
void |
onAssignment(org.apache.kafka.clients.consumer.internals.PartitionAssignor.Assignment assignment) |
|
org.apache.kafka.clients.consumer.internals.PartitionAssignor.Subscription |
subscription(java.util.Set<java.lang.String> topics) |
public java.util.Map<java.lang.String,java.util.List<TopicPartition>> assign(java.util.Map<java.lang.String,java.lang.Integer> partitionsPerTopic, java.util.Map<java.lang.String,org.apache.kafka.clients.consumer.internals.PartitionAssignor.Subscription> subscriptions)
assign
in class org.apache.kafka.clients.consumer.internals.AbstractPartitionAssignor
public void onAssignment(org.apache.kafka.clients.consumer.internals.PartitionAssignor.Assignment assignment)
onAssignment
in class org.apache.kafka.clients.consumer.internals.AbstractPartitionAssignor
public org.apache.kafka.clients.consumer.internals.PartitionAssignor.Subscription subscription(java.util.Set<java.lang.String> topics)
subscription
in class org.apache.kafka.clients.consumer.internals.AbstractPartitionAssignor
public java.lang.String name()