Status
Current state: Under Discussion"
Discussion thread: here
JIRA: here
Released: <Kafka Version>
Please keep the discussion on the mailing list rather than commenting on the wiki (wiki discussions get unwieldy fast).
Motivation
The most expensive part of a Kafka cluster is probably its storage system. At LinkedIn we use RAID-10 for storage and set Kafka’s replication factor = 2. This setup requires 4X space to store data and tolerates up to 1 broker failure. We are at risk of data loss with just 1 broker failure, which is not acceptable for e.g. financial data. On the other hand, it is prohibitively expensive to set replication factor = 3 with RAID-10 because it will increase our existing hardware cost and operational cost by 50%.
The solution is to use JBOD and set replication factor = 3 or higher. It is based on the idea that Kafka already has replication across brokers and it is unnecessary to use RAID-10 for replication. Let’s say we set the replication factor = 4 with JBOD. This setup requires 4X space to store data and tolerate up to 3 broker failures in order not to lose any data. In comparison to our existing setup, this allows us to obtain 3X broker failure tolerance without increasing storage hardware cost.
We have evaluated the possibility of using other RAID setup in LinkedIn. But none of them addresses our problem as JBOD does. RAID-0 stops working entirely with just one disk failure. RAID-5 or RAID-6 has sizable performance loss as compared to RAID-0 and probably JBOD as well, due to their use of block-level striping with distributed parity.
Unfortunately, JBOD is not recommended for Kafka because some important features are missing. For example, Kafka lacks good support for tools as well as load balancing across disks when multiple disks are used. Here is a list of problems that need to be addressed for JBOD to be useful:
1) Broker will shutdown if any disk fails. This means a single disk failure can bring down the entire broker. Instead, broker should still serve those replicas on the good disks as long as there is good disk available.
2) Kafka doesn’t provide the necessary tools for users to manage JBOD. For example, Kafka doesn’t provide script to re-assign replicas between disks of the same broker. These tools are needed before we can use JBOD with Kafka.
3) JBOD doesn’t by itself balance load across disks as RAID-10 does. This will be a new problem for us to solve in order for JBOD setup to work well. We should have a better solution than round-robin which we are using to select disk to place a new replica. And we should probably figure out how to re-assign replicas across disks of the same broker if we notice load imbalance across disks of a broker.
For ease of discussion, we have separated the design of JBOD support into two different KIPs. This KIP address the first problem. See KIP - Support replicas movement between log directories for our proposal to address the second problem.
Since Kafka configuration and implementation does not expose "disk", we will use log directory and disk interchangably in the rest of the KIP.
Goals
The goal of this KIP is to allow broker to serve replicas on good log directories even if some log directories have failed. This addresses the first problem raised in the motivation section. See KIP - Support replicas movement between log directories to read our proposal of how to address the second problem.
Proposed change
How to handle log directory failure
Problem statement:
Currently LeaderAndIsrRequest is used for two purpose: 1) create a new replica on a broker and 2) switch a replica between leader/follower of the partition. If a broker starts with some replicas unavailable because they are on a bad log directory, it will re-create those replicas on a good log directory when it receives LeaderAndIsrRequest from the controller. This is wrong. To avoid this, controller needs to know whether the replica has been created on the broker and explicitly specify whether broker should create replica in the LeaderAndIsrRequest.
Further, currently a replica is offline if and only if the broker hosting the replica is offline. This logic is no longer applicable with JBOD. Broker needs to explicitly tell controller the list of online replicas on its good log directories so that controller can elect leader from only online replicas. And admin tools should be developed to allow user to query which replicas are online or offline.
Solution:
The idea is for controller to keep track of weather a replica has been successfully created by getting this information from LeaderAndIsrResponse and persisting this information in the zookeeper. Then controller can explicitly tell broker whether to create replica or not by specifying a newly-added boolean field in the LeaderAndIsrRequest. Each broker can tell controller whether a replica is created and online by specifying the error_code per partition in the LeaderAndIsrResponse, which in turn allows broker to derive the offline replicas per partition and elect leader appropriately.
In the following we describe how our solution works under five different scenarios. Some existing steps (e.g. kafka-topics.sh creates znode) are omitted for simplicity.
1. Topic gets created
- The controller creates znode /broker/topics/[topic]/partitions/[partitionId]/controller_managed_state with json-formatted data {"version" : 1, "created" : []} for this partition.
- The controller sends LeaderAndIsrRequest with create=True to the leader and followers.
- The leader and followers create replicas locally and sends LeaderAndIsrReponse to the controller with error=None.
- After receiving LeaderAndIsrResponse from leader and followers of this partition, the controller adds broker to the list "created" of this partition if error=None in LeaderAndIsrResponse. Otherwise, the replica is considered offline.
2. A log directory stops working on a broker during runtime
- The controller watches the path /log_dir_event_notification for new znode.
- The broker detects offline log directories during runtime.
- The broker notifies the controller by creating a sequential znode under path /log_dir_event_notification with data of the format {"version" : 1, "broker" : brokerId, "event" : LogDirFailure}.
- The controller reads the znode to get the brokerId and finds that the event type is LogDirFailure.
- The controller deletes the notification znode
- The controller sends LeaderAndIsrRequest to that broker to query the state of all topic partitions on the broker. The LeaderAndIsrResponse from this broker should tell the controller the list of partitions that are on the bad log directories.
- The controller updates the information of offline replicas in memory and trigger leader election as appropriate.
- The controller propagates the information of offline replicas to brokers by sending UpdateMetadataRequest.
3. Broker bootstraps with bad log directories
- Broker collects list of replicas found on the good log directories. If there is no good log directory the broker will exit.
- The controller sends LeaderAndIsrRequest for all partitions that should exist on this broker. If a replica is not in the created list of a partition, its create=True in the LeaderAndIsrRequest. Otherwise, its create=False.
- The broker will specify error=KafkaStorageException for those partitions that are in the LeaderAndIsrRequest with create=False but not found on any good log directory.
- The controller considers a replica on that broker to be offline if its error!=None in the LeaderAndIsrResponse.
- The controller updates the information of offline replicas in memory and triggers leader election as appropriate.
- The controller propagates the information of offline replicas to brokers by sending UpdateMetadataRequest.
4. The disk (or log directory) gets fixed
- The controller watches the path /log_dir_event_notification for new znode.
- User fixes the bad disk. The disk can either be empty or contain the old data.
- User runs kafka-log-dirs.sh like this: ./bin/kafka-log-dirs.sh --delete --zookeeper zookeeerUrl --broker brokerId
- The script creates a sequential znode under path /log_dir_event_notification with data of the format {"version" : 1, "broker" : brokerId, "event" : LogDirReset}
- The controller reads the znode to get the brokerId and finds that the event type is LogDirReset.
- The controller deletes this broker from list “created” for all partitions that should exist on this broker.
- The controller deletes the notification znode from zookeeper.
- The controller sends LeaderAndIsrRequest with create=True to this broker. If LeaderAndIsrResponse shows success, the controller adds broker to the list "created" of the respective partitions. Otherwise, those replicas are considered offline.
5. User queries replicas state
- Controller propagates the information of offline replicas to brokers by sending UpdateMetadataRequest. MetadataResponse will include offline replicas per partition.
- kafka-topics script will display offline replicas when describing a topic partition. The offline replicas is the union of offline replicas on live brokers and replicas on dead brokers. kafka-topics script obtains offline replicas by sending MetadataRequest to any broker.
Public interface
Zookeeper
1) Add znode at /broker/topics/[topic]/partitions/[partitionId]/controller_managed_state with the following data format:
{
"version" : int,
"created" : [int]
}
2) Store data with the following json format in znode /log_dir_event_notification/log_dir_event_*
{
"version" : int,
"broker" : int,
"event" : int <-- This can be LogDirFailure or LogDirReset
}
Protocol
Add a create field to LeaderAndIsrRequestPartitionState which will be used by LeaderAndIsrRequest
LeaderAndIsrRequest => controller_id controller_epoch partition_states live_leaders controller_id => int32 controller_epoch => int32 partition_states => [LeaderAndIsrRequestPartitionState] live_leaders => [LeaderAndIsrRequestLiveLeader] LeaderAndIsrRequestPartitionState => topic partition controller_epoch leader leader_epoch isr zk_version replicas topic => str partition => int32 controller_epoch => int32 leader => int32 leader_epoch => int32 isr => [int32] zk_version => int32 replicas => [int32] create => boolean <-- NEW
Add a offline_replicas field to UpdateMetadataRequestPartitionState which will be used by UpdateMetadataRequest
UpdateMetadataRequest => controller_id controller_epoch partition_states live_brokers controller_id => int32 controller_epoch => int32 partition_states => [UpdateMetadataRequestPartitionState] live_brokers => [UpdateMetadataRequestBroker] UpdateMetadataRequestPartitionState => topic partition controller_epoch leader leader_epoch isr zk_version replicas offline_replicas topic => string partition => int32 controller_epoch => int32 leader => int32 leader_epoch => int32 isr => [int32] zk_version => int32 replicas => [int32] offline_replicas => [int32] <-- NEW
Add a offline_replicas field to PartitionMetadata which will be used by MetadataResponse
MetadataResponse => brokers cluster_id controller_id topic_metadata brokers => [MetadatBroker] cluster_id => nullable_str controller_id => int32 topic_metadata => TopicMetadata TopicMetadata => topic_error_code topic is_internal partition_metadata topic_error_code => int16 topic => str is_internal => boolean partition_metadata => [PartitionMetadata] PartitionMetadata => partition_error_code partition_id leader replicas isr offline_replicas partition_error_code => int16 partition_id => int32 leader => int32 replicas => [int32] isr => [int32] offline_replicas => [int32] <-- NEW
Scripts
1) When describing a topic, kafka-topics.sh will show the offline replicas for each partition.
2) Add kafka-log-dirs.sh which allows user to reset log directory state of a broker.
./bin/kafka-log-dirs.sh --delete --zookeeper localhost:2181 --broker 1 will delete this broker from list “created” of all znode /broker/topics/[topic]/partitions/[partitionId]/state
Changes in Operational Procedures
In this section we describe the expected changes in operational procedures in order to switch Kafka to run with JBOD instead of RAID. Administrators of Kafka cluster need to be aware of these changes before switching from RAID-10 to JBOD.
1) Need to reset broker's log directory state after disk is fixed.
As of current Kafka implementation, a broker will automatically create replica on a good log directory if it receives LeaderAndIsrRequest for a partition. No extra operation is needed e.g. if a broker is restarted after replacing failed disks with empty disks, or if broker is restarted on a new machine with empty disks, because the broker will automatically populate good log directories with data read from the partition leader. But after this KIP, administrator needs to explicitly execute the script kafka-log-dirs.sh to remove this broker from the list "created" of all partitions and restart broker after the hardware problem is fixed. This is needed to ensure that those replicas can be re-created on the good log directories of the broker after administrator has fixed the problem.
2) Need to adjust replication factor and min.insync.replicas
After we switch from RAID-10 to JBOD, the number of disks that can fail will be smaller if replication factor is not changed. Administrator needs to change replication factor and min.insync.replicas to balance the cost, availability and performance of Kafka cluster. With proper configuration of these two configs, we can have reduced disk cost or increased tolerance of broker failure and disk failure. Here are a few examples:
- If we switch from RAID-10 to JBOD and keep replication factor to 2, the disk usage of Kafka cluster would be reduced by 50% without reducing the availability against broker failure. But tolerance of disk failure will decrease.
- If we switch from RAID-10 to JBOD and increase replication factor from 2 to 3, the disk usage of Kafka cluster would be reduced by 25%, the number of brokers that can fail without impacting availability can increase from 1 to 2. But tolerance of disk failure will still decrease.
- If we switch from RAID-10 to JBOD and increase replication factor from 2 to 4, the disk usage of Kafka would stay the same, the number of brokers that can fail without impacting availability can increase from 1 to 3, and number of disks that can fail without impacting availability would stay the same.
Compatibility, Deprecation, and Migration Plan
This KIP is a pure addition. So there is no backward compatibility concern.
The KIP changes the inter-broker protocol. Therefore the migration requires two rolling bounce. In the first rolling bounce we will deploy the new code but broker will still communicate using the existing protocol. In the second rolling bounce we will change the config so that broker will start to communicate with each other using the new protocol.
Test Plan
The new features will be tested through unit, integration, and system tests. In the following we explain the system tests only.
Note that we validate the following when we say "validate client/cluster state" in the system tests.
- Brokers are all running and show expected error message
- topic description shows expected results for all topics
- kafka-log-dirs.sh can show the expected offline replicas for all brokers
- A pair of producer and consumer can succcessfully produce/consume from a topic without message loss or duplication.
1) Log directory failure on leader during bootstrap
- Start 1 zookeeper and 3 brokers
- Create a topic of 1 partition with 3 replicas
- Start a pair of producer and consumer to produce/consume from the topic
- Kill the leader of the partition
- Remove the first log directory of the leader and create a file with the same path
- Start leader again
- Validated client/cluster state
2) Log directory failure on leader during runtime
- Start 1 zookeeper and 3 brokers
- Create a topic of 1 partition with 3 replicas
- Start a pair of producer and consumer to produce/consume from the topic
- Remove the first log directory of the leader and create a file with the same path
- Validated client/cluster state
// Now validate that the previous leader can still serve replicas on the good log directories
- Create another topic of 1 partition with 3 replicas
- Kill the other two brokers
- Start a pair of producer and consumer to produce/consume from the new topic
- Validated client/cluster state
3) Log directory failure on follower during runtime
- Start 1 zookeeper and 3 brokers
- Create a topic of 1 partition with 3 replicas
- Start a pair of producer and consumer to produce/consume from the topic
- Remove the first log directory of a follower
- Validated client/cluster state
// Now validate that the follower can still serve replicas on the good log directories
- Create another topic of 1 partition with 3 replicas
- Kill the other two brokers
- Start a pair of producer and consumer to produce/consume from the new topic
- Validated client/cluster state
Rejected Alternatives
- Let broker keep track of the replicas that it has created.
The cons of this approach is that each broker, instead of controller, keeps track of the replica placement information. However, this solution will split the task of determining offline replicas among controller and brokers as opposed to the current Kafka design, where the controller determines states of replicas and propagate this information to brokers. We think it is less error-prone to still let controller be the only entity that maintains metadata (e.g. replica state) of Kafka cluster.
- Avoid adding "create" field to LeaderAndIsrRequest.
- Add a new field "created" in the existing znode
/broker/topics/[topic]/partitions/[partitionId]/state instead of creating a new znodeLeaderAndIsrRequset, the leader would need to read this list of created replicas from zookeeper before updating isr in the zookeeper. This is different from the current design where all information except isr are read from LeaderAndIsrRequest from controller. And it creates opportunity for race condition. Thus we propose to add a new znode to keep those information that can only be written by controller.
- Identify replica by 4-tuple (topic, partition, broker, log_directory) in zookeeper and various requests
one-broker-per-disk would work and should require no major change in Kafka as compared to this KIP. So it would be a good short term solution. But it has a few drawbacks which makes it less desirable in the long term. Assume we have 10 disks on a machine. Here are the problems:
1) Our stress test result shows that one-broker-per-disk has 15% lower throughput
2) Controller would need to send 10X as many LeaderAndIsrRequest, MetadataUpdateRequest and StopReplicaRequest. This increases the burden on the controller and makes it increasingly a performance bottleneck.
3) Less efficient use of physical resource on the machine. The number of socket on each machine will increase by 10X. The number of connection between any two machine will increase by 100X.
4) Less efficient way to manage memory and quota.
5) Rebalance between disks/brokers on the same machine will be less efficient and less flexible. Broker has to read data from another broker on the same machine via socket. It is also harder to do automatic load balance between disks on the same machine in the future.
Potential Future Improvement
1. Distribute segments of a given replica across multiple log directories on the same broker. It is useful but complicated. It is something that can be done later via a separate KIP.
2. Provide intelligent solution to select log directory to place new replicas and re-assign replicas across log directories to balance the load.
3. Have broker automatically rebalance replicas across its log directories. It is worth exploring separately in a future KIP as there are a few options in the design space.
4. Allow controller/user to specify quota when moving replicas between log directories on the same broker.