Overview ▹

Overview ▾

Package kafka provides high-level Apache Kafka producer and consumers using bindings on-top of the librdkafka C library.

High-level Consumer

* Decide if you want to read messages and events by calling `.Poll()` or the deprecated option of using the `.Events()` channel. (If you want to use `.Events()` channel then set `"go.events.channel.enable": true`).

* Create a Consumer with `kafka.NewConsumer()` providing at least the `bootstrap.servers` and `group.id` configuration properties.

* Call `.Subscribe()` or (`.SubscribeTopics()` to subscribe to multiple topics) to join the group with the specified subscription set. Subscriptions are atomic, calling `.Subscribe*()` again will leave the group and rejoin with the new set of topics.

* Start reading events and messages from either the `.Events` channel or by calling `.Poll()`.

* When the group has rebalanced each client member is assigned a (sub-)set of topic+partitions. By default the consumer will start fetching messages for its assigned partitions at this point, but your application may enable rebalance events to get an insight into what the assigned partitions where as well as set the initial offsets. To do this you need to pass `"go.application.rebalance.enable": true` to the `NewConsumer()` call mentioned above. You will (eventually) see a `kafka.AssignedPartitions` event with the assigned partition set. You can optionally modify the initial offsets (they'll default to stored offsets and if there are no previously stored offsets it will fall back to `"auto.offset.reset"` which defaults to the `latest` message) and then call `.Assign(partitions)` to start consuming. If you don't need to modify the initial offsets you will not need to call `.Assign()`, the client will do so automatically for you if you dont, unless you are using the channel-based consumer in which case you MUST call `.Assign()` when receiving the `AssignedPartitions` and `RevokedPartitions` events.

* As messages are fetched they will be made available on either the `.Events` channel or by calling `.Poll()`, look for event type `*kafka.Message`.

* Handle messages, events and errors to your liking.

* When you are done consuming call `.Close()` to commit final offsets and leave the consumer group.

Producer

* Create a Producer with `kafka.NewProducer()` providing at least the `bootstrap.servers` configuration properties.

* Messages may now be produced either by sending a `*kafka.Message` on the `.ProduceChannel` or by calling `.Produce()`.

* Producing is an asynchronous operation so the client notifies the application of per-message produce success or failure through something called delivery reports. Delivery reports are by default emitted on the `.Events()` channel as `*kafka.Message` and you should check `msg.TopicPartition.Error` for `nil` to find out if the message was succesfully delivered or not. It is also possible to direct delivery reports to alternate channels by providing a non-nil `chan Event` channel to `.Produce()`. If no delivery reports are wanted they can be completely disabled by setting configuration property `"go.delivery.reports": false`.

* When you are done producing messages you will need to make sure all messages are indeed delivered to the broker (or failed), remember that this is an asynchronous client so some of your messages may be lingering in internal channels or tranmission queues. To do this you can either keep track of the messages you've produced and wait for their corresponding delivery reports, or call the convenience function `.Flush()` that will block until all message deliveries are done or the provided timeout elapses.

* Finally call `.Close()` to decommission the producer.

Transactional producer API

The transactional producer operates on top of the idempotent producer, and provides full exactly-once semantics (EOS) for Apache Kafka when used with the transaction aware consumer (`isolation.level=read_committed`).

A producer instance is configured for transactions by setting the `transactional.id` to an identifier unique for the application. This id will be used to fence stale transactions from previous instances of the application, typically following an outage or crash.

After creating the transactional producer instance using `NewProducer()` the transactional state must be initialized by calling `InitTransactions()`. This is a blocking call that will acquire a runtime producer id from the transaction coordinator broker as well as abort any stale transactions and fence any still running producer instances with the same `transactional.id`.

Once transactions are initialized the application may begin a new transaction by calling `BeginTransaction()`. A producer instance may only have one single on-going transaction.

Any messages produced after the transaction has been started will belong to the ongoing transaction and will be committed or aborted atomically. It is not permitted to produce messages outside a transaction boundary, e.g., before `BeginTransaction()` or after `CommitTransaction()`, `AbortTransaction()` or if the current transaction has failed.

If consumed messages are used as input to the transaction, the consumer instance must be configured with `enable.auto.commit` set to `false`. To commit the consumed offsets along with the transaction pass the list of consumed partitions and the last offset processed + 1 to `SendOffsetsToTransaction()` prior to committing the transaction. This allows an aborted transaction to be restarted using the previously committed offsets.

To commit the produced messages, and any consumed offsets, to the current transaction, call `CommitTransaction()`. This call will block until the transaction has been fully committed or failed (typically due to fencing by a newer producer instance).

Alternatively, if processing fails, or an abortable transaction error is raised, the transaction needs to be aborted by calling `AbortTransaction()` which marks any produced messages and offset commits as aborted.

After the current transaction has been committed or aborted a new transaction may be started by calling `BeginTransaction()` again.

Retriable errors: Some error cases allow the attempted operation to be retried, this is indicated by the error object having the retriable flag set which can be detected by calling `err.(kafka.Error).IsRetriable()`. When this flag is set the application may retry the operation immediately or preferably after a shorter grace period (to avoid busy-looping). Retriable errors include timeouts, broker transport failures, etc.

Abortable errors: An ongoing transaction may fail permanently due to various errors, such as transaction coordinator becoming unavailable, write failures to the Apache Kafka log, under-replicated partitions, etc. At this point the producer application must abort the current transaction using `AbortTransaction()` and optionally start a new transaction by calling `BeginTransaction()`. Whether an error is abortable or not is detected by calling `err.(kafka.Error).TxnRequiresAbort()` on the returned error object.

Fatal errors: While the underlying idempotent producer will typically only raise fatal errors for unrecoverable cluster errors where the idempotency guarantees can't be maintained, most of these are treated as abortable by the transactional producer since transactions may be aborted and retried in their entirety; The transactional producer on the other hand introduces a set of additional fatal errors which the application needs to handle by shutting down the producer and terminate. There is no way for a producer instance to recover from fatal errors. Whether an error is fatal or not is detected by calling `err.(kafka.Error).IsFatal()` on the returned error object or by checking the global `GetFatalError()`.

Handling of other errors: For errors that have neither retriable, abortable or the fatal flag set it is not always obvious how to handle them. While some of these errors may be indicative of bugs in the application code, such as when an invalid parameter is passed to a method, other errors might originate from the broker and be passed thru as-is to the application. The general recommendation is to treat these errors, that have neither the retriable or abortable flags set, as fatal.

Error handling example:

retry:

   err := producer.CommitTransaction(...)
   if err == nil {
       return nil
   } else if err.(kafka.Error).TxnRequiresAbort() {
       do_abort_transaction_and_reset_inputs()
   } else if err.(kafka.Error).IsRetriable() {
       goto retry
   } else { // treat all other errors as fatal errors
       panic(err)
   }

Events

Apart from emitting messages and delivery reports the client also communicates with the application through a number of different event types. An application may choose to handle or ignore these events.

Consumer events

* `*kafka.Message` - a fetched message.

* `AssignedPartitions` - The assigned partition set for this client following a rebalance. Requires `go.application.rebalance.enable`

* `RevokedPartitions` - The counter part to `AssignedPartitions` following a rebalance. `AssignedPartitions` and `RevokedPartitions` are symmetrical. Requires `go.application.rebalance.enable`

* `PartitionEOF` - Consumer has reached the end of a partition. NOTE: The consumer will keep trying to fetch new messages for the partition.

* `OffsetsCommitted` - Offset commit results (when `enable.auto.commit` is enabled).

Producer events

* `*kafka.Message` - delivery report for produced message. Check `.TopicPartition.Error` for delivery result.

Generic events for both Consumer and Producer

* `KafkaError` - client (error codes are prefixed with _) or broker error. These errors are normally just informational since the client will try its best to automatically recover (eventually).

* `OAuthBearerTokenRefresh` - retrieval of a new SASL/OAUTHBEARER token is required. This event only occurs with sasl.mechanism=OAUTHBEARER. Be sure to invoke SetOAuthBearerToken() on the Producer/Consumer/AdminClient instance when a successful token retrieval is completed, otherwise be sure to invoke SetOAuthBearerTokenFailure() to indicate that retrieval failed (or if setting the token failed, which could happen if an extension doesn't meet the required regular expression); invoking SetOAuthBearerTokenFailure() will schedule a new event for 10 seconds later so another retrieval can be attempted.

Hint: If your application registers a signal notification (signal.Notify) makes sure the signals channel is buffered to avoid possible complications with blocking Poll() calls.

Note: The Confluent Kafka Go client is safe for concurrent use.

Package kafka

Overview ▹

Overview ▾

High-level Consumer

Producer

Transactional producer API

Events

Consumer events

Producer events

Generic events for both Consumer and Producer

Index ▹

Index ▾

Package files

Constants

func LibraryVersion ¶

func WriteErrorCodes ¶

type AdminClient ¶

func NewAdminClient ¶

func NewAdminClientFromConsumer ¶

func NewAdminClientFromProducer ¶

func (*AdminClient) AlterConfigs ¶

func (*AdminClient) Close ¶

func (*AdminClient) ClusterID ¶

func (*AdminClient) ControllerID ¶

func (*AdminClient) CreatePartitions ¶

func (*AdminClient) CreateTopics ¶

func (*AdminClient) DeleteTopics ¶

func (*AdminClient) DescribeConfigs ¶

func (*AdminClient) GetMetadata ¶

func (*AdminClient) SetOAuthBearerToken ¶

func (*AdminClient) SetOAuthBearerTokenFailure ¶

func (*AdminClient) String ¶

type AdminOption ¶

type AdminOptionOperationTimeout ¶

func SetAdminOperationTimeout ¶

type AdminOptionRequestTimeout ¶

func SetAdminRequestTimeout ¶

type AdminOptionValidateOnly ¶

func SetAdminValidateOnly ¶

type AlterConfigsAdminOption ¶

type AlterOperation ¶

func (AlterOperation) String ¶

type AssignedPartitions ¶

func (AssignedPartitions) String ¶

type BrokerMetadata ¶

type ConfigEntry ¶

func StringMapToConfigEntries ¶

func (ConfigEntry) String ¶

type ConfigEntryResult ¶

func (ConfigEntryResult) String ¶

type ConfigMap ¶

func (ConfigMap) Get ¶

func (ConfigMap) Set ¶

func (ConfigMap) SetKey ¶

type ConfigResource ¶

func (ConfigResource) String ¶

type ConfigResourceResult ¶

func (ConfigResourceResult) String ¶

type ConfigSource ¶

func (ConfigSource) String ¶

type ConfigValue ¶

type Consumer ¶

func NewConsumer ¶

func (*Consumer) Assign ¶

func (*Consumer) Assignment ¶

func (*Consumer) AssignmentLost ¶

func (*Consumer) Close ¶

func (*Consumer) Commit ¶

func (*Consumer) CommitMessage ¶

func (*Consumer) CommitOffsets ¶

func (*Consumer) Committed ¶

func (*Consumer) Events ¶

func (*Consumer) GetConsumerGroupMetadata ¶

func (*Consumer) GetMetadata ¶

func (*Consumer) GetRebalanceProtocol ¶

func (*Consumer) GetWatermarkOffsets ¶

func (*Consumer) IncrementalAssign ¶

func (*Consumer) IncrementalUnassign ¶

func (*Consumer) Logs ¶

func (*Consumer) OffsetsForTimes ¶