chatwars-offers/vendor/github.com/confluentinc/confluent-kafka-go/kafka/kafka.go

/**
 * Copyright 2016 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 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

import (
	"fmt"
	// Make sure librdkafka_vendor/ sub-directory is included in vendor pulls.
	_ "github.com/confluentinc/confluent-kafka-go/kafka/librdkafka_vendor"
	"unsafe"
)

/*
#include <stdlib.h>
#include <string.h>
#include "select_rdkafka.h"

static rd_kafka_topic_partition_t *_c_rdkafka_topic_partition_list_entry(rd_kafka_topic_partition_list_t *rktparlist, int idx) {
   return idx < rktparlist->cnt ? &rktparlist->elems[idx] : NULL;
}
*/
import "C"

// PartitionAny represents any partition (for partitioning),
// or unspecified value (for all other cases)
const PartitionAny = int32(C.RD_KAFKA_PARTITION_UA)

// TopicPartition is a generic placeholder for a Topic+Partition and optionally Offset.
type TopicPartition struct {
	Topic     *string
	Partition int32
	Offset    Offset
	Metadata  *string
	Error     error
}

func (p TopicPartition) String() string {
	topic := "<null>"
	if p.Topic != nil {
		topic = *p.Topic
	}
	if p.Error != nil {
		return fmt.Sprintf("%s[%d]@%s(%s)",
			topic, p.Partition, p.Offset, p.Error)
	}
	return fmt.Sprintf("%s[%d]@%s",
		topic, p.Partition, p.Offset)
}

// TopicPartitions is a slice of TopicPartitions that also implements
// the sort interface
type TopicPartitions []TopicPartition

func (tps TopicPartitions) Len() int {
	return len(tps)
}

func (tps TopicPartitions) Less(i, j int) bool {
	if *tps[i].Topic < *tps[j].Topic {
		return true
	} else if *tps[i].Topic > *tps[j].Topic {
		return false
	}
	return tps[i].Partition < tps[j].Partition
}

func (tps TopicPartitions) Swap(i, j int) {
	tps[i], tps[j] = tps[j], tps[i]
}

// new_cparts_from_TopicPartitions creates a new C rd_kafka_topic_partition_list_t
// from a TopicPartition array.
func newCPartsFromTopicPartitions(partitions []TopicPartition) (cparts *C.rd_kafka_topic_partition_list_t) {
	cparts = C.rd_kafka_topic_partition_list_new(C.int(len(partitions)))
	for _, part := range partitions {
		ctopic := C.CString(*part.Topic)
		defer C.free(unsafe.Pointer(ctopic))
		rktpar := C.rd_kafka_topic_partition_list_add(cparts, ctopic, C.int32_t(part.Partition))
		rktpar.offset = C.int64_t(part.Offset)

		if part.Metadata != nil {
			cmetadata := C.CString(*part.Metadata)
			rktpar.metadata = unsafe.Pointer(cmetadata)
			rktpar.metadata_size = C.size_t(len(*part.Metadata))
		}
	}

	return cparts
}

func setupTopicPartitionFromCrktpar(partition *TopicPartition, crktpar *C.rd_kafka_topic_partition_t) {

	topic := C.GoString(crktpar.topic)
	partition.Topic = &topic
	partition.Partition = int32(crktpar.partition)
	partition.Offset = Offset(crktpar.offset)
	if crktpar.metadata_size > 0 {
		size := C.int(crktpar.metadata_size)
		cstr := (*C.char)(unsafe.Pointer(crktpar.metadata))
		metadata := C.GoStringN(cstr, size)
		partition.Metadata = &metadata
	}
	if crktpar.err != C.RD_KAFKA_RESP_ERR_NO_ERROR {
		partition.Error = newError(crktpar.err)
	}
}

func newTopicPartitionsFromCparts(cparts *C.rd_kafka_topic_partition_list_t) (partitions []TopicPartition) {

	partcnt := int(cparts.cnt)

	partitions = make([]TopicPartition, partcnt)
	for i := 0; i < partcnt; i++ {
		crktpar := C._c_rdkafka_topic_partition_list_entry(cparts, C.int(i))
		setupTopicPartitionFromCrktpar(&partitions[i], crktpar)
	}

	return partitions
}

// LibraryVersion returns the underlying librdkafka library version as a
// (version_int, version_str) tuple.
func LibraryVersion() (int, string) {
	ver := (int)(C.rd_kafka_version())
	verstr := C.GoString(C.rd_kafka_version_str())
	return ver, verstr
}
drone.yml 3 years ago			`/**`
			`* Copyright 2016 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 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`

			`import (`
			`"fmt"`
			`// Make sure librdkafka_vendor/ sub-directory is included in vendor pulls.`
			`_ "github.com/confluentinc/confluent-kafka-go/kafka/librdkafka_vendor"`
			`"unsafe"`
			`)`

			`/*`
			`#include <stdlib.h>`
			`#include <string.h>`
			`#include "select_rdkafka.h"`

			`static rd_kafka_topic_partition_t _c_rdkafka_topic_partition_list_entry(rd_kafka_topic_partition_list_t rktparlist, int idx) {`
			`return idx < rktparlist->cnt ? &rktparlist->elems[idx] : NULL;`
			`}`
			`*/`
			`import "C"`

			`// PartitionAny represents any partition (for partitioning),`
			`// or unspecified value (for all other cases)`
			`const PartitionAny = int32(C.RD_KAFKA_PARTITION_UA)`

			`// TopicPartition is a generic placeholder for a Topic+Partition and optionally Offset.`
			`type TopicPartition struct {`
			`Topic *string`
			`Partition int32`
			`Offset Offset`
			`Metadata *string`
			`Error error`
			`}`

			`func (p TopicPartition) String() string {`
			`topic := "<null>"`
			`if p.Topic != nil {`
			`topic = *p.Topic`
			`}`
			`if p.Error != nil {`
			`return fmt.Sprintf("%s[%d]@%s(%s)",`
			`topic, p.Partition, p.Offset, p.Error)`
			`}`
			`return fmt.Sprintf("%s[%d]@%s",`
			`topic, p.Partition, p.Offset)`
			`}`

			`// TopicPartitions is a slice of TopicPartitions that also implements`
			`// the sort interface`
			`type TopicPartitions []TopicPartition`

			`func (tps TopicPartitions) Len() int {`
			`return len(tps)`
			`}`

			`func (tps TopicPartitions) Less(i, j int) bool {`
			`if tps[i].Topic < tps[j].Topic {`
			`return true`
			`} else if tps[i].Topic > tps[j].Topic {`
			`return false`
			`}`
			`return tps[i].Partition < tps[j].Partition`
			`}`

			`func (tps TopicPartitions) Swap(i, j int) {`
			`tps[i], tps[j] = tps[j], tps[i]`
			`}`

			`// new_cparts_from_TopicPartitions creates a new C rd_kafka_topic_partition_list_t`
			`// from a TopicPartition array.`
			`func newCPartsFromTopicPartitions(partitions []TopicPartition) (cparts *C.rd_kafka_topic_partition_list_t) {`
			`cparts = C.rd_kafka_topic_partition_list_new(C.int(len(partitions)))`
			`for _, part := range partitions {`
			`ctopic := C.CString(*part.Topic)`
			`defer C.free(unsafe.Pointer(ctopic))`
			`rktpar := C.rd_kafka_topic_partition_list_add(cparts, ctopic, C.int32_t(part.Partition))`
			`rktpar.offset = C.int64_t(part.Offset)`

			`if part.Metadata != nil {`
			`cmetadata := C.CString(*part.Metadata)`
			`rktpar.metadata = unsafe.Pointer(cmetadata)`
			`rktpar.metadata_size = C.size_t(len(*part.Metadata))`
			`}`
			`}`

			`return cparts`
			`}`

			`func setupTopicPartitionFromCrktpar(partition TopicPartition, crktpar C.rd_kafka_topic_partition_t) {`

			`topic := C.GoString(crktpar.topic)`
			`partition.Topic = &topic`
			`partition.Partition = int32(crktpar.partition)`
			`partition.Offset = Offset(crktpar.offset)`
			`if crktpar.metadata_size > 0 {`
			`size := C.int(crktpar.metadata_size)`
			`cstr := (*C.char)(unsafe.Pointer(crktpar.metadata))`
			`metadata := C.GoStringN(cstr, size)`
			`partition.Metadata = &metadata`
			`}`
			`if crktpar.err != C.RD_KAFKA_RESP_ERR_NO_ERROR {`
			`partition.Error = newError(crktpar.err)`
			`}`
			`}`

			`func newTopicPartitionsFromCparts(cparts *C.rd_kafka_topic_partition_list_t) (partitions []TopicPartition) {`

			`partcnt := int(cparts.cnt)`

			`partitions = make([]TopicPartition, partcnt)`
			`for i := 0; i < partcnt; i++ {`
			`crktpar := C._c_rdkafka_topic_partition_list_entry(cparts, C.int(i))`
			`setupTopicPartitionFromCrktpar(&partitions[i], crktpar)`
			`}`

			`return partitions`
			`}`

			`// LibraryVersion returns the underlying librdkafka library version as a`
			`// (version_int, version_str) tuple.`
			`func LibraryVersion() (int, string) {`
			`ver := (int)(C.rd_kafka_version())`
			`verstr := C.GoString(C.rd_kafka_version_str())`
			`return ver, verstr`
			`}`