finclip-app-manager/vendor/github.com/Shopify/sarama/async_producer.go

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2023-11-02 18:36:36 +08:00
package sarama
import (
"encoding/binary"
"fmt"
"sync"
"time"
"github.com/eapache/go-resiliency/breaker"
"github.com/eapache/queue"
)
// AsyncProducer publishes Kafka messages using a non-blocking API. It routes messages
// to the correct broker for the provided topic-partition, refreshing metadata as appropriate,
// and parses responses for errors. You must read from the Errors() channel or the
// producer will deadlock. You must call Close() or AsyncClose() on a producer to avoid
// leaks: it will not be garbage-collected automatically when it passes out of
// scope.
type AsyncProducer interface {
// AsyncClose triggers a shutdown of the producer. The shutdown has completed
// when both the Errors and Successes channels have been closed. When calling
// AsyncClose, you *must* continue to read from those channels in order to
// drain the results of any messages in flight.
AsyncClose()
// Close shuts down the producer and waits for any buffered messages to be
// flushed. You must call this function before a producer object passes out of
// scope, as it may otherwise leak memory. You must call this before calling
// Close on the underlying client.
Close() error
// Input is the input channel for the user to write messages to that they
// wish to send.
Input() chan<- *ProducerMessage
// Successes is the success output channel back to the user when Return.Successes is
// enabled. If Return.Successes is true, you MUST read from this channel or the
// Producer will deadlock. It is suggested that you send and read messages
// together in a single select statement.
Successes() <-chan *ProducerMessage
// Errors is the error output channel back to the user. You MUST read from this
// channel or the Producer will deadlock when the channel is full. Alternatively,
// you can set Producer.Return.Errors in your config to false, which prevents
// errors to be returned.
Errors() <-chan *ProducerError
}
// transactionManager keeps the state necessary to ensure idempotent production
type transactionManager struct {
producerID int64
producerEpoch int16
sequenceNumbers map[string]int32
mutex sync.Mutex
}
const (
noProducerID = -1
noProducerEpoch = -1
)
func (t *transactionManager) getAndIncrementSequenceNumber(topic string, partition int32) int32 {
key := fmt.Sprintf("%s-%d", topic, partition)
t.mutex.Lock()
defer t.mutex.Unlock()
sequence := t.sequenceNumbers[key]
t.sequenceNumbers[key] = sequence + 1
return sequence
}
func newTransactionManager(conf *Config, client Client) (*transactionManager, error) {
txnmgr := &transactionManager{
producerID: noProducerID,
producerEpoch: noProducerEpoch,
}
if conf.Producer.Idempotent {
initProducerIDResponse, err := client.InitProducerID()
if err != nil {
return nil, err
}
txnmgr.producerID = initProducerIDResponse.ProducerID
txnmgr.producerEpoch = initProducerIDResponse.ProducerEpoch
txnmgr.sequenceNumbers = make(map[string]int32)
txnmgr.mutex = sync.Mutex{}
Logger.Printf("Obtained a ProducerId: %d and ProducerEpoch: %d\n", txnmgr.producerID, txnmgr.producerEpoch)
}
return txnmgr, nil
}
type asyncProducer struct {
client Client
conf *Config
errors chan *ProducerError
input, successes, retries chan *ProducerMessage
inFlight sync.WaitGroup
brokers map[*Broker]*brokerProducer
brokerRefs map[*brokerProducer]int
brokerLock sync.Mutex
txnmgr *transactionManager
}
// NewAsyncProducer creates a new AsyncProducer using the given broker addresses and configuration.
func NewAsyncProducer(addrs []string, conf *Config) (AsyncProducer, error) {
client, err := NewClient(addrs, conf)
if err != nil {
return nil, err
}
return newAsyncProducer(client)
}
// NewAsyncProducerFromClient creates a new Producer using the given client. It is still
// necessary to call Close() on the underlying client when shutting down this producer.
func NewAsyncProducerFromClient(client Client) (AsyncProducer, error) {
// For clients passed in by the client, ensure we don't
// call Close() on it.
cli := &nopCloserClient{client}
return newAsyncProducer(cli)
}
func newAsyncProducer(client Client) (AsyncProducer, error) {
// Check that we are not dealing with a closed Client before processing any other arguments
if client.Closed() {
return nil, ErrClosedClient
}
txnmgr, err := newTransactionManager(client.Config(), client)
if err != nil {
return nil, err
}
p := &asyncProducer{
client: client,
conf: client.Config(),
errors: make(chan *ProducerError),
input: make(chan *ProducerMessage),
successes: make(chan *ProducerMessage),
retries: make(chan *ProducerMessage),
brokers: make(map[*Broker]*brokerProducer),
brokerRefs: make(map[*brokerProducer]int),
txnmgr: txnmgr,
}
// launch our singleton dispatchers
go withRecover(p.dispatcher)
go withRecover(p.retryHandler)
return p, nil
}
type flagSet int8
const (
syn flagSet = 1 << iota // first message from partitionProducer to brokerProducer
fin // final message from partitionProducer to brokerProducer and back
shutdown // start the shutdown process
)
// ProducerMessage is the collection of elements passed to the Producer in order to send a message.
type ProducerMessage struct {
Topic string // The Kafka topic for this message.
// The partitioning key for this message. Pre-existing Encoders include
// StringEncoder and ByteEncoder.
Key Encoder
// The actual message to store in Kafka. Pre-existing Encoders include
// StringEncoder and ByteEncoder.
Value Encoder
// The headers are key-value pairs that are transparently passed
// by Kafka between producers and consumers.
Headers []RecordHeader
// This field is used to hold arbitrary data you wish to include so it
// will be available when receiving on the Successes and Errors channels.
// Sarama completely ignores this field and is only to be used for
// pass-through data.
Metadata interface{}
// Below this point are filled in by the producer as the message is processed
// Offset is the offset of the message stored on the broker. This is only
// guaranteed to be defined if the message was successfully delivered and
// RequiredAcks is not NoResponse.
Offset int64
// Partition is the partition that the message was sent to. This is only
// guaranteed to be defined if the message was successfully delivered.
Partition int32
// Timestamp can vary in behaviour depending on broker configuration, being
// in either one of the CreateTime or LogAppendTime modes (default CreateTime),
// and requiring version at least 0.10.0.
//
// When configured to CreateTime, the timestamp is specified by the producer
// either by explicitly setting this field, or when the message is added
// to a produce set.
//
// When configured to LogAppendTime, the timestamp assigned to the message
// by the broker. This is only guaranteed to be defined if the message was
// successfully delivered and RequiredAcks is not NoResponse.
Timestamp time.Time
retries int
flags flagSet
expectation chan *ProducerError
sequenceNumber int32
}
const producerMessageOverhead = 26 // the metadata overhead of CRC, flags, etc.
func (m *ProducerMessage) byteSize(version int) int {
var size int
if version >= 2 {
size = maximumRecordOverhead
for _, h := range m.Headers {
size += len(h.Key) + len(h.Value) + 2*binary.MaxVarintLen32
}
} else {
size = producerMessageOverhead
}
if m.Key != nil {
size += m.Key.Length()
}
if m.Value != nil {
size += m.Value.Length()
}
return size
}
func (m *ProducerMessage) clear() {
m.flags = 0
m.retries = 0
}
// ProducerError is the type of error generated when the producer fails to deliver a message.
// It contains the original ProducerMessage as well as the actual error value.
type ProducerError struct {
Msg *ProducerMessage
Err error
}
func (pe ProducerError) Error() string {
return fmt.Sprintf("kafka: Failed to produce message to topic %s: %s", pe.Msg.Topic, pe.Err)
}
// ProducerErrors is a type that wraps a batch of "ProducerError"s and implements the Error interface.
// It can be returned from the Producer's Close method to avoid the need to manually drain the Errors channel
// when closing a producer.
type ProducerErrors []*ProducerError
func (pe ProducerErrors) Error() string {
return fmt.Sprintf("kafka: Failed to deliver %d messages.", len(pe))
}
func (p *asyncProducer) Errors() <-chan *ProducerError {
return p.errors
}
func (p *asyncProducer) Successes() <-chan *ProducerMessage {
return p.successes
}
func (p *asyncProducer) Input() chan<- *ProducerMessage {
return p.input
}
func (p *asyncProducer) Close() error {
p.AsyncClose()
if p.conf.Producer.Return.Successes {
go withRecover(func() {
for range p.successes {
}
})
}
var errors ProducerErrors
if p.conf.Producer.Return.Errors {
for event := range p.errors {
errors = append(errors, event)
}
} else {
<-p.errors
}
if len(errors) > 0 {
return errors
}
return nil
}
func (p *asyncProducer) AsyncClose() {
go withRecover(p.shutdown)
}
// singleton
// dispatches messages by topic
func (p *asyncProducer) dispatcher() {
handlers := make(map[string]chan<- *ProducerMessage)
shuttingDown := false
for msg := range p.input {
if msg == nil {
Logger.Println("Something tried to send a nil message, it was ignored.")
continue
}
if msg.flags&shutdown != 0 {
shuttingDown = true
p.inFlight.Done()
continue
} else if msg.retries == 0 {
if shuttingDown {
// we can't just call returnError here because that decrements the wait group,
// which hasn't been incremented yet for this message, and shouldn't be
pErr := &ProducerError{Msg: msg, Err: ErrShuttingDown}
if p.conf.Producer.Return.Errors {
p.errors <- pErr
} else {
Logger.Println(pErr)
}
continue
}
p.inFlight.Add(1)
}
version := 1
if p.conf.Version.IsAtLeast(V0_11_0_0) {
version = 2
} else if msg.Headers != nil {
p.returnError(msg, ConfigurationError("Producing headers requires Kafka at least v0.11"))
continue
}
if msg.byteSize(version) > p.conf.Producer.MaxMessageBytes {
p.returnError(msg, ErrMessageSizeTooLarge)
continue
}
handler := handlers[msg.Topic]
if handler == nil {
handler = p.newTopicProducer(msg.Topic)
handlers[msg.Topic] = handler
}
handler <- msg
}
for _, handler := range handlers {
close(handler)
}
}
// one per topic
// partitions messages, then dispatches them by partition
type topicProducer struct {
parent *asyncProducer
topic string
input <-chan *ProducerMessage
breaker *breaker.Breaker
handlers map[int32]chan<- *ProducerMessage
partitioner Partitioner
}
func (p *asyncProducer) newTopicProducer(topic string) chan<- *ProducerMessage {
input := make(chan *ProducerMessage, p.conf.ChannelBufferSize)
tp := &topicProducer{
parent: p,
topic: topic,
input: input,
breaker: breaker.New(3, 1, 10*time.Second),
handlers: make(map[int32]chan<- *ProducerMessage),
partitioner: p.conf.Producer.Partitioner(topic),
}
go withRecover(tp.dispatch)
return input
}
func (tp *topicProducer) dispatch() {
for msg := range tp.input {
if msg.retries == 0 {
if err := tp.partitionMessage(msg); err != nil {
tp.parent.returnError(msg, err)
continue
}
}
// All messages being retried (sent or not) have already had their retry count updated
if tp.parent.conf.Producer.Idempotent && msg.retries == 0 {
msg.sequenceNumber = tp.parent.txnmgr.getAndIncrementSequenceNumber(msg.Topic, msg.Partition)
}
handler := tp.handlers[msg.Partition]
if handler == nil {
handler = tp.parent.newPartitionProducer(msg.Topic, msg.Partition)
tp.handlers[msg.Partition] = handler
}
handler <- msg
}
for _, handler := range tp.handlers {
close(handler)
}
}
func (tp *topicProducer) partitionMessage(msg *ProducerMessage) error {
var partitions []int32
err := tp.breaker.Run(func() (err error) {
var requiresConsistency = false
if ep, ok := tp.partitioner.(DynamicConsistencyPartitioner); ok {
requiresConsistency = ep.MessageRequiresConsistency(msg)
} else {
requiresConsistency = tp.partitioner.RequiresConsistency()
}
if requiresConsistency {
partitions, err = tp.parent.client.Partitions(msg.Topic)
} else {
partitions, err = tp.parent.client.WritablePartitions(msg.Topic)
}
return
})
if err != nil {
return err
}
numPartitions := int32(len(partitions))
if numPartitions == 0 {
return ErrLeaderNotAvailable
}
choice, err := tp.partitioner.Partition(msg, numPartitions)
if err != nil {
return err
} else if choice < 0 || choice >= numPartitions {
return ErrInvalidPartition
}
msg.Partition = partitions[choice]
return nil
}
// one per partition per topic
// dispatches messages to the appropriate broker
// also responsible for maintaining message order during retries
type partitionProducer struct {
parent *asyncProducer
topic string
partition int32
input <-chan *ProducerMessage
leader *Broker
breaker *breaker.Breaker
brokerProducer *brokerProducer
// highWatermark tracks the "current" retry level, which is the only one where we actually let messages through,
// all other messages get buffered in retryState[msg.retries].buf to preserve ordering
// retryState[msg.retries].expectChaser simply tracks whether we've seen a fin message for a given level (and
// therefore whether our buffer is complete and safe to flush)
highWatermark int
retryState []partitionRetryState
}
type partitionRetryState struct {
buf []*ProducerMessage
expectChaser bool
}
func (p *asyncProducer) newPartitionProducer(topic string, partition int32) chan<- *ProducerMessage {
input := make(chan *ProducerMessage, p.conf.ChannelBufferSize)
pp := &partitionProducer{
parent: p,
topic: topic,
partition: partition,
input: input,
breaker: breaker.New(3, 1, 10*time.Second),
retryState: make([]partitionRetryState, p.conf.Producer.Retry.Max+1),
}
go withRecover(pp.dispatch)
return input
}
func (pp *partitionProducer) backoff(retries int) {
var backoff time.Duration
if pp.parent.conf.Producer.Retry.BackoffFunc != nil {
maxRetries := pp.parent.conf.Producer.Retry.Max
backoff = pp.parent.conf.Producer.Retry.BackoffFunc(retries, maxRetries)
} else {
backoff = pp.parent.conf.Producer.Retry.Backoff
}
if backoff > 0 {
time.Sleep(backoff)
}
}
func (pp *partitionProducer) dispatch() {
// try to prefetch the leader; if this doesn't work, we'll do a proper call to `updateLeader`
// on the first message
pp.leader, _ = pp.parent.client.Leader(pp.topic, pp.partition)
if pp.leader != nil {
pp.brokerProducer = pp.parent.getBrokerProducer(pp.leader)
pp.parent.inFlight.Add(1) // we're generating a syn message; track it so we don't shut down while it's still inflight
pp.brokerProducer.input <- &ProducerMessage{Topic: pp.topic, Partition: pp.partition, flags: syn}
}
defer func() {
if pp.brokerProducer != nil {
pp.parent.unrefBrokerProducer(pp.leader, pp.brokerProducer)
}
}()
for msg := range pp.input {
if pp.brokerProducer != nil && pp.brokerProducer.abandoned != nil {
select {
case <-pp.brokerProducer.abandoned:
// a message on the abandoned channel means that our current broker selection is out of date
Logger.Printf("producer/leader/%s/%d abandoning broker %d\n", pp.topic, pp.partition, pp.leader.ID())
pp.parent.unrefBrokerProducer(pp.leader, pp.brokerProducer)
pp.brokerProducer = nil
time.Sleep(pp.parent.conf.Producer.Retry.Backoff)
default:
// producer connection is still open.
}
}
if msg.retries > pp.highWatermark {
// a new, higher, retry level; handle it and then back off
pp.newHighWatermark(msg.retries)
pp.backoff(msg.retries)
} else if pp.highWatermark > 0 {
// we are retrying something (else highWatermark would be 0) but this message is not a *new* retry level
if msg.retries < pp.highWatermark {
// in fact this message is not even the current retry level, so buffer it for now (unless it's a just a fin)
if msg.flags&fin == fin {
pp.retryState[msg.retries].expectChaser = false
pp.parent.inFlight.Done() // this fin is now handled and will be garbage collected
} else {
pp.retryState[msg.retries].buf = append(pp.retryState[msg.retries].buf, msg)
}
continue
} else if msg.flags&fin == fin {
// this message is of the current retry level (msg.retries == highWatermark) and the fin flag is set,
// meaning this retry level is done and we can go down (at least) one level and flush that
pp.retryState[pp.highWatermark].expectChaser = false
pp.flushRetryBuffers()
pp.parent.inFlight.Done() // this fin is now handled and will be garbage collected
continue
}
}
// if we made it this far then the current msg contains real data, and can be sent to the next goroutine
// without breaking any of our ordering guarantees
if pp.brokerProducer == nil {
if err := pp.updateLeader(); err != nil {
pp.parent.returnError(msg, err)
pp.backoff(msg.retries)
continue
}
Logger.Printf("producer/leader/%s/%d selected broker %d\n", pp.topic, pp.partition, pp.leader.ID())
}
pp.brokerProducer.input <- msg
}
}
func (pp *partitionProducer) newHighWatermark(hwm int) {
Logger.Printf("producer/leader/%s/%d state change to [retrying-%d]\n", pp.topic, pp.partition, hwm)
pp.highWatermark = hwm
// send off a fin so that we know when everything "in between" has made it
// back to us and we can safely flush the backlog (otherwise we risk re-ordering messages)
pp.retryState[pp.highWatermark].expectChaser = true
pp.parent.inFlight.Add(1) // we're generating a fin message; track it so we don't shut down while it's still inflight
pp.brokerProducer.input <- &ProducerMessage{Topic: pp.topic, Partition: pp.partition, flags: fin, retries: pp.highWatermark - 1}
// a new HWM means that our current broker selection is out of date
Logger.Printf("producer/leader/%s/%d abandoning broker %d\n", pp.topic, pp.partition, pp.leader.ID())
pp.parent.unrefBrokerProducer(pp.leader, pp.brokerProducer)
pp.brokerProducer = nil
}
func (pp *partitionProducer) flushRetryBuffers() {
Logger.Printf("producer/leader/%s/%d state change to [flushing-%d]\n", pp.topic, pp.partition, pp.highWatermark)
for {
pp.highWatermark--
if pp.brokerProducer == nil {
if err := pp.updateLeader(); err != nil {
pp.parent.returnErrors(pp.retryState[pp.highWatermark].buf, err)
goto flushDone
}
Logger.Printf("producer/leader/%s/%d selected broker %d\n", pp.topic, pp.partition, pp.leader.ID())
}
for _, msg := range pp.retryState[pp.highWatermark].buf {
pp.brokerProducer.input <- msg
}
flushDone:
pp.retryState[pp.highWatermark].buf = nil
if pp.retryState[pp.highWatermark].expectChaser {
Logger.Printf("producer/leader/%s/%d state change to [retrying-%d]\n", pp.topic, pp.partition, pp.highWatermark)
break
} else if pp.highWatermark == 0 {
Logger.Printf("producer/leader/%s/%d state change to [normal]\n", pp.topic, pp.partition)
break
}
}
}
func (pp *partitionProducer) updateLeader() error {
return pp.breaker.Run(func() (err error) {
if err = pp.parent.client.RefreshMetadata(pp.topic); err != nil {
return err
}
if pp.leader, err = pp.parent.client.Leader(pp.topic, pp.partition); err != nil {
return err
}
pp.brokerProducer = pp.parent.getBrokerProducer(pp.leader)
pp.parent.inFlight.Add(1) // we're generating a syn message; track it so we don't shut down while it's still inflight
pp.brokerProducer.input <- &ProducerMessage{Topic: pp.topic, Partition: pp.partition, flags: syn}
return nil
})
}
// one per broker; also constructs an associated flusher
func (p *asyncProducer) newBrokerProducer(broker *Broker) *brokerProducer {
var (
input = make(chan *ProducerMessage)
bridge = make(chan *produceSet)
responses = make(chan *brokerProducerResponse)
)
bp := &brokerProducer{
parent: p,
broker: broker,
input: input,
output: bridge,
responses: responses,
stopchan: make(chan struct{}),
buffer: newProduceSet(p),
currentRetries: make(map[string]map[int32]error),
}
go withRecover(bp.run)
// minimal bridge to make the network response `select`able
go withRecover(func() {
for set := range bridge {
request := set.buildRequest()
response, err := broker.Produce(request)
responses <- &brokerProducerResponse{
set: set,
err: err,
res: response,
}
}
close(responses)
})
if p.conf.Producer.Retry.Max <= 0 {
bp.abandoned = make(chan struct{})
}
return bp
}
type brokerProducerResponse struct {
set *produceSet
err error
res *ProduceResponse
}
// groups messages together into appropriately-sized batches for sending to the broker
// handles state related to retries etc
type brokerProducer struct {
parent *asyncProducer
broker *Broker
input chan *ProducerMessage
output chan<- *produceSet
responses <-chan *brokerProducerResponse
abandoned chan struct{}
stopchan chan struct{}
buffer *produceSet
timer <-chan time.Time
timerFired bool
closing error
currentRetries map[string]map[int32]error
}
func (bp *brokerProducer) run() {
var output chan<- *produceSet
Logger.Printf("producer/broker/%d starting up\n", bp.broker.ID())
for {
select {
case msg, ok := <-bp.input:
if !ok {
Logger.Printf("producer/broker/%d input chan closed\n", bp.broker.ID())
bp.shutdown()
return
}
if msg == nil {
continue
}
if msg.flags&syn == syn {
Logger.Printf("producer/broker/%d state change to [open] on %s/%d\n",
bp.broker.ID(), msg.Topic, msg.Partition)
if bp.currentRetries[msg.Topic] == nil {
bp.currentRetries[msg.Topic] = make(map[int32]error)
}
bp.currentRetries[msg.Topic][msg.Partition] = nil
bp.parent.inFlight.Done()
continue
}
if reason := bp.needsRetry(msg); reason != nil {
bp.parent.retryMessage(msg, reason)
if bp.closing == nil && msg.flags&fin == fin {
// we were retrying this partition but we can start processing again
delete(bp.currentRetries[msg.Topic], msg.Partition)
Logger.Printf("producer/broker/%d state change to [closed] on %s/%d\n",
bp.broker.ID(), msg.Topic, msg.Partition)
}
continue
}
if bp.buffer.wouldOverflow(msg) {
if err := bp.waitForSpace(msg); err != nil {
bp.parent.retryMessage(msg, err)
continue
}
}
if err := bp.buffer.add(msg); err != nil {
bp.parent.returnError(msg, err)
continue
}
if bp.parent.conf.Producer.Flush.Frequency > 0 && bp.timer == nil {
bp.timer = time.After(bp.parent.conf.Producer.Flush.Frequency)
}
case <-bp.timer:
bp.timerFired = true
case output <- bp.buffer:
bp.rollOver()
case response, ok := <-bp.responses:
if ok {
bp.handleResponse(response)
}
case <-bp.stopchan:
Logger.Printf(
"producer/broker/%d run loop asked to stop\n", bp.broker.ID())
return
}
if bp.timerFired || bp.buffer.readyToFlush() {
output = bp.output
} else {
output = nil
}
}
}
func (bp *brokerProducer) shutdown() {
for !bp.buffer.empty() {
select {
case response := <-bp.responses:
bp.handleResponse(response)
case bp.output <- bp.buffer:
bp.rollOver()
}
}
close(bp.output)
for response := range bp.responses {
bp.handleResponse(response)
}
close(bp.stopchan)
Logger.Printf("producer/broker/%d shut down\n", bp.broker.ID())
}
func (bp *brokerProducer) needsRetry(msg *ProducerMessage) error {
if bp.closing != nil {
return bp.closing
}
return bp.currentRetries[msg.Topic][msg.Partition]
}
func (bp *brokerProducer) waitForSpace(msg *ProducerMessage) error {
Logger.Printf("producer/broker/%d maximum request accumulated, waiting for space\n", bp.broker.ID())
for {
select {
case response := <-bp.responses:
bp.handleResponse(response)
// handling a response can change our state, so re-check some things
if reason := bp.needsRetry(msg); reason != nil {
return reason
} else if !bp.buffer.wouldOverflow(msg) {
return nil
}
case bp.output <- bp.buffer:
bp.rollOver()
return nil
}
}
}
func (bp *brokerProducer) rollOver() {
bp.timer = nil
bp.timerFired = false
bp.buffer = newProduceSet(bp.parent)
}
func (bp *brokerProducer) handleResponse(response *brokerProducerResponse) {
if response.err != nil {
bp.handleError(response.set, response.err)
} else {
bp.handleSuccess(response.set, response.res)
}
if bp.buffer.empty() {
bp.rollOver() // this can happen if the response invalidated our buffer
}
}
func (bp *brokerProducer) handleSuccess(sent *produceSet, response *ProduceResponse) {
// we iterate through the blocks in the request set, not the response, so that we notice
// if the response is missing a block completely
var retryTopics []string
sent.eachPartition(func(topic string, partition int32, pSet *partitionSet) {
if response == nil {
// this only happens when RequiredAcks is NoResponse, so we have to assume success
bp.parent.returnSuccesses(pSet.msgs)
return
}
block := response.GetBlock(topic, partition)
if block == nil {
bp.parent.returnErrors(pSet.msgs, ErrIncompleteResponse)
return
}
switch block.Err {
// Success
case ErrNoError:
if bp.parent.conf.Version.IsAtLeast(V0_10_0_0) && !block.Timestamp.IsZero() {
for _, msg := range pSet.msgs {
msg.Timestamp = block.Timestamp
}
}
for i, msg := range pSet.msgs {
msg.Offset = block.Offset + int64(i)
}
bp.parent.returnSuccesses(pSet.msgs)
// Duplicate
case ErrDuplicateSequenceNumber:
bp.parent.returnSuccesses(pSet.msgs)
// Retriable errors
case ErrInvalidMessage, ErrUnknownTopicOrPartition, ErrLeaderNotAvailable, ErrNotLeaderForPartition,
ErrRequestTimedOut, ErrNotEnoughReplicas, ErrNotEnoughReplicasAfterAppend:
if bp.parent.conf.Producer.Retry.Max <= 0 {
bp.parent.abandonBrokerConnection(bp.broker)
bp.parent.returnErrors(pSet.msgs, block.Err)
} else {
retryTopics = append(retryTopics, topic)
}
// Other non-retriable errors
default:
if bp.parent.conf.Producer.Retry.Max <= 0 {
bp.parent.abandonBrokerConnection(bp.broker)
}
bp.parent.returnErrors(pSet.msgs, block.Err)
}
})
if len(retryTopics) > 0 {
if bp.parent.conf.Producer.Idempotent {
err := bp.parent.client.RefreshMetadata(retryTopics...)
if err != nil {
Logger.Printf("Failed refreshing metadata because of %v\n", err)
}
}
sent.eachPartition(func(topic string, partition int32, pSet *partitionSet) {
block := response.GetBlock(topic, partition)
if block == nil {
// handled in the previous "eachPartition" loop
return
}
switch block.Err {
case ErrInvalidMessage, ErrUnknownTopicOrPartition, ErrLeaderNotAvailable, ErrNotLeaderForPartition,
ErrRequestTimedOut, ErrNotEnoughReplicas, ErrNotEnoughReplicasAfterAppend:
Logger.Printf("producer/broker/%d state change to [retrying] on %s/%d because %v\n",
bp.broker.ID(), topic, partition, block.Err)
if bp.currentRetries[topic] == nil {
bp.currentRetries[topic] = make(map[int32]error)
}
bp.currentRetries[topic][partition] = block.Err
if bp.parent.conf.Producer.Idempotent {
go bp.parent.retryBatch(topic, partition, pSet, block.Err)
} else {
bp.parent.retryMessages(pSet.msgs, block.Err)
}
// dropping the following messages has the side effect of incrementing their retry count
bp.parent.retryMessages(bp.buffer.dropPartition(topic, partition), block.Err)
}
})
}
}
func (p *asyncProducer) retryBatch(topic string, partition int32, pSet *partitionSet, kerr KError) {
Logger.Printf("Retrying batch for %v-%d because of %s\n", topic, partition, kerr)
produceSet := newProduceSet(p)
produceSet.msgs[topic] = make(map[int32]*partitionSet)
produceSet.msgs[topic][partition] = pSet
produceSet.bufferBytes += pSet.bufferBytes
produceSet.bufferCount += len(pSet.msgs)
for _, msg := range pSet.msgs {
if msg.retries >= p.conf.Producer.Retry.Max {
p.returnError(msg, kerr)
return
}
msg.retries++
}
// it's expected that a metadata refresh has been requested prior to calling retryBatch
leader, err := p.client.Leader(topic, partition)
if err != nil {
Logger.Printf("Failed retrying batch for %v-%d because of %v while looking up for new leader\n", topic, partition, err)
for _, msg := range pSet.msgs {
p.returnError(msg, kerr)
}
return
}
bp := p.getBrokerProducer(leader)
bp.output <- produceSet
}
func (bp *brokerProducer) handleError(sent *produceSet, err error) {
switch err.(type) {
case PacketEncodingError:
sent.eachPartition(func(topic string, partition int32, pSet *partitionSet) {
bp.parent.returnErrors(pSet.msgs, err)
})
default:
Logger.Printf("producer/broker/%d state change to [closing] because %s\n", bp.broker.ID(), err)
bp.parent.abandonBrokerConnection(bp.broker)
_ = bp.broker.Close()
bp.closing = err
sent.eachPartition(func(topic string, partition int32, pSet *partitionSet) {
bp.parent.retryMessages(pSet.msgs, err)
})
bp.buffer.eachPartition(func(topic string, partition int32, pSet *partitionSet) {
bp.parent.retryMessages(pSet.msgs, err)
})
bp.rollOver()
}
}
// singleton
// effectively a "bridge" between the flushers and the dispatcher in order to avoid deadlock
// based on https://godoc.org/github.com/eapache/channels#InfiniteChannel
func (p *asyncProducer) retryHandler() {
var msg *ProducerMessage
buf := queue.New()
for {
if buf.Length() == 0 {
msg = <-p.retries
} else {
select {
case msg = <-p.retries:
case p.input <- buf.Peek().(*ProducerMessage):
buf.Remove()
continue
}
}
if msg == nil {
return
}
buf.Add(msg)
}
}
// utility functions
func (p *asyncProducer) shutdown() {
Logger.Println("Producer shutting down.")
p.inFlight.Add(1)
p.input <- &ProducerMessage{flags: shutdown}
p.inFlight.Wait()
err := p.client.Close()
if err != nil {
Logger.Println("producer/shutdown failed to close the embedded client:", err)
}
close(p.input)
close(p.retries)
close(p.errors)
close(p.successes)
}
func (p *asyncProducer) returnError(msg *ProducerMessage, err error) {
msg.clear()
pErr := &ProducerError{Msg: msg, Err: err}
if p.conf.Producer.Return.Errors {
p.errors <- pErr
} else {
Logger.Println(pErr)
}
p.inFlight.Done()
}
func (p *asyncProducer) returnErrors(batch []*ProducerMessage, err error) {
for _, msg := range batch {
p.returnError(msg, err)
}
}
func (p *asyncProducer) returnSuccesses(batch []*ProducerMessage) {
for _, msg := range batch {
if p.conf.Producer.Return.Successes {
msg.clear()
p.successes <- msg
}
p.inFlight.Done()
}
}
func (p *asyncProducer) retryMessage(msg *ProducerMessage, err error) {
if msg.retries >= p.conf.Producer.Retry.Max {
p.returnError(msg, err)
} else {
msg.retries++
p.retries <- msg
}
}
func (p *asyncProducer) retryMessages(batch []*ProducerMessage, err error) {
for _, msg := range batch {
p.retryMessage(msg, err)
}
}
func (p *asyncProducer) getBrokerProducer(broker *Broker) *brokerProducer {
p.brokerLock.Lock()
defer p.brokerLock.Unlock()
bp := p.brokers[broker]
if bp == nil {
bp = p.newBrokerProducer(broker)
p.brokers[broker] = bp
p.brokerRefs[bp] = 0
}
p.brokerRefs[bp]++
return bp
}
func (p *asyncProducer) unrefBrokerProducer(broker *Broker, bp *brokerProducer) {
p.brokerLock.Lock()
defer p.brokerLock.Unlock()
p.brokerRefs[bp]--
if p.brokerRefs[bp] == 0 {
close(bp.input)
delete(p.brokerRefs, bp)
if p.brokers[broker] == bp {
delete(p.brokers, broker)
}
}
}
func (p *asyncProducer) abandonBrokerConnection(broker *Broker) {
p.brokerLock.Lock()
defer p.brokerLock.Unlock()
bc, ok := p.brokers[broker]
if ok && bc.abandoned != nil {
close(bc.abandoned)
}
delete(p.brokers, broker)
}