go-common/vendor/github.com/Shopify/sarama/offset_manager.go

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2019-04-22 10:49:16 +00:00
package sarama
import (
"sync"
"time"
)
// Offset Manager
// OffsetManager uses Kafka to store and fetch consumed partition offsets.
type OffsetManager interface {
// ManagePartition creates a PartitionOffsetManager on the given topic/partition.
// It will return an error if this OffsetManager is already managing the given
// topic/partition.
ManagePartition(topic string, partition int32) (PartitionOffsetManager, error)
// Close stops the OffsetManager from managing offsets. It is required to call
// this function before an OffsetManager object passes out of scope, as it
// will otherwise leak memory. You must call this after all the
// PartitionOffsetManagers are closed.
Close() error
}
type offsetManager struct {
client Client
conf *Config
group string
ticker *time.Ticker
broker *Broker
brokerLock sync.RWMutex
poms map[string]map[int32]*partitionOffsetManager
pomsLock sync.Mutex
closeOnce sync.Once
closing chan none
closed chan none
}
// NewOffsetManagerFromClient creates a new OffsetManager from the given client.
// It is still necessary to call Close() on the underlying client when finished with the partition manager.
func NewOffsetManagerFromClient(group string, client Client) (OffsetManager, error) {
// Check that we are not dealing with a closed Client before processing any other arguments
if client.Closed() {
return nil, ErrClosedClient
}
conf := client.Config()
om := &offsetManager{
client: client,
conf: conf,
group: group,
ticker: time.NewTicker(conf.Consumer.Offsets.CommitInterval),
poms: make(map[string]map[int32]*partitionOffsetManager),
closing: make(chan none),
closed: make(chan none),
}
go withRecover(om.mainLoop)
return om, nil
}
func (om *offsetManager) ManagePartition(topic string, partition int32) (PartitionOffsetManager, error) {
pom, err := om.newPartitionOffsetManager(topic, partition)
if err != nil {
return nil, err
}
om.pomsLock.Lock()
defer om.pomsLock.Unlock()
topicManagers := om.poms[topic]
if topicManagers == nil {
topicManagers = make(map[int32]*partitionOffsetManager)
om.poms[topic] = topicManagers
}
if topicManagers[partition] != nil {
return nil, ConfigurationError("That topic/partition is already being managed")
}
topicManagers[partition] = pom
return pom, nil
}
func (om *offsetManager) Close() error {
om.closeOnce.Do(func() {
// exit the mainLoop
close(om.closing)
<-om.closed
// mark all POMs as closed
om.asyncClosePOMs()
// flush one last time
for attempt := 0; attempt <= om.conf.Consumer.Offsets.Retry.Max; attempt++ {
om.flushToBroker()
if om.releasePOMs(false) == 0 {
break
}
}
om.releasePOMs(true)
om.brokerLock.Lock()
om.broker = nil
om.brokerLock.Unlock()
})
return nil
}
func (om *offsetManager) fetchInitialOffset(topic string, partition int32, retries int) (int64, string, error) {
broker, err := om.coordinator()
if err != nil {
if retries <= 0 {
return 0, "", err
}
return om.fetchInitialOffset(topic, partition, retries-1)
}
req := new(OffsetFetchRequest)
req.Version = 1
req.ConsumerGroup = om.group
req.AddPartition(topic, partition)
resp, err := broker.FetchOffset(req)
if err != nil {
if retries <= 0 {
return 0, "", err
}
om.releaseCoordinator(broker)
return om.fetchInitialOffset(topic, partition, retries-1)
}
block := resp.GetBlock(topic, partition)
if block == nil {
return 0, "", ErrIncompleteResponse
}
switch block.Err {
case ErrNoError:
return block.Offset, block.Metadata, nil
case ErrNotCoordinatorForConsumer:
if retries <= 0 {
return 0, "", block.Err
}
om.releaseCoordinator(broker)
return om.fetchInitialOffset(topic, partition, retries-1)
case ErrOffsetsLoadInProgress:
if retries <= 0 {
return 0, "", block.Err
}
select {
case <-om.closing:
return 0, "", block.Err
case <-time.After(om.conf.Metadata.Retry.Backoff):
}
return om.fetchInitialOffset(topic, partition, retries-1)
default:
return 0, "", block.Err
}
}
func (om *offsetManager) coordinator() (*Broker, error) {
om.brokerLock.RLock()
broker := om.broker
om.brokerLock.RUnlock()
if broker != nil {
return broker, nil
}
om.brokerLock.Lock()
defer om.brokerLock.Unlock()
if broker := om.broker; broker != nil {
return broker, nil
}
if err := om.client.RefreshCoordinator(om.group); err != nil {
return nil, err
}
broker, err := om.client.Coordinator(om.group)
if err != nil {
return nil, err
}
om.broker = broker
return broker, nil
}
func (om *offsetManager) releaseCoordinator(b *Broker) {
om.brokerLock.Lock()
if om.broker == b {
om.broker = nil
}
om.brokerLock.Unlock()
}
func (om *offsetManager) mainLoop() {
defer om.ticker.Stop()
defer close(om.closed)
for {
select {
case <-om.ticker.C:
om.flushToBroker()
om.releasePOMs(false)
case <-om.closing:
return
}
}
}
func (om *offsetManager) flushToBroker() {
req := om.constructRequest()
if req == nil {
return
}
broker, err := om.coordinator()
if err != nil {
om.handleError(err)
return
}
resp, err := broker.CommitOffset(req)
if err != nil {
om.handleError(err)
om.releaseCoordinator(broker)
_ = broker.Close()
return
}
om.handleResponse(broker, req, resp)
}
func (om *offsetManager) constructRequest() *OffsetCommitRequest {
var r *OffsetCommitRequest
var perPartitionTimestamp int64
if om.conf.Consumer.Offsets.Retention == 0 {
perPartitionTimestamp = ReceiveTime
r = &OffsetCommitRequest{
Version: 1,
ConsumerGroup: om.group,
ConsumerGroupGeneration: GroupGenerationUndefined,
}
} else {
r = &OffsetCommitRequest{
Version: 2,
RetentionTime: int64(om.conf.Consumer.Offsets.Retention / time.Millisecond),
ConsumerGroup: om.group,
ConsumerGroupGeneration: GroupGenerationUndefined,
}
}
om.pomsLock.Lock()
defer om.pomsLock.Unlock()
for _, topicManagers := range om.poms {
for _, pom := range topicManagers {
pom.lock.Lock()
if pom.dirty {
r.AddBlock(pom.topic, pom.partition, pom.offset, perPartitionTimestamp, pom.metadata)
}
pom.lock.Unlock()
}
}
if len(r.blocks) > 0 {
return r
}
return nil
}
func (om *offsetManager) handleResponse(broker *Broker, req *OffsetCommitRequest, resp *OffsetCommitResponse) {
om.pomsLock.Lock()
defer om.pomsLock.Unlock()
for _, topicManagers := range om.poms {
for _, pom := range topicManagers {
if req.blocks[pom.topic] == nil || req.blocks[pom.topic][pom.partition] == nil {
continue
}
var err KError
var ok bool
if resp.Errors[pom.topic] == nil {
pom.handleError(ErrIncompleteResponse)
continue
}
if err, ok = resp.Errors[pom.topic][pom.partition]; !ok {
pom.handleError(ErrIncompleteResponse)
continue
}
switch err {
case ErrNoError:
block := req.blocks[pom.topic][pom.partition]
pom.updateCommitted(block.offset, block.metadata)
case ErrNotLeaderForPartition, ErrLeaderNotAvailable,
ErrConsumerCoordinatorNotAvailable, ErrNotCoordinatorForConsumer:
// not a critical error, we just need to redispatch
om.releaseCoordinator(broker)
case ErrOffsetMetadataTooLarge, ErrInvalidCommitOffsetSize:
// nothing we can do about this, just tell the user and carry on
pom.handleError(err)
case ErrOffsetsLoadInProgress:
// nothing wrong but we didn't commit, we'll get it next time round
break
case ErrUnknownTopicOrPartition:
// let the user know *and* try redispatching - if topic-auto-create is
// enabled, redispatching should trigger a metadata req and create the
// topic; if not then re-dispatching won't help, but we've let the user
// know and it shouldn't hurt either (see https://github.com/Shopify/sarama/issues/706)
fallthrough
default:
// dunno, tell the user and try redispatching
pom.handleError(err)
om.releaseCoordinator(broker)
}
}
}
}
func (om *offsetManager) handleError(err error) {
om.pomsLock.Lock()
defer om.pomsLock.Unlock()
for _, topicManagers := range om.poms {
for _, pom := range topicManagers {
pom.handleError(err)
}
}
}
func (om *offsetManager) asyncClosePOMs() {
om.pomsLock.Lock()
defer om.pomsLock.Unlock()
for _, topicManagers := range om.poms {
for _, pom := range topicManagers {
pom.AsyncClose()
}
}
}
// Releases/removes closed POMs once they are clean (or when forced)
func (om *offsetManager) releasePOMs(force bool) (remaining int) {
om.pomsLock.Lock()
defer om.pomsLock.Unlock()
for topic, topicManagers := range om.poms {
for partition, pom := range topicManagers {
pom.lock.Lock()
releaseDue := pom.done && (force || !pom.dirty)
pom.lock.Unlock()
if releaseDue {
pom.release()
delete(om.poms[topic], partition)
if len(om.poms[topic]) == 0 {
delete(om.poms, topic)
}
}
}
remaining += len(om.poms[topic])
}
return
}
// Partition Offset Manager
// PartitionOffsetManager uses Kafka to store and fetch consumed partition offsets. You MUST call Close()
// on a partition offset manager to avoid leaks, it will not be garbage-collected automatically when it passes
// out of scope.
type PartitionOffsetManager interface {
// NextOffset returns the next offset that should be consumed for the managed
// partition, accompanied by metadata which can be used to reconstruct the state
// of the partition consumer when it resumes. NextOffset() will return
// `config.Consumer.Offsets.Initial` and an empty metadata string if no offset
// was committed for this partition yet.
NextOffset() (int64, string)
// MarkOffset marks the provided offset, alongside a metadata string
// that represents the state of the partition consumer at that point in time. The
// metadata string can be used by another consumer to restore that state, so it
// can resume consumption.
//
// To follow upstream conventions, you are expected to mark the offset of the
// next message to read, not the last message read. Thus, when calling `MarkOffset`
// you should typically add one to the offset of the last consumed message.
//
// Note: calling MarkOffset does not necessarily commit the offset to the backend
// store immediately for efficiency reasons, and it may never be committed if
// your application crashes. This means that you may end up processing the same
// message twice, and your processing should ideally be idempotent.
MarkOffset(offset int64, metadata string)
// ResetOffset resets to the provided offset, alongside a metadata string that
// represents the state of the partition consumer at that point in time. Reset
// acts as a counterpart to MarkOffset, the difference being that it allows to
// reset an offset to an earlier or smaller value, where MarkOffset only
// allows incrementing the offset. cf MarkOffset for more details.
ResetOffset(offset int64, metadata string)
// Errors returns a read channel of errors that occur during offset management, if
// enabled. By default, errors are logged and not returned over this channel. If
// you want to implement any custom error handling, set your config's
// Consumer.Return.Errors setting to true, and read from this channel.
Errors() <-chan *ConsumerError
// AsyncClose initiates a shutdown of the PartitionOffsetManager. This method will
// return immediately, after which you should wait until the 'errors' channel has
// been drained and closed. It is required to call this function, or Close before
// a consumer object passes out of scope, as it will otherwise leak memory. You
// must call this before calling Close on the underlying client.
AsyncClose()
// Close stops the PartitionOffsetManager from managing offsets. It is required to
// call this function (or AsyncClose) before a PartitionOffsetManager object
// passes out of scope, as it will otherwise leak memory. You must call this
// before calling Close on the underlying client.
Close() error
}
type partitionOffsetManager struct {
parent *offsetManager
topic string
partition int32
lock sync.Mutex
offset int64
metadata string
dirty bool
done bool
releaseOnce sync.Once
errors chan *ConsumerError
}
func (om *offsetManager) newPartitionOffsetManager(topic string, partition int32) (*partitionOffsetManager, error) {
offset, metadata, err := om.fetchInitialOffset(topic, partition, om.conf.Metadata.Retry.Max)
if err != nil {
return nil, err
}
return &partitionOffsetManager{
parent: om,
topic: topic,
partition: partition,
errors: make(chan *ConsumerError, om.conf.ChannelBufferSize),
offset: offset,
metadata: metadata,
}, nil
}
func (pom *partitionOffsetManager) Errors() <-chan *ConsumerError {
return pom.errors
}
func (pom *partitionOffsetManager) MarkOffset(offset int64, metadata string) {
pom.lock.Lock()
defer pom.lock.Unlock()
if offset > pom.offset {
pom.offset = offset
pom.metadata = metadata
pom.dirty = true
}
}
func (pom *partitionOffsetManager) ResetOffset(offset int64, metadata string) {
pom.lock.Lock()
defer pom.lock.Unlock()
if offset <= pom.offset {
pom.offset = offset
pom.metadata = metadata
pom.dirty = true
}
}
func (pom *partitionOffsetManager) updateCommitted(offset int64, metadata string) {
pom.lock.Lock()
defer pom.lock.Unlock()
if pom.offset == offset && pom.metadata == metadata {
pom.dirty = false
}
}
func (pom *partitionOffsetManager) NextOffset() (int64, string) {
pom.lock.Lock()
defer pom.lock.Unlock()
if pom.offset >= 0 {
return pom.offset, pom.metadata
}
return pom.parent.conf.Consumer.Offsets.Initial, ""
}
func (pom *partitionOffsetManager) AsyncClose() {
pom.lock.Lock()
pom.done = true
pom.lock.Unlock()
}
func (pom *partitionOffsetManager) Close() error {
pom.AsyncClose()
var errors ConsumerErrors
for err := range pom.errors {
errors = append(errors, err)
}
if len(errors) > 0 {
return errors
}
return nil
}
func (pom *partitionOffsetManager) handleError(err error) {
cErr := &ConsumerError{
Topic: pom.topic,
Partition: pom.partition,
Err: err,
}
if pom.parent.conf.Consumer.Return.Errors {
pom.errors <- cErr
} else {
Logger.Println(cErr)
}
}
func (pom *partitionOffsetManager) release() {
pom.releaseOnce.Do(func() {
go close(pom.errors)
})
}