githaven/vendor/github.com/olivere/elastic/v7/bulk_processor.go
Lunny Xiao 5dbf36f356
Issue search support elasticsearch (#9428)
* Issue search support elasticsearch

* Fix lint

* Add indexer name on app.ini

* add a warnning on SearchIssuesByKeyword

* improve code
2020-02-13 14:06:17 +08:00

657 lines
19 KiB
Go

// Copyright 2012-present Oliver Eilhard. All rights reserved.
// Use of this source code is governed by a MIT-license.
// See http://olivere.mit-license.org/license.txt for details.
package elastic
import (
"context"
"errors"
"net"
"sync"
"sync/atomic"
"time"
)
var (
// ErrBulkItemRetry is returned in BulkProcessor from a worker when
// a response item needs to be retried.
ErrBulkItemRetry = errors.New("elastic: uncommitted bulk response items")
defaultRetryItemStatusCodes = []int{408, 429, 503, 507}
)
// BulkProcessorService allows to easily process bulk requests. It allows setting
// policies when to flush new bulk requests, e.g. based on a number of actions,
// on the size of the actions, and/or to flush periodically. It also allows
// to control the number of concurrent bulk requests allowed to be executed
// in parallel.
//
// BulkProcessorService, by default, commits either every 1000 requests or when the
// (estimated) size of the bulk requests exceeds 5 MB. However, it does not
// commit periodically. BulkProcessorService also does retry by default, using
// an exponential backoff algorithm. It also will automatically re-enqueue items
// returned with a status of 408, 429, 503 or 507. You can change this
// behavior with RetryItemStatusCodes.
//
// The caller is responsible for setting the index and type on every
// bulk request added to BulkProcessorService.
//
// BulkProcessorService takes ideas from the BulkProcessor of the
// Elasticsearch Java API as documented in
// https://www.elastic.co/guide/en/elasticsearch/client/java-api/current/java-docs-bulk-processor.html.
type BulkProcessorService struct {
c *Client
beforeFn BulkBeforeFunc
afterFn BulkAfterFunc
name string // name of processor
numWorkers int // # of workers (>= 1)
bulkActions int // # of requests after which to commit
bulkSize int // # of bytes after which to commit
flushInterval time.Duration // periodic flush interval
wantStats bool // indicates whether to gather statistics
backoff Backoff // a custom Backoff to use for errors
retryItemStatusCodes []int // array of status codes for bulk response line items that may be retried
}
// NewBulkProcessorService creates a new BulkProcessorService.
func NewBulkProcessorService(client *Client) *BulkProcessorService {
return &BulkProcessorService{
c: client,
numWorkers: 1,
bulkActions: 1000,
bulkSize: 5 << 20, // 5 MB
backoff: NewExponentialBackoff(
time.Duration(200)*time.Millisecond,
time.Duration(10000)*time.Millisecond,
),
retryItemStatusCodes: defaultRetryItemStatusCodes,
}
}
// BulkBeforeFunc defines the signature of callbacks that are executed
// before a commit to Elasticsearch.
type BulkBeforeFunc func(executionId int64, requests []BulkableRequest)
// BulkAfterFunc defines the signature of callbacks that are executed
// after a commit to Elasticsearch. The err parameter signals an error.
type BulkAfterFunc func(executionId int64, requests []BulkableRequest, response *BulkResponse, err error)
// Before specifies a function to be executed before bulk requests get committed
// to Elasticsearch.
func (s *BulkProcessorService) Before(fn BulkBeforeFunc) *BulkProcessorService {
s.beforeFn = fn
return s
}
// After specifies a function to be executed when bulk requests have been
// committed to Elasticsearch. The After callback executes both when the
// commit was successful as well as on failures.
func (s *BulkProcessorService) After(fn BulkAfterFunc) *BulkProcessorService {
s.afterFn = fn
return s
}
// Name is an optional name to identify this bulk processor.
func (s *BulkProcessorService) Name(name string) *BulkProcessorService {
s.name = name
return s
}
// Workers is the number of concurrent workers allowed to be
// executed. Defaults to 1 and must be greater or equal to 1.
func (s *BulkProcessorService) Workers(num int) *BulkProcessorService {
s.numWorkers = num
return s
}
// BulkActions specifies when to flush based on the number of actions
// currently added. Defaults to 1000 and can be set to -1 to be disabled.
func (s *BulkProcessorService) BulkActions(bulkActions int) *BulkProcessorService {
s.bulkActions = bulkActions
return s
}
// BulkSize specifies when to flush based on the size (in bytes) of the actions
// currently added. Defaults to 5 MB and can be set to -1 to be disabled.
func (s *BulkProcessorService) BulkSize(bulkSize int) *BulkProcessorService {
s.bulkSize = bulkSize
return s
}
// FlushInterval specifies when to flush at the end of the given interval.
// This is disabled by default. If you want the bulk processor to
// operate completely asynchronously, set both BulkActions and BulkSize to
// -1 and set the FlushInterval to a meaningful interval.
func (s *BulkProcessorService) FlushInterval(interval time.Duration) *BulkProcessorService {
s.flushInterval = interval
return s
}
// Stats tells bulk processor to gather stats while running.
// Use Stats to return the stats. This is disabled by default.
func (s *BulkProcessorService) Stats(wantStats bool) *BulkProcessorService {
s.wantStats = wantStats
return s
}
// Backoff sets the backoff strategy to use for errors.
func (s *BulkProcessorService) Backoff(backoff Backoff) *BulkProcessorService {
s.backoff = backoff
return s
}
// RetryItemStatusCodes sets an array of status codes that indicate that a bulk
// response line item should be retried.
func (s *BulkProcessorService) RetryItemStatusCodes(retryItemStatusCodes ...int) *BulkProcessorService {
s.retryItemStatusCodes = retryItemStatusCodes
return s
}
// Do creates a new BulkProcessor and starts it.
// Consider the BulkProcessor as a running instance that accepts bulk requests
// and commits them to Elasticsearch, spreading the work across one or more
// workers.
//
// You can interoperate with the BulkProcessor returned by Do, e.g. Start and
// Stop (or Close) it.
//
// Context is an optional context that is passed into the bulk request
// service calls. In contrast to other operations, this context is used in
// a long running process. You could use it to pass e.g. loggers, but you
// shouldn't use it for cancellation.
//
// Calling Do several times returns new BulkProcessors. You probably don't
// want to do this. BulkProcessorService implements just a builder pattern.
func (s *BulkProcessorService) Do(ctx context.Context) (*BulkProcessor, error) {
retryItemStatusCodes := make(map[int]struct{})
for _, code := range s.retryItemStatusCodes {
retryItemStatusCodes[code] = struct{}{}
}
p := newBulkProcessor(
s.c,
s.beforeFn,
s.afterFn,
s.name,
s.numWorkers,
s.bulkActions,
s.bulkSize,
s.flushInterval,
s.wantStats,
s.backoff,
retryItemStatusCodes)
err := p.Start(ctx)
if err != nil {
return nil, err
}
return p, nil
}
// -- Bulk Processor Statistics --
// BulkProcessorStats contains various statistics of a bulk processor
// while it is running. Use the Stats func to return it while running.
type BulkProcessorStats struct {
Flushed int64 // number of times the flush interval has been invoked
Committed int64 // # of times workers committed bulk requests
Indexed int64 // # of requests indexed
Created int64 // # of requests that ES reported as creates (201)
Updated int64 // # of requests that ES reported as updates
Deleted int64 // # of requests that ES reported as deletes
Succeeded int64 // # of requests that ES reported as successful
Failed int64 // # of requests that ES reported as failed
Workers []*BulkProcessorWorkerStats // stats for each worker
}
// BulkProcessorWorkerStats represents per-worker statistics.
type BulkProcessorWorkerStats struct {
Queued int64 // # of requests queued in this worker
LastDuration time.Duration // duration of last commit
}
// newBulkProcessorStats initializes and returns a BulkProcessorStats struct.
func newBulkProcessorStats(workers int) *BulkProcessorStats {
stats := &BulkProcessorStats{
Workers: make([]*BulkProcessorWorkerStats, workers),
}
for i := 0; i < workers; i++ {
stats.Workers[i] = &BulkProcessorWorkerStats{}
}
return stats
}
func (st *BulkProcessorStats) dup() *BulkProcessorStats {
dst := new(BulkProcessorStats)
dst.Flushed = st.Flushed
dst.Committed = st.Committed
dst.Indexed = st.Indexed
dst.Created = st.Created
dst.Updated = st.Updated
dst.Deleted = st.Deleted
dst.Succeeded = st.Succeeded
dst.Failed = st.Failed
for _, src := range st.Workers {
dst.Workers = append(dst.Workers, src.dup())
}
return dst
}
func (st *BulkProcessorWorkerStats) dup() *BulkProcessorWorkerStats {
dst := new(BulkProcessorWorkerStats)
dst.Queued = st.Queued
dst.LastDuration = st.LastDuration
return dst
}
// -- Bulk Processor --
// BulkProcessor encapsulates a task that accepts bulk requests and
// orchestrates committing them to Elasticsearch via one or more workers.
//
// BulkProcessor is returned by setting up a BulkProcessorService and
// calling the Do method.
type BulkProcessor struct {
c *Client
beforeFn BulkBeforeFunc
afterFn BulkAfterFunc
name string
bulkActions int
bulkSize int
numWorkers int
executionId int64
requestsC chan BulkableRequest
workerWg sync.WaitGroup
workers []*bulkWorker
flushInterval time.Duration
flusherStopC chan struct{}
wantStats bool
retryItemStatusCodes map[int]struct{}
backoff Backoff
startedMu sync.Mutex // guards the following block
started bool
statsMu sync.Mutex // guards the following block
stats *BulkProcessorStats
stopReconnC chan struct{} // channel to signal stop reconnection attempts
}
func newBulkProcessor(
client *Client,
beforeFn BulkBeforeFunc,
afterFn BulkAfterFunc,
name string,
numWorkers int,
bulkActions int,
bulkSize int,
flushInterval time.Duration,
wantStats bool,
backoff Backoff,
retryItemStatusCodes map[int]struct{}) *BulkProcessor {
return &BulkProcessor{
c: client,
beforeFn: beforeFn,
afterFn: afterFn,
name: name,
numWorkers: numWorkers,
bulkActions: bulkActions,
bulkSize: bulkSize,
flushInterval: flushInterval,
wantStats: wantStats,
retryItemStatusCodes: retryItemStatusCodes,
backoff: backoff,
}
}
// Start starts the bulk processor. If the processor is already started,
// nil is returned.
func (p *BulkProcessor) Start(ctx context.Context) error {
p.startedMu.Lock()
defer p.startedMu.Unlock()
if p.started {
return nil
}
// We must have at least one worker.
if p.numWorkers < 1 {
p.numWorkers = 1
}
p.requestsC = make(chan BulkableRequest)
p.executionId = 0
p.stats = newBulkProcessorStats(p.numWorkers)
p.stopReconnC = make(chan struct{})
// Create and start up workers.
p.workers = make([]*bulkWorker, p.numWorkers)
for i := 0; i < p.numWorkers; i++ {
p.workerWg.Add(1)
p.workers[i] = newBulkWorker(p, i)
go p.workers[i].work(ctx)
}
// Start the ticker for flush (if enabled)
if int64(p.flushInterval) > 0 {
p.flusherStopC = make(chan struct{})
go p.flusher(p.flushInterval)
}
p.started = true
return nil
}
// Stop is an alias for Close.
func (p *BulkProcessor) Stop() error {
return p.Close()
}
// Close stops the bulk processor previously started with Do.
// If it is already stopped, this is a no-op and nil is returned.
//
// By implementing Close, BulkProcessor implements the io.Closer interface.
func (p *BulkProcessor) Close() error {
p.startedMu.Lock()
defer p.startedMu.Unlock()
// Already stopped? Do nothing.
if !p.started {
return nil
}
// Tell connection checkers to stop
if p.stopReconnC != nil {
close(p.stopReconnC)
p.stopReconnC = nil
}
// Stop flusher (if enabled)
if p.flusherStopC != nil {
p.flusherStopC <- struct{}{}
<-p.flusherStopC
close(p.flusherStopC)
p.flusherStopC = nil
}
// Stop all workers.
close(p.requestsC)
p.workerWg.Wait()
p.started = false
return nil
}
// Stats returns the latest bulk processor statistics.
// Collecting stats must be enabled first by calling Stats(true) on
// the service that created this processor.
func (p *BulkProcessor) Stats() BulkProcessorStats {
p.statsMu.Lock()
defer p.statsMu.Unlock()
return *p.stats.dup()
}
// Add adds a single request to commit by the BulkProcessorService.
//
// The caller is responsible for setting the index and type on the request.
func (p *BulkProcessor) Add(request BulkableRequest) {
p.requestsC <- request
}
// Flush manually asks all workers to commit their outstanding requests.
// It returns only when all workers acknowledge completion.
func (p *BulkProcessor) Flush() error {
p.statsMu.Lock()
p.stats.Flushed++
p.statsMu.Unlock()
for _, w := range p.workers {
w.flushC <- struct{}{}
<-w.flushAckC // wait for completion
}
return nil
}
// flusher is a single goroutine that periodically asks all workers to
// commit their outstanding bulk requests. It is only started if
// FlushInterval is greater than 0.
func (p *BulkProcessor) flusher(interval time.Duration) {
ticker := time.NewTicker(interval)
defer ticker.Stop()
for {
select {
case <-ticker.C: // Periodic flush
p.Flush() // TODO swallow errors here?
case <-p.flusherStopC:
p.flusherStopC <- struct{}{}
return
}
}
}
// -- Bulk Worker --
// bulkWorker encapsulates a single worker, running in a goroutine,
// receiving bulk requests and eventually committing them to Elasticsearch.
// It is strongly bound to a BulkProcessor.
type bulkWorker struct {
p *BulkProcessor
i int
bulkActions int
bulkSize int
service *BulkService
flushC chan struct{}
flushAckC chan struct{}
}
// newBulkWorker creates a new bulkWorker instance.
func newBulkWorker(p *BulkProcessor, i int) *bulkWorker {
return &bulkWorker{
p: p,
i: i,
bulkActions: p.bulkActions,
bulkSize: p.bulkSize,
service: NewBulkService(p.c),
flushC: make(chan struct{}),
flushAckC: make(chan struct{}),
}
}
// work waits for bulk requests and manual flush calls on the respective
// channels and is invoked as a goroutine when the bulk processor is started.
func (w *bulkWorker) work(ctx context.Context) {
defer func() {
w.p.workerWg.Done()
close(w.flushAckC)
close(w.flushC)
}()
var stop bool
for !stop {
var err error
select {
case req, open := <-w.p.requestsC:
if open {
// Received a new request
if _, err = req.Source(); err == nil {
w.service.Add(req)
if w.commitRequired() {
err = w.commit(ctx)
}
}
} else {
// Channel closed: Stop.
stop = true
if w.service.NumberOfActions() > 0 {
err = w.commit(ctx)
}
}
case <-w.flushC:
// Commit outstanding requests
if w.service.NumberOfActions() > 0 {
err = w.commit(ctx)
}
w.flushAckC <- struct{}{}
}
if err != nil {
w.p.c.errorf("elastic: bulk processor %q was unable to perform work: %v", w.p.name, err)
if !stop {
waitForActive := func() {
// Add back pressure to prevent Add calls from filling up the request queue
ready := make(chan struct{})
go w.waitForActiveConnection(ready)
<-ready
}
if _, ok := err.(net.Error); ok {
waitForActive()
} else if IsConnErr(err) {
waitForActive()
}
}
}
}
}
// commit commits the bulk requests in the given service,
// invoking callbacks as specified.
func (w *bulkWorker) commit(ctx context.Context) error {
var res *BulkResponse
// commitFunc will commit bulk requests and, on failure, be retried
// via exponential backoff
commitFunc := func() error {
var err error
// Save requests because they will be reset in service.Do
reqs := w.service.requests
res, err = w.service.Do(ctx)
if err == nil {
// Overall bulk request was OK. But each bulk response item also has a status
if w.p.retryItemStatusCodes != nil && len(w.p.retryItemStatusCodes) > 0 {
// Check res.Items since some might be soft failures
if res.Items != nil && res.Errors {
// res.Items will be 1 to 1 with reqs in same order
for i, item := range res.Items {
for _, result := range item {
if _, found := w.p.retryItemStatusCodes[result.Status]; found {
w.service.Add(reqs[i])
if err == nil {
err = ErrBulkItemRetry
}
}
}
}
}
}
}
return err
}
// notifyFunc will be called if retry fails
notifyFunc := func(err error) {
w.p.c.errorf("elastic: bulk processor %q failed but may retry: %v", w.p.name, err)
}
id := atomic.AddInt64(&w.p.executionId, 1)
// Update # documents in queue before eventual retries
w.p.statsMu.Lock()
if w.p.wantStats {
w.p.stats.Workers[w.i].Queued = int64(len(w.service.requests))
}
w.p.statsMu.Unlock()
// Save requests because they will be reset in commitFunc
reqs := w.service.requests
// Invoke before callback
if w.p.beforeFn != nil {
w.p.beforeFn(id, reqs)
}
// Commit bulk requests
err := RetryNotify(commitFunc, w.p.backoff, notifyFunc)
w.updateStats(res)
if err != nil {
w.p.c.errorf("elastic: bulk processor %q failed: %v", w.p.name, err)
}
// Invoke after callback
if w.p.afterFn != nil {
w.p.afterFn(id, reqs, res, err)
}
return err
}
func (w *bulkWorker) waitForActiveConnection(ready chan<- struct{}) {
defer close(ready)
t := time.NewTicker(5 * time.Second)
defer t.Stop()
client := w.p.c
stopReconnC := w.p.stopReconnC
w.p.c.errorf("elastic: bulk processor %q is waiting for an active connection", w.p.name)
// loop until a health check finds at least 1 active connection or the reconnection channel is closed
for {
select {
case _, ok := <-stopReconnC:
if !ok {
w.p.c.errorf("elastic: bulk processor %q active connection check interrupted", w.p.name)
return
}
case <-t.C:
client.healthcheck(context.Background(), 3*time.Second, true)
if client.mustActiveConn() == nil {
// found an active connection
// exit and signal done to the WaitGroup
return
}
}
}
}
func (w *bulkWorker) updateStats(res *BulkResponse) {
// Update stats
if res != nil {
w.p.statsMu.Lock()
if w.p.wantStats {
w.p.stats.Committed++
if res != nil {
w.p.stats.Indexed += int64(len(res.Indexed()))
w.p.stats.Created += int64(len(res.Created()))
w.p.stats.Updated += int64(len(res.Updated()))
w.p.stats.Deleted += int64(len(res.Deleted()))
w.p.stats.Succeeded += int64(len(res.Succeeded()))
w.p.stats.Failed += int64(len(res.Failed()))
}
w.p.stats.Workers[w.i].Queued = int64(len(w.service.requests))
w.p.stats.Workers[w.i].LastDuration = time.Duration(int64(res.Took)) * time.Millisecond
}
w.p.statsMu.Unlock()
}
}
// commitRequired returns true if the service has to commit its
// bulk requests. This can be either because the number of actions
// or the estimated size in bytes is larger than specified in the
// BulkProcessorService.
func (w *bulkWorker) commitRequired() bool {
if w.bulkActions >= 0 && w.service.NumberOfActions() >= w.bulkActions {
return true
}
if w.bulkSize >= 0 && w.service.EstimatedSizeInBytes() >= int64(w.bulkSize) {
return true
}
return false
}