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mirror of https://github.com/go-gitea/gitea synced 2024-11-14 14:14:25 +00:00
gitea/modules/queue/workergroup.go
wxiaoguang 18f26cfbf7
Improve queue and logger context (#24924)
Before there was a "graceful function": RunWithShutdownFns, it's mainly
for some modules which doesn't support context.

The old queue system doesn't work well with context, so the old queues
need it.

After the queue refactoring, the new queue works with context well, so,
use Golang context as much as possible, the `RunWithShutdownFns` could
be removed (replaced by RunWithCancel for context cancel mechanism), the
related code could be simplified.

This PR also fixes some legacy queue-init problems, eg:

* typo : archiver: "unable to create codes indexer queue" => "unable to
create repo-archive queue"
* no nil check for failed queues, which causes unfriendly panic

After this PR, many goroutines could have better display name:

![image](https://github.com/go-gitea/gitea/assets/2114189/701b2a9b-8065-4137-aeaa-0bda2b34604a)

![image](https://github.com/go-gitea/gitea/assets/2114189/f1d5f50f-0534-40f0-b0be-f2c9daa5fe92)
2023-05-26 07:31:55 +00:00

338 lines
9.9 KiB
Go

// Copyright 2023 The Gitea Authors. All rights reserved.
// SPDX-License-Identifier: MIT
package queue
import (
"context"
"runtime/pprof"
"sync"
"sync/atomic"
"time"
"code.gitea.io/gitea/modules/log"
)
var (
infiniteTimerC = make(chan time.Time)
batchDebounceDuration = 100 * time.Millisecond
workerIdleDuration = 1 * time.Second
shutdownDefaultTimeout = 2 * time.Second
unhandledItemRequeueDuration atomic.Int64 // to avoid data race during test
)
func init() {
unhandledItemRequeueDuration.Store(int64(5 * time.Second))
}
// workerGroup is a group of workers to work with a WorkerPoolQueue
type workerGroup[T any] struct {
q *WorkerPoolQueue[T]
wg sync.WaitGroup
ctxWorker context.Context
ctxWorkerCancel context.CancelFunc
batchBuffer []T
popItemChan chan []byte
popItemErr chan error
}
func (wg *workerGroup[T]) doPrepareWorkerContext() {
wg.ctxWorker, wg.ctxWorkerCancel = context.WithCancel(wg.q.ctxRun)
}
// doDispatchBatchToWorker dispatches a batch of items to worker's channel.
// If the channel is full, it tries to start a new worker if possible.
func (q *WorkerPoolQueue[T]) doDispatchBatchToWorker(wg *workerGroup[T], flushChan chan flushType) {
batch := wg.batchBuffer
wg.batchBuffer = nil
if len(batch) == 0 {
return
}
full := false
select {
case q.batchChan <- batch:
default:
full = true
}
q.workerNumMu.Lock()
noWorker := q.workerNum == 0
if full || noWorker {
if q.workerNum < q.workerMaxNum || noWorker && q.workerMaxNum <= 0 {
q.workerNum++
q.doStartNewWorker(wg)
}
}
q.workerNumMu.Unlock()
if full {
select {
case q.batchChan <- batch:
case flush := <-flushChan:
q.doWorkerHandle(batch)
q.doFlush(wg, flush)
case <-q.ctxRun.Done():
wg.batchBuffer = batch // return the batch to buffer, the "doRun" function will handle it
}
}
}
// doWorkerHandle calls the safeHandler to handle a batch of items, and it increases/decreases the active worker number.
// If the context has been canceled, it should not be caller because the "Push" still needs the context, in such case, call q.safeHandler directly
func (q *WorkerPoolQueue[T]) doWorkerHandle(batch []T) {
q.workerNumMu.Lock()
q.workerActiveNum++
q.workerNumMu.Unlock()
defer func() {
q.workerNumMu.Lock()
q.workerActiveNum--
q.workerNumMu.Unlock()
}()
unhandled := q.safeHandler(batch...)
// if none of the items were handled, it should back-off for a few seconds
// in this case the handler (eg: document indexer) may have encountered some errors/failures
if len(unhandled) == len(batch) && unhandledItemRequeueDuration.Load() != 0 {
log.Error("Queue %q failed to handle batch of %d items, backoff for a few seconds", q.GetName(), len(batch))
select {
case <-q.ctxRun.Done():
case <-time.After(time.Duration(unhandledItemRequeueDuration.Load())):
}
}
for _, item := range unhandled {
if err := q.Push(item); err != nil {
if !q.basePushForShutdown(item) {
log.Error("Failed to requeue item for queue %q when calling handler: %v", q.GetName(), err)
}
}
}
}
// basePushForShutdown tries to requeue items into the base queue when the WorkerPoolQueue is shutting down.
// If the queue is shutting down, it returns true and try to push the items
// Otherwise it does nothing and returns false
func (q *WorkerPoolQueue[T]) basePushForShutdown(items ...T) bool {
shutdownTimeout := time.Duration(q.shutdownTimeout.Load())
if shutdownTimeout == 0 {
return false
}
ctxShutdown, ctxShutdownCancel := context.WithTimeout(context.Background(), shutdownTimeout)
defer ctxShutdownCancel()
for _, item := range items {
// if there is still any error, the queue can do nothing instead of losing the items
if err := q.baseQueue.PushItem(ctxShutdown, q.marshal(item)); err != nil {
log.Error("Failed to requeue item for queue %q when shutting down: %v", q.GetName(), err)
}
}
return true
}
// doStartNewWorker starts a new worker for the queue, the worker reads from worker's channel and handles the items.
func (q *WorkerPoolQueue[T]) doStartNewWorker(wp *workerGroup[T]) {
wp.wg.Add(1)
go func() {
defer wp.wg.Done()
log.Debug("Queue %q starts new worker", q.GetName())
defer log.Debug("Queue %q stops idle worker", q.GetName())
t := time.NewTicker(workerIdleDuration)
keepWorking := true
stopWorking := func() {
q.workerNumMu.Lock()
keepWorking = false
q.workerNum--
q.workerNumMu.Unlock()
}
for keepWorking {
select {
case <-wp.ctxWorker.Done():
stopWorking()
case batch, ok := <-q.batchChan:
if !ok {
stopWorking()
} else {
q.doWorkerHandle(batch)
t.Reset(workerIdleDuration)
}
case <-t.C:
q.workerNumMu.Lock()
keepWorking = q.workerNum <= 1
if !keepWorking {
q.workerNum--
}
q.workerNumMu.Unlock()
}
}
}()
}
// doFlush flushes the queue: it tries to read all items from the queue and handles them.
// It is for testing purpose only. It's not designed to work for a cluster.
func (q *WorkerPoolQueue[T]) doFlush(wg *workerGroup[T], flush flushType) {
log.Debug("Queue %q starts flushing", q.GetName())
defer log.Debug("Queue %q finishes flushing", q.GetName())
// stop all workers, and prepare a new worker context to start new workers
wg.ctxWorkerCancel()
wg.wg.Wait()
defer func() {
close(flush)
wg.doPrepareWorkerContext()
}()
// drain the batch channel first
loop:
for {
select {
case batch := <-q.batchChan:
q.doWorkerHandle(batch)
default:
break loop
}
}
// drain the popItem channel
emptyCounter := 0
for {
select {
case data, dataOk := <-wg.popItemChan:
if !dataOk {
return
}
emptyCounter = 0
if v, jsonOk := q.unmarshal(data); !jsonOk {
continue
} else {
q.doWorkerHandle([]T{v})
}
case err := <-wg.popItemErr:
if !q.isCtxRunCanceled() {
log.Error("Failed to pop item from queue %q (doFlush): %v", q.GetName(), err)
}
return
case <-q.ctxRun.Done():
log.Debug("Queue %q is shutting down", q.GetName())
return
case <-time.After(20 * time.Millisecond):
// There is no reliable way to make sure all queue items are consumed by the Flush, there always might be some items stored in some buffers/temp variables.
// If we run Gitea in a cluster, we can even not guarantee all items are consumed in a deterministic instance.
// Luckily, the "Flush" trick is only used in tests, so far so good.
if cnt, _ := q.baseQueue.Len(q.ctxRun); cnt == 0 && len(wg.popItemChan) == 0 {
emptyCounter++
}
if emptyCounter >= 2 {
return
}
}
}
}
func (q *WorkerPoolQueue[T]) isCtxRunCanceled() bool {
select {
case <-q.ctxRun.Done():
return true
default:
return false
}
}
var skipFlushChan = make(chan flushType) // an empty flush chan, used to skip reading other flush requests
// doRun is the main loop of the queue. All related "doXxx" functions are executed in its context.
func (q *WorkerPoolQueue[T]) doRun() {
pprof.SetGoroutineLabels(q.ctxRun)
log.Debug("Queue %q starts running", q.GetName())
defer log.Debug("Queue %q stops running", q.GetName())
wg := &workerGroup[T]{q: q}
wg.doPrepareWorkerContext()
wg.popItemChan, wg.popItemErr = popItemByChan(q.ctxRun, q.baseQueue.PopItem)
defer func() {
q.ctxRunCancel()
// drain all data on the fly
// since the queue is shutting down, the items can't be dispatched to workers because the context is canceled
// it can't call doWorkerHandle either, because there is no chance to push unhandled items back to the queue
var unhandled []T
close(q.batchChan)
for batch := range q.batchChan {
unhandled = append(unhandled, batch...)
}
unhandled = append(unhandled, wg.batchBuffer...)
for data := range wg.popItemChan {
if v, ok := q.unmarshal(data); ok {
unhandled = append(unhandled, v)
}
}
shutdownTimeout := time.Duration(q.shutdownTimeout.Load())
if shutdownTimeout != 0 {
// if there is a shutdown context, try to push the items back to the base queue
q.basePushForShutdown(unhandled...)
workerDone := make(chan struct{})
// the only way to wait for the workers, because the handlers do not have context to wait for
go func() { wg.wg.Wait(); close(workerDone) }()
select {
case <-workerDone:
case <-time.After(shutdownTimeout):
log.Error("Queue %q is shutting down, but workers are still running after timeout", q.GetName())
}
} else {
// if there is no shutdown context, just call the handler to try to handle the items. if the handler fails again, the items are lost
q.safeHandler(unhandled...)
}
close(q.shutdownDone)
}()
var batchDispatchC <-chan time.Time = infiniteTimerC
for {
select {
case data, dataOk := <-wg.popItemChan:
if !dataOk {
return
}
if v, jsonOk := q.unmarshal(data); !jsonOk {
testRecorder.Record("pop:corrupted:%s", data) // in rare cases the levelqueue(leveldb) might be corrupted
continue
} else {
wg.batchBuffer = append(wg.batchBuffer, v)
}
if len(wg.batchBuffer) >= q.batchLength {
q.doDispatchBatchToWorker(wg, q.flushChan)
} else if batchDispatchC == infiniteTimerC {
batchDispatchC = time.After(batchDebounceDuration)
} // else: batchDispatchC is already a debounce timer, it will be triggered soon
case <-batchDispatchC:
batchDispatchC = infiniteTimerC
q.doDispatchBatchToWorker(wg, q.flushChan)
case flush := <-q.flushChan:
// before flushing, it needs to try to dispatch the batch to worker first, in case there is no worker running
// after the flushing, there is at least one worker running, so "doFlush" could wait for workers to finish
// since we are already in a "flush" operation, so the dispatching function shouldn't read the flush chan.
q.doDispatchBatchToWorker(wg, skipFlushChan)
q.doFlush(wg, flush)
case err := <-wg.popItemErr:
if !q.isCtxRunCanceled() {
log.Error("Failed to pop item from queue %q (doRun): %v", q.GetName(), err)
}
return
case <-q.ctxRun.Done():
log.Debug("Queue %q is shutting down", q.GetName())
return
}
}
}