mirror of
https://codeberg.org/forgejo/forgejo
synced 2024-11-25 11:16:11 +01:00
a609cae9fb
There are a few places in FlushQueueWithContext which make an incorrect assumption about how `select` on multiple channels works. The problem is best expressed by looking at the following example: ```go package main import "fmt" func main() { closedChan := make(chan struct{}) close(closedChan) toClose := make(chan struct{}) count := 0 for { select { case <-closedChan: count++ fmt.Println(count) if count == 2 { close(toClose) } case <-toClose: return } } } ``` This PR double-checks that the contexts are closed outside of checking if there is data in the dataChan. It also rationalises the WorkerPool FlushWithContext because the previous implementation failed to handle pausing correctly. This will probably fix the underlying problem in #22145 Fix #22145 Signed-off-by: Andrew Thornton <art27@cantab.net> Signed-off-by: Andrew Thornton <art27@cantab.net>
614 lines
17 KiB
Go
614 lines
17 KiB
Go
// Copyright 2019 The Gitea Authors. All rights reserved.
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// SPDX-License-Identifier: MIT
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package queue
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import (
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"context"
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"fmt"
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"runtime/pprof"
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"sync"
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"sync/atomic"
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"time"
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"code.gitea.io/gitea/modules/log"
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"code.gitea.io/gitea/modules/process"
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"code.gitea.io/gitea/modules/util"
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)
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// WorkerPool represent a dynamically growable worker pool for a
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// provided handler function. They have an internal channel which
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// they use to detect if there is a block and will grow and shrink in
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// response to demand as per configuration.
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type WorkerPool struct {
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// This field requires to be the first one in the struct.
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// This is to allow 64 bit atomic operations on 32-bit machines.
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// See: https://pkg.go.dev/sync/atomic#pkg-note-BUG & Gitea issue 19518
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numInQueue int64
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lock sync.Mutex
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baseCtx context.Context
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baseCtxCancel context.CancelFunc
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baseCtxFinished process.FinishedFunc
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paused chan struct{}
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resumed chan struct{}
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cond *sync.Cond
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qid int64
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maxNumberOfWorkers int
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numberOfWorkers int
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batchLength int
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handle HandlerFunc
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dataChan chan Data
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blockTimeout time.Duration
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boostTimeout time.Duration
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boostWorkers int
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}
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var (
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_ Flushable = &WorkerPool{}
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_ ManagedPool = &WorkerPool{}
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)
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// WorkerPoolConfiguration is the basic configuration for a WorkerPool
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type WorkerPoolConfiguration struct {
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Name string
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QueueLength int
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BatchLength int
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BlockTimeout time.Duration
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BoostTimeout time.Duration
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BoostWorkers int
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MaxWorkers int
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}
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// NewWorkerPool creates a new worker pool
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func NewWorkerPool(handle HandlerFunc, config WorkerPoolConfiguration) *WorkerPool {
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ctx, cancel, finished := process.GetManager().AddTypedContext(context.Background(), fmt.Sprintf("Queue: %s", config.Name), process.SystemProcessType, false)
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dataChan := make(chan Data, config.QueueLength)
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pool := &WorkerPool{
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baseCtx: ctx,
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baseCtxCancel: cancel,
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baseCtxFinished: finished,
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batchLength: config.BatchLength,
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dataChan: dataChan,
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resumed: closedChan,
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paused: make(chan struct{}),
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handle: handle,
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blockTimeout: config.BlockTimeout,
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boostTimeout: config.BoostTimeout,
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boostWorkers: config.BoostWorkers,
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maxNumberOfWorkers: config.MaxWorkers,
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}
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return pool
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}
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// Done returns when this worker pool's base context has been cancelled
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func (p *WorkerPool) Done() <-chan struct{} {
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return p.baseCtx.Done()
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}
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// Push pushes the data to the internal channel
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func (p *WorkerPool) Push(data Data) {
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atomic.AddInt64(&p.numInQueue, 1)
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p.lock.Lock()
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select {
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case <-p.paused:
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p.lock.Unlock()
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p.dataChan <- data
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return
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default:
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}
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if p.blockTimeout > 0 && p.boostTimeout > 0 && (p.numberOfWorkers <= p.maxNumberOfWorkers || p.maxNumberOfWorkers < 0) {
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if p.numberOfWorkers == 0 {
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p.zeroBoost()
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} else {
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p.lock.Unlock()
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}
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p.pushBoost(data)
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} else {
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p.lock.Unlock()
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p.dataChan <- data
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}
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}
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// HasNoWorkerScaling will return true if the queue has no workers, and has no worker boosting
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func (p *WorkerPool) HasNoWorkerScaling() bool {
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p.lock.Lock()
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defer p.lock.Unlock()
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return p.hasNoWorkerScaling()
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}
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func (p *WorkerPool) hasNoWorkerScaling() bool {
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return p.numberOfWorkers == 0 && (p.boostTimeout == 0 || p.boostWorkers == 0 || p.maxNumberOfWorkers == 0)
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}
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// zeroBoost will add a temporary boost worker for a no worker queue
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// p.lock must be locked at the start of this function BUT it will be unlocked by the end of this function
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// (This is because addWorkers has to be called whilst unlocked)
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func (p *WorkerPool) zeroBoost() {
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ctx, cancel := context.WithTimeout(p.baseCtx, p.boostTimeout)
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mq := GetManager().GetManagedQueue(p.qid)
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boost := p.boostWorkers
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if (boost+p.numberOfWorkers) > p.maxNumberOfWorkers && p.maxNumberOfWorkers >= 0 {
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boost = p.maxNumberOfWorkers - p.numberOfWorkers
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}
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if mq != nil {
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log.Debug("WorkerPool: %d (for %s) has zero workers - adding %d temporary workers for %s", p.qid, mq.Name, boost, p.boostTimeout)
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start := time.Now()
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pid := mq.RegisterWorkers(boost, start, true, start.Add(p.boostTimeout), cancel, false)
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cancel = func() {
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mq.RemoveWorkers(pid)
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}
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} else {
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log.Debug("WorkerPool: %d has zero workers - adding %d temporary workers for %s", p.qid, p.boostWorkers, p.boostTimeout)
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}
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p.lock.Unlock()
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p.addWorkers(ctx, cancel, boost)
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}
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func (p *WorkerPool) pushBoost(data Data) {
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select {
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case p.dataChan <- data:
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default:
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p.lock.Lock()
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if p.blockTimeout <= 0 {
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p.lock.Unlock()
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p.dataChan <- data
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return
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}
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ourTimeout := p.blockTimeout
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timer := time.NewTimer(p.blockTimeout)
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p.lock.Unlock()
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select {
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case p.dataChan <- data:
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util.StopTimer(timer)
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case <-timer.C:
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p.lock.Lock()
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if p.blockTimeout > ourTimeout || (p.numberOfWorkers > p.maxNumberOfWorkers && p.maxNumberOfWorkers >= 0) {
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p.lock.Unlock()
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p.dataChan <- data
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return
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}
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p.blockTimeout *= 2
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boostCtx, boostCtxCancel := context.WithCancel(p.baseCtx)
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mq := GetManager().GetManagedQueue(p.qid)
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boost := p.boostWorkers
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if (boost+p.numberOfWorkers) > p.maxNumberOfWorkers && p.maxNumberOfWorkers >= 0 {
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boost = p.maxNumberOfWorkers - p.numberOfWorkers
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}
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if mq != nil {
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log.Debug("WorkerPool: %d (for %s) Channel blocked for %v - adding %d temporary workers for %s, block timeout now %v", p.qid, mq.Name, ourTimeout, boost, p.boostTimeout, p.blockTimeout)
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start := time.Now()
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pid := mq.RegisterWorkers(boost, start, true, start.Add(p.boostTimeout), boostCtxCancel, false)
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go func() {
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<-boostCtx.Done()
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mq.RemoveWorkers(pid)
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boostCtxCancel()
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}()
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} else {
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log.Debug("WorkerPool: %d Channel blocked for %v - adding %d temporary workers for %s, block timeout now %v", p.qid, ourTimeout, p.boostWorkers, p.boostTimeout, p.blockTimeout)
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}
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go func() {
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<-time.After(p.boostTimeout)
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boostCtxCancel()
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p.lock.Lock()
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p.blockTimeout /= 2
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p.lock.Unlock()
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}()
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p.lock.Unlock()
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p.addWorkers(boostCtx, boostCtxCancel, boost)
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p.dataChan <- data
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}
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}
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}
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// NumberOfWorkers returns the number of current workers in the pool
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func (p *WorkerPool) NumberOfWorkers() int {
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p.lock.Lock()
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defer p.lock.Unlock()
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return p.numberOfWorkers
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}
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// NumberInQueue returns the number of items in the queue
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func (p *WorkerPool) NumberInQueue() int64 {
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return atomic.LoadInt64(&p.numInQueue)
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}
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// MaxNumberOfWorkers returns the maximum number of workers automatically added to the pool
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func (p *WorkerPool) MaxNumberOfWorkers() int {
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p.lock.Lock()
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defer p.lock.Unlock()
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return p.maxNumberOfWorkers
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}
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// BoostWorkers returns the number of workers for a boost
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func (p *WorkerPool) BoostWorkers() int {
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p.lock.Lock()
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defer p.lock.Unlock()
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return p.boostWorkers
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}
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// BoostTimeout returns the timeout of the next boost
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func (p *WorkerPool) BoostTimeout() time.Duration {
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p.lock.Lock()
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defer p.lock.Unlock()
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return p.boostTimeout
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}
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// BlockTimeout returns the timeout til the next boost
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func (p *WorkerPool) BlockTimeout() time.Duration {
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p.lock.Lock()
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defer p.lock.Unlock()
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return p.blockTimeout
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}
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// SetPoolSettings sets the setable boost values
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func (p *WorkerPool) SetPoolSettings(maxNumberOfWorkers, boostWorkers int, timeout time.Duration) {
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p.lock.Lock()
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defer p.lock.Unlock()
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p.maxNumberOfWorkers = maxNumberOfWorkers
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p.boostWorkers = boostWorkers
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p.boostTimeout = timeout
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}
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// SetMaxNumberOfWorkers sets the maximum number of workers automatically added to the pool
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// Changing this number will not change the number of current workers but will change the limit
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// for future additions
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func (p *WorkerPool) SetMaxNumberOfWorkers(newMax int) {
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p.lock.Lock()
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defer p.lock.Unlock()
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p.maxNumberOfWorkers = newMax
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}
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func (p *WorkerPool) commonRegisterWorkers(number int, timeout time.Duration, isFlusher bool) (context.Context, context.CancelFunc) {
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var ctx context.Context
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var cancel context.CancelFunc
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start := time.Now()
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end := start
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hasTimeout := false
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if timeout > 0 {
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ctx, cancel = context.WithTimeout(p.baseCtx, timeout)
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end = start.Add(timeout)
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hasTimeout = true
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} else {
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ctx, cancel = context.WithCancel(p.baseCtx)
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}
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mq := GetManager().GetManagedQueue(p.qid)
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if mq != nil {
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pid := mq.RegisterWorkers(number, start, hasTimeout, end, cancel, isFlusher)
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log.Trace("WorkerPool: %d (for %s) adding %d workers with group id: %d", p.qid, mq.Name, number, pid)
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return ctx, func() {
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mq.RemoveWorkers(pid)
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}
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}
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log.Trace("WorkerPool: %d adding %d workers (no group id)", p.qid, number)
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return ctx, cancel
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}
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// AddWorkers adds workers to the pool - this allows the number of workers to go above the limit
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func (p *WorkerPool) AddWorkers(number int, timeout time.Duration) context.CancelFunc {
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ctx, cancel := p.commonRegisterWorkers(number, timeout, false)
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p.addWorkers(ctx, cancel, number)
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return cancel
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}
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// addWorkers adds workers to the pool
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func (p *WorkerPool) addWorkers(ctx context.Context, cancel context.CancelFunc, number int) {
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for i := 0; i < number; i++ {
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p.lock.Lock()
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if p.cond == nil {
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p.cond = sync.NewCond(&p.lock)
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}
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p.numberOfWorkers++
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p.lock.Unlock()
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go func() {
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pprof.SetGoroutineLabels(ctx)
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p.doWork(ctx)
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p.lock.Lock()
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p.numberOfWorkers--
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if p.numberOfWorkers == 0 {
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p.cond.Broadcast()
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cancel()
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} else if p.numberOfWorkers < 0 {
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// numberOfWorkers can't go negative but...
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log.Warn("Number of Workers < 0 for QID %d - this shouldn't happen", p.qid)
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p.numberOfWorkers = 0
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p.cond.Broadcast()
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cancel()
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}
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select {
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case <-p.baseCtx.Done():
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// Don't warn or check for ongoing work if the baseCtx is shutdown
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case <-p.paused:
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// Don't warn or check for ongoing work if the pool is paused
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default:
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if p.hasNoWorkerScaling() {
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log.Warn(
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"Queue: %d is configured to be non-scaling and has no workers - this configuration is likely incorrect.\n"+
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"The queue will be paused to prevent data-loss with the assumption that you will add workers and unpause as required.", p.qid)
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p.pause()
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} else if p.numberOfWorkers == 0 && atomic.LoadInt64(&p.numInQueue) > 0 {
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// OK there are no workers but... there's still work to be done -> Reboost
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p.zeroBoost()
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// p.lock will be unlocked by zeroBoost
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return
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}
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}
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p.lock.Unlock()
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}()
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}
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}
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// Wait for WorkerPool to finish
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func (p *WorkerPool) Wait() {
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p.lock.Lock()
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defer p.lock.Unlock()
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if p.cond == nil {
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p.cond = sync.NewCond(&p.lock)
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}
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if p.numberOfWorkers <= 0 {
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return
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}
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p.cond.Wait()
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}
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// IsPaused returns if the pool is paused
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func (p *WorkerPool) IsPaused() bool {
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p.lock.Lock()
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defer p.lock.Unlock()
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select {
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case <-p.paused:
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return true
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default:
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return false
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}
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}
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// IsPausedIsResumed returns if the pool is paused and a channel that is closed when it is resumed
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func (p *WorkerPool) IsPausedIsResumed() (<-chan struct{}, <-chan struct{}) {
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p.lock.Lock()
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defer p.lock.Unlock()
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return p.paused, p.resumed
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}
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// Pause pauses the WorkerPool
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func (p *WorkerPool) Pause() {
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p.lock.Lock()
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defer p.lock.Unlock()
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p.pause()
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}
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func (p *WorkerPool) pause() {
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select {
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case <-p.paused:
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default:
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p.resumed = make(chan struct{})
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close(p.paused)
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}
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}
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// Resume resumes the WorkerPool
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func (p *WorkerPool) Resume() {
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p.lock.Lock() // can't defer unlock because of the zeroBoost at the end
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select {
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case <-p.resumed:
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// already resumed - there's nothing to do
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p.lock.Unlock()
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return
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default:
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}
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p.paused = make(chan struct{})
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close(p.resumed)
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// OK now we need to check if we need to add some workers...
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if p.numberOfWorkers > 0 || p.hasNoWorkerScaling() || atomic.LoadInt64(&p.numInQueue) == 0 {
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// We either have workers, can't scale or there's no work to be done -> so just resume
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p.lock.Unlock()
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return
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}
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// OK we got some work but no workers we need to think about boosting
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select {
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case <-p.baseCtx.Done():
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// don't bother boosting if the baseCtx is done
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p.lock.Unlock()
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return
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default:
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}
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// OK we'd better add some boost workers!
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p.zeroBoost()
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// p.zeroBoost will unlock the lock
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}
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// CleanUp will drain the remaining contents of the channel
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// This should be called after AddWorkers context is closed
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func (p *WorkerPool) CleanUp(ctx context.Context) {
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log.Trace("WorkerPool: %d CleanUp", p.qid)
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close(p.dataChan)
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for data := range p.dataChan {
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if unhandled := p.handle(data); unhandled != nil {
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if unhandled != nil {
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log.Error("Unhandled Data in clean-up of queue %d", p.qid)
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}
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}
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atomic.AddInt64(&p.numInQueue, -1)
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select {
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case <-ctx.Done():
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log.Warn("WorkerPool: %d Cleanup context closed before finishing clean-up", p.qid)
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return
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default:
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}
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}
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log.Trace("WorkerPool: %d CleanUp Done", p.qid)
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}
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// Flush flushes the channel with a timeout - the Flush worker will be registered as a flush worker with the manager
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func (p *WorkerPool) Flush(timeout time.Duration) error {
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ctx, cancel := p.commonRegisterWorkers(1, timeout, true)
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defer cancel()
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return p.FlushWithContext(ctx)
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}
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// IsEmpty returns if true if the worker queue is empty
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func (p *WorkerPool) IsEmpty() bool {
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return atomic.LoadInt64(&p.numInQueue) == 0
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}
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// contextError returns either ctx.Done(), the base context's error or nil
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func (p *WorkerPool) contextError(ctx context.Context) error {
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select {
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case <-p.baseCtx.Done():
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return p.baseCtx.Err()
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case <-ctx.Done():
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return ctx.Err()
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default:
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return nil
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}
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}
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// FlushWithContext is very similar to CleanUp but it will return as soon as the dataChan is empty
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// NB: The worker will not be registered with the manager.
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func (p *WorkerPool) FlushWithContext(ctx context.Context) error {
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log.Trace("WorkerPool: %d Flush", p.qid)
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paused, _ := p.IsPausedIsResumed()
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for {
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// Because select will return any case that is satisified at random we precheck here before looking at dataChan.
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select {
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case <-paused:
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// Ensure that even if paused that the cancelled error is still sent
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return p.contextError(ctx)
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case <-p.baseCtx.Done():
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return p.baseCtx.Err()
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case <-ctx.Done():
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return ctx.Err()
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default:
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}
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select {
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case <-paused:
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return p.contextError(ctx)
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case data, ok := <-p.dataChan:
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if !ok {
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return nil
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}
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if unhandled := p.handle(data); unhandled != nil {
|
|
log.Error("Unhandled Data whilst flushing queue %d", p.qid)
|
|
}
|
|
atomic.AddInt64(&p.numInQueue, -1)
|
|
case <-p.baseCtx.Done():
|
|
return p.baseCtx.Err()
|
|
case <-ctx.Done():
|
|
return ctx.Err()
|
|
default:
|
|
return nil
|
|
}
|
|
}
|
|
}
|
|
|
|
func (p *WorkerPool) doWork(ctx context.Context) {
|
|
pprof.SetGoroutineLabels(ctx)
|
|
delay := time.Millisecond * 300
|
|
|
|
// Create a common timer - we will use this elsewhere
|
|
timer := time.NewTimer(0)
|
|
util.StopTimer(timer)
|
|
|
|
paused, _ := p.IsPausedIsResumed()
|
|
data := make([]Data, 0, p.batchLength)
|
|
for {
|
|
// Because select will return any case that is satisified at random we precheck here before looking at dataChan.
|
|
select {
|
|
case <-paused:
|
|
log.Trace("Worker for Queue %d Pausing", p.qid)
|
|
if len(data) > 0 {
|
|
log.Trace("Handling: %d data, %v", len(data), data)
|
|
if unhandled := p.handle(data...); unhandled != nil {
|
|
log.Error("Unhandled Data in queue %d", p.qid)
|
|
}
|
|
atomic.AddInt64(&p.numInQueue, -1*int64(len(data)))
|
|
}
|
|
_, resumed := p.IsPausedIsResumed()
|
|
select {
|
|
case <-resumed:
|
|
paused, _ = p.IsPausedIsResumed()
|
|
log.Trace("Worker for Queue %d Resuming", p.qid)
|
|
util.StopTimer(timer)
|
|
case <-ctx.Done():
|
|
log.Trace("Worker shutting down")
|
|
return
|
|
}
|
|
case <-ctx.Done():
|
|
if len(data) > 0 {
|
|
log.Trace("Handling: %d data, %v", len(data), data)
|
|
if unhandled := p.handle(data...); unhandled != nil {
|
|
log.Error("Unhandled Data in queue %d", p.qid)
|
|
}
|
|
atomic.AddInt64(&p.numInQueue, -1*int64(len(data)))
|
|
}
|
|
log.Trace("Worker shutting down")
|
|
return
|
|
default:
|
|
}
|
|
|
|
select {
|
|
case <-paused:
|
|
// go back around
|
|
case <-ctx.Done():
|
|
if len(data) > 0 {
|
|
log.Trace("Handling: %d data, %v", len(data), data)
|
|
if unhandled := p.handle(data...); unhandled != nil {
|
|
log.Error("Unhandled Data in queue %d", p.qid)
|
|
}
|
|
atomic.AddInt64(&p.numInQueue, -1*int64(len(data)))
|
|
}
|
|
log.Trace("Worker shutting down")
|
|
return
|
|
case datum, ok := <-p.dataChan:
|
|
if !ok {
|
|
// the dataChan has been closed - we should finish up:
|
|
if len(data) > 0 {
|
|
log.Trace("Handling: %d data, %v", len(data), data)
|
|
if unhandled := p.handle(data...); unhandled != nil {
|
|
log.Error("Unhandled Data in queue %d", p.qid)
|
|
}
|
|
atomic.AddInt64(&p.numInQueue, -1*int64(len(data)))
|
|
}
|
|
log.Trace("Worker shutting down")
|
|
return
|
|
}
|
|
data = append(data, datum)
|
|
util.StopTimer(timer)
|
|
|
|
if len(data) >= p.batchLength {
|
|
log.Trace("Handling: %d data, %v", len(data), data)
|
|
if unhandled := p.handle(data...); unhandled != nil {
|
|
log.Error("Unhandled Data in queue %d", p.qid)
|
|
}
|
|
atomic.AddInt64(&p.numInQueue, -1*int64(len(data)))
|
|
data = make([]Data, 0, p.batchLength)
|
|
} else {
|
|
timer.Reset(delay)
|
|
}
|
|
case <-timer.C:
|
|
delay = time.Millisecond * 100
|
|
if len(data) > 0 {
|
|
log.Trace("Handling: %d data, %v", len(data), data)
|
|
if unhandled := p.handle(data...); unhandled != nil {
|
|
log.Error("Unhandled Data in queue %d", p.qid)
|
|
}
|
|
atomic.AddInt64(&p.numInQueue, -1*int64(len(data)))
|
|
data = make([]Data, 0, p.batchLength)
|
|
}
|
|
}
|
|
}
|
|
}
|