How to use a goroutine pool

Question

I want to use Go for downloading stock price spreadsheets from Yahoo finance. I'll be making an http request for every stock in its own goroutine. I have a list of around 2500 symbols, but instead of making 2500 requests in parallel, I'd prefer making 250 at a time. In Java I'd create a thread pool and reuse threads as and when they get free. I was trying to find something similar, a goroutine pool, if you will, but was unable to find any resources. I'd appreciate if someone can tell me how to accomplish the task at hand or point me to resources for the same. Thanks!

Answer 1

The simplest way, I suppose, is to create 250 goroutines and pass them a channel which you can use to pass links from main goroutine to child ones, listening that channel.

When all links are passed to goroutines, you close a channel and all goroutines just finish their jobs.

To secure yourself from main goroutine get finished before children process data, you can use sync.WaitGroup.

Here is some code to illustrate (not a final working version but shows the point) that I told above:

func worker(linkChan chan string, wg *sync.WaitGroup) {
   // Decreasing internal counter for wait-group as soon as goroutine finishes
   defer wg.Done()

   for url := range linkChan {
     // Analyze value and do the job here
   }
}

func main() {
    lCh := make(chan string)
    wg := new(sync.WaitGroup)

    // Adding routines to workgroup and running then
    for i := 0; i < 250; i++ {
        wg.Add(1)
        go worker(lCh, wg)
    }

    // Processing all links by spreading them to `free` goroutines
    for _, link := range yourLinksSlice {
        lCh <- link
    }

    // Closing channel (waiting in goroutines won't continue any more)
    close(lCh)

    // Waiting for all goroutines to finish (otherwise they die as main routine dies)
    wg.Wait()
}

Answer 2

You can use the thread pool implementation library in Go from this git repo

Here is the nice blog about how to use the channels as thread pool

Snippet from the blog

    var (
 MaxWorker = os.Getenv("MAX_WORKERS")
 MaxQueue  = os.Getenv("MAX_QUEUE")
)

//Job represents the job to be run
type Job struct {
    Payload Payload
}

// A buffered channel that we can send work requests on.
var JobQueue chan Job

// Worker represents the worker that executes the job
type Worker struct {
    WorkerPool  chan chan Job
    JobChannel  chan Job
    quit        chan bool
}

func NewWorker(workerPool chan chan Job) Worker {
    return Worker{
        WorkerPool: workerPool,
        JobChannel: make(chan Job),
        quit:       make(chan bool)}
}

// Start method starts the run loop for the worker, listening for a quit channel in
// case we need to stop it
func (w Worker) Start() {
    go func() {
        for {
            // register the current worker into the worker queue.
            w.WorkerPool <- w.JobChannel

            select {
            case job := <-w.JobChannel:
                // we have received a work request.
                if err := job.Payload.UploadToS3(); err != nil {
                    log.Errorf("Error uploading to S3: %s", err.Error())
                }

            case <-w.quit:
                // we have received a signal to stop
                return
            }
        }
    }()
}

// Stop signals the worker to stop listening for work requests.
func (w Worker) Stop() {
    go func() {
        w.quit <- true
    }()
} 

Answer 3

You can take a look at this

We have created a thread pool in go and have been using it for our production systems.

I had taken reference from here

Its pretty simple to use and also has a prometheus client that tells you how many workers are used.

To initialize just create an instance of dispatcher

dispatcher = workerpool.NewDispatcher(
    "DispatcherName",
    workerpool.SetMaxWorkers(10),
)

Create an object (lets say job) that implements this interface. So it should implement the Process method

// IJob : Interface for the Job to be processed
type IJob interface {
    Process() error
}

Then just send the job to the dispatcher

dispatcher.JobQueue <- job //object of job

This is it.

Answer 4

This example uses two chanels, one for the inputs and another for output. Workers can scale to whatever size and each goroutine works on the input queue and saves all output to the output channel. Feedback on easier methods are very welcome.

package main

import (
    "fmt"
    "sync"
)

var wg sync.WaitGroup

func worker(input chan string, output chan string) {
    defer wg.Done()
    // Consumer: Process items from the input channel and send results to output channel
    for value := range input {
        output <- value + " processed"
    }
}

func main() {
    var jobs = []string{"one", "two", "three", "four", "two", "three", "four", "two", "three", "four", "two", "three", "four", "two", "three", "four", "two"}
    input := make(chan string, len(jobs))
    output := make(chan string, len(jobs))
    workers := 250

    // Increment waitgroup counter and create go routines
    for i := 0; i < workers; i++ {
        wg.Add(1)
        go worker(input, output)
    }

    // Producer: load up input channel with jobs
    for _, job := range jobs {
        input <- job
    }

    // Close input channel since no more jobs are being sent to input channel
    close(input)
    // Wait for all goroutines to finish processing
    wg.Wait()
    // Close output channel since all workers have finished processing
    close(output)

    // Read from output channel
    for result := range output {
        fmt.Println(result)
    }

}

Answer 5

Let me bring my 2 cents on the table.

On Java threads are created on OS kernel level and that is why it is quite heavy operation. That is a reason of using a thread pool on such programming languages like Java, C#.Net. It allows us to use threads from pool without need of creation of them (threads).

For Golang, theads (goroutines) are created on user space level and not so heavy operation. That is why usage of thread pool pattern does not make much sense for GoLang environment.

More details about it on Tanenbaum's book "Distributed Systems".