# How to receive data and send back signal using goroutines

I want to make use of concurrency in Go to send data to a goroutine for processing and computation using channels. The data points come one after another in a function which can be main function or some `sendData` function. If possible, I would like to have the sending of the data to be done from main function.

I want to send the data from the send function to a goroutine, where data is stored in a slice (lets call this goroutine `getData`). Certain computations are done on this slice. After a certain condition is reached (which depends on the slice), I want the goroutine to signal the `sendData` function that processing is complete for a certain batch of data points. And now, the `sendData` function keeps sending data points through the channel to `getData` goroutine where a new slice keeps getting built and when the condition is reached the signal is sent - that processing is complete and the entire sequence keeps getting repeated.

As an example, lets imagine that data in the form of numbers is being sent from `sendData` to `getData`. The condition is that the running mean of numbers received by `getData` should be equal to 4. Lets take the following sequence of numbers as our data - `[]int{3, 2, 3, 8, 2, 1, 1, 1, 15}`. Here, the first batch of numbers would be `{3, 2, 3, 8}` because after these numbers are sent in this sequence to `getData`, it finds that the running mean of numbers is equal to 4 after the number 8 is received by `getData`. Then it sends a signal to `sendData`. And the process of sending data starts again in sequence of numbers with the next batch being `{2, 1, 1, 1, 15}`. Here, after the number `15` is received by `getData` it finds that the running mean is equal to 4 an sigal is sent again to `sendData`. ( This is a very basic example - in my real use case, the input data and the condition are more complex. I have data which will be read live in `sendData`. Here each data point is read sequentially but each data point arrives at a few microseconds after the previous one. As such the arrival of data is fast paced here, and I don't want to do too much of processing and calculations in this function. Furthermore, I want keep concurrency intact, because in the function where data is being read, data is arriving at a fast rate. And, I don't want the reading of data here to be missed because of the processing of data in the goroutine where processing is done.)

Here is how I have tried to structure the code:

``````package main

import (
"fmt"
)

func main() {
ch := make(chan int)
go sendData(ch)
go getData(ch)
}

func sendData(ch chan int) {
syntheticData := []int{3, 2, 3, 8, 2, 1, 1, 1, 15}
for _, data := range syntheticData {
ch <- data
}
}

func getData(ch chan int) {
dataArr := []int{}
dataArr = append( dataArr, <-ch )
fmt.Println(dataArr)

if mean(dataArr) == 4{
close(ch)
}

}

func sum(array []int) int {
var result int = 0
for _, v := range array {
result += v
}

return result
}

func mean(array []int) float64 {
sumArr := float64(sum(array)) / float64(len(array))
return sumArr
}
``````

I didn't achieve the functionality that I wanted to with the above code. How can I achieve the desired functionality in Go?

You only need one extera receiving goroutine e.g. `getData` and then the `main` goroutine will send the data as it arrives using a channel named `ch`, and you need one buffered channel for signalling e.g. `batchCompleted`, and a `WaitGroup` to wait for the `getData` synchronization, when it is done.
That is all, try it:

``````package main

import (
"fmt"
"sync"
)

func main() {
wg := &sync.WaitGroup{}
ch := make(chan int)
batchCompleted := make(chan struct{}, 1) // non-blocking signaling channel
go getData(ch, batchCompleted, wg)

syntheticData := []int{3, 2, 3, 8, 2, 1, 1, 1, 15}
i := 0
check := func() {
select {
case <-batchCompleted:
i++
fmt.Println(i, " batch completed")
default:
}
}
for _, data := range syntheticData {
ch <- data
check()
}
close(ch)
wg.Wait()
check()
}

func getData(ch chan int, batchCompleted chan struct{}, wg *sync.WaitGroup) {
defer wg.Done()
a := []int{}
sum, n := 0, 0
for v := range ch {
sum += v
n++
a = append(a, v)
if sum == 4*n {
batchCompleted <- struct{}{}
fmt.Println(a)
sum, n = 0, 0
a = a[:0]
}
}
if len(a) > 0 {
fmt.Println("remaining data:", a)
}
}
``````

Output:

``````[3 2 3 8]
1  batch completed
[2 1 1 1 15]
2  batch completed
``````
• Splendid answer. This does the job. Thank you. :) Mar 14, 2021 at 19:32

If I understood your problem correctly, this should work fine. But not a good solution, though. I've commented out the code so that it's understandable.

``````package main

import "fmt"

func main() {
// Data channel
ch := make(chan int)
// Batch close/create channel for signalling
bsig := make(chan struct{})

go put(ch, bsig)
get(ch, bsig, 4)
}

func put(ch chan<- int, bsig chan struct{}) {
// Listen for batch creation
go func() {
n := 1
// Receives signal from get on the bidrectional
// channel, and ping back when done on the same
// channel.
for range bsig {
fmt.Printf("Batch #%d\n", n)
bsig <- struct{}{}
n++
}
}()

// Steam of numbers
stream := []int{3, 2, 3, 8, 2, 1, 1, 1, 15}
for _, s := range stream {
ch <- s
}
close(ch)
}

func get(ch <-chan int, bsig chan struct{}, mean int) {
num := 0
sum := 0
batch := make([]int, 0)
for s := range ch {
sum += s
num++
batch = append(batch, s)
// Matches the mean, close batch
// and signal the sender
if sum/num == mean {
// Send ping
bsig <- struct{}{}
// Wait for pong?
<-bsig
// Print the batch
fmt.Println(batch)
// Reset the batch
sum = 0
num = 0
batch = batch[:0]
}
}
// Close the channel
close(bsig)
}
``````