Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

Sign up and start helping → Learn more about Documentation →

I have a test program that gives different results when executing more than one goroutine on more than one Cpu (Goroutines = Cpus). The "test" is about syncing goroutines using channels, and the program itself counts occurences of chars in strings. It produces consistent results on one Cpu / one goroutine.

See code example on playground (Note: Run on local machine to execute on multi core, and watch the resulting numbers vary): http://play.golang.org/p/PT5jeCKgBv .

Code summary: The program counts occurences of 4 different chars (A,T, G,C) in (DNA) strings.

Problem: Result (n occurences of chars) varies when executed on multiple Cpu's (goroutines). Why?


  1. A goroutine spawns work (SpawnWork) as strings to Workers. Sets up artificial string input data (hardcoded strings are copied n times).
  2. Goroutine Workers (Worker) are created equalling the numbers of Cpu's.
  3. Workers checks each char in string and counts A,T's and sends the sum into a channel, and G,C counts to another channel.
  4. SpawnWork closes workstring channel as to control Workers (which consumes strings using range, which quits when the input channel is closed by SpawnWork).
  5. When Workers has consumed its ranges (of chars) it sends a quit signal on the quit channel (quit <- true). These "pulses" will occure Cpu number of times ( Cpu count = goroutines count).
  6. Main (select) loop will quit when it has received Cpu-count number of quit signals.
  7. Main func prints a summary of occurences of Chars (A,T's, G,C's).

Simplified code:

1. "Worker" (goroutines) counting chars in lines:

func Worker(inCh chan *[]byte, resA chan<- *int, resB chan<- *int, quit chan bool) {
    //for p_ch := range inCh {
    for {
        p_ch, ok := <-inCh // similar to range
        if ok {
            ch := *p_ch
            for i := 0; i < len(ch); i++ {
                if ch[i] == 'A' || ch[i] == 'T' {        // Count A:s and T:s
                } else if ch[i] == 'G' || ch[i] == 'C' { // Count G:s and C:s
            resA <- &at  // Send line results on separate channels
            resB <- &gc  // Send line results on separate channels
        } else {
            quit <- true // Indicate that we're all done

2. Spawn work (strings) to workers:

func SpawnWork(inStr chan<- *[]byte, quit chan bool) {
    // Artificial input data
    StringData :=
        "... etc\n" +
    // ...
    for scanner.Scan() {
        s := scanner.Bytes()
        if len(s) == 0 || s[0] == '>' {
        } else {
            inStr <- &s
    close(inStr) // Indicate (to Workers) that there's no more strings coming.

3. Main routine:

func main() {
    // Count Cpus, and count down in final select clause
    CpuCnt := runtime.NumCPU() 
    // Make channels
    resChA := make(chan *int)
    resChB := make(chan *int)
    quit := make(chan bool)
    inStr := make(chan *[]byte)

    // Set up Workers ( n = Cpu )
    for i := 0; i < CpuCnt; i++ {
        go Worker(inStr, resChA, resChB, quit)
    // Send lines to Workers
    go SpawnWork(inStr, quit)

    // Count the number of "A","T" & "G","C" per line 
    // (comes in here as ints per row, on separate channels (at and gt))
    for {
        select {
        case tmp_at := <-resChA:
            tmp_gc := <-resChB // Ch A and B go in pairs anyway
            A += *tmp_at       // sum of A's and T's
            B += *tmp_gc       // sum of G's and C's
        case <-quit:
            // Each goroutine sends "quit" signals when it's done. Since 
            // the number of goroutines equals the Cpu counter, we count 
            // down each time a goroutine tells us it's done (quit at 0):
            if CpuCnt == 0 { // When all goroutines are done then we're done.
                goto out     
    // Print report to screen

Why does this code count consistently only when executed on a singel cpu/goroutine? That is, the channels doesn't seem to sync, or the main loop quits forcefully before all goroutines are done? Scratching head.

(Again: See/run the full code at the playground: http://play.golang.org/p/PT5jeCKgBv )

// Rolf Lampa

share|improve this question
Have you tried running it with go run -race? golang.org/doc/articles/race_detector.html – MatrixFrog Jun 14 '13 at 3:10
I looked through the code and didn't see any problems so I tried -race myself. It found a few problems but one of them is that the at variable at the beginnning of Worker is exposed to main because you do tmp_at := <-resChA. Maybe if you pass the numbers themselves through the channels (instead of pointers to the numbers) then it won't be racy? – MatrixFrog Jun 14 '13 at 3:18
@MatrixFog: I actually had forgot about the -race option. Doh! However, removing the pointers does not do away with the races, that really puzzles me. I'll keep trying to narrowing it down. – RIL Jun 14 '13 at 10:29
See discussion with Nick Craig-Wood below about all the problems, both apparent and (potentially) hidden that was revealed. Many lessons learned in one..., well, go. :) – RIL Jun 14 '13 at 12:15
Tying the number of goroutines to be the same as the number of CPUs is a risky policy - it may sometimes lead to under-utilisation of CPUs, especially if I/O is involved. In your case, you might well be lucky though. The alternative policy is to use 'excess parallelism' - i.e. more goroutines than there are CPUs. Even when some of them get blocked (e.g. on channels) there are others that the CPU cores can carry on executing. – Rick-777 Jun 15 '13 at 8:29
up vote 2 down vote accepted

Here is a working version which consistently produces the same results no matter how many cpus are used.

Here is what I did

  • remove passing of *int - very racy to pass in a channel!
  • remove passing of *[]byte - pointless as slices are reference types anyway
  • copy the slice before putting it in the channel - the slice points to the same memory causing a race
  • fix initialisation of at and gc in Worker - they were in the wrong place - this was the major cause of the difference in results
  • use sync.WaitGroup for synchronisation and channel close()

I used the -race parameter of go build to find and fix the data races.

package main

import (

func Worker(inCh chan []byte, resA chan<- int, resB chan<- int, wg *sync.WaitGroup) {
    defer wg.Done()
    fmt.Println("Worker started...")
    for ch := range inCh {
        at := 0
        gc := 0
        for i := 0; i < len(ch); i++ {
            if ch[i] == 'A' || ch[i] == 'T' {
            } else if ch[i] == 'G' || ch[i] == 'C' {
        resA <- at
        resB <- gc


func SpawnWork(inStr chan<- []byte) {
    fmt.Println("Spawning work:")
    // An artificial input source.
    StringData :=
    // Expand data n times
    tmp := StringData
    for n := 0; n < 1000; n++ {
        StringData = StringData + tmp
    scanner := bufio.NewScanner(strings.NewReader(StringData))

    var i int
    for scanner.Scan() {
        s := scanner.Bytes()
        if len(s) == 0 || s[0] == '>' {
        } else {
            s_copy := append([]byte(nil), s...)
            inStr <- s_copy

func main() {
    CpuCnt := runtime.NumCPU() // Count down in select clause
    CpuOut := CpuCnt           // Save for print report
    fmt.Printf("Processors: %d\n", CpuCnt)

    resChA := make(chan int)
    resChB := make(chan int)
    inStr := make(chan []byte)

    fmt.Println("Spawning workers:")
    var wg sync.WaitGroup
    for i := 0; i < CpuCnt; i++ {
        go Worker(inStr, resChA, resChB, &wg)
    fmt.Println("Spawning work:")
    go func() {

    A := 0
    B := 0
    LineCnt := 0
    for tmp_at := range resChA {
        tmp_gc := <-resChB // Theese go together anyway
        A += tmp_at
        B += tmp_gc

    if !(A+B > 0) {
        fmt.Println("No A/B was found!")
    } else {
        ABFraction := float32(B) / float32(A+B)
        fmt.Printf("Cpu's  : %d\n", CpuOut)
        fmt.Printf("Lines  : %d\n", LineCnt)
        fmt.Printf("A+B    : %d\n", A+B)
        fmt.Printf("A      : %d\n", A)
        fmt.Printf("B      : %d\n", A)
        fmt.Printf("AB frac: %v\n", ABFraction*100)
share|improve this answer
Thank you very much for your elaborate answer! Unfortunately the pointers alone don't seem to be the problem (removing all ptrs doesn't do away with the races). The exact (and only) cause of the race problem was a conflict with the s (string), caused by scanner replacing it while reading in workers. That problem you also have solved in your code using a copy of s ( "s_copy := append([]byte(nil), s...)" ). Thank you very very much for pointing that one out! Also thank you for your alternative strategy with the wait-groups. Gold! :) – RIL Jun 14 '13 at 10:42
In addition to spotting the race problem above, I would like to point out why all the pointers in my example (they actually makes sense). I used this example algorithm from a (language) performance test for reading DNA sequences. Ptrs were optimizations which made a significant difference. It could be of interest to see how Go-lang did compared to C, C++, D, Pascal, Phyton etc. (super optimized (go) speed: gist.github.com/samuell/5591369) . Comparison: saml.rilspace.org/… (Go did very well!) :) – RIL Jun 14 '13 at 10:52
Hint: If you point out that the race problem was the scan string (which you copied), then I can endorse your answer as "The answer". And yes, the initialization of the variables in the worker got accindently moved when trying to replace the "for... range" loop (it originally was inside the loop). So ponting out those two fixes solves the entire problem, even if keeping the pointers and all the rest as is in the original code. – RIL Jun 14 '13 at 11:05
The *[]byte and the *int pointers can both cause races (and the race detector agrees) but since your channels aren't buffered they didn't this time! Try your example using buffered channels (give a second parameter to make(chan XXX, 1000)) and you'll see the races come into play I suspect. You'll also see a performance rise. – Nick Craig-Wood Jun 14 '13 at 11:05
Glad to be of service! Interesting the race detector didn't detect all the races - a good experiment. The channel strategy for quitting is fine - I think the WaitGroup is neater though - perhaps I shouldn't have changed that as it didn't directly illustrate the fix, but I can't resist trying to make code more beautiful! – Nick Craig-Wood Jun 14 '13 at 13:26

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.