# Why do my goroutines wait for each other instead of finishing when done?

I'm pretty new to Go and there is one thing in my code which I don't understand. I wrote a simple bubblesort algorithm (I know it's not really efficient ;)). Now I want to start 3 GoRoutines. Each thread should sort his array independent from the other ones. When finished, the func. should print a "done"-Message.

Here is my Code:

``````package main

import (
"fmt"
"time" //for time functions e.g. Now()
"math/rand" //for pseudo random numbers
)

/* Simple bubblesort algorithm*/
func bubblesort(str string, a []int) []int {
for n:=len(a); n>1; n-- {
for i:=0; i<n-1; i++ {
if a[i] > a[i+1] {
a[i], a[i+1] = a[i+1], a[i] //swap
}
}
}
fmt.Println(str+" done") //done message
return a
}

/*fill slice with pseudo numbers*/
func random_fill(a []int) []int {
for i:=0; i<len(a); i++ {
a[i] = rand.Int()
}
return a
}

func main() {
rand.Seed( time.Now().UTC().UnixNano()) //set seed for rand.

a1 := make([]int, 34589) //create slice
a2 := make([]int, 42) //create slice
a3 := make([]int, 9999) //create slice

a1 = random_fill(a1) //fill slice
a2 = random_fill(a2) //fill slice
a3 = random_fill(a3) //fill slice
fmt.Println("Slices filled ...")

go bubblesort("Thread 1", a1) //1. Routine Start
go bubblesort("Thread 2", a2) //2. Routine Start
go bubblesort("Thread 3", a3) //3. Routine Start
fmt.Println("Main working ...")

time.Sleep(1*60*1e9) //Wait 1 minute for the "done" messages
}
``````

This is what I get:

``````Slices filled ...
Main working ...
``````

Should'nt Thread 2 finish first, since his slice is the smallest? It seems that all the threads are waiting for the others to finish, because the "done"-messages appear at the same time, no matter how big the slices are..

Where is my brainbug? =)

*Edit: When putting "time.Sleep(1)" in the for-loop in the bubblesort func. it seems to work.. but I want to clock the duration on different machines with this code (I know, i have to change the random thing), so sleep would falsify the results.

-
As you are new to Go, I suggest you use channels for managing synchronization : read golang.org/doc/effective_go.html#concurrency. It's a really neat core feature of Go, which will usually let you avoid using active waiting or time.Sleep(). –  Ripounet Jan 18 '13 at 13:09
thank you! that's nice. –  phineliner Jan 18 '13 at 14:17
Also note that `rand` has a mutex lock which will harm your concurrent performance; see stackoverflow.com/questions/14298523/… –  johusman Jan 18 '13 at 14:41
thanks too, i fixed that –  phineliner Jan 18 '13 at 17:05
See also very related questions : stackoverflow.com/questions/12314317/… , stackoverflow.com/questions/12413510/… –  Ripounet Jan 21 '13 at 11:07

Indeed, there is no garantee regarding the order in which your goroutines will be executed.

However if you force the true parallel processing by explicitly letting 2 processor cores run :

``````import (
"fmt"
"time" //for time functions e.g. Now()
"math/rand" //for pseudo random numbers
"runtime"
)
...

func main() {
runtime.GOMAXPROCS(2)

rand.Seed( time.Now().UTC().UnixNano()) //set seed for rand.
...
``````

Then you will get the expected result :

``````Slices filled ...
Main working ...
``````

Best regards

-
Great! That was it. Thanks a lot! –  phineliner Jan 18 '13 at 13:10
Please note this was the best answer for Go up to 1.1 . Things have changed in december 2013 : see new answer –  Ripounet Dec 30 '13 at 9:07

The important thing is the ability to "yield" the processor to other processes, before the whole potentialy long-running workload is finished. This holds true as well in single-core context or multi-core context (because Concurrency is not the same as Parallelism).

This is exactly what the runtime.Gosched() function does :

Gosched yields the processor, allowing other goroutines to run. It does not suspend the current goroutine, so execution resumes automatically.

Be aware that a "context switch" is not free : it costs a little time each time.

• On my machine without yielding, your program runs in 5.1s.
• If you yield in the outer loop (`for n:=len(a); n>1; n--`), it runs in 5.2s : small overhead.
• If you yield in the inner loop (`for i:=0; i<n-1; i++`), it runs in 61.7s : huge overhead !!

Here is the modified program correctly yielding, with the small overhead :

``````package main

import (
"fmt"
"math/rand"
"runtime"
"time"
)

/* Simple bubblesort algorithm*/
func bubblesort(str string, a []int, ch chan []int) {
for n := len(a); n > 1; n-- {
for i := 0; i < n-1; i++ {
if a[i] > a[i+1] {
a[i], a[i+1] = a[i+1], a[i] //swap
}
runtime.Gosched() // yield after part of the workload
}
}
fmt.Println(str + " done") //done message
ch <- a
}

/*fill slice with pseudo numbers*/
func random_fill(a []int) []int {
for i := 0; i < len(a); i++ {
a[i] = rand.Int()
}
return a
}

func main() {
rand.Seed(time.Now().UTC().UnixNano()) //set seed for rand.

a1 := make([]int, 34589) //create slice
a2 := make([]int, 42)    //create slice
a3 := make([]int, 9999)  //create slice

a1 = random_fill(a1) //fill slice
a2 = random_fill(a2) //fill slice
a3 = random_fill(a3) //fill slice
fmt.Println("Slices filled ...")

ch1 := make(chan []int) //create channel of result
ch2 := make(chan []int) //create channel of result
ch3 := make(chan []int) //create channel of result

go bubblesort("Thread 1", a1, ch1) //1. Routine Start
go bubblesort("Thread 2", a2, ch2) //2. Routine Start
go bubblesort("Thread 3", a3, ch3) //3. Routine Start
fmt.Println("Main working ...")

<-ch1 // Wait for result 1
<-ch2 // Wait for result 2
<-ch3 // Wait for result 3
}
``````

Output :

``````Slices filled ...
Main working ...
``````

I also used channels to implement the rendez-vous, as suggested in my previous comment.

Best regards :)

-
Thank you, especially for the link "Concurrency is not the same as Parallelism". that was not this clear before! –  phineliner Jan 21 '13 at 17:17