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I am attempting to benchmark the maximum STW GC pause time for different numbers of heap objects. To do this I have written a simple benchmark that pushes and pops messages from a map:

package main

type message []byte

type channel map[int]message

const (
    windowSize = 200000
    msgCount   = 1000000
)

func mkMessage(n int) message {
    m := make(message, 1024)
    for i := range m {
        m[i] = byte(n)
    }
    return m
}

func pushMsg(c *channel, highID int) {
    lowID := highID - windowSize
    m := mkMessage(highID)
    (*c)[highID] = m
    if lowID >= 0 {
        delete(*c, lowID)
    }
}

func main() {
    c := make(channel)
    for i := 0; i < msgCount; i++ {
        pushMsg(&c, i)
    }
}

I ran this with GODEBUG=gctrace=1, and on my machine the output is:

gc 1 @0.004s 2%: 0.007+0.44+0.032 ms clock, 0.029+0.22/0.20/0.28+0.12 ms cpu, 4->4->3 MB, 5 MB goal, 4 P
gc 2 @0.009s 3%: 0.007+0.64+0.042 ms clock, 0.030+0/0.53/0.18+0.17 ms cpu, 7->7->7 MB, 8 MB goal, 4 P
gc 3 @0.019s 1%: 0.007+0.99+0.037 ms clock, 0.031+0/0.13/1.0+0.14 ms cpu, 13->13->13 MB, 14 MB goal, 4 P
gc 4 @0.044s 2%: 0.009+2.3+0.032 ms clock, 0.039+0/2.3/0.30+0.13 ms cpu, 25->25->25 MB, 26 MB goal, 4 P
gc 5 @0.081s 1%: 0.009+9.2+0.082 ms clock, 0.039+0/0.32/9.7+0.32 ms cpu, 49->49->48 MB, 50 MB goal, 4 P
gc 6 @0.162s 0%: 0.020+10+0.078 ms clock, 0.082+0/0.28/11+0.31 ms cpu, 93->93->91 MB, 96 MB goal, 4 P
gc 7 @0.289s 0%: 0.020+27+0.092 ms clock, 0.080+0/0.95/28+0.37 ms cpu, 178->178->173 MB, 182 MB goal, 4 P
gc 8 @0.557s 1%: 0.023+38+0.086 ms clock, 0.092+0/38/10+0.34 ms cpu, 337->339->209 MB, 346 MB goal, 4 P
gc 9 @0.844s 1%: 0.008+40+0.077 ms clock, 0.032+0/5.6/46+0.30 ms cpu, 407->409->211 MB, 418 MB goal, 4 P
gc 10 @1.100s 1%: 0.009+43+0.047 ms clock, 0.036+0/6.6/50+0.19 ms cpu, 411->414->212 MB, 422 MB goal, 4 P
gc 11 @1.378s 1%: 0.008+45+0.093 ms clock, 0.033+0/6.5/52+0.37 ms cpu, 414->417->213 MB, 425 MB goal, 4 P

See the link above for documentation on this output.

My version of Go is:

$ go version
go version go1.7.1 darwin/amd64

From the above results, the longest wall clock STW pause time is 0.093 ms. Great!

However as a sanity check I also manually timed how long it took to create a new message by wrapping mkMessage with

start := time.Now()
m := mkMessage(highID)
elapsed := time.Since(start)

and printed the slowest elapsed time. The time I get for this was 38.573036ms!

I was instantly suspicious because this correlated strongly with the wall clock times in the supposedly concurrent mark/scan phase, and in particular with "idle GC time".

My question is: why does this supposedly concurrent phase of the GC appear to block the mutator?

If I force the GC to run at regular intervals, my manually calculated pause times go way down to <1ms, so it appears to be hitting some kind of limit of non-live heap objects. If so, I'm not sure what that limit is, and why it would cause a concurrent phase of the GC to appear to block the mutator.

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  • 2
    Since this is implementation and version specific, if you want a specific answer the go mailing list is probably a more appropriate forum (you should also test this with the current master branch if you haven't done so)
    – JimB
    Oct 18, 2016 at 17:09
  • Took a minute to look at this, and I'm only seeing a rough correlation here, and only with small inputs. The bulk of time in mkMessage is spent waiting for an allocation during GC, not in mutating the slice. If I increase the number of pointers an order of magnitude, the time spent in the concurrent phase increases accordingly, but there's no significant increase in the time taken to allocate or mutate the slices.
    – JimB
    Oct 18, 2016 at 20:01
  • This has a huge map, and there are bugs where they cause pauses. The incremental "mutator assist"--where your code's interrupted to do a small chunk of work, meant to be just microseconds--sometimes wound up scanning the whole map. See groups.google.com/forum/#!topic/golang-codereviews/kIqdlqEZ47M, github.com/golang/go/issues/16432, github.com/golang/go/issues/14812, and github.com/golang/go/issues/9477. Go tip might work better, or 1.7 if you're on an older version.
    – twotwotwo
    Oct 18, 2016 at 20:45
  • @JimB I will ask in the go mailing list too, thanks for the suggestion. I don't think this is inappropriate for SO because I think it's likely this problem is a characteristic of concurrent STW collectors in general. When I increase the number of messages an order of magnitude, I do see the time to allocate increase: concurrent GC time = 915ms and time to allocate = 824ms. However the anomalous "background GC time" doesn't seem to correlate over more runs, so I'll remove this from the question. Oct 19, 2016 at 9:16
  • @twotwotwo I did originally investigate that, but I'm not sure it's the problem here because the large STW pause appears to happen when allocating with mkMessage, not inserting or deleting from the map. Oct 19, 2016 at 9:19

2 Answers 2

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A concurrent GC pass will typically start at a time when a certain amount of space is available for new allocations. If that amount of space is adequate to handle all allocations that occur before the pass is complete, the amount of time the application has to wait on the GC will be minimal. If, however, the quantity of allocations exceeds the space available, new allocation requests will have to wait for the GC to free up more space.

Note that most concurrent GC systems have definite cycles even though programs can run while they are in progress. The bulk of a GC cycle is spent identifying all of the objects to which references exist, and the only way to identify that no references exist to any individual object is to identify all the references that exist to everything else. Consequently, everything that will get freed by a GC cycle will get freed at once, and nothing will get freed in the interim.

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  • Let me see if I understand what you are saying. The GC has a certain amount of memory available for new allocations, call this s. In my example, as more objects are created, s will decrease. When s reaches a certain value, a GC will start. If s becomes 0, requests to create new objects will block. The requests will only continue once the GC runs again, or more memory is requested from the OS. That makes sense to me, but let me know if I'm not following. Oct 19, 2016 at 9:00
  • @WillSewell: That's pretty much it, except that the requests have to wait not just until the GC "runs", but until it completes a cycle. To find out whether any particular piece of memory can be freed, the system would have to scan through every live object, but a single scan through all live objects would allow the system to identify all of the pieces of memory that can be freed.
    – supercat
    Oct 19, 2016 at 14:10
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To give this more visibility (and detail) than in my comment--the behavior seems to match what's described in Go bug #9477 and fixed by Go changelist 23540.

What happens is, when a thread allocates memory, the garbage collector might give it a little memory-scanning work to do; this is called a "mutator assist." But previously, the work might consist of scanning a map, which would cause a long pause with a big enough map. Consistent with what's reported in the question and comments, the pause would happen when some arbitrary allocation took place--not necessarily while using the map--and would not show up in GC pause stats since it wasn't part of the stop-the-world phase.

The fix made to Go, not yet released as I'm writing, was to limit how much memory a single mutator assist would scan so that it would take no more than about 100 microseconds on typical modern server hardware. If you're encountering this problem I'd recommend trying the latest from the github.com/golang/go repository (or 1.8 once it's out) where the fix is applied. (There's also another big pause-reduction change in there since 1.7.) If you still have problems and haven't been able to find any explanation, I'd go to golang-nuts.

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