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I'm upgrading production hardware, and we're seeing far more young-gen GCing on the new set of kit compared to the old.

The same program is running (identical binaries) on both machines. One obvious difference (I hope this doesn't make a difference to the JVM) is that we have upgraded RHEL5 -> RHEL6.

Our JVM (Java 64-bit Hotspot 1.6, same java -version on both) is running with the same command-line GC options:

-XX:+PrintGC -XX:+PrintGCDetails -XX:+PrintGCTimeStamps -XX:+UseParallelGC -XX:+UseCompressedOops


-Xmx1024M -Xms1024M -XX:NewSize=512M -XX:SurvivorRatio=2

The difference between the machines is that the new box has approximately twice as much RAM (32gb - although the max heap is unchanged) and some more cores (24 vs. 16).

The application itself connects to several external processes and performs lots of network operations - so this could indicate some regression, misconfiguration, or incompatibility (this is why we test...). What I would like to know is:

Is an increased level of young-gen GC likely to be a natural and expected consequence of running on more cores, or should I be concerned about this development?

We confirmed the number of GCs in JConsole, but that's about the same as doing:

grep "PSYoungGen" ./log | wc -l 

(note -XX:+PrintGC -XX:+PrintGCDetails)

Full GCs look about the same on both boxes.

Note, this is the number of GCs over the course of the whole application startup process - so it's not performing "more work." It's the same work, with more GC runs.

I wondered, for example, whether -XX:+UseParallelGC would lead to lots more entries in the log, because more threads were being used (chopping the young-gen collections into smaller pieces, meaning more, smaller collections - not something to be worried about).

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More cores -> more computing per second -> more GC's per second. – Marko Topolnik May 16 '13 at 14:17
Same JVM on both machines? (1.6x64) – assylias May 16 '13 at 14:17
@assylias Same JVM on both (updated question). – jelford May 16 '13 at 14:19
@MarkoTopolnik good point - but this is actually more GCs for the whole startup sequence, not just more GCs per minute. Will update. – jelford May 16 '13 at 14:20
Is it the same OS also? – NG. May 16 '13 at 14:20
up vote 1 down vote accepted

Puzzling question...

Short answer

No, the GC frequency is only a function of your creation rate. Unless your application takes advantage of this new hardware, the GC frequency should be identical.

Long answer

I don't think it is related to the OS upgrade, nor do I think the increase in total RAM has something to do with it.

It cannot come from an increase in pointers size since the maximum heap size is 1GB. So the JVM already uses 32-bits pointers, even if you are on a 64-bits JVM.

Is your application using all of the cores during startup ?

It could explain the increase in YoungGC rates : If you application uses 8 more threads, it means that it will perform more work for the same amount of time. You should observe an increase in the allocation rate (see your GC logs).

You should also notice a drop in Young GC duration, since PSScavenge uses more threads. Is this correct ?

According to this page, ParallelGCThreads = (ncpus <= 8) ? ncpus : 3 + ((ncpus * 5) / 8). You were using 13 threads for a YGC cycle and now are using 18.

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The number of threads is corroborated by…. But the weird part is that it's more GCs over the course of the same amount of work (I think - it could be that some third party library is sneakily spawning threads). – jelford May 16 '13 at 15:33
You really need to compare your allocation rate before upgrade and after upgrade to confirm this "same amount of work" thing. If you had an AR of 500MB/s before and now you have 750MB/s, your GC will necessarely be more frequent to keep up with your application needs. – Pierre Laporte May 16 '13 at 16:12
Would I measure that by doing AR = GCs * Eden Space / #seconds? If so, then since Eden Space is unchanged, it must necessarily be more (since GC count is higher). Or have I missed something? – jelford May 16 '13 at 16:19
AR = ((Heap occupancy after previous GC - Heap occupancy before current GC) / (Current GC timestamp - Previous GC timestamp)). You should use a log viewer like HPJMeter to calculate this automatically – Pierre Laporte May 17 '13 at 8:46
Accepted this - as you so rightly pointed out, more GC probably = more work. Turns out, it was doing more work; persisted state was being re-loaded in staging that had been cleared in PROD. About 7gb of it (all thrown away as soon as processed, which is why it wasn't obvious). – jelford May 17 '13 at 13:01

It depend on your os architecture (x64 or x86) with a x86 the jvm goes up to 4Gb with a x64 it goes to 2Gb (RAM ammount).

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