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My openfire server chat reach high CPU and RAM.
It becomes bigger time by time.
It is 4579MB RAM (openfire process 41.3%) at this time, but after 5 minutes, it will be 4600MB (41.5%). Bigger then bigger.
And it will reach ~100% RAM usage at the next morning.
I just used room chat feature.
Concurency ~600 at day, ~300 at night.
Connection timeout 30 min.
Openfire version: 4.2.1
What's my problem? How can I resolve it?
Thanks!
Openfire is written in Java. Java's memory management works in a way that is not compatible with how you analyzed your system. Java's memory usage can be expected to grow over time, up until it uses up a significant amount of memory that is available to it. Only then, a memory cleanup (garbage collect) will take place.
From what you wrote, it is not clear that you actually are experiencing a memory leak. Garbage collections can be infrequent: 5 minutes is not nearly enough time to observer a memory leak.
To get some kind of indication, try observing your process for a number of days. If you see a steady increase in memory usage, when usage patterns are not changed, then you can carefully assume that a memory leak might be present. If you get to that level, you'll need specialized tooling to inspect the state of the Java heap.
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How to force garbage collection in Java?
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Closed 9 years ago.
I have an application that's running on a 24x6 schedule. Currently, after running for a few days, a Full GC is performed automatically - and usually during a busy part of the day, which negatively impacts user response times.
What I'd like to do is force a Full GC - perhaps at midnight each night, during very low usage times - to prevent it from happening during the day. I've tried System.gc(), but it doesn't seem to guarantee when a Full GC will happen, or even if it will. Is there some means of doing this?
Version info:
Java(TM) SE Runtime Environment (build 1.6.0_11-b03)
Java HotSpot(TM) Server VM (build 11.0-b16, mixed mode)
Additionally -
Minor GCs are running, about every 10-15 seconds. But these are are not freeing up enough RAM to get the app through a full week. When a Full GC does happen, nearly 50% of the heap is freed.
In relation to the above, calling System.gc() doesn't seem to mean that any of the next GCs, will be of the Full form needed to free those large chucks of memory. Yes, it is enabled (or not disabled, depending on how you read the -XX option).
I've already played around with several of the CMS GC settings, which has helped greatly, but not solved the problem. Originally it was throwing OOMs, two to three times a week.
I want to stop the endless loops of:
constantly adding to heap space - which can only go on for so long
constant tuning and testing of GC settings - it is long past the point of diminishing return
I don't want to treat this like an NT machine and bounce it nightly. There are active user sessions throughout the night, and bouncing the app would mean loosing session data.
To be more specific, I'm looking more for a technique to use to ensure that a Full GC is going to happen, rather than a simple method/function to call to run it.
At the moment I'm looking at the modification of the percentage threshold used by CMS to determine when a Full GC is required.
Thanks for any help.
jmap -histo:live <PID> will force Full GC as "side effect" of finding all live objects. You can schedule it to recycle your JVM processes on off-working hours.
Your JVM build 1.6.0_11-b03 is pretty ancient, but jmap should be supported on all 1.6 HotSpot JVMs.
No.
System.gc() suggests to the GC that you would like a collection.
Further, there is probably very little garbage generated during the quiet period and that is why calling System.gc() doesn't do much.
During peak time there is, presumably, more activity and therefore more garbage being generated - hence the need for a collection.
It should be obvious that you cannot defer collection in that simplistic manner. The JVM will collect when it needs to.
You need to look into tuning your GC - if you have stop the world collection happening then you have some issue. This shouldn't really happen on a modern server JVM.
You should look into tuning the CMS collector - this is a pretty good article on the basics of the GC system in Java. In Java 7 there is the new G1GC which may or may not be better.
You should find a way to simulate load conditions and try different GC parameters, the CMS GC has many tuning parameters and configuring it is somewhat of a dark art...
This is a somewhat more involved article on GC tuning and benchmarking.
I'd say yes - schedule a process for your quiet time that does something you believe will trigger a GC.
Eat some serious memory. Allocate a truckload of objects and use weak references to keep track of them - just do something at your quiet time that should trigger a GC.
Do make sure you have in place some logic that detects the GC and stops the process.
There is no way to force and immediate collection as the garbage collector is non-deterministic.
I have an application that is responsible for archiving old applications, which will do a large number of applications at a time and so it will need to run for days at a time.
When my company developed this they did a fair bit of performance testing on it and they seemed to get decent numbers out of this, but I have been running an archive for a customer recently and it seems to be running really slowly and the performance seems to be degrading even more longer it runs.
There does not appear to be a memory leak, as since I have monitoring it with jconsole there still is plenty of memory available and does not appear to be shrinking.
I have noticed however that the survivor space and tenured gen of the heap can very quickly fill up until a garbage collection comes along and clears it out which seems to be happening rather frequently which I am not sure if that could be a source of the apparent slow down.
The application has been running now for 7 days 3 hours and according to jconsole it has spent 6 hours performing copy garbage collection (772, 611 collections) and 12 hours and 25 minutes on marksweep compaction's (145,940 collections).
This seems like a large amount of time to be spent on garbage collection and I am just wondering if anyone has looked into something like this before and knows if this is normal or not?
Edits
Local processing seems to be slow, for instance I am looking at one part in the logs that took 5 seconds to extract some xml from a SOAP envelope using xpath which it then appends to a string buffer along with a root tag.. that's all it does. I haven't profiled it yet, as this is running in production, I would either have to pull the data down over the net or set up a large test base in our dev environment which may end up having to do.
Running Java HotSpot Client VM version 10.0-b23
Really just need high throughput, haven't configured any specific garbage collection parameters, would be running what ever the defaults would be. Not sure how to find what collectors would be in use?
Fix
End up getting a profiler going on it, turned out the cause of the slow down was some code that was constantly trimming lines off a status box outputting logging statements which was pretty badly done. Should have figured the garbage collection was symptom from constantly copying the status text into memory, rather than an actual cause.
Cheers Guys.
According to your numbers, total garbage collection time was about 18 hours out of 7 days execution time. At about 10% of total execution time, that's slightly elevated, but even if you managed to get this down to 0%, you'd only have saved 10% execution time ... so if you're looking for substantial savings, you should better look into the other 90%, for instance with a profiler.
Without proper profiling, this is a guessing game. As an anectode, though, a few years ago a web app I was involved with at the time suddenly slowed down (response time) by a factor of 10 after a JDK upgrade. We ended up chasing it down to an explicit GC invocation added by a genious who was no longer with the company.
There is a balance you will try and maintain between JVM heap footprints and GC time. Another question might be do you have heap (and generations) (under-)allocated in such a way which mandates too frequent GCing. When deploying muti-tenant JVMs on these system, I've tried to maintain the balance to under 5% total GC time along with aggressive heap shrinkage to keep footprint low (again, multi-tenant). Heap and generations will mostly ALWAYS fill as to avoid frequent GCing to whatever it is set. Remove the -Xms parameter to see a more realistic steady state (if it has any idle time)
+1 to the suggestion on profiling though; it may be something not related to GC, but code.
I have heard several people claiming that you can not scale the JVM heap size up. I've heard claims of the practical limit being 4 gigabytes (I heard an IBM consultant say that), 10 gigabytes, 32 gigabytes, and so on... I simply can not believe any of those numbers and have been wondering about the issue now for a while.
So, I have three part question I would hope someone with experience could answer:
Given the following case how would you tune the heap and GC settings?
Would there be noticeable hickups (pauses of JVM etc) that would be noticed by the end users?
Should this really still work? I think it should.
The case:
64 bit platform
64 cores
64 gigabytes of memory
The application server is client facing (ie. Jboss/tomcat web application server) - complete pauses of JVM would probably be noticed by end users
Sun JVM, probably 1.5
To prove I am not asking you guys to do my homework this is what I came up with:
-XX:+UseConcMarkSweepGC -XX:+AggressiveOpts -XX:+UnlockDiagnosticVMOptions -XX:-EliminateZeroing -Xmn768m -Xmx55000m
CMS should reduce the amount of pauses, although it comes with overhead. The other settings for CMS seem to default automatically to the number of CPUs so they seem sane to me. The rest that I added are extras that might do good or bad generally for performance, and they should probably be tested.
Definitely.
I think it's going to be difficult for anybody to give you anything more than general advice, without having further knowledge of your application.
What I would suggest is that you use VisualGC (or the VisualGC plugin for VisualVM) to actually look at what the garbage collection is doing when your app is running. Once you have a greater understanding of how the GC is working alongside your application, it'll be far easier to tune it.
#1. Given the following case how would you tune the heap and GC settings?
First, having 64 gigabytes of memory doesn't imply that you have to use them all for one JVM. Actually, it rather means you can run many of them. Then, it is impossible to answer your question without any access to your machine and application to measure and analyse things (knowing what your application is doing isn't enough). And no, I'm not asking to get access to your environment :)
#2. Would there be noticeable hickups (pauses of JVM etc) that would be noticed by the end users?
The goal of tuning is to find a good compromise between frequency and duration of (major) GCs. With a ~55g heap, GC won't be frequent but will take noticeable time, for sure (the bigger the heap, the longer the major GC). Using a Parallel or Concurrent garbage collector will help on multiprocessor systems but won't entirely solve this issue. Why do you need ~55g (this is mega ultra huge for a webapp IMO), that's my question. I'd rather run many clustered JVMs to handle load if required (at some point, the database will become the bottleneck anyway with a data oriented application).
#3. Should this really still work? I think it should.
Hmm... not sure I get the question. What is "this"? Instantiating a JVM with a big heap? Yes, it should. Is it equivalent to running several JVMs? No, certainly not.
PS: 4G is the maximum theoretical heap limit for the 32-bit JVM running on a 64-bit operating system (see Why can't I get a larger heap with the 32-bit JVM?)
PPS: On 64-bit VMs, you have 64 bits of addressability to work with resulting in a maximum Java heap size limited only by the amount of physical memory and swap space your system provides. (see How large a heap can I create using a 64-bit VM?)
Obviously heap size is not unlimited and the larger is the heap size, the more your JVM will eventually spend on GC. Though I think it is possible to set heap size quite high on 64-bit JVM, I still think it's not really practical. The advice here is better to have several JVMs running with the same parameters i.e. cluster of JBoss/Tomcat nodes running on the same physical machine and you will get better throughput.
EDIT: Also your GC behavior depends on the taxonomy of your heap. If you have a lot of short-living objects and each request to the server creates a lot of those, then your GC will collect a lot of garbage very often and thus on large heap size this will result in longer pauses. If you have very many long-living objects (e.g. caching most of your data in memory) and the amount of short-living objects is not that big, then having bigger heap size is OK.
As Chris Rice already wrote, I wouldn't expect any obvious problems with the GC for heap sizes up to 32-64GB, although there may of course be some point of your application logic, which can cause problems.
Not directly related to GC, but I would still recommend you to perform a realistic load test on your production system. I used to work on a project, where we had a similar setup (relatively large, clustered JBoss/Tomcat setup to serve a public web application) and without exaggeration, JBoss is not behaving very well under high load or with a high number of concurrent calls if you are using EJBs. JBoss is spending a lot of time in synchronized blocks when accessing and managing the EJB instance pools and if you opt for a cluster, it will even wait for intra-cluster network communication within these synchronized blocks. Be especially aware of poorly performing state replication, if you are using SFSBs.
Only to add some more switches I would use by default: -Xms55g can help to reduce the rampup time because it frees Java from the need to check if it can fall back to the initial size and allows also better internal initial sizing of memory areas.
Additionally we made good experiences with NewSize to give you a large young size to get rid of short term garbage: -XX:NewSize=1g Additionally most webapps create a lot of short time garbage that will never survive the request processing. You can even make that bigger. With Xms55g, the VM reserves a large chunk already. Maybe downsizing can help.
-Xincgc helps to clean the young generation incrementally and return the cpu often to the user threads.
-XX:CMSInitiatingOccupancyFraction=70 If you really fill all that memory, try to start CMS garbage collection earlier.
-XX:+CMSIncrementalMode puts the CMS into incremental mode to return the cpu to the user threads more often.
Attach to the process with jstat -gc -h 10 <pid> 1s and watch the GC working.
Will you really fill up the memory? I assume that 64cpus for request processing might even be able to work with less memory. What do you store in there?
Depending on your GC pause analysis, you may wish to implement Incremental mode whereby the long pause may be broken out over a period of time.
I have found memory architecture plays a part in large memory sizes. Applications in general don't perform as well if they use more than one memory bank. The JVM appears to suffer as well, esp the GC which has to sweep the whole memory.
If you have an application which doesn't fit into one memory bank, your application has to pull in memory which is not local to a processor and use memory local to another processor.
On linux you can run numactl --hardware to see the layout of processors and memory banks.
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Does anyone have experience with using very large heaps, 12 GB or higher in Java?
Does the GC make the program unusable?
What GC params do you use?
Which JVM, Sun or BEA would be better suited for this?
Which platform, Linux or Windows, performs better under such conditions?
In the case of Windows is there any performance difference to be had between 64 bit Vista and XP under such high memory loads?
If your application is not interactive, and GC pauses are not an issue for you, there shouldn't be any problem for 64-bit Java to handle very large heaps, even in hundreds of GBs. We also haven't noticed any stability issues on either Windows or Linux.
However, when you need to keep GC pauses low, things get really nasty:
Forget the default throughput, stop-the-world GC. It will pause you application for several tens of seconds for moderate heaps (< ~30 GB) and several minutes for large ones (> ~30 GB). And buying faster DIMMs won't help.
The best bet is probably the CMS collector, enabled by -XX:+UseConcMarkSweepGC. The CMS garbage collector stops the application only for the initial marking phase and remarking phases. For very small heaps like < 4 GB this is usually not a problem, but for an application that creates a lot of garbage and a large heap, the remarking phase can take quite a long time - usually much less then full stop-the-world, but still can be a problem for very large heaps.
When the CMS garbage collector is not fast enough to finish operation before the tenured generation fills up, it falls back to standard stop-the-world GC. Expect ~30 or more second long pauses for heaps of size 16 GB. You can try to avoid this keeping the long-lived garbage production rate of you application as low as possible. Note that the higher the number of the cores running your application is, the bigger is getting this problem, because the CMS utilizes only one core. Obviously, beware there is no guarantee the CMS does not fall back to the STW collector. And when it does, it usually happens at the peak loads, and your application is dead for several seconds. You would probably not want to sign an SLA for such a configuration.
Well, there is that new G1 thing. It is theoretically designed to avoid the problems with CMS, but we have tried it and observed that:
Its throughput is worse than that of CMS.
It theoretically should avoid collecting the popular blocks of memory first, however it soon reaches a state where almost all blocks are "popular", and the assumptions it is based on simply stop working.
Finally, the stop-the-world fallback still exists for G1; ask Oracle, when that code is supposed to be run. If they say "never", ask them, why the code is there. So IMHO G1 really doesn't make the huge heap problem of Java go away, it only makes it (arguably) a little smaller.
If you have bucks for a big server with big memory, you have probably also bucks for a good, commercial hardware accelerated, pauseless GC technology, like the one offered by Azul. We have one of their servers with 384 GB RAM and it really works fine - no pauses, 0-lines of stop-the-world code in the GC.
Write the damn part of your application that requires lots of memory in C++, like LinkedIn did with social graph processing. You still won't avoid all the problems by doing this (e.g. heap fragmentation), but it would be definitely easier to keep the pauses low.
I am CEO of Azul Systems so I am obviously biased in my opinion on this topic! :) That being said...
Azul's CTO, Gil Tene, has a nice overview of the problems associated with Garbage Collection and a review of various solutions in his Understanding Java Garbage Collection and What You Can Do about It presentation, and there's additional detail in this article: http://www.infoq.com/articles/azul_gc_in_detail.
Azul's C4 Garbage Collector in our Zing JVM is both parallel and concurrent, and uses the same GC mechanism for both the new and old generations, working concurrently and compacting in both cases. Most importantly, C4 has no stop-the-world fall back. All compaction is performed concurrently with the running application. We have customers running very large (hundreds of GBytes) with worse case GC pause times of <10 msec, and depending on the application often times less than 1-2 msec.
The problem with CMS and G1 is that at some point Java heap memory must be compacted, and both of those garbage collectors stop-the-world/STW (i.e. pause the application) to perform compaction. So while CMS and G1 can push out STW pauses, they don't eliminate them. Azul's C4, however, does completely eliminate STW pauses and that's why Zing has such low GC pauses even for gigantic heap sizes.
We have an application that we allocate 12-16 Gb for but it really only reaches 8-10 during normal operation. We use the Sun JVM (tried IBMs and it was a bit of a disaster but that just might have been ignorance on our part...I have friends that swear by it--that work at IBM). As long as you give your app breathing room, the JVM can handle large heap sizes with not too much GC. Plenty of 'extra' memory is key.
Linux is almost always more stable than Windows and when it is not stable it is a hell of a lot easier to figure out why. Solaris is rock solid as well and you get DTrace too :)
With these kind of loads, why on earth would you be using Vista or XP? You are just asking for trouble.
We don't do anything fancy with the GC params. We do set the minimum allocation to be equal to the maximum so it is not constantly trying to resize but that is it.
I have used over 60 GB heap sizes on two different applications under Linux and Solaris respectively using 64-bit versions (obviously) of the Sun 1.6 JVM.
I never encountered garbage collection problems with the Linux-based application except when pushing up near the heap size limit. To avoid the thrashing problems inherent to that scenario (too much time spent doing garbage collection), I simply optimized memory usage throughout the program so that peak usage was about 5-10% below a 64 GB heap size limit.
With a different application running under Solaris, however, I encountered significant garbage-collection problems which made it necessary to do a lot of tweaking. This consisted primarily of three steps:
Enabling/forcing use of the parallel garbage collector via the -XX:+UseParallelGC -XX:+UseParallelOldGC JVM options, as well as controlling the number of GC threads used via the -XX:ParallelGCThreads option. See "Java SE 6 HotSpot Virtual Machine Garbage Collection Tuning" for more details.
Extensive and seemingly ridiculous setting of local variables to "null" after they are no longer needed. Most of these were variables that should have been eligible for garbage collection after going out of scope, and they were not memory leak situations since the references were not copied. However, this "hand-holding" strategy to aid garbage collection was inexplicably necessary for some reason for this application under the Solaris platform in question.
Selective use of the System.gc() method call in key code sections after extensive periods of temporary object allocation. I'm aware of the standard caveats against using these calls, and the argument that they should normally be unnecessary, but I found them to be critical in taming garbage collection when running this memory-intensive application.
The three above steps made it feasible to keep this application contained and running productively at around 60 GB heap usage instead of growing out of control up into the 128 GB heap size limit that was in place. The parallel garbage collector in particular was very helpful since major garbage-collection cycles are expensive when there are a lot of objects, i.e., the time required for major garbage collection is a function of the number of objects in the heap.
I cannot comment on other platform-specific issues at this scale, nor have I used non-Sun (Oracle) JVMs.
12Gb should be no problem with a decent JVM implementation such as Sun's Hotspot.
I would advice you to use the Concurrent Mark and Sweep colllector ( -XX:+UseConcMarkSweepGC) when using a SUN VM.Otherwies you may face long "stop the world" phases, were all threads are stopped during a GC.
The OS should not make a big difference for the GC performance.
You will need of course a 64 bit OS and a machine with enough physical RAM.
I recommend also considering taking a heap dump and see where memory usage can be improved in your app and analyzing the dump in something such as Eclipse's MAT . There are a few articles on the MAT page on getting started in looking for memory leaks. You can use jmap to obtain the dump with something such as ...
jmap -heap:format=b pid
As mentioned above, if you have a non-interactive program, the default (compacting) garbage collector (GC) should work well. If you have an interactive program, and you (1) don't allocate memory faster than the GC can keep up, and (2) don't create temporary objects (or collections of objects) that are too big (relative to the total maximum JVM memory) for the GC to work around, then CMS is for you.
You run into trouble if you have an interactive program where the GC doesn't have enough breathing room. That's true regardless of how much memory you have, but the more memory you have, the worse it gets. That's because when you get too low on memory, CMS will run out of memory, whereas the compacting GCs (including G1) will pause everything until all the memory has been checked for garbage. This stop-the-world pause gets bigger the more memory you have. Trust me, you don't want your servlets to pause for over a minute. I wrote a detailed StackOverflow answer about these pauses in G1.
Since then, my company has switched to Azul Zing. It still can't handle the case where your app really needs more memory than you've got, but up until that very moment it runs like a dream.
But, of course, Zing isn't free and its special sauce is patented. If you have far more time than money, try rewriting your app to use a cluster of JVMs.
On the horizon, Oracle is working on a high-performance GC for multi-gigabyte heaps. However, as of today that's not an option.
If you switch to 64-bit you will use more memory. Pointers become 8 bytes instead of 4. If you are creating lots of objects this can be noticeable seeing as every object is a reference (pointer).
I have recently allocated 15GB of memory in Java using the Sun 1.6 JVM with no problems. Though it is all only allocated once. Not much more memory is allocated or released after the initial amount. This was on a Linux but I imagine the Sun JVM will work just as well on 64-bit Windows.
You should try running visualgc against your app. It´s a heap visualization tool that´s part of the jvmstat download at http://java.sun.com/performance/jvmstat/
It is a lot easier than reading GC logs.
It quickly helps you understand how the parts (generations) of the heap are working. While your total heap may be 10GB, the various parts of the heap will be much smaller. GCs in the Eden portion of the heap are relatively cheap, while full GCs in the old generation are expensive. Sizing your heap so that that the Eden is large and the old generation is hardly ever touched is a good strategy. This may result in a very large overall heap, but what the heck, if the JVM never touches the page, it´s just a virtual page, and doesn´t have to take up RAM.
A couple of years ago, I compared JRockit and the Sun JVM for a 12G heap. JRockit won, and Linux hugepages support made our test run 20% faster. YMMV as our test was very processor/memory intensive and was primarily single-threaded.
here's an article on gc FROM one of Java Champions --
http://kirk.blog-city.com/is_your_concurrent_collector_failing_you.htm
Kirk, the author writes
"Send me your GC logs
I'm currently interested in studying Sun JVM produced GC logs. Since these logs contain no business relevent information it should be ease concerns about protecting proriatary information. All I ask that with the log you mention the OS, complete version information for the JRE, and any heap/gc related command line switches that you have set. I'd also like to know if you are running Grails/Groovey, JRuby, Scala or something other than or along side Java. The best setting is -Xloggc:. Please be aware that this log does not roll over when it reaches your OS size limit. If I find anything interesting I'll be happy to give you a very quick synopsis in return. "
An article from Sun on Java 6 can help you: https://www.oracle.com/java/technologies/javase/troubleshooting-javase.html
The max memory that XP can address is 4 gig(here). So you may not want to use XP for that(use a 64 bit os).
sun has had an itanium 64-bit jvm for a while although itanium is not a popular destination. The solaris and linux 64-bit JVMs should be what you should be after.
Some questions
1) is your application stable ?
2) have you already tested the app in a 32 bit JVM ?
3) is it OK to run multiple JVMs on the same box ?
I would expect the 64-bit OS from windows to get stable in about a year or so but until then, solaris/linux might be better bet.