By Poonam-Oracle on Jul 31, 2013
Low pause times during the application run is the most important goal for many enterprise applications, especially for the transaction-based systems where long latencies can result in the transaction time-outs. For systems running on the Java Virtual Machines, garbage collections can sometimes be the cause of the long pauses.
In this post I am going to describe different scenarios where we can encounter long GC pauses and how we can diagnose and troubleshoot these GC pauses.
Following are the different situations that can cause long GC pauses during the application run.
1. Fragmentation in the heap
Fragmentation in the Java Heap can cause GCs to occur more frequently and also sometimes causing long pauses in the GCs. This is more probable in the case of Concurrent Mark Sweep collector, also known as CMS, where the tenured generation space is not compacted with the concurrent collections.
In case of the CMS, due to fragmentation in the tenured generation space, the young generation collections can face promotion failures and thus triggering 'Concurrent Mode Failure' collections that are stop-the-world Full GCs, and Full GCs take a long time to finish as compared to the concurrent collection pauses.
Due to the fragmentation, the direct allocations in the tenured generation may fail even when there is lot of free space available and thus causing Full GCs. Fragmentation can also cause frequent allocation failures and thus triggering frequent Full GCs that increase the overall time the application is paused for.
The following logs collected with the CMS collector show that the fragmentation in the CMS generation space is very high, that leads to the promotion failure during a young generation ParNew collection and then a 'concurrent mode failure'. A Full GC is done in the event of 'concurrent mode failure' that takes a very long time, 17.1365396 seconds to finish.
2. Other OS activities happening at the time of GC
Sometimes the OS activities such as the swap space or networking activity happening at the time when GC is taking place can make the GC pauses last much longer. These pauses can be of the order of few seconds to some minutes.
If your system is configured to use swap space, Operating System may move inactive pages of memory of the JVM process to the swap space, to free up memory for the currently active process which may be the same process or a different process on the system. Swapping is very expensive as it requires disk accesses which are much slower as compared to the physical memory access. So, if during a garbage collection the system needs to perform swapping, the GC would seem to run for a very long time.
Following is the log of a young generation collection that lasts for 29.47 seconds.
Corresponding 'vmstat' output at 03:58:
This minor GC takes around 29 secs to complete. The corresponding vmstat output shows that the available swap space drops down by ~600mb during this period. That means during this garbage collection some pages from the RAM were moved out to the swap space, not necessarily by the same process running on the system.
From the above, it is clear that the physical memory available on the system is not enough for all the processes running on the system. The way to resolve this is to run fewer processes or if possible, add more RAM to increase the physical memory of the system. In the case above, the specified maximum tenured generation size is set as 9G and out of that only 1.8G is occupied. So it makes sense to reduce the heap size to lower the memory pressure on the physical memory so as to avoid or minimize the swapping activity.
Apart from swapping, we should monitor if there is any i/o or network activity happening during the long GC pauses. These can be monitored using iostat and netstat tools. It is also helpful to see the CPU statistics with the mpstat tool to figure out if enough CPU resources were available during the GC pauses.
3. Insufficient heap size
If the application footprint is larger than the maximum heap space that we have specified for the JVM, it results in frequent collections. Due to the insufficient heap space, the allocation requests fail and the JVM needs to invoke garbage collections in an attempt to reclaim space for the allocations. But since it cannot claim much space with each collection, subsequent allocation failures result in more GC invocations.
These frequent Full GCs cause long pauses in the application run. For example, in the following case, the permanent generation is almost full and the allocation attempts into the permanent generation are failing, triggering the Full GCs.
Similarly, the frequent Full GCs can occur if there is insufficient space in the tenured generation for the allocations or promotions.
The solution for these long pauses is to identify the average footprint of the application and then specify the heap size accordingly.
4. Bug in the JVM
Sometimes these long pauses could be due to a bug in the JVM. For example, due to the following bugs in the JVM, Java applications may face long GC pauses.
- 6459113: CMS+ParNew: wildly different ParNew pause times depending on heap shape caused by allocation spread
- fixed in JDK 6u1 and 7
- 6572569: CMS: consistently skewed work distribution indicated in (long) re-mark pauses
- fixed in JDK 6u4 and 7
- 6631166: CMS: better heuristics when combatting fragmentation
- fixed in JDK 6u21 and 7
- 6999988: CMS: Increased fragmentation leading to promotion failure after CR#6631166 got implemented
- fixed in JDK 6u25 and 7
- 6683623: G1: use logarithmic BOT code such as used by other collectors
- fixed in JDK 6u14 and 7
- 6976350: G1: deal with fragmentation while copying objects during GC
- fixed in JDK 8
If you are running with a JVM version affected with these bugs, please upgrade to the version where these bugs are fixed.
5. Explicit System GCs
Check if there are any explicit System GCs happening. Requests to invoke these System GCs which are stop-the-world Full GCs could be coming from the System.gc() calls from some class in the application or from a some third party module. These explicit System GCs too can cause very long pauses.
If you are using RMI and are observing explicit Full GCs on a regular interval, then these are coming from the RMI implementation that triggers System.gc() on a regular interval. This interval can be configured using the following system properties:
The default value for these properties in JDK 1.4.2 and 5.0 is 60000 milliseconds, and 3600000 milliseconds in JDK 6 and later releases.
If you want to disable the explicit Full GCs invoked using System.gc(), run the application with -XX:+DisableExplicitGC JVM option.
How to approach the problem
1. Collect GC logs with -XX:+PrintGCDetails -XX:+PrintHeapAtGC -XX:+PrintGCTimeStamps -XX:+PrintGCDateStamps and -XX:+PrintGCApplicationStoppedTime. In case of the CMS collector, add option -XX:PrintFLSStatistics=2 as well.
The GC logs can give us details on the nature and the frequency of the GC pauses i.e. they can provide answers to the questions like - are the long GC pauses occurring during young collections or old collections, and how frequently those collections are encountering long pauses.
2. Monitor the overall health of the system using OS tools like vmstat, iostat, netstat and mpstat etc. on Solaris and Linux platforms, and tools like Process Monitor and Task Manager on the Windows operating system.
3. Use GCHisto tool to visually analyze the GC Logs and figure out which GCs are taking long time and if there is a pattern in the occurrence of these collections.
4. Try to see from the GC logs if there are any signs of fragmentation in the Java Heap space.
5. Monitor if the specified Heap size is enough to contain the footprint of the application.
6. Check if you are running with a JVM that has a known bug related to the long GC pauses and then upgrade if that bug is fixed in a later version.