How to interpret a method profile

In a previous post, I described the general methodology I use to diagnose performance problems.

Once an application has been identified as CPU-bound, either by using the Health Center or CPU monitoring, the next step is to figure out what is eating CPU. In a Java application, this will usually be Java code, but it could be native code. Profiling native code usually requires platform specific tools; on linux, I use tprof. Profiling Java code is a lot easier, and is more likely to yield big performance improvements, so I usually start with a Java profile and only profile native code if I didn't get anywhere with the Java profile. For Java profiling, I use the Health Center. It's got a few advantages, one of which is that there's no bytecode instrumentation needed, there's no need to specify only a few packages to profile, and the overhead is very low, so it won't affect the performance characteristics of what you're trying to profile.

So what does a method profile tell you? Simply put, it tells you what your application is spending its time doing. More precisely, it tells you what code your application is spending its time running - it doesn't tell you when your application is waiting on a lock instead of running your code, and it doesn't tell you when the JVM is collecting garbage instead of running your code. Assuming locking and GC aren't the cause of the performance problem (see triaging a performance problem), the method profile will give you the information you need to make your application go faster.

The application is doing too much work, and that's slowing it down. Your aim in performance tuning is to make the application do less work. There are lots of ways to make code more efficient. Sometimes people start performance tuning by code inspection - they read through the code base looking for obvious inefficiencies. I've done this myself lots of times, but it's not a particularly efficient technique. Say I find a method which is pretty carelessly implemented, and I double its speed with a bit of refactoring. Then I triumphantly re-run my application, only to discover nothing's changed. What's going on? The problem is that a big performance improvement on a method which is rarely called isn't going to change much of anything. For example, if I double the speed of a method which uses 0.5% of my CPU time, I've sped my application up by an imperceptible 0.25%. If, on the other hand, I shave 10% of the time of a method which is using 20% of my CPU, my application will go 2% faster. So the first rule of performance tuning is to optimise the methods at the top of the profile and ignore the ones near the bottom.

This is example from a method profiler, in this case the one in the Health Center. One method is clearly using more CPU than the rest, and so it's coloured red. In this case, 60% of the time the JVM checked what the application was doing, it was executing the FireworkParticle.animate() method. This is what's shown by the left-hand 'Self' column. The 'Tree' column on the right shows how much time the application spent in both the animate() method and its descendants. Some profilers call this column 'descendants' instead. Usually the Self figures are more useful for optimising an application.



What makes a method appear near the top of a method profile? It's taking up a lot of CPU time, but why? There are two reasons; either the method is being called too often, or the method is doing too much work when it's called. Sometimes it happens that a method really is doing the right amount of work the right number of times, but this is usually only the case after a fair amount of work. In their natural state, most programs can - and should - contain inefficiencies. (Remember that premature optimisation is the root of all evil.)

Some profilers can distinguish between a method which is called several times, and one which is called once and then spends a long time executing, but many cannot. The reason is that some profilers operate by tracing - that is, recording every entry and exit of a method. This gives very precise information, but usually carries a fairly heavy performance cost. The IBM JVM can be configured with launch parameters to count or time method executions, but it's only advisable to do this for a restricted subset of methods. An alternate method of collecting profiling information is to sample - that is, check periodically what method is executing. This is much less expensive but doesn't give as much detail as tracing profilers. The Health Center uses method sampling already built into the JVM to allow profiling with extremely low overhead.

Often it will be obvious when inspecting a hot method if it's being called frequently or is slow to run. Code with loops, particularly nested loops, is probably expensive to run. Code which doesn't seem to do much but which is at the top of a profile is probably being called a lot. This leads neatly to the next steps in optimization: eliminate loops and do less work inside loops for expensive methods, and call inexpensive method less frequently.

How do you go about making sure a method is called less? Method profilers which also record stack traces can make calling method less pretty easy. For example, this is the output of the Health Center, showing where calls to one of the top methods in the profile have come from:



In this case, 98% of the time the doSomeWork() method was sampled, it was animate() that called it. 2% of the time, it was draw() that called it. In this case, the next step is to inspect the animate() method and see why it's calling doSomeWork(). Often, at least in the first passes of optimisation, most of the calls to the top method are totally unnecessary and can be trivially eliminated.

How do you solve a performance problem?

I was talking to a friend today about a performance problem he was seeing, and he explained that he wasn't entirely sure how to fix it. Performance tuning can be very skilled, but the basic principles are straightforward and should be accessible to every Java developer.

This is the methodology I recommend.

All performance problems are caused by a limited resource. Your job as a performance analyst (or developer who's suddenly required to be a performance analyst) is to identify what resource is limited - what's the bottleneck for this application? Often after fixing the first bottleneck, a second bottleneck will become apparent - the process of performance tuning is the process of eliminating bottlenecks, one by one, until the performance is good enough for you and your stakeholders.

Computational resources fall into a few basic categories. Different people count them differently, but I like to think of four types of resource: the CPU, memory, I/O, and locks.

A CPU-bound application can't get enough processor time to complete its work. A memory-bound application needs more memory than is available. An I/O-bound application is trying to do I/O faster than the system can handle. Finally, a lock-bound application is being held up by the fact that multiple threads are contending on the same locks. 'Lock-bound' isn't a terribly common term, but I think it's really important to consider lock contention when analyzing performance problems. As systems become more and more parallel, synchronization are increasingly a limiting factor in the scalability of the system.

So how do you identify which of these resources is the cause of the hold-up? Some heuristics can help as a first step. If the CPU is at or near 100%, the CPU is likely to be the culprit. If the CPU isn't near 100%, it's probably locking or I/O. The rule of thumb becomes a bit muddier when it comes to memory. Sometimes memory problems can show up as low CPU usage, because the system is waiting on a heap lock (which is properly locking) or physical memory access - paging in the worst case (technically, I/O). However, in a garbage collected system, excessive memory consumption will often manifest as lots of processing time being spent in the garbage collector (CPU).

Tools can help turn these fairly fuzzy heuristics into a more precise diagnosis. There are lots of tools available, both free and not-free. My favourite tool is IBM's Health Center. This is probably because I'm the technical lead for the Health Center, so I think what it does is pretty sensible and cool. :) The Health Center is free, but it can only monitor IBM JVMs. I do think it's one of the best ways to investigate garbage collection, locking, and collect method profiles from an IBM JVM.

The Health Center tries to automate the process of identifying the root cause of a performance problem. The front page shows a dashboard with a bunch of status indicators. If one of them is red or orange, that's a pretty good indicator of where to start tweaking the performance. The one area the Health Center doesn't cover at the moment is I/O. It can identify garbage collection and locking bottlenecks pretty accurately, and the method profiler can identify the root cause of much excessive CPU usage.



So let's say you've used the Health Center (or your tool of choice) and you're seeing some red crosses. What next? In the Health Center, clicking on the link next to a red cross will bring up more information and more detailed recommendations about how to fix the problem. In later posts I'll give a bit more background about how to go about fixing locking issues, memory issues, and CPU issues.

Forward links:

• How to interpret a method profile
  

More Health Center features

In a previous post, I described a new IBM tool, IBM Monitoring and Diagnostic Tools for Java - Health Center. We've added some new features to the Health Center beta.

Ever wondered what the classpath of that application which is behaving strangely is? Or why all the core files are truncated? The environment perspective provides details of the Java version, Java classpath, boot classpath, environment variables, and system properties. This can be really handy for debugging problems, particularly problems on remote systems or systems where you don't control the configuration. It also shows the ulimit, which is a common cause of strange behaviour on linux and unix systems. If the Health Center detects misconfigured applications, it will provide recommendations on how to fix it.



Another new feature is the ability to export and import data. This means one person can collect the data, and if there's a problem, they can send it to someone else for more analysis. For example, if a method is unusually hot in the method profile, a system operator could send the exported data to the developer responsible for that area of the code.

IBM Monitoring and Diagnostic Tools for Java™ - Health Center™ is now available

I'm part of a team in IBM's Java Technology Centre which develops diagnostic tools, and we've just released a brand new tool. It's called IBM Monitoring and Diagnostic Tools for Java™ - Health Center™ and it's available as an early access beta download from developerWorks. We're really excited about the diagnostic insights it can offer. It allows running JVMs to be observed, health-checked, and tuned. At the moment it gives insight into general system health, application activity, and garbage collection activity. There are visualizations and also recommendations, so you don't have to be an expert to improve the performance of your application.

One of the nice things about the Health Center is that it presents different kinds of information in one place. There's a status page which shows at a glance what's going well and what might need attention:


Garbage collection is one of the first and easiest things to check when tuning an application. Sometimes garbage collection can benefit from a bit of tuning, and sometimes looking at what the garbage collection is doing can highlight application problems. Is your application using more memory than seems reasonable? Is it leaking memory? The Health Center will suggest a command line, diagnose when garbage collection is causing performance problems, and point out memory leaks:



Synchronization can be a big performance bottleneck for applications on multi-CPU systems, and it can be difficult to identify hot locks or even assess the impact of locking. The Health Center has always-on lock monitoring which identifies the objects which are most contended and provides guidance about whether synchronization is hurting performance:


Last, but not least, the Health Center includes a nice sampling method profiler. This can be really valuable in diagnosing applications which are using high CPU. Because it's low overhead, there's no need to specify in advance which parts of the application should be profiled. It works without recompilation or byte code instrumentation. It shows where the application is spending its time and gives full call stacks for all sampled methods. Because of the call stacks, this kind of profiling isn't just for performance problems - sometimes it can give surprising functional insight:


The way the Health Center is able to get so much information without much overhead is that it's closely linked to the JVM, so there are minimum system requirements. The absolute minimum requirement is an IBM JVM, version 5.0 or higher. This will give locking information and some GC information. To get profiling Java 5 SR8 or Java 6 SR1 is required. The fullest GC information is available in Java 6 service refresh 2. IBM JVMs can be downloaded from developerWorks.