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If something is making a single-thread program take, say, 10 times as long as it should, you could run a profiler on it. You could also just halt it with a "pause" button, and you'll see exactly what it's doing.

Even if it's only 10% slower than it should be, if you halt it more times, before long you'll see it repeatedly doing the unnecessary thing. Usually the problem is a function call somewhere in the middle of the stack that isn't really needed. This doesn't measure the problem, but it sure does find it.

Edit: The objections mostly assume that you only take 1 sample. If you're serious, take 10. Any line of code causing some percentage of wastage, like 40%, will appear on the stack on that fraction of samples, on average. Bottlenecks (in single-thread code) can't hide from it.

EDIT: To show what I mean, many objections are of the form "there aren't enough samples, so what you see could be entirely spurious" - vague ideas about chance. But if something of any recognizable description, not just being in a routine or the routine being active, is in effect for 30% of the time, then the probability of seeing it on any given sample is 30%.

Then suppose only 10 samples are taken. The number of times the problem will be seen in 10 samples follows a binomial distribution, and the probability of seeing it 0 times is .028. The probability of seeing it 1 time is .121. For 2 times, the probability is .233, and for 3 times it is .267, after which it falls off. Since the probability of seeing it less than two times is .028 + .121 = .139, that means the probability of seeing it two or more times is 1 - .139 = .861. The general rule is if you see something you could fix on two or more samples, it is worth fixing.

In this case, the chance of seeing it in 10 samples is 86%. If you're in the 14% who don't see it, just take more samples until you do. (If the number of samples is increased to 20, the chance of seeing it two or more times increases to more than 99%.) So it hasn't been precisely measured, but it has been precisely found, and it's important to understand that it could easily be something that a profiler could not actually find, such as something involving the state of the data, not the program counter.

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Does "halting the program" work in multi-threaded applications? –  Paul Tomblin Nov 5 '08 at 21:29
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Sadly no, that's more of a challenge. I usually concentrate on the code in each thread by itself. If there are messages between processes, I use a logging technique. Not easy, but it works. –  Mike Dunlavey Nov 5 '08 at 22:20
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You may be getting downvoted for two reasons. 1) "Why isn't it better known?" is hardly a question, and can't be answered. 2) You present an argumentative case for your method. "My way is great, why aren't you all on board yet?" isn't a good social tactic - it doesn't elicit a thoughtful response. –  Adam Davis Nov 23 '08 at 1:14
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Also, who doesn't try doing this before breaking out the profiler? –  Robert Rossney Nov 23 '08 at 1:19
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I am not bothered as such - I am just informing you that using phrases like that tend to get questions closed prematurely. It is entirely up to you to choose your wording. –  Thorbjørn Ravn Andersen Oct 17 '09 at 16:33
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17 Answers

up vote 37 down vote accepted

On Java servers it's always been a neat trick to do 2-3 quick Ctrl-Breakss in a row and get 2-3 threaddumps of all running threads. Simply looking at where all the threads "are" may extremely quickly pinpoint where your performance problems are.

This technique can reveal more performance problems in 2 minutes than any other technique I know of.

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There's still the issue of tracking down asynchronous problems, but for that other methods are needed. –  Mike Dunlavey Nov 25 '08 at 13:25
    
Have you experimented by doing this programmatically with the Java 6 additions allowing for stack trace introspection? –  Thorbjørn Ravn Andersen Oct 17 '09 at 8:34
    
I'm not sure we're thinking about the same thing; a thread dump gives you a view of where all your threads are at any given point in time. If you're going to do this inside your code, you'll need to know where to put it, right ? –  krosenvold Oct 17 '09 at 12:08
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Note that this is exactly how the "cpu=samples" feature of hprofworks. It will wake up regularly (default 10ms) and record the current stack trace of every thread. Handy if you find it difficult to press ctrl-break 100 times a second ;-). –  sleske Sep 20 '10 at 15:09
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@sleske: 1) That's a problem because it dilutes with irrelevant samples. 2) Good. 3) i.e. If your biggest problem is very small, why bother optimizing? My experience is when you think there are no big problems, there actually are (stackoverflow.com/questions/926266/…). 4) See point 3 of (stackoverflow.com/questions/1777556/alternatives-to-gprof/…). I'm sure hprof is a nice tool. So is Zoom. I need effective, not nice. –  Mike Dunlavey Nov 8 '10 at 0:56
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Because sometimes it works, and sometimes it gives you completely wrong answers. A profiler has a far better record of finding the right answer, and it usually gets there faster.

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Beg to differ. If a statement shows up on X% of N samples, then if you can get rid of it you'll save X% of time. Of course, if N is big, you'll know X with more precision, but who cares? –  Mike Dunlavey Nov 5 '08 at 20:18
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@mike you'd be surprised by how many people care. people have full time jobs working on or using profiling software. in many firms and applications it is critical and when the landscape gets big @Paul is on the money. –  dove Nov 5 '08 at 20:25
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In the sort of programs I'm working on, I'd have to hit pause about a thousand times before I got any meaningful results. –  Paul Tomblin Nov 5 '08 at 21:10
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Paul, we should get specific about what the type of program is. I've had a few bake-offs and never disappointed. If you take lots of samples while it's running (not waiting) and you can't find anything to optimize, your code is very unusual. –  Mike Dunlavey Nov 5 '08 at 21:20
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@Paul, for the archives - could you describe in more detail what programs you are working on, so we get an idea of areas where we might just as well grab the profiler instead of looking at multiple stack traces? –  Thorbjørn Ravn Andersen Jan 13 '11 at 8:05
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Doing this manually can't really be called "quick" or "effective", but there are several profiling tools which do this automatically; also known as statistical profiling.

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The devil's in the details. It's not just taking samples that matters, it's what get recorded and how it is summarized. You need to record the entire call stack on each sample. Then you need for each statement (not function, statement) in the samples, what fraction of samples does it appear on. –  Mike Dunlavey Nov 5 '08 at 20:13
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I'm glad they are finally coming around to doing that. I hope they are also raising the visibility of the statistic that I think matters most - fraction of samples containing each statement (in the interval of interest). Too bad you need Vista. –  Mike Dunlavey Nov 14 '08 at 2:35
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@Mankarse: Trying all over again to make the point. What do you want to do: A) make precise measurements or B) find juicy bottlenecks? (I bet you assumed B requires A.) If there are bottlenecks taking 1) 50%, 2) 25%, 3) 12.5% and 4) 6.25% of the time, fixing all of them gives you 16x speedup. If you miss any one of them you get 8x or less. Now, can measuring find every single one? ... –  Mike Dunlavey Jun 7 '12 at 13:57
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@Mankarse: ... That’s a long bet, but if you take 10 samples and study them (not just count them), bottleneck (1) will be staring you in the face on 5 of them. (So what did you need the other thousand samples for?) If you fix it, and repeat, bottleneck (2) will do the same thing. That’s how you get all the bottlenecks, not missing any. –  Mike Dunlavey Jun 7 '12 at 13:58
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@Mankarse: Suppose you have a bunch of stack samples, 10 or 1000. Now what? Each one is information-rich about a point in time. If you don't study them, but only make summaries, you miss opportunities, and that is critical for this reason: Typically there are multiple opportunities, like 6 as here, for a 730x speedup. Suppose most are found, but not every one. Any one missed severely reduces the final speedup factor. So the issue isn't the number of samples, it is the number you take the trouble to understand. –  Mike Dunlavey Aug 31 '12 at 17:42
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Callstack sampling is a very useful technique for profiling, especially when looking at a large, complicated codebase that could be spending its time in any number of places. It has the advantage of measuring the CPU's usage by wall-clock time, which is what matters for interactivity, and getting callstacks with each sample lets you see why a function is being called. I use it a lot, but I use automated tools for it, such as Luke Stackwalker and OProfile and various hardware-vendor-supplied things.

The reason I prefer automated tools over manual sampling for the work I do is statistical power. Grabbing ten samples by hand is fine when you've got one function taking up 40% of runtime, because on average you'll get four samples in it, and always at least one. But you need more samples when you have a flat profile, with hundreds of leaf functions, none taking more than 1.5% of the runtime.

Say you have a lake with many different kinds of fish. If 40% of the fish in the lake are salmon (and 60% "everything else"), then you only need to catch ten fish to know there's a lot of salmon in the lake. But if you have hundreds of different species of fish, and each species is individually no more than 1%, you'll need to catch a lot more than ten fish to be able to say "this lake is 0.8% salmon and 0.6% trout."

Similarly in the games I work on, there are several major systems each of which call dozens of functions in hundreds of different entities, and all of this happens 60 times a second. Some of those functions' time funnels into common operations (like malloc), but most of it doesn't, and in any case there's no single leaf that occupies more than 1000 μs per frame.

I can look at the trunk functions and see, "we're spending 10% of our time on collision", but that's not very helpful: I need to know exactly where in collision, so I know which functions to squeeze. Just "do less collision" only gets you so far, especially when it means throwing out features. I'd rather know "we're spending an average 600 μs/frame on cache misses in the narrow phase of the octree because the magic missile moves so fast and touches lots of cells," because then I can track down the exact fix: either a better tree, or slower missiles.

Manual sampling would be fine if there were a big 20% lump in, say, stricmp, but with our profiles that's not the case. Instead I have hundreds of functions that I need to get from, say, 0.6% of frame to 0.4% of frame. I need to shave 10 μs off every 50 μs function that is called 300 times per second. To get that kind of precision, I need more samples.

But at heart what Luke Stackwalker does is what you describe: every millisecond or so, it halts the program and records the callstack (including the precise instruction and line number of the IP). Some programs just need tens of thousands of samples to be usefully profiled.

(We've talked about this before, of course, but I figured this was a good place to summarize the debate.)

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+1 Thanks for the response. I assume you've seen what I posted on sourceforge. What it says to me is the money lies not in this routine or that line of code, but in some description I can make of what the samples say, that may apply in a lot of places. Anyway, it would be fun to get some exposure to the kind of software you're talking about, to see first-hand where I'm wrong. Cheers. (BTW I'm fully aware of statistical power. That's my day job - building products for biostatistics simulation and analysis.) –  Mike Dunlavey Nov 28 '11 at 2:14
    
@MikeDunlavey I know you know, this answer was more about summarizing the points of view for other readers. =) –  Crashworks Nov 28 '11 at 2:45
    
@MikeDunlavey I really wish I could show you profiles from the stuff I'm working on. Unfortunately I'm working on a massive, multimillion-line app under NDA. I wonder if the bake-offs you've done had selection bias in that they were single-purpose apps with small dev teams and a few dominant hotspots. Our app is huge and has had a performance team sweep through it annually for a decade; all the big lumps have been squashed long ago. (Any new code that ate more than 5% of loop would be instantly noticed and ridiculed.) These might give a flavor of the perf work we do: bitly.com/sJndaK –  Crashworks Nov 28 '11 at 3:19
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I sympathize with your constraints. I'm also dubious when I hear all the big performance bugs have been squashed, because the "state of the art" is to use profilers, and they miss stuff, big stuff, because they have a selection bias saying that problems are in particular places - hotspots. If they say "there are no big problems" they are really saying "we didn't find any". (I'm not asserting that the big problems in there, like the choice of vector class, is necessarily easy to fix, only that it can be unambiguously identified as costing a large percent, compared to an alternative.) –  Mike Dunlavey Nov 28 '11 at 16:06
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I just read through the ppt in the first download of that link you gave. It was very impressive, I must say, but it deals in fixing the kinds of problems you can find with the tools mentioned. Not much in the form of macro-level optimization. The very fact that these games tend to be CPU, not GPU, bound, makes me suspect there's room for improvement, possibly quite a bit. –  Mike Dunlavey Nov 28 '11 at 16:42
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There's a difference between things that programmers actually do, and things that they recommend others do.

I know of lots of programmers (myself included) that actually use this method. It only really helps to find the most obvious of performance problems, but it's quick and dirty and it works.

But I wouldn't really tell other programmers to do it, because it would take me too long to explain all the caveats. It's far too easy to make an inaccurate conclusion based on this method, and there are many areas where it just doesn't work at all. (for example, that method doesn't reveal any code that is triggered by user input).

So just like using lie detectors in court, or the "goto" statement, we just don't recommend that you do it, even though they all have their uses.

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I'm glad you use it. I suppose it takes some practice. It certainly takes explaining. I've never had it give me wrong information, and hardly ever obvious. On fast code, like user input, you gotta puff it up with a temporary outer loop. –  Mike Dunlavey Nov 5 '08 at 20:23
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I'm surprised by the religous tone on both sides.

Profiling is great, and certainly is a more refined and precise when you can do it. Sometimes you can't, and it's nice to have a trusty back-up. The pause technique is like the manual screwdriver you use when your power tool is too far away or the bateries have run-down.

Here is a short true story. An application (kind of a batch proccessing task) had been running fine in production for six months, suddenly the operators are calling developers because it is going "too slow". They aren't going to let us attach a sampling profiler in production! You have to work with the tools already installed. Without stopping the production process, just using Process Explorer, (which operators had already installed on the machine) we could see a snapshot of a thread's stack. You can glance at the top of the stack, dismiss it with the enter key and get another snapshot with another mouse click. You can easily get a sample every second or so.

It doesn't take long to see if the top of the stack is most often in the database client library DLL (waiting on the database), or in another system DLL (waiting for a system operation), or actually in some method of the application itself. In this case, if I remember right, we quickly noticed that 8 times out of 10 the application was in a system DLL file call reading or writing a network file. Sure enough recent "upgrades" had changed the performance characteristics of a file share. Without a quick and dirty and (system administrator sanctioned) approach to see what the application was doing in production, we would have spent far more time trying to measure the issue, than correcting the issue.

On the other hand, when performance requirements move beyond "good enough" to really pushing the envelope, a profiler becomes essential so that you can try to shave cycles from all of your closely-tied top-ten or twenty hot spots. Even if you are just trying to hold to a moderate performance requirement durring a project, when you can get the right tools lined-up to help you measure and test, and even get them integrated into your automated test process it can be fantasticly helpful.

But when the power is out (so to speak) and the batteries are dead, it's nice know how to use that manual screwdriver.

So the direct answer: Know what you can learn from halting the program, but don't be afraid of precision tools either. Most importantly know which jobs call for which tools.

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"Religious tone" - Ouch! Process Explorer - sounds great, now don't just look at the top of the stack. The "gold nuggets" are in the middle. I agree profilers are precision tools - precision of the wrong thing. They measure time with precision, but (if they take and retain stack samples) they actually know the problem location with high precision, but they don't show it to you, and that's what you're looking for. –  Mike Dunlavey Oct 28 '09 at 11:14
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... Sorry, can't leave well enough alone. Here's a (only slightly artificial) case study: stackoverflow.com/questions/926266/… It's tempting to think that a profiler will do a better job when you're really trying to push performance, but when you get down to an actual experiment, that doesn't seem to hold. In fact, I've never seen a story where a profiler was used to really wring out a program through a series of steps, as in that example. –  Mike Dunlavey Oct 28 '09 at 13:00
    
... I don't mean to give you a hard time. Your story about the file system upgrade showing you an 8 in 10 problem is exactly what I'm talking about. Now I'm just trying to raise awareness that in big software it's really easy to get issues like that in your own code in the form of mid-stack calls, and those are not hot-spots, because the program counter is not there. (In real hot-spots, by my understanding, the memory chip actually has a spot of higher temperature.) –  Mike Dunlavey Oct 28 '09 at 13:21
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Hitting the pause button during the execution of a program in "debug" mode might not provide the right data to perform any performance optimizations. To put it bluntly, it is a crude form of profiling.

If you must avoid using a profiler, a better bet is to use a logger, and then apply a slowdown factor to "guesstimate" where the real problem is. Profilers however, are better tools for guesstimating.

The reason why hitting the pause button in debug mode, may not give a real picture of application behavior is because debuggers introduce additional executable code that can slowdown certain parts of the application. One can refer to Mike Stall's blog post on possible reasons for application slowdown in a debugging environment. The post sheds light on certain reasons like too many breakpoints,creation of exception objects, unoptimized code etc. The part about unoptimized code is important - the "debug" mode will result in a lot of optimizations (usually code in-lining and re-ordering) being thrown out of the window, to enable the debug host (the process running your code) and the IDE to synchronize code execution. Therefore, hitting pause repeatedly in "debug" mode might be a bad idea.

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The things you say are true but don't matter, because a single-thread program spends a sequence of cycles, and you need to find out if any of them are being spent for poor reasons. After you fix those, it takes less cycles, and then runs faster. –  Mike Dunlavey Nov 23 '08 at 16:39
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In debug mode, sure there's overhead, but it goes away in release mode. The thing about inlining is it matters in code where the program counter lives. Higher up the call stack it makes no difference, and thats where many problems are. –  Mike Dunlavey Nov 23 '08 at 16:43
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I think the problem is confusion between measuring performance and finding performance problems. I suggest separating these goals. –  Mike Dunlavey Nov 23 '08 at 16:44
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I've said that profilers help if they sample the entire call stack (some do) and if they tell you, for each instruction (call or non-call) what percentage of stacks it was on. The only remaining point is, for big issues, not many samples are needed. –  Mike Dunlavey Nov 23 '08 at 16:53
    
Yes, fixing issues will cause the program to run faster. But you might solve the wrong problem. Besides, you have already pointed you the real issue which is unknown behavior of the program in runtime. The only way to optimize such an application, would involve studying the codeflow. –  Vineet Reynolds Nov 24 '08 at 1:22
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If we take the question "Why isn't it better known?" then the answer is going to be subjective. Presumably the reason why it is not better known is because profiling provides a long term solution rather than a current problem solution. It isn't effective for multi-threaded applications and isn't effective for applications like games which spend a significant portion of its time rendering.

Furthermore, in single threaded applications if you have a method that you expect to consume the most run time, and you want to reduce the run-time of all other methods then it is going to be harder to determine which secondary methods to focus your efforts upon first.

Your process for profiling is an acceptable method that can and does work, but profiling provides you with more information and has the benefit of showing you more detailed performance improvements and regressions.

If you have well instrumented code then you can examine more than just the how long a particular method; you can see all the methods.

With profiling:

  • You can then rerun your scenario after each change to determine the degree of performance improvement/regression.

  • You can profile the code on different hardware configurations to determine if your production hardware is going to be sufficient.

  • You can profile the code under load and stress testing scenarios to determine how the volume of information impacts performance

  • You can make it easier for junior developers to visualise the impacts of their changes to your code because they can re-profile the code in six months time while you're off at the beach or the pub, or both. Beach-pub, ftw.

Profiling is given more weight because enterprise code should always have some degree of profiling because of the benefits it gives to the organisation of an extended period of time. The more important the code the more profiling and testing you do.

Your approach is valid and is another item is the toolbox of the developer. It just gets outweighed by profiling.

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I agree with what you say about profilers as general health-monitoring tools. For finding bottlenecks precisely they only give clues. They don't pinpoint the problem (most of them). They find the haystack, but this method finds the needles. –  Mike Dunlavey Nov 6 '08 at 16:17
    
Profiling can give you as much info as you want from per component to per statement. It gives it under a variety of scenarios and provides more long term benefits. With AOP or a VM you don't even need to instrument you're code to gain the benefits. The skill of the tool is in the hands of the owner –  Ryan Boucher Nov 7 '08 at 12:02
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Thanks, Ryan. I confess I'm not a profiler expert. All I know about them is what I see from their specs. I'm in a big team, and people talk about them but don't use them. Often I just halt the code a few times and say "Did you know you're spending a lot of time doing this ...?" Oops-didn't mean to. –  Mike Dunlavey Nov 7 '08 at 16:40
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Sampling profilers are only useful when

  1. You are monitoring a runtime with a small number of threads. Preferably one.
  2. The call stack depth of each thread is relatively small (to reduce the incredible overhead in collecting a sample).
  3. You are only concerned about wall clock time and not other meters or resource bottlenecks.
  4. You have not instrumented the code for management and monitoring purposes (hence the stack dump requests)
  5. You mistakenly believe removing a stack frame is an effective performance improvement strategy whether the inherent costs (excluding callees) are practically zero or not
  6. You can't be bothered to learn how to apply software performance engineering day-to-day in your job
  7. ....
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@William: What you really need to do is decide what you care about. If the system is empirically "too slow" then wall clock time slices are the thing to sample. For each sample you need to find out why it is being spent. In a single-thread program, the stack can often tell you that, but not always, like if it's an interpreter or message-driven. If it's multi-thread, it may be even harder to determine the why, but that's what you need to determine, because to spend fewer units of the desired resource, you need to find those that have a nonessential reason. –  Mike Dunlavey Jul 29 '09 at 13:22
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... ignoring unhelpful remarks, like 6, I just scanned your blog entry and absorbed as much as I could in 10 minutes. It seems we are solving different problems. I am less concerned with ongoing health-monitoring, and more with discovery and removal of performance problems. To that end, I don't care about the overhead of sampling, only that it is unbiased. I am not trying to remove stack frames, but unnecessary time-taking operations, which are very often method calls, and the more levels there are, the better the hunting is. –  Mike Dunlavey Jul 29 '09 at 14:17
    
... but I'll give you an up-vote for taking the trouble to answer, and as a welcome to SO :-) –  Mike Dunlavey Jul 29 '09 at 14:22
    
... and BTW your weblog has comments disabled. Is that to avoid being questioned? –  Mike Dunlavey Aug 9 '09 at 16:04
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Stack trace snapshots only allow you to see stroboscopic x-rays of your application. You may require more accumulated knowledge which a profiler may give you.

The trick is knowing your tools well and choose the best for the job at hand.

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@Thorbjørn: Well, who can argue with your last sentence? Every tool automates a technique. My point is that the nature of this problem is that the technique of sampling (and analyzing) the stack is little-known, simple, and very effective. What's more, the ambient attitudes people have about performance need to be re-evaluated. For example, if you want to measure performance precisely, that's fine, but if you want to improve performance, measurement misses the point. –  Mike Dunlavey Oct 17 '09 at 15:21
    
... If I could add, yes you are taking stroboscopic x-rays of your application. (I think that is an excellent metaphor.) Typically there are unexpected things that the app is doing that could be replaced for substantial speedup. The time that would save is the probability they will appear on each stackshot. That's why it works. –  Mike Dunlavey Oct 17 '09 at 15:31
    
... So I gave you an upvote for that nice metaphor. –  Mike Dunlavey Oct 17 '09 at 15:35
    
Thank you for the upvote. In return I think you should know that your choice of words in comments may convey the image that you are a "I know better than you"-person instead of considering others as equals. If that is not intentional,well, at least you know now. –  Thorbjørn Ravn Andersen Oct 17 '09 at 16:37
    
And a very useful tool could be one that programatically takes a complete application stacktrace and dump it somewhere. jvisualvm can do it externally, but you may not always be able to attach with jvisualvm (or you want to do it on a schedule instead of invoked manually). This requires Java 6. –  Thorbjørn Ravn Andersen Oct 17 '09 at 16:38
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These must be some trivial examples that you are working with to get useful results with your method. I can't think of a project where profiling was useful (by whatever method) that would have gotten decent results with your "quick and effective" method. The time it takes to start and stop some applications already puts your assertion of "quick" in question.

Again, with non-trivial programs the method you advocate is useless.

EDIT: Regarding "why isn't it better known"?

In my experience code reviews avoid poor quality code and algorithms, and profiling would find these as well. If you wish to continue with your method that is great - but I think for most of the professional community this is so far down on the list of things to try that it will never get positive reinforcement as a good use of time.

It appears to be quite inaccurate with small sample sets and to get large sample sets would take lots of time that would have been better spent with other useful activities.

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Actually it works better on bigger software because, since the stack is generally deeper, there are more instructions on it, so more candidates for optimizing. As far as applications taking long time to start and stop, that's exactly when halting it will find out why. –  Mike Dunlavey Nov 6 '08 at 15:54
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So here's the scenario: there's a big system, and it's all been done with code reviews, etc., but there's still a problem. The profiler tells you what state and county contains the problem, but stack sampling tells you the exact doorstep. –  Mike Dunlavey Nov 6 '08 at 16:23
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Profilers could tell you this, but for some reason they don't, as I explained in my "answer" below. –  Mike Dunlavey Nov 6 '08 at 16:24
    
Um, I have used profilers that give this information. –  Tim Nov 6 '08 at 17:11
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Are you sure? Fraction of time on call stack, per statement (not function), in time interval of interest, sorted in decreasing order? I think some can do this. Most do not, from what I read. –  Mike Dunlavey Nov 6 '08 at 17:36
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What if the program is in production and being used at the same time by paying clients or colleagues. A profiler allows you to observe without interferring (as much, because of course it will have a little hit too as per the Heisenberg principle).

Profiling can also give you much richer and more detailed accurate reports. This will be quicker in the long run.

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You're confusing the Heisenberg principle with the Observer effect: en.wikipedia.org/wiki/Conflated –  JesperE Nov 5 '08 at 19:57
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Only if it's hooked into the outside world. Otherwise, stopping it doesn't change its behavior. –  Mike Dunlavey Nov 5 '08 at 20:27
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I like quantum physics too, and you could be right for issues like cache misses. What I nearly always find is just dumb code, usually caused by too many layers of abstraction, and speedups of 40x are common. –  Mike Dunlavey Nov 5 '08 at 20:39
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That's a cute concept, but it's a diversion. It simply doesn't apply here. –  Mike Dunlavey Nov 5 '08 at 21:35
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On the physics front, in the 30s Hitler tried to denigrate Einstein by saying thousands of scientists disagreed with him. Einstein said if he were wrong, it would only take one. –  Mike Dunlavey Nov 5 '08 at 21:37
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Stepping through code is great for seeing the nitty-gritty details and troubleshooting algorithms. It's like looking at a tree really up close and following each vein of bark and branch individually.

Profiling lets you see the big picture, and quickly identify trouble points -- like taking a step backwards and looking at the whole forest and noticing the tallest trees. By sorting your function calls by length of execution time, you can quickly identify the areas that are the trouble points.

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If you sort function calls by (length_of_execution_time TIMES number_of_invocations), then I agree you're getting there. Even so, you may need more context to really understand if a function call could be avoided, and halting gives you that. –  Mike Dunlavey Nov 5 '08 at 20:51
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Actually, that's tricky because of recursion. The call-stack-sampling technique does not suffer from confusion about recursion. –  Mike Dunlavey Nov 5 '08 at 23:42
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I used this method for Commodore 64 BASIC many years ago. It is surprising how well it works.

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I've typically used it on real-time programs that were overrunning their timeslice. You can't manually stop and restart code that has to run 60 times every second.

I've also used it to track down the bottleneck in a compiler I had written. You wouldn't want to try to break such a program manually, because you really have no way of knowing if you are breaking at the spot where the bottlenck is, or just at the spot after the bottleneck when the OS is allowed back in to stop it. Also, what if the major bottleneck is something you can't do anything about, but you'd like to get rid of all the other largeish bottlenecks in the system? How to you prioritize which bottlenecks to attack first, when you don't have good data on where they all are, and what their relative impact each is?

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First question: run the code separately in a long loop, and take your time about squeezing it. –  Mike Dunlavey Nov 6 '08 at 16:04
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Second question: That's why you take several samples. The bigger each bottleneck is, the more it will stand out. And it doesn't matter what order you tackle them, because each one will make it faster. –  Mike Dunlavey Nov 6 '08 at 16:07
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The point is, you don't have to wonder where they are. It pinpoints each one. All you have to do is figure out which ones you can do something about. –  Mike Dunlavey Nov 6 '08 at 16:29
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Actually, the term "bottleneck" bothers me, because it gives a misleading image of typical problems. They are more like government waste. The more layers there are, the more likely it's in there somewhere. –  Mike Dunlavey Nov 6 '08 at 17:13
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Good point. Fortunately it's not a serious problem, because it's no different from a lengthy instruction. If you halt right after "call FileOpen", you're looking at a gold nugget of information. Is the file being opened/closed unnecessarily? Look higher up. –  Mike Dunlavey Nov 6 '08 at 19:49
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The larger your program gets, the more useful a profiler will be. If you need to optimize a program which contains thousands of conditional branches, a profiler can be indispensible. Feed in your largest sample of test data, and when it's done import the profiling data into Excel. Then you check your assumptions about likely hot spots against the actual data. There are always surprises.

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Thanks for your comment. Few people have actually tried this, instead relying on intuition. Profilers are fine for what they do. But if you actually take some samples and study them, you'll be surprised, especially in big programs. I know it's hard to believe. –  Mike Dunlavey Nov 23 '08 at 2:07
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EDIT 2008/11/25: OK, Vineet's response has finally made me see what the issue is here. Better late than never.

Somehow the idea got loose in the land that performance problems are found by measuring performance. That is confusing means with ends. Somehow I avoided this by single-stepping entire programs long ago. I did not berate myself for slowing it down to human speed. I was trying to see if it was doing wrong or unnecessary things. That's how to make software fast - find and remove unnecessary operations.

Nobody has the patience for single-stepping these days, but the next best thing is to pick a number of cycles at random and ask what their reasons are. (That's what the call stack can often tell you.) If a good percentage of them don't have good reasons, you can do something about it.

It's harder these days, what with threading and asynchrony, but that's how I tune software - by finding unnecessary cycles. Not by seeing how fast it is - I do that at the end.


Here's why sampling the call stack cannot give a wrong answer, and why not many samples are needed.

During the interval of interest, when the program is taking more time than you would like, the call stack exists continuously, even when you're not sampling it.

  • If an instruction I is on the call stack for fraction P(I) of that time, removing it from the program, if you could, would save exactly that much. If this isn't obvious, give it a bit of thought.

If the instruction shows up on M = 2 or more samples, out of N, its P(I) is approximately M/N, and is definitely significant.

The only way you can fail to see the instruction is to magically time all your samples for when the instruction is not on the call stack. The simple fact that it is present for a fraction of the time is what exposes it to your probes.

So the process of performance tuning is a simple matter of picking off instructions (mostly function call instructions) that raise their heads by turning up on multiple samples of the call stack. Those are the tall trees in the forest.

Notice that we don't have to care about the call graph, or how long functions take, or how many times they are called, or recursion.

I'm against obfuscation, not against profilers. They give you lots of statistics, but most don't give P(I), and most users don't realize that that's what matters.

You can talk about forests and trees, but for any performance problem that you can fix by modifying code, you need to modify instructions, specifically instructions with high P(I). So you need to know where those are, preferably without playing Sherlock Holmes. Stack sampling tells you exactly where they are.

This technique is harder to employ in multi-thread, event-driven, or systems in production. That's where profilers, if they would report P(I), could really help.

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"never"??? Man, your experience is nothing like mine. Methinks you're generalizing from a very small data set. –  Paul Tomblin Nov 5 '08 at 21:32
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Hardly. Been doing it 30 years. If you've had bad luck with sampling maybe you're not doing it quite right. I've done my level best to explain it: en.wikipedia.org/wiki/… –  Mike Dunlavey Nov 5 '08 at 22:25
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Tim, like most people on this website, I'm just trying to be helpful. Stack sampling is a really useful idea and I'm trying to tell people about it. Ideas are tested by proof, by reason or example, not by "lending credence". –  Mike Dunlavey Nov 7 '08 at 13:06
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Sampling works if you do it right. I've seen people take 1 sample, of a 30-level stack. It appears meaningless, so they give up, considering their skepticism justified. You gotta follow the procedure. –  Mike Dunlavey Nov 7 '08 at 13:20
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Hi Suma. What I do in a case like that is take the code that has to run on each frame and write a loop that runs it flat out, not on a timer. That's what I take samples of in order to make it faster. –  Mike Dunlavey Nov 14 '08 at 2:30
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