I have a C++ application, running on Linux, which I'm in the process of optimizing. How can I pinpoint which areas of my code are running slowly?

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    If you will provide more data about your development stack you might get better answers. There are profilers from Intel and Sun but you have to use their compilers. Is that an option? – Nazgob Dec 17 '08 at 20:38
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    It is already answered on the following link: stackoverflow.com/questions/2497211/… – Kapil Gupta May 22 '12 at 10:12
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    Most of the answers are code profilers. However, priority inversion, cache aliasing, resource contention, etc. can all be factors in optimizing and performance. I think that people read information into my slow code. FAQs are referencing this thread. – artless noise Mar 17 '13 at 18:44
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    I used to use pstack randomly, most of the time will print out the most typical stack where the program is most of the time, hence pointing to the bottleneck. – Jose Manuel Gomez Alvarez Dec 15 '16 at 9:26

10 Answers 10

up vote 1197 down vote accepted

If your goal is to use a profiler, use one of the suggested ones.

However, if you're in a hurry and you can manually interrupt your program under the debugger while it's being subjectively slow, there's a simple way to find performance problems.

Just halt it several times, and each time look at the call stack. If there is some code that is wasting some percentage of the time, 20% or 50% or whatever, that is the probability that you will catch it in the act on each sample. So that is roughly the percentage of samples on which you will see it. There is no educated guesswork required. If you do have a guess as to what the problem is, this will prove or disprove it.

You may have multiple performance problems of different sizes. If you clean out any one of them, the remaining ones will take a larger percentage, and be easier to spot, on subsequent passes. This magnification effect, when compounded over multiple problems, can lead to truly massive speedup factors.

Caveat: Programmers tend to be skeptical of this technique unless they've used it themselves. They will say that profilers give you this information, but that is only true if they sample the entire call stack, and then let you examine a random set of samples. (The summaries are where the insight is lost.) Call graphs don't give you the same information, because

  1. they don't summarize at the instruction level, and
  2. they give confusing summaries in the presence of recursion.

They will also say it only works on toy programs, when actually it works on any program, and it seems to work better on bigger programs, because they tend to have more problems to find. They will say it sometimes finds things that aren't problems, but that is only true if you see something once. If you see a problem on more than one sample, it is real.

P.S. This can also be done on multi-thread programs if there is a way to collect call-stack samples of the thread pool at a point in time, as there is in Java.

P.P.S As a rough generality, the more layers of abstraction you have in your software, the more likely you are to find that that is the cause of performance problems (and the opportunity to get speedup).

Added: It might not be obvious, but the stack sampling technique works equally well in the presence of recursion. The reason is that the time that would be saved by removal of an instruction is approximated by the fraction of samples containing it, regardless of the number of times it may occur within a sample.

Another objection I often hear is: "It will stop someplace random, and it will miss the real problem". This comes from having a prior concept of what the real problem is. A key property of performance problems is that they defy expectations. Sampling tells you something is a problem, and your first reaction is disbelief. That is natural, but you can be sure if it finds a problem it is real, and vice-versa.

ADDED: Let me make a Bayesian explanation of how it works. Suppose there is some instruction I (call or otherwise) which is on the call stack some fraction f of the time (and thus costs that much). For simplicity, suppose we don't know what f is, but assume it is either 0.1, 0.2, 0.3, ... 0.9, 1.0, and the prior probability of each of these possibilities is 0.1, so all of these costs are equally likely a-priori.

Then suppose we take just 2 stack samples, and we see instruction I on both samples, designated observation o=2/2. This gives us new estimates of the frequency f of I, according to this:

P(f=x) x  P(o=2/2|f=x) P(o=2/2&&f=x)  P(o=2/2&&f >= x)  P(f >= x)

0.1    1     1             0.1          0.1            0.25974026
0.1    0.9   0.81          0.081        0.181          0.47012987
0.1    0.8   0.64          0.064        0.245          0.636363636
0.1    0.7   0.49          0.049        0.294          0.763636364
0.1    0.6   0.36          0.036        0.33           0.857142857
0.1    0.5   0.25          0.025        0.355          0.922077922
0.1    0.4   0.16          0.016        0.371          0.963636364
0.1    0.3   0.09          0.009        0.38           0.987012987
0.1    0.2   0.04          0.004        0.384          0.997402597
0.1    0.1   0.01          0.001        0.385          1

                  P(o=2/2) 0.385                

The last column says that, for example, the probability that f >= 0.5 is 92%, up from the prior assumption of 60%.

Suppose the prior assumptions are different. Suppose we assume P(f=0.1) is .991 (nearly certain), and all the other possibilities are almost impossible (0.001). In other words, our prior certainty is that I is cheap. Then we get:

P(f=x) x  P(o=2/2|f=x) P(o=2/2&& f=x)  P(o=2/2&&f >= x)  P(f >= x)

0.001  1    1              0.001        0.001          0.072727273
0.001  0.9  0.81           0.00081      0.00181        0.131636364
0.001  0.8  0.64           0.00064      0.00245        0.178181818
0.001  0.7  0.49           0.00049      0.00294        0.213818182
0.001  0.6  0.36           0.00036      0.0033         0.24
0.001  0.5  0.25           0.00025      0.00355        0.258181818
0.001  0.4  0.16           0.00016      0.00371        0.269818182
0.001  0.3  0.09           0.00009      0.0038         0.276363636
0.001  0.2  0.04           0.00004      0.00384        0.279272727
0.991  0.1  0.01           0.00991      0.01375        1

                  P(o=2/2) 0.01375                

Now it says P(f >= 0.5) is 26%, up from the prior assumption of 0.6%. So Bayes allows us to update our estimate of the probable cost of I. If the amount of data is small, it doesn't tell us accurately what the cost is, only that it is big enough to be worth fixing.

Yet another way to look at it is called the Rule Of Succession. If you flip a coin 2 times, and it comes up heads both times, what does that tell you about the probable weighting of the coin? The respected way to answer is to say that it's a Beta distribution, with average value (number of hits + 1) / (number of tries + 2) = (2+1)/(2+2) = 75%.

(The key is that we see I more than once. If we only see it once, that doesn't tell us much except that f > 0.)

So, even a very small number of samples can tell us a lot about the cost of instructions that it sees. (And it will see them with a frequency, on average, proportional to their cost. If n samples are taken, and f is the cost, then I will appear on nf+/-sqrt(nf(1-f)) samples. Example, n=10, f=0.3, that is 3+/-1.4 samples.)

ADDED, to give an intuitive feel for the difference between measuring and random stack sampling:
There are profilers now that sample the stack, even on wall-clock time, but what comes out is measurements (or hot path, or hot spot, from which a "bottleneck" can easily hide). What they don't show you (and they easily could) is the actual samples themselves. And if your goal is to find the bottleneck, the number of them you need to see is, on average, 2 divided by the fraction of time it takes. So if it takes 30% of time, 2/.3 = 6.7 samples, on average, will show it, and the chance that 20 samples will show it is 99.2%.

Here is an off-the-cuff illustration of the difference between examining measurements and examining stack samples. The bottleneck could be one big blob like this, or numerous small ones, it makes no difference.

enter image description here

Measurement is horizontal; it tells you what fraction of time specific routines take. Sampling is vertical. If there is any way to avoid what the whole program is doing at that moment, and if you see it on a second sample, you've found the bottleneck. That's what makes the difference - seeing the whole reason for the time being spent, not just how much.

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    This is basically a poor man's sampling profiler, which is great, but you run the risk of a too-small sample size which will possibly give you entirely spurious results. – Crashworks May 22 '09 at 21:56
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    @Crash: I won't debate the "poor man" part :-) It's true that statistical measurement precision requires many samples, but there are two conflicting goals - measurement and problem location. I'm focussing on the latter, for which you need precision of location, not precision of measure. So for example, there can be, mid-stack, a single function call A(); that accounts for 50% of time, but it can be in another large function B, along with many other calls to A() that are not costly. Precise summaries of function times can be a clue, but every other stack sample will pinpoint the problem. – Mike Dunlavey May 23 '09 at 1:14
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    ... the world seems to think that a call-graph, annotated with call counts and/or average timing, is good enough. It is not. And the sad part is, for those that sample the call stack, the most useful information is right in front of them, but they throw it away, in the interests of "statistics". – Mike Dunlavey May 24 '09 at 18:08
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    I don't mean to disagree with your technique. Clearly I rely quite heavily on stack-walking sampling profilers. I'm just pointing out that there are some tools that do it in an automated way now, which is important when you're past the point of getting a function from 25% to 15% and need to knock it down from 1.2% to 0.6%. – Crashworks Jun 2 '09 at 3:27
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    Thank you SO much for this idea. I just used it and I was able to identify and ameliorate some serious bottlenecks light years faster than any other method I've tried in the past. I sped up execution by 60 times. I shudder at the thought of all the timing debugging code I was considering adding. – ErikE Jan 20 '10 at 0:48

You can use Valgrind with the following options

valgrind --tool=callgrind ./(Your binary)

It will generate a file called callgrind.out.x. You can then use kcachegrind tool to read this file. It will give you a graphical analysis of things with results like which lines cost how much.

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    valgrind is great, but be warned that it will make your program darn slow – neves Jan 25 '12 at 20:07
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    Check out also Gprof2Dot for an amazing alternative way to visualize the output. ./gprof2dot.py -f callgrind callgrind.out.x | dot -Tsvg -o output.svg – Sebastian May 22 '13 at 13:42
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    @neves Yes Valgrind is just not very helpful in terms of speed for profiling "gstreamer" and "opencv" applications real-time. – enthusiasticgeek May 22 '13 at 20:20
  • stackoverflow.com/questions/375913/… is partial soluton for speed issue. – Tõnu Samuel Jul 9 '14 at 10:33
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    @Sebastian: gprof2dot is now here: github.com/jrfonseca/gprof2dot – John Zwinck Apr 27 '17 at 3:19

I assume you're using GCC. The standard solution would be to profile with gprof.

Be sure to add -pg to compilation before profiling:

cc -o myprog myprog.c utils.c -g -pg

I haven't tried it yet but I've heard good things about google-perftools. It is definitely worth a try.

Related question here.

A few other buzzwords if gprof does not do the job for you: Valgrind, Intel VTune, Sun DTrace.

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    I agree that gprof is the current standard. Just a note, though, Valgrind is used to profile memory leaks and other memory-related aspects of your programs, not for speed optimization. – Bill the Lizard Dec 18 '08 at 15:02
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    Bill, In vaglrind suite you can find callgrind and massif. Both are pretty useful to profile apps – dario minonne Dec 18 '08 at 15:05
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    @Bill-the-Lizard: Some comments on gprof : stackoverflow.com/questions/1777556/alternatives-to-gprof/… – Mike Dunlavey Mar 4 '10 at 13:23
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    See also my gprof caveats below, stackoverflow.com/a/6540100/823636 – Rob_before_edits Jan 27 '12 at 23:09
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    gprof -pg is only an approximation of callstack profiling. It inserts mcount calls to track which functions are calling which other functions. It uses standard time based sampling for, uh, time. It then apportions times sampled in a function foo() back to the callers of foo(), in proprtion to the numberr of calls. So it doesn't distinguish between calls of different costs. – Krazy Glew Apr 28 '12 at 5:45

Newer kernels (e.g. the latest Ubuntu kernels) come with the new 'perf' tools (apt-get install linux-tools) AKA perf_events.

These come with classic sampling profilers (man-page) as well as the awesome timechart!

The important thing is that these tools can be system profiling and not just process profiling - they can show the interaction between threads, processes and the kernel and let you understand the scheduling and I/O dependencies between processes.

Alt text

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    Great tool! Is there anyway for me to get a typical "butterfly" view that starts from "main->func1->fun2" style? I can't seem to figure that out... perf report seems to give me the function names with the call parents... (so it's sort of an inverted butterfly view) – kizzx2 Oct 1 '10 at 6:17
  • Will, can perf show timechart of thread activity; with CPU number information added? I want to see when and which thread was running on every CPU. – osgx Dec 6 '11 at 4:24
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    @kizzx2 - you can use gprof2dot and perf script. Very nice tool! – dashesy May 14 '12 at 23:55
  • Even newer kernels like 4.13 have eBPF for profiling. See brendangregg.com/blog/2015-05-15/ebpf-one-small-step.html and brendangregg.com/ebpf.html – Andrew Stern Oct 13 '17 at 15:00
  • Another nice introduction to perf exists at archive.li/9r927#selection-767.126-767.271 (Why the SO gods decided to delete that page from the SO knowledge base is beyond me....) – ragerdl Jun 28 at 17:20

I would use Valgrind and Callgrind as a base for my profiling tool suite. What is important to know is that Valgrind is basically a Virtual Machine:

(wikipedia) Valgrind is in essence a virtual machine using just-in-time (JIT) compilation techniques, including dynamic recompilation. Nothing from the original program ever gets run directly on the host processor. Instead, Valgrind first translates the program into a temporary, simpler form called Intermediate Representation (IR), which is a processor-neutral, SSA-based form. After the conversion, a tool (see below) is free to do whatever transformations it would like on the IR, before Valgrind translates the IR back into machine code and lets the host processor run it.

Callgrind is a profiler build upon that. Main benefit is that you don't have to run your aplication for hours to get reliable result. Even one second run is sufficient to get rock-solid, reliable results, because Callgrind is a non-probing profiler.

Another tool build upon Valgrind is Massif. I use it to profile heap memory usage. It works great. What it does is that it gives you snapshots of memory usage -- detailed information WHAT holds WHAT percentage of memory, and WHO had put it there. Such information is available at different points of time of application run.

This is a response to Nazgob's Gprof answer.

I've been using Gprof the last couple of days and have already found three significant limitations, one of which I've not seen documented anywhere else (yet):

  1. It doesn't work properly on multi-threaded code, unless you use a workaround

  2. The call graph gets confused by function pointers. Example: I have a function called multithread() which enables me to multi-thread a specified function over a specified array (both passed as arguments). Gprof however, views all calls to multithread() as equivalent for the purposes of computing time spent in children. Since some functions I pass to multithread() take much longer than others my call graphs are mostly useless. (To those wondering if threading is the issue here: no, multithread() can optionally, and did in this case, run everything sequentially on the calling thread only).

  3. It says here that "... the number-of-calls figures are derived by counting, not sampling. They are completely accurate...". Yet I find my call graph giving me 5345859132+784984078 as call stats to my most-called function, where the first number is supposed to be direct calls, and the second recursive calls (which are all from itself). Since this implied I had a bug, I put in long (64-bit) counters into the code and did the same run again. My counts: 5345859132 direct, and 78094395406 self-recursive calls. There are a lot of digits there, so I'll point out the recursive calls I measure are 78bn, versus 784m from Gprof: a factor of 100 different. Both runs were single threaded and unoptimised code, one compiled -g and the other -pg.

This was GNU Gprof (GNU Binutils for Debian) running under 64-bit Debian Lenny, if that helps anyone.

  • apparently it can do sampling stackoverflow.com/a/11143125/32453 – rogerdpack Jun 21 '12 at 17:01
  • Yes, it does sampling, but not for number-of-calls figures. Interestingly, following your link ultimately led me to an updated version of the manual page I linked to in my post, new URL: sourceware.org/binutils/docs/gprof/… This repeats the quote in part (iii) of my answer, but also says "In multi-threaded applications, or single threaded applications that link with multi-threaded libraries, the counts are only deterministic if the counting function is thread-safe. (Note: beware that the mcount counting function in glibc is not thread-safe)." – Rob_before_edits Jun 22 '12 at 4:30
  • It is not clear to me if this explains my result in (iii). My code was linked -lpthread -lm and declared both a "pthread_t *thr" and a "pthread_mutex_t nextLock = PTHREAD_MUTEX_INITIALIZER" static variable even when it was running single threaded. I would ordinarily presume that "link with multi-threaded libraries" means actually using those libraries, and to a greater extent than this, but I could be wrong! – Rob_before_edits Jun 22 '12 at 6:05

The answer to run valgrind --tool=callgrind is not quite complete without some options. We usually do not want to profile 10 minutes of slow startup time under Valgrind and want to profile our program when it is doing some task.

So this is what I recommend. Run program first:

valgrind --tool=callgrind --dump-instr=yes -v --instr-atstart=no ./binary > tmp

Now when it works and we want to start profiling we should run in another window:

callgrind_control -i on

This turns profiling on. To turn it off and stop whole task we might use:

callgrind_control -k

Now we have some files named callgrind.out.* in current directory. To see profiling results use:

kcachegrind callgrind.out.*

I recommend in next window to click on "Self" column header, otherwise it shows that "main()" is most time consuming task. "Self" shows how much each function itself took time, not together with dependents.

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    Now on some reason callgrind.out.* files were always empty. Executing callgrind_control -d was useful to force dump of data to disk. – Tõnu Samuel Jul 31 '14 at 4:25
  • i'm confused about these instructions. are you saying that while the program is running, we can execute callgrind_control in another window to turn profiling on/off? it seems to me like it'd be way better to design a minimal program that includes only what you want to profile, and then profile the whole program. – dbliss Nov 21 '15 at 2:25
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    Can't. My usual contexts are something like whole MySQL or PHP or some similar big thing. Often even do not know what I want to separate at first. – Tõnu Samuel Nov 21 '15 at 22:50
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    Or in my case my program actually loads a bunch of data into an LRU cache, and I want not to profile that. So I force-load a subset of the cache at startup, and profile the code using only that data (letting the OS+CPU manage the memory use within my cache). It works, but loading that cache is slow and CPU intensive across code that I'm trying to profile in a different context, so callgrind produces badly polluted results. – Code Abominator Mar 17 '16 at 3:49
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    there is also CALLGRIND_TOGGLE_COLLECT to enable/disable collection programmatically; see stackoverflow.com/a/13700817/288875 – Andre Holzner Aug 29 '17 at 16:59

Use Valgrind, callgrind and kcachegrind:

valgrind --tool=callgrind ./(Your binary)

generates callgrind.out.x. Read it using kcachegrind.

Use gprof (add -pg):

cc -o myprog myprog.c utils.c -g -pg 

(not so good for multi-threads, function pointers)

Use google-perftools:

Uses time sampling, reveals I/O and CPU bottlenecks are revealed.

Intel VTune is the best (free for educational purposes).

Others: AMD Codeanalyst, OProfile, 'perf' tools (apt-get install linux-tools)

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    I disagree with your answer, but I agree with your history - engineering, CS, post-graduate degrees, and advanced teaching. Good Luck. – Mike Dunlavey Feb 24 '17 at 1:05

For single-threaded programs you can use igprof, The Ignominous Profiler: https://igprof.org/ .

It is a sampling profiler, along the lines of the... long... answer by Mike Dunlavey, which will gift wrap the results in a browsable call stack tree, annotated with the time or memory spent in each function, either cumulative or per-function.

These are the two methods I use for speeding up my code:

For CPU bound applications:

  1. Use a profiler in DEBUG mode to identify questionable parts of your code
  2. Then switch to RELEASE mode and comment out the questionable sections of your code (stub it with nothing) until you see changes in performance.

For I/O bound applications:

  1. Use a profiler in RELEASE mode to identify questionable parts of your code.


If you don't have a profiler, use the poor man's profiler. Hit pause while debugging your application. Most developer suites will break into assembly with commented line numbers. You're statistically likely to land in a region that is eating most of your CPU cycles.

For CPU, the reason for profiling in DEBUG mode is because if your tried profiling in RELEASE mode, the compiler is going to reduce math, vectorize loops, and inline functions which tends to glob your code into an un-mappable mess when it's assembled. An un-mappable mess means your profiler will not be able to clearly identify what is taking so long because the assembly may not correspond to the source code under optimization. If you need the performance (e.g. timing sensitive) of RELEASE mode, disable debugger features as needed to keep a usable performance.

For I/O-bound, the profiler can still identify I/O operations in RELEASE mode because I/O operations are either externally linked to a shared library (most of the time) or in the worst case, will result in a sys-call interrupt vector (which is also easily identifiable by the profiler).

  • +1 The poor man's method works just as well for I/O bound as for CPU bound, and I recommend doing all performance tuning in DEBUG mode. When you're finished tuning, then turn on RELEASE. It will make an improvement if the program is CPU-bound in your code. Here's a crude but short video of the process. – Mike Dunlavey Jun 27 '14 at 20:55
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    I wouldn't use DEBUG builds for performance profiling. Often have I seen that performance critical parts in DEBUG mode are completely optimized away in release mode. Another problem is the use of asserts in debug code which add noise to the performance. – gast128 Jul 21 '14 at 18:55
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    Did you read my post at all? "If you need the performance (e.g. timing sensitive) of RELEASE mode, disable debugger features as needed to keep a usable performance", "Then switch to RELEASE mode and comment the questionable sections of your code (Stub it with nothing) until you see changes in performance."? I said check for possible problem areas in debug mode and verify those problems in release mode to avoid the pitfall you mentioned. – seo Jul 22 '14 at 15:54

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