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What is a good workflow for detecting performance regressions in R packages? Ideally, I'm looking for something that integrates with R CMD check that alerts me when I have introduced a significant performance regression in my code.

What is a good workflow in general? What other languages provide good tools? Is it something that can be built on top unit testing, or that is usually done separately?

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Tricky. You might not even be running the tests on the same PC as previously, so it'll have to be relative to some stable benchmark... –  Spacedman Dec 11 '11 at 15:58
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This method works in any language, including R. It doesn't measure time with any accuracy; what it does is accurately point out the code that takes time, and gives a rough estimate of the percent of time it takes. If you see a change in what's taking time, or a significant increase in its percent, that tells you what the regression is. –  Mike Dunlavey Dec 11 '11 at 16:41
    
... If you do identify something that takes high percent, and you fix it, you will see the percent due to that will drop, and the overall time will drop. The percent of something else will rise because it takes a larger fraction of a smaller total. That's to be expected. –  Mike Dunlavey Dec 11 '11 at 16:45

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up vote 15 down vote accepted

This is a very challenging question, and one that I'm frequently dealing with, as I swap out different code in a package to speed things up. Sometimes a performance regression comes along with a change in algorithms or implementation, but it may also arise due to changes in the data structures used.

What is a good workflow for detecting performance regressions in R packages?

In my case, I tend to have very specific use cases that I'm trying to speed up, with different fixed data sets. As Spacedman wrote, it's important to have a fixed computing system, but that's almost infeasible: sometimes a shared computer may have other processes that slow things down 10-20%, even when it looks quite idle.

My steps:

  1. Standardize the platform (e.g. one or a few machines, a particular virtual machine, or a virtual machine + specific infrastructure, a la Amazon's EC2 instance types).
  2. Standardize the data set that will be used for speed testing.
  3. Create scripts and fixed intermediate data output (i.e. saved to .rdat files) that involve very minimal data transformations. My focus is on some kind of modeling, rather than data manipulation or transformation. This means that I want to give exactly the same block of data to the modeling functions. If, however, data transformation is the goal, then be sure that the pre-transformed/manipulated data is as close as possible to standard across tests of different versions of the package. (See this question for examples of memoization, cacheing, etc., that can be used to standardize or speed up non-focal computations. It references several packages by the OP.)
  4. Repeat tests multiple times.
  5. Scale the results relative to fixed benchmarks, e.g. the time to perform a linear regression, to sort a matrix, etc. This can allow for "local" or transient variations in infrastructure, such as may be due to I/O, the memory system, dependent packages, etc.
  6. Examine the profiling output as vigorously as possible (see this question for some insights, also referencing tools from the OP).

    Ideally, I'm looking for something that integrates with R CMD check that alerts me when I have introduced a significant performance regression in my code.

    Unfortunately, I don't have an answer for this.

    What is a good workflow in general?

    For me, it's quite similar to general dynamic code testing: is the output (execution time in this case) reproducible, optimal, and transparent? Transparency comes from understanding what affects the overall time. This is where Mike Dunlavey's suggestions are important, but I prefer to go further, with a line profiler.

    Regarding a line profiler, see my previous question, which refers to options in Python and Matlab for other examples. It's most important to examine clock time, but also very important to track memory allocation, number of times the line is executed, and call stack depth.

    What other languages provide good tools?

    Almost all other languages have better tools. :) Interpreted languages like Python and Matlab have the good & possibly familiar examples of tools that can be adapted for this purpose. Although dynamic analysis is very important, static analysis can help identify where there may be some serious problems. Matlab has a great static analyzer that can report when objects (e.g. vectors, matrices) are growing inside of loops, for instance. It is terrible to find this only via dynamic analysis - you've already wasted execution time to discover something like this, and it's not always discernible if your execution context is pretty simple (e.g. just a few iterations, or small objects).

    As far as language-agnostic methods, you can look at:

    1. Valgrind & cachegrind
    2. Monitoring of disk I/O, dirty buffers, etc.
    3. Monitoring of RAM (Cachegrind is helpful, but you could just monitor RAM allocation, and lots of details about RAM usage)
    4. Usage of multiple cores

    Is it something that can be built on top unit testing, or that is usually done separately?

    This is hard to answer. For static analysis, it can occur before unit testing. For dynamic analysis, one may want to add more tests. Think of it as sequential design (i.e. from an experimental design framework): if the execution costs appear to be, within some statistical allowances for variation, the same, then no further tests are needed. If, however, method B seems to have an average execution cost greater than method A, then one should perform more intensive tests.


Update 1: If I may be so bold, there's another question that I'd recommend including, which is: "What are some gotchas in comparing the execution time of two versions of a package?" This is analogous to assuming that two programs that implement the same algorithm should have the same intermediate objects. That's not exactly true (see this question - not that I'm promoting my own questions, here - it's just hard work to make things better and faster...leading to multiple SO questions on this topic :)). In a similar way, two executions of the same code can differ in time consumed due to factors other than the implementation.

So, some gotchas that can occur, either within the same language or across languages, within the same execution instance or across "identical" instances, which can affect runtime:

  1. Garbage collection - different implementations or languages can hit garbage collection under different circumstances. This can make two executions appear different, though it can be very dependent on context, parameters, data sets, etc. The GC-obsessive execution will look slower.
  2. Cacheing at the level of the disk, motherboard (e.g. L1, L2, L3 caches), or other levels (e.g. memoization). Often, the first execution will pay a penalty.
  3. Dynamic voltage scaling - This one sucks. When there is a problem, this may be one of the hardest beasties to find, since it can go away quickly. It looks like cacheing, but it isn't.
  4. Any job priority manager that you don't know about.
  5. One method uses multiple cores or does some clever stuff about how work is parceled among cores or CPUs. For instance, getting a process locked to a core can be useful in some scenarios. One execution of an R package may be luckier in this regard, another package may be very clever...
  6. Unused variables, excessive data transfer, dirty caches, unflushed buffers, ... the list goes on.

The key result is: Ideally, how should we test for differences in expected values, subject to the randomness created due to order effects? Well, pretty simple: go back to experimental design. :)

When the empirical differences in execution times are different from the "expected" differences, it's great to have enabled additional system and execution monitoring so that we don't have to re-run the experiments until we're blue in the face.

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The only way to do anything here is to make some assumptions. So let us assume an unchanged machine, or else require a 'recalibration'.

Then use a unit-test alike framework, and treat 'has to be done in X units of time' as just yet another testing criterion to be fulfilled. In other words, do something like

 stopifnot( timingOf( someExpression ) < savedValue plus fudge)

so we would have to associate prior timings with given expressions. Equality-testing comparisons from any one of the three existing unit testing packages could be used as well.

Nothing that Hadley couldn't handle so I think we can almost expect a new package timr after the next long academic break :). Of course, this has to be either be optional because on a "unknown" machine (think: CRAN testing the package) we have no reference point, or else the fudge factor has to "go to 11" to automatically accept on a new machine.

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Or maybe an extension to testthat? expect_that(foo(x),takes_less_than(bar(y)))? –  Spacedman Dec 11 '11 at 16:54
    
With bar(y) being the function that gets us previous times of foo(x) plus some tolerance / fudge measure? Possibly. –  Dirk Eddelbuettel Dec 11 '11 at 16:57
    
not sure if this is connected, but svUnit captures timing information in the unit tests, and reports it to the log. –  Ramnath Dec 11 '11 at 16:59
    
So does RUnit. But both only report the aggregate if I am not mistaken. –  Dirk Eddelbuettel Dec 11 '11 at 17:01

A recent change announced on the R-devel feed could give a crude measure for this.

CHANGES IN R-devel UTILITIES

‘R CMD check’ can optionally report timings on various parts of the check: this is controlled by environment variables documented in ‘Writing R Extensions’.

See http://developer.r-project.org/blosxom.cgi/R-devel/2011/12/13#n2011-12-13

The overall time spent running the tests could be checked and compared to previous values. Of course, adding new tests will increase the time, but dramatic performance regressions could still be seen, albeit manually.

This is not as fine grained as timing support within individual test suites, but it also does not depend on any one specific test suite.

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