Difference between revisions of "Profiling"
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Revision as of 17:59, 6 August 2009
Can I speed up my program?
Introduction
How fast does each part of my program take? Perhaps I could speed it up? As with debugging, we could add print statements, use a stopwatch, compile and re-run etc. etc. But that would be tedius and there are tools around which do the job way better.
Compiler Options
You probably want to make sure that you've added all the go-faster flags that are available before you embark on any profiling. Activating optimisations for speed can make your progam run a lot faster!
Using Valgrind
Valgrind is an excellent open-source tool for debugging and profiling.
Compile your program as normal, adding in any optimisation flags that you desire and also -g. Then run it through the callgrind tool, embedded in valgrind:
valgrind --tool=callgrind your-program [program options]
When your program has run you find a file called callgrind.out.xxxx in the current directory, where xxxx is replaced with a number (the process ID of the command you have just executed).
You can inspect the contents of this newly created file using a graphical display too call kcachegrind:
kcachegrind callgrind.out.xxxx
An Simple Example
svn co http://source.ggy.bris.ac.uk/subversion-open/profiling ./profiling cd profiling/examples/example1 make valgrind --tool=callgrind ./div.exe >& div.out kcachegrind callgrind.out.xxxx
We can see from the graphical display given by kcachegrind that our inefficient division routine takes far more of the runtime that our efficient routine. Using this kind of information, we can focus our re-engineering efforts on the slower parts of our program.
A Common Situation Involoving Loops
OK, let's assume that we've located a region of our program that is taking a long time. So far so good, but how can we address that? There are--of course--a great many reasons why some code may take a long time to run. One reason could be just that it has a lot to do! Let's assume, however, that the code can be made to run faster by applying a little more of the old grey matter. With this in mind, let's consider a few common examples of code which can tweaked to run faster.
For our first example, consider the way we loop over the contents of a 2-dimensional array--a pretty common situation!. Skip over a directory and compile the example programs:
cd ../example2 make
In this directory, we have two almost identical programs. Compare the contents of loopingA.f90 and loopingB.f90. You will see that inside each program a 2-dimensional array is declared and two nested loops are used to visit each of the cells of the array in turn (and an arithmetic value is dropped in). The only way in which the two programs differ is the order in which the cycle through the contents of the arrays. In loopingA.f90, the outer loop is over the columns of the array and the inner loop is over the rows (i.e. for a given value of ii, all values of jj and cycled over). The opposite is true for loopingB.f90.
Let's compare how long it takes these two programs to run. We can do this using the Linux time command:
time ./loopingA.exe
and now,
time ./loopingB.exe
Dude! loopingA.exe takes more than twice the time of loopingB.exe. What's the reason?
Well, Fortran stores it's 2-dimensional arrays in column-major order. Our 2-dimension array is actually stored in the computer memory as a 1-dimension array, where the cells in a given column are next to each other. For example, the array:
- [math]\displaystyle{ \begin{bmatrix} 1 & 2 & 3 \\ 4 & 5 & 6 \end{bmatrix} }[/math]
would actually be stored in memory as:
1 4 2 5 3 6
That means is that our outer loop should be over the columns, and our inner loop over the rows. Otherwise we would end up hopping all around the memory, which takes extra time, and explains why loopingA takes longer.
The opposite situation is true for the C programming language, which stores its 2-dimensional arrays in row-major order. You can type:
make testC
To run some equivalent C code examples.
Some Costly Operations
Consider the following code snippet: