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I would like to write a program that makes extensive use of BLAS and LAPACK linear algebra functionalities. Since performance is an issue I did some benchmarking and would like know, if the approach I took is legitimate.

I have, so to speak, three contestants and want to test their performance with a simple matrix-matrix multiplication. The contestants are:

  1. Numpy, making use only of the functionality of dot.
  2. Python, calling the BLAS functionalities through a shared object.
  3. C++, calling the BLAS functionalities through a shared object.


I implemented a matrix-matrix multiplication for different dimensions i. i runs from 5 to 500 with an increment of 5 and the matricies m1 and m2 are set up like this:

m1 = numpy.random.rand(i,i).astype(numpy.float32)
m2 = numpy.random.rand(i,i).astype(numpy.float32)

1. Numpy

The code used looks like this:

tNumpy = timeit.Timer("numpy.dot(m1, m2)", "import numpy; from __main__ import m1, m2")
rNumpy.append((i, tNumpy.repeat(20, 1)))

2. Python, calling BLAS through a shared object

With the function

_blaslib = ctypes.cdll.LoadLibrary("libblas.so")
def Mul(m1, m2, i, r):

    no_trans = c_char("n")
    n = c_int(i)
    one = c_float(1.0)
    zero = c_float(0.0)

    _blaslib.sgemm_(byref(no_trans), byref(no_trans), byref(n), byref(n), byref(n), 
            byref(one), m1.ctypes.data_as(ctypes.c_void_p), byref(n), 
            m2.ctypes.data_as(ctypes.c_void_p), byref(n), byref(zero), 
            r.ctypes.data_as(ctypes.c_void_p), byref(n))

the test code looks like this:

r = numpy.zeros((i,i), numpy.float32)
tBlas = timeit.Timer("Mul(m1, m2, i, r)", "import numpy; from __main__ import i, m1, m2, r, Mul")
rBlas.append((i, tBlas.repeat(20, 1)))

3. c++, calling BLAS through a shared object

Now the c++ code naturally is a little longer so I reduce the information to a minimum.
I load the function with

void* handle = dlopen("libblas.so", RTLD_LAZY);
void* Func = dlsym(handle, "sgemm_");

I measure the time with gettimeofday like this:

gettimeofday(&start, NULL);
f(&no_trans, &no_trans, &dim, &dim, &dim, &one, A, &dim, B, &dim, &zero, Return, &dim);
gettimeofday(&end, NULL);
dTimes[j] = CalcTime(start, end);

where j is a loop running 20 times. I calculate the time passed with

double CalcTime(timeval start, timeval end)
double factor = 1000000;
return (((double)end.tv_sec) * factor + ((double)end.tv_usec) - (((double)start.tv_sec) * factor + ((double)start.tv_usec))) / factor;


The result is shown in the plot below:

enter image description here


  1. Do you think my approach is fair, or are there some unnecessary overheads I can avoid?
  2. Would you expect that the result would show such a huge discrepancy between the c++ and python approach? Both are using shared objects for their calculations.
  3. Since I would rather use python for my program, what could I do to increase the performance when calling BLAS or LAPACK routines?


The complete benchmark can be downloaded here. (J.F. Sebastian made that link possible^^)

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in your ctypes approach, you have the memory allocation inside the measured function. Does your c++ code follow this approach ? But compared to matrix multiplication this should not make a big difference.... –  rocksportrocker Sep 29 '11 at 11:29
@rocksportrocker You are correct. The memory allocation for the r matrix is unfair. I am resolving the "issue" right now and post the new results. –  Woltan Sep 29 '11 at 11:35
1. make sure that arrays have the same memory layout np.ascontiguousarray() (consider C vs. Fortran order). 2. make sure that np.dot() uses the same libblas.so. –  J.F. Sebastian Sep 29 '11 at 12:44
@Woltan: don't use filefactory the service is awful. I've added your benchmark to github: woltan-benchmark. If you use github I could add you as a collaborator. –  J.F. Sebastian Sep 30 '11 at 17:50
excellent formulated question! –  Fredrik Pihl Oct 4 '11 at 8:12
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4 Answers

up vote 22 down vote accepted

I've run your benchmark. There is no difference between C++ and numpy on my machine:

woltan's benchmark

Do you think my approach is fair, or are there some unnecessary overheads I can avoid?

It seems fair due to there is no difference in results.

Would you expect that the result would show such a huge discrepancy between the c++ and python approach? Both are using shared objects for their calculations.


Since I would rather use python for my program, what could I do to increase the performance when calling BLAS or LAPACK routines?

Make sure that numpy uses optimized version of BLAS/LAPACK libraries on your system.

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Some time ago I had to optimize some linear algebra calculations/algorithms which were written in python using numpy and BLAS so I benchmarked/tested different numpy/BLAS configurations.

Specifically I tested:

  • Numpy with ATLAS
  • Numpy with GotoBlas2 (1.13)
  • Numpy with MKL (11.1/073)
  • Numpy with Accelerate Framework (Mac OS X)

I did run two different benchmarks:

  1. simple dot product of matrices with different sizes
  2. Benchmark suite which can be found here.

Here are my results:


Linux (MKL, ATLAS, No-MKL, GotoBlas2):

  • OS: Ubuntu Lucid 10.4 64 Bit.
  • CPU: 2 x 4 Intel(R) Xeon(R) E5504 @ 2.00GHz (8 Cores)
  • RAM: 24 GB
  • Intel Compiler: 11.1/073
  • Scipy: 0.8
  • Numpy: 1.5

Mac Book Pro (Accelerate Framework):

  • OS: Mac OS X Snow Leopard (10.6)
  • CPU: 1 Intel Core 2 Duo 2.93 Ghz (2 Cores)
  • RAM: 4 GB
  • Scipy: 0.7
  • Numpy: 1.3

Mac Server (Accelerate Framework):

  • OS: Mac OS X Snow Leopard Server (10.6)
  • CPU: 4 X Intel(R) Xeon(R) E5520 @ 2.26 Ghz (8 Cores)
  • RAM: 4 GB
  • Scipy: 0.8
  • Numpy: 1.5.1

Dot product benchmark


import numpy as np
a = np.random.random_sample((size,size))
b = np.random.random_sample((size,size))
%timeit np.dot(a,b)


    System        |  size = 1000  | size = 2000 | size = 3000 |
netlib BLAS       |  1350 ms      |   10900 ms  |  39200 ms   |    
ATLAS (1 CPU)     |   314 ms      |    2560 ms  |   8700 ms   |     
MKL (1 CPUs)      |   268 ms      |    2110 ms  |   7120 ms   |
MKL (2 CPUs)      |    -          |       -     |   3660 ms   |
MKL (8 CPUs)      |    39 ms      |     319 ms  |   1000 ms   |
GotoBlas2 (1 CPU) |   266 ms      |    2100 ms  |   7280 ms   |
GotoBlas2 (2 CPUs)|   139 ms      |    1009 ms  |   3690 ms   |
GotoBlas2 (8 CPUs)|    54 ms      |     389 ms  |   1250 ms   |
Mac OS X (1 CPU)  |   143 ms      |    1060 ms  |   3605 ms   |
Mac Server (1 CPU)|    92 ms      |     714 ms  |   2130 ms   |

Dot product benchmark - chart

Benchmark Suite

For additional information about the benchmark suite see here.


    System        | eigenvalues   |    svd   |   det  |   inv   |   dot   |
netlib BLAS       |  1688 ms      | 13102 ms | 438 ms | 2155 ms | 3522 ms |
ATLAS (1 CPU)     |   1210 ms     |  5897 ms | 170 ms |  560 ms |  893 ms |
MKL (1 CPUs)      |   691 ms      |  4475 ms | 141 ms |  450 ms |  736 ms |
MKL (2 CPUs)      |   552 ms      |  2718 ms |  96 ms |  267 ms |  423 ms |
MKL (8 CPUs)      |   525 ms      |  1679 ms |  60 ms |  137 ms |  197 ms |  
GotoBlas2 (1 CPU) |  2124 ms      |  4636 ms | 147 ms |  456 ms |  743 ms |
GotoBlas2 (2 CPUs)|  1560 ms      |  3278 ms | 116 ms |  295 ms |  460 ms |
GotoBlas2 (8 CPUs)|   741 ms      |  2914 ms |  82 ms |  262 ms |  192 ms |
Mac OS X (1 CPU)  |   948 ms      |  4339 ms | 151 ms |  318 ms |  566 ms |
Mac Server (1 CPU)|  1033 ms      |  3645 ms |  99 ms |  232 ms |  342 ms |

Benchmark suite - chart


Installation of MKL included installing the complete Intel Compiler Suite which is pretty straight forward. However because of some bugs/issues configuring and compiling numpy with MKL support was a bit of a hassle.

GotoBlas2 is a small package which can be easily compiled as a shared library. However because of a bug you have to re-create the shared library after building it in order to use it with numpy.
In addition to this building it for multiple target plattform didn't work for some reason. So I had to create an .so file for each platform for which i want to have an optimized libgoto2.so file.

If you install numpy from Ubuntu's repository it will automatically install and configure numpy to use ATLAS. Installing ATLAS from source can take some time and requires some additional steps (fortran, etc).

If you install numpy on a Mac OS X machine with Fink or Mac Ports it will either configure numpy to use ATLAS or Apple's Accelerate Framework. You can check by either running ldd on the numpy.core._dotblas file or calling numpy.show_config().


MKL performs best closely followed by GotoBlas2.
In the eigenvalue test GotoBlas2 performs surprisingly worse than expected. Not sure why this is the case.
Apple's Accelerate Framework performs really good especially in single threaded mode (compared to the other BLAS implementations).

Both GotoBlas2 and MKL scale very well with number of threads. So if you have to deal with big matrices running it on multiple threads will help a lot.

In any case don't use the default netlib blas implementation because it is way too slow for any serious computational work.

On our cluster I also installed AMD's ACML and performance was similar to MKL and GotoBlas2. I don't have any numbers tough.

I personally would recommend to use GotoBlas2 because it's easier to install and it's free.

If you want to code in C++/C also check out Eigen3 which is supposed to outperform MKL/GotoBlas2 in some cases and is also pretty easy to use.

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Thank you very much for this elaborate answer! –  Woltan Oct 4 '11 at 9:49
Truly awesome answer, wish I could give you multiple votes. –  Will Sep 3 '13 at 9:31
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Here's another benchmark (on Linux, just type make): http://dl.dropbox.com/u/5453551/blas_call_benchmark.zip

I do not see essentially any difference between the different methods for large matrices, between Numpy, Ctypes and Fortran. (Fortran instead of C++ --- and if this matters, your benchmark is probably broken.)

Your CalcTime function in C++ seems to have a sign error. ... + ((double)start.tv_usec)) should be instead ... - ((double)start.tv_usec)). Perhaps your benchmark also has other bugs, e.g., comparing between different BLAS libraries, or different BLAS settings such as number of threads, or between real time and CPU time?

EDIT: failed to count the braces in the CalcTime function -- it's OK.

As a guideline: if you do a benchmark, please always post all the code somewhere. Commenting on benchmarks, especially when surprising, without having the full code is usually not productive.

To find out which BLAS Numpy is linked against, do:

$ python
Python 2.7.2+ (default, Aug 16 2011, 07:24:41) 
[GCC 4.6.1] on linux2
Type "help", "copyright", "credits" or "license" for more information.
>>> import numpy.core._dotblas
>>> numpy.core._dotblas.__file__
$ ldd /usr/lib/pymodules/python2.7/numpy/core/_dotblas.so
    linux-vdso.so.1 =>  (0x00007fff5ebff000)
    libblas.so.3gf => /usr/lib/libblas.so.3gf (0x00007fbe618b3000)
    libc.so.6 => /lib/x86_64-linux-gnu/libc.so.6 (0x00007fbe61514000)

UPDATE: If you can't import numpy.core._dotblas, your Numpy is using its internal fallback copy of BLAS, which is slower, and not meant to be used in performance computing! The reply from @Woltan below indicates that this is the explanation for the difference he/she sees in Numpy vs. Ctypes+BLAS.

To fix the situation, you need either ATLAS or MKL --- check these instructions: http://scipy.org/Installing_SciPy/Linux Most Linux distributions ship with ATLAS, so the best option is to install their libatlas-dev package (name may vary).

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I've run your benchmark; the results are the same –  J.F. Sebastian Sep 29 '11 at 22:58
Thank you very much for your posting. I ran your benchmark with this result. So I cannot reproduce yours. To check which BLAS my numpy is using: I cannot import numpy.core._dotblas. What could be the problem here? I will try to clean up my benchmark an write a makefile in order for other to test it. –  Woltan Sep 30 '11 at 7:13
@Woltan: the fact that you can't import numpy.core._dotblas means that your Numpy is using its internal fallback copy of BLAS (slower, and not meant to be used in performance computing!), rather than the BLAS library you have on your system. This explains the results you got from the benchmark. To fix the situation, you need to install a BLAS version Numpy can work with --- which means ATLAS or MKL. Here's a set of instructions: scipy.org/Installing_SciPy/Linux –  pv. Sep 30 '11 at 7:51
@pv.: Could you run Woltan's benchmark to compare results. –  J.F. Sebastian Sep 30 '11 at 18:07
@J.F.Sebastian: Sure, here. It agrees with my benchmark, and does not show a difference between the different approaches. –  pv. Sep 30 '11 at 18:20
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Given the rigor you've shown with your analysis, I'm surprised by the results thus far. I put this as an 'answer' but only because it's too long for a comment and does provide a possibility (though I expect you've considered it).

I would've thought the numpy/python approach wouldn't add much overhead for a matrix of reasonable complexity, since as the complexity increases, the proportion that python participates in should be small. I'm more interested in the results on the right hand side of the graph, but orders of magnitude discrepancy shown there would be disturbing.

I wonder if you're using the best algorithms that numpy can leverage. From the compilation guide for linux:

"Build FFTW (3.1.2): SciPy Versions >= 0.7 and Numpy >= 1.2: Because of license, configuration, and maintenance issues support for FFTW was removed in versions of SciPy >= 0.7 and NumPy >= 1.2. Instead now uses a built-in version of fftpack. There are a couple ways to take advantage of the speed of FFTW if necessary for your analysis. Downgrade to a Numpy/Scipy version that includes support. Install or create your own wrapper of FFTW. See http://developer.berlios.de/projects/pyfftw/ as an un-endorsed example."

Did you compile numpy with mkl? (http://software.intel.com/en-us/articles/intel-mkl/). If you're running on linux, the instructions for compiling numpy with mkl are here: http://www.scipy.org/Installing_SciPy/Linux#head-7ce43956a69ec51c6f2cedd894a4715d5bfff974 (in spite of url). The key part is:

library_dirs = /opt/intel/composer_xe_2011_sp1.6.233/mkl/lib/intel64
include_dirs = /opt/intel/composer_xe_2011_sp1.6.233/mkl/include
mkl_libs = mkl_intel_lp64,mkl_intel_thread,mkl_core 

If you're on windows, you can obtain a compiled binary with mkl, (and also obtain pyfftw, and many other related algorithms) at: http://www.lfd.uci.edu/~gohlke/pythonlibs/, with a debt of gratitude to Christoph Gohlke at the Laboratory for Fluorescence Dynamics, UC Irvine.

Caveat, in either case, there are many licensing issues and so on to be aware of, but the intel page explains those. Again, I imagine you've considered this, but if you meet the licensing requirements (which on linux is very easy to do), this would speed up the numpy part a great deal relative to using a simple automatic build, without even FFTW. I'll be interested to follow this thread and see what others think. Regardless, excellent rigor and excellent question. Thanks for posting it.

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Thank you for your elaborate "comment"^^. To clarify my python/numpy/BLAS setup: I followed this installation guide. I am on a linux os and the versions are: Python 2.7, Scipy 0.9 Numpy 1.6. Unfortunately I did not build FFTW before hand, neither did I use mkl... –  Woltan Sep 29 '11 at 12:18
In a way, it is fortunate. It means there is huge room for improvement in the python results and it sounds like you'd like to use python. I think if you amend your build to the one shown on the link you will be much happier with numpy's speed, though I'd still be fascinated to see how it compared to your C++ implementation. –  Profane Sep 29 '11 at 12:33
You could try to build ATLAS too, but that sounded like too many headaches for my performance needs, so I haven't any experience. I imagine if you're interested in using python but able to use C++, there'd be some point at which the setup cost of doing lots of special compilation would outweigh the language savings, and it'd be easier to do c++. But mkl and fftw should both be pretty straightforward. –  Profane Sep 29 '11 at 12:40
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