I've got some code which performs a packed symmetric matrix inversion and multiplication using the LAPACK routines
DSPMV. Here is an older topic in which you can see the C++ code I use to invoke the LAPACK routines.
My code currently assembles a symmetric matrix which is mostly populated along the diagonal.
I am testing different BLAS and LAPACK implementations and I am comparing GotoBLAS2 with the reference LAPACK implementation from netlib.
Here is how I compile the netlib LAPACK code. I select the
.f code files from source, and compile them all into a compact static library like this:
$ ls ddot.f dpptrf.f dscal.f dspr.f dtpsv.f lsame.f dgemm.f dpptri.f dspmv.f dtpmv.f dtptri.f xerbla.f $ gfortran -c *.f $ ar rcs liblapack_lite.a *.o
I can then link this lib to my C++ application using
I then tried using GotoBLAS2. I got it from here. The package contained scripts that compiled a massive 19MB static lib automatically. It works great with my existing code by linking it:
I felt that this went well at first. With GotoBLAS2, on large problem sets (inverting 1000x1000 or larger matrices) I saw about a 6x performance increase. Since GotoBLAS is threaded for my architecture and reference LAPACK is single threaded I thought this was reasonable. System monitor also showed >300% CPU usage to corroborate.
Here's where it gets weird. I think, what if I optimize the reference implementation?
I recompile my lapack_lite lib like this:
gfortran -c -O3 *.f
My lapack_lite lib now outperforms GotoBLAS2 even on a 3200x3200 matrix inversion, using only one thread. It also consumes ~80MB less RAM.
The subsequent packed matrix-vector multiply does happen faster with GotoBLAS, however.
How is this even remotely possible? Did the make configuration of the GotoBLAS package fail to use an optimization switch with gfortran?