# This file provides configuration information about non-Python dependencies for # numpy.distutils-using packages. Create a file like this called "site.cfg" next # to your package's setup.py file and fill in the appropriate sections. Not all # packages will use all sections so you should leave out sections that your # package does not use. # To assist automatic installation like easy_install, the user's home directory # will also be checked for the file ~/.numpy-site.cfg . # The format of the file is that of the standard library's ConfigParser module. # No interpolation is allowed, RawConfigParser class being used to load it. # # http://docs.python.org/3/library/configparser.html # # Each section defines settings that apply to one particular dependency. Some of # the settings are general and apply to nearly any section and are defined here. # Settings specific to a particular section will be defined near their section. # # libraries # Comma-separated list of library names to add to compile the extension # with. Note that these should be just the names, not the filenames. For # example, the file "libfoo.so" would become simply "foo". # libraries = lapack,f77blas,cblas,atlas # # library_dirs # List of directories to add to the library search path when compiling # extensions with this dependency. Use the character given by os.pathsep # to separate the items in the list. Note that this character is known to # vary on some unix-like systems; if a colon does not work, try a comma. # This also applies to include_dirs and src_dirs (see below). # On UN*X-type systems (OS X, most BSD and Linux systems): # library_dirs = /usr/lib:/usr/local/lib # On Windows: # library_dirs = c:\mingw\lib,c:\atlas\lib # On some BSD and Linux systems: # library_dirs = /usr/lib,/usr/local/lib # # include_dirs # List of directories to add to the header file search path. # include_dirs = /usr/include:/usr/local/include # # src_dirs # List of directories that contain extracted source code for the # dependency. For some dependencies, numpy.distutils will be able to build # them from source if binaries cannot be found. The FORTRAN BLAS and # LAPACK libraries are one example. However, most dependencies are more # complicated and require actual installation that you need to do # yourself. # src_dirs = /home/rkern/src/BLAS_SRC:/home/rkern/src/LAPACK_SRC # # search_static_first # Boolean (one of (0, false, no, off) for False or (1, true, yes, on) for # True) to tell numpy.distutils to prefer static libraries (.a) over # shared libraries (.so). It is turned off by default. # search_static_first = false # # runtime_library_dirs/rpath # List of directories that contains the libraries that should be # used at runtime, thereby disregarding the LD_LIBRARY_PATH variable. # See 'library_dirs' for formatting on different platforms. # runtime_library_dirs = /opt/blas/lib:/opt/lapack/lib # or equivalently # rpath = /opt/blas/lib:/opt/lapack/lib # # extra_compile_args # Add additional arguments to the compilation of sources. # Simple variable with no parsing done. # Provide a single line with all complete flags. # extra_compile_args = -g -ftree-vectorize # # extra_link_args # Add additional arguments when libraries/executables # are linked. # Simple variable with no parsing done. # Provide a single line with all complete flags. # extra_link_args = -lgfortran # # Defaults # ======== # The settings given here will apply to all other sections if not overridden. # This is a good place to add general library and include directories like # /usr/local/{lib,include} # #[ALL] #library_dirs = /usr/local/lib #include_dirs = /usr/local/include # # Atlas # ----- # Atlas is an open source optimized implementation of the BLAS and Lapack # routines. Numpy will try to build against Atlas by default when available in # the system library dirs. To build numpy against a custom installation of # Atlas you can add an explicit section such as the following. Here we assume # that Atlas was configured with ``prefix=/opt/atlas``. # # [atlas] # library_dirs = /opt/atlas/lib # include_dirs = /opt/atlas/include # OpenBLAS # -------- # OpenBLAS is another open source optimized implementation of BLAS and Lapack # and can be seen as an alternative to Atlas. To build numpy against OpenBLAS # instead of Atlas, use this section instead of the above, adjusting as needed # for your configuration (in the following example we installed OpenBLAS with # ``make install PREFIX=/opt/OpenBLAS``. # OpenBLAS is generically installed as a shared library, to force the OpenBLAS # library linked to also be used at runtime you can utilize the # runtime_library_dirs variable. # # **Warning**: OpenBLAS, by default, is built in multithreaded mode. Due to the # way Python's multiprocessing is implemented, a multithreaded OpenBLAS can # cause programs using both to hang as soon as a worker process is forked on # POSIX systems (Linux, Mac). # This is fixed in Openblas 0.2.9 for the pthread build, the OpenMP build using # GNU openmp is as of gcc-4.9 not fixed yet. # Python 3.4 will introduce a new feature in multiprocessing, called the # "forkserver", which solves this problem. For older versions, make sure # OpenBLAS is built using pthreads or use Python threads instead of # multiprocessing. # (This problem does not exist with multithreaded ATLAS.) # # http://docs.python.org/3.4/library/multiprocessing.html#contexts-and-start-methods # https://github.com/xianyi/OpenBLAS/issues/294 # # [openblas] # libraries = openblas # library_dirs = /opt/OpenBLAS/lib # include_dirs = /opt/OpenBLAS/include # runtime_library_dirs = /opt/OpenBLAS/lib # MKL #---- # MKL is Intel's very optimized yet proprietary implementation of BLAS and # Lapack. # For recent (9.0.21, for example) mkl, you need to change the names of the # lapack library. Assuming you installed the mkl in /opt, for a 32 bits cpu: # [mkl] # library_dirs = /opt/intel/mkl/9.1.023/lib/32/ # lapack_libs = mkl_lapack # # For 10.*, on 32 bits machines: # [mkl] # library_dirs = /opt/intel/mkl/10.0.1.014/lib/32/ # lapack_libs = mkl_lapack # mkl_libs = mkl, guide # # On win-64, the following options compiles numpy with the MKL library # dynamically linked. # [mkl] # include_dirs = C:\Program Files (x86)\Intel\Composer XE 2015\mkl\include # library_dirs = C:\Program Files (x86)\Intel\Composer XE 2015\mkl\lib\intel64 # mkl_libs = mkl_core_dll, mkl_intel_lp64_dll, mkl_intel_thread_dll # lapack_libs = mkl_lapack95_lp64 # UMFPACK # ------- # The UMFPACK library is used in scikits.umfpack to factor large sparse matrices. # It, in turn, depends on the AMD library for reordering the matrices for # better performance. Note that the AMD library has nothing to do with AMD # (Advanced Micro Devices), the CPU company. # # UMFPACK is not used by numpy. # # http://www.cise.ufl.edu/research/sparse/umfpack/ # http://www.cise.ufl.edu/research/sparse/amd/ # http://scikits.appspot.com/umfpack # #[amd] #amd_libs = amd # #[umfpack] #umfpack_libs = umfpack # FFT libraries # ------------- # There are two FFT libraries that we can configure here: FFTW (2 and 3) and djbfft. # Note that these libraries are not used by for numpy or scipy. # # http://fftw.org/ # http://cr.yp.to/djbfft.html # # Given only this section, numpy.distutils will try to figure out which version # of FFTW you are using. #[fftw] #libraries = fftw3 # # For djbfft, numpy.distutils will look for either djbfft.a or libdjbfft.a . #[djbfft] #include_dirs = /usr/local/djbfft/include #library_dirs = /usr/local/djbfft/lib