Libxc is a library of exchange-correlation functionals for density-functional theory. The aim is to provide a portable, well tested and reliable set of exchange and correlation functionals that can be used by a variety of programs.
For more information, please check the manual at http://www.tddft.org/programs/Libxc
The recommended way to install the library is by using GNU Autotools.
To install the library, just use the standard procedure:
./configure --prefix=PATH/TO/LIBXC
make
make check
make install
If you're not using a stable release tarball, you'll first need to
generate configure with autoreconf -i.
Support for CMake has also been recently contributed by Lori Burns.
The CMake file has the following caveats
- tested on Linux and Mac, static and shared lib, namespaced and non-namespaced headers, but really only to the extent that it works for Psi4
- all the fancy libtool options and Fortran interface not tested
- test suite executed after build via
ctest. But it has always totally passed or totally failed, which doesn't inspire confidence - The generated
libxc_docs.txtis large, and the generation step sometimes balks on it, leading toxc_funcs.hnot found errors. Just execute again.
Use the following procedure:
cmake -H. -Bobjdir
cd objdir && make
make test
make installThe build is also responsive to
- static/shared toggle
BUILD_SHARED_LIBS - install location
CMAKE_INSTALL_PREFIX - namespacing of headers
NAMESPACE_INSTALL_INCLUDEDIR - of course,
CMAKE_C_COMPILER,BUILD_TESTING, andCMAKE_C_FLAGS
See CMakeLists.txt for options details. All these build options should be passed as cmake -DOPTION.
CMake builds install with LibxcConfig.cmake, LibxcConfigVersion.cmake, and LibxcTargets.cmake files suitable for use with CMake find_package() in CONFIG mode.
find_package(Libxc)- find any xc libraries and headersfind_package(Libxc 3.0.0 EXACT CONFIG REQUIRED COMPONENTS static)- find Libxc exactly version 3.0.0 built with static libraries or die trying
See cmake/LibxcConfig.cmake.in for details of how to detect the Config file and what CMake variables and targets are exported to your project.
After find_package(Libxc ...),
- test if package found with
if(${Libxc_FOUND})orif(TARGET Libxc::xc) - link to library (establishes dependency), including header and definitions configuration with
target_link_libraries(mytarget Libxc::xc) - include header files using
target_include_directories(mytarget PRIVATE $<TARGET_PROPERTY:Libxc::xc,INTERFACE_INCLUDE_DIRECTORIES>) - compile target applying
-DUSING_Libxcdefinition usingtarget_compile_definitions(mytarget PRIVATE $<TARGET_PROPERTY:Libxc::xc,INTERFACE_COMPILE_DEFINITIONS>)
Optional Python bindings are available through the cytpes module. To install
into Python site-packages plese run:
python setup.py install
or, to install locally for development:
python setup.py develop
The Python bindings require the CMake compilation pathway and the Python Numerical Python library. A short usage example is provided below:
# Build functional
>>> func = pylibxc.LibXCFunctional("gga_c_pbe", "unpolarized")
# Create input
>>> inp = {}
>>> inp["rho"] = np.random.random((3))
>>> inp["sigma"] = np.random.random((3))
# Compute
>>> ret = func.compute(inp)
>>> for k, v in ret.items():
>>> print(k, v)
zk [[-0.06782171 -0.05452743 -0.04663709]]
vrho [[-0.08349967 -0.0824188 -0.08054892]]
vsigma [[ 0.00381277 0.00899967 0.01460601]]The distribution is organized as follows
| ./cmake | CMake helper files |
| ./build | pkgconfig and Fedora spec files |
| ./m4 | m4 scripts used by configure.ac, and libxc.m4 used by other projects linking to libxc |
| ./maple | the Maple source code for the functionals |
| ./scripts | various scripts for libxc development |
| ./src | source files |
| ./testsuite | regression tests |
The most important contents of the src directory for users are
| xc.h | main header file with all external definitions |
| xc_funcs.h | automatically generated file with the list of functionals |
In addition, developers will be interested in the following
| util.h | header file with internal definitions |
| *.f90 *.F90 xc_f.c string_f.h | Fortran 90 interface |
| *.f03 *.F03 | Fortran 2003 interface |
| funcs_*.c | automatically generated files with the functional definitions |
| functionals.c | generic interface to simplify access to the different families |
| lda.c gga.c mgga.c | interface to the different families of functionals |
| special_functions.c | implementation of a series of special functions |
| hyb_gga_*.c | definition of the different hybrid GGA functionals |
| hyb_mgga_*.c | definition of the different hybrid meta-GGA functionals |
| lda_*.c | definition of the different LDA functionals |
| gga_*.c | definition of the different GGA functionals |
| mgga_*.c | definition of the different meta-GGA functionals |
| work_lda.c | code that simplifies the implementation of LDAs |
| work_gga_x.c | code that simplifies the implementation of exchange GGAs |
| work_gga_c.c | code that simplifies the implementation of some correlation GGAs |
| work_mgga_x.c | code that simplifies the implementation of exchange meta-GGAs |
| work_mgga_c.c | code that simplifies the implementation of some correlation meta-GGAs |
Notes:
- Most functionals use the framework contained in a work_*.c file. This simplifies tremendously the implementation of the different functionals. The work_*.c are #include'd in the functional implementations through a preprocessor directive.
- Some files contain more than one functional, as similar functionals are usually grouped together. Therefore, the best way to find where a functional is implemented is by looking at its keyword in xc_funcs.h and using grep to find the correct file.
- The files where the functionals are defined are named as family_type_name.c, where: family - functional family (lda, gga, hyb_gga, or mgga) type - type of functional (x, c, xc, or k) name - name of the functional or class of functionals