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3.5. Optional build settings
LAMMPS can be built with several optional settings. Each subsection explains how to do this for building both with CMake and make.
C++11 standard compliance when building all of LAMMPS
FFT library for use with the kspace_style pppm command
Output of JPEG, PNG, and movie files via the dump image or dump movie commands
Exception handling when using LAMMPS as a library to capture errors
3.5.1. C++11 standard compliance
A C++11 standard compatible compiler is a requirement for compiling LAMMPS. LAMMPS version 3 March 2020 is the last version compatible with the previous C++98 standard for the core code and most packages. Most currently used C++ compilers are compatible with C++11, but some older ones may need extra flags to enable C++11 compliance. Example for GNU c++ 4.8.x:
CCFLAGS = -g -O3 -std=c++11
Individual packages may require compliance with a later C++ standard like C++14 or C++17. These requirements will be documented with the individual packages.
3.5.2. FFT library
When the KSPACE package is included in a LAMMPS build, the kspace_style pppm command performs 3d FFTs which require use of an FFT library to compute 1d FFTs. The KISS FFT library is included with LAMMPS, but other libraries can be faster. LAMMPS can use them if they are available on your system.
Added in version 7Feb2024.
Alternatively, LAMMPS can use the heFFTe library for the MPI communication algorithms, which comes with many optimizations for special cases, e.g. leveraging available 2D and 3D FFTs in the back end libraries and better pipelining for packing and communication.
-D FFT=value # FFTW3 or MKL or KISS, default is FFTW3 if found,
# else KISS
-D FFT_KOKKOS=value # FFTW3 or MKL or KISS or CUFFT or HIPFFT,
# default is KISS
-D FFT_SINGLE=value # yes or no (default), no = double precision
-D FFT_PACK=value # array (default) or pointer or memcpy
-D FFT_USE_HEFFTE=value # yes or no (default), yes links to heFFTe
Note
When the Kokkos variant of a package is compiled and selected at run time,
the FFT library selected by the FFT_KOKKOS
variable applies. Otherwise,
the FFT library selected by the FFT variable applies.
The same FFT settings apply to both. FFT_KOKKOS
must be compatible with the
Kokkos back end - for example, when using the CUDA back end of Kokkos,
you must use either CUFFT
or KISS
.
Usually these settings are all that is needed. If FFTW3 is selected, then CMake will try to detect, if threaded FFTW libraries are available and enable them by default. This setting is independent of whether OpenMP threads are enabled and a package like KOKKOS or OPENMP is used. If CMake cannot detect the FFT library, you can set these variables to assist:
-D FFTW3_INCLUDE_DIR=path # path to FFTW3 include files
-D FFTW3_LIBRARY=path # path to FFTW3 libraries
-D FFTW3_OMP_LIBRARY=path # path to FFTW3 OpenMP wrapper libraries
-D FFT_FFTW_THREADS=on # enable using OpenMP threaded FFTW3 libraries
-D MKL_INCLUDE_DIR=path # ditto for Intel MKL library
-D FFT_MKL_THREADS=on # enable using threaded FFTs with MKL libraries
-D MKL_LIBRARY=path # path to MKL libraries
-D FFT_HEFFTE_BACKEND=value # FFTW or MKL or empty/undefined for the stock
# heFFTe back end
-D Heffte_ROOT=path # path to an existing heFFTe installation
Note
heFFTe comes with a builtin (= stock) back end for FFTs, i.e. a default internal FFT implementation; however, this stock back end is intended for testing purposes only and is not optimized for production runs.
To change the FFT library to be used and its options, you have to edit your machine Makefile. Below are examples how the makefile variables could be changed.
FFT_INC = -DFFT_<NAME> # where <NAME> is KISS (default), FFTW3,
# FFTW (same as FFTW3), or MKL
FFT_INC = -DFFT_KOKKOS_<NAME> # where <NAME> is KISS (default), FFTW3,
# FFTW (same as FFTW3), MKL, CUFFT, or HIPFFT
FFT_INC = -DFFT_SINGLE # do not specify for double precision
FFT_INC = -DFFT_FFTW_THREADS # enable using threaded FFTW3 libraries
FFT_INC = -DFFT_MKL_THREADS # enable using threaded FFTs with MKL libraries
FFT_INC = -DFFT_PACK_ARRAY # or -DFFT_PACK_POINTER or -DFFT_PACK_MEMCPY
# default is FFT_PACK_ARRAY if not specified
FFT_INC = -I/usr/local/include
FFT_PATH = -L/usr/local/lib
# hipFFT either precision
FFT_LIB = -lhipfft
# cuFFT either precision
FFT_LIB = -lcufft
# FFTW3 double precision
FFT_LIB = -lfftw3
# FFTW3 double precision with threads (needs -DFFT_FFTW_THREADS)
FFT_LIB = -lfftw3 -lfftw3_omp
# FFTW3 single precision
FFT_LIB = -lfftw3 -lfftw3f
# serial MKL with Intel compiler
FFT_LIB = -lmkl_intel_lp64 -lmkl_sequential -lmkl_core
# serial MKL with GNU compiler
FFT_LIB = -lmkl_gf_lp64 -lmkl_sequential -lmkl_core
# threaded MKL with Intel compiler
FFT_LIB = -lmkl_intel_lp64 -lmkl_intel_thread -lmkl_core
# threaded MKL with GNU compiler
FFT_LIB = -lmkl_gf_lp64 -lmkl_gnu_thread -lmkl_core
# MKL with automatic runtime selection of interface libs
FFT_LIB = -lmkl_rt
As with CMake, you do not need to set paths in FFT_INC
or
FFT_PATH
, if the compiler can find the FFT header and library
files in its default search path. You must specify FFT_LIB
with the appropriate FFT libraries to include in the link.
Traditional make can also link to heFFTe using an existing installation
include <path-to-heffte-installation>/share/heffte/HeffteMakefile.in
FFT_INC = -DFFT_HEFFTE -DFFT_HEFFTE_FFTW $(heffte_include)
FFT_PATH =
FFT_LIB = $(heffte_link) $(heffte_libs)
The heFFTe install path will contain HeffteMakefile.in
.
which will define the heffte_
include variables needed to link to heFFTe from
an external project using traditional make.
The -DFFT_HEFFTE
is required to switch to using heFFTe, while the optional -DFFT_HEFFTE_FFTW
selects the desired heFFTe back end, e.g., -DFFT_HEFFTE_FFTW
or -DFFT_HEFFTE_MKL
,
omitting the variable will default to the stock back end.
The heFFTe stock back end is intended to be used for testing and debugging,
but is not performance optimized for large scale production runs.
The KISS FFT library is included in the LAMMPS distribution. It is portable across all platforms. Depending on the size of the FFTs and the number of processors used, the other libraries listed here can be faster.
However, note that long-range Coulombics are only a portion of the per-timestep CPU cost, FFTs are only a portion of long-range Coulombics, and 1d FFTs are only a portion of the FFT cost (parallel communication can be costly). A breakdown of these timings is printed to the screen at the end of a run when using the kspace_style pppm command. The Screen and logfile output page gives more details. A more detailed (and time consuming) report of the FFT performance is generated with the kspace_modify fftbench yes command.
FFTW is a fast, portable FFT library that should also work on any platform and can be faster than the KISS FFT library. You can download it from www.fftw.org. LAMMPS requires version 3.X; the legacy version 2.1.X is no longer supported.
Building FFTW for your box should be as simple as ./configure; make;
make install
. The install command typically requires root privileges
(e.g. invoke it via sudo), unless you specify a local directory with
the --prefix
option of configure. Type ./configure --help
to see
various options.
The Intel MKL math library is part of the Intel compiler suite. It
can be used with the Intel or GNU compiler (see the FFT_LIB
setting
above).
The cuFFT and hipFFT FFT libraries are packaged with NVIDIA’s CUDA and AMD’s HIP installations, respectively. These FFT libraries require the Kokkos acceleration package to be enabled and the Kokkos back end to be GPU-resident (i.e., HIP or CUDA).
Performing 3d FFTs in parallel can be time-consuming due to data access
and required communication. This cost can be reduced by performing
single-precision FFTs instead of double precision. Single precision
means the real and imaginary parts of a complex datum are 4-byte floats.
Double precision means they are 8-byte doubles. Note that Fourier
transform and related PPPM operations are somewhat less sensitive to
floating point truncation errors, and thus the resulting error is
generally less than the difference in precision. Using the
-DFFT_SINGLE
setting trades off a little accuracy for reduced memory
use and parallel communication costs for transposing 3d FFT data.
When using -DFFT_SINGLE
with FFTW3, you may need to ensure that
the FFTW3 installation includes support for single-precision.
When compiler FFTW3 from source, you can do the following, which should
produce the additional libraries libfftw3f.a
and/or libfftw3f.so
.
make clean
./configure --enable-single; make; make install
Performing 3d FFTs requires communication to transpose the 3d FFT
grid. The data packing/unpacking for this can be done in one of 3
modes (ARRAY, POINTER, MEMCPY) as set by the FFT_PACK
syntax above.
Depending on the machine, the size of the FFT grid, the number of
processors used, one option may be slightly faster. The default is
ARRAY mode.
When using -DFFT_HEFFTE
CMake will first look for an existing
install with hints provided by -DHeffte_ROOT
, as recommended by the
CMake standard and note that the name is case sensitive. If CMake cannot
find a heFFTe installation with the correct back end (e.g., FFTW or
MKL), it will attempt to download and build the library automatically.
In this case, LAMMPS CMake will also accept all heFFTe specific
variables listed in the heFFTe documentation
and those variables will be passed into the heFFTe build.
3.5.3. Size of LAMMPS integer types and size limits
LAMMPS uses a few custom integer data types, which can be defined as either 4-byte (= 32-bit) or 8-byte (= 64-bit) integers at compile time. This has an impact on the size of a system that can be simulated, or how large counters can become before “rolling over”. The default setting of “smallbig” is almost always adequate.
With CMake the choice of integer types is made via setting a variable during configuration.
-D LAMMPS_SIZES=value # smallbig (default) or bigbig or smallsmall
If the variable is not set explicitly, “smallbig” is used.
If you want a setting different from the default, you need to edit the
LMP_INC
variable setting your machine Makefile.
LMP_INC = -DLAMMPS_SMALLBIG # or -DLAMMPS_BIGBIG or -DLAMMPS_SMALLSMALL
The default setting is -DLAMMPS_SMALLBIG
if nothing is specified
LAMMPS system size restrictions
smallbig |
bigbig |
smallsmall |
|
---|---|---|---|
Total atom count |
\(2^{63}\) atoms (= \(9.223 \cdot 10^{18}\)) |
\(2^{63}\) atoms (= \(9.223 \cdot 10^{18}\)) |
\(2^{31}\) atoms (= \(2.147 \cdot 10^9\)) |
Total timesteps |
\(2^{63}\) steps (= \(9.223 \cdot 10^{18}\)) |
\(2^{63}\) steps (= \(9.223 \cdot 10^{18}\)) |
\(2^{31}\) steps (= \(2.147 \cdot 10^9\)) |
Atom ID values |
\(1 \le i \le 2^{31} (= 2.147 \cdot 10^9)\) |
\(1 \le i \le 2^{63} (= 9.223 \cdot 10^{18})\) |
\(1 \le i \le 2^{31} (= 2.147 \cdot 10^9)\) |
Image flag values |
\(-512 \le i \le 511\) |
\(- 1\,048\,576 \le i \le 1\,048\,575\) |
\(-512 \le i \le 511\) |
The “bigbig” setting increases the size of image flags and atom IDs over “smallbig” and the “smallsmall” setting is only needed if your machine does not support 64-bit integers or incurs performance penalties when using them.
These are limits for the core of the LAMMPS code, specific features or some styles may impose additional limits. The ATC package cannot be compiled with the “bigbig” setting. Also, there are limitations when using the library interface where some functions with known issues have been replaced by dummy calls printing a corresponding error message rather than crashing randomly or corrupting data.
Atom IDs are not required for atomic systems which do not store bond topology information, though IDs are enabled by default. The atom_modify id no command will turn them off. Atom IDs are required for molecular systems with bond topology (bonds, angles, dihedrals, etc). Similarly, some force or compute or fix styles require atom IDs. Thus, if you model a molecular system or use one of those styles with more than 2 billion atoms, you need the “bigbig” setting.
Regardless of the total system size limits, the maximum number of atoms per MPI rank (local + ghost atoms) is limited to 2 billion for atomic systems and 500 million for systems with bonds (the additional restriction is due to using the 2 upper bits of the local atom index in neighbor lists for storing special bonds info).
Image flags store 3 values per atom in a single integer, which count the number of times an atom has moved through the periodic box in each dimension. See the dump manual page for a discussion. If an atom moves through the periodic box more than this limit, the value will “roll over”, e.g. from 511 to -512, which can cause diagnostics like the mean-squared displacement, as calculated by the compute msd command, to be faulty.
Also note that the GPU package requires its lib/gpu library to be
compiled with the same size setting, or the link will fail. A CMake
build does this automatically. When building with make, the setting
in whichever lib/gpu/Makefile
is used must be the same as above.
3.5.4. Output of JPEG, PNG, and movie files
The dump image command has options to output JPEG or PNG image files. Likewise, the dump movie command outputs movie files in a variety of movie formats. Using these options requires the following settings:
-D WITH_JPEG=value # yes or no
# default = yes if CMake finds JPEG development files, else no
-D WITH_PNG=value # yes or no
# default = yes if CMake finds PNG and ZLIB development files,
# else no
-D WITH_FFMPEG=value # yes or no
# default = yes if CMake can find ffmpeg, else no
Usually these settings are all that is needed. If CMake cannot find the graphics header, library, executable files, you can set these variables:
-D JPEG_INCLUDE_DIR=path # path to jpeglib.h header file
-D JPEG_LIBRARY=path # path to libjpeg.a (.so) file
-D PNG_INCLUDE_DIR=path # path to png.h header file
-D PNG_LIBRARY=path # path to libpng.a (.so) file
-D ZLIB_INCLUDE_DIR=path # path to zlib.h header file
-D ZLIB_LIBRARY=path # path to libz.a (.so) file
-D FFMPEG_EXECUTABLE=path # path to ffmpeg executable
LMP_INC = -DLAMMPS_JPEG -DLAMMPS_PNG -DLAMMPS_FFMPEG <other LMP_INC settings>
JPG_INC = -I/usr/local/include # path to jpeglib.h, png.h, zlib.h headers
# if make cannot find them
JPG_PATH = -L/usr/lib # paths to libjpeg.a, libpng.a, libz.a (.so)
# files if make cannot find them
JPG_LIB = -ljpeg -lpng -lz # library names
As with CMake, you do not need to set JPG_INC
or JPG_PATH
,
if make can find the graphics header and library files in their
default system locations. You must specify JPG_LIB
with a
list of graphics libraries to include in the link. You must make
certain that the ffmpeg executable (or ffmpeg.exe on Windows) is
in a directory where LAMMPS can find it at runtime; that is
usually a directory list in your PATH
environment variable.
Using ffmpeg
to output movie files requires that your machine
supports the “popen” function in the standard runtime library.
Note
On some clusters with high-speed networks, using the fork() library call (required by popen()) can interfere with the fast communication library and lead to simulations using ffmpeg to hang or crash.
3.5.5. Read or write compressed files
If this option is enabled, large files can be read or written with
compression by gzip
or similar tools by several LAMMPS commands,
including read_data, rerun, and
dump. Supported compression tools and algorithms are currently
gzip
, bzip2
, zstd
, xz
, lz4
, and lzma
(via xz).
-D WITH_GZIP=value # yes or no
# default is yes if CMake can find the gzip program
LMP_INC = -DLAMMPS_GZIP <other LMP_INC settings>
This option requires that your operating system fully supports the
“popen()” function in the standard runtime library and that a gzip
or other executable can be found by LAMMPS in the standard search path
during a run.
Note
On clusters with high-speed networks, using the “fork()” library call (required by “popen()”) can interfere with the fast communication library and lead to simulations using compressed output or input to hang or crash. For selected operations, compressed file I/O is also available using a compression library instead, which is what the COMPRESS package enables.
3.5.6. Support for downloading files
Added in version 29Aug2024.
The geturl command command uses the the libcurl library to download files. This requires that LAMMPS is compiled accordingly which needs the following settings:
-D WITH_CURL=value # yes or no
# default = yes if CMake finds CURL development files, else no
Usually these settings are all that is needed. If CMake cannot find the graphics header, library, executable files, you can set these variables:
-D CURL_INCLUDE_DIR=path # path to folder which contains curl.h header file
-D CURL_LIBRARY=path # path to libcurls.a (.so) file
LMP_INC = -DLAMMPS_CURL <other LMP_INC settings>
CURL_INC = -I/usr/local/include # path to curl folder with curl.h
CURL_PATH = -L/usr/lib # paths to libcurl.a(.so) if make cannot find it
CURL_LIB = -lcurl # library names
As with CMake, you do not need to set CURL_INC
or CURL_PATH
,
if make can find the libcurl header and library files in their
default system locations. You must specify CURL_LIB
with a
paths or linker flags to link to libcurl.
3.5.7. Memory allocation alignment
This setting enables the use of the posix_memalign()
call instead of
malloc()
when LAMMPS allocates large chunks of memory. Vector
instructions on CPUs may become more efficient, if dynamically allocated
memory is aligned on larger-than-default byte boundaries. On most
current operating systems, the malloc()
implementation returns
pointers that are aligned to 16-byte boundaries. Using SSE vector
instructions efficiently, however, requires memory blocks being aligned
on 64-byte boundaries.
-D LAMMPS_MEMALIGN=value # 0, 8, 16, 32, 64 (default)
Use a LAMMPS_MEMALIGN
value of 0 to disable using
posix_memalign()
and revert to using the malloc()
C-library
function instead. When compiling LAMMPS for Windows systems,
malloc()
will always be used and this setting is ignored.
LMP_INC = -DLAMMPS_MEMALIGN=value # 8, 16, 32, 64
Do not set -DLAMMPS_MEMALIGN
, if you want to have memory
allocated with the malloc()
function call
instead. -DLAMMPS_MEMALIGN
cannot be used on Windows, as
Windows different function calls with different semantics for
allocating aligned memory, that are not compatible with how LAMMPS
manages its dynamical memory.
3.5.8. Workaround for long long integers
If your system or MPI version does not recognize “long long” data types, the following setting will be needed. It converts “long long” to a “long” data type, which should be the desired 8-byte integer on those systems:
-D LAMMPS_LONGLONG_TO_LONG=value # yes or no (default)
LMP_INC = -DLAMMPS_LONGLONG_TO_LONG <other LMP_INC settings>
3.5.9. Exception handling when using LAMMPS as a library
LAMMPS errors do not kill the calling code, but throw an exception. In the C-library interface, the call stack is unwound and control returns to the caller, e.g. to Python or a code that is coupled to LAMMPS. The error status can then be queried. When using C++ directly, the calling code has to be set up to catch exceptions thrown from within LAMMPS.
Note
When LAMMPS is running in parallel, it is not always possible to cleanly recover from an exception since not all parallel ranks may throw an exception and thus other MPI ranks may get stuck waiting for messages from the ones with errors.
3.5.10. Trigger selected floating-point exceptions
Many kinds of CPUs have the capability to detect when a calculation
results in an invalid math operation, like a division by zero or calling
the square root with a negative argument. The default behavior on
most operating systems is to continue and have values for NaN
(= not
a number) or Inf
(= infinity). This allows software to detect and
recover from such conditions. This behavior can be changed, however,
often through use of compiler flags. On Linux systems (or more general
on systems using the GNU C library), these so-called floating-point traps
can also be selectively enabled through library calls. LAMMPS supports
that by setting the -DLAMMPS_TRAP_FPE
pre-processor define. As it is
done in the main()
function, this applies only to the standalone
executable, not the library.
-D CMAKE_TUNE_FLAGS=-DLAMMPS_TRAP_FPE
LMP_INC = -DLAMMPS_TRAP_FPE <other LMP_INC settings>
After compilation with this flag set, the LAMMPS executable will stop and produce a core dump when a division by zero, overflow, illegal math function argument or other invalid floating point operation is encountered.