# Packages with extra build options When building with some packages, additional steps may be required, in addition to +-----------------------+------------------+ | CMake build | Traditional make | +=======================+==================+ | ``` bash | ``` console | | cmake -D PKG_NAME=yes | make yes-name | | ``` | ``` | +-----------------------+------------------+ as described on the [Build_package](Build_package) page. For a CMake build there may be additional optional or required variables to set. For a build with make, a provided library under the lammps/lib directory may need to be built first. Or an external library may need to exist on your system or be downloaded and built. You may need to tell LAMMPS where it is found on your system. This is the list of packages that may require additional steps. ------------------------------------------------------------------------ ## COMPRESS package {#compress} To build with this package you must have the [zlib compression library](https://zlib.net)\_ available on your system to build dump styles with a \'/gz\' suffix. There are also styles using the [Zstandard](https://facebook.github.io/zstd/)\_ library which have a \'/zstd\' suffix. The zstd library version must be at least 1.4. Older versions use an incompatible API and thus LAMMPS will fail to compile. ::::: tabs ::: tab CMake build If CMake cannot find the zlib library or include files, you can set these variables: ``` bash -D ZLIB_INCLUDE_DIR=path # path to zlib.h header file -D ZLIB_LIBRARY=path # path to libz.a (.so) file ``` Support for Zstandard compression is auto-detected and for that CMake depends on the [pkg-config](https://www.freedesktop.org/wiki/Software/pkg-config/)\_ tool to identify the necessary flags to compile with this library, so the corresponding `libzstandard.pc` file must be in a folder where pkg-config can find it, which may require adding it to the `PKG_CONFIG_PATH` environment variable. ::: ::: tab Traditional make To include support for Zstandard compression, `-DLAMMPS_ZSTD` must be added to the compiler flags. If make cannot find the libraries, you can edit the file `lib/compress/Makefile.lammps` to specify the paths and library names. This must be done **before** the package is installed. ::: ::::: ------------------------------------------------------------------------ ## GPU package {#gpu} To build with this package, you must choose options for precision and which GPU hardware to build for. The GPU package currently supports three different types of backends: OpenCL, CUDA and HIP. ### CMake build ``` bash -D GPU_API=value # value = opencl (default) or cuda or hip -D GPU_PREC=value # precision setting # value = double or mixed (default) or single -D GPU_ARCH=value # primary GPU hardware choice for GPU_API=cuda # value = sm_XX (see below, default is sm_50) -D GPU_DEBUG=value # enable debug code in the GPU package library, mostly useful for developers # value = yes or no (default) -D HIP_PATH=value # value = path to HIP installation. Must be set if GPU_API=HIP -D HIP_ARCH=value # primary GPU hardware choice for GPU_API=hip # value depends on selected HIP_PLATFORM # default is 'gfx906' for HIP_PLATFORM=amd and 'sm_50' for HIP_PLATFORM=nvcc -D HIP_USE_DEVICE_SORT=value # enables GPU sorting # value = yes (default) or no -D CUDPP_OPT=value # use GPU binning on with CUDA (should be off for modern GPUs) # enables CUDA Performance Primitives, must be "no" for CUDA_MPS_SUPPORT=yes # value = yes or no (default) -D CUDA_MPS_SUPPORT=value # enables some tweaks required to run with active nvidia-cuda-mps daemon # value = yes or no (default) -D USE_STATIC_OPENCL_LOADER=value # downloads/includes OpenCL ICD loader library, no local OpenCL headers/libs needed # value = yes (default) or no ``` `GPU_ARCH` settings for different GPU hardware is as follows: - sm_30 for Kepler (supported since CUDA 5 and until CUDA 10.x) - sm_35 or sm_37 for Kepler (supported since CUDA 5 and until CUDA 11.x) - sm_50 or sm_52 for Maxwell (supported since CUDA 6) - sm_60 or sm_61 for Pascal (supported since CUDA 8) - sm_70 for Volta (supported since CUDA 9) - sm_75 for Turing (supported since CUDA 10) - sm_80 or sm_86 for Ampere (supported since CUDA 11, sm_86 since CUDA 11.1) - sm_89 for Lovelace (supported since CUDA 11.8) - sm_90 for Hopper (supported since CUDA 12.0) A more detailed list can be found, for example, at [Wikipedia\'s CUDA article](https://en.wikipedia.org/wiki/CUDA#GPUs_supported)\_ CMake can detect which version of the CUDA toolkit is used and thus will try to include support for **all** major GPU architectures supported by this toolkit. Thus the GPU_ARCH setting is merely an optimization, to have code for the preferred GPU architecture directly included rather than having to wait for the JIT compiler of the CUDA driver to translate it. When compiling for CUDA or HIP with CUDA, version 8.0 or later of the CUDA toolkit is required and a GPU architecture of Kepler or later, which must *also* be supported by the CUDA toolkit in use **and** the CUDA driver in use. When compiling for OpenCL, OpenCL version 1.2 or later is required and the GPU must be supported by the GPU driver and OpenCL runtime bundled with the driver. When building with CMake, you **must NOT** build the GPU library in `lib/gpu` using the traditional build procedure. CMake will detect files generated by that process and will terminate with an error and a suggestion for how to remove them. If you are compiling for OpenCL, the default setting is to download, build, and link with a static OpenCL ICD loader library and standard OpenCL headers. This way no local OpenCL development headers or library needs to be present and only OpenCL compatible drivers need to be installed to use OpenCL. If this is not desired, you can set `USE_STATIC_OPENCL_LOADER` to `no`. The GPU library has some multi-thread support using OpenMP. If LAMMPS is built with `-D BUILD_OMP=on` this will also be enabled. If you are compiling with HIP, note that before running CMake you will have to set appropriate environment variables. Some variables such as `HCC_AMDGPU_TARGET` (for ROCm \<= 4.0) or `CUDA_PATH` are necessary for `hipcc` and the linker to work correctly. Using CHIP-SPV implementation of HIP is now supported. It allows one to run HIP code on Intel GPUs via the OpenCL or Level Zero backends. To use CHIP-SPV, you must set `-DHIP_USE_DEVICE_SORT=OFF` in your CMake command line as CHIP-SPV does not yet support hipCUB. The use of HIP for Intel GPUs is still experimental so you should only use this option in preparations to run on Aurora system at ANL. ``` bash # AMDGPU target (ROCm <= 4.0) export HIP_PLATFORM=hcc export HIP_PATH=/path/to/HIP/install export HCC_AMDGPU_TARGET=gfx906 cmake -D PKG_GPU=on -D GPU_API=HIP -D HIP_ARCH=gfx906 -D CMAKE_CXX_COMPILER=hipcc .. make -j 4 ``` ``` bash # AMDGPU target (ROCm >= 4.1) export HIP_PLATFORM=amd export HIP_PATH=/path/to/HIP/install cmake -D PKG_GPU=on -D GPU_API=HIP -D HIP_ARCH=gfx906 -D CMAKE_CXX_COMPILER=hipcc .. make -j 4 ``` ``` bash # CUDA target (not recommended, use GPU_ARCH=cuda) # !!! DO NOT set CMAKE_CXX_COMPILER !!! export HIP_PLATFORM=nvcc export HIP_PATH=/path/to/HIP/install export CUDA_PATH=/usr/local/cuda cmake -D PKG_GPU=on -D GPU_API=HIP -D HIP_ARCH=sm_70 .. make -j 4 ``` ``` bash # SPIR-V target (Intel GPUs) export HIP_PLATFORM=spirv export HIP_PATH=/path/to/HIP/install export CMAKE_CXX_COMPILER= cmake -D PKG_GPU=on -D GPU_API=HIP .. make -j 4 ``` ### Traditional make Before building LAMMPS, you must build the GPU library in `lib/gpu`. You can do this manually if you prefer; follow the instructions in `lib/gpu/README`. Note that the GPU library uses MPI calls, so you must use the same MPI library (or the STUBS library) settings as the main LAMMPS code. This also applies to the `-DLAMMPS_BIGBIG`, `-DLAMMPS_SMALLBIG`, or `-DLAMMPS_SMALLSMALL` settings in whichever Makefile you use. You can also build the library in one step from the `lammps/src` dir, using a command like these, which simply invokes the `lib/gpu/Install.py` script with the specified args: ``` bash make lib-gpu # print help message make lib-gpu args="-b" # build GPU library with default Makefile.linux make lib-gpu args="-m xk7 -p single -o xk7.single" # create new Makefile.xk7.single, altered for single-precision make lib-gpu args="-m mpi -a sm_60 -p mixed -b" # build GPU library with mixed precision and P100 using other settings in Makefile.mpi ``` Note that this procedure starts with a Makefile.machine in lib/gpu, as specified by the \"-m\" switch. For your convenience, machine makefiles for \"mpi\" and \"serial\" are provided, which have the same settings as the corresponding machine makefiles in the main LAMMPS source folder. In addition you can alter 4 important settings in the Makefile.machine you start from via the corresponding -c, -a, -p, -e switches (as in the examples above), and also save a copy of the new Makefile if desired: - `CUDA_HOME` = where NVIDIA CUDA software is installed on your system - `CUDA_ARCH` = sm_XX, what GPU hardware you have, same as CMake GPU_ARCH above - `CUDA_PRECISION` = precision (double, mixed, single) - `EXTRAMAKE` = which Makefile.lammps.\* file to copy to Makefile.lammps The file Makefile.cuda is set up to include support for multiple GPU architectures as supported by the CUDA toolkit in use. This is done through using the \"\--gencode \" flag, which can be used multiple times and thus support all GPU architectures supported by your CUDA compiler. To enable GPU binning via CUDA performance primitives set the Makefile variable `CUDPP_OPT = -DUSE_CUDPP -Icudpp_mini`. This should **not** be used with most modern GPUs. To support the CUDA multiprocessor server you can set the define `-DCUDA_MPS_SUPPORT`. Please note that in this case you must **not** use the CUDA performance primitives and thus set the variable `CUDPP_OPT` to empty. The GPU library has some multi-thread support using OpenMP. You need to add the compiler flag that enables OpenMP to the `CUDR_OPTS` Makefile variable. If the library build is successful, 3 files should be created: `lib/gpu/libgpu.a`, `lib/gpu/nvc_get_devices`, and `lib/gpu/Makefile.lammps`. The latter has settings that enable LAMMPS to link with CUDA libraries. If the settings in `Makefile.lammps` for your machine are not correct, the LAMMPS build will fail, and `lib/gpu/Makefile.lammps` may need to be edited. :::: note ::: title Note ::: If you re-build the GPU library in `lib/gpu`, you should always uninstall the GPU package in `lammps/src`, then re-install it and re-build LAMMPS. This is because the compilation of files in the GPU package uses the library settings from the `lib/gpu/Makefile.machine` used to build the GPU library. :::: ------------------------------------------------------------------------ ## KIM package {#kim} To build with this package, the KIM library with API v2 must be downloaded and built on your system. It must include the KIM models that you want to use with LAMMPS. If you would like to use the [kim query](kim_commands) command, you also need to have libcurl installed with the matching development headers and the curl-config tool. If you would like to use the [kim property](kim_commands) command, you need to build LAMMPS with the PYTHON package installed and linked to Python 3.6 or later. See the [PYTHON package build info](python) for more details on this. After successfully building LAMMPS with Python, you also need to install the `kim-property` Python package, which can be easily done using *pip* as `pip install kim-property`, or from the *conda-forge* channel as `conda install kim-property` if LAMMPS is built in Conda. More detailed information is available at: [kim-property installation](https://github.com/openkim/kim-property#installing-kim-property)\_. In addition to installing the KIM API, it is also necessary to install the library of KIM models (interatomic potentials). See [Obtaining KIM Models](https://openkim.org/doc/usage/obtaining-models)\_ to learn how to install a pre-build binary of the OpenKIM Repository of Models. See the list of all KIM models here: (Also note that when downloading and installing from source the KIM API library with all its models, may take a long time (tens of minutes to hours) to build. Of course you only need to do that once.) ::::: tabs ::: tab CMake build ``` bash -D DOWNLOAD_KIM=value # download OpenKIM API v2 for build, value = no (default) or yes -D LMP_DEBUG_CURL=value # set libcurl verbose mode on/off, value = off (default) or on -D LMP_NO_SSL_CHECK=value # tell libcurl to not verify the peer, value = no (default) or yes -D KIM_EXTRA_UNITTESTS=value # enables extra unit tests, value = no (default) or yes ``` If `DOWNLOAD_KIM` is set to *yes* (or *on*), the KIM API library will be downloaded and built inside the CMake build directory. If the KIM library is already installed on your system (in a location where CMake cannot find it), you may need to set the `PKG_CONFIG_PATH` environment variable so that libkim-api can be found, or run the command `source kim-api-activate`. Extra unit tests can only be available if they are explicitly requested (`KIM_EXTRA_UNITTESTS` is set to *yes* (or *on*)) and the prerequisites are met. See [KIM Extra unit tests](kim_extra_unittests) for more details on this. ::: ::: tab Traditional make You can download and build the KIM library manually if you prefer; follow the instructions in `lib/kim/README`. You can also do this in one step from the lammps/src directory, using a command like these, which simply invokes the `lib/kim/Install.py` script with the specified args. ``` bash make lib-kim # print help message make lib-kim args="-b " # (re-)install KIM API lib with only example models make lib-kim args="-b -a Glue_Ercolessi_Adams_Al__MO_324507536345_001" # ditto plus one model make lib-kim args="-b -a everything" # install KIM API lib with all models make lib-kim args="-n -a EAM_Dynamo_Ackland_W__MO_141627196590_002" # add one model or model driver make lib-kim args="-p /usr/local" # use an existing KIM API installation at the provided location make lib-kim args="-p /usr/local -a EAM_Dynamo_Ackland_W__MO_141627196590_002" # ditto but add one model or driver ``` When using the \"-b \" option, the KIM library is built using its native cmake build system. The `lib/kim/Install.py` script supports a `CMAKE` environment variable if the cmake executable is named other than `cmake` on your system. Additional environment variables may be provided on the command line for use by cmake. For example, to use the `cmake3` executable and tell it to use the gnu version 11 compilers to build KIM, one could use the following command line. ``` bash CMAKE=cmake3 CXX=g++-11 CC=gcc-11 FC=gfortran-11 make lib-kim args="-b " # (re-)install KIM API lib using cmake3 and gnu v11 compilers with only example models ``` Settings for debugging OpenKIM web queries discussed below need to be applied by adding them to the `LMP_INC` variable through editing the `Makefile.machine` you are using. For example: ``` make LMP_INC = -DLMP_NO_SSL_CHECK ``` ::: ::::: ### Debugging OpenKIM web queries in LAMMPS If `LMP_DEBUG_CURL` is set, the libcurl verbose mode will be turned on, and any libcurl calls within the KIM web query display a lot of information about libcurl operations. You hardly ever want this set in production use, you will almost always want this when you debug or report problems. The libcurl library performs peer SSL certificate verification by default. This verification is done using a CA certificate store that the SSL library can use to make sure the peer\'s server certificate is valid. If SSL reports an error (\"certificate verify failed\") during the handshake and thus refuses further communicate with that server, you can set `LMP_NO_SSL_CHECK` to override that behavior. When LAMMPS is compiled with `LMP_NO_SSL_CHECK` set, libcurl does not verify the peer and connection attempts will succeed regardless of the names in the certificate. This option is insecure. As an alternative, you can specify your own CA cert path by setting the environment variable `CURL_CA_BUNDLE` to the path of your choice. A call to the KIM web query would get this value from the environment variable. ### KIM Extra unit tests (CMake only) {#kim_extra_unittests} During development, testing, or debugging, if [unit testing](Build_development) is enabled in LAMMPS, one can also enable extra tests on [KIM commands](kim_commands) by setting the `KIM_EXTRA_UNITTESTS` to *yes* (or *on*). Enabling the extra unit tests have some requirements, - It requires to have internet access. - It requires to have libcurl installed with the matching development headers and the curl-config tool. - It requires to build LAMMPS with the PYTHON package installed and linked to Python 3.6 or later. See the [PYTHON package build info](python) for more details on this. - It requires to have `kim-property` Python package installed, which can be easily done using *pip* as `pip install kim-property`, or from the *conda-forge* channel as `conda install kim-property` if LAMMPS is built in Conda. More detailed information is available at: [kim-property installation](https://github.com/openkim/kim-property#installing-kim-property)\_. - It is also necessary to install `EAM_Dynamo_MendelevAckland_2007v3_Zr__MO_004835508849_000`, `EAM_Dynamo_ErcolessiAdams_1994_Al__MO_123629422045_005`, and `LennardJones612_UniversalShifted__MO_959249795837_003` KIM models. See [Obtaining KIM Models](https://openkim.org/doc/usage/obtaining-models)\_ to learn how to install a pre-built binary of the OpenKIM Repository of Models or see [Installing KIM Models](https://openkim.org/doc/usage/obtaining-models/#installing_models)\_ to learn how to install the specific KIM models. ------------------------------------------------------------------------ ## KOKKOS package {#kokkos} Using the KOKKOS package requires choosing several settings. You have to select whether you want to compile with parallelization on the host and whether you want to include offloading of calculations to a device (e.g. a GPU). The default setting is to have no host parallelization and no device offloading. In addition, you can select the hardware architecture to select the instruction set. Since most hardware is backward compatible, you may choose settings for an older architecture to have an executable that will run on this and newer architectures. :::: note ::: title Note ::: If you run Kokkos on a different GPU architecture than what LAMMPS was compiled with, there will be a delay during device initialization while the just-in-time compiler is recompiling all GPU kernels for the new hardware. This is, however, only supported for GPUs of the **same** major hardware version and different minor hardware versions, e.g. 5.0 and 5.2 but not 5.2 and 6.0. LAMMPS will abort with an error message indicating a mismatch, if that happens. :::: The settings discussed below have been tested with LAMMPS and are confirmed to work. Kokkos is an active project with ongoing improvements and projects working on including support for additional architectures. More information on Kokkos can be found on the [Kokkos GitHub project](https://github.com/kokkos)\_. ### Available Architecture settings These are the possible choices for the Kokkos architecture ID. They must be specified in uppercase. ----------------- ----------------- -------------------------------------------------------------- **Arch-ID** **HOST or GPU** **Description** NATIVE HOST Local machine AMDAVX HOST AMD 64-bit x86 CPU (AVX 1) ZEN HOST AMD Zen class CPU (AVX 2) ZEN2 HOST AMD Zen2 class CPU (AVX 2) ZEN3 HOST AMD Zen3 class CPU (AVX 2) ARMV80 HOST ARMv8.0 Compatible CPU ARMV81 HOST ARMv8.1 Compatible CPU ARMV8_THUNDERX HOST ARMv8 Cavium ThunderX CPU ARMV8_THUNDERX2 HOST ARMv8 Cavium ThunderX2 CPU A64FX HOST ARMv8.2 with SVE Support WSM HOST Intel Westmere CPU (SSE 4.2) SNB HOST Intel Sandy/Ivy Bridge CPU (AVX 1) HSW HOST Intel Haswell CPU (AVX 2) BDW HOST Intel Broadwell Xeon E-class CPU (AVX 2 + transactional mem) SKL HOST Intel Skylake Client CPU SKX HOST Intel Skylake Xeon Server CPU (AVX512) ICL HOST Intel Ice Lake Client CPU (AVX512) ICX HOST Intel Ice Lake Xeon Server CPU (AVX512) SPR HOST Intel Sapphire Rapids Xeon Server CPU (AVX512) KNC HOST Intel Knights Corner Xeon Phi KNL HOST Intel Knights Landing Xeon Phi BGQ HOST IBM Blue Gene/Q CPU POWER7 HOST IBM POWER7 CPU POWER8 HOST IBM POWER8 CPU POWER9 HOST IBM POWER9 CPU KEPLER30 GPU NVIDIA Kepler generation CC 3.0 GPU KEPLER32 GPU NVIDIA Kepler generation CC 3.2 GPU KEPLER35 GPU NVIDIA Kepler generation CC 3.5 GPU KEPLER37 GPU NVIDIA Kepler generation CC 3.7 GPU MAXWELL50 GPU NVIDIA Maxwell generation CC 5.0 GPU MAXWELL52 GPU NVIDIA Maxwell generation CC 5.2 GPU MAXWELL53 GPU NVIDIA Maxwell generation CC 5.3 GPU PASCAL60 GPU NVIDIA Pascal generation CC 6.0 GPU PASCAL61 GPU NVIDIA Pascal generation CC 6.1 GPU VOLTA70 GPU NVIDIA Volta generation CC 7.0 GPU VOLTA72 GPU NVIDIA Volta generation CC 7.2 GPU TURING75 GPU NVIDIA Turing generation CC 7.5 GPU AMPERE80 GPU NVIDIA Ampere generation CC 8.0 GPU AMPERE86 GPU NVIDIA Ampere generation CC 8.6 GPU ADA89 GPU NVIDIA Ada Lovelace generation CC 8.9 GPU HOPPER90 GPU NVIDIA Hopper generation CC 9.0 GPU VEGA900 GPU AMD GPU MI25 GFX900 VEGA906 GPU AMD GPU MI50/MI60 GFX906 VEGA908 GPU AMD GPU MI100 GFX908 VEGA90A GPU AMD GPU MI200 GFX90A INTEL_GEN GPU SPIR64-based devices, e.g. Intel GPUs, using JIT INTEL_DG1 GPU Intel Iris XeMAX GPU INTEL_GEN9 GPU Intel GPU Gen9 INTEL_GEN11 GPU Intel GPU Gen11 INTEL_GEN12LP GPU Intel GPU Gen12LP INTEL_XEHP GPU Intel GPU Xe-HP INTEL_PVC GPU Intel GPU Ponte Vecchio ----------------- ----------------- -------------------------------------------------------------- This list was last updated for version 3.7.1 of the Kokkos library. ::::: tabs ::: tab Basic CMake build settings: For multicore CPUs using OpenMP, set these 2 variables. ``` bash -D Kokkos_ARCH_HOSTARCH=yes # HOSTARCH = HOST from list above -D Kokkos_ENABLE_OPENMP=yes -D BUILD_OMP=yes ``` Please note that enabling OpenMP for KOKKOS requires that OpenMP is also [enabled for the rest of LAMMPS](serial). For Intel KNLs using OpenMP, set these variables: ``` bash -D Kokkos_ARCH_KNL=yes -D Kokkos_ENABLE_OPENMP=yes ``` For NVIDIA GPUs using CUDA, set these variables: ``` bash -D Kokkos_ARCH_HOSTARCH=yes # HOSTARCH = HOST from list above -D Kokkos_ARCH_GPUARCH=yes # GPUARCH = GPU from list above -D Kokkos_ENABLE_CUDA=yes -D Kokkos_ENABLE_OPENMP=yes ``` This will also enable executing FFTs on the GPU, either via the internal KISSFFT library, or - by preference - with the cuFFT library bundled with the CUDA toolkit, depending on whether CMake can identify its location. For AMD or NVIDIA GPUs using HIP, set these variables: ``` bash -D Kokkos_ARCH_HOSTARCH=yes # HOSTARCH = HOST from list above -D Kokkos_ARCH_GPUARCH=yes # GPUARCH = GPU from list above -D Kokkos_ENABLE_HIP=yes -D Kokkos_ENABLE_OPENMP=yes ``` This will enable FFTs on the GPU, either by the internal KISSFFT library or with the hipFFT wrapper library, which will call out to the platform-appropriate vendor library: rocFFT on AMD GPUs or cuFFT on NVIDIA GPUs. To simplify compilation, five preset files are included in the `cmake/presets` folder, `kokkos-serial.cmake`, `kokkos-openmp.cmake`, `kokkos-cuda.cmake`, `kokkos-hip.cmake`, and `kokkos-sycl.cmake`. They will enable the KOKKOS package and enable some hardware choice. So to compile with CUDA device parallelization (for GPUs with CC 5.0 and up) with some common packages enabled, you can do the following: ``` bash mkdir build-kokkos-cuda cd build-kokkos-cuda cmake -C ../cmake/presets/basic.cmake -C ../cmake/presets/kokkos-cuda.cmake ../cmake cmake --build . ``` ::: ::: tab Basic traditional make settings: Choose which hardware to support in `Makefile.machine` via `KOKKOS_DEVICES` and `KOKKOS_ARCH` settings. See the `src/MAKE/OPTIONS/Makefile.kokkos*` files for examples. For multicore CPUs using OpenMP: ``` make KOKKOS_DEVICES = OpenMP KOKKOS_ARCH = HOSTARCH # HOSTARCH = HOST from list above ``` For Intel KNLs using OpenMP: ``` make KOKKOS_DEVICES = OpenMP KOKKOS_ARCH = KNL ``` For NVIDIA GPUs using CUDA: ``` make KOKKOS_DEVICES = Cuda KOKKOS_ARCH = HOSTARCH,GPUARCH # HOSTARCH = HOST from list above that is hosting the GPU KOKKOS_CUDA_OPTIONS = "enable_lambda" # GPUARCH = GPU from list above FFT_INC = -DFFT_CUFFT # enable use of cuFFT (optional) FFT_LIB = -lcufft # link to cuFFT library ``` For GPUs, you also need the following lines in your `Makefile.machine` before the CC line is defined. They tell `mpicxx` to use an `nvcc` compiler wrapper, which will use `nvcc` for compiling CUDA files and a C++ compiler for non-Kokkos, non-CUDA files. ``` make # For OpenMPI KOKKOS_ABSOLUTE_PATH = $(shell cd $(KOKKOS_PATH); pwd) export OMPI_CXX = $(KOKKOS_ABSOLUTE_PATH)/config/nvcc_wrapper CC = mpicxx ``` ``` make # For MPICH and derivatives KOKKOS_ABSOLUTE_PATH = $(shell cd $(KOKKOS_PATH); pwd) CC = mpicxx -cxx=$(KOKKOS_ABSOLUTE_PATH)/config/nvcc_wrapper ``` For AMD or NVIDIA GPUs using HIP: ``` make KOKKOS_DEVICES = HIP KOKKOS_ARCH = HOSTARCH,GPUARCH # HOSTARCH = HOST from list above that is hosting the GPU # GPUARCH = GPU from list above FFT_INC = -DFFT_HIPFFT # enable use of hipFFT (optional) FFT_LIB = -lhipfft # link to hipFFT library ``` ::: ::::: ### Advanced KOKKOS compilation settings There are other allowed options when building with the KOKKOS package that can improve performance or assist in debugging or profiling. Below are some examples that may be useful in combination with LAMMPS. For the full list (which keeps changing as the Kokkos package itself evolves), please consult the Kokkos library documentation. As alternative to using multi-threading via OpenMP (`-DKokkos_ENABLE_OPENMP=on` or `KOKKOS_DEVICES=OpenMP`) it is also possible to use Posix threads directly (`-DKokkos_ENABLE_PTHREAD=on` or `KOKKOS_DEVICES=Pthread`). While binding of threads to individual or groups of CPU cores is managed in OpenMP with environment variables, you need assistance from either the \"hwloc\" or \"libnuma\" library for the Pthread thread parallelization option. To enable use with CMake: `-DKokkos_ENABLE_HWLOC=on` or `-DKokkos_ENABLE_LIBNUMA=on`; and with conventional make: `KOKKOS_USE_TPLS=hwloc` or `KOKKOS_USE_TPLS=libnuma`. The CMake option `-DKokkos_ENABLE_LIBRT=on` or the makefile setting `KOKKOS_USE_TPLS=librt` enables the use of a more accurate timer mechanism on many Unix-like platforms for internal profiling. The CMake option `-DKokkos_ENABLE_DEBUG=on` or the makefile setting `KOKKOS_DEBUG=yes` enables printing of run-time debugging information that can be useful. It also enables runtime bounds checking on Kokkos data structures. As to be expected, enabling this option will negatively impact the performance and thus is only recommended when developing a Kokkos-enabled style in LAMMPS. The CMake option `-DKokkos_ENABLE_CUDA_UVM=on` or the makefile setting `KOKKOS_CUDA_OPTIONS=enable_lambda,force_uvm` enables the use of CUDA \"Unified Virtual Memory\" (UVM) in Kokkos. UVM allows to transparently use RAM on the host to supplement the memory used on the GPU (with some performance penalty) and thus enables running larger problems that would otherwise not fit into the RAM on the GPU. Please note, that the LAMMPS KOKKOS package must **always** be compiled with the *enable_lambda* option when using GPUs. The CMake configuration will thus always enable it. ------------------------------------------------------------------------ ## LEPTON package {#lepton} To build with this package, you must build the Lepton library which is included in the LAMMPS source distribution in the `lib/lepton` folder. ::::: tabs ::: tab CMake build This is the recommended build procedure for using Lepton in LAMMPS. No additional settings are normally needed besides `-D PKG_LEPTON=yes`. On x86 hardware the Lepton library will also include a just-in-time compiler for faster execution. This is auto detected but can be explicitly disabled by setting `-D LEPTON_ENABLE_JIT=no` (or enabled by setting it to yes). ::: ::: tab Traditional make Before building LAMMPS, one must build the Lepton library in lib/lepton. This can be done manually in the same folder by using or adapting one of the provided Makefiles: for example, `Makefile.serial` for the GNU C++ compiler, or `Makefile.mpi` for the MPI compiler wrapper. The Lepton library is written in C++-11 and thus the C++ compiler may need to be instructed to enable support for that. In general, it is safer to use build setting consistent with the rest of LAMMPS. This is best carried out from the LAMMPS src directory using a command like these, which simply invokes the `lib/lepton/Install.py` script with the specified args: ``` bash make lib-lepton # print help message make lib-lepton args="-m serial" # build with GNU g++ compiler (settings as with "make serial") make lib-lepton args="-m mpi" # build with default MPI compiler (settings as with "make mpi") ``` The \"machine\" argument of the \"-m\" flag is used to find a Makefile.machine to use as build recipe. The build should produce a `build` folder and the library `lib/lepton/liblmplepton.a` ::: ::::: ------------------------------------------------------------------------ ## ML-IAP package {#mliap} Building the ML-IAP package requires including the [ML-SNAP](PKG-ML-SNAP) package. There will be an error message if this requirement is not satisfied. Using the *mliappy* model also requires enabling Python support, which in turn requires to include the [PYTHON](PKG-PYTHON) package **and** requires to have the [cython](https://cython.org)\_ software installed and with it a working `cythonize` command. This feature requires compiling LAMMPS with Python version 3.6 or later. ::::: tabs ::: tab CMake build ``` bash -D MLIAP_ENABLE_PYTHON=value # enable mliappy model (default is autodetect) ``` Without this setting, CMake will check whether it can find a suitable Python version and the `cythonize` command and choose the default accordingly. During the build procedure the provided .pyx file(s) will be automatically translated to C++ code and compiled. Please do **not** run `cythonize` manually in the `src/ML-IAP` folder, as that can lead to compilation errors if Python support is not enabled. If you did it by accident, please remove the generated .cpp and .h files. ::: ::: tab Traditional make The build uses the `lib/python/Makefile.mliap_python` file in the compile/link process to add a rule to update the files generated by the `cythonize` command in case the corresponding .pyx file(s) were modified. You may need to modify `lib/python/Makefile.lammps` if the LAMMPS build fails. To enable building the ML-IAP package with Python support enabled, you need to add `-DMLIAP_PYTHON` to the `LMP_INC` variable in your machine makefile. You may have to manually run the `cythonize` command on .pyx file(s) in the `src` folder, if this is not automatically done during installing the ML-IAP package. Please do **not** run `cythonize` in the `src/ML-IAP` folder, as that can lead to compilation errors if Python support is not enabled. If you did this by accident, please remove the generated .cpp and .h files. ::: ::::: ------------------------------------------------------------------------ ## MSCG package {#mscg} To build with this package, you must download and build the MS-CG library. Building the MS-CG library requires that the GSL (GNU Scientific Library) headers and libraries are installed on your machine. See the `lib/mscg/README` and `MSCG/Install` files for more details. ::::: tabs ::: tab CMake build ``` bash -D DOWNLOAD_MSCG=value # download MSCG for build, value = no (default) or yes -D MSCG_LIBRARY=path # MSCG library file (only needed if a custom location) -D MSCG_INCLUDE_DIR=path # MSCG include directory (only needed if a custom location) ``` If `DOWNLOAD_MSCG` is set, the MSCG library will be downloaded and built inside the CMake build directory. If the MSCG library is already on your system (in a location CMake cannot find it), `MSCG_LIBRARY` is the filename (plus path) of the MSCG library file, not the directory the library file is in. `MSCG_INCLUDE_DIR` is the directory the MSCG include file is in. ::: ::: tab Traditional make You can download and build the MS-CG library manually if you prefer; follow the instructions in `lib/mscg/README`. You can also do it in one step from the `lammps/src` dir, using a command like these, which simply invokes the `lib/mscg/Install.py` script with the specified args: ``` bash make lib-mscg # print help message make lib-mscg args="-b -m serial" # download and build in lib/mscg/MSCG-release-master # with the settings compatible with "make serial" make lib-mscg args="-b -m mpi" # download and build in lib/mscg/MSCG-release-master # with the settings compatible with "make mpi" make lib-mscg args="-p /usr/local/mscg-release" # use the existing MS-CG installation in /usr/local/mscg-release ``` Note that 2 symbolic (soft) links, `includelink` and `liblink`, will be created in `lib/mscg` to point to the MS-CG `src/installation` dir. When LAMMPS is built in src it will use these links. You should not need to edit the `lib/mscg/Makefile.lammps` file. ::: ::::: ------------------------------------------------------------------------ ## OPT package {#opt} ::::: tabs ::: tab CMake build No additional settings are needed besides `-D PKG_OPT=yes` ::: ::: tab Traditional make The compiler flag `-restrict` must be used to build LAMMPS with the OPT package when using Intel compilers. It should be added to the `CCFLAGS` line of your `Makefile.machine`. See `src/MAKE/OPTIONS/Makefile.opt` for an example. ::: ::::: ------------------------------------------------------------------------ ## POEMS package {#poems} ::::: tabs ::: tab CMake build No additional settings are needed besides `-D PKG_OPT=yes` ::: ::: tab Traditional make Before building LAMMPS, you must build the POEMS library in `lib/poems`. You can do this manually if you prefer; follow the instructions in `lib/poems/README`. You can also do it in one step from the `lammps/src` dir, using a command like these, which simply invokes the `lib/poems/Install.py` script with the specified args: ``` bash make lib-poems # print help message make lib-poems args="-m serial" # build with GNU g++ compiler (settings as with "make serial") make lib-poems args="-m mpi" # build with default MPI C++ compiler (settings as with "make mpi") make lib-poems args="-m icc" # build with Intel icc compiler ``` The build should produce two files: `lib/poems/libpoems.a` and `lib/poems/Makefile.lammps`. The latter is copied from an existing `Makefile.lammps.*` and has settings needed to build LAMMPS with the POEMS library (though typically the settings are just blank). If necessary, you can edit/create a new `lib/poems/Makefile.machine` file for your system, which should define an `EXTRAMAKE` variable to specify a corresponding `Makefile.lammps.machine` file. ::: ::::: ------------------------------------------------------------------------ ## PYTHON package {#python} Building with the PYTHON package requires you have a the Python development headers and library available on your system, which needs to be a Python 2.7 version or a Python 3.x version. Since support for Python 2.x has ended, using Python 3.x is strongly recommended. See `lib/python/README` for additional details. ::::: tabs ::: tab CMake build ``` bash -D PYTHON_EXECUTABLE=path # path to Python executable to use ``` Without this setting, CMake will guess the default Python version on your system. To use a different Python version, you can either create a virtualenv, activate it and then run cmake. Or you can set the PYTHON_EXECUTABLE variable to specify which Python interpreter should be used. Note note that you will also need to have the development headers installed for this version, e.g. python2-devel. ::: ::: tab Traditional make The build uses the `lib/python/Makefile.lammps` file in the compile/link process to find Python. You should only need to create a new `Makefile.lammps.*` file (and copy it to `Makefile.lammps`) if the LAMMPS build fails. ::: ::::: ------------------------------------------------------------------------ ## VORONOI package {#voronoi} To build with this package, you must download and build the [Voro++ library](https://math.lbl.gov/voro++/)\_ or install a binary package provided by your operating system. ::::: tabs ::: tab CMake build ``` bash -D DOWNLOAD_VORO=value # download Voro++ for build, value = no (default) or yes -D VORO_LIBRARY=path # Voro++ library file (only needed if at custom location) -D VORO_INCLUDE_DIR=path # Voro++ include directory (only needed if at custom location) ``` If `DOWNLOAD_VORO` is set, the Voro++ library will be downloaded and built inside the CMake build directory. If the Voro++ library is already on your system (in a location CMake cannot find it), `VORO_LIBRARY` is the filename (plus path) of the Voro++ library file, not the directory the library file is in. `VORO_INCLUDE_DIR` is the directory the Voro++ include file is in. ::: ::: tab Traditional make You can download and build the Voro++ library manually if you prefer; follow the instructions in `lib/voronoi/README`. You can also do it in one step from the `lammps/src` dir, using a command like these, which simply invokes the `lib/voronoi/Install.py` script with the specified args: ``` bash make lib-voronoi # print help message make lib-voronoi args="-b" # download and build the default version in lib/voronoi/voro++- make lib-voronoi args="-p $HOME/voro++" # use existing Voro++ installation in $HOME/voro++ make lib-voronoi args="-b -v voro++0.4.6" # download and build the 0.4.6 version in lib/voronoi/voro++-0.4.6 ``` Note that 2 symbolic (soft) links, `includelink` and `liblink`, are created in lib/voronoi to point to the Voro++ source dir. When LAMMPS builds in `src` it will use these links. You should not need to edit the `lib/voronoi/Makefile.lammps` file. ::: ::::: ------------------------------------------------------------------------ ## ADIOS package {#adios} The ADIOS package requires the [ADIOS I/O library](https://github.com/ornladios/ADIOS2)\_, version 2.3.1 or newer. Make sure that you have ADIOS built either with or without MPI to match if you build LAMMPS with or without MPI. ADIOS compilation settings for LAMMPS are automatically detected, if the PATH and LD_LIBRARY_PATH environment variables have been updated for the local ADIOS installation and the instructions below are followed for the respective build systems. ::::: tabs ::: tab CMake build ``` bash -D ADIOS2_DIR=path # path is where ADIOS 2.x is installed -D PKG_ADIOS=yes ``` ::: ::: tab Traditional make Turn on the ADIOS package before building LAMMPS. If the ADIOS 2.x software is installed in PATH, there is nothing else to do: ``` bash make yes-adios ``` otherwise, set ADIOS2_DIR environment variable when turning on the package: ``` bash ADIOS2_DIR=path make yes-adios # path is where ADIOS 2.x is installed ``` ::: ::::: ------------------------------------------------------------------------ ## ATC package {#atc} The ATC package requires the MANYBODY package also be installed. ::::: tabs ::: tab CMake build No additional settings are needed besides `-D PKG_ATC=yes` and `-D PKG_MANYBODY=yes`. ::: ::: tab Traditional make Before building LAMMPS, you must build the ATC library in `lib/atc`. You can do this manually if you prefer; follow the instructions in `lib/atc/README`. You can also do it in one step from the `lammps/src` dir, using a command like these, which simply invokes the `lib/atc/Install.py` script with the specified args: ``` bash make lib-atc # print help message make lib-atc args="-m serial" # build with GNU g++ compiler and MPI STUBS (settings as with "make serial") make lib-atc args="-m mpi" # build with default MPI compiler (settings as with "make mpi") make lib-atc args="-m icc" # build with Intel icc compiler ``` The build should produce two files: `lib/atc/libatc.a` and `lib/atc/Makefile.lammps`. The latter is copied from an existing `Makefile.lammps.*` and has settings needed to build LAMMPS with the ATC library. If necessary, you can edit/create a new `lib/atc/Makefile.machine` file for your system, which should define an `EXTRAMAKE` variable to specify a corresponding `Makefile.lammps.` file. Note that the Makefile.lammps file has settings for the BLAS and LAPACK linear algebra libraries. As explained in `lib/atc/README` these can either exist on your system, or you can use the files provided in `lib/linalg`. In the latter case you also need to build the library in `lib/linalg` with a command like these: ``` bash make lib-linalg # print help message make lib-linalg args="-m serial" # build with GNU C++ compiler (settings as with "make serial") make lib-linalg args="-m mpi" # build with default MPI C++ compiler (settings as with "make mpi") make lib-linalg args="-m g++" # build with GNU Fortran compiler ``` ::: ::::: ------------------------------------------------------------------------ ## AWPMD package {#awpmd} ::::: tabs ::: tab CMake build No additional settings are needed besides `-D PKG_AQPMD=yes`. ::: ::: tab Traditional make Before building LAMMPS, you must build the AWPMD library in `lib/awpmd`. You can do this manually if you prefer; follow the instructions in `lib/awpmd/README`. You can also do it in one step from the `lammps/src` dir, using a command like these, which simply invokes the `lib/awpmd/Install.py` script with the specified args: ``` bash make lib-awpmd # print help message make lib-awpmd args="-m serial" # build with GNU g++ compiler and MPI STUBS (settings as with "make serial") make lib-awpmd args="-m mpi" # build with default MPI compiler (settings as with "make mpi") make lib-awpmd args="-m icc" # build with Intel icc compiler ``` The build should produce two files: `lib/awpmd/libawpmd.a` and `lib/awpmd/Makefile.lammps`. The latter is copied from an existing `Makefile.lammps.*` and has settings needed to build LAMMPS with the AWPMD library. If necessary, you can edit/create a new `lib/awpmd/Makefile.machine` file for your system, which should define an `EXTRAMAKE` variable to specify a corresponding `Makefile.lammps.` file. Note that the `Makefile.lammps` file has settings for the BLAS and LAPACK linear algebra libraries. As explained in `lib/awpmd/README` these can either exist on your system, or you can use the files provided in `lib/linalg`. In the latter case you also need to build the library in `lib/linalg` with a command like these: ``` bash make lib-linalg # print help message make lib-linalg args="-m serial" # build with GNU C++ compiler (settings as with "make serial") make lib-linalg args="-m mpi" # build with default MPI C++ compiler (settings as with "make mpi") make lib-linalg args="-m g++" # build with GNU C++ compiler ``` ::: ::::: ------------------------------------------------------------------------ ## COLVARS package {#colvar} This package enables the use of the [Colvars](https://colvars.github.io/)\_ module included in the LAMMPS source distribution. :::::: tabs ::: tab CMake build This is the recommended build procedure for using Colvars in LAMMPS. No additional settings are normally needed besides `-D PKG_COLVARS=yes`. ::: :::: tab Traditional make As with other libraries distributed with LAMMPS, the Colvars library needs to be built before building the LAMMPS program with the COLVARS package enabled. From the LAMMPS `src` directory, this is most easily and safely done via one of the following commands, which implicitly rely on the `lib/colvars/Install.py` script with optional arguments: ``` bash make lib-colvars # print help message make lib-colvars args="-m serial" # build with GNU g++ compiler (settings as with "make serial") make lib-colvars args="-m mpi" # build with default MPI compiler (settings as with "make mpi") make lib-colvars args="-m g++-debug" # build with GNU g++ compiler and colvars debugging enabled ``` The \"machine\" argument of the \"-m\" flag is used to find a `Makefile.machine` file to use as build recipe. If such recipe does not already exist in `lib/colvars`, suitable settings will be auto-generated consistent with those used in the core LAMMPS makefiles. ::: versionchanged 8Feb2023 ::: Please note that Colvars uses the Lepton library, which is now included with the LEPTON package; if you use anything other than the `make lib-colvars` command, please make sure to [build Lepton beforehand](lepton). Optional flags may be specified as environment variables: ``` bash COLVARS_DEBUG=yes make lib-colvars args="-m machine" # Build with debug code (much slower) COLVARS_LEPTON=no make lib-colvars args="-m machine" # Build without Lepton (included otherwise) ``` The build should produce two files: the library `lib/colvars/libcolvars.a` and the specification file `lib/colvars/Makefile.lammps`. The latter is auto-generated, and normally does not need to be edited. :::: :::::: ------------------------------------------------------------------------ ## ELECTRODE package {#electrode} This package depends on the KSPACE package. ::::: tabs ::: tab CMake build ``` bash -D PKG_ELECTRODE=yes # enable the package itself -D PKG_KSPACE=yes # the ELECTRODE package requires KSPACE -D USE_INTERNAL_LINALG=value # ``` Features in the ELECTRODE package are dependent on code in the KSPACE package so the latter one *must* be enabled. The ELECTRODE package also requires LAPACK (and BLAS) and CMake can identify their locations and pass that info to the ELECTRODE build script. But on some systems this may cause problems when linking or the dependency is not desired. Try enabling `USE_INTERNAL_LINALG` in those cases to use the bundled linear algebra library and work around the limitation. ::: ::: tab Traditional make Before building LAMMPS, you must configure the ELECTRODE support libraries and settings in `lib/electrode`. You can do this manually, if you prefer, or do it in one step from the `lammps/src` dir, using a command like these, which simply invokes the `lib/electrode/Install.py` script with the specified args: ``` bash make lib-electrode # print help message make lib-electrode args="-m serial" # build with GNU g++ compiler and MPI STUBS (settings as with "make serial") make lib-electrode args="-m mpi" # build with default MPI compiler (settings as with "make mpi") ``` Note that the `Makefile.lammps` file has settings for the BLAS and LAPACK linear algebra libraries. These can either exist on your system, or you can use the files provided in `lib/linalg`. In the latter case you also need to build the library in `lib/linalg` with a command like these: ``` bash make lib-linalg # print help message make lib-linalg args="-m serial" # build with GNU C++ compiler (settings as with "make serial") make lib-linalg args="-m mpi" # build with default MPI C++ compiler (settings as with "make mpi") make lib-linalg args="-m g++" # build with GNU C++ compiler ``` The package itself is activated with `make yes-KSPACE` and `make yes-ELECTRODE` ::: ::::: ------------------------------------------------------------------------ ## ML-PACE package {#ml-pace} This package requires a library that can be downloaded and built in lib/pace or somewhere else, which must be done before building LAMMPS with this package. The code for the library can be found at: \_ ::::: tabs ::: tab CMake build By default the library will be downloaded from the git repository and built automatically when the ML-PACE package is enabled with `-D PKG_ML-PACE=yes`. The location for the sources may be customized by setting the variable `PACELIB_URL` when configuring with CMake (e.g. to use a local archive on machines without internet access). Since CMake checks the validity of the archive with `md5sum` you may also need to set `PACELIB_MD5` if you provide a different library version than what is downloaded automatically. ::: ::: tab Traditional make You can download and build the ML-PACE library in one step from the `lammps/src` dir, using these commands, which invoke the `lib/pace/Install.py` script. ``` bash make lib-pace # print help message make lib-pace args="-b" # download and build the default version in lib/pace ``` You should not need to edit the `lib/pace/Makefile.lammps` file. ::: ::::: ------------------------------------------------------------------------ ## ML-POD package {#ml-pod} ::::: tabs ::: tab CMake build No additional settings are needed besides `-D PKG_ML-POD=yes`. ::: ::: tab Traditional make Before building LAMMPS, you must configure the ML-POD support settings in `lib/mlpod`. You can do this manually, if you prefer, or do it in one step from the `lammps/src` dir, using a command like the following, which simply invoke the `lib/mlpod/Install.py` script with the specified args: ``` bash make lib-mlpod # print help message make lib-mlpod args="-m serial" # build with GNU g++ compiler and MPI STUBS (settings as with "make serial") make lib-mlpod args="-m mpi" # build with default MPI compiler (settings as with "make mpi") make lib-mlpod args="-m mpi -e linalg" # same as above but use the bundled linalg lib ``` Note that the `Makefile.lammps` file has settings to use the BLAS and LAPACK linear algebra libraries. These can either exist on your system, or you can use the files provided in `lib/linalg`. In the latter case you also need to build the library in `lib/linalg` with a command like these: ``` bash make lib-linalg # print help message make lib-linalg args="-m serial" # build with GNU C++ compiler (settings as with "make serial") make lib-linalg args="-m mpi" # build with default MPI C++ compiler (settings as with "make mpi") make lib-linalg args="-m g++" # build with GNU C++ compiler ``` The package itself is activated with `make yes-ML-POD`. ::: ::::: ------------------------------------------------------------------------ ## PLUMED package {#plumed} Before building LAMMPS with this package, you must first build PLUMED. PLUMED can be built as part of the LAMMPS build or installed separately from LAMMPS using the generic [PLUMED installation instructions](https://plumed.github.io/doc-master/user-doc/html/_installation.html)\_. The PLUMED package has been tested to work with Plumed versions 2.4.x, 2.5.x, and 2.6.x and will error out, when trying to run calculations with a different version of the Plumed kernel. PLUMED can be linked into MD codes in three different modes: static, shared, and runtime. With the \"static\" mode, all the code that PLUMED requires is linked statically into LAMMPS. LAMMPS is then fully independent from the PLUMED installation, but you have to rebuild/relink it in order to update the PLUMED code inside it. With the \"shared\" linkage mode, LAMMPS is linked to a shared library that contains the PLUMED code. This library should preferably be installed in a globally accessible location. When PLUMED is linked in this way the same library can be used by multiple MD packages. Furthermore, the PLUMED library LAMMPS uses can be updated without the need for a recompile of LAMMPS for as long as the shared PLUMED library is ABI-compatible. The third linkage mode is \"runtime\" which allows the user to specify which PLUMED kernel should be used at runtime by using the PLUMED_KERNEL environment variable. This variable should point to the location of the libplumedKernel.so dynamical shared object, which is then loaded at runtime. This mode of linking is particularly convenient for doing PLUMED development and comparing multiple PLUMED versions as these sorts of comparisons can be done without recompiling the hosting MD code. All three linkage modes are supported by LAMMPS on selected operating systems (e.g. Linux) and using either CMake or traditional make build. The \"static\" mode should be the most portable, while the \"runtime\" mode support in LAMMPS makes the most assumptions about operating system and compiler environment. If one mode does not work, try a different one, switch to a different build system, consider a global PLUMED installation or consider downloading PLUMED during the LAMMPS build. ::::: tabs ::: tab CMake build When the `-D PKG_PLUMED=yes` flag is included in the cmake command you must ensure that GSL is installed in locations that are specified in your environment. There are then two additional variables that control the manner in which PLUMED is obtained and linked into LAMMPS. ``` bash -D DOWNLOAD_PLUMED=value # download PLUMED for build, value = no (default) or yes -D PLUMED_MODE=value # Linkage mode for PLUMED, value = static (default), shared, or runtime ``` If DOWNLOAD_PLUMED is set to \"yes\", the PLUMED library will be downloaded (the version of PLUMED that will be downloaded is hard-coded to a vetted version of PLUMED, usually a recent stable release version) and built inside the CMake build directory. If `DOWNLOAD_PLUMED` is set to \"no\" (the default), CMake will try to detect and link to an installed version of PLUMED. For this to work, the PLUMED library has to be installed into a location where the `pkg-config` tool can find it or the PKG_CONFIG_PATH environment variable has to be set up accordingly. PLUMED should be installed in such a location if you compile it using the default make; make install commands. The `PLUMED_MODE` setting determines the linkage mode for the PLUMED library. The allowed values for this flag are \"static\" (default), \"shared\", or \"runtime\". If you want to switch the linkage mode, just re-run CMake with a different setting. For a discussion of PLUMED linkage modes, please see above. When `DOWNLOAD_PLUMED` is enabled the static linkage mode is recommended. ::: ::: tab Traditional make PLUMED needs to be installed before the PLUMED package is installed so that LAMMPS can find the right settings when compiling and linking the LAMMPS executable. You can either download and build PLUMED inside the LAMMPS plumed library folder or use a previously installed PLUMED library and point LAMMPS to its location. You also have to choose the linkage mode: \"static\" (default), \"shared\" or \"runtime\". For a discussion of PLUMED linkage modes, please see above. Download/compilation/configuration of the plumed library can be done from the src folder through the following make args: ``` bash make lib-plumed # print help message make lib-plumed args="-b" # download and build PLUMED in lib/plumed/plumed2 make lib-plumed args="-p $HOME/.local" # use existing PLUMED installation in $HOME/.local make lib-plumed args="-p /usr/local -m shared" # use existing PLUMED installation in # /usr/local and use shared linkage mode ``` Note that 2 symbolic (soft) links, `includelink` and `liblink` are created in lib/plumed that point to the location of the PLUMED build to use. A new file `lib/plumed/Makefile.lammps` is also created with settings suitable for LAMMPS to compile and link PLUMED using the desired linkage mode. After this step is completed, you can install the PLUMED package and compile LAMMPS in the usual manner: ``` bash make yes-plumed make machine ``` Once this compilation completes you should be able to run LAMMPS in the usual way. For shared linkage mode, libplumed.so must be found by the LAMMPS executable, which on many operating systems means, you have to set the LD_LIBRARY_PATH environment variable accordingly. Support for the different linkage modes in LAMMPS varies for different operating systems, using the static linkage is expected to be the most portable, and thus set to be the default. If you want to change the linkage mode, you have to re-run \"make lib-plumed\" with the desired settings **and** do a re-install if the PLUMED package with \"make yes-plumed\" to update the required makefile settings with the changes in the lib/plumed folder. ::: ::::: ------------------------------------------------------------------------ ## H5MD package {#h5md} To build with this package you must have the HDF5 software package installed on your system, which should include the h5cc compiler and the HDF5 library. ::::: tabs ::: tab CMake build No additional settings are needed besides `-D PKG_H5MD=yes`. This should auto-detect the H5MD library on your system. Several advanced CMake H5MD options exist if you need to specify where it is installed. Use the ccmake (terminal window) or cmake-gui (graphical) tools to see these options and set them interactively from their user interfaces. ::: ::: tab Traditional make Before building LAMMPS, you must build the CH5MD library in `lib/h5md`. You can do this manually if you prefer; follow the instructions in `lib/h5md/README`. You can also do it in one step from the `lammps/src` dir, using a command like these, which simply invokes the `lib/h5md/Install.py` script with the specified args: ``` bash make lib-h5md # print help message make lib-h5md args="-m h5cc" # build with h5cc compiler ``` The build should produce two files: `lib/h5md/libch5md.a` and `lib/h5md/Makefile.lammps`. The latter is copied from an existing `Makefile.lammps.*` and has settings needed to build LAMMPS with the system HDF5 library. If necessary, you can edit/create a new `lib/h5md/Makefile.machine` file for your system, which should define an EXTRAMAKE variable to specify a corresponding `Makefile.lammps.` file. ::: ::::: ------------------------------------------------------------------------ ## ML-HDNNP package {#ml-hdnnp} To build with the ML-HDNNP package it is required to download and build the external [n2p2](https://github.com/CompPhysVienna/n2p2)\_ library `v2.1.4` (or higher). The LAMMPS build process offers an automatic download and compilation of *n2p2* or allows you to choose the installation directory of *n2p2* manually. Please see the boxes below for the CMake and traditional build system for detailed information. In case of a manual installation of *n2p2* you only need to build the *n2p2* core library `libnnp` and interface library `libnnpif`. When using GCC it should suffice to execute `make libnnpif` in the *n2p2* `src` directory. For more details please see `lib/hdnnp/README` and the [n2p2 build documentation](https://compphysvienna.github.io/n2p2/topics/build.html)\_. ::::: tabs ::: tab CMake build ``` bash -D DOWNLOAD_N2P2=value # download n2p2 for build, value = no (default) or yes -D N2P2_DIR=path # n2p2 base directory (only needed if a custom location) ``` If `DOWNLOAD_N2P2` is set, the *n2p2* library will be downloaded and built inside the CMake build directory. If the *n2p2* library is already on your system (in a location CMake cannot find it), set the `N2P2_DIR` to path where *n2p2* is located. If *n2p2* is located directly in `lib/hdnnp/n2p2` it will be automatically found by CMake. ::: ::: tab Traditional make You can download and build the *n2p2* library manually if you prefer; follow the instructions in `lib/hdnnp/README`. You can also do it in one step from the `lammps/src` dir, using a command like these, which simply invokes the `lib/hdnnp/Install.py` script with the specified args: ``` bash make lib-hdnnp # print help message make lib-hdnnp args="-b" # download and build in lib/hdnnp/n2p2-... make lib-hdnnp args="-b -v 2.1.4" # download and build specific version make lib-hdnnp args="-p /usr/local/n2p2" # use the existing n2p2 installation in /usr/local/n2p2 ``` Note that 3 symbolic (soft) links, `includelink`, `liblink` and `Makefile.lammps`, will be created in `lib/hdnnp` to point to `n2p2/include`, `n2p2/lib` and `n2p2/lib/Makefile.lammps-extra`, respectively. When LAMMPS is built in `src` it will use these links. ::: ::::: ------------------------------------------------------------------------ ## INTEL package {#intel} To build with this package, you must choose which hardware you want to build for, either x86 CPUs or Intel KNLs in offload mode. You should also typically [install the OPENMP package](openmp), as it can be used in tandem with the INTEL package to good effect, as explained on the [Speed_intel]{.title-ref} page. When using Intel compilers version 16.0 or later is required. You can also use the GNU or Clang compilers and they will provide performance improvements over regular styles and OPENMP styles, but less so than with the Intel compilers. Please also note, that some compilers have been found to apply memory alignment constraints incompletely or incorrectly and thus can cause segmentation faults in otherwise correct code when using features from the INTEL package. ::::: tabs ::: tab CMake build ``` bash -D INTEL_ARCH=value # value = cpu (default) or knl -D INTEL_LRT_MODE=value # value = threads, none, or c++11 ``` ::: ::: tab Traditional make Choose which hardware to compile for in Makefile.machine via the following settings. See `src/MAKE/OPTIONS/Makefile.intel_cpu*` and `Makefile.knl` files for examples. and `src/INTEL/README` for additional information. For CPUs: ``` make OPTFLAGS = -xHost -O2 -fp-model fast=2 -no-prec-div -qoverride-limits -qopt-zmm-usage=high CCFLAGS = -g -qopenmp -DLAMMPS_MEMALIGN=64 -no-offload -fno-alias -ansi-alias -restrict $(OPTFLAGS) LINKFLAGS = -g -qopenmp $(OPTFLAGS) LIB = -ltbbmalloc ``` For KNLs: ``` make OPTFLAGS = -xMIC-AVX512 -O2 -fp-model fast=2 -no-prec-div -qoverride-limits CCFLAGS = -g -qopenmp -DLAMMPS_MEMALIGN=64 -no-offload -fno-alias -ansi-alias -restrict $(OPTFLAGS) LINKFLAGS = -g -qopenmp $(OPTFLAGS) LIB = -ltbbmalloc ``` ::: ::::: In Long-range thread mode (LRT) a modified verlet style is used, that operates the Kspace calculation in a separate thread concurrently to other calculations. This has to be enabled in the [package intel](package) command at runtime. With the setting \"threads\" it used the pthreads library, while \"c++11\" will use the built-in thread support of C++11 compilers. The option \"none\" skips compilation of this feature. The default is to use \"threads\" if pthreads is available and otherwise \"none\". Best performance is achieved with Intel hardware, Intel compilers, as well as the Intel TBB and MKL libraries. However, the code also compiles, links, and runs with other compilers / hardware and without TBB and MKL. ------------------------------------------------------------------------ ## MDI package {#mdi} ::::: tabs ::: tab CMake build ``` bash -D DOWNLOAD_MDI=value # download MDI Library for build, value = no (default) or yes ``` ::: ::: tab Traditional make Before building LAMMPS, you must build the MDI Library in `lib/mdi`. You can do this by executing a command like one of the following from the `lib/mdi` directory: ``` bash python Install.py -m gcc # build using gcc compiler python Install.py -m icc # build using icc compiler ``` The build should produce two files: `lib/mdi/includelink/mdi.h` and `lib/mdi/liblink/libmdi.so`. ::: ::::: ------------------------------------------------------------------------ ## MOLFILE package {#molfile} ::::: tabs ::: tab CMake build ``` bash -D MOLFILE_INCLUDE_DIR=path # (optional) path where VMD molfile plugin headers are installed -D PKG_MOLFILE=yes ``` Using `-D PKG_MOLFILE=yes` enables the package, and setting `-D MOLFILE_INCLUDE_DIR` allows to provide a custom location for the molfile plugin header files. These should match the ABI of the plugin files used, and thus one typically sets them to include folder of the local VMD installation in use. LAMMPS ships with a couple of default header files that correspond to a popular VMD version, usually the latest release. ::: ::: tab Traditional make The `lib/molfile/Makefile.lammps` file has a setting for a dynamic loading library libdl.a that is typically present on all systems. It is required for LAMMPS to link with this package. If the setting is not valid for your system, you will need to edit the Makefile.lammps file. See `lib/molfile/README` and `lib/molfile/Makefile.lammps` for details. It is also possible to configure a different folder with the VMD molfile plugin header files. LAMMPS ships with a couple of default headers, but these are not compatible with all VMD versions, so it is often best to change this setting to the location of the same include files of the local VMD installation in use. ::: ::::: ------------------------------------------------------------------------ ## NETCDF package {#netcdf} To build with this package you must have the NetCDF library installed on your system. ::::: tabs ::: tab CMake build No additional settings are needed besides `-D PKG_NETCDF=yes`. This should auto-detect the NETCDF library if it is installed on your system at standard locations. Several advanced CMake NETCDF options exist if you need to specify where it was installed. Use the `ccmake` (terminal window) or `cmake-gui` (graphical) tools to see these options and set them interactively from their user interfaces. ::: ::: tab Traditional make The `lib/netcdf/Makefile.lammps` file has settings for NetCDF include and library files which LAMMPS needs to build with this package. If the settings are not valid for your system, you will need to edit the `Makefile.lammps` file. See `lib/netcdf/README` for details. ::: ::::: ------------------------------------------------------------------------ ## OPENMP package {#openmp} ::::: tabs ::: tab CMake build No additional settings are required besides `-D PKG_OPENMP=yes`. If CMake detects OpenMP compiler support, the OPENMP code will be compiled with multi-threading support enabled, otherwise as optimized serial code. ::: ::: tab Traditional make To enable multi-threading support in the OPENMP package (and other styles supporting OpenMP) the following compile and link flags must be added to your Makefile.machine file. See `src/MAKE/OPTIONS/Makefile.omp` for an example. CCFLAGS: -fopenmp # for GNU and Clang Compilers CCFLAGS: -qopenmp -restrict # for Intel compilers on Linux LINKFLAGS: -fopenmp # for GNU and Clang Compilers LINKFLAGS: -qopenmp # for Intel compilers on Linux For other platforms and compilers, please consult the documentation about OpenMP support for your compiler. ::: ::::: ::: {.admonition .note} Adding OpenMP support on macOS Apple offers the [Xcode package and IDE](https://developer.apple.com/xcode/)\_ for compiling software on macOS, so you have likely installed it to compile LAMMPS. Their compiler is based on [Clang](https://clang.llvm.org/)\_, but while it is capable of processing OpenMP directives, the necessary header files and OpenMP runtime library are missing. The [R developers](https://www.r-project.org/)\_ have figured out a way to build those in a compatible fashion. One can download them from \_. Simply adding those files as instructed enables the Xcode C++ compiler to compile LAMMPS with `-D BUILD_OMP=yes`. ::: ------------------------------------------------------------------------ ## QMMM package {#qmmm} For using LAMMPS to do QM/MM simulations via the QMMM package you need to build LAMMPS as a library. A LAMMPS executable with [fix qmmm](fix_qmmm) included can be built, but will not be able to do a QM/MM simulation on as such. You must also build a QM code - currently only Quantum ESPRESSO (QE) is supported - and create a new executable which links LAMMPS and the QM code together. Details are given in the `lib/qmmm/README` file. It is also recommended to read the instructions for [linking with LAMMPS as a library](Build_link) for background information. This requires compatible Quantum Espresso and LAMMPS versions. The current interface and makefiles have last been verified to work in February 2020 with Quantum Espresso versions 6.3 to 6.5. ::::: tabs ::: tab CMake build When using CMake, building a LAMMPS library is required and it is recommended to build a shared library, since any libraries built from the sources in the *lib* folder (including the essential libqmmm.a) are not included in the static LAMMPS library and (currently) not installed, while their code is included in the shared LAMMPS library. Thus a typical command line to configure building LAMMPS for QMMM would be: ``` bash cmake -C ../cmake/presets/basic.cmake -D PKG_QMMM=yes \ -D BUILD_LIB=yes -DBUILD_SHARED_LIBS=yes ../cmake ``` After completing the LAMMPS build and also configuring and compiling Quantum ESPRESSO with external library support (via \"make couple\"), go back to the `lib/qmmm` folder and follow the instructions on the README file to build the combined LAMMPS/QE QM/MM executable (pwqmmm.x) in the `lib/qmmm` folder. ::: ::: tab Traditional make Before building LAMMPS, you must build the QMMM library in `lib/qmmm`. You can do this manually if you prefer; follow the first two steps explained in `lib/qmmm/README`. You can also do it in one step from the `lammps/src` dir, using a command like these, which simply invokes the `lib/qmmm/Install.py` script with the specified args: ``` bash make lib-qmmm # print help message make lib-qmmm args="-m serial" # build with GNU Fortran compiler (settings as in "make serial") make lib-qmmm args="-m mpi" # build with default MPI compiler (settings as in "make mpi") make lib-qmmm args="-m gfortran" # build with GNU Fortran compiler ``` The build should produce two files: `lib/qmmm/libqmmm.a` and `lib/qmmm/Makefile.lammps`. The latter is copied from an existing `Makefile.lammps.*` and has settings needed to build LAMMPS with the QMMM library (though typically the settings are just blank). If necessary, you can edit/create a new `lib/qmmm/Makefile.` file for your system, which should define an `EXTRAMAKE` variable to specify a corresponding `Makefile.lammps.` file. You can then install QMMM package and build LAMMPS in the usual manner. After completing the LAMMPS build and compiling Quantum ESPRESSO with external library support (via \"make couple\"), go back to the `lib/qmmm` folder and follow the instructions in the README file to build the combined LAMMPS/QE QM/MM executable (pwqmmm.x) in the lib/qmmm folder. ::: ::::: ------------------------------------------------------------------------ ## ML-QUIP package {#ml-quip} To build with this package, you must download and build the QUIP library. It can be obtained from GitHub. For support of GAP potentials, additional files with specific licensing conditions need to be downloaded and configured. The automatic download will from within CMake will download the non-commercial use version. ::::: tabs ::: tab CMake build ``` bash -D DOWNLOAD_QUIP=value # download QUIP library for build, value = no (default) or yes -D QUIP_LIBRARY=path # path to libquip.a (only needed if a custom location) -D USE_INTERNAL_LINALG=value # Use the internal linear algebra library instead of LAPACK # value = no (default) or yes ``` CMake will try to download and build the QUIP library from GitHub, if it is not found on the local machine. This requires to have git installed. It will use the same compilers and flags as used for compiling LAMMPS. Currently this is only supported for the GNU and the Intel compilers. Set the `QUIP_LIBRARY` variable if you want to use a previously compiled and installed QUIP library and CMake cannot find it. The QUIP library requires LAPACK (and BLAS) and CMake can identify their locations and pass that info to the QUIP build script. But on some systems this triggers a (current) limitation of CMake and the configuration will fail. Try enabling `USE_INTERNAL_LINALG` in those cases to use the bundled linear algebra library and work around the limitation. ::: ::: tab Traditional make The download/build procedure for the QUIP library, described in `lib/quip/README` file requires setting two environment variables, `QUIP_ROOT` and `QUIP_ARCH`. These are accessed by the `lib/quip/Makefile.lammps` file which is used when you compile and link LAMMPS with this package. You should only need to edit `Makefile.lammps` if the LAMMPS build can not use its settings to successfully build on your system. ::: ::::: ------------------------------------------------------------------------ ## SCAFACOS package {#scafacos} To build with this package, you must download and build the [ScaFaCoS Coulomb solver library](http://www.scafacos.de)\_ ::::: tabs ::: tab CMake build ``` bash -D DOWNLOAD_SCAFACOS=value # download ScaFaCoS for build, value = no (default) or yes -D SCAFACOS_LIBRARY=path # ScaFaCos library file (only needed if at custom location) -D SCAFACOS_INCLUDE_DIR=path # ScaFaCoS include directory (only needed if at custom location) ``` If `DOWNLOAD_SCAFACOS` is set, the ScaFaCoS library will be downloaded and built inside the CMake build directory. If the ScaFaCoS library is already on your system (in a location CMake cannot find it), `SCAFACOS_LIBRARY` is the filename (plus path) of the ScaFaCoS library file, not the directory the library file is in. `SCAFACOS_INCLUDE_DIR` is the directory the ScaFaCoS include file is in. ::: ::: tab Traditional make You can download and build the ScaFaCoS library manually if you prefer; follow the instructions in `lib/scafacos/README`. You can also do it in one step from the `lammps/src` dir, using a command like these, which simply invokes the `lib/scafacos/Install.py` script with the specified args: ``` bash make lib-scafacos # print help message make lib-scafacos args="-b" # download and build in lib/scafacos/scafacos- make lib-scafacos args="-p $HOME/scafacos # use existing ScaFaCoS installation in $HOME/scafacos ``` Note that 2 symbolic (soft) links, `includelink` and `liblink`, are created in `lib/scafacos` to point to the ScaFaCoS src dir. When LAMMPS builds in src it will use these links. You should not need to edit the `lib/scafacos/Makefile.lammps` file. ::: ::::: ------------------------------------------------------------------------ ## MACHDYN package {#machdyn} To build with this package, you must download the Eigen3 library. Eigen3 is a template library, so you do not need to build it. ::::: tabs ::: tab CMake build ``` bash -D DOWNLOAD_EIGEN3 # download Eigen3, value = no (default) or yes -D EIGEN3_INCLUDE_DIR=path # path to Eigen library (only needed if a custom location) ``` If `DOWNLOAD_EIGEN3` is set, the Eigen3 library will be downloaded and inside the CMake build directory. If the Eigen3 library is already on your system (in a location where CMake cannot find it), set `EIGEN3_INCLUDE_DIR` to the directory the `Eigen3` include file is in. ::: ::: tab Traditional make You can download the Eigen3 library manually if you prefer; follow the instructions in `lib/smd/README`. You can also do it in one step from the `lammps/src` dir, using a command like these, which simply invokes the `lib/smd/Install.py` script with the specified args: ``` bash make lib-smd # print help message make lib-smd args="-b" # download to lib/smd/eigen3 make lib-smd args="-p /usr/include/eigen3" # use existing Eigen installation in /usr/include/eigen3 ``` Note that a symbolic (soft) link named `includelink` is created in `lib/smd` to point to the Eigen dir. When LAMMPS builds it will use this link. You should not need to edit the `lib/smd/Makefile.lammps` file. ::: ::::: ------------------------------------------------------------------------ ## VTK package {#vtk} To build with this package you must have the VTK library installed on your system. ::::: tabs ::: tab CMake build No additional settings are needed besides `-D PKG_VTK=yes`. This should auto-detect the VTK library if it is installed on your system at standard locations. Several advanced VTK options exist if you need to specify where it was installed. Use the `ccmake` (terminal window) or `cmake-gui` (graphical) tools to see these options and set them interactively from their user interfaces. ::: ::: tab Traditional make The `lib/vtk/Makefile.lammps` file has settings for accessing VTK files and its library, which LAMMPS needs to build with this package. If the settings are not valid for your system, check if one of the other `lib/vtk/Makefile.lammps.*` files is compatible and copy it to Makefile.lammps. If none of the provided files work, you will need to edit the `Makefile.lammps` file. See `lib/vtk/README` for details. ::: :::::