Merge pull request #4 from cosmo-sims/master

merge from master

.github/workflows/cmake-multi-platform.yml

@@ -0,0 +1,78 @@
+# This starter workflow is for a CMake project running on multiple platforms. There is a different starter workflow if you just want a single platform.
+# See: https://github.com/actions/starter-workflows/blob/main/ci/cmake-single-platform.yml
+name: CMake on multiple platforms
+
+on:
+  push:
+    branches: [ "master" ]
+  pull_request:
+    branches: [ "master" ]
+
+jobs:
+  build:
+    runs-on: ${{ matrix.os }}
+
+    strategy:
+      # Set fail-fast to false to ensure that feedback is delivered for all matrix combinations. Consider changing this to true when your workflow is stable.
+      fail-fast: false
+
+      # Set up a matrix to run the following 3 configurations:
+      # 1. <Windows, Release, latest MSVC compiler toolchain on the default runner image, default generator>
+      # 2. <Linux, Release, latest GCC compiler toolchain on the default runner image, default generator>
+      # 3. <Linux, Release, latest Clang compiler toolchain on the default runner image, default generator>
+      #
+      # To add more build types (Release, Debug, RelWithDebInfo, etc.) customize the build_type list.
+      matrix:
+        os: [ubuntu-latest]
+        build_type: [Release]
+        c_compiler: [gcc]
+        include:
+          - os: ubuntu-latest
+            c_compiler: gcc
+            cpp_compiler: g++
+
+    steps:
+    - uses: actions/checkout@v4
+
+    - name: Set reusable strings
+      # Turn repeated input strings (such as the build output directory) into step outputs. These step outputs can be used throughout the workflow file.
+      id: strings
+      shell: bash
+      run: |
+        echo "build-output-dir=${{ github.workspace }}/build" >> "$GITHUB_OUTPUT"
+
+    - name: Install prerequisite libraries
+      # Install 3rd party libraries
+      run: |
+        sudo apt-get update -qq
+        sudo apt-get install gcc g++ gfortran -qq -y
+        gcc --version
+        #  Install a CMake 3.0.2 version.
+        sudo apt-get install git cmake pkg-config cmake-data -y --force-yes
+        # Print the CMake version.
+        cmake --version   
+        # Install the necessary libraries
+        sudo apt-get install libfftw3-mpi-dev libfftw3-dev -y
+        sudo apt-get install libgsl-dev -y
+        sudo apt-get install libhdf5-serial-dev -y
+        sudo apt-get install openmpi-bin libopenmpi-dev -y
+
+    - name: Configure CMake
+      # Configure CMake in a 'build' subdirectory. `CMAKE_BUILD_TYPE` is only required if you are using a single-configuration generator such as make.
+      # See https://cmake.org/cmake/help/latest/variable/CMAKE_BUILD_TYPE.html?highlight=cmake_build_type
+      run: >
+        cmake -B ${{ steps.strings.outputs.build-output-dir }}
+        -DCMAKE_CXX_COMPILER=${{ matrix.cpp_compiler }}
+        -DCMAKE_C_COMPILER=${{ matrix.c_compiler }}
+        -DCMAKE_BUILD_TYPE=${{ matrix.build_type }}
+        -S ${{ github.workspace }}
+
+    - name: Build
+      # Build your program with the given configuration. Note that --config is needed because the default Windows generator is a multi-config generator (Visual Studio generator).
+      run: cmake --build ${{ steps.strings.outputs.build-output-dir }} --config ${{ matrix.build_type }}
+
+    - name: Test
+      working-directory: ${{ steps.strings.outputs.build-output-dir }}
+      # Execute tests defined by the CMake configuration. Note that --build-config is needed because the default Windows generator is a multi-config generator (Visual Studio generator).
+      # See https://cmake.org/cmake/help/latest/manual/ctest.1.html for more detail
+      run: ctest --build-config ${{ matrix.build_type }}

CITATION.bib

@@ -0,0 +1,27 @@
+@article{MONOFONIC:3LPT,
+    author = {Michaux, Micha\"el and Hahn, Oliver and Rampf, Cornelius and Angulo, Raul E.},
+    title = "{Accurate initial conditions for cosmological N-body simulations: Minimizing truncation and discreteness errors}",
+    eprint = "2008.09588",
+    archivePrefix = "arXiv",
+    primaryClass = "astro-ph.CO",
+    doi = "10.1093/mnras/staa3149",
+    journal = "Mon. Not. Roy. Astron. Soc.",
+    volume = "500",
+    number = "1",
+    pages = "663--683",
+    year = "2020"
+}
+
+@article{MONOFONIC:BARYONS,
+    author = "Hahn, Oliver and Rampf, Cornelius and Uhlemann, Cora",
+    title = "{Higher order initial conditions for mixed baryon\textendash{}CDM simulations}",
+    eprint = "2008.09124",
+    archivePrefix = "arXiv",
+    primaryClass = "astro-ph.CO",
+    doi = "10.1093/mnras/staa3773",
+    journal = "Mon. Not. Roy. Astron. Soc.",
+    volume = "503",
+    number = "1",
+    pages = "426--445",
+    year = "2021"
+}

README.md

@@ -1,3 +1,5 @@
+[![CMake on multiple platforms](https://github.com/cosmo-sims/monofonIC/actions/workflows/cmake-multi-platform.yml/badge.svg)](https://github.com/cosmo-sims/monofonIC/actions/workflows/cmake-multi-platform.yml)
+
 # MUSIC2 - monofonIC
 Modular high-precision IC generator for cosmological simulations. MUSIC2-monofonIC is for non-zoom full box ICs (use [MUSIC](https://bitbucket.org/ohahn/music) for zooms, MUSIC2 for zooms is in the works).
 
@@ -51,6 +53,7 @@ If you use MUSIC2-monofonIC in your scientific work, you are required to acknowl
 
 - For baryon+CDM sims, or PPT numerics related aspects: Hahn et al. 2020 [arXiv:2008.09124](https://arxiv.org/abs/2008.09124)
 
+You can find the respective BibTeX entries in the enclosed CITATION.bib file.
 
 ## Acknowledgments