This repository facilitates parallel development between the tudat (C++) and the
tudatpy (Python) library.
Specific indications for documenting tudat or tudapy are reported in the tudat-multidoc/README.md file.
The tudat-bundle comprises the following repositories:
tudat, where the tudat source code is located (this is a separate git repository);tudatpy, where the tudatpy binding code is located (this is a separate git repository);tudat-multidoc, where the documentation and the system to build the API is located (this is a separate git repository);cli, where the Python Command Line Interface scripts to build the API are located;
In addition, once the project is built, all the build output will be dumped in the cmake-build-debug directory, which
is not tracked by Git. If the API is also built, more untracked directories will appear, but this is explained in the
tudat-multidoc/README.md file.
- [Windows Users] Windows Subsystem for Linux (WSL)
- All procedures, including the following prerequisite, assume the use of WSL. Power users who wish to do otherwise, must do so at their own risk, with reduced support from the team.
- Note that WSL is a, partially separated, Ubuntu terminal environment for Windows. Anaconda/Miniconda, Python and any other dependencies you require while executing code from the
tudat-bundle, must be installed in its Linux version via the Ubuntu terminal. This does not apply to PyCharm/CLion however, which can be configured to compile and/or run Python code through the WSL. - Note that, to access files and folders of WSL directly in Windows explorer, one can type
\\wsl$orLinuxin the Windows explorer access bar, then press enter. - At the opposite, please follow this guide to access Windows file trough WSL.
- This guide from Microsoft contains more information on the possibilities given trough WSL.
- Anaconda/Miniconda installation (Installing Anaconda)
- Clone the repository and enter directory
git clone https://github.com/tudat-team/tudat-bundle
cd tudat-bundle
Note
Thetudat-bundlerepository uses git submodules, which "allow you to keep a Git repository as a subdirectory of another Git repository" (from the Git guide). In particular, in thetudat-bundlethere are four different subdirectories that are separate repositories:tudat,tudatpy,tudat-multidocandtudat-multidoc/multidoc. Each repository has its own branches and functions separately from the others. This is the reason why the following two steps are needed.
- Clone the
tudat&tudatpysubmodules
git submodule update --init --recursive
- [Optional] Switch
tudat&tudatpyto their desired branches using
cd <tudat/tudatpy>
git checkout <branch-name>
Be advised that the branch from with the Conda packages are built, and that is being maintained the most, is develop.
See here for tudatpy develop branch, and here for tudat develop branch.
It is then recommended to switch to the develop branch using the commands above.
- Install the contained
environment.yamlfile to satisfy dependencies
conda env create -f environment.yaml
Note Are you a Mac user with a M1 processor (a osx-arm64 system)? Then, edit the channels of the
environment.yamlfile as follows, before creating the environment:channels: - https://conda.anaconda.org/conda-forge/osx-arm64 - https://conda.anaconda.org/tudat-team/osx-arm64
There are two directions you can go from here. CLion or the command line.
Note
[Windows Users ∩ CLion Users] In CLion, be sure to set WSL as your Toolchain in
File>Settings>Build, Execution, Deployment>Toolchains.[CLion Users] In CLion, the convention to set CMake arguments is to add them to
File>Settings>Build, Execution, Deployment>CMake Options.
- Open CLion, create a new project from
File > New Projectand select the directory that has been cloned under bullet point 1 (namedtudat-bundle).
Note
To avoid issues with CLion, the directory of the project should correspond exactly to the cloned directory namedtudat-bundle.
- Create a build profile in
File > Settings > Build, Execution, Deployment > CMake.
Note
The CMake configuration optionCMAKE_BUILD_TYPEwill be determined by the the build profile'sBuild typeentry. AReleaseconfiguration will suppress a significant amount of harmless warnings during compilation. Currently, with the move to a later version of boost, some warnings have cropped up that have either not been fixed in the source code, or have not been suppressed viatudat/cmake_modules/compiler.cmake.
- Add the CMake configuration to the
File > Settings > Build, Execution, Deployment > CMake > CMake optionstext box:
-DCMAKE_PREFIX_PATH=<CONDA_PREFIX>
-DCMAKE_CXX_STANDARD=14
-DBoost_NO_BOOST_CMAKE=ON
[Optional] Also add the following line to the File > Settings > Build, Execution, Deployment > CMake > CMake options text box to to build tudatpy with the tests.
-DTUDAT_BUILD_TESTS="${build_tests:-1}"
The following line can also be edited if you wish to build tudatpy with its debug info (switching from Release to RelWithDebInfo; note that Debug is also available):
-DCMAKE_BUILD_TYPE=RelWithDebInfo
Note
TheCONDA_PREFIXmay be determined with by activating the environment installed in step 4 and printing its value:conda activate tudat-bundle && echo $CONDA_PREFIX
[Optional] Add -j<n> to File > Settings > Build, Execution, Deployment > CMake > Build options to use multiple
processors. It is likely that if you use all of your processors, your build will freeze your PC indefinitely. It is
recommended to start at -j2 and work your way up with further builds, ensuring no unsaved work in the background.
-
In the source tree on the left, right click the top level
CMakeLists.txtthenLoad/Reload CMake Project. -
Build > Build Project
- Activate the environment installed in step 4
conda activate tudat-bundle
[Optional] Edit the build.sh script to build tudatpy with the tests by changing the BUILD_TESTS variable:
BUILD_TESTS="${build_tests:-1}"
The following line can also be edited if you wish to build tudatpy with its debug info (switching from Release to RelWithDebInfo; note that Debug is also available):
-DCMAKE_BUILD_TYPE=RelWithDebInfo
As building can take a while, you can build using multiple processors by appending -j4 to the cmake --build . command as seen below, where 4 can be any number that you think your machine can handle. Do note that this can take up a few GB of RAM per processor used, so be aware of the other processes on your machine to avoid freezing or crashing.
cmake --build . -j4
- Run the build.sh script.
bash build.sh
- Enter the
tudatbuild directory
cd <build_directory>/tudat
- Run the tests using
ctest(packaged with CMake)
ctest
Desired result:
..
100% tests passed, 0 tests failed out of 224
Total Test time (real) = 490.77 sec
- Enter the
tudatpybuild directory
cd <build_directory>/tudatpy
- Run the tests using
pytest
pytest
Desired result:
=========================================== 6 passed in 1.78s ============================================
The path of the TudatPy kernel that has been manually compiled needs to be added before importing any tudatpy.kernel module.
This can be done with the following two lines, with <kernel_path> being similar to <tudat-bundle_path>/build/tudatpy:
import sys
sys.path.insert(0, <kernel_path>)
- [All Users] You can increase the number of cores used to compile
tudat&tudatpyusing the-j<n>build argument, but be aware that the current complexity of the libraries can often result in your PC freezing indefinitely.