The UWGeodynamics module facilitates prototyping of geodynamics models using Underworld. It can be seen as a set of high-level functions within the Underworld ecosystem. It is a means to quickly get the user into Underworld modelling and assumes very little knowledge in coding. The module make some assumptions based on how the user defines the boundary conditions and the properties of the materials (rocks, phases). Its simplicity comes with a relatively more rigid workflow (compared to the classic Underworld functions). However, the user can easily break the high level objects and get back to core Underworld function at any step of model design.
The UWGeodynamics is inspired by the [Lithospheric Modelling Recipe (LMR)](https://github.com/LukeMondy/lithospheric_modelling_recipe) originally developed by Luke Mondy, Guillaume Duclaux and Patrice Rey for Underworld 1. Some of the naming conventions have been reused to facilitate the transition from LMR. The Rheological libraries is also taken from LMR.
As we think the low-level interface is more flexible, and in so allows for more complex models, we strongly encourage users to explore and break the High Level functions.
We hope that the user will naturally move to the low-level functionalities as he or her gets more confident, and by doing so will access the wide range of possibilities offered by Underworld.
UWGeodynamics uses the Underworld Application Programming Interface (API). Both projects are supported by The Underworld development team led by Louis Moresi and based in Melbourne, Australia at the University of Melbourne and at Monash University.
Underworld and UWGeodynamics both provide powerful tools to develop numerical geodynamic models. But their approaches are different: UWGeodynamics largely guides users into a way of doing things. The Underworld API provides a series of tools and components (Mesh, Mesh variables, system of equations, functions) and leaves the responsibility to arrange those components to the user. The main advantage of the Underworld API is its flexibility. The main inconvenient resides in a somewhat steeper learning curve. UWGeodynamics components are designed to be more natural to non-experimented numerical modellers or people with little knowledge in programming. It is a way to quickly get started and design numerical models. Developing complex models can also be facilitated by the UWGeodynamics high-level interface as it requires less time and less involvement with the details of the Underworld API.
The two approaches are complementary and mixing the two approaches is possible and highly encouraged.
Since version 1.0 The Underworld development team has decided to match the UWGeodynamics version number with the latest supported version of Underworld. UWGeodynamics v2.7 is then supporing Underworld up to version 2.7.
The third number is used for UWGeodynamics only (v2.7.1, v2.7.2 etc.)
The development branch is based on the current Underworld development branch.
The Current release (DOI citable):
We provide a docker container via binder. This is a quick solution to get you started and run the examples and tutorials without installing anything on your machine. That is a good way to see if the software can actually be useful to you. The ressource are however limited and you should not try to run model with high resolution. 3D models can not be run in the binder.
The full documentation is available on ReadTheDocs
Additional documentation and function specific documentation can be find in the python doctrings.
You can acces them in the Jupyter notebook by prepending or appending the method, variable or function with ?
.
Docker installation
Docker containers provide and easy-way to set up and distribute applications. They also provide a safe and consistent environment which facilitate debugging and reproducibility of models. The image we provide contains all the dependencies and configuration files required to run Underworld models. Users can start developping model as soon as they have downloaded the image, independently of the operating system running on their machine.
We strongly encourage users to run UWGeodynamics using the docker images we provide on Docker Hub
Different version of the underworldcode/uwgeodynamics image can be pulled using a tag:
- The latest tag points to the github master branch and uses the latest underworld release.
- The dev tag points to the github development and uses the development branch of underworld.
- release tags such as v2.7.1 points to a specific version.
Command line
Once you have installed docker on your system you can pull the UWGeodynamics official image as follow:
docker pull underworldcode/uwgeodynamics
You can list all the images available on your system as follow:
docker images
An image can be deleted as follow:
docker rmi underworldcode/uwgeodynamics
You can then start a docker container. (An instance of an image).
docker run -d \
--name my_container \
-p 8888:8888 \
-v $HOME:/home/jovyan/workspace
underworldcode/uwgeodynamics
You can access the container via your browser at the following address: http://localhost:8888. Your directory $HOME should be available at /home/jovyan/workspace.
It is also possible to ssh into the container as follow:
docker exec -it my_container /bin/bash
You can list the containers currently existing on your machine by running:
docker ps -a
The "a" means "all container". The docker ps
command only list
running containers.
Docker containers can be stop (so that they do not use CPU or RAM ressource):
docker stop my_container
They can also be deleted:
docker rm my_container
Warning
It's a good idea to keep track of how many containers have been created as they can rapidly take a lot of space on your machine.
Kitematic is a program that provides a graphical user interface to the docker daemon and to Docker Hub. The software is available for Windows, MacOsx and Linux. Be aware that on linux the installation may differ depending on the distribution you are running.
- Download and Install Kitematic
- Open Kitematic and search for the uwgeodynamics image.
- Create a container by clicking on the create button.
You should now have a container appearing on the left side of your kitematic window. The first thing to do now is to create a link between a local directory (A directory on your physical hard drive) and a volume directory inside the docker container. A volume is a special directory that can be accessed from outside the container. It is the location you will use to save your results.
This is not recommended and involves installing Underworld and all its dependencies. Docker is highly recommended!!!
Requirements
- Python >= 2.7
- A Working version of Underworld2 >=2.6.0 (Please refer to the Underworld documentation)
- pint >= 0.8
Note
The bleeding edge version of Underworld (development branch) is now python 3 compatible only. UWGeodynamics is python 3 ready and can thus be used with it.
Install
from Pip
The UWGeodynamics module can be installed directly from the Python Package Index:
pip install UWGeodynamics
from sources
The module source files are available through github
git clone https://github.com/underworldcode/UWGeodynamics.git
It can then be installed globally on your system using
pip install UWGeodynamics/
Error messages are useful to understand the source of a problem.
If you cannot solve the problem by yourself you can ask for help by creating an issue on GitHub. If the problem if specific to your model you may be ask to continue the conversation through email.
UWGeodynamics is an open source free software and we cannot guarantee that it is free of bugs. Feel free to signal any strange behaviour by raising an issue (see below section on how to contribute.)
If you want to contribute to the UWGeodynamics projects and make it better, your help is very welcome.
So how can you contribute?
- Found a bug? Submit an issue using the issue tracker here on GitHub
- Have some suggestions? You can create an issue. Just add [Feature Request] in the title.
If you have developed some code and you think that it should be included in UWGeodynamics, you can create a Pull Request and We will be happy to review it.
Create a personal fork of the project on Github.
You will need a Github Account to do that. Just click on the Fork button at the top right corner of this repository.
Clone the fork on your local machine. Your remote repo on Github is called origin.
git clone https://github.com/your-github-name/UWGeodynamics
replacing "your-github-name" with your actual github name...
Add the original repository as a remote called upstream.
git remote add upstream https://github.com/underworldcode/UWGeodynamics
If you created your fork a while ago be sure to pull upstream changes into your local repository.
git pull upstream
Create a new branch to work on! Branch from development!
git checkout upstream/development
git checkout -b newFeature
Implement/fix your feature, comment your code.
Follow the code style of the project, including indentation.
Include some tests or usage cases
Add or change the documentation as needed. The UWGeodynamics documentation is located in the docs directory.
Push your branch to your fork on Github, the remote origin.
git push origin newFeature
From your fork open a pull request in the correct branch. Target the project's development.
Always write your commit messages in the present tense. Your commit message should describe what the commit, when applied, does to the code – not what you did to the code.
There is no small contribution!
This program is free software: you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version.
This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License along with this program. If not, see <http://www.gnu.org/licenses/lgpl-3.0.en.html>.