/jobflow

jobflow is a library for writing computational workflows.

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Jobflow

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Jobflow is a free, open-source library for writing and executing workflows. Complex workflows can be defined using simple python functions and executed locally or on arbitrary computing resources using the jobflow-remote or FireWorks workflow managers.

Some features that distinguish jobflow are dynamic workflows, easy compositing and connecting of workflows, and the ability to store workflow outputs across multiple databases.

Is jobflow for me

jobflow is intended to be a friendly workflow software that is easy to get started with, but flexible enough to handle complicated use cases.

Some of its features include:

  • A clean and flexible Python API.
  • A powerful approach to compositing and connecting workflows — information passing between jobs is a key goal of jobflow. Workflows can be nested allowing for a natural way to build complex workflows.
  • Integration with multiple databases (MongoDB, S3, GridFS, and more) through the Maggma package.
  • Support for the jobflow-remote and FireWorks workflow management systems, allowing workflow execution on multicore machines or through a queue, on a single machine or multiple machines.
  • Support for dynamic workflows — workflows that modify themselves or create new ones based on what happens during execution.

Workflow model

Workflows in jobflows are made up of two main components:

  • A Job is an atomic computing job. Essentially any python function can be Job, provided its input and return values can be serialized to json. Anything returned by the job is considered an "output" and is stored in the jobflow database.
  • A Flow is a collection of Job objects or other Flow objects. The connectivity between jobs is determined automatically from the job inputs. The execution order of jobs is automatically determined based on their connectivity.

Python functions can be easily converted in to Job objects using the @job decorator. In the example below, we define a job to add two numbers.

from jobflow import job, Flow

@job
def add(a, b):
    return a + b

add_first = add(1, 5)
add_second = add(add_first.output, 5)

flow = Flow([add_first, add_second])
flow.draw_graph().show()

The output of the job is accessed using the output attribute. As the job has not yet been run, output contains be a reference to a future output. Outputs can be used as inputs to other jobs and will be automatically "resolved" before the job is executed.

Finally, we created a flow using the two Job objects. The connectivity between the jobs is determined automatically and can be visualised using the flow graph.

simple flow graph

Installation

jobflow is a Python 3.9+ library and can be installed using pip.

pip install jobflow

Quickstart and tutorials

To get a first glimpse of jobflow, we suggest that you follow our quickstart tutorial. Later tutorials delve into the advanced features of jobflow.

Need help?

Ask questions about jobflow on the jobflow support forum. If you've found an issue with jobflow, please submit a bug report on GitHub Issues.

What’s new?

Track changes to jobflow through the changelog.

Contributing

We greatly appreciate any contributions in the form of a pull request. Additional information on contributing to jobflow can be found here. We maintain a list of all contributors here.

License

jobflow is released under a modified BSD license; the full text can be found here.

Citation

If you use Jobflow in your work, please cite it as follows:

  • "Jobflow: Computational Workflows Made Simple", A.S. Rosen, M. Gallant, J. George, J. Riebesell, H. Sahasrabuddhe, J.X. Shen, M. Wen, M.L. Evans, G. Petretto, D. Waroquiers, G.‑M. Rignanese, K.A. Persson, A. Jain, A.M. Ganose, Journal of Open Source Software, 9(93), 5995 (2024) DOI: 10.21105/joss.05995

Acknowledgements

Jobflow was designed by Alex Ganose, Anubhav Jain, Gian-Marco Rignanese, David Waroquiers, and Guido Petretto. Alex Ganose implemented the first version of the package. Later versions have benefited from the contributions of several research groups. A full list of contributors is available here.